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frequency_response.py
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frequency_response.py
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# -*- coding: utf-8 -*_
import os
import matplotlib.pyplot as plt
import matplotlib.ticker as ticker
import math
import pandas as pd
from io import StringIO
from scipy.interpolate import InterpolatedUnivariateSpline
from scipy.signal import savgol_filter, find_peaks, minimum_phase, firwin2
from scipy.special import expit
from scipy.stats import linregress
from scipy.fftpack import next_fast_len
import numpy as np
import urllib
from time import time
from tabulate import tabulate
from PIL import Image
import re
import warnings
import biquad
from constants import DEFAULT_F_MIN, DEFAULT_F_MAX, DEFAULT_STEP, DEFAULT_MAX_GAIN, DEFAULT_TREBLE_F_LOWER, \
DEFAULT_TREBLE_F_UPPER, DEFAULT_TREBLE_MAX_GAIN, DEFAULT_TREBLE_GAIN_K, DEFAULT_SMOOTHING_WINDOW_SIZE, \
DEFAULT_SMOOTHING_ITERATIONS, DEFAULT_TREBLE_SMOOTHING_F_LOWER, DEFAULT_TREBLE_SMOOTHING_F_UPPER, \
DEFAULT_TREBLE_SMOOTHING_WINDOW_SIZE, DEFAULT_TREBLE_SMOOTHING_ITERATIONS, DEFAULT_TILT, DEFAULT_FS, \
DEFAULT_F_RES, DEFAULT_BASS_BOOST_GAIN, DEFAULT_BASS_BOOST_FC, \
DEFAULT_BASS_BOOST_Q, DEFAULT_GRAPHIC_EQ_STEP, HARMAN_INEAR_PREFENCE_FREQUENCIES, \
HARMAN_ONEAR_PREFERENCE_FREQUENCIES, PREAMP_HEADROOM
class FrequencyResponse:
def __init__(self,
name=None,
frequency=None,
raw=None,
error=None,
smoothed=None,
error_smoothed=None,
equalization=None,
parametric_eq=None,
fixed_band_eq=None,
equalized_raw=None,
equalized_smoothed=None,
target=None):
if not name:
raise TypeError('Name must not be a non-empty string.')
self.name = name.strip()
self.frequency = self._init_data(frequency)
if not len(self.frequency):
self.frequency = self.generate_frequencies()
self.raw = self._init_data(raw)
self.smoothed = self._init_data(smoothed)
self.error = self._init_data(error)
self.error_smoothed = self._init_data(error_smoothed)
self.equalization = self._init_data(equalization)
self.parametric_eq = self._init_data(parametric_eq)
self.fixed_band_eq = self._init_data(fixed_band_eq)
self.equalized_raw = self._init_data(equalized_raw)
self.equalized_smoothed = self._init_data(equalized_smoothed)
self.target = self._init_data(target)
self._sort()
def copy(self, name=None):
return self.__class__(
name=self.name + '_copy' if name is None else name,
frequency=self._init_data(self.frequency),
raw=self._init_data(self.raw),
error=self._init_data(self.error),
smoothed=self._init_data(self.smoothed),
error_smoothed=self._init_data(self.error_smoothed),
equalization=self._init_data(self.equalization),
parametric_eq=self._init_data(self.parametric_eq),
fixed_band_eq=self._init_data(self.fixed_band_eq),
equalized_raw=self._init_data(self.equalized_raw),
equalized_smoothed=self._init_data(self.equalized_smoothed),
target=self._init_data(self.target)
)
def _init_data(self, data):
"""Initializes data to a clean format. If None is passed and empty array is created. Non-numbers are removed."""
if data is None:
# None means empty array
data = []
elif type(data) == float or type(data) == int:
# Scalar means all values are that, same shape as frequency
data = np.ones(self.frequency.shape) * data
# Replace nans with Nones
data = [None if x is None or math.isnan(x) else x for x in data]
# Wrap in Numpy array
data = np.array(data)
return data
def _sort(self):
sorted_inds = self.frequency.argsort()
self.frequency = self.frequency[sorted_inds]
for i in range(1, len(self.frequency)):
if self.frequency[i] == self.frequency[i-1]:
raise ValueError('Duplicate values found at frequency {}. Remove duplicates manually.'.format(
self.frequency[i])
)
if len(self.raw):
self.raw = self.raw[sorted_inds]
if len(self.error):
self.error = self.error[sorted_inds]
if len(self.smoothed):
self.smoothed = self.smoothed[sorted_inds]
if len(self.error_smoothed):
self.error_smoothed = self.error_smoothed[sorted_inds]
if len(self.equalization):
self.equalization = self.equalization[sorted_inds]
if len(self.parametric_eq):
self.parametric_eq = self.parametric_eq[sorted_inds]
if len(self.fixed_band_eq):
self.fixed_band_eq = self.fixed_band_eq[sorted_inds]
if len(self.equalized_raw):
self.equalized_raw = self.equalized_raw[sorted_inds]
if len(self.equalized_smoothed):
self.equalized_smoothed = self.equalized_smoothed[sorted_inds]
if len(self.target):
self.target = self.target[sorted_inds]
def reset(self,
raw=False,
smoothed=True,
error=True,
error_smoothed=True,
equalization=True,
fixed_band_eq=True,
parametric_eq=True,
equalized_raw=True,
equalized_smoothed=True,
target=True):
"""Resets data."""
