/* * bmp180.c: * Extend wiringPi with the BMP180 I2C Pressure and Temperature * sensor. This is used in the Pi Weather Station * Copyright (c) 2016 Gordon Henderson * * Information from the document held at: * http://wmrx00.sourceforge.net/Arduino/BMP085-Calcs.pdf * was very useful when building this code. * *********************************************************************** * This file is part of wiringPi: * https://github.com/WiringPi/WiringPi/ * * wiringPi is free software: you can redistribute it and/or modify * it under the terms of the GNU Lesser General Public License as * published by the Free Software Foundation, either version 3 of the * License, or (at your option) any later version. * * wiringPi is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with wiringPi. * If not, see . *********************************************************************** */ #include #include #include #include #include "wiringPi.h" #include "wiringPiI2C.h" #include "bmp180.h" #undef DEBUG #define I2C_ADDRESS 0x77 #define BMP180_OSS 0 // Static calibration data // The down-side of this is that there can only be one BMP180 in // a system - which is practice isn't an issue as it's I2C // address is fixed. static int16_t AC1, AC2, AC3 ; static uint16_t AC4, AC5, AC6 ; static int16_t VB1, VB2 ; static int16_t MB, MC, MD ; static double c5, c6, mc, md, x0, x1, x2, yy0, yy1, yy2, p0, p1, p2 ; // Pressure & Temp variables uint32_t cPress, cTemp ; static int altitude ; /* * read16: * Quick hack to read the 16-bit data with the correct endian ********************************************************************************* */ uint16_t read16 (int fd, int reg) { return (wiringPiI2CReadReg8 (fd, reg) << 8) | wiringPiI2CReadReg8 (fd, reg + 1) ; } /* * bmp180ReadTempPress: * Does the hard work of reading the sensor ********************************************************************************* */ static void bmp180ReadTempPress (int fd) { double fTemp, fPress ; double tu, a ; double pu, s, x, y, z ; uint8_t data [4] ; // Start a temperature sensor reading wiringPiI2CWriteReg8 (fd, 0xF4, 0x2E) ; delay (5) ; // Read the raw data data [0] = wiringPiI2CReadReg8 (fd, 0xF6) ; data [1] = wiringPiI2CReadReg8 (fd, 0xF7) ; // And calculate... tu = (data [0] * 256.0) + data [1] ; a = c5 * (tu - c6) ; fTemp = a + (mc / (a + md)) ; cTemp = (int)rint (((100.0 * fTemp) + 0.5) / 10.0) ; #ifdef DEBUG printf ("fTemp: %f, cTemp: %6d\n", fTemp, cTemp) ; #endif // Start a pressure snsor reading wiringPiI2CWriteReg8 (fd, 0xF4, 0x34 | (BMP180_OSS << 6)) ; delay (5) ; // Read the raw data data [0] = wiringPiI2CReadReg8 (fd, 0xF6) ; data [1] = wiringPiI2CReadReg8 (fd, 0xF7) ; data [2] = wiringPiI2CReadReg8 (fd, 0xF8) ; // And calculate... pu = ((double)data [0] * 256.0) + (double)data [1] + ((double)data [2] / 256.0) ; s = fTemp - 25.0 ; x = (x2 * pow (s, 2.0)) + (x1 * s) + x0 ; y = (yy2 * pow (s, 2.0)) + (yy1 * s) + yy0 ; z = (pu - x) / y ; fPress = (p2 * pow (z, 2.0)) + (p1 * z) + p0 ; cPress = (int)rint (((100.0 * fPress) + 0.5) / 10.0) ; #ifdef DEBUG printf ("fPress: %f, cPress: %6d\n", fPress, cPress) ; #endif } /* * myAnalogWrite: * Write to a fake register to represent the height above sea level * so that the peudo millibar register can read the pressure in mB ********************************************************************************* */ static void myAnalogWrite (struct wiringPiNodeStruct *node, int pin, int value) { int chan = pin - node->pinBase ; if (chan == 0) altitude = value ; } /* * myAnalogRead: ********************************************************************************* */ static int myAnalogRead (struct wiringPiNodeStruct *node, int pin) { int chan = pin - node->pinBase ; bmp180ReadTempPress (node->fd) ; /**/ if (chan == 0) // Read Temperature return cTemp ; else if (chan == 1) // Pressure return cPress ; else if (chan == 2) // Pressure in mB return cPress / pow (1 - ((double)altitude / 44330.0), 5.255) ; else return -9999 ; } /* * bmp180Setup: * Create a new instance of a PCF8591 I2C GPIO interface. We know it * has 4 pins, (4 analog inputs and 1 analog output which we'll shadow * input 0) so all we need to know here is the I2C address and the * user-defined pin base. ********************************************************************************* */ int bmp180Setup (const int pinBase) { double c3, c4, b1 ; int fd ; struct wiringPiNodeStruct *node ; if ((fd = wiringPiI2CSetup (I2C_ADDRESS)) < 0) return FALSE ; node = wiringPiNewNode (pinBase, 4) ; node->fd = fd ; node->analogRead = myAnalogRead ; node->analogWrite = myAnalogWrite ; // Read calibration data AC1 = read16 (fd, 0xAA) ; AC2 = read16 (fd, 0xAC) ; AC3 = read16 (fd, 0xAE) ; AC4 = read16 (fd, 0xB0) ; AC5 = read16 (fd, 0xB2) ; AC6 = read16 (fd, 0xB4) ; VB1 = read16 (fd, 0xB6) ; VB2 = read16 (fd, 0xB8) ; MB = read16 (fd, 0xBA) ; MC = read16 (fd, 0xBC) ; MD = read16 (fd, 0xBE) ; // Calculate coefficients c3 = 160.0 * pow (2.0, -15.0) * AC3 ; c4 = pow (10.0, -3.0) * pow(2.0,-15.0) * AC4 ; b1 = pow (160.0, 2.0) * pow(2.0,-30.0) * VB1 ; c5 = (pow (2.0, -15.0) / 160.0) * AC5 ; c6 = AC6 ; mc = (pow (2.0, 11.0) / pow(160.0,2.0)) * MC ; md = MD / 160.0 ; x0 = AC1 ; x1 = 160.0 * pow (2.0, -13.0) * AC2 ; x2 = pow (160.0, 2.0) * pow(2.0,-25.0) * VB2 ; yy0 = c4 * pow (2.0, 15.0) ; yy1 = c4 * c3 ; yy2 = c4 * b1 ; p0 = (3791.0 - 8.0) / 1600.0 ; p1 = 1.0 - 7357.0 * pow (2.0, -20.0) ; p2 = 3038.0 * 100.0 * pow (2.0, -36.0) ; return TRUE ; }