# Training with Proximal Policy Optimization ML-Agents uses a reinforcement learning technique called [Proximal Policy Optimization (PPO)](https://blog.openai.com/openai-baselines-ppo/). PPO uses a neural network to approximate the ideal function that maps an agent's observations to the best action an agent can take in a given state. The ML-Agents PPO algorithm is implemented in TensorFlow and runs in a separate Python process (communicating with the running Unity application over a socket). To train an agent, you will need to provide the agent one or more reward signals which the agent should attempt to maximize. See [Reward Signals](Reward-Signals.md) for the available reward signals and the corresponding hyperparameters. See [Training ML-Agents](Training-ML-Agents.md) for instructions on running the training program, `learn.py`. If you are using the recurrent neural network (RNN) to utilize memory, see [Using Recurrent Neural Networks](Feature-Memory.md) for RNN-specific training details. If you are using curriculum training to pace the difficulty of the learning task presented to an agent, see [Training with Curriculum Learning](Training-Curriculum-Learning.md). For information about imitation learning from demonstrations, see [Training with Imitation Learning](Training-Imitation-Learning.md). ## Best Practices Training with PPO Successfully training a Reinforcement Learning model often involves tuning the training hyperparameters. This guide contains some best practices for tuning the training process when the default parameters don't seem to be giving the level of performance you would like. ## Hyperparameters ### Reward Signals In reinforcement learning, the goal is to learn a Policy that maximizes reward. At a base level, the reward is given by the environment. However, we could imagine rewarding the agent for various different behaviors. For instance, we could reward the agent for exploring new states, rather than just when an explicit reward is given. Furthermore, we could mix reward signals to help the learning process. Using `reward_signals` allows you to define [reward signals.](Reward-Signals.md) The ML-Agents toolkit provides three reward signals by default, the Extrinsic (environment) reward signal, the Curiosity reward signal, which can be used to encourage exploration in sparse extrinsic reward environments, and the GAIL reward signal. Please see [Reward Signals](Reward-Signals.md) for additional details. ### Lambda `lambd` corresponds to the `lambda` parameter used when calculating the Generalized Advantage Estimate ([GAE](https://arxiv.org/abs/1506.02438)). This can be thought of as how much the agent relies on its current value estimate when calculating an updated value estimate. Low values correspond to relying more on the current value estimate (which can be high bias), and high values correspond to relying more on the actual rewards received in the environment (which can be high variance). The parameter provides a trade-off between the two, and the right value can lead to a more stable training process. Typical Range: `0.9` - `0.95` ### Buffer Size `buffer_size` corresponds to how many experiences (agent observations, actions and rewards obtained) should be collected before we do any learning or updating of the model. **This should be a multiple of `batch_size`**. Typically a larger `buffer_size` corresponds to more stable training updates. Typical Range: `2048` - `409600` ### Batch Size `batch_size` is the number of experiences used for one iteration of a gradient descent update. **This should always be a fraction of the `buffer_size`**. If you are using a continuous action space, this value should be large (in the order of 1000s). If you are using a discrete action space, this value should be smaller (in order of 10s). Typical Range (Continuous): `512` - `5120` Typical Range (Discrete): `32` - `512` ### Number of Epochs `num_epoch` is the number of passes through the experience buffer during gradient descent. The larger the `batch_size`, the larger it is acceptable to make this. Decreasing this will ensure more stable updates, at the cost of slower learning. Typical Range: `3` - `10` ### Learning Rate `learning_rate` corresponds to the strength of each gradient descent update step. This should typically be decreased if training is unstable, and the reward does not consistently increase. Typical Range: `1e-5` - `1e-3` ### Time Horizon `time_horizon` corresponds to how many steps of experience to collect per-agent before adding it to the experience buffer. When this limit is reached before the end of an episode, a value estimate is used to predict the overall expected reward from the agent's current state. As such, this parameter trades off between a less biased, but higher variance estimate (long time horizon) and more biased, but less varied estimate (short time horizon). In cases where there are frequent rewards within an episode, or episodes are prohibitively large, a smaller number can be more ideal. This number should be large enough to capture all the important behavior within a sequence of an agent's actions. Typical Range: `32` - `2048` ### Max Steps `max_steps` corresponds to how many steps of the simulation (multiplied by frame-skip) are run during the training process. This value should be increased for more complex problems. Typical Range: `5e5` - `1e7` ### Beta `beta` corresponds to the strength of the entropy regularization, which makes the policy "more random." This ensures that agents properly explore the action space during training. Increasing this will ensure more random actions are taken. This should be adjusted such that the entropy (measurable from TensorBoard) slowly decreases alongside increases in reward. If entropy drops too quickly, increase `beta`. If entropy drops too slowly, decrease `beta`. Typical Range: `1e-4` - `1e-2` ### Epsilon `epsilon` corresponds to the acceptable threshold of divergence between the old and new policies during gradient descent updating. Setting this value small will result in more stable updates, but will also slow the training process. Typical Range: `0.1` - `0.3` ### Normalize `normalize` corresponds to whether