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1.
ISSN: 2278 –
1323 International Journal of Advanced Research in Computer Engineering & Technology Volume 1, Issue 2, April 2012 The dynamics of disease transmission in a Prey Predator System with harvesting of prey , Kul Bhushan Agnihotri* Department of Applied Sciences and Humanties Shaheed Bhagat Singh College of Engg & Tech Ferozepur-152004, Punjab, India Sunita Gakkhar ** Department of Mathematics, IIT Roorkee, Roorkee, India Abstract: In this present work on predator-prey system, a disease transmission model, incorporating provisions for harvesting of prey have been discussed and analyzed. The disease spread is from infected prey to predator species. The SI models are considered for both the species. Conditions are derived for existence and stability of disease free equilibrium state of the system. The effect of harvesting of prey has been analyzed from point view of the stability of system. The epidemiological threshold R0 and R1 quantities have been obtained using next generation approach for the model system. Conditions for endemic disease in prey species are discussed. This study also considers the impact of disease in prey on the extinction aspect of the predator. Numerical and computer simulations of the model have been done. Mathematics Subject Classification (2000) 35B35 - 92C05 - 92D30 -92D40 Keywords: Predator, prey, Equilibrium point, carrying capacity, Basic reproduction number, Stability, Harvesting 1. Introduction: Predator-prey interactions give regulatory system for the advancement of biological species. in natural ecosystem. Prey predator interactions and disease in the system affects each other [1, 3, 5, 7, 8-10, and 17]. Some previous studies of infectious diseases in animal populations were focused on the effects of disease-induced mortality or disease-reduced reproduction in the regulation of populations in their natural habitats [3, 7, 8, 17 and 18]. Reduced population sizes and destabilization of equilibrium into oscillations are caused by the presence of infectious disease in one or both of the populations. The fact that predators take a disproportionate number of infected preys has been confirmed by earlier studies [8, 11 and 17]. Infected prey is more exposed to predation on All Rights Reserved © 2012 IJARCET 1
2.
ISSN: 2278 –
1323 International Journal of Advanced Research in Computer Engineering & Technology Volume 1, Issue 2, April 2012 account of the fact that the disease may weaken their ability to protect themselves and expose them to predators [1]. This increased vulnerability of infected prey may lead to persistence of the predator (which would otherwise be starved and become extinct). Further, predation of the infected prey may lead to the disappearance of disease which may otherwise be endemic in prey population [3]. Together with no reproduction in infected prey, as predation on infected prey increases, the infection tends to destabilize prey-predator interactions [17]. Most of the eco-epidemiological studies are restricted to the situations where only prey species can get infection. Few investigations [4, 11, 19-21] consider the spread of disease from prey to predator through predation of infected prey. For the purpose of eliminating either the disease from predator- prey system or eliminating the menace of the predator by controlling disease in prey, a simplified eco- epidemiological four species prey predator SI model [4] is shown to be useful. Exploitation of biological resources as practiced in fishery, and forestry has strong impact on dynamic evolution of biological population. The over exploitation of resources may lead to extinction of species which adversely affects the ecosystem. However, reasonable and controlled harvesting is beneficial from economical and ecological point of view. The research on harvesting in predator-prey systems has been of interest to economists, ecologists and natural resource management for some time now. Very few has explicitly put a harvested parameter in a predator–prey–parasite model and studied its effect on the system. Here we study the role of harvesting in an eco-epidemiological system where the susceptible and infected prey are subjected to combined harvesting. In this present work on predator-prey system, a disease transmission model, incorporating provisions for harvesting of prey have been proposed and studied. In the model, the disease is spreading from infected prey to susceptible prey and consequently to the predator species via predation related activities: capturing, handling and eating the infected prey. Both, the prey and the predator species are compartmentalized into susceptible and infected classes. Recovery from disease is not considered for both prey and the predator species. Consequently, SI model is considered for both the species. 2. Mathematical Analysis Consider an eco-epidemiological system comprising of four populations, namely, the susceptible prey ( S1 ), infected prey ( I1 ), susceptible predator ( S 2 ) and infective predator ( I 2 ) All Rights Reserved © 2012 IJARCET 2
3.
