AND
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Sensor_iAQ_core
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main.cpp
- Committer:
- mehrnaz
- Date:
- 2019-07-25
- Revision:
- 3:3d51f8870e91
- Parent:
- 2:ef98576cd67b
- Child:
- 5:44f7dbc5c75d
File content as of revision 3:3d51f8870e91:
#include "mbed.h"
#include "flow.h"
/////////////////////////
// In this version of the program developed for the Breath project, flow and CO2, as well as 8 channel sensors,
// are measured in a separate .h file called: "flow.h" which is included in the
// main code. So 10 sets of data is streamed using a serial connection (TTL cable or Bluetooth)
// without any intruption.
// This version is especially suitable to be used for KST.
// Also, a solenoid would be turned on and off based on calculating the standard deviation in CO2 profile.
//
// START POINT: calculates SD for 9 samples of CO2, if it's grater than 0.02 it enables the solenoid.
// END POINT: calculates SD for 9 samples of CO2, if it's grater thatn 0.05 it disables the solenoid.
//
// You can easily change the threshold of Standard deviation to detect plateau
//
// Generated by: Mehrnaz Javadipour
//////////////////////////
Serial ttl(PC_12,PD_2); //TTL cable TX,RX
DigitalOut sol(PC_5); //Solenoid: Digital Output
PwmOut led(PB_6);
int main()
{
ttl.baud(9600); //baudrate for the serial connection
flow(); //calling flow from flow.h
carbon(); //calling CO2 from flow.h
s1(); //calling 8 channels from flow.h
s2();
s3();
s4();
s5();
s6();
s7();
s8();
getTemp(); //calling Temperature from flow.h
//////////////////////////////
// I defined a flag for each section of specific functions, so by enabling the
// flag the section starts and by disabling the flag it finishes the section.
// at the end of the program, I reset the flags so it would be ready for the next loop.
/////////////////////////////
int bf=0; //FLAG for detecting base flow
int i=0;
float bfArray[4]; //sampling flow for finding the average base flow
float sf=0; //sum of flow samples for calculating base flow
float fv=0; //final value of base flow
int measurement_started=0; //FLAG for starting calculations after detecting breath
int solstart=0; //FLAG for starting calculations for detecting plateau
int m=0;
int myArray[9]; //sampling 9 values of CO2
unsigned int sum=0; //sum of 9 samples of CO2
int avg=0; //average of 9 samples of CO2
int difSum=0; //used for the Standard deviation algorithm
long double var=0.0; //used for the Standard deviation algorithm
float sigma=0.0; //final value for standar deviation
int flags=0; //FLAG for keep taking samples from CO2 profile when it's too early to detect plateau
int solend=0; //FLAG for ending calculations for detecting plateau
unsigned int sum2=0; //same as before; used for finding standard deviation
long double var2=0.0;
float sigma2=0.0;
int difSum2=0;
int avg2=0;
int flage=0; //FLAG for keep taking samples from CO2 profile when it's too early to finish plateau
int fin=0;
while(1)
{
led=1.00f; //an LED is fully turned on at the beginning, the brightness will be reduced when the plateau is detected.
ttl.printf("%f,%f,%f,%f,%f,%f,%f,%f,%f,%f,%f\n",getTemp(),flow(), carbon(),s1(),s2(),s3(),s4(),s5(),s6(),s7(),s8());
if (bf==0) //finding base flow before breath
{
for(i=0; i<4; i++)
{
bfArray[i]=flow();
sf+=bfArray[i];
}
fv=sf/4;
fv=fv+0.2;
//ttl.printf("set\n");
bf=1;
}
//Starts calculations when it detects breathing into the device:
if ((flow()>fv) and (measurement_started ==0))
{
measurement_started = 1;
}
//Starts detecting plateau:
if ((measurement_started == 1) and (solstart==0))
{
//Takes 9 samples of CO2:
//I have also included printing the values inside the loops so we don't loose any data during calculatins.
for(m=0;m<9;m++)
{
ttl.printf("%f,%f,%f,%f,%f,%f,%f,%f,%f,%f,%f\n",getTemp(),flow(), carbon(),s1(),s2(),s3(),s4(),s5(),s6(),s7(),s8());
myArray[m]=carbon();
}
while(flags==0)
{
//While "flags" is enabled, keeps calculating the standard deviation.
