https://opencommons.org/api.php?action=feedcontributions&feedformat=atom&user=ElisleOpenCommons - User contributions [en]2026-05-12T23:33:27ZUser contributionsMediaWiki 1.43.1https://opencommons.org/index.php?title=Smart_Data_Monitoring_Solution_of_Indoor_Farms&diff=15293Smart Data Monitoring Solution of Indoor Farms2024-12-03T20:38:28Z<p>Elisle: </p>
<hr />
<div>{{ActionCluster<br />
|image=Aquaponics2.jpg<br />
|team=LATERAL<br />
|leader=Ed Lisle<br />
|imagecaption=Aquaponics<br />
|municipalities=Portland OR<br />
|status= Development<br />
|website=https://www.vcpost.com/articles/128663/20241118/lateral-helps-commercial-indoor-farms-thrive-smart-data-monitoring-solution.htm<br />
|download=None<br />
|description=LATERAL.systems LLC, an AgTech startup, has developed the LATERAL Edge Platform, an edge-based monitoring system designed to enhance the efficiency and sustainability of commercial indoor farms. By continuously monitoring water quality and atmospheric conditions, the platform helps farmers detect and respond to potential imbalances before they cause significant crop damage, reducing waste and increasing yields. The system offers customizable Grow Profiles for various crops and provides real-time alerts, alarms, and actionable mediation options, making it particularly valuable for addressing the challenges faced by novice farm workers. Unlike cloud-based solutions, LATERAL’s edge-based approach ensures reliable data processing even in areas with limited internet connectivity, lowers operational costs, and improves data security. With its innovative tools, LATERAL aims to democratize access to smart monitoring solutions, support food security, and advance the growing indoor farming industry.<br />
|challenges=The LATERAL Edge Platform addresses challenges in the commercial indoor farming industry, including the rapid onset of imbalances that can damage crops within hours, a largely inexperienced workforce struggling to interpret and act on monitoring data, and the lack of reliable internet connectivity on many farms. Traditional manual monitoring methods are inadequate for detecting early warning signs, leading to unnecessary food waste in an industry critical to addressing global food insecurity. Furthermore, the high cost and data latency of existing cloud-based solutions create barriers to widespread adoption, particularly for smaller or resource-constrained farms. Overcoming these challenges requires not only developing accessible, edge-based technology but also designing intuitive systems that train workers to understand data patterns, make informed decisions, and retain knowledge to improve long-term farm productivity.<br />
|solutions=The LATERAL Edge Platform provides a cutting-edge solution to the challenges faced by commercial indoor farms through an edge-based monitoring system that continuously tracks water quality and atmospheric conditions in real time. By locating data collection, storage, and analytics at the source, the platform eliminates the need for high-speed internet, reduces data latency, and ensures cost-effective and secure operations. Its customizable Grow Profiles enable farmers to tailor monitoring parameters to specific crops, offering early alerts and actionable mediation options to prevent crop damage and optimize yields. Additionally, the platform incorporates intuitive dashboards with visual data trends and scaffolding tools to support worker training and retention, fostering a skilled workforce capable of making data-driven decisions. This comprehensive approach not only reduces waste and increases farm efficiency but also democratizes access to advanced AgTech solutions for farms of all sizes.<br />
|requirements=The LATERAL Edge Platform requires the development and deployment of modular, interoperable sensor hardware and software capable of continuously monitoring water quality and atmospheric conditions in commercial indoor farms. It necessitates an edge-computing framework to process, store, and analyze data locally, ensuring functionality in environments with limited or unreliable internet connectivity. The system must support customizable Grow Profiles for various crops, provide real-time alerts and mediation options, and feature an intuitive dashboard with visual data trends to assist farmers and train novice workers. Additionally, the project demands a secure and cost-effective design that minimizes operational costs while addressing scalability to meet the needs of diverse indoor farming operations.<br />
|kpi=*System Uptime<br />
*Alert Responsiveness<br />
*Crop Yield Improvement<br />
*Waste Reduction<br />
*Worker Retention Rate<br />
*Adoption of Custom Grow Profiles<br />
*System Cost Efficiency<br />
*Farmer Satisfaction<br />
*Data Accuracy<br />
*Market Penetration<br />
|measurement=* Percentage of time the monitoring system operates without failure (target: 99.9% uptime).<br />
* Average time from detection of an anomaly to delivery of an alert to the farmer (target: < 2 seconds for critical alerts).<br />
* Percentage increase in crop yield per unit area compared to farms using manual monitoring (target: 10–20% improvement).<br />
* Reduction in the percentage of crop loss due to imbalances or undetected issues (target: 30–50% reduction).<br />
* Percentage of new farm workers retained beyond 90 days (target: increase from 60% to 80%).<br />
* Number of new Custom Grow Profiles created by farmers within six months of deployment (target: >50 profiles).<br />
* Total operational cost savings compared to cloud-based solutions (target: 20–30% reduction in data storage and analytics costs).<br />
* Percentage of surveyed users reporting improved ease of farm management and decision-making (target: 85% satisfaction rate).<br />
* Percentage accuracy of sensor data readings compared to laboratory-calibrated instruments (target: >95% accuracy).<br />
* Number of farms adopting the system within the first year post-launch (target: 50–100 farms).<br />
|standards=The hardware components comply with environmental durability standards such as IP65 for water and dust resistance, while the sensors align with ISO calibration standards for accuracy in water quality and atmospheric monitoring. The edge computing framework incorporates software architecture that follows IoT interoperability standards like MQTT and OPC-UA for seamless integration with existing farm systems. Usability design standards, including ISO 9241 for ergonomics, guide the development of intuitive dashboards that support user training and operational efficiency. Together, these standards ensure a robust, secure, and user-friendly system tailored to the unique demands of indoor farming.<br />
|cybersecurity=The LATERAL Edge Platform's cybersecurity requirements focus on ensuring the confidentiality, integrity, and availability of critical farm data. <br />
|impacts=The LATERAL Edge Platform has transformative impacts on commercial indoor farming, enhancing food security and sustainability. By providing real-time monitoring and early alerts, the system reduces crop losses, minimizes waste, and increases yields, contributing to more efficient food production. Its edge-based design democratizes access to advanced AgTech solutions, enabling farms in remote or underserved areas to benefit from automated monitoring without reliance on high-speed internet. The platform also fosters workforce development by equipping novice workers with tools and insights to interpret data, improving retention rates and cultivating a skilled agricultural workforce. Additionally, the reduction in water and fertilizer usage aligns with environmental sustainability goals, while cost savings from local data processing and increased farm efficiency improve profitability. Overall, the project supports resilient food systems, reduces food waste, and contributes to the economic viability of indoor farming.<br />
|demonstration=A demonstration could involve showcasing these features in a controlled indoor farming environment, illustrating how the platform detects and resolves imbalances, improves crop yields, and supports worker training. To confirm whether a formal demonstration exists, interested parties are encouraged to contact LATERAL.systems LLC through their website<br />
|chapter=Precision Farming<br />
|supercluster=Agriculture<br />
|year=2022, 2023,2024<br />
}}</div>Elislehttps://opencommons.org/index.php?title=Smart_Data_Monitoring_Solution_of_Indoor_Farms&diff=15292Smart Data Monitoring Solution of Indoor Farms2024-12-03T20:30:23Z<p>Elisle: </p>
<hr />
<div>{{ActionCluster<br />
|image=Aquaponics2.jpg<br />
|team=LATERAL<br />
|leader=Ed Lisle<br />
|imagecaption=Aquaponics<br />
|municipalities=Portland OR<br />
|status= Development<br />
|website=https://www.vcpost.com/articles/128663/20241118/lateral-helps-commercial-indoor-farms-thrive-smart-data-monitoring-solution.htm<br />
|download=None<br />
|description=LATERAL.systems LLC, an AgTech startup, has developed the LATERAL Edge Platform, an edge-based monitoring system designed to enhance the efficiency and sustainability of commercial indoor farms. By continuously monitoring water quality and atmospheric conditions, the platform helps farmers detect and respond to potential imbalances before they cause significant crop damage, reducing waste and increasing yields. The system offers customizable Grow Profiles for various crops and provides real-time alerts, alarms, and actionable mediation options, making it particularly valuable for addressing the challenges faced by novice farm workers. Unlike cloud-based solutions, LATERAL’s edge-based approach ensures reliable data processing even in areas with limited internet connectivity, lowers operational costs, and improves data security. With its innovative tools, LATERAL aims to democratize access to smart monitoring solutions, support food security, and advance the growing indoor farming industry.<br />
|challenges=The LATERAL Edge Platform addresses challenges in the commercial indoor farming industry, including the rapid onset of imbalances that can damage crops within hours, a largely inexperienced workforce struggling to interpret and act on monitoring data, and the lack of reliable internet connectivity on many farms. Traditional manual monitoring methods are inadequate for detecting early warning signs, leading to unnecessary food waste in an industry critical to addressing global food insecurity. Furthermore, the high cost and data latency of existing cloud-based solutions create barriers to widespread adoption, particularly for smaller or resource-constrained farms. Overcoming these challenges requires not only developing accessible, edge-based technology but also designing intuitive systems that train workers to understand data patterns, make informed decisions, and retain knowledge to improve long-term farm productivity.<br />
|solutions=The LATERAL Edge Platform provides a cutting-edge solution to the challenges faced by commercial indoor farms through an edge-based monitoring system that continuously tracks water quality and atmospheric conditions in real time. By locating data collection, storage, and analytics at the source, the platform eliminates the need for high-speed internet, reduces data latency, and ensures cost-effective and secure operations. Its customizable Grow Profiles enable farmers to tailor monitoring parameters to specific crops, offering early alerts and actionable mediation options to prevent crop damage and optimize yields. Additionally, the platform incorporates intuitive dashboards with visual data trends and scaffolding tools to support worker training and retention, fostering a skilled workforce capable of making data-driven decisions. This comprehensive approach not only reduces waste and increases farm efficiency but also democratizes access to advanced AgTech solutions for farms of all sizes.<br />
|requirements=The LATERAL Edge Platform requires the development and deployment of modular, interoperable sensor hardware and software capable of continuously monitoring water quality and atmospheric conditions in commercial indoor farms. It necessitates an edge-computing framework to process, store, and analyze data locally, ensuring functionality in environments with limited or unreliable internet connectivity. The system must support customizable Grow Profiles for various crops, provide real-time alerts and mediation options, and feature an intuitive dashboard with visual data trends to assist farmers and train novice workers. Additionally, the project demands a secure and cost-effective design that minimizes operational costs while addressing scalability to meet the needs of diverse indoor farming operations.<br />
|kpi=*System Uptime<br />
*Alert Responsiveness<br />
*Crop Yield Improvement<br />
*Waste Reduction<br />
*Worker Retention Rate<br />
*Adoption of Custom Grow Profiles<br />
*System Cost Efficiency<br />
*Farmer Satisfaction<br />
*Data Accuracy<br />
*Market Penetration<br />
|measurement=* Percentage of time the monitoring system operates without failure (target: 99.9% uptime).<br />
* Average time from detection of an anomaly to delivery of an alert to the farmer (target: < 2 seconds for critical alerts).<br />
* Percentage increase in crop yield per unit area compared to farms using manual monitoring (target: 10–20% improvement).<br />
* Reduction in the percentage of crop loss due to imbalances or undetected issues (target: 30–50% reduction).<br />
* Percentage of new farm workers retained beyond 90 days (target: increase from 60% to 80%).<br />
* Number of new Custom Grow Profiles created by farmers within six months of deployment (target: >50 profiles).<br />
* Total operational cost savings compared to cloud-based solutions (target: 20–30% reduction in data storage and analytics costs).<br />
* Percentage of surveyed users reporting improved ease of farm management and decision-making (target: 85% satisfaction rate).<br />
* Percentage accuracy of sensor data readings compared to laboratory-calibrated instruments (target: >95% accuracy).<br />
* Number of farms adopting the system within the first year post-launch (target: 50–100 farms).<br />
|standards=The hardware components comply with environmental durability standards such as IP65 for water and dust resistance, while the sensors align with ISO calibration standards for accuracy in water quality and atmospheric monitoring. The edge computing framework incorporates cybersecurity protocols such as AES-256 encryption to safeguard data integrity and confidentiality. Additionally, the software architecture follows IoT interoperability standards like MQTT and OPC-UA for seamless integration with existing farm systems. Usability design standards, including ISO 9241 for ergonomics, guide the development of intuitive dashboards that support user training and operational efficiency. Together, these standards ensure a robust, secure, and user-friendly system tailored to the unique demands of indoor farming.<br />
|cybersecurity=The LATERAL Edge Platform's cybersecurity requirements focus on ensuring the confidentiality, integrity, and availability of critical farm data. The system must incorporate robust encryption protocols, such as AES-256, to protect data at rest and in transit. User authentication must include multi-factor authentication (MFA) and role-based access controls to prevent unauthorized access. The edge-based architecture requires secure boot processes, firmware integrity checks, and tamper detection to safeguard hardware against physical and software attacks. Regular vulnerability assessments and compliance with cybersecurity standards like NIST Cybersecurity Framework or ISO 27001 are necessary to address potential threats. Additionally, secure communication protocols like TLS/SSL must be implemented for data transmission between sensors, edge devices, and user interfaces, minimizing risks of interception or tampering. These measures collectively ensure the system remains resilient against cyber threats, protecting both farm operations and sensitive data.<br />
|impacts=The LATERAL Edge Platform has transformative impacts on commercial indoor farming, enhancing food security and sustainability. By providing real-time monitoring and early alerts, the system reduces crop losses, minimizes waste, and increases yields, contributing to more efficient food production. Its edge-based design democratizes access to advanced AgTech solutions, enabling farms in remote or underserved areas to benefit from automated monitoring without reliance on high-speed internet. The platform also fosters workforce development by equipping novice workers with tools and insights to interpret data, improving retention rates and cultivating a skilled agricultural workforce. Additionally, the reduction in water and fertilizer usage aligns with environmental sustainability goals, while cost savings from local data processing and increased farm efficiency improve profitability. Overall, the project supports resilient food systems, reduces food waste, and contributes to the economic viability of indoor farming.<br />
|demonstration=A demonstration could involve showcasing these features in a controlled indoor farming environment, illustrating how the platform detects and resolves imbalances, improves crop yields, and supports worker training. To confirm whether a formal demonstration exists, interested parties are encouraged to contact LATERAL.systems LLC through their website<br />
|chapter=Precision Farming<br />
|supercluster=Agriculture<br />
|year=2022, 2023,2024<br />
}}</div>Elislehttps://opencommons.org/index.php?title=Smart_Data_Monitoring_Solution_of_Indoor_Farms&diff=15291Smart Data Monitoring Solution of Indoor Farms2024-12-03T20:29:51Z<p>Elisle: </p>
<hr />
<div>{{ActionCluster<br />
|image=Aquaponics2.jpg<br />
|team=LATERAL<br />
|leader=Ed Lisle<br />
|imagecaption=Aquaponics<br />
|municipalities=Portland OR<br />
|status=Early Startup Stage<br />
|website=https://www.vcpost.com/articles/128663/20241118/lateral-helps-commercial-indoor-farms-thrive-smart-data-monitoring-solution.htm<br />
|download=None<br />
|description=LATERAL.systems LLC, an AgTech startup, has developed the LATERAL Edge Platform, an edge-based monitoring system designed to enhance the efficiency and sustainability of commercial indoor farms. By continuously monitoring water quality and atmospheric conditions, the platform helps farmers detect and respond to potential imbalances before they cause significant crop damage, reducing waste and increasing yields. The system offers customizable Grow Profiles for various crops and provides real-time alerts, alarms, and actionable mediation options, making it particularly valuable for addressing the challenges faced by novice farm workers. Unlike cloud-based solutions, LATERAL’s edge-based approach ensures reliable data processing even in areas with limited internet connectivity, lowers operational costs, and improves data security. With its innovative tools, LATERAL aims to democratize access to smart monitoring solutions, support food security, and advance the growing indoor farming industry.<br />
|challenges=The LATERAL Edge Platform addresses challenges in the commercial indoor farming industry, including the rapid onset of imbalances that can damage crops within hours, a largely inexperienced workforce struggling to interpret and act on monitoring data, and the lack of reliable internet connectivity on many farms. Traditional manual monitoring methods are inadequate for detecting early warning signs, leading to unnecessary food waste in an industry critical to addressing global food insecurity. Furthermore, the high cost and data latency of existing cloud-based solutions create barriers to widespread adoption, particularly for smaller or resource-constrained farms. Overcoming these challenges requires not only developing accessible, edge-based technology but also designing intuitive systems that train workers to understand data patterns, make informed decisions, and retain knowledge to improve long-term farm productivity.<br />
|solutions=The LATERAL Edge Platform provides a cutting-edge solution to the challenges faced by commercial indoor farms through an edge-based monitoring system that continuously tracks water quality and atmospheric conditions in real time. By locating data collection, storage, and analytics at the source, the platform eliminates the need for high-speed internet, reduces data latency, and ensures cost-effective and secure operations. Its customizable Grow Profiles enable farmers to tailor monitoring parameters to specific crops, offering early alerts and actionable mediation options to prevent crop damage and optimize yields. Additionally, the platform incorporates intuitive dashboards with visual data trends and scaffolding tools to support worker training and retention, fostering a skilled workforce capable of making data-driven decisions. This comprehensive approach not only reduces waste and increases farm efficiency but also democratizes access to advanced AgTech solutions for farms of all sizes.<br />
|requirements=The LATERAL Edge Platform requires the development and deployment of modular, interoperable sensor hardware and software capable of continuously monitoring water quality and atmospheric conditions in commercial indoor farms. It necessitates an edge-computing framework to process, store, and analyze data locally, ensuring functionality in environments with limited or unreliable internet connectivity. The system must support customizable Grow Profiles for various crops, provide real-time alerts and mediation options, and feature an intuitive dashboard with visual data trends to assist farmers and train novice workers. Additionally, the project demands a secure and cost-effective design that minimizes operational costs while addressing scalability to meet the needs of diverse indoor farming operations.<br />
|kpi=*System Uptime<br />
*Alert Responsiveness<br />
*Crop Yield Improvement<br />
*Waste Reduction<br />
*Worker Retention Rate<br />
*Adoption of Custom Grow Profiles<br />
*System Cost Efficiency<br />
*Farmer Satisfaction<br />
*Data Accuracy<br />
*Market Penetration<br />
|measurement=* Percentage of time the monitoring system operates without failure (target: 99.9% uptime).<br />
* Average time from detection of an anomaly to delivery of an alert to the farmer (target: < 2 seconds for critical alerts).<br />
* Percentage increase in crop yield per unit area compared to farms using manual monitoring (target: 10–20% improvement).<br />
* Reduction in the percentage of crop loss due to imbalances or undetected issues (target: 30–50% reduction).<br />
* Percentage of new farm workers retained beyond 90 days (target: increase from 60% to 80%).<br />
* Number of new Custom Grow Profiles created by farmers within six months of deployment (target: >50 profiles).<br />
* Total operational cost savings compared to cloud-based solutions (target: 20–30% reduction in data storage and analytics costs).<br />
* Percentage of surveyed users reporting improved ease of farm management and decision-making (target: 85% satisfaction rate).<br />
* Percentage accuracy of sensor data readings compared to laboratory-calibrated instruments (target: >95% accuracy).<br />
* Number of farms adopting the system within the first year post-launch (target: 50–100 farms).<br />
|standards=The hardware components comply with environmental durability standards such as IP65 for water and dust resistance, while the sensors align with ISO calibration standards for accuracy in water quality and atmospheric monitoring. The edge computing framework incorporates cybersecurity protocols such as AES-256 encryption to safeguard data integrity and confidentiality. Additionally, the software architecture follows IoT interoperability standards like MQTT and OPC-UA for seamless integration with existing farm systems. Usability design standards, including ISO 9241 for ergonomics, guide the development of intuitive dashboards that support user training and operational efficiency. Together, these standards ensure a robust, secure, and user-friendly system tailored to the unique demands of indoor farming.<br />
|cybersecurity=The LATERAL Edge Platform's cybersecurity requirements focus on ensuring the confidentiality, integrity, and availability of critical farm data. The system must incorporate robust encryption protocols, such as AES-256, to protect data at rest and in transit. User authentication must include multi-factor authentication (MFA) and role-based access controls to prevent unauthorized access. The edge-based architecture requires secure boot processes, firmware integrity checks, and tamper detection to safeguard hardware against physical and software attacks. Regular vulnerability assessments and compliance with cybersecurity standards like NIST Cybersecurity Framework or ISO 27001 are necessary to address potential threats. Additionally, secure communication protocols like TLS/SSL must be implemented for data transmission between sensors, edge devices, and user interfaces, minimizing risks of interception or tampering. These measures collectively ensure the system remains resilient against cyber threats, protecting both farm operations and sensitive data.<br />
|impacts=The LATERAL Edge Platform has transformative impacts on commercial indoor farming, enhancing food security and sustainability. By providing real-time monitoring and early alerts, the system reduces crop losses, minimizes waste, and increases yields, contributing to more efficient food production. Its edge-based design democratizes access to advanced AgTech solutions, enabling farms in remote or underserved areas to benefit from automated monitoring without reliance on high-speed internet. The platform also fosters workforce development by equipping novice workers with tools and insights to interpret data, improving retention rates and cultivating a skilled agricultural workforce. Additionally, the reduction in water and fertilizer usage aligns with environmental sustainability goals, while cost savings from local data processing and increased farm efficiency improve profitability. Overall, the project supports resilient food systems, reduces food waste, and contributes to the economic viability of indoor farming.<br />
|demonstration=A demonstration could involve showcasing these features in a controlled indoor farming environment, illustrating how the platform detects and resolves imbalances, improves crop yields, and supports worker training. To confirm whether a formal demonstration exists, interested parties are encouraged to contact LATERAL.systems LLC through their website<br />
|chapter=Precision Farming<br />
|supercluster=Agriculture<br />
|year=2022, 2023,2024<br />
}}</div>Elislehttps://opencommons.org/index.php?title=Smart_Data_Monitoring_Solution_of_Indoor_Farms&diff=15290Smart Data Monitoring Solution of Indoor Farms2024-12-03T20:29:21Z<p>Elisle: </p>
<hr />
<div>{{ActionCluster<br />
|image=Aquaponics2.jpg<br />
|team=LATERAL<br />
|leader=Ed Lisle<br />
|imagecaption=Aquaponics<br />
|municipalities=Portland OR<br />
|status=Launched<br />
|website=https://www.vcpost.com/articles/128663/20241118/lateral-helps-commercial-indoor-farms-thrive-smart-data-monitoring-solution.htm<br />
