ECEN5458/Software/python/hwtest.py

import time
import numpy as np

import board
import busio
import digitalio
from adafruit_servokit import ServoKit
import adafruit_ads1x15.ads1015 as ADS
from adafruit_ads1x15.analog_in import AnalogIn
import threading

from bokeh.io import curdoc
from bokeh.layouts import column, row
from bokeh.models import ColumnDataSource, Slider, TextInput, Button
from bokeh.plotting import figure

DEBUG = True

mux_io = [None] * 4
mux_io[0] = digitalio.DigitalInOut(board.D23)
mux_io[1] = digitalio.DigitalInOut(board.D22)
mux_io[2] = digitalio.DigitalInOut(board.D27)
mux_io[3] = digitalio.DigitalInOut(board.D17)

for ii, io in enumerate(mux_io):
    io.switch_to_output()

i2c = busio.I2C(board.SCL, board.SDA)
adc = ADS.ADS1015(i2c)
adc_mux = AnalogIn(adc, ADS.P0)
white_cal = [0]*8
black_cal = [5]*8

adc_lock = threading.Lock()

def get_reflectivity(chan):
    chan = int(chan)
    global mux_io
    global adc_mux
    global adc_lock
    mux = 1-np.array(list(f"{chan:04b}"), dtype=int)
    adc_lock.acquire()
    for ii, io in enumerate(mux_io):
        io.value = mux[ii]
    time.sleep(0.001)
    voltage = adc_mux.voltage
    adc_lock.release()
    return voltage

def get_normalized_reflectivity(chan):
    global white_cal
    global black_cal
    
    return (get_reflectivity(chan) - black_cal[chan]) / (white_cal[chan] - black_cal[chan])

brightness_idx = np.arange(8)
brightness = [get_normalized_reflectivity(c) for c in range(8)]
t = np.array([])
error = np.array([])

brightness_plot_source = ColumnDataSource(data=dict(sensor=brightness_idx, brightness=brightness))
time_plot_source = ColumnDataSource(data=dict(t=t, e=error))

# Set up plots
brightness_plot = figure(plot_height=150, plot_width=400, title="Reflectivity", x_range=[0, 7], y_range=[0, 1])
brightness_plot.line('sensor', 'brightness', source=brightness_plot_source, line_width=3)
brightness_plot.circle('sensor', 'brightness', source=brightness_plot_source, size=8, fill_color="white", line_width=2)

time_plot = figure(plot_height=400, plot_width=400, title="Signals")
time_plot.line('t', 'e', source=time_plot_source, line_width=3, line_alpha=0.6)

def update_plots(attrname=None, old=None, new=None):
    global brightness
    global error
    global brightness_plot_source
    brightness_plot_source.data = dict(sensor=brightness_idx, brightness=brightness)
    time_plot_source.data = dict(t=t, e=error)


def cal_white(attrname=None, old=None, new=None):
    global white_cal
    white_cal = [get_reflectivity(c) for c in range(8)]
    update_plots()

def cal_black(attrname=None, old=None, new=None):
    global black_cal
    black_cal = [get_reflectivity(c) for c in range(8)]
    update_plots()

cal_white_button = Button(label="Cal White")
cal_white_button.on_click(cal_white)
cal_black_button = Button(label="Cal Black")
cal_black_button.on_click(cal_black)

controls = column(cal_white_button, cal_black_button)

curdoc().add_root(row(controls, plot, width=800))
curdoc().title = "TriangleBot Control Panel"
curdoc().add_periodic_callback(update_plots, 250)

def control_thread():
    global brightness
    global t
    global error
    sample_interval = 0.01
    while True:
        # TODO: replace sleep statement with something that doesn't depend on execution time of loop
        time.sleep(sample_interval)
        if len(time) == 0:
            this_time = 0
        else: 
            this_time = t[-1] + sample_interval

        brightness = np.clip([get_normalized_reflectivity(c) for c in range(8)], 0, 1)
        line_position = np.sum((1 - brightness) * (np.arange(8) - 3.5))/np.sum(1-brightness)
        # TODO: implement control stuff and drive outputs

        t = np.concatenate((t, this_time))
        error = np.concatenate((error, line_position))

        if DEBUG:
            for b in brightness:
                print(f"{b:1.2f}\t", end="")
            print(f"{line_position:+1.2f}", end="")
            print()


t = threading.Thread(target=control_thread)
t.start()


