Beispiel #1
0
import board
import neopixel
from analogio import AnalogIn
from simpleio import map_range
# from adafruit_circuitplayground.express import cpx

pixels = neopixel.NeoPixel(board.NEOPIXEL, 10, auto_write=0, brightness=0.1)
pixels.fill((0, 0, 0))
pixels.show()

# cpx.pixels.brightness = 0.05

analogin = AnalogIn(board.LIGHT)

max_analog_value = 0

while True:
    if analogin.value > max_analog_value:
        max_analog_value = analogin.value

    # light value remapped to pixel position
    peak = map_range(analogin.value, 500, max_analog_value, 0, 10)
    print(analogin.value)
    print(int(peak))

    for i in range(0, 10, 1):
        if i <= peak:
            pixels[i] = (0, 25, 0)  #25 is darker than 255
        else:
            pixels[i] = (0, 0, 0)
    pixels.show()
Beispiel #2
0
    # Read analog voltage on A1
    print("A1: %0.2f" % getVoltage(analog1in), end="\t")

    # use A2 as capacitive touch to turn on internal LED
    print("A2 touch: %d" % touch.raw_value, end="\t")
    if touch.value:
        print("A2 touched!", end="\t")
    led.value = touch.value

    if not buttons[0].value:
        print("Button D2 pressed!", end="\t")
        # optional! uncomment below & save to have it sent a keypress
        #kbd.press(Keycode.A)
        #kbd.release_all()

    if not buttons[1].value:
        print("Button D3 pressed!", end="\t")
        play_file(audiofiles[0])

    if not buttons[2].value:
        print("Button D4 pressed!", end="\t")
        play_file(audiofiles[1])

    # sweep a servo from 0-180 degrees (map from 0-255)
    servo.angle = simpleio.map_range(i, 0, 255, 0, 180)

    i = (i + 1) % 256  # run from 0 to 255
    #time.sleep(0.01) # make bigger to slow down

    print("")
    if time.monotonic() - last_update_internet_time > weather_update_freq:
        update_internet_time()
        last_update_internet_time = time.monotonic()

    # CURRENT WEATHER
    if time.monotonic() - last_update_current_weather > weather_update_freq:
        update_current_weather()
        last_update_current_weather = time.monotonic()

    # FORECASTS
    if time.monotonic() - last_update_forecast > weather_update_freq:
        update_forecast()
        last_update_forecast = time.monotonic()

    # BRIGHTNESS
    board.DISPLAY.brightness = simpleio.map_range(light.value, 0, 40000, 0,
                                                  100) / 100

    # CLEAR MEMORY
    print('X Clear memory... Mem free: {:,} allocated: {:,}'.format(
        gc.mem_free(), gc.mem_alloc()),
          end='')
    gc.collect()
    print(' | Mem free: {:,} allocated: {:,}'.format(gc.mem_free(),
                                                     gc.mem_alloc()),
          end='')
    print(' | Progress: {:02.0f}'.format(progress), '%')

    # UPDATE DISPLAY
    display.show(group)

    time.sleep(update_freq)
Beispiel #4
0
#  time.monotonic for blinka animation
slither = 0
#  blinka animation sprite index
g = 1

#  array for random beat division values
rando_div = [240, 120, 60, 30, 15]
#  array of beat division values
beat_division = [whole, half, quarter, eighth, sixteenth]
#  strings for beat division names
beat_division_name = ["1", "1/2", "1/4", "1/8", "1/16", "Random"]

while True:
    #  mapping analog pot values to the different parameters
    #  MIDI modulation 0-127
    mod_val1 = round(simpleio.map_range(val(mod_pot), 0, 65535, 0, 127))
    #  BPM range 60-220
    bpm_val1 = simpleio.map_range(val(bpm_slider), 0, 65535, 60, 220)
    #  6 options for beat division
    beat_val1 = round(simpleio.map_range(val(beat_pot), 0, 65535, 0, 5))
    #  12 options for key selection
    key_val1 = round(simpleio.map_range(val(key_pot), 0, 65535, 0, 11))
    #  6 options for mode selection
    mode_val1 = round(simpleio.map_range(val(mode_pot), 0, 65535, 0, 5))

