matlab_23550/Inu/xilinx_wrapper/adc_sim.c

#include "adc_sim.h"

AdcSimHandle AdcSim;


void Simulate_ADC(SimStruct* S)
{
	real_T* IN = ssGetInputPortRealSignal(S, 0);

	adcMeasure(&AdcSim.Measure, IN, 0);

	adcConvert(&AdcSim.convertion, &AdcSim.udc1, AdcSim.Measure.udc1, 0);
	adcConvert(&AdcSim.convertion, &AdcSim.udc2, AdcSim.Measure.udc2, 0);
	adcConvert(&AdcSim.convertion, &AdcSim.ia1, AdcSim.Measure.ia1, 0);
	adcConvert(&AdcSim.convertion, &AdcSim.ib1, AdcSim.Measure.ib1, 0);
	adcConvert(&AdcSim.convertion, &AdcSim.ic1, AdcSim.Measure.ic1, 0);
	adcConvert(&AdcSim.convertion, &AdcSim.ia2, AdcSim.Measure.ia2, 0);
	adcConvert(&AdcSim.convertion, &AdcSim.ib2, AdcSim.Measure.ib2, 0);
	adcConvert(&AdcSim.convertion, &AdcSim.ic2, AdcSim.Measure.ic2, 0);
}

void Init_ADC_Simulation()
{
	adcInitConvertion(&AdcSim.convertion, NORMA_ACP, 2.5, 4096);
	adcInitMeasure(&AdcSim.udc1, K_LEM_ADC[0], R_ADC[0], DEFAULT_ZERO_ADC);
	adcInitMeasure(&AdcSim.udc2, K_LEM_ADC[1], R_ADC[1], DEFAULT_ZERO_ADC);
	adcInitMeasure(&AdcSim.ia1, K_LEM_ADC[2], R_ADC[2], DEFAULT_ZERO_ADC);
	adcInitMeasure(&AdcSim.ib1, K_LEM_ADC[3], R_ADC[3], DEFAULT_ZERO_ADC);
	adcInitMeasure(&AdcSim.ic1, K_LEM_ADC[4], R_ADC[4], DEFAULT_ZERO_ADC);
	adcInitMeasure(&AdcSim.ia2, K_LEM_ADC[5], R_ADC[5], DEFAULT_ZERO_ADC);
	adcInitMeasure(&AdcSim.ib2, K_LEM_ADC[6], R_ADC[6], DEFAULT_ZERO_ADC);
	adcInitMeasure(&AdcSim.ic2, K_LEM_ADC[7], R_ADC[7], DEFAULT_ZERO_ADC);

}

void adcInitConvertion(AdcConvertionHandle* hconv, int norma_adc, double adc_amplitude, int adc_bit_depth)
{
	hconv->norma_adc		= norma_adc;
	hconv->adc_amplitude	= adc_amplitude;
	hconv->adc_bit_depth	= adc_bit_depth;
}

void adcInitMeasure(AdcMeasureHandle* hmeasure, int k_lem_adc, int r_adc, int offset)
{
	hmeasure->k_lem_adc = k_lem_adc;
	hmeasure->r_adc		= r_adc;
	hmeasure->offset	= offset;
}

void adcMeasure(AdcRealMeasureHandle *hrmeasure, const real_T* u, int startind)
{
	hrmeasure->udc1 = u[startind++];
	hrmeasure->udc2 = u[startind++];
	hrmeasure->ia1 = u[startind++];
	hrmeasure->ib1 = u[startind++];
	hrmeasure->ic1 = u[startind++];
	hrmeasure->ia2 = u[startind++];
	hrmeasure->ib2 = u[startind++];
	hrmeasure->ic2 = u[startind++];
}

void adcConvert(AdcConvertionHandle* hconv, AdcMeasureHandle* hmeasure, double realMeasure, double MeasureSatur)
{
	if (MeasureSatur != 0)
	{
		if (realMeasure > MeasureSatur)
			realMeasure = MeasureSatur;
		else if (realMeasure < -MeasureSatur)
			realMeasure = -MeasureSatur;
	}
	// AdcMirror.ADCRESULT0 = (unsigned short)(realMeasure/MeasureSatur*2048. + (float)offset.Udc1);
	hmeasure->adc_val =
		(unsigned short)(realMeasure / hmeasure->k_lem_adc * hmeasure->r_adc / hconv->norma_adc / hconv->adc_amplitude * hconv->adc_bit_depth + (float)hmeasure->offset);
}
заготовка для симуляции АЦП 2025-01-15 11:49:27 +03:00			`#include "adc_sim.h"`

#5 Работает и векторное и скалярное Видимо была проблема в измерениях с двигателя, они принимались непонятно в каком формате. Сейчас сделан модуль АЦП, который все правильно преобразует 2025-01-20 10:45:47 +03:00			`AdcSimHandle AdcSim;`


