#Business #People

How Can We Make Building Decarbonization Faster and More Effective? | Problem Solved | Geoawesome Podcast

Buildings contribute 39% of global CO₂ emissions, yet decarbonization remains slow and costly. In the first episode of Problem Solved, Bobbie H. Kalra, Founder of Magnasoft, joins Geoawesome to discuss how geospatial intelligence is transforming carbon reduction efforts.

The Challenge: Why ESG Reporting is Difficult

Traditional ESG reporting is manual, expensive, and difficult to scale. Bobbie explains:


“Data is at the heart of planning, operations, and maintenance. Geospatial provides the platform for decision-making.”

A Smarter Solution: Magnasoft’s mGreen

Magnasoft’s mGreen simplifies decarbonization using AI-powered data capture and analysis:
DIY Data Collection – Asset owners use iPads/iPhones instead of costly LiDAR.
Automated Carbon Analysis – AI models embodied carbon and compliance with BREEAM, LEED, NEN 2767.
Faster, Cheaper Reporting – A pilot in the Netherlands reduced ESG reporting costs by 60% while maintaining ±5% accuracy.

The Future of Geospatial in Sustainability

“We are running out of time. Geospatial will soon be a default enabler for decarbonization,” says Bobbie. However, the geospatial industry must focus more on solving real-world business problems rather than just advancing technology.

🚀 Problem Solved is a new Geoawesome podcast exploring how geospatial tech tackles real-world challenges.

🔗 Listen to the full episode
🔗 Learn more about mGreen & Magnasoft: https://www.magnasoft.com


Did you like the article? Read more and subscribe to our monthly newsletter!

Say thanks for this article (0)
The community is supported by:
Become a sponsor
#Business
#Business #Environment #Ideas #Satellites
China’s Smart Agriculture Boom Has Tech Potential but Requires Affordable Solutions
Nianhua Liu 05.9.2024
AWESOME 3
#Business #GeoDev
3 Pathways For Integrating Planet Data Into Your GIS Workflow
Avatar for Sponsored Article
Sponsored Article 08.12.2024
AWESOME 2
#Business #Environment #People
The Role of Geospatial Technologies in Decarbonization and ESG
GeoawesomeTeam 03.18.2025
AWESOME 0
Next article
#Contributing Writers #Environment #Featured #Science

Harnessing UAV Technology to Support Municipal Solid Waste Management

The Relevance of MSW 

Municipal Solid Waste (MSW) management poses a challenge in many countries, especially in regions with insufficient waste management infrastructure.

According to a UN Report 2018, several regions in Africa are identified as critical hotspots for waste mismanagement. In 2012, only 55% of MSW was collected across the continent, and 4% was recycled, despite the fact that 70–80% of the waste was recyclable.

The lack of formal waste collection and management systems can lead to waste accumulation in illegal dumpsites. This can contribute to environmental pollution, including the contamination of drinking water sources, soil degradation that impacts agricultural productivity, and the creation of unsanitary conditions that potentially facilitate the spread of infectious diseases. Beyond this, the accumulation of MSW along riverbanks can increase the risk of flooding by obstructing water flow, altering natural drainage pathways, trapping sediment, and blocking drainage infrastructure.

These combined challenges directly impact several United Nations Sustainable Development Goals (SDGs), particularly those related to good health and well-being (Goal 3), clean water and sanitation (Goal 6), life below water (Goal 14), and life on land (Goal 15).

Figure 1: Illegal Municipal Solid Waste piles in the Msimbazi River Delta are causing regular flooding after heavy rainfall and contributing to environmental pollution. © Wikipedia Commons

Unmanned Aerial Vehicles (UAVs) for MSW Dumpsite Detection

Accurate knowledge of the location of MSW, including illegal dumpsites, is crucial for optimizing waste disposal and recycling efforts. The integration of UAVs with pre-trained neural networks for object detection presents a promising solution for mapping waste distribution in urban areas. UAVs offer high-resolution aerial imagery that surpasses the resolution of openly accessible satellite data, enabling the identification of both large and small waste piles with greater precision.

