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479 lines
14 KiB
Python
479 lines
14 KiB
Python
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"""
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Mel Frequency Cepstral Coefficients (MFCC) Calculation
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MFCC is an algorithm widely used in audio and speech processing to represent the
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short-term power spectrum of a sound signal in a more compact and
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discriminative way. It is particularly popular in speech and audio processing
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tasks such as speech recognition and speaker identification.
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How Mel Frequency Cepstral Coefficients are Calculated:
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1. Preprocessing:
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- Load an audio signal and normalize it to ensure that the values fall
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within a specific range (e.g., between -1 and 1).
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- Frame the audio signal into overlapping, fixed-length segments, typically
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using a technique like windowing to reduce spectral leakage.
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2. Fourier Transform:
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- Apply a Fast Fourier Transform (FFT) to each audio frame to convert it
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from the time domain to the frequency domain. This results in a
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representation of the audio frame as a sequence of frequency components.
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3. Power Spectrum:
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- Calculate the power spectrum by taking the squared magnitude of each
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frequency component obtained from the FFT. This step measures the energy
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distribution across different frequency bands.
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4. Mel Filterbank:
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- Apply a set of triangular filterbanks spaced in the Mel frequency scale
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to the power spectrum. These filters mimic the human auditory system's
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frequency response. Each filterbank sums the power spectrum values within
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its band.
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5. Logarithmic Compression:
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- Take the logarithm (typically base 10) of the filterbank values to
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compress the dynamic range. This step mimics the logarithmic response of
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the human ear to sound intensity.
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6. Discrete Cosine Transform (DCT):
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- Apply the Discrete Cosine Transform to the log filterbank energies to
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obtain the MFCC coefficients. This transformation helps decorrelate the
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filterbank energies and captures the most important features of the audio
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signal.
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7. Feature Extraction:
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- Select a subset of the DCT coefficients to form the feature vector.
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Often, the first few coefficients (e.g., 12-13) are used for most
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applications.
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References:
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- Mel-Frequency Cepstral Coefficients (MFCCs):
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https://en.wikipedia.org/wiki/Mel-frequency_cepstrum
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- Speech and Language Processing by Daniel Jurafsky & James H. Martin:
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https://web.stanford.edu/~jurafsky/slp3/
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- Mel Frequency Cepstral Coefficient (MFCC) tutorial
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http://practicalcryptography.com/miscellaneous/machine-learning
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/guide-mel-frequency-cepstral-coefficients-mfccs/
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Author: Amir Lavasani
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"""
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import logging
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import numpy as np
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import scipy.fftpack as fft
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from scipy.signal import get_window
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logging.basicConfig(filename=f"{__file__}.log", level=logging.INFO)
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def mfcc(
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audio: np.ndarray,
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sample_rate: int,
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ftt_size: int = 1024,
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hop_length: int = 20,
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mel_filter_num: int = 10,
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dct_filter_num: int = 40,
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) -> np.ndarray:
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"""
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Calculate Mel Frequency Cepstral Coefficients (MFCCs) from an audio signal.
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Args:
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audio: The input audio signal.
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sample_rate: The sample rate of the audio signal (in Hz).
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ftt_size: The size of the FFT window (default is 1024).
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hop_length: The hop length for frame creation (default is 20ms).
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mel_filter_num: The number of Mel filters (default is 10).
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dct_filter_num: The number of DCT filters (default is 40).
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Returns:
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A matrix of MFCCs for the input audio.
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Raises:
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ValueError: If the input audio is empty.
