d3rlpy.dynamics.mopo.MOPO¶
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class
d3rlpy.dynamics.mopo.
MOPO
(n_epochs=30, batch_size=100, learning_rate=0.001, eps=1e-08, weight_decay=0.0001, n_ensembles=5, n_transitions=400, horizon=5, lam=1.0, use_batch_norm=False, discrete_action=False, scaler=None, augmentation=[], use_gpu=False, impl=None, **kwargs)[source]¶ Model-based Offline Policy Optimization.
MOPO is a model-based RL approach for offline policy optimization. MOPO leverages the probablistic ensemble dynamics model to generate new dynamics data with uncertainty penalties.
The ensemble dynamics model consists of \(N\) probablistic models \(\{T_{\theta_i}\}_{i=1}^N\). At each epoch, new transitions are generated via randomly picked dynamics model \(T_\theta\).
\[s_{t+1}, r_{t+1} \sim T_\theta(s_t, a_t)\]where \(s_t \sim D\) for the first step, otherwise \(s_t\) is the previous generated observation, and \(a_t \sim \pi(\cdot|s_t)\). The generated \(r_{t+1}\) would be far from the ground truth if the actions sampled from the policy function is out-of-distribution. Thus, the uncertainty penalty reguralizes this bias.
\[\tilde{r_{t+1}} = r_{t+1} - \lambda \max_{i=1}^N || \Sigma_i (s_t, a_t) ||\]where \(\Sigma(s_t, a_t)\) is the estimated variance.
Finally, the generated transitions \((s_t, a_t, \tilde{r_{t+1}}, s_{t+1})\) are appended to dataset \(D\).
This generation process starts with randomly sampled n_transitions transitions till horizon steps.
Note
Currently, MOPO only supports vector observations.
References
Parameters: - n_epochs (int) – the number of epochs to train.
- batch_size (int) – mini-batch size.
- learning_rate (float) – learning rate for dynamics model.
- eps (float) – \(\epsilon\) for Adam optimizer.
- weight_decay (float) – weight decay rate.
- n_ensembles (int) – the number of dynamics model for ensemble.
- n_transitions (int) – the number of parallel trajectories to generate.
- horizon (int) – the number of steps to generate.
- lam (float) – \(\lambda\) for uncertainty penalties.
- use_batch_norm (bool) – flag to insert batch normalization layers.
- discrete_action (bool) – flag to take discrete actions.
- scaler (d3rlpy.preprocessing.scalers.Scaler or str) – preprocessor. The available options are [‘pixel’, ‘min_max’, ‘standard’].
- augmentation (d3rlpy.augmentation.AugmentationPipeline or list(str)) – augmentation pipeline.
- use_gpu (bool or d3rlpy.gpu.Device) – flag to use GPU or device.
- impl (d3rlpy.dynamics.base.DynamicsImplBase) – dynamics implementation.
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scaler
¶ preprocessor.
Type: d3rlpy.preprocessing.scalers.Scaler
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augmentation
¶ augmentation pipeline.
Type: d3rlpy.augmentation.AugmentationPipeline
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use_gpu
¶ flag to use GPU or device.
Type: d3rlpy.gpu.Device
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impl
¶ dynamics implementation.
Type: d3rlpy.dynamics.base.DynamicsImplBase
Methods
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create_impl
(observation_shape, action_size)[source]¶ Instantiate implementation objects with the dataset shapes.
This method will be used internally when fit method is called.
Parameters:
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fit
(episodes, experiment_name=None, with_timestamp=True, logdir='d3rlpy_logs', verbose=True, show_progress=True, tensorboard=True, eval_episodes=None, save_interval=1, scorers=None)¶ Trains with the given dataset.
algo.fit(episodes)
Parameters: - episodes (list(d3rlpy.dataset.Episode)) – list of episodes to train.
- experiment_name (str) – experiment name for logging. If not passed, the directory name will be {class name}_{timestamp}.
- with_timestamp (bool) – flag to add timestamp string to the last of directory name.
- logdir (str) – root directory name to save logs.
- verbose (bool) – flag to show logged information on stdout.
- show_progress (bool) – flag to show progress bar for iterations.
- tensorboard (bool) – flag to save logged information in tensorboard (additional to the csv data)
- eval_episodes (list(d3rlpy.dataset.Episode)) – list of episodes to test.
- save_interval (int) – interval to save parameters.
- scorers (list(callable)) – list of scorer functions used with eval_episodes.
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classmethod
from_json
(fname, use_gpu=False)¶ Returns algorithm configured with json file.
The Json file should be the one saved during fitting.
from d3rlpy.algos import Algo # create algorithm with saved configuration algo = Algo.from_json('d3rlpy_logs/<path-to-json>/params.json') # ready to load algo.load_model('d3rlpy_logs/<path-to-model>/model_100.pt') # ready to predict algo.predict(...)
Parameters: Returns: algorithm.
Return type: d3rlpy.base.LearnableBase
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generate
(algo, transitions)¶ Returns new transitions for data augmentation.
Parameters: - algo (d3rlpy.algos.base.AlgoBase) – algorithm.
- transitions (list(d3rlpy.dataset.Transition)) – list of transitions.
Returns: list of generated transitions.
Return type:
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get_params
(deep=True)¶ Returns the all attributes.
This method returns the all attributes including ones in subclasses. Some of scikit-learn utilities will use this method.
params = algo.get_params(deep=True) # the returned values can be used to instantiate the new object. algo2 = AlgoBase(**params)
Parameters: deep (bool) – flag to deeply copy objects such as impl. Returns: attribute values in dictionary. Return type: dict
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load_model
(fname)¶ Load neural network parameters.
algo.load_model('model.pt')
Parameters: fname (str) – source file path.
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predict
(x, action, with_variance=False)¶ Returns predicted observation and reward.
Parameters: - x (numpy.ndarray) – observation
- action (numpy.ndarray) – action
- with_variance (bool) – flag to return prediction variance.
Returns: tuple of predicted observation and reward.
Return type:
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save_model
(fname)¶ Saves neural network parameters.
algo.save_model('model.pt')
Parameters: fname (str) – destination file path.
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set_params
(**params)¶ Sets the given arguments to the attributes if they exist.
This method sets the given values to the attributes including ones in subclasses. If the values that don’t exist as attributes are passed, they are ignored. Some of scikit-learn utilities will use this method.
algo.set_params(n_epochs=10, batch_size=100)
Parameters: **params – arbitrary inputs to set as attributes. Returns: itself. Return type: d3rlpy.algos.base.AlgoBase