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Radiation detection and measurement
A finite element method for neutron transport If there is no upscattering, i.e. o,. = 0 for m > n the multigroup equations can be solved sequentially starting with n = N. Then the source term becomes
o~(i, f l ' . l ~ ) =
,~ a , ( i , f¥ •f~) ~bo,(r, fy) d.Q'.
(7)
re+n+ 1
By defining even O~,(r, £1) and odd Oo.(r, 11) parity fluxes; the even parity equations can be generalized (Ackroyd, 1978):
= S,+(r,11) - 11. VG, S;-(r,~),
v . 1 1 , L ( r , a ) + ~.(i)4,~;.(r, f~) = f n o,~(i, fl'.l~)~.(r,f¥)d.Q' + S~(r, fl),
(8)
+ fR d11' n-1 ~ o.(i,11"fl)~0.(r, f l ' ) d ~ ' . '
C~(r, ~ ) = o,(i)u(r, 1"1)
- fa,
a'. a)u(r, a') da',
~b~-(r, 11)--- ½{~,(r, 11) - ~n(r, - fl)},
= ½{o.n(i, a ' . a ) (9)
where, in general, on(i, 1"1"11') is the solution of
l'L V *-(~o ,(r,l ))4 -
o.(i)2
fT.(i)
C (~n(r, ~) = S~ + (r, ~),
a . V* ÷ ~;, (r, a ) - G- 1 ~ -
(r, a ) = s~ - (,, a).
(16) Note that the sign of the leakage operator has been changed. From the above equations it is possible to derive the even parity adjoint equation.
~;,(~, a . a')
fn g'(i'trt~') o;,(t~ • 11") d ~ " ,
a.v{G,(a.v~,+(r,a)} (11)
+ c, ~,+ (,, a)
-- S*+(r,a) + f L V G , S~',(r, I)). (17)
Table 1. Positive definite leakage and removal operators in plane geometry (where o~., is the Ith Legendre polynomial expansion of the scattering cross section and P ~ ) are the Legendre polynomials) ],/ N
G.
c.{,
(15)
and using similar definitions for S~n+(v,~) and Sn*-(v,l~); the even parity adjoint equations are obtained.
G.u(r, 11) = u(r, ~_~) Jr fn on(i, ~" 11')u(r, 1~') d£~', ~,(i) ... (1o)
,,
(14)
m=O
Defining even and odd adjoint parity fluxes
+ o,,(i,a'.~)},
+
(13)
S*,(r, 11) = S~(r, 11)
follows.
g~(i, [~. f¥) =
(12)
The adjoint multi-group equations can be written as
where the operators C. and G. are defined as
a.a')
- ~r,(i, - 11'.a)}.
where
a - V{G,fl. V4~'.(r, 11)} + C , ~ , ( r , fl)
~:n(i,
½{o,(i, f l ' . a )
2.2 The even parity adjoint equations
N
-
with,
To illustrate the theory Table 1 lists operators of the transport equation for infinite slabs.
S.(r, ¢~) = S,,(r, t~) + fa, dfl' x
337
-°'- 1 _ ~41+ 1 (o..-1
)
l
x
}
t ~ P21+l(#') d~'
o~(i, f l ' . l ~ ) =
,~ a , ( i , f¥ •f~) ~bo,(r, fy) d.Q'.
(7)
re+n+ 1
By defining even O~,(r, £1) and odd Oo.(r, 11) parity fluxes; the even parity equations can be generalized (Ackroyd, 1978):
= S,+(r,11) - 11. VG, S;-(r,~),
v . 1 1 , L ( r , a ) + ~.(i)4,~;.(r, f~) = f n o,~(i, fl'.l~)~.(r,f¥)d.Q' + S~(r, fl),
(8)
+ fR d11' n-1 ~ o.(i,11"fl)~0.(r, f l ' ) d ~ ' . '
C~(r, ~ ) = o,(i)u(r, 1"1)
- fa,
a'. a)u(r, a') da',
~b~-(r, 11)--- ½{~,(r, 11) - ~n(r, - fl)},
= ½{o.n(i, a ' . a ) (9)
where, in general, on(i, 1"1"11') is the solution of
l'L V *-(~o ,(r,l ))4 -
o.(i)2
fT.(i)
C (~n(r, ~) = S~ + (r, ~),
a . V* ÷ ~;, (r, a ) - G- 1 ~ -
(r, a ) = s~ - (,, a).
(16) Note that the sign of the leakage operator has been changed. From the above equations it is possible to derive the even parity adjoint equation.
~;,(~, a . a')
fn g'(i'trt~') o;,(t~ • 11") d ~ " ,
a.v{G,(a.v~,+(r,a)} (11)
+ c, ~,+ (,, a)
-- S*+(r,a) + f L V G , S~',(r, I)). (17)
Table 1. Positive definite leakage and removal operators in plane geometry (where o~., is the Ith Legendre polynomial expansion of the scattering cross section and P ~ ) are the Legendre polynomials) ],/ N
G.
c.{,
(15)
and using similar definitions for S~n+(v,~) and Sn*-(v,l~); the even parity adjoint equations are obtained.
G.u(r, 11) = u(r, ~_~) Jr fn on(i, ~" 11')u(r, 1~') d£~', ~,(i) ... (1o)
,,
(14)
m=O
Defining even and odd adjoint parity fluxes
+ o,,(i,a'.~)},
+
(13)
S*,(r, 11) = S~(r, 11)
follows.
g~(i, [~. f¥) =
(12)
The adjoint multi-group equations can be written as
where the operators C. and G. are defined as
a.a')
- ~r,(i, - 11'.a)}.
where
a - V{G,fl. V4~'.(r, 11)} + C , ~ , ( r , fl)
~:n(i,
½{o,(i, f l ' . a )
2.2 The even parity adjoint equations
N
-
with,
To illustrate the theory Table 1 lists operators of the transport equation for infinite slabs.
S.(r, ¢~) = S,,(r, t~) + fa, dfl' x
337
-°'- 1 _ ~41+ 1 (o..-1
)
l
x
}
t ~ P21+l(#') d~'