    #  sending MIDI modulation
    if abs(mod_val1 - mod_val2) > 2:
        #  updates previous value to hold current value
        mod_val2 = mod_val1
        #  MIDI data has to be sent as an integer
        #  this converts the pot data into an int
    except ValueError:
        # these happen, no biggie - retry
        continue

    #    print("Time for data aquisition: %0.2f s" % (time.monotonic()-stamp))

    mini = frame[0]  # Define a min temperature of current image
    maxi = frame[0]  # Define a max temperature of current image

    for h in range(24):
        for w in range(32):
            t = frame[h * 32 + w]
            if t > maxi:
                maxi = t
            if t < mini:
                mini = t
            image_bitmap[w, (23 - h)] = int(
                map_range(t, min_t, max_t, 0, last_color))

    min_label.text = "%0.2f" % (min_t)

    max_string = "%0.2f" % (max_t)
    max_label.x = 120 - (5 * len(max_string)
                         )  # Tricky calculation to left align
    max_label.text = max_string

    min_t = mini  # Automatically change the color scale
    max_t = maxi
#    print((mini, maxi))           # Use this line to display min and max graph in Mu
#    print("Total time for aquisition and display %0.2f s" % (time.monotonic()-stamp))
        ))
        time.sleep(0.2)

    else:
        print("Waiting for connection")
        while not ble.connected:
            pass
        print("Connected")
        while ble.connected:
            # Feather Sense accelerometer readings to CC
            accel_data = sense_accel.acceleration  # get accelerometer reading
            accel_x = accel_data[0]
            accel_y = accel_data[1]
            # accel_z = accel_data[2]
            # Remap analog readings to cc range
            cc_x = int(simpleio.map_range(accel_x, 0, 9, 127, 0))
            cc_y = int(simpleio.map_range(accel_y, 1, -9, 0, 127))

            cc_thumb = get_flex_cc(analog_in_thumb, 49000, 35000, 127, 0)
            cc_index = get_flex_cc(analog_in_index, 50000, 35000, 0, 127)
            cc_middle = get_flex_cc(analog_in_middle, 55000, 40000, 0, 127)
            cc_ring = get_flex_cc(analog_in_ring, 55000, 42000, 0, 127)
            '''
            print(
                "CC_X:{} CC_Y:{} CC_Thumb:{} CC_Index:{} CC_Middle:{} CC_Ring:{}".format(
                    cc_x, cc_y, cc_thumb, cc_index, cc_middle, cc_ring
                )
            )'''

            # send all the midi messages in a list
            midi.send([
Beispiel #7
0
def adc_to_wind_speed(val):
    """Returns anemometer wind speed, in m/s.
    :param int val: ADC value
    """
    voltage_val = val / 65535 * 3.3
    return map_range(voltage_val, 0.4, 2, 0, 32.4)
Beispiel #8
0
import simpleio

print("Aloha")

cpx.pixels.auto_write = False
cpx.pixels.brightness = 0.05

while True:
    if cpx.switch:
        print("Slide switch set to off!")
        cpx.pixels.fill((0, 0, 0))
        continue
    else:
        x, y, z = cpx.acceleration

        x_value = abs(int(simpleio.map_range(x, -10, 10, 0, 10)))
        y_value = abs(int(simpleio.map_range(y, -10, 10, 0, 10)))
        z_value = abs(int(simpleio.map_range(z, -10, 10, 0, 10)))

        print((x_value, y_value, z_value))

        if x_value >= 8:
            cpx.pixels[2] = (0, 150, 150)
        else:
            cpx.pixels[2] = (0, 0, 0)

        if x_value >= 7 and y_value >= 3:
            cpx.pixels[3] = (0, 150, 150)
        else:
            cpx.pixels[3] = (0, 0, 0)
Beispiel #9
0
    if touch_raw_value > 800:
        print("chase")
        color_chase(PURPLE, 0.1)
    else:
        pixels.fill((0, 0, 0))
        pixels.show()

