几类生态种群动力系统性质的研究
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摘要
随着科学的发展,Lotka-Volterra系统和Gilpin-Ayala系统作为种群生态学中的两个经典模型,在自然科学和社会科学的很多学科中的重要性越来越突出,已发表大量的研究工作.本文分五章研究了上述两种系统的持久性,灭绝性或指数稳定性,所得结果改进并推广了相关已有的工作.
第一章,介绍了所关注问题的研究背景和本文的主要工作.
第二章,首先讨论了一类广义非自治N-种群Lotka-Volterra系统的强持久性,在此基础上,研究了经典的Lotka-Volterra系统并得到了系统部分持久与灭绝的充分条件,得到了若干新的结果,其中一些结果包含了原文献的工作.
第三章,主要研究了具有时滞的Lotka-Volterra扩散系统给出了系统一致持久的充分条件.
第四章,首先考虑了单种群扩散系统的一致持久性,在此基础上,又讨论了非线性捕食系统得到其若干持久性的充分条件.所得结果改进并推广了一些已有的结果。
第五章,考虑了具有时滞变元的Lotka-Volterra模型的一致持久性和指数稳定性,建立了若干新的结果,改进并推广了一些已有结果.
With the development of science, Lotka-Volterra system and Gilpin-Ayala system, as two basic models in population dynamics, play important roles in physical and social science. This thesis is composed of five chapters to consider the persistence, extinction or global exponential stability of above two systems. The results given in this paper improve and extend the corresponding ones in the literatures.
In Chapter 1, we introduce the historical background of problems which will be investigated and the main works of this thesis.
In Chapter 2, firstly the strong persistence of the following general nonautonomous Lotka-Volterra system is considered,By the above analysis, we consider the following Lotka-Volterra systemThe suficient conditions for the partial permanence and extinction of above system are obtained, which include the corresponding ones in the literatures.
In Chapter 3, we mainly investicate in uniform persistence for a diffusive LotkaVolterrasystem with time delay,
In Chapter 4, firstly we consider the following single species diffusive systemThe sufficient conditions for the uniform persistence of above system are obtained.
Secondly, we propose the following nonlinear diffusive predator-prey systemsome sufficient conditions for the persistence of above system are obtained. Our results improve and extend the corresponding ones in the literatures.
Chapter 5 is considered with a Lotka-Volterra system with time delaysome new sufficient conditions for permanence and exponential stability of above systemare obtained.
第一章,介绍了所关注问题的研究背景和本文的主要工作.
第二章,首先讨论了一类广义非自治N-种群Lotka-Volterra系统的强持久性,在此基础上,研究了经典的Lotka-Volterra系统并得到了系统部分持久与灭绝的充分条件,得到了若干新的结果,其中一些结果包含了原文献的工作.
第三章,主要研究了具有时滞的Lotka-Volterra扩散系统给出了系统一致持久的充分条件.
第四章,首先考虑了单种群扩散系统的一致持久性,在此基础上,又讨论了非线性捕食系统得到其若干持久性的充分条件.所得结果改进并推广了一些已有的结果。
第五章,考虑了具有时滞变元的Lotka-Volterra模型的一致持久性和指数稳定性,建立了若干新的结果,改进并推广了一些已有结果.
With the development of science, Lotka-Volterra system and Gilpin-Ayala system, as two basic models in population dynamics, play important roles in physical and social science. This thesis is composed of five chapters to consider the persistence, extinction or global exponential stability of above two systems. The results given in this paper improve and extend the corresponding ones in the literatures.
In Chapter 1, we introduce the historical background of problems which will be investigated and the main works of this thesis.
In Chapter 2, firstly the strong persistence of the following general nonautonomous Lotka-Volterra system is considered,By the above analysis, we consider the following Lotka-Volterra systemThe suficient conditions for the partial permanence and extinction of above system are obtained, which include the corresponding ones in the literatures.
In Chapter 3, we mainly investicate in uniform persistence for a diffusive LotkaVolterrasystem with time delay,
In Chapter 4, firstly we consider the following single species diffusive systemThe sufficient conditions for the uniform persistence of above system are obtained.
Secondly, we propose the following nonlinear diffusive predator-prey systemsome sufficient conditions for the persistence of above system are obtained. Our results improve and extend the corresponding ones in the literatures.
Chapter 5 is considered with a Lotka-Volterra system with time delaysome new sufficient conditions for permanence and exponential stability of above systemare obtained.
引文
[1] Philip Hartman. Ordinary Differential Equations[M]. Boston: Birkhauser, 1982.
[2]马知恩,周义仓.常微分方程定性与稳定性方法[M].北京:科学出版社,2001.
[3]张芷芬,丁同仁.黄文灶,董镇喜,微分方程定性理论[M].北京:科学出版社, 1985.
[4] T. P. Dreyer. Modelling with Ordinary Differential Equations[M]. the United States: CRC Press, Inc, 1993.
[5] Wolfgang Walter. Ordinary Differential Equations[M]. New York: Springer-Verlag, 1998.
[6]廖晓昕.稳定性的数学理论及应用[M].武汉:华中师范大学出版社, 1988.
[7] Driver R. D, Ordinary and Delay Differential Equations[M]. Berlin, Springer-Verlag, 1977.
[8]郑祖庥.泛函微分方程理论[M].合肥:安徽教育出版社, 1994.
[9]徐远通.泛函微分方程与测度微分方程[M].广州:中山大学出版社,1988.
[10] Jack Hale. Theory of Functional Differential Equations[M]. New York: Spinger-Verlag, 1977.
[11] J. D. Murray. Mathematical Biology[M]. New York: Springer-Verlag, 1998.
[12] Gopalsamy K. Stability and Oscillation in Delay Differential Equations of Population Dynamics[M]. Dordrecht: Kluwer Academic Publishers, 1992.
[13] Lakshmikantham V., Bainov D. D., Simeonov P S. Theory of Impulsive Differential Equations[M]. Singapore: World Scientific, 1989.
[14] Kuang Y. Delay Differential Equations with Applications in Population Dynamics [M]. Boston: Academic Press, 1993.
[15]陈兰荪.数学生态学模型与研究方法[M].北京:科学出版社, 1988.
[16]陈兰荪,陈健.非线性生物动力系统[M],北京:科学出版社, 1993.
[17]张炳根.生态学数学模型[M].青岛:青岛海洋大学出版社, 1990.
[18]马知恩.种群生态学的数学建模与研究[M].合肥:安徽教育出版社, 1996.
[19]William F.Lucas.微分方程模型[M].长沙:国防科技大学出版社, 1998.
