Hux Connect
Test firmware for the Supermote hardware.
Dependencies: K30_I2C libxDot-mbed5
Fork of
K30_I2C_Program
by 
Hux Connect
Diff: main.cpp
- Revision:
- 2:680fc2690d10
- Parent:
- 0:85741f91edf0
- Child:
- 3:2ab969b31f6b
diff -r 15a68a12eb1e -r 680fc2690d10 main.cpp
--- a/main.cpp Fri Aug 17 07:25:00 2018 +0000
+++ b/main.cpp Fri Sep 07 02:54:05 2018 +0000
@@ -1,74 +1,164 @@
#include "mbed.h"
#include "mDot.h"
#include "ChannelPlans.h"
-#include "K30_I2C.h"
+
+//#define TEST_HPM // particle
+//#define TEST_MICS_VZ_89TE // voc
+#define TEST_SPEC_3SP_CO // CO
+#define TEST_K30 // CO2 sensor
+
+#ifdef TEST_HPM
+ #include "hpm.h"
+#endif
+
+#ifdef TEST_MICS_VZ_89TE
+ #include "mics_vz_89te.h"
+#endif
+
+#ifdef TEST_SPEC_3SP_CO
+ #include "spec_3sp_co.h"
+#endif
+
+#ifdef TEST_K30
+ #include "K30_I2C.h"
+#endif
mDot* dot = NULL;
+Serial pc (USBTX, USBRX); // xDot USB interface
+Serial device (UART_TX, UART_RX); // xDot UART to sensors
+bool need5v = false;
-Serial pc(USBTX,USBRX); // xDot dev board
-//Serial pc(PA_2, PA_3); // Murata dev board
-K30_I2C k30(I2C_SDA, I2C_SCL, 0x68<<1); // xDot dev board
-//K30_I2C k30(PB_9, PB_8, 0x68<<1); // Muarata dev board
-//AnalogIn HCHO(PB_14);
+#ifdef TEST_HPM
+ HPM hpm = HPM::HPM(&device, &pc);
+ long int PM25;
+ long int PM10;
+#endif
+
+#ifdef TEST_MICS_VZ_89TE
+ MICS_VZ_89TE sensor_voc = MICS_VZ_89TE::MICS_VZ_89TE(I2C_SDA, I2C_SCL, 0x70<<1);
+ int co2_fromVOC = 0;
+ int voc = 0;
+#endif
+
+#ifdef TEST_SPEC_3SP_CO
+ SPEC_3SP_CO sensor_co = SPEC_3SP_CO::SPEC_3SP_CO(I2C_SDA, I2C_SCL, ADS1x1x_I2C_ADDRESS_ADDR_TO_VCC<<1, 3.29);
+ int co = 0;
+#endif
+
+#ifdef TEST_K30
+ K30_I2C k30(I2C_SDA, I2C_SCL, 0x68<<1); // xDot dev board
+ int co2 = 0;
+#endif
-DigitalOut blueLED (GPIO0);
-DigitalOut orangeLED (GPIO1);
-DigitalOut enable_5V (GPIO3);
+DigitalOut blueLED (GPIO0);
+DigitalOut orangeLED (GPIO1);
+DigitalOut enable_5V (GPIO3);
+DigitalOut enable_voc (UART_RTS);
+DigitalOut enable_co (SPI_SCK);
+
+bool b_response;
+
+void turnOn5v(void)
+{
+ pc.printf("Turning on 5v rail...");
+ enable_5V = true;
+ wait(1);
+ pc.printf("done\r\n");
+}
+
+void turnOffv(void)
+{
+ pc.printf("Turning off 5v rail...");
+ enable_5V = false;
+ wait(1);
+ pc.printf("done\r\n");
+}
int main (){
- lora::ChannelPlan * plan = new lora::ChannelPlan_AS923();
- dot = mDot::getInstance(plan);
-
- pc.baud(115200);
- pc.printf("**************************\r\n");
- pc.printf("\tCO2 Sensor\r\n");
- pc.printf("**************************\r\n");
-
- enable_5V = true;
+
+ // Initialising
+ blueLED = true;
+ orangeLED = false;
+
+ //lora::ChannelPlan * plan = new lora::ChannelPlan_AS923();
+ //dot = mDot::getInstance(plan);
