bontor humala
Calibrate and get energy readings from ADE7758 IC from Analog Devices
Currently this library can be used to calibrate and get VRMS, IRMS, active, and apparent energy. I havent worked on reactive energy measurement.
ade7758.cpp
- Committer:
- bonchenko
- Date:
- 2015-04-08
- Revision:
- 0:cf3dc3c5156b
- Child:
- 1:f5e8c8591449
File content as of revision 0:cf3dc3c5156b:
#include "mbed.h"
#include "ade7758.h"
#include "SWSPI.h"
// public
ADE7758::ADE7758(PinName mosi, PinName miso, PinName sclk, PinName cs):
_ADE7758SPI(mosi, miso, sclk), _ADESS(cs)
{
_ADESS = 1;
}
void ADE7758::begin()
{
enableChip();
//normal mode
_ADE7758SPI.format(8);
write8bits(OPMODE, 0x04);
}
int ADE7758::getWattHR(char phase)
{
return read16bits(AWATTHR+phase);
}
int ADE7758::getVARHR(char phase)
{
return read16bits(AVARHR+phase);
}
int ADE7758::getVAHR(char phase)
{
return read16bits(AVAHR+phase);
}
int ADE7758::WattHR(char phase)
{
return getWattHR(phase);
}
int ADE7758::VARHR(char phase)
{
return getVARHR(phase);
}
int ADE7758::VAHR(char phase)
{
return getVAHR(phase);
}
long ADE7758::VRMS(char phase)
{
char i=0;
long volts=0;
getVRMS(phase);//Ignore first reading
for(i=0;i<10;++i){
volts+=getVRMS(phase);
wait_us(50);
}
//average
return volts/10;
}
long ADE7758::IRMS(char phase)
{
char i=0;
long current=0;
getIRMS(phase);//Ignore first reading
for(i=0;i<10;++i){
current+=getIRMS(phase);
wait_us(50);
}
//average
return current/10;
}
void accumulateEnergy()
{
}
long ADE7758::waveform(char phase,char source)
{
return 1;
}
void ADE7758::powerOff()
{
}
void ADE7758::powerON()
{
}
void ADE7758::sleep()
{
}
void ADE7758::wakeUp()
{
}
long ADE7758::getInterruptStatus(void){
return read24bits(STATUS);
}
long ADE7758::getResetInterruptStatus(void){
return read24bits(RSTATUS);
}
int ADE7758::lineFreq(char phase){
uint8_t mmode;
mmode = read8bits(MMODE);
write8bits(MMODE,(mmode&0x11111100 )| phase);
wait_ms(10);
return read16bits(FREQ);
}
// private
void ADE7758::enableChip()
{
_ADESS = 0;
}
void ADE7758::disableChip()
{
_ADESS = 1;
}
void ADE7758::write8bits(char reg, unsigned char data)
{
enableChip();
wait_ms(10);
_ADE7758SPI.write(REG_WRITE(reg));
wait_ms(2);
_ADE7758SPI.write(data);
wait_ms(1);
disableChip();
}
void ADE7758::write16bits(char reg, unsigned int data)
{
enableChip();
wait_ms(10);
_ADE7758SPI.write(REG_WRITE(reg));
wait_ms(2);
_ADE7758SPI.write((unsigned char)((data>>8)&0xFF));
wait_ms(2);
_ADE7758SPI.write((unsigned char)(data&0xFF));
wait_ms(1);
disableChip();
}
unsigned char ADE7758::read8bits(char reg)
{
enableChip();
unsigned char ret;
wait_ms(10);
_ADE7758SPI.write(REG_READ(reg));
wait_ms(2);
ret=_ADE7758SPI.write(0x00);
wait_ms(1);
disableChip();
return ret;
}
unsigned int ADE7758::read16bits(char reg)
{
enableChip();
unsigned int ret=0;
unsigned char ret0=0;
wait_ms(10);
_ADE7758SPI.write(REG_READ(reg));
wait_ms(2);
ret=_ADE7758SPI.write(0x00);
wait_ms(2);
ret0=_ADE7758SPI.write(0x00);
wait_ms(1);
disableChip();
ret= (ret<<8)|ret0;
return ret;
}
unsigned long ADE7758::read24bits(char reg)
{
enableChip();
unsigned long ret=0;
unsigned int ret1=0;
unsigned char ret0=0;
wait_ms(10);
_ADE7758SPI.write(REG_READ(reg));
wait_ms(2);
ret=_ADE7758SPI.write(0x00);
wait_ms(2);
ret1=_ADE7758SPI.write(0x00);
wait_ms(2);
ret0=_ADE7758SPI.write(0x00);
wait_ms(1);
disableChip();
ret= (ret<<16)|(ret1<<8)|ret0;
return ret;
}
long ADE7758::getIRMS(char phase)
{
return read24bits(AIRMS+phase);
}
long ADE7758::getVRMS(char phase)
{
return read24bits(AVRMS+phase);
}
// ADE7758 ADE(mosi, miso, sclk, cs);