Convolutions encode equivariance symmetries into neural networks leading to
better generalisation performance. However, symmetries provide fixed hard
constraints on the functions a network can represent, need to be specified in
advance, and can not be adapted. Our goal is to allow flexible symmetry
constraints that can automatically be learned from data using gradients.
Learning symmetry and associated weight connectivity structures from scratch is
difficult for two reasons. First, it requires efficient and flexible
parameterisations of layer-wise equivariances. Secondly, symmetries act as
constraints and are therefore not encouraged by training losses measuring data
fit. To overcome these challenges, we improve parameterisations of soft
equivariance and learn the amount of equivariance in layers by optimising the
marginal likelihood, estimated using differentiable Laplace approximations. The
objective balances data fit and model complexity enabling layer-wise symmetry
discovery in deep networks. We demonstrate the ability to automatically learn
layer-wise equivariances on image classification tasks, achieving equivalent or
improved performance over baselines with hard-coded symmetry