# servos = ServoKit(channels=16).continuous_servo
# servos[0].throttle = 0
# servos[1].throttle = 0
# servos[2].throttle = 0
# time.sleep(1)
# servos[0].throttle = 20
# servos[1].throttle = 20
# servos[2].throttle = 20
# time.sleep(1)
# servos[0].throttle = 0
# servos[1].throttle = 0
# servos[2].throttle = 0
initial commit 2020-02-26 10:47:21 -07:00			`import time`
			`import numpy as np`
add ADC stuff 2020-03-02 11:39:07 -07:00
			`import board`
WIP: trying to get ADC working 2020-03-02 13:40:42 -07:00			`import busio`
add ADC stuff 2020-03-02 11:39:07 -07:00			`import digitalio`
initial commit 2020-02-26 10:47:21 -07:00			`from adafruit_servokit import ServoKit`
fix import statement for adc 2020-03-02 13:39:37 -07:00			`import adafruit_ads1x15.ads1015 as ADS`
add ADC stuff 2020-03-02 11:39:07 -07:00			`from adafruit_ads1x15.analog_in import AnalogIn`
WIP: hopefully update data periodically 2020-03-02 16:06:58 -07:00			`import threading`
initial commit 2020-02-26 10:47:21 -07:00
add attempt at web interface 2020-03-02 14:45:16 -07:00			`from bokeh.io import curdoc`
			`from bokeh.layouts import column, row`
move calibration to web thing 2020-03-02 15:16:55 -07:00			`from bokeh.models import ColumnDataSource, Slider, TextInput, Button`
add attempt at web interface 2020-03-02 14:45:16 -07:00			`from bokeh.plotting import figure`

improve formatting of print string 2020-03-02 16:27:41 -07:00			`DEBUG = True`

WIP: remove if main 2020-03-02 15:59:59 -07:00			`mux_io = [None] * 4`
fix channel order 2020-03-02 18:56:42 -07:00			`mux_io[0] = digitalio.DigitalInOut(board.D23)`
			`mux_io[1] = digitalio.DigitalInOut(board.D22)`
			`mux_io[2] = digitalio.DigitalInOut(board.D27)`
			`mux_io[3] = digitalio.DigitalInOut(board.D17)`
WIP: remove if main 2020-03-02 15:59:59 -07:00
			`for ii, io in enumerate(mux_io):`
			`io.switch_to_output()`

			`i2c = busio.I2C(board.SCL, board.SDA)`
			`adc = ADS.ADS1015(i2c)`
			`adc_mux = AnalogIn(adc, ADS.P0)`
			`white_cal = [0]*8`
			`black_cal = [5]*8`

add lock for external resources 2020-03-02 16:24:01 -07:00			`adc_lock = threading.Lock()`

WIP: remove if main 2020-03-02 15:59:59 -07:00			`def get_reflectivity(chan):`
			`chan = int(chan)`
			`global mux_io`
			`global adc_mux`
add lock for external resources 2020-03-02 16:24:01 -07:00			`global adc_lock`
WIP: remove if main 2020-03-02 15:59:59 -07:00			`mux = 1-np.array(list(f"{chan:04b}"), dtype=int)`
add lock for external resources 2020-03-02 16:24:01 -07:00			`adc_lock.acquire()`
properly sets mux 2020-03-02 13:57:55 -07:00			`for ii, io in enumerate(mux_io):`
WIP: remove if main 2020-03-02 15:59:59 -07:00			`io.value = mux[ii]`
hopefully fix calibration issues 2020-03-02 16:30:00 -07:00			`time.sleep(0.001)`
add lock for external resources 2020-03-02 16:24:01 -07:00			`voltage = adc_mux.voltage`
			`adc_lock.release()`
			`return voltage`
WIP: trying to serve a page properly 2020-03-02 15:22:01 -07:00
WIP: remove if main 2020-03-02 15:59:59 -07:00			`def get_normalized_reflectivity(chan):`
			`global white_cal`
			`global black_cal`

			`return (get_reflectivity(chan) - black_cal[chan]) / (white_cal[chan] - black_cal[chan])`
WIP: trying to serve a page properly 2020-03-02 15:22:01 -07:00
WIP: remove if main 2020-03-02 15:59:59 -07:00			`brightness_idx = np.arange(8)`
			`brightness = [get_normalized_reflectivity(c) for c in range(8)]`
Add time plot 2020-03-02 19:45:04 -07:00			`t = np.array([])`
			`error = np.array([])`
add attempt at web interface 2020-03-02 14:45:16 -07:00
Add time plot 2020-03-02 19:45:04 -07:00			`brightness_plot_source = ColumnDataSource(data=dict(sensor=brightness_idx, brightness=brightness))`
			`time_plot_source = ColumnDataSource(data=dict(t=t, e=error))`
add attempt at web interface 2020-03-02 14:45:16 -07:00
Add time plot 2020-03-02 19:45:04 -07:00			`# Set up plots`
			`brightness_plot = figure(plot_height=150, plot_width=400, title="Reflectivity", x_range=[0, 7], y_range=[0, 1])`
			`brightness_plot.line('sensor', 'brightness', source=brightness_plot_source, line_width=3)`
			`brightness_plot.circle('sensor', 'brightness', source=brightness_plot_source, size=8, fill_color="white", line_width=2)`
add attempt at web interface 2020-03-02 14:45:16 -07:00
Add time plot 2020-03-02 19:45:04 -07:00			`time_plot = figure(plot_height=400, plot_width=400, title="Signals")`
			`time_plot.line('t', 'e', source=time_plot_source, line_width=3, line_alpha=0.6)`
WIP: add debugging stuff to hwtest.py 2020-03-02 15:24:40 -07:00
Add time plot 2020-03-02 19:45:04 -07:00			`def update_plots(attrname=None, old=None, new=None):`
WIP: this may allow for plot updates 2020-03-02 16:32:55 -07:00			`global brightness`
Add time plot 2020-03-02 19:45:04 -07:00			`global error`
			`global brightness_plot_source`
			`brightness_plot_source.data = dict(sensor=brightness_idx, brightness=brightness)`
			`time_plot_source.data = dict(t=t, e=error)`