			`void Simulate_ADC(SimStruct* S)`
			`{`
			`real_T* IN = ssGetInputPortRealSignal(S, 0);`

			`adcMeasure(&AdcSim.Measure, IN, 0);`

			`adcConvert(&AdcSim.convertion, &AdcSim.udc1, AdcSim.Measure.udc1, 0);`
			`adcConvert(&AdcSim.convertion, &AdcSim.udc2, AdcSim.Measure.udc2, 0);`
			`adcConvert(&AdcSim.convertion, &AdcSim.ia1, AdcSim.Measure.ia1, 0);`
			`adcConvert(&AdcSim.convertion, &AdcSim.ib1, AdcSim.Measure.ib1, 0);`
			`adcConvert(&AdcSim.convertion, &AdcSim.ic1, AdcSim.Measure.ic1, 0);`
			`adcConvert(&AdcSim.convertion, &AdcSim.ia2, AdcSim.Measure.ia2, 0);`
			`adcConvert(&AdcSim.convertion, &AdcSim.ib2, AdcSim.Measure.ib2, 0);`
			`adcConvert(&AdcSim.convertion, &AdcSim.ic2, AdcSim.Measure.ic2, 0);`
			`}`

			`void Init_ADC_Simulation()`
			`{`
			`adcInitConvertion(&AdcSim.convertion, NORMA_ACP, 2.5, 4096);`
			`adcInitMeasure(&AdcSim.udc1, K_LEM_ADC[0], R_ADC[0], DEFAULT_ZERO_ADC);`
			`adcInitMeasure(&AdcSim.udc2, K_LEM_ADC[1], R_ADC[1], DEFAULT_ZERO_ADC);`
			`adcInitMeasure(&AdcSim.ia1, K_LEM_ADC[2], R_ADC[2], DEFAULT_ZERO_ADC);`
			`adcInitMeasure(&AdcSim.ib1, K_LEM_ADC[3], R_ADC[3], DEFAULT_ZERO_ADC);`
			`adcInitMeasure(&AdcSim.ic1, K_LEM_ADC[4], R_ADC[4], DEFAULT_ZERO_ADC);`
			`adcInitMeasure(&AdcSim.ia2, K_LEM_ADC[5], R_ADC[5], DEFAULT_ZERO_ADC);`
			`adcInitMeasure(&AdcSim.ib2, K_LEM_ADC[6], R_ADC[6], DEFAULT_ZERO_ADC);`
			`adcInitMeasure(&AdcSim.ic2, K_LEM_ADC[7], R_ADC[7], DEFAULT_ZERO_ADC);`

			`}`

			`void adcInitConvertion(AdcConvertionHandle* hconv, int norma_adc, double adc_amplitude, int adc_bit_depth)`
			`{`
			`hconv->norma_adc = norma_adc;`
			`hconv->adc_amplitude = adc_amplitude;`
			`hconv->adc_bit_depth = adc_bit_depth;`
			`}`

			`void adcInitMeasure(AdcMeasureHandle* hmeasure, int k_lem_adc, int r_adc, int offset)`
			`{`
			`hmeasure->k_lem_adc = k_lem_adc;`
			`hmeasure->r_adc = r_adc;`
			`hmeasure->offset = offset;`
			`}`

			`void adcMeasure(AdcRealMeasureHandle hrmeasure, const real_T u, int startind)`
			`{`
			`hrmeasure->udc1 = u[startind++];`
			`hrmeasure->udc2 = u[startind++];`
			`hrmeasure->ia1 = u[startind++];`
			`hrmeasure->ib1 = u[startind++];`
			`hrmeasure->ic1 = u[startind++];`
			`hrmeasure->ia2 = u[startind++];`
			`hrmeasure->ib2 = u[startind++];`
			`hrmeasure->ic2 = u[startind++];`
			`}`

			`void adcConvert(AdcConvertionHandle* hconv, AdcMeasureHandle* hmeasure, double realMeasure, double MeasureSatur)`
			`{`
			`if (MeasureSatur != 0)`
			`{`
			`if (realMeasure > MeasureSatur)`
			`realMeasure = MeasureSatur;`
			`else if (realMeasure < -MeasureSatur)`
			`realMeasure = -MeasureSatur;`
			`}`
			`// AdcMirror.ADCRESULT0 = (unsigned short)(realMeasure/MeasureSatur*2048. + (float)offset.Udc1);`
			`hmeasure->adc_val =`
			`(unsigned short)(realMeasure / hmeasure->k_lem_adc * hmeasure->r_adc / hconv->norma_adc / hconv->adc_amplitude * hconv->adc_bit_depth + (float)hmeasure->offset);`
			`}`