Discrete N-barrier maximum principle for a lattice dynamical system arising in competition models

Chiun-Chuan Chen; Ting-Yang Hsiao; Li-Chang Hung

doi:10.3934/dcds.2020007

Article Contents

2020, Volume 40, Issue 1: 153-187. Doi: 10.3934/dcds.2020007

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Discrete N-barrier maximum principle for a lattice dynamical system arising in competition models

1.
Department of Mathematics, National Taiwan University, National Center for Theoretical Sciences, Taipei, Taiwan
2.
Department of Mathematics, National Taiwan University, Taipei, Taiwan

^* Corresponding author
^* Corresponding author

Received: October 31, 2018

Revised: May 31, 2019

Published: October 2019

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Abstract

In the present paper, we show that an analogous N-barrier maximum principle (see [3,7,5]) remains true for lattice systems. This extends the results in [3,7,5] from continuous equations to discrete equations. In order to overcome the difficulty induced by a discretized version of the classical diffusion in the lattice systems, we propose a more delicate construction of the N-barrier which is appropriate for the proof of the N-barrier maximum principle for lattice systems. As an application of the discrete N-barrier maximum principle, we study a coexistence problem of three species arising from biology, and show that the three species cannot coexist under certain conditions.

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Mathematics Subject Classification: Primary: 35B50; Secondary: 35C07, 35K57.

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Figure 1. $ \phi(x) $ in (12) and $ \psi(x) = \frac{\phi(x)}{h^2} $ in Definition 2.1 $ (iv) $

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Figure 2. Integral domain of $ \int_{z_2}^{z_1} \left((v\ast\psi)''(x)\,v'(x)-(v\ast\psi)'(x)\,v''(x)\right)\,dx $ in (44)

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Figure 3. Domain of the integral $ \int_{s_1}^{s_2}\int_{\bar{s}_1}^{\bar{s}_2}I_2(z_2)\,dz_2\,dz_1 $ in (48)

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Figure 4. Graph of $ \Psi (x) $ given by (49)

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Figure 5. The distance $ L $ between the two lines $ \frac{S_u}{\hat{u}}+\frac{S_v}{\hat{v}} = 1 $ and $ \frac{S_u}{\underline{u}}+\frac{S_v}{\underline{v}} = 1 $ given by (87)

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Figure 6. N-barrier for the case $ a_1 $, $ a_2>1 $ in the $ S_uS_v $-plane. Dashed black curves: the solution $ (u(x),v(x)) $ of (BVP^*); black lines: $ 1-u-a_1\,v = 0 $ and $ 1-a_2\,u-v = 0 $; green curve: $ F(u,v) = 0 $; magenta line (above): $ \frac{u}{\underline{u}}+\frac{v}{\underline{v}} = 1 $, where $ \underline{u} $ and $ \underline{v} $ are given by (83); magenta line (below): $ \frac{u}{\hat{u}}+\frac{v}{\hat{v}} = 1 $, where $ \hat{u} $ and $ \hat{v} $ are given by (84) and (85); blue line (above): $ \alpha\,S_u+\beta\,d\,S_v = \lambda_2 $, where $ \lambda_2 = \min\left\{\alpha\,\hat{u},\beta\,d\,\hat{v}\right\} $; red lines: $ \alpha\,S_u+\beta\,S_v = \eta_2 $ (above), where $ \eta_2 = \lambda_2\,\min\left\{1,1/d\right\} $, and $ \alpha\,S_u+\beta\,S_v = \eta_1 $ (below), where $ \eta_1 $ satisfies (99); blue line (below): $ \alpha\,S_u+\beta\,d\,S_v = \lambda_1 $, where $ \lambda_1 = \eta_1\,\min\left\{1,d\right\} $

