PyWavelets 1.1.0 Release Notes¶
Contents
We are very pleased to announce the release of PyWavelets 1.1.
This release includes enhanced functionality for both the stationary wavelet
transforms (swt
, swt2
, swtn
) as well as the continuous wavelet
transform (cwt
). In addition, there are a handful of bug fixes as
described in more detail below.
This release has dropped Python 2.7 support and now requires Python >= 3.5.
In addition to these changes to the software itself, a paper describing PyWavelets was recently published in The Journal of Open Source Software: https://joss.theoj.org/papers/10.21105/joss.01237
New features¶
All
swt
functions now have a newtrim_approx
option that can be used to exclude the approximation coefficients from all but the final level of decomposition. This mode makes the output of these functions consistent with the format of the output from the correspondingwavedec
functions.All
swt
functions also now have a newnorm
option that, when set toTrue
and used in combination withtrim_approx=True
, gives a partition of variance across the transform coefficients. In other words, the sum of the variances of all coefficients is equal to the variance of the original data. This partitioning of variance makes theswt
transform more similar to the multiple-overlap DWT (MODWT) described in Percival and Walden’s book, “Wavelet Methods for Time Series Analysis”. (#476)A demo of this new
swt
functionality is available at https://github.com/PyWavelets/pywt/blob/master/demo/swt_variance.pyThe continuous wavelet transform (
cwt
) now offers an FFT-based implementation in addition to the previous convolution based one. The newmethod
argument can be set to either'conv'
or'fft'
to select between these two implementations. (#490).The
cwt
now also hasaxis
support so that CWTs can be applied in batch along any axis of an n-dimensional array. This enables faster batch transformation of signals. (#509)
Backwards incompatible changes¶
- When the input to
cwt
is single precision, the computations are now performed in single precision. This was done both for efficiency and to makecwt
handle dtypes consistently with the discrete transforms in PyWavelets. This is a change from the prior behaviour of always performing thecwt
in double precision. (#507) - When using complex-valued wavelets with the
cwt
, the output will now be the complex conjugate of the result that was produced by PyWavelets 1.0.x. This was done to account for a bug described below. The magnitude of thecwt
coefficients will still match those from previous releases. (#439)
Bugs Fixed¶
- For a
cwt
with complex wavelets, the results in PyWavelets 1.0.x releases matched the output of Matlab R2012a’scwt
. Howveer, older Matlab releases like R2012a had a phase that was of opposite sign to that given in textbook definitions of the CWT (Eq. 2 of Torrence and Compo’s review article, “A Practical Guide to Wavelet Analysis”). Consequently, the wavelet coefficients were the complex conjugates of the expected result. This was validated by comparing the results of a transform usingcmor1.0-1.0
as compared to thecwt
implementation available in Matlab R2017b as well as the functionwt.m
from the Lancaster University Physics department’s MODA toolbox. (#439) - For some boundary modes and data sizes, round-trip
dwt
/idwt
can result in an output that has one additional coefficient. Prior to this relese, this could cause a failure duringWaveletPacket
orWaveletPacket2D
reconstruction. These wavelet packet transforms have now been fixed and round-trip wavelet packet transforms always preserve the original data shape. (#448) - All inverse transforms now handle mixed precision coefficients consistently. Prior to this release some inverse transform raised an error upon encountering mixed precision dtypes in the wavelet subbands. In release 1.1, when the user-provided coefficients are a mixture of single and double precision, all coefficients will be promoted to double precision. (#450)
- A bug that caused a failure for
iswtn
when using user-providedaxes
with non-uniform shape along the transformed axes has been fixed. (#462)
Other changes¶
- The PyWavelet test suite now uses
pytest
rather thannose
. (#477) - Cython code has been updated to use
language_level=3
. (#435) - PyWavelets has adopted the SciPy Code of Conduct. (#521)
Authors¶
- Pavle Boškoski +
- Luke M Craig +
- Corey Goldberg
- Ralf Gommers
- Gregory R. Lee
- Pavle Boškoski +
- Lokesh Ravindranathan
- Alexandre Sauve +
- Arfon Smith +
- Valentin Valls +
A total of 10 people contributed to this release. People with a “+” by their names contributed a patch for the first time. This list of names is automatically generated, and may not be fully complete.
Pull requests for v1.1.0¶
- #434: Drop Python 2.7 testing on CI and update docs for Python 3.5+…
- #435: set language_level=3 for Cython
- #436: Fix deprecated import for Iterable
- #438: Fix spelling of “Garrote”
- #439: fix the phase of CWT when using complex mother wavelets
- #442: document the numpy.pad equivalent of ‘antireflect’
- #446: Spelling correction
- #448: Properly trim wavelet packet node coefficients during reconstruction
- #450: handle mixed dtype cofficients correctly across inverse transforms
- #462: fix bug in iswtn for data of arbitrary shape when using user-specified…
- #463: TST: fix misc. doctest failures (test_doc.py)
- #471: user-friendly error messages about multilevel DWT format
- #476: swt normalization and option to trim the approximation coefficients
- #477: MAINT/TST: update tests to use pytest
- #490: cwt with fft convolution support
- #495: BLD: add missing import of warnings module to setup.py
- #499: register markers for pytest 4.5 compatibility
- #502: fix docstring’s scale2frequency parameter order
- #506: Guard against trying to transform along size 0 axes
- #507: preserve single precision in CWT
- #509: add axis support to cwt
- #510: add demo using swt with norm=True to analyze variance across…
- #511: MAINT: split bundled licenses into a separate file
- #514: Small typo in the doc
- #516: Fix docstrings to avoid sphinx warnings
- #521: DOC: adopt the SciPy Code of Conduct