La Suno
Added a GPIO to power on/off for external I2C sensor(s) (with LEDs)
Dependencies: UniGraphic mbed vt100
18-Jun-2018 外部センサの電源オン・オフ機能は下位互換の為に無効になっていました。 この版で再度有効にしました。
sensors/VEML6040.cpp
- Committer:
- Rhyme
- Date:
- 2018-04-13
- Revision:
- 0:846e2321c637
File content as of revision 0:846e2321c637:
/*
* File description here
*/
#include "VEML6040.h"
#include "af_mgr.h"
/* VEML6075 SLAVE ADDRESS AND FUNCTION DESCRIPTION */
#define REG_COLOR_CONF 0x00
#define REG_Reserved1 0x01
#define REG_Reserved2 0x02
#define REG_Reserved3 0x03
#define REG_Reserved4 0x04
#define REG_Reserved5 0x05
#define REG_Reserved6 0x06
#define REG_Reserved7 0x07
#define REG_R_Data 0x08
#define REG_G_Data 0x09
#define REG_B_Data 0x0A
#define REG_W_Data 0x0B
// Following magic numbers are from
// VISHAY VEML6040 Application Note 84331
// Page 4
#define LUX_RESOLUTION_0 (0.25168)
#define LUX_RESOLUTION_1 (0.12584)
#define LUX_RESOLUTION_2 (0.06292)
#define LUX_RESOLUTION_3 (0.03146)
#define LUX_RESOLUTION_4 (0.01573)
#define LUX_RESOLUTION_5 (0.007865)
// Following magic numbers are from
// VISHAY VEML6040 Application Note 84331
// Page 9
#define CORR_COEFF_M0 (0.048403)
#define CORR_COEFF_M1 (0.183633)
#define CORR_COEFF_M2 (-0.253589)
#define CORR_COEFF_M3 (0.022916)
#define CORR_COEFF_M4 (0.176388)
#define CORR_COEFF_M5 (-0.183205)
#define CORR_COEFF_M6 (-0.077436)
#define CORR_COEFF_M7 (0.124541)
#define CORR_COEFF_M8 (0.032081)
// Following magic numbers are from
// VISHAY VEML6040 Application Note 84331
// Page 10
#define CCT_CONST (4278.6)
#define OFFSET_OPEN_AIR (0.5)
VEML6040::VEML6040(I2C *i2c, int addr) : m_addr(addr<<1) {
p_i2c = i2c ;
p_i2c->frequency(100000); /* 100kHz */
// activate the peripheral
}
VEML6040::~VEML6040() { }
/**
* set COLOR Config
* @param colorconf uint8_t 8bit register value
* @returns 0: success non-0: failure
* @note Command Code 0x00 is used to access CONF register
* @note bit[7] (reserved)
* @note bit[6:4] = IT[2:0] Integration Time Selector
* @note bit[3] (reserved)
* @note bit[2] TRIG Proceed one detcting cycle at manual force mode
* @note bit[1] AF 0: Auto mode 1: manual force mode
* @note bit[0] SD 0: normal 1: chip shutdown setting
*
* @note IT[2:0] 0=40ms, 1=80ms, 2=160ms, 3=320ms, 4=640ms, 5=1280ms
* @note as our WatchDog is set to 1sec, 1280ms is invalid
* @note and 640ms may not be practical
*/
int VEML6040::setCOLORConf(uint8_t colorconf)
{
int result ;
uint8_t data[3] ;
data[0] = REG_COLOR_CONF ;
data[1] = colorconf ;
data[2] = 0 ;
result = writeRegs(data, 3) ;
return( result ) ;
}
/**
* get COLOR Config
* @param *colorconf uint8_t refer to setCOLORConf for the value
* @returns 0: success non-0: failure
*/
int VEML6040::getCOLORConf(uint8_t *colorconf)
{
int result ;
uint8_t data[2] ;
result = readRegs(REG_COLOR_CONF, data, 2) ;
if (result == 0) {
*colorconf = data[0] ;
}
return( result ) ;
}
int VEML6040::getRData(uint16_t *rdata)
{
uint8_t data[2] ;
int result ;
result = readRegs(REG_R_Data, data, 2) ;
*rdata = (data[1]<<8) | data[0] ;
return( result ) ;
}
int VEML6040::getGData(uint16_t *gdata)
{
uint8_t data[2] ;
int result ;
result = readRegs(REG_G_Data, data, 2) ;
*gdata = (data[1]<<8) | data[0] ;
