Underground Infrastructure Sensing and Mapping: Difference between revisions

From OpenCommons
Jump to navigation Jump to search
en>Ocadmin
No edit summary
 
No edit summary
 
(6 intermediate revisions by the same user not shown)
Line 1: Line 1:
{{ActionCluster
{{ActionCluster
 
|image=Mapping Underground Infrastructure.jpeg
| title            = Underground Infrastructure Sensing and Mapping for Smart Maintenance, Sustainability, Usage and Resilience
|team=BTV Ignite, Kardinal Microsystems, University of Vermont
| team             = BTV Ignite, Kardinal Microsystems, University of Vermont; City of Winooski, VT
|leader=Dryver Huston, Tian Xia
 
|imagecaption=Mapping Underground Infrastructure
| leader           = Dryver Huston
|municipalities=Winooski VT
| email            = dryver.huston@uvm.edu
|status=Development
<!-- [mailto:txia@uvm.edu Tian Xia]-->
|description=Use sensing and information technology to determine the state of infrastructure and provide it in an appropriate, timely and secure format for the managers, planners and users.  Information processing techniques convert the data in information-laden databases for use in analytics, graphical presentations, metering and planning.
 
|challenges=* Technical challenges for sensor selection, design, operation and use. Subsurface congestion and unknown features are complications.
| image            =
| imagecaption     =  
| municipalities   = Winooski, VT
| status           =  
| website          =
| download          =
 
| description       =  
Use sensing and information technology to determine the state of infrastructure and provide it in an appropriate, timely and secure format for the managers, planners and users.  Information processing techniques convert the data in information-laden databases for use in analytics, graphical presentations, metering and planning.
 
 
| challenges       =  
* Technical challenges for sensor selection, design, operation and use. Subsurface congestion and unknown features are complications.
* Information processing challenges to convert sensor data into database of subsurface mapping and condition.
* Information processing challenges to convert sensor data into database of subsurface mapping and condition.
* Communication, management and interoperability – multiple utilities, some span neighboring municipalities: water, sewer (sanitary and stormwater), electric, gas, and telecommunications ; have different features, protocols and management issues.
* Communication, management and interoperability – multiple utilities, some span neighboring municipalities: water, sewer (sanitary and stormwater), electric, gas, and telecommunications ; have different features, protocols and management issues.
 
|solutions=Digital Twin
 
|requirements=# Develop map of underground utilities using ground penetrating radar, pipe robot telemetry, new construction observations and historical records; using combination of constructive, pattern recognition and data fusion methods.
| solutions             =  
 
| requirements       =  
# Develop map of underground utilities using ground penetrating radar, pipe robot telemetry, new construction observations and historical records; using combination of constructive, pattern recognition and data fusion methods.
# Place condition and operation sensors into underground infrastructure at key locations.
# Place condition and operation sensors into underground infrastructure at key locations.
# Use fiber optic high-speed telecommunications network to transmit data.
# Use fiber optic high-speed telecommunications network to transmit data.
# Create Underground Infrastructure Information Model database for use in infrastructure management and planning.
# Create Underground Infrastructure Information Model database for use in infrastructure management and planning.
# Integrate cybersecurity measures into design decisions.
# Integrate cybersecurity measures into design decisions.
 
|kpi=* Emergency repair reduction of 20%
| kpi               =  
* Emergency repair reduction of 20%
* Service outage reduction of 20%
* Service outage reduction of 20%
* Inappropriate sanitary and storm water sewage discharge reduction of 20%
* Inappropriate sanitary and storm water sewage discharge reduction of 20%
 
|measurement=Billing records, service records, and sewer sensing
 
|standards=* The sensing systems, data streams, and databases can all easily conform to existing and emerging standards.
 
| measurement       =  
Billing records, service records, and sewer sensing
 
 
| standards         =  
* The sensing systems, data streams, and databases can all easily conform to existing and emerging standards.
* The initial deployment is in a small city that is big enough to capture many of the pertinent issues, yet small enough to allow degrees of freedom for easy deployment.  Conceptual and technical development then easily scales to bigger cities.
* The initial deployment is in a small city that is big enough to capture many of the pertinent issues, yet small enough to allow degrees of freedom for easy deployment.  Conceptual and technical development then easily scales to bigger cities.
 