ISSN: 2278 –
1323 International Journal of Advanced Research in Computer Engineering & Technology Volume 1, Issue 2, April 2012 such that N1 t S1 (t ) I1 (t ) and N 2 t S2 (t ) I 2 (t ) . An SI type eco-epidemiological model for prey predator dynamics is presented under following assumptions: Only susceptible prey is capable of reproducing logistically. While susceptible prey can easily escape the predation, the infected prey are weakened due to disease and become easier to catch. The infected prey and predator do not reproduce but still continue to consume resources. The susceptible predator gets food from infected prey for its survival. It may become infected due to interaction with infected prey. Mortality rate of infected predator is higher than that of susceptible predator. It is also assumed that the disease does not affect the hunting ability of infected predator. Further, all the predators who predate the infected prey become infected. Let e1 be the harvesting rate of susceptible prey and e2 be the harvesting rate of infected prey. Since it is easy to catch infected prey as compare to susceptible prey, therefore e1 e2 . Accordingly, the following mathematical model is obtained under the above assumptions: dS1 S I rS1 1- 1 1 - a1S1 ( S2 I 2 ) - c1S1I1 e1S1 dt K1 dI1 c1S1 I1 - a2 I1 ( S2 I 2 ) - d1 I1 e2 I1 dt dS2 -a2 S2 I1 (-d 2 ka1S1 ) S2 dt dI 2 a2 S2 I1 - d3 I 2 dt (1) where a1 Predation rate on the susceptible prey (hectare per individual day-1) a2 Predation rate on the infective prey (hectare per individual day-1) k Feeding efficiency of predator (per individual day-1) r Intrinsic growth rate constant of susceptible prey (day-1) K1 Carrying capacity of environment with respect to prey species (Individual ha-1) c1 Rate of force of infection (hectare per individual day-1) d1 Net death rate of prey (Natural death + death due to infection) (day-1) d 2 Natural death rate of susceptible predator (day-1) All Rights Reserved © 2012 IJARCET 3
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1323 International Journal of Advanced Research in Computer Engineering & Technology Volume 1, Issue 2, April 2012 d3 Net death rate of infected predator (day ) -1 According to the assumptions a2 a1 , d3 d2 and e2 e1 , k 1. Also, S1 (0) 0, S2 (0) 0, I1 (0) 0 and I 2 (0) 0 . 3. Mathematical Analysis Theorem 1 All the solutions of the system (1) which initiate in 4 are uniformly bounded. Proof: By theorems of Nagumo [13] , it can be easily proved that S1 , I1 , S 2 and I 2 remain positive. Let W1 S1 I1 From (1), the following can be easily obtained: d ( S1 I1 ) S rS1 1- 1 e1S1 - d1I1 e2 I1 dt K1 d (S1 I1 ) rS 2 (r e1 )S1 - 1 - (d1 e2 ) I1 dt K1 For arbitrarily chosen 1 , this simplifies to d ( S1 I1 ) rS 2 1 ( S1 I1 ) (r e1 1 ) S1 - 1 - (d1 e2 1 ) I1 dt K1 dW1 K1 (r e1 1 ) 2 r 2 K1 K12 (r e1 1 ) 2 1W1 S1 (r e1 1 ) S1 - (d1 e2 1 ) I1 dt 4r K1 r 4r 2 K (r e1 1 )2 r 2 dW1 K 1W1 1 S1 (r e1 1 ) 1 - (d1 e2 1 ) I1 dt 4r K1 2r Choosing 1 d1 e2 and applying the results of Birkhoff and Rota [6], yields L1 K1 (r e1 1 )2 0 W1 ( S1 (t ), I1 (t )) (1 e 1t ) W1 ( S1 (0), I1 (0))e 1t ; L1 1 4r As t , it gives L1 0 S1 I1 ( K ) , 1 W1 S1 I1 is bounded From positivity of S1 and I1 , 0 S1 K ;0 I1 K . All Rights Reserved © 2012 IJARCET 4