normalization is applied to the vector observation inputs. This normalization is based on the running average and variance of the vector observation. Normalization can be helpful in cases with complex continuous control problems, but may be harmful with simpler discrete control problems. ### Number of Layers `num_layers` corresponds to how many hidden layers are present after the observation input, or after the CNN encoding of the visual observation. For simple problems, fewer layers are likely to train faster and more efficiently. More layers may be necessary for more complex control problems. Typical range: `1` - `3` ### Hidden Units `hidden_units` correspond to how many units are in each fully connected layer of the neural network. For simple problems where the correct action is a straightforward combination of the observation inputs, this should be small. For problems where the action is a very complex interaction between the observation variables, this should be larger. Typical Range: `32` - `512` ### (Optional) Visual Encoder Type `vis_encode_type` corresponds to the encoder type for encoding visual observations. Valid options include: * `simple` (default): a simple encoder which consists of two convolutional layers * `nature_cnn`: CNN implementation proposed by Mnih et al.(https://www.nature.com/articles/nature14236), consisting of three convolutional layers * `resnet`: IMPALA Resnet implementation (https://arxiv.org/abs/1802.01561), consisting of three stacked layers, each with two residual blocks, making a much larger network than the other two. Options: `simple`, `nature_cnn`, `resnet` ## (Optional) Recurrent Neural Network Hyperparameters The below hyperparameters are only used when `use_recurrent` is set to true. ### Sequence Length `sequence_length` corresponds to the length of the sequences of experience passed through the network during training. This should be long enough to capture whatever information your agent might need to remember over time. For example, if your agent needs to remember the velocity of objects, then this can be a small value. If your agent needs to remember a piece of information given only once at the beginning of an episode, then this should be a larger value. Typical Range: `4` - `128` ### Memory Size `memory_size` corresponds to the size of the array of floating point numbers used to store the hidden state of the recurrent neural network. This value must be a multiple of 4, and should scale with the amount of information you expect the agent will need to remember in order to successfully complete the task. Typical Range: `64` - `512` ## (Optional) Pretraining Using Demonstrations In some cases, you might want to bootstrap the agent's policy using behavior recorded from a player. This can help guide the agent towards the reward. Pretraining adds training operations that mimic a demonstration rather than attempting to maximize reward. It is essentially equivalent to running [behavioral cloning](Training-Behavioral-Cloning.md) in-line with PPO. To use pretraining, add a `pretraining` section to the trainer_config. For instance: ``` pretraining: demo_path: ./demos/ExpertPyramid.demo strength: 0.5 steps: 10000 ``` Below are the avaliable hyperparameters for pretraining. ### Strength `strength` corresponds to the learning rate of the imitation relative to the learning rate of PPO, and roughly corresponds to how strongly we allow the behavioral cloning to influence the policy. Typical Range: `0.1` - `0.5` ### Demo Path `demo_path` is the path to your `.demo` file or directory of `.demo` files. See the [imitation learning guide](Training-Imitation-Learning.md) for more on `.demo` files. ### Steps During pretraining, it is often desirable to stop using demonstrations after the agent has "seen" rewards, and allow it to optimize past the available demonstrations and/or generalize outside of the provided demonstrations. `steps` corresponds to the training steps over which pretraining is active. The learning rate of the pretrainer will anneal over the steps. Set the steps to 0 for constant imitation over the entire training run. ### (Optional) Batch Size `batch_size` is the number of demonstration experiences used for one iteration of a gradient descent update. If not specified, it will default to the `batch_size` defined for PPO. Typical Range (Continuous): `512` - `5120` Typical Range (Discrete): `32` - `512` ### (Optional) Number of Epochs `num_epoch` is the number of passes through the experience buffer during gradient descent. If not specified, it will default to the number of epochs set for PPO. Typical Range: `3` - `10` ### (Optional) Samples Per Update `samples_per_update` is the maximum number of samples to use during each imitation update. You may want to lower this if your demonstration dataset is very large to avoid overfitting the policy on demonstrations. Set to 0 to train over all of the demonstrations at each update step. Default Value: `0` (all) Typical Range: Approximately equal to PPO's `buffer_size` ## Training Statistics To view training statistics, use TensorBoard. For information on launching and using TensorBoard, see [here](./Getting-Started-with-Balance-Ball.md#observing-training-progress). ### Cumulative Reward The general trend in reward should consistently increase over time. Small ups and downs are to be expected. Depending on the complexity of the task, a significant increase in reward may not present itself until millions of steps into the training process. ### Entropy This corresponds to how random the decisions of a Brain are. This should consistently decrease during training. If it decreases too soon or not at all, `beta` should be adjusted (when using discrete action space). ### Learning Rate This will decrease over time on a linear schedule. ### Policy Loss These values will oscillate during training. Generally they should be less than 1.0. ### Value Estimate These values should increase as the cumulative reward increases. They correspond to how much future reward the agent predicts itself receiving at any given point. ### Value Loss These values will increase as the reward increases, and then should decrease once reward becomes stable.