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PMS7003 MicroPython Driver

This is a MicroPython adaptation inspired by this Raspberry implementation: https://www.raspberrypi.org/forums/viewtopic.php?p=1244895&sid=5f9dab0e19a7086f9b900b51316ff349#p1244895

Here you can find the data sheet from botland.com.pl

Caveats

UART

I used it with an ESP32. Tried with ESP8266 but since it has only one (full)UART that is being used by the REPL (and WebREPL) it was unusable. ESP32 has an unused UART (UART 2) that can be used to communicate with other devices. So you need a chip that has a free UART (like ESP32).

Voltage

The documentation claims that the device needs to run on 5V as it's internal fan is driven by 5V where the data pins output 3.3V for high. This was not the case for me I could not read any data other than zeros from the UART when running on 5V. Powering the whole device with 3.3V works fine (even though the fan may spin with slower). I tested running on 3.3V on six different PMS7003 devices. MicroPython forum link where I asked for help

Example usage

from pms7003 import Pms7003

pms = Pms7003(uart=2)
pms_data = pms.read()

Pms7003.read() will return a dictionary with the oldest read that is in the buffer. It means that your reads will always be a bit off in time, depending on the UART's buffer size and the frequency of your reads. It's generaly a good idea not to read faster than the device writes.

The dictionary will contain the following data:

Key Description
PM1_0 PM 1.0 concentration μ g/m3 (factory environment)
PM2_5 PM 2.5 concentration μ g/m3 (factory environment)
PM10_0 PM 10 concentration μ g/m3 (factory environment)
PM1_0_ATM PM 1.0 concentration μ g/m3 (atmospheric environment)
PM2_5_ATM PM 2.5 concentration μ g/m3 (atmospheric environment)
PM10_0_ATM PM 10 concentration μ g/m3 (atmospheric environment)
PCNT_0_3 Particle count of diameter beyond 0.3 um in 0.1 liter or air
PCNT_0_5 Particle count of diameter beyond 0.5 um in 0.1 liter or air
PCNT_1_0 Particle count of diameter beyond 1.0 um in 0.1 liter or air
PCNT_2_5 Particle count of diameter beyond 2.5 um in 0.1 liter or air
PCNT_5_0 Particle count of diameter beyond 5.0 um in 0.1 liter or air
PCNT_10_0 Particle count of diameter beyond 10 um in 0.1 liter or air

(and four more with FRAME_LENGTH, VERSION, ERROR and CHECKSUM)

Passive Driver

PMS7003 can work also in passive mode. It means that user has to request data explicitly by sending a command message with appropriate data. More about this article. Details are in datasheet as well.

import micropython
from pms7003 import PassivePms7003

pms = PassivePms7003(uart=2)

def do_work(__):
    pms.wakeup()
    
    pms_data = pms.read()
    print(pms_data)
    
    pms.sleep()

# usually performing readings in interrupt handler (e.g. Timer's)
# so use schedule to avoid heap lock limitations:
# https://docs.micropython.org/en/latest/reference/isr_rules.html
callback = lambda __: micropython.schedule(do_work, 0)

AQI

This repo also contains a simple class that can help calculate the Air Quality Index (as described here)

from pms7003 import Pms7003
from aqi import AQI

pms = Pms7003(uart=2)
pms_data = pms.read()
aqi = AQI.aqi(pms_data['PM2_5_ATM'], pms_data['PM10_0_ATM'])

AQI.aqi(pm2_5_atm, pm10_0_atm) returns an integer representing the AQI.

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Micropython driver for the PMS7003 Air Quality Sensor

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