Related
I am writing a python application using tkinter that plots weather data on a map. I am currently testing out my button that is supposed to plot the data on the map I created using basemap. However, when I run my program, my button does nothing. I defined my function that plots the data and called the function in the command attribute of my button. Anyone know what the problem could be?
import tkinter as tk
from tkinter import ttk
import tkinter.font as tkFont
from matplotlib.backends.backend_tkagg import FigureCanvasTkAgg
from matplotlib.figure import Figure
from mpl_toolkits.basemap import Basemap
import matplotlib.pyplot as plt
import numpy as np
import requests
lon = [-76.5152, -76.7311, -76.3055, -76.7277, -75.4714, -75.1652, -77.0011, -75.6624, -78.3947, -77.8600, -78.7583, -79.9959, -80.0851]
lat = [40.3295, 40.1998, 40.0379, 39.9626, 40.6023, 39.9526, 41.2412, 41.4090, 40.5187, 40.7934, 41.1210, 40.4406, 42.1292]
def current_weather():
key = '4a7a419e4e16e2629a4cedc37cbf7e50'
url = 'https://api.openweathermap.org/data/2.5/weather'
global observation
observation = []
for i in range(0,len(lon)):
params = {'lat': lat[i], 'lon': lon[i], 'appid': key, 'units': 'imperial'}
response = requests.get(url, params = params)
weather = response.json()
observation.append(round(weather['main']['temp']))
current_weather()
root = tk.Tk()
#place map on canvas
fig = Figure(figsize=(5, 4), dpi=100)
ax = fig.add_subplot(111)
map = Basemap(llcrnrlon=-80.5, llcrnrlat=39.8, urcrnrlon=-74.7, urcrnrlat=42.3,resolution='i',
lat_0 = 40., lon_0 = -80, ax = ax)
map.drawmapboundary(fill_color='#A6CAE0')
map.drawcounties(zorder = 20)
map.drawstates()
map.fillcontinents(color='#e6b800',lake_color='#A6CAE0')
def plot_data():
for i in range(0, len(lon)):
x,y = map(lon[i], lat[i])
ax.text(x, y, observation[i], fontsize = 7)
#create widgets
canvas = FigureCanvasTkAgg(fig, master = root)
canvas.draw()
canvas.get_tk_widget().pack(side=tk.TOP, fill=tk.BOTH, expand=1)
radiovalue = tk.IntVar()
temperature = tk.Radiobutton(root, text = "Plot current temperatures", variable = radiovalue, value = 1)
dewpoint = tk.Radiobutton(root, text = "Plot current dewpoints", variable = radiovalue, value = 2)
wind = tk.Radiobutton(root, text = "Plot current winds", variable = radiovalue, value = 3)
button = tk.Button(root, text = "Plot", command = plot_data)
#organize widgets
temperature.place(relx = 0.025, rely = 0.8)
dewpoint.place(relx = 0.385, rely = 0.8)
wind.place(relx = 0.675, rely = 0.8)
button.place(relx = 0.35, rely = 0.1)
root.mainloop()
I would like to make an equivalent of the function FuncAnimation from matplotlib.animation, in which I could control the current plotted data using the scrollbar.
Say you have a data array which contains data points to be plotted at each time i. When using FuncAnimation, you first need to define a function ( here animate(i) ) which will be called for each time i = 1 to len(data[:,0]) :
def animate(i):
ax.plot(data[i,:])
anim = FuncAnimation(fig, animate, interval=100, frames=len(data[:,0]))
plt.draw()
plt.show()
but you cannot control the time i, like with a play/stop functionality. What I would like to do is to call the function animate(i), with i being the position of the scrollbar.
I found this example ( using the events from matplotlib:
https://matplotlib.org/3.2.1/users/event_handling.html )
but the mpl_connect doesn't have a "scrollbar_event".
import tkinter
from random import randint
import matplotlib as plt
import numpy as np
from matplotlib.backends.backend_tkagg import (
FigureCanvasTkAgg, NavigationToolbar2Tk)
# Implement the default Matplotlib key bindings.
from matplotlib.backend_bases import key_press_handler
from matplotlib.figure import Figure
root = tkinter.Tk()
root.wm_title("Embedding in Tk")
#create figure
fig = Figure(figsize=(5, 4), dpi=100)
ax = fig.add_axes([0,0,1,1])
ax.imshow(np.array([[0,10],[23,40]]))
#create canvas with figure
canvas = FigureCanvasTkAgg(fig, master=root) # A tk.DrawingArea.
canvas.get_tk_widget().pack(side=tkinter.TOP, fill=tkinter.BOTH, expand=1)
def on_key_press(event):
ax.clear()
ax.imshow(np.array([[randint(0,30),randint(0,30)],[randint(0,30),randint(0,30)]]))
canvas.draw_idle()
key_press_handler(event, canvas)
print("you pressed {}".format(event.key))
#connect canvas to event function
canvas.mpl_connect("key_press_event", on_key_press)
def _quit():
root.quit() # stops mainloop
root.destroy() # this is necessary on Windows to prevent
# Fatal Python Error: PyEval_RestoreThread: NULL tstate
button = tkinter.Button(master=root, text="Quit", command=_quit)
button.pack(side=tkinter.BOTTOM)
tkinter.mainloop()
Actually the scroll functionality is given by matplotlib widgets !!
The example below works fine :
import matplotlib
import tkinter as Tk
import matplotlib.pyplot as plt
from matplotlib.widgets import Slider
from matplotlib.backends.backend_tkagg import FigureCanvasTkAgg
from myPytHeader import *
matplotlib.use('TkAgg')
root = Tk.Tk()
root.wm_title("Embedding in TK")
fig = plt.Figure(figsize=(8, 6))
canvas = FigureCanvasTkAgg(fig, root)
canvas.get_tk_widget().pack(side=Tk.TOP, fill=Tk.BOTH, expand=1)
nDt = nbLines("grid.dat")
nDx = nbGridPoints("grid.dat")
grid = np.zeros( (nDt,nDx) ) ; loadData("grid.dat", grid)
valu = np.zeros( (nDt,nDx) ) ; loadData("valu.dat", valu)
ax=fig.add_subplot(111)
fig.subplots_adjust(bottom=0.25)
ax_time = fig.add_axes([0.12, 0.1, 0.78, 0.03])
s_time = Slider(ax_time, 'Time', 0, nDt, valinit=0, valstep=1)
def update(val):
frame = int(s_time.val)
ax.clear()
ax.set(xlim=(-0.05, 1.05), ylim=(-0.05, 1.25))
ax.grid()
ax.scatter(grid[frame,:], valu[frame,:], color='b', marker='.')
fig.canvas.draw_idle()
s_time.on_changed(update)
Tk.mainloop()
After all these years I've found solutions to my problems here, I am in debt !!!
Here is the final solution I came with.
