PCB_Analog_Values
Dependencies: mbed LoRaWAN-lib SX1276Lib
Revision 12:8d057a5bf72e, committed 2020-01-30
- Comitter:
- amirchaudhary
- Date:
- Thu Jan 30 13:51:38 2020 +0000
- Parent:
- 11:9e35ddff7ed8
- Commit message:
- Analog Values Reading (Emerg Lights)
Changed in this revision
app/main.cpp | Show annotated file Show diff for this revision Revisions of this file |
--- a/app/main.cpp Mon Jan 07 17:08:38 2019 +0000 +++ b/app/main.cpp Thu Jan 30 13:51:38 2020 +0000 @@ -3,12 +3,14 @@ #include "SerialDisplay.h" -AnalogIn Vbat(A1); -AnalogIn Led1(A2); -AnalogIn Led2(A5); +AnalogIn Vbat(PA_4); +AnalogIn Led1(PA_1); +AnalogIn Led2(PC_0); AnalogIn RM(PC_2); AnalogIn Vce(PB_1); - +DigitalOut Relay(D6); +AnalogIn Exit(PC_4); +//AnalogIn Exit2(PC_5); /** * Main application entry point. @@ -78,21 +80,134 @@ } int main() -{ +{ pc.printf("mbed-os-rev: %d.%d.%d lib-rev: %d\r\n", \ MBED_MAJOR_VERSION, MBED_MINOR_VERSION,MBED_PATCH_VERSION,MBED_LIBRARY_VERSION); pc.printf("BUILD= %s, SysClock= %d, RCC= %0X\r\n", __TIME__, SystemCoreClock, RCC->CR); my_patch(); pc.printf("NEW SysClock= %d, NEW RCC= %0X\r\n", SystemCoreClock, RCC->CR); - wait(3); + wait(1); printf("\n"); printf("\n"); - int min=0; - float meas_Vbat,meas_Led1,meas_Led2,meas_RM,meas_Vce; - float v_Vbat,v_Led1,v_Led2,v_RM,v_Vce; + int min=0,count=0; + + float meas_Vbat,meas_Led1,meas_Led2,meas_RM,meas_Vce,meas_Exit,meas_Exit2; + float v_Vbat,v_Led1,v_Led2,v_RM,v_Vce,v_Exit,v_Exit2; // float meas_v; + + + + pc.printf("***Charging Mode***\n\n"); + Relay= 0; // Start the test Relay =1 + +// printf("\tAnalogIn example\n"); + printf("count"); + printf("\tVbat"); + printf("\tLED1"); + printf("\tLED2"); + printf("\tRM"); + printf("\tVce"); + printf("\tExit"); + // printf("\tExit2"); + printf("\n"); + + + for(int j=0;j<=300;j++){ + meas_Vbat = Vbat.read(); // Read the analog input value (value from 0.0 to 1.0 = full ADC conversion range) + meas_Led1 = Led1.read() - Vce.read(); // Read the analog input value (value from 0.0 to 1.0 = full ADC conversion range) + meas_Led2 = Led2.read() - Vce.read(); + meas_RM = RM.read() - Vce.read(); + meas_Vce = Vce.read(); + meas_Exit = Exit.read(); + // meas_Exit2 = Exit2.read(); + + + + // Display readings + v_Vbat = meas_Vbat * 3300 *2; + v_Led1 = (meas_Led1 * 3.300)/2.2; + v_Led2 = (meas_Led2 * 3.300)/2.2; + v_RM = (meas_RM * 3.300)/2.2; + v_Vce = meas_Vce * 3.300; + v_Exit = meas_Exit * 3.300/24; + // v_Exit2 = meas_Exit2 * 3.300/2.2; + + + printf("%d\t", count); + printf("%.0f\t", v_Vbat); + printf("%.03f\t", v_Led1); + printf("%.03f\t", v_Led2); + printf("%.03f\t", v_RM); + printf("%.03f\t", v_Vce); + printf("%.03f\t",v_Exit); + // printf("%.03f\t",v_Exit2); + printf("\n"); + + count++; + wait(0.1); // 10 second + +} + count = 0; + + + pc.printf("***Discharging Mode 1***\n\n"); + Relay= 0; // Start the test Relay =1 + +// printf("\tAnalogIn