Frederick Huang
ADXL345 Evaluation
main.cpp
- Committer:
- Frederick_H
- Date:
- 2017-09-01
- Revision:
- 5:88787a48e96e
- Parent:
- 4:f5a78245f2d0
- Child:
- 6:592373200317
File content as of revision 5:88787a48e96e:
#include "ADXL345_I2C.h"
ADXL345_I2C accelerometer(I2C_SDA, I2C_SCL);
Serial pc(USBTX, USBRX);
class RangeMapper
{
/*
RangeMapper convert data from input range to output range
Math formular is y_output = ratio * x_input + offset;
*/
protected:
double _ratio;
double _offset;
public:
RangeMapper(double x_min, double x_max, double y_min, double y_max)
{
_ratio = (y_max - y_min) / (x_max - x_min);
_offset = y_min - x_min * _ratio;
};
~RangeMapper(){};
double getOutput(double x_input)
{return x_input * _ratio + _offset;};
};
class DataProcess
{
protected:
// Statistics
int64_t _summary;
double _squardsum; // summary (xi^2)
int64_t _numbers;
int64_t _max;
int64_t _min;
// integration, assume time interval is same
int64_t _itg1; //1 order integration
int64_t _itg2; //2 order integration
int64_t _itg3; //3 order integration
// differentiation, assume time interval is same
int64_t _preData;
int64_t _dif1; //1 order differentiation
int64_t _dif2; //2 order differentiation
public:
DataProcess():
_summary(0), _squardsum(0), _numbers(0), _max(0), _min(0),
_itg1(0), _itg2(0), _itg3(0), _preData(0), _dif1(0), _dif2(0) {};
~DataProcess() {};
void putData(int64_t x) {
int64_t temp;
if (x > _max) _max = x;
if (x < _min) _min = x;
_summary += x;
_squardsum += x*x;
_numbers ++;
_itg1 += x - _summary / _numbers ;
_itg2 += _itg1;
_itg3 += _itg2;
temp = _dif1;
_dif1 = x - _preData;
_preData = x;
_dif2 = _dif1 - temp;
};
int64_t getSum(void) {return _summary;};
double getMean(void) {return (double)_summary / (double)_numbers ;};
double getStdDiv(void) {return sqrt((_squardsum - (double)_summary*_summary / (double)_numbers ) / (double)_numbers ); };
int64_t getMax(void) {return _max; };
int64_t getMin(void) {return _min; };
int64_t getCount(void) {return _numbers;} ;
int64_t getO1integration(void) {return _itg1;};
int64_t getO2integration(void) {return _itg2;};
int64_t getO3integration(void) {return _itg3;};
int64_t GetO1differ(void) {return _dif1;};
int64_t GetO2differ(void) {return _dif2;};
};
int main() {
char getc =0;
int channel = 0, datamode =0;
bool output = true, mapout = true;
pc.baud(115200);
int readings[3] = {0, 0, 0};
RangeMapper DAC_Mapper( 0 - 1<<13, 1<<13, 0, 1);
DataProcess dp1, dp2, dp3;
DataProcess dp[3] = {dp1, dp2, dp3};
pc.printf("Starting ADXL345 test...\r\n");
wait(.001);
pc.printf("Device ID is: 0x%02x\r\n", accelerometer.getDeviceID());
wait(.001);
restart:
// These are here to test whether any of the initialization fails. It will print the failure
if (accelerometer.setPowerControl(0x00)){
pc.printf("didn't intitialize power control\r\n");
return 0; }
wait(.001);
//Full resolution, +/-16g, 4mg/LSB.
if(accelerometer.setDataFormatControl(0x0B)){
//Full resolution, +/-2g, 4mg/LSB.
//if(accelerometer.setDataFormatControl(0x08)){
pc.printf("didn't set data format\r\n");
return 0; }
wait(.001);
//3.2kHz data rate.
if(accelerometer.setDataRate(ADXL345_3200HZ)){
pc.printf("didn't set data rate\r\n");
return 0; }
wait(.001);
//Measurement mode.
