What is bathymetric modeling? And how can it protect ecosystems while saving resources?
September 04, 2025
Bathymetric modeling maps underwater terrain. It also helps guide planning, prevent hazards, and build climate-resilient infrastructure.
Ever wondered what the bottom of a lake or ocean really looks like and why it matters? Bathymetric modeling gives us the answer. Bathymetric modeling is the process of mapping and analyzing the depth, shape, and features of underwater terrain, such as lakebeds, riverbeds, and ocean floors. It uses technologies¡ªsonar, green laser LiDAR, and remote sensing methods¡ªto create detailed 3D models of submerged environments.
Bathymetric modeling data gives us an accurate view of the conditions in the water. This helps engineers and environmental experts make better-informed decisions. For example, it can spot fragile habitats, areas where land is wearing away, or places where sediment piles up. This allows for early action to stop problems from getting worse. It¡¯s a proactive approach that helps protect aquatic ecosystems; at the same time, it also helps avoid costly surprises during construction, maintenance, or restoration projects. In short, better data leads to smarter planning, which benefits both the environment and the bottom line.
In recent years, we¡¯ve seen an increased need for accurate and current data. This is especially true when it comes to things like environmental sustainability and water management. This information can help policymakers when it¡¯s time to make decisions about infrastructure. It¡¯s also important for engineers and consultants. It allows them to create effective solutions while protecting the environment.
The Peace-Athabasca Delta in Alberta is one of the world¡¯s largest freshwater deltas. Our Geospatial and Water teams used innovative bathymetric modeling to study its water systems, support conservation, and protect Indigenous traditions.
Accurate data is just the starting point. The real impact happens when we have the knowledge to turn that data into meaningful action. Then, we can solve complex problems. This often calls for innovation and creativity. Before delving into the specifics, it¡¯s important to understand how bathymetric modeling relates to engineering. Let¡¯s review.
What is bathymetric modeling?
Bathymetric modeling measures the depth and shape of water bodies. It¡¯s like a topographic map of what¡¯s under the water. It can provide information for many scientific studies and applications. These systems might include:
- Geophysical
- Geological
- Biological
- Hydrological?
Most bathymetric surveys use a boat equipped with a high-precision Global Navigation Satellite System (GNSS) and a depth-sounding sonar. As the boat glides across the water, the GNSS receiver logs the exact positions, while the sonar beams bounce off the bottom to measure the depth. Systems like single-beam sonars measure depths directly beneath the vessel. Others, such as side-scanning or multi-beam units, measure a swath along the path. Bathymetric modeling is often paired with topographic mapping programs like LiDAR survey (Light Detection and Ranging) or ground surveys. Using both creates a seamless model for running accurate analysis. The key factor is the density of these measurements, which not only affects the model¡¯s detail and accuracy but also the cost of the program¡ªgenerally speaking, more bathymetric data means higher expenses.?
As we dig into bathymetric modeling, here are some important terms.
- Kriging Method: It.s a spatial form of averaging used to estimate values between known data points. It¡¯s ideal for filling gaps in underwater terrain maps.
- LiDAR: It uses laser beams to generate precise maps of an environment and measure distances.
- UAV photogrammetry: A survey technique that uses drones to capture aerial images. The images are used to create accurate geospatial models.
Members of our team conduct stream measurements to support environmental assessment work. Collecting critical data helps guide sustainable project planning.
How and where is bathymetric modeling most used?
Bathymetric modeling plays a crucial role in shaping a variety of projects that touch our everyday lives. It has a wide application. For example, bathymetry provides data for bridge and utility line construction across water bodies. It even supports challenges like sourcing water for ice roads in remote areas and mapping fish habitats for environmental projects, which helps preserve aquatic ecosystems.?
Bathymetry is especially useful for ?
- Flood control and water management for rivers and reservoirs.?
- Stormwater management and sediment buildup monitoring.?
- Bridges, piers, and docks. And other coastal engineering projects.?
- Pipeline and utility crossings that go over, under, or through water bodies.?
- Maritime navigation safety, dredging planning, and exploration of resources.
- Hazard prevention in vulnerable infrastructure areas.
How can bathymetric modeling provide climate change solutions?
Tackling climate change requires forward-thinking strategies, and the work we do is a powerful tool in this effort. Yet, the reality of working in vast and remote areas with limited time and budget makes data collection a challenge. We need smarter, sustainable solutions to overcome these hurdles. The end result? More efficient, correct, and cost-effective bathymetric data mapping. By embracing innovation and working together, we can better understand underwater areas, check ecosystem health, and make choices that protect coasts and support climate resilience. In hard-to-reach locations, advanced analysis and estimation methods can offset required field work. In other cases, extensive field data collection can streamline analysis in the office.