    # potentiomter + servo

    # uncomment this line to see the values of the pot
    # print((ss.analog_read(pot),))
    # time.sleep(0.25)

    # maps the range of the pot to the range of the servo
    angle = map_range(ss.analog_read(pot), 0, 1023, 180, 0)

    # sets the servo equal to the relative position on the pot
    crickit.servo_1.angle = angle

    # Light sensor + DC motor

    # uncomment to see values of light
    # print(light_in.value)
    # time.sleep(0.5)

    # reads the on-board light sensor and graphs the brighness with NeoPixels
    # light value remaped to motor speed
    peak = map_range(light_in.value, 3000, 62000, 0, 1)

    # DC motor
Beispiel #10
0
    # to keep the connection active
    #try:
    #io.loop()
    #except (ValueError, RuntimeError) as e:
    #print("Failed to get data, retrying...\n", e)
    #wifi.reset()
    #continue
    now = time.monotonic()

    print("reading soil sensor...")
    # Read capactive
    moisture = ss.moisture_read()
    label_level.text = str(moisture)

    # Convert into percentage for filling the screen
    moisture_percentage = map_range(float(moisture), SOIL_LEVEL_MIN,
                                    SOIL_LEVEL_MAX, 0.0, 1.0)

    # Read temperature
    temp = ss.get_temp()
    temp = display_temperature(temp)

    # fill display
    print("filling disp..")
    fill_water(moisture_percentage)
    print("disp filled..")

    print("temp: " + str(temp) + "  moisture: " + str(moisture))

    # Play water level alarms
    if moisture <= SOIL_LEVEL_MIN and alarm_sounded_min == False:
        print("Playing low water level warning...")
         if sin_bright == 0 and sin_slope > 0:
             cpx.pixels[sin_pix] = (0, 0, 0)
             sin_pix = (sin_pix + 1) % 10
         elif sin_bright >= 0:
             cpx.pixels[sin_pix] = (sin_bright, 0, 0)
         else:
             cpx.pixels[sin_pix] = (0, abs(sin_bright), 0)
         start = now
 if button_iter == 5:
     if time.monotonic() % 30 == 0:
         max_light_reading = 0
     if now - start > 0.1:
         brightness = cpx.light
         if brightness > max_light_reading:
             max_light_reading = brightness
         peak = map_range(brightness, 0, max_light_reading, 0, 10)
         for i in range(0, 10, 1):
             if i <= peak:
                 cpx.pixels[i] = (0, 15, 0)  #25 is darker than 255
             else:
                 cpx.pixels[i] = (1, 0, 0)
         start = now
 if button_iter == 6:
     if now - start > 0.1:
         x, y, z = cpx.acceleration
         if x <= (-1 * accel_threshold):
             cpx.pixels[7] = (0, accel_brightness, 0)
         else:
             cpx.pixels[7] = (0, 0, 0)
         if x >= accel_threshold:
             cpx.pixels[2] = (0, accel_brightness, 0)
# PROJ01 - Theremin
# (CircuitPython)
# this circuit was designed for use with the Metro Express Explorers Guide on Learn.Adafruit.com

# by Asher Lieber for Adafruit Industries.

import board
import analogio
import pulseio
from simpleio import map_range

piezo = pulseio.PWMOut(board.D9)
photo = analogio.AnalogIn(board.A0)

while True:
    # map photo sensor value to hearable sound on piezo
    val = int(map_range(photo.value, 0, 65520, 1000, 64000))
    piezo.duty_cycle = val
Beispiel #13
0
        int(l * r) for l, r in zip(neopixel_utils.RED, (brightness, brightness,
                                                        brightness)))
    if file_write_status == 'out_of_space':
        file_write_status_color = tuple(
            int(l * r)
            for l, r in zip(neopixel_utils.YELLOW, (brightness, brightness,
                                                    brightness)))
    elif file_write_status == 'rw':
        file_write_status_color = tuple(
            int(l * r)
            for l, r in zip(neopixel_utils.GREEN, (brightness, brightness,
                                                   brightness)))

