Barometer program : Data Logger function includes Barometer & temperature (BMP180), Humidity & temp. (RHT03), Sunshine (Cds), RTC(M41T62) data. : Logging data saves into EEPROM (AT24C1024) using ring buffer function.
Dependencies: AT24C1024 RHT03 TextLCD BMP180 M41T62
Fork of mbed_blinky by
Please see https://mbed.org/users/kenjiArai/notebook/mbed-lpc1114fn28-barometer-with-data-logging/#
main.cpp
- Committer:
- kenjiArai
- Date:
- 2014-06-22
- Revision:
- 13:950adc9d6d61
- Parent:
- 12:1e21119688fe
- Child:
- 14:18a98cad6109
File content as of revision 13:950adc9d6d61:
/* * mbed Application program for the mbed LPC1114FN28 * Test program -> Check RTC module * * Copyright (c) 2014 Kenji Arai / JH1PJL * http://www.page.sannet.ne.jp/kenjia/index.html * http://mbed.org/users/kenjiArai/ * Created: June 13th, 2014 * Revised: June 22nd, 2014 * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, * INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE * AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, * DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, * OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. */ #include "mbed.h" #include "BMP180.h" // Own lib. / Pressure sensor #include "RHT03.h" // Std. lib./ Humidity sensor #include "TextLCD.h" // Std. lib./ LCD control #include "AT24C1024.h" // Own lib. / EEPROM control #include "m41t62_rtc.h" // Own lib. / RTC control #define USE_C_STD_LIB 1 #define VREF_VOLT 2.482 // TA76431F Vref real measued data #define R_FIX 9930 // 10K ohm <- real measued data #define VOL_OFFSET 3 // Offset data ,= real measured data #define CDS_TBL_SIZE 13 I2C i2c(dp5,dp27); // SDA, SCL DigitalOut myled0(dp28); // LED for Debug DigitalOut myled1(dp14); // Indicate state transition DigitalOut analog_pwr(dp6); // VCC for analog interface (vol, cds and vref) DigitalOut vref_pwr(dp4); // VCC for Vref DigitalIn sw_chng(dp1,PullUp);// SW for select DigitalIn sw_mode(dp2,PullUp);// SW for Mode change AnalogIn cds(dp11); // Input / CDS data AnalogIn vref(dp9); // Input / Bandgap 2.5V AnalogIn vol(dp10); // Input / contrast volume RHT03 humtemp(dp26); // RHT03 interface Serial pc(dp16,dp15); // UART (vertual COM) BMP180 bmp180(i2c); // Bosch sensor TextLCD_I2C_N i2clcd(&i2c, 0x7c, TextLCD::LCD8x2); // LCD(Akizuki AQM0802A) AT24C1024 at24c1024(i2c); // Atmel 1Mbit EE-PROM M41T62 m41t62(i2c); // STmicro RTC(M41T62) typedef enum {CDS = 0, VREF, VOL} ADC_Select; // ADC float av_cds, av_vref, av_vol, cal_vcc; float r_cds, lux; uint32_t nor_vol; // Humidity Sensor float humidity_temp, humidity; // EEPROM uint8_t eep_buf[256 + 2]; // Cds GL5528 (Dark Resistance 1 Mohm type) SENBA OPTICAL & ELECTRONIC CO.,LTD. // Table value referrence: http://homepage3.nifty.com/skomo/f35/hp35_20.htm const float lux_cds[CDS_TBL_SIZE][2] = {{50,21194},{100,8356},{200,3294},{400,1299},{800,512},{1600,202},{3200,79.6},{6400,31.4}, {12800,12.4},{25600,4.88},{51200,1.92},{102400,0.758},{409600,0.118}}; #if USE_C_STD_LIB == 0 const char