return( result ) ;
}
int VEML6040::getBData(uint16_t *bdata)
{
uint8_t data[2] ;
int result ;
result = readRegs(REG_B_Data, data, 2) ;
*bdata = (data[1]<<8) | data[0] ;
return( result ) ;
}
int VEML6040::getWData(uint16_t *wdata)
{
uint8_t data[2] ;
int result ;
result = readRegs(REG_W_Data, data, 2) ;
*wdata = (data[1]<<8) | data[0] ;
return( result ) ;
}
// usage
// fvalue = veml->getUVA() ;
// printf("%f", fvalue) ;
float VEML6040::getR(void)
{
uint16_t data ;
float value ;
getRData(&data) ;
value = (float)LUX_RESOLUTION_0 * (float)data ;
return( value ) ;
}
float VEML6040::getG(void)
{
uint16_t data ;
float value ;
getGData(&data) ;
value = (float)LUX_RESOLUTION_0 * (float)data ;
return( value ) ;
}
float VEML6040::getB(void)
{
uint16_t data ;
float value ;
getBData(&data) ;
value = (float)LUX_RESOLUTION_0 * (float)data ;
return( value ) ;
}
float VEML6040::getW(void)
{
uint16_t data ;
float value ;
getWData(&data) ;
value = (float)LUX_RESOLUTION_0 * (float)data ;
return( value ) ;
}
float VEML6040::getX(void)
{
uint16_t R ;
uint16_t G ;
uint16_t B ;
float value ;
getRData(&R) ;
getGData(&G) ;
getBData(&B) ;
value = (float)CORR_COEFF_M0 * (float)R + (float)CORR_COEFF_M1 * (float)G + (float)CORR_COEFF_M2 * (float)B ;
return( value ) ;
}
float VEML6040::getY(void)
{
uint16_t R ;
uint16_t G ;
uint16_t B ;
float value ;
getRData(&R) ;
getGData(&G) ;
getBData(&B) ;
value = (float)CORR_COEFF_M3 * (float)R + (float)CORR_COEFF_M4 * (float)G + (float)CORR_COEFF_M5 * (float)B ;
return( value ) ;
}
float VEML6040::getZ(void)
{
uint16_t R ;
uint16_t G ;
uint16_t B ;
float value ;
getRData(&R) ;
getGData(&G) ;
getBData(&B) ;
value = (float)CORR_COEFF_M6 * (float)R + (float)CORR_COEFF_M7 * (float)G + (float)CORR_COEFF_M8 * (float)B ;
return( value ) ;
}
float VEML6040::getCCTiData(void)
{
uint16_t rdata ;
uint16_t gdata ;
uint16_t bdata ;
float value ;
getRData(&rdata) ;
getGData(&gdata) ;
getBData(&bdata) ;
value = ((float)rdata - (float)bdata) / (float)gdata + (float)OFFSET_OPEN_AIR ;
return( value ) ;
}
float VEML6040::getCCTData(void)
{
// uint16_t cctidata ;
float cctidata ;
float value ;
cctidata = getCCTiData() ;
// getCCTiData(&cctidata) ;
value = (float)CCT_CONST * powf( cctidata, -1.2455 ) ;
return( value ) ;
}
float VEML6040::getCIEX(void)
{
float X ;
float Y ;
float Z ;
float value ;
X = getX() ;
Y = getY() ;
Z = getZ() ;
value = (float)X / ((float)X + (float)Y + (float)Z) ;
return( value ) ;
}
float VEML6040::getCIEY(void)
{
float X ;
float Y ;
float Z ;
float value ;
X = getX() ;
Y = getY() ;
Z = getZ() ;
value = (float)Y / ((float)X + (float)Y + (float)Z) ;
return( value ) ;
}
int VEML6040::readRegs(int addr, uint8_t * data, int len) {
char t[1] = {addr};
int result ;
__disable_irq() ; // Disable Interrupts
result = p_i2c->write(m_addr, t, 1, true);
if (result == 0) { // write success
result = p_i2c->read(m_addr, (char *)data, len, false);
}
__enable_irq() ; // Enable Interrupts
return(result) ;
}
int VEML6040::writeRegs(uint8_t * data, int len) {
int result ;
__disable_irq() ; // Disable Interrupts
result = p_i2c->write(m_addr, (char *)data, len);
__enable_irq() ; // Enable Interrupts
return(result) ;
}