Пример #1
0
 def mfcc(data=EMPTY, pos=None, repeatable=True):
     global last_operation, dataset
     ssub = int(spectrum_subtraction.get())
     range_ = int(range_mfcc.get())
     cmap_ = var_cmap.get()
     if data is EMPTY:
         window = dataset.windows[int(range_window.get())]
         data = gui.plot(ax, dsp.MFCC, range_, cmap_, ssub, window=window)
     else:
         if pos is not None and not args.disable_window:
             window = dataset.windows[pos]
         else:
             window = None
         gui.plot(ax,
                  dsp.MFCC,
                  range_,
                  cmap_,
                  ssub,
                  data=data,
                  window=window)
     # TODO: inference for MFCCs
     #if cnn_model:
     #    infer(data, pos)
     last_operation = (mfcc, data, window, pos)
     fig.tight_layout()
     canvas.draw()
     if repeatable:
         repeat(mfcc)
Пример #2
0
 def mfsc(data=EMPTY, pos=None, repeatable=True):
     global last_operation, dataset
     print(pos)
     ssub = int(spectrum_subtraction.get())
     range_ = int(range_mfsc.get())
     cmap_ = var_cmap.get()
     if data is EMPTY:
         window = dataset.windows[int(range_window.get())]
         data = gui.plot(ax, dsp.MFSC, range_, cmap_, ssub, window=window)
     else:
         if pos is not None and not args.disable_window:
             window = dataset.windows[pos]
         else:
             window = None
         gui.plot(ax,
                  dsp.MFSC,
                  range_,
                  cmap_,
                  ssub,
                  data=data,
                  window=window)
     if cnn_model:
         print(window)
         a, b, c = window[0], window[1], window[2]
         infer(data[a:b, :c])
     last_operation = (mfsc, data, window, pos)
     fig.tight_layout()
     canvas.draw()
     if repeatable:
         repeat(mfsc)
Пример #3
0
 def fft(repeatable=True):
     global last_operation
     ssub = int(spectrum_subtraction.get())
     data = gui.plot(ax, dsp.FFT)
     last_operation = (fft, data, None, None)
     fig.tight_layout()
     canvas.draw()
     if repeatable:
         repeat(fft)
Пример #4
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 def raw_wave(repeatable=True):
     global last_operation
     range_ = int(range_amplitude.get())
     data = gui.plot(ax, dsp.RAW_WAVE, range_=range_)
     last_operation = (raw_wave, data, None, None)
     fig.tight_layout()
     canvas.draw()
     if repeatable:
         repeat(raw_wave)
Пример #5
0
 def spectrogram(data=EMPTY, pos=0, repeatable=True):
     global last_operation, dataset
     ssub = int(spectrum_subtraction.get())
     range_ = int(range_spectrogram.get())
     cmap_ = var_cmap.get()
     if data is EMPTY:
         window = dataset.windows[int(range_window.get())]
         data = gui.plot(ax, dsp.SPECTROGRAM, range_, cmap_, ssub)
     else:
         window = dataset.windows[pos]
         gui.plot(ax,
                  dsp.SPECTROGRAM,
                  range_,
                  cmap_,
                  ssub,
                  data=data,
                  window=None)
     last_operation = (spectrogram, data, window, pos)
     fig.tight_layout()
     canvas.draw()
     if repeatable:
         repeat(spectrogram)
Пример #6
0
def MST(v):
    if (gui.t != 0):
        for i in range(0, len(main.adjacency_matrix)):
            for j in range(i, len(main.adjacency_matrix[i])):
                if (main.adjacency_matrix[i][j] == 1):
                    print("assign weight to edge", i + 1, "to", j + 1)
                    temp = int(input())
                    off_y = (gui.y_matrix[j] - gui.y_matrix[i]) / 2
                    off_x = (gui.x_matrix[j] - gui.x_matrix[i]) / 2
                    gui.canvas.create_text(gui.x_matrix[i] + off_x,
                                           gui.y_matrix[i] + off_y,
                                           text=str(temp),
                                           font="Times 20 italic bold")

                    main.adjacency_matrix[i][j] = temp
                    main.adjacency_matrix[j][i] = temp

    g = Graph(len(main.adjacency_matrix))
    g.graph = []
    g.graph.extend(main.adjacency_matrix)
    g.primsAlgo()
    print("how many weights you want to change ?")
    z = int(input())
    if (z > 0):
        for i in range(0, z):
            print(
                "Type the edge of which you want to change weight in fromat ->",
                "e1 e2 w")
            s = list(map(int, input().split()))
            main.adjacency_matrix[s[0] - 1][s[1] - 1] = s[2]
            gui.canvas.delete("all")
            #print(gui.x_matrix)
            #print(gui.y_matrix)
            tag_name = str(s[0] - 1) + str(s[1] - 1)
            gui.canvas.delete(tag_name)
            gui.plot(main.adjacency_matrix)
Пример #7
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 def elapsed_time():
     gui.plot(ax, dsp.ELAPSED_TIME)
Пример #8
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 def filterbank():
     data = gui.plot(ax, dsp.FILTERBANK)
     canvas.draw()