[20] Yongkun Li, Yang Kuang. Periodic solutions of periodic delay Lotka-Volterra equations and systems[J]. J. Math. Anal. Appl., 2001, 255: 260-280.
[21] Norimichi Hirano, SLawomire Rybichi. Existence of periodic solutions for the LotkaVolterratype systems[J]. J. Differ. Equa., 2006, 229: 121-137.
[22] Zhijun Liu, Lansun Chen. Periodic solution of neutral Lotka-Volterra system with periodicdelays[J]. J. Math. Anal. Appl., 2006, 324: 435-451.
[23] Rui Xu , Zhiqiang Wang, Periodic solutions of a nonautonomous predator-prey system with stage structure and time delays[J]. J. Comput. Appl. Math., 2006, 196: 70-86.
[24] Zhihu Zhou, Zhihui Yang, Periodic solutions in higher-dimensional Lotka-Volterra neutralcompetition systems with state-dependent delays[J]. Appl. Math. Comput., 2007, 189: 986-995.
[25] Yonghui Xia, Jinde Cao, Suisun Cheng. Periodic solutions for a Lotka-Volterra mutualismsystem with several delays[J], Appl. Math. Modelling, 2007, 31: 1960-1969.
[26] Lingzhen Dong, Lansun Chen, Peilin Shi. Periodic solutions for a two-species nonautonomouscompetition system with diffusion and impulses [J]. Chaos, Solitons and Fractals,2007, 32: 1916-1926.
[27] Xinzhu Meng, Lansun Chen. Periodic solution and almost solution for a nonautonomous Lotka-Volterra dispersal system with infinite delay[J]. J. Math. Anal. Appl., 2008, 339: 125-145.
[28] Haihui Wu, Yonghui Xia, Muren Lin. Existence of positive periodic solution of mutualismsystem with several delays[J]. Chaos, Solitons and Fractals, 2008, 36: 487-493.
[29] Hui Fang, Yongfeng Xiao. Existence of multiple periodic solutions for delay LotkaVolterracompetition patch systems with harvesting[J]. Appl. Math. Modelling, doi: 10.1016/j.apm.2007.12.025.
[30] Shiping Lu. On the existence of positive periodic solutions to a Lotka Volterra cooperative population model with multiple delays[J]. Nolinear Anal, 2008, 68: 1453-1461.
[31] Sun Wen, Shihua Chen, Huihai Mei. Positive periodic solution of a more realistic three- species Lotka-Volterra model with delay and density regulation[J]. Chaos, Solitons and Fractals, 10.1016/j.chaos.2007.10.027.
[32] Xinzhu Meng. Lansun Chen, Almost periodic solution of non-autonomous Lotka- Volterra Predator-prey dispersal system with delays[J]. J. Theoretical Biol., 2006, 243: 562-574.
[33] Changzhong Wang, Jinlin Shi. Positive almost periodic solutions of a class of Lotka- Volterra type competitive system with delays and feedback controls [J]. Appl. Math. Comput., 2007, 193: 240-252.
[34] Wang Qi, Bingxiang Dai, Almost Periodic solution for n-species Lotka-Volterra competitive system with delays and feedback controls[J]. Appl. Math. Comput., 10.1016/j.amc.2007.10.055.
[35] Rong Yuan. On almost periodic solutions of logistic delay differential equations with almost periodic time dependence[J]. J. Math. Anal. Appl., 2007, 330: 780-798.
[36] Kaien Liu, Xilin Fu. Stability of functional differential equations with impulses[J]. J. Math. Anal. Appl., 2007, 328: 830-841.
[37] Antonio Tineo. Asymptotic behavior of an invading species[J], Nonlinear Analysis: Real World Applications, 2008, 9: 1-8.
[38] Wenzhen Gan, Zhihui Lin. Coexistence and asymptotic periodicity in a competitor- mutualist model[J]. J. Math. Anal. Appl. 2008, 337: 1089-1099.
[39] Xianhua Tang, Daomin Cao, Xingfu Zou. Global attractivity of positive periodic solution to periodic Lotka-Volterra competition systems[J], J. Differ. Equa., 2006, 228: 580-610.
[40] Wei Fengying, Wang Ke. Global stability and asymptotically periodic solution for nonau- tonomous cooperative Lotka-Volterra diffusion system[J]. Appl. Math. Comput., 2006, 182: 161-165.
[41] Fengyan Wang. Guoping Pang. The global stability of a delayed predator-prey system with two stage-structure[J]. Chaos, Solitons and Fractals, 10.1016/j.chaos.2007.08.024.
[42] Wonlyyui Ko, Kimun Ryu. Qualitative analysis of a predator-prey model with Holling type Ⅱ functional response incorporating a prey refuge[J]. J. Differ. Equa., 2006, 231: 534-550.
[43]滕志东.具有时滞的非自治Lotka-Volterra竞争系统的全局渐近稳定性[J].微分方 程理论和应用,487-492.
[44]郑丽丽,宋新宇.一类带有扩散和时滞的捕食与被捕食模型的渐近性质[J].应用 数学学报,2004,27(2):361-370.
[45] M. Braun. Differential Equations and their Applications[M]. New York: Springer-Verlag, 1983.
[46] S. Ahmad, A. C. Lazer. One species extinction in an autonomous competition model[J]. Proceeding of the First World Congress of Nonlinear Analysis, Walter de Gruyter, Berlin, 1996, 359-368.
[47] K. Gopalsamy. Global asymptotic stability in a periodic Lotka-Volterra system[J], J. Austral. Math. Soc. Ser. B, 1986, 27: 66-72.
[48] K. Gopalsamy. Global asymptotic stability in an almost-periodic Lotka-Volterra system[J], J. Austral. Math. Soc. Ser. B, 1986, 27: 346-360.
[49] A. Tineo, C. Alvarez. A different consideration about the globally asymptotic stable solution of the periodic n-competing species problem[J], J. Math. Anal. Appl. 1991, 159: 44-60.
[50] Shair Ahmad, Alan C. Lazer. Necessary and sufficient average growth in a Lotka-Volterra system[J], Nonlinear Anal., 1998, 34: 191-228,
[51] Shair Ahmad. Francisco Montes de Oca, Extinction in nonautonomous T-periodic competitiveLotka-Volterra system[J]. Appl. Math. Comput., 1998, 90(2-3): 155-166.
[52] Shair Ahmad, A. C. Lazer. On a property of nonautonomous Lotka-Volterra competition model[J]. Nonlinear Anal., 1999, 37(5): 603-611.
[53] S. Ahmad, A. C. Lazer. Average conditions for global asymptotic stability in a nonautonomousLotka-Volterra systems[J]. Nonlinear Anal, 2000, 40: 37-49.
