Videos

  • Model and simulate fluid systems.
  • Design hydraulic systems using SimHydraulics ® . Example applications include a hydraulic actuator and a fuel supply system.
  • Model a hydraulic actuation system. A double-acting hydraulic cylinder controlled by a four-way directional valve is modeled using Simscape Fluids™.
  • Model a hydraulic actuation system. A double-acting hydraulic cylinder controlled by a four-way directional valve is modeled using Simscape Fluids™.
  • Model a custom hydraulic servovalve with flapper and spool dynamics using Simscape Fluids™. Configure model to include or neglect hydraulic forces on the spool.
  • Model a fuel supply system. Scripts are used to automatically evaluate system performance under different flight conditions as components fail.
  • Model a custom hydraulic orifice. Simscape™ extensions to MATLAB ® are used to define implicit equations.
  • Automatically tune parameters until simulation results match measurement data. Optimization algorithms are used to obtain realistic parameter values for a Simscape Fluids™ model.
  • Detect system integration issues in simulation. Mechanical, hydraulic, electrical, and control systems are gradually integrated into a full system model.
  • Automatically log all simulation data from the physical system to the MATLAB ® workspace. Explore data using Simscape™ Results Explorer.
  • Use the Simulink ® Solver Profiler to find the causes for slow simulations. Plots and tables showing solver behavior during simulation help identify modeling issues.
  • Run simulations in parallel on a multicore desktop. Parameter values for an aileron control system are tested in multiple simulations executed simultaneously.
  • Optimize a hydromechanical actuation system to meet system requirements. Parameters in a Simscape Fluids™ model are automatically tuned using optimization algorithms.
  • Automatically tune hydraulic valve parameters to match flow rate characteristics on manufacturer’s data sheets using optimization algorithms.
  • Automatically tune hydraulic valve parameters to match transient response characteristics on manufacturer’s data sheets using optimization algorithms.
  • Automatically tune hydraulic valve parameters to match frequency response characteristics on manufacturer’s data sheets using optimization algorithms.
  • Configure multiple, independent solvers to enable real-time simulation. The model of a hydraulic aileron actuation system is simulated on a real-time target.
  • Convert a hydraulic lift model to C code and simulate in a hardware-in-the-loop configuration. Simscape™ parameters are tuned on the real-time target.
  • Convert a backhoe model to C code and simulate in a hardware-in-the-loop configuration. Simscape™ parameters are tuned on the real-time target.
  • Configure Simscape™ local solvers on your physical networks to enable real-time simulation. The computations per time step are minimized while maintaining accuracy.
  • Configure multiple, independent solvers to enable real-time simulation. The model of a hydromechanical pitch control system is simulated on a real-time target.
  • Use HIL testing instead of hardware prototypes to test control algorithms. Convert physical model to C code and simulate in real time on controller hardware.
  • Share models without requiring licenses for Simscape™ add-on libraries. Open models in Restricted Mode and perform tasks such as simulation, parameter tests, and code generation.
  • Share Simscape™ language source code without exposing your intellectual property. The protected components can be used for simulation and parameter testing.
  • Share physical models without exposing intellectual property. The protected subsystems can be used for simulation and parameter testing.