I had the same problem as you. To solve it, I wrote two custom Sklearn transformers (see below). As I am still a beginner, the implementation may not be 100% accurate.
Information about my dataset: I have a dataset with time series data. Each row of my dataset corresponds to a time series. With the fm_cwt_transform_into_scalogramm
class, I convert each row of my dataset using pywt.cwt
with a single wavelet. With fm_transform_into_image
, I convert the data that was transformed with fm_cwt_transform_into_scalogramm
into an image with 4 channels.
Please note: After transforming the data with fm_cwt_transform_into_scalogramm
, you should normalize the transformed data, I believe. I did this with my custom Sklearn transformer fm_normalize
.
The fm_cwt_transform_into_scalogramm
Sklearn Transformer:
class fm_cwt_transform_into_scalogramm(BaseEstimator, TransformerMixin):
def __init__(self, wavelet, motherwavelet_is_complex, scale_bis=None):
# motherwavelet_is_complex == "reel" oder "komplex" --> z.B. mexh=komplex (set motherwavelet_is_complex=True); gaus=reel (set motherwavelet_is_complex=False)
self.scale_bis = scale_bis # ACHTUNG: MUSS EIN SKALAR sein!!!!!!!!
self.wavelet = wavelet
self.motherwavelet_is_complex= motherwavelet_is_complex
def fit(self, X, y=None):
return self
def transform(self, X, y=None):
if not isinstance(X, np.ndarray):
X = np.array(X)
if X.ndim < 2:
raise ValueError("Input data must have at least two dimensions.")
if self.scale_bis is None:
self.scale_bis=X.shape[1]+1 #damit hat scalogramm gleich höhe und breite; X.shape[1]=X-achselänge; self.scale_bis=Y-achselänge
return_coefs = np.empty(shape=(X.shape[0],X.shape[1], self.scale_bis-1))
if self.motherwavelet_is_complex:
for sample_index in range(X.shape[0]):
coef, _ = cwt(X[sample_index,:], np.arange(1,self.scale_bis), self.wavelet)
return_coefs[sample_index] = np.abs(coef)
else:
for sample_index in range(X.shape[0]):
return_coefs[sample_index], _ = cwt(X[sample_index,:], np.arange(1,self.scale_bis), self.wavelet)
return return_coefs
The "fm_transform_into_image" Sklearn Transformer:
class fm_transform_into_image(BaseEstimator, TransformerMixin):
# ACHTUNG!!: Die Daten müssen davor mit fm_normalizer normalisiert werden.
def __init__(self, colormap, scale_bis=None):
self.colormap = colormap
self.scale_bis = scale_bis # muss den selben wert wie bei fm_cwt_transform_into_scalogramm haben
def fit(self, X, y=None):
return self
def transform(self, X, y=None): # X sind die cwt transformeireten Daten
if not isinstance(X, np.ndarray):
X = np.array(X)
if X.ndim < 2:
raise ValueError("Input data must have at least two dimensions.")
if self.scale_bis is None:
self.scale_bis=X.shape[1]+1 #damit hat scalogramm gleich höhe und breite; X.shape[1]=X-achselänge; self.scale_bis=Y-achselänge
return_image = np.empty(shape=(X.shape[0],X.shape[1], self.scale_bis-1, 4))
for sample_index in range(X.shape[0]):
return_image[sample_index] = ScalarMappable(cmap=self.colormap, norm = NoNorm()).to_rgba(X[sample_index])
return return_image
The "fm_normalizer" Sklearn Transformer:
class fm_normalizer(BaseEstimator, TransformerMixin):
def __init__(self):
self.min = None
self.max = None
def fit(self, X, y=None):
self.min = np.min(X)
self.max = np.max(X)
return self
def transform(self, X, y=None):
return (X - self.min) / (self.max - self.min)
My Sklearn pipeline for fully transforming my data into an image looks as follows:
transf_into_image_pipeline = make_pipeline(
fm_cwt_transform_into_scalogramm(wavelet="gaus2", motherwavelet_is_complex=False),
fm_normalizer(),
fm_transform_into_image(colormap="Pastel2"))