Alex Leung
/
HealthTracker
Test version
Diff: main.cpp
- Revision:
- 0:4be500de690c
- Child:
- 1:bd9f39f9d91c
diff -r 000000000000 -r 4be500de690c main.cpp --- /dev/null Thu Jan 01 00:00:00 1970 +0000 +++ b/main.cpp Tue Mar 20 02:09:21 2018 +0000 @@ -0,0 +1,153 @@ +#include "mbed.h" +#include "algorithm.h" +#include "MAX30102.h" +#include "LEDS.h" +#include "WIFI.h" + +#define MAX_BRIGHTNESS 255 +extern int* ReadDS1621(void); +uint32_t aun_ir_buffer[500]; //IR LED sensor data +int32_t n_ir_buffer_length; //data length +uint32_t aun_red_buffer[500]; //Red LED sensor data +int32_t n_sp02; //SPO2 value +int8_t ch_spo2_valid; //indicator to show if the SP02 calculation is valid +int32_t n_heart_rate; //heart rate value +int8_t ch_hr_valid; //indicator to show if the heart rate calculation is valid +uint8_t uch_dummy; + +Serial pc(USBTX, USBRX); //initializes the serial port, TX-PA2, RX-PA3 + +PwmOut pwmled(PA_10); //initializes the pwm output PB3 that connects to the LED +DigitalIn INT(PC_5); //pin PB7 connects to the interrupt output pin of the MAX30102 +DigitalOut led(PC_9); //PC13 connects to the on board user LED +AnalogIn xd(PA_0); +AnalogIn yd(PA_1); +AnalogIn zd(PA_4); + +// the setup routine runs once when you press reset: +int main() { + uint32_t un_min, un_max, un_prev_data; //variables to calculate the on-board LED brightness that reflects the heartbeats + int i; + int32_t n_brightness; + float f_temp; + int* temp; + + maxim_max30102_reset(); //resets the MAX30102 + + // initialize serial communication at 115200 bits per second: + //pc.baud(115200); + //while(1); + //pc.format(8,SerialBase::None,1); + wait(5); + //init wifi + scan_demo(&wifi); + int ret = wifi.connect("Wo4G-YDL0", "by353006", NSAPI_SECURITY_WPA_WPA2); + if (ret != 0) { + pc.printf("\r\nConnection error\r\n"); + return -1; + } + + //wifi.disconnect(); + //read and clear status register + maxim_max30102_read_reg(0,&uch_dummy); + + maxim_max30102_init(); //initializes the MAX30102 + + + n_brightness=0; + un_min=0x3FFFF; + un_max=0; + + n_ir_buffer_length=500; //buffer length of 100 stores 5 seconds of samples running at 100sps + + //read the first 500 samples, and determine the signal range + for(i=0;i<n_ir_buffer_length;i++) + { + while(INT.read()==1); //wait until the interrupt pin asserts + + maxim_max30102_read_fifo((aun_red_buffer+i), (aun_ir_buffer+i)); //read from MAX30102 FIFO + + if(un_min>aun_red_buffer[i]) + un_min=aun_red_buffer[i]; //update signal min + if(un_max<aun_red_buffer[i]) + un_max=aun_red_buffer[i]; //update signal max + //pc.printf("red=%i", aun_red_buffer[i]); + //pc.printf(", ir=%i\n", aun_ir_buffer[i]); + wait(0.01); + } + un_prev_data=aun_red_buffer[i]; + + + //calculate heart rate and SpO2 after first 500 samples (first 5 seconds of samples) + maxim_heart_rate_and_oxygen_saturation(aun_ir_buffer, n_ir_buffer_length, aun_red_buffer, &n_sp02, &ch_spo2_valid, &n_heart_rate, &ch_hr_valid); + + //Continuously taking samples from MAX30102. Heart rate and SpO2 are calculated every 1 second + while(1) + { + i=0; + un_min=0x3FFFF; + un_max=0; + + //dumping the first 100 sets of samples in the memory and shift the last 400 sets of samples to the top + for(i=100;i<500;i++) + { + aun_red_buffer[i-100]=aun_red_buffer[i]; + aun_ir_buffer[i-100]=aun_ir_buffer[i]; + + //update the signal min and max + if(un_min>aun_red_buffer[i]) + un_min=aun_red_buffer[i]; + if(un_max<aun_red_buffer[i]) + un_max=aun_red_buffer[i]; + } + + //take 100 sets of samples before calculating the heart rate. + for(i=400;i<500;i++) + { + un_prev_data=aun_red_buffer[i-1]; + while(INT.read()==1); + maxim_max30102_read_fifo((aun_red_buffer+i), (aun_ir_buffer+i)); + + if(aun_red_buffer[i]>un_prev_data)//just to determine the brightness of LED according to the deviation of adjacent two AD data + { + f_temp=aun_red_buffer[i]-un_prev_data; + f_temp/=(un_max-un_min); + f_temp*=MAX_BRIGHTNESS; + n_brightness-=(int)f_temp; + if(n_brightness<0) + n_brightness=0; + } + else + { + f_temp=un_prev_data-aun_red_buffer[i]; + f_temp/=(un_max-un_min); + f_temp*=MAX_BRIGHTNESS; + n_brightness+=(int)f_temp; + if(n_brightness>MAX_BRIGHTNESS) + n_brightness=MAX_BRIGHTNESS; + } + + pwmled.write(1-(float)n_brightness/256);//pwm control led brightness + if(n_brightness<120) + led=1; + else + led=0; + + //send samples and calculation result to terminal program through UART + //pc.printf("red="); + //pc.printf("%i", aun_red_buffer[i]); + //pc.printf(", ir="); + //pc.printf("%i", aun_ir_buffer[i]); + temp = ReadDS1621(); + http_demo(&wifi); + LightLEDs(n_heart_rate); + //pc.printf("HR=%i, temperature=%i:%i,SpO2=%i,x=%f,y=%f,z=%f\n", n_heart_rate,temp[0],temp[1],n_sp02,xd.read(),yd.read(),zd.read()); + //pc.printf("HR=%i\n", n_heart_rate); + //pc.printf("HRvalid=%i, ", ch_hr_valid); + //pc.printf("SpO2=%i, ", n_sp02); + //pc.printf("SPO2Valid=%i\n\r", ch_spo2_valid); + } + maxim_heart_rate_and_oxygen_saturation(aun_ir_buffer, n_ir_buffer_length, aun_red_buffer, &n_sp02, &ch_spo2_valid, &n_heart_rate, &ch_hr_valid); + wait(0.01); + } +}