1 research outputs found
Similarity Learning via Adaptive Regression and Its Application to Image Retrieval
We study the problem of similarity learning and its application to image
retrieval with large-scale data. The similarity between pairs of images can be
measured by the distances between their high dimensional representations, and
the problem of learning the appropriate similarity is often addressed by
distance metric learning. However, distance metric learning requires the
learned metric to be a PSD matrix, which is computational expensive and not
necessary for retrieval ranking problem. On the other hand, the bilinear model
is shown to be more flexible for large-scale image retrieval task, hence, we
adopt it to learn a matrix for estimating pairwise similarities under the
regression framework. By adaptively updating the target matrix in regression,
we can mimic the hinge loss, which is more appropriate for similarity learning
problem. Although the regression problem can have the closed-form solution, the
computational cost can be very expensive. The computational challenges come
from two aspects: the number of images can be very large and image features
have high dimensionality. We address the first challenge by compressing the
data by a randomized algorithm with the theoretical guarantee. For the high
dimensional issue, we address it by taking low rank assumption and applying
alternating method to obtain the partial matrix, which has a global optimal
solution. Empirical studies on real world image datasets (i.e., Caltech and
ImageNet) demonstrate the effectiveness and efficiency of the proposed method