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Dependents: TestBenchSerenity-proto_F429ZI TestBenchFlow HSPFLOW1 TestBenchFlow1 ... more
keller_pressure.cpp
- Committer:
- dmwahl
- Date:
- 2017-05-09
- Revision:
- 0:fc5c10fc5a05
- Child:
- 1:805ee7853062
File content as of revision 0:fc5c10fc5a05:
#include "keller_pressure.h"
// Default constructor, input is the I2C address followed by min/max pressures (psi)
KELLER_PRESSURE::KELLER_PRESSURE(I2C &i2c, int i2cAddress) : i2c(i2c), mi2cAddress(i2cAddress << 1)
{
readUserInfo();
};
KELLER_PRESSURE::~KELLER_PRESSURE()
{
}
// Write out a single address byte to I2C bus, if the sensor returns an ACK the function returns true.
bool KELLER_PRESSURE::isAvailable()
{
uint8_t i = false;
i2c.start();
i = i2c.write(mi2cAddress|I2C_WRITE);
i2c.stop();
if (i == 1) {
return true;
} else {
return false;
}
}
// Check if conversion has completed
char KELLER_PRESSURE::getStatus()
{
char result = 0xFF;
i2c.start();
i2c.write(mi2cAddress|I2C_READ);
result = i2c.read(0);
i2c.stop();
return result;
}
// Read pressure and temperature
bool KELLER_PRESSURE::readPT()
{
bool result = false;
char data[5];
_read_multibyte(KELLER_PRESSURE_REQUEST_MEASUREMENT, data, 5);
status = data[0];
pressure = (data[1] << 8) | data[2];
temperature = (data[3] << 8) | data[4];
pressureBAR = ((pressure - 16384)*(pmax-pmin))/32768+pmin;
pressurePSI = pressureBAR*14.5038;
pressureKPA = pressureBAR*100;
temperatureC = (temperature - 384)*0.003125-50;
temperatureF = (temperatureC*1.8+32);
result = true;
return result;
}
void KELLER_PRESSURE::readUserInfo()
{
char data[3];
//const uint8_t i = NELEMS(data);
// _read_multibyte(char regAddress, char* data, char count)
_read_multibyte(KELLER_PRESSURE_CUST_ID0, data, 3);
Cust_ID0 = (data[1] << 8) | data[2];
_read_multibyte(KELLER_PRESSURE_CUST_ID1, data, 3);
Cust_ID1 = (data[1] << 8) | data[2];
_read_multibyte(KELLER_PRESSURE_SCALING0, data, 3);
Scaling0 = (data[1] << 8) | data[2];
_read_multibyte(KELLER_PRESSURE_SCALING1, data, 3);
Scaling1 = (data[1] << 8) | data[2];
_read_multibyte(KELLER_PRESSURE_SCALING2, data, 3);
Scaling2 = (data[1] << 8) | data[2];
_read_multibyte(KELLER_PRESSURE_SCALING3, data, 3);
Scaling3 = (data[1] << 8) | data[2];
_read_multibyte(KELLER_PRESSURE_SCALING4, data, 3);
Scaling4 = (data[1] << 8) | data[2];
pmin = ((Scaling1 << 16) | Scaling2)/(0xBF800000)*-1.0;
pmax = ((Scaling3 << 16) | Scaling4)/(1092616192.0)*10.0;
year = ((Scaling0 & KELLER_PRESSURE_SCALING0_YEAR_MASK) >> 11) + 2010;
month = (Scaling0 & KELLER_PRESSURE_SCALING0_MONTH_MASK) >> 7;
day = (Scaling0 & KELLER_PRESSURE_SCALING0_DAY_MASK) >> 2;
mode = (Scaling0 & KELLER_PRESSURE_SCALING0_MODE_MASK);
}
void KELLER_PRESSURE::_write(char regAddress, char data)
{
i2c.start();
i2c.write(mi2cAddress|I2C_WRITE);
i2c.write(regAddress);
i2c.write(data);
i2c.stop();
}
char KELLER_PRESSURE::_read(char regAddress)
{
char result = 0;
i2c.start();
i2c.write(mi2cAddress|I2C_WRITE);
i2c.write(regAddress);
i2c.start();
i2c.write(mi2cAddress|I2C_READ);
result = i2c.read(0);
i2c.stop();
return result;
}
void KELLER_PRESSURE::_read_multibyte(char regAddress, char* data, char count)
{
//char count = (sizeof(data) / sizeof((data)[0]))-1;
/*wait_ms(1);
char data_write = regAddress;
i2c.write(mi2cAddress, &data_write, 1, false);
wait_ms(1);
i2c.read(mi2cAddress, data, count, false);
wait_ms(1);*/
i2c.start();
i2c.write(mi2cAddress|I2C_WRITE);
i2c.write(regAddress);
i2c.stop();
//wait_us(500);
while (getStatus() != 0x40)
{
wait_us(10); // wait until the status bit indicates conversion has completed
}
i2c.start();
i2c.write(mi2cAddress|I2C_READ);
for(int i = 0; i < count; i++) {
data[i] = i2c.read((i == count - 1) ? 0 : 1);
}
i2c.stop();
}