I'd suggest first understanding slow feature matching, without kdtrees.
- input: 1000 reference features, e.g. of faces or flowers; call these F1 .. F1000
- a query feature Q: which face or flower feature is most like, nearest, Q ?
As you know,
reduces an image feature to 128 8-bit numbers, scaled so that
similarity( feature F, feature Q ) =
Euclidean distance( SIFT(F), SIFT(Q) ).
The simplest way to find which of F1 .. F1000 is most like Q
is just to look at F1, F2 ... one by one:
# find the feature of F1 .. F1000 nearest Q
nearestdistance = infinity
nearestindex = 0
for j in 1 .. 1000:
distance = Euclideandistance( SIFT(Fj), SIFT(Q) ) # 128 numbers vs. 128 numbers
if distance < nearestdistance:
nearestdistance = distance
nearestindex = j
(Of course one computes the SIFT numbers outside the loop.)
is just a way of finding nearby vectors quickly;
it has little to do with what is being matched
(vectors of numbers representing ...), or how (Euclidean distance).
Now kdtrees are very fast for 2d, 3d ... up to perhaps 20d,
but may be no faster than a linear scan of all the data above 20d.
So how can a kdtree work for features in 128d ?
The main trick is to quit searching early.
The paper by Muja and Lowe,
Fast approximate nearest neighbors with automatic algorithm configuration,
2009, 10p, describes multiple randomized kdtrees for matching 128d SIFT features.
(Lowe is the inventor of SIFT.)
To compare two images I and Q, one finds a set of feature vectors --
several hundred up to a few thousand SIFT vectors -- for each,
and looks for near matches of these sets.
(One may think of images as molecules, features as atoms;
near-matching molecules is much harder than near-matching atoms,
but it helps to be able to match atoms quickly.)
Hope this helps.