# Numpy high precision

I am using numpy and pyfits to manipulate spectra and I require high precision (something like 8-10 decimal places on a value which might go as high as 10^12). For that the data type "decimal" would be perfect (float64 is not good enough), but unfortunalely numpy.interp does not like it:

``````File ".../modules/manip_fits.py", line 47, in get_shift
pix_shift = np.interp(x, xp, fp)-fp
File "/usr/lib/python2.7/dist-packages/numpy/lib/function_base.py", line 1053, in interp
return compiled_interp(x, xp, fp, left, right)
TypeError: array cannot be safely cast to required type
``````

A simplified version of the code I use:

``````fp = np.array(range(new_wave.shape[-1]),dtype=Decimal)
pix_shift = np.empty_like(wave,dtype=Decimal)
x = wave
xp = new_wave
pix_shift = np.interp(x, xp, fp)-fp
``````

where 'wave' and 'new_wave' are a one-dimension numpy array representing a 1D spectrum. This code is needed to shift my spectra along the x-axis (which is wavelenght)

My biggest issue is that further down the code I divide my spectra by a template spectrum constructed from the sum of all my spectra in order to analyse the differences and since I do not have enough decimal places I am getting rounding errors. Any ideas?

Thanks!

UPDATE:

Test Example:

``````import numpy as np
from decimal import *
getcontext().prec = 12

wave = np.array([Decimal(xx*np.pi) for xx in range(0,10)],dtype=np.dtype(Decimal))
new_wave = np.array([Decimal(xx*np.pi+0.5) for xx in range(0,10)],dtype=np.dtype(Decimal))

fp = np.array(range(new_wave.shape[-1]),dtype=Decimal)
pix_shift = np.empty_like(wave,dtype=Decimal)

x = wave
xp = new_wave
pix_shift = np.interp(x, xp, fp)-fp
``````

The error is:

``````Traceback (most recent call last):
File "untitled.py", line 16, in <module>
pix_shift = np.interp(x, xp, fp)-fp
File "/usr/lib/python2.7/dist-packages/numpy/lib/function_base.py", line 1053, in interp
return compiled_interp(x, xp, fp, left, right)
TypeError: array cannot be safely cast to required type
``````

this is the closest I can provide without using the real spectra in fits format.

UPDATE 2: Some typical values of my spectra, printed using Decimal:

``````  18786960689.118938446044921875
18473926205.282184600830078125
18325454516.792461395263671875
18400241010.149127960205078125
2577901751996.03857421875
2571812230557.63330078125
2567431795280.80712890625
``````

the problem I am getting is when I make operations between them, I get rounding up errors. For instance, I create a template for all spectra by summing all of them. Then I use this template to normalize every spectra. An example:

``````Spectra = np.array([Spectrum1, Spectrum2, ...])
Template = np.nansum(Spectra, axis= 0)

NormSpectra = Spectra/Template
``````

This should return me only the noise on the spectra (assuming that the template is a good representation of the star). I tried normalizing each spectrum to its total flux

``````(Spectrum1 = Spectrum1/np.nansum(Spectrum1), ...)
``````

as well as the template, but would get even worse rounding up errors.

Using Decimal would work fine for me, but I need to "shift" my spectra so all spectral features/lines are aligned.

Hope this makes sense?

-
Have you tried using `numpy.longdouble` as a dtype? mail.scipy.org/pipermail/scipy-dev/2008-March/008562.html –  Zhenya May 15 '13 at 15:27
"something like 8-10 decimal places on a value which might go as high as 10^12" could be problematic for float32, but it's far from the limits of float64. Can you post an example showing how float64 is not enough? You could try scaling your problem too. –  jorgeca May 15 '13 at 17:31
Decimal is not a numpy dtype object or convertable to one, so you will never be able to use it as a dtype. What Numpy is doing is seeing 'oh, you provided an arbitrary class, better create a Python-Object array`. Which works okay, until you have to cast back to a NumPy datatype to do the calculation.I get a more useful error message from your code, which is `TypeError: Cannot cast array data from dtype('O') to dtype('float64') according to the rule 'safe'`. It supports this theory. I would be quite surprised if scipy.interp1d worked for this object-array you created either, since an array of.. –  kampu May 15 '13 at 23:33
.. since an array of dtype 'O' is not considered as a numeric type, and NumPy will not attempt to perform numeric calculations with it. –  kampu May 15 '13 at 23:34
I'm sorry but I don't know how to reproduce your rounding errors from the data you provided. By the way, did you try whether the extra bits of `dtype=np.longdouble` are enough? Also, mpmath could be interesting for you (it's a library for multiprecision floating-point arithmetic in pure Python than can also use fast compiled backends). –  jorgeca May 16 '13 at 10:36

How can you be sure `np.float64`? In typical usecases, one can expect ~15 significant figures from a double.
If you are sure that this is not enough, you can try `np.float128` (aka `np.longdouble`).