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1323 International Journal of Advanced Research in Computer Engineering & Technology Volume 1, Issue 2, April 2012 Similarly, defining another positive definite function W as W S1 I1 S2 I 2 Proceeding in the similar manner and choosing min(d1 e2 , d 2 , d3 ) yields L1 (r ) 0 W ( S1 , I1 , S 2 .I 2 ) (1 e t ) W ( S1 (0), I1 (0), S 2 (0), I 2 (0))e t 1 As t , it gives K (r ) (r ) 0 W L , where L W S1 I1 S2 I 2 is bounded. 4 Hence all solutions of (1) that initiate in are confined in the region B ( S1 , I1 , S2 , I 2 ) n : Si L; I i L; i 1, 2 4. Equilibrium points: The following equilibrium points exist for the system (1): a) The trivial equilibrium point E0 (0,0,0,0) b) The axial equilibrium point E1 ( S1 , 0, 0, 0) , K (r e1 ) Where S1 1 always exist provided r r e1 . (2) c) The planar equilibrium point E2 ( S1' , I1' ,0,0) in S1 I1 plane is obtained as d1 e2 ' c1K1 (r e1 ) (d1 e2 )r S1' , I1 , c1 c1 (c1K1 r ) The existence of this equilibrium point is possible provided c1K1 (r e1 ) (d1 e2 )r 0 (3) In this case, the predator species is eliminated and the disease persists in the prey species. Harvesting of susceptible and infected prey will reduce the possibility of existence of All Rights Reserved © 2012 IJARCET 5
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1323 International Journal of Advanced Research in Computer Engineering & Technology Volume 1, Issue 2, April 2012 E2 ( S1' , I1' ,0,0). If it exist then number of susceptible prey will increase but number of infected prey will decrease due to harvesting of susceptible and infected prey. ˆ ˆ Another disease free planar equilibrium point E3 (S1 ,0, S2 ,0) on S1 S2 plane exists provided ka1K1 (r e1 ) rd2 0 (4) where ˆ d ˆ ka K (r e ) rd 2 , S1 2 and, S2 1 1 2 1 ka1 ka1 K1 It has been also observed that even if the feeding efficiency k of predator is high enough d2 ˆ ˆ that K1 , even then the disease free equilibrium in E3 (S1 ,0, S2 ,0) may not exist with ka1 harvesting of susceptible prey. If it exists then number of susceptible prey will remain same but number of susceptible predator will decrease due to removal of susceptible prey. d) For non-zero equilibrium point E* (S1* , I1* , S1* , I1* ) of the system (1) is given by ˆ (r e1 )a2 K1 a1c1K1S1' (r c1K1 )ka1S1 S1* r (a2 ka1 ) a1c1K1 (1 k ) ˆ ka1 (S1* S1 ) I1* , S1* I1* K1 a2 c1d3 ( S1* S1' ) S2 * , ˆ a2 (d3 (S1* S1 )ka1 ) ˆ * ka1 ( S1* S1 )S2 I2 * d3 Accordingly, E * (S * , I * , S * , I * ) exists provided S1* max S1' , S1 S , r e1 ˆ (5) The Basic Reproduction Number is defined as the average number of secondary infections when one infective is introduced into a completely susceptible host population. It is also called the basic reproduction ratio or basic reproductive rate. Using next generation approach [2, 15 and 16], the epidemiological threshold quantities for the system (1) are obtained as All Rights Reserved © 2012 IJARCET 6
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1323 International Journal of Advanced Research in Computer Engineering & Technology Volume 1, Issue 2, April 2012 c1K1 (r e1 ) ˆ c1S1 R0 , R1 (6) r (d1 e2 ) ˆ d1 e2 a2 S2 Here, R0 is the basic reproduction number for isolated prey population and R1 is the basic reproduction in the prey population when both prey and predator are present in the system. The greater vulnerability of prey will reduce R1 . Harvesting of infected prey (e2 ) will reduce both R1 and R2 . Also by simplification it can be proved that R0 R1 5. Local Stability Analysis The variational matrix V of given system (1) is given by 2rS1 rI1 rS r K - a1 (S2 I 2 ) - c1I1 - K e1 - 1 - c1S1 K1 -a1S1 -a1S1 1 1 V c1I1 c1S1 - d1 - a2 (S2 I 2 ) e2 -a2 I1 -a2 I1 ka1S2 -a2 S2 -a2 I1 (-d 2 ka1S1 ) 0 -d 3 0 a2 S2 a2 I1 The following theorem is direct consequences of linear stability analysis of the system (1) about E0 and E1 . Theorem 2 The trivial equilibrium point E0 (0,0,0,0) is locally asymptotically stable provided r e1 (7) Theorem 3 The axial equilibrium E1 ( S1 , 0, 0, 0) is locally asymptotically stable provided ˆ S1 min S1' , S1 (8) The equilibrium E1 ( S1 , 0, 0, 0) is unstable when S1 min S1' , S1 , ˆ (9) It can be concluded from (8) that E1 ( S1 , 0, 0, 0) may be stable for those parametric values for which it was not stable without harvesting of prey. So harvesting of susceptible and infected prey has positive effect on the stability of E1 ( S1 , 0, 0, 0). Also from (8) it may be noticed that when E1 ( S1 , 0, 0, 0) is locally asymptotically stable, All Rights Reserved © 2012 IJARCET 7
