2022-07-15 00:52:44 -04:00
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/*
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* SPDX-FileCopyrightText: 2019-2021 Espressif Systems (Shanghai) CO LTD
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*
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* SPDX-License-Identifier: Apache-2.0
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*/
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#include <stdint.h>
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#include "assert.h"
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#include "esp_types.h"
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#include "esp_err.h"
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#include "esp_check.h"
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#include "esp_heap_caps.h"
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#include "esp_efuse.h"
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#include "esp_efuse_table.h"
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#include "esp_efuse_rtc_table.h"
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#include "hal/adc_types.h"
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#include "soc/efuse_periph.h"
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#include "soc/soc_caps.h"
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#include "esp_adc/adc_cali_scheme.h"
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#include "adc_cali_interface.h"
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const __attribute__((unused)) static char *TAG = "adc_cali";
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/* ------------------------ Characterization Constants ---------------------- */
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// coeff_a and coeff_b are actually floats
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// they are scaled to put them into uint32_t so that the headers do not have to be changed
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static const int coeff_a_scaling = 65536;
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static const int coeff_b_scaling = 1024;
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/* -------------------- Characterization Helper Data Types ------------------ */
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typedef struct {
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int adc_calib_high;
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int adc_calib_low;
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} adc_calib_data_ver1_t;
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typedef struct {
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int adc_calib_high; // the reading of adc ...
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int adc_calib_high_voltage; // ... at this voltage (mV)
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} adc_calib_data_ver2_t;
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typedef struct {
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char version_num;
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adc_unit_t unit_id;
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adc_atten_t atten_level;
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union {
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adc_calib_data_ver1_t ver1;
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adc_calib_data_ver2_t ver2;
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} efuse_data;
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} adc_calib_parsed_info_t;
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/* ------------------------ Context Structure--------------------------- */
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typedef struct {
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adc_unit_t unit_id; ///< ADC unit
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adc_atten_t atten; ///< ADC attenuation
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uint32_t coeff_a; ///< Gradient of ADC-Voltage curve
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uint32_t coeff_b; ///< Offset of ADC-Voltage curve
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} cali_chars_line_fitting_t;
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/* ----------------------- Characterization Functions ----------------------- */
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static bool prepare_calib_data_for(adc_unit_t unit_id, adc_atten_t atten, adc_calib_parsed_info_t *parsed_data_storage);
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/**
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* (Used in V1 of calibration scheme)
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* The Two Point calibration measures the reading at two specific input voltages, and calculates the (assumed linear) relation
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* between input voltage and ADC response. (Response = A * Vinput + B)
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* A and B are scaled ints.
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* @param high The ADC response at the higher voltage of the corresponding attenuation (600mV, 800mV, 1000mV, 2000mV).
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* @param low The ADC response at the lower voltage of the corresponding attenuation (all 250mV).
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*
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*/
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static void characterize_using_two_point(adc_unit_t unit_id,
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adc_atten_t atten,
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uint32_t high,
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uint32_t low,
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uint32_t *coeff_a,
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uint32_t *coeff_b);
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/*
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* Estimate the (assumed) linear relationship btwn the measured raw value and the voltage
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* with the previously done measurement when the chip was manufactured.
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* */
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static bool calculate_characterization_coefficients(const adc_calib_parsed_info_t *parsed_data, cali_chars_line_fitting_t *ctx);
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/* ------------------------ Interface Functions --------------------------- */
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static esp_err_t cali_raw_to_voltage(void *arg, int raw, int *voltage);
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/* ------------------------- Public API ------------------------------------- */
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esp_err_t adc_cali_create_scheme_line_fitting(const adc_cali_line_fitting_config_t *config, adc_cali_handle_t *ret_handle)
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{
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esp_err_t ret = ESP_OK;
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ESP_RETURN_ON_FALSE(config && ret_handle, ESP_ERR_INVALID_ARG, TAG, "invalid arg: null pointer");
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ESP_RETURN_ON_FALSE(config->unit_id < SOC_ADC_PERIPH_NUM, ESP_ERR_INVALID_ARG, TAG, "invalid ADC unit");
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ESP_RETURN_ON_FALSE(config->atten < SOC_ADC_ATTEN_NUM, ESP_ERR_INVALID_ARG, TAG, "invalid ADC attenuation");
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//S2 Oneshot read only supports 13 bits, DMA read only supports 12 bits
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ESP_RETURN_ON_FALSE(((config->bitwidth == SOC_ADC_RTC_MAX_BITWIDTH || config->bitwidth == SOC_ADC_DIGI_MAX_BITWIDTH) || config->bitwidth == ADC_BITWIDTH_DEFAULT), ESP_ERR_INVALID_ARG, TAG, "invalid bitwidth");
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// current version only accepts encoding ver 1 and ver 2.