|download=None<br />
|description=LATERAL.systems LLC, an AgTech startup, has developed the LATERAL Edge Platform, an edge-based monitoring system designed to enhance the efficiency and sustainability of commercial indoor farms. By continuously monitoring water quality and atmospheric conditions, the platform helps farmers detect and respond to potential imbalances before they cause significant crop damage, reducing waste and increasing yields. The system offers customizable Grow Profiles for various crops and provides real-time alerts, alarms, and actionable mediation options, making it particularly valuable for addressing the challenges faced by novice farm workers. Unlike cloud-based solutions, LATERAL’s edge-based approach ensures reliable data processing even in areas with limited internet connectivity, lowers operational costs, and improves data security. With its innovative tools, LATERAL aims to democratize access to smart monitoring solutions, support food security, and advance the growing indoor farming industry.<br />
|challenges=The LATERAL Edge Platform addresses challenges in the commercial indoor farming industry, including the rapid onset of imbalances that can damage crops within hours, a largely inexperienced workforce struggling to interpret and act on monitoring data, and the lack of reliable internet connectivity on many farms. Traditional manual monitoring methods are inadequate for detecting early warning signs, leading to unnecessary food waste in an industry critical to addressing global food insecurity. Furthermore, the high cost and data latency of existing cloud-based solutions create barriers to widespread adoption, particularly for smaller or resource-constrained farms. Overcoming these challenges requires not only developing accessible, edge-based technology but also designing intuitive systems that train workers to understand data patterns, make informed decisions, and retain knowledge to improve long-term farm productivity.<br />
|solutions=The LATERAL Edge Platform provides a cutting-edge solution to the challenges faced by commercial indoor farms through an edge-based monitoring system that continuously tracks water quality and atmospheric conditions in real time. By locating data collection, storage, and analytics at the source, the platform eliminates the need for high-speed internet, reduces data latency, and ensures cost-effective and secure operations. Its customizable Grow Profiles enable farmers to tailor monitoring parameters to specific crops, offering early alerts and actionable mediation options to prevent crop damage and optimize yields. Additionally, the platform incorporates intuitive dashboards with visual data trends and scaffolding tools to support worker training and retention, fostering a skilled workforce capable of making data-driven decisions. This comprehensive approach not only reduces waste and increases farm efficiency but also democratizes access to advanced AgTech solutions for farms of all sizes.<br />
|requirements=The LATERAL Edge Platform requires the development and deployment of modular, interoperable sensor hardware and software capable of continuously monitoring water quality and atmospheric conditions in commercial indoor farms. It necessitates an edge-computing framework to process, store, and analyze data locally, ensuring functionality in environments with limited or unreliable internet connectivity. The system must support customizable Grow Profiles for various crops, provide real-time alerts and mediation options, and feature an intuitive dashboard with visual data trends to assist farmers and train novice workers. Additionally, the project demands a secure and cost-effective design that minimizes operational costs while addressing scalability to meet the needs of diverse indoor farming operations.<br />
|kpi=*System Uptime<br />
*Alert Responsiveness<br />
*Crop Yield Improvement<br />
*Waste Reduction<br />
*Worker Retention Rate<br />
*Adoption of Custom Grow Profiles<br />
*System Cost Efficiency<br />
*Farmer Satisfaction<br />
*Data Accuracy<br />
*Market Penetration<br />
|measurement=* Percentage of time the monitoring system operates without failure (target: 99.9% uptime).<br />
* Average time from detection of an anomaly to delivery of an alert to the farmer (target: < 2 seconds for critical alerts).<br />
* Percentage increase in crop yield per unit area compared to farms using manual monitoring (target: 10–20% improvement).<br />
* Reduction in the percentage of crop loss due to imbalances or undetected issues (target: 30–50% reduction).<br />
* Percentage of new farm workers retained beyond 90 days (target: increase from 60% to 80%).<br />
* Number of new Custom Grow Profiles created by farmers within six months of deployment (target: >50 profiles).<br />
* Total operational cost savings compared to cloud-based solutions (target: 20–30% reduction in data storage and analytics costs).<br />
* Percentage of surveyed users reporting improved ease of farm management and decision-making (target: 85% satisfaction rate).<br />
* Percentage accuracy of sensor data readings compared to laboratory-calibrated instruments (target: >95% accuracy).<br />
* Number of farms adopting the system within the first year post-launch (target: 50–100 farms).<br />
|standards=The hardware components comply with environmental durability standards such as IP65 for water and dust resistance, while the sensors align with ISO calibration standards for accuracy in water quality and atmospheric monitoring. The edge computing framework incorporates cybersecurity protocols such as AES-256 encryption to safeguard data integrity and confidentiality. Additionally, the software architecture follows IoT interoperability standards like MQTT and OPC-UA for seamless integration with existing farm systems. Usability design standards, including ISO 9241 for ergonomics, guide the development of intuitive dashboards that support user training and operational efficiency. Together, these standards ensure a robust, secure, and user-friendly system tailored to the unique demands of indoor farming.<br />
|cybersecurity=The LATERAL Edge Platform's cybersecurity requirements focus on ensuring the confidentiality, integrity, and availability of critical farm data. The system must incorporate robust encryption protocols, such as AES-256, to protect data at rest and in transit. User authentication must include multi-factor authentication (MFA) and role-based access controls to prevent unauthorized access. The edge-based architecture requires secure boot processes, firmware integrity checks, and tamper detection to safeguard hardware against physical and software attacks. Regular vulnerability assessments and compliance with cybersecurity standards like NIST Cybersecurity Framework or ISO 27001 are necessary to address potential threats. Additionally, secure communication protocols like TLS/SSL must be implemented for data transmission between sensors, edge devices, and user interfaces, minimizing risks of interception or tampering. These measures collectively ensure the system remains resilient against cyber threats, protecting both farm operations and sensitive data.<br />
|impacts=The LATERAL Edge Platform has transformative impacts on commercial indoor farming, enhancing food security and sustainability. By providing real-time monitoring and early alerts, the system reduces crop losses, minimizes waste, and increases yields, contributing to more efficient food production. Its edge-based design democratizes access to advanced AgTech solutions, enabling farms in remote or underserved areas to benefit from automated monitoring without reliance on high-speed internet. The platform also fosters workforce development by equipping novice workers with tools and insights to interpret data, improving retention rates and cultivating a skilled agricultural workforce. Additionally, the reduction in water and fertilizer usage aligns with environmental sustainability goals, while cost savings from local data processing and increased farm efficiency improve profitability. Overall, the project supports resilient food systems, reduces food waste, and contributes to the economic viability of indoor farming.<br />
|demonstration=A demonstration could involve showcasing these features in a controlled indoor farming environment, illustrating how the platform detects and resolves imbalances, improves crop yields, and supports worker training. To confirm whether a formal demonstration exists, interested parties are encouraged to contact LATERAL.systems LLC through their website<br />
|chapter=Precision Farming<br />
|supercluster=Agriculture<br />
|year=2022, 2023,2024<br />
}}</div>Elislehttps://opencommons.org/index.php?title=Regenerative_Agriculture&diff=11275Regenerative Agriculture2022-12-02T10:04:23Z<p>Elisle: </p>
<hr />
<div>{{Chapter<br />
|image=SmartAgBanner.jpg<br />
|poc=Ed Lisle<br />
|authors=Jennifer Wells,Ed Lisle<br />
|blueprint=Agriculture<br />
|chapter=612<br />
|sectors=Agriculture<br />
|summary='''REGENERATIVE AGRICULTURE''' (''RegenAG'') involves shifting from a carbon intensive food system to carbon-negative agriculture that restores rather than degrades ecosystems. While there is no globally accepted definition, this term is widely accepted to refer to integrated systems of farming, ranching, and pastoral practices that contribute to stabilizing the planet’s climate and carbon cycles by rehabilitating and safeguarding biodiversity and living systems.}}<br />
<br />
A shift to Regenerative Agriculture signals a radical transformation of how, where and when we grow food, a great expansion of the varieties of seeds grown and a new microclimate-based approach focusing on smallholder farms, intercropping, agroforestry and micro-farming industry strategies. For example, the use of cover crops, crop rotation, and no till practices, reducing use or elimination of synthetic inputs, and employing integrated crop and livestock systems and managed grazing have long since been recognized as sustainable farming practices. <br />
<br />
At the same time, new approaches are under development and ancient practices reinvented, some of which are up for debate as to whether or not they fall under the Regenerative Agriculture umbrella. For instance, while there is some debate about inclusion of soilless agriculture under the Regenerative Agriculture umbrella, there is growing consensus that organic soilless methods such as aquaponics (''involving cultivation of fish that fertilize plants in interconnected, contained systems'') represent promising, sustainable approaches to growing more with less water and energy and little to no pollution. <br />
<br />
'''United Nations Sustainable Development Goals'''<br />
<br />
The United Nations Sustainable Development Goal 2 is focused on creating a world free of hunger by 2030 by improving food security, nutrition and promoting sustainable agriculture. Of the 8 billion people living today, only three-quarters of us are receiving adequate nutrition. One billion people experience chronic hunger and as our population grows, more and more people are expected to experience food insecurity. It is starkly apparent that current industrial farming practices that squander and degrade the very resources they depend on cannot continue unchanged. Industrial agricultural practices are producing an estimated 21–37% of annual emissions of the three largest individual contributors to global warming gasses, carbon dioxide, methane, and nitrous oxide, and using 70% of the fresh water available on our planet (United Nations Food and Agriculture Organization, 2022). Clearly a large conservation and restoration effort is essential if we are to provide nutrition for an anticipated population of 10 billion by 2050, which is precisely what the Regenerative Agriculture movement seeks to enable.<br />
<br />
Obviously no single solution is capable of fulfilling this lofty goal. A decade ago in 2012, the United Nations Conference on Sustainable Development (UNCSD), known as Rio+20, produced an outcome document that called for achieving a land-degradation-neutral world in the context of sustainable development. Given the current extent of land degradation globally, the potential benefits from land restoration for food security and for mitigating climate change are enormous. While it is true that scientific understanding of the drivers of desertification, land degradation and drought is still evolving, advocates of Regenerative Agriculture point out that these crises actually create new opportunities for increasing food security, carbon storage and climate resiliency. <br />
<br />
Regenerative Agriculture approaches are already being implemented to varying degrees across our agricultural system, while others are newly emerging. Globally, movement is underway to return to native crops specifically adapted to variations in the local climate and to greatly increase the natural fertility and carbon sequestration potential of degraded soils. Nations such as Niger, with some of the most degraded soils on the planet, are demonstrating how restoration can be accomplished – restoring an astonishing 5 million hectares to productivity in the Sahel. Private/public partnerships such as the agroforestry project in inner Mongolia’s Kubuqi Desert, have restored approximately one-third of 18,600 sq km of sand dunes and in Mali, restoration has created forest plots with higher biomass than even native forests.<br />
<br />
'''Key Trends Pushing Forward Regenerative Ag Practice Adoption'''<br />
<br />
# Data and the Digital Ag Revolution <br />
# Biologicals<br />
# Carbon / Climate - Smart Commodities<br />
<br />
'''Emerging Digital AG Revolution Solutions'''<br />
<br />
A body of scientific literature is now emerging that presents numerous strategies to decouple food production from land area, enabling increased food productivity and nutrition on the current agricultural footprint. A few examples of solutions related to data and the digital ag revolution and smart communities include:<br />
<br />
* Integrating AI enabled predictive analytics within indoor growing environments to precisely control growing variables in response to biotic and chemical signals at different stages of the growth cycle to reduce resource consumption and waste while maximizing rapid plant growth. <br />
* Deploying controlled growing environments near to where produce is sold and consumed to drastically reduce travel time, resource consumption, pollution, and shipping costs to deliver fresher, nutrient-dense food that tastes better.<br />
* Utilizing AI solutions for optimized outdoor crop placement <br />
* IoT solutions such as robots, drones, remote sensors, and computer imaging combined with continuously progressing machine learning and analytical tools for monitoring crops, surveying, and mapping the fields, and providing data to farmers for rational farm management plans to save both time and money.<br />
* Employing block-chain tracking to improve traceability of food to appeal to location-conscious buyers (sometimes called locavores), who are having an important impact on food sourcing, including the popularity of farmers markets. <br />
<br />
'''OpenCommons Embraces The Formation Of A RegenAG Community: Call For Action'''<br />
<br />
The purpose of this RegenAg/AgTech partnership with OpenCommons is to cultivate a collaborative community to advance promising smart technologies for urban and rural regenerative agriculture solutions.<br />
<br />
=Demonstration Projects=<br />
{{#ask: <br />
[[Category:Activity]]<br />
[[Has tag::Regenerative Agriculture]]<br />
|?=#<br />
|?Has image#=2<br />
|?Has description#=3<br />
|format=plainlist<br />
|named args=yes<br />
|introtemplate=Show image Header<br />
|template=Show image<br />
|outrotemplate=Show link Footer<br />
}}<br />
=News=<br />
{{#ask: <br />
[[Category:News]]<br />
[[Has tag::Regenerative Agriculture]]<br />
|?=#<br />
|?Has image#=2<br />
|?Has summary#=3<br />
|format=plainlist<br />
|named args=yes<br />
|introtemplate=Show image Header<br />
|template=Show image<br />
|outrotemplate=Show link Footer<br />
}}</div>Elislehttps://opencommons.org/index.php?title=Regenerative_Agriculture&diff=11267Regenerative Agriculture2022-12-02T04:06:28Z<p>Elisle: </p>
<hr />
<div>{{Chapter<br />
|image=Smart-agriculture-iot-with-hand-planting-tree-background.tiff<br />
|poc=Ed Lisle<br />
|authors=Jennifer Wells,Ed Lisle<br />
|blueprint=Agriculture<br />
|chapter=612<br />
|sectors=Agriculture<br />
|summary='''REGENERATIVE AGRICULTURE''' (''RegenAG'') involves shifting from a carbon intensive food system to carbon-negative agriculture that restores rather than degrades ecosystems. While there is no globally accepted definition, this term is widely accepted to refer to integrated systems of farming, ranching, and pastoral practices that contribute to stabilizing the planet’s climate and carbon cycles by rehabilitating and safeguarding biodiversity and living systems.<br />
<br />
A shift to Regenerative Agriculture signals a radical transformation of how, where and when we grow food, a great expansion of the varieties of seeds grown and a new microclimate-based approach focusing on smallholder farms, intercropping, agroforestry and micro-farming industry strategies. For example, the use of cover crops, crop rotation, and no till practices, reducing use or elimination of synthetic inputs, and employing integrated crop and livestock systems and managed grazing have long since been recognized as sustainable farming practices. <br />
<br />
At the same time, new approaches are under development and ancient practices reinvented, some of which are up for debate as to whether or not they fall under the Regenerative Agriculture umbrella. For instance, while there is some debate about inclusion of soilless agriculture under the Regenerative Agriculture umbrella, there is growing consensus that organic soilless methods such as aquaponics (''involving cultivation of fish that fertilize plants in interconnected, contained systems'') represent promising, sustainable approaches to growing more with less water and energy and little to no pollution. <br />
<br />
'''United Nations Sustainable Development Goals'''<br />
<br />
The United Nations Sustainable Development Goal 2 is focused on creating a world free of hunger by 2030 by improving food security, nutrition and promoting sustainable agriculture. Of the 8 billion people living today, only three-quarters of us are receiving adequate nutrition. One billion people experience chronic hunger and as our population grows, more and more people are expected to experience food insecurity. It is starkly apparent that current industrial farming practices that squander and degrade the very resources they depend on cannot continue unchanged. Industrial agricultural practices are producing an estimated 21–37% of annual emissions of the three largest individual contributors to global warming gasses, carbon dioxide, methane, and nitrous oxide, and using 70% of the fresh water available on our planet (United Nations Food and Agriculture Organization, 2022). Clearly a large conservation and restoration effort is essential if we are to provide nutrition for an anticipated population of 10 billion by 2050, which is precisely what the Regenerative Agriculture movement seeks to enable.<br />
<br />
Obviously no single solution is capable of fulfilling this lofty goal. A decade ago in 2012, the United Nations Conference on Sustainable Development (UNCSD), known as Rio+20, produced an outcome document that called for achieving a land-degradation-neutral world in the context of sustainable development. Given the current extent of land degradation globally, the potential benefits from land restoration for food security and for mitigating climate change are enormous. While it is true that scientific understanding of the drivers of desertification, land degradation and drought is still evolving, advocates of Regenerative Agriculture point out that these crises actually create new opportunities for increasing food security, carbon storage and climate resiliency. <br />
<br />
Regenerative Agriculture approaches are already being implemented to varying degrees across our agricultural system, while others are newly emerging. Globally, movement is underway to return to native crops specifically adapted to variations in the local climate and to greatly increase the natural fertility and carbon sequestration potential of degraded soils. Nations such as Niger, with some of the most degraded soils on the planet, are demonstrating how restoration can be accomplished – restoring an astonishing 5 million hectares to productivity in the Sahel. Private/public partnerships such as the agroforestry project in inner Mongolia’s Kubuqi Desert, have restored approximately one-third of 18,600 sq km of sand dunes and in Mali, restoration has created forest plots with higher biomass than even native forests.<br />
}}<br />
'''Key Trends Pushing Forward Regenerative Ag Practice Adoption'''<br />
<br />
# Data and the Digital Ag Revolution <br />
# Biologicals<br />
# Carbon / Climate - Smart Commodities<br />
<br />
'''Emerging Digital AG Revolution Solutions'''<br />
<br />
A body of scientific literature is now emerging that presents numerous strategies to decouple food production from land area, enabling increased food productivity and nutrition on the current agricultural footprint. A few examples of solutions related to data and the digital ag revolution and smart communities include:<br />
<br />
* Integrating AI enabled predictive analytics within indoor growing environments to precisely control growing variables in response to biotic and chemical signals at different stages of the growth cycle to reduce resource consumption and waste while maximizing rapid plant growth. <br />
* Deploying controlled growing environments near to where produce is sold and consumed to drastically reduce travel time, resource consumption, pollution, and shipping costs to deliver fresher, nutrient-dense food that tastes better.<br />
* Utilizing AI solutions for optimized outdoor crop placement <br />
* IoT solutions such as robots, drones, remote sensors, and computer imaging combined with continuously progressing machine learning and analytical tools for monitoring crops, surveying, and mapping the fields, and providing data to farmers for rational farm management plans to save both time and money.<br />
* Employing block-chain tracking to improve traceability of food to appeal to location-conscious buyers (sometimes called locavores), who are having an important impact on food sourcing, including the popularity of farmers markets. <br />
<br />
'''OpenCommons Embraces The Formation Of A RegenAG Community: Call For Action'''<br />
<br />
The purpose of this RegenAg/AgTech partnership with OpenCommons is to cultivate a collaborative community to advance promising smart technologies for urban and rural regenerative agriculture solutions.<br />
<br />
=Demonstration Projects=<br />
{{#ask: <br />
[[Category:Activity]]<br />
[[Has tag::Regenerative Agriculture]]<br />
|?=#<br />
|?Has image#=2<br />
|?Has description#=3<br />
|format=plainlist<br />
|named args=yes<br />
|introtemplate=Show image Header<br />
|template=Show image<br />
|outrotemplate=Show link Footer<br />
}}<br />
=News=<br />
{{#ask: <br />
[[Category:News]]<br />
[[Has tag::Regenerative Agriculture, Regen, RegenAG, AgTech]]<br />
|?=#<br />
|?Has image#=2<br />
|?Has summary#=3<br />
|format=plainlist<br />
|named args=yes<br />
|introtemplate=Show image Header<br />
|template=Show image<br />
|outrotemplate=Show link Footer<br />
}}</div>Elislehttps://opencommons.org/index.php?title=File:Smart-agriculture-iot-with-hand-planting-tree-background.tiff&diff=11266File:Smart-agriculture-iot-with-hand-planting-tree-background.tiff2022-12-02T04:06:11Z<p>Elisle: </p>
<hr />
<div></div>Elislehttps://opencommons.org/index.php?title=File:Regenerative_Agriculture.tiff&diff=11265File:Regenerative Agriculture.tiff2022-12-02T04:05:21Z<p>Elisle: </p>
<hr />
<div></div>Elislehttps://opencommons.org/index.php?title=Regenerative_Agriculture&diff=11264Regenerative Agriculture2022-12-02T04:03:12Z<p>Elisle: </p>
<hr />
<div>{{Chapter<br />
|image=Smart Agriculture<br />
|poc=Ed Lisle<br />
|authors=Jennifer Wells,Ed Lisle<br />
|blueprint=Agriculture<br />
|chapter=612<br />
|sectors=Agriculture<br />
|summary='''REGENERATIVE AGRICULTURE''' (''RegenAG'') involves shifting from a carbon intensive food system to carbon-negative agriculture that restores rather than degrades ecosystems. While there is no globally accepted definition, this term is widely accepted to refer to integrated systems of farming, ranching, and pastoral practices that contribute to stabilizing the planet’s climate and carbon cycles by rehabilitating and safeguarding biodiversity and living systems.<br />
<br />
A shift to Regenerative Agriculture signals a radical transformation of how, where and when we grow food, a great expansion of the varieties of seeds grown and a new microclimate-based approach focusing on smallholder farms, intercropping, agroforestry and micro-farming industry strategies. For example, the use of cover crops, crop rotation, and no till practices, reducing use or elimination of synthetic inputs, and employing integrated crop and livestock systems and managed grazing have long since been recognized as sustainable farming practices. <br />
<br />
At the same time, new approaches are under development and ancient practices reinvented, some of which are up for debate as to whether or not they fall under the Regenerative Agriculture umbrella. For instance, while there is some debate about inclusion of soilless agriculture under the Regenerative Agriculture umbrella, there is growing consensus that organic soilless methods such as aquaponics (''involving cultivation of fish that fertilize plants in interconnected, contained systems'') represent promising, sustainable approaches to growing more with less water and energy and little to no pollution. <br />
<br />
'''United Nations Sustainable Development Goals'''<br />
<br />
The United Nations Sustainable Development Goal 2 is focused on creating a world free of hunger by 2030 by improving food security, nutrition and promoting sustainable agriculture. Of the 8 billion people living today, only three-quarters of us are receiving adequate nutrition. One billion people experience chronic hunger and as our population grows, more and more people are expected to experience food insecurity. It is starkly apparent that current industrial farming practices that squander and degrade the very resources they depend on cannot continue unchanged. Industrial agricultural practices are producing an estimated 21–37% of annual emissions of the three largest individual contributors to global warming gasses, carbon dioxide, methane, and nitrous oxide, and using 70% of the fresh water available on our planet (United Nations Food and Agriculture Organization, 2022). Clearly a large conservation and restoration effort is essential if we are to provide nutrition for an anticipated population of 10 billion by 2050, which is precisely what the Regenerative Agriculture movement seeks to enable.<br />
