First Commit
3
Example - 7 Segment/README.md
Normal file
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# 7 Segment Example Code #
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I adapted original code from somewhere into this code. There is an example how to use the code in **main section** of the code.
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151
Example - 7 Segment/main_7Segment.py
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from machine import Pin
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from time import time,sleep
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from utime import sleep_ms
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# Map 1st Segment Pins
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d1_p1 = Pin(2,Pin.OUT) # E
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d1_p2 = Pin(3,Pin.OUT) # D
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d1_p3 = Pin(4,Pin.OUT) # DP
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d1_p4 = Pin(5,Pin.OUT) # C
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d1_p5 = Pin(6,Pin.OUT) # G
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d1_p7 = Pin(22,Pin.OUT) # B
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d1_p10 = Pin(26,Pin.OUT) # F
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d1_p11 = Pin(27,Pin.OUT) # A
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# Map 1st Digit Pins
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c1_1 = Pin(10,Pin.OUT)
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c1_2 = Pin(9,Pin.OUT)
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c1_3 = Pin(8,Pin.OUT)
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# Map 2nd Segment Pins
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d2_p1 = Pin(11,Pin.OUT) # E
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d2_p2 = Pin(12,Pin.OUT) # D
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d2_p3 = Pin(13,Pin.OUT) # DP
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d2_p4 = Pin(14,Pin.OUT) # C
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d2_p5 = Pin(15,Pin.OUT) # G
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d2_p7 = Pin(16,Pin.OUT) # B
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d2_p10 = Pin(17,Pin.OUT) # F
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d2_p11 = Pin(18,Pin.OUT) # A
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# Map 2nd Digit Pins
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c2_1 = Pin(19,Pin.OUT)
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c2_2 = Pin(20,Pin.OUT)
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c2_3 = Pin(21,Pin.OUT)
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# Store into Lists
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c1_pins = [c1_1,c1_2,c1_3]
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d1_pins = [d1_p11,d1_p7,d1_p4,d1_p2,d1_p1,d1_p10,d1_p5]
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c2_pins = [c2_1,c2_2,c2_3]
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d2_pins = [d2_p11,d2_p7,d2_p4,d2_p2,d2_p1,d2_p10,d2_p5]
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# Define Numeric Patterns
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num_patterns = [
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0b1111110, # 0
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0b0110000, # 1
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0b1101101, # 2
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0b1111001, # 3
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0b0110011, # 4
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0b1011011, # 5
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0b1011111, # 6
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0b1110000, # 7
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0b1111111, # 8
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0b1111011 # 9
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]
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def turnDigits(board,power):
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if(board == 1):
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if(power):
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for control in c1_pins:
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control.value(0)
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else:
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for control in c1_pins:
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control.value(1)
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else:
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if(power):
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for control in c2_pins:
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control.value(0)
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else:
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for control in c2_pins:
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control.value(1)
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def switchDigits(board,digit):
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if(board == 1):
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if(digit == 0):
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c1_pins[0].value(0)
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c1_pins[1].value(1)
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c1_pins[2].value(1)
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elif(digit == 1):
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c1_pins[0].value(1)
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c1_pins[1].value(0)
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c1_pins[2].value(1)
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else:
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c1_pins[0].value(1)
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c1_pins[1].value(1)
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c1_pins[2].value(0)
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else:
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if(digit == 0):
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c2_pins[0].value(0)
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c2_pins[1].value(1)
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c2_pins[2].value(1)
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elif(digit == 1):
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c2_pins[0].value(1)
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c2_pins[1].value(0)
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c2_pins[2].value(1)
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else:
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c2_pins[0].value(1)
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c2_pins[1].value(1)
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c2_pins[2].value(0)
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def displayNumber(board,number):
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# Extract the individual digits from the number
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num1 = number // 100
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num2 = (number % 100) // 10
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num3 = number % 10
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# Turn Off All
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turnDigits(board,False)
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start_time = time()
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# Display the digits on the 7-segment display
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while time() - start_time < .25:
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switchDigits(board,0)
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setDisplay(board, 0, num3)
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sleep_ms(5)
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switchDigits(board,1)
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setDisplay(board, 1, num2)
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sleep_ms(5)
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switchDigits(board,2)
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setDisplay(board, 2, num1)
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sleep_ms(5)
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else:
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turnDigits(board,False)
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def setDisplay(board,digit,num):
