On Neutral Functional-Differential Equations with
Transcription
On Neutral Functional-Differential Equations with
JOURNAL OF MATHEMATICAL ANALYSIS AND APPLICATIONS ARTICLE NO. 207, 73]95 Ž1997. AY975262 On Neutral Functional]Differential Equations with Proportional Delays Arieh Iserles Department of Applied Mathematics and Theoretical Physics, Uni¨ ersity of Cambridge, Cambridge, England and Yunkang Liu* Fitzwilliam College, Uni¨ ersity of Cambridge, Cambridge, England Submitted by Thomas S. Angell Received June 9, 1994 In this paper we develop a comprehensive theory on the well-posedness of the initial-value problem for the neutral functional-differential equation X y Ž t . s ay Ž t . q ` ` is1 is1 Ý bi y Ž qi t . q Ý ci yX Ž pi t . , t ) 0, y Ž0. s y 0 , and the asymptotic behaviour of its solutions. We prove that the existence and uniqueness of solutions depend mainly on the coefficients c i , i s 1, 2, . . . , and on the smoothness of functions in the solution space. As far as the asymptotic behaviour of analytic solutions is concerned, the c i have little effect. We prove that if Re a ) 0 then the solution y Ž t . either grows exponentially or is polynomial. The most interesting result is that if Re a F 0 and a / 0 then the asymptotic behaviour of the solution depends mainly on the characteristic equation ` aq Ý bi qil s 0. is1 These results can be generalized to systems of equations. Finally, we present some examples to illustrate the change of asymptotic behaviour in response to the variation of some parameters. The main idea used in this paper is to express the solution in either Dirichlet or Dirichlet]Taylor series form. Q 1997 Academic Press Current Address: Gonville and Caius College, University of Cambridge, Cambridge, England. 73 0022-247Xr97 $25.00 Copyright Q 1997 by Academic Press All rights of reproduction in any form reserved. 74 ISERLES AND LIU 1. INTRODUCTION Initial-value problems for functional-differential equations of constant time delays of the form d dt ž yŽ t. y ` Ý c i y Ž t y pi . is1 / s ay Ž t . q ` Ý bi y Ž t y qi . , t ) 0, Ž 1.1. is1 y Ž t . s y0 Ž t . , x F 0, Ž 1.2. where a, bi , and c i are complex constants, pi , qi ) 0, i s 1, 2, . . . , satisfying sup i G 1 pi , sup iG 1 qi - `, and y 0 Ž t . is a given function, have been studied extensively. It is well known that Ž1.1. ] Ž1.2., under some minor restrictions, has a unique solution and the asymptotic behaviour of this solution depends mainly on the corresponding characteristic equation l 1y ž ` Ý c i exp Ž yl pi . is1 / saq ` Ý bi exp Ž yl qi . . is1 Details for this and for more general results can be found in Hale w11x. In this paper we study the initial-value problem for neutral functional-differential equations of the form yX Ž t . s ay Ž t . q ` ` is1 is1 Ý byi Ž qi t . q Ý c i yX Ž pi t . , y Ž 0. s y 0 , t ) 0, Ž 1.3. Ž 1.4. where a, bi , and c i are complex constants, pi , qi g Ž0, 1., i s 1, 2, . . . , and y 0 is a given initial value. To guarantee convergence of the series in Ž1.3., we assume that Ý`is1 < bi <, Ý`is1 < c i < - `. A list of applications for this kind of equation features in Iserles w12x. One remarkable difference between Ž1.1. and Ž1.3. is that the latter has unbounded variable time delays. The objective of this paper is to develop a fairly comprehensive theory on the well-posedness of the initial-value problem Ž1.3. ] Ž1.4. and, most importantly of all, the asymptotic behaviour of its solutions. We prove that the existence and uniqueness of solutions of Ž1.3. ] Ž1.4. depend mainly on the coefficients c i , i s 1, 2, . . . , and the smoothness of functions in the solution space. However, the c i have little effect on the asymptotic