1. Better completion of fragmentary river networks with the induced terrain approach by using known non-river locations
Tsz-Yam Lau and W. Randolph Franklin
Rensselaer Polytechnic Institute
partially supported by NSF grants CMMI and IIS
SDH 2012

2. Outline Background Contribution Motivation of river reconnection
The induced terrain concept
Contribution
Easy incorporation of known non-river locations to improve accuracy of river reconnection problem
SDH 2012

3. River reconnection problem
2. Ground surveys are expensive, time-costly and sometimes impossible.
1. The complete river network is needed to address transportation problems
4. Automatic river location identification is incomplete (black). We need to reconnect the segments (red).
3. There are problems with remote multispectral imaging: obstacles, varied reflectance of water
SDH 2012

4. The induced terrain approach
Use given heights to eliminate invalid reconnections
Model given river locations as local minima w.r.t. non-river locations R
Guarantee given river locations must still be river locations
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5. Improvement with additional known non-river location information
We should not let water flow there.
Ground truth river network
Ground truth river network
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6. Improvement with additional known non-river location information
A few river flow derivation algorithms have already offered relevant options. (e.g. the –blocking option of r.watershed in GRASS GIS)
But it could be unreasonable to expect every implementation to have such an option.
There is no way to add that feature to a closed-source implementation.
It is difficult to realize similar things even if we have the source code.
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7. Original induced terrain
Height point samples and partial river
Hydrologically corrected terrain
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8. Adaptation to known non-river locations
Blue: known river locations
Heights of known non-river locations raised
Terrain from last step
White: known cloud locations
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9. How many should we raise?
for known non-river locations
Objective
No water at given river locations should flow to known non-river locations.
It should be effective with many different river derivation algorithms.
Different kinds of river derivation algorithms
Flow assignment based on local relative heights
Flooding before local flow assignment
Least-cost search
Otherwise
SDH 2012

10. How many should we raise?
for known non-river locations
Otherwise
Objective
No water should flow to known non-river locations.
It should be effective with many different river derivation algorithms.
Different kinds of river derivation algorithms 25 30 22 10 5 15 25 30 22 25 30 22 25 30 22 11 14 13 10 5 15 10 10 15 10 20 15 25 30 22 11 14 13 11 14 13 11 14 13 10 5 15
Flow assignment based on local relative heights (e.g. single-flow direction) 11 14 13
Flooding before flow assignment
Least cost search
SDH 2012

11. How many should we raise?
Raising by the maximum height in the terrain
Flow assignment based on local relative heights
Locations higher than those locations are now places with no water. So they can never receive any water.
Flooding before local flow assignment:
The level raised can never be higher than those non-river locations since they are supposed to leave from other places
Least-cost search:
Known non-river locations are guaranteed to find inflow cells after all other uncertain locations. In other words, they will never find inflow cells which has water inflow.
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12. Improvement with additional known non-river location information
No more reconnections at known non-river locations
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13. Improvement in reconnection accuracy
Around 5 percentage point improvement
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14. Conclusion Contribution of our work
Avoid reconnection of segments using regions known to have no river flow by setting the heights of known river locations to an unreachable level
Need not change anything in the river derivation algorithm
Improve accuracy by 5%.
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15. Further work
Incorporate other terrain information (e.g. segment geometry) to improve accuracy further
Port the induced terrain framework to completion of 3D dendrite networks
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16. Questions?
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