esphome/esphome/components/ads1115/ads1115.cpp
WitchKing aca56fcdcc
Added support for ADS1015 (#4281)
Co-authored-by: vilrexa-at-412611259294 <pdzBdl8EkgUikpOWsRCKzTVHMEX2wLnZJRdLhK38oNk=>
2023-01-26 17:20:45 +13:00

192 lines
5.4 KiB
C++

#include "ads1115.h"
#include "esphome/core/log.h"
#include "esphome/core/hal.h"
namespace esphome {
namespace ads1115 {
static const char *const TAG = "ads1115";
static const uint8_t ADS1115_REGISTER_CONVERSION = 0x00;
static const uint8_t ADS1115_REGISTER_CONFIG = 0x01;
static const uint8_t ADS1115_DATA_RATE_860_SPS = 0b111; // 3300_SPS for ADS1015
void ADS1115Component::setup() {
ESP_LOGCONFIG(TAG, "Setting up ADS1115...");
uint16_t value;
if (!this->read_byte_16(ADS1115_REGISTER_CONVERSION, &value)) {
this->mark_failed();
return;
}
ESP_LOGCONFIG(TAG, "Configuring ADS1115...");
uint16_t config = 0;
// Clear single-shot bit
// 0b0xxxxxxxxxxxxxxx
config |= 0b0000000000000000;
// Setup multiplexer
// 0bx000xxxxxxxxxxxx
config |= ADS1115_MULTIPLEXER_P0_N1 << 12;
// Setup Gain
// 0bxxxx000xxxxxxxxx
config |= ADS1115_GAIN_6P144 << 9;
if (this->continuous_mode_) {
// Set continuous mode
// 0bxxxxxxx0xxxxxxxx
config |= 0b0000000000000000;
} else {
// Set singleshot mode
// 0bxxxxxxx1xxxxxxxx
config |= 0b0000000100000000;
}
// Set data rate - 860 samples per second (we're in singleshot mode)
// 0bxxxxxxxx100xxxxx
config |= ADS1115_DATA_RATE_860_SPS << 5;
// Set comparator mode - hysteresis
// 0bxxxxxxxxxxx0xxxx
config |= 0b0000000000000000;
// Set comparator polarity - active low
// 0bxxxxxxxxxxxx0xxx
config |= 0b0000000000000000;
// Set comparator latch enabled - false
// 0bxxxxxxxxxxxxx0xx
config |= 0b0000000000000000;
// Set comparator que mode - disabled
// 0bxxxxxxxxxxxxxx11
config |= 0b0000000000000011;
if (!this->write_byte_16(ADS1115_REGISTER_CONFIG, config)) {
this->mark_failed();
return;
}
this->prev_config_ = config;
}
void ADS1115Component::dump_config() {
ESP_LOGCONFIG(TAG, "Setting up ADS1115...");
LOG_I2C_DEVICE(this);
if (this->is_failed()) {
ESP_LOGE(TAG, "Communication with ADS1115 failed!");
}
for (auto *sensor : this->sensors_) {
LOG_SENSOR(" ", "Sensor", sensor);
ESP_LOGCONFIG(TAG, " Multiplexer: %u", sensor->get_multiplexer());
ESP_LOGCONFIG(TAG, " Gain: %u", sensor->get_gain());
ESP_LOGCONFIG(TAG, " Resolution: %u", sensor->get_resolution());
}
}
float ADS1115Component::request_measurement(ADS1115Sensor *sensor) {
uint16_t config = this->prev_config_;
// Multiplexer
// 0bxBBBxxxxxxxxxxxx
config &= 0b1000111111111111;
config |= (sensor->get_multiplexer() & 0b111) << 12;
// Gain
// 0bxxxxBBBxxxxxxxxx
config &= 0b1111000111111111;
config |= (sensor->get_gain() & 0b111) << 9;
if (!this->continuous_mode_) {
// Start conversion
config |= 0b1000000000000000;
}
if (!this->continuous_mode_ || this->prev_config_ != config) {
if (!this->write_byte_16(ADS1115_REGISTER_CONFIG, config)) {
this->status_set_warning();
return NAN;
}
this->prev_config_ = config;
// about 1.2 ms with 860 samples per second
delay(2);
// in continuous mode, conversion will always be running, rely on the delay
// to ensure conversion is taking place with the correct settings
// can we use the rdy pin to trigger when a conversion is done?
if (!this->continuous_mode_) {
uint32_t start = millis();
while (this->read_byte_16(ADS1115_REGISTER_CONFIG, &config) && (config >> 15) == 0) {
if (millis() - start > 100) {
ESP_LOGW(TAG, "Reading ADS1115 timed out");
this->status_set_warning();
return NAN;
}
yield();
}
}
}
uint16_t raw_conversion;
if (!this->read_byte_16(ADS1115_REGISTER_CONVERSION, &raw_conversion)) {
this->status_set_warning();
return NAN;
}
if (sensor->get_resolution() == ADS1015_12_BITS) {
bool negative = (raw_conversion >> 15) == 1;
// shift raw_conversion as it's only 12-bits, left justified
raw_conversion = raw_conversion >> (16 - ADS1015_12_BITS);
// check if number was negative in order to keep the sign
if (negative) {
// the number was negative
// 1) set the negative bit back
raw_conversion |= 0x8000;
// 2) reset the former (shifted) negative bit
raw_conversion &= 0xF7FF;
}
}
auto signed_conversion = static_cast<int16_t>(raw_conversion);
float millivolts;
float divider = (sensor->get_resolution() == ADS1115_16_BITS) ? 32768.0f : 2048.0f;
switch (sensor->get_gain()) {
case ADS1115_GAIN_6P144:
millivolts = (signed_conversion * 6144) / divider;
break;
case ADS1115_GAIN_4P096:
millivolts = (signed_conversion * 4096) / divider;
break;
case ADS1115_GAIN_2P048:
millivolts = (signed_conversion * 2048) / divider;
break;
case ADS1115_GAIN_1P024:
millivolts = (signed_conversion * 1024) / divider;
break;
case ADS1115_GAIN_0P512:
millivolts = (signed_conversion * 512) / divider;
break;
case ADS1115_GAIN_0P256:
millivolts = (signed_conversion * 256) / divider;
break;
default:
millivolts = NAN;
}
this->status_clear_warning();
return millivolts / 1e3f;
}
float ADS1115Sensor::sample() { return this->parent_->request_measurement(this); }
void ADS1115Sensor::update() {
float v = this->parent_->request_measurement(this);
if (!std::isnan(v)) {
ESP_LOGD(TAG, "'%s': Got Voltage=%fV", this->get_name().c_str(), v);
this->publish_state(v);
}
}
} // namespace ads1115
} // namespace esphome