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| author | tlatorre <tlatorre@uchicago.edu> | 2018-08-14 09:53:09 -0500 |
|---|---|---|
| committer | tlatorre <tlatorre@uchicago.edu> | 2018-08-14 09:53:09 -0500 |
| commit | 0b7f199c0d93074484ea580504485a32dc29f5e2 (patch) | |
| tree | e167b6d102b87b7a5eca4558e7f39265d5edc502 /mt19937ar.h | |
| parent | 636595905c9f63e6bfcb6d331312090ac2075377 (diff) | |
| download | sddm-0b7f199c0d93074484ea580504485a32dc29f5e2.tar.gz sddm-0b7f199c0d93074484ea580504485a32dc29f5e2.tar.bz2 sddm-0b7f199c0d93074484ea580504485a32dc29f5e2.zip | |
initial commit of likelihood fit for muons
This commit contains code to fit for the energy, position, and direction of
muons in the SNO detector. Currently, we read events from SNOMAN zebra files
and fill an event struct containing the PMT hits and fit it with the Nelder
Mead simplex algorithm from GSL.
I've also added code to read in ZEBRA title bank files to read in the DQXX
files for a specific run. Any problems with channels in the DQCH and DQCR banks
are flagged in the event struct by masking in a bit in the flags variable and
these PMT hits are not included in the likelihood calculation.
The likelihood for an event is calculated by integrating along the particle
track for each PMT and computing the expected number of PE. The charge
likelihood is then calculated by looping over all possible number of PE and
computing:
P(q|n)*P(n|mu)
where q is the calibrated QHS charge, n is the number of PE, and mu is the
expected number of photoelectrons. The latter is calculated assuming the
distribution of PE at a given PMT follows a Poisson distribution (which I think
should be correct given the track, but is probably not perfect for tracks which
scatter a lot).
The time part of the likelihood is calculated by integrating over the track for
each PMT and calculating the average time at which the PMT is hit. We then
assume the PDF for the photons to arrive is approximately a delta function and
compute the first order statistic for a given time to compute the probability
that the first photon arrived at a given time. So far I've only tested this
with single tracks but the method was designed to be easy to use when you are
fitting for multiple particles.
Diffstat (limited to 'mt19937ar.h')
| -rw-r--r-- | mt19937ar.h | 30 |
1 files changed, 30 insertions, 0 deletions
diff --git a/mt19937ar.h b/mt19937ar.h new file mode 100644 index 0000000..d544847 --- /dev/null +++ b/mt19937ar.h @@ -0,0 +1,30 @@ +#ifndef MT19937AR_H +#define MT19937AR_H + +void init_genrand(unsigned long s); + +/* initialize by an array with array-length */ +/* init_key is the array for initializing keys */ +/* key_length is its length */ +/* slight change for C++, 2004/2/26 */ +void init_by_array(unsigned long init_key[], int key_length); + +/* generates a random number on [0,0xffffffff]-interval */ +unsigned long genrand_int32(void); + +/* generates a random number on [0,0x7fffffff]-interval */ +long genrand_int31(void); + +/* generates a random number on [0,1]-real-interval */ +double genrand_real1(void); + +/* generates a random number on [0,1)-real-interval */ +double genrand_real2(void); + +/* generates a random number on (0,1)-real-interval */ +double genrand_real3(void); + +/* generates a random number on [0,1) with 53-bit resolution*/ +double genrand_res53(void) ; + +#endif |