esp-open-rtos/extras/tsl2561/tsl2561.c

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/*
* Part of esp-open-rtos
* Copyright (C) 2016 Brian Schwind (https://github.com/bschwind)
* BSD Licensed as described in the file LICENSE
*/
#include <stdio.h>
#include "FreeRTOS.h"
#include "i2c/i2c.h"
#include "task.h"
#include "tsl2561.h"
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// Registers
#define TSL2561_REG_COMMAND 0x80
#define TSL2561_REG_CONTROL 0x00
#define TSL2561_REG_TIMING 0x01
#define TSL2561_REG_THRESHOLD_LOW_0 0x02
#define TSL2561_REG_THRESHOLD_LOW_1 0x03
#define TSL2561_REG_THRESHOLD_HIGH_0 0x04
#define TSL2561_REG_THRESHOLD_HIGH_1 0x05
#define TSL2561_REG_INTERRUPT 0x06
#define TSL2561_REG_PART_ID 0x0A
#define TSL2561_REG_CHANNEL_0_LOW 0x0C
#define TSL2561_REG_CHANNEL_0_HIGH 0x0D
#define TSL2561_REG_CHANNEL_1_LOW 0x0E
#define TSL2561_REG_CHANNEL_1_HIGH 0x0F
// TSL2561 Misc Values
#define TSL2561_ON 0x03
#define TSL2561_OFF 0x00
#define TSL2561_READ_WORD 0x20
// Integration times in milliseconds
#define TSL2561_INTEGRATION_TIME_13MS 20
#define TSL2561_INTEGRATION_TIME_101MS 110
#define TSL2561_INTEGRATION_TIME_402MS 410 // Default
// Calculation constants
#define LUX_SCALE 14
#define RATIO_SCALE 9
#define CH_SCALE 10
#define CHSCALE_TINT0 0x7517
#define CHSCALE_TINT1 0x0fe7
// Package constants
#define TSL2561_PACKAGE_CS 0x00
#define TSL2561_PACKAGE_T_FN_CL 0x01
// Constants from the TSL2561 data sheet
#define K1T 0x0040 // 0.125 * 2^RATIO_SCALE
#define B1T 0x01f2 // 0.0304 * 2^LUX_SCALE
#define M1T 0x01be // 0.0272 * 2^LUX_SCALE
#define K2T 0x0080 // 0.250 * 2^RATIO_SCALE
#define B2T 0x0214 // 0.0325 * 2^LUX_SCALE
#define M2T 0x02d1 // 0.0440 * 2^LUX_SCALE
#define K3T 0x00c0 // 0.375 * 2^RATIO_SCALE
#define B3T 0x023f // 0.0351 * 2^LUX_SCALE
#define M3T 0x037b // 0.0544 * 2^LUX_SCALE
#define K4T 0x0100 // 0.50 * 2^RATIO_SCALE
#define B4T 0x0270 // 0.0381 * 2^LUX_SCALE
#define M4T 0x03fe // 0.0624 * 2^LUX_SCALE
#define K5T 0x0138 // 0.61 * 2^RATIO_SCALE
#define B5T 0x016f // 0.0224 * 2^LUX_SCALE
#define M5T 0x01fc // 0.0310 * 2^LUX_SCALE
#define K6T 0x019a // 0.80 * 2^RATIO_SCALE
#define B6T 0x00d2 // 0.0128 * 2^LUX_SCALE
#define M6T 0x00fb // 0.0153 * 2^LUX_SCALE
#define K7T 0x029a // 1.3 * 2^RATIO_SCALE
#define B7T 0x0018 // 0.00146 * 2^LUX_SCALE
#define M7T 0x0012 // 0.00112 * 2^LUX_SCALE
#define K8T 0x029a // 1.3 * 2^RATIO_SCALE
#define B8T 0x0000 // 0.000 * 2^LUX_SCALE
#define M8T 0x0000 // 0.000 * 2^LUX_SCALE
#define K1C 0x0043 // 0.130 * 2^RATIO_SCALE
#define B1C 0x0204 // 0.0315 * 2^LUX_SCALE
#define M1C 0x01ad // 0.0262 * 2^LUX_SCALE
#define K2C 0x0085 // 0.260 * 2^RATIO_SCALE
#define B2C 0x0228 // 0.0337 * 2^LUX_SCALE
#define M2C 0x02c1 // 0.0430 * 2^LUX_SCALE
#define K3C 0x00c8 // 0.390 * 2^RATIO_SCALE
#define B3C 0x0253 // 0.0363 * 2^LUX_SCALE
#define M3C 0x0363 // 0.0529 * 2^LUX_SCALE
#define K4C 0x010a // 0.520 * 2^RATIO_SCALE
#define B4C 0x0282 // 0.0392 * 2^LUX_SCALE
#define M4C 0x03df // 0.0605 * 2^LUX_SCALE
#define K5C 0x014d // 0.65 * 2^RATIO_SCALE
#define B5C 0x0177 // 0.0229 * 2^LUX_SCALE
#define M5C 0x01dd // 0.0291 * 2^LUX_SCALE
#define K6C 0x019a // 0.80 * 2^RATIO_SCALE
#define B6C 0x0101 // 0.0157 * 2^LUX_SCALE
#define M6C 0x0127 // 0.0180 * 2^LUX_SCALE
#define K7C 0x029a // 1.3 * 2^RATIO_SCALE
#define B7C 0x0037 // 0.00338 * 2^LUX_SCALE
