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RE: Hey steem guys!
This is a bad idea because the use of non-Euclidean spaces, making it impossible to clearly determine the distance between the points. Imagine how many times you will have to solve the geodesic equation.
You can construct the model of the blood-vascular system via full body scanning and then calculate homology groups. And i think these groups can identify your person with high accuracy. Maybe using of homology is more difficult then calculating of invariants of your blood-vascular system graph.
Unfortunately, nested comments can't go on further than a depth of 6.
I just wanted to add that other techniques are taking data and using the Veronese embedding and applying Euclidean distance there. The idea here is that you have some additional info on your data, maybe it's only 20 variables and degree 8 or something, and then you can map these points under this embedding and consider the distance here. Alternatively, you can consider the inverse of this problem where you are trying to find some (approximate, possibly) generator of the ideal that defines the points on the variety.
Why would you want to restrict yourself to metrics on Euclidean spaces?
And it's not impossible to determine distance given a well-defined metric on any space. That's why it's a metric.
I'm not sure what you mean by having to solve the geodesic equation. Why is this done?
@complexring!
Sorry for a long time answer.
My message: it's may be bad idea to calculate distance between points on embedded surface as Euclidean metric. For example, take a look for sphere (Earth): Euclidean distance between north pole and south pole equal to 2R, but you can't penetrate through the Earth! You must keeping aboard surface, and, in this case, the real distance between point is equal to \pi * R.
Close point, obviously, should have similar properties, so you need to use a local metric.But of course it is necessary to take a closer look into the details of the task.e details of the task.