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Example:
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>>> sample_rate = 44100 # Sample rate of 44.1 kHz
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>>> duration = 2.0 # Duration of 1 second
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>>> t = np.linspace(0, duration, int(sample_rate * duration), endpoint=False)
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>>> audio = 0.5 * np.sin(2 * np.pi * 440.0 * t) # Generate a 440 Hz sine wave
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>>> mfccs = mfcc(audio, sample_rate)
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>>> mfccs.shape
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(40, 101)
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"""
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logging.info(f"Sample rate: {sample_rate}Hz")
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logging.info(f"Audio duration: {len(audio) / sample_rate}s")
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logging.info(f"Audio min: {np.min(audio)}")
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logging.info(f"Audio max: {np.max(audio)}")
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# normalize audio
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audio_normalized = normalize(audio)
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logging.info(f"Normalized audio min: {np.min(audio_normalized)}")
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logging.info(f"Normalized audio max: {np.max(audio_normalized)}")
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# frame audio into
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audio_framed = audio_frames(
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audio_normalized, sample_rate, ftt_size=ftt_size, hop_length=hop_length
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)
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logging.info(f"Framed audio shape: {audio_framed.shape}")
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logging.info(f"First frame: {audio_framed[0]}")
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# convert to frequency domain
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# For simplicity we will choose the Hanning window.
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window = get_window("hann", ftt_size, fftbins=True)
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audio_windowed = audio_framed * window
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logging.info(f"Windowed audio shape: {audio_windowed.shape}")
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logging.info(f"First frame: {audio_windowed[0]}")
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audio_fft = calculate_fft(audio_windowed, ftt_size)
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logging.info(f"fft audio shape: {audio_fft.shape}")
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logging.info(f"First frame: {audio_fft[0]}")
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audio_power = calculate_signal_power(audio_fft)
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logging.info(f"power audio shape: {audio_power.shape}")
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logging.info(f"First frame: {audio_power[0]}")
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filters = mel_spaced_filterbank(sample_rate, mel_filter_num, ftt_size)
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logging.info(f"filters shape: {filters.shape}")
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audio_filtered = np.dot(filters, np.transpose(audio_power))
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audio_log = 10.0 * np.log10(audio_filtered)
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logging.info(f"audio_log shape: {audio_log.shape}")
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dct_filters = discrete_cosine_transform(dct_filter_num, mel_filter_num)
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cepstral_coefficents = np.dot(dct_filters, audio_log)
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logging.info(f"cepstral_coefficents shape: {cepstral_coefficents.shape}")
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return cepstral_coefficents
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def normalize(audio: np.ndarray) -> np.ndarray:
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"""
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Normalize an audio signal by scaling it to have values between -1 and 1.
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Args:
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audio: The input audio signal.
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Returns:
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The normalized audio signal.
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Examples:
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>>> audio = np.array([1, 2, 3, 4, 5])
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>>> normalized_audio = normalize(audio)
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>>> np.max(normalized_audio)
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1.0
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>>> np.min(normalized_audio)
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0.2
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"""
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# Divide the entire audio signal by the maximum absolute value
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return audio / np.max(np.abs(audio))
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def audio_frames(
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audio: np.ndarray,
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sample_rate: int,
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hop_length: int = 20,
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ftt_size: int = 1024,
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) -> np.ndarray:
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"""
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Split an audio signal into overlapping frames.
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Args:
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audio: The input audio signal.
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sample_rate: The sample rate of the audio signal.
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hop_length: The length of the hopping (default is 20ms).
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ftt_size: The size of the FFT window (default is 1024).
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Returns:
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An array of overlapping frames.
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Examples:
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>>> audio = np.array([1, 2, 3, 4, 5, 6, 7, 8, 9, 10]*1000)
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>>> sample_rate = 8000
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>>> frames = audio_frames(audio, sample_rate, hop_length=10, ftt_size=512)
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>>> frames.shape
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(126, 512)
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"""
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hop_size = np.round(sample_rate * hop_length / 1000).astype(int)
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# Pad the audio signal to handle edge cases
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audio = np.pad(audio, int(ftt_size / 2), mode="reflect")
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# Calculate the number of frames
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frame_count = int((len(audio) - ftt_size) / hop_size) + 1
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# Initialize an array to store the frames
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frames = np.zeros((frame_count, ftt_size))
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# Split the audio signal into frames
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for n in range(frame_count):
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frames[n] = audio[n * hop_size : n * hop_size + ftt_size]
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return frames
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def calculate_fft(audio_windowed: np.ndarray, ftt_size: int = 1024) -> np.ndarray:
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"""
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Calculate the Fast Fourier Transform (FFT) of windowed audio data.