week[7][4] = { "Mon", "Tue", "Wed", "Thu", "Fri", "Sat", "Sun"}; #endif //------------------------------------------------------------------------------------------------- // Control Program //------------------------------------------------------------------------------------------------- // Normalize ADC data void adc_normalize (ADC_Select n){ int i; float x1,y1,dx; switch (n){ case CDS: // v_adc = Rfix / (Rcds + Rfix) -> Rcds = ( Rfix / v_adc ) - Rfix r_cds = (R_FIX / av_cds) - R_FIX; // CDS resistance to Lux conversion using convertion table (luc_cds[][]) for (i =0; i < CDS_TBL_SIZE; i++){ // search table if ( r_cds <= lux_cds[i][0]){ break; } } // Check table position if (i == 0){ lux = lux_cds[0][1]; break; } else if ( i == CDS_TBL_SIZE ){ if ( r_cds <= lux_cds[i][0] ){ lux = lux_cds[i-1][1]; break; } } // Linear interpolation y1 = lux_cds[i-1][1] - lux_cds[i][1]; x1 = lux_cds[i][0] - lux_cds[i-1][0]; dx = r_cds - lux_cds[i-1][0]; lux = lux_cds[i-1][1] - ((dx/x1) * y1); break; case VREF: // vref = VREF_VOLT / VCC -> VCC = VREF_VOLT / vref cal_vcc = VREF_VOLT / vref; break; case VOL: // Vol center = 1.00 (actual 100) nor_vol = (uint32_t)(av_vol * 200) + VOL_OFFSET; break; } } // Read adc data and averaging void adc_all_read (void){ if (av_cds == 0){ av_cds = cds.read(); } else { av_cds = av_cds *0.5 + cds.read() * 0.5; } if (av_vref == 0){ av_vref = vref.read(); } else { av_vref = av_vref *0.9 + vref.read() * 0.1; } if (av_vol == 0){ av_vol = vol.read(); } else { av_vol = av_vol *0.2 + vol.read() * 0.8; } } // Read Humidity sensor data void hum_RHT03_read (void){ while (true){ // wait data if ( humtemp.readData() == RHT_ERROR_NONE ){ break; } } if (humidity_temp == 0){humidity_temp = humtemp.getTemperatureC(); } else { humidity_temp = humidity_temp * 0.9 + humtemp.getTemperatureC() * 0.1; } if ( humidity == 0 ){ humidity = humtemp.getHumidity(); } else { humidity = humidity * 0.9 + humtemp.getHumidity() * 0.1; } } // Clear LCD void cls(void){ i2clcd.locate(0, 0); i2clcd.printf(" "); i2clcd.locate(0, 1); i2clcd.printf(" "); } // Set initial time void set_initial_time (void){ // Set Initial data -> 2014/06/22 10:20:00 #if USE_C_STD_LIB struct tm t; m41t62.read_rtc_std(&t); if ((sw_chng == 0) && (sw_mode == 0)){ t.tm_sec = 0; t.tm_min = 20; t.tm_hour = 10; t.tm_mday = 22; t.tm_wday = 0; // Sun is not 7 but 0 t.tm_mon = 5; // Jan. = 0 t.tm_year = 14 + 100; // 1900+x = now m41t62.write_rtc_std(&t); } #else rtc_time t; m41t62.read_rtc_direct(&t); if ((sw_chng == 0) && (sw_mode == 0)){ t.rtc_seconds = 0; t.rtc_minutes = 20; t.rtc_hours = 10; t.rtc_date = 22; t.rtc_weekday = RTC_Wk_Sunday; t.rtc_month = 6; t.rtc_year_raw= 14; m41t62.write_rtc_direct(&t); } #endif } //------------------------------------- // Application program starts here //------------------------------------- int main() { pc.baud(9600); pc.printf("\r\nmbed LPC1114FN28 test program by JH1PJL created on "__DATE__"(UTC)\r\n"); i2clcd.setContrast(25); i2clcd.locate(0, 0); i2clcd.printf("LPC1114F"); i2clcd.locate(0, 1); i2clcd.printf(" JH1PJL "); // Initialize data av_cds = 0; av_vref = 0; av_vol = 0; humidity_temp = 0; humidity = 0; // RTC m41t62.set_sq_wave(RTC_SQW_NONE); set_initial_time(); // Show initial screen wait(5.0); while(1) { // ---------- Cds Sensor, Vref, Volume --------------------------------------------------- // Power on / Analog sensor analog_pwr = 1; vref_pwr = 1; wait(0.2); adc_all_read(); // Power off / Analog sensor analog_pwr = 0; // Normalize adc_normalize(CDS); adc_normalize(VREF); adc_normalize(VOL); cls(); i2clcd.locate(0, 0); // 1st line top // 12345678 i2clcd.printf("L:%.1f", lux); i2clcd.locate(0, 1); // 2nd line top i2clcd.printf("V:%.3f", cal_vcc); myled0 = 1; pc.printf( "\r\nCds:%.0fohm->%.1flux, Vcc:%.3fV, Vol:%d\r\n", r_cds, lux, cal_vcc, nor_vol ); myled0 = 0; wait(4.0); // ---------- Barometer Sensor / BMP180 -------------------------------------------------- bmp180.normalize(); cls(); i2clcd.locate(0, 0); // 1st line top i2clcd.printf("P:%.1f", bmp180.read_pressure()); i2clcd.locate(0, 1); // 2nd line top i2clcd.printf("T:%\+-6.1f", bmp180.read_temperature()); myled1 = 1; pc.printf("Pres:%4.1fhPa, Temp:%\+-0.1fdegC\r\n", bmp180.read_pressure(), bmp180.read_temperature()); myled1 = 0; wait(4.0); // ---------- Humidity Sensor / RHT03 ---------------------------------------------------- hum_RHT03_read(); // Read Humidity data then avaraging cls(); i2clcd.locate(0, 0); // 1st line top i2clcd.printf("H:%.1f", humidity); i2clcd.locate(0, 1); // 2nd line top i2clcd.printf("T:%\+-6.1f", humidity_temp); myled1 = 1; pc.printf("Humid: %0.1f%%RH, Temp:%\+-0.1fdegC\r\n", humidity, humidity_temp); myled1 = 0; wait(4.0); // ---------- Check RTC ------------------------------------------------------------------ #if USE_C_STD_LIB tm t; time_t seconds; char buf[40]; m41t62.read_rtc_std(&t); seconds = mktime(&t); cls(); i2clcd.locate(0, 0); // 1st line top i2clcd.printf("%02d/%02d/%02d", t.tm_year % 100, t.tm_mon, t.tm_mday); i2clcd.locate(0, 1); // 2nd line top i2clcd.printf("%02d:%02d:%02d", t.tm_hour, t.tm_min, t.tm_sec); myled1 = 1; // Show Time with several example // ex.1 pc.printf("Date: %04d/%02d/%02d, %02d:%02d:%02d\r\n", t.tm_year + 1900, t.tm_mon, t.tm_mday, t.tm_hour, t.tm_min, t.tm_sec); // ex.2 strftime(buf, 40, "%x %X", localtime(&seconds)); printf("Date: %s\r\n", buf); // ex.3 strftime(buf, 40, "%I:%M:%S %p (%Y/%m/%d)", localtime(&seconds)); printf("Date: %s\r\n", buf); // ex.4 strftime(buf, 40, "%B %d,'%y, %H:%M:%S", localtime(&seconds)); printf("Date: %s\r\n", buf); myled1 = 0; wait(4.0); #else rtc_time t; m41t62.read_rtc_direct(&t); cls(); i2clcd.locate(0, 0); // 1st line top i2clcd.printf("%02d/%02d/%02d", t.rtc_year, t.rtc_month, t.rtc_date); i2clcd.locate(0, 1); // 2nd line top i2clcd.printf("%02d:%02d:%02d", t.rtc_hours, t.rtc_minutes, t.rtc_seconds); myled1 = 1; pc.printf("Date:%04d/%02d/%02d(%s), Time:%02d:%02d:%02d\r\n", t.rtc_year, t.rtc_month, t.rtc_date, &week[t.rtc_weekday-1][0], t.rtc_hours, t.rtc_minutes, t.rtc_seconds); myled1 = 0; wait(4.0); #endif } }