[英]Real time plotting of serial data with python and tkinter
我已经工作了一段时间,以找到一种使用Python GUI从arduino绘制图形数据的方法。 我可以使用Matplotlib动画函数读取6个不同的变量,并将其中的4个绘制在一个子图上,将2个绘制在另一个子图上,从而完成此操作。 这样做的速度足够快,可以实时绘制图形(每秒20个样本)。
现在,我需要修改系统,以同时读取12个不同的变量,其中8个被绘制成图表。 一个子图上的4个以另一个每秒20个样本的相同速率在另一个子图上显示4。 我一直无法使它工作,并尝试了一些不同的东西并进行了大量研究,但似乎无法用我有限的python知识弄清楚如何做到这一点。 我对多处理或多线程不是很熟悉,但是它们似乎是人们能够加快绘图过程的方式。 我知道matplotlib动画函数本身是线程化的,因此我不确定该线程化有多大帮助,或者不确定是否有一种方法可以读取一个线程并更新另一个线程中的图形。 我在那个Arduino的支持250000我也能找到一个例子,其中一个人是能够得到非常高的速度情节在这篇文章中,但还没有能够修改为我的工作使用的最高波特率操作: 什么是wxPython最好的实时绘图小部件?
像这样从arduino接收数据:
integer.integer.integer | integer.integer.integer | integer.integer.integer | integer.integer.integer
管道代表一个新的执行器(每个发送即时消息来自的变量)
我是python的新手,很抱歉,如果这不是pythonic,但是我有两个示例:这是使用animation函数的gui:
import Tkinter
import serial
from matplotlib.backends.backend_tkagg import FigureCanvasTkAgg
from matplotlib.figure import Figure
from matplotlib import pyplot as plt
import matplotlib.animation as animation
from collections import deque
import random
class App:
def __init__(self, master):
self.arduinoData = serial.Serial('com5', 250000)#115200)
frame = Tkinter.Frame(master)
self.running = False
self.ani = None
self.start = Tkinter.LabelFrame(frame, text="Start", borderwidth=10, relief=Tkinter.GROOVE, padx=10, pady=10)
self.start.grid(row=0, column=0, padx=20, pady=20)
self.run = Tkinter.Button(self.start, text="RUN", bd=10, height=5, width=10, command=self.getData)
self.run.grid(row=0, column=0, padx=5, pady=5)
self.stop_frame = Tkinter.LabelFrame(frame, text="STOP", borderwidth=10, relief=Tkinter.GROOVE, padx=10, pady=10 )
self.stop_frame.grid(row=0, column=1, padx=20, pady=20)
self.stop = Tkinter.Button(self.stop_frame, text="STOP", bd=10, height=5, width=10, command=self.stopTest)
self.stop.grid(row=0, column=0, padx=5, pady=5)
self.fig = plt.Figure()
self.ax1 = self.fig.add_subplot(211)
self.line0, = self.ax1.plot([], [], lw=2)
self.line1, = self.ax1.plot([], [], lw=2)
self.line2, = self.ax1.plot([], [], lw=2)
self.line3, = self.ax1.plot([], [], lw=2)
self.ax2 = self.fig.add_subplot(212)
self.line4, = self.ax2.plot([], [], lw=2)
self.line5, = self.ax2.plot([], [], lw=2)
self.line6, = self.ax2.plot([], [], lw=2)
self.line7, = self.ax2.plot([], [], lw=2)
self.canvas = FigureCanvasTkAgg(self.fig,master=master)
self.canvas.show()
self.canvas.get_tk_widget().grid(row=0, column=4, padx=20, pady=20)
frame.grid(row=0, column=0, padx=20, pady=20)
def getData(self):
if self.ani is None:
self.k = 0
self.arduinoData.flushInput()
self.arduinoData.write("<L>")
return self.start()
else:
self.arduinoData.write("<L>")
self.arduinoData.flushInput()
self.ani.event_source.start()
self.running = not self.running
def stopTest(self):
self.arduinoData.write("<H>")
if self.running:
self.ani.event_source.stop()
self.running = not self.running
def resetTest(self):
self.k = 0
self.xdata = []
self.pressure1 = []
self.displacement1 = []
self.cycle1 = []
self.pressure2 = []
self.displacement2 = []
self.cycle2 = []
self.pressure3 = []
self.displacement3 = []
self.cycle3 = []
self.pressure4 = []
self.displacement4 = []
self.cycle4 = []
self.line1.set_data(self.xdata, self.ydata1)
self.line2.set_data(self.xdata, self.ydata2)
self.ax1.set_ylim(0,1)
self.ax1.set_xlim(0,1)
self.ax2.set_ylim(0,1)
self.ax2.set_xlim(0,1)
def start(self):
self.xdata = []
self.pressure1 = []
self.displacement1 = []
self.cycle1 = []
self.pressure2 = []
self.displacement2 = []
self.cycle2 = []
self.pressure3 = []
self.displacement3 = []
self.cycle3 = []
self.pressure4 = []
self.displacement4 = []
self.cycle4 = []
self.k = 0
self.arduinoData.flushInput()
self.ani = animation.FuncAnimation(
self.fig,
self.update_graph,
interval=1,
repeat=True)
self.arduinoData.write("<L>")
self.running = True
self.ani._start()
def update_graph(self, i):
self.xdata.append(self.k)
while (self.arduinoData.inWaiting()==0):
pass
x = self.arduinoData.readline()
strip_data = x.strip()
split_data = x.split("|")
actuator1 = split_data[0].split(".")
