DSP_Lib/Examples/arm_signal_converge_example/ARM/arm_signal_converge_example_f32.c - third_party/github/STMicroelectronics/cmsis_core - Git at Google

 /* ----------------------------------------------------------------------
 * Copyright (C) 2010-2012 ARM Limited. All rights reserved.
 *
 * $Date:         17. January 2013
 * $Revision:     V1.4.0
 *
 * Project:       CMSIS DSP Library
 * Title:         arm_signal_converge_example_f32.c
 *
 * Description:   Example code demonstrating convergence of an adaptive
 *                filter.
 *
 * Target Processor: Cortex-M4/Cortex-M3
 *
 * Redistribution and use in source and binary forms, with or without
 * modification, are permitted provided that the following conditions
 * are met:
 *   - Redistributions of source code must retain the above copyright
 *     notice, this list of conditions and the following disclaimer.
 *   - Redistributions in binary form must reproduce the above copyright
 *     notice, this list of conditions and the following disclaimer in
 *     the documentation and/or other materials provided with the
 *     distribution.
 *   - Neither the name of ARM LIMITED nor the names of its contributors
 *     may be used to endorse or promote products derived from this
 *     software without specific prior written permission.
 *
 * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
 * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
 * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
 * FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE
 * COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT,
 * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING,
 * BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
 * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER
 * CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
 * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN
 * ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
 * POSSIBILITY OF SUCH DAMAGE.
  * -------------------------------------------------------------------- */

 /**
  * @ingroup groupExamples
  */

 /**
  * @defgroup SignalConvergence Signal Convergence Example
  *
  * \par Description:
  * \par
  * Demonstrates the ability of an adaptive filter to "learn" the transfer function of
  * a FIR lowpass filter using the Normalized LMS Filter, Finite Impulse
  * Response (FIR) Filter, and Basic Math Functions.
  *
  * \par Algorithm:
  * \par
  * The figure below illustrates the signal flow in this example. Uniformly distributed white
  * noise is passed through an FIR lowpass filter. The output of the FIR filter serves as the
  * reference input of the adaptive filter (normalized LMS filter). The white noise is input
  * to the adaptive filter. The adaptive filter learns the transfer function of the FIR filter.
  * The filter outputs two signals: (1) the output of the internal adaptive FIR filter, and
  * (2) the error signal which is the difference between the adaptive filter and the reference
  * output of the FIR filter. Over time as the adaptive filter learns the transfer function
  * of the FIR filter, the first output approaches the reference output of the FIR filter,
  * and the error signal approaches zero.
  * \par
  * The adaptive filter converges properly even if the input signal has a large dynamic
  * range (i.e., varies from small to large values). The coefficients of the adaptive filter
  * are initially zero, and then converge over 1536 samples. The internal function test_signal_converge()
  * implements the stopping condition. The function checks if all of the values of the error signal have a
  * magnitude below a threshold DELTA.
  *
  * \par Block Diagram:
  * \par
  * \image html SignalFlow.gif
  *
  *
  * \par Variables Description:
  * \par
  * \li \c testInput_f32 points to the input data
  * \li \c firStateF32 points to FIR state buffer
  * \li \c lmsStateF32 points to Normalised Least mean square FIR filter state buffer
  * \li \c FIRCoeff_f32 points to coefficient buffer
  * \li \c lmsNormCoeff_f32 points to Normalised Least mean square FIR filter coefficient buffer
  * \li \c wire1, wir2, wire3 temporary buffers
  * \li \c errOutput, err_signal temporary error buffers
  *
  * \par CMSIS DSP Software Library Functions Used:
  * \par
  * - arm_lms_norm_init_f32()
  * - arm_fir_init_f32()
  * - arm_fir_f32()
  * - arm_lms_norm_f32()
  * - arm_scale_f32()
  * - arm_abs_f32()
  * - arm_sub_f32()
  * - arm_min_f32()
  * - arm_copy_f32()
  *
  * <b> Refer  </b>
  * \link arm_signal_converge_example_f32.c \endlink
  *
  */


 /** \example arm_signal_converge_example_f32.c
   */

 #include "arm_math.h"
 #include "math_helper.h"

 /* ----------------------------------------------------------------------
 ** Global defines for the simulation
 * ------------------------------------------------------------------- */

 #define TEST_LENGTH_SAMPLES 1536
 #define NUMTAPS               32
 #define BLOCKSIZE             32
 #define DELTA_ERROR         0.000001f
 #define DELTA_COEFF         0.0001f
 #define MU                  0.5f

 #define NUMFRAMES (TEST_LENGTH_SAMPLES / BLOCKSIZE)

