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The objective of this article is to investigate some qualitative behavior of the solutions of the nonlinear difference equation bxn-k [dxp=k– eXp–1] Xn+1 = Axn+ Bxn-k+ Cxp–1+Dxp- n= 0,1,2, .... (1) where the coefficients A, B, C, D, b, d, e E (0, 0), while k, 1 and o are positive integers. The initial conditions i,.……, X_1,..., X_ky •……, X_1, Xo are arbitrary positive real numbers such that k < 1< 0. Note that the special cases of Eq.(1) have been studied in [1] when B= C = D= 0, and k = 0,1= 1, b is replaced by – b and in [27] when B=C= D=0, and k= 0, b is replaced by [33] when B = C = D = 0, 1= 0 and in [32] when A= C=D=0, 1=0, b is replaced by – b. b and in |

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Theorem 9.If k is even and 1, 0 are odd positive integers, then Eq.(1) has prime period two solution if the condition t (1–(C+D)) (3e– d) < (e+ d) (A+ B), (20) is valid, provided (C+D) 1 and e (1– (C+ D)) – d (A+B) > 0. a Proof.If k is even and 1, o are odd positive integers, then Xn = Xn-k and xn+1 = Xn-1= Xn-o• It follows from Eq.(1) that bQ P= (A+B) Q+(C+D)P – (21) (еР — dQ)" and V БР Q= (A+B) P+(C+D) Q – (22) (eQ– dP)' Consequently, we get e P – dPQ = e (A+B) PQ– d (A+B) Q + e(C+ D) P - (C+D) dPQ– bQ, (23) and e Q – dPQ = e (A+B) PQ– d (A+B) +e(C+D) Q - (C+D) dPQ– bP. i %3D (24) By subtracting (24) from (23), we get P+Q= (25) [e (1– (C+D))– d (A+B)]’ where e (1-(C+ D)) – d (A+B) > 0. By adding (23) and (24), we obtain t e b (1 – (C+D)) (e+d) [K1+(A+B)][e K1 – d (A+B)]² ' PQ= (26) (1–(C+D)), provided (C+D) < 1. where K1 = Assume that P and Q are two positive distinct real roots of the quadratic equation 2- (P+Q)t+ PQ=0. (27) Thus, we deduce that (P+ Q)² > 4PQ. (28) Substituting (25) and (26) into (28), we get the condition (20). Thus, the proof is now completed.O