Arduino/build/shared/dist/examples/Sensors/Ping/Ping.pde

int pingPin = 7;
int ledPin = 13;

void setup()
{
  pinMode(13, OUTPUT);
}

void loop()
{
  long duration, inches, cm;

  // The PING))) is triggered by a HIGH pulse of 2 or more microseconds.
  // We give a short LOW pulse beforehand to ensure a clean HIGH pulse.
  pinMode(pingPin, OUTPUT);
  digitalWrite(pingPin, LOW);
  delayMicroseconds(2);
  digitalWrite(pingPin, HIGH);
  delayMicroseconds(5);
  digitalWrite(pingPin, LOW);

  // The same pin is used to read the signal from the PING))): a HIGH
  // pulse whose duration is the time (in microseconds) from the sending
  // of the ping to the reception of its echo off of an object.
  pinMode(pingPin, INPUT);
  duration = pulseIn(pingPin, HIGH);

  // convert the time into a distance
  inches = microsecondsToInches(duration);
  cm = microsecondsToCentimeters(duration);

  // the closer an object is, the faster the led will blink
  digitalWrite(ledPin, HIGH);
  delay(cm);
  digitalWrite(ledPin, LOW);
  delay(cm);
}

long microsecondsToInches(long microseconds)
{
  // According to Parallax's datasheet for the PING))), there are
  // 73.746 microseconds per inch (i.e. sound travels at 1130 feet per
  // second).  This gives the distance travelled by the ping, outbound
  // and return, so we divide by 2 to get the distance of the obstacle.
  // See: http://www.parallax.com/dl/docs/prod/acc/28015-PING-v1.3.pdf
  return microseconds / 74 / 2;
}

long microsecondsToCentimeters(long microseconds)
{
  // The speed of sound is 340 m/s or 29 microseconds per centimeter.
  // The ping travels out and back, so to find the distance of the
  // object we take half of the distance travelled.
  return microseconds / 29 / 2;
}
Adding examples for Ping ultrasound distance sensor and Memsic 2125 accelerometer from Parallax. 2008-10-26 13:37:47 +01:00			`int pingPin = 7;`
			`int ledPin = 13;`

			`void setup()`
			`{`
			`pinMode(13, OUTPUT);`
			`}`

			`void loop()`
			`{`
			`long duration, inches, cm;`

			`// The PING))) is triggered by a HIGH pulse of 2 or more microseconds.`
			`// We give a short LOW pulse beforehand to ensure a clean HIGH pulse.`
			`pinMode(pingPin, OUTPUT);`
			`digitalWrite(pingPin, LOW);`
			`delayMicroseconds(2);`
			`digitalWrite(pingPin, HIGH);`
			`delayMicroseconds(5);`
			`digitalWrite(pingPin, LOW);`

			`// The same pin is used to read the signal from the PING))): a HIGH`
			`// pulse whose duration is the time (in microseconds) from the sending`
			`// of the ping to the reception of its echo off of an object.`
			`pinMode(pingPin, INPUT);`
			`duration = pulseIn(pingPin, HIGH);`

			`// convert the time into a distance`
			`inches = microsecondsToInches(duration);`
			`cm = microsecondsToCentimeters(duration);`

			`// the closer an object is, the faster the led will blink`
			`digitalWrite(ledPin, HIGH);`
			`delay(cm);`
			`digitalWrite(ledPin, LOW);`
			`delay(cm);`
			`}`

			`long microsecondsToInches(long microseconds)`
			`{`
			`// According to Parallax's datasheet for the PING))), there are`
			`// 73.746 microseconds per inch (i.e. sound travels at 1130 feet per`
			`// second). This gives the distance travelled by the ping, outbound`
			`// and return, so we divide by 2 to get the distance of the obstacle.`
			`// See: http://www.parallax.com/dl/docs/prod/acc/28015-PING-v1.3.pdf`
			`return microseconds / 74 / 2;`
			`}`

			`long microsecondsToCentimeters(long microseconds)`
			`{`
			`// The speed of sound is 340 m/s or 29 microseconds per centimeter.`
			`// The ping travels out and back, so to find the distance of the`
			`// object we take half of the distance travelled.`
			`return microseconds / 29 / 2;`
			`}`