520 lines
17 KiB
ReStructuredText
520 lines
17 KiB
ReStructuredText
.. _esp32_quickref:
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Quick reference for the ESP32
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=============================
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.. image:: img/esp32.jpg
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:alt: ESP32 board
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:width: 640px
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The Espressif ESP32 Development Board (image attribution: Adafruit).
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Below is a quick reference for ESP32-based boards. If it is your first time
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working with this board it may be useful to get an overview of the microcontroller:
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.. toctree::
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:maxdepth: 1
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general.rst
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tutorial/intro.rst
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Installing MicroPython
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----------------------
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See the corresponding section of tutorial: :ref:`esp32_intro`. It also includes
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a troubleshooting subsection.
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General board control
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---------------------
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The MicroPython REPL is on UART0 (GPIO1=TX, GPIO3=RX) at baudrate 115200.
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Tab-completion is useful to find out what methods an object has.
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Paste mode (ctrl-E) is useful to paste a large slab of Python code into
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the REPL.
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The :mod:`machine` module::
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import machine
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machine.freq() # get the current frequency of the CPU
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machine.freq(240000000) # set the CPU frequency to 240 MHz
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The :mod:`esp` module::
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import esp
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esp.osdebug(None) # turn off vendor O/S debugging messages
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esp.osdebug(0) # redirect vendor O/S debugging messages to UART(0)
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# low level methods to interact with flash storage
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esp.flash_size()
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esp.flash_user_start()
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esp.flash_erase(sector_no)
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esp.flash_write(byte_offset, buffer)
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esp.flash_read(byte_offset, buffer)
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The :mod:`esp32` module::
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import esp32
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esp32.hall_sensor() # read the internal hall sensor
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esp32.raw_temperature() # read the internal temperature of the MCU, in Farenheit
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esp32.ULP() # access to the Ultra-Low-Power Co-processor
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Note that the temperature sensor in the ESP32 will typically read higher than
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ambient due to the IC getting warm while it runs. This effect can be minimised
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by reading the temperature sensor immediately after waking up from sleep.
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Networking
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----------
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The :mod:`network` module::
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import network
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wlan = network.WLAN(network.STA_IF) # create station interface
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wlan.active(True) # activate the interface
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wlan.scan() # scan for access points
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wlan.isconnected() # check if the station is connected to an AP
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wlan.connect('essid', 'password') # connect to an AP
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wlan.config('mac') # get the interface's MAC address
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wlan.ifconfig() # get the interface's IP/netmask/gw/DNS addresses
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ap = network.WLAN(network.AP_IF) # create access-point interface
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ap.config(essid='ESP-AP') # set the ESSID of the access point
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ap.active(True) # activate the interface
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A useful function for connecting to your local WiFi network is::
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def do_connect():
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import network
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wlan = network.WLAN(network.STA_IF)
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wlan.active(True)
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if not wlan.isconnected():
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print('connecting to network...')
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wlan.connect('essid', 'password')
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while not wlan.isconnected():
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pass
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print('network config:', wlan.ifconfig())
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Once the network is established the :mod:`socket <usocket>` module can be used
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to create and use TCP/UDP sockets as usual, and the ``urequests`` module for
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convenient HTTP requests.
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Delay and timing
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----------------
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Use the :mod:`time <utime>` module::
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import time
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time.sleep(1) # sleep for 1 second
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time.sleep_ms(500) # sleep for 500 milliseconds
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time.sleep_us(10) # sleep for 10 microseconds
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start = time.ticks_ms() # get millisecond counter
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delta = time.ticks_diff(time.ticks_ms(), start) # compute time difference
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Timers
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------
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Virtual (RTOS-based) timers are supported. Use the :ref:`machine.Timer <machine.Timer>` class
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with timer ID of -1::
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from machine import Timer
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tim = Timer(-1)
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tim.init(period=5000, mode=Timer.ONE_SHOT, callback=lambda t:print(1))
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tim.init(period=2000, mode=Timer.PERIODIC, callback=lambda t:print(2))
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The period is in milliseconds.
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.. _Pins_and_GPIO:
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Pins and GPIO
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-------------
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Use the :ref:`machine.Pin <machine.Pin>` class::
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from machine import Pin
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p0 = Pin(0, Pin.OUT) # create output pin on GPIO0
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p0.on() # set pin to "on" (high) level
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p0.off() # set pin to "off" (low) level
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p0.value(1) # set pin to on/high
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p2 = Pin(2, Pin.IN) # create input pin on GPIO2
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print(p2.value()) # get value, 0 or 1
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p4 = Pin(4, Pin.IN, Pin.PULL_UP) # enable internal pull-up resistor
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p5 = Pin(5, Pin.OUT, value=1) # set pin high on creation
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Available Pins are from the following ranges (inclusive): 0-19, 21-23, 25-27, 32-39.
