Analog to Digital Converter (ADC) Oneshot Mode Driver

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Introduction

The Analog to Digital Converter is integrated on the chip and is capable of measuring analog signals from specific analog IO pins.

ESP32-C61 has {SOC_ADC_PERIPH_NUM} ADC unit(s), which can be used in scenario(s) like:

  • Generate one-shot ADC conversion result

  • Generate continuous ADC conversion results

This guide introduces ADC oneshot mode conversion.

Functional Overview

The following sections of this document cover the typical steps to install and operate an ADC:

  • Resource Allocation - covers which parameters should be set up to get an ADC handle and how to recycle the resources when ADC finishes working.

  • Unit Configuration - covers the parameters that should be set up to configure the ADC unit, so as to get ADC conversion raw result.

  • Read Conversion Result - covers how to get ADC conversion raw result.

  • Hardware Limitations - describes the ADC-related hardware limitations.

  • Power Management - covers power management-related information.

  • IRAM Safe - describes tips on how to read ADC conversion raw results when the cache is disabled.

  • Thread Safety - lists which APIs are guaranteed to be thread-safe by the driver.

  • Kconfig Options - lists the supported Kconfig options that can be used to make a different effect on driver behavior.

Resource Allocation

The ADC oneshot mode driver is implemented based on ESP32-C61 SAR ADC module. Different ESP chips might have different numbers of independent ADCs. From the oneshot mode driver's point of view, an ADC instance is represented by adc_oneshot_unit_handle_t.

To install an ADC instance, set up the required initial configuration structure adc_oneshot_unit_init_cfg_t:

After setting up the initial configurations for the ADC, call adc_oneshot_new_unit() with the prepared adc_oneshot_unit_init_cfg_t. This function will return an ADC unit handle if the allocation is successful.

This function may fail due to various errors such as invalid arguments, insufficient memory, etc. Specifically, when the to-be-allocated ADC instance is registered already, this function will return ESP_ERR_NOT_FOUND error. Number of available ADC(s) is recorded by SOC_ADC_PERIPH_NUM.

If a previously created ADC instance is no longer required, you should recycle the ADC instance by calling adc_oneshot_del_unit(), related hardware and software resources will be recycled as well.

Create an ADC Unit Handle Under Normal Oneshot Mode

adc_oneshot_unit_handle_t adc1_handle;
adc_oneshot_unit_init_cfg_t init_config1 = {
    .unit_id = ADC_UNIT_1,
    .ulp_mode = ADC_ULP_MODE_DISABLE,
};
ESP_ERROR_CHECK(adc_oneshot_new_unit(&init_config1, &adc1_handle));

Recycle the ADC Unit

ESP_ERROR_CHECK(adc_oneshot_del_unit(adc1_handle));

Unit Configuration

After an ADC instance is created, set up the adc_oneshot_chan_cfg_t to configure ADC IOs to measure analog signal:

Note

For the IO corresponding ADC channel number, check datasheet to know the ADC IOs.

Additionally, adc_continuous_io_to_channel() and adc_continuous_channel_to_io() can be used to know the ADC channels and ADC IOs.

To make these settings take effect, call adc_oneshot_config_channel() with the above configuration structure. You should specify an ADC channel to be configured as well. Function adc_oneshot_config_channel() can be called multiple times to configure different ADC channels. The Driver will save each of these channel configurations internally.

Configure Two ADC Channels

adc_oneshot_chan_cfg_t config = {
    .bitwidth = ADC_BITWIDTH_DEFAULT,
    .atten = ADC_ATTEN_DB_12,
};
ESP_ERROR_CHECK(adc_oneshot_config_channel(adc1_handle, EXAMPLE_ADC1_CHAN0, &config));
ESP_ERROR_CHECK(adc_oneshot_config_channel(adc1_handle, EXAMPLE_ADC1_CHAN1, &config));

Read Conversion Result

After above configurations, the ADC is ready to measure the analog signal(s) from the configured ADC channel(s). Call adc_oneshot_read() to get the conversion raw result of an ADC channel.

  • adc_oneshot_read() is safe to use. ADC(s) are shared by some other drivers/peripherals, see Hardware Limitations. This function uses mutexes to avoid concurrent hardware usage. Therefore, this function should not be used in an ISR context. This function may fail when the ADC is in use by other drivers/peripherals, and return ESP_ERR_TIMEOUT. Under this condition, the ADC raw result is invalid.

This function will fail due to invalid arguments.

The ADC conversion results read from this function are raw data. To calculate the voltage based on the ADC raw results, this formula can be used:

Vout = Dout * Vmax / Dmax       (1)

where:

Vout

Digital output result, standing for the voltage.

