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Add JYMCU, IRDistance, Relay and SR04Distance 

Bunch of driver and code format changes
master
GuyCarver 2014-11-24 22:40:17 -05:00
rodzic e2842f1754
commit 54babcede8
17 zmienionych plików z 413 dodań i 299 usunięć
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122
DistanceDisplay.py 100644
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@ -0,0 +1,122 @@
#Display distance in inches on ST7734 LCD.
#Distance is taken from the given distance sensor.
import pyb
import terminalfont
ZeroPoint = (0, 0)
DISPLAY_DELAY = 100
FONT_HEIGHT = terminalfont.terminalfont["Height"]
NUM_DISTANCES = 4 #The number of _distances to use for throwing away anomalies
THRESHOLD = 0.5
#100-15 = blue
#15-10 = green
#10-5 = yellow
#5-0 = red
COLORS = [(0, 255, 0, 0),
(.35, 255, 255, 0),
(.50, 0, 255, 0),
(.75, 0, 255, 255),
(1.0, 0, 0, 255)
]
def round( aValue ) :
'''Round float value to 2 decimal places'''
return (aValue - (aValue % 0.01))
def getrgb( aDisplay, aDistance, maxdist ) :
'''Get an interpolated color based on distance.
Uses the COLORS list.'''
clr = aDisplay.NAVY
def interp( l, v0, v1 ) :
return int(v0 * (1.0 - l) + (v1 * l))
for i in range(1, len(COLORS)) :
c = COLORS[i]
if c[0] * maxdist >= aDistance:
rng0, r0, g0, b0 = COLORS[i - 1]
rng1, r1, g1, b1 = c
rng0 *= maxdist
rng1 *= maxdist
#interpolate between rng0 and rng1
l = (aDistance - rng0) / float(rng1 - rng0)
r = interp(l, r0, r1)
g = interp(l, g0, g1)
b = interp(l, b0, b1)
clr = aDisplay.color(r,g,b)
break
return clr
class RangePoint(object):
"""Display a point on the screen"""
def __init__( self, size, maxrange ) :
self._size = (50, size)
self._pos = (-1, 0)
self._prevdistance = -1
self._maxrange = maxrange
def update( self, aDisplay, aDistance, aTime ) :
if (self._prevdistance != aDistance):
self._draw(aDisplay, 0)
clr = getrgb(aDisplay, aDistance, self._maxrange)
y = min(1.0, aDistance / self._maxrange)
self._pos = (int((aDisplay.size()[0] / 2) - (self._size[0] / 2)), int(y * aDisplay.size()[1] - self._size[1]))
self._draw(aDisplay, clr)
self._prevdistance = aDistance
def _draw( self, aDisplay, aColor ) :
if self._pos[0] >= 0:
aDisplay.fillrect(self._pos, self._size, aColor)
def wrap( aVal, aMax ) : return aVal if aVal < aMax else 0
class Display(object):
"""Display distance on ST7735 LCD with text and a box"""
def __init__( self, display, ranger ):
self._display = display
self._ranger = ranger
self._rangepoint = RangePoint(4, ranger.maxinches)
self._curdistance = 0.0
self._distances = [0.0] * NUM_DISTANCES
self._distindex = 0
def printdistance( self, aDistance ) :
s = "I:" + str(round(aDistance))
self._display.fillrect(ZeroPoint, (self._display.size()[0], FONT_HEIGHT * 2), 0)
self._display.text(ZeroPoint, s, self._display.CYAN, terminalfont.terminalfont, 2)
def _getdistance( self ) :
'''Throw away changes that are not averaged. This introduces
a slight delay in update but gets rid of most bad _distances'''
d = self._ranger.inches
# self._curdistance = d
good = 0
for c in self._distances :
if abs(c - d) < THRESHOLD:
good += 1
if good > 2:
self._curdistance = d
break
self._distances[self._distindex] = d
self._distindex = wrap(self._distindex + 1, NUM_DISTANCES)
return self._curdistance
def run( self ) :
self._display.fill(0)
sw = pyb.Switch()
lasttime = pyb.millis()
while sw() == False :
pyb.delay(DISPLAY_DELAY)
distance = self._getdistance()
thistime = pyb.millis()
t = thistime - lasttime
self.printdistance(distance)
self._rangepoint.update(self._display, distance, t / 1000.0)
lasttime = thistime

