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Adversarial recovery of agent rewards from latent spaces of the limit order book

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arxiv 1912.04242 v1 pith:X4U4FKX7 submitted 2019-12-09 cs.LG q-fin.TRstat.ML

Adversarial recovery of agent rewards from latent spaces of the limit order book

classification cs.LG q-fin.TRstat.ML
keywords inverseadversarialenvironmentenvironmentslatentlearningrealability
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Inverse reinforcement learning has proved its ability to explain state-action trajectories of expert agents by recovering their underlying reward functions in increasingly challenging environments. Recent advances in adversarial learning have allowed extending inverse RL to applications with non-stationary environment dynamics unknown to the agents, arbitrary structures of reward functions and improved handling of the ambiguities inherent to the ill-posed nature of inverse RL. This is particularly relevant in real time applications on stochastic environments involving risk, like volatile financial markets. Moreover, recent work on simulation of complex environments enable learning algorithms to engage with real market data through simulations of its latent space representations, avoiding a costly exploration of the original environment. In this paper, we explore whether adversarial inverse RL algorithms can be adapted and trained within such latent space simulations from real market data, while maintaining their ability to recover agent rewards robust to variations in the underlying dynamics, and transfer them to new regimes of the original environment.

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