Dout

ADC raw digital reading result.

Vmax

Maximum measurable input analog voltage, this is related to the ADC attenuation, please refer to TRM > On-Chip Sensor and Analog Signal Processing.

Dmax

Maximum of the output ADC raw digital reading result, which is 2^bitwidth, where bitwidth is the adc_oneshot_chan_cfg_t::bitwidth configured before.

To do further calibration to convert the ADC raw result to voltage in mV, please refer to calibration doc Analog to Digital Converter (ADC) Calibration Driver.

Read Raw Result

ESP_ERROR_CHECK(adc_oneshot_read(adc1_handle, EXAMPLE_ADC1_CHAN0, &adc_raw[0][0]));
ESP_LOGI(TAG, "ADC%d Channel[%d] Raw Data: %d", ADC_UNIT_1 + 1, EXAMPLE_ADC1_CHAN0, adc_raw[0][0]);

ESP_ERROR_CHECK(adc_oneshot_read(adc1_handle, EXAMPLE_ADC1_CHAN1, &adc_raw[0][1]));
ESP_LOGI(TAG, "ADC%d Channel[%d] Raw Data: %d", ADC_UNIT_1 + 1, EXAMPLE_ADC1_CHAN1, adc_raw[0][1]);

Hardware Limitations

  • Random Number Generator (RNG) uses ADC as an input source. When ADC adc_oneshot_read() works, the random number generated from RNG will be less random.

  • A specific ADC unit can only work under one operating mode at any one time, either continuous mode or oneshot mode. adc_oneshot_read() has provided the protection.

Power Management

When power management is enabled, i.e., CONFIG_PM_ENABLE is on, the system clock frequency may be adjusted when the system is in an idle state. However, the ADC oneshot mode driver works in a polling routine, the adc_oneshot_read() will poll the CPU until the function returns. During this period of time, the task in which ADC oneshot mode driver resides will not be blocked. Therefore the clock frequency is stable when reading.

IRAM Safe

By default, all the ADC oneshot mode driver APIs are not supposed to be run when the Cache is disabled. Cache may be disabled due to many reasons, such as Flash writing/erasing, OTA, etc. If these APIs execute when the Cache is disabled, you will probably see errors like Illegal Instruction or Load/Store Prohibited.

Thread Safety

Above functions are guaranteed to be thread-safe. Therefore, you can call them from different RTOS tasks without protection by extra locks.

  • adc_oneshot_del_unit() is not thread-safe. Besides, concurrently calling this function may result in failures of the above thread-safe APIs.

Kconfig Options

Application Examples

  • peripherals/adc/oneshot_read demonstrates how to obtain a one-shot ADC reading from a GPIO pin using the ADC one-shot mode driver and how to use the ADC Calibration functions to obtain a calibrated result in mV on ESP32-C61.

API Reference

Header File

Structures

struct adc_digi_pattern_config_t

ADC digital controller pattern configuration.

Public Members

uint8_t atten

Attenuation of this ADC channel.

uint8_t channel

ADC channel.

uint8_t unit

ADC unit.

uint8_t bit_width

ADC output bit width.

struct adc_digi_output_data_t

ADC digital controller (DMA mode) output data format. Used to analyze the acquired ADC (DMA) data.

Public Members

uint32_t data

ADC real output data info. Resolution: 12 bit.

uint32_t reserved12

Reserved12.

uint32_t channel

ADC channel index info. If (channel < ADC_CHANNEL_MAX), The data is valid. If (channel > ADC_CHANNEL_MAX), The data is invalid.

uint32_t reserved17_31

Reserved 17-31.

struct adc_digi_output_data_t::[anonymous]::[anonymous] type2

When the configured output format is 12bit.

uint32_t val

Raw data value

Type Definitions

typedef soc_periph_adc_digi_clk_src_t adc_oneshot_clk_src_t

Clock source type of oneshot mode which uses digital controller.

typedef soc_periph_adc_digi_clk_src_t adc_continuous_clk_src_t

Clock source type of continuous mode which uses digital controller.

Enumerations

enum adc_unit_t

ADC unit.

Values:

enumerator ADC_UNIT_1

SAR ADC 1.

enumerator ADC_UNIT_2

SAR ADC 2.

enum adc_channel_t

ADC channels.

