EXISTENCE OF TRIPLE POSITIVE PERIODIC SOLUTIONS OF A FUNCTIONAL DIFFERENTIAL EQUATION DEPENDING ON A PARAMETER XI-LAN LIU, GUANG ZHANG, AND SUI SUN CHENG Received 15 Ocober 2002 We esablish he exisence of hree posiive periodic soluions for a class of delay funcional differenial equaions depending on a parameer by he Legge-Williams fixed poin heorem. 1. Inroducion In his paper, we will discuss he exisence of posiive periodic soluions for he firs-order funcionaldifferenial equaions y () = a()y()+λh() f ( y ( τ() )), R, (1.1) x () = a()x() λh() f ( x ( τ() )), R, (1.2) where a = a(), h = h(), and τ = τ() are coninuous T-periodic funcions, and f = f (u) is a nonnegaive coninuous funcion. We assume ha T is a fixed posiive number and ha a = a() saisfies he condiion T 0 a(u)du > 0. The number λ will be reaed as a parameer in boh equaions. Funcional differenial equaions wih periodic delays appear in a number of ecological models. In paricular, our equaions can be inerpreed as he sandard Malhusian populaion model y = a()y subjec o perurbaions wih periodic delays. One imporan quesion is wheher hese equaions can suppor posiive periodic soluions. The exisence of one or wo posiive periodic soluions for hese funcional differenial equaions has been sudied, see for examples [1, 2, 3, 5, 6, 7, 8, 9]. In his paper, we will obain some exisence crieria for hree posiive periodic soluions when he parameer λ varies. E = (E, ) in he sequel is a Banach space, and C E is a cone. By a concave nonnegaive coninuous funcional ψ on C, we mean a coninuous mapping ψ : C [0,+ ) wih ψ ( µx +(1 µ)y ) µψ(x)+(1 µ)ψ(y), x, y C, µ [0,1]. (1.3) Copyrigh 2004 Hindawi Publishing Corporaion Absrac and Applied Analysis 2004:10 (2004) 897 905 2000 Mahemaics Subjec Classificaion: 34K13 URL: hp://dx.doi.org/10.1155/s1085337504311085
898 Triple periodic soluions of FDE Le ξ, α, β be posiive consans, we will employ he following noaions: C ξ = { y C : y <ξ }, C ξ = { y C : y ξ }, C(ψ,α,β) = { y C β : ψ(y) α }. (1.4) Our exisence crieria will be based on he Legge-Williams fixed poin heorem (see [4]). Theorem 1.1. Le E = (E, ) be a Banach space, C E aconeofe and R>0 aconsan. Suppose here exiss a concave nonnegaive coninuous funcional ψ on C wih ψ(y) y for y C R.LeA : C R C R be a compleely coninuous operaor. Assume here are numbers r, L,andK wih 0 <r<l<k R such ha (H1) he se {y C(ψ,L,K) :ψ(y) >L} is nonempy and ψ(ay) >Lfor all y C(ψ, L,K); (H2) Ay <rfor y C r ; (H3) ψ(ay) >Lfor all y C(ψ,L,R) wih Ay >K. Then A has a leas hree fixed poins y 1, y 2,andy 3 C R.Furhermore,y 1 C r, y 2 {y C(ψ,L,R):ψ(y) >L},andy 3 C R \(C(ψ,L,R) C r ). 