#define M7C 0x002b // 0.00260 * 2^LUX_SCALE
#define K8C 0x029a // 1.3 * 2^RATIO_SCALE
#define B8C 0x0000 // 0.000 * 2^LUX_SCALE
#define M8C 0x0000 // 0.000 * 2^LUX_SCALE
static bool write_register(uint8_t i2c_addr, uint8_t reg, uint8_t value)
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{
uint8_t data[2];
data[0] = TSL2561_REG_COMMAND | reg;
data[1] = value;
return i2c_slave_write(i2c_addr, data, 2);
}
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static uint8_t read_register(uint8_t i2c_addr, uint8_t reg)
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{
uint8_t data[1];
if (!i2c_slave_read(i2c_addr, TSL2561_REG_COMMAND | reg, data, 1))
{
printf("Error in tsl261 read_register\n");
}
return data[0];
}
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static uint16_t read_register_16(uint8_t i2c_addr, uint8_t low_register_addr)
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{
uint16_t value = 0;
uint8_t data[2];
if (!i2c_slave_read(i2c_addr, TSL2561_REG_COMMAND | TSL2561_READ_WORD | low_register_addr, data, 2))
{
printf("Error with i2c_slave_read in read_register_16\n");
}
value = ((uint16_t)data[1] << 8) | (data[0]);
return value;
}
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static bool enable(uint8_t i2c_addr)
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{
return write_register(i2c_addr, TSL2561_REG_CONTROL, TSL2561_ON);
}
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static bool disable(uint8_t i2c_addr)
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{
return write_register(i2c_addr, TSL2561_REG_CONTROL, TSL2561_OFF);
}
void tsl2561_init(tsl2561_t *device)
{
if (!enable(device->i2c_addr))
{
printf("Error initializing tsl2561\n");
}
uint8_t control_reg = (read_register(device->i2c_addr, TSL2561_REG_CONTROL) & TSL2561_ON);
if (control_reg != TSL2561_ON)
{
printf("Error initializing tsl2561, control register wasn't set to ON\n");
}
// Fetch the package type
uint8_t part_reg = read_register(device->i2c_addr, TSL2561_REG_PART_ID);
uint8_t package = part_reg >> 6;
device->package_type = package;
// Fetch the gain and integration time
uint8_t timing_register = read_register(device->i2c_addr, TSL2561_REG_TIMING);
device->gain = timing_register & 0x10;
device->integration_time = timing_register & 0x03;
disable(device->i2c_addr);
}
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void tsl2561_set_integration_time(tsl2561_t *device, tsl2561_integration_time_t integration_time_id)
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{
enable(device->i2c_addr);
write_register(device->i2c_addr, TSL2561_REG_TIMING, integration_time_id | device->gain);
disable(device->i2c_addr);
device->integration_time = integration_time_id;
}
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void tsl2561_set_gain(tsl2561_t *device, tsl2561_gain_t gain)
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{
enable(device->i2c_addr);
write_register(device->i2c_addr, TSL2561_REG_TIMING, gain | device->integration_time);
disable(device->i2c_addr);
device->gain = gain;
}
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static void get_channel_data(tsl2561_t *device, uint16_t *channel0, uint16_t *channel1)
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{
enable(device->i2c_addr);
// Since we just enabled the chip, we need to sleep
