micropython/docs/library/pyb.DAC.rst

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.. currentmodule:: pyb
.. _pyb.DAC:
class DAC -- digital to analog conversion
=========================================
The DAC is used to output analog values (a specific voltage) on pin X5 or pin X6.
The voltage will be between 0 and 3.3V.
*This module will undergo changes to the API.*
Example usage::
from pyb import DAC
dac = DAC(1) # create DAC 1 on pin X5
dac.write(128) # write a value to the DAC (makes X5 1.65V)
dac = DAC(1, bits=12) # use 12 bit resolution
dac.write(4095) # output maximum value, 3.3V
To output a continuous sine-wave::
import math
from pyb import DAC
# create a buffer containing a sine-wave
buf = bytearray(100)
for i in range(len(buf)):
buf[i] = 128 + int(127 * math.sin(2 * math.pi * i / len(buf)))
# output the sine-wave at 400Hz
dac = DAC(1)
dac.write_timed(buf, 400 * len(buf), mode=DAC.CIRCULAR)
To output a continuous sine-wave at 12-bit resolution::
import math
from array import array
from pyb import DAC
# create a buffer containing a sine-wave, using half-word samples
buf = array('H', 2048 + int(2047 * math.sin(2 * math.pi * i / 128)) for i in range(128))
# output the sine-wave at 400Hz
dac = DAC(1, bits=12)
dac.write_timed(buf, 400 * len(buf), mode=DAC.CIRCULAR)
Constructors
------------
.. class:: pyb.DAC(port, bits=8, *, buffering=None)
Construct a new DAC object.
``port`` can be a pin object, or an integer (1 or 2).
DAC(1) is on pin X5 and DAC(2) is on pin X6.
``bits`` is an integer specifying the resolution, and can be 8 or 12.
The maximum value for the write and write_timed methods will be
2\*\*``bits``-1.
The *buffering* parameter selects the behaviour of the DAC op-amp output
buffer, whose purpose is to reduce the output impedance. It can be
``None`` to select the default (buffering enabled for :meth:`DAC.noise`,
:meth:`DAC.triangle` and :meth:`DAC.write_timed`, and disabled for
:meth:`DAC.write`), ``False`` to disable buffering completely, or ``True``
to enable output buffering.
When buffering is enabled the DAC pin can drive loads down to 5KΩ.
Otherwise it has an output impedance of 15KΩ maximum: consequently
to achieve a 1% accuracy without buffering requires the applied load
to be less than 1.5MΩ. Using the buffer incurs a penalty in accuracy,
especially near the extremes of range.
Methods
-------
.. method:: DAC.init(bits=8, *, buffering=None)
Reinitialise the DAC. *bits* can be 8 or 12. *buffering* can be
``None``, ``False`` or ``True``; see above constructor for the meaning
of this parameter.
.. method:: DAC.deinit()
De-initialise the DAC making its pin available for other uses.
.. method:: DAC.noise(freq)
Generate a pseudo-random noise signal. A new random sample is written
to the DAC output at the given frequency.
.. method:: DAC.triangle(freq)
Generate a triangle wave. The value on the DAC output changes at the given
frequency and ramps through the full 12-bit range (up and down). Therefore
the frequency of the repeating triangle wave itself is 8192 times smaller.
.. method:: DAC.write(value)
Direct access to the DAC output. The minimum value is 0. The maximum
value is 2\*\*``bits``-1, where ``bits`` is set when creating the DAC
object or by using the ``init`` method.
.. method:: DAC.write_timed(data, freq, *, mode=DAC.NORMAL)
Initiates a burst of RAM to DAC using a DMA transfer.
The input data is treated as an array of bytes in 8-bit mode, and
an array of unsigned half-words (array typecode 'H') in 12-bit mode.
``freq`` can be an integer specifying the frequency to write the DAC
samples at, using Timer(6). Or it can be an already-initialised
Timer object which is used to trigger the DAC sample. Valid timers
are 2, 4, 5, 6, 7 and 8.
``mode`` can be ``DAC.NORMAL`` or ``DAC.CIRCULAR``.
Example using both DACs at the same time::
dac1 = DAC(1)
dac2 = DAC(2)
dac1.write_timed(buf1, pyb.Timer(6, freq=100), mode=DAC.CIRCULAR)
dac2.write_timed(buf2, pyb.Timer(7, freq=200), mode=DAC.CIRCULAR)