TheAlgorithms-C/numerical_methods/realtime_stats.c

/**
 * \file
 * \brief Compute statistics for data entered in rreal-time
 * \author [Krishna Vedala](https://github.com/kvedala)
 *
 * This algorithm is really beneficial to compute statistics on data read in
 * realtime. For example, devices reading biometrics data. The algorithm is
 * simple enough to be easily implemented in an embedded system.
 */
#include <assert.h>
#include <math.h>
#include <stdio.h>

/**
 * continuous mean and variance computance using
 * first value as an approximation for the mean.
 * If the first number is much far form the mean, the algorithm becomes very
 * inaccurate to compute variance and standard deviation.
 * \param[in] x new value added to data set
 * \param[out] mean if not NULL, mean returns mean of data set
 * \param[out] variance if not NULL, mean returns variance of data set
 * \param[out] std if not NULL, mean returns standard deviation of data set
 */
void stats_computer1(float x, float *mean, float *variance, float *std)
{
    /* following variables declared static becuase they need to be remembered
     * when updating for next sample, when received.
     */
    static unsigned int n = 0;
    static float Ex = 0.f, Ex2 = 0.f;
    static float K = 0.f;

    if (n == 0)
        K = x;
    n++;
    float tmp = x - K;
    Ex += tmp;
    Ex2 += tmp * tmp;

    /* return sample mean computed till last sample */
    if (mean != NULL)
        *mean = K + Ex / n;

    /* return data variance computed till last sample */
    if (variance != NULL)
        *variance = (Ex2 - (Ex * Ex) / n) / (n - 1);

    /* return sample standard deviation computed till last sample */
    if (std != NULL)
        *std = sqrtf(*variance);
}

/**
 * continuous mean and variance computance using
 * Welford's algorithm  (very accurate)
 * \param[in] x new value added to data set
 * \param[out] mean if not NULL, mean returns mean of data set
 * \param[out] variance if not NULL, mean returns variance of data set
 * \param[out] std if not NULL, mean returns standard deviation of data set
 */
void stats_computer2(float x, float *mean, float *variance, float *std)
{
    /* following variables declared static becuase they need to be remembered
     * when updating for next sample, when received.
     */
    static unsigned int n = 0;
    static float mu = 0, M = 0;

    n++;
    float delta = x - mu;
    mu += delta / n;
    float delta2 = x - mu;
    M += delta * delta2;

    /* return sample mean computed till last sample */
    if (mean != NULL)
        *mean = mu;

    /* return data variance computed till last sample */
    if (variance != NULL)
        *variance = M / n;

    /* return sample standard deviation computed till last sample */
    if (std != NULL)
        *std = sqrtf(*variance);
}

/** Test the algorithm implementation
 * \param[in] test_data array of data to test the algorithms
 * \param[in] number_of_samples number of samples of data
 */
void test_function(const float *test_data, const int number_of_samples)
{
    float ref_mean = 0.f, ref_variance = 0.f;
    float s1_mean = 0.f, s1_variance = 0.f, s1_std = 0.f;
    float s2_mean = 0.f, s2_variance = 0.f, s2_std = 0.f;

    for (int i = 0; i < number_of_samples; i++)
    {
        stats_computer1(test_data[i], &s1_mean, &s1_variance, &s1_std);
        stats_computer2(test_data[i], &s2_mean, &s2_variance, &s2_std);
        ref_mean += test_data[i];
    }
    ref_mean /= number_of_samples;

    for (int i = 0; i < number_of_samples; i++)
    {
        float temp = test_data[i] - ref_mean;
        ref_variance += temp * temp;
    }
    ref_variance /= number_of_samples;

    printf("<<<<<<<< Test Function >>>>>>>>\n");
    printf("Expected: Mean: %.4f\t Variance: %.4f\n", ref_mean, ref_variance);
    printf("\tMethod 1:\tMean: %.4f\t Variance: %.4f\t Std: %.4f\n", s1_mean,
           s1_variance, s1_std);
    printf("\tMethod 2:\tMean: %.4f\t Variance: %.4f\t Std: %.4f\n", s2_mean,
           s2_variance, s2_std);