if raw:
self.raw = self._init_data(None)
if smoothed:
self.smoothed = self._init_data(None)
if error:
self.error = self._init_data(None)
if error_smoothed:
self.error_smoothed = self._init_data(None)
if equalization:
self.equalization = self._init_data(None)
if parametric_eq:
self.parametric_eq = self._init_data(None)
if fixed_band_eq:
self.fixed_band_eq = self._init_data(None)
if equalized_raw:
self.equalized_raw = self._init_data(None)
if equalized_smoothed:
self.equalized_smoothed = self._init_data(None)
if target:
self.target = self._init_data(None)
@classmethod
def read_from_csv(cls, file_path):
"""Reads data from CSV file and constructs class instance."""
name = '.'.join(os.path.split(file_path)[1].split('.')[:-1])
# Read file
f = open(file_path, 'r', encoding='utf-8')
s = f.read()
# Regex for AutoEq style CSV
header_pattern = r'frequency(,(raw|smoothed|error|error_smoothed|equalization|parametric_eq|fixed_band_eq|equalized_raw|equalized_smoothed|target))+'
float_pattern = r'-?\d+\.?\d+'
data_2_pattern = r'{fl}[ ,;:\t]+{fl}?'.format(fl=float_pattern)
data_n_pattern = r'{fl}([ ,;:\t]+{fl})+?'.format(fl=float_pattern)
autoeq_pattern = r'^{header}(\n{data})+\n*$'.format(header=header_pattern, data=data_n_pattern)
if re.match(autoeq_pattern, s):
# Known AutoEq CSV format
df = pd.read_csv(StringIO(s), sep=',', header=0)
frequency = list(df['frequency'])
raw = list(df['raw']) if 'raw' in df else None
smoothed = list(df['smoothed']) if 'smoothed' in df else None
error = list(df['error']) if 'error' in df else None
error_smoothed = list(df['error_smoothed']) if 'error_smoothed' in df else None
equalization = list(df['equalization']) if 'equalization' in df else None
parametric_eq = list(df['parametric_eq']) if 'parametric_eq' in df else None
fixed_band_eq = list(df['fixed_band_eq']) if 'fixed_band_eq' in df else None
equalized_raw = list(df['equalized_raw']) if 'equalized_raw' in df else None
equalized_smoothed = list(df['equalized_smoothed']) if 'equalized_smoothed' in df else None
target = list(df['target']) if 'target' in df else None
return cls(
name=name,
frequency=frequency,
raw=raw,
smoothed=smoothed,
error=error,
error_smoothed=error_smoothed,
equalization=equalization,
parametric_eq=parametric_eq,
fixed_band_eq=fixed_band_eq,
equalized_raw=equalized_raw,
equalized_smoothed=equalized_smoothed,
target=target
)
else:
# Unknown format, try to guess
lines = s.split('\n')
frequency = []
raw = []
for line in lines:
if re.match(data_2_pattern, line): # float separator float
floats = re.findall(float_pattern, line)
frequency.append(float(floats[0])) # Assume first to be frequency
raw.append(float(floats[1])) # Assume second to be raw
# Discard all lines which don't match data pattern
return cls(name=name, frequency=frequency, raw=raw)
def to_dict(self):
d = dict()
if len(self.frequency):
d['frequency'] = self.frequency.tolist()
if len(self.raw):
d['raw'] = [x if x is not None else 'NaN' for x in self.raw]
if len(self.error):
d['error'] = [x if x is not None else 'NaN' for x in self.error]
if len(self.smoothed):
d['smoothed'] = [x if x is not None else 'NaN' for x in self.smoothed]
if len(self.error_smoothed):
d['error_smoothed'] = [x if x is not None else 'NaN' for x in self.error_smoothed]
if len(self.equalization):
d['equalization'] = [x if x is not None else 'NaN' for x in self.equalization]
if len(self.parametric_eq):
d['parametric_eq'] = [x if x is not None else 'NaN' for x in self.parametric_eq]
if len(self.fixed_band_eq):
d['fixed_band_eq'] = [x if x is not None else 'NaN' for x in self.fixed_band_eq]
if len(self.equalized_raw):
d['equalized_raw'] = [x if x is not None else 'NaN' for x in self.equalized_raw]
if len(self.equalized_smoothed):
d['equalized_smoothed'] = [x if x is not None else 'NaN' for x in self.equalized_smoothed]
if len(self.target):
d['target'] = [x if x is not None else 'NaN' for x in self.target]
return d
def write_to_csv(self, file_path=None):
"""Writes data to files as CSV."""
file_path = os.path.abspath(file_path)
df = pd.DataFrame(self.to_dict())
df.to_csv(file_path, header=True, index=False, float_format='%.2f')
def eqapo_graphic_eq(self, normalize=True, f_step=DEFAULT_GRAPHIC_EQ_STEP):
"""Generates EqualizerAPO GraphicEQ string from equalization curve."""