    # Calculate color to display for temperatures
    cpu_temp_color_red = int(simpleio.map_range(
        cpu_temp, 20, 40, 0,
        255))  # Scale the value of temp from (20, 40) to (0, 255)
    cpu_temp_color_blue = 255 - cpu_temp_color_red
    therm_temp_color_red = int(simpleio.map_range(
        therm_temp, 15, 40, 0,
        255))  # Scale the value of temp from (15, 40) to (0, 255)
    therm_temp_color_blue = 255 - therm_temp_color_red
    # adjust color brightness based on ambient brightness
    cpu_temp_color_red = int(cpu_temp_color_red * brightness)
    cpu_temp_color_blue = int(cpu_temp_color_blue * brightness)
    therm_temp_color_red = int(therm_temp_color_red * brightness)
    therm_temp_color_blue = int(therm_temp_color_blue * brightness)

    if touch_A1.value:
        print("A1 touched!")
    if touch_A2.value:
    try:
        mlx.getFrame(frame)
    except ValueError:
        # these happen, no biggie - retry
        continue

    #    print("Time for data aquisition: %0.2f s" % (time.monotonic()-stamp))

    mini = frame[0]  # Define a min temperature of current image
    maxi = frame[0]  # Define a max temperature of current image

    for h in range(24):
        for w in range(32):
            t = frame[h * 32 + w]
            if t > maxi:
                maxi = t
            if t < mini:
                mini = t
            image_bitmap[w, (23 - h)] = int(map_range(t, min_t, max_t, 0, last_color))

    min_label.text = "%0.2f" % (min_t)

    max_string = "%0.2f" % (max_t)
    max_label.x = 120 - (5 * len(max_string))  # Tricky calculation to left align
    max_label.text = max_string

    min_t = mini  # Automatically change the color scale
    max_t = maxi
#    print((mini, maxi))           # Use this line to display min and max graph in Mu
#    print("Total time for aquisition and display %0.2f s" % (time.monotonic()-stamp))
Beispiel #15
0
    clue_display.patch_label.text = "Connected!"
    time.sleep(1.0)
    clue_display.show_screen(0)
    while BLE.connected:
        if clue.button_a:
            if not debouncer.hot(BUTTONS["MODE"]):
                clue_display.next_screen()

        ACCEL_DATA = clue.acceleration
        PROX_DATA = clue.proximity
        ACCEL_X = ACCEL_DATA[0]

        if clue_display.current_screen == 0:
            midi_data = []
            # Remap analog readings to cc range
            cc_x = int(simpleio.map_range(ACCEL_X, -9, 9, 0, 127))
            cc_x = remap(cc_x, START_RANGE, 127, 0, 127)
            midi_data.append(
                ControlChange(clue_display.starting_patch + 4, cc_x))
            # It's easier to map it inverted for a shoe mount...
            # CC_Y = int(simpleio.map_range(ACCEL_Y, -9, 9, 0, 127))
            if clue.white_leds and debouncer.hot(BUTTONS["PROXY"], check=True):
                clue.white_leds = False
            CC_PROX = int(simpleio.map_range(clue.proximity, 0, 255, 0, 127))
            CC_PROX_SWITCH = 127 if CC_PROX > 4 else 0
            if CC_PROX_SWITCH != 0 and not debouncer.hot(BUTTONS["PROXY"]):
                clue.white_leds = True
                midi_data.append(
                    ControlChange(clue_display.starting_patch + 3,
                                  CC_PROX_SWITCH))
            if clue.touch_0:
Beispiel #16
0
    #  run state for main program after selecting whether or not to connect to wifi
    if run:
        #  print eCO2 and TVOC data to REPL
        print("eCO2 = %d ppm \t TVOC = %d ppb" % (sgp30.eCO2, sgp30.TVOC))
        #  2 second delay
        time.sleep(2)

        #  fumes variable for reading from SGP30
        #  comment out either TVOC or eCO2 depending on data preference
        fumes = sgp30.TVOC
        #  fumes = sgp30.eCO2

        #  mapping fumes data to fan RPM
        #  value for TVOC
        mapped_val = simpleio.map_range(fumes, 10, 1000, 10, 100)
        #  value for eCO2
        #  mapped_val = simpleio.map_range(fumes, 400, 2500, 10, 100)