[54] Shair Ahmad, I. M. Stamova. Almost necessary and sufficient conditions for survival of species[J]. Nonlinear Analysis: Real World Applications, 2004, 5(1): 219-229.
[55] Shair Ahmad, Alan C. Lazer. Average growth and extinction in a competitive LotkaVolterrasystem[J]. Nonlinear Anal., 2005, 62(3): 545-557.
[56] Shair Ahmad, Ivanka M. Stamova. Partial persistence and extinction in N-dimensional competitive systems[J]. Nonlinear Anal., 2005, 60(5): 821-836.
[57] S. Ahmand, A. C. Lazer. Average growth and total permanence in a competitive LotkaVolterrasystem[J]. Ann. Mat. Pur. Appl. 2006, 185: S47-S67.
[58] Shair Ahmad, Ivanka M. Stamova. Asymptotic stability of competitive systems with delays and impulsive perturbations[J], J. Math. Anal. Appl., 2007, 334(1): 686-700.
[59] Shair Ahmad, Ivanka M. Stamova. Asymptotic stability of a N-dimensional impulsive competitive system[J]. Nonlinear Analysis: Real World Applications, 2007, 8(2): 654-663.
[60] Shair Ahmad, Ivanka Stamova. Survival and extinction in competitive systems [J]. NonlinearAnalysis: Real World Applications, 2008, 9: 708-717.
[61] J. Zhao, J. Jiang, A. C. Lazer. The permanence and global attractivity in a nonautonoumousLotka-Volterra system[J]. Nonlinear Anal., 2002, 5: 265-276.
[62]滕志东,陈兰荪.非自治竞争Lotka-Volterra系统的持续生存和全局稳定[J].高校 应用数学学报,1999,14(2):
[63]滕志东.一般非自治单种群Kolmgorov时滞生态系统的持久性准则及其应用[J]. 新疆大学学报,2005,22(1):9-16.
[64]滕志东.具有时滞的非自治Lotka-Volterra竞争系统的持久与灭绝[J].数学学报, 2001,44(2):293-306.
[65]崔景安.时滞Lotka-Volterra系统的持久性和周期解[J].数学学报, 2004,47(3): 511-520.
[66]滕志东.Lotka-Volterra型N-种群竞争系统的持久性和稳定性[J].数学学报,2002, 45(5):905-918.
[67]赵立纯.Lotka-Volterra区间系统的鲁棒持久性[J].鞍山师范学院学报,2003,5(6): 18-21.
[68]郑绿洲,李必文,程舰.非自治Lotka-Volterra型竞争生态系统的绝灭性和持久性 [J].数学杂志,2003,23(3):295-298.
[69] Chen Fengde. Persistence and periodic orbits for two-species non-autonomous diffusion Lotka-Volterra models[J]. Appl. Math. J. Chines Univ. Ser. B, 2004, 19(4): 359-366.
[70] Chen Fengde. Persistence and global stability for nonautonomous cooperative system with diffusion and time delay[J].北京大学学报(自然科学版),2003,39(1):22-28.
[71] Jinxian Li, Jurang Yan. Partial permanence and extinction in a N-species nonautonomousLotka-Volterra competitive system[J]. Comput. Math. Appl., 2008, 55: 76-88.
[72] Jinxian Li, Jurang Yan. Persistence for Lotka-Volterra Patch-system with time delay[J]. Nonlinear Analysis: Real World Applications, 2008, 9: 490-499.
[73] Jinxian Li, Guirong Liu, Xiaoling Hu, Liping Wen. Persistence for two-species nonautonomousLotka-Volterra patch-system with time delay [J]. Complex Systems and Applications-Modeling, Control and Simulations, 2007, 14: 968-971.
[74] Jinxian Li, Aimin Zhao, Jurang Yan. The permanence and global attractivity of a Kolmogorovsystem with feedback controls[J]. Nonlinear Analysis: Real World Applications, 2007, doi: 10.1016/j.nonrwa.2007.10.012.
[75]李金仙,燕居让.一类带有时滞的非自治捕食扩散系统的一致持久性和全局渐近 性定理[J].应用数学学报,2007,30(2):312-320.
[76]李金仙,燕居让.非自治脉冲Lotka-Volterra系统的持久性与渐近稳定性[J].山西 大学学报(自然科学版),2007,30(1):24-27.
[77] Xinzhu Meng, Ianjun Jiao, Lansun Chen. Global dynamics behaviors for a nonautonomousLotka-Volterra almost periodic dispersal system with delay [J]. Nonlinear Anal., (2007), doi: 10.1016/j. na. 2007. 04. 006.
[78] Yoshiaki Muroya. Permanence of nonautonomous Lotka-Volterra delay differntial sys- tems[J]. Appl. Math. Lett., 2006, 19: 445-450.
[79] M. E. Gilpin, F. J. Ayala. Global models of growth and competition[J]. Proc. Nat. Acad. Sci. USA 1973, 70: 3590-3593.
[80] Fengde Chen, Liping Wu, Zhong Li. Permanence and global attractivity of the discrete Gilpin-Ayala type population model [J]. Comput. Math. Appl., 2007, 53: 1214-1227.
[81] F. Chen and X. Xie. Permanence and extinction in nonlinear single and multiple species system with diffusion [J]. Appl. Math. Comput., 2006;177: 410-426.
[82] J. Yan, Q. Feng. Global attractivity and oscillation in a nonlinear delay equation[J]. Nonlinear Anal., TMA 2001, 43(1): 101-108.
[83] F. Chen. Average conditions for permanence and extinction in nonautonomous Gilpin- Ayala competition model[J]. Nonlinear Anal.: Real World Applications 2006;7: 895-915.
[84] C. Shi, Z. Li, F. Chen. The permanence and extinction of a nonlinear growth rate single-species non-autonomous dispersal models with time delays[J]. Nonlinear Anal: Real World Applications, 2007, 8: 1536-1550.
[85] J. Zhao, W. Chen. The qualitative analysis of N-species nonlinear prey -competition systems[J]. Appl. Math. Comput., 2004, 149: 567-576.
[86] S. Harrison. Metapopulations and conservation, In Largescale Ecology and Conservation Biology [J]. the 35th Symposium of the British Ecological Society with the Society for Coservation Biology, University of Southampton, 1994, 111-128.
[87] J. Diamond. Overview of Recent Extinctions. In Coservation for the Twenty-First Cen- tury[M]. New York: Oxford University Press, 1989.
[88] Y. Xun. State, disturbance and devolopment of Chinese Giant Pandas[J]. Chinese Wild-ife, 1990, 9-11.
[89] Y. Yange et al., Giant panda's moving habit in poping[J]. Acta Theridogica Sinica, 1994, 14(1): 9-14.