WIP: remove if main 2020-03-02 15:59:59 -07:00
WIP: potentially fix function signatures for callbacks 2020-03-02 16:01:28 -07:00			`def cal_white(attrname=None, old=None, new=None):`
WIP: remove if main 2020-03-02 15:59:59 -07:00			`global white_cal`
add lock for external resources 2020-03-02 16:24:01 -07:00			`white_cal = [get_reflectivity(c) for c in range(8)]`
Add time plot 2020-03-02 19:45:04 -07:00			`update_plots()`
WIP: remove if main 2020-03-02 15:59:59 -07:00
WIP: potentially fix function signatures for callbacks 2020-03-02 16:01:28 -07:00			`def cal_black(attrname=None, old=None, new=None):`
WIP: remove if main 2020-03-02 15:59:59 -07:00			`global black_cal`
add lock for external resources 2020-03-02 16:24:01 -07:00			`black_cal = [get_reflectivity(c) for c in range(8)]`
Add time plot 2020-03-02 19:45:04 -07:00			`update_plots()`
WIP: remove if main 2020-03-02 15:59:59 -07:00
			`cal_white_button = Button(label="Cal White")`
			`cal_white_button.on_click(cal_white)`
			`cal_black_button = Button(label="Cal Black")`
			`cal_black_button.on_click(cal_black)`

remove 'update plot' button 2020-03-02 19:03:20 -07:00			`controls = column(cal_white_button, cal_black_button)`
WIP: remove if main 2020-03-02 15:59:59 -07:00
			`curdoc().add_root(row(controls, plot, width=800))`
WIP: still hoping 2020-03-02 16:20:43 -07:00			`curdoc().title = "TriangleBot Control Panel"`
Add time plot 2020-03-02 19:45:04 -07:00			`curdoc().add_periodic_callback(update_plots, 250)`
WIP: remove if main 2020-03-02 15:59:59 -07:00
make data fetch happen in a second thread 2020-03-02 16:11:21 -07:00			`def control_thread():`
WIP: this may allow for plot updates 2020-03-02 16:32:55 -07:00			`global brightness`
Add time plot 2020-03-02 19:45:04 -07:00			`global t`
			`global error`
			`sample_interval = 0.01`
make data fetch happen in a second thread 2020-03-02 16:11:21 -07:00			`while True:`
Add time plot 2020-03-02 19:45:04 -07:00			`# TODO: replace sleep statement with something that doesn't depend on execution time of loop`
			`time.sleep(sample_interval)`
			`if len(time) == 0:`
			`this_time = 0`
			`else:`
			`this_time = t[-1] + sample_interval`

add line position calculation 2020-03-02 19:29:40 -07:00			`brightness = np.clip([get_normalized_reflectivity(c) for c in range(8)], 0, 1)`
			`line_position = np.sum((1 - brightness) * (np.arange(8) - 3.5))/np.sum(1-brightness)`
Add time plot 2020-03-02 19:45:04 -07:00			`# TODO: implement control stuff and drive outputs`

			`t = np.concatenate((t, this_time))`
			`error = np.concatenate((error, line_position))`

improve formatting of print string 2020-03-02 16:27:41 -07:00			`if DEBUG:`
			`for b in brightness:`
			`print(f"{b:1.2f}\t", end="")`
add line position calculation 2020-03-02 19:29:40 -07:00			`print(f"{line_position:+1.2f}", end="")`
improve formatting of print string 2020-03-02 16:27:41 -07:00			`print()`
WIP: hopefully make plots update 2020-03-02 16:17:34 -07:00
make data fetch happen in a second thread 2020-03-02 16:11:21 -07:00
			`t = threading.Thread(target=control_thread)`
WIP: hopefully update data periodically 2020-03-02 16:06:58 -07:00			`t.start()`
WIP: remove if main 2020-03-02 15:59:59 -07:00

			`# servos = ServoKit(channels=16).continuous_servo`
			`# servos[0].throttle = 0`
			`# servos[1].throttle = 0`
			`# servos[2].throttle = 0`
			`# time.sleep(1)`
			`# servos[0].throttle = 20`
			`# servos[1].throttle = 20`
			`# servos[2].throttle = 20`
			`# time.sleep(1)`
			`# servos[0].throttle = 0`
			`# servos[1].throttle = 0`
			`# servos[2].throttle = 0`
WIP: add debugging stuff to hwtest.py 2020-03-02 15:24:40 -07:00