2. Exisence of riple soluions for (1.1) A coninuously differeniable and T-periodic funcion y : R R is called a T-periodic soluion of (1.1) associaed wih ω if i saisfies (1.1)when λ = ω in (1.1). I is no difficul o check ha any T-periodic coninuous funcion y() ha saisfies y() = λ G(,s)h(s) f ( y ( s τ(s) )) ds, R, (2.1) where G(,s) = exp( s a(u)du ) exp ( T 0 a(u)du ),,s R, (2.2) 1 is also a T-periodic soluion of (1.1) associaedwih λ. Noe furher ha 0 <N min G(,s) G(,s) max G(,s) M, s + T;,s [0,T],s [0,T] G(,s) 1 max,s [0,T] G(,s) min,s [0,T] G(,s) max,s [0,T] G(,s) = N M > 0. (2.3)
Xi-lan Liu e al. 899 For he sake of convenience, we se A 0 = max [0,T] B 0 = min [0,T] G(,s)h(s)ds, G(,s)h(s)ds. (2.4) We use Theorem 1.1 o esablish he exisence of hree posiive periodic soluions o (2.1). To his end, one or several of he following condiions will be needed: (S1) f :[0,+ ) [0,+ ) is a coninuous and nondecreasing funcion, (S2) h() > 0for R, (S3) lim x 0 f (x)/x = l 1, (S4) lim x + f (x)/x = l 2. Le E be he se of all real T-periodic coninuous funcions endowed wih he usual operaions and he norm y =max [0,T] y().thene is a Banach space wih cone C = { y E : y() 0, (,+ ) }. (2.5) Theorem 2.1. Suppose (S1) (S4) hold such ha l 1 = l 2 = 0. Suppose furher ha here is a number L>0 such ha f (L) > 0.LeR, K, L,andr be four numbers such ha R K> LM N f (r) < f (R) r R L>r>0, (2.6) < B 0 f (L) A 0 L. (2.7) Then for each λ (L/(B 0 f (L)),R/(A 0 f (R))], here exis hree nonnegaive periodic soluions y 1, y 2,andy 3 of (1.1) associaed wih λ such ha y 1 () <r<y 2 () <L<y 3 () R for R. Proof. Firsofall,inviewof(S2),A 0,B 0 > 0. Noe furher ha if f (L) > 0, hen by (S1), f (R) > 0foranyR greaer han L. In view of (S4), we may choose R K>Lsuch ha he second inequaliy in (2.7) holds, and in view of (S3), we may choose r (0,L) suchha he firs inequaliy in (2.7) holds.weseλ 1 = L/(B 0 f (L)) and λ 2 = R/(A 0 f (R)). Then λ 1,λ 2 > 0. Furhermore, λ 1 <λ 2 in view of (2.7). We now define for each λ (λ 1,λ 2 ]a coninuous mapping A : C C by and a funcional ψ : C [0, )by (Ay)() = λ G(,s)h(s) f ( y ( s τ(s) )) ds, R (2.8) ψ(y) = min y(). (2.9) [0,T]
