#include <math.h>
#include <stdio.h>
/*********************************************************************
*
*
* Name: mag_est.c
*
* Synopsis:
*
* Demonstrates and tests the "Alpha * Min + Beta * Max" magnitude
* estimation algorithm.
*
* Description:
*
* This program demonstrates the "Alpha, Beta" algorithm for
* estimating the magnitude of a complex number. Compared to
* calculating the magnitude directly using sqrt(I^2 + Q^2), this
* estimation is very quick.
*
* Various values of Alpha and Beta can be used to trade among RMS
* error, peak error, and coefficient complexity. This program
* includes a table of the most useful values, and it prints out the
* resulting RMS and peak errors.
*
* Copyright 1999 Grant R. Griffin
*
* The Wide Open License (WOL)
*
* Permission to use, copy, modify, distribute and sell this software
* and its documentation for any purpose is hereby granted without
* fee, provided that the above copyright notice and this license
* appear in all source copies. THIS SOFTWARE IS PROVIDED "AS IS"
* WITHOUT EXPRESS OR IMPLIED WARRANTY OF ANY KIND. See
* http://scopeplot.com/dg/wol.htm for more information.
*
*********************************************************************/
/********************************************************************/
double alpha_beta_mag(double alpha, double beta, double inphase,
double quadrature)
{
/* magnitude ~= alpha * max(|I|, |Q|) + beta * min(|I|, |Q|) */
double abs_inphase = fabs(inphase);
double abs_quadrature = fabs(quadrature);
if (abs_inphase > abs_quadrature) {
return alpha * abs_inphase + beta * abs_quadrature;
} else {
return alpha * abs_quadrature + beta * abs_inphase;
}
}
/*********************************************************************/
double decibels(double linear)
{
#define SMALL 1e-20
if (linear <= SMALL) {
linear = SMALL;
}
return 20.0 * log10(linear);
}
/*********************************************************************/
void test_alpha_beta(char *name, double alpha, double beta,
int num_points)
{
#define PI 3.141592653589793
int ii;
double phase, real, imag, err, avg_err, rms_err;
double peak_err = 0.0;
double sum_err = 0.0;
double sum_err_sqrd = 0.0;
double delta_phase = (2.0 * PI) / num_points;
for (ii = 0; ii < num_points; ii++) {
phase = delta_phase * ii;
real = cos(phase);
imag = sin(phase);
err = sqrt(real * real + imag * imag)
- alpha_beta_mag(alpha, beta, real, imag);
sum_err += err;
sum_err_sqrd += err * err;
err = fabs(err);
if (err > peak_err) {
peak_err = err;
}
}
avg_err = sum_err / num_points;
rms_err = sqrt(sum_err_sqrd / num_points);
printf("%-16s %14.12lf %14.12lf %9.6lf %4.1lf %4.1lf\n",
name, alpha, beta, avg_err, decibels(rms_err),
decibels(peak_err));
}
/*********************************************************************/
void main(void)
{
#define NUM_CHECK_POINTS 100000
typedef struct tagALPHA_BETA {
char *name;
double alpha;
double beta;
} ALPHA_BETA;
#define NUM_ALPHA_BETA 16
const ALPHA_BETA coeff[NUM_ALPHA_BETA] = {
{ "Min RMS Err", 0.947543636291, 0.3924854250920 },
{ "Min Peak Err", 0.960433870103, 0.3978247347593 },
{ "Min RMS w/ Avg=0", 0.948059448969, 0.3926990816987 },
{ "1, Min RMS Err", 1.0, 0.323260990 },
{ "1, Min Peak Err", 1.0, 0.335982538 },
{ "1, 1/2", 1.0, 1.0 / 2.0 },
{ "1, 1/4", 1.0, 1.0 / 4.0 },
{ "Frerking", 1.0, 0.4 },
{ "1, 11/32", 1.0, 11.0 / 32.0 },
{ "1, 3/8", 1.0, 3.0 / 8.0 },
{ "15/16, 15/32", 15.0 / 16.0, 15.0 / 32.0 },
{ "15/16, 1/2", 15.0 / 16.0, 1.0 / 2.0 },
{ "31/32, 11/32", 31.0 / 32.0, 11.0 / 32.0 },
{ "31/32, 3/8", 31.0 / 32.0, 3.0 / 8.0 },
{ "61/64, 3/8", 61.0 / 64.0, 3.0 / 8.0 },
{ "61/64, 13/32", 61.0 / 64.0, 13.0 / 32.0 }
};
int ii;
printf("\n Alpha * Max + Beta * Min Magnitude Estimator\n\n");
printf("Name Alpha Beta Avg Err RMS Peak\n");
printf(" (linear) (dB) (dB)\n");
printf("---------------------------------------------------------------------\n");
for (ii = 0; ii < NUM_ALPHA_BETA; ii++) {
test_alpha_beta(coeff[ii].name, coeff[ii].alpha, coeff[ii].beta, 1024);
}
}
