DVM - Design Verification Module

BodePlot() Test Objective

The purpose of the BodePlot() test is to measure the control-loop stability. The input is configured as a DC Input Source, and the output is configured as a special BodePlot Load with a small-signal AC source and a Bode Plot probe. Since the test objective does not specify the input voltage nor the output current, you must provide these values in the Source and Load columns in the testplan.

Both a POP and an AC analysis are used in the BodePlot() test.

The POP and AC analysis directives are taken from the POP tab and the AC tab of the Full Power Assist DVM control symbol. The AC tab is shown below.

The test report includes gain, phase, source, and load graphs as well as the following scalar values which are defined in the Measured Scalar Values section below:

  • Efficiency
  • Power({load_name})
  • Power({source_name})
  • gain_crossover_freq
  • gain_margin
  • min_phase
  • phase_crossover_freq
  • min_phase_freq
  • phase_margin
  • sw_freq

In this Topic Hide

Testplan Syntax

The BodePlot() function has the following syntax with the argument described in the table below:

BodePlot(REF)

Argument Range Description

REF

n/a

The actual reference designator of the DVM Load or the generic syntax of OUTPUT:n where n is an integer indicating a position in the list of managed DVM loads

Source and Load Subcircuit Configuration

The BodePlot() test objective sets the source and load subcircuits to the following:

Source Load

DC Input Source

Bode Plot Load

Loads other than the output under test are set to the Resistive Load. All other sources are set to the DC Input Source.

Measured Scalar Values

The BodePlot() test objective measures the following scalar values:

Scalar Name

Description

Efficiency

The overall efficiency of the converter taken from the POP simulation
Power({load_name) The power of each input source taken from the POP simulation
Power({load_name}) The power of each output load taken from the POP simulation
gain_crossover_freq The frequency where the gain of the control loop is 0dB
gain_margin The gain margin when the phase change in the control loop is 180
min_phase The minimum value for the phase during the AC analysis
phase_crossover_freq The frequency where the phase change in the control loop is 180
min_phase_freq The frequency where the phase is at its minimum value
phase_margin The phase when the gain of the control loop is 0 dB

sw_freq

A number which represents the converter switching frequency

Measured Specification Values

In the following table, {load_name} is the name assigned to each load. The default value is LOAD. DVM forces each load name to be unique so that the scalar and specification values for each load are unique.

Specification Name

PASS/FAIL Criteria

Min_V{load_name}

The minimum value of the output voltage during the simulation time is greater that the minimum specification value.

Max_V{load_name}

The maximum value of the output during the simulation time is less than the maximum specification value.

min_gain_margin

The minimum value of the gain margin during the AC analysis is greater than minimum specification value.

min_phase_margin

The minimum value of the phase margin during the AC analysis is greater than minimum specification value.

Testplan Example

The BodePlot() test objective is used in several built-in testplans. Shown below is a test from the DC/DC 1 input/1 output testplan.  The source and load are defined in the Full Power Assist DVM control symbol. The test configures the source to use the Nominal symbolic value from the Input tab and configures the load based on the Light symbolic value from the Output tab.

*?@ Analysis Objective Source Load Label
Ac BodePlot(OUTPUT:1) SOURCE(INPUT:1, Nominal) LOAD(OUTPUT:1, Light) Ac Analysis|Bode Plot|Vin Nominal|Light Load

Test Report

You can view the complete test report in a new browser window here: BodePlot Test Report. Below is an interactive link to the same test report.

© 2015 simplistechnologies.com | All Rights Reserved