example\n"); + printf("count"); + printf("\tVbat"); + printf("\tLED1"); + printf("\tLED2"); + printf("\tRM"); + printf("\tVce"); + printf("\tExit"); + // printf("\tExit2"); + printf("\n"); + + + for(int j=0;j<=300;j++){ + meas_Vbat = Vbat.read(); // Read the analog input value (value from 0.0 to 1.0 = full ADC conversion range) + meas_Led1 = Led1.read() - Vce.read(); // Read the analog input value (value from 0.0 to 1.0 = full ADC conversion range) + meas_Led2 = Led2.read() - Vce.read(); + meas_RM = RM.read() - Vce.read(); + meas_Vce = Vce.read(); + meas_Exit = Exit.read(); + // meas_Exit2 = Exit2.read(); + + + + // Display readings + v_Vbat = meas_Vbat * 3300 *2; + v_Led1 = (meas_Led1 * 3.300)/2.2; + v_Led2 = (meas_Led2 * 3.300)/2.2; + v_RM = (meas_RM * 3.300)/2.2; + v_Vce = meas_Vce * 3.300; + v_Exit = meas_Exit * 3.300/24; + // v_Exit2 = meas_Exit2 * 3.300/2.2; + + + printf("%d\t", count); + printf("%.0f\t", v_Vbat); + printf("%.03f\t", v_Led1); + printf("%.03f\t", v_Led2); + printf("%.03f\t", v_RM); + printf("%.03f\t", v_Vce); + printf("%.03f\t",v_Exit); + // printf("%.03f\t",v_Exit2); + printf("\n"); + + count++; + wait(0.1); // 10 second +} + + + + + printf("\n"); + printf("\n"); + pc.printf("***Discharging Mode 2***\n\n"); // printf("\tAnalogIn example\n"); printf("min"); printf("\tVbat"); @@ -100,34 +215,45 @@ printf("\tLED2"); printf("\tRM"); printf("\tVce"); + printf("\tExit"); + // printf("\tExit2"); printf("\n"); - while(1) { - + Relay= 0; // Start the test Relay =1 + meas_Vbat = Vbat.read(); // Read the analog input value (value from 0.0 to 1.0 = full ADC conversion range) - meas_Led1 = Led1.read(); // Read the analog input value (value from 0.0 to 1.0 = full ADC conversion range) - meas_Led2 = Led2.read(); - meas_RM = RM.read(); + meas_Led1 = Led1.read() - Vce.read(); // Read the analog input value (value from 0.0 to 1.0 = full ADC conversion range) + meas_Led2 = Led2.read() - Vce.read(); + meas_RM = RM.read() - Vce.read(); meas_Vce = Vce.read(); - - // Display readings - v_Vbat = meas_Vbat*3300*2; - v_Led1 = meas_Led1*3300; - v_Led2 = meas_Led2*3300; - v_RM = meas_RM*3300; - v_Vce = meas_Vce*3300; + meas_Exit = Exit.read(); + // meas_Exit2 = Exit2.read(); + + + // Display readings + v_Vbat = meas_Vbat * 3300 *2; + v_Led1 = (meas_Led1 * 3.300)/2.2; + v_Led2 = (meas_Led2 * 3.300)/2.2; + v_RM = (meas_RM * 3.300)/2.2; + v_Vce = meas_Vce * 3.300; + v_Exit = meas_Exit * 3.300/24; + // v_Exit2 = meas_Exit2 * 3.300/2.2; printf("%d\t", min); printf("%.0f\t", v_Vbat); - printf("%.0f\t", v_Led1); - printf("%.0f\t", v_Led2); - printf("%.0f\t", v_RM); - printf("%.0f\n", v_Vce); + printf("%.03f\t", v_Led1); + printf("%.03f\t", v_Led2); + printf("%.03f\t", v_RM); + printf("%.03f\t", v_Vce); + printf("%.03f\t",v_Exit); + // printf("%.03f\t",v_Exit2); + printf("\n"); - - wait(5.0); // 1 second + + wait(5.0); // 10 second min++; } + }