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1323 International Journal of Advanced Research in Computer Engineering & Technology Volume 1, Issue 2, April 2012 d1 e2 d S1 and S1 2 , c1 ka1 (d1 e2 )r rd 2 K1 and K1 or c1 (r e1 ) ka1 (r e1 ) rd 2 R0 1 and K1 ka1 (r e1 ) ˆ ˆ which violate existence conditions (3) and (4) of E2 ( S1' , I1' ,0,0) and E3 ( S1 ,0, S2 ,0) respectively. So, when E1 ( S1 , 0, 0, 0) is locally asymptotically stable then E0 (0,0,0,0), E2 ( S1' , I1' ,0,0) and ˆ ˆ E3 ( S1 ,0, S2 ,0) do not exist. When the perturbations are confined in S1 I1 plane only, then the equilibrium point E1 ( S1 , 0, 0, 0) is locally asymptotically stable for R0 1 . However in the presence of predator population the stability depends upon the dynamics of predator also as is evident from (8). In fact, when the feeding efficiency of predator is sufficiently low then the disease will die out from both the prey and predator under condition (8) and the equilibrium point E1 ( S1 , 0, 0, 0) is locally asymptotically stable. In other words, when the feeding efficiency is sufficiently low and the basic reproduction number R0 in prey population is below the threshold then predator population become extinct and disease dies out from the prey population. Theorem 4. If R0 1 , then E2 (S1' , I1' ,0,0) locally asymptotically stable provided ka1S1' a2 I1' d2 0 (10) Proof: From variational matrix V, the characteristic equation about E2 (S1' , I1' ,0,0) is obtained as 2 rS1' rS ' c1 I1' 1 c1S1' (a2 I1' ka1S1' d 2 ) (d3 ) 0 K1 K1 The quadratic factor gives two eigen values with negative real parts . Therefore, the system around E2 (S1' , I1' ,0,0) is locally asymptotically stable provided (10) is satisfied. If the basic reproduction number R0 in the prey population is above the threshold, the disease in prey population approaches to endemic level and predator population becomes extinct due to (10). All Rights Reserved © 2012 IJARCET 8
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1323 International Journal of Advanced Research in Computer Engineering & Technology Volume 1, Issue 2, April 2012 Harvesting of susceptible and infected prey has negative effect on the stability of E2 (S1' , I1' ,0,0). The condition of instability of E2 (S1' , I1' ,0,0) if it exists, is given by ka1S1' a2 I1' d2 0 (11) ˆ ˆ Theorem 5. The disease free equilibrium state E3 ( S1 ,0, S2 ,0) , if it exists, is locally , asymptotically stable provided R1 1 . ˆ ˆ Proof: From variational matrix V, the characteristic equation about E3 ( S1 ,0, S2 ,0) is ˆ rS1 ( 2 ˆ ˆ ˆ ˆ ka12 S1S2 )(c1S1 a2 S2 d1 e2 )(d3 ) 0 K1 Since the quadratic factor always yield eigen values with negative real parts, the condition for stability is ˆ ˆ c1S1 a2 S2 d1 e2 0 Its simplification gives R1 1 (12) This completes the proof. When the basic reproduction number R1 is below the threshold, then the disease dies out ˆ ˆ from both the species and the equilibrium point E3 ( S1 ,0, S2 ,0) is stabilized. Rewriting stability condition gives the critical value of e2 for which the disease free equilibrium state is locally asymptotically stable: ra ˆ a ˆ d e2 c1 2 S1 2 (r e1 ) d1 , S1 2 K1a1 a1 ka1 (13) The greater vulnerability of prey to predation may be responsible for persistence of disease free prey predator population. By simplifying above condition for stability it has been observed that harvesting of ˆ ˆ infected prey may improve the stability of equilibrium point E3 ( S1 ,0, S2 ,0) where as it become less stable with harvesting of susceptible prey. Thus with an appropriate harvesting of ˆ ˆ susceptible and infected prey, disease free equilibrium point E3 ( S1 ,0, S2 ,0) can be maintained at desired level. All Rights Reserved © 2012 IJARCET 9