I hope it can be useful to someone someday somehow !!
import matplotlib
import numpy as np
import tkinter as tk
import matplotlib.pyplot as plt
from matplotlib.animation import FuncAnimation
from matplotlib.widgets import Slider
from matplotlib.backends.backend_tkagg import FigureCanvasTkAgg
# load data
nDt = 1000
nDx = 400
grd = np.zeros( (nDt,nDx) )
val = np.zeros( (nDt,nDx) )
for t in np.arange(nDt):
for x in np.arange(nDx):
grd[t,x] = x / nDx
val[t,x] = (x / nDx) * (t/nDt) * np.sin(10 * 2*np.pi * (t-x)/nDt)
matplotlib.use('TkAgg')
root = tk.Tk()
root.wm_title("Embedding in TK")
fig = plt.Figure(figsize=(8, 6))
canvas = FigureCanvasTkAgg(fig, root)
canvas.get_tk_widget().pack(side=tk.TOP, fill=tk.BOTH, expand=1)
ax=fig.add_subplot(111)
fig.subplots_adjust(bottom=0.25)
ax.set(xlim=(-0.05, 1.05), ylim=(-1.05, 1.05))
ax.grid()
scat = ax.scatter(grd[0,:], val[0,:], color='b', marker='.')
ax_time = fig.add_axes([0.12, 0.1, 0.78, 0.03])
s_time = Slider(ax_time, 'Time', 0, nDt, valinit=0, valstep=1)
i_anim = 0
i_relative = 0
i_current = 0
def updateGraph(i):
y_i = val[i,:]
scat.set_offsets(np.c_[grd[i,:], y_i])
def updateFromAnim(i):
global i_anim
global i_current
global i_relative
i_anim = i
i_current = i + i_relative
s_time.set_val(i_current)
updateGraph(i_current)
def updateFromScroll(val):
global i_anim
global i_current
global i_relative
i_relative = int(s_time.val) - i_anim
i_current = int(s_time.val)
updateGraph(i_current)
def onClick():
global anim_running
if anim_running:
anim.event_source.stop()
anim_running = False
else:
anim.event_source.start()
anim_running = True
start_button = tk.Button(root, text="START/STOP", command=onClick)
start_button.pack()
anim_running = True
anim = FuncAnimation(fig, updateFromAnim, interval=100, frames=nDt)
s_time.on_changed(updateFromScroll)
tk.mainloop()
I'm currently working on a visualisation of different sorting algorithms and am now attempting to embed the animations in a tkinker gui for ease of use. The animations are done with matplotlib and use bar charts. I'm currently struggling to get the graphs to be animated. I had it working without the gui but currently I get a static graph in the gui. Please could I have some advice on how to rectify this. Full code so far can be found at https://github.com/MGedney1/Sorting_Algorithm_Visualisation
Area of interest code:
import random
import time
import matplotlib
import matplotlib.pyplot as plt
import matplotlib.animation as animation
matplotlib.use("TkAgg")
from matplotlib.backends.backend_tkagg import FigureCanvasTkAgg
from matplotlib.figure import Figure
import tkinter as tk
from tkinter import Frame,Label,Entry,Button
def bubble_sort(lst): #Bubble Sort
index = len(lst) - 1
while index >= 0:
test_index = index
while test_index >= 0:
if lst[index] < lst[test_index]:
temp = lst[index]
lst[index] = lst[test_index]
lst[test_index] = temp
test_index -= 1
yield lst
index -= 1
class Window(Frame):
def __init__(self, master = None):
Frame.__init__(self,master)
self.master = master
self.set_up_window()
def update_fig(self): #Update fig function
for self.rect, val in zip(self.rects,self.unordered): #Setting height of the rectangles
self.rect.set_height(val)
self.iteration[0] += 1
text.set_text("# of operations: {}".format(iteration[0]))
def set_up_window(self):
n,self.unordered = create_array()
title = 'Test'
generator = bubble_sort(self.unordered)
self.fig,self.ax = plt.subplots() #Creating axis and figure
self.bar_rects = self.ax.bar(range(len(self.unordered)), self.unordered, align="edge") #Creating the rectangular bars
self.ax.set_xlim(0, n) #Axis limits
self.ax.set_ylim(0, int(1.07 * n))
self.text = self.ax.text(0.02, 0.95, "", transform=self.ax.transAxes) #Number of operations counter
self.iteration = [0]
self.anim = animation.FuncAnimation(self.fig, func=self.update_fig, frames=generator, interval=1,repeat=False) #Creating the animatio
self.canvas = FigureCanvasTkAgg(self.fig, master=root)
self.canvas.get_tk_widget().grid(column=0,row=1)
if __name__ == '__main__':
root = tk.Tk()
root.geometry("700x400")
app = Window(root)
tk.mainloop()
I am trying to plot some data from a camera in real time using OpenCV. However, the real-time plotting (using matplotlib) doesn't seem to be working.
I've isolated the problem into this simple example:
fig = plt.figure()
plt.axis([0, 1000, 0, 1])
i = 0
x = list()
y = list()
while i < 1000:
temp_y = np.random.random()
x.append(i)
y.append(temp_y)
plt.scatter(i, temp_y)
i += 1
plt.show()
I would expect this example to plot 1000 points individually. What actually happens is that the window pops up with the first point showing (ok with that), then waits for the loop to finish before it populates the rest of the graph.
Any thoughts why I am not seeing points populated one at a time?
Here's the working version of the code in question (requires at least version Matplotlib 1.1.0 from 2011-11-14):
import numpy as np
import matplotlib.pyplot as plt
plt.axis([0, 10, 0, 1])
for i in range(10):
y = np.random.random()
plt.scatter(i, y)
plt.pause(0.05)
plt.show()
Note the call to plt.pause(0.05), which both draws the new data and runs the GUI's event loop (allowing for mouse interaction).