behaviour of analytic solutions of Ž1.3. ] Ž1.4.. We prove that if Re a ) 0 then the solution y Ž t . either grows exponentially, i.e., lim t ª` y Ž t . eya t / 0, or is polynomial. Our most interesting result is that if Re a F 0 and a / 0 then the asymptotic behaviour of the solution depends mainly on the characteristic equation aq ` Ý bi qil s 0. is1 NEUTRAL FUNCTIONAL-DIFFERENTIAL EQUATIONS 75 Our results can be generalized to systems of functional-differential equations with proportional time delays. Finally, we specialize our discussion by paying closer attention to the generalized pantograph equation w12x yX Ž t . s ay Ž t . q by Ž qt . q cyX Ž qt . , t ) 0, y Ž 0 . s 1. Ž 1.5. We present some examples that illustrate the change of asymptotic behaviour in response to the variation of some parameters. 2. EXISTENCE AND UNIQUENESS OF SOLUTIONS Analogous to the existence and uniqueness theorem of Nussbaum w22x, we have the following result Žsee also Iserles and Liu w14x and w17x.. THEOREM 1. If Ý`is1 pim < c i < - 1 for some m g Zq then in the function space C mq 1 w0, `. the solution of Ž1.3. ] Ž1.4. exists and is unique if and only if ` Ý pin c i / 1, n s 0, 1, . . . , m y 1. Ž 2.1. is1 If Ž2.1. holds then the unique solution is analytic and can be written as y Ž t . s y0 q y0 ` ` ny1 Ý Ł ns1 ks0 ž 1y Ý pik c i is1 y1 / ž aq ` Ý qik bi is1 / tn n! . Ž 2.2. Kuang and Feldstein w20x studied the scalar initial-value problem yX Ž t . s ay Ž t . q M K is1 is1 Ý bi y Ž qi t . q Ý c i yX Ž pi t . , t ) 0, y Ž 0. s y 0 , Ž 2.3. where a, bi , i s 1, . . . , M, and c i , i s 1, . . . , K, are real constants. By transforming Ž2.3. into an integral equation, they proved that it has a K < < - 1. They unique solution Žin the function space C 1 w0, `.. if Ý is1 c i py1 i then posed the problem of establishing the same result in the case of K < K < < G 1. Our result shows that the condition Ý is1 < - 1 can Ý is1 c i py1 c i py1 i i K < < be modified to Ý is1 c i - 1. Next we discuss the necessity of the assumption Ý`is1 pim < c i < - 1 made in Theorem 1. For simplicity, we only consider the case m s 0. First, we introduce the following lemma, which is almost the same as a result of Nussbaum w22x. 76 ISERLES AND LIU LEMMA 2. Let p g Ž0, 1. be gi¨ en and consider the homogeneous functional equation y Ž t . s cy Ž pt . , t G 0, Ž 2.4. in the function space C w0, `.. 1. 2. 3. tions of If < c < F 1 but c / 1 then Ž2.4. has only the tri¨ ial solution y Ž t . ' 0. If c s 1 then all solutions of Ž2.4. are constant. If < c < ) 1 then there is a one-to-one correspondence between soluŽ2.4. and functions in the space CU s f Ž t . g C w p, 1x: f Ž1. s cf Ž p .4 . Proof. The first two parts of Lemma 2 are easy to prove. Consider part 3. For every solution y Ž t . g C w0, `. of Ž2.4., there corresponds a function f Ž t . s y Ž t ., t g w p, 1x, which belongs to CU . On the other hand, for every function f Ž t . g CU , it is easy to see that the function y Ž t . given by the following recurrence relation: y Ž 0 . s 0, y Ž t . s c k f Ž pyk t . , p kq 1 F t F p k , k s 0, " 1, " 2, . . . , is a continuous solution of Ž2.4.. EXAMPLE 1. Consider solutions of the initial-value problem yX Ž t . s cyX Ž pt . , t ) 0, y Ž 0. s y 0 , Ž 2.5. in the function space C 1 w0, `.. It follows from Lemma 2 that 1. The only solution of Ž2.5. is y Ž t . ' y 0 if < c < F 1 but c / 1. 2. All the solutions of Ž2.5. can be written as y Ž t . s y 0 q y 1 t if c s 1, where y 1 is an arbitrary constant. 