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These correspond to the actual GPIO pin numbers of ESP32 chip. Note that many
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end-user boards use their own adhoc pin numbering (marked e.g. D0, D1, ...).
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For mapping between board logical pins and physical chip pins consult your board
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documentation.
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Notes:
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* Pins 1 and 3 are REPL UART TX and RX respectively
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* Pins 6, 7, 8, 11, 16, and 17 are used for connecting the embedded flash,
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and are not recommended for other uses
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* Pins 34-39 are input only, and also do not have internal pull-up resistors
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* The pull value of some pins can be set to ``Pin.PULL_HOLD`` to reduce power
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consumption during deepsleep.
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PWM (pulse width modulation)
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----------------------------
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PWM can be enabled on all output-enabled pins. The base frequency can
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range from 1Hz to 40MHz but there is a tradeoff; as the base frequency
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*increases* the duty resolution *decreases*. See
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`LED Control <https://docs.espressif.com/projects/esp-idf/en/latest/api-reference/peripherals/ledc.html>`_
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for more details.
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Use the ``machine.PWM`` class::
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from machine import Pin, PWM
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pwm0 = PWM(Pin(0)) # create PWM object from a pin
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pwm0.freq() # get current frequency
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pwm0.freq(1000) # set frequency
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pwm0.duty() # get current duty cycle
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pwm0.duty(200) # set duty cycle
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pwm0.deinit() # turn off PWM on the pin
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pwm2 = PWM(Pin(2), freq=20000, duty=512) # create and configure in one go
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ADC (analog to digital conversion)
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----------------------------------
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On the ESP32 ADC functionality is available on Pins 32-39. Note that, when
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using the default configuration, input voltages on the ADC pin must be between
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0.0v and 1.0v (anything above 1.0v will just read as 4095). Attenuation must
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be applied in order to increase this usable voltage range.
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Use the :ref:`machine.ADC <machine.ADC>` class::
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from machine import ADC
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adc = ADC(Pin(32)) # create ADC object on ADC pin
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adc.read() # read value, 0-4095 across voltage range 0.0v - 1.0v
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adc.atten(ADC.ATTN_11DB) # set 11dB input attenuation (voltage range roughly 0.0v - 3.6v)
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adc.width(ADC.WIDTH_9BIT) # set 9 bit return values (returned range 0-511)
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adc.read() # read value using the newly configured attenuation and width
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ESP32 specific ADC class method reference:
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.. method:: ADC.atten(attenuation)
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This method allows for the setting of the amount of attenuation on the
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input of the ADC. This allows for a wider possible input voltage range,
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at the cost of accuracy (the same number of bits now represents a wider
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range). The possible attenuation options are:
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- ``ADC.ATTN_0DB``: 0dB attenuation, gives a maximum input voltage
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of 1.00v - this is the default configuration
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- ``ADC.ATTN_2_5DB``: 2.5dB attenuation, gives a maximum input voltage
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of approximately 1.34v
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- ``ADC.ATTN_6DB``: 6dB attenuation, gives a maximum input voltage
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of approximately 2.00v
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- ``ADC.ATTN_11DB``: 11dB attenuation, gives a maximum input voltage
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of approximately 3.6v
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.. Warning::
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Despite 11dB attenuation allowing for up to a 3.6v range, note that the
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absolute maximum voltage rating for the input pins is 3.6v, and so going
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near this boundary may be damaging to the IC!
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.. method:: ADC.width(width)
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This method allows for the setting of the number of bits to be utilised
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and returned during ADC reads. Possible width options are:
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- ``ADC.WIDTH_9BIT``: 9 bit data
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- ``ADC.WIDTH_10BIT``: 10 bit data
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- ``ADC.WIDTH_11BIT``: 11 bit data
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- ``ADC.WIDTH_12BIT``: 12 bit data - this is the default configuration
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Software SPI bus
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----------------
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There are two SPI drivers. One is implemented in software (bit-banging)
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and works on all pins, and is accessed via the :ref:`machine.SPI <machine.SPI>`
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class::
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from machine import Pin, SPI
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# construct an SPI bus on the given pins
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# polarity is the idle state of SCK
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# phase=0 means sample on the first edge of SCK, phase=1 means the second
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spi = SPI(baudrate=100000, polarity=1, phase=0, sck=Pin(0), mosi=Pin(2), miso=Pin(4))
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spi.init(baudrate=200000) # set the baudrate
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spi.read(10) # read 10 bytes on MISO
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spi.read(10, 0xff) # read 10 bytes while outputting 0xff on MOSI
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buf = bytearray(50) # create a buffer
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spi.readinto(buf) # read into the given buffer (reads 50 bytes in this case)
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spi.readinto(buf, 0xff) # read into the given buffer and output 0xff on MOSI
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spi.write(b'12345') # write 5 bytes on MOSI
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buf = bytearray(4) # create a buffer
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spi.write_readinto(b'1234', buf) # write to MOSI and read from MISO into the buffer
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spi.write_readinto(buf, buf) # write buf to MOSI and read MISO back into buf
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.. Warning::
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Currently *all* of ``sck``, ``mosi`` and ``miso`` *must* be specified when
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initialising Software SPI.