<br />
Obviously no single solution is capable of fulfilling this lofty goal. A decade ago in 2012, the United Nations Conference on Sustainable Development (UNCSD), known as Rio+20, produced an outcome document that called for achieving a land-degradation-neutral world in the context of sustainable development. Given the current extent of land degradation globally, the potential benefits from land restoration for food security and for mitigating climate change are enormous. While it is true that scientific understanding of the drivers of desertification, land degradation and drought is still evolving, advocates of Regenerative Agriculture point out that these crises actually create new opportunities for increasing food security, carbon storage and climate resiliency. <br />
<br />
Regenerative Agriculture approaches are already being implemented to varying degrees across our agricultural system, while others are newly emerging. Globally, movement is underway to return to native crops specifically adapted to variations in the local climate and to greatly increase the natural fertility and carbon sequestration potential of degraded soils. Nations such as Niger, with some of the most degraded soils on the planet, are demonstrating how restoration can be accomplished – restoring an astonishing 5 million hectares to productivity in the Sahel. Private/public partnerships such as the agroforestry project in inner Mongolia’s Kubuqi Desert, have restored approximately one-third of 18,600 sq km of sand dunes and in Mali, restoration has created forest plots with higher biomass than even native forests.<br />
}}<br />
'''Key Trends Pushing Forward Regenerative Ag Practice Adoption'''<br />
<br />
# Data and the Digital Ag Revolution <br />
# Biologicals<br />
# Carbon / Climate - Smart Commodities<br />
<br />
'''Emerging Digital AG Revolution Solutions'''<br />
<br />
A body of scientific literature is now emerging that presents numerous strategies to decouple food production from land area, enabling increased food productivity and nutrition on the current agricultural footprint. A few examples of solutions related to data and the digital ag revolution and smart communities include:<br />
<br />
* Integrating AI enabled predictive analytics within indoor growing environments to precisely control growing variables in response to biotic and chemical signals at different stages of the growth cycle to reduce resource consumption and waste while maximizing rapid plant growth. <br />
* Deploying controlled growing environments near to where produce is sold and consumed to drastically reduce travel time, resource consumption, pollution, and shipping costs to deliver fresher, nutrient-dense food that tastes better.<br />
* Utilizing AI solutions for optimized outdoor crop placement <br />
* IoT solutions such as robots, drones, remote sensors, and computer imaging combined with continuously progressing machine learning and analytical tools for monitoring crops, surveying, and mapping the fields, and providing data to farmers for rational farm management plans to save both time and money.<br />
* Employing block-chain tracking to improve traceability of food to appeal to location-conscious buyers (sometimes called locavores), who are having an important impact on food sourcing, including the popularity of farmers markets. <br />
<br />
'''OpenCommons Embraces The Formation Of A RegenAG Community: Call For Action'''<br />
<br />
The purpose of this RegenAg/AgTech partnership with OpenCommons is to cultivate a collaborative community to advance promising smart technologies for urban and rural regenerative agriculture solutions.<br />
<br />
=Demonstration Projects=<br />
{{#ask: <br />
[[Category:Activity]]<br />
[[Has tag::Regenerative Agriculture]]<br />
|?=#<br />
|?Has image#=2<br />
|?Has description#=3<br />
|format=plainlist<br />
|named args=yes<br />
|introtemplate=Show image Header<br />
|template=Show image<br />
|outrotemplate=Show link Footer<br />
}}<br />
=News=<br />
{{#ask: <br />
[[Category:News]]<br />
[[Has tag::Regenerative Agriculture, Regen, RegenAG, AgTech]]<br />
|?=#<br />
|?Has image#=2<br />
|?Has summary#=3<br />
|format=plainlist<br />
|named args=yes<br />
|introtemplate=Show image Header<br />
|template=Show image<br />
|outrotemplate=Show link Footer<br />
}}</div>Elislehttps://opencommons.org/index.php?title=File:Smart_Agriculture.jpeg&diff=11263File:Smart Agriculture.jpeg2022-12-02T04:02:42Z<p>Elisle: </p>
<hr />
<div></div>Elislehttps://opencommons.org/index.php?title=Regenerative_Agriculture&diff=11262Regenerative Agriculture2022-12-02T04:00:58Z<p>Elisle: </p>
<hr />
<div>{{Chapter<br />
|image=SmartAg<br />
|poc=Ed Lisle<br />
|authors=Jennifer Wells,Ed Lisle<br />
|blueprint=Agriculture<br />
|chapter=612<br />
|sectors=Agriculture<br />
|summary='''REGENERATIVE AGRICULTURE''' (''RegenAG'') involves shifting from a carbon intensive food system to carbon-negative agriculture that restores rather than degrades ecosystems. While there is no globally accepted definition, this term is widely accepted to refer to integrated systems of farming, ranching, and pastoral practices that contribute to stabilizing the planet’s climate and carbon cycles by rehabilitating and safeguarding biodiversity and living systems.<br />
<br />
A shift to Regenerative Agriculture signals a radical transformation of how, where and when we grow food, a great expansion of the varieties of seeds grown and a new microclimate-based approach focusing on smallholder farms, intercropping, agroforestry and micro-farming industry strategies. For example, the use of cover crops, crop rotation, and no till practices, reducing use or elimination of synthetic inputs, and employing integrated crop and livestock systems and managed grazing have long since been recognized as sustainable farming practices. <br />
<br />
At the same time, new approaches are under development and ancient practices reinvented, some of which are up for debate as to whether or not they fall under the Regenerative Agriculture umbrella. For instance, while there is some debate about inclusion of soilless agriculture under the Regenerative Agriculture umbrella, there is growing consensus that organic soilless methods such as aquaponics (''involving cultivation of fish that fertilize plants in interconnected, contained systems'') represent promising, sustainable approaches to growing more with less water and energy and little to no pollution. <br />
<br />
'''United Nations Sustainable Development Goals'''<br />
<br />
The United Nations Sustainable Development Goal 2 is focused on creating a world free of hunger by 2030 by improving food security, nutrition and promoting sustainable agriculture. Of the 8 billion people living today, only three-quarters of us are receiving adequate nutrition. One billion people experience chronic hunger and as our population grows, more and more people are expected to experience food insecurity. It is starkly apparent that current industrial farming practices that squander and degrade the very resources they depend on cannot continue unchanged. Industrial agricultural practices are producing an estimated 21–37% of annual emissions of the three largest individual contributors to global warming gasses, carbon dioxide, methane, and nitrous oxide, and using 70% of the fresh water available on our planet (United Nations Food and Agriculture Organization, 2022). Clearly a large conservation and restoration effort is essential if we are to provide nutrition for an anticipated population of 10 billion by 2050, which is precisely what the Regenerative Agriculture movement seeks to enable.<br />
<br />
Obviously no single solution is capable of fulfilling this lofty goal. A decade ago in 2012, the United Nations Conference on Sustainable Development (UNCSD), known as Rio+20, produced an outcome document that called for achieving a land-degradation-neutral world in the context of sustainable development. Given the current extent of land degradation globally, the potential benefits from land restoration for food security and for mitigating climate change are enormous. While it is true that scientific understanding of the drivers of desertification, land degradation and drought is still evolving, advocates of Regenerative Agriculture point out that these crises actually create new opportunities for increasing food security, carbon storage and climate resiliency. <br />
<br />
Regenerative Agriculture approaches are already being implemented to varying degrees across our agricultural system, while others are newly emerging. Globally, movement is underway to return to native crops specifically adapted to variations in the local climate and to greatly increase the natural fertility and carbon sequestration potential of degraded soils. Nations such as Niger, with some of the most degraded soils on the planet, are demonstrating how restoration can be accomplished – restoring an astonishing 5 million hectares to productivity in the Sahel. Private/public partnerships such as the agroforestry project in inner Mongolia’s Kubuqi Desert, have restored approximately one-third of 18,600 sq km of sand dunes and in Mali, restoration has created forest plots with higher biomass than even native forests.<br />
}}<br />
'''Key Trends Pushing Forward Regenerative Ag Practice Adoption'''<br />
<br />
# Data and the Digital Ag Revolution <br />
# Biologicals<br />
# Carbon / Climate - Smart Commodities<br />
<br />
'''Emerging Digital AG Revolution Solutions'''<br />
<br />
A body of scientific literature is now emerging that presents numerous strategies to decouple food production from land area, enabling increased food productivity and nutrition on the current agricultural footprint. A few examples of solutions related to data and the digital ag revolution and smart communities include:<br />
<br />
* Integrating AI enabled predictive analytics within indoor growing environments to precisely control growing variables in response to biotic and chemical signals at different stages of the growth cycle to reduce resource consumption and waste while maximizing rapid plant growth. <br />
* Deploying controlled growing environments near to where produce is sold and consumed to drastically reduce travel time, resource consumption, pollution, and shipping costs to deliver fresher, nutrient-dense food that tastes better.<br />
* Utilizing AI solutions for optimized outdoor crop placement <br />
* IoT solutions such as robots, drones, remote sensors, and computer imaging combined with continuously progressing machine learning and analytical tools for monitoring crops, surveying, and mapping the fields, and providing data to farmers for rational farm management plans to save both time and money.<br />
* Employing block-chain tracking to improve traceability of food to appeal to location-conscious buyers (sometimes called locavores), who are having an important impact on food sourcing, including the popularity of farmers markets. <br />
<br />
'''OpenCommons Embraces The Formation Of A RegenAG Community: Call For Action'''<br />
<br />
The purpose of this RegenAg/AgTech partnership with OpenCommons is to cultivate a collaborative community to advance promising smart technologies for urban and rural regenerative agriculture solutions.<br />
<br />
=Demonstration Projects=<br />
{{#ask: <br />
[[Category:Activity]]<br />
[[Has tag::Regenerative Agriculture]]<br />
|?=#<br />
|?Has image#=2<br />
|?Has description#=3<br />
|format=plainlist<br />
|named args=yes<br />
|introtemplate=Show image Header<br />
|template=Show image<br />
|outrotemplate=Show link Footer<br />
}}<br />
=News=<br />
{{#ask: <br />
[[Category:News]]<br />
[[Has tag::Regenerative Agriculture, Regen, RegenAG, AgTech]]<br />
|?=#<br />
|?Has image#=2<br />
|?Has summary#=3<br />
|format=plainlist<br />
|named args=yes<br />
|introtemplate=Show image Header<br />
|template=Show image<br />
|outrotemplate=Show link Footer<br />
}}</div>Elislehttps://opencommons.org/index.php?title=File:SmartAg.jpeg&diff=11261File:SmartAg.jpeg2022-12-02T04:00:49Z<p>Elisle: </p>
<hr />
<div></div>Elislehttps://opencommons.org/index.php?title=Regenerative_Agriculture&diff=11260Regenerative Agriculture2022-12-01T07:27:40Z<p>Elisle: </p>
<hr />
<div>{{Chapter<br />
|image=Agriculture.JPG<br />
|poc=Ed Lisle<br />
|authors=Jennifer Wells,Ed Lisle<br />
|blueprint=Agriculture<br />
|chapter=612<br />
|sectors=Agriculture<br />
|summary='''REGENERATIVE AGRICULTURE''' (''RegenAG'') involves shifting from a carbon intensive food system to carbon-negative agriculture that restores rather than degrades ecosystems. While there is no globally accepted definition, this term is widely accepted to refer to integrated systems of farming, ranching, and pastoral practices that contribute to stabilizing the planet’s climate and carbon cycles by rehabilitating and safeguarding biodiversity and living systems.<br />
<br />
A shift to Regenerative Agriculture signals a radical transformation of how, where and when we grow food, a great expansion of the varieties of seeds grown and a new microclimate-based approach focusing on smallholder farms, intercropping, agroforestry and micro-farming industry strategies. For example, the use of cover crops, crop rotation, and no till practices, reducing use or elimination of synthetic inputs, and employing integrated crop and livestock systems and managed grazing have long since been recognized as sustainable farming practices. <br />
<br />
At the same time, new approaches are under development and ancient practices reinvented, some of which are up for debate as to whether or not they fall under the Regenerative Agriculture umbrella. For instance, while there is some debate about inclusion of soilless agriculture under the Regenerative Agriculture umbrella, there is growing consensus that organic soilless methods such as aquaponics (''involving cultivation of fish that fertilize plants in interconnected, contained systems'') represent promising, sustainable approaches to growing more with less water and energy and little to no pollution. <br />
<br />
'''United Nations Sustainable Development Goals'''<br />
<br />
The United Nations Sustainable Development Goal 2 is focused on creating a world free of hunger by 2030 by improving food security, nutrition and promoting sustainable agriculture. Of the 8 billion people living today, only three-quarters of us are receiving adequate nutrition. One billion people experience chronic hunger and as our population grows, more and more people are expected to experience food insecurity. It is starkly apparent that current industrial farming practices that squander and degrade the very resources they depend on cannot continue unchanged. Industrial agricultural practices are producing an estimated 21–37% of annual emissions of the three largest individual contributors to global warming gasses, carbon dioxide, methane, and nitrous oxide, and using 70% of the fresh water available on our planet (United Nations Food and Agriculture Organization, 2022). Clearly a large conservation and restoration effort is essential if we are to provide nutrition for an anticipated population of 10 billion by 2050, which is precisely what the Regenerative Agriculture movement seeks to enable.<br />
<br />
Obviously no single solution is capable of fulfilling this lofty goal. A decade ago in 2012, the United Nations Conference on Sustainable Development (UNCSD), known as Rio+20, produced an outcome document that called for achieving a land-degradation-neutral world in the context of sustainable development. Given the current extent of land degradation globally, the potential benefits from land restoration for food security and for mitigating climate change are enormous. While it is true that scientific understanding of the drivers of desertification, land degradation and drought is still evolving, advocates of Regenerative Agriculture point out that these crises actually create new opportunities for increasing food security, carbon storage and climate resiliency. <br />
<br />
Regenerative Agriculture approaches are already being implemented to varying degrees across our agricultural system, while others are newly emerging. Globally, movement is underway to return to native crops specifically adapted to variations in the local climate and to greatly increase the natural fertility and carbon sequestration potential of degraded soils. Nations such as Niger, with some of the most degraded soils on the planet, are demonstrating how restoration can be accomplished – restoring an astonishing 5 million hectares to productivity in the Sahel. Private/public partnerships such as the agroforestry project in inner Mongolia’s Kubuqi Desert, have restored approximately one-third of 18,600 sq km of sand dunes and in Mali, restoration has created forest plots with higher biomass than even native forests.<br />
}}<br />
'''Key Trends Pushing Forward Regenerative Ag Practice Adoption'''<br />
<br />
# Data and the Digital Ag Revolution <br />
# Biologicals<br />
# Carbon / Climate - Smart Commodities<br />
<br />
'''Emerging Digital AG Revolution Solutions'''<br />
<br />
A body of scientific literature is now emerging that presents numerous strategies to decouple food production from land area, enabling increased food productivity and nutrition on the current agricultural footprint. A few examples of solutions related to data and the digital ag revolution and smart communities include:<br />
<br />
* Integrating AI enabled predictive analytics within indoor growing environments to precisely control growing variables in response to biotic and chemical signals at different stages of the growth cycle to reduce resource consumption and waste while maximizing rapid plant growth. <br />
* Deploying controlled growing environments near to where produce is sold and consumed to drastically reduce travel time, resource consumption, pollution, and shipping costs to deliver fresher, nutrient-dense food that tastes better.<br />
* Utilizing AI solutions for optimized outdoor crop placement <br />
* IoT solutions such as robots, drones, remote sensors, and computer imaging combined with continuously progressing machine learning and analytical tools for monitoring crops, surveying, and mapping the fields, and providing data to farmers for rational farm management plans to save both time and money.<br />
* Employing block-chain tracking to improve traceability of food to appeal to location-conscious buyers (sometimes called locavores), who are having an important impact on food sourcing, including the popularity of farmers markets. <br />
<br />
'''OpenCommons Embraces The Formation Of A RegenAG Community: Call For Action'''<br />
<br />
The purpose of this RegenAg/AgTech partnership with OpenCommons is to cultivate a collaborative community to advance promising smart technologies for urban and rural regenerative agriculture solutions.<br />
<br />
=Demonstration Projects=<br />
{{#ask: <br />
[[Category:Activity]]<br />
[[Has tag::Regenerative Agriculture]]<br />
|?=#<br />
|?Has image#=2<br />
|?Has description#=3<br />
|format=plainlist<br />
|named args=yes<br />
|introtemplate=Show image Header<br />
|template=Show image<br />
|outrotemplate=Show link Footer<br />
}}<br />
=News=<br />
{{#ask: <br />
[[Category:News]]<br />
[[Has tag::Regenerative Agriculture, Regen, RegenAG, AgTech]]<br />
|?=#<br />
|?Has image#=2<br />
|?Has summary#=3<br />
|format=plainlist<br />
|named args=yes<br />
|introtemplate=Show image Header<br />
|template=Show image<br />
|outrotemplate=Show link Footer<br />
}}</div>Elislehttps://opencommons.org/index.php?title=Regenerative_Agriculture&diff=11259Regenerative Agriculture2022-12-01T07:26:10Z<p>Elisle: </p>
<hr />
<div>{{Chapter<br />
|image=Agriculture.JPG<br />
|poc=Ed Lisle<br />
|authors=Jennifer Wells,Ed Lisle<br />
|blueprint=Agriculture<br />
|chapter=612<br />
|sectors=Agriculture<br />
|summary='''REGENERATIVE AGRICULTURE''' (''RegenAG'') involves shifting from a carbon intensive food system to carbon-negative agriculture that restores rather than degrades ecosystems. While there is no globally accepted definition, this term is widely accepted to refer to integrated systems of farming, ranching, and pastoral practices that contribute to stabilizing the planet’s climate and carbon cycles by rehabilitating and safeguarding biodiversity and living systems.<br />
<br />
A shift to Regenerative Agriculture signals a radical transformation of how, where and when we grow food, a great expansion of the varieties of seeds grown and a new microclimate-based approach focusing on smallholder farms, intercropping, agroforestry and micro-farming industry strategies. For example, the use of cover crops, crop rotation, and no till practices, reducing use or elimination of synthetic inputs, and employing integrated crop and livestock systems and managed grazing have long since been recognized as sustainable farming practices. <br />
<br />
At the same time, new approaches are under development and ancient practices reinvented, some of which are up for debate as to whether or not they fall under the Regenerative Agriculture umbrella. For instance, while there is some debate about inclusion of soilless agriculture under the Regenerative Agriculture umbrella, there is growing consensus that organic soilless methods such as aquaponics (''involving cultivation of fish that fertilize plants in interconnected, contained systems'') represent promising, sustainable approaches to growing more with less water and energy and little to no pollution. <br />
<br />
'''United Nations Sustainable Development Goals'''<br />
<br />
The United Nations Sustainable Development Goal 2 is focused on creating a world free of hunger by 2030 by improving food security, nutrition and promoting sustainable agriculture. Of the 8 billion people living today, only three-quarters of us are receiving adequate nutrition. One billion people experience chronic hunger and as our population grows, more and more people are expected to experience food insecurity. It is starkly apparent that current industrial farming practices that squander and degrade the very resources they depend on cannot continue unchanged. Industrial agricultural practices are producing an estimated 21–37% of annual emissions of the three largest individual contributors to global warming gasses, carbon dioxide, methane, and nitrous oxide, and using 70% of the fresh water available on our planet (United Nations Food and Agriculture Organization, 2022). Clearly a large conservation and restoration effort is essential if we are to provide nutrition for an anticipated population of 10 billion by 2050, which is precisely what the Regenerative Agriculture movement seeks to enable.<br />
<br />
Obviously no single solution is capable of fulfilling this lofty goal. A decade ago in 2012, the United Nations Conference on Sustainable Development (UNCSD), known as Rio+20, produced an outcome document that called for achieving a land-degradation-neutral world in the context of sustainable development. Given the current extent of land degradation globally, the potential benefits from land restoration for food security and for mitigating climate change are enormous. While it is true that scientific understanding of the drivers of desertification, land degradation and drought is still evolving, advocates of Regenerative Agriculture point out that these crises actually create new opportunities for increasing food security, carbon storage and climate resiliency. <br />
<br />
Regenerative Agriculture approaches are already being implemented to varying degrees across our agricultural system, while others are newly emerging. Globally, movement is underway to return to native crops specifically adapted to variations in the local climate and to greatly increase the natural fertility and carbon sequestration potential of degraded soils. Nations such as Niger, with some of the most degraded soils on the planet, are demonstrating how restoration can be accomplished – restoring an astonishing 5 million hectares to productivity in the Sahel. Private/public partnerships such as the agroforestry project in inner Mongolia’s Kubuqi Desert, have restored approximately one-third of 18,600 sq km of sand dunes and in Mali, restoration has created forest plots with higher biomass than even native forests.<br />
}}<br />
'''Three Key Trends Pushing Forward Regenerative Ag Practice Adoption'''<br />
<br />
# Data and the Digital Ag Revolution <br />
# Biologicals<br />
# Carbon / Climate - Smart Commodities<br />
<br />
'''Emerging Digital AG Revolution Solutions'''<br />
<br />
A body of scientific literature is now emerging that presents numerous strategies to decouple food production from land area, enabling increased food productivity and nutrition on the current agricultural footprint. A few examples of solutions related to data and the digital ag revolution and smart communities include:<br />
<br />
* Integrating AI enabled predictive analytics within indoor growing environments to precisely control growing variables in response to biotic and chemical signals at different stages of the growth cycle to reduce resource consumption and waste while maximizing rapid plant growth. <br />
* Deploying controlled growing environments near to where produce is sold and consumed to drastically reduce travel time, resource consumption, pollution, and shipping costs to deliver fresher, nutrient-dense food that tastes better.<br />
* Utilizing AI solutions for optimized outdoor crop placement <br />
* IoT solutions such as robots, drones, remote sensors, and computer imaging combined with continuously progressing machine learning and analytical tools for monitoring crops, surveying, and mapping the fields, and providing data to farmers for rational farm management plans to save both time and money.<br />
* Employing block-chain tracking to improve traceability of food to appeal to location-conscious buyers (sometimes called locavores), who are having an important impact on food sourcing, including the popularity of farmers markets. <br />
<br />
'''OpenCommons Embraces The Formation Of A RegenAG Community: Call For Action'''<br />
<br />
The purpose of this RegenAg/AgTech partnership with OpenCommons is to cultivate a collaborative community to advance promising smart technologies for urban and rural regenerative agriculture solutions.<br />
<br />
=Demonstration Projects=<br />
{{#ask: <br />
[[Category:Activity]]<br />
[[Has tag::Regenerative Agriculture]]<br />
|?=#<br />
|?Has image#=2<br />
|?Has description#=3<br />
|format=plainlist<br />
|named args=yes<br />
|introtemplate=Show image Header<br />
|template=Show image<br />
|outrotemplate=Show link Footer<br />
}}<br />
=News=<br />
{{#ask: <br />
[[Category:News]]<br />
[[Has tag::Regenerative Agriculture, Regen, RegenAG, AgTech]]<br />
|?=#<br />
|?Has image#=2<br />
|?Has summary#=3<br />
|format=plainlist<br />
|named args=yes<br />
|introtemplate=Show image Header<br />
|template=Show image<br />
|outrotemplate=Show link Footer<br />
}}</div>Elislehttps://opencommons.org/index.php?title=Regenerative_Agriculture&diff=11258Regenerative Agriculture2022-12-01T07:21:00Z<p>Elisle: </p>