        #  adding fume text
        #  PPB is for TVOC, PPM is for eCO2
        funhouse.set_text("%d PPB" % fumes, fume_text)
        #  funhouse.set_text("%d PPM" % fumes, fume_text)

        #  adding fan's RPM text
        funhouse.set_text("%d%s" % (mapped_val, "%"), fan_text)
        #  printing fan's data to the REPL
        print("fan = ", mapped_val)
        #  setting fan's RPM
        emc.manual_fan_speed = int(mapped_val)
Beispiel #17
0
import time
from adafruit_circuitplayground.express import cpx
import touchio
import simpleio
import board

cpx.pixels.brightness = 0.2
touch = touchio.TouchIn(board.A1)

DRY_VALUE = 1500  # calibrate this by hand!
WET_VALUE = 2100  # calibrate this by hand!

while True:
    value_A1 = touch.raw_value
    print((value_A1, ))

    # fill the pixels from red to green based on soil moisture
    percent_wet = int(
        simpleio.map_range(value_A1, DRY_VALUE, WET_VALUE, 0, 100))
    cpx.pixels.fill((100 - percent_wet, percent_wet, 0))
    time.sleep(0.5)
Beispiel #18
0
import time
import digitalio
import adafruit_bus_device
import adafruit_hcsr04
import simpleio

sonar = adafruit_hcsr04.HCSR04(trigger_pin=board.D11, echo_pin=board.D12)
dot = neopixel.NeoPixel(board.NEOPIXEL, 1, brightness=.1)
r = 0
g = 0
b = 0

while True:

    try:
        print((sonar.distance, ))

        if sonar.distance < 20:
            r = simpleio.map_range(sonar.distance, 0, 20, 255, 0)
            b = simpleio.map_range(sonar.distance, 5, 20, 0, 255)
            g = simpleio.map_range(sonar.distance, 20, 35, 0, 255)
        else:
            r = simpleio.map_range(sonar.distance, 0, 20, 255, 0)
            b = simpleio.map_range(sonar.distance, 35, 20, 255, 0)
            g = simpleio.map_range(sonar.distance, 20, 35, 0, 255)

        dot.fill((int(r), int(b), int(g)))
    except RuntimeError:
        print("Retrying!")

    time.sleep(0.1)
Beispiel #19
0
import time #pylint: disable-msg=import-error
import board #pylint: disable-msg=import-error
from analogio import AnalogIn #pylint: disable-msg=import-error
import busio #pylint: disable-msg=import-error
import simpleio #pylint: disable-msg=import-error

potentiometer = AnalogIn(board.A0)

uart = busio.UART(board.TX, board.RX, baudrate=9600)

def get_voltage(pin):
    return(pin.value * 3.3) / 6553

while True:
    #print (get_voltage(potentiometer))
    myPotValue = simpleio.map_range(potentiometer.value, 0, 65000, 0, 180)
    print((myPotValue))
    uart.write(bytes([int(myPotValue)]))
    time.sleep(.1)
Beispiel #20
0
# CircuitPlaygroundExpress_LightSensor
# reads the on-board light sensor and graphs the brightness with NeoPixels

import time

import board
import neopixel
from analogio import AnalogIn
from simpleio import map_range

pixels = neopixel.NeoPixel(board.NEOPIXEL, 10, auto_write=0, brightness=.05)
pixels.fill((0, 0, 0))
pixels.show()

analogin = AnalogIn(board.LIGHT)

while True:
    # light value remapped to pixel position
    peak = map_range(analogin.value, 2000, 62000, 0, 9)
    print(analogin.value)
    print(int(peak))

    for i in range(0, 9, 1):
        if i <= peak:
            pixels[i] = (0, 255, 0)
        else:
            pixels[i] = (0, 0, 0)
    pixels.show()

    time.sleep(0.01)
Beispiel #21
0
def heard_signal(threshold):
    return (simpleio.map_range(mic.get_mic_magnitude(), 15, 1000, 0, 1) >
            threshold)
def get_flex_cc(sensor, low_in, high_in, min_out, max_out):
    flex_raw = sensor.value
    flex_cc = simpleio.map_range(flex_raw, low_in, high_in, min_out, max_out)
    flex_cc = int(flex_cc)
    return flex_cc
    # update led display
    if "led" or "big_led" in clock_display:
        led_disp.colon = not led_disp.colon