If you're interested in realtime plotting, I'd recommend looking into matplotlib's animation API. In particular, using blit to avoid redrawing the background on every frame can give you substantial speed gains (~10x):
#!/usr/bin/env python
import numpy as np
import time
import matplotlib
matplotlib.use('GTKAgg')
from matplotlib import pyplot as plt
def randomwalk(dims=(256, 256), n=20, sigma=5, alpha=0.95, seed=1):
""" A simple random walk with memory """
r, c = dims
gen = np.random.RandomState(seed)
pos = gen.rand(2, n) * ((r,), (c,))
old_delta = gen.randn(2, n) * sigma
while True:
delta = (1. - alpha) * gen.randn(2, n) * sigma + alpha * old_delta
pos += delta
for ii in xrange(n):
if not (0. <= pos[0, ii] < r):
pos[0, ii] = abs(pos[0, ii] % r)
if not (0. <= pos[1, ii] < c):
pos[1, ii] = abs(pos[1, ii] % c)
old_delta = delta
yield pos
def run(niter=1000, doblit=True):
"""
Display the simulation using matplotlib, optionally using blit for speed
"""
fig, ax = plt.subplots(1, 1)
ax.set_aspect('equal')
ax.set_xlim(0, 255)
ax.set_ylim(0, 255)
ax.hold(True)
rw = randomwalk()
x, y = rw.next()
plt.show(False)
plt.draw()
if doblit:
# cache the background
background = fig.canvas.copy_from_bbox(ax.bbox)
points = ax.plot(x, y, 'o')[0]
tic = time.time()
for ii in xrange(niter):
# update the xy data
x, y = rw.next()
points.set_data(x, y)
if doblit:
# restore background
fig.canvas.restore_region(background)
# redraw just the points
ax.draw_artist(points)
# fill in the axes rectangle
fig.canvas.blit(ax.bbox)
else:
# redraw everything
fig.canvas.draw()
plt.close(fig)
print "Blit = %s, average FPS: %.2f" % (
str(doblit), niter / (time.time() - tic))
if __name__ == '__main__':
run(doblit=False)
run(doblit=True)
Output:
Blit = False, average FPS: 54.37
Blit = True, average FPS: 438.27
I know I'm a bit late to answer this question. Nevertheless, I've made some code a while ago to plot live graphs, that I would like to share:
Code for PyQt4:
###################################################################
# #
# PLOT A LIVE GRAPH (PyQt4) #
# ----------------------------- #
# EMBED A MATPLOTLIB ANIMATION INSIDE YOUR #
# OWN GUI! #
# #
###################################################################
import sys
import os
from PyQt4 import QtGui
from PyQt4 import QtCore
import functools
import numpy as np
import random as rd
import matplotlib
matplotlib.use("Qt4Agg")
from matplotlib.figure import Figure
from matplotlib.animation import TimedAnimation
from matplotlib.lines import Line2D
from matplotlib.backends.backend_qt4agg import FigureCanvasQTAgg as FigureCanvas
import time
import threading
def setCustomSize(x, width, height):
sizePolicy = QtGui.QSizePolicy(QtGui.QSizePolicy.Fixed, QtGui.QSizePolicy.Fixed)
sizePolicy.setHorizontalStretch(0)
sizePolicy.setVerticalStretch(0)
sizePolicy.setHeightForWidth(x.sizePolicy().hasHeightForWidth())
x.setSizePolicy(sizePolicy)
x.setMinimumSize(QtCore.QSize(width, height))
x.setMaximumSize(QtCore.QSize(width, height))
''''''
class CustomMainWindow(QtGui.QMainWindow):
def __init__(self):
super(CustomMainWindow, self).__init__()
# Define the geometry of the main window
self.setGeometry(300, 300, 800, 400)
self.setWindowTitle("my first window")
# Create FRAME_A
self.FRAME_A = QtGui.QFrame(self)
self.FRAME_A.setStyleSheet("QWidget { background-color: %s }" % QtGui.QColor(210,210,235,255).name())
self.LAYOUT_A = QtGui.QGridLayout()
self.FRAME_A.setLayout(self.LAYOUT_A)
self.setCentralWidget(self.FRAME_A)
# Place the zoom button
self.zoomBtn = QtGui.QPushButton(text = 'zoom')
setCustomSize(self.zoomBtn, 100, 50)
self.zoomBtn.clicked.connect(self.zoomBtnAction)
self.LAYOUT_A.addWidget(self.zoomBtn, *(0,0))
# Place the matplotlib figure
self.myFig = CustomFigCanvas()
self.LAYOUT_A.addWidget(self.myFig, *(0,1))
# Add the callbackfunc to ..
myDataLoop = threading.Thread(name = 'myDataLoop', target = dataSendLoop, daemon = True, args = (self.addData_callbackFunc,))
myDataLoop.start()
self.show()
''''''
def zoomBtnAction(self):
print("zoom in")
self.myFig.zoomIn(5)
''''''
def addData_callbackFunc(self, value):
# print("Add data: " + str(value))
self.myFig.addData(value)
''' End Class '''
class CustomFigCanvas(FigureCanvas, TimedAnimation):
def __init__(self):
self.addedData = []
print(matplotlib.__version__)
# The data
self.xlim = 200
self.n = np.linspace(0, self.xlim - 1, self.xlim)
a = []
b = []
a.append(2.0)
a.append(4.0)
a.append(2.0)
b.append(4.0)
b.append(3.0)
b.append(4.0)
self.y = (self.n * 0.0) + 50
# The window
self.fig = Figure(figsize=(5,5), dpi=100)
self.ax1 = self.fig.add_subplot(111)
# self.ax1 settings
self.ax1.set_xlabel('time')
self.ax1.set_ylabel('raw data')
self.line1 = Line2D([], [], color='blue')
self.line1_tail = Line2D([], [], color='red', linewidth=2)
self.line1_head = Line2D([], [], color='red', marker='o', markeredgecolor='r')
self.ax1.add_line(self.line1)
self.ax1.add_line(self.line1_tail)
self.ax1.add_line(self.line1_head)
self.ax1.set_xlim(0, self.xlim - 1)
self.ax1.set_ylim(0, 100)
FigureCanvas.__init__(self, self.fig)
TimedAnimation.__init__(self, self.fig, interval = 50, blit = True)
def new_frame_seq(self):
return iter(range(self.n.size))
def _init_draw(self):
lines = [self.line1, self.line1_tail, self.line1_head]
for l in lines:
l.set_data([], [])
def addData(self, value):
self.addedData.append(value)
def zoomIn(self, value):
bottom = self.ax1.get_ylim()[0]
top = self.ax1.get_ylim()[1]
bottom += value
top -= value
self.ax1.set_ylim(bottom,top)
self.draw()
def _step(self, *args):
# Extends the _step() method for the TimedAnimation class.
try:
TimedAnimation._step(self, *args)
except Exception as e:
self.abc += 1
print(str(self.abc))
TimedAnimation._stop(self)
pass
def _draw_frame(self, framedata):
margin = 2
while(len(self.addedData) > 0):
self.y = np.roll(self.y, -1)
self.y[-1] = self.addedData[0]
del(self.addedData[0])
self.line1.set_data(self.n[ 0 : self.n.size - margin ], self.y[ 0 : self.n.size - margin ])
self.line1_tail.set_data(np.append(self.n[-10:-1 - margin], self.n[-1 - margin]), np.append(self.y[-10:-1 - margin], self.y[-1 - margin]))
self.line1_head.set_data(self.n[-1 - margin], self.y[-1 - margin])
self._drawn_artists = [self.line1, self.line1_tail, self.line1_head]
''' End Class '''
# You need to setup a signal slot mechanism, to
# send data to your GUI in a thread-safe way.
# Believe me, if you don't do this right, things
# go very very wrong..
class Communicate(QtCore.QObject):
data_signal = QtCore.pyqtSignal(float)
''' End Class '''
def dataSendLoop(addData_callbackFunc):
# Setup the signal-slot mechanism.
mySrc = Communicate()
mySrc.data_signal.connect(addData_callbackFunc)
# Simulate some data
n = np.linspace(0, 499, 500)
y = 50 + 25*(np.sin(n / 8.3)) + 10*(np.sin(n / 7.5)) - 5*(np.sin(n / 1.5))
i = 0
while(True):
if(i > 499):
i = 0
time.sleep(0.1)
mySrc.data_signal.emit(y[i]) # <- Here you emit a signal!
i += 1
###
###
if __name__== '__main__':
app = QtGui.QApplication(sys.argv)
QtGui.QApplication.setStyle(QtGui.QStyleFactory.create('Plastique'))
myGUI = CustomMainWindow()
sys.exit(app.exec_())
''''''
I recently rewrote the code for PyQt5.