3. There is a one-to-one correspondence between solutions of Ž2.5. and functions in the space CU if < c < ) 1. This example shows that the initial-value problem Ž2.5. loses uniqueness of solutions if either c s 1 or < c < ) 1. EXAMPLE 2. Consider the homogeneous problem yX Ž t . s ` Ý c i yX Ž pi t . , t ) 0, y Ž 0 . s 0. Ž 2.6. is1 Suppose that Ý`is1 c i ) 1. By the intermediate-value theorem there exists a constant l ) 1 such that Ý`is1 pilc i s 1. Hence, the homogenous problem Ž2.6. has the nontrivial solution y Ž t . s t lq1. NEUTRAL FUNCTIONAL-DIFFERENTIAL EQUATIONS 77 EXAMPLE 3. Consider solutions of the initial-value problem yX Ž t . s c1 yX Ž p 1 t . q c 2 yX Ž p 2 t . y c1 c 2 yX Ž p 1 p 2 t . , t ) 0, y Ž 0. s y 0 , Ž 2.7. in the function space C 1 w0, `.. Suppose that < c1 < F 1 and < c 2 < F 1 but c1 , c 2 / 1. Let y Ž t . g C 1w0, `. be a solution of Ž2.7.. Then x Ž t . s yX Ž t . y c1 yX Ž p1 t . satisfies the functional equation x Ž t . s c2 x Ž p2 t . , t 2 G 0. Lemma 2 implies that x Ž t . ' 0. Therefore, yX Ž t . s c1 yX Ž p 1 t . , t G 0, y Ž 0. s y 0 . It follows from Lemma 2 that yX Ž t . ' 0. Hence, the only C 1w0, `. solution of Ž2.7. is y Ž t . ' y 0 . This example shows that the condition < c1 < q < c 2 < q < c1 c 2 < - 1 is unnecessary for the uniqueness of solution of Ž2.7. in the function space C 1 w0, `.. In the rest of this paper, we assume that a / 0, that Ž2.1. holds, and that lqs sup iG 1 max pi , qi 4 - 1. We shall only consider the analytic solution of Ž1.3. ] Ž1.4.. 3. DIRICHLET AND DIRICHLET]TAYLOR SERIES SOLUTIONS The Taylor series solution Ž2.2. is of little use in the study of asymptotic behaviour. On the other hand, it seems that the solution cannot be found through Laplace transform as was done in the case of Ž1.1. ] Ž1.2.. Fortunately, it can be expressed in either Dirichlet or Dirichlet]Taylor series form. To begin with, we introduce some notation. For sequences x i 4`is1 , yi 4`is1 of complex numbers and ji 4`is1 of integers, we define x s Ž x 1 , x 2 , . . . . g C` , y s Ž y 1 , y 2 , . . . . g C` , j s Ž j1 , j2 , . . . . g Z` , and the standard multi-index operations <x < s ` Ý < xi <, <j < s is1 ` Ý < ji < , is1 Ž x, y . s xjs ` Ł x ij , i is1 ` Ý x i yi , is1 xy s Ž x 1 y 1 , x 2 y 2 , . . . . , x k s Ž x 1k , x 2k , . . . . , k g Zq. 78 ISERLES AND LIU First, we seek Dirichlet series solution of the form y Ž t . s a y0 ` Ý Ý ns0 <j <q <k <sn d j, k exp Ž atq j p k . , Ž 3.1. where a and d j, k , j, k g ŽZq. ` , are coefficients to be determined. It is understood that pi s 1 Ž qi s 1. if c i s 0 Ž bi s 0. for some i g N. Let d 0, 0 s 1, where 0 s Ž0, 0, . . . ., and d j, k s 0 if ji - 0 or k i - 0 for some i g N. It is easy to see that ` yX Ž t . s a a Ý Ý ns0 <j <q <k <sn q j p k d j, k exp Ž atq j p k . , and for i g N that y Ž qi t . s a y 0 ` Ý Ý ns0 <j <q <k <sn yX Ž pi t . s a a y 0 d jye i , k exp Ž atq j p k . , ` Ý Ý ns0 <j <q <k <sn q j p kye i d j, kye i exp Ž atq j p k . , where e i s Ž d 1, i , d 2, i , . . . . with dn, i denoting the Kronecker symbol. By substituting Ž3.1. into Ž1.3. and comparing the coefficients of expŽ atq j p k . on both sides, we obtain the recurrence relation ` Ž q j p k y 1 . d j, k s Ý is1 ž bi a d jye i , k q q j p kye i c i d j, kye i , / ` j, k g Ž Zq . , Ž 3.2. which leads to the following result. THEOREM 3. If <b < - < a < then the solution of Ž1.3. ] Ž1.4. has a Dirichlet series expansion of the form Ž3.1., where d j, k 4 are determined by Ž3.2. and as ` Ł 1 q Ž b, q n . ra ns0 1 y Ž c, p n . . Ž 3.3. Proof. It is not difficult to see from Ž3.2. that < d j, k < F r max <l <q <m <- <j <q <k <y1 < d l, m < , ` j, k g Ž Zq . , for r s Ž<b <r< a < q <c <.rŽ1 y lq ., which implies that < d j, k < F r < j<q< k < , ` j, k g Ž Zq . . NEUTRAL FUNCTIONAL-DIFFERENTIAL EQUATIONS 79 Therefore, the generating function g Ž x, y . s ` Ý Ý ns0 <j <q <k <sn d j, k x j y k is analytic for all x, y g C` satisfying <x < q <y < - r . Multiplying Ž3.2. by x j y k and summing up for j, k g ŽZq. ` yields g Ž qx, py . y g Ž x, y . s Ž b, x . a g Ž x, y . q Ž c, y . g Ž qx, py . , which implies that g Ž x, y . s 1 y Ž c, y . 