TY - GEN
T1 - Automated weight-window generation for threat detection applications using advantg
AU - Mosher, Scott W.
AU - Miller, Thomas M.
AU - Evans, Thomas M.
AU - Wagner, John C.
PY - 2009
Y1 - 2009
N2 - Deterministic transport codes have been used for some time to generate weight-window parameters that can improve the efficiency of Monte Carlo simulations. As the use of this hybrid computational technique is becoming more widespread, the scope of applications in which it is being applied is expanding. An active source of new applications is the field of homeland security - particularly the detection of nuclear material threats. For these problems, automated hybrid methods offer an efficient alternative to trial-and-error variance reduction techniques (e.g., geometry splitting or the stochastic weight window generator). The ADVANTG code has been developed to automate the generation of weight-window parameters for MCNP using the Consistent Adjoint Driven Importance Sampling method and employs the TORT or Denovo 3-D discrete ordinates codes to generate importance maps. In this paper, we describe the application of ADVANTG to a set of threat-detection simulations. We present numerical results for an "active-interrogation" problem in which a standard cargo container is irradiated by a deuterium-tritium fusion neutron generator. We also present results for two passive detection problems in which a cargo container holding a shielded neutron or gamma source is placed near a portal monitor. For the passive detection problems, ADVANTG obtains an O(10 4) speedup and, for a detailed gamma spectrum tally, an average O(102) speedup relative to implicit-capture-only simulations, including the deterministic calculation time. For the active-interrogation problem, an O(104) speedup is obtained when compared to a simulation with angular source biasing and crude geometry splitting.
AB - Deterministic transport codes have been used for some time to generate weight-window parameters that can improve the efficiency of Monte Carlo simulations. As the use of this hybrid computational technique is becoming more widespread, the scope of applications in which it is being applied is expanding. An active source of new applications is the field of homeland security - particularly the detection of nuclear material threats. For these problems, automated hybrid methods offer an efficient alternative to trial-and-error variance reduction techniques (e.g., geometry splitting or the stochastic weight window generator). The ADVANTG code has been developed to automate the generation of weight-window parameters for MCNP using the Consistent Adjoint Driven Importance Sampling method and employs the TORT or Denovo 3-D discrete ordinates codes to generate importance maps. In this paper, we describe the application of ADVANTG to a set of threat-detection simulations. We present numerical results for an "active-interrogation" problem in which a standard cargo container is irradiated by a deuterium-tritium fusion neutron generator. We also present results for two passive detection problems in which a cargo container holding a shielded neutron or gamma source is placed near a portal monitor. For the passive detection problems, ADVANTG obtains an O(10 4) speedup and, for a detailed gamma spectrum tally, an average O(102) speedup relative to implicit-capture-only simulations, including the deterministic calculation time. For the active-interrogation problem, an O(104) speedup is obtained when compared to a simulation with angular source biasing and crude geometry splitting.
KW - Hybrid transport methods
KW - Nuclear material detection
KW - Weight-window simulations
UR - http://www.scopus.com/inward/record.url?scp=76749153936&partnerID=8YFLogxK
M3 - Conference contribution
AN - SCOPUS:76749153936
SN - 9781615673490
T3 - American Nuclear Society - International Conference on Mathematics, Computational Methods and Reactor Physics 2009, M and C 2009
SP - 1334
EP - 1346
BT - American Nuclear Society - International Conference on Mathematics, Computational Methods and Reactor Physics 2009, M and C 2009
T2 - International Conference on Mathematics, Computational Methods and Reactor Physics 2009, M and C 2009
Y2 - 3 May 2009 through 7 May 2009
ER -