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1323 International Journal of Advanced Research in Computer Engineering & Technology Volume 1, Issue 2, April 2012 ˆ ˆ The disease free equilibrium state E3 ( S1 ,0, S2 ,0) if it exist, is unstable if ˆ ˆ c1S1 a2 S2 d1 e2 0 (14) It is observed that E2 (S1' , I1' ,0,0) , if it exists, is locally asymptotically stable provided ˆ ˆ E3 ( S1 ,0, S2 ,0) is unstable and vice-versa. However, it is possible for some choice of parameters that both E2 ( S1, I1, 0, 0) and ˆ ˆ E3 (S1 ,0, S2 ,0) exist and locally stable. ˆ ˆ It is also observed that when both E2 ( S1, I1, 0, 0) and E3 (S1 ,0, S2 ,0) are stable then non-zero equilibrium point E* (S1* , I1* , S2* , I 2* ) always exist. Theorem 6. The non-zero equilibrium point E* (S1* , I1* , S1* , I1* ) , if exists, is a saddle point. Proof: The characteristic equation about E* is obtained as 4 A0 3 A1 2 A2 A3 0 (15) Where r A3 a2 (d3 a2 I1* ) (k 1)a1c1 ka1 a2 I1*S1*S 2 * K1 As the constant term A3 is always negative, at least one eigenvalue of the equation (15) will be positive, therefore E* (S1* , I1* , S2 , I 2 ) is not locally asymptotically stable. * * It is either unstable or a saddle point. □ 6. Numerical simulations Numerical simulations have been carried out to investigate dynamics of the proposed model. Computer simulations have been performed on MATLAB for different set of parameters. Consider the following set of parametric values: r 0.1, K1 50, e1 0.03, e2 0.05, d1 0.7, d 2 0.6, (16) d3 0.7, c1 0.01, a1 0.8, a2 0.9, k 0.012 The system (1) has equilibrium point E1 (35, 0, 0, 0) for the data set (16). It is locally asymptotically stable by the computed value of R0 is 0.4667 1 and the value of feeding efficiency k of predator population is sufficiently low and the condition (8) is satisfied. The solution trajectories in phase space S1 I1 S2 are drawn in Fig. 1 for different initial values. All All Rights Reserved © 2012 IJARCET 10
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1323 International Journal of Advanced Research in Computer Engineering & Technology Volume 1, Issue 2, April 2012 the solution trajectories to tend to E1 (35, 0, 0, 0). D 20 15 A=( 1, 10, 10, 1 ) 10 B=( 20, 0, 10, 0 ) S2 A C=( 20, 10, 0, 0 ) 5 B D=( 20, 20, 20, 20 ) 0 20 C E1 E =( 35, 0, 0, 0 ) 1 15 10 30 5 20 10 I1 0 0 S1 Fig 1: Phase plot depicting the stability of equilibrium point E1 in phase space S1 - I1 - S2 for data-set (16) Now consider following set of data r 0.02, K1 100, e1 0.021, e2 0.03, d1 0.01, d 2 0.11, (17) d3 0.15, c1 0.002, a1 0.01, a2 0.02, k 0.33 For above set of data, the equilibrium point E0 (0, 0, 0, 0) is locally asymptotically stable as r e1 (see Fig. 2) and all other equilibrium points do not exist. 20 D 15 A=( 1, 10, 10, 1 ) 10 S2 B=( 20, 0, 10, 0 ) 5 A C=( 20, 10, 0, 0 ) 0 B D=( 20, 20, 20, 20 ) 20 C 15 E0=( 0, 0, 0, 0 ) 10 5 30 20 I1 0 10 0 E0 S1 All Rights Reserved © 2012 IJARCET 11