33
Lib/IRDistance.py 100644
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@ -0,0 +1,33 @@
from pyb import Pin, ADC
class IRDistance(object):
""" Driver for Sharp Gp2y0a IR distance sensor. The distance
range is around 3 to 40 inches. """
maxinches = 31.5 #Maximun range of IR board in inches.
_v2i = -1.02 #Voltage to inches power.
def __init__( self, pin ) :
"""pin may be name or pin object. It must be able to handle ADC input."""
if type(pin) == str:
p = Pin(pin)
elif type(pin) == Pin:
p = pin
else:
raise Exception("pin must be pin name or pyb.Pin able to support ADC")
self._adc = ADC(p)
@property
def distance( self ) : return self._adc.read()
@property
def inches( self ) :
volts = self.distance * 0.0048828125
return 65.0 * pow(volts, IRDistance._v2i)
@property
def centimeters( self ) : return self.inches * 2.54

69
Lib/JYMCU.py 100644
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@ -0,0 +1,69 @@
from pyb import UART, repl_uart, udelay
# JY-MCU Bluetooth board ----------------------------------------
# This opens connection with Bluetooth module connected to Y1, Y2 (UART 6)
# Then it sets the repl output to this UART.
#COMMANDS AT - does nothing but get an ok.
# The posible baudrates are:
# AT+BAUD1-------1200
# AT+BAUD2-------2400
# AT+BAUD3-------4800
# AT+BAUD4-------9600 - Default for hc-06
# AT+BAUD5------19200
# AT+BAUD6------38400
# AT+BAUD7------57600 - Johnny-five speed
# AT+BAUD8-----115200
# AT+BAUD9-----230400
# AT+BAUDA-----460800
# AT+BAUDB-----921600
# AT+BAUDC----1382400
# AT+VERSION
# AT+NAMEnewname This is the name that will show up in windows.
# AT+PIN???? set 4 digit pairing pin.
class JYMCU(object):
"""JY-MCU Bluetooth serial device driver. This is simply a light UART wrapper
with addition AT command methods to customize the device."""
def __init__( self, uart, baudrate ):
""" uart = uart #1-6, baudrate must match what is set on the JY-MCU.
Needs to be a #1-C. """
self._uart = UART(uart, baudrate)
def __del__( self ) : self._uart.deinit()
def any( self ) : return self._uart.any()
def write( self, astring ) : return self._uart.write(astring)
def writechar( self, achar ) : self._uart.writechar(achar)
def read( self, num = None ) : return self._uart.read(num)
def readline( self ) : return self._uart.readline()
def readchar( self ) : return self._uart.readchar()
def readall( self ) : return self._uart.readall()
def readinto( self, buf, count = None ) : return self._uart.readinto(buf, count)
def _cmd( self, cmd ) :
""" Send AT command, wait a bit then return result string. """
self._uart.write("AT+" + cmd)
udelay(500)
return self.readline()
def baudrate( self, rate ) :
""" Set the baud rate. Needs to be #1-C. """
return self._cmd("BAUD" + str(rate))
def name( self, name ) :
""" Set the name to show up on the connecting device. """
return self._cmd("NAME" + name)
def pin( self, pin ) :
""" Set the given 4 digit numeric pin. """
return self._cmd("PIN" + str(pin))
def version( self ) : return self._cmd("VERSION")
def setrepl( self ) : repl_uart(self._uart)