1 q Ž b, x . ra g Ž qx, py . . Due to the fact that lim x, y ª 0 g Žx, y. s g Ž0, 0. s 1, we deduce that g Ž x, y . s ` Ł ns0 1 y Ž c, p n y . 1 q Ž b, q n x . ra , Ž 3.4. where the convergence of the product follows from our assumption that lq- 1. ŽNote that formula Ž3.4. is, in fact, a generalization of the q-binomial theorem w10x. A further generalization is Ž5.9., which features in Section 5.. Hence, g Žx, y. can be extended analytically to x, y g C` : <b < <x < - < a <4 . Since < a < ) <b <, we deduce that the series Ý`ns 0 Ý < j<q< k <sn d j, k converges absolutely. Therefore, the Dirichlet series Ž3.1. converges absolutely for all t g R. Our assumption that Ž2.1. holds implies that g Ž1, 1. / 0, where 1 s Ž1, 1, . . . .. It is easy to verify that the Dirichlet series Ž3.1. satisfies Ž1.3. ] Ž1.4. if we let a s 1rg Ž1, 1.. The Dirichlet series may fail to converge if <b < G < a <. However, we can express a high-order derivative of the solution of Ž1.3. ] Ž1.4. into a Dirichlet series, and find the solution through the Taylor expansion formula with integral remainder. Let m g N be such that <Žb, q m .< - < a <, and let ymŽ t . be the mth derivative of the solution y Ž t . of Ž1.3. ] Ž1.4.. Therefore, my1 yŽ t. s Ý yn Ž 0 . ns0 n! tn q 1 t Ž m y 1. ! H0 Ž t y t . my1 ym Ž t . dt , Ž 3.5. where, by Theorem 1, ny1 yn Ž 0 . s y 0 Ł ks0 ž 1y y1 ` Ý is1 pik c i / ž aq ` Ý qik bi is1 / , n s 1, 2, . . . . Ž 3.6. 80 ISERLES AND LIU Differentiating both sides of Ž1.3. m times yields X ym Ž t . s aym Ž t . q ` Ý bi qim ym Ž qi t . q is1 ` Ý c i pim ymX Ž pi t . , t ) 0. Ž 3.7. is1 According to Theorem 3, we have ym Ž t . s a m ym Ž 0 . ` Ý Ý ns0 <j <q <k <sn d j, k , m exp Ž atq j p k . , where d 0, 0, m s 1, d j, k, m s 0 if ji - 0 or k i - 0 for some i g N, d j, k, m 4 satisfies the recurrence relation ` Ž q j p k y 1 . d j, k , m s Ý is1 ž bi qim a d jye i , k , m q q j p kye i c i pim d j, kye i , m , / ` j, k g Ž Zq . , and a m satisfies a m ymŽ0. s a ma y 0 . Noting that d j, k, m s Žq j p k . m d j, k and 1 t H Žtyt. Ž m y 1. ! 0 my 1 e at dt s aym e at y ž my1 Ý ls0 al l! / tl , we have the following result. THEOREM 4. If m [ min n g Zq: <Žb, q n .< - < a <4 G 1, then the solution of Ž1.3. ] Ž1.4. has the Dirichlet]Taylor series expansion my1 yŽ t. s y Ž n. Ž 0 . Ý ns0 q a y0 n! tn ` Ý Ý ns0 <j <q <k <sn ž my1 j d j, k exp Ž atq p k .y Ý ls0 Ž aq j p k . l! l / tl , where y Ž n. Ž0., a and d j, k 4 are gi¨ en by Ž3.6., Ž3.3., and Ž3.2., respecti¨ ely. 4. ASYMPTOTIC BEHAVIOUR In this section we demonstrate how to use Dirichlet and Dirichlet]Taylor series solutions to analyse the asymptotic behaviour of the neutral equation Ž1.3.. NEUTRAL FUNCTIONAL-DIFFERENTIAL EQUATIONS 81 THEOREM 5. Let y Ž t . be the unique solution of Ž1.3. ] Ž1.4. and m [ min n g Zq: <Žb, q n .< - < a <4 . Then 1. lim t ª` y Ž t . eya t s a y 0 if Re a ) 0, where a is gi¨ en by Ž3.3.; 2. y Ž t . s O Ž t m . as t ª ` if Re a s 0. Moreo¨ er, y Ž m. Ž t . is almost periodic; and 3. y Ž t . s oŽ t m . as t ª ` if Re a - 0. Proof. We only give proof of the case of Re a ) 0, since the other two cases can be proved similarly. If m s 0 then we deduce from Ž3.1. that y Ž t . exp Ž yat . y a y 0 F exp Ž yRe a Ž 1 y lq . t . ` Ý Ý ns1 <j <q <k <sn < d j, k < , which implies that lim t ª` y Ž t . eya t s a y 0 . If m G 1 then we deduce from Ž3.7. that lim t ª` ymŽ t . eya t s a m ymŽ0. s a ma y 0 . Using the Taylor expansion Ž3.5., we deduce that lim t ª` y Ž t . eya t s a y 0 . Part 1 of the last theorem shows that the solution y Ž t . either grows exponentially, i.e., lim t ª` y Ž t . eya t / 0, or is polynomial. THEOREM 6. Let y Ž t . be the unique solution of Ž1.3. ] Ž1.4. and let ¡sup Re l: a q Ý b q ½ [~ ¢y`, ` m0 1. w0, `.. 