GY-63_MS5611/sketches/fastHaverSine/fastHaverSine.ino

//
//    FILE: fastHaverSine.ino
//  AUTHOR: Rob Tillaart
// VERSION: 0.1.01
// PURPOSE: fastHaverSine is a faster function than haversine for short distances (<1km).
//    DATE: 2015-07-18
//     URL: http://forum.arduino.cc/index.php?topic=336729
//
// Released to the public domain
//


#define NUMTESTS 8

float ts[NUMTESTS][4] = {
  {50, 5, 51, 5},
  {50, 5, 50, 6},
  {50, 5, 50.1, 5},
  {50, 5, 50, 5.1},
  {50, 5, 50.1, 5.1},
  {50, 5, 50.01, 5.01},
  {50, 5, 50.001, 5.001},
  {50, 5, 50.0001, 5.0001},
};


uint32_t start;
uint32_t stop;

void setup()
{
  Serial.begin(115200);
  Serial.println("Start fastHaverSine()");

  start = micros();
  float d = HaverSine(50, 5, 50.01, 5.01);
  stop = micros();
  Serial.println("HAVERSINE");
  Serial.print("TIME: ");
  Serial.println(stop - start);
  Serial.print("DIST: ");
  Serial.println(d);

  start = micros();
  d = fastHaverSine(50, 5, 50.01, 5.01);
  stop = micros();
  Serial.println("\nFASTHAVERSINE");
  Serial.print("TIME: ");
  Serial.println(stop - start);
  Serial.print("DIST: ");
  Serial.println(d);

  start = micros();
  d = fastHaverSine2(50, 5, 50.01, 5.01);
  stop = micros();
  Serial.println("\nFASTHAVERSINE2");
  Serial.print("TIME: ");
  Serial.println(stop - start);
  Serial.print("DIST: ");
  Serial.println(d);

  for (int i = 0; i < NUMTESTS; i++)
  {
    Serial.print("\ntest: ");
    Serial.print(i);
    Serial.print("\t\t");
    for (int j = 0; j < 4; j++)
    {
      Serial.print("\t");
      Serial.print(ts[i][j], 1);
    }
    Serial.println();
    d = HaverSine(ts[i][0], ts[i][1], ts[i][2], ts[i][3]);
    Serial.println(d);
    d = fastHaverSine(ts[i][0], ts[i][1], ts[i][2], ts[i][3]);
    Serial.println(d);
  }

  Serial.println("\nrelative error map test\nLAT/LONG:\t45-50\nSTEPSIZE:\t0.2 degrees");
  float y = 45.0;
  while (y <= 50.0)
  {
    float x = 45.0;
    while (x <= 50.0)
    {
      float d1 = HaverSine(45.0, 45.0, x, y);
      float d2 = fastHaverSine(45.0, 45.0, x, y);
      float relError = 100.0 * abs(d2 - d1) / d1;
      Serial.print(relError, 3);
      Serial.print("\t");
      x += 0.2;
    }
    Serial.println();
    y += 0.2;
  }
  Serial.println();


  Serial.println("\nrelative error map test\nLAT/LONG:\t45-46\nSTEPSIZE:\t0.05 degrees");
  y = 45.0;
  while (y <= 46.0)
  {
    float x = 45.0;
    while (x <= 46.0)
    {
      float d1 = HaverSine(45.0, 45.0, x, y);
      float d2 = fastHaverSine(45.0, 45.0, x, y);
      float relError = 100.0 * abs(d2 - d1) / d1;
      Serial.print(relError, 3);
      Serial.print("\t");
      x += 0.05;
    }
    Serial.println();
    y += 0.05;
  }
  Serial.println();


  Serial.println("\nrelative error map test\nLAT/LONG:\t45-45.1\nSTEPSIZE:\t0.005 degrees");
  y = 45.0;
  while (y <= 45.1)
  {
    float x = 45.0;
    while (x <= 45.1)
    {
      float d1 = HaverSine(45.0, 45.0, x, y);
      float d2 = fastHaverSine(45.0, 45.0, x, y);
      float relError = 100.0 * abs(d2 - d1) / d1;
      Serial.print(relError, 3);
      Serial.print("\t");
      x += 0.005;
    }
    Serial.println();
    y += 0.005;
  }
  Serial.println();


