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In addition to drastically simplifying the adversarial inverse reinforcement learning framework, our methods perform on par or better than previous approaches on all but one environment
Adversarial Soft Advantage Fitting: Imitation Learning without Policy Optimization
NIPS 2020, (2020)
Adversarial imitation learning alternates between learning a discriminator -- which tells apart expert's demonstrations from generated ones -- and a generator's policy to produce trajectories that can fool this discriminator. This alternated optimization is known to be delicate in practice since it compounds unstable adversarial trainin...More
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- Imitation Learning (IL) treats the task of learning a policy from a set of expert demonstrations.
- Behavioral cloning casts IL as a supervised learning objective and seeks to imitate the expert’s actions using the provided demonstrations as a fixed dataset .
- This usually requires a lot of expert data and results in agents that struggle to generalize.
- Imitation Learning (IL) treats the task of learning a policy from a set of expert demonstrations
- IL is effective on control problems that are challenging for traditional reinforcement learning methods, either due to reward function design challenges or the inherent difficult of the task itself [1, 23]
- In addition to drastically simplifying the adversarial inverse reinforcement learning (IRL) framework, our methods perform on par or better than previous approaches on all but one environment
- While Generative Adversarial Imitation Learning (GAIL) was originally proposed without gradient penalty (GP) , we empirically found that GP prevents the discriminator to overfit and enables reinforcement learning (RL) to exploit dense rewards, which highly improves its sample efficiency
- We propose an important simplification to the adversarial inverse reinforcement learning framework by removing the reinforcement learning optimisation loop altogether
- We evaluate our approach against prior works on many different benchmarking tasks and show that our method (ASAF) compares favorably to the predominant imitation learning algorithms
- Experiments on classic control and
Figure 1 shows that ASAF and its approximate variations ASAF-1 and ASAF-w quickly converge to expert’s performance.
- For GAIL and AIRL, this is likely due to the concurrent RL and IRL loops, whereas for SQIL, it has been noted that an effective reward decay can occur when accurately mimicking the expert 
- This instability is severe in the continuous control case.
- To scale up the evaluations in continuous control the authors use the popular MuJoCo simulator
- In this domain, the trajectory length is either fixed at a large value (1000 steps on HalfCheetah) or varies a lot across episodes (Hopper and Walker2d).
- Results and discussion
The authors evaluate the methods on a variety of discrete and continuous control tasks.
- 4 shows that ASQF performs well on small scale environments but struggles and eventually fails on more complicated environments
- It seems that ASQF does not scale well with the observation space size.
- For each state, several transitions with different actions are required in order to learn it
- Approximating this partition function could lead to assigning too low a probability to expert-like actions and eventually failing to behave appropriately.
- ASAF on the other hand explicitly learns the probability of an action given the state – in other word it explicitly learns the partition function – and is immune to that problem
- The authors propose an important simplification to the adversarial inverse reinforcement learning framework by removing the reinforcement learning optimisation loop altogether.
- By using a particular form for the discriminator, the method recovers a policy that matches the expert’s trajectory distribution.
- The authors evaluate the approach against prior works on many different benchmarking tasks and show that the method (ASAF) compares favorably to the predominant imitation learning algorithms.
- The authors' approach still involves a reward learning module through its discriminator, and it would be interesting in future work to explore how ASAF can be used to learn robust rewards along the lines of Fu et al .
- Table1: Fixed Hyperparameters for classic control tasks
- Table2: Best found hyper-parameters for Cartpole
- Table3: Best found hyper-parameters for Mountaincar
- Table4: Best found hyper-parameters for Lunarlander
- Table5: Best found hyper-parameters for Pendulum
- Table6: Best found hyper-parameters for Mountaincar-c
- Table7: Best found hyper-parameters for Lunarlander-c
- Table8: Hyperparameters for MuJoCo environments
- Table9: Fixed Hyperparameters for Pommerman Random-Tag environment
- Table10: Figure 3 uses these configurations retrained on 10 seeds. Best found hyper-parameters for the Pommerman Random-Tag environment
- Table11: Expert demonstrations used for Imitation Learning
- Ziebart et al  first proposed MaxEnt IRL, the foundation of modern IL. Ziebart  further elaborated MaxEnt IRL as well as deriving the optimal form of the MaxEnt policy at the core of our methods. Finn et al  proposed a GAN formulation to IRL that leveraged the energy based models of Ziebart . Finn et al ’s implementation of this method, however, relied on processing full trajectories with Linear Quadratic Regulator and on optimizing with guided policy search, to manage the high variance of trajectory costs. To retrieve robust rewards, Fu et al  proposed a straightforward transposition of  to state-action transitions. In doing so, they had to however do away with a GAN objective during policy optimization, consequently minimizing the Kullback–Leibler divergence from the expert occupancy measure to the policy occupancy measure (instead of the Jensen-Shannon divergence) .
- We would also like to thank Fonds de Recherche Nature et Technologies (FRQNT), Ubisoft Montreal and Mitacs Accelerate Program for providing funding for this work as well as Compute Canada for providing the computing resources
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