[90] C. Yucun. The urgent problems in reproduction of giant pandas[J]. Chines Wildlife, 1994, 3: 3-5.
[91] L. J. S. Allen. Persistence and extinction in single-species reaction-diffusion modles[J]. Bull. Math. Biol., 1983, 45: 209-227.
[92] L. J. S. Allen. Persistence, extinction, and critical patch number for island popula- tions[J]. J. Math. Bid., 1987, 24: 617-625.
[93] E. Beretta, P. Solimano, Y. Takeuchi. Global stability and periodic orbits for two-patch predator-prey diffusion-delay models[J]. Math. Biosci., 1987, 85: 153-183.
[94] E. Beretta, Y. Takeuchi. Global stability of single-species diffusion models with continuous time delaysp]. Bull. Math. Bid., 1987, 49(4): 431-448.
[95] L. Edelstein-keshet. Mathematical Models in Biology[M]. New York: Random House,1988.
[96] H. I. Freedman. Single species migration in two habitats: persistence and extinction [J]. Math. Model., 1987, 8: 778-780.
[97] H. I. Freedman, Y. Takeuchi. Global stability and predator dynamics in a model of prey dispersal in a patchy environment [J]. Nonlinear. Anal., 1989, 13: 993-1002.
[98] H. I. Freedman, J. H. Wu. Periodic solutions of single species models with periodic delay[J]. SIAM J. Math. Anal., 1992, 23: 689-701.
[99] Y. Kuang, R. H. Martin, H. L. Smith. Global stability for infinity delay, dispersive Lotka-Volterra systems: weakly interacting populations in nearly indentical patches [J]. J. Dynam. Differ. Equa., 1991, 3: 339-360.
[100] Y. Kuang, H. L. Smith. Global stability for infinite delay Lotka-Volterra type sys- tems[J]. J. Differ. Equa., 1993, 103: 221-246.
[101] Y. Kuang, Y. Takeuchi, Predator-prey dynamics in models of prey dispersal in two- patch environments [J]. Math. Biosci., 1994, 120: 77-98.
[102] S. A. Levin. Dispersion and population inter actions [J]. Amer. Natur., 1974, 108: 207- 228.
[103] Z. Y. Lu, Y. Takeuchi. Global asymptotic behavior in single-species discrete diffusion systems[J]. J. Math. Biol., 1993, 32: 67-77.
[104] Z. Y. Lu, Y. Takeuchi. Permanence and global stability for cooperative Lotka-Volterra diffusion systems[J]. Nonlinear Anal., 1992, 19: 963-975.
[105] R. R. Vance. The effect of dispersal on population stability in one-species, discrete space population growth models[J]. Amer. Nat., 1984, 123: 230-254.
[106] A. Hastings. Dynamics of a single species in a spatially varing environment: the stabilizing role of higher dispersal rates[J]. J. Math. Biol., 1982, 16: 49-55.
[107] J. Zhang, L. Chen. Periodic solutions of single-species nonautonomous diffusion models with continuous time delays[J]. Math. Comput. Modelling, 1996, 23: 17-27.
[108] Zhang J., Chen L., Chen X, Persistence and global stability for two-species nonautonomous competition Lotka-Volterra patch-system with time delay[J]. Nonlinear Anal., 1999, 37: 1019-1028.
[109] S. Ahmand. Extinction of species nonautonomous Lotka-Volterra systems[J]. Proc. Amer. Math. Soc, 1999, 127: 2905-2910.
[110] S. Ahmand, A. C. Lazer. Average growth and extinction in a competitive Lotka- Volterra system[J]. Nonlinear Anal., 2005, 62: 547-557.
[111] A. Tinea. An iterative scheme for the N-competing species problem[J]. J. Differ. Equa., 1995, 116:1-15.
[112] Redheffer. Nonautonomous Lotka-Volterra systems I[J]. J. Differ. Equa., 1996, 127: 519-541.
[113] Zhidong Teng, Zhiming Li. Permanence and asymptotic behavior of the N-species nonautonomous Lotka-Volterra competitive systems[J]. Comput. Math. Appl., 2000, 39: 107-116.
[114] Chen Fengde, Shi Linlin, Chen Xiaoxing. A nonautonomous diffusion predator-prey system with functional' response and time delay [J]. 纯粹数学与应用数学, 2003, 19(4): 311-317.
[115] Zheng Weiwei, Cui Jingan. Control of population size and stability through diffusion: a stage-structure model[J].生物数学学报,2001,16(3):275-280.
[116]穆晓霞,崔景安.扩散对一类食饵-捕食系统正平衡点和持久性的影响[J].河南 师范大学学报(自然科学版),2006,34(1):161-165.
[117] Song Xinyu, Ye Kaili. Conditions for global stability of n-patches ecological system with dispersion[J]. J. Math. Research and Exposition, 2001, 21(3): 329-333.
[118]崔景安.具有扩散和时滞的捕食系统的持续生存[J].数学学报,2005,48(3):479- 488.
[119] K. Kishimoto. Coexistence of any number of species in the Lotka-Volterra competitive system over two patches[J]. Theoret. Popu. Biol, 1990, 38: 149-158.
[120] Y. Takeuchi. Conflict between the need to forage and the need to avoid competition; Persistence of two-species model[J]. Math. Biosi., 1990, 99: 181-194.
[121] G. Z. Zeng, L. S. Chen. Persistence and periodic orbits for two-species nonautonomous diffusion Lotka-Volterra models[J]. Math. Comput. Modelling, 1994, 20: 69-80.
[122] Song X, Cui J. Uniform persistence and global attractivity for nonautonomous competitivesystem with nonlinear dispersion and delays]J]. Appl. Math. Comput., 2003, 146: 273-288.
[123] Song X, Chen L. Harmless delays and global attractivity for nonautonomous PredatorPreysystem with dispersion[J]. Comput. Math. Appl., 2000, 39: 33-42.
[124] Sun W., Teng Z., Yu Y. Permanence in nonautonomous Predator-Prey Lotka-Volterra systems[J]. Acta Math. Appl. Sinica, English Series, 2002, 18(3): 411-422.
[125] Fengde Chen. Some new results on the permanence and extinction of nonautonomous Gilpin Ayala type competition model with delays[J]. Nonlinear Anal.: Real World Applications,2006, 7(5): 1205-1222.
[126] Z. Teng, L. Chen. Permanence and extinction of periodic predator-prey system in a patchy environment with delay[J]. Nonlinear Anal.: Real World Applications, 2003, 4: 335-364.
[127] J. Cui, Y. Takeuche. Permanence of a single-species dispersal system and predator survival[J]. J. Comput. Appl. Math., 2005, 175: 375-394.