fr = self.__class__(name='hack', frequency=self.frequency, raw=self.equalization)
n = np.ceil(np.log(20000 / 20) / np.log(f_step))
f = 20 * f_step**np.arange(n)
f = np.sort(np.unique(f.astype('int')))
fr.interpolate(f=f)
if normalize:
fr.raw -= np.max(fr.raw) + PREAMP_HEADROOM
if fr.raw[0] > 0.0:
# Prevent bass boost below lowest frequency
fr.raw[0] = 0.0
# Remove leading zeros
while np.abs(fr.raw[-1]) < 0.1 and np.abs(fr.raw[-2]) < 0.1: # Last two are zeros
fr.raw = fr.raw[:-1]
s = '; '.join(['{f} {a:.1f}'.format(f=f, a=a) for f, a in zip(fr.frequency, fr.raw)])
s = 'GraphicEQ: ' + s
return s
def write_eqapo_graphic_eq(self, file_path, normalize=True):
"""Writes equalization graph to a file as Equalizer APO config."""
file_path = os.path.abspath(file_path)
s = self.eqapo_graphic_eq(normalize=normalize)
with open(file_path, 'w', encoding='utf-8') as f:
f.write(s)
return s
@classmethod
def optimize_biquad_filters(cls, frequency, target, max_time=5, max_filters=None, fs=DEFAULT_FS, fc=None, q=None):
os.environ['TF_CPP_MIN_LOG_LEVEL'] = '3'
import tensorflow.compat.v1 as tf
tf.get_logger().setLevel('ERROR')
tf.disable_v2_behavior()
if fc is not None or q is not None:
if fc is None:
raise TypeError('"fc" must be given if "q" is given.')
if q is None:
raise TypeError('"q" must be give nif "fc" is given.')
if max_filters is not None:
raise TypeError('"max_filters" must not be given when "fc" and "q" are given.')
fc = np.array(fc, dtype='float32')
q = np.array(q, dtype='float32')
parametric = fc is None
# Reset graph to be able to run this again
tf.reset_default_graph()
# Sampling frequency
fs_tf = tf.constant(fs, name='f', dtype='float32')
# Smoothen heavily
fr_target = cls(name='Filter Initialization', frequency=frequency, raw=target)
fr_target.smoothen_fractional_octave(window_size=1 / 7, iterations=1000)
# Equalization target
eq_target = tf.constant(target, name='eq_target', dtype='float32')
n_ls = n_hs = 0
if parametric:
# Fc and Q not given, parametric equalizer, find initial estimation of peaks and gains
fr_target_pos = np.clip(fr_target.smoothed, a_min=0.0, a_max=None)
peak_inds = find_peaks(fr_target_pos)[0]
fr_target_neg = np.clip(-fr_target.smoothed, a_min=0.0, a_max=None)
peak_inds = np.concatenate((peak_inds, find_peaks(fr_target_neg)[0]))
peak_inds.sort()
peak_inds = peak_inds[np.abs(fr_target.smoothed[peak_inds]) > 0.1]
# Peak center frequencies and gains
peak_fc = frequency[peak_inds].astype('float32')
if peak_fc[0] > 80:
# First peak is beyond 80Hz, add peaks to 20Hz and 60Hz
peak_fc = np.concatenate((np.array([20, 60], dtype='float32'), peak_fc))
elif peak_fc[0] > 40:
# First peak is beyond 40Hz, add peak to 20Hz
peak_fc = np.concatenate((np.array([20], dtype='float32'), peak_fc))
# Gains at peak center frequencies
interpolator = InterpolatedUnivariateSpline(np.log10(frequency), fr_target.smoothed, k=1)
peak_g = interpolator(np.log10(peak_fc)).astype('float32')
def remove_small_filters(min_gain):
# Remove peaks with too little gain
nonlocal peak_fc, peak_g
peak_fc = peak_fc[np.abs(peak_g) > min_gain]
peak_g = peak_g[np.abs(peak_g) > min_gain]
def merge_filters():
# Merge two filters which have small integral between them
nonlocal peak_fc, peak_g
# Form filter pairs, select only filters with equal gain sign
pair_inds = []
for j in range(len(peak_fc) - 1):
if np.sign(peak_g[j]) == np.sign(peak_g[j + 1]):
pair_inds.append(j)
min_err = None
min_err_ind = None
for pair_ind in pair_inds:
# Interpolate between the two points
f_0 = peak_fc[pair_ind]
g_0 = peak_g[pair_ind]
i_0 = np.argmin(np.abs(frequency - f_0))
f_1 = peak_fc[pair_ind + 1]
i_1 = np.argmin(np.abs(frequency - f_1))
g_1 = peak_g[pair_ind]
interp = InterpolatedUnivariateSpline(np.log10([f_0, f_1]), [g_0, g_1], k=1)
line = interp(frequency[i_0:i_1 + 1])
err = line - fr_target.smoothed[i_0:i_1 + 1]
err = np.sqrt(np.mean(np.square(err))) # Root mean squared error
if min_err is None or err < min_err:
min_err = err
min_err_ind = pair_ind
if min_err is None:
# No pairs detected
return False