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Args:
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audio_windowed: The windowed audio signal.
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ftt_size: The size of the FFT (default is 1024).
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Returns:
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The FFT of the audio data.
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Examples:
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>>> audio_windowed = np.array([[1.0, 2.0, 3.0], [4.0, 5.0, 6.0]])
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>>> audio_fft = calculate_fft(audio_windowed, ftt_size=4)
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>>> np.allclose(audio_fft[0], np.array([6.0+0.j, -1.5+0.8660254j, -1.5-0.8660254j]))
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True
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"""
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# Transpose the audio data to have time in rows and channels in columns
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audio_transposed = np.transpose(audio_windowed)
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# Initialize an array to store the FFT results
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audio_fft = np.empty(
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(int(1 + ftt_size // 2), audio_transposed.shape[1]),
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dtype=np.complex64,
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order="F",
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)
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# Compute FFT for each channel
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for n in range(audio_fft.shape[1]):
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audio_fft[:, n] = fft.fft(audio_transposed[:, n], axis=0)[: audio_fft.shape[0]]
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# Transpose the FFT results back to the original shape
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return np.transpose(audio_fft)
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def calculate_signal_power(audio_fft: np.ndarray) -> np.ndarray:
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"""
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Calculate the power of the audio signal from its FFT.
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Args:
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audio_fft: The FFT of the audio signal.
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Returns:
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The power of the audio signal.
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Examples:
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>>> audio_fft = np.array([1+2j, 2+3j, 3+4j, 4+5j])
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>>> power = calculate_signal_power(audio_fft)
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>>> np.allclose(power, np.array([5, 13, 25, 41]))
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True
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"""
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# Calculate the power by squaring the absolute values of the FFT coefficients
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return np.square(np.abs(audio_fft))
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def freq_to_mel(freq: float) -> float:
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"""
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Convert a frequency in Hertz to the mel scale.
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Args:
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freq: The frequency in Hertz.
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Returns:
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The frequency in mel scale.
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Examples:
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>>> round(freq_to_mel(1000), 2)
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999.99
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"""
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# Use the formula to convert frequency to the mel scale
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return 2595.0 * np.log10(1.0 + freq / 700.0)
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def mel_to_freq(mels: float) -> float:
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"""
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Convert a frequency in the mel scale to Hertz.
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Args:
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mels: The frequency in mel scale.
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Returns:
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The frequency in Hertz.
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Examples:
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>>> round(mel_to_freq(999.99), 2)
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1000.01
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"""
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# Use the formula to convert mel scale to frequency
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return 700.0 * (10.0 ** (mels / 2595.0) - 1.0)
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def mel_spaced_filterbank(
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sample_rate: int, mel_filter_num: int = 10, ftt_size: int = 1024
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) -> np.ndarray:
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"""
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Create a Mel-spaced filter bank for audio processing.
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Args:
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sample_rate: The sample rate of the audio.
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mel_filter_num: The number of mel filters (default is 10).
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ftt_size: The size of the FFT (default is 1024).
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Returns:
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Mel-spaced filter bank.
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Examples:
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>>> round(mel_spaced_filterbank(8000, 10, 1024)[0][1], 10)
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0.0004603981
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"""
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freq_min = 0
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freq_high = sample_rate // 2
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logging.info(f"Minimum frequency: {freq_min}")
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logging.info(f"Maximum frequency: {freq_high}")
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# Calculate filter points and mel frequencies
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filter_points, mel_freqs = get_filter_points(
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sample_rate,
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freq_min,
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freq_high,
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mel_filter_num,
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ftt_size,
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)
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filters = get_filters(filter_points, ftt_size)
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# normalize filters
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# taken from the librosa library
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enorm = 2.0 / (mel_freqs[2 : mel_filter_num + 2] - mel_freqs[:mel_filter_num])
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return filters * enorm[:, np.newaxis]
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def get_filters(filter_points: np.ndarray, ftt_size: int) -> np.ndarray:
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"""
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Generate filters for audio processing.
