Penetration and Diffusion of X Rays

“…We can follow reference [6] farther by defining an "error build-up" function Eb (z), 2 See Appendix B for a discussion of the automatic exclusion of functions having all moments zero.…”

“…was derived from the differential equation, using eq (17.16'), both given on p. 744 of reference [2]. The recursion approach eventually breaks down, particularly for large values of k; hut with suitable restrictions, and depending somewhat on the size of the argument z, 30-40 terms gives accurate results.…”

“…In the moment me thod of calculating space distributions in radiation trans port theory, spatial moments defined by n. -x (I') are evaluated by numerical integration of a re cursive system of Volterra integral equations of the second kind [1 , 2),1 For any of several re asons , one frequently encounters the problem of constructing distributions by use of alternate, rather than consecutive moments [2,5] . Because spatial trends, are basically exponential, this leads to the possibility of representations in a family of biorthonormal systems of polynomials U~(z) , with adjoint polynomials U~(z) , satisfying the condition rX dzz"e-Z{;A·(z)Uk (z) = 011111 ,…”

“…Existence of these problems led very early to use of nonlinear approximations which were designated "function-fitting" methods , in which the individual terms in an approximating series have the same functional form, with differing weight and differing scale factor [2]. While very useful, and in good agreement with the more basic polynomial representation, these methods have the limitation that it is difficult to assess their accuracy.…”

Plural-series approximations of functions

“…We can follow reference [6] farther by defining an "error build-up" function Eb (z), 2 See Appendix B for a discussion of the automatic exclusion of functions having all moments zero.…”

“…was derived from the differential equation, using eq (17.16'), both given on p. 744 of reference [2]. The recursion approach eventually breaks down, particularly for large values of k; hut with suitable restrictions, and depending somewhat on the size of the argument z, 30-40 terms gives accurate results.…”

“…In the moment me thod of calculating space distributions in radiation trans port theory, spatial moments defined by n. -x (I') are evaluated by numerical integration of a re cursive system of Volterra integral equations of the second kind [1 , 2),1 For any of several re asons , one frequently encounters the problem of constructing distributions by use of alternate, rather than consecutive moments [2,5] . Because spatial trends, are basically exponential, this leads to the possibility of representations in a family of biorthonormal systems of polynomials U~(z) , with adjoint polynomials U~(z) , satisfying the condition rX dzz"e-Z{;A·(z)Uk (z) = 011111 ,…”

“…Existence of these problems led very early to use of nonlinear approximations which were designated "function-fitting" methods , in which the individual terms in an approximating series have the same functional form, with differing weight and differing scale factor [2]. While very useful, and in good agreement with the more basic polynomial representation, these methods have the limitation that it is difficult to assess their accuracy.…”

Plural-series approximations of functions

“…There is an important class of radiation transport problems for which it is feasible to calculate spatial moments (I') by numerical integration of a recursive system of Volterra integral equations of the second kind [1,2].1 A detailed description of the proce,'ure for obtaining and evaluating these equations is not pertinent to the discussion here; but it is important that accurate calculation is feasible only for a limited number of the moments, say 6 to 10.…”

Bounds to truncation errors in biorthogonal polynomial approximations, with illustrative applications to gamma ray transport distributions

X‐Ray Quantum Cutting Scintillator Based on CsPbCl_xBr_3−x:Yb³⁺ Single Crystals