900 Triple periodic soluions of FDE In view of (S1), (S2), and (2.7), we have (Ay)() = λ G(,s)h(s) f ( y ( s τ(s) )) ds λf ( y ) G(,s)h(s)ds λf(r) G(,s)h(s)ds λa 0 f (R) λ 2 A 0 f (R) = R, (2.10) for [0,T]andally C R. Therefore, A(C R ) C R. We asser ha A is compleely coninuous on C R. Indeed, in view of he heorem of Arzela-Ascoli, i suffices o show ha A(C R ) is equiconinuous. To see his, noe ha for 1 < 2, 2+T 2 G ( 2,s ) h(s) f ( y ( s τ(s) )) 1+T ds 2+T = 1+T 1+T + 2 2 G ( 2,s ) h(s) f ( y ( s τ(s) )) ds { G ( 2,s ) G ( 1,s )} h(s) f ( y ( s τ(s) )) ds 1 G ( 1,s ) h(s) f ( y ( s τ(s) )) ds. 1 G ( 1,s ) h(s) f ( y ( s τ(s) )) ds (2.11) Furhermore, 2 G ( 1,s ) h(s) f ( y ( s τ(s) )) ds 1 { f ( y ) 1+T } G(,s)h(s)ds 2 1 2+T 1+T 1+T 2 1 A 0 f ( y ) 2 1, G(,s)h(s) f ( y ( s τ(s) )) ds { f ( y ) 1+2T G(,s)h(s)ds} 2 1 1+T A 0 f ( y ) 2 1, { ( G 2,s ) G ( 1,s )} h(s) f ( y ( s τ(s) )) ds f ( y ) 1+T max h(x) G ( 2,s ) G ( 1,s ) ds x [0,T] 2 f ( y ) 2T max h(x) G ( 2,s ) G ( 1,s ) ds. x [0,T] 0 (2.12)
Xi-lan Liu e al. 901 In view of he uniform coninuiy of G in {(,s) 0, s 2T}, foranyε>0, here is δ which saisfies { 0 <δ<min T, and for 0 < 2 1 <δ,wehave ε 3λ 2 A 0 f (R), ε 3λ 2 f (R) [ max 0, s 2T G(,s) ][ max x [0,T] h(x) ] }, (2.13) G ( 1,s ) G ( 2,s ) ε <, s [0,2T]. (2.14) 6λ 2 Tf(R)max 0 T h() Thus (Ay) ( ) ( ) 1 (Ay) 2 2+T = λ G(,s)h(s) f ( y ( s τ(s) )) 1+T ds G(,s)h(s) f ( y ( s τ(s) )) ds 2 1 2+T λ 2 G ( 2,s ) h(s) f ( y ( s τ(s) )) ds 1+T 1+T { ( + λ 2 G 2,s ) G ( 1,s )} h(s) f ( y ( s τ(s) )) ds 2 2 + λ 2 G ( 1,s ) h(s) f ( y ( s τ(s) )) ds 1 2λ 2 A 0 f (R) 2 1 + λ 2 f (R)2T max h() ε [0,T] 6λ 2 Tf(R)max 0 T h() <ε (2.15) for any y() C R. This means ha A(C R )isequiconinuous. We now asser ha Theorem 1.1(H2) holds. Indeed, (Ay)() = λ G(,s)h(s) f ( y ( s τ(s) )) ds λf ( y ) G(,s)h(s)ds λf(r) G(,s)h(s)ds λ 2 A 0 f (r) <r (2.16) for all y C r, where he las inequaliy follows from (2.7). In addiion, we can show ha he condiion (H1) of Theorem 1.1 holds. Obviously, ψ(y) is a concave coninuous funcion on C wih ψ(y) y for y C R. We noice ha if u() = (1/2)(L + K)for (,+ ), hen u {y C(ψ,L,K):ψ(y) >L} which impliesha {y C(ψ,L,K): ψ(y) >L} is nonempy. For y C(ψ,L,K), we haveψ(y) = min [0,T] y() L and y K. In view of (S1) (S4), we have ψ(ay) = λ min G(,s)h(s) f ( y ( s τ(s) )) ds λb 0 f (L) >λ 1 B 0 f (L) = L (2.17) [0,T] for all y C(ψ,L,K).
