Goal-Conditioned GFlowNets for Controllable Multi-Objective Molecular Design
Abstract
In recent years, in-silico molecular design has received much attention from the machine learning community. When designing a new compound for pharmaceutical applications, there are usually multiple properties of such molecules that need to be optimised: binding energy to the target, synthesizability, toxicity, EC50, and so on. While previous approaches have employed a scalarization scheme to turn the multi-objective problem into a preference-conditioned single objective, it has been established that this kind of reduction may produce solutions that tend to slide towards the extreme points of the objective space when presented with a problem that exhibits a concave Pareto front. In this work we experiment with an alternative formulation of goal-conditioned molecular generation to obtain a more controllable conditional model that can uniformly explore solutions along the entire Pareto front.
Cite
Text
Roy et al. "Goal-Conditioned GFlowNets for Controllable Multi-Objective Molecular Design." ICML 2023 Workshops: DeployableGenerativeAI, 2023.Markdown
[Roy et al. "Goal-Conditioned GFlowNets for Controllable Multi-Objective Molecular Design." ICML 2023 Workshops: DeployableGenerativeAI, 2023.](https://mlanthology.org/icmlw/2023/roy2023icmlw-goalconditioned/)BibTeX
@inproceedings{roy2023icmlw-goalconditioned,
title = {{Goal-Conditioned GFlowNets for Controllable Multi-Objective Molecular Design}},
author = {Roy, Julien and Bacon, Pierre-Luc and Pal, Christopher and Bengio, Emmanuel},
booktitle = {ICML 2023 Workshops: DeployableGenerativeAI},
year = {2023},
url = {https://mlanthology.org/icmlw/2023/roy2023icmlw-goalconditioned/}
}