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if(board == 1):
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# Set Pattern to Display
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for i, pin in enumerate(d1_pins):
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pattern = num_patterns[num]
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target = (pattern >> (6 - i)) & 1
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pin.value(target)
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else:
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# Set Pattern to Display
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for i, pin in enumerate(d2_pins):
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pattern = num_patterns[num]
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target = (pattern >> (6 - i)) & 1
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pin.value(target)
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# Main Script
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def main():
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board = 1
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powerOff = False
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if(powerOff):
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turnDigits(board,False)
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else:
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for data in range(100):
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displayNumber(board,data)
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if __name__ == "__main__":
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main()
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3
Example - ADC Reading/README.md
Normal file
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# ADC Reading Example Code #
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This is a simple code to read ADC using MicroPython.
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11
Example - ADC Reading/main_ReadADC.py
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from machine import ADC
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import time
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# Assign ADC Pin 0 to Sensor
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sensor = ADC(0)
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# Repeatedly Read u16 value and print
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while True:
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result = sensor.read_u16()
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print(result)
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time.sleep(1)
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36
Example - Blynk API/BlynkAPI.py
Normal file
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from urequests import get
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## Blynk API Class
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class BlynkAPI:
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# Initialize Blynk API Class
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def __init__(self):
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self.server_address: str = "blynk.cloud"
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self.token: str = "<Put Yout Token Here>"
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self.fetch_link = f"https://{self.server_address}/external/api/get?token={self.token}&"
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self.update_link = f"https://{self.server_address}/external/api/update?token={self.token}&"
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# Method to get vpin value (pin: v0, v1, v2, ...)
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def fetchPin(self, pin: str):
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response = get(self.fetch_link+pin)
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result = response.json() # For some reason this line will cause some devices to stuck. Only to limited to Blynk API Response
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status = response.status_code
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response.close()
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return status, result # Return Status Code and Result
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# Method to update vpin value (pin: v0, v1, v2, ...; value: int or str)
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def updatePin(self, pin: str, value):
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if type(value) is int:
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value = str(value)
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response = get(self.update_link+pin+"="+value)
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status = response.status_code
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response.close
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return status # Return Status Code
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## Usage Sample
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def main():
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# Connect to Network
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# Initialize Class
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api = BlynkAPI()
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status, result = fetchPin("v0") # Fetch vPin v0
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status = updatePin("v1", 10) # Update vPin v1 to 10
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3
Example - Blynk API/README.md
Normal file
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# Blynk HTTP API Access Example Code #
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This is a simple Blynk HTTP API access using MicroPython. However, for some reason there is a problem extracting data from Blynk HTTP API. This problem only limited to Blynk HTTP API response data.
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3
Example - DHT11/README.md
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# DHT11/22 Reading Example Code #
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This is a simple code for reading DHT11/22 sensor using MicroPython. With extra LED blinks
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32
Example - DHT11/main_DHT11.py
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from machine import Pin
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from time import sleep
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import dht
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from utime import sleep_ms
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# Define DHT Version (11 or 22) and Input Pin
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sensor = dht.DHT22(Pin(16))
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# Define Onboard LED Pin
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led = Pin(2,Pin.OUT)
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# Turn it off first
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led.value(0)
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# Define blink function
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def blink():
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led.value(0)
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sleep_ms(50)
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led.value(1)
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# Main Script Here
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while True:
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try:
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sleep(2)
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sensor.measure()
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temp = sensor.temperature()
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hum = sensor.humidity()
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if(temp > 24.0 or hum > 49.0):
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blink()
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print('Temperature: %3.1f C' %temp)
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print('Humidity: %3.1f %%' %hum)
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print("")
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except OSError as e:
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print('Failed to read sensor.')