# Select smallest error if err < threshold
if min_err < 0.3:
# New filter
c = peak_fc[min_err_ind] * np.sqrt(peak_fc[min_err_ind + 1] / peak_fc[min_err_ind])
c = frequency[np.argmin(np.abs(frequency - c))]
g = np.mean([peak_g[min_err_ind], peak_g[min_err_ind + 1]])
# Remove filters
peak_fc = np.delete(peak_fc, [min_err_ind, min_err_ind + 1])
peak_g = np.delete(peak_g, [min_err_ind, min_err_ind + 1])
# Add filter in-between
peak_fc = np.insert(peak_fc, min_err_ind, c)
peak_g = np.insert(peak_g, min_err_ind, g)
return True
return False # No prominent filter pairs
# Remove insignificant filters
remove_small_filters(0.1)
if len(peak_fc) == 0:
# All filters were insignificant, exit
return np.zeros(frequency.shape), 0.0, np.array([]), np.array([]), np.array([])
# Limit filter number to max_filters by removing least significant filters and merging close filters
if max_filters is not None:
if len(peak_fc) > max_filters:
# Remove too small filters
remove_small_filters(0.2)
if len(peak_fc) > max_filters:
# Try to remove some more
remove_small_filters(0.33)
# Merge filters if needed
while merge_filters() and len(peak_fc) > max_filters:
pass
if len(peak_fc) > max_filters:
# Remove smallest filters
sorted_inds = np.flip(np.argsort(np.abs(peak_g)))
sorted_inds = sorted_inds[:max_filters]
peak_fc = peak_fc[sorted_inds]
peak_g = peak_g[sorted_inds]
sorted_inds = np.argsort(peak_fc)
peak_fc = peak_fc[sorted_inds]
peak_g = peak_g[sorted_inds]
n = n_pk = len(peak_fc)
# Frequencies
f = tf.constant(np.repeat(np.expand_dims(frequency, axis=0), n, axis=0), name='f', dtype='float32')
# Center frequencies
fc = tf.get_variable('fc', initializer=np.expand_dims(np.log10(peak_fc), axis=1), dtype='float32')
# Q
Q_init = np.ones([n, 1], dtype='float32') * np.ones([n_pk, 1], dtype='float32')
Q = tf.get_variable('Q', initializer=Q_init, dtype='float32')
else:
# Fc and Q given, fixed band equalizer
Q = tf.get_variable(
'Q',
initializer=np.expand_dims(q, axis=1),
dtype='float32',
trainable=False
)
# Gains at peak center frequencies
interpolator = InterpolatedUnivariateSpline(np.log10(frequency), fr_target.smoothed, k=1)
peak_g = interpolator(np.log10(fc)).astype('float32')
# Number of filters
n = n_pk = len(fc)
# Frequencies
f = tf.constant(np.repeat(np.expand_dims(frequency, axis=0), n, axis=0), name='f', dtype='float32')
# Center frequencies
fc = tf.get_variable(
'fc',
initializer=np.expand_dims(np.log10(fc), axis=1),
dtype='float32',
trainable=False
)
# Gain
gain = tf.get_variable('gain', initializer=np.expand_dims(peak_g, axis=1), dtype='float32')
# Filter design
# Low shelf filter
# This is not used at the moment but is kept for future
A = 10 ** (gain[:n_ls, :] / 40)
w0 = 2 * np.pi * tf.pow(10.0, fc[:n_ls, :]) / fs_tf
alpha = tf.sin(w0) / (2 * Q[:n_ls, :])
a0_ls = ((A + 1) + (A - 1) * tf.cos(w0) + 2 * tf.sqrt(A) * alpha)
a1_ls = (-(-2 * ((A - 1) + (A + 1) * tf.cos(w0))) / a0_ls)
a2_ls = (-((A + 1) + (A - 1) * tf.cos(w0) - 2 * tf.sqrt(A) * alpha) / a0_ls)
b0_ls = ((A * ((A + 1) - (A - 1) * tf.cos(w0) + 2 * tf.sqrt(A) * alpha)) / a0_ls)
b1_ls = ((2 * A * ((A - 1) - (A + 1) * tf.cos(w0))) / a0_ls)
b2_ls = ((A * ((A + 1) - (A - 1) * tf.cos(w0) - 2 * tf.sqrt(A) * alpha)) / a0_ls)
# Peak filter
A = 10 ** (gain[n_ls:n_ls+n_pk, :] / 40)
w0 = 2 * np.pi * tf.pow(10.0, fc[n_ls:n_ls+n_pk, :]) / fs_tf
alpha = tf.sin(w0) / (2 * Q[n_ls:n_ls+n_pk, :])
a0_pk = (1 + alpha / A)
a1_pk = -(-2 * tf.cos(w0)) / a0_pk
a2_pk = -(1 - alpha / A) / a0_pk
b0_pk = (1 + alpha * A) / a0_pk
b1_pk = (-2 * tf.cos(w0)) / a0_pk
b2_pk = (1 - alpha * A) / a0_pk
# High self filter
# This is not kept at the moment but kept for future
A = 10 ** (gain[n_ls+n_pk:, :] / 40)
w0 = 2 * np.pi * tf.pow(10.0, fc[n_ls+n_pk:, :]) / fs_tf
alpha = tf.sin(w0) / (2 * Q[n_ls+n_pk:, :])
a0_hs = (A + 1) - (A - 1) * tf.cos(w0) + 2 * tf.sqrt(A) * alpha
a1_hs = -(2 * ((A - 1) - (A + 1) * tf.cos(w0))) / a0_hs
a2_hs = -((A + 1) - (A - 1) * tf.cos(w0) - 2 * tf.sqrt(A) * alpha) / a0_hs
b0_hs = (A * ((A + 1) + (A - 1) * tf.cos(w0) + 2 * tf.sqrt(A) * alpha)) / a0_hs
b1_hs = (-2 * A * ((A - 1) + (A + 1) * tf.cos(w0))) / a0_hs
