Asked 19 days ago
Viewed 260 times
Raspberry Pico Pi, how can micropython be used to get the values from a MEMS microphone such as the
Adafruit Silicon MEMS Microphone Breakout - SPW2430 link to ada fruit Product ID: 2716.
Can this be connected to a GPIO pin and then in a while true loop read the pin outputs which are then fed into a speaker? Since the breakout board should be returning digital signals then the CPIO pins can be used directly and if so how should it be implemented? If code directly is not provided some overall pseudo code would be great.
- microphone0 watchers 59 questionsHelp us edit this wiki Watch tag Ignore tag
asked Dec 30, 2022 at 22:29
13355 bronze badges
- 1I goggled :How to convert PDM to analog?” and got the following answer: The process of decoding a PDM signal into an analog one is simple: one only has to pass the PDM signal through a low-pass filter. This works because the function of a low-pass filter is essentially to average the signal. – tlfong01 Dec 31, 2022 at 3:50
- 1Have you actually read the link you posted. This device outputs line-level analog. – Milliways Dec 31, 2022 at 5:05
- 1@Vass: It is not clear what sort of audio signal you wish to process. I would suggest to begin with experimenting with the simplest, say 1 kHz: 1k Hz Tone Test Tone – Sonic Electronix youtube.com/watch?v=TbPh0pmNjo8 – tlfong01 Dec 31, 2022 at 7:04
- 1If you agree 1kHz tone signal is good to start with, I would then suggest how to connect the MEMS mic output to a PicoW GPIO pin and count the number of pulses, … – tlfong01 Dec 31, 2022 at 7:10
- 1@tlfong01, that is a great recommendation, do you know the pseudo-code for that in micropython or C? – Vass Dec 31, 2022 at 15:35
Reset to default Highest score (default) Date modified (newest first) Date created (oldest first)
How can PicoW read MEMS digital microphone output?
17.0 For the preliminary testing, I am only considering PLL A and Clock 0:
16.0 Using declarative programming tools to convert Si5351 flowchart/pseudo code to ADT (Abstract Data Type) for preventive/troubleshooting/newbie proof/friendly program development.
I found the Github libraries out there too powerful and comprehensive for newbie like me difficult to understand and use. So I am thinking to make to the six or seven pseudo as simple as possible. As a example/case study, I would start with the first pseudo statement:
15.0 Programming Considerations
I found the Si5351 Clock setup procedure straightforward, and therefore to translate it to pseudocode, and if I use functional programming technique, translate it further to a couple of high level programs. One problem is that the free Window 10 SkyClock’s Clock Builder app is no longer available, so I need to calculate parameters, using my always dodgy arithmetic.
14.0 Writing a MicroPython program to set up Si5153 2MHz Clock
The I2C read/write registers function seem OK, Next step is to setup a 2MHz clock for the digital PDM microphone module MT40DT01. I am following the following programming procedure.
12.0 Testing writing to si5351 registers
11.0 Using PicoW I2C1 (GP6, 7) to control Si5351 (address 0x60)
10.0 Si5351 HF Clock Gen Wiring
0.9 Si5351 testing notes
I found Si5351 HF square wave sig gen seemingly flexible and easy to use (There are quite a number of AdaFruit and Arduino tutorials around!). So I have begun reading the datasheet and trying to write a simple PicoW micropython python to test it.
0.8 1MHz to 3.5MHz Clock for MT40DT01
The 1MHz Clock works for MT40DT01. However it is expensive and awkward to handle. So I am looking for an alternative. The following looks good.
0.7 MT40DT01 now with external 1 MHz clock outputs something
0.6 Microphone not working because input frequency to low, < 1MHz
Earlier I used 200kHz as clock frequency but found nothing happening. I checked the datasheet and found that the minimum frequency is 1 MHz (Max 3.5MHz). Now I have a problem, because it seems that the PicoW’s system timers are software timers and so could not support too many clocks at high frequency higher than 500 KHz. So now I need to check if an external clock > 1MHz can solve the problem.
0.5 Real time test setup
mt40dt01 test program listing – https://penzu.com/p/2f213cb6
0.4 Creating 4 PicoW system clocks, two for real time tone signals, two for MT34DT01 MEMS digital microphone clock inputs
# PicoW Mems Digi Mic v16.0 - tlfong01 2023jan07hkt2138 import machine import utime from machine import Pin, Timer, RTC print('MemsDigiMicV16.0, 2023jan07hkt2138') redFreq = 20000 # DigiMic #1 Clock signal grnFreq = 4 # For troubleshooting redLed = Pin(0, Pin.OUT, value = 1) # Create Red LED object, init On grnLed = Pin(1, Pin.OUT, value = 1) # Create grn LED object, init On redTimer = Timer() # Red LED timer, callback toggleRedLed grnTimer = Timer() # Grn LED timer, callback toggleGrnLed def toggleRedLed(dummy): #ISR RedLed redLed.toggle() return def togglegrnLed(dummy): #ISR grnLed grnLed.toggle() return redTimer.init(freq = redFreq, mode = Timer.PERIODIC, callback = toggleRedLed) grnTimer.init(freq = grnFreq, mode = Timer.PERIODIC, callback = togglegrnLed) utime.sleep(10) redTimer.deinit() grnTimer.deinit() redLed.off() grnLed.off() # *** End of program ***
0.3 Using MT34DT01 MEMS Digital Microphone for Very simple Speech Recognition
The MP34DT01-M MEMS digital microphone datashheet says it can be used for AI applications such as speech recognition, (Ref 1). Now I am thinking of exploring the fisibility of doing very simple speech recognition, say, for a very, very small subset of audio signals, denoting doggie commands like “Sit”, “Eat”, “OK” etc.