29
Lib/L298N.py
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@ -1,28 +1,26 @@
#Driver for the L298N Dual HBridge motor controller.
from PWM import PWM
from pyb import Pin
#motordata
#Forward pin
#Back pin
#Speed pin (PWM)
from pyb import Pin, delay
class Motor( ):
"""docstring for Motor"""
"""Control a motor connected to the L298N Dual motor controller."""
def __init__(self, forward, backward, speed):
"""Speed = (pin name, timer#)"""
def __init__( self, forward, backward, speed ) :
"""forward pin name, backward pin name, speed = (pin name, timer#)
Need to make sure the given timer # is associated with the speed
pin or an exception will be raised. The speed pin must support
PWM."""
self._forward = Pin(forward, Pin.OUT_PP)
self._backward = Pin(backward, Pin.OUT_PP)
self._speedControl = PWM(speed[0], speed[1])
self._speed = 0
@property
def speed(self): return self._speed
def speed( self ) : return self._speed
@speed.setter
def speed(self, value):
def speed( self, value ) :
self._speed = value
if (value == 0):
self._forward.low()
@ -34,11 +32,12 @@ class Motor( ):
self._forward.high()
self._backward.low()
self._speedControl.pulse_width_percent = abs(value)
self._speedControl.pulse_width_percent = min(100, abs(value))
def brake( self ) :
""" """
""" Brake the motor by sending power both directions. """
self._forward.high()
self._backward.high()
self._speedControl.pulse_width_percent(1.0)
self._speedControl.pulse_width_percent = 100
delay(1000)
self.speed = 0

16
Lib/PIR.py
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@ -32,38 +32,38 @@ class PIR(object):
self._power.low()
@property
def power(self): return True if (self._power == None) else self._power.value()
def power( self ) : return True if (self._power == None) else self._power.value()
@power.setter
def power(self, value): self._onoff(value)
def power( self, value ) : self._onoff(value)
def on( self ) : self.power = True
def off( self ) : self.power = False
@property
def trigger(self): return self._trigger.value()
def trigger( self ) : return self._trigger.value()
@property
def interrupt(self): return self._interrupt
def interrupt( self ) : return self._interrupt
@interrupt.setter
def interrupt(self, func):
def interrupt( self, func ) :
self._interrupt = None;
self._func = func
if (func != None):
self._interrupt = pyb.ExtInt(self._trigger, pyb.ExtInt.IRQ_RISING_FALLING, pyb.Pin.PULL_DOWN, self._inthandler)
self._inton = True
def _inthandler(self, line):
def _inthandler( self, line ) :
'''Function to handle interrupts and pass on to callback with on/off trigger state.'''
if (self._func != None):
self._func(self.trigger)
@property
def inton(self): return self._inton
def inton( self ) : return self._inton
@inton.setter
def inton(self, value):
def inton( self, value ) :
self._inton = value
if self._interrupt != None:
if value :

20
Lib/PWM.py
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@ -30,11 +30,11 @@ class PWM(object):
}
class PWMException(Exception):
def __init__(self, msg):
def __init__( self, msg ) :
self.msg = msg
@staticmethod
def timerandchannel( pinname, timernum ):
def timerandchannel( pinname, timernum ) :
try:
a = PWM.PinChannels[pinname]
if timernum <= 0:
@ -48,7 +48,7 @@ class PWM(object):
raise PWM.PWMException("Pin {} cannot use timer {}".format(pinname, timernum))
def __init__( self, p, timernum, afreq = 100 ):
def __init__( self, p, timernum, afreq = 100 ) :
isname = type(p) == str
pinname = p if isname else p.name()
timernum, channel = PWM.timerandchannel(pinname, timernum)
@ -59,23 +59,23 @@ class PWM(object):
self._channel = self._timer.channel(channel, Timer.PWM, pin = p)
@property
def pulse_width(self): return self._channel.pulse_width()
def pulse_width( self ) : return self._channel.pulse_width()
@pulse_width.setter
def pulse_width(self, value): self._channel.pulse_width(value)
def pulse_width( self, value ) : self._channel.pulse_width(value)
@property
def pulse_width_percent(self): return self._channel.pulse_width_percent()
def pulse_width_percent( self ) : return self._channel.pulse_width_percent()
@pulse_width_percent.setter
def pulse_width_percent(self, value): self._channel.pulse_width_percent(value)
def pulse_width_percent( self, value ) : self._channel.pulse_width_percent(value)
@property
def freq(self): return self._timer.freq()
def freq( self ) : return self._timer.freq()
@freq.setter
def freq(self, value): self._timer.freq(value)
def freq( self, value ) : self._timer.freq(value)
def callback(self, value):
def callback( self, value ) :
self._channel.callback(value)