Code for PyQt5:
###################################################################
# #
# PLOT A LIVE GRAPH (PyQt5) #
# ----------------------------- #
# EMBED A MATPLOTLIB ANIMATION INSIDE YOUR #
# OWN GUI! #
# #
###################################################################
import sys
import os
from PyQt5.QtWidgets import *
from PyQt5.QtCore import *
from PyQt5.QtGui import *
import functools
import numpy as np
import random as rd
import matplotlib
matplotlib.use("Qt5Agg")
from matplotlib.figure import Figure
from matplotlib.animation import TimedAnimation
from matplotlib.lines import Line2D
from matplotlib.backends.backend_qt5agg import FigureCanvasQTAgg as FigureCanvas
import time
import threading
class CustomMainWindow(QMainWindow):
def __init__(self):
super(CustomMainWindow, self).__init__()
# Define the geometry of the main window
self.setGeometry(300, 300, 800, 400)
self.setWindowTitle("my first window")
# Create FRAME_A
self.FRAME_A = QFrame(self)
self.FRAME_A.setStyleSheet("QWidget { background-color: %s }" % QColor(210,210,235,255).name())
self.LAYOUT_A = QGridLayout()
self.FRAME_A.setLayout(self.LAYOUT_A)
self.setCentralWidget(self.FRAME_A)
# Place the zoom button
self.zoomBtn = QPushButton(text = 'zoom')
self.zoomBtn.setFixedSize(100, 50)
self.zoomBtn.clicked.connect(self.zoomBtnAction)
self.LAYOUT_A.addWidget(self.zoomBtn, *(0,0))
# Place the matplotlib figure
self.myFig = CustomFigCanvas()
self.LAYOUT_A.addWidget(self.myFig, *(0,1))
# Add the callbackfunc to ..
myDataLoop = threading.Thread(name = 'myDataLoop', target = dataSendLoop, daemon = True, args = (self.addData_callbackFunc,))
myDataLoop.start()
self.show()
return
def zoomBtnAction(self):
print("zoom in")
self.myFig.zoomIn(5)
return
def addData_callbackFunc(self, value):
# print("Add data: " + str(value))
self.myFig.addData(value)
return
''' End Class '''
class CustomFigCanvas(FigureCanvas, TimedAnimation):
def __init__(self):
self.addedData = []
print(matplotlib.__version__)
# The data
self.xlim = 200
self.n = np.linspace(0, self.xlim - 1, self.xlim)
a = []
b = []
a.append(2.0)
a.append(4.0)
a.append(2.0)
b.append(4.0)
b.append(3.0)
b.append(4.0)
self.y = (self.n * 0.0) + 50
# The window
self.fig = Figure(figsize=(5,5), dpi=100)
self.ax1 = self.fig.add_subplot(111)
# self.ax1 settings
self.ax1.set_xlabel('time')
self.ax1.set_ylabel('raw data')
self.line1 = Line2D([], [], color='blue')
self.line1_tail = Line2D([], [], color='red', linewidth=2)
self.line1_head = Line2D([], [], color='red', marker='o', markeredgecolor='r')
self.ax1.add_line(self.line1)
self.ax1.add_line(self.line1_tail)
self.ax1.add_line(self.line1_head)
self.ax1.set_xlim(0, self.xlim - 1)
self.ax1.set_ylim(0, 100)
FigureCanvas.__init__(self, self.fig)
TimedAnimation.__init__(self, self.fig, interval = 50, blit = True)
return
def new_frame_seq(self):
return iter(range(self.n.size))
def _init_draw(self):
lines = [self.line1, self.line1_tail, self.line1_head]
for l in lines:
l.set_data([], [])
return
def addData(self, value):
self.addedData.append(value)
return
def zoomIn(self, value):
bottom = self.ax1.get_ylim()[0]
top = self.ax1.get_ylim()[1]
bottom += value
top -= value
self.ax1.set_ylim(bottom,top)
self.draw()
return
def _step(self, *args):
# Extends the _step() method for the TimedAnimation class.
try:
TimedAnimation._step(self, *args)
except Exception as e:
self.abc += 1
print(str(self.abc))
TimedAnimation._stop(self)
pass
return
def _draw_frame(self, framedata):
margin = 2
while(len(self.addedData) > 0):
self.y = np.roll(self.y, -1)
self.y[-1] = self.addedData[0]
del(self.addedData[0])
self.line1.set_data(self.n[ 0 : self.n.size - margin ], self.y[ 0 : self.n.size - margin ])
self.line1_tail.set_data(np.append(self.n[-10:-1 - margin], self.n[-1 - margin]), np.append(self.y[-10:-1 - margin], self.y[-1 - margin]))
self.line1_head.set_data(self.n[-1 - margin], self.y[-1 - margin])
self._drawn_artists = [self.line1, self.line1_tail, self.line1_head]
return
''' End Class '''
# You need to setup a signal slot mechanism, to
# send data to your GUI in a thread-safe way.
# Believe me, if you don't do this right, things
# go very very wrong..
class Communicate(QObject):
data_signal = pyqtSignal(float)
''' End Class '''
def dataSendLoop(addData_callbackFunc):
# Setup the signal-slot mechanism.
mySrc = Communicate()
mySrc.data_signal.connect(addData_callbackFunc)
# Simulate some data
n = np.linspace(0, 499, 500)
y = 50 + 25*(np.sin(n / 8.3)) + 10*(np.sin(n / 7.5)) - 5*(np.sin(n / 1.5))
i = 0
while(True):
if(i > 499):
i = 0
time.sleep(0.1)
mySrc.data_signal.emit(y[i]) # <- Here you emit a signal!
i += 1
###
###
if __name__== '__main__':
app = QApplication(sys.argv)
QApplication.setStyle(QStyleFactory.create('Plastique'))
myGUI = CustomMainWindow()
sys.exit(app.exec_())
Just try it out. Copy-paste this code in a new python-file, and run it. You should get a beautiful, smoothly moving graph:
The top (and many other) answers were built upon plt.pause(), but that was an old way of animating the plot in matplotlib. It is not only slow, but also causes focus to be grabbed upon each update (I had a hard time stopping the plotting python process).
TL;DR: you may want to use matplotlib.animation (as mentioned in documentation).
After digging around various answers and pieces of code, this in fact proved to be a smooth way of drawing incoming data infinitely for me.
Here is my code for a quick start. It plots current time with a random number in [0, 100) every 200ms infinitely, while also handling auto rescaling of the view:
from datetime import datetime
from matplotlib import pyplot
from matplotlib.animation import FuncAnimation
from random import randrange
x_data, y_data = [], []
figure = pyplot.figure()
line, = pyplot.plot_date(x_data, y_data, '-')
def update(frame):
x_data.append(datetime.now())
y_data.append(randrange(0, 100))
line.set_data(x_data, y_data)
figure.gca().relim()
figure.gca().autoscale_view()
return line,
animation = FuncAnimation(figure, update, interval=200)
pyplot.show()
You can also explore blit for even better performance as in FuncAnimation documentation.
An example from the blit documentation:
import numpy as np
import matplotlib.pyplot as plt
from matplotlib.animation import FuncAnimation
fig, ax = plt.subplots()
xdata, ydata = [], []
ln, = plt.plot([], [], 'ro')
def init():
ax.set_xlim(0, 2*np.pi)
ax.set_ylim(-1, 1)
return ln,
def update(frame):
xdata.append(frame)
ydata.append(np.sin(frame))
ln.set_data(xdata, ydata)
return ln,
ani = FuncAnimation(fig, update, frames=np.linspace(0, 2*np.pi, 128),
init_func=init, blit=True)
plt.show()
None of the methods worked for me.
But I have found this
Real time matplotlib plot is not working while still in a loop
All you need is to add
plt.pause(0.0001)
and then you could see the new plots.
So your code should look like this, and it will work
import matplotlib.pyplot as plt
import numpy as np
plt.ion() ## Note this correction
fig=plt.figure()
plt.axis([0,1000,0,1])
i=0
x=list()
y=list()
while i <1000:
temp_y=np.random.random();
x.append(i);
y.append(temp_y);
plt.scatter(i,temp_y);
i+=1;
plt.show()
plt.pause(0.0001) #Note this correction
show is probably not the best choice for this. What I would do is use pyplot.draw() instead. You also might want to include a small time delay (e.g., time.sleep(0.05)) in the loop so that you can see the plots happening. If I make these changes to your example it works for me and I see each point appearing one at a time.
