{IDF_TARGET_ANA_CMPR_SRC_CHAN0: default="NOT UPDATED", esp32h2="GPIO11", esp32p4="GPIO52"} {IDF_TARGET_ANA_CMPR_EXT_REF_CHAN0: default="NOT UPDATED", esp32h2="GPIO10", esp32p4="GPIO51"} {IDF_TARGET_ANA_CMPR_SRC_CHAN1: default="NOT UPDATED", esp32p4="GPIO54"} {IDF_TARGET_ANA_CMPR_EXT_REF_CHAN1: default="NOT UPDATED", esp32p4="GPIO53"}
Analog Comparator is a peripheral that can be used to compare a source signal with the internal reference voltage or an external reference signal.
It is a cost effective way to replace an amplifier comparator in some scenarios. But unlike the continuous comparing of the amplifier comparator, ESP Analog Comparator is driven by a source clock, which decides the sampling frequency.
Analog Comparator on {IDF_TARGET_NAME} has {IDF_TARGET_SOC_ANA_CMPR_NUM} unit(s), the channels in the unit(s) are:
UNIT0
- Source Channel: {IDF_TARGET_ANA_CMPR_SRC_CHAN0}
- External Reference Channel: {IDF_TARGET_ANA_CMPR_EXT_REF_CHAN0}
- Internal Reference Channel: Range 0% ~ 70% of the VDD, the step is 10% of the VDD
.. only:: esp32p4 **UNIT1** - Source Channel: {IDF_TARGET_ANA_CMPR_SRC_CHAN1} - External Reference Channel: {IDF_TARGET_ANA_CMPR_EXT_REF_CHAN1} - Internal Reference Channel: Range 0% ~ 70% of the VDD, the step is 10% of the VDD
The following sections of this document cover the typical steps to install and operate an Analog Comparator unit:
- Resource Allocation - covers which parameters should be set up to get a unit handle and how to recycle the resources when it finishes working.
- Further Configurations - covers the other configurations that might need to specific and what they are used for.
- Enable and Disable Unit - covers how to enable and disable the unit.
- Power Management - describes how different source clock selections can affect power consumption.
- IRAM Safe - lists which functions are supposed to work even 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.
.. only:: SOC_ANA_CMPR_SUPPORT_ETM - `ETM Events <#etm-events>`__ -
An Analog Comparator unit channel is represented by :cpp:type:`ana_cmpr_handle_t`. Each unit can support either an internal or an external reference.
To allocate the resource of the Analog Comparator unit, :cpp:func:`ana_cmpr_new_unit` need to be called to get the handle of the unit. Configurations :cpp:type:`ana_cmpr_config_t` need to be specified while allocating the unit:
- :cpp:member:`ana_cmpr_config_t::unit` selects the Analog Comparator unit.
- :cpp:member:`ana_cmpr_config_t::clk_src` selects the source clock for Analog Comparator, it can affect the sampling frequency. Note that the clock source of the Analog Comparator comes from the io mux, it is shared with GPIO extension peripherals like SDM (Sigma-Delta Modulation) and Glitch Filter. The configuration will fail if you specific different clock sources for multiple GPIO extension peripherals. The default clock sources of these peripherals are same, typically, we select :cpp:enumerator:`soc_periph_ana_cmpr_clk_src_t::ANA_CMPR_CLK_SRC_DEFAULT` as the clock source.
- :cpp:member:`ana_cmpr_config_t::ref_src` selects the reference source from internal voltage or external signal.
- :cpp:member:`ana_cmpr_config_t::cross_type` selects which kind of cross type can trigger the interrupt.
The function :cpp:func:`ana_cmpr_new_unit` can fail due to various errors such as insufficient memory, invalid arguments, etc. If a previously created Analog Comparator unit is no longer required, you should recycle it by calling :cpp:func:`ana_cmpr_del_unit`. It allows the underlying HW channel to be used for other purposes. Before deleting an Analog Comparator unit handle, you should disable it by :cpp:func:`ana_cmpr_unit_disable` in advance, or make sure it has not enabled yet by :cpp:func:`ana_cmpr_unit_enable`.
