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pwm signal generation  (MathWorks Inc)


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    Structured Review

    MathWorks Inc pwm signal generation
    <t>SIMULINK</t> schematic to generate <t>PWM</t> signal for a given control signal to drive the associated DC motor.
    Pwm Signal Generation, supplied by MathWorks Inc, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
    https://www.bioz.com/result/pwm signal generation/product/MathWorks Inc
    Average 90 stars, based on 1 article reviews
    pwm signal generation - by Bioz Stars, 2026-04
    90/100 stars

    Images

    1) Product Images from "Multi-Scale Robotics: A Numerical Investigation on Mobile Micro-Tweezers for Micro-Manipulation with Extreme Requirements"

    Article Title: Multi-Scale Robotics: A Numerical Investigation on Mobile Micro-Tweezers for Micro-Manipulation with Extreme Requirements

    Journal: Micromachines

    doi: 10.3390/mi16010040

    SIMULINK schematic to generate PWM signal for a given control signal to drive the associated DC motor.
    Figure Legend Snippet: SIMULINK schematic to generate PWM signal for a given control signal to drive the associated DC motor.

    Techniques Used: Control

    PWM signals on the third degree-of-freedom for the control tasks in this study: ( a ) PWM signals before (in blue) and after (in red) the direction of motion was altered; ( b ) PWM signal while dragging the vortex core with a relatively greater velocity reference.
    Figure Legend Snippet: PWM signals on the third degree-of-freedom for the control tasks in this study: ( a ) PWM signals before (in blue) and after (in red) the direction of motion was altered; ( b ) PWM signal while dragging the vortex core with a relatively greater velocity reference.

    Techniques Used: Control

    Reaction to a sudden change in direction of velocity reference before and after the change in direction occurs, in blue and in red, respectively: ( a ) tracking error calculated for the vortex core on the XY-plane; ( b ) computed control signal comparison for traverse on the XY-plane with an inset for the second velocity reference (in red); ( c ) motor currents for traverse on the XY-plane; ( d ) amplified PWM signal and motor current for the third degree-of-freedom; ( e ) magnetic field density felt by the vortex; ( f ) Brownian noise for the bacterium.
    Figure Legend Snippet: Reaction to a sudden change in direction of velocity reference before and after the change in direction occurs, in blue and in red, respectively: ( a ) tracking error calculated for the vortex core on the XY-plane; ( b ) computed control signal comparison for traverse on the XY-plane with an inset for the second velocity reference (in red); ( c ) motor currents for traverse on the XY-plane; ( d ) amplified PWM signal and motor current for the third degree-of-freedom; ( e ) magnetic field density felt by the vortex; ( f ) Brownian noise for the bacterium.

    Techniques Used: Control, Comparison, Amplification

    Reaction to constant and comparatively violent pull by the magnetic field: ( a ) error in tracking calculated for the vortex core on the XY-plane; ( b ) computed control signal comparison for traverse on the XY-plane ( c ) motor currents for traverse on the XY-plane; ( d ) amplified PWM signal and motor current for the third degree-of-freedom; ( e ) magnetic field density felt by the vortex; ( f ) Brownian noise on the bacterium.
    Figure Legend Snippet: Reaction to constant and comparatively violent pull by the magnetic field: ( a ) error in tracking calculated for the vortex core on the XY-plane; ( b ) computed control signal comparison for traverse on the XY-plane ( c ) motor currents for traverse on the XY-plane; ( d ) amplified PWM signal and motor current for the third degree-of-freedom; ( e ) magnetic field density felt by the vortex; ( f ) Brownian noise on the bacterium.

    Techniques Used: Control, Comparison, Amplification



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    Image Search Results


    SIMULINK schematic to generate PWM signal for a given control signal to drive the associated DC motor.

    Journal: Micromachines

    Article Title: Multi-Scale Robotics: A Numerical Investigation on Mobile Micro-Tweezers for Micro-Manipulation with Extreme Requirements

    doi: 10.3390/mi16010040

    Figure Lengend Snippet: SIMULINK schematic to generate PWM signal for a given control signal to drive the associated DC motor.