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7
Example - HCSR04 Ultrasonic/README.md
Normal file
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# HC-SR04 Example Code #
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This code show how to use the HC-SR04 Ultrasonic Sensor using Micropython.
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* Original Driver code : https://github.com/rsc1975/micropython-hcsr04/tree/master.
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* The main code I made it myself.
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82
Example - HCSR04 Ultrasonic/hcsr04.py
Normal file
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from machine import Pin, time_pulse_us
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from utime import sleep_us
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__version__ = '0.2.1'
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__author__ = 'Roberto Sánchez'
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__license__ = "Apache License 2.0. https://www.apache.org/licenses/LICENSE-2.0"
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class HCSR04:
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"""
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Driver to use the untrasonic sensor HC-SR04.
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The sensor range is between 2cm and 4m.
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The timeouts received listening to echo pin are converted to OSError('Out of range')
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"""
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# echo_timeout_us is based in chip range limit (400cm)
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def __init__(self, trigger_pin, echo_pin, echo_timeout_us=500*2*30):
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"""
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trigger_pin: Output pin to send pulses
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echo_pin: Readonly pin to measure the distance. The pin should be protected with 1k resistor
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echo_timeout_us: Timeout in microseconds to listen to echo pin.
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By default is based in sensor limit range (4m)
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"""
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self.echo_timeout_us = echo_timeout_us
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# Init trigger pin (out)
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self.trigger = Pin(trigger_pin, mode=Pin.OUT, pull=None)
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self.trigger.value(0)
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# Init echo pin (in)
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self.echo = Pin(echo_pin, mode=Pin.IN, pull=None)
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def _send_pulse_and_wait(self):
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"""
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Send the pulse to trigger and listen on echo pin.
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We use the method `machine.time_pulse_us()` to get the microseconds until the echo is received.
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"""
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self.trigger.value(0) # Stabilize the sensor
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sleep_us(5)
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self.trigger.value(1)
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# Send a 10us pulse.
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sleep_us(10)
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self.trigger.value(0)
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try:
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pulse_time = time_pulse_us(self.echo, 1, self.echo_timeout_us)
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# time_pulse_us returns -2 if there was timeout waiting for condition; and -1 if there was timeout during the main measurement. It DOES NOT raise an exception
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# ...as of MicroPython 1.17: http://docs.micropython.org/en/v1.17/library/machine.html#machine.time_pulse_us
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if pulse_time < 0:
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MAX_RANGE_IN_CM = const(500) # it's really ~400 but I've read people say they see it working up to ~460
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pulse_time = int(MAX_RANGE_IN_CM * 29.1) # 1cm each 29.1us
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return pulse_time
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except OSError as ex:
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if ex.args[0] == 110: # 110 = ETIMEDOUT
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raise OSError('Out of range')
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raise ex
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def distance_mm(self):
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"""
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Get the distance in milimeters without floating point operations.
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"""
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pulse_time = self._send_pulse_and_wait()
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# To calculate the distance we get the pulse_time and divide it by 2
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# (the pulse walk the distance twice) and by 29.1 becasue
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# the sound speed on air (343.2 m/s), that It's equivalent to
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# 0.34320 mm/us that is 1mm each 2.91us
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# pulse_time // 2 // 2.91 -> pulse_time // 5.82 -> pulse_time * 100 // 582
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mm = pulse_time * 100 // 582
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return mm
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def distance_cm(self):
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"""
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Get the distance in centimeters with floating point operations.