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1323 International Journal of Advanced Research in Computer Engineering & Technology Volume 1, Issue 2, April 2012 Fig 2: Phase plot depicting the stability of equilibrium point E1 in phase space S1 - I1 - S2 for data set 17 For the following data set of parameters, E2 is stable and E3 is unstable: r 0.02, K1 100, e1 0.01, e2 0.03, d1 0.01, d 2 0.11, (18) d3 0.15, c1 0.002, a1 0.01, a2 0.02, k 0.33 The equilibrium point E1 (50, 0, 0, 0) is unstable as condition (8) is not satisfied and both the planar equilibrium points E2 (20, 2.7273, 0, 0) and E3 (33.3333, 0, 0.3333, 0) exists condition (3) and (4) are satisfied respectively. The equilibrium point E3 (33.3333, 0, 0.3333, 0) is found to be unstable as it satisfies the condition (14). The equilibrium point E2 (20, 2.7273, 0, 0) is found to be locally asymptotically stable as condition (10) is satisfied. The solution trajectories in phase space S1 I1 S2 are drawn in Fig. 4 for different initial values. All these trajectories converge to E2 (20, 2.7273, 0, 0) . Starting with initial value in the neighborhood of the point E3 (33.3333, 0, 0.3333, 0) , the solution trajectory approaches to the equilibrium point E2 (20, 2.7273, 0, 0). This confirms the instability of E3 . 20 D E2=(20, 2.7273, 0, 0) 15 A=(0.1, 0.1, 0.1,0.1) 10 S2 5 B=(50, 0.1, 0.1, 0.1) 0 C=(33.33,0.1,0.33,0.1) 20 15 E2 B D=(20, 20, 20, 20) C 10 50 A 40 5 30 20 I1 0 10 0 S1 Fig. 3: Phase plot depicting the stability of E2 and instability of E3 in S1 I1 S 2 space for dataset (18) All Rights Reserved © 2012 IJARCET 12
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1323 International Journal of Advanced Research in Computer Engineering & Technology Volume 1, Issue 2, April 2012 The following data is selected for which all the equilibrium points exist: r 0.02, K1 100, e1 0.01, e2 0.068, d1 0.01, d 2 0.11, (19) d3 0.15, c1 0.002, a1 0.01, a2 0.02, k 0.33 In this case, the equilibrium point E1 (50, 0, 0, 0) is unstable. It is observed that both the equilibrium points E2 (39, 1, 0, 0) and E3 (33.3333, 0, 0.3333, 0) are locally asymptotically stable. The point E2 (39, 1, 0, 0) is stable since ka1S1' d3 I1' d2 0.0013 0 and R0 1.2821 1 . Also, E3 (33.3333, 0, 0.3333, 0) is locally asymptotically stable as R1 0.7874 1 . Both the equilibrium points have their own domains of attractions. Trajectories with different initial conditions converge to different equilibrium points (See Fig. 4). The instability of non-zero equilibrium point E* (39.0915,0.9501,0.0081,0.0010) can be seen from Fig. 4. It is also noticed that when even a very small perturbation is taken from E* (39.0915,0.9501,0.0081,0.0010) to D(40, 0.9501, 0.0081, 0.0010) , along S1 direction, the trajectory converges to E2 (39, 1, 0, 0) . Whereas, when the perturbation is taken to E (39.0915,1, 0.0081, 0.0010) , the trajectory of the system converges to E3 (33.3333, 0, 0.3333, 0) . A=(0.1, 0.1, 0.1,0.1) B=(50, 0.1, 0.1, 0.1) C=(1, 1, 1, 1) D=(40, 0.9501, 0.0081, 0.0010) E=(39.0915, 1, 0.0081,0.00100) E2=(39,1, 0, 0) 1 E3=(33.3333,0.3333,0,0) E3 A S2 0.5 C 0 0 B 0.5 D 0 I1 E 10 E 2 20 1 30 40 50 S1 Fig 4: Phase plot depicting the stable behaviour of E2 , E3 in S1 I1 S2 space for dataset (19) All Rights Reserved © 2012 IJARCET 13
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1323 International Journal of Advanced Research in Computer Engineering & Technology Volume 1, Issue 2, April 2012 Now, consider the following data set where E3 is stable and E2 unstable: r 0.02, K1 100, e1 0.01, e2 0.069, d1 0.01, d 2 0.11, (20) d3 0.15, c1 0.002, a1 0.01, a2 0.02, k 0.33 d2 (d1 e2 ) As S1 ( 50) is greater than computed value 33.3333 of and 39.5 of in this case, ka1 c1 the equilibrium point E1 (50, 0, 0, 0) is unstable and system (1) has two planar equilibrium points, say E2 (39.5, 0.9545, 0, 0) and E3 (33.3333, 0, 0.3333, 0) . The equilibrium point E3 (33.3333, 0, 0.3333, 0) is found to be stable as it satisfies the condition (12). The equilibrium point E2 (39.5, 0.9545, 0, 0) is found to be unstable as it satisfies the condition (11). The solution trajectories in phase space