Analysis of Reliability Characteristic of a System

1. International Research Research and Development (IJTSRD) International Open Access Journal Analysis of Reliability Characteristic of a System International Journal of Trend in Scientific Scientific (IJTSRD) International Open Access Journal ISSN No: 2456 ISSN No: 2456 - 6470 | www.ijtsrd.com | Volume 6470 | www.ijtsrd.com | Volume - 2 | Issue – 2 Analysis of R System Praveen Gupta Ruchi Yadav Ruchi Yadav School of Studies in Statistics Vikram University, Ujjain, M.P., India University, Ujjain, M.P., India School of Studies in Statistics Vikram School of Studies in Statistics Vikram School of Studies in Statistics Vikram University, Ujjain, M.P., India University, Ujjain, M.P., India ABSTRACT In this Paper, two system models are analyzed. The system have too dissimilar components working independently in parallel. In order to prolong the system operation preventive maintenance (inspection, minor repair) is provided in system at random epochs of time. There are two repair facilities to repair the components. Failure of one component changes the life time parameter of the other component. The failure times of the components are assumed to be exponentially distributed. Keywords: Reliability, Exponential distribution, Mean time to system Failure. Introduction models are analyzed. The dissimilar unit parallel system model assuming that a delay occurs due to administrative action in g and getting the repairman available to the system. Recently, Gupta et. al. (2000) have analyzed unit standby system with correlated failure, repair, random appearance and disappearance rate of two-dissimilar unit parallel system model assuming that a delay occurs due to administrative action in locating and getting the repairman available to the system. Recently, Gupta et. al. (2000) have analyzed a two-unit standby system with correlated failure, repair, random appearance and disappearance rate of repairman. have too dissimilar components working independently in parallel. In order to prolong the system operation preventive maintenance (inspection, minor repair) is provided in system at random epochs ir facilities to repair the components. Failure of one component changes the life time parameter of the other component. The failure times of the components are assumed to be System Description and Assumptions System Description and Assumptions 1)The system consists of a single unit having two dissimilar components say A and B are arranged in parallel. ystem consists of a single unit having two dissimilar components say A and B are arranged Reliability, Exponential distribution, Mean 2)Failure of one components affects the failure rate of other component due to increase in working stresses. Failure of one components affects the failure rate of other component due to increase in working Researchers in reliability have shown keen interest in the analysis of two (or more) component parallel systems. Owing to their practical utility in the modern industry and technological set systems, we come across with the system in which the failure in one component affects the failure rate of the other component. Taking consideration, in this paper, system model is analyzed. The system have too dissimilar components working independently in parallel. Several authors have analyzed various system models considering different repair policies. Gupta and Goel (1990) considering a Researchers in reliability have shown keen interest in the analysis of two (or more) component parallel systems. Owing to their practical utility in the modern industry and technological set-ups of these come across with the system in which the failure in one component affects the failure rate of the other component. Taking consideration, in this paper, system model is analyzed. The system have too dissimilar components working ntly in parallel. Several authors have analyzed various system models considering different repair policies. Gupta and Goel (1990) considering a 3)The system remains operative even if a single component operates. The system remains operative even if a single 4)There are two repair facilities to repair the components. When both the components are failed, they work independently on each other. failed, they work independently on each other. There are two repair facilities to repair the components. When both the components are this this concept concept into into 5)The repair rates are different, when both the repair facilities work on same component and when work on different components. on different components. The repair rates are different, when both the repair facilities work on same component and 6)After repair, each component is as good as new. After repair, each component is as good as new. @ IJTSRD | Available Online @ www.ijtsrd.com @ IJTSRD | Available Online @ www.ijtsrd.com | Volume – 2 | Issue – 2 | Jan-Feb 2018 Feb 2018 Page: 810

2. International Journal of Trend in Scientific Research and Development (IJTSRD) ISSN: 2456-6470 Notations and States of the System  Set of regenerative. E   constant failure rate of component A when B is also operating.   constant failure rate of component B when A is also operating. ’  failure rate of component A when B has already failed. ’  failure rate of component B when A has already failed.   repair rate of component A when B is operating.   repair rate of component B when A is operating.   repair rate of component B when A is also under repair.   repair rate of component A when B is also under repair. The system will be one of the following states :  AN component A is in normal mode and operative.  BN component B is in normal mode  S0(ANBN) Both the components A and B are in normal operative mode.  S1(ARBN) Component A is in under repair and B is normal mode.  S2(ANBR) Component A is in normal operative mode and component B is under repair.  S3(AFBF) Both the components is in failed state.  S4(ANPBF) Component A is in operative and under preventive maintenance.  S5(AFBNP) Component B is operative and under preventive maintenance.  S6(ANPBNP) Both the components are under preventive maintenance. @ IJTSRD | Available Online @ www.ijtsrd.com | Volume – 2 | Issue – 2 | Jan-Feb 2018 Page: 811