<hr />
<div>{{Chapter<br />
|image=Agriculture.JPG<br />
|poc=Ed Lisle<br />
|authors=Jennifer Wells,Ed Lisle<br />
|blueprint=Agriculture<br />
|chapter=612<br />
|sectors=Agriculture<br />
|summary='''REGENERATIVE AGRICULTURE''' (''RegenAG'') involves shifting from a carbon intensive food system to carbon-negative agriculture that restores rather than degrades ecosystems. While there is no globally accepted definition, this term is widely accepted to refer to integrated systems of farming, ranching, and pastoral practices that contribute to stabilizing the planet’s climate and carbon cycles by rehabilitating and safeguarding biodiversity and living systems.<br />
<br />
A shift to Regenerative Agriculture signals a radical transformation of how, where and when we grow food, a great expansion of the varieties of seeds grown and a new microclimate-based approach focusing on smallholder farms, intercropping, agroforestry and micro-farming industry strategies. For example, the use of cover crops, crop rotation, and no till practices, reducing use or elimination of synthetic inputs, and employing integrated crop and livestock systems and managed grazing have long since been recognized as sustainable farming practices. <br />
<br />
At the same time, new approaches are under development and ancient practices reinvented, some of which are up for debate as to whether or not they fall under the Regenerative Agriculture umbrella. For instance, while there is some debate about inclusion of soilless agriculture under the Regenerative Agriculture umbrella, there is growing consensus that organic soilless methods such as aquaponics (''involving cultivation of fish that fertilize plants in interconnected, contained systems'') represent promising, sustainable approaches to growing more with less water and energy and little to no pollution. <br />
<br />
'''United Nations Sustainable Development Goals'''<br />
<br />
The United Nations Sustainable Development Goal 2 is focused on creating a world free of hunger by 2030 by improving food security, nutrition and promoting sustainable agriculture. Of the 8 billion people living today, only three-quarters of us are receiving adequate nutrition. One billion people experience chronic hunger and as our population grows, more and more people are expected to experience food insecurity. It is starkly apparent that current industrial farming practices that squander and degrade the very resources they depend on cannot continue unchanged. Industrial agricultural practices are producing an estimated 21–37% of annual emissions of the three largest individual contributors to global warming gasses, carbon dioxide, methane, and nitrous oxide, and using 70% of the fresh water available on our planet (United Nations Food and Agriculture Organization, 2022). Clearly a large conservation and restoration effort is essential if we are to provide nutrition for an anticipated population of 10 billion by 2050, which is precisely what the Regenerative Agriculture movement seeks to enable.<br />
<br />
Obviously no single solution is capable of fulfilling this lofty goal. A decade ago in 2012, the United Nations Conference on Sustainable Development (UNCSD), known as Rio+20, produced an outcome document that called for achieving a land-degradation-neutral world in the context of sustainable development. Given the current extent of land degradation globally, the potential benefits from land restoration for food security and for mitigating climate change are enormous. While it is true that scientific understanding of the drivers of desertification, land degradation and drought is still evolving, advocates of Regenerative Agriculture point out that these crises actually create new opportunities for increasing food security, carbon storage and climate resiliency. <br />
<br />
Regenerative Agriculture approaches are already being implemented to varying degrees across our agricultural system, while others are newly emerging. Globally, movement is underway to return to native crops specifically adapted to variations in the local climate and to greatly increase the natural fertility and carbon sequestration potential of degraded soils. Nations such as Niger, with some of the most degraded soils on the planet, are demonstrating how restoration can be accomplished – restoring an astonishing 5 million hectares to productivity in the Sahel. Private/public partnerships such as the agroforestry project in inner Mongolia’s Kubuqi Desert, have restored approximately one-third of 18,600 sq km of sand dunes and in Mali, restoration has created forest plots with higher biomass than even native forests.<br />
}}<br />
'''Three Key Trends Pushing Forward Regenerative Ag Practice Adoption'''<br />
<br />
# Data and the Digital Ag Revolution <br />
# Biologicals<br />
# Carbon / Climate - Smart Commodities<br />
<br />
'''Emerging Digital AG Revolution Solutions'''<br />
<br />
A body of scientific literature is now emerging that presents numerous strategies to decouple food production from land area, enabling increased food productivity and nutrition on the current agricultural footprint. A few examples of solutions related to data and the digital ag revolution and smart communities include:<br />
<br />
* Integrating AI enabled predictive analytics within indoor growing environments to precisely control growing variables in response to biotic and chemical signals at different stages of the growth cycle to reduce resource consumption and waste while maximizing rapid plant growth. <br />
* Deploying controlled growing environments near to where produce is sold and consumed to drastically reduce travel time, resource consumption, pollution, and shipping costs to deliver fresher, nutrient-dense food that tastes better.<br />
* Utilizing AI solutions for optimized outdoor crop placement <br />
* IoT solutions such as robots, drones, remote sensors, and computer imaging combined with continuously progressing machine learning and analytical tools for monitoring crops, surveying, and mapping the fields, and providing data to farmers for rational farm management plans to save both time and money.<br />
* Employing block-chain tracking to improve traceability of food to appeal to location-conscious buyers (sometimes called locavores), who are having an important impact on food sourcing, including the popularity of farmers markets. <br />
<br />
'''OpenCommons Cause To Embrace A RegenAG Community: Call For Action'''<br />
<br />
The purpose of this partnership with OpenCommons is to cultivate a collaborative RegenAg/AgTech community to advance promising smart technologies for urban and rural regenerative agriculture solutions.<br />
<br />
=Demonstration Projects=<br />
{{#ask: <br />
[[Category:Activity]]<br />
[[Has tag::Regenerative Agriculture]]<br />
|?=#<br />
|?Has image#=2<br />
|?Has description#=3<br />
|format=plainlist<br />
|named args=yes<br />
|introtemplate=Show image Header<br />
|template=Show image<br />
|outrotemplate=Show link Footer<br />
}}<br />
=News=<br />
{{#ask: <br />
[[Category:News]]<br />
[[Has tag::Regenerative Agriculture, Regen, RegenAG, AgTech]]<br />
|?=#<br />
|?Has image#=2<br />
|?Has summary#=3<br />
|format=plainlist<br />
|named args=yes<br />
|introtemplate=Show image Header<br />
|template=Show image<br />
|outrotemplate=Show link Footer<br />
}}</div>Elislehttps://opencommons.org/index.php?title=Regenerative_Agriculture&diff=11257Regenerative Agriculture2022-12-01T07:20:31Z<p>Elisle: </p>
<hr />
<div>{{Chapter<br />
|image=Agriculture.JPG<br />
|poc=Ed Lisle<br />
|authors=Jennifer Wells,Ed Lisle<br />
|blueprint=Agriculture<br />
|chapter=612<br />
|sectors=Agriculture<br />
|summary='''''REGENERATIVE AGRICULTURE''''' (RegenAG) involves shifting from a carbon intensive food system to carbon-negative agriculture that restores rather than degrades ecosystems. While there is no globally accepted definition, this term is widely accepted to refer to integrated systems of farming, ranching, and pastoral practices that contribute to stabilizing the planet’s climate and carbon cycles by rehabilitating and safeguarding biodiversity and living systems.<br />
<br />
A shift to Regenerative Agriculture signals a radical transformation of how, where and when we grow food, a great expansion of the varieties of seeds grown and a new microclimate-based approach focusing on smallholder farms, intercropping, agroforestry and micro-farming industry strategies. For example, the use of cover crops, crop rotation, and no till practices, reducing use or elimination of synthetic inputs, and employing integrated crop and livestock systems and managed grazing have long since been recognized as sustainable farming practices. <br />
<br />
At the same time, new approaches are under development and ancient practices reinvented, some of which are up for debate as to whether or not they fall under the Regenerative Agriculture umbrella. For instance, while there is some debate about inclusion of soilless agriculture under the Regenerative Agriculture umbrella, there is growing consensus that organic soilless methods such as aquaponics (''involving cultivation of fish that fertilize plants in interconnected, contained systems'') represent promising, sustainable approaches to growing more with less water and energy and little to no pollution. <br />
<br />
'''United Nations Sustainable Development Goals'''<br />
<br />
The United Nations Sustainable Development Goal 2 is focused on creating a world free of hunger by 2030 by improving food security, nutrition and promoting sustainable agriculture. Of the 8 billion people living today, only three-quarters of us are receiving adequate nutrition. One billion people experience chronic hunger and as our population grows, more and more people are expected to experience food insecurity. It is starkly apparent that current industrial farming practices that squander and degrade the very resources they depend on cannot continue unchanged. Industrial agricultural practices are producing an estimated 21–37% of annual emissions of the three largest individual contributors to global warming gasses, carbon dioxide, methane, and nitrous oxide, and using 70% of the fresh water available on our planet (United Nations Food and Agriculture Organization, 2022). Clearly a large conservation and restoration effort is essential if we are to provide nutrition for an anticipated population of 10 billion by 2050, which is precisely what the Regenerative Agriculture movement seeks to enable.<br />
<br />
Obviously no single solution is capable of fulfilling this lofty goal. A decade ago in 2012, the United Nations Conference on Sustainable Development (UNCSD), known as Rio+20, produced an outcome document that called for achieving a land-degradation-neutral world in the context of sustainable development. Given the current extent of land degradation globally, the potential benefits from land restoration for food security and for mitigating climate change are enormous. While it is true that scientific understanding of the drivers of desertification, land degradation and drought is still evolving, advocates of Regenerative Agriculture point out that these crises actually create new opportunities for increasing food security, carbon storage and climate resiliency. <br />
<br />
Regenerative Agriculture approaches are already being implemented to varying degrees across our agricultural system, while others are newly emerging. Globally, movement is underway to return to native crops specifically adapted to variations in the local climate and to greatly increase the natural fertility and carbon sequestration potential of degraded soils. Nations such as Niger, with some of the most degraded soils on the planet, are demonstrating how restoration can be accomplished – restoring an astonishing 5 million hectares to productivity in the Sahel. Private/public partnerships such as the agroforestry project in inner Mongolia’s Kubuqi Desert, have restored approximately one-third of 18,600 sq km of sand dunes and in Mali, restoration has created forest plots with higher biomass than even native forests.<br />
}}<br />
'''Three Key Trends Pushing Forward Regenerative Ag Practice Adoption'''<br />
<br />
# Data and the Digital Ag Revolution <br />
# Biologicals<br />
# Carbon / Climate - Smart Commodities<br />
<br />
'''Emerging Digital AG Revolution Solutions'''<br />
<br />
A body of scientific literature is now emerging that presents numerous strategies to decouple food production from land area, enabling increased food productivity and nutrition on the current agricultural footprint. A few examples of solutions related to data and the digital ag revolution and smart communities include:<br />
<br />
* Integrating AI enabled predictive analytics within indoor growing environments to precisely control growing variables in response to biotic and chemical signals at different stages of the growth cycle to reduce resource consumption and waste while maximizing rapid plant growth. <br />
* Deploying controlled growing environments near to where produce is sold and consumed to drastically reduce travel time, resource consumption, pollution, and shipping costs to deliver fresher, nutrient-dense food that tastes better.<br />
* Utilizing AI solutions for optimized outdoor crop placement <br />
* IoT solutions such as robots, drones, remote sensors, and computer imaging combined with continuously progressing machine learning and analytical tools for monitoring crops, surveying, and mapping the fields, and providing data to farmers for rational farm management plans to save both time and money.<br />
* Employing block-chain tracking to improve traceability of food to appeal to location-conscious buyers (sometimes called locavores), who are having an important impact on food sourcing, including the popularity of farmers markets. <br />
<br />
'''OpenCommons Cause To Embrace A RegenAG Community: Call For Action'''<br />
<br />
The purpose of this partnership with OpenCommons is to cultivate a collaborative RegenAg/AgTech community to advance promising smart technologies for urban and rural regenerative agriculture solutions.<br />
<br />
=Demonstration Projects=<br />
{{#ask: <br />
[[Category:Activity]]<br />
[[Has tag::Regenerative Agriculture]]<br />
|?=#<br />
|?Has image#=2<br />
|?Has description#=3<br />
|format=plainlist<br />
|named args=yes<br />
|introtemplate=Show image Header<br />
|template=Show image<br />
|outrotemplate=Show link Footer<br />
}}<br />
=News=<br />
{{#ask: <br />
[[Category:News]]<br />
[[Has tag::Regenerative Agriculture, Regen, RegenAG, AgTech]]<br />
|?=#<br />
|?Has image#=2<br />
|?Has summary#=3<br />
|format=plainlist<br />
|named args=yes<br />
|introtemplate=Show image Header<br />
|template=Show image<br />
|outrotemplate=Show link Footer<br />
}}</div>Elislehttps://opencommons.org/index.php?title=Regenerative_Agriculture&diff=11256Regenerative Agriculture2022-12-01T03:15:14Z<p>Elisle: </p>
<hr />
<div>{{Chapter<br />
|image=Agriculture.JPG<br />
|poc=Ed Lisle<br />
|authors=Jennifer Wells,Ed Lisle<br />
|blueprint=Agriculture<br />
|chapter=612<br />
|sectors=Agriculture<br />
|summary='''''REGENERATIVE AGRICULTURE''''' (RegenAG) involves shifting from a carbon intensive food system to carbon-negative agriculture that restores rather than degrades ecosystems. While there is no globally accepted definition, this term is widely accepted to refer to integrated systems of farming, ranching, and pastoral practices that contribute to stabilizing the planet’s climate and carbon cycles by rehabilitating and safeguarding biodiversity and living systems.<br />
<br />
A shift to Regenerative Agriculture signals a radical transformation of how, where and when we grow food, a great expansion of the varieties of seeds grown and a new microclimate-based approach focusing on smallholder farms, intercropping, agroforestry and micro-farming industry strategies. For example, the use of cover crops, crop rotation, and no till practices, reducing use or elimination of synthetic inputs, and employing integrated crop and livestock systems and managed grazing have long since been recognized as sustainable farming practices. <br />
<br />
At the same time, new approaches are under development and ancient practices reinvented, some of which are up for debate as to whether or not they fall under the Regenerative Agriculture umbrella. For instance, while there is some debate about inclusion of soilless agriculture under the Regenerative Agriculture umbrella, there is growing consensus that organic soilless methods such as aquaponics (''involving cultivation of fish that fertilize plants in interconnected, contained systems'') represent promising, sustainable approaches to growing more with less water and energy and little to no pollution. <br />
<br />
'''United Nations Sustainable Development Goals'''<br />
<br />
The United Nations Sustainable Development Goal 2 is focused on creating a world free of hunger by 2030 by improving food security, nutrition and promoting sustainable agriculture. Of the 8 billion people living today, only three-quarters of us are receiving adequate nutrition. One billion people experience chronic hunger and as our population grows, more and more people are expected to experience food insecurity. It is starkly apparent that current industrial farming practices that squander and degrade the very resources they depend on cannot continue unchanged. Industrial agricultural practices are producing an estimated 21–37% of annual emissions of the three largest individual contributors to global warming gasses, carbon dioxide, methane, and nitrous oxide, and using 70% of the fresh water available on our planet (United Nations Food and Agriculture Organization, 2022). Clearly a large conservation and restoration effort is essential if we are to provide nutrition for an anticipated population of 10 billion by 2050, which is precisely what the Regenerative Agriculture movement seeks to enable.<br />
<br />
Obviously no single solution is capable of fulfilling this lofty goal. A decade ago in 2012, the United Nations Conference on Sustainable Development (UNCSD), also known as Rio+20. Produced an outcome document that called for achieving a land-degradation-neutral world in the context of sustainable development. Given the current extent of land degradation globally, the potential benefits from land restoration for food security and for mitigating climate change are enormous. While it is true that scientific understanding of the drivers of desertification, land degradation and drought is still evolving, advocates of Regenerative Agriculture point out that these crises actually create new opportunities for increasing food security, carbon storage and climate resiliency. <br />
<br />
Happily, Regenerative Agriculture approaches are already being implemented to varying degrees across our agricultural system, while others are newly emerging. Globally, movement is underway to return to native crops specifically adapted to variations in the local climate and to greatly increase the natural fertility and carbon sequestration potential of degraded soils. Nations such as Niger, with some of the most degraded soils on the planet, are demonstrating how restoration can be accomplished – restoring an astonishing 5 million hectares to productivity in the Sahel. Private/public partnerships such as the agroforestry project in inner Mongolia’s Kubuqi Desert, have restored approximately one-third of 18,600 sq km of sand dunes and in Mali, restoration has created forest plots with higher biomass than even native forests.<br />
}}<br />
'''Three Key Trends Pushing Forward Regenerative Ag Practice Adoption'''<br />
<br />
# Data and the Digital Ag Revolution <br />
# Biologicals<br />
# Carbon / Climate - Smart Commodities<br />
<br />
'''Emerging Digital AG Revolution Solutions'''<br />
<br />
A body of scientific literature is now emerging that presents numerous strategies to decouple food production from land area, enabling increased food productivity and nutrition on the current agricultural footprint. A few examples of solutions related to data and the digital ag revolution and smart communities include:<br />
<br />
* Integrating AI enabled predictive analytics within indoor growing environments to precisely control growing variables in response to biotic and chemical signals at different stages of the growth cycle to reduce resource consumption and waste while maximizing rapid plant growth. <br />
* Deploying controlled growing environments near to where produce is sold and consumed to drastically reduce travel time, resource consumption, pollution, and shipping costs to deliver fresher, nutrient-dense food that tastes better.<br />
* Utilizing AI solutions for optimized outdoor crop placement <br />
* IoT solutions such as robots, drones, remote sensors, and computer imaging combined with continuously progressing machine learning and analytical tools for monitoring crops, surveying, and mapping the fields, and providing data to farmers for rational farm management plans to save both time and money.<br />
* Employing block-chain tracking to improve traceability of food to appeal to location-conscious buyers (sometimes called locavores), who are having an important impact on food sourcing, including the popularity of farmers markets. <br />
<br />
'''OpenCommons Cause To Embrace A RegenAG Community: Call For Action'''<br />
<br />
The purpose of this partnership with OpenCommons is to cultivate a collaborative RegenAg/AgTech community to advance promising smart technologies for urban and rural regenerative agriculture solutions.<br />
<br />
=Demonstration Projects=<br />
{{#ask: <br />
[[Category:Activity]]<br />
[[Has tag::Regenerative Agriculture]]<br />
|?=#<br />
|?Has image#=2<br />
|?Has description#=3<br />
|format=plainlist<br />
|named args=yes<br />
|introtemplate=Show image Header<br />
|template=Show image<br />
|outrotemplate=Show link Footer<br />
}}<br />
=News=<br />
{{#ask: <br />
[[Category:News]]<br />
[[Has tag::Regenerative Agriculture, Regen, RegenAG, AgTech]]<br />
|?=#<br />
|?Has image#=2<br />
|?Has summary#=3<br />
|format=plainlist<br />
|named args=yes<br />
|introtemplate=Show image Header<br />
|template=Show image<br />
|outrotemplate=Show link Footer<br />
}}</div>Elislehttps://opencommons.org/index.php?title=Regenerative_Agriculture&diff=11255Regenerative Agriculture2022-12-01T03:13:09Z<p>Elisle: </p>
<hr />
<div>{{Chapter<br />
|image=Agriculture.JPG<br />
|poc=Ed Lisle<br />
|authors=Jennifer Wells,Ed Lisle<br />
|blueprint=Agriculture<br />
|chapter=612<br />
|sectors=Agriculture<br />
|summary='''''REGENERATIVE AGRICULTURE''''' (RegenAG) involves shifting from a carbon intensive food system to carbon-negative agriculture that restores rather than degrades ecosystems. While there is no globally accepted definition, this term is widely accepted to refer to integrated systems of farming, ranching, and pastoral practices that contribute to stabilizing the planet’s climate and carbon cycles by rehabilitating and safeguarding biodiversity and living systems.<br />
<br />
A shift to Regenerative Agriculture signals a radical transformation of how, where and when we grow food, a great expansion of the varieties of seeds grown and a new microclimate-based approach focusing on smallholder farms, intercropping, agroforestry and micro-farming industry strategies. For example, the use of cover crops, crop rotation, and no till practices, reducing use or elimination of synthetic inputs, and employing integrated crop and livestock systems and managed grazing have long since been recognized as sustainable farming practices. <br />
<br />
At the same time, new approaches are under development and ancient practices reinvented, some of which are up for debate as to whether or not they fall under the Regenerative Agriculture umbrella. For instance, while there is some debate about inclusion of soilless agriculture under the Regenerative Agriculture umbrella, there is growing consensus that organic soilless methods such as aquaponics (''involving cultivation of fish that fertilize plants in interconnected, contained systems'') represent promising, sustainable approaches to growing more with less water and energy and little to no pollution. <br />
<br />
'''United Nations Sustainable Development Goals'''<br />
<br />
The United Nations Sustainable Development Goal 2 is focused on creating a world free of hunger by 2030 by improving food security, nutrition and promoting sustainable agriculture. Of the 8 billion people living today, only three-quarters of us are receiving adequate nutrition. One billion people experience chronic hunger and as our population grows, more and more people are expected to experience food insecurity. It is starkly apparent that current industrial farming practices that squander and degrade the very resources they depend on cannot continue unchanged. Industrial agricultural practices are producing an estimated 21–37% of annual emissions of the three largest individual contributors to global warming gasses, carbon dioxide, methane, and nitrous oxide, and using 70% of the fresh water available on our planet (United Nations Food and Agriculture Organization, 2022). Clearly a large conservation and restoration effort is essential if we are to provide nutrition for an anticipated population of 10 billion by 2050, which is precisely what the Regenerative Agriculture movement seeks to enable.<br />
<br />
Obviously no single solution is capable of fulfilling this lofty goal. A decade ago in 2012, the United Nations Conference on Sustainable Development (UNCSD), also known as [https://sustainabledevelopment.un.org/rio20/about Rio+20]<br />
. Produced an outcome document that called for achieving a land-degradation-neutral world in the context of sustainable development. Given the current extent of land degradation globally, the potential benefits from land restoration for food security and for mitigating climate change are enormous. While it is true that scientific understanding of the drivers of desertification, land degradation and drought is still evolving, advocates of Regenerative Agriculture point out that these crises actually create new opportunities for increasing food security, carbon storage and climate resiliency. <br />
<br />
Happily, Regenerative Agriculture approaches are already being implemented to varying degrees across our agricultural system, while others are newly emerging. Globally, movement is underway to return to native crops specifically adapted to variations in the local climate and to greatly increase the natural fertility and carbon sequestration potential of degraded soils. Nations such as Niger, with some of the most degraded soils on the planet, are demonstrating how restoration can be accomplished – restoring an astonishing 5 million hectares to productivity in the Sahel. Private/public partnerships such as the agroforestry project in inner Mongolia’s Kubuqi Desert, have restored approximately one-third of 18,600 sq km of sand dunes and in Mali, restoration has created forest plots with higher biomass than even native forests.<br />
}}<br />
