/* SCP1000 Barometric Pressure Sensor Display Serves the output of a Barometric Pressure Sensor as a web page. Uses the SPI library. For details on the sensor, see: http://www.sparkfun.com/commerce/product_info.php?products_id=8161 This sketch adapted from Nathan Seidle's SCP1000 example for PIC: http://www.sparkfun.com/datasheets/Sensors/SCP1000-Testing.zip Circuit: SCP1000 sensor attached to pins 6,7, and 11 - 13: DRDY: pin 6 CSB: pin 7 MOSI: pin 11 MISO: pin 12 SCK: pin 13 created 31 July 2010 by Tom Igoe */ #include // the sensor communicates using SPI, so include the library: #include // assign a MAC address for the Ethernet controller. // fill in your address here: byte mac[] = { 0xDE, 0xAD, 0xBE, 0xEF, 0xFE, 0xED }; // assign an IP address for the controller: IPAddress ip(192, 168, 1, 20); // Initialize the Ethernet server library // with the IP address and port you want to use // (port 80 is default for HTTP): EthernetServer server(80); //Sensor's memory register addresses: const int PRESSURE = 0x1F; //3 most significant bits of pressure const int PRESSURE_LSB = 0x20; //16 least significant bits of pressure const int TEMPERATURE = 0x21; //16 bit temperature reading // pins used for the connection with the sensor // the others you need are controlled by the SPI library): const int dataReadyPin = 6; const int chipSelectPin = 7; float temperature = 0.0; long pressure = 0; long lastReadingTime = 0; void setup() { // start the SPI library: SPI.begin(); // start the Ethernet connection and the server: Ethernet.begin(mac, ip); server.begin(); // initalize the data ready and chip select pins: pinMode(dataReadyPin, INPUT); pinMode(chipSelectPin, OUTPUT); Serial.begin(9600); //Configure SCP1000 for low noise configuration: writeRegister(0x02, 0x2D); writeRegister(0x01, 0x03); writeRegister(0x03, 0x02); // give the sensor and Ethernet shield time to set up: delay(1000); //Set the sensor to high resolution mode tp start readings: writeRegister(0x03, 0x0A); } void loop() { // check for a reading no more than once a second. if (millis() - lastReadingTime > 1000) { // if there's a reading ready, read it: // don't do anything until the data ready pin is high: if (digitalRead(dataReadyPin) == HIGH) { getData(); // timestamp the last time you got a reading: lastReadingTime = millis(); } } // listen for incoming Ethernet connections: listenForEthernetClients(); } void getData() { Serial.println("Getting reading"); //Read the temperature data int tempData = readRegister(0x21, 2); // convert the temperature to celsius and display it: temperature = (float)tempData / 20.0; //Read the pressure data highest 3 bits: byte pressureDataHigh = readRegister(0x1F, 1); pressureDataHigh &= 0b00000111; //you only needs bits 2 to 0 //Read the pressure data lower 16 bits: unsigned int pressureDataLow = readRegister(0x20, 2); //combine the two parts into one 19-bit number: pressure = ((pressureDataHigh << 16) | pressureDataLow) / 4; Serial.print("Temperature: "); Serial.print(temperature); Serial.println(" degrees C"); Serial.print("Pressure: " + String(pressure)); Serial.println(" Pa"); } void listenForEthernetClients() { // listen for incoming clients EthernetClient client = server.available(); if (client) { Serial.println("Got a client"); // an http request ends with a blank line boolean currentLineIsBlank = true; while (client.connected()) { if (client.available()) { char c = client.read(); // if you've gotten to the end of the line (received a newline // character) and the line is blank, the http request has ended, // so you can send a reply if (c == '\n' && currentLineIsBlank) { // send a standard http response header client.println("HTTP/1.1 200 OK"); client.println("Content-Type: text/html"); client.println(); // print the current readings, in HTML format: client.print("Temperature: "); client.print(temperature); client.print(" degrees C"); client.println("
"); client.print("Pressure: " + String(pressure)); client.print(" Pa"); client.println("
"); break; } if (c == '\n') { // you're starting a new line currentLineIsBlank = true; } else if (c != '\r') { // you've gotten a character on the current line currentLineIsBlank = false; } } } // give the web browser time to receive the data delay(1); // close the connection: client.stop(); } } //Send a write command to SCP1000 void writeRegister(byte registerName, byte registerValue) { // SCP1000 expects the register name in the upper 6 bits // of the byte: registerName <<= 2; // command (read or write) goes in the lower two bits: registerName |= 0b00000010; //Write command // take the chip select low to select the device: digitalWrite(chipSelectPin, LOW); SPI.transfer(registerName); //Send register location SPI.transfer(registerValue); //Send value to record into register // take the chip select high to de-select: digitalWrite(chipSelectPin, HIGH); } //Read register from the SCP1000: unsigned int readRegister(byte registerName, int numBytes) { byte inByte = 0; // incoming from the SPI read unsigned int result = 0; // result to return // SCP1000 expects the register name in the upper 6 bits // of the byte: registerName <<= 2; // command (read or write) goes in the lower two bits: registerName &= 0b11111100; //Read command // take the chip select low to select the device: digitalWrite(chipSelectPin, LOW); // send the device the register you want to read: int command = SPI.transfer(registerName); // send a value of 0 to read the first byte returned: inByte = SPI.transfer(0x00); result = inByte; // if there's more than one byte returned, // shift the first byte then get the second byte: if (numBytes > 1) { result = inByte << 8; inByte = SPI.transfer(0x00); result = result | inByte; } // take the chip select high to de-select: digitalWrite(chipSelectPin, HIGH); // return the result: return (result); }