1 research outputs found
Key-Nets: Optical Transformation Convolutional Networks for Privacy Preserving Vision Sensors
Modern cameras are not designed with computer vision or machine learning as
the target application. There is a need for a new class of vision sensors that
are privacy preserving by design, that do not leak private information and
collect only the information necessary for a target machine learning task. In
this paper, we introduce key-nets, which are convolutional networks paired with
a custom vision sensor which applies an optical/analog transform such that the
key-net can perform exact encrypted inference on this transformed image, but
the image is not interpretable by a human or any other key-net. We provide five
sufficient conditions for an optical transformation suitable for a key-net, and
show that generalized stochastic matrices (e.g. scale, bias and fractional
pixel shuffling) satisfy these conditions. We motivate the key-net by showing
that without it there is a utility/privacy tradeoff for a network fine-tuned
directly on optically transformed images for face identification and object
detection. Finally, we show that a key-net is equivalent to homomorphic
encryption using a Hill cipher, with an upper bound on memory and runtime that
scales quadratically with a user specified privacy parameter. Therefore, the
key-net is the first practical, efficient and privacy preserving vision sensor
based on optical homomorphic encryption.Comment: BMVC'20 (Best Paper - Runner up