actuator2 = split_data[1].split(".")
actuator3 = split_data[2].split(".")
actuator4 = split_data[3].split(".")
self.pressure1.append(int(actuator1[0]))
self.displacement1.append(int(actuator1[1]))
self.cycle1 = int(actuator1[2])
self.pressure2.append(int(actuator2[0]))
self.displacement2.append(int(actuator2[1]))
self.cycle2 = int(actuator2[2])
self.pressure3.append(int(actuator3[0]))
self.displacement3.append(int(actuator3[1]))
self.cycle3 = int(actuator3[2])
self.pressure4.append(int(actuator4[0]))
self.displacement4.append(int(actuator4[1]))
self.cycle4 = int(actuator4[2])
self.line0.set_data(self.xdata, self.pressure1)
self.line1.set_data(self.xdata, self.pressure2)
self.line2.set_data(self.xdata, self.pressure3)
self.line3.set_data(self.xdata, self.pressure4)
self.line4.set_data(self.xdata, self.displacement1)
self.line5.set_data(self.xdata, self.displacement2)
self.line6.set_data(self.xdata, self.displacement3)
self.line7.set_data(self.xdata, self.displacement4)
if self.k < 49:
self.ax1.set_ylim(min(self.pressure1)-1, max(self.pressure3) + 1)
self.ax1.set_xlim(0, self.k+1)
self.ax2.set_ylim(min(self.displacement1)-1, max(self.displacement3) + 1)
self.ax2.set_xlim(0, self.k+1)
elif self.k >= 49:
self.ax1.set_ylim(min(self.pressure1[self.k-49:self.k])-1, max(self.pressure3[self.k-49:self.k]) + 1)
self.ax1.set_xlim(self.xdata[self.k-49], self.xdata[self.k-1])
self.ax2.set_ylim(min(self.displacement1[self.k-49:self.k])-1, max(self.displacement3[self.k-49:self.k]) + 1)
self.ax2.set_xlim(self.xdata[self.k-49], self.xdata[self.k-1])
self.k += 1
root = Tkinter.Tk()
app = App(root)
root.mainloop()
这是可打印到监视器的gui:
import Tkinter
import serial
from matplotlib.backends.backend_tkagg import FigureCanvasTkAgg
from matplotlib.figure import Figure
from matplotlib import pyplot as plt
import matplotlib.animation as animation
import time
class App:
def __init__(self, master):
self.arduinoData = serial.Serial('com5', 250000, timeout=0)
frame = Tkinter.Frame(master)
self.go = 0
self.start = Tkinter.LabelFrame(frame, text="Start", borderwidth=10, relief=Tkinter.GROOVE, padx=10, pady=10)
self.start.grid(row=0, column=0, padx=20, pady=20)
self.run = Tkinter.Button(self.start, text="RUN", bd=10, height=5, width=10, command=self.getData)
self.run.grid(row=0, column=0, padx=5, pady=5)
self.stop_frame = Tkinter.LabelFrame(frame, text="STOP", borderwidth=10, relief=Tkinter.GROOVE, padx=10, pady=10 )
self.stop_frame.grid(row=0, column=1, padx=20, pady=20)
self.stop = Tkinter.Button(self.stop_frame, text="STOP", bd=10, height=5, width=10, command=self.stopTest)
self.stop.grid(row=0, column=0, padx=5, pady=5)
self.fig = plt.Figure()
self.ax1 = self.fig.add_subplot(211)
self.line0, = self.ax1.plot([], [], lw=2)
self.line1, = self.ax1.plot([], [], lw=2)
self.line2, = self.ax1.plot([], [], lw=2)
self.line3, = self.ax1.plot([], [], lw=2)
self.ax2 = self.fig.add_subplot(212)
self.line4, = self.ax2.plot([], [], lw=2)
self.line5, = self.ax2.plot([], [], lw=2)
self.line6, = self.ax2.plot([], [], lw=2)
self.line7, = self.ax2.plot([], [], lw=2)
self.canvas = FigureCanvasTkAgg(self.fig,master=master)
self.canvas.show()
self.canvas.get_tk_widget().grid(row=0, column=4, padx=20, pady=20)
frame.grid(row=0, column=0, padx=20, pady=20)
def getData(self):
self.k = 0
self.xdata = []
self.pressure1 = []
self.displacement1 = []
self.cycle1 = []
self.pressure2 = []
self.displacement2 = []
self.cycle2 = []
self.pressure3 = []
self.displacement3 = []
self.cycle3 = []
self.pressure4 = []
self.displacement4 = []
self.cycle4 = []
self.arduinoData.flushInput()
self.go = 1
self.readData()
def readData(self):
if self.go == 1:
self.xdata.append(self.k)
while (self.arduinoData.inWaiting()==0):
pass
x = self.arduinoData.readline()
strip_data = x.strip()
split_data = x.split("|")
actuator1 = split_data[0].split(".")
