Jun 16, 2022

Digital evolution of geotechnical monitoring webinar

2 years ago

Digital Evolution of Geotechnical Monitoring Webinar Questions & answers

3vGeomatics‘ Parwant Ghuman, along with RST Instruments’ Pierre Choquet and Terra Insights’ James Saunders presented a live webinar, Digital Evolution of Geotechnical Monitoring, that explored what the phrase “smart monitoring” means to geotechnical monitoring, as well as emerging technologies in the field. In doing so, the experts discussed what technological solutions have a role to play in critical asset management and risk mitigation strategies. The presenters made the case that the digital evolution of geotechnical monitoring also enables smarter geotechnical monitoring.

A number of different questions were posed by attendees to the panellists. We’ve highlighted three of the questions below.

What is the current trend most worth following in geotechnical monitoring?

While AI and machine learning seem to be a major talking point at present—machine learning can and often does produce better results than traditional algorithms—remote sensing is actually the number one trend to keep an eye on.

Advances in satellite technologies and remote sensing (specifically InSAR and drones) are allowing for simpler automated real-time monitoring and better data visualization and interpretation. These advancements have revolutionized the way we measure very small ambient vibrations on steel and concrete; they’ve allowed us to monitor both vertical and horizontal deformation in the ground, and they have strengthened our ability to measure multi-point pore pressure. As InSAR and drone technology continues to advance, so too will manufacturers’ ability to deliver data that matters to their clients.

How should a MEMs inclinometer’s drift over time be addressed?

Even with the newest generation of IPIs released two years ago, this issue is always going to be a constant. If there is any drift in an IPI, a good portion of it comes from minute mechanical adjustments that occur just after installation.

Therefore, waiting a day or two before taking your baseline measurements is important. The components—including the sensors, the extension bays, and the joints—need 24 to 48 hours to settle. Once they have, you should then be free and clear to take your first measurements.

How should mining engineers react when InSAR information reveals an area where new movements are detected, such as on a tailing dam?

First and foremost, a visual on-site inspection is necessary. The next crucial step is reviewing available local geological monitoring and instrumentation information that you have already gathered. Gathering and analyzing the following data should help engineers properly assess the situation:

  • The state of the foundation
  • The borehole logs review
  • Back analysis of additional numerical modelling
  • Sampling CPT testing
  • Geophysical surveys
  • Eventual remedial design measures such as reducing the slope or building an abutment or discharging tailings

Of course, you should also be following your trigger action response plans (TARPs). Proper instrumentation in place during both the design phase and throughout an operating lifespan should trip trigger alarms when deformation data exceeds thresholds. This type of approach allows engineers the ability to better predict and mitigate risk during the design phase, construction, operation, maintenance, and closure and post-closure activities.


This blog is a part of a series that recaps the topics explored in Digital Evolution of Geotechnical Monitoring presented by Terra Insights. Watch the webinar on-demand to learn how advances in monitoring technology have had wide-ranging impacts, from the design of instrumentation sensor components to wireless data acquisition and connectivity to space-based satellite imagery.

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  • 1993

    The Beginning

    Measurand is established in Fredericton, New Brunswick
  • 1994

    Bend sensor development

    Measurand develops and patents fiber optic bend and position sensors for the medical and automotive sectors

    U.S. Patent 5,321,257

  • 1995

    Canadian Space Agency

    Receives funding from the CSA to develop sensor technology that ultimately leads to invention of ShapeTape

    U.S. Patent 5,633,494

  • 1999

    Patent on fiber optic sensor

    Measurand receives patent for "Fiber Optic Bending and Positioning Sensor" issued June 29, 1999

    Canadian Patent 2,073,162

  • 2001

    ShapeTape & ShapeHand debut

    Measurand designs and develops innovative motion capture technology

    U.S. Patent 6,127,672, 6,563,107

  • 2002

    Measurand Attends the ICPMG

    First contact with the geotechnical sector at the International Conference on Physical Modelling in Geotechnics (ICPMG)
  • 2004

    ShapeArray

    Design patent application sent about a new product designed to meet the specific needs of the geotechnical industry

    U.S. Patent 6,127,672, 6,563,107

  • 2005-08

    ShapeWrap

    Measurand debuts ShapeWrap motion capture technology for the film and animation industry

    U.S. Patent 7,296,363

  • 2006

    Malibu installation

    ShapeAccelArray installed for ground monitoring for the first time​ in Malibu, CA

    Canadian Patent 2,472,421

  • 2007

    ShapeMRI

    Suite of instrumentation developed for motion capture within Magnetic Resonance Imaging (MRI) machines

    U.S. Patent 7,296,363

  • 2011

    SAAScan launched

    Built for rapid deployment and repeated use

    Canadian Patent 2,472,421

  • 2014

    SAAX launched

    Purpose-built for heavy-duty horizontal installation

    Canadian application 2,815,199 & 2,815,195

  • 2017

    SAAV launched

    The only geotechnical instrument with a patented cyclical installation method

    Cyclical Sensor Array, Canadian application 2,815,199 & 2,911,175