In 2022, our Geospatial team partnered with our Water team to conduct extensive research on the Peace-Athabasca Delta (PAD) in Alberta, Canada. They studied water systems and ways to protect the environment and the culture of the area. We also looked at how similar projects have addressed climate challenges in the past.
The PAD is within Wood Buffalo National Park, a UNESCO World Heritage Site. It¡¯s one of the largest freshwater deltas in the world. It covers 321,000 hectares. That¡¯s almost the same size as 450,000 FIFA-sized soccer fields. Complex geology and regular flooding help shape this unique ecosystem. However, climate change, the gradual buildup of sediment in the delta, and flow regulation have disrupted these natural patterns. As a result, lower water levels are putting the ecosystem at risk. Also at risk are local Indigenous traditions. This includes hunting; trapping; fishing; berry-picking; and spiritual, medicinal, and cultural land uses.?
Accurate data is just the starting point. The real impact happens when we have the knowledge to turn that data into meaningful action.
In response, Parks Canada released an . It included measures like building water control structures to help restore the natural water flow and offset impacts.?
When I first learned about the project, I knew comprehensive bathymetric modeling was the right approach. However, creating full bathymetric models for a massive area of 264 square miles (684 square kilometers)¡ªfour times the size of Edmonton, Alberta¡ªseemed almost impossible. Here was the challenge: We had limited time and survey control, dense vegetation cover, and remote access. And we needed accurate river topography to model water levels.
Traditional methods would have made it difficult to deliver a complete model on time and within budget. So, we used two innovative techniques instead:
- Developing a flow-oriented coordinate system for each bathymetric survey segment
- Applying the Kriging Method
For example, imagine you're mapping the depth of a lake but only have measurements at a handful of points. Kriging helps you estimate the depth between those points in a way that reflects how depth usually changes across the lake¡ªand it tells you how confident it is in those estimates.
By using these methods and automation, we cut down on prediction bias and improved accuracy. We also made a bathymetric data model using far fewer resources than traditional methods. Our statistics-based approach tested how well the interpolated surface matched the surveyed measurements. And it turned what could have been 50 times more field days into a manageable and timely process for full 3D impact evaluations.
I had the opportunity to collaborate with Matt Wood, who leads natural systems design in North America. Together with local community-based monitoring groups, we surveyed over 500 kilometres of remote channels and wetlands. We used custom tools and methods to create a 300-square-kilometre Digital Elevation Model (DEM) with enhanced features and one complete data package. By working together, we have made the delta¡¯s complex modeling easier and improved the quality of our work.
How can data and mapping protect against climate risks?
Preparing for the impacts of climate change isn¡¯t easy. But geospatial engineering can help analyze and show water systems with remarkable precision. After the 2013 Elbow River flood in southern Alberta, the provincial government launched the Springbank Off-Stream Storage Reservoir (SR1) project. The solution? To create an off-stream storage reservoir during extreme floods.?
Alberta¡¯s Elbow River winds through farmland and forest. Here, geospatial engineering and bathymetric modeling are helping protect communities from future flood risks through projects like the Springbank Off-Stream Storage Reservoir (SR1) project.
SR1 is a large-scale, fast-moving project with a tight schedule and lots of moving parts. It requires seamless execution and coordination between our teams, stakeholders, subconsultants, and suppliers. Geospatial engineering plays a critical role in keeping the project on track¡ªsupporting hydrotechnical design, which allows real-time decisions using accurate, detailed data. These insights are key to guiding infrastructure development that is built efficiently but also with resilience in mind.
We applied the same innovative Kriging method to previously collected river data. This improved our team¡¯s Hydrologic Engineering Center¡ªRiver Analysis System flow models. And it helped us better understand the Elbow River¡¯s water flow. To manage the project¡¯s scale, we also deployed large-area UAV photogrammetric mapping. We mapped roughly 700 hectares each month to document construction progress, capture the in-stream fish offsetting works, and track changes along the Elbow River. The UAV program also supported post-completion monitoring of the fishway and fast, safe assessments after high-water events, letting us observe channel response and verify habitat performance. This digital workflow made data delivery faster. It also improved quality and kept colleagues across North America up to date with timely visuals. It turned a complex task into an efficient, high-impact program.
What are the benefits of bathymetric modeling?
We use bathymetric modeling to help preserve the environment, manage resources, and protect infrastructure. Meeting these challenges depends on having precise data and the skills to use it well. When combined with advanced geospatial tools and expert analysis, bathymetric modeling turns data into meaningful action.
The world faces growing environmental pressures and a need for more resilient infrastructure. That makes the ability to map and understand our water systems more critical. These tools empower us to deliver smarter, faster, and more sustainable solutions. Whether that¡¯s supporting Indigenous communities in remote deltas to protecting urban centers from extreme flooding.
