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Alphabetical List
By Category

Ideal Force Sensor | Force sensor in mechanical translational systems |

Ideal Rotational Motion Sensor | Motion sensor in mechanical rotational systems |

Ideal Torque Sensor | Torque sensor in mechanical rotational systems |

Ideal Translational Motion Sensor | Motion sensor in mechanical translational systems |

Ideal Angular Velocity Source | Ideal angular velocity source in mechanical rotational systems |

Ideal Force Source | Ideal source of mechanical energy that generates force proportional to the input signal |

Ideal Torque Source | Ideal source of mechanical energy that generates torque proportional to the input signal |

Ideal Translational Velocity Source | Ideal velocity source in mechanical translational systems |

Gear Box | Gear box in mechanical systems |

Lever | Generic mechanical lever |

Wheel and Axle | Wheel and axle mechanism in mechanical systems |

Inertia | Ideal mechanical rotational inertia |

Mechanical Rotational Reference | Reference connection for mechanical rotational ports |

Rotational Damper | Viscous damper in mechanical rotational systems |

Rotational Free End | Rotational port terminator with zero torque |

Rotational Friction | Friction in contact between rotating bodies |

Rotational Hard Stop | Double-sided rotational hard stop |

Rotational Inerter | Two-port inertia in mechanical rotational systems |

Rotational Spring | Ideal spring in mechanical rotational systems |

Mass | Ideal mechanical translational mass |

Mechanical Translational Reference | Reference connection for mechanical translational ports |

Translational Damper | Viscous damper in mechanical translational systems |

Translational Free End | Translational port terminator with zero force |

Translational Friction | Friction in contact between moving bodies |

Translational Hard Stop | Double-sided translational hard stop |

Translational Inerter | Two-port inertia in mechanical translational systems |

Translational Spring | Ideal spring in mechanical translational systems |

Capacitor | Linear capacitor in electrical systems |

Diode | Piecewise linear diode in electrical systems |

Electrical Reference | Connection to electrical ground |

Gyrator | Ideal gyrator in electrical systems |

Ideal Transformer | Ideal transformer in electrical systems |

Inductor | Linear inductor in electrical systems |

Infinite Resistance | Electrical element for setting initial voltage difference between two nodes |

Memristor | Ideal memristor with nonlinear dopant drift approach |

Mutual Inductor | Mutual inductor in electrical systems |

Op-Amp | Ideal operational amplifier |

Open Circuit | Electrical port terminator that draws no current |

Resistor | Linear resistor in electrical systems |

Rotational Electromechanical Converter | Interface between electrical and mechanical rotational domains |

Switch | Switch controlled by external physical signal |

Thermal Resistor | Resistor with thermal port |

Translational Electromechanical Converter | Interface between electrical and mechanical translational domains |

Variable Resistor | Linear variable resistor in electrical systems |

Current Sensor | Current sensor in electrical systems |

Voltage Sensor | Voltage sensor in electrical systems |

AC Current Source | Ideal sinusoidal current source |

AC Voltage Source | Ideal constant voltage source |

Controlled Current Source | Ideal current source driven by input signal |

Controlled Voltage Source | Ideal voltage source driven by input signal |

Current-Controlled Current Source | Linear current-controlled current source |

Current-Controlled Voltage Source | Linear current-controlled voltage source |

DC Current Source | Ideal constant current source |

DC Voltage Source | Ideal constant voltage source |

Voltage-Controlled Current Source | Linear voltage-controlled current source |

Voltage-Controlled Voltage Source | Linear voltage-controlled voltage source |

Electromagnetic Converter | Lossless electromagnetic energy conversion device |

Fundamental Reluctance | Simplified implementation of magnetic reluctance |

Magnetic Reference | Reference connection for magnetic ports |

Reluctance | Magnetic reluctance |

Reluctance Force Actuator | Magnetomotive device based on reluctance force |

Variable Reluctance | Variable reluctance in electromagnetic systems |

Flux Sensor | Ideal flux sensor |

MMF Sensor | Ideal magnetomotive force sensor |

Controlled Flux Source | Ideal flux source driven by input signal |

Controlled MMF Source | Ideal magnetomotive force source driven by input signal |

Flux Source | Ideal flux source |

MMF Source | Ideal magnetomotive force source |

Constant Area Hydraulic Orifice | Hydraulic orifice with constant cross-sectional area |

Constant Volume Hydraulic Chamber | Hydraulic capacity of constant volume |

Fluid Inertia | Pressure differential across tube or channel due to change in fluid velocity |

Hydraulic Cap | Hydraulic port terminator with zero flow |

Hydraulic Piston Chamber | Variable volume hydraulic capacity in cylinders |

Hydraulic Reference | Connection to atmospheric pressure |

Hydraulic Resistive Tube | Hydraulic pipeline which accounts for friction losses only |

Infinite Hydraulic Resistance | Hydraulic element for setting initial pressure difference between two nodes |

