rlACAgent

Create an environment and obtain its observation and action specifications. For this example, load the environment used in the example Create DQN Agent Using Deep Network Designer and Train Using Image Observations. This environment has two observations: a 50-by-50 grayscale image and a scalar (the angular velocity of the pendulum). The action is a scalar with five possible elements (a torque of -2, -1, 0, 1, or 2 Nm applied to a swinging pole).

env = rlPredefinedEnv("SimplePendulumWithImage-Discrete");

Obtain observation and action specifications.

obsInfo = getObservationInfo(env);
actInfo = getActionInfo(env);

The agent creation function initializes the actor and critic networks randomly. Ensure reproducibility by fixing the seed of the random generator.

rng(0)

Create an actor-critic agent from the environment observation and action specifications. Since actInfo is an rlFiniteSetSpec object, rlPGAgent creates an agent with a discrete action space. When actInfo is an rlNumericSpec object, rlPGAgent creates an agent with a continuous action space.

agent = rlACAgent(obsInfo,actInfo);

To check your agent, use getAction to return the action from random observations.

getAction(agent,{rand(obsInfo(1).Dimension),rand(obsInfo(2).Dimension)})

ans = 1x1 cell array
    {[-2]}

You can now test and train the agent within the environment. You can also use getActor and getCritic to extract the actor and critic, respectively, and getModel to extract the approximator model (by default a deep neural network) from the actor or critic.

Create an environment and obtain its observation and action specifications. For this example, load the environment used in the example Train DDPG Agent to Swing Up and Balance Pendulum with Image Observation. This environment has two observations: a 50-by-50 grayscale image and a scalar (the angular velocity of the pendulum). The action is a scalar representing a torque ranging continuously from -2 to 2 Nm.

% Load predefined environment
env = rlPredefinedEnv("SimplePendulumWithImage-Continuous");

% Obtain observation and action specifications
obsInfo = getObservationInfo(env);
actInfo = getActionInfo(env);

Create an agent initialization option object, specifying that each hidden fully connected layer in the network must have 128 neurons (instead of the default number, 256).

initOpts = rlAgentInitializationOptions(NumHiddenUnit=128);

The agent creation function initializes the actor and critic networks randomly. You can ensure reproducibility by fixing the seed of the random generator.

rng(0)

Create an actor-critic agent from the environment observation and action specifications. Since actInfo is an rlNumericSpec object, rlACAgent creates an agent with a continuous action space. When actInfo is an rlFiniteSetSpec object, rlACAgent creates an agent with a discrete action space.

agent = rlACAgent(obsInfo,actInfo,initOpts);

Extract the deep neural networks from both the agent actor and critic.

actorNet = getModel(getActor(agent));
criticNet = getModel(getCritic(agent));

To verify that each hidden fully connected layer has 128 neurons, you can display the layers on the MATLAB® command window,

criticNet.Layers

or visualize the structure interactively using analyzeNetwork.

analyzeNetwork(criticNet)

Plot actor and critic networks

plot(actorNet)

plot(criticNet)

To check your agent, use getAction to return the action from a random observation.

getAction(agent,{rand(obsInfo(1).Dimension),rand(obsInfo(2).Dimension)})

ans = 1x1 cell array
    {[0.9228]}

You can now test and train the agent within the environment.

Create an environment with a discrete action space and obtain its observation and action specifications. For this example, load the environment used in the example Train DQN Agent to Balance Discrete Cart-Pole System. This environment has a four-dimensional observation vector (cart position and velocity, pole angle, and pole angle derivative), and a scalar action with two possible elements (a force of either -10 or +10 N applied on the cart).

env = rlPredefinedEnv("CartPole-Discrete");

Obtain observation and action specifications.

obsInfo = getObservationInfo(env)

obsInfo = 
  rlNumericSpec with properties:

     LowerLimit: -Inf
     UpperLimit: Inf
           Name: "CartPole States"
    Description: "x, dx, theta, dtheta"
      Dimension: [4 1]
       DataType: "double"

actInfo = getActionInfo(env)

actInfo = 
  rlFiniteSetSpec with properties:

       Elements: [-10 10]
           Name: "CartPole Action"
    Description: [0x0 string]
      Dimension: [1 1]
       DataType: "double"

The agent creation function initializes the actor and critic networks randomly. You can ensure reproducibility by fixing the seed of the random generator.

rng(0)

Actor-critic agents use a parametrized value function approximator to estimate the value of the policy. A value-function critic takes the current observation as input and returns a single scalar as output (the estimated discounted cumulative long-term reward for following the policy from the state corresponding to the current observation).

