论文信息 - Visual Monitoring Path Forecasting for Digital Human-Computer Interface in Nuclear Power Plant and its Application

Visual Monitoring Path Forecasting for Digital Human-Computer Interface in Nuclear Power Plant and its Application

The operators sometimes can not judge next possible monitoring object which would lead to monitoring delay or transfer error in the monitoring digital human-computer interface (DHCI) parameter information process in nuclear power plant(NPP). For this purpose, the Markov process based forecasting path dynamic plan (FPDP) method which included forecasting path model, forecasting path plan algorithm and the calculation method of transfer path success probability was proposed. Then the monitoring transfer behavior of the operators when SGTR(Stream Generator Tube Rupture) occurred abruption accidents is analyzed based on the method proposed in this paper, taking the DHCI as the source node of monitoring task of t time, the transfer path to next monitoring object was obtained successfully to improve the efficiency of monitoring and to minimize the risk of monitoring error, which will also contribute to the analysis of the driving mechanism of operators' monitoring activities, to train simulated for monitoring behavior, and to optimize the digital man- machine interface.

[1] Kun Zhang,et al. Markov reliability model research of monitoring process in digital main control room of nuclear power plant , 2011 .

[2] Solon Venâncio de Carvalho,et al. Markov decision process applied to the control of hospital elective admissions , 2009, Artif. Intell. Medicine.

[3] Kun Zhang,et al. Association rules analysis of human factor events based on statistics method in digital nuclear power plant , 2011 .

[4] Zhang Kun. Research on Cognitive Reliability Model for Main Control Room Considering Human Factors in Nuclear Power Plants , 2012 .

[5] Ali Mosleh,et al. A methodology for collection and analysis of human error data based on a cognitive model: IDA , 1997 .

[6] Massimo Bertolini,et al. Assessment of human reliability factors: A fuzzy cognitive maps approach , 2007 .

[7] Natasha Smith,et al. Bayesian networks for system reliability reassessment , 2001 .

[8] Ali Mosleh,et al. Cognitive modeling and dynamic probabilistic simulation of operating crew response to complex system accidents: Part 1: Overview of the IDAC Model , 2007, Reliab. Eng. Syst. Saf..

[9] Y. Changa,et al. Cognitive modeling and dynamic probabilistic simulation of operating crew response to complex system accidents . Part 2 : IDAC performance influencing factors model , 2007 .