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I am an electronic engineer that perfoms several circuits related to Analog and digital control.

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lazo cerrado haro

bernardo.haro
Designer233532

Member for

4 years 3 months

394

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I am an electronic engineer that perfoms several circuits related to Analog and digital control.

Description

This example shows a VCA driven motion control loop that is acting through an equivalent model of a flexible mechanical structure. This model is shown on the right side of the schematic. It was calibrated to match a physical structure, based purely on its frequency response data and using the HyperLynx complex-pole fitting technology. The original mechanical model can be seen here: https://www.systemvision.com/design/spring-mass-structural-model-and-fitted-equivalent

The top net in this schematic represents the displacement of an ideal position sensor, which provides the actual target position feedback. The loop compensation was designed by using "AC" or frequency-domain analysis of the open loop transfer function. The results are shown in the Magnitude and Phase difference plots (sensor_displacement - feedback). The loop crossover is seen to be at approximately 100 Hz, and the phase margin is just over 44 degrees. The corresponding time-domain step response is shown in the left-most waveform plot.

You can see this same design and analysis using the original mechanical structural model for the "plant" here:

https://www.systemvision.com/design/motion-control-voice-coil-actuator-vca-physical-plant

You can see a more detailed model of this system, that includes the Power Electronics section (i.e. a PWM controlled MOSFET H-Bridge used to drive the VCA), here: https://www.systemvision.com/design/motion-control-vca-pwm-drive

Copy of Motion Control with Voice Coil Actuator (VCA) - CPF Plant - on Wed, 07/01/2020 - 16:26

francisco.eduardo.ortiz
Designer231374

francisco.eduardo.ortiz

Member for

4 years 6 months

designs

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Add a bio to your profile to share information about yourself with other SystemVision users.

Description

This example shows a VCA driven motion control loop that is acting through an equivalent model of a flexible mechanical structure. This model is shown on the right side of the schematic. It was calibrated to match a physical structure, based purely on its frequency response data and using the HyperLynx complex-pole fitting technology. The original mechanical model can be seen here: https://www.systemvision.com/design/spring-mass-structural-model-and-fitted-equivalent

The top net in this schematic represents the displacement of an ideal position sensor, which provides the actual target position feedback. The loop compensation was designed by using "AC" or frequency-domain analysis of the open loop transfer function. The results are shown in the Magnitude and Phase difference plots (sensor_displacement - feedback). The loop crossover is seen to be at approximately 100 Hz, and the phase margin is just over 44 degrees. The corresponding time-domain step response is shown in the left-most waveform plot.

You can see this same design and analysis using the original mechanical structural model for the "plant" here:

https://www.systemvision.com/design/motion-control-voice-coil-actuator-vca-physical-plant

You can see a more detailed model of this system, that includes the Power Electronics section (i.e. a PWM controlled MOSFET H-Bridge used to drive the VCA), here: https://www.systemvision.com/design/motion-control-vca-pwm-drive

Copy of Motion Control with Voice Coil Actuator (VCA) - CPF Plant - on Wed, 07/01/2020 - 16:26

francisco.eduardo.ortiz
Designer231374

francisco.eduardo.ortiz

Member for

4 years 6 months

designs

groups

Add a bio to your profile to share information about yourself with other SystemVision users.

Description

This example shows a VCA driven motion control loop that is acting through an equivalent model of a flexible mechanical structure. This model is shown on the right side of the schematic. It was calibrated to match a physical structure, based purely on its frequency response data and using the HyperLynx complex-pole fitting technology. The original mechanical model can be seen here: https://www.systemvision.com/design/spring-mass-structural-model-and-fitted-equivalent

The top net in this schematic represents the displacement of an ideal position sensor, which provides the actual target position feedback. The loop compensation was designed by using "AC" or frequency-domain analysis of the open loop transfer function. The results are shown in the Magnitude and Phase difference plots (sensor_displacement - feedback). The loop crossover is seen to be at approximately 100 Hz, and the phase margin is just over 44 degrees. The corresponding time-domain step response is shown in the left-most waveform plot.

You can see this same design and analysis using the original mechanical structural model for the "plant" here:

https://www.systemvision.com/design/motion-control-voice-coil-actuator-vca-physical-plant

You can see a more detailed model of this system, that includes the Power Electronics section (i.e. a PWM controlled MOSFET H-Bridge used to drive the VCA), here: https://www.systemvision.com/design/motion-control-vca-pwm-drive

Copy of Motion Control with Voice Coil Actuator (VCA) - CPF Plant - on Wed, 07/01/2020 - 16:26

francisco.eduardo.ortiz
Designer231374

francisco.eduardo.ortiz

Member for

4 years 6 months

designs

groups

Add a bio to your profile to share information about yourself with other SystemVision users.

