Exercise 9: Analogue to Digital (ADC) and Digital to Analogue (DAC) conversion
Introduction
The ESP32 has two 12 bit SAR (
Successive
Approximation
Register)
Analogue to
Digital
Converters (ADCs) and two 8 bit
Digital to
Analogue
Converters on chip. Checking for drivers in the MicroPython manual I only find a
description of the ADC. Checking the MicroPython source code however, I see that also the driver for the DACs is available.
The ADC
ADC 2 is used for WiFi and therefore not accessible to us. ADC 1 however has multiplexed input and 8 ADC channels are available for use (on Pins 32-39). The ADC has a range 0..1V but attenuators are available. If we set the attenuation to 11 DB we get a voltage range of approximately 0 .. 3.6 V. Pin 36 and pin 26 are available on the WeMos D1 bus but pins on the ESP32 CPU card can also be used (e.g. pin 33, 34, 35).
The DAC
The DACs are accessible on pins 25 and 26. Since there is no description in the manual, here is the way how to access the DAC:
from machine import Pin,DAC
from time import sleep_ms
dac = DAC(Pin(26))
print("Running a triangular wave form with a frequency of ~ 1 Hz on pin 26")
while True:
for i in range(256):
dac.write(i)
sleep_ms(2)
for i in range(256):
dac.write(256-i-1)
sleep_ms(2)
This will generate a slow triangular wave form that can be observed on a multi-meter.
Checking linearity
If we connect the DAC output to the input of an ADC channel and we slowly ramp up the DAC value from 0 to its maximum and we read back the signal level with an ADC, then we expect a perfectly linear curve. This is true under the condition that both, the DAC and the ADC are perfectly linear.
linearity full range |
linearity restricted range |
|
|
As we can see, the curve becomes very non-linear for values above 200 (3.3V * 200 / 256 ~ 2.6 V). Unfortunately we do not know if the ADC or the DAC is responsible for this non-linearity. We need an external ADC to check. We also see that the line does not pass though 0,0 as it should.
--
Uli Raich - 2020-07-26
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