Difference between revisions of "Result estimators"

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(Analog estimators)
(Analog estimators)
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*Thermal neutron absorption in coolant -- count the number of neutrons absorbed in the coolant with energy in the thermal region (integration over specific volume and energy)
 
*Thermal neutron absorption in coolant -- count the number of neutrons absorbed in the coolant with energy in the thermal region (integration over specific volume and energy)
 
*Total fission rate as function of time -- count the number of fissions, and place the results in successive bins depending on the time of the event (integration over specific time)
 
*Total fission rate as function of time -- count the number of fissions, and place the results in successive bins depending on the time of the event (integration over specific time)
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These examples also illustrate the fact the results are always integrated
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over the variables.
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== Implicit estimators ==
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Implicit estimators

Revision as of 16:26, 19 November 2015

The Monte Carlo transport simulation is run to obtain statistical estimates for integrals of the form:

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where $f$ is a response function that can be evaluated at an arbitrary position of the phase space, most typically a reaction cross section. These estimates are based on the collection of simulated events (collisions, track-lengths, surface crossings, etc.) that occur during the course of the simulated random walk.

The estimates can be divided into:

  1. Analog estimates, based on recorded simulated physical events
  2. Implicit estimators, based the expected frequency of events

Implicit estimators are derived from analog estimators, with the purpose of obtaining better statistics.

Analog estimators

Analog estimates are the most straightforward way to obtain physical results from the Monte Carlo transport simulation. Each particle history consists of a number of events containing relevant information on the transport process, which can be counted as-is, for example:

  • Collisions
  • Sampled reactions
  • Crossed surfaces
  • Neutrons emitted in fission

The integration domain is defined by separating the scores into different bins based on particle position, energy and time (and direction of motion). For example:

  • Fission rate in a specific fuel pin -- count the number of simulated fission events in that fuel pin (integration over specific volume)
  • Thermal neutron absorption in coolant -- count the number of neutrons absorbed in the coolant with energy in the thermal region (integration over specific volume and energy)
  • Total fission rate as function of time -- count the number of fissions, and place the results in successive bins depending on the time of the event (integration over specific time)

These examples also illustrate the fact the results are always integrated over the variables.

Implicit estimators

Implicit estimators