30
Lib/Relay.py 100644
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@ -0,0 +1,30 @@
#Control a relay board.
from pyb import Pin
class Relay(object):
"""Control a relay board with an output pin. Set on to True to drive the relay pin low
which turns the relay on."""
def __init__( self, pin ) :
"""Pin may be a pin name or pyb.Pin object set for output."""
if type(pin) == str:
self._pin = Pin(pin, Pin.OUT_PP, Pin.PULL_DOWN)
elif type(pin) == Pin:
self._pin = pin
else:
raise Exception("pin must be pin name or pyb.Pin")
self.on = False
@property
def on( self ) : return self._pin.value()
@on.setter
def on( self, value ) :
if value:
self._pin.low()
else:
self._pin.high()

71
Lib/SR04Distance.py 100644
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@ -0,0 +1,71 @@
from pyb import Pin, Timer, udelay
# WARNING: Do not use PA4-X5 or PA5-X6 as the echo pin without a 1k resistor.
class SR04Distance(object):
""" """
maxinches = 20 #maximum range of SR04.
def __init__( self, tpin, epin, timer=2 ) :
""" """
if type(tpin) == str:
self._tpin = Pin(tpin, Pin.OUT_PP, Pin.PULL_NONE)
elif type(tpin) == Pin:
self._tpin = tpin
else:
raise Exception("trigger pin must be pin name or pyb.Pin configured for output.")
self._tpin.low()
if type(epin) == str:
self._epin = Pin(epin, Pin.IN, Pin.PULL_NONE)
elif type(epin) == Pin:
self._epin = epin
else:
raise Exception("echo pin must be pin name or pyb.Pin configured for input.")
# Create a microseconds counter.
self._micros = Timer(timer, prescaler=83, period=0x3fffffff)
def __del__( self ) :
self._micros.deinit()
@property
def counter( self ) : return self._micros.counter()
@counter.setter
def counter( self, value ) : self._micros.counter(value)
@property
def centimeters( self ) :
start = 0
end = 0
self.counter = 0
#Send 10us pulse.
self._tpin.high()
udelay(10)
self._tpin.low()
while not self._epin.value():
start = self.counter
j = 0
# Wait 'till the pulse is gone.
while self._epin.value() and j < 1000:
j += 1
end = self.counter
# Calc the duration of the recieved pulse, divide the result by
# 2 (round-trip) and divide it by 29 (the speed of sound is
# 340 m/s and that is 29 us/cm).
return (end - start) / 58
@property
def inches( self ) : return self.centimeters * 0.3937

20
Lib/ST7735.py
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@ -95,11 +95,11 @@ class TFT(object) :
GRAY = TFTColor(0x80, 0x80, 0x80)
@staticmethod
def color(aR, aG, aB):
def color( aR, aG, aB ) :
'''Create a 565 rgb TFTColor value'''
return TFTColor(aR, aG, aB)
def __init__(self, aLoc, aDC, aReset) :
def __init__( self, aLoc, aDC, aReset ) :
"""aLoc SPI pin location is either 1 for 'X' or 2 for 'Y'.
aDC is the DC pin and aReset is the reset pin."""
self._size = ScreenSize
@ -115,7 +115,7 @@ class TFT(object) :
self.colorData = bytearray(2)
self.windowLocData = bytearray(4)
def size( self ):
def size( self ) :
return self._size
# @micropython.native
@ -448,7 +448,7 @@ class TFT(object) :
self._writedata(TFTRotations[self.rotate] | rgb)
@micropython.native
def _reset(self):
def _reset( self ) :
'''Reset the device.'''
self.dc.low()
self.reset.high()
@ -458,7 +458,7 @@ class TFT(object) :
self.reset.high()
pyb.delay(500)
def initb(self):
def initb( self ) :
'''Initialize blue tab version.'''
self._size = (ScreenSize[0] + 2, ScreenSize[1] + 1)
self._reset()
@ -556,7 +556,7 @@ class TFT(object) :
self.cs.high()
pyb.delay(500)
def initr(self):
def initr( self ) :
'''Initialize a red tab version.'''
self._reset()
@ -653,7 +653,7 @@ class TFT(object) :
self.cs.high()
@micropython.native
def initg(self):
def initg( self ) :
'''Initialize a green tab version.'''
self._reset()
@ -741,21 +741,21 @@ class TFT(object) :
self.cs.high()
def maker():
def maker( ) :
t = TFT(1, "X1", "X2")
print("Initializing")
t.initr()
t.fill(0)
return t
def makeb( ):
def makeb( ) :
t = TFT(1, "X1", "X2")
print("Initializing")
t.initb()
t.fill(0)
return t
def makeg( ):
def makeg( ) :
t = TFT(1, "X1", "X2")
print("Initializing")
t.initg()