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uint8_t adc_encoding_version = esp_efuse_rtc_table_read_calib_version();
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ESP_RETURN_ON_FALSE(((adc_encoding_version == 1) || (adc_encoding_version == 2)), ESP_ERR_NOT_SUPPORTED, TAG, "Calibration required eFuse bits not burnt");
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adc_cali_scheme_t *scheme = (adc_cali_scheme_t *)heap_caps_calloc(1, sizeof(adc_cali_scheme_t), MALLOC_CAP_INTERNAL | MALLOC_CAP_8BIT);
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ESP_RETURN_ON_FALSE(scheme, ESP_ERR_NO_MEM, TAG, "no mem for adc calibration scheme");
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cali_chars_line_fitting_t *chars = (cali_chars_line_fitting_t *)heap_caps_calloc(1, sizeof(cali_chars_line_fitting_t), MALLOC_CAP_INTERNAL | MALLOC_CAP_8BIT);
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ESP_GOTO_ON_FALSE(chars, ESP_ERR_NO_MEM, err, TAG, "no memory for the calibration characteristics");
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scheme->raw_to_voltage = cali_raw_to_voltage;
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scheme->ctx = chars;
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adc_calib_parsed_info_t efuse_parsed_data = {0};
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bool success = prepare_calib_data_for(config->unit_id, config->atten, &efuse_parsed_data);
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assert(success);
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success = calculate_characterization_coefficients(&efuse_parsed_data, chars);
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assert(success);
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2022-08-25 23:28:01 -04:00
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ESP_LOGD(TAG, "adc%d (atten leven %d) calibration done: A:%"PRId32" B:%"PRId32"\n", config->unit_id, config->atten, chars->coeff_a, chars->coeff_b);
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2022-07-15 00:52:44 -04:00
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chars->unit_id = config->unit_id;
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chars->atten = config->atten;
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*ret_handle = scheme;
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return ESP_OK;
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err:
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if (scheme) {
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free(scheme);
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}
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return ret;
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}
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esp_err_t adc_cali_delete_scheme_line_fitting(adc_cali_handle_t handle)
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{
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ESP_RETURN_ON_FALSE(handle, ESP_ERR_INVALID_ARG, TAG, "invalid argument: null pointer");
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free(handle->ctx);
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handle->ctx = NULL;
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free(handle);
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handle = NULL;
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return ESP_OK;
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}
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/* ------------------------ Interface Functions --------------------------- */
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static esp_err_t cali_raw_to_voltage(void *arg, int raw, int *voltage)
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{
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//pointers are checked in the upper layer
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cali_chars_line_fitting_t *ctx = arg;
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*voltage = raw * ctx->coeff_a / coeff_a_scaling + ctx->coeff_b / coeff_b_scaling;
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return ESP_OK;
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}
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/* ----------------------- Characterization Functions ----------------------- */
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static bool prepare_calib_data_for(adc_unit_t unit_id, adc_atten_t atten, adc_calib_parsed_info_t *parsed_data_storage)
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{
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int version_num = esp_efuse_rtc_table_read_calib_version();
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int tag;
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parsed_data_storage->version_num = version_num;
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parsed_data_storage->unit_id = unit_id;
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parsed_data_storage->atten_level = atten;
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switch (version_num) {
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case 1:
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// note: use the unit_id as in hal, which start from 0.