#include "driver/ana_cmpr.h"
ana_cmpr_handle_t cmpr = NULL;
ana_cmpr_config_t config = {
.unit = 0,
.clk_src = ANA_CMPR_CLK_SRC_DEFAULT,
.ref_src = ANA_CMPR_REF_SRC_INTERNAL,
.cross_type = ANA_CMPR_CROSS_ANY,
};
ESP_ERROR_CHECK(ana_cmpr_new_unit(&config, &cmpr));
// ...
ESP_ERROR_CHECK(ana_cmpr_del_unit(cmpr));
- :cpp:func:`ana_cmpr_set_intl_reference` - Specify the internal reference voltage when :cpp:enumerator:`ana_cmpr_ref_source_t::ANA_CMPR_REF_SRC_INTERNAL` is selected as reference source.
It requires :cpp:member:`ana_cmpr_internal_ref_config_t::ref_volt` to specify the voltage. The voltage related to the VDD power supply, which can only support a certain fixed percentage of VDD. Currently on {IDF_TARGET_NAME}, the internal reference voltage can be range to 0 ~ 70% VDD with a step 10%.
#include "driver/ana_cmpr.h"
ana_cmpr_internal_ref_config_t ref_cfg = {
.ref_volt = ANA_CMPR_REF_VOLT_50_PCT_VDD,
};
ESP_ERROR_CHECK(ana_cmpr_set_internal_reference(cmpr, &ref_cfg));
- :cpp:func:`ana_cmpr_set_debounce` - Set the debounce configuration.
It requires :cpp:member:`ana_cmpr_debounce_config_t::wait_us` to set the interrupt waiting time. The interrupt is disabled temporarily for :cpp:member:`ana_cmpr_debounce_config_t::wait_us` micro seconds, so that the frequent triggering can be avoid while the source signal crossing the reference signal. That is, the waiting time is supposed to be inverse ratio to the relative frequency between the source and reference. If the waiting time is set too short, it can not bypass the jitter totally, but if too long, the next crossing interrupt might be missed.
#include "driver/ana_cmpr.h"
ana_cmpr_debounce_config_t dbc_cfg = {
.wait_us = 1,
};
ESP_ERROR_CHECK(ana_cmpr_set_debounce(cmpr, &dbc_cfg));
- :cpp:func:`ana_cmpr_set_cross_type` - Set the source signal cross type.
The initial cross type is set int :cpp:func:`ana_cmpr_new_unit`, this function can update the cross type, even in ISR context.
#include "driver/ana_cmpr.h"
ESP_ERROR_CHECK(ana_cmpr_set_cross_type(cmpr, ANA_CMPR_CROSS_POS));
- :cpp:func:`ana_cmpr_register_event_callbacks` - Register the callbacks.
Currently it supports :cpp:member:`ana_cmpr_event_callbacks_t::on_cross`, it will be called when the crossing event (specified by :cpp:member:`ana_cmpr_config_t::cross_type`) occurs.
#include "driver/ana_cmpr.h"
static bool IRAM_ATTR example_ana_cmpr_on_cross_callback(ana_cmpr_handle_t cmpr,
const ana_cmpr_cross_event_data_t *edata,
void *user_ctx)
{
// ...
return false;
}
ana_cmpr_event_callbacks_t cbs = {
.on_cross = example_ana_cmpr_on_cross_callback,
};
ESP_ERROR_CHECK(ana_cmpr_register_event_callbacks(cmpr, &cbs, NULL));
Note
When :ref:`CONFIG_ANA_CMPR_ISR_IRAM_SAFE` is enabled, you should guarantee the callback context and involved data to be in internal RAM by add the attribute IRAM_ATTR
. (See more in IRAM Safe)
- :cpp:func:`ana_cmpr_enable` - Enable the Analog Comparator unit.
- :cpp:func:`ana_cmpr_disable` - Disable the Analog Comparator unit.
After the Analog Comparator unit is enabled and the crossing event interrupt is enabled, a power management lock will be acquired if the power management is enabled (see Power Management). Under the enable state, only :cpp:func:`ana_cmpr_set_intl_reference` and :cpp:func:`ana_cmpr_set_debounce` can be called, other functions can only be called after the unit is disabled.