To model the parametrized value function within the critic, use a neural network with one input layer (which receives the content of the observation channel, as specified by obsInfo) and one output layer (which returns the scalar value). Note that prod(obsInfo.Dimension) returns the total number of dimensions of the observation space regardless of whether the observation space is a column vector, row vector, or matrix.

Define the network as an array of layer objects, and get the dimension of the observation space from the environment specification objects.

criticNet = [
    featureInputLayer(prod(obsInfo.Dimension))
    fullyConnectedLayer(50)
    reluLayer
    fullyConnectedLayer(1)
    ];

Convert the network to a dlnetwork object, and display the number of weights.

criticNet = dlnetwork(criticNet);
summary(criticNet)

   Initialized: true

   Number of learnables: 301

   Inputs:
      1   'input'   4 features

Create the critic approximator object using criticNet and the observation specification. For more information on value function approximators, see rlValueFunction.

critic = rlValueFunction(criticNet,obsInfo);

Check your critic with a random observation input.

getValue(critic,{rand(obsInfo.Dimension)})

ans = single

-0.1411

Actor-critic agents use a parametrized stochastic policy, which for discrete action spaces is implemented by a discrete categorical actor. This actor takes an observation as input and returns as output a random action sampled (among the finite number of possible actions) from a categorical probability distribution.

To model the parametrized policy within the actor, use a neural network with one input layer (which receives the content of the observation channel, as specified by obsInfo) and one output layer. The output layer must return a vector of probabilities for each possible action, as specified by actInfo. Note that numel(actInfo.Dimension) returns the number of elements of the discrete action space.

Define the network as an array of layer objects.

actorNet = [
    featureInputLayer(prod(obsInfo.Dimension))
    fullyConnectedLayer(16)
    reluLayer
    fullyConnectedLayer(16)
    reluLayer
    fullyConnectedLayer(numel(actInfo.Dimension))
    ];

Convert the network to a dlnetwork object, and display the number of weights.

actorNet = dlnetwork(actorNet);
summary(actorNet)

   Initialized: true

   Number of learnables: 386

   Inputs:
      1   'input'   4 features

Create the actor using actorNet and the observation and action specifications. For more information on discrete categorical actors, see rlDiscreteCategoricalActor.

actor = rlDiscreteCategoricalActor(actorNet,obsInfo,actInfo);

Check your actor with a random observation input.

getAction(actor,{rand(obsInfo.Dimension)})

ans = 1x1 cell array
    {[10]}

Create the AC agent using the actor and the critic.

agent = rlACAgent(actor,critic)

agent = 
  rlACAgent with properties:

            AgentOptions: [1x1 rl.option.rlACAgentOptions]
    UseExplorationPolicy: 1
         ObservationInfo: [1x1 rl.util.rlNumericSpec]
              ActionInfo: [1x1 rl.util.rlFiniteSetSpec]
              SampleTime: 1

Specify some options for the agent, including training options for the actor and critic.

agent.AgentOptions.NumStepsToLookAhead=32;
agent.AgentOptions.DiscountFactor=0.99;
agent.AgentOptions.CriticOptimizerOptions.LearnRate=8e-3;
agent.AgentOptions.CriticOptimizerOptions.GradientThreshold=1;
agent.AgentOptions.ActorOptimizerOptions.LearnRate=8e-3;
agent.AgentOptions.ActorOptimizerOptions.GradientThreshold=1;

Check your agent with a random observation.

getAction(agent,{rand(obsInfo.Dimension)})

ans = 1x1 cell array
    {[-10]}

You can now test and train the agent within the environment.