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It returns a float
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"""
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pulse_time = self._send_pulse_and_wait()
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# To calculate the distance we get the pulse_time and divide it by 2
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# (the pulse walk the distance twice) and by 29.1 becasue
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# the sound speed on air (343.2 m/s), that It's equivalent to
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# 0.034320 cm/us that is 1cm each 29.1us
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cms = (pulse_time / 2) / 29.1
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return cms
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24
Example - HCSR04 Ultrasonic/main_Ultrasonic.py
Normal file
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from hcsr04 import HCSR04
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from time import sleep
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from machine import Pin
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from utime import sleep_ms
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# Load Driver and Assign Each Pin
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sensor = HCSR04(trigger_pin=4, echo_pin=5, echo_timeout_us=10000)
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# LED Pin for Fun
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led = Pin(2,Pin.OUT)
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led.value(0)
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# Create Blink Function
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def blink():
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led.value(0)
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sleep_ms(50)
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led.value(1)
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# Main Script Here
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while True:
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distance = sensor.distance_cm()
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print('Distance:', distance, 'cm')
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if(distance<=20):
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blink()
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sleep(1)
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3
Example - I2C LED Display/README.md
Normal file
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@ -0,0 +1,3 @@
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# I2C Display Controller Example Code #
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This is a simple code to control I2C Display. MicroPython needs **ssd1306 driver** to work.
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11
Example - I2C LED Display/main_I2CDisplay.py
Normal file
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@ -0,0 +1,11 @@
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from machine import Pin, SoftI2C
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# This Driver Lib may not installed yet
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import ssd1306
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# Define i2c peripheral
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i2c = SoftI2C(sda=Pin(5), scl=Pin(4))
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# Configure I2C Display Resolution
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display = ssd1306.SSD1306_I2C(128, 64, i2c)
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# Test Output
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display.text('Hello, World!', 0, 0, 1)
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display.show()
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8
Example - MQ9/README.md
Normal file
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# MQ-9 Gas Sensor Example Code
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The main script I wrote it myself adjusting to my needs
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* Original Driver: https://github.com/tutRPi/Raspberry-Pi-Gas-Sensor-MQ
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* Adapted by : https://github.com/leech001/MQ9/tree/master
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* The main code I made it myself.
|
69
Example - MQ9/main_MQ9.py
Normal file
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from machine import ADC, Pin
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from mq9 import MQ
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import time
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import dht
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import network
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import ntptime
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import urequests
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# Global Params
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gas = ADC(Pin(35))
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led = Pin(2,Pin.OUT)
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led.value(0)
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# Function to read MQ9 Sensor
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def read_mq9(mq):
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while True:
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try:
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adc = gas.read_u16()
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sensor_volt = gas.read_uv()/1000000
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perc = mq.MQPercentage()
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break
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except:
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pass
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co = perc["CO"]*1000
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if co >= 10000:
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cp = 10000
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result = [adc,sensor_volt,co]
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return result
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# Function to Blink
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def blink():
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led.value(1)
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time.sleep(0.5)
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led.value(0)
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time.sleep(0.5)
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# Function to Blink Faster
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def blink_fast():
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led.value(1)
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time.sleep(0.25)
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led.value(0)
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time.sleep(0.25)
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# Main Script
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def main():
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# Calibrate Sensor
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print("Calibrating MQ-9 Sensor")
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led.value(1)
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while True:
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try:
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mq = MQ()
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break
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||||
except:
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pass
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led.value(0)
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print("Calibrated")
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||||
print("")
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||||
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||||
print("Start Monitoring:")
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||||
print("")
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while True:
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result = read_mq9(mq)
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||||
print(f"ADC Value : {result[0]}, Sensor Voltage : {result[1]} Volt, and Carbon Monoxide : {result[2]} ppm")
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||||
if __name__ == "__main__":
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||||
main()
|
125
Example - MQ9/mq9.py
Normal file
|
@ -0,0 +1,125 @@
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|||
# adapted from https://github.com/tutRPi/Raspberry-Pi-Gas-Sensor-MQ
|
||||
|
||||
import time
|
||||
import math
|
||||
from machine import ADC,Pin
|
||||
|
||||
|
||||
class MQ:
|
||||
# Hardware Related Macros
|
||||
RL_VALUE = 10 # define the load resistance on the board, in kilo ohms
|
||||
RO_CLEAN_AIR_FACTOR = 9.83 # RO_CLEAR_AIR_FACTOR=(Sensor resistance in clean air)/RO,
|
||||
# which is derived from the chart in datasheet
|
||||
|
||||
# Software Related Macros
|
||||
CALIBARAION_SAMPLE_TIMES = 50 # define how many samples you are going to take in the calibration phase
|
||||
CALIBRATION_SAMPLE_INTERVAL = 500 # define the time interal(in milisecond) between each samples in the
|
||||
# cablibration phase
|
||||
READ_SAMPLE_INTERVAL = 50 # define how many samples you are going to take in normal operation
|
||||
READ_SAMPLE_TIMES = 5 # define the time interal(in milisecond) between each samples in
|
||||
# normal operation
|
||||
|
||||
# Application Related Macros
|
||||
GAS_LPG = 0
|
||||
GAS_CO = 1
|
||||
GAS_SMOKE = 2
|
||||
|
||||
def __init__(self, ro=10):
|
||||
self.ro = ro
|
||||
self.adc = ADC(Pin(35))
|
||||
|
||||
self.LPGCurve = [2.3, 0.21, -0.47] # two points are taken from the curve.
|
||||
# with these two points, a line is formed which is "approximately equivalent"
|
||||
# to the original curve.
|
||||
# data format:{ x, y, slope}; point1: (lg200, 0.21), point2: (lg10000, -0.59)
|
||||
self.COCurve = [2.3, 0.72, -0.34] # two points are taken from the curve.
|
||||
# with these two points, a line is formed which is "approximately equivalent"
|
||||
# to the original curve.
|
||||
# data format:[ x, y, slope]; point1: (lg200, 0.72), point2: (lg10000, 0.15)
|
||||
self.SmokeCurve = [2.3, 0.53, -0.44] # two points are taken from the curve.
|
||||
# with these two points, a line is formed which is "approximately equivalent"
|
||||
# to the original curve.
|
||||
# data format:[ x, y, slope]; point1: (lg200, 0.53), point2: (lg10000, -0.22)
|
||||
|
||||
# print("Calibrating...")
|
||||
self.ro = self.MQCalibration()
|
||||
# print("Calibration is done...\n")
|
||||
# print("Ro=%f kohm" % self.ro)
|
||||
|
||||
def MQPercentage(self):
|
||||
val = {}
|
||||
read = self.MQRead()
|
||||
val["GAS_LPG"] = self.MQGetGasPercentage(read / self.ro, self.GAS_LPG)
|
||||
val["CO"] = self.MQGetGasPercentage(read / self.ro, self.GAS_CO)
|
||||
val["SMOKE"] = self.MQGetGasPercentage(read / self.ro, self.GAS_SMOKE)
|
||||
return val
|
||||
|
||||
# MQResistanceCalculation
|
||||
# Input: raw_adc - raw value read from adc, which represents the voltage
|
||||
# Output: the calculated sensor resistance
|
||||
# Remarks: The sensor and the load resistor forms a voltage divider. Given the voltage
|
||||
# across the load resistor and its resistance, the resistance of the sensor
|
||||
# could be derived.
|
||||
def MQResistanceCalculation(self, raw_adc):
|
||||
return float(self.RL_VALUE * (4095.0 - raw_adc) / float(raw_adc))