|cybersecurity=TBD
| cybersecurity         =  
|impacts=# Overall more efficient and resilient subsurface infrastructure
 
| impacts                 =  
# Overall more efficient and resilient subsurface infrastructure
# Reduced service outages and emergency repairs
# Reduced service outages and emergency repairs
# Better planning tools  
# Better planning tools  
# Reduced environmental impacts – energy use, and stormwater and sewage discharge.
# Reduced environmental impacts – energy use, and stormwater and sewage discharge.
# Quicker construction cycles.
# Quicker construction cycles.
 
|demonstration=* Phase I Pilot/Demonstration:
| demonstration       =
 
* Phase I Pilot/Demonstration:
GPR measurement and integration of historical records to construct UIIM database for one or two city blocks
GPR measurement and integration of historical records to construct UIIM database for one or two city blocks


Line 71: Line 39:
# System performance assessment.
# System performance assessment.
# Study of scalability.
# Study of scalability.
 
|chapter=Digital Twins
 
|supercluster=Utility
 
|year=2016, 2017
| supercluster           = Utility
|title=Underground Infrastructure Sensing and Mapping for Smart Maintenance, Sustainability, Usage and Resilience
| year                   = 2017
|email=dryver.huston@uvm.edu
 
<!-- [mailto:txia@uvm.edu Tian Xia]-->
}}
}}
[[Category:Year_2016]]

Latest revision as of 06:18, January 25, 2023


Underground Infrastructure Sensing and Mapping
GCTC logo 344x80.png
Mapping Underground Infrastructure.jpeg
Mapping Underground Infrastructure
Team Organizations BTV Ignite
Kardinal Microsystems
University of Vermont
Team Leaders Dryver Huston
Tian Xia
Participating Municipalities Winooski VT
Status Development
Document None

Description

Use sensing and information technology to determine the state of infrastructure and provide it in an appropriate, timely and secure format for the managers, planners and users. Information processing techniques convert the data in information-laden databases for use in analytics, graphical presentations, metering and planning.

Challenges

  • Technical challenges for sensor selection, design, operation and use. Subsurface congestion and unknown features are complications.
  • Information processing challenges to convert sensor data into database of subsurface mapping and condition.
  • Communication, management and interoperability – multiple utilities, some span neighboring municipalities: water, sewer (sanitary and stormwater), electric, gas, and telecommunications ; have different features, protocols and management issues.

Solutions

Digital Twin

Major Requirements

  1. Develop map of underground utilities using ground penetrating radar, pipe robot telemetry, new construction observations and historical records; using combination of constructive, pattern recognition and data fusion methods.
  2. Place condition and operation sensors into underground infrastructure at key locations.
  3. Use fiber optic high-speed telecommunications network to transmit data.
  4. Create Underground Infrastructure Information Model database for use in infrastructure management and planning.
  5. Integrate cybersecurity measures into design decisions.

Performance Targets

Key Performance Indicators (KPIs) Measurement Methods
  • Emergency repair reduction of 20%
  • Service outage reduction of 20%
  • Inappropriate sanitary and storm water sewage discharge reduction of 20%

Billing records, service records, and sewer sensing

Standards, Replicability, Scalability, and Sustainability

  • The sensing systems, data streams, and databases can all easily conform to existing and emerging standards.
  • The initial deployment is in a small city that is big enough to capture many of the pertinent issues, yet small enough to allow degrees of freedom for easy deployment. Conceptual and technical development then easily scales to bigger cities.

Cybersecurity and Privacy

TBD

Impacts

  1. Overall more efficient and resilient subsurface infrastructure
  2. Reduced service outages and emergency repairs
  3. Better planning tools
  4. Reduced environmental impacts – energy use, and stormwater and sewage discharge.
  5. Quicker construction cycles.

Demonstration/Deployment

  • Phase I Pilot/Demonstration:

GPR measurement and integration of historical records to construct UIIM database for one or two city blocks

  • Phase II Deployment:
  1. Selection of best deployment sites.
  2. Construct database using tomographic GPR, construction and historic records.
  3. Integration of sensors into telecommunications (fiber optic) system.
  4. Database usage and demonstration, including mobile apps.
  5. Cybersecurity integration.
  6. System performance assessment.
  7. Study of scalability.