I read that it is practical to use Rpi python to do Alphabet reqognition of 26 handwritten patterns A to Z, using CNN (Convolutional Neural Network), for example, Glezer, Ref 2. In CNN application usually represent one visual paatern, say one alphabet, by a liner list of bits. For audio patterns, I think we can also similarly represent doggie commends “Sit”, “Eat” etc, each by a list of bits.
The MEMS digital microphone MP34DT01 seems ideal for our simple application. This is what will explored in the subsquent sections.
0.2 Tone Generator and Frequency Counter Schematic
0.1 MEMS PDM Digital Microphone MT34DT01 Test Setup V0.1
We can connect the MEMS microphone output pin to a PicoW GPIO pin and read signal, into a list for later processing.
For prototyping, we can simulate the microphone output signal as a GPIO output pin connected blinking LED, and use another GPIO input pin to read the blinking LED pin.
3. Trying Blink rates 1kHz, 2kHx, to simulate 1kHz, 2kHz tones
*4. The OP wishes to connect the MEMS digital mic output to PicoW. So now I am looking at the real thing.
5. MP34DT01-M MEMS audio sensor omnidirectional digital microphone
6. MT34DT01 MEMS Digital Microphone
9. / to continue, …
Appendix A – MicroPython program blinking two LEDs simulating two MEMS digital microphone output signals
# Pico W Blink Two LEDs - tlfong01 2023jan01hkt1941 # *** Modules *** import machine from machine import Pin, Timer # *** Configuration*** redLed = Pin(0, Pin.OUT) greenLed = Pin(1, Pin.OUT) redFreq = 2 greenFreq = 4 redTimer = Timer() greenTimer = Timer() # *** Callbacks *** def blinkRedLed(dummy): redLed.toggle() return def blinkGreenLed(dummy): greenLed.toggle() return # *** Main *** redTimer.init(freq = redFreq, mode = Timer.PERIODIC, callback = blinkRedLed) greenTimer.init(freq = greenFreq, mode = Timer.PERIODIC, callback = blinkGreenLed) # *** End of program ***
Appendix B – Blinking LEDs Video
Appendix C – MEMS Mic, PicoW GPIO Eval Brd Setup
# PicoW GPIO Input Testing v7.0 - tlfong01 2023jan02hkt1410 # *** 1.0 Modules *** import machine import utime from machine import Pin, Timer # *** 2.0 Configuration and Functions *** # 2.1 Blinking LED Configurations and Functions redFreq = 6 # Red LED blinking frequency greenFreq = 3 # Green LED blinking frequency redLed = Pin(0, Pin.OUT, value = 1) # Create Red LED object, init On greenLed = Pin(1, Pin.OUT, value = 1) # Create Green LED object, init On redTimer = Timer() # Red LED timer, callback blinkRedLed greenTimer = Timer() # Greed LED timer, callback blinkGreenLed # 2.2 Blinking LED Callbacks def blinkRedLed(dummy): redLed.toggle() return def blinkGreenLed(dummy): greenLed.toggle() return # *** 3.0 GPIO Input Configurations and Functions *** readGpioPin2 = Pin(2, Pin.IN, Pin.PULL_UP) # Create GPIO input pin object readGpioPin3 = Pin(3, Pin.IN, Pin.PULL_UP) # Create GPIO input pin object def readRedLed(): ledStatus = readGpioPin2() if ledStatus == 1: return "High" else: return "Low" def readGreenLed(): ledStatus = readGpioPin3() if ledStatus == 1: return "High" else: return "Low" def readPrintRedGreenLedStatus(): redLedStatus = readRedLed() greenLedStatus = readGreenLed() print('RedLedStatus =', redLedStatus) print('GreenLedStatus =', greenLedStatus) return ### *** 4.0 / to continue, ... *** # *** 9.0 Main *** # 9.1 Run Red/Green Timer for 2 seconds redTimer.init(freq = redFreq, mode = Timer.PERIODIC, callback = blinkRedLed) greenTimer.init(freq = greenFreq, mode = Timer.PERIODIC, callback = blinkGreenLed) utime.sleep(2) redTimer.deinit() greenTimer.deinit() # 9.2 Set/Read/Print Red/Green LED status redLed.on() greenLed.on() readPrintRedGreenLedStatus() # *** End of program ***
answered Jan 1 at 12:29
4,48933 gold badges99 silver badges2424 bronze badges