[128] M. Fan, K. Wang. Global periodic solutions of a generalized n-species Gilpin-Ayala competition model[J]. Comput. Math. Appl., 2000, 40: 1141-1151.
[129] J. Cui, L. Chen. The effect of diffusion on time varying logistic population growth [J]. Comput. Math. Appl., 1998, 36(3): 1-9.
[130] H. L. Smith. Cooperative systems of differential equations with concave nonlineari-ties[J]. Nonlinear Anal., 1986, 10: 1037-1052.
[131] J. Cui, Y. Takeuchi, Z. Lin. Permanence and extinction for dispersal population systems[J]. J. Math. Anal. Appl., 2004, 298: 73-93.
[132] J. Cui, L. Chen. Permanence and extinction in Logistic and Lotka-Volterra systems with diffusion[J]. J. Math. Anal. Appl., 2001, 258: 521-535.
[133] P. Hartman. Ordinary Differential Equations[M]. Boston: Birkh a user, 1982.
[134] T. Asai, T. Fukai, S. Tanaka. A subthreshold MOS circuit for the Lotka-Volterra neural network producing the winner-share all solution[J]. Neural Networks, 1999,12: 211-216.
[135] Y. Moreau, S. Louies, J. Vandewalle, L. Brenig. Embedding recurrent neural networks into predator-prey models[J]. Neural Networks, 1999, 12: 237-245.
[136] Ray Redheffer. Lotka-Volterra systems with constant interaction coefficients[J]. NonlinearAnal., 2001, 46: 1151-1164.
[137]曾永福. Lotka-Volterra方程的全局指数稳定性[J].四川大学学报,2005,42(1): 38-40.
[138] Wei Lin, Tianping Chen. Positive periodic solutions of delayed periodic Lotka-Volterra systems[J]. Physics Letters A, 2005, 334:273-287.
[139] J. Qiu, J. Cao. Exponential stability of a competitive Lotka-Volterra system with delays[J]. Appl. Math. Comput. 2007, doi: 10.1016/j.amc.2007.11.046.
[140] Zhao Weirui. Dynamics of Cohen-Grossberg neural network with variable coefficient and time-varing delays[J]. Nonlinear Analysis: Real World Applications, 2008, 9: 1024-1037.
[2]马知恩,周义仓.常微分方程定性与稳定性方法[M].北京:科学出版社,2001.
[3]张芷芬,丁同仁.黄文灶,董镇喜,微分方程定性理论[M].北京:科学出版社, 1985.
[4] T. P. Dreyer. Modelling with Ordinary Differential Equations[M]. the United States: CRC Press, Inc, 1993.
[5] Wolfgang Walter. Ordinary Differential Equations[M]. New York: Springer-Verlag, 1998.
[6]廖晓昕.稳定性的数学理论及应用[M].武汉:华中师范大学出版社, 1988.
[7] Driver R. D, Ordinary and Delay Differential Equations[M]. Berlin, Springer-Verlag, 1977.
[8]郑祖庥.泛函微分方程理论[M].合肥:安徽教育出版社, 1994.
[9]徐远通.泛函微分方程与测度微分方程[M].广州:中山大学出版社,1988.
[10] Jack Hale. Theory of Functional Differential Equations[M]. New York: Spinger-Verlag, 1977.
[11] J. D. Murray. Mathematical Biology[M]. New York: Springer-Verlag, 1998.
[12] Gopalsamy K. Stability and Oscillation in Delay Differential Equations of Population Dynamics[M]. Dordrecht: Kluwer Academic Publishers, 1992.
[13] Lakshmikantham V., Bainov D. D., Simeonov P S. Theory of Impulsive Differential Equations[M]. Singapore: World Scientific, 1989.
[14] Kuang Y. Delay Differential Equations with Applications in Population Dynamics [M]. Boston: Academic Press, 1993.
[15]陈兰荪.数学生态学模型与研究方法[M].北京:科学出版社, 1988.
[16]陈兰荪,陈健.非线性生物动力系统[M],北京:科学出版社, 1993.
[17]张炳根.生态学数学模型[M].青岛:青岛海洋大学出版社, 1990.
[18]马知恩.种群生态学的数学建模与研究[M].合肥:安徽教育出版社, 1996.
[19]William F.Lucas.微分方程模型[M].长沙:国防科技大学出版社, 1998.
[20] Yongkun Li, Yang Kuang. Periodic solutions of periodic delay Lotka-Volterra equations and systems[J]. J. Math. Anal. Appl., 2001, 255: 260-280.
[21] Norimichi Hirano, SLawomire Rybichi. Existence of periodic solutions for the LotkaVolterratype systems[J]. J. Differ. Equa., 2006, 229: 121-137.
[22] Zhijun Liu, Lansun Chen. Periodic solution of neutral Lotka-Volterra system with periodicdelays[J]. J. Math. Anal. Appl., 2006, 324: 435-451.
[23] Rui Xu , Zhiqiang Wang, Periodic solutions of a nonautonomous predator-prey system with stage structure and time delays[J]. J. Comput. Appl. Math., 2006, 196: 70-86.
[24] Zhihu Zhou, Zhihui Yang, Periodic solutions in higher-dimensional Lotka-Volterra neutralcompetition systems with state-dependent delays[J]. Appl. Math. Comput., 2007, 189: 986-995.
[25] Yonghui Xia, Jinde Cao, Suisun Cheng. Periodic solutions for a Lotka-Volterra mutualismsystem with several delays[J], Appl. Math. Modelling, 2007, 31: 1960-1969.
[26] Lingzhen Dong, Lansun Chen, Peilin Shi. Periodic solutions for a two-species nonautonomouscompetition system with diffusion and impulses [J]. Chaos, Solitons and Fractals,2007, 32: 1916-1926.
[27] Xinzhu Meng, Lansun Chen. Periodic solution and almost solution for a nonautonomous Lotka-Volterra dispersal system with infinite delay[J]. J. Math. Anal. Appl., 2008, 339: 125-145.
[28] Haihui Wu, Yonghui Xia, Muren Lin. Existence of positive periodic solution of mutualismsystem with several delays[J]. Chaos, Solitons and Fractals, 2008, 36: 487-493.
[29] Hui Fang, Yongfeng Xiao. Existence of multiple periodic solutions for delay LotkaVolterracompetition patch systems with harvesting[J]. Appl. Math. Modelling, doi: 10.1016/j.apm.2007.12.025.
[30] Shiping Lu. On the existence of positive periodic solutions to a Lotka Volterra cooperative population model with multiple delays[J]. Nolinear Anal, 2008, 68: 1453-1461.
