Multitask learning, i.e. learning several tasks at once with the same neural network, can improve performance in each of the tasks. Designing deep neural network architectures for multitask learning is a challenge: There are many ways to tie the tasks together, and the design choices matter. The size and complexity of this problem exceeds human design ability, making it a compelling domain for evolutionary optimization. Using the existing state of the art soft ordering architecture as the starting point, methods for evolving the modules of this architecture and for evolving the overall topology or routing between modules are evaluated in this paper. A synergetic approach of evolving custom routings with evolved, shared modules for each task is found to be very powerful, significantly improving the state of the art in the Omniglot multitask, multialphabet character recognition domain. This result demonstrates how evolution can be instrumental in advancing deep neural network and complex system design in general.

PDF

In Proceedings of the Genetic and Evolutionary Computation Conference (GECCO), pp. 466–473, Kyoto, Japan, 2018.

@inproceedings{liang:gecco18, title={Evolutionary Architecture Search For Deep Multitask Networks}, author={Jason Liang and Elliot Meyerson and Risto Miikkulainen}, booktitle={Proceedings of the Genetic and Evolutionary Computation Conference (GECCO)}, month={ }, address={Kyoto, Japan}, pages={466–473}, url="http://www.cs.utexas.edu/users/ai-lab?liang:gecco18", year={2018} }