Create an environment with a continuous action space, and obtain its observation and action specifications. For this example, load the double integrator continuous action space environment used in the example Compare DDPG Agent to LQR Controller.

env = rlPredefinedEnv("DoubleIntegrator-Continuous");

Obtain observation and action specifications.

obsInfo = getObservationInfo(env)

obsInfo = 
  rlNumericSpec with properties:

     LowerLimit: -Inf
     UpperLimit: Inf
           Name: "states"
    Description: "x, dx"
      Dimension: [2 1]
       DataType: "double"

actInfo = getActionInfo(env)

actInfo = 
  rlNumericSpec with properties:

     LowerLimit: -Inf
     UpperLimit: Inf
           Name: "force"
    Description: [0x0 string]
      Dimension: [1 1]
       DataType: "double"

In this example, the action is a scalar value representing a force ranging from -2 to 2 Newton. To make sure that the output from the agent is in this range, you perform an appropriate scaling operation. Store these limits so you can easily access them later.

% Make sure action space upper and lower limits are finite
actInfo.LowerLimit=-2;
actInfo.UpperLimit=2;

The actor and critic networks are initialized randomly. You can ensure reproducibility by fixing the seed of the random generator.

rng(0)

Actor-critic agents use a parametrized value function approximator to estimate the value of the policy. A value-function critic takes the current observation as input and returns a single scalar as output (the estimated discounted cumulative long-term reward for following the policy from the state corresponding to the current observation).

To model the parametrized value function within the critic, use a neural network with one input layer (which receives the content of the observation channel, as specified by obsInfo) and one output layer (which returns the scalar value). Note that prod(obsInfo.Dimension) returns the total number of dimensions of the observation space regardless of whether the observation space is a column vector, row vector, or matrix.

Define the network as an array of layer objects.

criticNet = [
    featureInputLayer(prod(obsInfo.Dimension))
    fullyConnectedLayer(20)
    reluLayer
    fullyConnectedLayer(20)
    reluLayer
    fullyConnectedLayer(1)
    ];

Convert the network to a dlnetwork object, initialize it, and display the number of weights.

criticNet = dlnetwork(criticNet);
criticNet = initialize(criticNet);
summary(criticNet)

   Initialized: true

   Number of learnables: 501

   Inputs:
      1   'input'   2 features

Create the critic approximator object using criticNet and the observation specification. For more information on value function approximators, see rlValueFunction.

critic = rlValueFunction(criticNet,obsInfo);

Check your critic with a random input observation.

getValue(critic,{rand(obsInfo.Dimension)})

ans = single

-0.0311

Actor-critic agents use a parametrized stochastic policy, which for continuous action spaces is implemented by a continuous Gaussian actor. This actor takes an observation as input and returns as output a random action sampled from a Gaussian probability distribution.

To approximate the mean values and standard deviations of the Gaussian distribution, you must use a neural network with two output layers, each having as many elements as the dimension of the action space. One output layer must return a vector containing the mean values for each action dimension. The other must return a vector containing the standard deviation for each action dimension.

Note that standard deviations must be nonnegative and mean values must fall within the range of the action. Therefore the output layer that returns the standard deviations must be a softplus or ReLU layer, to enforce nonnegativity, while the output layer that returns the mean values must be a scaling layer, to scale the mean values to the output range.

For this example the environment has only one observation channel and therefore the network has only one input layer.

Define each network path as an array of layer objects, and assign names to the input and output layers of each path. These names allow you to connect the paths and then later explicitly associate the network input and output layers with the appropriate environment channel.

