# Tag Info

22

There is no need to write your own parser if you're willing to transform S in to a string suitable for use with eval(). Change S from '(A or B) and not(A and C)' into an equivalent T that uses Python's in-operator '(x in A or x in B) and not(x in A and x in C)'. Compute the result by looping over the universe of elements and testing whether they match the ...

16

One way to do this quickly is by convolution with the derivative of a gaussian kernel. The simple case is a convolution of your array with [-1, 1] which gives exactly the simple finite difference formula. Beyond that, (f*g)'= f'*g = f*g' where the * is convolution, so you end up with your derivative convolved with a plain gaussian, so of course this will ...

15

If you are interested in a "smooth" version of a signal that is periodic (like your example), then a FFT is the right way to go. Take the fourier transform and subtract out the low-contributing frequencies: import numpy as np import scipy.fftpack N = 100 x = np.linspace(0,2*np.pi,N) y = np.sin(x) + np.random.random(N) * 0.2 w = scipy.fftpack.rfft(y) f = ...

14

Calling BLAS bundled with Scipy is "fairly" straightforward, here's one example for calling DGEMM to compute matrix multiplication: https://gist.github.com/pv/5437087 Note that BLAS and LAPACK expect all arrays to be Fortran-contiguous (modulo the lda/b/c parameters), hence order="F" and double[::1,:] which are required for correct functioning. Computing ...

14

Sure! There are two options that do different things but both exploit the regularly-gridded nature of the original data. The first is scipy.ndimage.zoom. If you just want to produce a denser regular grid based on interpolating the original data, this is the way to go. The second is scipy.ndimage.map_coordinates. If you'd like to interpolate a few (or ...

14

A NumPy scalar is any object which is an instance of np.generic or whose type is in np.ScalarType: In [12]: np.ScalarType Out[13]: (int, float, complex, long, bool, str, unicode, buffer, numpy.int16, numpy.float16, numpy.int8, numpy.uint64, numpy.complex192, numpy.void, numpy.uint32, numpy.complex128, numpy.unicode_, numpy.uint32, ...

13

There are several alternative tools for converting Python code to Matlab code (not tested yet): Small Matlab to Python compiler: convert Matlab code to Python code, also developed here: SMOP@chiselapp LiberMate: translate from Matlab to Python and SciPy OMPC: Matlab to Python (a bit outdated) Matlab to Python conversion: No download files available Also, ...

12

Based on your description, you want scipy.ndimage.zoom. Bilinear interpolation would be order=1, nearest is order=0, and cubic is the default (order=3). zoom is specifically for regularly-gridded data that you want to resample to a new resolution. As a quick example: import numpy as np import scipy.ndimage x = np.arange(9).reshape(3,3) print 'Original ...

12

I think it would be simpler to use numpy.polyfit, which performs Least squares polynomial fit. This is a simple snippet: import numpy as np x = np.array([0,1,2,3,4,5]) y = np.array([2.1, 2.9, 4.15, 4.98, 5.5, 6]) z = np.polyfit(x, y, 1) p = np.poly1d(z) #plotting import matplotlib.pyplot as plt xp = np.linspace(-1, 6, 100) plt.plot(x, y, '.', xp, p(xp)) ...

11

I'm still coming to terms with the Python ecosystem and PyCharm, so take the following with a grain of salt, but after reading up a bit, I thought I'd write a detailed explanation. During installation, Anaconda changes the default Python interpreter to ~/anaconda/bin/python. This interpreter is configured with a sys.path that defaults to the libraries in ...

11

There are two ways to do this. Use a non-linear solver Linearize the problem and solve it in the least-squares sense Setup So, as I understand your question, you know F, a, b, and c at 4 different points, and you want to invert for the model parameters X, Y, and Z. We have 3 unknowns and 4 observed data points, so the problem is overdetermined. ...

10

scipy.linalg.cholesky is giving you the upper-triangular decomposition by default, whereas np.linalg.cholesky is giving you the lower-triangular version. From the docs for scipy.linalg.cholesky: cholesky(a, lower=False, overwrite_a=False) Compute the Cholesky decomposition of a matrix. Returns the Cholesky decomposition, :math:`A = L L^*` or ...

10

The simplest way would be to first replace infs to NaN: df.replace([np.inf, -np.inf], np.nan) and then use the dropna: df.replace([np.inf, -np.inf], np.nan).dropna(subset=["col1", "col2"], how="all") For example: In [11]: df = pd.DataFrame([1, 2, np.inf, -np.inf]) In [12]: df.replace([np.inf, -np.inf], np.nan) Out[12]: 0 0 1 1 2 2 NaN 3 NaN ...

10

scipy.io.savemat or scipy.io.loadmat does NOT work for matlab arrays --v7.3. But the good part is that matlab --v7.3 files are hdf5 datasets. So they can be read using a number of tools, including numpy. For python, you will need the h5py extension, which requires HDF5 on your system. import numpy as np, h5py f = h5py.File('somefile.mat','r') data = ...

10

A minor edit to answer your question about 2d: You can use the original answer below, just take: data = np.column_stack([x,y]) If you want to plot the centroids, it is the same as below in the original answer. If you want to color each value by the group selected, you can use kmeans2 from scipy.cluster.vq import kmeans2 centroids, ks = kmeans2(data, 3, ...