'''Three Key Trends Pushing Forward Regenerative Ag Practice Adoption'''<br />
<br />
# Data and the Digital Ag Revolution <br />
# Biologicals<br />
# Carbon / Climate - Smart Commodities<br />
<br />
'''Emerging Digital AG Revolution Solutions'''<br />
<br />
A body of scientific literature is now emerging that presents numerous strategies to decouple food production from land area, enabling increased food productivity and nutrition on the current agricultural footprint. A few examples of solutions related to data and the digital ag revolution and smart communities include:<br />
<br />
* Integrating AI enabled predictive analytics within indoor growing environments to precisely control growing variables in response to biotic and chemical signals at different stages of the growth cycle to reduce resource consumption and waste while maximizing rapid plant growth. <br />
* Deploying controlled growing environments near to where produce is sold and consumed to drastically reduce travel time, resource consumption, pollution, and shipping costs to deliver fresher, nutrient-dense food that tastes better.<br />
* Utilizing AI solutions for optimized outdoor crop placement <br />
* IoT solutions such as robots, drones, remote sensors, and computer imaging combined with continuously progressing machine learning and analytical tools for monitoring crops, surveying, and mapping the fields, and providing data to farmers for rational farm management plans to save both time and money.<br />
* Employing block-chain tracking to improve traceability of food to appeal to location-conscious buyers (sometimes called locavores), who are having an important impact on food sourcing, including the popularity of farmers markets. <br />
<br />
'''OpenCommons Cause To Embrace A RegenAG Community: Call For Action'''<br />
<br />
The purpose of this partnership with OpenCommons is to cultivate a collaborative RegenAg/AgTech community to advance promising smart technologies for urban and rural regenerative agriculture solutions.<br />
<br />
=Demonstration Projects=<br />
{{#ask: <br />
[[Category:Activity]]<br />
[[Has tag::Regenerative Agriculture]]<br />
|?=#<br />
|?Has image#=2<br />
|?Has description#=3<br />
|format=plainlist<br />
|named args=yes<br />
|introtemplate=Show image Header<br />
|template=Show image<br />
|outrotemplate=Show link Footer<br />
}}<br />
=News=<br />
{{#ask: <br />
[[Category:News]]<br />
[[Has tag::Regenerative Agriculture, Regen, RegenAG, AgTech]]<br />
|?=#<br />
|?Has image#=2<br />
|?Has summary#=3<br />
|format=plainlist<br />
|named args=yes<br />
|introtemplate=Show image Header<br />
|template=Show image<br />
|outrotemplate=Show link Footer<br />
}}</div>Elislehttps://opencommons.org/index.php?title=Regenerative_Agriculture&diff=11254Regenerative Agriculture2022-11-30T17:22:27Z<p>Elisle: </p>
<hr />
<div>{{Chapter<br />
|image=Agriculture.JPG<br />
|poc=Ed Lisle<br />
|authors=Jennifer Wells,Ed Lisle<br />
|blueprint=Agriculture<br />
|chapter=612<br />
|sectors=Agriculture<br />
|summary='''''REGENERATIVE AGRICULTURE''''' (RegenAG) involves shifting from a carbon intensive food system to carbon-negative agriculture that restores rather than degrades ecosystems. While there is no globally accepted definition, this term is widely accepted to refer to integrated systems of farming, ranching, and pastoral practices that contribute to stabilizing the planet’s climate and carbon cycles by rehabilitating and safeguarding biodiversity and living systems.<br />
<br />
A shift to Regenerative Agriculture signals a radical transformation of how, where and when we grow food, a great expansion of the varieties of seeds grown and a new microclimate-based approach focusing on smallholder farms, intercropping, agroforestry and micro-farming industry strategies. For example, the use of cover crops, crop rotation, and no till practices, reducing use or elimination of synthetic inputs, and employing integrated crop and livestock systems and managed grazing have long since been recognized as sustainable farming practices. <br />
<br />
At the same time, new approaches are under development and ancient practices reinvented, some of which are up for debate as to whether or not they fall under the Regenerative Agriculture umbrella. For instance, while there is some debate about inclusion of soilless agriculture under the Regenerative Agriculture umbrella, there is growing consensus that organic soilless methods such as aquaponics (''involving cultivation of fish that fertilize plants in interconnected, contained systems'') represent promising, sustainable approaches to growing more with less water and energy and little to no pollution. <br />
<br />
'''United Nations Sustainable Development Goals'''<br />
<br />
The United Nations Sustainable Development Goal 2 is focused on creating a world free of hunger by 2030 by improving food security, nutrition and promoting sustainable agriculture. Of the 8 billion people living today, only three-quarters of us are receiving adequate nutrition. One billion people experience chronic hunger and as our population grows, more and more people are expected to experience food insecurity. It is starkly apparent that current industrial farming practices that squander and degrade the very resources they depend on cannot continue unchanged. Industrial agricultural practices are producing an estimated 21–37% of annual emissions of the three largest individual contributors to global warming gasses, carbon dioxide, methane, and nitrous oxide, and using 70% of the fresh water available on our planet (United Nations Food and Agriculture Organization, 2022). Clearly a large conservation and restoration effort is essential if we are to provide nutrition for an anticipated population of 10 billion by 2050, which is precisely what the Regenerative Agriculture movement seeks to enable.<br />
<br />
Obviously no single solution is capable of fulfilling this lofty goal. A decade ago in 2012, the United Nations Conference on Sustainable Development (UNCSD), also known as Rio+20. Produced an outcome document that called for achieving a land-degradation-neutral world in the context of sustainable development. Given the current extent of land degradation globally, the potential benefits from land restoration for food security and for mitigating climate change are enormous. While it is true that scientific understanding of the drivers of desertification, land degradation and drought is still evolving, advocates of Regenerative Agriculture point out that these crises actually create new opportunities for increasing food security, carbon storage and climate resiliency. <br />
<br />
Happily, Regenerative Agriculture approaches are already being implemented to varying degrees across our agricultural system, while others are newly emerging. Globally, movement is underway to return to native crops specifically adapted to variations in the local climate and to greatly increase the natural fertility and carbon sequestration potential of degraded soils. Nations such as Niger, with some of the most degraded soils on the planet, are demonstrating how restoration can be accomplished – restoring an astonishing 5 million hectares to productivity in the Sahel. Private/public partnerships such as the agroforestry project in inner Mongolia’s Kubuqi Desert, have restored approximately one-third of 18,600 sq km of sand dunes and in Mali, restoration has created forest plots with higher biomass than even native forests.<br />
}}<br />
'''Three Key Trends Pushing Forward Regenerative Ag Practice Adoption'''<br />
<br />
# Data and the Digital Ag Revolution <br />
# Biologicals<br />
# Carbon / Climate - Smart Commodities<br />
<br />
'''Emerging Digital AG Revolution Solutions'''<br />
<br />
A body of scientific literature is now emerging that presents numerous strategies to decouple food production from land area, enabling increased food productivity and nutrition on the current agricultural footprint. A few examples of solutions related to data and the digital ag revolution and smart communities include:<br />
<br />
* Integrating AI enabled predictive analytics within indoor growing environments to precisely control growing variables in response to biotic and chemical signals at different stages of the growth cycle to reduce resource consumption and waste while maximizing rapid plant growth. <br />
* Deploying controlled growing environments near to where produce is sold and consumed to drastically reduce travel time, resource consumption, pollution, and shipping costs to deliver fresher, nutrient-dense food that tastes better.<br />
* Utilizing AI solutions for optimized outdoor crop placement <br />
* IoT solutions such as robots, drones, remote sensors, and computer imaging combined with continuously progressing machine learning and analytical tools for monitoring crops, surveying, and mapping the fields, and providing data to farmers for rational farm management plans to save both time and money.<br />
* Employing block-chain tracking to improve traceability of food to appeal to location-conscious buyers (sometimes called locavores), who are having an important impact on food sourcing, including the popularity of farmers markets. <br />
<br />
'''OpenCommons Cause To Embrace A RegenAG Community: A Call For Action'''<br />
<br />
The purpose of this partnership with OpenCommons is to cultivate a collaborative RegenAg/AgTech community to advance promising smart technologies for urban and rural regenerative agriculture solutions.<br />
<br />
=Demonstration Projects=<br />
{{#ask: <br />
[[Category:Activity]]<br />
[[Has tag::Regenerative Agriculture]]<br />
|?=#<br />
|?Has image#=2<br />
|?Has description#=3<br />
|format=plainlist<br />
|named args=yes<br />
|introtemplate=Show image Header<br />
|template=Show image<br />
|outrotemplate=Show link Footer<br />
}}<br />
=News=<br />
{{#ask: <br />
[[Category:News]]<br />
[[Has tag::Regenerative Agriculture]]<br />
|?=#<br />
|?Has image#=2<br />
|?Has summary#=3<br />
|format=plainlist<br />
|named args=yes<br />
|introtemplate=Show image Header<br />
|template=Show image<br />
|outrotemplate=Show link Footer<br />
}}</div>Elislehttps://opencommons.org/index.php?title=Regenerative_Agriculture&diff=11253Regenerative Agriculture2022-11-30T04:42:20Z<p>Elisle: </p>
<hr />
<div>{{Chapter<br />
|image=Agriculture.JPG<br />
|poc=Ed Lisle<br />
|authors=Jennifer Wells,Ed Lisle<br />
|blueprint=Agriculture<br />
|chapter=612<br />
|sectors=Agriculture<br />
|summary='''''REGENERATIVE AGRICULTURE''''' (RegenAG) involves shifting from a carbon intensive food system to carbon-negative agriculture that restores rather than degrades ecosystems. While there is no globally accepted definition, this term is widely accepted to refer to integrated systems of farming, ranching, and pastoral practices that contribute to stabilizing the planet’s climate and carbon cycles by rehabilitating and safeguarding biodiversity and living systems.<br />
<br />
A shift to Regenerative Agriculture signals a radical transformation of how, where and when we grow food, a great expansion of the varieties of seeds grown and a new microclimate-based approach focusing on smallholder farms, intercropping, agroforestry and micro-farming industry strategies. For example, the use of cover crops, crop rotation, and no till practices, reducing use or elimination of synthetic inputs, and employing integrated crop and livestock systems and managed grazing have long since been recognized as sustainable farming practices. <br />
<br />
At the same time, new approaches are under development and ancient practices reinvented, some of which are up for debate as to whether or not they fall under the Regenerative Agriculture umbrella. For instance, while there is some debate about inclusion of soilless agriculture under the Regenerative Agriculture umbrella, there is growing consensus that organic soilless methods such as aquaponics (''involving cultivation of fish that fertilize plants in interconnected, contained systems'') represent promising, sustainable approaches to growing more with less water and energy and little to no pollution. <br />
<br />
'''United Nations Sustainable Development Goals'''<br />
<br />
The United Nations Sustainable Development Goal 2 is focused on creating a world free of hunger by 2030 by improving food security, nutrition and promoting sustainable agriculture. Of the 8 billion people living today, only three-quarters of us are receiving adequate nutrition. One billion people experience chronic hunger and as our population grows, more and more people are expected to experience food insecurity. It is starkly apparent that current industrial farming practices that squander and degrade the very resources they depend on cannot continue unchanged. Industrial agricultural practices are producing an estimated 21–37% of annual emissions of the three largest individual contributors to global warming gasses, carbon dioxide, methane, and nitrous oxide, and using 70% of the fresh water available on our planet (United Nations Food and Agriculture Organization, 2022). Clearly a large conservation and restoration effort is essential if we are to provide nutrition for an anticipated population of 10 billion by 2050, which is precisely what the Regenerative Agriculture movement seeks to enable.<br />
<br />
Obviously no single solution is capable of fulfilling this lofty goal. A decade ago in 2012, the United Nations Conference on Sustainable Development (UNCSD), also known as Rio+20. Produced an outcome document that called for achieving a land-degradation-neutral world in the context of sustainable development. Given the current extent of land degradation globally, the potential benefits from land restoration for food security and for mitigating climate change are enormous. While it is true that scientific understanding of the drivers of desertification, land degradation and drought is still evolving, advocates of Regenerative Agriculture point out that these crises actually create new opportunities for increasing food security, carbon storage and climate resiliency. <br />
<br />
Happily, Regenerative Agriculture approaches are already being implemented to varying degrees across our agricultural system, while others are newly emerging. Globally, movement is underway to return to native crops specifically adapted to variations in the local climate and to greatly increase the natural fertility and carbon sequestration potential of degraded soils. Nations such as Niger, with some of the most degraded soils on the planet, are demonstrating how restoration can be accomplished – restoring an astonishing 5 million hectares to productivity in the Sahel. Private/public partnerships such as the agroforestry project in inner Mongolia’s Kubuqi Desert, have restored approximately one-third of 18,600 sq km of sand dunes and in Mali, restoration has created forest plots with higher biomass than even native forests.<br />
}}<br />
'''Three Key Trends Pushing Forward Regenerative Ag Practice Adoption'''<br />
<br />
# Data and the Digital Ag Revolution <br />
# Biologicals<br />
# Carbon / Climate - Smart Commodities<br />
<br />
'''Emerging Digital AG Revolution Solutions'''<br />
<br />
A body of scientific literature is now emerging that presents numerous strategies to decouple food production from land area, enabling increased food productivity and nutrition on the current agricultural footprint. A few examples of solutions related to data and the digital ag revolution and smart communities include:<br />
<br />
* Integrating AI enabled predictive analytics within indoor growing environments to precisely control growing variables in response to biotic and chemical signals at different stages of the growth cycle to reduce resource consumption and waste while maximizing rapid plant growth. <br />
* Deploying controlled growing environments near to where produce is sold and consumed to drastically reduce travel time, resource consumption, pollution, and shipping costs to deliver fresher, nutrient-dense food that tastes better.<br />
* Utilizing AI solutions for optimized outdoor crop placement <br />
* IoT solutions such as robots, drones, remote sensors, and computer imaging combined with continuously progressing machine learning and analytical tools for monitoring crops, surveying, and mapping the fields, and providing data to farmers for rational farm management plans to save both time and money.<br />
* Employing block-chain tracking to improve traceability of food to appeal to location-conscious buyers (sometimes called locavores), who are having an important impact on food sourcing, including the popularity of farmers markets. <br />
<br />
'''OpenCommons Cause To Embrace A RegenAG Community: A Call For Action'''<br />
<br />
The purpose of this partnership with OpenCommons is to cultivate a collaborative community to advance promising smart technologies for urban and rural regenerative agriculture solutions.<br />
<br />
=Demonstration Projects=<br />
{{#ask: <br />
[[Category:Activity]]<br />
[[Has tag::Regenerative Agriculture]]<br />
|?=#<br />
|?Has image#=2<br />
|?Has description#=3<br />
|format=plainlist<br />
|named args=yes<br />
|introtemplate=Show image Header<br />
|template=Show image<br />
|outrotemplate=Show link Footer<br />
}}<br />
=News=<br />
{{#ask: <br />
[[Category:News]]<br />
[[Has tag::Regenerative Agriculture]]<br />
|?=#<br />
|?Has image#=2<br />
|?Has summary#=3<br />
|format=plainlist<br />
|named args=yes<br />
|introtemplate=Show image Header<br />
|template=Show image<br />
|outrotemplate=Show link Footer<br />
}}</div>Elislehttps://opencommons.org/index.php?title=Regenerative_Agriculture&diff=11252Regenerative Agriculture2022-11-30T04:41:37Z<p>Elisle: </p>
<hr />
<div>{{Chapter<br />
|image=Agriculture.JPG<br />
|poc=Ed Lisle<br />
|authors=Jennifer Wells,Ed Lisle<br />
|blueprint=Agriculture<br />
|chapter=612<br />
|sectors=Agriculture<br />
|summary='''''REGENERATIVE AGRICULTURE''''' (RegenAG) involves shifting from a carbon intensive food system to carbon-negative agriculture that restores rather than degrades ecosystems. While there is no globally accepted definition, this term is widely accepted to refer to integrated systems of farming, ranching, and pastoral practices that contribute to stabilizing the planet’s climate and carbon cycles by rehabilitating and safeguarding biodiversity and living systems.<br />
<br />
A shift to Regenerative Agriculture signals a radical transformation of how, where and when we grow food, a great expansion of the varieties of seeds grown and a new microclimate-based approach focusing on smallholder farms, intercropping, agroforestry and micro-farming industry strategies. For example, the use of cover crops, crop rotation, and no till practices, reducing use or elimination of synthetic inputs, and employing integrated crop and livestock systems and managed grazing have long since been recognized as sustainable farming practices. <br />
<br />
At the same time, new approaches are under development and ancient practices reinvented, some of which are up for debate as to whether or not they fall under the Regenerative Agriculture umbrella. For instance, while there is some debate about inclusion of soilless agriculture under the Regenerative Agriculture umbrella, there is growing consensus that organic soilless methods such as aquaponics (''involving cultivation of fish that fertilize plants in interconnected, contained systems'') represent promising, sustainable approaches to growing more with less water and energy and little to no pollution. <br />
<br />
'''United Nations Sustainable Development Goals'''<br />
<br />
The United Nations Sustainable Development Goal 2 is focused on creating a world free of hunger by 2030 by improving food security, nutrition and promoting sustainable agriculture. Of the 8 billion people living today, only three-quarters of us are receiving adequate nutrition. One billion people experience chronic hunger and as our population grows, more and more people are expected to experience food insecurity. It is starkly apparent that current industrial farming practices that squander and degrade the very resources they depend on cannot continue unchanged. Industrial agricultural practices are producing an estimated 21–37% of annual emissions of the three largest individual contributors to global warming gasses, carbon dioxide, methane, and nitrous oxide, and using 70% of the fresh water available on our planet (United Nations Food and Agriculture Organization, 2022). Clearly a large conservation and restoration effort is essential if we are to provide nutrition for an anticipated population of 10 billion by 2050, which is precisely what the Regenerative Agriculture movement seeks to enable.<br />
<br />
Obviously no single solution is capable of fulfilling this lofty goal. A decade ago in 2012, the United Nations Conference on Sustainable Development (UNCSD), also known as Rio+20. Produced an outcome document that called for achieving a land-degradation-neutral world in the context of sustainable development. Given the current extent of land degradation globally, the potential benefits from land restoration for food security and for mitigating climate change are enormous. While it is true that scientific understanding of the drivers of desertification, land degradation and drought is still evolving, advocates of Regenerative Agriculture point out that these crises actually create new opportunities for increasing food security, carbon storage and climate resiliency. <br />
<br />
Happily, Regenerative Agriculture approaches are already being implemented to varying degrees across our agricultural system, while others are newly emerging. Globally, movement is underway to return to native crops specifically adapted to variations in the local climate and to greatly increase the natural fertility and carbon sequestration potential of degraded soils. Nations such as Niger, with some of the most degraded soils on the planet, are demonstrating how restoration can be accomplished – restoring an astonishing 5 million hectares to productivity in the Sahel. Private/public partnerships such as the agroforestry project in inner Mongolia’s Kubuqi Desert, have restored approximately one-third of 18,600 sq km of sand dunes and in Mali, restoration has created forest plots with higher biomass than even native forests.<br />
}}<br />
'''Three Key Trends Pushing Forward Regenerative Practice Adoption'''<br />
<br />
# Data and the Digital Ag Revolution <br />
# Biologicals<br />
# Carbon / Climate - Smart Commodities<br />
<br />
'''Emerging Digital AG Revolution Solutions'''<br />
<br />
A body of scientific literature is now emerging that presents numerous strategies to decouple food production from land area, enabling increased food productivity and nutrition on the current agricultural footprint. A few examples of solutions related to data and the digital ag revolution and smart communities include:<br />
<br />
* Integrating AI enabled predictive analytics within indoor growing environments to precisely control growing variables in response to biotic and chemical signals at different stages of the growth cycle to reduce resource consumption and waste while maximizing rapid plant growth. <br />
* Deploying controlled growing environments near to where produce is sold and consumed to drastically reduce travel time, resource consumption, pollution, and shipping costs to deliver fresher, nutrient-dense food that tastes better.<br />
* Utilizing AI solutions for optimized outdoor crop placement <br />
* IoT solutions such as robots, drones, remote sensors, and computer imaging combined with continuously progressing machine learning and analytical tools for monitoring crops, surveying, and mapping the fields, and providing data to farmers for rational farm management plans to save both time and money.<br />
* Employing block-chain tracking to improve traceability of food to appeal to location-conscious buyers (sometimes called locavores), who are having an important impact on food sourcing, including the popularity of farmers markets. <br />
<br />
'''OpenCommons Cause To Embrace A RegenAG Community: A Call For Action'''<br />
<br />
The purpose of this partnership with OpenCommons is to cultivate a collaborative community to advance promising smart technologies for urban and rural regenerative agriculture solutions.<br />
<br />
=Demonstration Projects=<br />
{{#ask: <br />
[[Category:Activity]]<br />
[[Has tag::Regenerative Agriculture]]<br />
|?=#<br />
|?Has image#=2<br />
|?Has description#=3<br />
|format=plainlist<br />
|named args=yes<br />
|introtemplate=Show image Header<br />
|template=Show image<br />
|outrotemplate=Show link Footer<br />
}}<br />
=News=<br />
{{#ask: <br />
[[Category:News]]<br />
[[Has tag::Regenerative Agriculture]]<br />
|?=#<br />
|?Has image#=2<br />
|?Has summary#=3<br />
|format=plainlist<br />
|named args=yes<br />
|introtemplate=Show image Header<br />
|template=Show image<br />
|outrotemplate=Show link Footer<br />
}}</div>Elislehttps://opencommons.org/index.php?title=Regenerative_Agriculture&diff=11251Regenerative Agriculture2022-11-30T04:35:30Z<p>Elisle: </p>
<hr />
<div>{{Chapter<br />
|image=Agriculture.JPG<br />
|poc=Ed Lisle<br />
|authors=Jennifer Wells,Ed Lisle<br />
|blueprint=Agriculture<br />
|chapter=612<br />
|sectors=Agriculture<br />
|summary='''''REGENERATIVE AGRICULTURE''''' (RegenAG) involves shifting from a carbon intensive food system to carbon-negative agriculture that restores rather than degrades ecosystems. While there is no globally accepted definition, this term is widely accepted to refer to integrated systems of farming, ranching, and pastoral practices that contribute to stabilizing the planet’s climate and carbon cycles by rehabilitating and safeguarding biodiversity and living systems.<br />
<br />
A shift to Regenerative Agriculture signals a radical transformation of how, where and when we grow food, a great expansion of the varieties of seeds grown and a new microclimate-based approach focusing on smallholder farms, intercropping, agroforestry and micro-farming industry strategies. For example, the use of cover crops, crop rotation, and no till practices, reducing use or elimination of synthetic inputs, and employing integrated crop and livestock systems and managed grazing have long since been recognized as sustainable farming practices. <br />
<br />
At the same time, new approaches are under development and ancient practices reinvented, some of which are up for debate as to whether or not they fall under the Regenerative Agriculture umbrella. For instance, while there is some debate about inclusion of soilless agriculture under the Regenerative Agriculture umbrella, there is growing consensus that organic soilless methods such as aquaponics (''involving cultivation of fish that fertilize plants in interconnected, contained systems'') represent promising, sustainable approaches to growing more with less water and energy and little to no pollution. <br />
<br />
'''United Nations Sustainable Development Goals'''<br />
<br />