2. i l i If Re a s 0 then y Ž t . s O Ž t m. 5 s0 , is1 b / 0, b s 0. as t ª ` for all m g Ž m 0 , `. l If Re a - 0 then y Ž t . s oŽ t m . as t ª ` for all m ) m 0 . To prove the theorem, we introduce three lemmas. LEMMA 7. Suppose that y Ž t . g C w0, `. satisfies the functional equation ay Ž t . q ` Ý bi y Ž qi t . s h Ž t . , t G 0, is1 where a, bi , and qi , i s 1, 2, . . . , are as before, and hŽ t . g C w0, `. satisfies hŽ t . s O Ž t m1 . as t ª ` for some constant m 1. Then y Ž t . s O Ž t m . as t ª ` for any m g Ž m 0 , `. l w m 1 , `., where m 0 is the same as in Theorem 6. Proof. For any m g Ž m 0 , `. l w m 1 , `. we define x Ž t . s eym t y Ž e t ., y` - t - `. The function x Ž t . satisfies the difference equation ax Ž t . q ` Ý bi qim x Ž t q log qi . s H Ž t . , is1 0 F t - `, 82 ISERLES AND LIU where H Ž t . [ ey m t hŽ e t . s O Ž1. as t ª `. Since sup Re l: a q Ý`is1 bi qim q l s 04 s m 0 y m - 0, it follows from Theorem 4.1 of Hale w11, p. 287x that x Ž t . s O Ž1. as t ª `. Therefore, y Ž t . s O Ž t m . as t ª ` for any m g Ž m 0 , `. l w m 1 , `.. LEMMA 8. If b , l g Ž0, 1. then Ý`ns 0 b n expŽyt l n . s O Ž t m . but not oŽ t m . as t ª ` for m s ylog brlog l - 0. Proof. If m F y1 then ty m ` Ý b n exp Ž yt l n . s ns0 l1q m 1yl 1q m F - l 1yl l1q m ` ym y1 exp Ž yt l n . Ž t l n y t l nq1 . Ý Ž t lnq1 . ns0 ` tln ÝH nq1 ns0 t l ` ym y1 Hx 1yl 0 xym y1 exp Ž yx . dx exp Ž yx . dx - `, and, for t G l, ty m ` Ý b n exp Ž yt l n . s ns0 lym 1yl ym G l 1yl ` ym y1 exp Ž yt l n . Ž t l ny1 y t l n . Ý Ž t lny1 . ns0 ` t l ny1 ym y1 ÝH n ns0 t l x exp Ž yx . dx lym xy m y1 exp Ž yx . dx ) 0. 1yl Hence, Ý`ns 0 b n expŽyt l n . s O Ž t m . but not oŽ t m . as t ª `. The case of m g Žy1, 0. can be proved similarly. ) Alternatively, we can prove the preceding lemma in the following way. The function ` 1 xŽ t. [ Ý b n exp Ž yt l n . ns0 Ž l ; l . n satisfies the functional-differential equation xX Ž t . s b x Ž l t . y x Ž t . , t ) 0. ŽIn what follows we use standard notation from the theory of basic hypergeometric functions w10x, e.g., Ž a; q . n s ½ 1, Ž 1 y a. Ž 1 y aq . ??? Ž 1 y aq ny 1 . , n s 0, n s 1, 2, . . . , called the shifted factorial or q-factorial or Gauss]Heine symbol, and Ž a; q .` s Ł`ks0 Ž1 y aq k ... NEUTRAL FUNCTIONAL-DIFFERENTIAL EQUATIONS 83 According to Theorem 3Ži. and Žii. of Kato and McLeod w19x, x Ž t . s O Ž t m . but not oŽ t m . as t ª `. Hence, Lemma 8 holds since Ž l ; l. ` x Ž t . - ` b n exp Ž yt l n . - x Ž t . . Ý ns0 In the remainder of this section we let ly[ inf iG 1 max pi , qi 4 ) 0. LEMMA 9. If Re a - 0 and <b < - < a < then y Ž t . s O Ž t m . as t ª ` for m ) Žlog < a < y log <b <.rlog ly. Proof. It is easy to see from Ž3.2. that for any e g Ž0, 1 y <b <r< a <. there exists a constant M ) 0 such that Ý <j <q <k <sn < d j, k < F M ž <b < q e < a< n / , n G 0. According to Theorem 3, we have y Ž t . F < a y0 < M ` Ý ns0 ž <b < q e < a< n / n exp Ž Re at ly .. It follows from Lemma 8 that y Ž t . s O Ž t m . as t ª ` for m s Žlog < a < y logŽ<b < q e ..rlog ly. The arbitrariness of e implies the desired result. Proof of Theorem 6. Denote ynŽ t . s y Ž n. Ž t ., n g N. An important observation is that ynŽ t . satisfies the functional-differential equation ynX Ž t . s ayn Ž t . q ` ` is1 is1 Ý bi qin yn Ž qi t . q Ý c i pin ynX Ž pi t . , t ) 0, Ž 4.1. and the functional equation ayn Ž t . q ` Ý bi qin yn Ž qi t . s h n Ž t . , t G 0, Ž 4.2. is1 where h n Ž t . s ynq1 Ž t . y ` Ý c i pin ynq1Ž pi t . . is1 Another useful observation is that ynq 1Ž t . s O Ž t m . as t ª ` implies h nŽ t . s O Ž t m . as t ª ` for any fixed m and n. First, let us consider the case Re a s 0. Let m g N be such that <Žb, q m .