1 research outputs found
Learning to Warm-Start Fixed-Point Optimization Algorithms
We introduce a machine-learning framework to warm-start fixed-point
optimization algorithms. Our architecture consists of a neural network mapping
problem parameters to warm starts, followed by a predefined number of
fixed-point iterations. We propose two loss functions designed to either
minimize the fixed-point residual or the distance to a ground truth solution.
In this way, the neural network predicts warm starts with the end-to-end goal
of minimizing the downstream loss. An important feature of our architecture is
its flexibility, in that it can predict a warm start for fixed-point algorithms
run for any number of steps, without being limited to the number of steps it
has been trained on. We provide PAC-Bayes generalization bounds on unseen data
for common classes of fixed-point operators: contractive, linearly convergent,
and averaged. Applying this framework to well-known applications in control,
statistics, and signal processing, we observe a significant reduction in the
number of iterations and solution time required to solve these problems,
through learned warm starts