b2_hs = (A * ((A + 1) + (A - 1) * tf.cos(w0) - 2 * tf.sqrt(A) * alpha)) / a0_hs
# Concatenate all
a0 = tf.concat([a0_ls, a0_pk, a0_hs], axis=0)
a1 = tf.concat([a1_ls, a1_pk, a1_hs], axis=0)
a2 = tf.concat([a2_ls, a2_pk, a2_hs], axis=0)
b0 = tf.concat([b0_ls, b0_pk, b0_hs], axis=0)
b1 = tf.concat([b1_ls, b1_pk, b1_hs], axis=0)
b2 = tf.concat([b2_ls, b2_pk, b2_hs], axis=0)
w = 2 * np.pi * f / fs_tf
phi = 4 * tf.sin(w / 2) ** 2
a0 = 1.0
a1 *= -1
a2 *= -1
# Equalizer frequency response
eq_op = 10 * tf.log(
(b0 + b1 + b2) ** 2 + (b0 * b2 * phi - (b1 * (b0 + b2) + 4 * b0 * b2)) * phi
) / tf.log(10.0) - 10 * tf.log(
(a0 + a1 + a2) ** 2 + (a0 * a2 * phi - (a1 * (a0 + a2) + 4 * a0 * a2)) * phi
) / tf.log(10.0)
eq_op = tf.reduce_sum(eq_op, axis=0)
# RMSE as loss
loss = tf.reduce_mean(tf.square(eq_op - eq_target))
learning_rate_value = 0.1
decay = 0.9995
learning_rate = tf.placeholder('float32', shape=(), name='learning_rate')
train_step = tf.train.AdamOptimizer(learning_rate=learning_rate).minimize(loss)
# Optimization loop
min_loss = None
threshold = 0.01
momentum = 100
bad_steps = 0
with tf.Session() as sess:
sess.run(tf.global_variables_initializer())
t = time()
while time() - t < max_time:
step_loss, _ = sess.run([loss, train_step], feed_dict={learning_rate: learning_rate_value})
if min_loss is None or step_loss < min_loss:
# Improvement, update model
_eq, _fc, _Q, _gain = sess.run([eq_op, fc, Q, gain])
_fc = 10**_fc
if min_loss is None or min_loss - step_loss > threshold:
# Loss improved
min_loss = step_loss
bad_steps = 0
else:
# No improvement, increment bad step counter
bad_steps += 1
if bad_steps > momentum:
# Bad steps exceed maximum number of bad steps, break
break
learning_rate_value = learning_rate_value * decay
rmse = np.sqrt(min_loss) # RMSE
# Fold center frequencies back to normal
_fc = np.abs(np.round(_fc / fs) * fs - _fc)
# Squeeze to rank-1 arrays
_fc = np.squeeze(_fc)
_Q = np.squeeze(_Q)
_gain = np.squeeze(_gain)
if parametric:
# Filter selection slice
sl = np.logical_and(np.abs(_gain) > 0.1, _fc > 10)
_fc = _fc[sl]
_Q = np.abs(_Q[sl])
_gain = _gain[sl]
# Sort filters by center frequency
sorted_inds = np.argsort(_fc)
_fc = _fc[sorted_inds]
_Q = _Q[sorted_inds]
_gain = _gain[sorted_inds]
# Expand dimensionality for biquad
_fc = np.expand_dims(_fc, axis=1)
_Q = np.expand_dims(np.abs(_Q), axis=1)
_gain = np.expand_dims(_gain, axis=1)
# Re-compute eq
a0, a1, a2, b0, b1, b2 = biquad.peaking(_fc, _Q, _gain, fs=fs)
frequency = np.repeat(np.expand_dims(frequency, axis=0), len(_fc), axis=0)
_eq = np.sum(biquad.digital_coeffs(frequency, fs, a0, a1, a2, b0, b1, b2), axis=0)
coeffs_a = np.hstack((np.tile(a0, a1.shape), a1, a2))
coeffs_b = np.hstack((b0, b1, b2))
return _eq, rmse, np.squeeze(_fc, axis=1), np.squeeze(_Q, axis=1), np.squeeze(_gain, axis=1), coeffs_a, coeffs_b
def optimize_parametric_eq(self, max_filters=None, fs=DEFAULT_FS):
"""Fits multiple biquad filters to equalization curve. If max_filters is a list with more than one element, one
optimization run will be ran for each element. Each optimization run will continue from the previous. Each
optimization run results must be combined with results of all the previous runs but can be used independently of
the preceeding runs' results. If max_filters is [5, 5, 5] the first 5, 10 and 15 filters can be used
independently.
Args:
max_filters: List of maximum number of filters available for each filter group optimization.
fs: Sampling frequency
Returns:
- **filters:** Numpy array of filters where each row contains one filter fc, Q and gain
- **n_produced:** Actual number of filters produced for each filter group. Calling with [5, 5] max_filters
might actually produce [4, 5] filters meaning that first 4 filters can be used
independently.
- **max_gains:** Maximum gain value of the equalizer frequency response after each filter group
optimization. When using sub-set of filters independently the actual max gain of that
sub-set's frequency response must be applied as a negative digital preamp to avoid
clipping.