actuator2 = split_data[1].split(".")
actuator3 = split_data[2].split(".")
actuator4 = split_data[3].split(".")
self.pressure1.append(int(actuator1[0]))
self.displacement1.append(int(actuator1[1]))
self.cycle1 = int(actuator1[2])
self.pressure2.append(int(actuator2[0]))
self.displacement2.append(int(actuator2[1]))
self.cycle2 = int(actuator2[2])
self.pressure3.append(int(actuator3[0]))
self.displacement3.append(int(actuator3[1]))
self.cycle3 = int(actuator3[2])
self.pressure4.append(int(actuator4[0]))
self.displacement4.append(int(actuator4[1]))
self.cycle4 = int(actuator4[2])
self.printData()
root.after(0, self.readData)
def printData(self):
print str(self.pressure1[self.k-1]) + " " +
str(self.displacement1[self.k-1]) + " " + str(self.cycle1) + " " +
str(self.pressure2[self.k-1]) + " " + str(self.displacement2[self.k-
1]) + " " + str(self.cycle2) + " " + str(self.pressure3[self.k-1]) +
" " + str(self.displacement3[self.k-1]) + " " + str(self.cycle3) + "
" + str(self.pressure4[self.k-1]) + " " +
str(self.displacement4[self.k-1]) + " " + str(self.cycle4)
def stopTest(self):
self.arduinoData.write("<H>")
self.go = 0
def resetTest(self):
self.k = 0
self.xdata = []
self.pressure1 = []
self.displacement1 = []
self.cycle1 = []
self.pressure2 = []
self.displacement2 = []
self.cycle2 = []
self.pressure3 = []
self.displacement3 = []
self.cycle3 = []
self.pressure4 = []
self.displacement4 = []
self.cycle4 = []
self.line1.set_data(self.xdata, self.ydata1)
self.line2.set_data(self.xdata, self.ydata2)
self.ax1.set_ylim(0,1)
self.ax1.set_xlim(0,1)
self.ax2.set_ylim(0,1)
self.ax2.set_xlim(0,1)
def start(self):
self.xdata = []
self.pressure1 = []
self.displacement1 = []
self.cycle1 = []
self.pressure2 = []
self.displacement2 = []
self.cycle2 = []
self.pressure3 = []
self.displacement3 = []
self.cycle3 = []
self.pressure4 = []
self.displacement4 = []
self.cycle4 = []
self.k = 0
self.arduinoData.write("<L>")
root = Tkinter.Tk()
app = App(root)
root.mainloop()
这是一个示例arduino代码:
int analog0 = 0;
int analog1 = 1;
int analog2 = 2;
int sensor0;
int sensor1;
int sensor2;
String pot0;
String pot1;
String Force;
int pot0holder;
int pot1holder;
String Forceholder;
unsigned long i = 0;
String Is;
int val = 0;
boolean Sensordata = false;
int cycles;
const byte numChars = 32;
char receivedChars[numChars];
boolean newData = false;
unsigned long CurrentMillis = 0;
unsigned long PrintMillis = 0;
int PrintValMillis = 50;
unsigned long SensorMillis = 0;
int SensorValMillis = 0;
void setup() {
// put your setup code here, to run once:
Serial.begin(250000);
}
void loop()
{
CurrentMillis = millis();
recvWithStartEndMarkers();
commands();
sensordata();
}
void sensordata()
{
if (CurrentMillis - SensorMillis >= SensorValMillis)
{
sensor0 = analogRead(analog0);
pot0holder = sensor0;
sensor1 = analogRead(analog1);
pot1holder = sensor1;
i += 1;
String potcolumn = String(pot0holder) + "." + String(pot1holder) + "." + String(i) + "|" + String(int(pot0holder)+30) + "." + String(int(pot1holder)+30) + "." + String(i) + "|" + String(int(pot0holder)+60) + "." + String(int(pot1holder)+60) + "." + String(i) + "|" + String(int(pot0holder)+90) + "." + String(int(pot1holder)+90) + "." + String(i);
Serial.println(potcolumn);