Linear Hydraulic Resistance | Hydraulic pipeline with linear resistance losses |

Rotational Hydro-Mechanical Converter | Interface between hydraulic and mechanical rotational domains |

Translational Hydro-Mechanical Converter | Interface between hydraulic and mechanical translational domains |

Variable Area Hydraulic Orifice | Hydraulic variable orifice created by cylindrical spool and sleeve |

Variable Hydraulic Chamber | Hydraulic capacity of variable volume with compressible fluid |

Hydraulic Flow Rate Sensor | Ideal flow meter |

Hydraulic Pressure Sensor | Ideal pressure sensing device |

Hydraulic Constant Flow Rate Source | Ideal source of hydraulic energy, characterized by constant flow rate |

Hydraulic Constant Mass Flow Rate Source | Ideal source of mechanical energy in hydraulic network, characterized by constant mass flow rate |

Hydraulic Constant Pressure Source | Ideal source of hydraulic energy, characterized by constant pressure |

Hydraulic Flow Rate Source | Ideal source of hydraulic energy, characterized by flow rate |

Hydraulic Mass Flow Rate Source | Ideal source of mechanical energy in hydraulic network, characterized by mass flow rate |

Hydraulic Pressure Source | Ideal source of hydraulic energy, characterized by pressure |

Custom Hydraulic Fluid | Working fluid properties, set by specifying parameter values |

Absolute Reference (TL) | Reference point at zero absolute temperature and pressure |

Cap (TL) | Perfectly insulated stop to fluid flow |

Constant Volume Chamber (TL) | Rigid chamber with constant volume of thermal liquid |

Controlled Reservoir (TL) | Thermal liquid reservoir at time-varying temperature |

Infinite Flow Resistance (TL) | Perfectly insulated barrier between thermal liquid networks |

Local Restriction (TL) | Time-invariant reduction in flow area |

Pipe (TL) | Rigid conduit for fluid flow in thermal liquid systems |

Reservoir (TL) | Thermal liquid reservoir at constant temperature and pressure |

Rotational Mechanical Converter (TL) | Interface between thermal liquid and mechanical rotational networks |

Translational Mechanical Converter (TL) | Interface between thermal liquid and mechanical translational networks |

Variable Local Restriction (TL) | Time-varying reduction in flow area |

Mass & Energy Flow Rate Sensor (TL) | Measure mass and energy flow rates |

Pressure & Temperature Sensor (TL) | Measure pressure and temperature differences |

Thermodynamic Properties Sensor (TL) | Measure specific internal energy, density, and specific heat at constant pressure |

Volumetric Flow Rate Sensor (TL) | Measure volumetric flow rate |

Controlled Mass Flow Rate Source (TL) | Generate time-varying mass flow rate |

Controlled Pressure Source (TL) | Generate time-varying pressure differential |

Controlled Volumetric Flow Rate Source (TL) | Generate time-varying volumetric flow rate |

Mass Flow Rate Source (TL) | Generate constant mass flow rate |

Pressure Source (TL) | Generate constant pressure differential |

Volumetric Flow Rate Source (TL) | Generate constant volumetric flow rate |

Thermal Liquid Settings (TL) | Fluid properties in thermal liquid network |

Absolute Reference (2P) | Reference point at zero absolute pressure and specific internal energy |

Cap (2P) | Perfectly insulated stop to fluid flow |

Constant Volume Chamber (2P) | Rigid chamber with constant volume of two-phase fluid |

Infinite Flow Resistance (2P) | Perfectly insulated barrier between two-phase fluid networks |

Local Restriction (2P) | Fixed flow resistance |

Pipe (2P) | Rigid conduit for fluid flow in two-phase fluid systems |

Reservoir (2P) | Two-phase fluid reservoir at constant temperature and pressure |

Rotational Mechanical Converter (2P) | Interface between two-phase fluid and mechanical rotational networks |

Translational Mechanical Converter (2P) | Interface between two-phase fluid and mechanical translational networks |

Variable Local Restriction (2P) | Time-varying flow resistance |

Mass & Energy Flow Rate Sensor (2P) | Measure mass and energy flow rates |

Pressure & Internal Energy Sensor (2P) | Measure pressure and specific internal energy differences |

Thermodynamic Properties Sensor (2P) | Measure temperature, specific enthalpy, specific volume, and vapor quality |

Volumetric Flow Rate Sensor (2P) | Measure volumetric flow rate |

Controlled Mass Flow Rate Source (2P) | Generate time-varying mass flow rate |

Controlled Pressure Source (2P) | Generate time-varying pressure differential |

Controlled Volumetric Flow Rate Source (2P) | Generate time-varying volumetric flow rate |

Mass Flow Rate Source (2P) | Generate constant mass flow rate |

Pressure Source (2P) | Generate constant pressure differential |

Volumetric Flow Rate Source (2P) | Generate constant volumetric flow rate |

Two-Phase Fluid Properties (2P) | Fluid properties in two-phase fluid network |

Absolute Reference (G) | Reference point at zero absolute temperature and pressure |