"""
if not len(self.equalization):
raise ValueError('Equalization has not been done yet.')
if type(max_filters) != list:
max_filters = [max_filters]
self.parametric_eq = np.zeros(self.frequency.shape)
fc = Q = gain = np.array([])
coeffs_a = coeffs_b = np.empty((0, 3))
n_produced = []
max_gains = []
for n in max_filters:
_eq, rmse, _fc, _Q, _gain, _coeffs_a, _coeffs_b = self.optimize_biquad_filters(
frequency=self.frequency,
target=self.equalization - self.parametric_eq,
max_filters=n,
fs=fs
)
n_produced.append(len(_fc))
# print('RMSE: {:.2f}dB'.format(rmse))
self.parametric_eq += _eq
max_gains.append(np.max(self.parametric_eq))
fc = np.concatenate((fc, _fc))
Q = np.concatenate((Q, _Q))
gain = np.concatenate((gain, _gain))
coeffs_a = np.vstack((coeffs_a, _coeffs_a))
coeffs_b = np.vstack((coeffs_b, _coeffs_b))
filters = np.transpose(np.vstack([fc, Q, gain]))
return filters, n_produced, max_gains
def optimize_fixed_band_eq(self, fc=None, q=None, fs=DEFAULT_FS):
"""Fits multiple fixed Fc and Q biquad filters to equalization curve.
Args:
fc: List of center frequencies for the filters
q: List of Q values for the filters
fs: Sampling frequency
Returns:
- **filters:** Numpy array of filters where each row contains one filter fc, Q and gain
- **n_produced:** Number of filters. Equals to length or inputs.
- **max_gains:** Maximum gain value of the equalizer frequency response.
"""
eq, rmse, fc, Q, gain, coeffs_a, coeffs_b = self.optimize_biquad_filters(
frequency=self.frequency,
target=self.equalization,
fc=fc,
q=q,
fs=fs
)
self.fixed_band_eq = eq
filters = np.transpose(np.vstack([fc, Q, gain]))
return filters, len(fc), np.max(self.fixed_band_eq)
def write_eqapo_parametric_eq(self, file_path, filters, preamp=None):
"""Writes EqualizerAPO Parameteric eq settings to a file."""
file_path = os.path.abspath(file_path)
if preamp is None:
# Calculate preamp from the cascade frequency response
fr = np.zeros(self.frequency.shape)
for filt in filters:
a0, a1, a2, b0, b1, b2 = biquad.peaking(filt[0], filt[1], filt[2], fs=44100)
fr += biquad.digital_coeffs(self.frequency, 44100, a0, a1, a2, b0, b1, b2)
preamp = np.min([0.0, -(np.max(fr) + PREAMP_HEADROOM)])
with open(file_path, 'w', encoding='utf-8') as f:
s = f'Preamp: {preamp:.1f} dB\n'
for i, filt in enumerate(filters):
s += f'Filter {i+1}: ON PK Fc {filt[0]:.0f} Hz Gain {filt[2]:.1f} dB Q {filt[1]:.2f}\n'
f.write(s)
def write_rockbox_10_band_fixed_eq(self, file_path, filters, preamp=None):
"""Writes Rockbox 10 band eq settings to a file."""
file_path = os.path.abspath(file_path)
if preamp is None:
# Calculate preamp from the cascade frequency response
fr = np.zeros(self.frequency.shape)
for filt in filters:
a0, a1, a2, b0, b1, b2 = biquad.peaking(filt[0], filt[1], filt[2], fs=44100)
fr += biquad.digital_coeffs(self.frequency, 44100, a0, a1, a2, b0, b1, b2)
preamp = np.min([0.0, -(np.max(fr) + PREAMP_HEADROOM)])
with open(file_path, 'w', encoding='utf-8') as f:
s = f'eq enabled: on\neq precut: {round(abs(preamp), 1) * 10:.0f}\n'
for i, filt in enumerate(filters):
if i == 0:
s += f'eq low shelf filter: {filt[0]:.0f}, {round(filt[1], 1) * 10:.0f}, {round(filt[2], 1) * 10:.0f}\n'
elif i == len(filters) - 1:
s += f'eq high shelf filter: {filt[0]:.0f}, {round(filt[1], 1) * 10:.0f}, {round(filt[2], 1) * 10:.0f}\n'
else:
s += f'eq peak filter {i}: {filt[0]:.0f}, {round(filt[1], 1) * 10:.0f}, {round(filt[2], 1) * 10:.0f}\n'
f.write(s)
@staticmethod
def _split_path(path):
"""Splits file system path into components."""
folders = []
while 1:
path, folder = os.path.split(path)
if folder != "":
folders.append(folder)
else:
if path != "":
folders.append(path)
break
folders.reverse()
return folders
def minimum_phase_impulse_response(self, fs=DEFAULT_FS, f_res=DEFAULT_F_RES, normalize=True):
"""Generates minimum phase impulse response
Inspired by:
https://sourceforge.net/p/equalizerapo/code/HEAD/tree/tags/1.2/filters/GraphicEQFilter.cpp#l45
Args:
fs: Sampling frequency in Hz
f_res: Frequency resolution as sampling interval. 20 would result in sampling at 0 Hz, 20 Hz, 40 Hz, ...