902 Triple periodic soluions of FDE Finally, we prove condiion (H3) in Theorem 1.1. Le y C(ψ,L,R) wih Ay > K. We noice ha (2.8) implies Thus T Ay λm h(s) f ( y ( s τ(s) )) ds. (2.18) 0 ψ(ay) = λ min λn [0,T] T 0 G(,s)h(s) f ( y ( s τ(s) )) ds h(s) f ( y ( s τ(s) )) ds N M Ay > N M K>L. (2.19) An applicaion of Theorem1.1 saedabove now yields our proof. We remark ha he assumpions of Theorem 2.1 are no vacuous as can be seen by leing T = 3, a() 1, h() 1, and xln(1 + x), 0 x<1, f (x) = e x e +ln2, 1 x<6, (2.20) x 6+e 6 e +ln2, x 6. Then by aking r = 3/2, L = 5, K = 101, and R = 5.0135 10 41, we easily check ha A 0 = 1.0524, B 0 = 5.239 10 2 and all he condiions of Theorem 2.1 hold. Theorem 2.2. Suppose (S1) (S4) hold such ha 0 <l 1 <l 2. Suppose here is a number L>0 such ha f (L) > 0 and 0 <l 1 <l 2 <B 0 f (L)/(A 0 L).LeR, K, L,andr be four numbers such ha R K> LM L>r>0, N (2.21) f (R) R <l 2 + ε, (2.22) f (r) <l 1 + ε, r (2.23) where ε is a posiive number such ha l 2 + ε< B 0 f (L) A 0 L. (2.24) Then for each λ (L/(B 0 f (L)),1/(A 0 l 2 )),(1.1) has a leas hree nonnegaive periodic soluions y 1, y 2,andy 3 associaed wih λ such ha y 1 () <r<y 2 () <L<y 3 () R for R. Proof. Firs of all, A 0,B 0 > 0 by (S2). Noe furher ha if f (L) > 0, hen by (S1), f (R) > 0 for any R greaer han L.Leλ 1 = L/(B 0 f (L)) and λ 2 = 1/(A 0 l 2 ). Then λ 1,λ 2 > 0. Furhermore, 0 <λ 1 <λ 2 in view of he condiion 0 <l 1 <l 2 <B 0 f (L)/(A 0 L). For posiive ε ha
Xi-lan Liu e al. 903 saisfies (2.24) andanyλ (λ 1,λ 2 ), in view of (S4) (and he fac ha λ 1/(A 0 (l 2 + ε))), here is R K>Lsuch ha (2.22) holds, and in view of (S3), here is r (0,L)suchha (2.23)holds. We now define for each λ (λ 1,λ 2 ) a coninuous mapping A : C C by (2.8) anda funcional ψ : C [0,+ ) by(2.9). As in he proof of Theorem 2.1, i is easy o see ha A is compleely coninuous on C R and maps C R ino C R.Forally C R,wehave (Ay)() = λ G(,s)h(s) f ( y ( s τ(s) )) ds λf ( y ) G(,s)h(s)ds λf(r) G(,s)h(s)ds λa 0 f (R) <λa 0 ( l2 + ε ) R R. (2.25) Furhermore, condiion (H2) of Theorem 1.1 holds. Indeed, for y C r,wehave (Ay)() = λ G(,s)h(s) f ( y ( s τ(s) )) ds λf ( y ) G(,s)h(s)ds λf(r) G(,s)h(s)ds λa 0 f (r) λa 0 ( l1 + ε ) r<r. (2.26) Similarly, we can prove ha he condiions (H1) and (H3) of Theorem 1.1 hold. An applicaionof Theorem 1.1 now yields our proof. Theorem 2.3. Suppose(S1)and(S2)holdand f (0) > 0. Suppose here exis four numbers L, R, K,andr such ha (2.6)and(2.7) hold. Then for each λ (L/(B 0 f (L)),R/(A 0 f (R))], (1.1) has a leas hree posiive periodic soluions y 1, y 2,andy 3 associaed wih λ such ha 0 <y 1 () <r<y 2 () <L<y 3 () R for R. The proof is similar o Theorem 2.1 and is hence omied. 3. Exisence of riple soluions for (1.2) Equaion (1.2) can be regarded as a dual of (1.1). Therefore, dual exisence heorems can be found. Their proofs are obained by argumens parallel o hose for our previous heorems. Therefore, only a shor summary will be given. Firs, (1.2)isransformedino x() = λ H(,s)h(s) f ( x ( s τ(s) )) ds, (3.1)