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Args:
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filter_points: A list of filter points.
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ftt_size: The size of the FFT.
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Returns:
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A matrix of filters.
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Examples:
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>>> get_filters(np.array([0, 20, 51, 95, 161, 256], dtype=int), 512).shape
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(4, 257)
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"""
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num_filters = len(filter_points) - 2
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filters = np.zeros((num_filters, int(ftt_size / 2) + 1))
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for n in range(num_filters):
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start = filter_points[n]
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mid = filter_points[n + 1]
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end = filter_points[n + 2]
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# Linearly increase values from 0 to 1
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filters[n, start:mid] = np.linspace(0, 1, mid - start)
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# Linearly decrease values from 1 to 0
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filters[n, mid:end] = np.linspace(1, 0, end - mid)
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return filters
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def get_filter_points(
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sample_rate: int,
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freq_min: int,
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freq_high: int,
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mel_filter_num: int = 10,
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ftt_size: int = 1024,
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) -> tuple[np.ndarray, np.ndarray]:
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"""
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Calculate the filter points and frequencies for mel frequency filters.
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Args:
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sample_rate: The sample rate of the audio.
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freq_min: The minimum frequency in Hertz.
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freq_high: The maximum frequency in Hertz.
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mel_filter_num: The number of mel filters (default is 10).
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ftt_size: The size of the FFT (default is 1024).
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Returns:
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Filter points and corresponding frequencies.
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Examples:
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>>> filter_points = get_filter_points(8000, 0, 4000, mel_filter_num=4, ftt_size=512)
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>>> filter_points[0]
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array([ 0, 20, 51, 95, 161, 256])
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>>> filter_points[1]
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array([ 0. , 324.46707094, 799.33254207, 1494.30973963,
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2511.42581671, 4000. ])
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"""
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# Convert minimum and maximum frequencies to mel scale
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fmin_mel = freq_to_mel(freq_min)
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fmax_mel = freq_to_mel(freq_high)
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logging.info(f"MEL min: {fmin_mel}")
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logging.info(f"MEL max: {fmax_mel}")
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# Generate equally spaced mel frequencies
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mels = np.linspace(fmin_mel, fmax_mel, num=mel_filter_num + 2)
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# Convert mel frequencies back to Hertz
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freqs = mel_to_freq(mels)
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# Calculate filter points as integer values
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filter_points = np.floor((ftt_size + 1) / sample_rate * freqs).astype(int)
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return filter_points, freqs
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def discrete_cosine_transform(dct_filter_num: int, filter_num: int) -> np.ndarray:
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"""
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Compute the Discrete Cosine Transform (DCT) basis matrix.
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Args:
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dct_filter_num: The number of DCT filters to generate.
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filter_num: The number of the fbank filters.
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Returns:
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The DCT basis matrix.
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Examples:
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>>> round(discrete_cosine_transform(3, 5)[0][0], 5)
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0.44721
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"""
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basis = np.empty((dct_filter_num, filter_num))
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basis[0, :] = 1.0 / np.sqrt(filter_num)
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samples = np.arange(1, 2 * filter_num, 2) * np.pi / (2.0 * filter_num)
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for i in range(1, dct_filter_num):
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basis[i, :] = np.cos(i * samples) * np.sqrt(2.0 / filter_num)
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return basis
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def example(wav_file_path: str = "./path-to-file/sample.wav") -> np.ndarray:
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"""
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|
Example function to calculate Mel Frequency Cepstral Coefficients
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|
(MFCCs) from an audio file.
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||
|
|
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|
Args:
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|
wav_file_path: The path to the WAV audio file.
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|
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|
Returns:
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np.ndarray: The computed MFCCs for the audio.
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|
"""
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from scipy.io import wavfile
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|
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# Load the audio from the WAV file
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sample_rate, audio = wavfile.read(wav_file_path)
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|
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|
# Calculate MFCCs
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|
return mfcc(audio, sample_rate)
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||
|
|
||
|
|
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|
if __name__ == "__main__":
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|
import doctest
|
||
|
|
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|
doctest.testmod()
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