9

Numerical algorithms tend to work better when not fed extremely small (or large) numbers. In this case, the graph shows your data has extremely small x and y values. If you scale them, the fit is remarkable better: xData = np.load('xData.npy')*10**5 yData = np.load('yData.npy')*10**5 from __future__ import division import os ...

9

Oh, this is cute. From the scipy __init__.py: # Emit a warning if numpy is too old majver, minver = [float(i) for i in _num.version.version.split('.')[:2]] In Python 2, list comprehensions "leak" their loop variables into the enclosing scope. And thus: >>> import numpy as _num >>> _num.version.version '1.6.2' >>> ...

9

Python lists and high performance math are incompatible, forget about cython_list_matmul. The only problem with your cython_array_matmul is incorrect usage of indexing. It should be C[i,k] += A[i,j] * B[j,k] That's how numpy arrays are indexed in Python and that's the syntax Cython optimizes. With this change you should get decent performance. Cython's ...

9

A generic code to do this would do something as follows: def average_values_bis(x, y): unq_x, idx = np.unique(x, return_inverse=True) count_x = np.bincount(idx) sum_y = np.bincount(idx, weights=y) return unq_x, sum_y / count_x Adding the function above and following line for the plotting to your script plt.plot(*average_values_bis(times, ...

9

I suggest you to start with simple polynomial fit, scipy.optimize.curve_fit tries to fit a function f that you must know to a set of points. This is a simple 3 degree polynomial fit using numpy.polyfit and poly1d, the first performs a least squares polynomial fit and the second calculates the new points: import numpy as np import matplotlib.pyplot as plt ...

8

np.random.permutation has two differences from np.random.shuffle: if passed an array, it will return a shuffled copy of the array; np.random.shuffle shuffles the array inplace if passed an integer, it will return a shuffled range i.e. np.random.shuffle(np.arange(n)) If x is an integer, randomly permute np.arange(x). If x is an array, make a copy and ...

8

From your mailing list link: because the one-sided tests can be backed out from the two-sided tests. (With symmetric distributions one-sided p-value is just half of the two-sided pvalue) It goes on to say that scipy always gives the test statistic as signed. This means that given p and t values from a two-tailed test, you would reject the null ...

8

You can use map_coordinates with a little bit of algebra. Lets say the spacings of your grid are dx, dy and dz. We need to map these real world coordinates to array index coordinates, so lets define three new variables: xx = x / dx yy = y / dy zz = z / dz The array index input to map_coordinates is an array of shape (d, ...) where d is the number of ...

8

AFAIK the closest you can get is to use &, |, and ^: >>> arr = np.array([1, 2, 1, 2, 3, 6, 9]) >>> (2 < arr) & (arr < 6) array([False, False, False, False, True, False, False], dtype=bool) >>> (2 < arr) | (arr < 6) array([ True, True, True, True, True, True, True], dtype=bool) >>> (2 < arr) ^ ...

8

The method numpy.__config__.show() outputs information about linkage gathered at build time. My output looks like this. I think it means I am using the BLAS/LAPACK that ships with Mac OS. >>>import numpy as np >>>np.__config__.show() lapack_opt_info: extra_link_args = ['-Wl,-framework', '-Wl,Accelerate'] extra_compile_args = ...

8

You're almost there, you just need to combine ndimage.label with numpy.bincount: import numpy as np from scipy import ndimage array = np.random.randint(0, 3, size=(200, 200)) label, num_label = ndimage.label(array == 0) size = np.bincount(label.ravel()) biggest_label = size[1:].argmax() + 1 clump_mask = label == biggest_label Once you have clump_mask ...

7

Just generate numbers over the range you want (0...10 in this case) >>> import random >>> nums = [10*random.random() for x in range(5)] Work out the average >>> sum(nums)/len(nums) 4.2315222659844824 Shift the average to where you want it >>> nums = [x - 4.2315222659844824 + 2.5 for x in nums] >>> nums ...

7

I highly recommend getting all of the components of Scipy-stack, which is just below the scipy files linked in the comment above. Unfortunately the maintainer hasn't updated scipy-stack to 3.3 yet (I emailed him about it), but all of the components (numpy-MKL, scipy, matplotlib, ipython, pandas, sympy, and nose), as well as all the dependencies ...

7

You can gain a factor of about 10 in speed by using Cython, see below: In [87]: %timeit cythonmodule.doit(lam=lam, y0=y0, zxp=zxp, z=z, k=k, ra=ra) 1 loops, best of 3: 501 ms per loop In [85]: %timeit doit() 1 loops, best of 3: 4.97 s per loop This is probably not enough, and the bad news is that this is probably quite close (maybe factor of 2 at most) to ...

7

As you've shown, you can write this as a system of six first-order ode's: x' = x2 y' = y2 z' = z2 x2' = -mu / np.sqrt(x ** 2 + y ** 2 + z ** 2) * x y2' = -mu / np.sqrt(x ** 2 + y ** 2 + z ** 2) * y z2' = -mu / np.sqrt(x ** 2 + y ** 2 + z ** 2) * z You can save this as a vector: u = (x, y, z, x2, y2, z2) and thus create a function that returns its ...

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