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This paper is devoted to considering the iterated order and the fixed points of some differential polynomials generated by solutions of the differential equation $$f^{{}^{\text{'}\text{'}}}+A_1\left(z\right)f^{{}^{\text{'}}}+A_0\left(z\right)f=F,$$ where $A_1\left(z\right)$, $A_0\left(z\right)$ $(\neg \equiv 0)$, $F$ are meromorphic functions of finite iterated $p$-order.

We investigate the growth and fixed points of meromorphic solutions of higher order linear differential equations with meromorphic coefficients and their derivatives. Our results extend the previous results due to Peng and Chen.

Firstly we study the growth of meromorphic solutions of linear difference equation of the form$$A_k\left(z\right)f(z+c_k)+\cdots +A_1\left(z\right)f(z+c_1)+A_0\left(z\right)f\left(z\right)=F\left(z\right),$$ where $A_k\left(z\right),...,A_0\left(z\right)$ and $F\left(z\right)$ are meromorphic functions of finite logarithmic order, $c_i$ $(i=1,...,k,k\in \mathbb{N})$ are distinct nonzero complex constants. Secondly, we deal with the growth of solutions of differential-difference equation of the form $$\sum _{i=0}^n\sum _{j=0}^m{A}_{ij}\left(z\right)f^{\left(j\right)}(z+c_i)=F\left(z\right),$$ where $A_{ij}\left(z\right)$ $(i=0,1,...,n,j=0,1,...,m,n,m\in \mathbb{N})$ and $F\left(z\right)$ are meromorphic functions of finite logarithmic order, $c_i$ $(i=0,...,n)$ are distinct complex constants. We extend some previous results obtained...

This paper is devoted to considering the complex oscillation of differential polynomials generated by meromorphic solutions of the differential equation $$f^{\left(k\right)}+A_{k-1}\left(z\right)f^{(k-1)}+\cdots +A_1\left(z\right)f^{\text{'}}+A_0\left(z\right)f=0,$$ where $A_i\left(z\right)$ $(i=0,1,\cdots ,k-1)$ are meromorphic functions of finite order in the complex plane.

This paper is devoted to studying the growth and oscillation of solutions and their derivatives of higher order non-homogeneous linear differential equations with finite order meromorphic coefficients. Illustrative examples are also treated.

In this paper, we investigate the relationship between small functions and differential polynomials $g_f\left(z\right)=d_2{f}^{\text{'}\text{'}}+d_1{f}^{\text{'}}+d_{0}f$, where $d_0\left(z\right)$, $d_1\left(z\right)$, $d_2\left(z\right)$ are entire functions that are not all equal to zero with $\rho \left(d_j\right)<1$ $(j=0,1,2)$ generated by solutions of the differential equation $f^{\text{'}\text{'}}+A_1\left(z\right)e^{az}{f}^{\text{'}}+A_0\left(z\right)e^{bz}f=F$, where $a,b$ are complex numbers that satisfy $ab(a-b)\ne 0$ and $A_j\left(z\right)\neg \equiv 0$ ($j=0,1$), $F\left(z\right)\neg \equiv 0$ are entire functions such that $max\left\{\rho \left(A_j\right),j=0,1,\rho \left(F\right)\right\}<1.$

In this paper we discuss the growth of solutions of the higher order nonhomogeneous linear differential equation $$\begin{array}{cc}& f^{\left(k\right)}+A_{k-1}{f}^{(k-1)}+\cdots +A_2{f}^{\text{'}\text{'}}+(D_1\left(z\right)+A_1\left(z\right){\mathrm{e}}^{az})f^{\text{'}}\hfill \\ & +(D_0\left(z\right)+A_0\left(z\right){\mathrm{e}}^{bz})f=F(k\ge 2),\hfill \end{array}$$ where $a$, $b$ are complex constants that satisfy $ab(a-b)\ne 0$ and $A_j\left(z\right)$ $(j=0,1,\cdots ,k-1)$, $D_j\left(z\right)$ $(j=0,1)$, $F\left(z\right)$ are entire functions with $max\{\rho \left(A_j\right)(j=0,1,\cdots ,k-1),\rho \left(D_j\right)$ $(j=0,1)\}<1$. We also investigate the relationship between small functions and the solutions of the above equation.