normalize: Normalize gain to -0.2 dB
Returns:
Minimum phase impulse response
"""
# Double frequency resolution because it will be halved when converting linear phase IR to minimum phase
f_res /= 2
# Interpolate to even sample interval
fr = self.__class__(name='fr_data', frequency=self.frequency.copy(), raw=self.equalization.copy())
# Save gain at lowest available frequency
f_min = np.max([fr.frequency[0], f_res])
interpolator = InterpolatedUnivariateSpline(np.log10(fr.frequency), fr.raw, k=1)
gain_f_min = interpolator(np.log10(f_min))
# Filter length, optimized for FFT speed
n = round(fs // 2 / f_res)
n = next_fast_len(n)
f = np.linspace(0.0, fs // 2, n)
# Run interpolation
fr.interpolate(f, pol_order=1)
# Set gain for all frequencies below original minimum frequency to match gain at the original minimum frequency
fr.raw[fr.frequency <= f_min] = gain_f_min
if normalize:
# Reduce by max gain to avoid clipping with 1 dB of headroom
fr.raw -= np.max(fr.raw)
fr.raw -= PREAMP_HEADROOM
# Minimum phase transformation by scipy's homomorphic method halves dB gain
fr.raw *= 2
# Convert amplitude to linear scale
fr.raw = 10**(fr.raw / 20)
# Zero gain at Nyquist frequency
fr.raw[-1] = 0.0
# Calculate response
ir = firwin2(len(fr.frequency)*2, fr.frequency, fr.raw, fs=fs)
# Convert to minimum phase
ir = minimum_phase(ir, n_fft=len(ir))
return ir
def linear_phase_impulse_response(self, fs=DEFAULT_FS, f_res=DEFAULT_F_RES, normalize=True):
"""Generates impulse response implementation of equalization filter."""
# Interpolate to even sample interval
fr = self.__class__(name='fr_data', frequency=self.frequency, raw=self.equalization)
# Save gain at lowest available frequency
f_min = np.max([fr.frequency[0], f_res])
interpolator = InterpolatedUnivariateSpline(np.log10(fr.frequency), fr.raw, k=1)
gain_f_min = interpolator(np.log10(f_min))
# Run interpolation
fr.interpolate(np.arange(0.0, fs // 2, f_res), pol_order=1)
# Set gain for all frequencies below original minimum frequency to match gain at the original minimum frequency
fr.raw[fr.frequency <= f_min] = gain_f_min
if normalize:
# Reduce by max gain to avoid clipping with 1 dB of headroom
fr.raw -= np.max(fr.raw)
fr.raw -= PREAMP_HEADROOM
# Convert amplitude to linear scale
fr.raw = 10**(fr.raw / 20)
# Calculate response
fr.frequency = np.append(fr.frequency, fs // 2)
fr.raw = np.append(fr.raw, 0.0)
ir = firwin2(len(fr.frequency)*2, fr.frequency, fr.raw, fs=fs)
return ir
def write_readme(self, file_path, max_filters=None, max_gains=None):
"""Writes README.md with picture and Equalizer APO settings."""
file_path = os.path.abspath(file_path)
dir_path = os.path.dirname(file_path)
model = self.name
# Write model
s = '# {}\n'.format(model)
s += 'See [usage instructions](https://github.com/jaakkopasanen/AutoEq#usage) for more options and ' \
'info.\n'
# Add parametric EQ settings
parametric_eq_path = os.path.join(dir_path, model + ' ParametricEQ.txt')
if os.path.isfile(parametric_eq_path) and self.parametric_eq is not None and len(self.parametric_eq):
# Read Parametric eq
with open(parametric_eq_path, 'r', encoding='utf-8') as f:
parametric_eq_str = f.read().strip()
# Filters as Markdown table
filters = []
for line in parametric_eq_str.split('\n'):
if line == '' or line.split()[0] != 'Filter':
continue
filter_type = line[line.index('ON')+3:line.index('Fc')-1]
if filter_type == 'PK':
filter_type = 'Peaking'
if filter_type == 'LS':
filter_type = 'Low Shelf'
if filter_type == 'HS':
filter_type = 'High Shelf'
fc = line[line.index('Fc')+3:line.index('Gain')-1]
gain = line[line.index('Gain')+5:line.index('Q')-1]
q = line[line.index('Q')+2:]
filters.append([filter_type, fc, q, gain])
filters_table_str = tabulate(
filters,
headers=['Type', 'Fc', 'Q', 'Gain'],
tablefmt='orgtbl'
).replace('+', '|').replace('|-', '|:')
max_filters_str = ''
if type(max_filters) == list and len(max_filters) > 1:
n = [0]
for x in max_filters:
n.append(n[-1] + x)
del n[0]
if len(max_filters) > 3:
max_filters_str = ', '.join([str(x) for x in n[:-2]]) + f' or {n[-2]}'
if len(max_filters) == 3:
max_filters_str = f'{n[0]} or {n[1]}'
if len(max_filters) == 2:
max_filters_str = str(n[0])
max_filters_str = f'The first {max_filters_str} filters can be used independently.'
preamp_str = ''
if type(max_gains) == list and len(max_gains) > 1:
if len(max_gains) > 3:
strs = f', '.join([f'{-(x + PREAMP_HEADROOM):.1f} dB' for x in max_gains[:-2]]) + f' or -{max_gains[-2]:.1f} dB'
preamp_str = f'When using independent subset of filters, apply preamp of {strs}, respectively.'