|
||||
|
||||
# MQCalibration
|
||||
# Output: Ro of the sensor
|
||||
# Remarks: This function assumes that the sensor is in clean air. It use
|
||||
# MQResistanceCalculation to calculates the sensor resistance in clean air
|
||||
# and then divides it with RO_CLEAN_AIR_FACTOR. RO_CLEAN_AIR_FACTOR is about
|
||||
# 10, which differs slightly between different sensors.
|
||||
def MQCalibration(self):
|
||||
val = 0.0
|
||||
for i in range(self.CALIBARAION_SAMPLE_TIMES): # take multiple samples
|
||||
val += self.MQResistanceCalculation(self.adc.read())
|
||||
time.sleep(self.CALIBRATION_SAMPLE_INTERVAL / 1000.0)
|
||||
|
||||
val = val / self.CALIBARAION_SAMPLE_TIMES # calculate the average value
|
||||
|
||||
val = val / self.RO_CLEAN_AIR_FACTOR # divided by RO_CLEAN_AIR_FACTOR yields the Ro
|
||||
# according to the chart in the datasheet
|
||||
return val
|
||||
|
||||
# MQRead
|
||||
# Output: Rs of the sensor
|
||||
# Remarks: This function use MQResistanceCalculation to caculate the sensor resistenc (Rs).
|
||||
# The Rs changes as the sensor is in the different consentration of the target
|
||||
# gas. The sample times and the time interval between samples could be configured
|
||||
# by changing the definition of the macros.
|
||||
def MQRead(self):
|
||||
rs = 0.0
|
||||
|
||||
for i in range(self.READ_SAMPLE_TIMES):
|
||||
rs += self.MQResistanceCalculation(self.adc.read())
|
||||
time.sleep(self.READ_SAMPLE_INTERVAL / 1000.0)
|
||||
|
||||
rs = rs / self.READ_SAMPLE_TIMES
|
||||
|
||||
return rs
|
||||
|
||||
# MQGetGasPercentage
|
||||
# Input: rs_ro_ratio - Rs divided by Ro
|
||||
# gas_id - target gas type
|
||||
# Output: ppm of the target gas
|
||||
# Remarks: This function passes different curves to the MQGetPercentage function which
|
||||
# calculates the ppm (parts per million) of the target gas.
|
||||
def MQGetGasPercentage(self, rs_ro_ratio, gas_id):
|
||||
if gas_id == self.GAS_LPG:
|
||||
return self.MQGetPercentage(rs_ro_ratio, self.LPGCurve)
|
||||
elif gas_id == self.GAS_CO:
|
||||
return self.MQGetPercentage(rs_ro_ratio, self.COCurve)
|
||||
elif gas_id == self.GAS_SMOKE:
|
||||
return self.MQGetPercentage(rs_ro_ratio, self.SmokeCurve)
|
||||
return 0
|
||||
|
||||
# MQGetPercentage
|
||||
# Input: rs_ro_ratio - Rs divided by Ro
|
||||
# pcurve - pointer to the curve of the target gas
|
||||
# Output: ppm of the target gas
|
||||
# Remarks: By using the slope and a point of the line. The x(logarithmic value of ppm)
|
||||
# of the line could be derived if y(rs_ro_ratio) is provided. As it is a
|
||||
# logarithmic coordinate, power of 10 is used to convert the result to non-logarithmic
|
||||
# value.
|
||||
def MQGetPercentage(self, rs_ro_ratio, pcurve):
|
||||
return math.pow(10, (((math.log(rs_ro_ratio) - pcurve[1]) / pcurve[2]) + pcurve[0]))
|
63
Example - Networking and Clients/LibInstaller.py
Normal file
|
@ -0,0 +1,63 @@
|
|||
import network
|
||||
import mip
|
||||
|
||||
# Put Your SSID and Password
|
||||
SSID: str = ""
|
||||
Password: str = ""
|
||||
reset = True # To Reset Network State and Force Connect
|
||||
|
||||
print(">> Start MicroPython Libs Installer ... ")
|
||||
print(">> Connecting ... ")
|
||||
wlan0 = network.WLAN(network.STA_IF)
|
||||
if reset:
|
||||
wlan0.active(True)
|
||||
|
||||
# Masukkan SSID dan Password
|
||||
wlan0.connect(SSID, Password)
|
||||
while not wlan0.isconnected():
|
||||
wlan0.active(True)
|
||||
pass
|
||||
status = wlan0.isconnected()
|
||||
|
||||
if(status == True):
|
||||
print("==>> Connected")
|
||||
print(">> Verifying Libs urequests ...")