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References

[1]	R. A. Armstrong and R. McGehee, Competitive exclusion, Amer. Natur., 115 (1980), 151-170. doi: 10.1086/283553.
[2]	Cantrell, Ward and Jr., On competition-mediated coexistence, SIAM J. Appl. Math., 57 (1997), 1311-1327. doi: 10.1137/S0036139995292367.
[3]	C.-C. Chen and L.-C. Hung, A maximum principle for diffusive lotka-volterra systems of two competing species, J. Differential Equations, 261 (2016), 4573-4592. doi: 10.1016/j.jde.2016.07.001.
[4]	C.-C. Chen and L.-C. Hung, Nonexistence of traveling wave solutions, exact and semi-exact traveling wave solutions for diffusive Lotka-Volterra systems of three competing species, Commun. Pure Appl. Anal., 15 (2016), 1451-1469. doi: 10.3934/cpaa.2016.15.1451.
[5]	C.-C. Chen and L.-C. Hung, An N-barrier maximum principle for elliptic systems arising from the study of traveling waves in reaction-diffusion systems, Discrete Contin. Dyn. Syst. B, 23 (2018), 1503-1521. doi: 10.3934/dcdsb.2018054.
[6]	C.-C. Chen, L.-C. Hung and C.-C. Lai, An N-barrier maximum principle for autonomous systems of n species and its application to problems arising from population dynamics, Commun. Pure Appl. Anal., 18 (2019), 33-50. doi: 10.3934/cpaa.2019003.
[7]	C.-C. Chen, L.-C. Hung and H.-F. Liu, N-barrier maximum principle for degenerate elliptic systems and its application, Discrete Contin. Dyn. Syst. A, 38 (2018), 791-821. doi: 10.3934/dcds.2018034.
[8]	C.-C. Chen, L.-C. Hung, M. Mimura, M. Tohma and D. Ueyama, Semi-exact equilibrium solutions for three-species competition-diffusion systems, Hiroshima Math J., 43 (2013), 179-206. doi: 10.32917/hmj/1372180511.
[9]	C.-C. Chen, L.-C. Hung, M. Mimura and D. Ueyama, Exact travelling wave solutions of three-species competition-diffusion systems, Discrete Contin. Dyn. Syst. Ser. B, 17 (2012), 2653-2669. doi: 10.3934/dcdsb.2012.17.2653.
[10]	P. de Mottoni, Qualitative analysis for some quasilinear parabolic systems, Institute of Math., Polish Academy Sci., 11 (1979), p190.
[11]	J.-S. Guo and C.-C. Wu, The existence of traveling wave solutions for a bistable three-component lattice dynamical system, J. Differential Equations, 260 (2016), 1445-1455. doi: 10.1016/j.jde.2015.09.036.
[12]	J.-S. Guo and C.-H. Wu, Wave propagation for a two-component lattice dynamical system arising in strong competition models, Journal of Differential Equations, 250 (2011), 3504-3533. doi: 10.1016/j.jde.2010.12.004.
[13]	J.-S. Guo and C.-H. Wu, Traveling wave front for a two-component lattice dynamical system arising in competition models, Journal of Differential Equations, 252 (2012), 4357-4391. doi: 10.1016/j.jde.2012.01.009.
[14]	S.-B. Hsu and T.-H. Hsu, Competitive exclusion of microbial species for a single nutrient with internal storage, SIAM J. Appl. Math., 68 (2008), 1600-1617. doi: 10.1137/070700784.
[15]	S. B. Hsu, H. L. Smith and P. Waltman, Competitive exclusion and coexistence for competitive systems on ordered Banach spaces, Trans. Amer. Math. Soc., 348 (1996), 4083-4094. doi: 10.1090/S0002-9947-96-01724-2.
[16]	L.-C. Hung, Exact traveling wave solutions for diffusive Lotka-Volterra systems of two competing species, Jpn. J. Ind. Appl. Math., 29 (2012), 237-251. doi: 10.1007/s13160-012-0056-2.
[17]	S. R.-J. Jang, Competitive exclusion and coexistence in a Leslie-Gower competition model with Allee effects, Appl. Anal., 92 (2013), 1527-1540. doi: 10.1080/00036811.2012.692365.
[18]	Y. Kan-on, Parameter dependence of propagation speed of travelling waves for competition-diffusion equations, SIAM J. Math. Anal., 26 (1995), 340-363. doi: 10.1137/S0036141093244556.
[19]	J. Kastendiek, Competitor-mediated coexistence: Interactions among three species of benthic macroalgae, Journal of Experimental Marine Biology and Ecology, 62 (1982), 201-210.
[20]	R. McGehee and R. A. Armstrong, Some mathematical problems concerning the ecological principle of competitive exclusion, J. Differential Equations, 23 (1977), 30-52. doi: 10.1016/0022-0396(77)90135-8.
[21]	M. Mimura and M. Tohma, Dynamic coexistence in a three-species competition–diffusion system, Ecological Complexity, 21 (2015), 215-232.
[22]	H. L. Smith and P. Waltman, Competition for a single limiting resource in continuous culture: the variable-yield model, SIAM J. Appl. Math., 54 (1994), 1113-1131. doi: 10.1137/S0036139993245344.