SensorMillis += SensorValMillis;
}
}
void recvWithStartEndMarkers()
{
static boolean recvInProgress = false; //creates variable visible to only one function with boolean
static byte ndx = 0;
char startMarker = '<'; //sets begin condition
char endMarker = '>'; //sets end condition
char rc; //sets variable type to char
while (Serial.available() > 0 && newData == false) {
rc = Serial.read(); //sets rc equal to serial value
if (recvInProgress == true) {
if (rc != endMarker) {
receivedChars[ndx] = rc;
ndx++;
if (ndx >= numChars) {
ndx = numChars - 1;
}
}
else {
receivedChars[ndx] = '\0'; // terminate the string
recvInProgress = false;
ndx = 0;
newData = true;
}
}
else if (rc == startMarker) {
recvInProgress = true;
}
}
}
void commands()
{
if (newData == true)
{
if (receivedChars[0] == 'T')
{
PrintValMillis = atoi(&receivedChars[1]); //atoi -> Converting strings to integer
}
else if (receivedChars[0] == 'S')
{
cycles = atoi(&receivedChars[1]);
i = 0;
}
else if (receivedChars[0] == 'L')
{
val = atoi(&receivedChars[1]);
i = 0;
}
}
newData = false;
}
在此先感谢您提供的任何帮助或建议。
因此,您的阅读过程会花费大部分时间。 我会将读数放在一个单独的任务中,并在主(绘图)过程中对数据进行评估/拆分。 不幸的是,我不是tkinter的用户,所以我在编写时没有任何特殊的GUI框架。 但是我认为您可以根据自己的需要进行调整。
看起来像这样:
import numpy as np
import matplotlib.pyplot as plt
import matplotlib.animation as animation
import multiprocessing as mp
import time
# global variables
fig = plt.figure(1)
# first sub-plot
ax1 = fig.add_subplot(211)
line1, = ax1.plot([], [], lw=2)
ax1.grid()
xdata1, ydata1 = [], []
# second sub-plot
ax2 = fig.add_subplot(212)
line2, = ax2.plot([], [], lw=2)
ax2.grid()
xdata2, ydata2 = [], []
# the multiprocessing queue
q = mp.Queue()
# data generator in separate process
# here would be your arduino data reader
def dataGen(output):
for x in range(50):
output.put((x, np.sin(x)))
# update first subplot
def update1(data):
# update the data
t, y = data
xdata1.append(t)
ydata1.append(y)
xmin, xmax = ax1.get_xlim()
ymin, ymax = ax1.get_ylim()
if t >= xmax:
ax1.set_xlim(xmin, 2*xmax)
if y >= ymax:
ax1.set_ylim(ymin, 2*ymax)
if y <= ymin:
ax1.set_ylim(2*ymin, ymax)
line1.set_data(xdata1, ydata1)
return line1,
# update second subplot
def update2(data):
# update the data
t, y = data
xdata2.append(t)
ydata2.append(y)
xmin, xmax = ax2.get_xlim()
ymin, ymax = ax2.get_ylim()
if t >= xmax:
ax2.set_xlim(xmin, 2*xmax)
if y >= ymax:
ax2.set_ylim(ymin, 2*ymax)
if y <= ymin:
ax2.set_ylim(2*ymin, ymax)
line2.set_data(xdata2, ydata2)
return line2,
# called at each drawing frame
def run(data):
# get data from queue, which is filled in separate process, blocks until
# data is available
data = q.get(block=True, timeout=.5)
# put here your variable separation
data1 = (2*data[0], 3*data[1])
data2 = (data[0], data[1])
#provide the data to the plots
a = update1(data1)
b = update2(data2)
fig.canvas.draw()
return a+b
if __name__ == "__main__":
# count of reader processes
n_proc = 1
# setup workers
pool = [mp.Process(target=dataGen, args=(q,)) for x in range(n_proc)]
for p in pool:
p.daemon = True
p.start()
# wait a few sec for the process to become alive
time.sleep(3)
# start your drawing
ani = animation.FuncAnimation(fig, run, frames=60, blit=True, interval=10,
repeat=False)
plt.show()
print('done')
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