A Hybrid Learning-to-Optimize Framework for Mixed-Integer Quadratic Programming
For researchers and practitioners in control and optimization, this work offers a practical method to accelerate MIQP solving with enhanced solution quality.
The paper proposes a hybrid learning-to-optimize framework for parametric mixed-integer quadratic programming, achieving improved optimality and feasibility over purely supervised and self-supervised models on two benchmark MI-MPC problems.
In this paper, we propose a learning-to-optimize (L2O) framework to accelerate solving parametric mixed-integer quadratic programming (MIQP) problems, with a particular focus on mixed-integer model predictive control (MI-MPC) applications. The framework learns to predict integer solutions with enhanced optimality and feasibility by integrating supervised learning (for optimality), self-supervised learning (for feasibility), and a differentiable quadratic programming (QP) layer, resulting in a hybrid L2O framework. Specifically, a neural network (NN) is used to learn the mapping from problem parameters to optimal integer solutions, while a differentiable QP layer is integrated to compute the corresponding continuous variables given the predicted integers and problem parameters. Moreover, a hybrid loss function is proposed, which combines a supervised loss with respect to the global optimal solution, and a self-supervised loss derived from the problem's objective and constraints. The effectiveness of the proposed framework is demonstrated on two benchmark MI-MPC problems, with comparative results against purely supervised and self-supervised learning models.