  Serial.println("done...");
}

void loop()
{
}

double fastHaverSine(double lat1, double long1, double lat2, double  long2)
{
  // assume the sphere has circumference 1 on the equator
  // to keep the number in same order of magnitude
  // helps to keep precision
  double dx = lat2 - lat1;
  double dy = (long2 - long1) * cos(lat2 * (PI / 180.0));
  double dist = sqrt(dx * dx + dy * dy);
  return dist * 111194.93;              // correct for earth sizes ;)
}

double fastHaverSine2(double lat1, double long1, double lat2, double  long2)
{
  // assume the sphere has circumference 1 on the equator
  // to keep the number in same order of magnitude
  // helps to keep precision
  double dx = lat2 - lat1;
  double dy = (long2 - long1) * cos(lat2 * (PI / 180.0));
  return hypot(dx, dy) * 111194.93;              // correct for earth sizes ;)
}

double HaverSine(double lat1, double lon1, double lat2, double lon2)
{
  double ToRad = PI / 180.0;
  double R = 6371000;   // radius earth in meter

  double dLat = (lat2 - lat1) * ToRad;
  double dLon = (lon2 - lon1) * ToRad;

  double a = sin(dLat / 2) * sin(dLat / 2) +
             cos(lat1 * ToRad) * cos(lat2 * ToRad) *
             sin(dLon / 2) * sin(dLon / 2);

  double c = 2 * atan2(sqrt(a), sqrt(1 - a));

  double d = R * c;
  return d;
}
0.1.01 fastHaverSine distance function 2015-12-20 10:21:14 -05:00			`//`
			`// FILE: fastHaverSine.ino`
			`// AUTHOR: Rob Tillaart`
			`// VERSION: 0.1.01`
			`// PURPOSE: fastHaverSine is a faster function than haversine for short distances (<1km).`
			`// DATE: 2015-07-18`
			`// URL: http://forum.arduino.cc/index.php?topic=336729`
			`//`
			`// Released to the public domain`
			`//`


			`#define NUMTESTS 8`

			`float ts[NUMTESTS][4] = {`
			`{50, 5, 51, 5},`
			`{50, 5, 50, 6},`
			`{50, 5, 50.1, 5},`
			`{50, 5, 50, 5.1},`
			`{50, 5, 50.1, 5.1},`
			`{50, 5, 50.01, 5.01},`
			`{50, 5, 50.001, 5.001},`
			`{50, 5, 50.0001, 5.0001},`
			`};`


			`uint32_t start;`
			`uint32_t stop;`

			`void setup()`
			`{`
			`Serial.begin(115200);`
			`Serial.println("Start fastHaverSine()");`

			`start = micros();`
			`float d = HaverSine(50, 5, 50.01, 5.01);`
			`stop = micros();`
			`Serial.println("HAVERSINE");`
			`Serial.print("TIME: ");`
			`Serial.println(stop - start);`
			`Serial.print("DIST: ");`
			`Serial.println(d);`

			`start = micros();`
			`d = fastHaverSine(50, 5, 50.01, 5.01);`
			`stop = micros();`
			`Serial.println("\nFASTHAVERSINE");`
			`Serial.print("TIME: ");`
			`Serial.println(stop - start);`
			`Serial.print("DIST: ");`
			`Serial.println(d);`

			`start = micros();`
			`d = fastHaverSine2(50, 5, 50.01, 5.01);`
			`stop = micros();`
			`Serial.println("\nFASTHAVERSINE2");`
			`Serial.print("TIME: ");`
			`Serial.println(stop - start);`
			`Serial.print("DIST: ");`
			`Serial.println(d);`

			`for (int i = 0; i < NUMTESTS; i++)`
			`{`
			`Serial.print("\ntest: ");`
			`Serial.print(i);`
			`Serial.print("\t\t");`
			`for (int j = 0; j < 4; j++)`
			`{`
			`Serial.print("\t");`
			`Serial.print(ts[i][j], 1);`
			`}`
			`Serial.println();`
			`d = HaverSine(ts[i][0], ts[i][1], ts[i][2], ts[i][3]);`
			`Serial.println(d);`
			`d = fastHaverSine(ts[i][0], ts[i][1], ts[i][2], ts[i][3]);`
			`Serial.println(d);`
			`}`