 /* ----------------------------------------------------------------------
 * Declare FIR state buffers and structure
 * ------------------------------------------------------------------- */

 float32_t firStateF32[NUMTAPS + BLOCKSIZE];
 arm_fir_instance_f32 LPF_instance;

 /* ----------------------------------------------------------------------
 * Declare LMSNorm state buffers and structure
 * ------------------------------------------------------------------- */

 float32_t lmsStateF32[NUMTAPS + BLOCKSIZE];
 float32_t errOutput[TEST_LENGTH_SAMPLES];
 arm_lms_norm_instance_f32 lmsNorm_instance;


 /* ----------------------------------------------------------------------
 * Function Declarations for Signal Convergence Example
 * ------------------------------------------------------------------- */

 arm_status test_signal_converge_example( void );


 /* ----------------------------------------------------------------------
 * Internal functions
 * ------------------------------------------------------------------- */
 arm_status test_signal_converge(float32_t* err_signal,
                         uint32_t blockSize);

 void getinput(float32_t* input,
      uint32_t fr_cnt,
           uint32_t blockSize);

 /* ----------------------------------------------------------------------
 * External Declarations for FIR F32 module Test
 * ------------------------------------------------------------------- */
 extern float32_t testInput_f32[TEST_LENGTH_SAMPLES];
 extern float32_t lmsNormCoeff_f32[32];
 extern const float32_t FIRCoeff_f32[32];
 extern arm_lms_norm_instance_f32 lmsNorm_instance;

 /* ----------------------------------------------------------------------
 * Declare I/O buffers
 * ------------------------------------------------------------------- */

 float32_t wire1[BLOCKSIZE];
 float32_t wire2[BLOCKSIZE];
 float32_t wire3[BLOCKSIZE];
 float32_t err_signal[BLOCKSIZE];

 /* ----------------------------------------------------------------------
 * Signal converge test
 * ------------------------------------------------------------------- */

 int32_t main(void)
 {
   uint32_t i;
   arm_status status;
   uint32_t index;
   float32_t minValue;

   /* Initialize the LMSNorm data structure */
   arm_lms_norm_init_f32(&lmsNorm_instance, NUMTAPS, lmsNormCoeff_f32, lmsStateF32, MU, BLOCKSIZE);

   /* Initialize the FIR data structure */
   arm_fir_init_f32(&LPF_instance, NUMTAPS, (float32_t *)FIRCoeff_f32, firStateF32, BLOCKSIZE);

   /* ----------------------------------------------------------------------
   * Loop over the frames of data and execute each of the processing
   * functions in the system.
   * ------------------------------------------------------------------- */

   for(i=0; i < NUMFRAMES; i++)
   {
     /* Read the input data - uniformly distributed random noise - into wire1 */
     arm_copy_f32(testInput_f32 + (i * BLOCKSIZE), wire1, BLOCKSIZE);

     /* Execute the FIR processing function.  Input wire1 and output wire2 */
     arm_fir_f32(&LPF_instance, wire1, wire2, BLOCKSIZE);

     /* Execute the LMS Norm processing function*/

     arm_lms_norm_f32(&lmsNorm_instance, /* LMSNorm instance */
          wire1,                         /* Input signal */
          wire2,                         /* Reference Signal */
          wire3,                         /* Converged Signal */
          err_signal,                    /* Error Signal, this will become small as the signal converges */
          BLOCKSIZE);                    /* BlockSize */

     /* apply overall gain */
     arm_scale_f32(wire3, 5, wire3, BLOCKSIZE);   /* in-place buffer */
   }

   status = ARM_MATH_SUCCESS;

   /* -------------------------------------------------------------------------------
   * Test whether the error signal has reached towards 0.
   * ----------------------------------------------------------------------------- */

   arm_abs_f32(err_signal, err_signal, BLOCKSIZE);
   arm_min_f32(err_signal, BLOCKSIZE, &minValue, &index);

   if (minValue > DELTA_ERROR)
   {
     status = ARM_MATH_TEST_FAILURE;
   }

   /* ----------------------------------------------------------------------
   * Test whether the filter coefficients have converged.
   * ------------------------------------------------------------------- */

   arm_sub_f32((float32_t *)FIRCoeff_f32, lmsNormCoeff_f32, lmsNormCoeff_f32, NUMTAPS);

   arm_abs_f32(lmsNormCoeff_f32, lmsNormCoeff_f32, NUMTAPS);
   arm_min_f32(lmsNormCoeff_f32, NUMTAPS, &minValue, &index);

   if (minValue > DELTA_COEFF)
   {
     status = ARM_MATH_TEST_FAILURE;
   }

   /* ----------------------------------------------------------------------
   * Loop here if the signals did not pass the convergence check.
   * This denotes a test failure
   * ------------------------------------------------------------------- */