The United Nations Sustainable Development Goal 2 is focused on creating a world free of hunger by 2030 by improving food security, nutrition and promoting sustainable agriculture. Of the 8 billion people living today, only three-quarters of us are receiving adequate nutrition. One billion people experience chronic hunger and as our population grows, more and more people are expected to experience food insecurity. It is starkly apparent that current industrial farming practices that squander and degrade the very resources they depend on cannot continue unchanged. Industrial agricultural practices are producing an estimated 21–37% of annual emissions of the three largest individual contributors to global warming gasses, carbon dioxide, methane, and nitrous oxide, and using 70% of the fresh water available on our planet (United Nations Food and Agriculture Organization, 2022). Clearly a large conservation and restoration effort is essential if we are to provide nutrition for an anticipated population of 10 billion by 2050, which is precisely what the Regenerative Agriculture movement seeks to enable.<br />
<br />
Obviously no single solution is capable of fulfilling this lofty goal. A decade ago in 2012, the United Nations Conference on Sustainable Development (UNCSD), also known as Rio+20. Produced an outcome document that called for achieving a land-degradation-neutral world in the context of sustainable development. Given the current extent of land degradation globally, the potential benefits from land restoration for food security and for mitigating climate change are enormous. While it is true that scientific understanding of the drivers of desertification, land degradation and drought is still evolving, advocates of Regenerative Agriculture point out that these crises actually create new opportunities for increasing food security, carbon storage and climate resiliency. <br />
<br />
Happily, Regenerative Agriculture approaches are already being implemented to varying degrees across our agricultural system, while others are newly emerging. Globally, movement is underway to return to native crops specifically adapted to variations in the local climate and to greatly increase the natural fertility and carbon sequestration potential of degraded soils. Nations such as Niger, with some of the most degraded soils on the planet, are demonstrating how restoration can be accomplished – restoring an astonishing 5 million hectares to productivity in the Sahel. Private/public partnerships such as the agroforestry project in inner Mongolia’s Kubuqi Desert, have restored approximately one-third of 18,600 sq km of sand dunes and in Mali, restoration has created forest plots with higher biomass than even native forests.<br />
}}<br />
'''Three Key Trends Pushing Forward Regenerative Practice Adoption'''<br />
<br />
# Data and the Digital Ag Revolution <br />
# Biologicals<br />
# Carbon / Climate - Smart Commodities<br />
<br />
'''Digital AG Revolution Solution Examples'''<br />
<br />
A body of scientific literature is now emerging that presents numerous strategies to decouple food production from land area, enabling increased food productivity and nutrition on the current agricultural footprint. A few examples of solutions related to data and the digital ag revolution and smart communities include:<br />
<br />
* Integrating AI enabled predictive analytics within indoor growing environments to precisely control growing variables in response to biotic and chemical signals at different stages of the growth cycle to reduce resource consumption and waste while maximizing rapid plant growth. <br />
* Deploying controlled growing environments near to where produce is sold and consumed to drastically reduce travel time, resource consumption, pollution, and shipping costs to deliver fresher, nutrient-dense food that tastes better.<br />
* Utilizing AI solutions for optimized outdoor crop placement <br />
* IoT solutions such as robots, drones, remote sensors, and computer imaging combined with continuously progressing machine learning and analytical tools for monitoring crops, surveying, and mapping the fields, and providing data to farmers for rational farm management plans to save both time and money.<br />
* Employing block-chain tracking to improve traceability of food to appeal to location-conscious buyers (sometimes called locavores), who are having an important impact on food sourcing, including the popularity of farmers markets. <br />
<br />
'''OpenCommons Cause To Embrace A RegenAG Community: A Call For Action'''<br />
<br />
The purpose of this partnership with OpenCommons is to cultivate a collaborative community to advance promising smart technologies for urban and rural regenerative agriculture solutions.<br />
<br />
=Demonstration Projects=<br />
{{#ask: <br />
[[Category:Activity]]<br />
[[Has tag::Regenerative Agriculture]]<br />
|?=#<br />
|?Has image#=2<br />
|?Has description#=3<br />
|format=plainlist<br />
|named args=yes<br />
|introtemplate=Show image Header<br />
|template=Show image<br />
|outrotemplate=Show link Footer<br />
}}<br />
=News=<br />
{{#ask: <br />
[[Category:News]]<br />
[[Has tag::Regenerative Agriculture]]<br />
|?=#<br />
|?Has image#=2<br />
|?Has summary#=3<br />
|format=plainlist<br />
|named args=yes<br />
|introtemplate=Show image Header<br />
|template=Show image<br />
|outrotemplate=Show link Footer<br />
}}</div>Elislehttps://opencommons.org/index.php?title=Regenerative_Agriculture&diff=11250Regenerative Agriculture2022-11-30T04:34:05Z<p>Elisle: </p>
<hr />
<div>{{Chapter<br />
|image=Agriculture.JPG<br />
|poc=Ed Lisle<br />
|authors=Jennifer Wells,Ed Lisle<br />
|blueprint=Agriculture<br />
|chapter=612<br />
|sectors=Agriculture<br />
|summary='''''REGENERATIVE AGRICULTURE''''' (RegenAG) involves shifting from a carbon intensive food system to carbon-negative agriculture that restores rather than degrades ecosystems. While there is no globally accepted definition, this term is widely accepted to refer to integrated systems of farming, ranching, and pastoral practices that contribute to stabilizing the planet’s climate and carbon cycles by rehabilitating and safeguarding biodiversity and living systems.<br />
<br />
A shift to Regenerative Agriculture signals a radical transformation of how, where and when we grow food, a great expansion of the varieties of seeds grown and a new microclimate-based approach focusing on smallholder farms, intercropping, agroforestry and micro-farming industry strategies. For example, the use of cover crops, crop rotation, and no till practices, reducing use or elimination of synthetic inputs, and employing integrated crop and livestock systems and managed grazing have long since been recognized as sustainable farming practices. <br />
<br />
At the same time, new approaches are under development and ancient practices reinvented, some of which are up for debate as to whether or not they fall under the Regenerative Agriculture umbrella. For instance, while there is some debate about inclusion of soilless agriculture under the Regenerative Agriculture umbrella, there is growing consensus that organic soilless methods such as aquaponics (''involving cultivation of fish that fertilize plants in interconnected, contained systems'') represent promising, sustainable approaches to growing more with less water and energy and little to no pollution. <br />
<br />
'''United Nations Sustainable Development Goals'''<br />
<br />
The United Nations Sustainable Development Goal 2 is focused on creating a world free of hunger by 2030 by improving food security, nutrition and promoting sustainable agriculture. Of the 8 billion people living today, only three-quarters of us are receiving adequate nutrition. One billion people experience chronic hunger and as our population grows, more and more people are expected to experience food insecurity. It is starkly apparent that current industrial farming practices that squander and degrade the very resources they depend on cannot continue unchanged. Industrial agricultural practices are producing an estimated 21–37% of annual emissions of the three largest individual contributors to global warming gasses, carbon dioxide, methane, and nitrous oxide, and using 70% of the fresh water available on our planet (United Nations Food and Agriculture Organization, 2022). Clearly a large conservation and restoration effort is essential if we are to provide nutrition for an anticipated population of 10 billion by 2050, which is precisely what the Regenerative Agriculture movement seeks to enable.<br />
<br />
Obviously no single solution is capable of fulfilling this lofty goal. A decade ago in 2012, the United Nations Conference on Sustainable Development (UNCSD), also known as Rio+20. Produced an outcome document that called for achieving a land-degradation-neutral world in the context of sustainable development. Given the current extent of land degradation globally, the potential benefits from land restoration for food security and for mitigating climate change are enormous. While it is true that scientific understanding of the drivers of desertification, land degradation and drought is still evolving, advocates of Regenerative Agriculture point out that these crises actually create new opportunities for increasing food security, carbon storage and climate resiliency. <br />
<br />
Happily, Regenerative Agriculture approaches are already being implemented to varying degrees across our agricultural system, while others are newly emerging. Globally, movement is underway to return to native crops specifically adapted to variations in the local climate and to greatly increase the natural fertility and carbon sequestration potential of degraded soils. Nations such as Niger, with some of the most degraded soils on the planet, are demonstrating how restoration can be accomplished – restoring an astonishing 5 million hectares to productivity in the Sahel. Private/public partnerships such as the agroforestry project in inner Mongolia’s Kubuqi Desert, have restored approximately one-third of 18,600 sq km of sand dunes and in Mali, restoration has created forest plots with higher biomass than even native forests.<br />
}}<br />
'''Three Key Trends Pushing Forward Regenerative Practice Adoption'''<br />
<br />
# Data and the Digital Ag Revolution <br />
# Biologicals<br />
# Carbon / Climate - Smart Commodities<br />
<br />
'''Digital AG Revolution Solution Examples'''<br />
<br />
A body of scientific literature is now emerging that presents numerous strategies to decouple food production from land area, enabling increased food productivity and nutrition on the current agricultural footprint. A few examples of solutions related to data and the digital ag revolution and smart communities include:<br />
<br />
* Integrating AI enabled predictive analytics within indoor growing environments to precisely control growing variables in response to biotic and chemical signals at different stages of the growth cycle to reduce resource consumption and waste while maximizing rapid plant growth. <br />
* Deploying controlled growing environments near to where produce is sold and consumed to drastically reduce travel time, resource consumption, pollution, and shipping costs to deliver fresher, nutrient-dense food that tastes better.<br />
* Utilizing AI solutions for optimized outdoor crop placement <br />
* IoT solutions such as robots, drones, remote sensors, and computer imaging combined with continuously progressing machine learning and analytical tools for monitoring crops, surveying, and mapping the fields, and providing data to farmers for rational farm management plans to save both time and money.<br />
* Employing block-chain tracking to improve traceability of food to appeal to location-conscious buyers (sometimes called locavores), who are having an important impact on food sourcing, including the popularity of farmers markets. <br />
<br />
'''OpenCommons Cause For RegenAG - A Call For Action'''<br />
<br />
The purpose of this partnership with OpenCommons is to cultivate a collaborative community to advance promising smart technologies for urban and rural regenerative agriculture solutions.<br />
<br />
=Demonstration Projects=<br />
{{#ask: <br />
[[Category:Activity]]<br />
[[Has tag::Regenerative Agriculture]]<br />
|?=#<br />
|?Has image#=2<br />
|?Has description#=3<br />
|format=plainlist<br />
|named args=yes<br />
|introtemplate=Show image Header<br />
|template=Show image<br />
|outrotemplate=Show link Footer<br />
}}<br />
=News=<br />
{{#ask: <br />
[[Category:News]]<br />
[[Has tag::Regenerative Agriculture]]<br />
|?=#<br />
|?Has image#=2<br />
|?Has summary#=3<br />
|format=plainlist<br />
|named args=yes<br />
|introtemplate=Show image Header<br />
|template=Show image<br />
|outrotemplate=Show link Footer<br />
}}</div>Elislehttps://opencommons.org/index.php?title=Regenerative_Agriculture&diff=11249Regenerative Agriculture2022-11-30T04:23:56Z<p>Elisle: </p>
<hr />
<div>{{Chapter<br />
|image=Agriculture.JPG<br />
|poc=Ed Lisle<br />
|authors=Jennifer Wells,Ed Lisle<br />
|blueprint=Agriculture<br />
|chapter=612<br />
|sectors=Agriculture<br />
|summary='''''REGENERATIVE AGRICULTURE''''' (RegenAG) involves shifting from a carbon intensive food system to carbon-negative agriculture that restores rather than degrades ecosystems. While there is no globally accepted definition, this term is widely accepted to refer to integrated systems of farming, ranching, and pastoral practices that contribute to stabilizing the planet’s climate and carbon cycles by rehabilitating and safeguarding biodiversity and living systems.<br />
<br />
A shift to Regenerative Agriculture signals a radical transformation of how, where and when we grow food, a great expansion of the varieties of seeds grown and a new microclimate-based approach focusing on smallholder farms, intercropping, agroforestry and micro-farming industry strategies. For example, the use of cover crops, crop rotation, and no till practices, reducing use or elimination of synthetic inputs, and employing integrated crop and livestock systems and managed grazing have long since been recognized as sustainable farming practices. <br />
<br />
At the same time, new approaches are under development and ancient practices reinvented, some of which are up for debate as to whether or not they fall under the Regenerative Agriculture umbrella. For instance, while there is some debate about inclusion of soilless agriculture under the Regenerative Agriculture umbrella, there is growing consensus that organic soilless methods such as aquaponics (''involving cultivation of fish that fertilize plants in interconnected, contained systems'') represent promising, sustainable approaches to growing more with less water and energy and little to no pollution. <br />
<br />
The United Nations Sustainable Development Goal 2 is focused on creating a world free of hunger by 2030 by improving food security, nutrition and promoting sustainable agriculture. Of the 8 billion people living today, only three-quarters of us are receiving adequate nutrition. One billion people experience chronic hunger and as our population grows, more and more people are expected to experience food insecurity. It is starkly apparent that current industrial farming practices that squander and degrade the very resources they depend on cannot continue unchanged. Industrial agricultural practices are producing an estimated 21–37% of annual emissions of the three largest individual contributors to global warming gasses, carbon dioxide, methane, and nitrous oxide, and using 70% of the fresh water available on our planet (United Nations Food and Agriculture Organization, 2022). Clearly a large conservation and restoration effort is essential if we are to provide nutrition for an anticipated population of 10 billion by 2050, which is precisely what the Regenerative Agriculture movement seeks to enable.<br />
<br />
Obviously no single solution is capable of fulfilling this lofty goal. A decade ago in 2012, the United Nations Conference on Sustainable Development (UNCSD), also known as Rio+20. Produced an outcome document that called for achieving a land-degradation-neutral world in the context of sustainable development. Given the current extent of land degradation globally, the potential benefits from land restoration for food security and for mitigating climate change are enormous. While it is true that scientific understanding of the drivers of desertification, land degradation and drought is still evolving, advocates of Regenerative Agriculture point out that these crises actually create new opportunities for increasing food security, carbon storage and climate resiliency. <br />
<br />
Happily, Regenerative Agriculture approaches are already being implemented to varying degrees across our agricultural system, while others are newly emerging. Globally, movement is underway to return to native crops specifically adapted to variations in the local climate and to greatly increase the natural fertility and carbon sequestration potential of degraded soils. Nations such as Niger, with some of the most degraded soils on the planet, are demonstrating how restoration can be accomplished – restoring an astonishing 5 million hectares to productivity in the Sahel. Private/public partnerships such as the agroforestry project in inner Mongolia’s Kubuqi Desert, have restored approximately one-third of 18,600 sq km of sand dunes and in Mali, restoration has created forest plots with higher biomass than even native forests.<br />
}}<br />
'''Three Key Trends Pushing Forward Regenerative Practice Adoption'''<br />
<br />
# Data and the Digital Ag Revolution <br />
# Biologicals<br />
# Carbon / Climate - Smart Commodities<br />
<br />
'''Digital AG Revolution Solution Examples'''<br />
<br />
A body of scientific literature is now emerging that presents numerous strategies to decouple food production from land area, enabling increased food productivity and nutrition on the current agricultural footprint. A few examples of solutions related to data and the digital ag revolution and smart communities include:<br />
<br />
* Integrating AI enabled predictive analytics within indoor growing environments to precisely control growing variables in response to biotic and chemical signals at different stages of the growth cycle to reduce resource consumption and waste while maximizing rapid plant growth. <br />
* Deploying controlled growing environments near to where produce is sold and consumed to drastically reduce travel time, resource consumption, pollution, and shipping costs to deliver fresher, nutrient-dense food that tastes better.<br />
* Utilizing AI solutions for optimized outdoor crop placement <br />
* IoT solutions such as robots, drones, remote sensors, and computer imaging combined with continuously progressing machine learning and analytical tools for monitoring crops, surveying, and mapping the fields, and providing data to farmers for rational farm management plans to save both time and money.<br />
* Employing block-chain tracking to improve traceability of food to appeal to location-conscious buyers (sometimes called locavores), who are having an important impact on food sourcing, including the popularity of farmers markets. <br />
<br />
The purpose of this partnership with OpenCommons is to cultivate a collaborative community to advance promising smart technologies for urban and rural regenerative agriculture solutions.<br />
<br />
=Demonstration Projects=<br />
{{#ask: <br />
[[Category:Activity]]<br />
[[Has tag::Regenerative Agriculture]]<br />
|?=#<br />
|?Has image#=2<br />
|?Has description#=3<br />
|format=plainlist<br />
|named args=yes<br />
|introtemplate=Show image Header<br />
|template=Show image<br />
|outrotemplate=Show link Footer<br />
}}<br />
=News=<br />
{{#ask: <br />
[[Category:News]]<br />
[[Has tag::Regenerative Agriculture]]<br />
|?=#<br />
|?Has image#=2<br />
|?Has summary#=3<br />
|format=plainlist<br />
|named args=yes<br />
|introtemplate=Show image Header<br />
|template=Show image<br />
|outrotemplate=Show link Footer<br />
}}</div>Elislehttps://opencommons.org/index.php?title=Regenerative_Agriculture&diff=11248Regenerative Agriculture2022-11-30T04:21:44Z<p>Elisle: </p>
<hr />
<div>{{Chapter<br />
|image=Agriculture.JPG<br />
|poc=Ed Lisle<br />
|authors=Ed Lisle<br />
|blueprint=Agriculture<br />
|chapter=612<br />
|sectors=Agriculture<br />
|summary='''''REGENERATIVE AGRICULTURE''''' (RegenAG) involves shifting from a carbon intensive food system to carbon-negative agriculture that restores rather than degrades ecosystems. While there is no globally accepted definition, this term is widely accepted to refer to integrated systems of farming, ranching, and pastoral practices that contribute to stabilizing the planet’s climate and carbon cycles by rehabilitating and safeguarding biodiversity and living systems.<br />
<br />
A shift to Regenerative Agriculture signals a radical transformation of how, where and when we grow food, a great expansion of the varieties of seeds grown and a new microclimate-based approach focusing on smallholder farms, intercropping, agroforestry and micro-farming industry strategies. For example, the use of cover crops, crop rotation, and no till practices, reducing use or elimination of synthetic inputs, and employing integrated crop and livestock systems and managed grazing have long since been recognized as sustainable farming practices. <br />
<br />
At the same time, new approaches are under development and ancient practices reinvented, some of which are up for debate as to whether or not they fall under the Regenerative Agriculture umbrella. For instance, while there is some debate about inclusion of soilless agriculture under the Regenerative Agriculture umbrella, there is growing consensus that organic soilless methods such as aquaponics (''involving cultivation of fish that fertilize plants in interconnected, contained systems'') represent promising, sustainable approaches to growing more with less water and energy and little to no pollution. <br />
<br />
The United Nations Sustainable Development Goal 2 is focused on creating a world free of hunger by 2030 by improving food security, nutrition and promoting sustainable agriculture. Of the 8 billion people living today, only three-quarters of us are receiving adequate nutrition. One billion people experience chronic hunger and as our population grows, more and more people are expected to experience food insecurity. It is starkly apparent that current industrial farming practices that squander and degrade the very resources they depend on cannot continue unchanged. Industrial agricultural practices are producing an estimated 21–37% of annual emissions of the three largest individual contributors to global warming gasses, carbon dioxide, methane, and nitrous oxide, and using 70% of the fresh water available on our planet (United Nations Food and Agriculture Organization, 2022). Clearly a large conservation and restoration effort is essential if we are to provide nutrition for an anticipated population of 10 billion by 2050, which is precisely what the Regenerative Agriculture movement seeks to enable.<br />
<br />
Obviously no single solution is capable of fulfilling this lofty goal. A decade ago in 2012, the United Nations Conference on Sustainable Development (UNCSD), also known as Rio+20. Produced an outcome document that called for achieving a land-degradation-neutral world in the context of sustainable development. Given the current extent of land degradation globally, the potential benefits from land restoration for food security and for mitigating climate change are enormous. While it is true that scientific understanding of the drivers of desertification, land degradation and drought is still evolving, advocates of Regenerative Agriculture point out that these crises actually create new opportunities for increasing food security, carbon storage and climate resiliency. <br />
<br />
Happily, Regenerative Agriculture approaches are already being implemented to varying degrees across our agricultural system, while others are newly emerging. Globally, movement is underway to return to native crops specifically adapted to variations in the local climate and to greatly increase the natural fertility and carbon sequestration potential of degraded soils. Nations such as Niger, with some of the most degraded soils on the planet, are demonstrating how restoration can be accomplished – restoring an astonishing 5 million hectares to productivity in the Sahel. Private/public partnerships such as the agroforestry project in inner Mongolia’s Kubuqi Desert, have restored approximately one-third of 18,600 sq km of sand dunes and in Mali, restoration has created forest plots with higher biomass than even native forests.<br />
}}<br />
'''Three Key Trends Pushing Forward Regenerative Practice Adoption'''<br />
<br />
# Data and the Digital Ag Revolution <br />
# Biologicals<br />
# Carbon / Climate - Smart Commodities<br />
<br />
'''Digital AG Revolution Solution Examples'''<br />
<br />
A body of scientific literature is now emerging that presents numerous strategies to decouple food production from land area, enabling increased food productivity and nutrition on the current agricultural footprint. A few examples of solutions related to data and the digital ag revolution and smart communities include:<br />
<br />
* Integrating AI enabled predictive analytics within indoor growing environments to precisely control growing variables in response to biotic and chemical signals at different stages of the growth cycle to reduce resource consumption and waste while maximizing rapid plant growth. <br />
* Deploying controlled growing environments near to where produce is sold and consumed to drastically reduce travel time, resource consumption, pollution, and shipping costs to deliver fresher, nutrient-dense food that tastes better.<br />
* Utilizing AI solutions for optimized outdoor crop placement <br />
* IoT solutions such as robots, drones, remote sensors, and computer imaging combined with continuously progressing machine learning and analytical tools for monitoring crops, surveying, and mapping the fields, and providing data to farmers for rational farm management plans to save both time and money.<br />
* Employing block-chain tracking to improve traceability of food to appeal to location-conscious buyers (sometimes called locavores), who are having an important impact on food sourcing, including the popularity of farmers markets. <br />
<br />
The purpose of this partnership with OpenCommons is to cultivate a collaborative community to advance promising smart technologies for urban and rural regenerative agriculture solutions.<br />
<br />
=Demonstration Projects=<br />
{{#ask: <br />
[[Category:Activity]]<br />
[[Has tag::Regenerative Agriculture]]<br />
|?=#<br />
|?Has image#=2<br />
|?Has description#=3<br />
|format=plainlist<br />
|named args=yes<br />
|introtemplate=Show image Header<br />
|template=Show image<br />
|outrotemplate=Show link Footer<br />
}}<br />
=News=<br />
{{#ask: <br />
[[Category:News]]<br />
[[Has tag::Regenerative Agriculture]]<br />
|?=#<br />
|?Has image#=2<br />
|?Has summary#=3<br />
|format=plainlist<br />
|named args=yes<br />