    Article Snippet: The control signal is used to generate the necessary pulse-width-modulation (PWM) signal with correct voltage amplification to attain the nominal voltage supply determined by the manufacturer, i.e., 48 V. Please see for the PWM signal generation in the SIMULINK environment and a,b for PWM signals without amplification.

    Techniques: Control

    PWM signals on the third degree-of-freedom for the control tasks in this study: ( a ) PWM signals before (in blue) and after (in red) the direction of motion was altered; ( b ) PWM signal while dragging the vortex core with a relatively greater velocity reference.

    Journal: Micromachines

    Article Title: Multi-Scale Robotics: A Numerical Investigation on Mobile Micro-Tweezers for Micro-Manipulation with Extreme Requirements

    doi: 10.3390/mi16010040

    Figure Lengend Snippet: PWM signals on the third degree-of-freedom for the control tasks in this study: ( a ) PWM signals before (in blue) and after (in red) the direction of motion was altered; ( b ) PWM signal while dragging the vortex core with a relatively greater velocity reference.

    Article Snippet: The control signal is used to generate the necessary pulse-width-modulation (PWM) signal with correct voltage amplification to attain the nominal voltage supply determined by the manufacturer, i.e., 48 V. Please see for the PWM signal generation in the SIMULINK environment and a,b for PWM signals without amplification.

    Techniques: Control

    Reaction to a sudden change in direction of velocity reference before and after the change in direction occurs, in blue and in red, respectively: ( a ) tracking error calculated for the vortex core on the XY-plane; ( b ) computed control signal comparison for traverse on the XY-plane with an inset for the second velocity reference (in red); ( c ) motor currents for traverse on the XY-plane; ( d ) amplified PWM signal and motor current for the third degree-of-freedom; ( e ) magnetic field density felt by the vortex; ( f ) Brownian noise for the bacterium.

    Journal: Micromachines

    Article Title: Multi-Scale Robotics: A Numerical Investigation on Mobile Micro-Tweezers for Micro-Manipulation with Extreme Requirements

    doi: 10.3390/mi16010040

    Figure Lengend Snippet: Reaction to a sudden change in direction of velocity reference before and after the change in direction occurs, in blue and in red, respectively: ( a ) tracking error calculated for the vortex core on the XY-plane; ( b ) computed control signal comparison for traverse on the XY-plane with an inset for the second velocity reference (in red); ( c ) motor currents for traverse on the XY-plane; ( d ) amplified PWM signal and motor current for the third degree-of-freedom; ( e ) magnetic field density felt by the vortex; ( f ) Brownian noise for the bacterium.

    Article Snippet: The control signal is used to generate the necessary pulse-width-modulation (PWM) signal with correct voltage amplification to attain the nominal voltage supply determined by the manufacturer, i.e., 48 V. Please see for the PWM signal generation in the SIMULINK environment and a,b for PWM signals without amplification.

    Techniques: Control, Comparison, Amplification

    Reaction to constant and comparatively violent pull by the magnetic field: ( a ) error in tracking calculated for the vortex core on the XY-plane; ( b ) computed control signal comparison for traverse on the XY-plane ( c ) motor currents for traverse on the XY-plane; ( d ) amplified PWM signal and motor current for the third degree-of-freedom; ( e ) magnetic field density felt by the vortex; ( f ) Brownian noise on the bacterium.

    Journal: Micromachines

    Article Title: Multi-Scale Robotics: A Numerical Investigation on Mobile Micro-Tweezers for Micro-Manipulation with Extreme Requirements

    doi: 10.3390/mi16010040

    Figure Lengend Snippet: Reaction to constant and comparatively violent pull by the magnetic field: ( a ) error in tracking calculated for the vortex core on the XY-plane; ( b ) computed control signal comparison for traverse on the XY-plane ( c ) motor currents for traverse on the XY-plane; ( d ) amplified PWM signal and motor current for the third degree-of-freedom; ( e ) magnetic field density felt by the vortex; ( f ) Brownian noise on the bacterium.

    Article Snippet: The control signal is used to generate the necessary pulse-width-modulation (PWM) signal with correct voltage amplification to attain the nominal voltage supply determined by the manufacturer, i.e., 48 V. Please see for the PWM signal generation in the SIMULINK environment and a,b for PWM signals without amplification.

    Techniques: Control, Comparison, Amplification