        # Check to see if time was set
        new_xst_datetime, clock_sound, update_flag = led_disp.set_datetime(
            ds3231.datetime)
        if update_flag:  # If so, update RTC Std Time with new datetime
            ds3231.datetime = new_xst_datetime
            print("RTC time was set")

        led_disp.dst = is_dst
        led_disp.show(current)  # refresh LED display

        # Refresh FeatherM4 NeoPixel to show "second hand"
        r = int(map_range(current.tm_sec, 0, 45, 255, 100))
        g = int(map_range(current.tm_sec, 15, 59, 100, 255))
        b = int(map_range(current.tm_sec, 55, 59, 100, 255))
        pixel[0] = (r, g, b)
        pixel.write()

    if "pybadge" in clock_display:
        pybadge_disp.colon = not pybadge_disp.colon  # auto-refresh

        # Check to see if time was set
        new_xst_datetime, clock_sound, update_flag = pybadge_disp.set_datetime(
            ds3231.datetime)
        if update_flag:  # If so, update RTC Std Time with new datetime
            ds3231.datetime = new_xst_datetime
            print("RTC time was set")
Beispiel #24
0

def set_pixels():
    pixels[0] = PURPLE
    pixels[1] = BLUE
    pixels[2] = BLUE
    pixels[3] = CYAN
    pixels[4] = LIGHT_BLUE
    pixels[5] = YELLOW
    pixels[6] = ORANGE
    pixels[7] = RED
    pixels[8] = RED
    pixels[9] = RED


while True:
    temp_c = temperature
    temp_f = temperature * 9 / 5 + 32
    print("Temperature is: %f C and %f F" % (temp_c, temp_f))

    set_pixels()

    # light value remapped to pixel position
    peak = simpleio.map_range(temp_f, 0, 100, 0, 9)

    for i in range(0, 10, 1):
        if i >= peak:
            pixels[i] = (0, 0, 0)

    pixels.show()
        pixels[8] = (0, 255, 0)
        pixels[9] = (255, 255, 0)
        print("Not hot enough, right moisture level")

    # ALL GREEN = COMPOST AT OPTIMUM TEMPERATURE & MOISTURE
    elif compostTemp > tempThreshhold:
        pixels.fill((0, 255, 0))  # green
        print("Compost Ready")

    # LIGHTING CONFIGURATION

    # print value of light sensor
    print((light.value, ))

    # map light snesor range to neopixel brightness range
    peak = map_range(light.value, 2000, 62000, 0.01, 0.3)

    # print neopixel brightness levels
    print(peak)

    # show neopixels
    pixels.show()

    # update neopixel brightness based on level of exposed light
    pixels = neopixel.NeoPixel(board.NEOPIXEL, 10, brightness=peak)

    # pause for three seconds
    time.sleep(3)

# END PROGRAM
Beispiel #26
0
# SPDX-FileCopyrightText: 2021 Brent Rubell for Adafruit Industries
#
# SPDX-License-Identifier: MIT
"""
'photo_sensor.py'.

=================================================
uses LIGHT to control a LED
"""
import analogio
import board
import pwmio
from simpleio import map_range

LED = pwmio.PWMOut(board.D9)
LIGHT = analogio.AnalogIn(board.A0)

while True:
    LIGHT_VAL = map_range(LIGHT.value, 20000, 32766, 0, 32766)
    LED.duty_cycle = int(LIGHT_VAL)
print("CPU.freqency: ", microcontroller.cpu.frequency)
print("CPU.temperature: ", microcontroller.cpu.temperature)
# print("Battery voltage: ", AnalogIn(board.Ax) )  # not used

# Slowly center (zero) the meter's output before reading the input voltage.
# This should take about one second to move the needle to the center.
meter_out_volt = inertia_move(-10, 0, 0.200, 0.050)
time.sleep(0.500)  # hold at center scale for 0.500 seconds

