Add example to demo ADC channel usage
[EVA-2020-02-2.git] / examples / all-in-one.py
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1#!/usr/bin/env python
2
3import time
4import colorsys
5import os
6import sys
7import ST7735
8import ltr559
9
10from bme280 import BME280
11from pms5003 import PMS5003
12from enviroplus import gas
9d2c6929 13from subprocess import PIPE, Popen
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14from PIL import Image
15from PIL import ImageDraw
16from PIL import ImageFont
17
18print("""all-in-one.py - Displays readings from all of Enviro plus' sensors
19
20Press Ctrl+C to exit!
21
22""")
23
24# BME280 temperature/pressure/humidity sensor
25bme280 = BME280()
26
27# PMS5003 particulate sensor
28pms5003 = PMS5003()
29
30# Create ST7735 LCD display class
31st7735 = ST7735.ST7735(
32 port=0,
33 cs=1,
34 dc=9,
35 backlight=12,
36 rotation=270,
37 spi_speed_hz=10000000
38)
39
40# Initialize display
41st7735.begin()
42
43WIDTH = st7735.width
44HEIGHT = st7735.height
45
46# Set up canvas and font
47img = Image.new('RGB', (WIDTH, HEIGHT), color=(0, 0, 0))
48draw = ImageDraw.Draw(img)
49path = os.path.dirname(os.path.realpath(__file__))
50font = ImageFont.truetype(path + "/fonts/Asap/Asap-Bold.ttf", 20)
51
52message = ""
53
54# The position of the top bar
55top_pos = 25
56
ec075941 57
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58# Displays data and text on the 0.96" LCD
59def display_text(variable, data, unit):
60 # Maintain length of list
61 values[variable] = values[variable][1:] + [data]
62 # Scale the values for the variable between 0 and 1
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63 colours = [(v - min(values[variable]) + 1) / (max(values[variable])
64 - min(values[variable]) + 1) for v in values[variable]]
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65 # Format the variable name and value
66 message = "{}: {:.1f} {}".format(variable[:4], data, unit)
67 print(message)
68 draw.rectangle((0, 0, WIDTH, HEIGHT), (255, 255, 255))
69 for i in range(len(colours)):
70 # Convert the values to colours from red to blue
71 colour = (1.0 - colours[i]) * 0.6
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72 r, g, b = [int(x * 255.0) for x in colorsys.hsv_to_rgb(colour,
73 1.0, 1.0)]
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74 # Draw a 1-pixel wide rectangle of colour
75 draw.rectangle((i, top_pos, i+1, HEIGHT), (r, g, b))
76 # Draw a line graph in black
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77 line_y = HEIGHT - (top_pos + (colours[i] * (HEIGHT - top_pos)))\
78 + top_pos
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79 draw.rectangle((i, line_y, i+1, line_y+1), (0, 0, 0))
80 # Write the text at the top in black
81 draw.text((0, 0), message, font=font, fill=(0, 0, 0))
82 st7735.display(img)
83
ec075941 84
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85# Get the temperature of the CPU for compensation
86def get_cpu_temperature():
87 process = Popen(['vcgencmd', 'measure_temp'], stdout=PIPE)
88 output, _error = process.communicate()
89 return float(output[output.index('=') + 1:output.rindex("'")])
90
ec075941 91
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92# Tuning factor for compensation. Decrease this number to adjust the
93# temperature down, and increase to adjust up
94factor = 0.8
95
96cpu_temps = [0] * 5
97
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98delay = 0.5 # Debounce the proximity tap
99mode = 0 # The starting mode
100last_page = 0
101light = 1
102
103# Create a values dict to store the data
104variables = ["temperature",
105 "pressure",
106 "humidity",
107 "light",
108 "oxidised",
109 "reduced",
110 "nh3",
111 "pm1",
112 "pm25",
113 "pm10"]
114
115values = {}
116
117for v in variables:
118 values[v] = [1] * WIDTH
119
120# The main loop
121try:
122 while True:
123 proximity = ltr559.get_proximity()
124
125 # If the proximity crosses the threshold, toggle the mode
126 if proximity > 1500 and time.time() - last_page > delay:
127 mode += 1
128 mode %= len(variables)
129 last_page = time.time()
130
131 # One mode for each variable
132 if mode == 0:
133 variable = "temperature"
134 unit = "C"
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135 cpu_temp = get_cpu_temperature()
136 # Smooth out with some averaging to decrease jitter
137 cpu_temps = cpu_temps[1:] + [cpu_temp]
138 avg_cpu_temp = sum(cpu_temps) / float(len(cpu_temps))
139 raw_temp = bme280.get_temperature()
140 data = raw_temp - ((avg_cpu_temp - raw_temp) / factor)
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141 display_text(variable, data, unit)
142
143 if mode == 1:
144 variable = "pressure"
145 unit = "hPa"
146 data = bme280.get_pressure()
147 display_text(variable, data, unit)
148
149 if mode == 2:
150 variable = "humidity"
151 unit = "%"
152 data = bme280.get_humidity()
153 display_text(variable, data, unit)
154
155 if mode == 3:
156 variable = "light"
157 unit = "Lux"
158 if proximity < 10:
159 data = ltr559.get_lux()
160 else:
161 data = 1
162 display_text(variable, data, unit)
163
164 if mode == 4:
165 variable = "oxidised"
166 unit = "kO"
167 data = gas.read_all()
168 data = data.oxidising / 1000
169 display_text(variable, data, unit)
170
171 if mode == 5:
172 variable = "reduced"
173 unit = "kO"
174 data = gas.read_all()
175 data = data.reducing / 1000
176 display_text(variable, data, unit)
177
178 if mode == 6:
179 variable = "nh3"
180 unit = "kO"
181 data = gas.read_all()
182 data = data.nh3 / 1000
183 display_text(variable, data, unit)
184
185 if mode == 7:
186 variable = "pm1"
187 unit = "ug/m3"
188 data = pms5003.read()
189 data = data.pm_ug_per_m3(1.0)
190 display_text(variable, data, unit)
191
192 if mode == 8:
193 variable = "pm25"
194 unit = "ug/m3"
195 data = pms5003.read()
196 data = data.pm_ug_per_m3(2.5)
197 display_text(variable, data, unit)
198
199 if mode == 9:
200 variable = "pm10"
f86c4c6d 201 unit = "ug/m3"
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202 data = pms5003.read()
203 data = data.pm_ug_per_m3(10)
204 display_text(variable, data, unit)
205
206# Exit cleanly
207except KeyboardInterrupt:
208 sys.exit(0)