   if( status != ARM_MATH_SUCCESS)
   {
     while(1);
   }

   while(1);                             /* main function does not return */
 }

  /** \endlink */
	/* ----------------------------------------------------------------------
	* Copyright (C) 2010-2012 ARM Limited. All rights reserved.
	*
	* $Date: 17. January 2013
	* $Revision: V1.4.0
	*
	* Project: CMSIS DSP Library
	* Title: arm_signal_converge_example_f32.c
	*
	* Description: Example code demonstrating convergence of an adaptive
	* filter.
	*
	* Target Processor: Cortex-M4/Cortex-M3
	*
	* Redistribution and use in source and binary forms, with or without
	* modification, are permitted provided that the following conditions
	* are met:
	* - Redistributions of source code must retain the above copyright
	* notice, this list of conditions and the following disclaimer.
	* - Redistributions in binary form must reproduce the above copyright
	* notice, this list of conditions and the following disclaimer in
	* the documentation and/or other materials provided with the
	* distribution.
	* - Neither the name of ARM LIMITED nor the names of its contributors
	* may be used to endorse or promote products derived from this
	* software without specific prior written permission.
	*
	* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
	* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
	* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
	* FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE
	* COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT,
	* INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING,
	* BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
	* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER
	* CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
	* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN
	* ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
	* POSSIBILITY OF SUCH DAMAGE.
	* -------------------------------------------------------------------- */

	/**
	* @ingroup groupExamples
	*/

	/**
	* @defgroup SignalConvergence Signal Convergence Example
	*
	* \par Description:
	* \par
	* Demonstrates the ability of an adaptive filter to "learn" the transfer function of
	* a FIR lowpass filter using the Normalized LMS Filter, Finite Impulse
	* Response (FIR) Filter, and Basic Math Functions.
	*
	* \par Algorithm:
	* \par
	* The figure below illustrates the signal flow in this example. Uniformly distributed white
	* noise is passed through an FIR lowpass filter. The output of the FIR filter serves as the
	* reference input of the adaptive filter (normalized LMS filter). The white noise is input
	* to the adaptive filter. The adaptive filter learns the transfer function of the FIR filter.
	* The filter outputs two signals: (1) the output of the internal adaptive FIR filter, and
	* (2) the error signal which is the difference between the adaptive filter and the reference
	* output of the FIR filter. Over time as the adaptive filter learns the transfer function
	* of the FIR filter, the first output approaches the reference output of the FIR filter,
	* and the error signal approaches zero.
	* \par
	* The adaptive filter converges properly even if the input signal has a large dynamic
	* range (i.e., varies from small to large values). The coefficients of the adaptive filter
	* are initially zero, and then converge over 1536 samples. The internal function test_signal_converge()
	* implements the stopping condition. The function checks if all of the values of the error signal have a
	* magnitude below a threshold DELTA.
	*
	* \par Block Diagram:
	* \par
	* \image html SignalFlow.gif
	*
	*
	* \par Variables Description:
	* \par
	* \li \c testInput_f32 points to the input data
	* \li \c firStateF32 points to FIR state buffer
	* \li \c lmsStateF32 points to Normalised Least mean square FIR filter state buffer
	* \li \c FIRCoeff_f32 points to coefficient buffer
	* \li \c lmsNormCoeff_f32 points to Normalised Least mean square FIR filter coefficient buffer
	* \li \c wire1, wir2, wire3 temporary buffers
	* \li \c errOutput, err_signal temporary error buffers
	*
	* \par CMSIS DSP Software Library Functions Used:
	* \par
	* - arm_lms_norm_init_f32()
	* - arm_fir_init_f32()
	* - arm_fir_f32()
	* - arm_lms_norm_f32()
	* - arm_scale_f32()
	* - arm_abs_f32()
	* - arm_sub_f32()
	* - arm_min_f32()
	* - arm_copy_f32()
	*
	* <b> Refer </b>
	* \link arm_signal_converge_example_f32.c \endlink
	*
	*/


	/** \example arm_signal_converge_example_f32.c
	*/

	#include "arm_math.h"
	#include "math_helper.h"

	/* ----------------------------------------------------------------------
	** Global defines for the simulation
	* ------------------------------------------------------------------- */

	#define TEST_LENGTH_SAMPLES 1536
	#define NUMTAPS 32
	#define BLOCKSIZE 32
	#define DELTA_ERROR 0.000001f
	#define DELTA_COEFF 0.0001f
	#define MU 0.5f

	#define NUMFRAMES (TEST_LENGTH_SAMPLES / BLOCKSIZE)

	/* ----------------------------------------------------------------------
	* Declare FIR state buffers and structure
	* ------------------------------------------------------------------- */

	float32_t firStateF32[NUMTAPS + BLOCKSIZE];
	arm_fir_instance_f32 LPF_instance;