[31] Sun Wen, Shihua Chen, Huihai Mei. Positive periodic solution of a more realistic three- species Lotka-Volterra model with delay and density regulation[J]. Chaos, Solitons and Fractals, 10.1016/j.chaos.2007.10.027.
[32] Xinzhu Meng. Lansun Chen, Almost periodic solution of non-autonomous Lotka- Volterra Predator-prey dispersal system with delays[J]. J. Theoretical Biol., 2006, 243: 562-574.
[33] Changzhong Wang, Jinlin Shi. Positive almost periodic solutions of a class of Lotka- Volterra type competitive system with delays and feedback controls [J]. Appl. Math. Comput., 2007, 193: 240-252.
[34] Wang Qi, Bingxiang Dai, Almost Periodic solution for n-species Lotka-Volterra competitive system with delays and feedback controls[J]. Appl. Math. Comput., 10.1016/j.amc.2007.10.055.
[35] Rong Yuan. On almost periodic solutions of logistic delay differential equations with almost periodic time dependence[J]. J. Math. Anal. Appl., 2007, 330: 780-798.
[36] Kaien Liu, Xilin Fu. Stability of functional differential equations with impulses[J]. J. Math. Anal. Appl., 2007, 328: 830-841.
[37] Antonio Tineo. Asymptotic behavior of an invading species[J], Nonlinear Analysis: Real World Applications, 2008, 9: 1-8.
[38] Wenzhen Gan, Zhihui Lin. Coexistence and asymptotic periodicity in a competitor- mutualist model[J]. J. Math. Anal. Appl. 2008, 337: 1089-1099.
[39] Xianhua Tang, Daomin Cao, Xingfu Zou. Global attractivity of positive periodic solution to periodic Lotka-Volterra competition systems[J], J. Differ. Equa., 2006, 228: 580-610.
[40] Wei Fengying, Wang Ke. Global stability and asymptotically periodic solution for nonau- tonomous cooperative Lotka-Volterra diffusion system[J]. Appl. Math. Comput., 2006, 182: 161-165.
[41] Fengyan Wang. Guoping Pang. The global stability of a delayed predator-prey system with two stage-structure[J]. Chaos, Solitons and Fractals, 10.1016/j.chaos.2007.08.024.
[42] Wonlyyui Ko, Kimun Ryu. Qualitative analysis of a predator-prey model with Holling type Ⅱ functional response incorporating a prey refuge[J]. J. Differ. Equa., 2006, 231: 534-550.
[43]滕志东.具有时滞的非自治Lotka-Volterra竞争系统的全局渐近稳定性[J].微分方 程理论和应用,487-492.
[44]郑丽丽,宋新宇.一类带有扩散和时滞的捕食与被捕食模型的渐近性质[J].应用 数学学报,2004,27(2):361-370.
[45] M. Braun. Differential Equations and their Applications[M]. New York: Springer-Verlag, 1983.
[46] S. Ahmad, A. C. Lazer. One species extinction in an autonomous competition model[J]. Proceeding of the First World Congress of Nonlinear Analysis, Walter de Gruyter, Berlin, 1996, 359-368.
[47] K. Gopalsamy. Global asymptotic stability in a periodic Lotka-Volterra system[J], J. Austral. Math. Soc. Ser. B, 1986, 27: 66-72.
[48] K. Gopalsamy. Global asymptotic stability in an almost-periodic Lotka-Volterra system[J], J. Austral. Math. Soc. Ser. B, 1986, 27: 346-360.
[49] A. Tineo, C. Alvarez. A different consideration about the globally asymptotic stable solution of the periodic n-competing species problem[J], J. Math. Anal. Appl. 1991, 159: 44-60.
[50] Shair Ahmad, Alan C. Lazer. Necessary and sufficient average growth in a Lotka-Volterra system[J], Nonlinear Anal., 1998, 34: 191-228,
[51] Shair Ahmad. Francisco Montes de Oca, Extinction in nonautonomous T-periodic competitiveLotka-Volterra system[J]. Appl. Math. Comput., 1998, 90(2-3): 155-166.
[52] Shair Ahmad, A. C. Lazer. On a property of nonautonomous Lotka-Volterra competition model[J]. Nonlinear Anal., 1999, 37(5): 603-611.
[53] S. Ahmad, A. C. Lazer. Average conditions for global asymptotic stability in a nonautonomousLotka-Volterra systems[J]. Nonlinear Anal, 2000, 40: 37-49.
[54] Shair Ahmad, I. M. Stamova. Almost necessary and sufficient conditions for survival of species[J]. Nonlinear Analysis: Real World Applications, 2004, 5(1): 219-229.
[55] Shair Ahmad, Alan C. Lazer. Average growth and extinction in a competitive LotkaVolterrasystem[J]. Nonlinear Anal., 2005, 62(3): 545-557.
[56] Shair Ahmad, Ivanka M. Stamova. Partial persistence and extinction in N-dimensional competitive systems[J]. Nonlinear Anal., 2005, 60(5): 821-836.
[57] S. Ahmand, A. C. Lazer. Average growth and total permanence in a competitive LotkaVolterrasystem[J]. Ann. Mat. Pur. Appl. 2006, 185: S47-S67.
[58] Shair Ahmad, Ivanka M. Stamova. Asymptotic stability of competitive systems with delays and impulsive perturbations[J], J. Math. Anal. Appl., 2007, 334(1): 686-700.
[59] Shair Ahmad, Ivanka M. Stamova. Asymptotic stability of a N-dimensional impulsive competitive system[J]. Nonlinear Analysis: Real World Applications, 2007, 8(2): 654-663.
[60] Shair Ahmad, Ivanka Stamova. Survival and extinction in competitive systems [J]. NonlinearAnalysis: Real World Applications, 2008, 9: 708-717.
[61] J. Zhao, J. Jiang, A. C. Lazer. The permanence and global attractivity in a nonautonoumousLotka-Volterra system[J]. Nonlinear Anal., 2002, 5: 265-276.
[62]滕志东,陈兰荪.非自治竞争Lotka-Volterra系统的持续生存和全局稳定[J].高校 应用数学学报,1999,14(2):
[63]滕志东.一般非自治单种群Kolmgorov时滞生态系统的持久性准则及其应用[J]. 新疆大学学报,2005,22(1):9-16.
[64]滕志东.具有时滞的非自治Lotka-Volterra竞争系统的持久与灭绝[J].数学学报, 2001,44(2):293-306.
[65]崔景安.时滞Lotka-Volterra系统的持久性和周期解[J].数学学报, 2004,47(3): 511-520.
[66]滕志东.Lotka-Volterra型N-种群竞争系统的持久性和稳定性[J].数学学报,2002, 45(5):905-918.