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tag = esp_efuse_rtc_table_get_tag(version_num, unit_id, atten, RTCCALIB_V1_PARAM_VLOW);
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parsed_data_storage->efuse_data.ver1.adc_calib_low = esp_efuse_rtc_table_get_parsed_efuse_value(tag, false);
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tag = esp_efuse_rtc_table_get_tag(version_num, unit_id, atten, RTCCALIB_V1_PARAM_VHIGH);
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parsed_data_storage->efuse_data.ver1.adc_calib_high = esp_efuse_rtc_table_get_parsed_efuse_value(tag, false);
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break;
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case 2:
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tag = esp_efuse_rtc_table_get_tag(version_num, unit_id, atten, RTCCALIB_V2_PARAM_VHIGH);
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parsed_data_storage->efuse_data.ver2.adc_calib_high = esp_efuse_rtc_table_get_parsed_efuse_value(tag, false);
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switch (parsed_data_storage->atten_level) {
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case ADC_ATTEN_DB_0:
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parsed_data_storage->efuse_data.ver2.adc_calib_high_voltage = 600;
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break;
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case ADC_ATTEN_DB_2_5:
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parsed_data_storage->efuse_data.ver2.adc_calib_high_voltage = 800;
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break;
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case ADC_ATTEN_DB_6:
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parsed_data_storage->efuse_data.ver2.adc_calib_high_voltage = 1000;
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break;
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2023-11-06 21:47:42 -05:00
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case ADC_ATTEN_DB_12:
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2022-07-15 00:52:44 -04:00
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parsed_data_storage->efuse_data.ver2.adc_calib_high_voltage = 2000;
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break;
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default:
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break;
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}
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break;
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default:
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// fall back to case 1 with zeros as params.
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parsed_data_storage->version_num = 1;
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tag = esp_efuse_rtc_table_get_tag(version_num, unit_id, atten, RTCCALIB_V1_PARAM_VLOW);
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parsed_data_storage->efuse_data.ver1.adc_calib_high = esp_efuse_rtc_table_get_parsed_efuse_value(tag, true);
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tag = esp_efuse_rtc_table_get_tag(version_num, unit_id, atten, RTCCALIB_V1_PARAM_VHIGH);
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parsed_data_storage->efuse_data.ver1.adc_calib_low = esp_efuse_rtc_table_get_parsed_efuse_value(tag, true);
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break;
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}
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return true;
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}
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/**
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* (Used in V1 of calibration scheme)
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* The Two Point calibration measures the reading at two specific input voltages, and calculates the (assumed linear) relation
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* between input voltage and ADC response. (Response = A * Vinput + B)
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* A and B are scaled ints.
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* @param high The ADC response at the higher voltage of the corresponding attenuation (600mV, 800mV, 1000mV, 2000mV).
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* @param low The ADC response at the lower voltage of the corresponding attenuation (all 250mV).
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*
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*/
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static void characterize_using_two_point(adc_unit_t unit_id,
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adc_atten_t atten,
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uint32_t high,
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uint32_t low,
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uint32_t *coeff_a,
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uint32_t *coeff_b)
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{
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// once we have recovered the reference high(Dhigh) and low(Dlow) readings, we can calculate a and b from
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// the measured high and low readings
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static const uint32_t v_high[] = {600, 800, 1000, 2000};
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static const uint32_t v_low = 250;
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*coeff_a = coeff_a_scaling * (v_high[atten] - v_low) / (high - low);
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*coeff_b = coeff_b_scaling * (v_low * high - v_high[atten] * low) / (high - low);
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}
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/*
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* Estimate the (assumed) linear relationship btwn the measured raw value and the voltage
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* with the previously done measurement when the chip was manufactured.
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* */
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static bool calculate_characterization_coefficients(const adc_calib_parsed_info_t *parsed_data, cali_chars_line_fitting_t *ctx)
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{
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switch (parsed_data->version_num) {
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case 1:
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ESP_LOGD(TAG, "Calib V1, low%dmV, high%dmV\n", parsed_data->efuse_data.ver1.adc_calib_low, parsed_data->efuse_data.ver1.adc_calib_high);
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characterize_using_two_point(parsed_data->unit_id, parsed_data->atten_level,
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parsed_data->efuse_data.ver1.adc_calib_high, parsed_data->efuse_data.ver1.adc_calib_low,
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&(ctx->coeff_a), &(ctx->coeff_b));
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break;
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case 2:
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ESP_LOGD(TAG, "Calib V2, volt%dmV\n", parsed_data->efuse_data.ver2.adc_calib_high);
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ctx->coeff_a = coeff_a_scaling * parsed_data->efuse_data.ver2.adc_calib_high_voltage /
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parsed_data->efuse_data.ver2.adc_calib_high;
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ctx->coeff_b = 0;
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break;
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default:
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return false;
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break;
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}
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return true;
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}
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