82
Lib/ultrasonic.py
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@ -1,82 +0,0 @@
##
# Ultrasonic library for MicroPython's pyboard.
# Compatible with HC-SR04 and SRF04.
#
# Copyright 2014 - Sergio Conde Gómez <skgsergio@gmail.com>
#
# This program is free software: you can redistribute it and/or modify
# it under the terms of the GNU General Public License as published by
# the Free Software Foundation, either version 3 of the License, or
# (at your option) any later version.
#
# This program is distributed in the hope that it will be useful,
# but WITHOUT ANY WARRANTY; without even the implied warranty of
# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
# GNU General Public License for more details.
#
# You should have received a copy of the GNU General Public License
# along with this program. If not, see <http://www.gnu.org/licenses/>.
##
import pyb
# Pin configuration.
# WARNING: Do not use PA4-X5 or PA5-X6 as the echo pin without a 1k resistor.
def wait( aCount ):
j = 0;
for i in range(aCount):
j += i
class Ultrasonic:
def __init__(self, tPin, ePin):
self.triggerPin = tPin
self.echoPin = ePin
# Init trigger pin (out)
self.trigger = pyb.Pin(self.triggerPin)
self.trigger.init(pyb.Pin.OUT_PP, pyb.Pin.PULL_NONE)
self.trigger.low()
# Init echo pin (in)
self.echo = pyb.Pin(self.echoPin)
self.echo.init(pyb.Pin.IN, pyb.Pin.PULL_NONE)
def distance_in_inches(self):
return (self.distance_in_cm() * 0.3937)
def distance_in_cm(self):
start = 0
end = 0
# Create a microseconds counter.
micros = pyb.Timer(2, prescaler=83, period=0x3fffffff)
micros.counter(0)
# Send a 10us pulse.
self.trigger.high()
pyb.udelay(10)
self.trigger.low()
# Wait 'till whe pulse starts.
while self.echo.value() == 0:
start = micros.counter()
j = 0
# Wait 'till the pulse is gone.
while self.echo.value() == 1 and j < 1000:
# print("wait end")
# wait(1000)
j += 1
end = micros.counter()
# Deinit the microseconds counter
micros.deinit()
# Calc the duration of the recieved pulse, divide the result by
# 2 (round-trip) and divide it by 29 (the speed of sound is
# 340 m/s and that is 29 us/cm).
dist_in_cm = ((end - start) / 2) / 29
return dist_in_cm