Case Study: Dar es Salaam, Tanzania

A team of geoinformatics researchers from the University of Heidelberg and HeiGIT, in collaboration with OpenData Development Tanzania, proposed a workflow utilizing UAVs to monitor Municipal Solid Waste (MSW). This workflow was tested in Dar es Salaam, Tanzania, with a specific focus on the Msimbazi River area, one of the most polluted riverbeds in eastern Africa. Dar es Salaam, home to approximately 5.3 million people, has around 27% of its population residing in the wider Msimbazi delta.

This region was chosen due to its significant contribution of waste to the Indian Ocean and its frequent flooding, exacerbated by clogged drainage systems caused by MSW. The research team trained an object detection algorithm on UAV imagery for MSW detection, which can be downloaded and fine-tuned for application in other areas (cf. UAV-Assisted Municipal Solid Waste Monitoring for Informed Disposal Decisions [Research Data] ). The model was evaluated using a crowdsourced, locally labeled MSW dataset to leverage regional expertise. The trained model achieved an F1-score of 0.92 for 1,289 MSW instance, indicating high accuracy.

Figure 2: Workflow of harnessing commercial UAV technology to support MSW management.

Discussion of the Proposed Workflow for MSW Detection Using UAV Imagery

While the proposed workflow for MSW detection using UAV imagery has demonstrated promising results, several challenges remain that could be addressed in future studies. One major challenge is the indistinct and ambiguous boundaries that characterize MSW piles, complicating the accuracy of object detection. Enhancements could likely be achieved by applying image classification or segmentation techniques to small UAV imagery tiles to improve detection accuracy. Common False Positives (FP) in the object detection on MSW piles included “reflections in water” and “drying clothes”, while typical True Negatives (TN) referred to “rubble piles” and “courtyard mosaics”.

To improve model performance, the four object classes could be incorporated into the labeling process as separate categories. Indoor MSW or MSW beneath tree canopies and shelters was completely missed by the proposed method (Figure 3). A comparative study with openly accessible satellite imagery highlighted the importance of high-resolution UAV imagery for precise MSW mapping (Figure 4). However, satellite imagery could still be useful for large-scale assessments prior to planning more targeted UAV missions, which are often associated with higher labor costs and regulatory constraints. When applying the pre-trained model on UAV imagery in different contexts, cultural factors related to waste should be considered. For instance, in some regions, discarded car tires serve a functional purpose, while in others, they are classified as waste. This emphasizes the value of crowdsourced labeling tools such as MapSwipe, which enable local communities to contribute their knowledge to the labeling process, ensuring greater accuracy.

Figure 3: Examples of True Positives, True Negatives, False Positives, and False Negatives predicted by the proposed model. Detected waste piles were indicated by red bounding boxes.

Figure 4: Left – Detected MSW piles along the Msimbazi delta in Dar es Salaam. Right – Satellite imagery based MSW pile detections for the Msimbazi delta utilizing UAV imagery based MSW detections as training and testing labels for rough evaluation of satellite imagery as a useful tool to map MSW piles.

By publishing the pre-trained MSW detection model (cf. UAV-Assisted Municipal Solid Waste Monitoring for Informed Disposal Decisions [Research Data] ), organizations such as OpenMap Development Tanzania (OMDTZ) can support local MSW management in Dar es Salaam, Tanzania, without relying on costly software. OMDTZ can regularly collect UAV imagery and apply the pre-trained MSW detection algorithms to generate up-to-date MSW contamination maps.

These maps can guide municipal decision-making, helping to prioritize waste collection efforts and identify optimal locations for establishing new official dumpsites that adhere to environmental regulations, ultimately reducing risks related to flooding and disease outbreaks.

 

This article was guest written by Steffen Knoblauch (Heidelberg University), Levi Szamek (Heidelberg University & HeiGIT), and Lisa Shkredova (HeiGIT).

 


Did you like the article? Read more and subscribe to our monthly newsletter!

Read on
Search