I know this question is old, but there's now a package available called drawnow on GitHub as "python-drawnow". This provides an interface similar to MATLAB's drawnow -- you can easily update a figure.
An example for your use case:
import matplotlib.pyplot as plt
from drawnow import drawnow
def make_fig():
plt.scatter(x, y) # I think you meant this
plt.ion() # enable interactivity
fig = plt.figure() # make a figure
x = list()
y = list()
for i in range(1000):
temp_y = np.random.random()
x.append(i)
y.append(temp_y) # or any arbitrary update to your figure's data
i += 1
drawnow(make_fig)
python-drawnow is a thin wrapper around plt.draw but provides the ability to confirm (or debug) after figure display.
Another option is to go with bokeh. IMO, it is a good alternative at least for real-time plots. Here is a bokeh version of the code in the question:
from bokeh.plotting import curdoc, figure
import random
import time
def update():
global i
temp_y = random.random()
r.data_source.stream({'x': [i], 'y': [temp_y]})
i += 1
i = 0
p = figure()
r = p.circle([], [])
curdoc().add_root(p)
curdoc().add_periodic_callback(update, 100)
and for running it:
pip3 install bokeh
bokeh serve --show test.py
bokeh shows the result in a web browser via websocket communications. It is especially useful when data is generated by remote headless server processes.
An example use-case to plot CPU usage in real-time.
import time
import psutil
import matplotlib.pyplot as plt
fig = plt.figure()
ax = fig.add_subplot(111)
i = 0
x, y = [], []
while True:
x.append(i)
y.append(psutil.cpu_percent())
ax.plot(x, y, color='b')
fig.canvas.draw()
ax.set_xlim(left=max(0, i - 50), right=i + 50)
fig.show()
plt.pause(0.05)
i += 1
The problem seems to be that you expect plt.show() to show the window and then to return. It does not do that. The program will stop at that point and only resume once you close the window. You should be able to test that: If you close the window and then another window should pop up.
To resolve that problem just call plt.show() once after your loop. Then you get the complete plot. (But not a 'real-time plotting')
You can try setting the keyword-argument block like this: plt.show(block=False) once at the beginning and then use .draw() to update.
Here is a version that I got to work on my system.
import matplotlib.pyplot as plt
from drawnow import drawnow
import numpy as np
def makeFig():
plt.scatter(xList,yList) # I think you meant this
plt.ion() # enable interactivity
fig=plt.figure() # make a figure
xList=list()
yList=list()
for i in np.arange(50):
y=np.random.random()
xList.append(i)
yList.append(y)
drawnow(makeFig)
#makeFig() The drawnow(makeFig) command can be replaced
#plt.draw() with makeFig(); plt.draw()
plt.pause(0.001)
The drawnow(makeFig) line can be replaced with a makeFig(); plt.draw() sequence and it still works OK.
If you want draw and not freeze your thread as more point are drawn you should use plt.pause() not time.sleep()
im using the following code to plot a series of xy coordinates.
import matplotlib.pyplot as plt
import math
pi = 3.14159
fig, ax = plt.subplots()
x = []
y = []
def PointsInCircum(r,n=20):
circle = [(math.cos(2*pi/n*x)*r,math.sin(2*pi/n*x)*r) for x in xrange(0,n+1)]
return circle
circle_list = PointsInCircum(3, 50)
for t in range(len(circle_list)):
if t == 0:
points, = ax.plot(x, y, marker='o', linestyle='--')
ax.set_xlim(-4, 4)
ax.set_ylim(-4, 4)
else:
x_coord, y_coord = circle_list.pop()
x.append(x_coord)
y.append(y_coord)
points.set_data(x, y)
plt.pause(0.01)
This is the right way to plot Dynamic real-time matplot plots animation using while loop
There is a medium article on that too:
pip install celluloid # this will capture the image/animation
import matplotlib.pyplot as plt
import numpy as np
from celluloid import Camera # getting the camera
import matplotlib.animation as animation
from IPython import display
import time
from IPython.display import HTML
import warnings
%matplotlib notebook
warnings.filterwarnings('ignore')
warnings.simplefilter('ignore')
fig = plt.figure() #Empty fig object
ax = fig.add_subplot() #Empty axis object
camera = Camera(fig) # Camera object to capture the snap
def f(x):
''' function to create a sine wave'''
return np.sin(x) + np.random.normal(scale=0.1, size=len(x))
l = []
while True:
value = np.random.randint(9) #random number generator
l.append(value) # appneds each time number is generated
X = np.linspace(10, len(l)) # creates a line space for x axis, Equal to the length of l
for i in range(10): #plots 10 such lines
plt.plot(X, f(X))
fig.show() #shows the figure object
fig.canvas.draw()
camera.snap() # camera object to capture teh animation
time.sleep(1)
And for saving etc:
animation = camera.animate(interval = 200, repeat = True, repeat_delay = 500)
HTML(animation.to_html5_video())
animation.save('abc.mp4') # to save
output is:
Live plot with circular buffer with line style retained:
import os
import time
import psutil
import collections
import matplotlib.pyplot as plt
pts_n = 100
x = collections.deque(maxlen=pts_n)
y = collections.deque(maxlen=pts_n)
(line, ) = plt.plot(x, y, linestyle="--")
my_process = psutil.Process(os.getpid())
t_start = time.time()
while True:
x.append(time.time() - t_start)
y.append(my_process.cpu_percent())
line.set_xdata(x)
line.set_ydata(y)
plt.gca().relim()
plt.gca().autoscale_view()
plt.pause(0.1)
I am trying to plot some data from a camera in real time using OpenCV. However, the real-time plotting (using matplotlib) doesn't seem to be working.
I've isolated the problem into this simple example:
fig = plt.figure()
plt.axis([0, 1000, 0, 1])
i = 0
x = list()
y = list()
while i < 1000:
temp_y = np.random.random()
x.append(i)
y.append(temp_y)
plt.scatter(i, temp_y)
i += 1
plt.show()
I would expect this example to plot 1000 points individually. What actually happens is that the window pops up with the first point showing (ok with that), then waits for the loop to finish before it populates the rest of the graph.
Any thoughts why I am not seeing points populated one at a time?
Here's the working version of the code in question (requires at least version Matplotlib 1.1.0 from 2011-11-14):
import numpy as np
import matplotlib.pyplot as plt
plt.axis([0, 10, 0, 1])
for i in range(10):
y = np.random.random()
plt.scatter(i, y)
plt.pause(0.05)
plt.show()
Note the call to plt.pause(0.05), which both draws the new data and runs the GUI's event loop (allowing for mouse interaction).