			`Serial.println("\nrelative error map test\nLAT/LONG:\t45-50\nSTEPSIZE:\t0.2 degrees");`
			`float y = 45.0;`
			`while (y <= 50.0)`
			`{`
			`float x = 45.0;`
			`while (x <= 50.0)`
			`{`
			`float d1 = HaverSine(45.0, 45.0, x, y);`
			`float d2 = fastHaverSine(45.0, 45.0, x, y);`
			`float relError = 100.0 * abs(d2 - d1) / d1;`
			`Serial.print(relError, 3);`
			`Serial.print("\t");`
			`x += 0.2;`
			`}`
			`Serial.println();`
			`y += 0.2;`
			`}`
			`Serial.println();`


			`Serial.println("\nrelative error map test\nLAT/LONG:\t45-46\nSTEPSIZE:\t0.05 degrees");`
			`y = 45.0;`
			`while (y <= 46.0)`
			`{`
			`float x = 45.0;`
			`while (x <= 46.0)`
			`{`
			`float d1 = HaverSine(45.0, 45.0, x, y);`
			`float d2 = fastHaverSine(45.0, 45.0, x, y);`
			`float relError = 100.0 * abs(d2 - d1) / d1;`
			`Serial.print(relError, 3);`
			`Serial.print("\t");`
			`x += 0.05;`
			`}`
			`Serial.println();`
			`y += 0.05;`
			`}`
			`Serial.println();`


			`Serial.println("\nrelative error map test\nLAT/LONG:\t45-45.1\nSTEPSIZE:\t0.005 degrees");`
			`y = 45.0;`
			`while (y <= 45.1)`
			`{`
			`float x = 45.0;`
			`while (x <= 45.1)`
			`{`
			`float d1 = HaverSine(45.0, 45.0, x, y);`
			`float d2 = fastHaverSine(45.0, 45.0, x, y);`
			`float relError = 100.0 * abs(d2 - d1) / d1;`
			`Serial.print(relError, 3);`
			`Serial.print("\t");`
			`x += 0.005;`
			`}`
			`Serial.println();`
			`y += 0.005;`
			`}`
			`Serial.println();`


			`Serial.println("done...");`
			`}`

			`void loop()`
			`{`
			`}`

			`double fastHaverSine(double lat1, double long1, double lat2, double long2)`
			`{`
			`// assume the sphere has circumference 1 on the equator`
			`// to keep the number in same order of magnitude`
			`// helps to keep precision`
			`double dx = lat2 - lat1;`
			`double dy = (long2 - long1) * cos(lat2 * (PI / 180.0));`
			`double dist = sqrt(dx * dx + dy * dy);`
			`return dist * 111194.93; // correct for earth sizes ;)`
			`}`

			`double fastHaverSine2(double lat1, double long1, double lat2, double long2)`
			`{`
			`// assume the sphere has circumference 1 on the equator`
			`// to keep the number in same order of magnitude`
			`// helps to keep precision`
			`double dx = lat2 - lat1;`
			`double dy = (long2 - long1) * cos(lat2 * (PI / 180.0));`
			`return hypot(dx, dy) * 111194.93; // correct for earth sizes ;)`
			`}`

			`double HaverSine(double lat1, double lon1, double lat2, double lon2)`
			`{`
			`double ToRad = PI / 180.0;`
			`double R = 6371000; // radius earth in meter`

			`double dLat = (lat2 - lat1) * ToRad;`
			`double dLon = (lon2 - lon1) * ToRad;`

			`double a = sin(dLat / 2) * sin(dLat / 2) +`
			`cos(lat1 * ToRad) * cos(lat2 * ToRad) *`
			`sin(dLon / 2) * sin(dLon / 2);`

			`double c = 2 * atan2(sqrt(a), sqrt(1 - a));`

			`double d = R * c;`
			`return d;`
			`}`