Values:

enumerator ADC_CHANNEL_0

ADC channel.

enumerator ADC_CHANNEL_1

ADC channel.

enumerator ADC_CHANNEL_2

ADC channel.

enumerator ADC_CHANNEL_3

ADC channel.

enumerator ADC_CHANNEL_4

ADC channel.

enumerator ADC_CHANNEL_5

ADC channel.

enumerator ADC_CHANNEL_6

ADC channel.

enumerator ADC_CHANNEL_7

ADC channel.

enumerator ADC_CHANNEL_8

ADC channel.

enumerator ADC_CHANNEL_9

ADC channel.

enum adc_atten_t

ADC attenuation parameter. Different parameters determine the range of the ADC.

Values:

enumerator ADC_ATTEN_DB_0

No input attenuation, ADC can measure up to approx.

enumerator ADC_ATTEN_DB_2_5

The input voltage of ADC will be attenuated extending the range of measurement by about 2.5 dB.

enumerator ADC_ATTEN_DB_6

The input voltage of ADC will be attenuated extending the range of measurement by about 6 dB.

enumerator ADC_ATTEN_DB_12

The input voltage of ADC will be attenuated extending the range of measurement by about 12 dB.

enumerator ADC_ATTEN_DB_11

This is deprecated, it behaves the same as ADC_ATTEN_DB_12

enum adc_bitwidth_t

Values:

enumerator ADC_BITWIDTH_DEFAULT

Default ADC output bits, max supported width will be selected.

enumerator ADC_BITWIDTH_9

ADC output width is 9Bit.

enumerator ADC_BITWIDTH_10

ADC output width is 10Bit.

enumerator ADC_BITWIDTH_11

ADC output width is 11Bit.

enumerator ADC_BITWIDTH_12

ADC output width is 12Bit.

enumerator ADC_BITWIDTH_13

ADC output width is 13Bit.

enum adc_ulp_mode_t

Values:

enumerator ADC_ULP_MODE_DISABLE

ADC ULP mode is disabled.

enumerator ADC_ULP_MODE_FSM

ADC is controlled by ULP FSM.

enumerator ADC_ULP_MODE_RISCV

ADC is controlled by ULP RISCV.

enum adc_digi_convert_mode_t

ADC digital controller (DMA mode) work mode.

Values:

enumerator ADC_CONV_SINGLE_UNIT_1

Only use ADC1 for conversion.

enumerator ADC_CONV_SINGLE_UNIT_2

Only use ADC2 for conversion.

enumerator ADC_CONV_BOTH_UNIT

Use Both ADC1 and ADC2 for conversion simultaneously.

enumerator ADC_CONV_ALTER_UNIT

Use both ADC1 and ADC2 for conversion by turn. e.g. ADC1 -> ADC2 -> ADC1 -> ADC2 .....

enum adc_digi_output_format_t

ADC digital controller (DMA mode) output data format option.

Values:

enumerator ADC_DIGI_OUTPUT_FORMAT_TYPE1

See adc_digi_output_data_t.type1

enumerator ADC_DIGI_OUTPUT_FORMAT_TYPE2

See adc_digi_output_data_t.type2

enum adc_digi_iir_filter_t

ADC IIR Filter ID.

Values:

enumerator ADC_DIGI_IIR_FILTER_0

Filter 0.

enumerator ADC_DIGI_IIR_FILTER_1

Filter 1.

enum adc_digi_iir_filter_coeff_t

IIR Filter Coefficient.

Values:

enumerator ADC_DIGI_IIR_FILTER_COEFF_2

The filter coefficient is 2.

enumerator ADC_DIGI_IIR_FILTER_COEFF_4

The filter coefficient is 4.

enumerator ADC_DIGI_IIR_FILTER_COEFF_8

The filter coefficient is 8.

enumerator ADC_DIGI_IIR_FILTER_COEFF_16

The filter coefficient is 16.

enumerator ADC_DIGI_IIR_FILTER_COEFF_64

The filter coefficient is 64.

enum adc_monitor_id_t

ADC monitor (continuous mode) ID.

Values:

enumerator ADC_MONITOR_0

The monitor index 0.

enumerator ADC_MONITOR_1

The monitor index 1.

enum adc_monitor_mode_t

Monitor config/event mode type.

Values:

enumerator ADC_MONITOR_MODE_HIGH

ADC raw_result > threshold value, monitor interrupt will be generated.

enumerator ADC_MONITOR_MODE_LOW

ADC raw_result < threshold value, monitor interrupt will be generated.

Header File

  • components/esp_adc/include/esp_adc/adc_oneshot.h

  • This header file can be included with:

    #include "esp_adc/adc_oneshot.h"
    
  • This header file is a part of the API provided by the esp_adc component. To declare that your component depends on esp_adc, add the following to your CMakeLists.txt:

    REQUIRES esp_adc
    

    or

    PRIV_REQUIRES esp_adc
    

Functions

esp_err_t adc_oneshot_new_unit(const adc_oneshot_unit_init_cfg_t *init_config, adc_oneshot_unit_handle_t *ret_unit)

Create a handle to a specific ADC unit.