% Input path
inPath = [ 
    featureInputLayer(prod(obsInfo.Dimension),Name="obsInLyr")
    fullyConnectedLayer(prod(actInfo.Dimension),Name="infc") 
    ];

% Mean value path
meanPath = [ 
    tanhLayer(Name="tanhMean");
    fullyConnectedLayer(50)
    reluLayer
    fullyConnectedLayer(prod(actInfo.Dimension));
    scalingLayer( ...
    Name="meanOutLyr", ...
    Scale=actInfo.UpperLimit)  % scale to range
    ];

% Standard deviation path
sdevPath = [ 
    tanhLayer(Name="tanhStdv");
    fullyConnectedLayer(50)
    reluLayer
    fullyConnectedLayer(prod(actInfo.Dimension));
    softplusLayer(Name="stdOutLyr")  % nonnegative
    ];

Assemble dlnetwork object.

actorNet = dlnetwork;
actorNet = addLayers(actorNet,inPath);
actorNet = addLayers(actorNet,meanPath);
actorNet = addLayers(actorNet,sdevPath);

Connect layers.

actorNet = connectLayers(actorNet,"infc","tanhMean/in");
actorNet = connectLayers(actorNet,"infc","tanhStdv/in");

Plot network.

plot(actorNet)

Initialize network and display the number of learnable parameters (weights).

actorNet = initialize(actorNet);
summary(actorNet)

   Initialized: true

   Number of learnables: 305

   Inputs:
      1   'obsInLyr'   2 features

Create the actor approximator object using actorNet and the environment specifications. For more information, on continuous Gaussian actors, see rlContinuousGaussianActor.

actor = rlContinuousGaussianActor(actorNet, obsInfo, actInfo, ...
    ActionMeanOutputNames="meanOutLyr",...
    ActionStandardDeviationOutputNames="stdOutLyr",...
    ObservationInputNames="obsInLyr");

Check your actor with a random input observation.

getAction(actor,{rand(obsInfo.Dimension)})

ans = 1x1 cell array
    {[0.0815]}

Create the AC agent using the actor and the critic.

agent = rlACAgent(actor,critic)

agent = 
  rlACAgent with properties:

            AgentOptions: [1x1 rl.option.rlACAgentOptions]
    UseExplorationPolicy: 1
         ObservationInfo: [1x1 rl.util.rlNumericSpec]
              ActionInfo: [1x1 rl.util.rlNumericSpec]
              SampleTime: 1

Specify agent options, including training options for its actor and critic.

agent.AgentOptions.NumStepsToLookAhead = 32;
agent.AgentOptions.DiscountFactor=0.99;

agent.AgentOptions.CriticOptimizerOptions.LearnRate=8e-3;
agent.AgentOptions.CriticOptimizerOptions.GradientThreshold=1;

agent.AgentOptions.ActorOptimizerOptions.LearnRate=8e-3;
agent.AgentOptions.ActorOptimizerOptions.GradientThreshold=1;

Check your agent using a random input observation.

getAction(agent,{rand(obsInfo.Dimension)})

ans = 1x1 cell array
    {[-0.8032]}

You can now test and train the agent within the environment.

For this example load the predefined environment used for the Train DQN Agent to Balance Discrete Cart-Pole System example. This environment has a four-dimensional observation vector (cart position and velocity, pole angle, and pole angle derivative), and a scalar action with two possible elements (a force of either -10 or +10 N applied on the cart).

env = rlPredefinedEnv("CartPole-Discrete");

Get observation and action information.

obsInfo = getObservationInfo(env);
actInfo = getActionInfo(env);

The agent creation function initializes the actor and critic networks randomly. Ensure reproducibility by fixing the seed of the random generator.

rng(0)

To model the parametrized value function within the critic, use a recurrent neural network, which must have one input layer (which receives the content of the observation channel, as specified by obsInfo) and one output layer (which returns the scalar value).