[67]赵立纯.Lotka-Volterra区间系统的鲁棒持久性[J].鞍山师范学院学报,2003,5(6): 18-21.
[68]郑绿洲,李必文,程舰.非自治Lotka-Volterra型竞争生态系统的绝灭性和持久性 [J].数学杂志,2003,23(3):295-298.
[69] Chen Fengde. Persistence and periodic orbits for two-species non-autonomous diffusion Lotka-Volterra models[J]. Appl. Math. J. Chines Univ. Ser. B, 2004, 19(4): 359-366.
[70] Chen Fengde. Persistence and global stability for nonautonomous cooperative system with diffusion and time delay[J].北京大学学报(自然科学版),2003,39(1):22-28.
[71] Jinxian Li, Jurang Yan. Partial permanence and extinction in a N-species nonautonomousLotka-Volterra competitive system[J]. Comput. Math. Appl., 2008, 55: 76-88.
[72] Jinxian Li, Jurang Yan. Persistence for Lotka-Volterra Patch-system with time delay[J]. Nonlinear Analysis: Real World Applications, 2008, 9: 490-499.
[73] Jinxian Li, Guirong Liu, Xiaoling Hu, Liping Wen. Persistence for two-species nonautonomousLotka-Volterra patch-system with time delay [J]. Complex Systems and Applications-Modeling, Control and Simulations, 2007, 14: 968-971.
[74] Jinxian Li, Aimin Zhao, Jurang Yan. The permanence and global attractivity of a Kolmogorovsystem with feedback controls[J]. Nonlinear Analysis: Real World Applications, 2007, doi: 10.1016/j.nonrwa.2007.10.012.
[75]李金仙,燕居让.一类带有时滞的非自治捕食扩散系统的一致持久性和全局渐近 性定理[J].应用数学学报,2007,30(2):312-320.
[76]李金仙,燕居让.非自治脉冲Lotka-Volterra系统的持久性与渐近稳定性[J].山西 大学学报(自然科学版),2007,30(1):24-27.
[77] Xinzhu Meng, Ianjun Jiao, Lansun Chen. Global dynamics behaviors for a nonautonomousLotka-Volterra almost periodic dispersal system with delay [J]. Nonlinear Anal., (2007), doi: 10.1016/j. na. 2007. 04. 006.
[78] Yoshiaki Muroya. Permanence of nonautonomous Lotka-Volterra delay differntial sys- tems[J]. Appl. Math. Lett., 2006, 19: 445-450.
[79] M. E. Gilpin, F. J. Ayala. Global models of growth and competition[J]. Proc. Nat. Acad. Sci. USA 1973, 70: 3590-3593.
[80] Fengde Chen, Liping Wu, Zhong Li. Permanence and global attractivity of the discrete Gilpin-Ayala type population model [J]. Comput. Math. Appl., 2007, 53: 1214-1227.
[81] F. Chen and X. Xie. Permanence and extinction in nonlinear single and multiple species system with diffusion [J]. Appl. Math. Comput., 2006;177: 410-426.
[82] J. Yan, Q. Feng. Global attractivity and oscillation in a nonlinear delay equation[J]. Nonlinear Anal., TMA 2001, 43(1): 101-108.
[83] F. Chen. Average conditions for permanence and extinction in nonautonomous Gilpin- Ayala competition model[J]. Nonlinear Anal.: Real World Applications 2006;7: 895-915.
[84] C. Shi, Z. Li, F. Chen. The permanence and extinction of a nonlinear growth rate single-species non-autonomous dispersal models with time delays[J]. Nonlinear Anal: Real World Applications, 2007, 8: 1536-1550.
[85] J. Zhao, W. Chen. The qualitative analysis of N-species nonlinear prey -competition systems[J]. Appl. Math. Comput., 2004, 149: 567-576.
[86] S. Harrison. Metapopulations and conservation, In Largescale Ecology and Conservation Biology [J]. the 35th Symposium of the British Ecological Society with the Society for Coservation Biology, University of Southampton, 1994, 111-128.
[87] J. Diamond. Overview of Recent Extinctions. In Coservation for the Twenty-First Cen- tury[M]. New York: Oxford University Press, 1989.
[88] Y. Xun. State, disturbance and devolopment of Chinese Giant Pandas[J]. Chinese Wild-ife, 1990, 9-11.
[89] Y. Yange et al., Giant panda's moving habit in poping[J]. Acta Theridogica Sinica, 1994, 14(1): 9-14.
[90] C. Yucun. The urgent problems in reproduction of giant pandas[J]. Chines Wildlife, 1994, 3: 3-5.
[91] L. J. S. Allen. Persistence and extinction in single-species reaction-diffusion modles[J]. Bull. Math. Biol., 1983, 45: 209-227.
[92] L. J. S. Allen. Persistence, extinction, and critical patch number for island popula- tions[J]. J. Math. Bid., 1987, 24: 617-625.
[93] E. Beretta, P. Solimano, Y. Takeuchi. Global stability and periodic orbits for two-patch predator-prey diffusion-delay models[J]. Math. Biosci., 1987, 85: 153-183.
[94] E. Beretta, Y. Takeuchi. Global stability of single-species diffusion models with continuous time delaysp]. Bull. Math. Bid., 1987, 49(4): 431-448.
[95] L. Edelstein-keshet. Mathematical Models in Biology[M]. New York: Random House,1988.
[96] H. I. Freedman. Single species migration in two habitats: persistence and extinction [J]. Math. Model., 1987, 8: 778-780.
[97] H. I. Freedman, Y. Takeuchi. Global stability and predator dynamics in a model of prey dispersal in a patchy environment [J]. Nonlinear. Anal., 1989, 13: 993-1002.
[98] H. I. Freedman, J. H. Wu. Periodic solutions of single species models with periodic delay[J]. SIAM J. Math. Anal., 1992, 23: 689-701.
[99] Y. Kuang, R. H. Martin, H. L. Smith. Global stability for infinity delay, dispersive Lotka-Volterra systems: weakly interacting populations in nearly indentical patches [J]. J. Dynam. Differ. Equa., 1991, 3: 339-360.
[100] Y. Kuang, H. L. Smith. Global stability for infinite delay Lotka-Volterra type sys- tems[J]. J. Differ. Equa., 1993, 103: 221-246.
[101] Y. Kuang, Y. Takeuchi, Predator-prey dynamics in models of prey dispersal in two- patch environments [J]. Math. Biosci., 1994, 120: 77-98.
[102] S. A. Levin. Dispersion and population inter actions [J]. Amer. Natur., 1974, 108: 207- 228.
