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  • SimHydraulics

    SimHydraulics® provides component libraries for modeling and simulating hydraulic systems. It includes models of hydraulic components, such as pumps, valves, actuators, pipelines, and hydraulic resistances. You can use these components to model fluid power systems such as front-loader, power steering, and landing gear actuation systems. Fuel supply and water supply systems can also be modeled using SimHydraulics. SimHydraulics models can be used to develop control systems and test system-level performance. You can parameterize your models using MATLAB® variables and expressions, and design control systems for your hydraulic system in Simulink®. You can add electrical, mechanical, pneumatic, and other components to your hydraulic model using Simscape™ and test them in a single simulation environment. To deploy models to other simulation environments, including hardware-in-the-loop (HIL) systems, SimHydraulics supports C-code generation.

    • Usage:
      AcademicEducationalCommercial⁄ProfessionalClassroomResearch
    • License type:
      StandaloneNetwork
    • Organisational Unit: Vice Rector for Science - Latvia, Rīga
    • Price: Contract price
  • SimMechanics

    SimMechanics™ provides a multibody simulation environment for 3D mechanical systems, such as robots, vehicle suspensions, construction equipment, and aircraft landing gear. You model the multibody system using blocks representing bodies, joints, constraints, and force elements, and then SimMechanics formulates and solves the equations of motion for the complete mechanical system. Models from CAD systems, including mass, inertia, joint, constraint, and 3D geometry, can be imported into SimMechanics. An automatically generated 3D animation lets you visualize the system dynamics. You can parameterize your models using MATLAB® variables and expressions, and design control systems for your multibody system in Simulink®. You can add electrical, hydraulic, pneumatic, and other components to your mechanical model using Simscape™ and test them all in a single simulation environment. To deploy your models to other simulation environments, including hardware-in-the-loop (HIL) systems, SimMechanics supports C-code generation (with Simulink Coder™).

    • Usage:
      AcademicEducationalCommercial⁄ProfessionalClassroomResearch
    • License type:
      StandaloneNetwork
    • Organisational Unit: Vice Rector for Science - Latvia, Rīga
    • Price: Contract price
  • SimPowerSystems

    SimPowerSystems™ provides component libraries and analysis tools for modeling and simulating electrical power systems. The libraries offer models of electrical power components, including three-phase machines, electric drives, and components for applications such as flexible AC transmission systems (FACTS) and renewable energy systems. Harmonic analysis, calculation of total harmonic distortion (THD), load flow, and other key electrical power system analyses are automated. SimPowerSystems models can be used to develop control systems and test system-level performance. You can parameterize your models using MATLAB® variables and expressions, and design control systems for your electrical power system in Simulink®. You can add mechanical, hydraulic, pneumatic, and other components to the model using Simscape™ and test them together in a single simulation environment. To deploy models to other simulation environments, including hardware-in-the-loop (HIL) systems, SimPowerSystems supports C-code generation.

    • Usage:
      AcademicEducationalCommercial⁄ProfessionalClassroomResearch
    • License type:
      StandaloneNetwork
    • Organisational Unit: Vice Rector for Science - Latvia, Rīga
    • Price: Contract price
  • SimRF

    SimRF™ provides a component library and simulation engine for designing RF systems. It includes amplifiers, mixers, S-parameter blocks, and other basic blocks for designing architectures for wireless transceivers used in communication and radar systems. You can connect these blocks arbitrarily to form diverse architectures and to simulate the behavior of the RF front-end at the system level. SimRF lets you simulate RF amplifiers to estimate gain, noise, even-order, and odd-order intermodulation distortion. The simulation of mixers enables you to predict image rejection, reciprocal mixing, local oscillator phase offsets, and DC conversion. You can also simulate frequency-dependent mismatches between linear and nonlinear components in the time and frequency domains. With SimRF you can model RF systems at different levels of abstraction. The circuit envelope solver enables high-fidelity, multicarrier simulation of networks with arbitrary topologies. The Equivalent Baseband library enables fast, discrete-time simulation of single-carrier cascaded systems.

    • Usage:
      AcademicEducationalCommercial⁄ProfessionalClassroomResearch
    • License type:
      StandaloneNetwork
    • Organisational Unit: Vice Rector for Science - Latvia, Rīga
    • Price: Contract price
  • Simscape

    Simscape™ provides an environment for modeling and simulating physical systems spanning mechanical, electrical, hydraulic, and other physical domains. It provides fundamental building blocks from these domains that you can assemble into models of physical components, such as electric motors, inverting op-amps, hydraulic valves, and ratchet mechanisms. Because Simscape components use physical connections, your models match the structure of the system you are developing. Simscape models can be used to develop control systems and test system-level performance. You can extend the libraries using the MATLAB® based Simscape language, which enables text-based authoring of physical modeling components, domains, and libraries. You can parameterize your models using MATLAB variables and expressions, and design control systems for your physical system in Simulink®. To deploy your models to other simulation environments, including hardware-in-the-loop (HIL) systems, Simscape supports C-code generation.

