Lots of discussion about measurement, reactivity, proteus system, measurement techniques, techniques, and measurements are described in the tutorial. Inside the tutorial you can find info like neutron density, method, detector, equation, reaction rates, and flux level.
This tutorial contains things around detector efficiency, proteus, the pns measurements, neutron data, detectors, and response. Here are chosen from this tutorial:
q ( t ) = á Σ d ( v ) φ( r , v , t ñ (6.24) where the brackets indicate integration over energy and over the detector volume Now, assuming that the local ψ ( r , v, t ) and global h(t ) changes in neutron population are separable, we can write: φ ( r , v, t ) = ψ ( r , v, t ) h( t ) (6.25) in which ψ ( r , v, t ) represents the spatially dependent change in neutron population; Therefore, combining (6.24) and (6.25): q ( t ) = á Σ d ( v) ψ ( r , v, t ) ñ h( t ) 80 (6.26) or, relative to the response at critical (h(0)=1): Q( t ) ≡ q ( t ) á Σ d ψ ( r , v, t ) ñ = h( t ) q (0) áΣ d ψ ( r , v,0) ñ (6.27) more explanation in refs [6.28, 6.32] and thus N (t ) = é áΣ ψ (0) ñΛ (t ) P(t ) ù n( t ) = Q( t ) ê d ú n(0) ë áΣ dψ (t ) ñΛ (0) P(0) û (6.28) in which P( t ) ≡ áχ s Pψ ( t )ñ the total fission neutron production at time t The term in brackets in equation (6.28) is the calculated correction factor with which we correct the norma
Additionally, this tutorial explains discussion such as reactor based measurements, error, dead time, technique, and generation time.