elif len(max_gains) == 3:
preamp_str = f'When using independent subset of filters, apply preamp of ' \
f'{-(max_gains[0] + PREAMP_HEADROOM):.1f} dB ' \
f'or {-(max_gains[1] + PREAMP_HEADROOM):.1f} dB, respectively.'
elif len(max_gains) == 2:
preamp_str = f'When using independent subset of filters, apply preamp of ' \
f'**{-(max_gains[0] + PREAMP_HEADROOM):.1f} dB**.'
s += '''
### Parametric EQs
In case of using parametric equalizer, apply preamp of **{preamp:.1f}dB** and build filters manually
with these parameters. {max_filters_str}
{preamp_str}
{filters_table}
'''.format(
model=model,
preamp=-(max_gains[-1] + PREAMP_HEADROOM),
max_filters_str=max_filters_str,
preamp_str=preamp_str,
filters_table=filters_table_str
)
# Add fixed band eq
fixed_band_eq_path = os.path.join(dir_path, model + ' FixedBandEQ.txt')
if os.path.isfile(fixed_band_eq_path) and self.fixed_band_eq is not None and len(self.fixed_band_eq):
preamp = np.min([0.0, -np.max(self.fixed_band_eq) - PREAMP_HEADROOM])
# Read Parametric eq
with open(fixed_band_eq_path, 'r', encoding='utf-8') as f:
fixed_band_eq_str = f.read().strip()
# Filters as Markdown table
filters = []
for line in fixed_band_eq_str.split('\n'):
if line == '' or line.split()[0] != 'Filter':
continue
filter_type = line[line.index('ON') + 3:line.index('Fc') - 1]
if filter_type == 'PK':
filter_type = 'Peaking'
if filter_type == 'LS':
filter_type = 'Low Shelf'
if filter_type == 'HS':
filter_type = 'High Shelf'
fc = line[line.index('Fc') + 3:line.index('Gain') - 1]
gain = line[line.index('Gain') + 5:line.index('Q') - 1]
q = line[line.index('Q') + 2:]
filters.append([filter_type, fc, q, gain])
filters_table_str = tabulate(
filters,
headers=['Type', 'Fc', 'Q', 'Gain'],
tablefmt='orgtbl'
).replace('+', '|').replace('|-', '|:')
s += '''
### Fixed Band EQs
In case of using fixed band (also called graphic) equalizer, apply preamp of **{preamp:.1f}dB**
(if available) and set gains manually with these parameters.
{filters_table}
'''.format(
model=model,
preamp=preamp,
filters_table=filters_table_str
)
# Write image link
img_path = os.path.join(dir_path, model + '.png')
if os.path.isfile(img_path):
img_url = f'./{os.path.split(img_path)[1]}'
img_url = urllib.parse.quote(img_url, safe="%/:=&?~#+!$,;'@()*[]")
s += '''
### Graphs
![]({})
'''.format(img_url)
# Write file
with open(file_path, 'w', encoding='utf-8') as f:
f.write(re.sub('\n[ \t]+', '\n', s).strip())
@staticmethod
def generate_frequencies(f_min=DEFAULT_F_MIN, f_max=DEFAULT_F_MAX, f_step=DEFAULT_STEP):
freq = []
f = f_min
while f <= f_max:
freq.append(f)
f *= f_step
return np.array(freq)
def interpolate(self, f=None, f_step=DEFAULT_STEP, pol_order=1, f_min=DEFAULT_F_MIN, f_max=DEFAULT_F_MAX):
"""Interpolates missing values from previous and next value. Resets all but raw data."""
# Remove None values
i = 0
while i < len(self.raw):
if self.raw[i] is None:
self.raw = np.delete(self.raw, i)
self.frequency = np.delete(self.frequency, i)
else:
i += 1
# Interpolation functions
keys = 'raw error error_smoothed equalization equalized_raw equalized_smoothed target'.split()
interpolators = dict()
log_f = np.log10(self.frequency)
for key in keys:
if len(self.__dict__[key]):
interpolators[key] = InterpolatedUnivariateSpline(log_f, self.__dict__[key], k=pol_order)
if f is None:
self.frequency = self.generate_frequencies(f_min=f_min, f_max=f_max, f_step=f_step)
else:
self.frequency = np.array(f)
# Prevent log10 from exploding by replacing zero frequency with small value
zero_freq_fix = False
if self.frequency[0] == 0:
self.frequency[0] = 0.001
zero_freq_fix = True
# Run interpolators
log_f = np.log10(self.frequency)
for key in keys:
if len(self.__dict__[key]) and key in interpolators:
self.__dict__[key] = interpolators[key](log_f)
if zero_freq_fix:
# Restore zero frequency
self.frequency[0] = 0
# Everything but the interpolated data is affected by interpolating, reset them
self.reset(**{key: False for key in keys})
def center(self, frequency=1000):
"""Removed bias from frequency response.
Args:
frequency: Frequency which is set to 0 dB. If this is a list with two values then an average between the two
frequencies is set to 0 dB.
Returns:
Gain shifted
"""
equal_energy_fr = self.__class__(name='equal_energy', frequency=self.frequency.copy(), raw=self.raw.copy())