144
SonarDisplay.py
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@ -1,144 +0,0 @@
#Display distance reported by the HC-SR04 on the ST7735 LCD.
import ultrasonic
import pyb
import terminalfont
ZeroPoint = (0, 0)
SONAR_DELAY = 100
MAX_RANGE = 25.0
FONT_HEIGHT = terminalfont.terminalfont["Height"]
NUM_DISTANCES = 4 #The number of distances to use for throwing away anomalies
THRESHOLD = 1.0
#100-15 = blue
#15-10 = green
#10-5 = yellow
#5-0 = red
COLORS = [(0, 255, 0, 0),
(5, 255, 255, 0),
(10, 0, 255, 0),
(15, 0, 255, 255),
(20, 0, 0, 255)
]
def round( aValue ) :
'''Round float value to 2 decimal places'''
return (aValue - (aValue % 0.01))
def getrgb( aDisplay, aDistance ) :
'''Get an interpolated color based on distance.
Uses the COLORS list.'''
clr = aDisplay.NAVY
def interp(l, v0, v1):
return int(v0 * (1.0 - l) + (v1 * l))
for i in range(1, len(COLORS)) :
c = COLORS[i]
if c[0] >= aDistance:
rng0, r0, g0, b0 = COLORS[i - 1]
rng1, r1, g1, b1 = c
#interpolate between rng0 and rng1
l = (aDistance - rng0) / float(rng1 - rng0)
r = interp(l, r0, r1)
g = interp(l, g0, g1)
b = interp(l, b0, b1)
clr = aDisplay.color(r,g,b)
break
return clr
class RangePoint(object):
"""Display a point on the screen"""
def __init__(self, aSize):
self.size = (50, aSize)
self.pos = (-1, 0)
self.prevdistance = -1
def update( self, aDisplay, aDistance, aTime ) :
if (self.prevdistance != aDistance):
self._draw(aDisplay, 0)
clr = getrgb(aDistance)
y = min(1.0, aDistance / MAX_RANGE)
self.pos = (int((aDisplay.size[0] / 2) - (self.size[0] / 2)), int(y * aDisplay.size[1] - self.size[1]))
self._draw(aDisplay, clr)
self.prevdistance = aDistance
def _draw( self, aDisplay, aColor ) :
if self.pos[0] >= 0:
aDisplay.fillrect(self.pos, self.size, aColor)
def wrap( aVal, aMax ) :
return aVal if aVal < aMax else 0
class SonarDisplay(object):
"""Display HC-SR04 distance on ST7735 LCD with text and a box"""
def __init__( self, aDisplay, aTrigger, aEcho ):
self.display = aDisplay
self.triggerpin = aTrigger
self.echopin = aEcho
self.rangepoint = RangePoint(4)
self.curdistance = 0.0
self.distances = [0.0] * NUM_DISTANCES
self.distindex = 0
self.hc = ultrasonic.Ultrasonic(self.triggerpin, self.echopin)
def printdistance( self, aDistance ) :
s = "I:" + str(round(aDistance))
self.display.fillrect(ZeroPoint, (self.display.size[0], FONT_HEIGHT), 0)
self.display.text(ZeroPoint, s, CYAN, terminalfont.terminalfont)
def _getdistance( self ) :
'''Throw away changes that are not averaged. This introduces
a slight delay in update but gets rid of most bad distances'''
d = self.hc.distance_in_inches()
good = 0
for c in self.distances :
if abs(c - d) < THRESHOLD:
good += 1
if good > 2:
self.curdistance = d
break
self.distances[self.distindex] = d
self.distindex = wrap(self.distindex + 1, NUM_DISTANCES)
return self.curdistance
def run( self ):
self.display.fill(0)
sw = pyb.Switch()
lasttime = pyb.millis()
while sw() == False :
pyb.delay(SONAR_DELAY)
distance = self._getdistance()
thistime = pyb.millis()
t = thistime - lasttime
self.printdistance(distance)
self.rangepoint.update(self.display, distance, t / 1000.0)
lasttime = thistime
# sensor1_trigPin = pyb.Pin.board.X8
# sensor1_echoPin = pyb.Pin.board.X7
# sensor1 = ultrasonic.Ultrasonic(sensor1_trigPin, sensor1_echoPin)
# switch = pyb.Switch()
# # function that prints each sensor's distance
# def print_sensor_values():
# # get sensor1's distance in cm
# distance1 = sensor1.distance_in_inches()
# print("Sensor1", distance1, "inches")
# # prints values every second
# while True:
# print("Sensing")
# print_sensor_values()
# # ultrasonic.wait(10000)
# pyb.delay(100)

2
TreatThrower.py
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@ -12,7 +12,7 @@ class TreatThrower(object):
servoTime = 1450
ledNum = 3
def __init__(self, sensor, servonum = 3):
def __init__( self, sensor, servonum = 3 ) :
self._sensor = sensor
self._servo = pyb.Servo(servonum)
mn, mx, _, a, s = self._servo.calibration()

BIN
_SYNCAPP/metadata.xml
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Plik binarny nie jest wyświetlany.