Cap (G) | Gas port terminator with zero flow |

Constant Volume Chamber (G) | Rigid chamber with constant volume of gas |

Controlled Reservoir (G) | Boundary conditions for gas network at time-varying pressure and temperature |

Infinite Flow Resistance (G) | Perfectly insulated barrier between gas networks |

Local Restriction (G) | Fixed restriction in flow area |

Pipe (G) | Rigid conduit for gas flow |

Reservoir (G) | Boundary conditions for gas network at constant pressure and temperature |

Rotational Mechanical Converter (G) | Interface between gas and mechanical rotational networks |

Translational Mechanical Converter (G) | Interface between gas and mechanical translational networks |

Variable Local Restriction (G) | Time-varying restriction in flow area |

Mass & Energy Flow Rate Sensor (G) | Measure mass and energy flow rates |

Pressure & Temperature Sensor (G) | Measure pressure and temperature differences |

Thermodynamic Properties Sensor (G) | Measure specific enthalpy, density, specific heat at constant pressure, and specific entropy |

Controlled Mass Flow Rate Source (G) | Generate time-varying mass flow rate |

Controlled Pressure Source (G) | Generate time-varying pressure differential |

Mass Flow Rate Source (G) | Generate constant mass flow rate |

Pressure Source (G) | Generate constant pressure differential |

Gas Properties (G) | Global gas properties for attached circuit |

Conductive Heat Transfer | Heat transfer by conduction |

Convective Heat Transfer | Heat transfer by convection |

Infinite Thermal Resistance | Thermal element for setting initial temperature difference between two nodes |

Perfect Insulator | Thermal element with perfect insulation and no thermal mass |

Radiative Heat Transfer | Heat transfer by radiation |

Thermal Mass | Mass in thermal systems |

Thermal Reference | Reference connection for thermal ports |

Ideal Heat Flow Sensor | Ideal heat flow meter |

Ideal Temperature Sensor | Ideal temperature sensor |

Ideal Heat Flow Source | Ideal source of thermal energy, characterized by heat flow |

Ideal Temperature Source | Ideal source of thermal energy, characterized by temperature |

PS Constant Delay | Delay input physical signal by specified time |

PS Variable Delay | Delay input physical signal by variable time |

Asynchronous Sample & Hold | Output sample-and-hold signal with external trigger |

PS Add | Add two physical signal inputs |

PS Divide | Compute simple division of two input physical signals |

PS Gain | Multiply input physical signal by constant |

PS Math Function | Apply mathematical function to input physical signal |

PS Product | Multiply two physical signal inputs |

PS Subtract | Compute simple subtraction of two input physical signals |

PS Integrator | Integrate physical signal |

PS Lookup Table (1D) | Approximate one-dimensional function using specified lookup method |

PS Lookup Table (2D) | Approximate two-dimensional function using specified lookup method |

PS Lookup Table (3D) | Approximate three-dimensional function using specified lookup method |

PS Lookup Table (4D) | Approximate four-dimensional function using specified lookup method |

PS Abs | Output absolute value of input physical signal |

PS Ceil | Output the smallest integer larger than or equal to input physical signal |

PS Dead Zone | Provide region of zero output for physical signals |

PS Fix | Round input physical signal toward zero |

PS Floor | Output the largest integer smaller than or equal to input physical signal |

PS Max | Output maximum of two input physical signals |

PS Min | Output minimum of two input physical signals |

PS Round | Round input physical signal toward nearest integer |

PS Saturation | Limit range of physical signal |

PS Sign | Output sign of input physical signal |

PS Switch | Single-pole double-throw switch controlled by external physical signal |

PS Constant Offset Estimator | Measure constant offset value of periodic signal |

PS Harmonic Estimator (Amplitude, Phase) | Measure harmonic amplitude and phase of periodic signal |

PS Harmonic Estimator (Real, Imaginary) | Measure real and imaginary parts of periodic signal harmonic |

PS RMS Estimator | Measure RMS value of periodic signal |

PS Terminator | Terminator for unconnected physical signal outputs |

Counter | Increment output signal by 1 with every time step |

PS Constant | Generate constant physical signal |

Random Number | Generate normally distributed random numbers for physical modeling |

Repeating Sequence | Output periodic piecewise linear signal |

Uniform Random Number | Generate uniformly distributed random numbers for physical modeling |

Connection Port | Physical Modeling connector port for subsystem |

PS-Simulink Converter | Convert physical signal into Simulink output signal |

Simulink-PS Converter | Convert Simulink input signal into physical signal |

Solver Configuration | Physical Networks environment and solver configuration |

Spectrum Analyzer | Display frequency spectrum of time-domain signals |

Simscape Component | Deploy Simscape language component as custom block in model diagram |

Simscape Component | Deploy Simscape language component as custom block in model diagram |

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