    • Usage:
      AcademicEducationalCommercial⁄ProfessionalClassroomResearch
    • License type:
      StandaloneNetwork
    • Organisational Unit: Vice Rector for Science - Latvia, Rīga
    • Price: Contract price
  • Simulink

    Simulink® is a block diagram environment for multidomain simulation and Model-Based Design. It supports simulation, automatic code generation, and continuous test and verification of embedded systems. Simulink provides a graphical editor, customizable block libraries, and solvers for modeling and simulating dynamic systems. It is integrated with MATLAB®, enabling you to incorporate MATLAB algorithms into models and export simulation results to MATLAB for further analysis.

    • Usage:
      AcademicEducationalCommercial⁄ProfessionalClassroomResearch
    • License type:
      StandaloneNetwork
    • Organisational Unit: Vice Rector for Science - Latvia, Rīga
    • Price: Contract price
  • Simulink 3D Animation

    Simulink 3D Animation™ provides apps for linking Simulink® models and MATLAB® algorithms to 3D graphics objects. It lets you visualize and verify dynamic system behavior in a virtual reality environment. Objects are represented in the Virtual Reality Modeling Language (VRML), a standard 3D modeling language. You can animate a 3D world by changing position, rotation, scale, and other object properties during desktop or real-time simulation. You can also inject virtual sensor signals and access 3D animation data in Simulink or MATLAB for postprocessing. Simulink 3D Animation includes viewers for rendering and interacting with virtual scenes. With the 3D World Editor, you can author detailed scenes assembled from 3D models exported from CAD-based or web-based sources. You can incorporate multiple 3D scene views inside MATLAB figures and interact with these views via a force-feedback joystick, space mouse, or other hardware device.

    • Usage:
      AcademicEducationalCommercial⁄ProfessionalClassroomResearch
    • License type:
      StandaloneNetwork
    • Organisational Unit: Vice Rector for Science - Latvia, Rīga
    • Price: Contract price
  • Simulink Coder

    Simulink Coder™ (formerly Real-Time Workshop®) generates and executes C and C++ code from Simulink® diagrams, Stateflow® charts, and MATLAB® functions. The generated source code can be used for real-time and nonreal-time applications, including simulation acceleration, rapid prototyping, and hardware-in-the-loop testing. You can tune and monitor the generated code using Simulink or run and interact with the code outside MATLAB and Simulink.

    • Usage:
      AcademicEducationalCommercial⁄ProfessionalClassroomResearch
    • License type:
      StandaloneNetwork
    • Organisational Unit: Vice Rector for Science - Latvia, Rīga
    • Price: Contract price
  • Simulink Control Design

    Simulink Control Design™ lets you design and analyze plants and control systems modeled in Simulink® and automatically tune PID controller gains to meet performance requirements You can also find operating points and compute exact linearizations of Simulink models at various operating conditions. Simulink Control Design provides tools that let you compute simulation-based frequency responses without modifying your model. A graphical interface lets you design and analyze arbitrary control structures modeled in Simulink, including cascaded, prefilter, regulation, and multiloop architectures.

    • Usage:
      AcademicEducationalCommercial⁄ProfessionalClassroomResearch
    • License type:
      StandaloneNetwork
    • Organisational Unit: Vice Rector for Science - Latvia, Rīga
    • Price: Contract price
  • Simulink Fixed Point

    Simulink Fixed Point enables the fixed-point capabilities of the Simulink product family, letting you use those products to design, simulate, and implement fixed-point control and signal processing algorithms. With Simulink Fixed Point, you specify fixed-point data attributes, including word length and scaling for signals and parameters, in your model. You can perform bit-true simulations to observe the effects of limited range and precision on designs built with Simulink, Stateflow, DSP System Toolbox™, and other Simulink products. Automated fixed-point advisors guide you through the steps of converting floating-point models to fixed point. Additional tools analyze your model or use simulation results to recommend data types and scaling. Simulink Fixed Point supports C, HDL, and PLC code generation with Simulink code-generation products.

    • Usage:
      AcademicEducationalCommercial⁄ProfessionalClassroomResearch
    • License type:
      StandaloneNetwork
    • Organisational Unit: Vice Rector for Science - Latvia, Rīga
    • Price: Contract price
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