< - < a <. Applying Theorem 5 to Ž4.1. with n s m yields ymŽ t . s O Ž1. as t ª `. Applying Lemma 7 84 ISERLES AND LIU repeatedly to Ž4.2. from n s m y 1 to n s 0 yields y Ž t . s O Ž t m . as t ª ` for any m g Ž m 0 , `. l w0, `.. Next, we consider the case Re a - 0. Let m g N be such that log < a < y log Ž b, q m . log ly - m0 . U Applying Lemma 9 to Ž4.1. with n s m yields ymŽ t . s O Ž t m . as t ª ` for any mU g ž log < a < y log Ž b, q m . log ly / , m0 . Applying Lemma 7 repeatedly to Ž4.2. from n s m y 1 to n s 0 yields y Ž t . s O Ž t Ž m q m 0 .r2 . as t ª ` for any m ) m 0 . Hence, y Ž t . s oŽ t m . as t ª ` for any m ) m 0 . This completes the proof of Theorem 6. 5. ON A SYSTEM OF EQUATIONS In this section we generalize our results on the scalar initial-value problem Ž1.3. ] Ž1.4. to the vector problem y X Ž t . s Ay Ž t . q ` Ý is1 y Ž 0 . s y0 , Bi y Ž qi t . q ` Ý Ci y X Ž pi t . , t ) 0, Ž 5.1. is1 Ž 5.2. where A, Bi , and Ci are d = d complex matrices, pi , qi g Ž0, 1., i s 1, 2, . . . , and y0 is a column vector in C d. To guarantee convergence of the series in Ž5.1., we assume that Ý`is1 5 Bi 5 - ` and Ý`is1 5 Ci 5 - `, where 5 ? 5 denotes the matrix norm induced by a vector norm, likewise denoted by 5 ? 5, which is arbitrary. Note that this assumption is independent of the norm, since all norms in a finite-dimensional space are equivalent. In the sequel s Ž?. denotes the spectrum, r Ž?. the spectral radius, a Ž?. the maximal real part of the eigenvalues of the matrix Žthe spectral abscissa., and k Ž A. the geometric multiplicity of the eigenvalue with maximal real part. If there is more than one eigenvalue that attains the maximal real part, then k Ž A. denotes the maximal geometric multiplicity of all such eigenvalues. NEUTRAL FUNCTIONAL-DIFFERENTIAL EQUATIONS 85 Analogously to Theorem 1 we have the following result. THEOREM 10. If Ý`is1 pim 5 Ci 5 - 1 for some m g Zq, then in the function space C mq 1 w0, `. the solution of Ž5.1. ] Ž5.2. exists and is unique if and only if ` Iy Ý pin Ci , n s 0, 1, . . . , m y 1, are nonsingular. Ž 5.3. is1 If Ž5.3. holds then the unique solution is analytic and can be written as ž ` yŽ t . s I q ny1 Ý Ł ns1 ks0 Iy ž y1 ` Ý pik Ci is1 / ž Aq ` Ý qik Bi is1 tn / / n! t G 0, y0 , Ž 5.4. where the multiplication of matrices in the product is carried out from left to right. In the rest of this section, we assume that A is nonsingular, Ž5.3. holds, lqs sup iG 1 max pi , qi 4 - 1, and s Ž A . l s Žq j p kA . s B Ž 5.5. holds for all Žj, k. g ŽZq. ` = ŽZq. ` _Ž0, 0.. Again we seek a Dirichlet or Dirichlet]Taylor series solution. Analogously to Theorem 3 we have the following result. THEOREM 11. series solution If Ý`is1 5 Ay1 Bi 5 - 1 then Ž5.1. ] Ž5.2. has the Dirichlet yŽ t . s ` Ý D j, k exp Ž Atq j p k . V y0 , Ý ns0 <j <q <k <sn Ž 5.6. where D 0, 0 s I, D j, k s 0 if ji - 0 or k i - 0 for some i g N, D j, k 4 , Žj, k. g ŽZq. ` = ŽZq. ` _Ž0, 0., are determined by the recurrence relation q j p k D j, k A y ADj, k s ` Ý Ž Bi Djye , k q q j p kye Ci Dj, kye A . , i i is1 i ` j, k g Ž Zq . , Ž 5.7. 