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Hardware SPI bus
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----------------
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There are two hardware SPI channels that allow faster transmission
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rates (up to 80Mhz). These may be used on any IO pins that support the
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required direction and are otherwise unused (see :ref:`Pins_and_GPIO`)
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but if they are not configured to their default pins then they need to
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pass through an extra layer of GPIO multiplexing, which can impact
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their reliability at high speeds. Hardware SPI channels are limited
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to 40MHz when used on pins other than the default ones listed below.
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===== =========== ============
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\ HSPI (id=1) VSPI (id=2)
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===== =========== ============
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sck 14 18
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mosi 13 23
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miso 12 19
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===== =========== ============
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Hardware SPI has the same methods as Software SPI above::
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from machine import Pin, SPI
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hspi = SPI(1, 10000000, sck=Pin(14), mosi=Pin(13), miso=Pin(12))
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vspi = SPI(2, baudrate=80000000, polarity=0, phase=0, bits=8, firstbit=0, sck=Pin(18), mosi=Pin(23), miso=Pin(19))
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I2C bus
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-------
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The I2C driver has both software and hardware implementations, and the two
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hardware peripherals have identifiers 0 and 1. Any available output-capable
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pins can be used for SCL and SDA. The driver is accessed via the
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:ref:`machine.I2C <machine.I2C>` class::
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from machine import Pin, I2C
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# construct a software I2C bus
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i2c = I2C(scl=Pin(5), sda=Pin(4), freq=100000)
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# construct a hardware I2C bus
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i2c = I2C(0)
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i2c = I2C(1, scl=Pin(5), sda=Pin(4), freq=400000)
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i2c.scan() # scan for slave devices
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i2c.readfrom(0x3a, 4) # read 4 bytes from slave device with address 0x3a
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i2c.writeto(0x3a, '12') # write '12' to slave device with address 0x3a
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buf = bytearray(10) # create a buffer with 10 bytes
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i2c.writeto(0x3a, buf) # write the given buffer to the slave
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Real time clock (RTC)
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---------------------
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See :ref:`machine.RTC <machine.RTC>` ::
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from machine import RTC
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rtc = RTC()
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rtc.datetime((2017, 8, 23, 1, 12, 48, 0, 0)) # set a specific date and time
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rtc.datetime() # get date and time
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Deep-sleep mode
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---------------
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The following code can be used to sleep, wake and check the reset cause::
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import machine
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# check if the device woke from a deep sleep
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if machine.reset_cause() == machine.DEEPSLEEP_RESET:
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print('woke from a deep sleep')
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# put the device to sleep for 10 seconds
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machine.deepsleep(10000)
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Notes:
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* Calling ``deepsleep()`` without an argument will put the device to sleep
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indefinitely
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* A software reset does not change the reset cause
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* There may be some leakage current flowing through enabled internal pullups.
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To further reduce power consumption it is possible to disable the internal pullups::
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p1 = Pin(4, Pin.IN, Pin.PULL_HOLD)
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After leaving deepsleep it may be necessary to un-hold the pin explicitly (e.g. if
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it is an output pin) via::
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p1 = Pin(4, Pin.OUT, None)
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RMT
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---
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The RMT is ESP32-specific and allows generation of accurate digital pulses with
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12.5ns resolution. See :ref:`esp32.RMT <esp32.RMT>` for details. Usage is::
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import esp32
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from machine import Pin
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r = esp32.RMT(0, pin=Pin(18), clock_div=8)
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r # RMT(channel=0, pin=18, source_freq=80000000, clock_div=8)
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# The channel resolution is 100ns (1/(source_freq/clock_div)).