|introtemplate=Show image Header<br />
|template=Show image<br />
|outrotemplate=Show link Footer<br />
}}</div>Elislehttps://opencommons.org/index.php?title=Regenerative_Agriculture&diff=11247Regenerative Agriculture2022-11-30T04:17:43Z<p>Elisle: </p>
<hr />
<div>{{Chapter<br />
|image=Agriculture.JPG<br />
|poc=Ed Lisle<br />
|authors=Ed Lisle<br />
|blueprint=Agriculture<br />
|chapter=612<br />
|sectors=Agriculture<br />
|summary='''''Regenerative Agriculture''''' (RegenAG) involves shifting from a carbon intensive food system to carbon-negative agriculture that restores rather than degrades ecosystems. While there is no globally accepted definition, this term is widely accepted to refer to integrated systems of farming, ranching, and pastoral practices that contribute to stabilizing the planet’s climate and carbon cycles by rehabilitating and safeguarding biodiversity and living systems.<br />
<br />
A shift to Regenerative Agriculture signals a radical transformation of how, where and when we grow food, a great expansion of the varieties of seeds grown and a new microclimate-based approach focusing on smallholder farms, intercropping, agroforestry and micro-farming industry strategies. For example, the use of cover crops, crop rotation, and no till practices, reducing use or elimination of synthetic inputs, and employing integrated crop and livestock systems and managed grazing have long since been recognized as sustainable farming practices. <br />
<br />
At the same time, new approaches are under development and ancient practices reinvented, some of which are up for debate as to whether or not they fall under the Regenerative Agriculture umbrella. For instance, while there is some debate about inclusion of soilless agriculture under the Regenerative Agriculture umbrella, there is growing consensus that organic soilless methods such as aquaponics (''involving cultivation of fish that fertilize plants in interconnected, contained systems'') represent promising, sustainable approaches to growing more with less water and energy and little to no pollution. <br />
<br />
The United Nations Sustainable Development Goal 2 is focused on creating a world free of hunger by 2030 by improving food security, nutrition and promoting sustainable agriculture. Of the 8 billion people living today, only three-quarters of us are receiving adequate nutrition. One billion people experience chronic hunger and as our population grows, more and more people are expected to experience food insecurity. It is starkly apparent that current industrial farming practices that squander and degrade the very resources they depend on cannot continue unchanged. Industrial agricultural practices are producing an estimated 21–37% of annual emissions of the three largest individual contributors to global warming gasses, carbon dioxide, methane, and nitrous oxide, and using 70% of the fresh water available on our planet (United Nations Food and Agriculture Organization, 2022). Clearly a large conservation and restoration effort is essential if we are to provide nutrition for an anticipated population of 10 billion by 2050, which is precisely what the Regenerative Agriculture movement seeks to enable.<br />
<br />
Obviously no single solution is capable of fulfilling this lofty goal. A decade ago in 2012, the United Nations Conference on Sustainable Development (UNCSD), also known as Rio+20. Produced an outcome document that called for achieving a land-degradation-neutral world in the context of sustainable development. Given the current extent of land degradation globally, the potential benefits from land restoration for food security and for mitigating climate change are enormous. While it is true that scientific understanding of the drivers of desertification, land degradation and drought is still evolving, advocates of Regenerative Agriculture point out that these crises actually create new opportunities for increasing food security, carbon storage and climate resiliency. <br />
<br />
Happily, Regenerative Agriculture approaches are already being implemented to varying degrees across our agricultural system, while others are newly emerging. Globally, movement is underway to return to native crops specifically adapted to variations in the local climate and to greatly increase the natural fertility and carbon sequestration potential of degraded soils. Nations such as Niger, with some of the most degraded soils on the planet, are demonstrating how restoration can be accomplished – restoring an astonishing 5 million hectares to productivity in the Sahel. Private/public partnerships such as the agroforestry project in inner Mongolia’s Kubuqi Desert, have restored approximately one-third of 18,600 sq km of sand dunes and in Mali, restoration has created forest plots with higher biomass than even native forests.<br />
}}<br />
'''Three Key Trends Are Pushing Forward Regenerative Practice Adoption:'''<br />
<br />
1) Data and the Digital Ag Revolution 2) Biologicals, and 3) Carbon / Climate - Smart Commodities. <br />
<br />
'''Digital AG Revolution Solution Examples'''<br />
<br />
A body of scientific literature is now emerging that presents numerous strategies to decouple food production from land area, enabling increased food productivity and nutrition on the current agricultural footprint. A few examples of solutions related to data and the digital ag revolution and smart communities include:<br />
<br />
* Integrating AI enabled predictive analytics within indoor growing environments to precisely control growing variables in response to biotic and chemical signals at different stages of the growth cycle to reduce resource consumption and waste while maximizing rapid plant growth. <br />
* Deploying controlled growing environments near to where produce is sold and consumed to drastically reduce travel time, resource consumption, pollution, and shipping costs to deliver fresher, nutrient-dense food that tastes better.<br />
* Utilizing AI solutions for optimized outdoor crop placement <br />
* IoT solutions such as robots, drones, remote sensors, and computer imaging combined with continuously progressing machine learning and analytical tools for monitoring crops, surveying, and mapping the fields, and providing data to farmers for rational farm management plans to save both time and money.<br />
* Employing block-chain tracking to improve traceability of food to appeal to location-conscious buyers (sometimes called locavores), who are having an important impact on food sourcing, including the popularity of farmers markets. <br />
<br />
The purpose of this partnership with OpenCommons is to cultivate a collaborative community to advance promising smart technologies for urban and rural regenerative agriculture solutions.<br />
<br />
=Demonstration Projects=<br />
{{#ask: <br />
[[Category:Activity]]<br />
[[Has tag::Regenerative Agriculture]]<br />
|?=#<br />
|?Has image#=2<br />
|?Has description#=3<br />
|format=plainlist<br />
|named args=yes<br />
|introtemplate=Show image Header<br />
|template=Show image<br />
|outrotemplate=Show link Footer<br />
}}<br />
=News=<br />
{{#ask: <br />
[[Category:News]]<br />
[[Has tag::Regenerative Agriculture]]<br />
|?=#<br />
|?Has image#=2<br />
|?Has summary#=3<br />
|format=plainlist<br />
|named args=yes<br />
|introtemplate=Show image Header<br />
|template=Show image<br />
|outrotemplate=Show link Footer<br />
}}</div>Elislehttps://opencommons.org/index.php?title=Regenerative_Agriculture&diff=11246Regenerative Agriculture2022-11-30T03:55:36Z<p>Elisle: </p>
<hr />
<div>{{Chapter<br />
|image=Agriculture.JPG<br />
|poc=Ed Lisle<br />
|authors=Ed Lisle<br />
|blueprint=Agriculture<br />
|chapter=612<br />
|sectors=Agriculture<br />
|summary='''''Regenerative Agriculture''''' (RegenAG) involves shifting from a carbon intensive food system to carbon-negative agriculture that restores rather than degrades ecosystems. While there is no globally accepted definition, this term is widely accepted to refer to integrated systems of farming, ranching, and pastoral practices that contribute to stabilizing the planet’s climate and carbon cycles by rehabilitating and safeguarding biodiversity and living systems.<br />
<br />
A shift to Regenerative Agriculture signals a radical transformation of how, where and when we grow food, a great expansion of the varieties of seeds grown and a new microclimate-based approach focusing on smallholder farms, intercropping, agroforestry and micro-farming industry strategies. For example, the use of cover crops, crop rotation, and no till practices, reducing use or elimination of synthetic inputs, and employing integrated crop and livestock systems and managed grazing have long since been recognized as sustainable farming practices. <br />
<br />
At the same time, new approaches are under development and ancient practices reinvented, some of which are up for debate as to whether or not they fall under the Regenerative Agriculture umbrella. For instance, while there is some debate about inclusion of soilless agriculture under the Regenerative Agriculture umbrella, there is growing consensus that organic soilless methods such as aquaponics (''involving cultivation of fish that fertilize plants in interconnected, contained systems'') represent promising, sustainable approaches to growing more with less water and energy and little to no pollution. <br />
<br />
The United Nations Sustainable Development Goal 2 is focused on creating a world free of hunger by 2030 by improving food security, nutrition and promoting sustainable agriculture. Of the 8 billion people living today, only three-quarters of us are receiving adequate nutrition. One billion people experience chronic hunger and as our population grows, more and more people are expected to experience food insecurity. It is starkly apparent that current industrial farming practices that squander and degrade the very resources they depend on cannot continue unchanged. Industrial agricultural practices are producing an estimated 21–37% of annual emissions of the three largest individual contributors to global warming gasses, carbon dioxide, methane, and nitrous oxide, and using 70% of the fresh water available on our planet (United Nations Food and Agriculture Organization, 2022). Clearly a large conservation and restoration effort is essential if we are to provide nutrition for an anticipated population of 10 billion by 2050, which is precisely what the Regenerative Agriculture movement seeks to enable.<br />
<br />
Obviously no single solution is capable of fulfilling this lofty goal. A decade ago in 2012, the United Nations Conference on Sustainable Development (UNCSD), also known as Rio+20. Produced an outcome document that called for achieving a land-degradation-neutral world in the context of sustainable development. Given the current extent of land degradation globally, the potential benefits from land restoration for food security and for mitigating climate change are enormous. While it is true that scientific understanding of the drivers of desertification, land degradation and drought is still evolving, advocates of Regenerative Agriculture point out that these crises actually create new opportunities for increasing food security, carbon storage and climate resiliency. <br />
<br />
Happily, Regenerative Agriculture approaches are already being implemented to varying degrees across our agricultural system, while others are newly emerging. Globally, movement is underway to return to native crops specifically adapted to variations in the local climate and to greatly increase the natural fertility and carbon sequestration potential of degraded soils. Nations such as Niger, with some of the most degraded soils on the planet, are demonstrating how restoration can be accomplished – restoring an astonishing 5 million hectares to productivity in the Sahel. Private/public partnerships such as the agroforestry project in inner Mongolia’s Kubuqi Desert, have restored approximately one-third of 18,600 sq km of sand dunes and in Mali, restoration has created forest plots with higher biomass than even native forests.<br />
}}<br />
'''Three Key Trends Are Pushing Forward Regenerative Practice Adoption:'''<br />
<br />
1) Data and the Digital Ag Revolution 2) Biologicals, and 3) Carbon / Climate - Smart Commodities. <br />
<br />
A body of scientific literature is now emerging that presents numerous strategies to decouple food production from land area, enabling increased food productivity and nutrition on the current agricultural footprint. A few examples of solutions related to data and the digital ag revolution and smart communities include:<br />
<br />
* Integrating AI enabled predictive analytics within indoor growing environments to precisely control growing variables in response to biotic and chemical signals at different stages of the growth cycle to reduce resource consumption and waste while maximizing rapid plant growth. <br />
* Deploying controlled growing environments near to where produce is sold and consumed to drastically reduce travel time, resource consumption, pollution, and shipping costs to deliver fresher, nutrient-dense food that tastes better.<br />
* Utilizing AI solutions for optimized outdoor crop placement <br />
* IoT solutions such as robots, drones, remote sensors, and computer imaging combined with continuously progressing machine learning and analytical tools for monitoring crops, surveying, and mapping the fields, and providing data to farmers for rational farm management plans to save both time and money.<br />
* Employing block-chain tracking to improve traceability of food to appeal to location-conscious buyers (sometimes called locavores), who are having an important impact on food sourcing, including the popularity of farmers markets. <br />
<br />
The purpose of this partnership with OpenCommons is to cultivate a collaborative community to advance promising smart technologies for urban and rural regenerative agriculture solutions.<br />
<br />
=Demonstration Projects=<br />
{{#ask: <br />
[[Category:Activity]]<br />
[[Has tag::Regenerative Agriculture]]<br />
|?=#<br />
|?Has image#=2<br />
|?Has description#=3<br />
|format=plainlist<br />
|named args=yes<br />
|introtemplate=Show image Header<br />
|template=Show image<br />
|outrotemplate=Show link Footer<br />
}}<br />
=News=<br />
{{#ask: <br />
[[Category:News]]<br />
[[Has tag::Regenerative Agriculture]]<br />
|?=#<br />
|?Has image#=2<br />
|?Has summary#=3<br />
|format=plainlist<br />
|named args=yes<br />
|introtemplate=Show image Header<br />
|template=Show image<br />
|outrotemplate=Show link Footer<br />
}}</div>Elislehttps://opencommons.org/index.php?title=Regenerative_Agriculture&diff=11245Regenerative Agriculture2022-11-30T03:52:49Z<p>Elisle: </p>
<hr />
<div>{{Chapter<br />
|image=Agriculture.JPG<br />
|poc=Ed Lisle<br />
|authors=Ed Lisle<br />
|blueprint=Agriculture<br />
|chapter=612<br />
|sectors=Agriculture<br />
|summary='''''Regenerative Agriculture''''' (RegenAG) involves shifting from a carbon intensive food system to carbon-negative agriculture that restores rather than degrades ecosystems. While there is no globally accepted definition, this term is widely accepted to refer to integrated systems of farming, ranching, and pastoral practices that contribute to stabilizing the planet’s climate and carbon cycles by rehabilitating and safeguarding biodiversity and living systems.<br />
<br />
A shift to Regenerative Agriculture signals a radical transformation of how, where and when we grow food, a great expansion of the varieties of seeds grown and a new microclimate-based approach focusing on smallholder farms, intercropping, agroforestry and micro-farming industry strategies. For example, the use of cover crops, crop rotation, and no till practices, reducing use or elimination of synthetic inputs, and employing integrated crop and livestock systems and managed grazing have long since been recognized as sustainable farming practices. <br />
<br />
At the same time, new approaches are under development and ancient practices reinvented, some of which are up for debate as to whether or not they fall under the Regenerative Agriculture umbrella. For instance, while there is some debate about inclusion of soilless agriculture under the Regenerative Agriculture umbrella, there is growing consensus that organic soilless methods such as aquaponics (''involving cultivation of fish that fertilize plants in interconnected, contained systems'') represent promising, sustainable approaches to growing more with less water and energy and little to no pollution. <br />
<br />
The United Nations Sustainable Development Goal 2 is focused on creating a world free of hunger by 2030 by improving food security, nutrition and promoting sustainable agriculture. Of the 8 billion people living today, only three-quarters of us are receiving adequate nutrition. One billion people experience chronic hunger and as our population grows, more and more people are expected to experience food insecurity. It is starkly apparent that current industrial farming practices that squander and degrade the very resources they depend on cannot continue unchanged. Industrial agricultural practices are producing an estimated 21–37% of annual emissions of the three largest individual contributors to global warming gasses, carbon dioxide, methane, and nitrous oxide, and using 70% of the fresh water available on our planet (United Nations Food and Agriculture Organization, 2022). Clearly a large conservation and restoration effort is essential if we are to provide nutrition for an anticipated population of 10 billion by 2050, which is precisely what the Regenerative Agriculture movement seeks to enable.<br />
<br />
Obviously no single solution is capable of fulfilling this lofty goal. A decade ago in 2012, the United Nations Conference on Sustainable Development (UNCSD), also known as Rio+20. Produced an outcome document that called for achieving a land-degradation-neutral world in the context of sustainable development. Given the current extent of land degradation globally, the potential benefits from land restoration for food security and for mitigating climate change are enormous. While it is true that scientific understanding of the drivers of desertification, land degradation and drought is still evolving, advocates of Regenerative Agriculture point out that these crises actually create new opportunities for increasing food security, carbon storage and climate resiliency. <br />
<br />
Happily, Regenerative Agriculture approaches are already being implemented to varying degrees across our agricultural system, while others are newly emerging. Globally, movement is underway to return to native crops specifically adapted to variations in the local climate and to greatly increase the natural fertility and carbon sequestration potential of degraded soils. Nations such as Niger, with some of the most degraded soils on the planet, are demonstrating how restoration can be accomplished – restoring an astonishing 5 million hectares to productivity in the Sahel. Private/public partnerships such as the agroforestry project in inner Mongolia’s Kubuqi Desert, have restored approximately one-third of 18,600 sq km of sand dunes and in Mali, restoration has created forest plots with higher biomass than even native forests.<br />
}}<br />
'''Three Key Trends Are Pushing Forward Regenerative Practice Adoption:'''<br />
<br />
1) Data and the Digital Ag Revolution 2) Biologicals, and 3) Carbon / Climate-Smart Commodities. <br />
<br />
A body of scientific literature is now emerging that presents numerous strategies to decouple food production from land area, enabling increased food productivity and nutrition on the current agricultural footprint. A few examples of solutions related to data and the digital ag revolution and smart communities include:<br />
<br />
* Integrating AI enabled predictive analytics within indoor growing environments to precisely control growing variables in response to biotic and chemical signals at different stages of the growth cycle to reduce resource consumption and waste while maximizing rapid plant growth. <br />
* Deploying controlled growing environments near to where produce is sold and consumed to drastically reduce travel time, resource consumption, pollution, and shipping costs to deliver fresher, nutrient-dense food that tastes better.<br />
* Utilizing AI solutions for optimized outdoor crop placement <br />
* IoT solutions such as robots, drones, remote sensors, and computer imaging combined with continuously progressing machine learning and analytical tools for monitoring crops, surveying, and mapping the fields, and providing data to farmers for rational farm management plans to save both time and money.<br />
* Employing block-chain tracking to improve traceability of food to appeal to location-conscious buyers (sometimes called locavores), who are having an important impact on food sourcing, including the popularity of farmers markets. <br />
<br />
The purpose of this partnership with OpenCommons is to cultivate a collaborative community to advance promising smart technologies for urban and rural regenerative agriculture solutions.<br />
<br />
=Demonstration Projects=<br />
{{#ask: <br />
[[Category:Activity]]<br />
[[Has tag::Regenerative Agriculture]]<br />
|?=#<br />
|?Has image#=2<br />
|?Has description#=3<br />
|format=plainlist<br />
|named args=yes<br />
|introtemplate=Show image Header<br />
|template=Show image<br />
|outrotemplate=Show link Footer<br />
}}<br />
=News=<br />
{{#ask: <br />
[[Category:News]]<br />
[[Has tag::Regenerative Agriculture]]<br />
|?=#<br />
|?Has image#=2<br />
|?Has summary#=3<br />
|format=plainlist<br />
|named args=yes<br />
|introtemplate=Show image Header<br />
|template=Show image<br />
|outrotemplate=Show link Footer<br />
}}</div>Elislehttps://opencommons.org/index.php?title=Regenerative_Agriculture&diff=11244Regenerative Agriculture2022-11-30T03:52:31Z<p>Elisle: </p>
<hr />
<div>{{Chapter<br />
|image=Agriculture.JPG<br />
|poc=Ed Lisle<br />
|authors=Ed Lisle<br />
|blueprint=Agriculture<br />
|chapter=612<br />
|sectors=Agriculture<br />
|summary='''''Regenerative Agriculture''''' (RegenAG)involves shifting from a carbon intensive food system to carbon-negative agriculture that restores rather than degrades ecosystems. While there is no globally accepted definition, this term is widely accepted to refer to integrated systems of farming, ranching, and pastoral practices that contribute to stabilizing the planet’s climate and carbon cycles by rehabilitating and safeguarding biodiversity and living systems.<br />
<br />
A shift to Regenerative Agriculture signals a radical transformation of how, where and when we grow food, a great expansion of the varieties of seeds grown and a new microclimate-based approach focusing on smallholder farms, intercropping, agroforestry and micro-farming industry strategies. For example, the use of cover crops, crop rotation, and no till practices, reducing use or elimination of synthetic inputs, and employing integrated crop and livestock systems and managed grazing have long since been recognized as sustainable farming practices. <br />
<br />
At the same time, new approaches are under development and ancient practices reinvented, some of which are up for debate as to whether or not they fall under the Regenerative Agriculture umbrella. For instance, while there is some debate about inclusion of soilless agriculture under the Regenerative Agriculture umbrella, there is growing consensus that organic soilless methods such as aquaponics (''involving cultivation of fish that fertilize plants in interconnected, contained systems'') represent promising, sustainable approaches to growing more with less water and energy and little to no pollution. <br />
<br />
The United Nations Sustainable Development Goal 2 is focused on creating a world free of hunger by 2030 by improving food security, nutrition and promoting sustainable agriculture. Of the 8 billion people living today, only three-quarters of us are receiving adequate nutrition. One billion people experience chronic hunger and as our population grows, more and more people are expected to experience food insecurity. It is starkly apparent that current industrial farming practices that squander and degrade the very resources they depend on cannot continue unchanged. Industrial agricultural practices are producing an estimated 21–37% of annual emissions of the three largest individual contributors to global warming gasses, carbon dioxide, methane, and nitrous oxide, and using 70% of the fresh water available on our planet (United Nations Food and Agriculture Organization, 2022). Clearly a large conservation and restoration effort is essential if we are to provide nutrition for an anticipated population of 10 billion by 2050, which is precisely what the Regenerative Agriculture movement seeks to enable.<br />
<br />
Obviously no single solution is capable of fulfilling this lofty goal. A decade ago in 2012, the United Nations Conference on Sustainable Development (UNCSD), also known as Rio+20. Produced an outcome document that called for achieving a land-degradation-neutral world in the context of sustainable development. Given the current extent of land degradation globally, the potential benefits from land restoration for food security and for mitigating climate change are enormous. While it is true that scientific understanding of the drivers of desertification, land degradation and drought is still evolving, advocates of Regenerative Agriculture point out that these crises actually create new opportunities for increasing food security, carbon storage and climate resiliency. <br />
<br />
Happily, Regenerative Agriculture approaches are already being implemented to varying degrees across our agricultural system, while others are newly emerging. Globally, movement is underway to return to native crops specifically adapted to variations in the local climate and to greatly increase the natural fertility and carbon sequestration potential of degraded soils. Nations such as Niger, with some of the most degraded soils on the planet, are demonstrating how restoration can be accomplished – restoring an astonishing 5 million hectares to productivity in the Sahel. Private/public partnerships such as the agroforestry project in inner Mongolia’s Kubuqi Desert, have restored approximately one-third of 18,600 sq km of sand dunes and in Mali, restoration has created forest plots with higher biomass than even native forests.<br />
}}<br />
'''Three Key Trends Are Pushing Forward Regenerative Practice Adoption:'''<br />
<br />
1) Data and the Digital Ag Revolution 2) Biologicals, and 3) Carbon / Climate-Smart Commodities. <br />
<br />
A body of scientific literature is now emerging that presents numerous strategies to decouple food production from land area, enabling increased food productivity and nutrition on the current agricultural footprint. A few examples of solutions related to data and the digital ag revolution and smart communities include:<br />
<br />