# ### Main Loop ###
while True:
    # Read the CV input and map to a +/-10V value.
    # Because of the input op-amp's signal inversion and fixed gain, a 0V
    # input to the Trinket's analog pin correlates to a CV input value of +10V;
    # a 3.3V input maps to a value of -10V. DO NOT adjust these values.
    cv_input_volt = map_range(cv_pin.value, 0, 65535, +10, -10)

    # Show the input voltage polarity on the DotStar indicator.
    if cv_input_volt > +1.0:  # 1V noise threshold
        dot[0] = (0, 255, 0)  # grn = positive
        neg_led.value = False
        zero_led.value = False
        pos_led.value = True
    elif cv_input_volt < -1.0:  # 1V noise threshold
        dot[0] = (255, 0, 0)  # red = negative
        neg_led.value = True
        zero_led.value = False
        pos_led.value = False
    else:
        dot[0] = (0, 0, 255)  # blu = zero
        neg_led.value = False
# CircuitPlaygroundExpress_LightSensor
# reads the on-board light sensor and graphs the brighness with NeoPixels

from adafruit_circuitplayground.express import cpx
from simpleio import map_range
import time

cpx.pixels.brightness = 0.05

while True:
    #light value remaped to pixel position
    peak = map_range(cpx.light, 10, 325, 0, 9)
    print(cpx.light)
    print(int(peak))

    for i in range(0, 9, 1):
        if i <= peak:
            cpx.pixels[i] = (0, 255, 0)
        else:
            cpx.pixels[i] = (0, 0, 0)

    time.sleep(0.01)
"""
'map_range_demo.py'.

=================================================
maps a number from one range to another
"""
import time
import simpleio

while True:
    sensor_value = 150

    # Map the sensor's range from 0<=sensor_value<=255 to 0<=sensor_value<=1023
    print("original sensor value: ", sensor_value)
    mapped_value = simpleio.map_range(sensor_value, 0, 255, 0, 1023)
    print("mapped sensor value: ", mapped_value)
    time.sleep(2)

    # Map the new sensor value back to the old range
    sensor_value = simpleio.map_range(mapped_value, 0, 1023, 0, 255)
    print("original value returned: ", sensor_value)
    time.sleep(2)
Beispiel #30
0
"""
'map_range_demo.py'.

=================================================
maps a number from one range to another
"""
import time
import simpleio

while True:
    sensor_value = 150

    # Map the sensor's range from 0<=sensor_value<=255 to 0<=sensor_value<=1023
    print('original sensor value: ', sensor_value)
    mapped_value = simpleio.map_range(sensor_value, 0, 255, 0, 1023)
    print('mapped sensor value: ', mapped_value)
    time.sleep(2)

    # Map the new sensor value back to the old range
    sensor_value = simpleio.map_range(mapped_value, 0, 1023, 0, 255)
    print('original value returned: ', sensor_value)
    time.sleep(2)
import digitalio
import adafruit_character_lcd as LCD
import board
import analogio
from simpleio import map_range

# LCD setup
lcd_columns = 16
lcd_rows = 2
lcd_rs = digitalio.DigitalInOut(board.D7)
lcd_en = digitalio.DigitalInOut(board.D8)
lcd_d7 = digitalio.DigitalInOut(board.D12)
lcd_d6 = digitalio.DigitalInOut(board.D11)
lcd_d5 = digitalio.DigitalInOut(board.D10)
lcd_d4 = digitalio.DigitalInOut(board.D9)
lcd_backlight = digitalio.DigitalInOut(board.D13)
lcd = LCD.cirpyth_char_lcd(lcd_rs, lcd_en, lcd_d4, lcd_d5, lcd_d6, lcd_d7,
                           lcd_columns, lcd_rows, lcd_backlight)

therm = analogio.AnalogIn(board.A0)

# loop forever
while True:
    # get temperature from sensor
    tmp = (((
        (map_range(therm.value, 0, 65535, 0, 3.3)) - .5) * 100) * 1.8) + 32
    lcd.clear()
    # lcd.message('temp: ' + str(therm.value * .004882814)[:5] + ' * f')
    lcd.message('temp: ' + str(tmp)[:5] + ' * f')
    time.sleep(.6)