Under Microsoft’s AI for Humanitarian Action program, Bing Maps is contributing to an initiative from Humanitarian OpenStreetMap Team that will bring AI Assistance to open map building. More information around the partnership is available on Bing Maps blog.
Bing Maps is releasing country wide open building footprints datasets in Uganda and Tanzania. This dataset contains 17,942,345 computer generated building footprints derived using Bing Maps algorithms on satellite imagery. Satellite imagery used for Uganda and Tanzania extraction is from our imagery partner Maxar Technologies. The data is freely available for download and use under applicable license.
This data is licensed by Microsoft under the Open Data Commons Open Database License (ODbL).
17,942,345 building footprint polygon geometries in Uganda and Tanzania in GeoJSON format. You can download the data here:
Country | Number of Buildings | Unzipped MB |
---|---|---|
Uganda | 6,928,078 | 1339 |
Tanzania | 11,014,267 | 2202 |
GeoJSON is a format for encoding a variety of geographic data structures. For intensive documentation and tutorials, refer to GeoJson blog.
Microsoft has a continued interest in supporting a thriving OpenStreetMap ecosystem.
Maybe. Never overwrite the hard work of other contributors or blindly import data into OSM without first checking the local quality. While our metrics show that this data meets or exceeds the quality of hand-drawn building footprints, the data does vary in quality from place to place, between rural and urban, mountains and plains, and so on. Inspect quality locally and discuss an import plan with the community. Always follow the OSM import community guidelines.
Yes. Currently Microsoft Open Buildings dataset is used in ml-enabler for task creation. You can try it out at AI assisted Tasking Manager. Facebook has also integrated the dataset into RapiD editor. Try it out here RapiD.
The building extraction is done in two stages:
- Semantic Segmentation – Recognizing building pixels on the satellite image using DNNs
- Polygonization – Converting building pixel blobs into polygons
The network backbone is EfficientNet B3 which can be found here. The model is fully-convolutional, meaning that the model can be applied to an image of any size (constrained by GPU memory, 4096x4096 in our case).
The training set consists of 1.2 million labeled buildings. The data is diverse in terms of geolocation, urbanization and underlying imagery, in order to attain the good corpus representativeness. We also used mixture of high and low quality labels. Images in the set are with 30 cm/pixel resolution.
These are the intermediate stage metrics we use to track DNN model improvements and they are pixel based. Pixel precision/recall = 86.8%/81.8%.
We developed a method that approximates the prediction pixels into polygons making decisions based on the whole prediction feature space. This is very different from standard approaches, e.g. Douglas-Peucker algorithm, which are greedy in nature. The method tries to impose some of a priori building properties, which is, at the moment, manually defined and automatically tuned.
Building matching metrics:
Metric | Value |
---|---|
Precision | 94.5% |
Recall | 61.8% |
False positive ratio across the board is 1.6%.
We track various metrics to measure the quality of the output:
- Intersection over Union – This is the standard metric measuring the overlap quality against the labels
- Shape distance – With this metric we measure the polygon outline similarity
- Dominant angle rotation error – This measures the polygon rotation deviation
The evaluation set contains 18.5k building. The metrics on the set are:
- IoU is 0.68, Shape distance is 0.39, Average rotation error is 4.1 degrees
The vintage of the footprints depends on the vintage of the underlying imagery. Bing Imagery is a composite of multiple sources, therefore it is difficult to know the exact dates for individual pieces of data.
Our metrics show that in the vast majority of cases the quality is at least as good as data hand digitized buildings in OpenStreetMap. It is not perfect, particularly in dense urban areas but it provides good recall in rural areas. See below for metrics by area type:
EPSG: 4326
Maybe. This is a work in progress.
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