S1 - I1 - S2 are drawn in Fig. 5 for different initial values. All these trajectories approach to E3 (33.3333, 0, 0.3333, 0) . Convergence of solution trajectory to equilibrium E3 (33.3333, 0, 0.3333, 0) with initial value near E2 (39.5, 0.9545, 0, 0) also confirms the instability of E2 (39.5, 0.9545, 0, 0) . A=(0.1, 0.1, 0.1,0.1) B=(50, 0.1, 0.1, 0.1) C=(1, 1, 1, 1) D=(39.5, 0.9545, 0.1, 0.1) E3=(33.3333, 0, 0.3333,0) 1.5 1 C S2 E3 0.5 A B 0 0 D 10 0 0.5 20 30 1 40 I1 50 S1 Fig. 5: Phase plot depicting the stability of E3 and instability of E2 in S1 I1 S 2 space for dataset (20) All Rights Reserved © 2012 IJARCET 14
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1323 International Journal of Advanced Research in Computer Engineering & Technology Volume 1, Issue 2, April 2012 7. Discussion and Conclusion In this paper on predator-prey system, a disease transmission model, incorporating provisions for harvesting of prey have been discussed and analyzed. From the infected prey, the disease is spreading to susceptible prey and consequently to the predator species. The predator- prey species are compartmentalized into susceptible and infected classes. Recovery from disease is not considered for both prey and the predator species. Consequently, SI model is considered for both the species. SI model system admits four boundary equilibrium points and one non-zero interior equilibrium point. The dynamic behavior of the system around each equilibrium point has been studied and threshold values for basic reproduction numbers R0 and R1 are computed. Conditions for the existence and stability of disease free prey predator system are obtained. Conditions for endemic disease in prey species are discussed. Numerical Simulations are carried out to confirm the results obtained analytically. It has been observed that the predator population becomes extinct and the disease dies out from the prey population for sufficiently small feeding efficiency of predator when the basic reproduction number R0 in prey population is below the threshold. If the basic reproduction number R0 in the prey population is above the threshold, the disease in prey population approaches endemic level and predator population becomes extinct. Disease in prey may be responsible for elimination of predator. In case the feeding efficiency of predator population is sufficiently high so that rd 2 K1 (r e1 ) then the predator population persists. When the basic reproduction (r e1 )ka1 number R1 is below the threshold, then the disease dies out. The prey and predator population ˆ ˆ both go to their persistent equilibrium values and the equilibrium point E3 (S1 ,0, S2 ,0) is stabilized. The difference in death rates of infected and susceptible species may be responsible for instability of the equilibrium point E* (S1* , I1* , S2 , I 2 ) . Therefore, the disease may not be * * endemic in prey predator system. It is observed that harvesting of infected prey helps in making the system disease free where as harvesting of susceptible prey has adverse effect on it. Thus with an appropriate ˆ ˆ harvesting of susceptible and infected prey, disease free equilibrium point E3 ( S1 ,0, S2 ,0) can be All Rights Reserved © 2012 IJARCET 15