|
||||
try:
|
||||
import urequests
|
||||
print("==>> OK")
|
||||
except:
|
||||
print("==>> Failed. Installing Libs ... ")
|
||||
mip.install('urequests')
|
||||
|
||||
print(">> Verifying Libs umqtt.robust ...")
|
||||
try:
|
||||
import umqtt.robust
|
||||
print("==>> OK")
|
||||
except:
|
||||
print("==>> Failed. Installing Libs ... ")
|
||||
mip.install("umqtt.robust")
|
||||
|
||||
print(">> Verifying Libs umqtt.simple ...")
|
||||
try:
|
||||
import umqtt.simple
|
||||
print("==>> OK")
|
||||
except:
|
||||
print("==>> Failed. Installing Libs ... ")
|
||||
mip.install("umqtt.simple")
|
||||
print(">> Verifying Libs ssd1306 ...")
|
||||
try:
|
||||
import ssd1306
|
||||
print("==>> OK")
|
||||
except:
|
||||
print("==>> Failed. Installing Libs ... ")
|
||||
mip.install("ssd1306")
|
||||
print(">> Verifying Libs aioble ...")
|
||||
try:
|
||||
import aioble
|
||||
print("==>> OK")
|
||||
except:
|
||||
print("==>> Failed. Installing Libs ... ")
|
||||
mip.install("aioble")
|
||||
|
||||
else:
|
||||
print("==>> Connection Failed")
|
24
Example - Networking and Clients/NTPSetup.py
Normal file
|
@ -0,0 +1,24 @@
|
|||
import ntptime
|
||||
import time
|
||||
|
||||
class NTPSetup():
|
||||
def __init__(self):
|
||||
# Set Date Time
|
||||
ntptime.settime()
|
||||
|
||||
# Get Date Time
|
||||
def getDateTime(self):
|
||||
self.devdatetime = time.localtime()
|
||||
self.devtime = str(self.devdatetime[3]+7)+":"+str(self.devdatetime[4])+":"+str(self.devdatetime[5])
|
||||
self.devdate = str(self.devdatetime[2])+"/"+str(self.devdatetime[1])+"/"+str(self.devdatetime[0])
|
||||
return self.devdate,self.devtime
|
||||
|
||||
|
||||
def main():
|
||||
# Connect to Internet
|
||||
ntp = NTPSetup()
|
||||
devdate,devtime = ntp.getDateTime()
|
||||
print(devdate,devtime)
|
||||
|
||||
if __name__ == "__main__":
|
||||
main()
|
6
Example - Networking and Clients/README.md
Normal file
|
@ -0,0 +1,6 @@
|
|||
# A Collection of Helper MicroPython Scripts #
|
||||
|
||||
* **NTPSetup.py** : A helper class to configure NTP (Need ISO Date Formatting)
|
||||
* **WiFiManager.py** : A helper class to connect WiFi and verify Internet using simple requests
|
||||
* **LibInstaller.py** : A helper class to install extra libraries from micropython.