Description

This example shows a VCA driven motion control loop that is acting through an equivalent model of a flexible mechanical structure. This model is shown on the right side of the schematic. It was calibrated to match a physical structure, based purely on its frequency response data and using the HyperLynx complex-pole fitting technology. The original mechanical model can be seen here: https://www.systemvision.com/design/spring-mass-structural-model-and-fitted-equivalent

The top net in this schematic represents the displacement of an ideal position sensor, which provides the actual target position feedback. The loop compensation was designed by using "AC" or frequency-domain analysis of the open loop transfer function. The results are shown in the Magnitude and Phase difference plots (sensor_displacement - feedback). The loop crossover is seen to be at approximately 100 Hz, and the phase margin is just over 44 degrees. The corresponding time-domain step response is shown in the left-most waveform plot.

You can see this same design and analysis using the original mechanical structural model for the "plant" here:

https://www.systemvision.com/design/motion-control-voice-coil-actuator-vca-physical-plant

You can see a more detailed model of this system, that includes the Power Electronics section (i.e. a PWM controlled MOSFET H-Bridge used to drive the VCA), here: https://www.systemvision.com/design/motion-control-vca-pwm-drive

Copy of Motion Control with Voice Coil Actuator (VCA) - CPF Plant - on Wed, 07/01/2020 - 16:26

francisco.eduardo.ortiz
Designer231374

francisco.eduardo.ortiz

Member for

4 years 6 months

designs

groups

Add a bio to your profile to share information about yourself with other SystemVision users.

Description

This example shows a VCA driven motion control loop that is acting through an equivalent model of a flexible mechanical structure. This model is shown on the right side of the schematic. It was calibrated to match a physical structure, based purely on its frequency response data and using the HyperLynx complex-pole fitting technology. The original mechanical model can be seen here: https://www.systemvision.com/design/spring-mass-structural-model-and-fitted-equivalent

The top net in this schematic represents the displacement of an ideal position sensor, which provides the actual target position feedback. The loop compensation was designed by using "AC" or frequency-domain analysis of the open loop transfer function. The results are shown in the Magnitude and Phase difference plots (sensor_displacement - feedback). The loop crossover is seen to be at approximately 100 Hz, and the phase margin is just over 44 degrees. The corresponding time-domain step response is shown in the left-most waveform plot.

You can see this same design and analysis using the original mechanical structural model for the "plant" here:

https://www.systemvision.com/design/motion-control-voice-coil-actuator-vca-physical-plant

You can see a more detailed model of this system, that includes the Power Electronics section (i.e. a PWM controlled MOSFET H-Bridge used to drive the VCA), here: https://www.systemvision.com/design/motion-control-vca-pwm-drive

Copy of LVDT Position Sensing System - on Fri, 06/05/2020 - 17:06

DeNDroon
Designer216017

DeNDroon

Member for

5 years 6 months

3

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Description

A Linear Variable Differential Transformer (LVDT) and analog signal conditioning circuit are used for a position sensing system. An oscillator provides a sinusoidal excitation signal to the primary winding of the LVDT. The differential secondary winding outputs are rectified and low-pass filtered. The difference voltage, which is proportional to the mechanical displacement of the LVDT core, is the measurement result.

This virtual prototype can be used to select the low pass filter frequency, so it is low enough that the oscillation frequency is mostly removed from the output signal, yet high enough to track the natural frequency of mechanical system the sensor is intended to measure. It can also be used to analyze parasitic effects, such as the resistance of the wires connecting the sensor to the signal conditioning circuits. This resistance affects the output voltage and therefore corrupts the measurement results. Likewise, the non-linear behavior of the rectifier diodes affects the linearity of the position measurement.This can be seen if the force input is slowly ramped from -1000N to 1000N over a 1 second interval.

Copy of Live Solenoid Driver Application of NCV84160 - on Fri, 05/15/2020 - 14:44

MASA
Designer208

MASA

Member for

9 years 9 months

579

designs

8

groups

Description

Copy of Live Solenoid Driver Application of NCV84160 - on Mon, 04/27/2020 - 13:52

瀧澤登
Designer123146

瀧澤登

Member for

7 years 6 months

365

designs

3

groups

Description

Copy of LVDT Position Sensing System - on Sat, 04/25/2020 - 18:32

s.aldalahmeh
Designer231384

s.aldalahmeh

Member for

4 years 6 months

designs

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Add a bio to your profile to share information about yourself with other SystemVision users.

Description

A Linear Variable Differential Transformer (LVDT) and analog signal conditioning circuit are used for a position sensing system. An oscillator provides a sinusoidal excitation signal to the primary winding of the LVDT. The differential secondary winding outputs are rectified and low-pass filtered. The difference voltage, which is proportional to the mechanical displacement of the LVDT core, is the measurement result.

This virtual prototype can be used to select the low pass filter frequency, so it is low enough that the oscillation frequency is mostly removed from the output signal, yet high enough to track the natural frequency of mechanical system the sensor is intended to measure. It can also be used to analyze parasitic effects, such as the resistance of the wires connecting the sensor to the signal conditioning circuits. This resistance affects the output voltage and therefore corrupts the measurement results. Likewise, the non-linear behavior of the rectifier diodes affects the linearity of the position measurement.This can be seen if the force input is slowly ramped from -1000N to 1000N over a 1 second interval.