[103] Z. Y. Lu, Y. Takeuchi. Global asymptotic behavior in single-species discrete diffusion systems[J]. J. Math. Biol., 1993, 32: 67-77.
[104] Z. Y. Lu, Y. Takeuchi. Permanence and global stability for cooperative Lotka-Volterra diffusion systems[J]. Nonlinear Anal., 1992, 19: 963-975.
[105] R. R. Vance. The effect of dispersal on population stability in one-species, discrete space population growth models[J]. Amer. Nat., 1984, 123: 230-254.
[106] A. Hastings. Dynamics of a single species in a spatially varing environment: the stabilizing role of higher dispersal rates[J]. J. Math. Biol., 1982, 16: 49-55.
[107] J. Zhang, L. Chen. Periodic solutions of single-species nonautonomous diffusion models with continuous time delays[J]. Math. Comput. Modelling, 1996, 23: 17-27.
[108] Zhang J., Chen L., Chen X, Persistence and global stability for two-species nonautonomous competition Lotka-Volterra patch-system with time delay[J]. Nonlinear Anal., 1999, 37: 1019-1028.
[109] S. Ahmand. Extinction of species nonautonomous Lotka-Volterra systems[J]. Proc. Amer. Math. Soc, 1999, 127: 2905-2910.
[110] S. Ahmand, A. C. Lazer. Average growth and extinction in a competitive Lotka- Volterra system[J]. Nonlinear Anal., 2005, 62: 547-557.
[111] A. Tinea. An iterative scheme for the N-competing species problem[J]. J. Differ. Equa., 1995, 116:1-15.
[112] Redheffer. Nonautonomous Lotka-Volterra systems I[J]. J. Differ. Equa., 1996, 127: 519-541.
[113] Zhidong Teng, Zhiming Li. Permanence and asymptotic behavior of the N-species nonautonomous Lotka-Volterra competitive systems[J]. Comput. Math. Appl., 2000, 39: 107-116.
[114] Chen Fengde, Shi Linlin, Chen Xiaoxing. A nonautonomous diffusion predator-prey system with functional' response and time delay [J]. 纯粹数学与应用数学, 2003, 19(4): 311-317.
[115] Zheng Weiwei, Cui Jingan. Control of population size and stability through diffusion: a stage-structure model[J].生物数学学报,2001,16(3):275-280.
[116]穆晓霞,崔景安.扩散对一类食饵-捕食系统正平衡点和持久性的影响[J].河南 师范大学学报(自然科学版),2006,34(1):161-165.
[117] Song Xinyu, Ye Kaili. Conditions for global stability of n-patches ecological system with dispersion[J]. J. Math. Research and Exposition, 2001, 21(3): 329-333.
[118]崔景安.具有扩散和时滞的捕食系统的持续生存[J].数学学报,2005,48(3):479- 488.
[119] K. Kishimoto. Coexistence of any number of species in the Lotka-Volterra competitive system over two patches[J]. Theoret. Popu. Biol, 1990, 38: 149-158.
[120] Y. Takeuchi. Conflict between the need to forage and the need to avoid competition; Persistence of two-species model[J]. Math. Biosi., 1990, 99: 181-194.
[121] G. Z. Zeng, L. S. Chen. Persistence and periodic orbits for two-species nonautonomous diffusion Lotka-Volterra models[J]. Math. Comput. Modelling, 1994, 20: 69-80.
[122] Song X, Cui J. Uniform persistence and global attractivity for nonautonomous competitivesystem with nonlinear dispersion and delays]J]. Appl. Math. Comput., 2003, 146: 273-288.
[123] Song X, Chen L. Harmless delays and global attractivity for nonautonomous PredatorPreysystem with dispersion[J]. Comput. Math. Appl., 2000, 39: 33-42.
[124] Sun W., Teng Z., Yu Y. Permanence in nonautonomous Predator-Prey Lotka-Volterra systems[J]. Acta Math. Appl. Sinica, English Series, 2002, 18(3): 411-422.
[125] Fengde Chen. Some new results on the permanence and extinction of nonautonomous Gilpin Ayala type competition model with delays[J]. Nonlinear Anal.: Real World Applications,2006, 7(5): 1205-1222.
[126] Z. Teng, L. Chen. Permanence and extinction of periodic predator-prey system in a patchy environment with delay[J]. Nonlinear Anal.: Real World Applications, 2003, 4: 335-364.
[127] J. Cui, Y. Takeuche. Permanence of a single-species dispersal system and predator survival[J]. J. Comput. Appl. Math., 2005, 175: 375-394.
[128] M. Fan, K. Wang. Global periodic solutions of a generalized n-species Gilpin-Ayala competition model[J]. Comput. Math. Appl., 2000, 40: 1141-1151.
[129] J. Cui, L. Chen. The effect of diffusion on time varying logistic population growth [J]. Comput. Math. Appl., 1998, 36(3): 1-9.
[130] H. L. Smith. Cooperative systems of differential equations with concave nonlineari-ties[J]. Nonlinear Anal., 1986, 10: 1037-1052.
[131] J. Cui, Y. Takeuchi, Z. Lin. Permanence and extinction for dispersal population systems[J]. J. Math. Anal. Appl., 2004, 298: 73-93.
[132] J. Cui, L. Chen. Permanence and extinction in Logistic and Lotka-Volterra systems with diffusion[J]. J. Math. Anal. Appl., 2001, 258: 521-535.
[133] P. Hartman. Ordinary Differential Equations[M]. Boston: Birkh a user, 1982.
[134] T. Asai, T. Fukai, S. Tanaka. A subthreshold MOS circuit for the Lotka-Volterra neural network producing the winner-share all solution[J]. Neural Networks, 1999,12: 211-216.
[135] Y. Moreau, S. Louies, J. Vandewalle, L. Brenig. Embedding recurrent neural networks into predator-prey models[J]. Neural Networks, 1999, 12: 237-245.
[136] Ray Redheffer. Lotka-Volterra systems with constant interaction coefficients[J]. NonlinearAnal., 2001, 46: 1151-1164.
[137]曾永福. Lotka-Volterra方程的全局指数稳定性[J].四川大学学报,2005,42(1): 38-40.
[138] Wei Lin, Tianping Chen. Positive periodic solutions of delayed periodic Lotka-Volterra systems[J]. Physics Letters A, 2005, 334:273-287.
[139] J. Qiu, J. Cao. Exponential stability of a competitive Lotka-Volterra system with delays[J]. Appl. Math. Comput. 2007, doi: 10.1016/j.amc.2007.11.046.
[140] Zhao Weirui. Dynamics of Cohen-Grossberg neural network with variable coefficient and time-varing delays[J]. Nonlinear Analysis: Real World Applications, 2008, 9: 1024-1037.