|
||||
|
42
Example - Networking and Clients/WiFiManager.py
Normal file
|
@ -0,0 +1,42 @@
|
|||
import network
|
||||
from urequests import get
|
||||
|
||||
class WiFiManager():
|
||||
def __init__(self,):
|
||||
self.reset = True
|
||||
|
||||
# Koneksi Wi-Fi
|
||||
def connectWifi(self,SSID,Password):
|
||||
self.wlan0 = network.WLAN(network.STA_IF)
|
||||
if self.reset:
|
||||
self.wlan0.active(True)
|
||||
self.wlan0.connect(SSID, Password)
|
||||
|
||||
while not self.wlan0.isconnected():
|
||||
self.wlan0.active(True)
|
||||
pass
|
||||
|
||||
self.status = self.wlan0.isconnected()
|
||||
self.ip_addr = self.wlan0.ifconfig()
|
||||
return self.status,self.ip_addr
|
||||
|
||||
# Tes Koneksi
|
||||
def testInternet(self):
|
||||
response = get("https://example.com/")
|
||||
status = response.status_code
|
||||
response.close()
|
||||
if status == 200:
|
||||
return True
|
||||
else:
|
||||
return False
|
||||
|
||||
|
||||
def main():
|
||||
handler = WiFiManager()
|
||||
status,ip = handler.connectWLAN("","")
|
||||
print(ip,status)
|
||||
status = handler.testInternet()
|
||||
print(status)
|
||||
|
||||
if __name__ == '__main__':
|
||||
main()
|
3
Example - SPI OLED Display/README.md
Normal file
|
@ -0,0 +1,3 @@
|
|||
# OLED Display Example Code #
|
||||
|
||||
This is a simple code to control OLED Display using SPI Protocol
|
28
Example - SPI OLED Display/main_OLED.py
Normal file
|
@ -0,0 +1,28 @@
|
|||
from machine import Pin, SoftSPI
|
||||
import ssd1306
|
||||
|
||||
sck = Pin(14) # D0
|
||||
scl = Pin(13) # D1
|
||||
|
||||
spi = SoftSPI(baudrate=500000, polarity=1, phase=0, sck=sck, mosi=scl, miso=Pin(12))
|
||||
|
||||
rst = Pin(4) # reset
|
||||
dc = Pin(5) # data/command
|
||||
cs = Pin(15) # chip select, some modules do not have a pin for this
|
||||
|
||||
display = ssd1306.SSD1306_SPI(128, 64, spi, dc, rst, cs)
|
||||
|
||||
# display.text('Hello, World!', 0, 0, 1)
|
||||
# display.show()
|
||||
|
||||
display.fill(0)
|
||||
display.fill_rect(0, 0, 32, 32, 1)
|
||||
display.fill_rect(2, 2, 28, 28, 0)
|
||||
display.vline(9, 8, 22, 1)
|
||||
display.vline(16, 2, 22, 1)
|
||||
display.vline(23, 8, 22, 1)
|
||||
display.fill_rect(26, 24, 2, 4, 1)
|
||||
display.text('MicroPython', 40, 0, 1)
|
||||
display.text('SSD1306', 40, 12, 1)
|
||||
display.text('OLED 128x64', 40, 24, 1)
|
||||
display.show()
|
BIN
Manuals/Manual-7Segment-5631AS.pdf
Normal file
BIN
Manuals/Manual-MQ-9_Hanwei.pdf
Normal file
BIN
Manuals/Manual-OLED-Guide.pdf
Normal file
BIN
Pinouts/Pinout-ESP32-Wroom.jpg
Normal file
After Width: | Height: | Size: 217 KiB |
BIN
Pinouts/Pinout-ESP32.webp
Normal file
After Width: | Height: | Size: 82 KiB |
BIN
Pinouts/Pinout-ESP8266.webp
Normal file
After Width: | Height: | Size: 42 KiB |
BIN
Pinouts/Pinout-MQ7.png
Normal file
After Width: | Height: | Size: 77 KiB |
BIN
Pinouts/Pinout-Pico-W.webp
Normal file
After Width: | Height: | Size: 79 KiB |
BIN
Pinouts/Pinout-Pico.jpg
Normal file
After Width: | Height: | Size: 165 KiB |
BIN
Pinouts/Pinout-SIM800L.jpg
Normal file
After Width: | Height: | Size: 95 KiB |
3
README.md
Normal file
|
@ -0,0 +1,3 @@
|
|||
# A Collection of Example Codes #
|
||||
|
||||
This folder contains many simple codes to access several sensors or peripherals. Need to be noted that this **MAY NOT** work in your board. Always **VERIFY** before using.
|