86 ISERLES AND LIU and ym my1 V s lim A Ł mª` ns0 ž Iy y1 ` Ý Ci pin is1 / ž Aq ` Ý Bi qin is1 / . Ž 5.8. Proof. By substituting Ž5.6. into Ž5.1. and comparing the coefficients of expŽ Atq j p k . on both sides, we obtain the recurrence relation Ž5.7.. Clearly, Ž5.7. is obeyed in the case j, k s 0. It follows from a classical theorem w9x that Ž5.7. is solvable for D j, k if Ž5.5. holds. Introducing the generating function G Ž x, y . s ` Ý Ý ns0 <j <q <k <sn D j, k x j y k , we obtain from Ž5.7. the relation ž ` Aq Ý Bi x i is1 / G Ž x, y . s I y ž ` Ý C i yi is1 / G Ž qx, py . A, which implies that det Ž G Ž x, y . . s ` Ł ns0 det Ž I y Ý`is1Ci pin yi . det Ž I q Ý`is1TAy1 Bi qin x i . / 0. Ž 5.9. Hence, GŽ1, 1. is nonsingular. By letting V s GŽ1, 1.y1 , we see that the Dirichlet series Ž5.6. satisfies Ž5.1. ] Ž5.2.. Analogously to Theorem 4 we have the following result. THEOREM 12. If m [ min n g Zq: Ý`is1 qin 5 Ay1 Bi 5 - 14 G 1, then Ž5.1. ] Ž5.2. has the Dirichlet]Taylor series solution my1 yŽ t . s y Ž n. Ž 0 . Ý ns0 q n! tn ` Ý Ý ns0 <j <q <k <sn ž D j, k exp Ž Atq j p k . y my1 Ý ls0 Ž Aq j p k . l! l / t l V y0 , where y Ž n. Ž0. can be obtained from Ž5.4., D j, k are determined by Ž5.7., and V is gi¨ en by Ž5.8.. NEUTRAL FUNCTIONAL-DIFFERENTIAL EQUATIONS 87 Noting that 5 e A t 5 F M Ž t q 1 . k Ž A .y1 e a Ž A.t , t G 0, for some constant M ) 0, we have analogously to Theorems 5 and 6 the following results. THEOREM 13. 1. 2. 3. Let yŽ t . be the unique solution of Ž5.1. ] Ž5.2.. Then 5yŽ t .5 s O Ž t k Ž A.y1 e a Ž A.t . as t ª ` if a Ž A. ) 0; 5yŽ t .5 s O Ž t mq k Ž A.y1 . as t ª ` if a Ž A. s 0; and 5yŽ t .5 s oŽ t m . as t ª ` if a Ž A. - 0, where m [ min n g Zq: Ý`is1 qin 5 Ay1 Bi 5 - 14 . THEOREM 14. if Suppose that ly[ inf iG 1 max pi , qi 4 ) 0. Let m 0 s y` det A q ž ` Ý Bi qil is1 / s0 has no solution; otherwise, let ½ m 0 [ sup Re l : det A q ž ` Ý Bi qil is1 / 5 s0 . Then the solution yŽ t . of Ž5.1. ] Ž5.2. satisfies 1. 5yŽ t .5 s O Ž t mq k Ž A.y1 . as t ª ` for any m g Ž m 0 , `. l w0, `. if a Ž A. s 0; and 2. 5yŽ t .5 s oŽ t m . as t ª ` for any m ) m 0 if a Ž A. - 0. Under further restrictions, we have the following result. THEOREM 15. If all eigen¨ alues of A ha¨ e a positi¨ e real part, and A, Bi , and Ci commute with each other for all i g N, then the solution yŽ t . of Ž5.1. ] Ž5.2. satisfies lim eyA t y Ž t . s V y0 , tª` where V is gi¨ en by Ž5.8.. Proof. It is easy to prove by induction from Ž5.7. that, in the present situation, A and D j, k 4 , Žj, k. g ŽZq. ` = ŽZq. ` , commute with each other. 88 ISERLES AND LIU We can then prove this theorem directly from Theorem 11 or 12, depending on whether the condition Ý`is1 5 Ay1 Bi 5 - 1 holds or not. 6. ON THE GENERALIZED PANTOGRAPH EQUATION In this section we discuss the generalized pantograph equation Ž1.5.. To guarantee the existence and uniqueness of the solution, we assume that c / qyk , k s 0, 1, . . . . Suppose that a / 0 and < b < - < a <. Then Ž1.5. has the Dirichlet series solution yŽ t. s Ž ybra; q . ` Ž c; q . ` ` Ý ns0 b Ž yacrb; q . n y a Ž q; q . n ž / n exp Ž atq n . if b / 0, or yŽ t. s n 1 ` Ž c; q . ` ns0 Ý Ž y1. c nq nŽ ny1.r2 exp Ž atq n . Ž q; q . n if b s 0. Suppose that < b < G < a < ) 0. Then Ž1.5. has the Dirichlet]Taylor series solution my1 yŽ t. s y Ž n. Ž 0 . Ý ns0 = ` Ý ns0 n! tn q Ž ybra; q . ` Ž c; q . ` b Ž yacrb; q . n y a Ž q; q. n n ž /ž my1 exp Ž atq n . y Ý ls0 Ž aq n . l! l / tl , where m [ wlogŽ< a <r< b <.rlog q x q 1. In the case where Re a - 0 and b / 0, the result in Section 4 can be improved. THEOREM 16. Suppose that Re a - 0 and b / 0. Let y Ž t . be the solution of Ž1.5., m s logŽ< a <r< b <.rlog q, u s 1rŽ2p .argŽyq may1 b ., and z Ž t . s tym y Ž t .. Then 1. y Ž t . s O Ž t m . as t ª `. 2. If u is rational, u s lrk, say, then the v-limit set of z Ž t . coincides with a closed continuous cur¨ e that can be represented parametrically by ŽRe zU Ž t ., Im zU Ž t .. for t g w1, qyk x in the complex plane, where zU Ž t . g NEUTRAL FUNCTIONAL-DIFFERENTIAL EQUATIONS FIG. 1. 