904 Triple periodic soluions of FDE where H(,s) = exp( s a(u)du ) 1 exp ( T 0 a(u)du ) = exp ( s a(u)du ) exp ( T 0 a(u)du ), 1 s + T, (3.2) which saisfies Le M max H(,s) H(,s) min,s [0,T],s [0,T] H(,s) N, s + T. (3.3) A = max [0,T] B = min [0,T] H(,s)h(s)ds, H(,s)h(s)ds. (3.4) Theorem 3.1. Suppose (S1) (S4) hold such ha l 1 = l 2 = 0. Suppose furher ha here is a number L>0 such ha f (L) > 0. Le R, K, L,andr be four numbers such ha R K> LM L>r>0, f (r) r N < f (R) R < B f (L) A L. (3.5) Then for each λ (L/(B f (L)),R/(A f (R))], here exis hree nonnegaive periodic soluions x 1, x 2,andx 3 of (1.2) associaed wih λ such ha x 1 () <r<x 2 () <L<x 3 () R for R. Theorem 3.2. Suppose (S1) (S4) hold such ha 0 <l 1 <l 2. Suppose here is a number L>0 such ha f (L) > 0 and 0 <l 1 <l 2 <B f (L)/(A L).LeR, K, L,andr be four numbers such ha where ε is a posiive number such ha R K> LM L>r>0, N f (R) R <l 2 + ε, f (r) <l 1 + ε, r (3.6) l 2 + ε< B f (L) A L. (3.7) Then for each λ (L/(B f (L)),1/(A l 2 )),(1.2) has a leas hree nonnegaive periodic soluions x 1, x 2,andx 3 associaed wih λ such ha x 1 () <r<x 2 () <L<x 3 () R for R. Theorem 3.3. Suppose(S1)and(S2)holdand f (0) > 0. Suppose here exis four numbers L, R, K, andr such ha (3.5) hold. Then for each λ (L/(B f (L)),R/(A f (R))], (1.2) has a leas hree posiive periodic soluions x 1, x 2,andx 3 associaed wih λ such ha 0 <x 1 () < r<x 2 () <L<x 3 () R for R.
Acknowledgmen Xi-lan Liu e al. 905 This projec is suppored by he Naural Science Foundaion of Shanxi Province and Yanbei Normal Insiue. References [1] S. S. Cheng and G. Zhang, Exisence of posiive periodic soluions for non-auonomous funcional differenial equaions, Elecron. J. Differenial Equaions 2001 (2001), no. 59, 1 8. [2] S.N.Chow,Remarks on one-dimensional delay-differenial equaions, J. Mah. Anal. Appl. 41 (1973), 426 429. [3] H.M.Gibbs,F.A.Hopf,D.L.Kaplan,andR.L.Shoemaker,Observaion of chaos in opical bisabiliy, Phys. Rev. Le. 46 (1981), 474 477. [4] D. J. Guo, Nonlinear Funcional Analysis, Shandong Science and Technology Press, Shandong, 1985. [5] K. P. Hadeler and J. Tomiuk, Periodic soluions of difference-differenial equaions,arch.raional Mech. Anal. 65 (1977), no. 1, 87 95. [6] D.Q.JiangandJ.J.Wei,Exisence of posiive periodic soluions for nonauonomous delay differenial equaions, Chinese Ann. Mah. Ser. A 20 (1999), no. 6, 715 720 (Chinese). [7] J. Malle-Pare and R. D. Nussbaum, Global coninuaion and asympoic behaviour for periodic soluions of a differenial-delay equaion, Ann. Ma. Pura Appl. (4) 145 (1986), 33 128. [8], Adifferenial-delay equaion arising in opics and physiology, SIAM J. Mah. Anal. 20 (1989), no. 2, 249 292. [9] G. Zhang and S. S. Cheng, Posiive periodic soluions of nonauonomous funcional differenial equaions depending on a parameer, Absr. Appl. Anal. 7 (2002), no. 5, 279 286. Xi-lan Liu: Deparmen of Mahemaics, Yanbei Normal Insiue, Daong, Shanxi 037000, China E-mail address: liuchl03@s.lzu.edu.cn Guang Zhang: Qingdao Polyechnic Universiy, Qingdao, Shandong 266033, China E-mail address: qd gzhang@126.com Sui Sun Cheng: Deparmen of Mahemaics, Naional Tsing Hua Universiy, Hsinchu 30043, Taiwan E-mail address: sscheng@mah.nhu.edu.w