praca-magisterska/docs/images/plots.py

#%% Change working directory from the workspace root to the ipynb file location. Turn this addition off with the DataScience.changeDirOnImportExport setting
# ms-python.python added
import os
try:
	os.chdir(os.path.join(os.getcwd(), 'docs\\images'))
	print(os.getcwd())
except:
	pass

#%%
import music21
from music21.midi import MidiFile

import numpy as np
import matplotlib.pyplot as plt
import mido

#%% [markdown]
# # midi messages

#%%
filepath = '/home/altarin/praca-magisterska/docs/images/seq2seq_generated_midi_7.mid'
mid = mido.MidiFile(filepath)
for i, track in enumerate(mid.tracks):
    for msg in track:
        print(msg)

#%% [markdown]
# # Regresja liniowa

#%%
x = np.arange(0,10)
y = np.arange(0,10) + np.random.random(10)-0.5
y_hat = np.arange(0,10)
plt.scatter(x, y, c='k')
plt.plot(x,y_hat, c='r')
# plt.labels
# plt.savefig('linear_reg.png')

#%%
from math import exp

x = np.arange(-10,10, 0.1)
# y = np.arange(0,10) 

tanh = lambda x: (exp(x) - exp(-x))/(exp(x) + exp(-x))

y_hat = [tanh(yy) for yy in x]
# plt.scatter(x, y, c='k')
plt.plot(x, y_hat)
# plt.show()
# plt.labels
plt.savefig('tanh.png')

#%%
# Gradient descent

fx = x^2
dx = 2x + c


#%%
func = lambda x: x**2
func_dx = lambda x:2*x

x = np.arange(-20,20,0.1)
y = func(x)

point_x = -6
point_y = func(point_x)


dx = styczna(x)

learning_points_xs = np.arange(point_x, 0, 0.8)
learning_points_ys = func(learning_points_xs)

fig, ax = plt.subplots()
ax.plot(x, y, c='k')

for px in learning_points_xs[0:1]:
    slope = func_dx(px)
    intercept = -px**2
    styczna = lambda x: slope*x + intercept
    dx = styczna(x)
    ax.plot(x, dx, c='r', zorder=1)

ax.scatter(x=point_x, y=point_y, c='r', zorder=6) #start
# ax.scatter(x=0, y=0, c='g', zorder=6) #min
# ax.scatter(x=learning_points_xs, y=learning_points_ys, c='y', zorder=5)
plt.ylim((-20,80))
plt.xlim((-20,20))
# plt.xlabel('x')
# plt.ylabel('f(x) = x^2')

plt.savefig('gradient_descent_1.png')

# https://towardsdatascience.com/understanding-the-mathematics-behind-gradient-descent-dde5dc9be06e?
# https://medium.com/code-heroku/gradient-descent-for-machine-learning-3d871fa48b4c


#%% sound wave

#import the pyplot and wavfile modules 
import matplotlib.pyplot as plot
from scipy.io import wavfile

# Read the wav file (mono)
samplingFrequency, signalData = wavfile.read('foo.wav')

# Plot the signal read from wav file
# plot.title('Spectrogram of a wav file with piano music')
plot.plot(signalData)
plot.xlabel('Próbki')
plot.ylabel('Amplituda')
plot.savefig('waveform_axis.png')
# plot.show()

# print(samplingFrequency)


#%%
Poprawiono pracę zgodnie z wytycznymi promotora 2020-05-29 11:49:23 +02:00			`#%% Change working directory from the workspace root to the ipynb file location. Turn this addition off with the DataScience.changeDirOnImportExport setting`
			`# ms-python.python added`
			`import os`
			`try:`
			`os.chdir(os.path.join(os.getcwd(), 'docs\\images'))`
			`print(os.getcwd())`
			`except:`
			`pass`

			`#%%`
			`import music21`
			`from music21.midi import MidiFile`

			`import numpy as np`
			`import matplotlib.pyplot as plt`
			`import mido`

			`#%% [markdown]`
			`# # midi messages`

			`#%%`
			`filepath = '/home/altarin/praca-magisterska/docs/images/seq2seq_generated_midi_7.mid'`
			`mid = mido.MidiFile(filepath)`
			`for i, track in enumerate(mid.tracks):`
			`for msg in track:`
			`print(msg)`

			`#%% [markdown]`
			`# # Regresja liniowa`

			`#%%`
			`x = np.arange(0,10)`
			`y = np.arange(0,10) + np.random.random(10)-0.5`
			`y_hat = np.arange(0,10)`
			`plt.scatter(x, y, c='k')`
			`plt.plot(x,y_hat, c='r')`
			`# plt.labels`
			`# plt.savefig('linear_reg.png')`

			`#%%`
			`from math import exp`

			`x = np.arange(-10,10, 0.1)`
			`# y = np.arange(0,10)`

			`tanh = lambda x: (exp(x) - exp(-x))/(exp(x) + exp(-x))`

			`y_hat = [tanh(yy) for yy in x]`
			`# plt.scatter(x, y, c='k')`
			`plt.plot(x, y_hat)`
			`# plt.show()`
			`# plt.labels`
			`plt.savefig('tanh.png')`

			`#%%`
			`# Gradient descent`

			`fx = x^2`
			`dx = 2x + c`




			`#%%`
			`func = lambda x: x**2`
			`func_dx = lambda x:2*x`

			`x = np.arange(-20,20,0.1)`
			`y = func(x)`

			`point_x = -6`
			`point_y = func(point_x)`



			`dx = styczna(x)`

			`learning_points_xs = np.arange(point_x, 0, 0.8)`
			`learning_points_ys = func(learning_points_xs)`

			`fig, ax = plt.subplots()`
			`ax.plot(x, y, c='k')`

			`for px in learning_points_xs[0:1]:`
			`slope = func_dx(px)`
			`intercept = -px**2`
			`styczna = lambda x: slope*x + intercept`
			`dx = styczna(x)`
			`ax.plot(x, dx, c='r', zorder=1)`

			`ax.scatter(x=point_x, y=point_y, c='r', zorder=6) #start`
			`# ax.scatter(x=0, y=0, c='g', zorder=6) #min`
			`# ax.scatter(x=learning_points_xs, y=learning_points_ys, c='y', zorder=5)`
			`plt.ylim((-20,80))`
			`plt.xlim((-20,20))`
			`# plt.xlabel('x')`
			`# plt.ylabel('f(x) = x^2')`

			`plt.savefig('gradient_descent_1.png')`

			`# https://towardsdatascience.com/understanding-the-mathematics-behind-gradient-descent-dde5dc9be06e?`
			`# https://medium.com/code-heroku/gradient-descent-for-machine-learning-3d871fa48b4c`


Poprawiono rozdziały 1-3 zgodnie z zaleceniami promotora 2020-06-15 18:20:53 +02:00			`#%% sound wave`

			`#import the pyplot and wavfile modules`
			`import matplotlib.pyplot as plot`
			`from scipy.io import wavfile`

			`# Read the wav file (mono)`
			`samplingFrequency, signalData = wavfile.read('foo.wav')`

			`# Plot the signal read from wav file`
			`# plot.title('Spectrogram of a wav file with piano music')`
			`plot.plot(signalData)`
			`plot.xlabel('Próbki')`
			`plot.ylabel('Amplituda')`
			`plot.savefig('waveform_axis.png')`
			`# plot.show()`

			`# print(samplingFrequency)`
Poprawiono pracę zgodnie z wytycznymi promotora 2020-05-29 11:49:23 +02:00


Poprawiono rozdziały 1-3 zgodnie z zaleceniami promotora 2020-06-15 18:20:53 +02:00



			`#%%`