	/* ----------------------------------------------------------------------
	* Declare LMSNorm state buffers and structure
	* ------------------------------------------------------------------- */

	float32_t lmsStateF32[NUMTAPS + BLOCKSIZE];
	float32_t errOutput[TEST_LENGTH_SAMPLES];
	arm_lms_norm_instance_f32 lmsNorm_instance;


	/* ----------------------------------------------------------------------
	* Function Declarations for Signal Convergence Example
	* ------------------------------------------------------------------- */

	arm_status test_signal_converge_example( void );


	/* ----------------------------------------------------------------------
	* Internal functions
	* ------------------------------------------------------------------- */
	arm_status test_signal_converge(float32_t* err_signal,
	uint32_t blockSize);

	void getinput(float32_t* input,
	uint32_t fr_cnt,
	uint32_t blockSize);

	/* ----------------------------------------------------------------------
	* External Declarations for FIR F32 module Test
	* ------------------------------------------------------------------- */
	extern float32_t testInput_f32[TEST_LENGTH_SAMPLES];
	extern float32_t lmsNormCoeff_f32[32];
	extern const float32_t FIRCoeff_f32[32];
	extern arm_lms_norm_instance_f32 lmsNorm_instance;

	/* ----------------------------------------------------------------------
	* Declare I/O buffers
	* ------------------------------------------------------------------- */

	float32_t wire1[BLOCKSIZE];
	float32_t wire2[BLOCKSIZE];
	float32_t wire3[BLOCKSIZE];
	float32_t err_signal[BLOCKSIZE];

	/* ----------------------------------------------------------------------
	* Signal converge test
	* ------------------------------------------------------------------- */

	int32_t main(void)
	{
	uint32_t i;
	arm_status status;
	uint32_t index;
	float32_t minValue;

	/* Initialize the LMSNorm data structure */
	arm_lms_norm_init_f32(&lmsNorm_instance, NUMTAPS, lmsNormCoeff_f32, lmsStateF32, MU, BLOCKSIZE);

	/* Initialize the FIR data structure */
	arm_fir_init_f32(&LPF_instance, NUMTAPS, (float32_t *)FIRCoeff_f32, firStateF32, BLOCKSIZE);

	/* ----------------------------------------------------------------------
	* Loop over the frames of data and execute each of the processing
	* functions in the system.
	* ------------------------------------------------------------------- */

	for(i=0; i < NUMFRAMES; i++)
	{
	/* Read the input data - uniformly distributed random noise - into wire1 */
	arm_copy_f32(testInput_f32 + (i * BLOCKSIZE), wire1, BLOCKSIZE);

	/* Execute the FIR processing function. Input wire1 and output wire2 */
	arm_fir_f32(&LPF_instance, wire1, wire2, BLOCKSIZE);

	/* Execute the LMS Norm processing function*/

	arm_lms_norm_f32(&lmsNorm_instance, /* LMSNorm instance */
	wire1, /* Input signal */
	wire2, /* Reference Signal */
	wire3, /* Converged Signal */
	err_signal, /* Error Signal, this will become small as the signal converges */
	BLOCKSIZE); /* BlockSize */

	/* apply overall gain */
	arm_scale_f32(wire3, 5, wire3, BLOCKSIZE); /* in-place buffer */
	}

	status = ARM_MATH_SUCCESS;

	/* -------------------------------------------------------------------------------
	* Test whether the error signal has reached towards 0.
	* ----------------------------------------------------------------------------- */

	arm_abs_f32(err_signal, err_signal, BLOCKSIZE);
	arm_min_f32(err_signal, BLOCKSIZE, &minValue, &index);

	if (minValue > DELTA_ERROR)
	{
	status = ARM_MATH_TEST_FAILURE;
	}

	/* ----------------------------------------------------------------------
	* Test whether the filter coefficients have converged.
	* ------------------------------------------------------------------- */

	arm_sub_f32((float32_t *)FIRCoeff_f32, lmsNormCoeff_f32, lmsNormCoeff_f32, NUMTAPS);

	arm_abs_f32(lmsNormCoeff_f32, lmsNormCoeff_f32, NUMTAPS);
	arm_min_f32(lmsNormCoeff_f32, NUMTAPS, &minValue, &index);

	if (minValue > DELTA_COEFF)
	{
	status = ARM_MATH_TEST_FAILURE;
	}

	/* ----------------------------------------------------------------------
	* Loop here if the signals did not pass the convergence check.
	* This denotes a test failure
	* ------------------------------------------------------------------- */

	if( status != ARM_MATH_SUCCESS)
	{
	while(1);
	}

	while(1); /* main function does not return */
	}

	/** \endlink */