if(accelerometer.setPowerControl(MeasurementMode)) {
pc.printf("didn't set the power control to measurement\r\n");
return 0; }
// pc.printf("x-axis, y-axis, z-axis\r\n");
pc.printf("Data Commands: \r\n");
pc.printf(" x -> x channdel \r\n");
pc.printf(" y -> y channdel \r\n");
pc.printf(" z -> z channdel \r\n");
pc.printf(" o,0 -> data output on/off \r\n");
pc.printf(" i,1 -> mapper on/off \r\n");
pc.printf(" a -> raw data \r\n");
pc.printf(" b -> mean \r\n");
pc.printf(" c -> summary \r\n");
pc.printf(" d -> variance \r\n");
pc.printf(" e -> 1st order Integration \r\n");
pc.printf(" f -> 2nd order Integration \r\n");
pc.printf(" g -> 3rd order Integration \r\n");
pc.printf(" h -> 1st order Differentiation \r\n");
pc.printf(" k -> 2nd order Differentiation \r\n");
pc.printf("Press any key to start. \r\n");
getc = pc.getc();
while (1) {
int error_count=0;
if (pc.readable())
{
getc = pc.getc();
switch( getc)
{
case 'x' : channel = 0 ; pc.printf("Data procesing output switch to X channdel \r\n"); break;
case 'y' : channel = 1 ; pc.printf("Data procesing output switch to Y channdel \r\n"); break;
case 'z' : channel = 2 ; pc.printf("Data procesing output switch to Z channdel \r\n"); break;
case '0' :
case 'o' : output = !output ; pc.printf("Turn %s data output.\r\n", (output ? "On" : "Off") ); break;
case '1' :
case 'i' : mapout = !mapout ; pc.printf("Turn %s mapping output.\r\n", (mapout ? "On" : "Off") ); break;
case 'a' : datamode = 0 ; pc.printf("Set to raw data output.\r\n"); break;
case 'b' : datamode = 1 ; pc.printf("Set to mean output.\r\n"); break;
case 'c' : datamode = 2 ; pc.printf("Set to summary output.\r\n"); break;
case 'd' : datamode = 3 ; pc.printf("Set to variance output.\r\n"); break;
case 'e' : datamode = 4 ; pc.printf("Set to 1st order Integration output.\r\n"); break;
case 'f' : datamode = 5 ; pc.printf("Set to 2nd order Integration output.\r\n"); break;
case 'g' : datamode = 6 ; pc.printf("Set to 3rd order Integration output.\r\n"); break;
case 'h' : datamode = 7 ; pc.printf("Set to 1st order Differentiation output.\r\n"); break;
case 'k' : datamode = 8 ; pc.printf("Set to 2nd order Differentiation output.\r\n"); break;
default: break;
}
}
accelerometer.getOutput(readings);
if (( 17601 == readings[0] ) || ( 17601 == readings[1] ) || ( 17601 == readings[2] ))
{
error_count++;
if (error_count>10)
{
accelerometer.setPowerControl(0);
pc.printf("Sensor Halt!\r\n");
goto restart;
}
}
else
{
error_count = 0;
int i;
for (i = 0; i<3; i++)
dp[i].putData(readings[i] = (int16_t) readings[i] );
if (output)
{
switch (datamode)
{
case 0: pc.printf("RAW: %i, %i, %i\r\n", (int16_t)readings[0], (int16_t)readings[1], (int16_t)readings[2]); break;
//case 0: pc.printf("RAW: %i, %i, %i\r\n", readings[0], readings[1], readings[2]); break;
case 1: pc.printf("MEAN: %f, %f, %f\r\n", dp[0].getMean(), dp[1].getMean(), dp[2].getMean() ); break;
case 2: pc.printf("SUM: %jd, %jd, %jd\r\n", dp[0].getSum(), dp[1].getSum(), dp[2].getSum() ); break;
case 3: pc.printf("STD: %f, %f, %f\r\n", dp[0].getStdDiv(), dp[1].getStdDiv(), dp[2].getStdDiv() ); break;
case 4: pc.printf("1ITG: %jd, %jd, %jd\r\n", dp[0].getO1integration(), dp[1].getO1integration(), dp[2].getO1integration() ); break;
case 5: pc.printf("2ITG: %jd, %jd, %jd\r\n", dp[0].getO2integration(), dp[1].getO2integration(), dp[2].getO2integration() ); break;
case 6: pc.printf("3ITG: %jd, %jd, %jd\r\n", dp[0].getO3integration(), dp[1].getO3integration(), dp[2].getO3integration() ); break;
case 7: pc.printf("1DIF: %jd, %jd, %jd\r\n", dp[0].GetO1differ(), dp[1].GetO1differ(), dp[2].GetO1differ() ); break;
case 8: pc.printf("2DIF: %jd, %jd, %jd\r\n", dp[0].GetO2differ(), dp[1].GetO2differ(), dp[2].GetO2differ() ); break;
default: break;
}
}
if (mapout)
{
double mapdata;
switch (datamode)
{
case 0: mapdata = readings[channel]; break;
case 1: mapdata = dp[channel].getMean(); break;
case 2: mapdata = dp[channel].getSum(); break;
case 3: mapdata = dp[channel].getStdDiv(); break;
case 4: mapdata = dp[channel].getO1integration(); break;
case 5: mapdata = dp[channel].getO2integration(); break;
case 6: mapdata = dp[channel].getO3integration(); break;
case 7: mapdata = dp[channel].GetO1differ(); break;
case 8: mapdata = dp[channel].GetO2differ(); break;
default: mapdata = 0; break;
}
// Set data the DAC
DAC_Mapper.getOutput(mapdata);
}
wait(1);
}
}
}