* Integrating AI enabled predictive analytics within indoor growing environments to precisely control growing variables in response to biotic and chemical signals at different stages of the growth cycle to reduce resource consumption and waste while maximizing rapid plant growth. <br />
* Deploying controlled growing environments near to where produce is sold and consumed to drastically reduce travel time, resource consumption, pollution, and shipping costs to deliver fresher, nutrient-dense food that tastes better.<br />
* Utilizing AI solutions for optimized outdoor crop placement <br />
* IoT solutions such as robots, drones, remote sensors, and computer imaging combined with continuously progressing machine learning and analytical tools for monitoring crops, surveying, and mapping the fields, and providing data to farmers for rational farm management plans to save both time and money.<br />
* Employing block-chain tracking to improve traceability of food to appeal to location-conscious buyers (sometimes called locavores), who are having an important impact on food sourcing, including the popularity of farmers markets. <br />
<br />
The purpose of this partnership with OpenCommons is to cultivate a collaborative community to advance promising smart technologies for urban and rural regenerative agriculture solutions.<br />
<br />
=Demonstration Projects=<br />
{{#ask: <br />
[[Category:Activity]]<br />
[[Has tag::Regenerative Agriculture]]<br />
|?=#<br />
|?Has image#=2<br />
|?Has description#=3<br />
|format=plainlist<br />
|named args=yes<br />
|introtemplate=Show image Header<br />
|template=Show image<br />
|outrotemplate=Show link Footer<br />
}}<br />
=News=<br />
{{#ask: <br />
[[Category:News]]<br />
[[Has tag::Regenerative Agriculture]]<br />
|?=#<br />
|?Has image#=2<br />
|?Has summary#=3<br />
|format=plainlist<br />
|named args=yes<br />
|introtemplate=Show image Header<br />
|template=Show image<br />
|outrotemplate=Show link Footer<br />
}}</div>Elislehttps://opencommons.org/index.php?title=Regenerative_Agriculture&diff=11243Regenerative Agriculture2022-11-30T03:52:04Z<p>Elisle: </p>
<hr />
<div>{{Chapter<br />
|image=Agriculture.JPG<br />
|poc=Ed Lisle<br />
|authors=Ed Lisle<br />
|blueprint=Agriculture<br />
|chapter=612<br />
|sectors=Agriculture<br />
|summary='''''Regenerative Agriculture''''' involves shifting from a carbon intensive food system to carbon-negative agriculture that restores rather than degrades ecosystems. While there is no globally accepted definition, this term is widely accepted to refer to integrated systems of farming, ranching, and pastoral practices that contribute to stabilizing the planet’s climate and carbon cycles by rehabilitating and safeguarding biodiversity and living systems.<br />
<br />
A shift to Regenerative Agriculture signals a radical transformation of how, where and when we grow food, a great expansion of the varieties of seeds grown and a new microclimate-based approach focusing on smallholder farms, intercropping, agroforestry and micro-farming industry strategies. For example, the use of cover crops, crop rotation, and no till practices, reducing use or elimination of synthetic inputs, and employing integrated crop and livestock systems and managed grazing have long since been recognized as sustainable farming practices. <br />
<br />
At the same time, new approaches are under development and ancient practices reinvented, some of which are up for debate as to whether or not they fall under the Regenerative Agriculture umbrella. For instance, while there is some debate about inclusion of soilless agriculture under the Regenerative Agriculture umbrella, there is growing consensus that organic soilless methods such as aquaponics (''involving cultivation of fish that fertilize plants in interconnected, contained systems'') represent promising, sustainable approaches to growing more with less water and energy and little to no pollution. <br />
<br />
The United Nations Sustainable Development Goal 2 is focused on creating a world free of hunger by 2030 by improving food security, nutrition and promoting sustainable agriculture. Of the 8 billion people living today, only three-quarters of us are receiving adequate nutrition. One billion people experience chronic hunger and as our population grows, more and more people are expected to experience food insecurity. It is starkly apparent that current industrial farming practices that squander and degrade the very resources they depend on cannot continue unchanged. Industrial agricultural practices are producing an estimated 21–37% of annual emissions of the three largest individual contributors to global warming gasses, carbon dioxide, methane, and nitrous oxide, and using 70% of the fresh water available on our planet (United Nations Food and Agriculture Organization, 2022). Clearly a large conservation and restoration effort is essential if we are to provide nutrition for an anticipated population of 10 billion by 2050, which is precisely what the Regenerative Agriculture movement seeks to enable.<br />
<br />
Obviously no single solution is capable of fulfilling this lofty goal. A decade ago in 2012, the United Nations Conference on Sustainable Development (UNCSD), also known as Rio+20. Produced an outcome document that called for achieving a land-degradation-neutral world in the context of sustainable development. Given the current extent of land degradation globally, the potential benefits from land restoration for food security and for mitigating climate change are enormous. While it is true that scientific understanding of the drivers of desertification, land degradation and drought is still evolving, advocates of Regenerative Agriculture point out that these crises actually create new opportunities for increasing food security, carbon storage and climate resiliency. <br />
<br />
Happily, Regenerative Agriculture approaches are already being implemented to varying degrees across our agricultural system, while others are newly emerging. Globally, movement is underway to return to native crops specifically adapted to variations in the local climate and to greatly increase the natural fertility and carbon sequestration potential of degraded soils. Nations such as Niger, with some of the most degraded soils on the planet, are demonstrating how restoration can be accomplished – restoring an astonishing 5 million hectares to productivity in the Sahel. Private/public partnerships such as the agroforestry project in inner Mongolia’s Kubuqi Desert, have restored approximately one-third of 18,600 sq km of sand dunes and in Mali, restoration has created forest plots with higher biomass than even native forests.<br />
}}<br />
'''Three Key Trends Are Pushing Forward Regenerative Practice Adoption:'''<br />
<br />
1) Data and the Digital Ag Revolution 2) Biologicals, and 3) Carbon / Climate-Smart Commodities. <br />
<br />
A body of scientific literature is now emerging that presents numerous strategies to decouple food production from land area, enabling increased food productivity and nutrition on the current agricultural footprint. A few examples of solutions related to data and the digital ag revolution and smart communities include:<br />
<br />
* Integrating AI enabled predictive analytics within indoor growing environments to precisely control growing variables in response to biotic and chemical signals at different stages of the growth cycle to reduce resource consumption and waste while maximizing rapid plant growth. <br />
* Deploying controlled growing environments near to where produce is sold and consumed to drastically reduce travel time, resource consumption, pollution, and shipping costs to deliver fresher, nutrient-dense food that tastes better.<br />
* Utilizing AI solutions for optimized outdoor crop placement <br />
* IoT solutions such as robots, drones, remote sensors, and computer imaging combined with continuously progressing machine learning and analytical tools for monitoring crops, surveying, and mapping the fields, and providing data to farmers for rational farm management plans to save both time and money.<br />
* Employing block-chain tracking to improve traceability of food to appeal to location-conscious buyers (sometimes called locavores), who are having an important impact on food sourcing, including the popularity of farmers markets. <br />
<br />
The purpose of this partnership with OpenCommons is to cultivate a collaborative community to advance promising smart technologies for urban and rural regenerative agriculture solutions.<br />
<br />
=Demonstration Projects=<br />
{{#ask: <br />
[[Category:Activity]]<br />
[[Has tag::Regenerative Agriculture]]<br />
|?=#<br />
|?Has image#=2<br />
|?Has description#=3<br />
|format=plainlist<br />
|named args=yes<br />
|introtemplate=Show image Header<br />
|template=Show image<br />
|outrotemplate=Show link Footer<br />
}}<br />
=News=<br />
{{#ask: <br />
[[Category:News]]<br />
[[Has tag::Regenerative Agriculture]]<br />
|?=#<br />
|?Has image#=2<br />
|?Has summary#=3<br />
|format=plainlist<br />
|named args=yes<br />
|introtemplate=Show image Header<br />
|template=Show image<br />
|outrotemplate=Show link Footer<br />
}}</div>Elislehttps://opencommons.org/index.php?title=Regenerative_Agriculture&diff=11116Regenerative Agriculture2022-11-13T08:10:29Z<p>Elisle: </p>
<hr />
<div>{{Chapter<br />
|image=Agriculture.JPG<br />
|poc=Ed Lisle<br />
|authors=Ed Lisle<br />
|blueprint=Agriculture<br />
|chapter=612<br />
|sectors=Agriculture<br />
|summary=Regenerative agriculture is a holistic approach to agriculture that focuses on the interconnection of farming systems and the ecological system as a whole. The concept of regenerative farming is not new. It was used by Indigenous communities centuries ago, long before industrial agriculture occurred.<br />
<br />
The Food and Agriculture Organization (FAO) of the United Nations is an international organization that leads international efforts to defeat hunger and improve nutrition and food security in promoting sustainable agriculture as the second of its 17 Sustainable Development Goals (SDGs) for the year 2030.<br />
<br />
The global food security challenge is straightforward: by 2050, the world must feed two billion more people, an increase of a quarter from today’s global population. The demand for food will be 56% greater than it was in 2010. Findings indicate that the world is not going to meet most of the food and agriculture-related Sustainable Development Goals targets by 2030. These challenges highlight the need for innovative agricultural advancements. <br />
<br />
Specifically, the recommendation from the United Nations G20 summit: "Enhance the food security by promoting sustainable agriculture, adopting circular economy models and healthy shifts in G20 countries, by leveraging key technological enablers and infrastructure."<br />
<br />
The purpose of this partnership with OpenCommons is to cultivate a collaborative community to advance promising smart technologies for urban and rural regenerative agriculture solutions.<br />
}}<br />
=The top five principles of regenerative agriculture=<br />
While there are many types of regenerative farms, they all seek to follow these five principles.<br />
<br />
#'''Minimizing soil disturbances''': Regenerative agriculture uses farming practices such as limited or no-tilling that minimize physical, biological, and chemical soil disturbances.<br />
#'''Soil coverage'''. Instead of relying on tilling, regenerative farming practices focus on keeping the soil covered with vegetation and natural materials through mulching, cover crops, and pastures.<br />
#'''Increased plant diversity''': Diversity is an essential component in building healthy soils that retain excess water and nutrients. It can help farmers obtain revenue from other sources and it's beneficial to other wildlife and pollinators.<br />
#'''Keeping living roots in the soil as much as possible'''. Having living roots in the soil ensures that fields are never bare. It can be done by farming practices such as planting winter cover crops or having land in permanent pasture. Keeping living roots in the soil helps stabilize the soil, retaining excess water and nutrient runoff.<br />
#'''Integrate animals into the farm as much as possible'''. Manure produced by livestock can add valuable nutrients to the soil, reducing the need for fertilizers, and increasing soil organic matter. Healthy soils capture large amounts of carbon and water and reduce the amount of polluted runoff.<br />
<br />
=Demonstration Projects=<br />
{{#ask: <br />
[[Category:Activity]]<br />
[[Has tag::Regenerative Agriculture]]<br />
|?=#<br />
|?Has image#=2<br />
|?Has description#=3<br />
|format=plainlist<br />
|named args=yes<br />
|introtemplate=Show image Header<br />
|template=Show image<br />
|outrotemplate=Show link Footer<br />
}}<br />
=News=<br />
{{#ask: <br />
[[Category:News]]<br />
[[Has tag::Regenerative Agriculture]]<br />
|?=#<br />
|?Has image#=2<br />
|?Has summary#=3<br />
|format=plainlist<br />
|named args=yes<br />
|introtemplate=Show image Header<br />
|template=Show image<br />
|outrotemplate=Show link Footer<br />
}}</div>Elislehttps://opencommons.org/index.php?title=LATERAL.systems&diff=10708LATERAL.systems2022-09-01T14:53:21Z<p>Elisle: </p>
<hr />
<div>{{Organization<br />
|logo=LATERAL-logo.png<br />
|sector=Rural, Smart Region, Wellbeing<br />
|industry=Technology Hardware & Equipment<br />
|type=Limited Liability<br />
|foundation=July 23, 2021<br />
|founder=Jennifer Wells, Ed Lisle<br />
|location_city=McMinnville OR<br />
|location_country=United States<br />
|area_served=Country<br />
|key_people=Jennifer Wells/CEO, Ed Lisle/President & CTO<br />
|products=Regenerative Agriculture Platform<br />
|revenue=0<br />
|num_employees=2<br />
|homepage=https://lateral.systems/<br />
|sponsorship=Sponsor<br />
|description=Founded in 2021, '''LATERAL.systems LLC''' is a Regenerative Agriculture (ReGen Ag) Platform Company targeting Novel Indoor Growing Farming Systems. Our mission is to enable rural and urban farmers by accelerating the intersection of promising AgTech smart solutions to advance sustainable production of food.<br />
}}</div>Elislehttps://opencommons.org/index.php?title=LATERAL.systems&diff=10707LATERAL.systems2022-09-01T14:51:21Z<p>Elisle: </p>
<hr />
<div>{{Organization<br />
|logo=LATERAL-logo.png<br />
|sector=Rural, Smart Region, Wellbeing<br />
|industry=Technology Hardware & Equipment<br />
|type=Limited Liability<br />
|foundation=July 23, 2021<br />
|founder=Jennifer Wells, Ed Lisle<br />
|location_city=McMinnville OR<br />
|location_country=United States<br />
|area_served=Country<br />
|key_people=Jennifer Wells/CEO, Ed Lisle/President & CTO<br />
|products=Regenerative Agriculture Platform<br />
|revenue=0<br />
|num_employees=2<br />
|homepage=https://lateral.systems/<br />
|sponsorship=Sponsor<br />
|description=Founded in 2021, '''LATERAL.systems LLC''' is a Regenerative Agriculture (ReGen) Platform Company targeting Novel Indoor Growing Farming Systems. Our mission is to enable rural and urban farmers by accelerating the intersection of promising AgTech smart solutions to advance sustainable production of food.<br />
}}</div>Elislehttps://opencommons.org/index.php?title=LATERAL.systems&diff=10706LATERAL.systems2022-09-01T14:48:57Z<p>Elisle: </p>
<hr />
<div>{{Organization<br />
|logo=LATERAL-logo.png<br />
|sector=Rural, Smart Region, Wellbeing<br />
|industry=Technology Hardware & Equipment<br />
|type=Limited Liability<br />
|foundation=July 23, 2021<br />
|founder=Jennifer Wells, Ed Lisle<br />
|location_city=McMinnville OR<br />
|location_country=United States<br />
|area_served=Country<br />
|key_people=Jennifer Wells/CEO, Ed Lisle/President & CTO<br />
|products=Regenerative Agriculture Platform<br />
|revenue=0<br />
|num_employees=2<br />
|homepage=https://lateral.systems/<br />
|sponsorship=Sponsor<br />
|description=Founded in 2021, '''LATERAL.systems LLC''' is a Regenerative Agriculture Platform Company targeting Novel Indoor Growing Farming Systems. Our mission is to enable generations of rural and urban farmers by accelerating the intersection of promising modern smart technologies to advance sustainable production of food.<br />
}}</div>Elislehttps://opencommons.org/index.php?title=LATERAL.systems&diff=10705LATERAL.systems2022-09-01T14:47:39Z<p>Elisle: </p>
<hr />
<div>{{Organization<br />
|logo=LATERAL-logo.png<br />
|sector=Rural, Smart Region<br />
|industry=Technology Hardware & Equipment<br />
|type=Limited Liability<br />
|foundation=July 23, 2021<br />
|founder=Jennifer Wells, Ed Lisle<br />
|location_city=McMinnville OR<br />
|location_country=United States<br />
|area_served=Country<br />
|key_people=Jennifer Wells/CEO, Ed Lisle/President & CTO<br />
|products=Regenerative Agriculture<br />
|revenue=0<br />
|num_employees=2<br />
|homepage=https://lateral.systems/<br />
|sponsorship=Sponsor<br />
|description=Founded in 2021, '''LATERAL.systems LLC''' is a Regenerative Agriculture Platform Company targeting Novel Indoor Agricultural Growing Farming Systems. Our mission is to enable generations of rural and urban farmers by accelerating the intersection of promising modern smart technologies to advance sustainable production of food.<br />
}}</div>Elislehttps://opencommons.org/index.php?title=LATERAL.systems&diff=10704LATERAL.systems2022-09-01T14:46:23Z<p>Elisle: </p>
<hr />
<div>{{Organization<br />
|logo=LATERAL-logo.png<br />
|sector=Rural, Smart Region<br />
|industry=Technology Hardware & Equipment<br />
|type=Limited Liability<br />
|foundation=July 23, 2021<br />
|founder=Jennifer Wells, Ed Lisle<br />
|location_city=McMinnville OR<br />
|location_country=United States<br />
|area_served=Country<br />
|key_people=Jennifer Wells/CEO, Ed Lisle/President & CTO<br />
|products=Regenerative Agriculture<br />
|revenue=0<br />
|num_employees=2<br />
|homepage=https://lateral.systems/<br />
|sponsorship=Sponsor<br />
|description=Founded in 2021, '''LATERAL.systems LLC''' is a platform company targeting Novel Indoor Agricultural Growing Farming Systems. Our mission is to enable generations of rural and urban farmers by accelerating the intersection of promising modern smart technologies to advance sustainable production of food.<br />
}}</div>Elislehttps://opencommons.org/index.php?title=LATERAL.systems&diff=10685LATERAL.systems2022-08-30T15:00:38Z<p>Elisle: </p>
<hr />
<div>{{Organization<br />
|logo=LATERAL-logo.png<br />
|sector=Rural, Smart Region<br />
|industry=Technology Hardware & Equipment<br />
|type=Limited Liability<br />
|foundation=July 23, 2021<br />
|founder=Jennifer Wells, Ed Lisle<br />
|location_city=McMinnville OR<br />
|location_country=United States<br />
|area_served=Country<br />
|key_people=Jennifer Wells/CEO, Ed Lisle/President & CTO<br />
|products=Smart Agriculture Technologies<br />
|revenue=0<br />
|num_employees=2<br />
|homepage=https://lateral.systems/<br />
|sponsorship=Sponsor<br />
|description=Founded in 2021, '''LATERAL.systems LLC''' is a platform company targeting Novel Indoor Agricultural Growing Farming Systems. Our mission is to enable generations of rural and urban farmers by accelerating the intersection of promising modern smart technologies to advance sustainable production of food.<br />
}}</div>Elislehttps://opencommons.org/index.php?title=Ed_Lisle&diff=10684Ed Lisle2022-08-30T14:58:45Z<p>Elisle: </p>
<hr />
<div>{{Person<br />
|portrait=Edlisle.jpeg<br />
|firstname=Ed<br />
|middlename=A<br />
|lastname=Lisle<br />
|company=LATERAL.systems<br />
|position=President & CTO<br />
|location=McMinnville OR<br />
|country=United States<br />
|sector=Rural, Smart Region<br />
|linkedin=https://www.linkedin.com/in/edlisle/<br />
}}</div>Elislehttps://opencommons.org/index.php?title=LATERAL.systems&diff=10683LATERAL.systems2022-08-30T10:00:38Z<p>Elisle: </p>
<hr />
<div>{{Organization<br />
|logo=LATERAL-logo.png<br />
|sector=Rural<br />
|industry=Technology Hardware & Equipment<br />
|type=Limited Liability<br />
|foundation=2021<br />
|founder=Jennifer Wells, Ed Lisle<br />
|location_city=McMinnville OR<br />
|location_country=United States<br />
|area_served=Country<br />
|key_people=Jennifer Wells/CEO, Ed Lisle/President & CTO<br />
|products=Smart Agriculture Technologies<br />
|revenue=0<br />
|num_employees=2<br />
|homepage=https://lateral.systems/<br />
|sponsorship=Sponsor<br />
|description=Founded in 2021, '''LATERAL.systems LLC''' is a platform company targeting Novel Indoor Agricultural Growing Farming Systems. Our mission is to enable generations of rural and urban farmers by accelerating the intersection of promising modern smart technologies to advance sustainable production of food.<br />
}}</div>Elislehttps://opencommons.org/index.php?title=LATERAL.systems&diff=10682LATERAL.systems2022-08-30T09:53:30Z<p>Elisle: </p>
<hr />
<div>{{Organization<br />
|logo=LATERAL-logo.png<br />
|sector=Rural<br />
|industry=Technology Hardware & Equipment<br />
|type=Limited Liability<br />
|foundation=2021<br />
|founder=Jennifer Wells, Ed Lisle<br />
|location_city=McMinnville OR<br />
|location_country=United States<br />
|area_served=Country<br />
|key_people=Jennifer Wells/CEO, Ed Lisle/President & CTO<br />
|products=Smart Agriculture Technologies<br />
|revenue=0<br />
|num_employees=2<br />
|homepage=https://lateral.systems/<br />
|sponsorship=Sponsor<br />
|description=Founded in 2021, '''LATERAL.systems LLC''' is a platform company targeting Novel Indoor Agricultural Growing Farming Systems. Our mission is to enable generations of farmers by accelerating the intersection of promising modern technologies to advance sustainable production of food.<br />
}}</div>Elislehttps://opencommons.org/index.php?title=LATERAL.systems&diff=10681LATERAL.systems2022-08-30T09:52:25Z<p>Elisle: </p>
<hr />
<div>{{Organization<br />
|logo=LATERAL-logo.png<br />
|sector=Rural<br />
|industry=Technology Hardware & Equipment<br />
|type=Limited Liability<br />
|foundation=2021<br />
|founder=Jennifer Wells, Ed Lisle<br />
|location_city=McMinnville OR<br />
|location_country=United States<br />
|area_served=Pacific Northwest Region<br />
|key_people=Jennifer Wells/CEO, Ed Lisle/President & CTO<br />
|products=Smart Agriculture Technologies<br />
|revenue=0<br />
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|homepage=https://lateral.systems/<br />
|sponsorship=Sponsor<br />
|description=Founded in 2021, '''LATERAL.systems LLC''' is a platform company targeting Novel Indoor Agricultural Growing Farming Systems. Our mission is to enable generations of farmers by accelerating the intersection of promising modern technologies to advance sustainable production of food.<br />
}}</div>Elislehttps://opencommons.org/index.php?title=LATERAL.systems&diff=10680LATERAL.systems2022-08-30T09:50:56Z<p>Elisle: </p>
<hr />
<div>{{Organization<br />
|logo=LATERAL-logo.png<br />
|sector=Rural<br />
|industry=Smart AgTech<br />
|type=Limited Liability<br />
|foundation=2021<br />
|founder=Jennifer Wells, Ed Lisle<br />
|location_city=McMinnville OR<br />
|location_country=United States<br />
|area_served=Pacific Northwest Region<br />
|key_people=Jennifer Wells/CEO, Ed Lisle/President & CTO<br />
|products=Smart Agriculture Technologies<br />
|revenue=0<br />
|num_employees=2<br />
|homepage=https://lateral.systems/<br />
|sponsorship=Sponsor<br />
|description=Founded in 2021, '''LATERAL.systems LLC''' is a platform company targeting Novel Indoor Agricultural Growing Farming Systems. Our mission is to enable generations of farmers by accelerating the intersection of promising modern technologies to advance sustainable production of food.<br />
}}</div>Elislehttps://opencommons.org/index.php?title=LATERAL.systems&diff=10679LATERAL.systems2022-08-30T09:48:53Z<p>Elisle: </p>
<hr />
<div>{{Organization<br />
|logo=LATERAL-logo.png<br />
|sector=Rural<br />
|industry=Technology Hardware & Equipment<br />
|type=Limited Liability<br />
|foundation=2021<br />
|founder=Jennifer Wells, Ed Lisle<br />
|location_city=McMinnville OR<br />
|location_country=United States<br />
|area_served=State<br />
|key_people=Jennifer Wells/CEO, Ed Lisle/President & CTO<br />
|products=Smart Agriculture Technologies<br />
|revenue=0<br />
|num_employees=2<br />
|homepage=https://lateral.systems/<br />
|sponsorship=Sponsor<br />
|description=Founded in 2021, '''LATERAL.systems LLC''' is a platform company targeting Novel Indoor Agricultural Growing Farming Systems. Our mission is to enable generations of farmers by accelerating the intersection of promising modern technologies to advance sustainable production of food.<br />
}}</div>Elislehttps://opencommons.org/index.php?title=LATERAL.systems&diff=10678LATERAL.systems2022-08-30T09:38:24Z<p>Elisle: </p>
<hr />
<div>{{Organization<br />
|logo=LATERAL-logo.png<br />
|sector=Rural<br />
|industry=Technology Hardware & Equipment<br />
|type=Limited Liability<br />
|foundation=2021<br />
|founder=Jennifer Wells, Ed Lisle<br />
|location_city=McMinnville OR<br />
|location_country=United States<br />
|area_served=State<br />
|key_people=Ed Lisle/President & CTO, Jennifer Wells/CEO<br />
|products=Smart Agriculture Technologies<br />
|revenue=0<br />
|num_employees=2<br />
|homepage=https://lateral.systems/<br />
|sponsorship=Sponsor<br />
|description=Founded in 2021, '''LATERAL.systems LLC''' is a platform company targeting Novel Indoor Agricultural Growing Farming Systems. Our mission is to enable generations of farmers by accelerating the intersection of promising modern technologies to advance sustainable production of food.<br />
}}</div>Elislehttps://opencommons.org/index.php?title=LATERAL.systems&diff=10677LATERAL.systems2022-08-30T09:29:42Z<p>Elisle: </p>
<hr />
<div>{{Organization<br />
|logo=LATERAL-logo.png<br />
|sector=Rural<br />
|industry=Technology Hardware & Equipment<br />
|type=Limited Liability<br />
|foundation=2021<br />
|founder=Jennifer Wells, Ed Lisle<br />
|location_city=McMinnville OR<br />
|location_country=United States<br />
|area_served=State<br />
|key_people=Ed Lisle/President & CTO, Jennifer Wells/CEO<br />
|products=Smart Agriculture Technologies<br />
|revenue=0<br />
|num_employees=2<br />
|homepage=https://lateral.systems/<br />
|sponsorship=Sponsor<br />
|description=Founded in 2021, LATERAL.systems LLC is a smart AgTech platform company advancing the social good of growing sustainable foods with emerging technologies targeting Novel Indoor Agricultural Growing Farming Systems. Our mission is to enable generations of farmers by accelerating the intersection of promising modern technologies to advance sustainable production of food.<br />
}}</div>Elislehttps://opencommons.org/index.php?title=File:LATERAL-logo.png&diff=10618File:LATERAL-logo.png2022-08-27T16:40:31Z<p>Elisle: LATERAL.systems LLC is a platform company targeting Regenerative Agricultural Indoor Farm Growing Environments. Our mission is to enable generations of farmers by accelerating the intersection of promising modern technologies to advance sustainable production of food.</p>
<hr />
<div>LATERAL.systems LLC is a platform company targeting Regenerative Agricultural Indoor Farm Growing Environments. Our mission is to enable generations of farmers by accelerating the intersection of promising modern technologies to advance sustainable production of food.</div>Elisle