89 X . Ž . Ž . Ž . y Ž t . s expŽ 11 20 p i y t y y tr4 , y 0 s 1. C w1, qyk x satisfies zU Ž t . s e 2 pu i zU Ž qt . , t g qy1 , qyk . 3. If u is irrational then the v-limit set of z Ž t . is the annulus V s z: z F < z < F z 4 , where z lim inf t ª` < z Ž t .<, z s lim sup t ª` < z Ž t .<. This theorem is proved in Liu w16x for a slightly more general case. The Dirichlet and Dirichlet]Taylor series solutions make it possible to calculate the v-limit set of z Ž t . Žthe numerical methods presented in Liu w17x can be used in more general cases.. In Figs. 1]6 we display the solutions for t c 1 in the ‘‘phase plane’’ ŽRe y, Im y .. Finally, we discuss the change in asymptotic behaviour in response to the variation of some parameters. Denote by y Ž t; q . the solution of Ž1.5.. It 90 ISERLES AND LIU FIG. 2. X . Ž . Ž . Ž . y Ž t . s expŽ 11 20 p i y t y y tr10 , y 0 s 1. is easy to see that y Ž t ; 1 . s exp ž aqb 1yc t / and y Ž t ; 0. s y c q bra 1yc q 1 q bra 1yc e at . Consider the case of Re a ) 0. Obviously, the asymptotic behaviour of y Ž t; q . is different from y Ž t; 1. no matter how close q is to 1 except when NEUTRAL FUNCTIONAL-DIFFERENTIAL EQUATIONS 91 X . Ž . Ž . y Ž t . s expŽ 116 p i . y Ž t . q expŽ 16 11 p i y tr20 , y 0 s 1. FIG. 3. b s yac. Noting that lim Ž 1 y q . log Ž a; q . ` s qª1y 1 H0 logŽ 1 y ax . dx x , we obtain from Theorem 5 that lim qª1y ž lim y Ž t ; q . expŽ yat . / 1y q tª` s exp 1 log 1 q žH ž ž 0 bx a / y log Ž 1 y cx . dx / / x . 92 ISERLES AND LIU FIG. 4. X . Ž y7 t ., y Ž0. s 1. y Ž t . s expŽ 116 p i . y Ž t . q expŽ 16 11 p i y 10 However, as q ª 0 q , the asymptotic behaviour of y Ž t; q . is quite similar to y Ž t; 0.. In fact, we have lim lim y Ž t ; q . eya t s lim y Ž t ; 0 . eyat s qª0q tª` tª` 1 q bra 1yc . Consider the case of Re a - 0. If we treat < bra< as a parameter, it is clear from Theorem 16 that there exists a Hopf-like bifurcation as < bra< passes through 1. Another interesting phenomenon happens when < b < s < a < and a ª 0 q . It seems that the v-limit set of y Ž t; q . tends to a set Žsee Figures 3 and 4. which is obivously distinct from yŽ c q bra.rŽ1 y c ., the limiting value of y Ž t; 0.. NEUTRAL FUNCTIONAL-DIFFERENTIAL EQUATIONS FIG. 5. 93 X . Ž . Ž 12 . Ž . Ž . y Ž t . s expŽ 40 41 p i y t q exp 41 p i y tr2 , y 0 s 1. Remark. The case a s 0 has been studied by Morris, Feldstein, and Bowen w21x, Kuang and Feldstein w20x, Iserles w12x, and Liu w16x. In the first two papers the authors proved the unboundedness of the nonpolynomial solution via the Phragmen]Lindelof ´ ¨ principle, and by the Ahlfors theorem in the third paper. In the fourth paper, the author proved by using the same technique as that used in Derfel w5x that for every nonpolynomial solution y Ž t . of Ž1.3. there exists a sequence t n4`ns1 , which tends to ` as n ª `, such that < y Ž t .< G M ŽexpŽ b Žlog t . 2 .. at t s t n , n s 1, 2, . . . , for some positive constants M and b . ACKNOWLEDGMENTS The second author wishes to thank Professor Chunlai Zhao ŽPeking University. for a helpful discussion on the proof of Lemma 8, and Cambridge Overseas Trust, CVCP, Fitzwilliam College, and C. T. Taylor Fund for their financial support. 94 ISERLES AND LIU FIG. 6. X . Ž . Ž 20 . Ž . Ž . y Ž t . s expŽ 22 41 p i y t q exp 41 p i y tr2 , y 0 s 1. REFERENCES 1. R. Bellman and K. L. Cooke, ‘‘Differential-Difference Equations,’’ Academic Press, New York, 1963. X 2. J. Carr and J. Dyson, The functional differential equation y Ž x . s ay Ž l x . q by Ž x ., Proc. Roy. Soc. Edinburgh Sect. A 74 Ž1974r75., 165]174. X 3. J. Carr and J. 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