    assert(fabs(s1_mean - ref_mean) < 0.01);
    assert(fabs(s2_mean - ref_mean) < 0.01);
    assert(fabs(s2_variance - ref_variance) < 0.01);

    printf("(Tests passed)\n\n");
}

/** Main function */
int main(int argc, char **argv)
{
    const float test_data1[] = {3, 4, 5, -1.4, -3.6, 1.9, 1.};
    test_function(test_data1, sizeof(test_data1) / sizeof(test_data1[0]));

    float s1_mean = 0.f, s1_variance = 0.f, s1_std = 0.f;
    float s2_mean = 0.f, s2_variance = 0.f, s2_std = 0.f;

    printf("Enter data. Any non-numeric data will terminate the data input.\n");

    while (1)
    {
        float val;
        printf("Enter number: ");

        // check for failure to read input. Happens for
        // non-numeric data
        if (!scanf("%f", &val))
            break;

        stats_computer1(val, &s1_mean, &s1_variance, &s1_std);
        stats_computer2(val, &s2_mean, &s2_variance, &s2_std);

        printf("\tMethod 1:\tMean: %.4f\t Variance: %.4f\t Std: %.4f\n",
               s1_mean, s1_variance, s1_std);
        printf("\tMethod 2:\tMean: %.4f\t Variance: %.4f\t Std: %.4f\n",
               s2_mean, s2_variance, s2_std);
    }

    return 0;
}
algorithm for realtime computation of data statistics 2020-05-30 21:01:02 +03:00			`/**`
			`* \file`
			`* \brief Compute statistics for data entered in rreal-time`
added authorship to docs 2020-06-06 21:51:49 +03:00			`* \author [Krishna Vedala](https://github.com/kvedala)`
algorithm for realtime computation of data statistics 2020-05-30 21:01:02 +03:00			`*`
			`* This algorithm is really beneficial to compute statistics on data read in`
			`* realtime. For example, devices reading biometrics data. The algorithm is`
			`* simple enough to be easily implemented in an embedded system.`
			`*/`
			`#include <assert.h>`
			`#include <math.h>`
			`#include <stdio.h>`

			`/**`
			`* continuous mean and variance computance using`
			`* first value as an approximation for the mean.`
			`* If the first number is much far form the mean, the algorithm becomes very`
			`* inaccurate to compute variance and standard deviation.`
			`* \param[in] x new value added to data set`
			`* \param[out] mean if not NULL, mean returns mean of data set`
			`* \param[out] variance if not NULL, mean returns variance of data set`
			`* \param[out] std if not NULL, mean returns standard deviation of data set`
			`*/`
			`void stats_computer1(float x, float mean, float variance, float *std)`
			`{`
			`/* following variables declared static becuase they need to be remembered`
			`* when updating for next sample, when received.`
			`*/`
			`static unsigned int n = 0;`
			`static float Ex = 0.f, Ex2 = 0.f;`
			`static float K = 0.f;`

			`if (n == 0)`
			`K = x;`
			`n++;`
			`float tmp = x - K;`
			`Ex += tmp;`
			`Ex2 += tmp * tmp;`

			`/* return sample mean computed till last sample */`
			`if (mean != NULL)`
			`*mean = K + Ex / n;`

			`/* return data variance computed till last sample */`
			`if (variance != NULL)`
			`variance = (Ex2 - (Ex Ex) / n) / (n - 1);`

			`/* return sample standard deviation computed till last sample */`
			`if (std != NULL)`
			`std = sqrtf(variance);`
			`}`

			`/**`
			`* continuous mean and variance computance using`
			`* Welford's algorithm (very accurate)`
			`* \param[in] x new value added to data set`
			`* \param[out] mean if not NULL, mean returns mean of data set`
			`* \param[out] variance if not NULL, mean returns variance of data set`
			`* \param[out] std if not NULL, mean returns standard deviation of data set`
			`*/`
			`void stats_computer2(float x, float mean, float variance, float *std)`
			`{`
			`/* following variables declared static becuase they need to be remembered`
			`* when updating for next sample, when received.`
			`*/`
			`static unsigned int n = 0;`
			`static float mu = 0, M = 0;`