for(int m=0;m<9;m++)
{
ttl.printf("%f,%f,%f,%f,%f,%f,%f,%f,%f,%f,%f\n",getTemp(),flow(), carbon(),s1(),s2(),s3(),s4(),s5(),s6(),s7(),s8());
sum+=myArray[m];
}
avg=sum/9;
for(int m=0;m<9;m++)
{
ttl.printf("%f,%f,%f,%f,%f,%f,%f,%f,%f,%f,%f\n",getTemp(),flow(), carbon(),s1(),s2(),s3(),s4(),s5(),s6(),s7(),s8());
difSum+=(myArray[m]-avg)*(myArray[m]-avg); //Find sum of difference between value X and mean
}
var=difSum/9;
sigma=sqrt(var);
if (sigma<0.02)
{
//if SD is less than 0.02 it means that it is too early to start the plateau
//So we shift all but the first sample and define the new set of arrays:
for(int m=0;m<8;m++)
{
ttl.printf("%f,%f,%f,%f,%f,%f,%f,%f,%f,%f,%f\n",getTemp(),flow(), carbon(),s1(),s2(),s3(),s4(),s5(),s6(),s7(),s8());
myArray[m]=myArray[m+1]; //Shift all CO2 values to the left by 1 value
}
myArray[8]=carbon(); //assign a new value for the 9th sample
}
//The new set of arrays are now generated and is sent back to be used for preveious SD calculations.
//If sigma for the new set is still small, a newer set will be generated and replaced
//Otherwise, it's accepted and will turn on the solenoid:
else
{
ttl.printf("%f,%f,%f,%f,%f,%f,%f,%f,%f,%f,%f\n",getTemp(),flow(), carbon(),s1(),s2(),s3(),s4(),s5(),s6(),s7(),s8());
sol=1; //Solenoid is ON
led=0.50f; //The brightness is reduced to half during the plateau
flags=1; //breakes the while loop
}
}
solend=1; //prepares the next section for finishing the plateau
solstart =1;
}
if ((measurement_started == 1) and (solend==1))
{
// same process happens for finishing the plateau:
for(m=0;m<9;m++)
{
ttl.printf("%f,%f,%f,%f,%f,%f,%f,%f,%f,%f,%f\n",getTemp(),flow(), carbon(),s1(),s2(),s3(),s4(),s5(),s6(),s7(),s8());
myArray[m]=carbon();
}
while(flage==0)
{
for(int m=0;m<9;m++)
{
ttl.printf("%f,%f,%f,%f,%f,%f,%f,%f,%f,%f,%f\n",getTemp(),flow(), carbon(),s1(),s2(),s3(),s4(),s5(),s6(),s7(),s8());
sum2+=myArray[m];
}
avg2=sum2/9;
for(int m=0;m<9;m++)
{
ttl.printf("%f,%f,%f,%f,%f,%f,%f,%f,%f,%f,%f\n",getTemp(),flow(), carbon(),s1(),s2(),s3(),s4(),s5(),s6(),s7(),s8());
difSum2+=(myArray[m]-avg2)*(myArray[m]-avg2);
}
var2=difSum2/9;
sigma2=sqrt(var2);
if (sigma2<0.05)
{
// here we defined the end threshold to be 0.05, it can be changed later based on experiment results
for(int m=0;m<8;m++)
{
ttl.printf("%f,%f,%f,%f,%f,%f,%f,%f,%f,%f,%f\n",getTemp(),flow(), carbon(),s1(),s2(),s3(),s4(),s5(),s6(),s7(),s8());
myArray[m]=myArray[m+1];
}
myArray[8]=carbon();
}else
{
ttl.printf("%f,%f,%f,%f,%f,%f,%f,%f,%f,%f,%f\n",getTemp(),flow(), carbon(),s1(),s2(),s3(),s4(),s5(),s6(),s7(),s8());
sol=0; //Solenoid is OFF
flage=1; //breakes the loop
}
}
solend =0; //end of this section
led=1.00f; //LED is back to full brightness
bf=0; //reset the detecting base flow flag
fin=1; //enables the next section flag
}
if((carbon()<10000) and (fin ==1))
{
//User has to wait for the CO2 level to drop less than 1% before testing again.
//Once it is less than 1%, all the flags and parameters used in calculations are reset
measurement_started =0;
solstart=0;
sum=0;
var=0.0;
sigma=0.0;
difSum=0;
sum2=0;
var2=0.0;
sigma2=0.0;
difSum2=0;
avg2=0;
avg=0;
flags=0;
flage=0;
fin=0;
}
}
}