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r.write_pulses((1, 20, 2, 40), start=0) # Send 0 for 100ns, 1 for 2000ns, 0 for 200ns, 1 for 4000ns
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OneWire driver
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--------------
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The OneWire driver is implemented in software and works on all pins::
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from machine import Pin
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import onewire
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ow = onewire.OneWire(Pin(12)) # create a OneWire bus on GPIO12
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ow.scan() # return a list of devices on the bus
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ow.reset() # reset the bus
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ow.readbyte() # read a byte
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ow.writebyte(0x12) # write a byte on the bus
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ow.write('123') # write bytes on the bus
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ow.select_rom(b'12345678') # select a specific device by its ROM code
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There is a specific driver for DS18S20 and DS18B20 devices::
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import time, ds18x20
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ds = ds18x20.DS18X20(ow)
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roms = ds.scan()
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ds.convert_temp()
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time.sleep_ms(750)
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for rom in roms:
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print(ds.read_temp(rom))
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Be sure to put a 4.7k pull-up resistor on the data line. Note that
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the ``convert_temp()`` method must be called each time you want to
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sample the temperature.
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NeoPixel driver
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---------------
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Use the ``neopixel`` module::
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from machine import Pin
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from neopixel import NeoPixel
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pin = Pin(0, Pin.OUT) # set GPIO0 to output to drive NeoPixels
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np = NeoPixel(pin, 8) # create NeoPixel driver on GPIO0 for 8 pixels
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np[0] = (255, 255, 255) # set the first pixel to white
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np.write() # write data to all pixels
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r, g, b = np[0] # get first pixel colour
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For low-level driving of a NeoPixel::
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import esp
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esp.neopixel_write(pin, grb_buf, is800khz)
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.. Warning::
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By default ``NeoPixel`` is configured to control the more popular *800kHz*
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units. It is possible to use alternative timing to control other (typically
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400kHz) devices by passing ``timing=0`` when constructing the
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``NeoPixel`` object.
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Capacitive touch
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----------------
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Use the ``TouchPad`` class in the ``machine`` module::
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from machine import TouchPad, Pin
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t = TouchPad(Pin(14))
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t.read() # Returns a smaller number when touched
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``TouchPad.read`` returns a value relative to the capacitive variation. Small numbers (typically in
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the *tens*) are common when a pin is touched, larger numbers (above *one thousand*) when
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no touch is present. However the values are *relative* and can vary depending on the board
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and surrounding composition so some calibration may be required.
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There are ten capacitive touch-enabled pins that can be used on the ESP32: 0, 2, 4, 12, 13
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14, 15, 27, 32, 33. Trying to assign to any other pins will result in a ``ValueError``.
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Note that TouchPads can be used to wake an ESP32 from sleep::
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import machine
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from machine import TouchPad, Pin
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import esp32
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t = TouchPad(Pin(14))
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t.config(500) # configure the threshold at which the pin is considered touched
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esp32.wake_on_touch(True)
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machine.lightsleep() # put the MCU to sleep until a touchpad is touched
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For more details on touchpads refer to `Espressif Touch Sensor
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<https://docs.espressif.com/projects/esp-idf/en/latest/api-reference/peripherals/touch_pad.html>`_.
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DHT driver
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----------
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The DHT driver is implemented in software and works on all pins::
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import dht
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import machine
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d = dht.DHT11(machine.Pin(4))
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d.measure()
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d.temperature() # eg. 23 (°C)
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d.humidity() # eg. 41 (% RH)
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d = dht.DHT22(machine.Pin(4))
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d.measure()
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d.temperature() # eg. 23.6 (°C)
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d.humidity() # eg. 41.3 (% RH)
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WebREPL (web browser interactive prompt)
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----------------------------------------
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WebREPL (REPL over WebSockets, accessible via a web browser) is an
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experimental feature available in ESP32 port. Download web client
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from https://github.com/micropython/webrepl (hosted version available
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at http://micropython.org/webrepl), and configure it by executing::
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import webrepl_setup
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and following on-screen instructions. After reboot, it will be available
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for connection. If you disabled automatic start-up on boot, you may
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run configured daemon on demand using::
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import webrepl
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webrepl.start()
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# or, start with a specific password
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webrepl.start(password='mypass')
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The WebREPL daemon listens on all active interfaces, which can be STA or
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AP. This allows you to connect to the ESP32 via a router (the STA
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interface) or directly when connected to its access point.
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In addition to terminal/command prompt access, WebREPL also has provision
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for file transfer (both upload and download). The web client has buttons for
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the corresponding functions, or you can use the command-line client
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``webrepl_cli.py`` from the repository above.
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See the MicroPython forum for other community-supported alternatives
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to transfer files to an ESP32 board.
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