+ //dot->setAdr(true);
+
+ pc.baud(57600); // start debug port
+ pc.printf("************************\r\n");
+ pc.printf(" HARDWARE TEST FIRMWARE\r\n");
+ pc.printf("************************\r\n\r\n");
+
+
+#ifdef TEST_HPM
+ turnOn5v();
+ b_response = hpm.init();
+#endif
+
+#ifdef TEST_MICS_VZ_89TE
+ pc.printf("Enabling MICS_VZ_89TE...");
+ enable_voc = true;
+ wait(1);
+ pc.printf("done\r\n");
- blueLED = orangeLED = true;
- dot->setAdr(true);
- dot->sleep(3,dot->RTC_ALARM,false);
-// k30.scan(); // Careful; has potential to cause breakage of system
+ sensor_voc.getVersion();
+#endif
+
+#ifdef TEST_SPEC_3SP_CO
+ pc.printf("Enabling SPEC_3SP_CO...");
+ enable_co = true;
+ wait(1);
+ pc.printf("done\r\n");
+
+ sensor_co.init();
+#endif
+
+#ifdef TEST_K30
+ turnOn5v();
+#endif
- int co2;
- int rc_check;
- int counter = 0;
- bool counterFail = false;
-
orangeLED = blueLED = false;
- while(1){
- dot->sleep(2,dot->RTC_ALARM,false);
- blueLED = orangeLED = !orangeLED;
-// k30.scan();
-// wait(7.0f);
-// pc.printf("**********************\r\n");
-// pc.printf("Reading CH2O sensor ...... \r\n");
-// ch2o_ppm = HCHO.read()*3.125*3.6 - 1.25;
-// pc.printf("Formaldehyde Level: %.3f ppm\r\n\n", ch2o_ppm);
-
- pc.printf("Reading K30 sensor ...... \r\n");
- rc_check = k30.readCO2(co2);
-
-// pc.printf("%d \r\n", rc_check);
+ while(1)
+ {
+#ifdef TEST_HPM
+ b_response = hpm.read_measurement(PM25, PM10);
+ if (b_response)
+ {
+ pc.printf ("PM2.5 = %d ug/m3, PM10 = %d ug/m3\r\n", PM25, PM10);
+ }
+ else
+ {
+ pc.printf("Read measurement status is %d\r\n", b_response);
+ }
+#endif
- if (rc_check&&co2){
- pc.printf("Successful reading\r\nCO2:\t%d ppm\r\n",co2);
- if(!co2){
- counterFail = true;
- }
- if(!counterFail) {
- counter++;
- pc.printf("Success Count: %d\r\n", counter);
- }
- else pc.printf("Failure at: %d\r\n", counter);
- }
- else{
- pc.printf("Failure to read sensor \r\n");
- pc.printf("Last count: %d\r\n", counter);
- counterFail = true;
- }
+#ifdef TEST_MICS_VZ_89TE
+ char status = sensor_voc.readSensor(co2_fromVOC, voc);
+ pc.printf ("MICS_VZ_89TE: CO2=%d ppm, VOC%d ppb (status=%02x)\r\n", co2_fromVOC, voc, status);
+#endif
+
+#ifdef TEST_SPEC_3SP_CO
+ sensor_co.start_conversion();
+ // wait 7.8ms
+ wait(0.01);
+
+ float co_ppm = sensor_co.read();
+ pc.printf ("SPEC_3SP_CO: CO=%.2fppm\r\n", co_ppm);
+#endif
+
+#ifdef TEST_K30
+ int rc_check;
+ rc_check = k30.readCO2(co2);
+ if (rc_check)
+ pc.printf("K30 CO2:%d ppm\r\n",co2);
+ else
+ pc.printf("Failed to read CO2 sensor\r\n");
+#endif
+
+ wait (1);
+ blueLED = !blueLED;
+ pc.printf ("\r\n");
}
}
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