If you're interested in realtime plotting, I'd recommend looking into matplotlib's animation API. In particular, using blit to avoid redrawing the background on every frame can give you substantial speed gains (~10x):
#!/usr/bin/env python
import numpy as np
import time
import matplotlib
matplotlib.use('GTKAgg')
from matplotlib import pyplot as plt
def randomwalk(dims=(256, 256), n=20, sigma=5, alpha=0.95, seed=1):
""" A simple random walk with memory """
r, c = dims
gen = np.random.RandomState(seed)
pos = gen.rand(2, n) * ((r,), (c,))
old_delta = gen.randn(2, n) * sigma
while True:
delta = (1. - alpha) * gen.randn(2, n) * sigma + alpha * old_delta
pos += delta
for ii in xrange(n):
if not (0. <= pos[0, ii] < r):
pos[0, ii] = abs(pos[0, ii] % r)
if not (0. <= pos[1, ii] < c):
pos[1, ii] = abs(pos[1, ii] % c)
old_delta = delta
yield pos
def run(niter=1000, doblit=True):
"""
Display the simulation using matplotlib, optionally using blit for speed
"""
fig, ax = plt.subplots(1, 1)
ax.set_aspect('equal')
ax.set_xlim(0, 255)
ax.set_ylim(0, 255)
ax.hold(True)
rw = randomwalk()
x, y = rw.next()
plt.show(False)
plt.draw()
if doblit:
# cache the background
background = fig.canvas.copy_from_bbox(ax.bbox)
points = ax.plot(x, y, 'o')[0]
tic = time.time()
for ii in xrange(niter):
# update the xy data
x, y = rw.next()
points.set_data(x, y)
if doblit:
# restore background
fig.canvas.restore_region(background)
# redraw just the points
ax.draw_artist(points)
# fill in the axes rectangle
fig.canvas.blit(ax.bbox)
else:
# redraw everything
fig.canvas.draw()
plt.close(fig)
print "Blit = %s, average FPS: %.2f" % (
str(doblit), niter / (time.time() - tic))
if __name__ == '__main__':
run(doblit=False)
run(doblit=True)
Output:
Blit = False, average FPS: 54.37
Blit = True, average FPS: 438.27
I know I'm a bit late to answer this question. Nevertheless, I've made some code a while ago to plot live graphs, that I would like to share:
Code for PyQt4:
###################################################################
# #
# PLOT A LIVE GRAPH (PyQt4) #
# ----------------------------- #
# EMBED A MATPLOTLIB ANIMATION INSIDE YOUR #
# OWN GUI! #
# #
###################################################################
import sys
import os
from PyQt4 import QtGui
from PyQt4 import QtCore
import functools
import numpy as np
import random as rd
import matplotlib
matplotlib.use("Qt4Agg")
from matplotlib.figure import Figure
from matplotlib.animation import TimedAnimation
from matplotlib.lines import Line2D
from matplotlib.backends.backend_qt4agg import FigureCanvasQTAgg as FigureCanvas
import time
import threading
def setCustomSize(x, width, height):
sizePolicy = QtGui.QSizePolicy(QtGui.QSizePolicy.Fixed, QtGui.QSizePolicy.Fixed)
sizePolicy.setHorizontalStretch(0)
sizePolicy.setVerticalStretch(0)
sizePolicy.setHeightForWidth(x.sizePolicy().hasHeightForWidth())
x.setSizePolicy(sizePolicy)
x.setMinimumSize(QtCore.QSize(width, height))
x.setMaximumSize(QtCore.QSize(width, height))
''''''
class CustomMainWindow(QtGui.QMainWindow):
def __init__(self):
super(CustomMainWindow, self).__init__()
# Define the geometry of the main window
self.setGeometry(300, 300, 800, 400)
self.setWindowTitle("my first window")
# Create FRAME_A
self.FRAME_A = QtGui.QFrame(self)
self.FRAME_A.setStyleSheet("QWidget { background-color: %s }" % QtGui.QColor(210,210,235,255).name())
self.LAYOUT_A = QtGui.QGridLayout()
self.FRAME_A.setLayout(self.LAYOUT_A)
self.setCentralWidget(self.FRAME_A)
# Place the zoom button
self.zoomBtn = QtGui.QPushButton(text = 'zoom')
setCustomSize(self.zoomBtn, 100, 50)
self.zoomBtn.clicked.connect(self.zoomBtnAction)
self.LAYOUT_A.addWidget(self.zoomBtn, *(0,0))
# Place the matplotlib figure
self.myFig = CustomFigCanvas()
self.LAYOUT_A.addWidget(self.myFig, *(0,1))
# Add the callbackfunc to ..
myDataLoop = threading.Thread(name = 'myDataLoop', target = dataSendLoop, daemon = True, args = (self.addData_callbackFunc,))
myDataLoop.start()
self.show()
''''''
def zoomBtnAction(self):
print("zoom in")
self.myFig.zoomIn(5)
''''''
def addData_callbackFunc(self, value):
# print("Add data: " + str(value))
self.myFig.addData(value)
''' End Class '''
class CustomFigCanvas(FigureCanvas, TimedAnimation):
def __init__(self):
self.addedData = []
print(matplotlib.__version__)
# The data
self.xlim = 200
self.n = np.linspace(0, self.xlim - 1, self.xlim)
a = []
b = []
a.append(2.0)
a.append(4.0)
a.append(2.0)
b.append(4.0)
b.append(3.0)
b.append(4.0)
self.y = (self.n * 0.0) + 50
# The window
self.fig = Figure(figsize=(5,5), dpi=100)
self.ax1 = self.fig.add_subplot(111)
# self.ax1 settings
self.ax1.set_xlabel('time')
self.ax1.set_ylabel('raw data')
self.line1 = Line2D([], [], color='blue')
self.line1_tail = Line2D([], [], color='red', linewidth=2)
self.line1_head = Line2D([], [], color='red', marker='o', markeredgecolor='r')
self.ax1.add_line(self.line1)
self.ax1.add_line(self.line1_tail)
self.ax1.add_line(self.line1_head)
self.ax1.set_xlim(0, self.xlim - 1)
self.ax1.set_ylim(0, 100)
FigureCanvas.__init__(self, self.fig)
TimedAnimation.__init__(self, self.fig, interval = 50, blit = True)
def new_frame_seq(self):
return iter(range(self.n.size))
def _init_draw(self):
lines = [self.line1, self.line1_tail, self.line1_head]
for l in lines:
l.set_data([], [])
def addData(self, value):
self.addedData.append(value)
def zoomIn(self, value):
bottom = self.ax1.get_ylim()[0]
top = self.ax1.get_ylim()[1]
bottom += value
top -= value
self.ax1.set_ylim(bottom,top)
self.draw()
def _step(self, *args):
# Extends the _step() method for the TimedAnimation class.
try:
TimedAnimation._step(self, *args)
except Exception as e:
self.abc += 1
print(str(self.abc))
TimedAnimation._stop(self)
pass
def _draw_frame(self, framedata):
margin = 2
while(len(self.addedData) > 0):
self.y = np.roll(self.y, -1)
self.y[-1] = self.addedData[0]
del(self.addedData[0])
self.line1.set_data(self.n[ 0 : self.n.size - margin ], self.y[ 0 : self.n.size - margin ])
self.line1_tail.set_data(np.append(self.n[-10:-1 - margin], self.n[-1 - margin]), np.append(self.y[-10:-1 - margin], self.y[-1 - margin]))
self.line1_head.set_data(self.n[-1 - margin], self.y[-1 - margin])
self._drawn_artists = [self.line1, self.line1_tail, self.line1_head]
''' End Class '''
# You need to setup a signal slot mechanism, to
# send data to your GUI in a thread-safe way.
# Believe me, if you don't do this right, things
# go very very wrong..
class Communicate(QtCore.QObject):
data_signal = QtCore.pyqtSignal(float)
''' End Class '''
def dataSendLoop(addData_callbackFunc):
# Setup the signal-slot mechanism.
mySrc = Communicate()
mySrc.data_signal.connect(addData_callbackFunc)
# Simulate some data
n = np.linspace(0, 499, 500)
y = 50 + 25*(np.sin(n / 8.3)) + 10*(np.sin(n / 7.5)) - 5*(np.sin(n / 1.5))
i = 0
while(True):
if(i > 499):
i = 0
time.sleep(0.1)
mySrc.data_signal.emit(y[i]) # <- Here you emit a signal!
i += 1
###
###
if __name__== '__main__':
app = QtGui.QApplication(sys.argv)
QtGui.QApplication.setStyle(QtGui.QStyleFactory.create('Plastique'))
myGUI = CustomMainWindow()
sys.exit(app.exec_())
''''''
I recently rewrote the code for PyQt5.