4
bombs.py
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@ -7,7 +7,7 @@ import time
class bomb(object):
"""Animate a circle on the screen."""
def __init__(self, aPos, aRadius, aColor, aSpeed):
def __init__( self, aPos, aRadius, aColor, aSpeed ) :
self.pos = aPos
self.radius = aRadius
self.color = aColor
@ -35,7 +35,7 @@ def randval( aVal ) :
class bomber(object):
"""Control a bunch of bombs."""
def __init__(self, aDisplay):
def __init__( self, aDisplay ) :
self.display = aDisplay
self.ds = self.display.size()
self.numbombs = 4

4
level.py
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@ -8,7 +8,7 @@ ZeroPoint = (0, 0)
class Bubble(object):
"""Circle simulating the level bubble."""
def __init__(self, aCenter, aSpeed, aRadius, aColor):
def __init__( self, aCenter, aSpeed, aRadius, aColor ) :
self.center = aCenter
self.pos = aCenter
self.oldpos = self.pos
@ -52,7 +52,7 @@ class Bubble(object):
class Level(object):
"""Simulate a level by controlling a bubble on the aDisplay
controlled by the accelerometer."""
def __init__(self, aDisplay):
def __init__( self, aDisplay ) :
self.display = aDisplay
cx, cy = aDisplay.size()
cx /= 2

64
main.py
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@ -1,16 +1,9 @@
# main.py -- put your code here!
# import Balance
# Balance.main()
# from seriffont import *
# from sysfont import *
from terminalfont import *
# from SonarDisplay import SonarDisplay
# from terminalfont import *
pyt = 0
if pyt :
from ST7735 import makeg
t = makeg()
@ -18,42 +11,65 @@ else:
t = pyb.TFT("x", "X1", "X2")
t.initg()
t.fill(0)
# t.fill(0)
# import TFT
# TFT.run(t)
def tst( aColor ):
s = "ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789-=_+[]{}l;'<>?,./!@#$%^&*():"
# t.text(Point(0, 0), s, aColor, basicfont)
# t.text(Point(0, 40), s, aColor, seriffont)
t.text((0, 40), s, aColor, terminalfont)
# tst(BLUE)
def s(aRot, aColor):
t.rotation(aRot)
tst(aColor)
# Display animated circle on TFT -------------------------
# from bombs import bomber
# t.rotation(2)
# b = bomber(t)
# b.run()
# Accelerometer display ----------------------------------
# import Balance
# Balance.main()
# Carpenter level display using accelerometer ------------
# from level import Level
# l = Level(t)
# l.run()
# sd = SonarDisplay(t, "X3", "X4")
# sd.run()
# PIR motion sensor --------------------------------------
# import motion
# m = motion.motion(t)
# # m.run()
# Cat Treat Thrower --------------------------------------
# import TreatThrower
# tt = TreatThrower.TreatThrower(m)
# tt.run()
from L298N import Motor
m = Motor('Y2', 'Y1', ('Y3', 10))
# L2082 Motor control ------------------------------------
# from L298N import Motor
# m1 = Motor('Y1', 'Y2', ('Y3', 4))
# m2 = Motor('Y5', 'Y6', ('Y4', 4))
# IR or SR04 distance display ----------------------------
# from IRDistance import IRDistance
# r = IRDistance("X12")
# from SR04Distance import SR04Distance
# r = SR04Distance("Y2", "Y1")
# t.rotation(2)
# from DistanceDisplay import Display
# d = Display(t, r)
# d.run()
# Bluetooth board ----------------------------------------
from JYMCU import JYMCU
u = JYMCU(6, 57600)
u.write("Testing.")
u.readline()
u.setrepl()

2
motion.py
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@ -12,7 +12,7 @@ class motion(PIR.PIR):
processdelay = 100
"""detect motion and print msg on TFT"""
def __init__(self, display):
def __init__( self, display ) :
super(motion, self).__init__(None, "X12", self.msg)
self._extpower = pyb.Pin("X11", pyb.Pin.OUT_PP)
self._extpower.high()