poisson_conf_interval¶

astropy.stats.
poisson_conf_interval
(n, interval='rootn', sigma=1, background=0, confidence_level=None)[source]¶ Poisson parameter confidence interval given observed counts
 Parameters
 nint or numpy.ndarray
Number of counts (0 <=
n
). interval{‘rootn’,’rootn0’,’pearson’,’sherpagehrels’,’frequentistconfidence’, ‘kraftburrowsnousek’}, optional
Formula used for confidence interval. See notes for details. Default is
'rootn'
. sigmafloat, optional
Number of sigma for confidence interval; only supported for the ‘frequentistconfidence’ mode.
 backgroundfloat, optional
Number of counts expected from the background; only supported for the ‘kraftburrowsnousek’ mode. This number is assumed to be determined from a large region so that the uncertainty on its value is negligible.
 confidence_levelfloat, optional
Confidence level between 0 and 1; only supported for the ‘kraftburrowsnousek’ mode.
 Returns
 conf_intervalnumpy.ndarray
conf_interval[0]
andconf_interval[1]
correspond to the lower and upper limits, respectively, for each element inn
.
Notes
The “right” confidence interval to use for Poisson data is a matter of debate. The CDF working group recommends using rootn throughout, largely in the interest of comprehensibility, but discusses other possibilities. The ATLAS group also discusses several possibilities but concludes that no single representation is suitable for all cases. The suggestion has also been floated that error bars should be attached to theoretical predictions instead of observed data, which this function will not help with (but it’s easy; then you really should use the square root of the theoretical prediction).
The intervals implemented here are:
1. ‘rootn’ This is a very widely used standard rule derived from the maximumlikelihood estimator for the mean of the Poisson process. While it produces questionable results for small n and outright wrong results for n=0, it is standard enough that people are (supposedly) used to interpreting these wonky values. The interval is
\[CI = (n\sqrt{n}, n+\sqrt{n})\]2. ‘rootn0’ This is identical to the above except that where n is zero the interval returned is (0,1).
3. ‘pearson’ This is an onlyslightlymorecomplicated rule based on Pearson’s chisquared rule (as explained by the CDF working group). It also has the nice feature that if your theory curve touches an endpoint of the interval, then your data point is indeed one sigma away. The interval is
\[CI = (n+0.5\sqrt{n+0.25}, n+0.5+\sqrt{n+0.25})\]4. ‘sherpagehrels’ This rule is used by default in the fitting package ‘sherpa’. The documentation claims it is based on a numerical approximation published in Gehrels (1986) but it does not actually appear there. It is symmetrical, and while the upper limits are within about 1% of those given by ‘frequentistconfidence’, the lower limits can be badly wrong. The interval is
\[CI = (n1\sqrt{n+0.75}, n+1+\sqrt{n+0.75})\]5. ‘frequentistconfidence’ These are frequentist central confidence intervals:
\[CI = (0.5 F_{\chi^2}^{1}(\alpha;2n), 0.5 F_{\chi^2}^{1}(1\alpha;2(n+1)))\]where \(F_{\chi^2}^{1}\) is the quantile of the chisquare distribution with the indicated number of degrees of freedom and \(\alpha\) is the onetailed probability of the normal distribution (at the point given by the parameter ‘sigma’). See Maxwell (2011) for further details.
6. ‘kraftburrowsnousek’ This is a Bayesian approach which allows for the presence of a known background \(B\) in the source signal \(N\). For a given confidence level \(CL\) the confidence interval \([S_\mathrm{min}, S_\mathrm{max}]\) is given by:
\[CL = \int^{S_\mathrm{max}}_{S_\mathrm{min}} f_{N,B}(S)dS\]where the function \(f_{N,B}\) is:
\[f_{N,B}(S) = C \frac{e^{(S+B)}(S+B)^N}{N!}\]and the normalization constant \(C\):
\[C = \left[ \int_0^\infty \frac{e^{(S+B)}(S+B)^N}{N!} dS \right] ^{1} = \left( \sum^N_{n=0} \frac{e^{B}B^n}{n!} \right)^{1}\]See Kraft, Burrows, and Nousek (1991) for further details.
These formulas implement a positive, uniform prior. Kraft, Burrows, and Nousek (1991) discuss this choice in more detail and show that the problem is relatively insensitive to the choice of prior.
This function has an optional dependency: Either Scipy or mpmath need to be available (Scipy works only for N < 100). This code is very intense numerically, which makes it much slower than the other methods, in particular for large count numbers (above 1000 even with
mpmath
). Fortunately, some of the other methods or a Gaussian approximation usually work well in this regime.Examples
>>> poisson_conf_interval(np.arange(10), interval='rootn').T array([[ 0. , 0. ], [ 0. , 2. ], [ 0.58578644, 3.41421356], [ 1.26794919, 4.73205081], [ 2. , 6. ], [ 2.76393202, 7.23606798], [ 3.55051026, 8.44948974], [ 4.35424869, 9.64575131], [ 5.17157288, 10.82842712], [ 6. , 12. ]])
>>> poisson_conf_interval(np.arange(10), interval='rootn0').T array([[ 0. , 1. ], [ 0. , 2. ], [ 0.58578644, 3.41421356], [ 1.26794919, 4.73205081], [ 2. , 6. ], [ 2.76393202, 7.23606798], [ 3.55051026, 8.44948974], [ 4.35424869, 9.64575131], [ 5.17157288, 10.82842712], [ 6. , 12. ]])
>>> poisson_conf_interval(np.arange(10), interval='pearson').T array([[ 0. , 1. ], [ 0.38196601, 2.61803399], [ 1. , 4. ], [ 1.69722436, 5.30277564], [ 2.43844719, 6.56155281], [ 3.20871215, 7.79128785], [ 4. , 9. ], [ 4.8074176 , 10.1925824 ], [ 5.62771868, 11.37228132], [ 6.45861873, 12.54138127]])
>>> poisson_conf_interval( ... np.arange(10), interval='frequentistconfidence').T array([[ 0. , 1.84102165], [ 0.17275378, 3.29952656], [ 0.70818544, 4.63785962], [ 1.36729531, 5.91818583], [ 2.08566081, 7.16275317], [ 2.84030886, 8.38247265], [ 3.62006862, 9.58364155], [ 4.41852954, 10.77028072], [ 5.23161394, 11.94514152], [ 6.05653896, 13.11020414]])
>>> poisson_conf_interval( ... 7, interval='frequentistconfidence').T array([ 4.41852954, 10.77028072])
>>> poisson_conf_interval( ... 10, background=1.5, confidence_level=0.95, ... interval='kraftburrowsnousek').T array([[ 3.47894005, 16.113329533]])