Calling :cpp:func:`ana_cmpr_disable` does the opposite.
When power management is enabled (i.e., :ref:`CONFIG_PM_ENABLE` is on), the system will adjust the APB frequency before going into light sleep, thus potentially changing the resolution of the Analog Comparator.
However, the driver can prevent the system from changing APB frequency by acquiring a power management lock of type :cpp:enumerator:`ESP_PM_NO_LIGHT_SLEEP`. Whenever the driver creates a Analog Comparator unit instance that has selected the clock source like :cpp:enumerator:`ANA_CMPR_CLK_SRC_DEFAULT` or :cpp:enumerator:`ANA_CMPR_CLK_SRC_XTAL` as its clock source, the driver guarantees that the power management lock is acquired when enable the channel by :cpp:func:`ana_cmpr_enable`. Likewise, the driver releases the lock when :cpp:func:`ana_cmpr_disable` is called for that channel.
By default, the Analog Comparator interrupt will be deferred when the Cache is disabled for reasons like programming/erasing Flash. Thus the alarm interrupt will not get executed in time, which is not expected in a real-time application.
There is a Kconfig option :ref:`CONFIG_ANA_CMPR_ISR_IRAM_SAFE` that:
- Enables the interrupt being serviced even when cache is disabled
- Places all functions that used by the ISR into IRAM [1]
- Places driver object into DRAM (in case it is allocated on PSRAM)
This allows the interrupt to run while the cache is disabled but comes at the cost of increased IRAM consumption.
There is a Kconfig option :ref:`CONFIG_ANA_CMPR_CTRL_FUNC_IN_IRAM` that can put commonly used IO control functions into IRAM as well. So that these functions can also be executable when the cache is disabled. These IO control functions are listed as follows:
- :cpp:func:`ana_cmpr_set_internal_reference`
- :cpp:func:`ana_cmpr_set_debounce`
- :cpp:func:`ana_cmpr_set_cross_type`
The factory function :cpp:func:`ana_cmpr_new_unit` is guaranteed to be thread safe by the driver, which means, user can call it from different RTOS tasks without protection by extra locks. The following functions are allowed to run under ISR context, the driver uses a critical section to prevent them being called concurrently in both task and ISR.
- :cpp:func:`ana_cmpr_set_internal_reference`
- :cpp:func:`ana_cmpr_set_debounce`
- :cpp:func:`ana_cmpr_set_cross_type`
Other functions that take the :cpp:type:`ana_cmpr_handle_t` as the first positional parameter, are not treated as thread safe. Which means the user should avoid calling them from multiple tasks.
- :ref:`CONFIG_ANA_CMPR_ISR_IRAM_SAFE` controls whether the default ISR handler can work when cache is disabled, see IRAM Safe for more information.
- :ref:`CONFIG_ANA_CMPR_CTRL_FUNC_IN_IRAM` controls where to place the Analog Comparator control functions (IRAM or Flash), see IRAM Safe for more information.
- :ref:`CONFIG_ANA_CMPR_ENABLE_DEBUG_LOG` is used to enabled the debug log output. Enabling this option increases the firmware binary size.
.. only:: SOC_ANA_CMPR_SUPPORT_ETM ETM Events ^^^^^^^^^^ To create an analog comparator cross event, you need to include ``driver/ana_cmpr_etm.h`` additionally, and allocate the event by :cpp:func:`ana_cmpr_new_etm_event`. You can refer to :doc:`ETM </api-reference/peripherals/etm>` for how to connect an event to a task.
- :example:`peripherals/analog_comparator` shows the basic usage of the analog comparator, and other potential usages like hysteresis comparator and SPWM generator.
.. include-build-file:: inc/ana_cmpr.inc
.. include-build-file:: inc/ana_cmpr_types.inc
[1] | :cpp:member:`ana_cmpr_event_callbacks_t::on_cross` callback and the functions invoked by itself should also be placed in IRAM, you need to take care of them by themselves. |