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1323 International Journal of Advanced Research in Computer Engineering & Technology Volume 1, Issue 2, April 2012 maintained at desired level. It is also observed that with harvesting of infected prey only, size of prey and predator population is not affected where as removal of susceptible prey will not affect the prey level but will reduce the predator level in disease free equilibrium state. Removal of both susceptible and infected prey will make the system free from disease. At the same time it will destabilize the predator free equilibrium point. If r e1 , i.e if intrinsic growth rate of susceptible prey is less than that of its harvesting from system then both the species will extinct from system. References: s [1] A.P. Dobson, The population biology of parasite-induced changes in host behavior, Q. Rev. Biol. 63(1988), pp. 139-165. [2] C. Castillo-Chavez, S. Blower, P. van der Driessche, D. Kirschner and A. A. Yakubu, Mathematical Approaches for Emerging and Reemerging Infectious Diseases: An Introduction”, Journal of Theoretical Biology. Springer-Verlag, New York, 2002. [3] E. Venturino, Epidemics in Predator-Prey Models: Disease in the Predators, IMA J. Math. Appl. Med. Biol. 19 (2002) 185-205. [4] E. Venturino, On Epidemics Crossing the Species Barrier in Interacting Population Models, Varahmihir J. Math. Sci. 6 (2006) 247-263. [5] E. Venturino, The influence of diseases on Lotka –Volterra system, Rky. Mt. J. Math. 24(1984), pp. 381-402. [6] G. Birkhoff, G. C. Rota, Ordinary Differntial quations. Ginn Boston.(1982). [7] H.W. Hethcote, Wendi Wang, L. Han, Z. Ma, A Predator-Prey Model With Infected Prey, Theor. Popul Biol. 66(2004) 259-268. [8] J. Chattopadhyay, O. Arino, A predator-prey model with disease in the prey, Nonlinear Anal. 36(1999), pp. 747-766. [9] J. Chattopadhyay, N. Bairagi, Pelicans at Risk in Salton Sea-An Eco- epidemiological Study, Ecol. Modell. 136 (2001) 103-112. [10] J. Moore, Parasites and the Behavior of Animals, Oxford University Press,Oxford. 2002. [11] K.P. Hadeler, H.I. Freedman, Predator-Prey Populations With parasitic Infection, J. Math. Biol. 27(1989) 609-631. All Rights Reserved © 2012 IJARCET 16
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1323 International Journal of Advanced Research in Computer Engineering & Technology Volume 1, Issue 2, April 2012 [12] L. Han, Z. Ma, H.W. Hethcote, Four Predator Prey Models With Infectious Diseases, Math. Comput. Model. 34(2001) 849-858. [13] N. Nagumo, Uber die lage der integeralkueven gewonlicher differentialgleichunger, Proc. Phys. Math. Soc. Japan, 24 (1942) 551. [14] O. Arino, A. El abdllaoui, J. Mikram, J. Chattopadhyay, Infection in Prey Population May Act As Biological Control in Ratio-Dependent Predator-Prey Models, Nonlinearity 17(2004) 1101-1116. [15] O. Diekmann, J.A.P. Heesterbeek, J.A.J. Metz, On the Definition and the Computation of the Basic Reproduction Ratio R0 in Models for Infectious Diseases in Heterogeneous Populations, J. Math. Biol. 28(1990) 365-382. [16] P. van. der Driessche, J. Watmough, Reproduction Numbers and Sub- threshold Endemic Equilibria for Compartmental Models of Disease Transmission, Math. Biosci. 180(2002) 29-48. [17] R.M. Anderson and R.M. May, The invasion, persistence, and spread of infectious diseases within animal and plant communities, Phillos. Trans. R. Soc. Lond. B 314(1986), pp. 533-570. [18] R.M. Anderson, R.M. May, Regulation and Stability of Host-Parasite Population Interactions I: Regulatory Processes, J. Anim. Ecol. 47(1978) 219-247. [19] S. Gakkhar, K. B. Agnihotri, A Prey Predator System with Disease Crossing Species Barrier, Proc. of International Conference on Recent Advances in Mathematical Sciences & Applications (RAMSA 2009), Vishakhapatnam, India, pp 296-303. [20] S. Gakkhar, K. B. Agnihotri, S.I.S Model for Disease Transmission from Prey to Predator, Journal of International Academy of Physical Sciences 14 (2010) 15-31 [21] S. Chaudhuri, A. Costamagna & E. Venturino, Epidemics spreading in predator–prey systems, International Journal of Computer Mathematics, 89(2012) 561–584. All Rights Reserved © 2012 IJARCET 17
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