3. International Journal of Trend in Scientific Research and Development (IJTSRD) ISSN: 2456-6470 Transition Probabilities and Mean Sojourn Times. Steady state transition probabilities pij are achieve from the conditional transition time cdf Qij(t) = P[Xn+1 = j, Tn+1 – Tn t|Xn = i]. Expressed as integrals by simple probabilistic considerations the non-zero elements of Qij(t) are :   t 1 e           t u 02 0      ,   ' t 1 e            t ' u 13 0   '      t ' u 15 0   '      t ' u 20 0   '      t       u Q (t) e du   01 0   1     e  t         Q (t) e du    t        ' u Q (t) e du     10 ' 0        ' t  1 e         Q (t) ' e du   1        ' t  e         Q (t) e du   1        ' t  e         Q (t) e du @ IJTSRD | Available Online @ www.ijtsrd.com | Volume – 2 | Issue – 2 | Jan-Feb 2018 Page: 812

4. International Journal of Trend in Scientific Research and Development (IJTSRD) ISSN: 2456-6470   1        ' t       e t        ' u  Q (t) e du   24 ' 0   1        ' t       e t        ' u  Q (t) ' e du   23 '   0   1   e     t  t       u  Q (t) e du   31 0 t t       u u Q (t) e du Q (t) e du 51 60 , . 0 0 By the subsequent relation p Q ( )    limQ (t).  ij ij ij t The non-zero elements of pij are given below :   01 p / ;     02 p  13 p '/ '          24 p / '         32 p / ;     42 p It can be established that : p p 1;   10 p p  The mean sojourn times I in states Si are :                             ; p ; p           p   p   / ;         1.  p ' /   ' ; ' ;       10   / '/ p  ; / / ' ; 15 20  ; 23 31 p 51 60           p 1; p p p 1; p p 1; p p p 1. 01 02 13 15 20 23 24 30 31 42 51 60  1 1  t  t       , , e dt e dt    0 1      0 0  1   ' t    , . e dt     2 3        ' 0 m °' Q (s)  ij ij Taking Laplace-Stieltje’s transform and using relation   01 m / ,      10 m   13 m '/ ' ,        From above relations, it is evident that m m ,    10 m m  Reliability and Mean Time to System Failure , s 0    2 2         /   / ' ,    2 2 2           m ' , m / . 15 32       m m . m , 31 32 3 01 02 0 13 15 1 To determine Ri(t), we assume that the failed state S3, S4 and S5 of the system as absorbing. By probabilistic arguments as the following recursive relation are as follows: where, R0(t) = Z0(t) + q01(t) © R1(t) + q01(t) © R2(t). R1(t) = Z1(t) + q01(t) © R0(t) R2(t) = Z2(t) + q20(t) © R0(t). (1-3)   ' t             ' t ' t    Z (t) e , Z (t) e , Z (t) e . 0 1 2 @ IJTSRD | Available Online @ www.ijtsrd.com | Volume – 2 | Issue – 2 | Jan-Feb 2018 Page: 813

5. International Journal of Trend in Scientific Research and Development (IJTSRD) ISSN: 2456-6470 form as follows – R      Taking Laplace Transform of relation (1-3), we can write solution of algebraic equations in the matrix                       * 0 * 1 * 2 * 01 * 02 * 0 * 1 * 2 1 q q q 1 0 q 0 1 Z Z Z   * 10 * 20 R R .  (4) R (s). Computing the above matrix * ij * 1 * i q (s), Z (s) and For brevity, we have omitted the argument ‘s’ from * 0 R (s), we get N (s) R (s) D (s) where * * * * 1 0 01 1 02 N (s) Z q Z q Z    Taking the inverse Laplace transform of the (4), we can get the reliability of the system when initially it starts from state S0. The mean time to system failure is given by – N (0). D (0) To determine N1(0) and D1(0), we can use the results * 0 i i s 0   Therefore,   1 0 01 1 02 2 N 0 p p      . equation from  * 0 1 (5) 1 D (s) 1 q q    * 2 * 01 10 * * 02 * 20 q q . and 1  1     * 0 limR (s)  E T R (t)dt 0 0 1 s 0    limZ (s) Z (t)dt . References 1.Goel, L.R. and Gupta, P. (1983): ‘Stochastic behavior of a two unit (dissimilar) hot standby system with three modes’. Microelectron and Reliability, 23, 1035-1040. Conclusion: This paper describes an improvement over the Said and Sherbeny (2010).They analyzed a two-unit cold standby system with two stage repair and waiting time. In this paper we analyzed a two dis-similar component system. The system operates even if a single component operates. A single repair facility is available with some fixed probability for the repair of failed components. . Several measures of system effectiveness such as MTSF, A, B etc. are obtained by using regenerative point technique which shows that the proposed model is better than Said and Sherbeny. 2.Gupta, P. and Saxena, M., (2006): “Reliability analysis of a single unit and two protection device system with two types of failure.” Ultra Science 18, 149-154. 3.Mogha, A.K. and Gupta, A.K., (2002): ‘A two priority unit warm standby system model with preparation of repair’. The Aligarh Journal of Statistics, 22, 73-90. 4.Said,K.M. and Sherbeny,M.S.(2010): Stochastic analysis of a two-unit cold standby system with two-stage repair and waiting time .Sankhya The Indian Journal of Statistics, 72 B ,1-1 @ IJTSRD | Available Online @ www.ijtsrd.com | Volume – 2 | Issue – 2 | Jan-Feb 2018 Page: 814