			`n++;`
			`float delta = x - mu;`
			`mu += delta / n;`
			`float delta2 = x - mu;`
			`M += delta * delta2;`

			`/* return sample mean computed till last sample */`
			`if (mean != NULL)`
			`*mean = mu;`

			`/* return data variance computed till last sample */`
			`if (variance != NULL)`
			`*variance = M / n;`

			`/* return sample standard deviation computed till last sample */`
			`if (std != NULL)`
			`std = sqrtf(variance);`
			`}`

			`/** Test the algorithm implementation`
			`* \param[in] test_data array of data to test the algorithms`
			`* \param[in] number_of_samples number of samples of data`
			`*/`
			`void test_function(const float *test_data, const int number_of_samples)`
			`{`
			`float ref_mean = 0.f, ref_variance = 0.f;`
			`float s1_mean = 0.f, s1_variance = 0.f, s1_std = 0.f;`
			`float s2_mean = 0.f, s2_variance = 0.f, s2_std = 0.f;`

			`for (int i = 0; i < number_of_samples; i++)`
			`{`
			`stats_computer1(test_data[i], &s1_mean, &s1_variance, &s1_std);`
			`stats_computer2(test_data[i], &s2_mean, &s2_variance, &s2_std);`
			`ref_mean += test_data[i];`
			`}`
			`ref_mean /= number_of_samples;`

			`for (int i = 0; i < number_of_samples; i++)`
			`{`
			`float temp = test_data[i] - ref_mean;`
			`ref_variance += temp * temp;`
			`}`
			`ref_variance /= number_of_samples;`

			`printf("<<<<<<<< Test Function >>>>>>>>\n");`
			`printf("Expected: Mean: %.4f\t Variance: %.4f\n", ref_mean, ref_variance);`
			`printf("\tMethod 1:\tMean: %.4f\t Variance: %.4f\t Std: %.4f\n", s1_mean,`
			`s1_variance, s1_std);`
			`printf("\tMethod 2:\tMean: %.4f\t Variance: %.4f\t Std: %.4f\n", s2_mean,`
			`s2_variance, s2_std);`

			`assert(fabs(s1_mean - ref_mean) < 0.01);`
			`assert(fabs(s2_mean - ref_mean) < 0.01);`
			`assert(fabs(s2_variance - ref_variance) < 0.01);`

			`printf("(Tests passed)\n\n");`
			`}`

			`/** Main function */`
			`int main(int argc, char **argv)`
			`{`
			`const float test_data1[] = {3, 4, 5, -1.4, -3.6, 1.9, 1.};`
			`test_function(test_data1, sizeof(test_data1) / sizeof(test_data1[0]));`

			`float s1_mean = 0.f, s1_variance = 0.f, s1_std = 0.f;`
			`float s2_mean = 0.f, s2_variance = 0.f, s2_std = 0.f;`

			`printf("Enter data. Any non-numeric data will terminate the data input.\n");`

			`while (1)`
			`{`
			`float val;`
			`printf("Enter number: ");`

			`// check for failure to read input. Happens for`
			`// non-numeric data`
			`if (!scanf("%f", &val))`
			`break;`

			`stats_computer1(val, &s1_mean, &s1_variance, &s1_std);`
			`stats_computer2(val, &s2_mean, &s2_variance, &s2_std);`

			`printf("\tMethod 1:\tMean: %.4f\t Variance: %.4f\t Std: %.4f\n",`
			`s1_mean, s1_variance, s1_std);`
			`printf("\tMethod 2:\tMean: %.4f\t Variance: %.4f\t Std: %.4f\n",`
			`s2_mean, s2_variance, s2_std);`
			`}`

			`return 0;`
			`}`