Control System Toolbox

Design and analyze control systems

Control System Toolbox provides algorithms and apps for systematically analyzing, designing, and tuning linear control systems. You can specify your system as a transfer function, state-space, zero-pole-gain, or frequency-response model. Apps and functions, such as step response plot and Bode plot, let you analyze and visualize system behavior in the time and frequency domains.

You can tune compensator parameters using interactive techniques such as Bode loop shaping and the root locus method. The toolbox automatically tunes both SISO and MIMO compensators, including PID controllers. Compensators can include multiple tunable blocks spanning several feedback loops. You can tune gain-scheduled controllers and specify multiple tuning objectives, such as reference tracking, disturbance rejection, and stability margins. You can validate your design by verifying rise time, overshoot, settling time, gain and phase margins, and other requirements.

What Is Control System Toolbox?

Discover new features in the release notes.

Dynamic System Modeling

Create linear models of your control system as transfer functions, (sparse) state-space models, LPV and LTV models, and other representations. Discretize and resample models. Simplify analysis and control design by reducing model order.

Documentation | Examples

Linear Analysis

Visualize system behavior in the time and frequency domain. Compute system characteristics such as rise time, overshoot, and settling time. Analyze system stability by computing gain and phase margins and crossover frequencies.

Documentation | Examples

PID Tuning

Automatically tune PID controller gains to balance performance and robustness using the PID Tuner app or command-line functions. Tune continuous or discrete controllers and 2-DOF PID controllers.

Documentation | Examples

Compensator Design

Interactively design and analyze single-input, single-output (SISO) controllers with the Control System Designer app, using automated tuning methods. Graphically tune common control components using root locus, Bode diagrams, and Nichols charts.

Documentation | Examples

State Estimation and State-Space Control Design

Use state-space control design methods, such as LQR/LQG and pole-placement algorithms. Estimate system states using observers, including linear and nonlinear Kalman filters.

Documentation | Examples

Multiloop, Multiobjective Tuning

Automatically tune arbitrary SISO and MIMO decentralized control structures modeled in MATLAB or Simulink to satisfy time and frequency-domain design requirements using the Control System Tuner app.

Documentation | Examples

Gain Scheduling

Design gain-scheduled controllers for nonlinear or time-varying plants. Specify requirements and automatically tune gain surface coefficients. Validate the tuning results across the entire operating range of your design.

Documentation | Examples

Control Design in Simulink

Analyze and tune control systems modeled in Simulink and analyze its time and frequency domain characteristics using Simulink Control Design. Linearize Simulink models and compute time and frequency responses. Graphically or automatically tune feedback loops modeled in Simulink.

Documentation | Examples

Gallery of images showing the HL-20 space plane’s model in Simulink, tuned gain surface coefficients, and reference tracking performance comparisons.

Reference Applications

Use reference application examples for flight control, power electronics, robotics, and other applications to design and analyze controllers for systems modeled in MATLAB and Simulink.

Documentation | Examples

Product Resources:

Documentation Examples Videos Technical articles Functions Blocks Requirements Release notes

WOM Reduces Time-to-Market for Surgical Device Control Software with Model-Based Design

“Simulink enabled us to produce a stable control system in a short time. We modeled the entire system, including a state machine and cascaded PI controls. We refined this model to improve robustness and response times, then verified it with RCP, and generated embedded code.”
René Pätznick, WOM

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