Define the network as an array of layer objects. To create a recurrent network, use a sequenceInputLayer as the input layer and include at least one lstmLayer.

criticNet = [
    sequenceInputLayer(prod(obsInfo.Dimension))
    lstmLayer(10)
    reluLayer
    fullyConnectedLayer(1)
    ];

Convert the network to a dlnetwork object and display the number of learnable parameters (weights).

criticNet = dlnetwork(criticNet);
summary(criticNet)

   Initialized: true

   Number of learnables: 611

   Inputs:
      1   'sequenceinput'   Sequence input with 4 dimensions

Create the critic approximator object using criticNet and the observation specification. For more information on value function approximators, see rlValueFunction.

critic = rlValueFunction(criticNet,obsInfo);

Check the critic with a random input observation.

getValue(critic,{rand(obsInfo.Dimension)})

ans = single

-0.0344

Since the critic has a recurrent network, the (discrete categorical) actor must also use a recurrent network. The network must have one input layer (which receives the content of the environment observation channel, as specified by obsInfo) and one output layer (which must return a vector of probabilities for each possible action, as specified by actInfo).

Define the recurrent network as an array of layer objects.

actorNet = [
    sequenceInputLayer(prod(obsInfo.Dimension))
    lstmLayer(20)
    reluLayer
    fullyConnectedLayer(numel(actInfo.Elements))
    ];

Convert the network to a dlnetwork object and display the number of weights.

actorNet = dlnetwork(actorNet);
summary(actorNet)

   Initialized: true

   Number of learnables: 2k

   Inputs:
      1   'sequenceinput'   Sequence input with 4 dimensions

Create the actor using actorNet and the observation and action specifications. For more information on discrete categorical actors, see rlDiscreteCategoricalActor.

actor = rlDiscreteCategoricalActor(actorNet,obsInfo,actInfo);

Check the actor with a random input observation.

getAction(actor,{rand(obsInfo.Dimension)})

ans = 1x1 cell array
    {[10]}

Set some training options for the critic.

criticOpts = rlOptimizerOptions( ...
    LearnRate=8e-3,GradientThreshold=1);

Set some training options for the actor.

actorOpts = rlOptimizerOptions( ...
    LearnRate=8e-3,GradientThreshold=1);

Specify training options for the agent, and include actorOpts and criticOpts. Since the agent uses recurrent neural networks, NumStepsToLookAhead is treated as the training trajectory length.

agentOpts = rlACAgentOptions( ...
    NumStepsToLookAhead=32, ...
    DiscountFactor=0.99, ...
    CriticOptimizerOptions=criticOpts, ...
    ActorOptimizerOptions=actorOpts);

Create an AC agent using the actor, the critic, and the agent options object.

agent = rlACAgent(actor,critic,agentOpts)

agent = 
  rlACAgent with properties:

            AgentOptions: [1x1 rl.option.rlACAgentOptions]
    UseExplorationPolicy: 1
         ObservationInfo: [1x1 rl.util.rlNumericSpec]
              ActionInfo: [1x1 rl.util.rlFiniteSetSpec]
              SampleTime: 1

To check your agent, return the action from a random observation.

getAction(agent,{rand(obsInfo.Dimension)})

ans = 1x1 cell array
    {[10]}

To evaluate the agent using sequential observations, use the sequence length (time) dimension. For example, obtain actions for a sequence of 9 observations.

[action,state] = getAction(agent, ...
    {rand([obsInfo.Dimension 1 9])});

Display the action corresponding to the seventh element of the observation.

action = action{1};
action(1,1,1,7)

ans = 
-10

You can now test and train the agent within the environment.

To train an agent using the asynchronous advantage actor-critic (A3C) method, you must set the agent and parallel training options appropriately.

When creating the AC agent, set the NumStepsToLookAhead value to be greater than 1. Common values are 64 and 128.

agentOpts = rlACAgentOptions(NumStepsToLookAhead=64);

Use agentOpts when creating your agent. Alternatively, create your agent first and then modify its options, including the actor and critic options later using dot notation.

Configure the training algorithm to use asynchronous parallel training.

trainOpts = rlTrainingOptions(UseParallel=true);
trainOpts.ParallelizationOptions.Mode = "async";

You can now use trainOpts to train your AC agent using the A3C method.

For an example on asynchronous advantage actor-critic agent training, see Train AC Agent to Balance Discrete Cart-Pole System Using Parallel Computing.