Code for PyQt5:
###################################################################
# #
# PLOT A LIVE GRAPH (PyQt5) #
# ----------------------------- #
# EMBED A MATPLOTLIB ANIMATION INSIDE YOUR #
# OWN GUI! #
# #
###################################################################
import sys
import os
from PyQt5.QtWidgets import *
from PyQt5.QtCore import *
from PyQt5.QtGui import *
import functools
import numpy as np
import random as rd
import matplotlib
matplotlib.use("Qt5Agg")
from matplotlib.figure import Figure
from matplotlib.animation import TimedAnimation
from matplotlib.lines import Line2D
from matplotlib.backends.backend_qt5agg import FigureCanvasQTAgg as FigureCanvas
import time
import threading
class CustomMainWindow(QMainWindow):
def __init__(self):
super(CustomMainWindow, self).__init__()
# Define the geometry of the main window
self.setGeometry(300, 300, 800, 400)
self.setWindowTitle("my first window")
# Create FRAME_A
self.FRAME_A = QFrame(self)
self.FRAME_A.setStyleSheet("QWidget { background-color: %s }" % QColor(210,210,235,255).name())
self.LAYOUT_A = QGridLayout()
self.FRAME_A.setLayout(self.LAYOUT_A)
self.setCentralWidget(self.FRAME_A)
# Place the zoom button
self.zoomBtn = QPushButton(text = 'zoom')
self.zoomBtn.setFixedSize(100, 50)
self.zoomBtn.clicked.connect(self.zoomBtnAction)
self.LAYOUT_A.addWidget(self.zoomBtn, *(0,0))
# Place the matplotlib figure
self.myFig = CustomFigCanvas()
self.LAYOUT_A.addWidget(self.myFig, *(0,1))
# Add the callbackfunc to ..
myDataLoop = threading.Thread(name = 'myDataLoop', target = dataSendLoop, daemon = True, args = (self.addData_callbackFunc,))
myDataLoop.start()
self.show()
return
def zoomBtnAction(self):
print("zoom in")
self.myFig.zoomIn(5)
return
def addData_callbackFunc(self, value):
# print("Add data: " + str(value))
self.myFig.addData(value)
return
''' End Class '''
class CustomFigCanvas(FigureCanvas, TimedAnimation):
def __init__(self):
self.addedData = []
print(matplotlib.__version__)
# The data
self.xlim = 200
self.n = np.linspace(0, self.xlim - 1, self.xlim)
a = []
b = []
a.append(2.0)
a.append(4.0)
a.append(2.0)
b.append(4.0)
b.append(3.0)
b.append(4.0)
self.y = (self.n * 0.0) + 50
# The window
self.fig = Figure(figsize=(5,5), dpi=100)
self.ax1 = self.fig.add_subplot(111)
# self.ax1 settings
self.ax1.set_xlabel('time')
self.ax1.set_ylabel('raw data')
self.line1 = Line2D([], [], color='blue')
self.line1_tail = Line2D([], [], color='red', linewidth=2)
self.line1_head = Line2D([], [], color='red', marker='o', markeredgecolor='r')
self.ax1.add_line(self.line1)
self.ax1.add_line(self.line1_tail)
self.ax1.add_line(self.line1_head)
self.ax1.set_xlim(0, self.xlim - 1)
self.ax1.set_ylim(0, 100)
FigureCanvas.__init__(self, self.fig)
TimedAnimation.__init__(self, self.fig, interval = 50, blit = True)
return
def new_frame_seq(self):
return iter(range(self.n.size))
def _init_draw(self):
lines = [self.line1, self.line1_tail, self.line1_head]
for l in lines:
l.set_data([], [])
return
def addData(self, value):
self.addedData.append(value)
return
def zoomIn(self, value):
bottom = self.ax1.get_ylim()[0]
top = self.ax1.get_ylim()[1]
bottom += value
top -= value
self.ax1.set_ylim(bottom,top)
self.draw()
return
def _step(self, *args):
# Extends the _step() method for the TimedAnimation class.
try:
TimedAnimation._step(self, *args)
except Exception as e:
self.abc += 1
print(str(self.abc))
TimedAnimation._stop(self)
pass
return
def _draw_frame(self, framedata):
margin = 2
while(len(self.addedData) > 0):
self.y = np.roll(self.y, -1)
self.y[-1] = self.addedData[0]
del(self.addedData[0])
self.line1.set_data(self.n[ 0 : self.n.size - margin ], self.y[ 0 : self.n.size - margin ])
self.line1_tail.set_data(np.append(self.n[-10:-1 - margin], self.n[-1 - margin]), np.append(self.y[-10:-1 - margin], self.y[-1 - margin]))
self.line1_head.set_data(self.n[-1 - margin], self.y[-1 - margin])
self._drawn_artists = [self.line1, self.line1_tail, self.line1_head]
return
''' End Class '''
# You need to setup a signal slot mechanism, to
# send data to your GUI in a thread-safe way.
# Believe me, if you don't do this right, things
# go very very wrong..
class Communicate(QObject):
data_signal = pyqtSignal(float)
''' End Class '''
def dataSendLoop(addData_callbackFunc):
# Setup the signal-slot mechanism.
mySrc = Communicate()
mySrc.data_signal.connect(addData_callbackFunc)
# Simulate some data
n = np.linspace(0, 499, 500)
y = 50 + 25*(np.sin(n / 8.3)) + 10*(np.sin(n / 7.5)) - 5*(np.sin(n / 1.5))
i = 0
while(True):
if(i > 499):
i = 0
time.sleep(0.1)
mySrc.data_signal.emit(y[i]) # <- Here you emit a signal!
i += 1
###
###
if __name__== '__main__':
app = QApplication(sys.argv)
QApplication.setStyle(QStyleFactory.create('Plastique'))
myGUI = CustomMainWindow()
sys.exit(app.exec_())
Just try it out. Copy-paste this code in a new python-file, and run it. You should get a beautiful, smoothly moving graph:
The top (and many other) answers were built upon plt.pause(), but that was an old way of animating the plot in matplotlib. It is not only slow, but also causes focus to be grabbed upon each update (I had a hard time stopping the plotting python process).
TL;DR: you may want to use matplotlib.animation (as mentioned in documentation).
After digging around various answers and pieces of code, this in fact proved to be a smooth way of drawing incoming data infinitely for me.