// for the chip's integration time so it can gather a reading
switch (device->integration_time)
{
case TSL2561_INTEGRATION_13MS:
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vTaskDelay(TSL2561_INTEGRATION_TIME_13MS / portTICK_PERIOD_MS);
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break;
case TSL2561_INTEGRATION_101MS:
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vTaskDelay(TSL2561_INTEGRATION_TIME_101MS / portTICK_PERIOD_MS);
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break;
default:
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vTaskDelay(TSL2561_INTEGRATION_TIME_402MS / portTICK_PERIOD_MS);
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break;
}
*channel0 = read_register_16(device->i2c_addr, TSL2561_REG_CHANNEL_0_LOW);
*channel1 = read_register_16(device->i2c_addr, TSL2561_REG_CHANNEL_1_LOW);
disable(device->i2c_addr);
}
bool tsl2561_read_lux(tsl2561_t *device, uint32_t *lux)
{
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bool success = true;
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uint32_t chScale;
uint32_t channel1;
uint32_t channel0;
switch (device->integration_time)
{
case TSL2561_INTEGRATION_13MS:
chScale = CHSCALE_TINT0;
break;
case TSL2561_INTEGRATION_101MS:
chScale = CHSCALE_TINT1;
break;
default:
chScale = (1 << CH_SCALE);
break;
}
// Scale if gain is 1x
if (device->gain == TSL2561_GAIN_1X)
{
// 16x is nominal, so if the gain is set to 1x then
// we need to scale by 16
chScale = chScale << 4;
}
uint16_t ch0;
uint16_t ch1;
get_channel_data(device, &ch0, &ch1);
// Scale the channel values
channel0 = (ch0 * chScale) >> CH_SCALE;
channel1 = (ch1 * chScale) >> CH_SCALE;
// Find the ratio of the channel values (channel1 / channel0)
// Protect against divide by zero
uint32_t ratio1 = 0;
if (channel0 != 0)
{
ratio1 = (channel1 << (RATIO_SCALE+1)) / channel0;
}
// Round the ratio value
uint32_t ratio = (ratio1 + 1) >> 1;
uint32_t b;
uint32_t m;
switch (device->package_type)
{
case TSL2561_PACKAGE_CS:
if ((ratio >= 0) && (ratio <= K1C))
{
b = B1C;
m = M1C;
}
else if (ratio <= K2C)
{
b = B2C;
m = M2C;
}
else if (ratio <= K3C)
{
b = B3C;
m = M3C;
}
else if (ratio <= K4C)
{
b = B4C;
m = M4C;
}
else if (ratio <= K5C)
{
b = B5C;
m = M5C;
}
else if (ratio <= K6C)
{
b = B6C;
m = M6C;
}
else if (ratio <= K7C)
{
b = B7C;
m = M7C;
}
else if (ratio > K8C)
{
b = B8C;
m = M8C;
}
break;
case TSL2561_PACKAGE_T_FN_CL:
if ((ratio >= 0) && (ratio <= K1T))
{
b = B1T;
m = M1T;
}
else if (ratio <= K2T)
{
b = B2T;
m = M2T;
}
else if (ratio <= K3T)
{
b = B3T;
m = M3T;
}
else if (ratio <= K4T)
{
b = B4T;
m = M4T;
}
else if (ratio <= K5T)
{
b = B5T;
m = M5T;
}
else if (ratio <= K6T)
{
b = B6T;
m = M6T;
}
else if (ratio <= K7T)
{
b = B7T;
m = M7T;
}
else if (ratio > K8T)
{
b = B8T;
m = M8T;
}
break;
default:
printf("Invalid package type in CalculateLux\n");
b = 0;
m = 0;
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success = false;
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break;
}
uint32_t temp;
temp = ((channel0 * b) - (channel1 * m));
// Do not allow negative lux value
if (temp < 0)
{
temp = 0;
}
// Round lsb (2^(LUX_SCALE1))
temp += (1 << (LUX_SCALE - 1));
// Strip off fractional portion
*lux = temp >> LUX_SCALE;
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return success;
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}