Note

This API is thread-safe. For more details, see ADC programming guide

Parameters
  • init_config -- [in] Driver initial configurations

  • ret_unit -- [out] ADC unit handle

Returns

  • ESP_OK: On success

  • ESP_ERR_INVALID_ARG: Invalid arguments

  • ESP_ERR_NO_MEM: No memory

  • ESP_ERR_NOT_FOUND: The ADC peripheral to be claimed is already in use

  • ESP_FAIL: Clock source isn't initialised correctly

esp_err_t adc_oneshot_config_channel(adc_oneshot_unit_handle_t handle, adc_channel_t channel, const adc_oneshot_chan_cfg_t *config)

Set ADC oneshot mode required configurations.

Note

This API is thread-safe. For more details, see ADC programming guide

Parameters
  • handle -- [in] ADC handle

  • channel -- [in] ADC channel to be configured

  • config -- [in] ADC configurations

Returns

  • ESP_OK: On success

  • ESP_ERR_INVALID_ARG: Invalid arguments

esp_err_t adc_oneshot_read(adc_oneshot_unit_handle_t handle, adc_channel_t chan, int *out_raw)

Get one ADC conversion raw result.

Note

This API is thread-safe. For more details, see ADC programming guide

Note

This API should NOT be called in an ISR context

Parameters
  • handle -- [in] ADC handle

  • chan -- [in] ADC channel

  • out_raw -- [out] ADC conversion raw result

Returns

  • ESP_OK: On success

  • ESP_ERR_INVALID_ARG: Invalid arguments

  • ESP_ERR_TIMEOUT: Timeout, the ADC result is invalid

esp_err_t adc_oneshot_del_unit(adc_oneshot_unit_handle_t handle)

Delete the ADC unit handle.

Note

This API is thread-safe. For more details, see ADC programming guide

Parameters

handle -- [in] ADC handle

Returns

  • ESP_OK: On success

  • ESP_ERR_INVALID_ARG: Invalid arguments

  • ESP_ERR_NOT_FOUND: The ADC peripheral to be disclaimed isn't in use

esp_err_t adc_oneshot_io_to_channel(int io_num, adc_unit_t *const unit_id, adc_channel_t *const channel)

Get ADC channel from the given GPIO number.

Parameters
  • io_num -- [in] GPIO number

  • unit_id -- [out] ADC unit

  • channel -- [out] ADC channel

Returns

  • ESP_OK: On success

  • ESP_ERR_INVALID_ARG: Invalid argument

  • ESP_ERR_NOT_FOUND: The IO is not a valid ADC pad

esp_err_t adc_oneshot_channel_to_io(adc_unit_t unit_id, adc_channel_t channel, int *const io_num)

Get GPIO number from the given ADC channel.

Parameters
  • unit_id -- [in] ADC unit

  • channel -- [in] ADC channel

  • io_num -- [out] GPIO number

  • - -- ESP_OK: On success

    • ESP_ERR_INVALID_ARG: Invalid argument

esp_err_t adc_oneshot_get_calibrated_result(adc_oneshot_unit_handle_t handle, adc_cali_handle_t cali_handle, adc_channel_t chan, int *cali_result)

Convenience function to get ADC calibrated result.

This is an all-in-one function which does:

  • oneshot read ADC raw result

  • calibrate the raw result and convert it into calibrated result (in mV)

Parameters
  • handle -- [in] ADC oneshot handle, you should call adc_oneshot_new_unit() to get this handle

  • cali_handle -- [in] ADC calibration handle, you should call adc_cali_create_scheme_x() in adc_cali_scheme.h to create a handle

  • chan -- [in] ADC channel

  • cali_result -- [out] Calibrated ADC result (in mV)

Returns

  • ESP_OK Other return errors from adc_oneshot_read() and adc_cali_raw_to_voltage()

Structures

struct adc_oneshot_unit_init_cfg_t

ADC oneshot driver initial configurations.

Public Members

adc_unit_t unit_id

ADC unit.

adc_oneshot_clk_src_t clk_src

Clock source.

adc_ulp_mode_t ulp_mode

ADC controlled by ULP, see adc_ulp_mode_t

struct adc_oneshot_chan_cfg_t

ADC channel configurations.

Public Members

adc_atten_t atten

ADC attenuation.

adc_bitwidth_t bitwidth

ADC conversion result bits.

Type Definitions

typedef struct adc_oneshot_unit_ctx_t *adc_oneshot_unit_handle_t

Type of ADC unit handle for oneshot mode.


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