Here is my code for a quick start. It plots current time with a random number in [0, 100) every 200ms infinitely, while also handling auto rescaling of the view:
from datetime import datetime
from matplotlib import pyplot
from matplotlib.animation import FuncAnimation
from random import randrange
x_data, y_data = [], []
figure = pyplot.figure()
line, = pyplot.plot_date(x_data, y_data, '-')
def update(frame):
x_data.append(datetime.now())
y_data.append(randrange(0, 100))
line.set_data(x_data, y_data)
figure.gca().relim()
figure.gca().autoscale_view()
return line,
animation = FuncAnimation(figure, update, interval=200)
pyplot.show()
You can also explore blit for even better performance as in FuncAnimation documentation.
An example from the blit documentation:
import numpy as np
import matplotlib.pyplot as plt
from matplotlib.animation import FuncAnimation
fig, ax = plt.subplots()
xdata, ydata = [], []
ln, = plt.plot([], [], 'ro')
def init():
ax.set_xlim(0, 2*np.pi)
ax.set_ylim(-1, 1)
return ln,
def update(frame):
xdata.append(frame)
ydata.append(np.sin(frame))
ln.set_data(xdata, ydata)
return ln,
ani = FuncAnimation(fig, update, frames=np.linspace(0, 2*np.pi, 128),
init_func=init, blit=True)
plt.show()
None of the methods worked for me.
But I have found this
Real time matplotlib plot is not working while still in a loop
All you need is to add
plt.pause(0.0001)
and then you could see the new plots.
So your code should look like this, and it will work
import matplotlib.pyplot as plt
import numpy as np
plt.ion() ## Note this correction
fig=plt.figure()
plt.axis([0,1000,0,1])
i=0
x=list()
y=list()
while i <1000:
temp_y=np.random.random();
x.append(i);
y.append(temp_y);
plt.scatter(i,temp_y);
i+=1;
plt.show()
plt.pause(0.0001) #Note this correction
show is probably not the best choice for this. What I would do is use pyplot.draw() instead. You also might want to include a small time delay (e.g., time.sleep(0.05)) in the loop so that you can see the plots happening. If I make these changes to your example it works for me and I see each point appearing one at a time.
I know this question is old, but there's now a package available called drawnow on GitHub as "python-drawnow". This provides an interface similar to MATLAB's drawnow -- you can easily update a figure.
An example for your use case:
import matplotlib.pyplot as plt
from drawnow import drawnow
def make_fig():
plt.scatter(x, y) # I think you meant this
plt.ion() # enable interactivity
fig = plt.figure() # make a figure
x = list()
y = list()
for i in range(1000):
temp_y = np.random.random()
x.append(i)
y.append(temp_y) # or any arbitrary update to your figure's data
i += 1
drawnow(make_fig)
python-drawnow is a thin wrapper around plt.draw but provides the ability to confirm (or debug) after figure display.
Another option is to go with bokeh. IMO, it is a good alternative at least for real-time plots. Here is a bokeh version of the code in the question:
from bokeh.plotting import curdoc, figure
import random
import time
def update():
global i
temp_y = random.random()
r.data_source.stream({'x': [i], 'y': [temp_y]})
i += 1
i = 0
p = figure()
r = p.circle([], [])
curdoc().add_root(p)
curdoc().add_periodic_callback(update, 100)
and for running it:
pip3 install bokeh
bokeh serve --show test.py
bokeh shows the result in a web browser via websocket communications. It is especially useful when data is generated by remote headless server processes.
An example use-case to plot CPU usage in real-time.
import time
import psutil
import matplotlib.pyplot as plt
fig = plt.figure()
ax = fig.add_subplot(111)
i = 0
x, y = [], []
while True:
x.append(i)
y.append(psutil.cpu_percent())
ax.plot(x, y, color='b')
fig.canvas.draw()
ax.set_xlim(left=max(0, i - 50), right=i + 50)
fig.show()
plt.pause(0.05)
i += 1
The problem seems to be that you expect plt.show() to show the window and then to return. It does not do that. The program will stop at that point and only resume once you close the window. You should be able to test that: If you close the window and then another window should pop up.
To resolve that problem just call plt.show() once after your loop. Then you get the complete plot. (But not a 'real-time plotting')
You can try setting the keyword-argument block like this: plt.show(block=False) once at the beginning and then use .draw() to update.
Here is a version that I got to work on my system.
import matplotlib.pyplot as plt
from drawnow import drawnow
import numpy as np
def makeFig():
plt.scatter(xList,yList) # I think you meant this
plt.ion() # enable interactivity
fig=plt.figure() # make a figure
xList=list()
yList=list()
for i in np.arange(50):
y=np.random.random()
xList.append(i)
yList.append(y)
drawnow(makeFig)
#makeFig() The drawnow(makeFig) command can be replaced
#plt.draw() with makeFig(); plt.draw()
plt.pause(0.001)
The drawnow(makeFig) line can be replaced with a makeFig(); plt.draw() sequence and it still works OK.
If you want draw and not freeze your thread as more point are drawn you should use plt.pause() not time.sleep()
im using the following code to plot a series of xy coordinates.
import matplotlib.pyplot as plt
import math
pi = 3.14159
fig, ax = plt.subplots()
x = []
y = []
def PointsInCircum(r,n=20):
circle = [(math.cos(2*pi/n*x)*r,math.sin(2*pi/n*x)*r) for x in xrange(0,n+1)]
return circle
circle_list = PointsInCircum(3, 50)
for t in range(len(circle_list)):
if t == 0:
points, = ax.plot(x, y, marker='o', linestyle='--')
ax.set_xlim(-4, 4)
ax.set_ylim(-4, 4)
else:
x_coord, y_coord = circle_list.pop()
x.append(x_coord)
y.append(y_coord)
points.set_data(x, y)
plt.pause(0.01)
This is the right way to plot Dynamic real-time matplot plots animation using while loop
There is a medium article on that too:
pip install celluloid # this will capture the image/animation
import matplotlib.pyplot as plt
import numpy as np
from celluloid import Camera # getting the camera
import matplotlib.animation as animation
from IPython import display
import time
from IPython.display import HTML
import warnings
%matplotlib notebook
warnings.filterwarnings('ignore')
warnings.simplefilter('ignore')
fig = plt.figure() #Empty fig object
ax = fig.add_subplot() #Empty axis object
camera = Camera(fig) # Camera object to capture the snap
def f(x):
''' function to create a sine wave'''
return np.sin(x) + np.random.normal(scale=0.1, size=len(x))
l = []
while True:
value = np.random.randint(9) #random number generator
l.append(value) # appneds each time number is generated
X = np.linspace(10, len(l)) # creates a line space for x axis, Equal to the length of l
for i in range(10): #plots 10 such lines
plt.plot(X, f(X))
fig.show() #shows the figure object
fig.canvas.draw()
camera.snap() # camera object to capture teh animation
time.sleep(1)
And for saving etc:
animation = camera.animate(interval = 200, repeat = True, repeat_delay = 500)
HTML(animation.to_html5_video())
animation.save('abc.mp4') # to save
output is:
Live plot with circular buffer with line style retained:
import os
import time
import psutil
import collections
import matplotlib.pyplot as plt
pts_n = 100
x = collections.deque(maxlen=pts_n)
y = collections.deque(maxlen=pts_n)
(line, ) = plt.plot(x, y, linestyle="--")
my_process = psutil.Process(os.getpid())
t_start = time.time()
while True:
x.append(time.time() - t_start)
y.append(my_process.cpu_percent())
line.set_xdata(x)
line.set_ydata(y)
plt.gca().relim()
plt.gca().autoscale_view()
plt.pause(0.1)