1. Introduction
In classical Nevanlinna theory, the lemma on the logarithmic derivative states that for a nonconstant meromorphic function
$f:{\mathbb {C}}\to {\mathbb {C}}\cup \{\infty \}$
,
$$ \begin{align*} m\bigg(r,\frac{f'}{f}\bigg) = o(T(r,f)) \end{align*} $$
as r tends to infinity outside an exceptional set of finite linear measure, where
$$ \begin{align*} m(r,f) = \frac{1}{2\pi}\int_0^{2\pi}\log^+|f(re^{i\theta})|\,d\theta \end{align*} $$
and
$T(r,f)$
is the Nevanlinna characteristic function for f. The lemma on the logarithmic derivative is an important result that is used to prove several results in Nevanlinna theory. The most important consequence of the lemma on the logarithmic derivative is the second main theorem of Nevanlinna theory [Reference Cherry and Ye2, Reference Hayman6].
Tropical Nevanlinna theory was first introduced in [Reference Halburd and Southall4], where Halburd and Southall proved the tropical analogue of the lemma on the logarithmic derivative for finite order tropical meromorphic functions. Later, the growth condition was improved for functions of hyper-order less than one by Laine and Tohge [Reference Laine and Tohge8], and for subnormal functions by Cao and Zheng [Reference Cao and Zheng1]. Tropical Nevanlinna theory was extended for noncontinuous tropical meromorphic functions in [Reference Halonen, Korhonen and Filipuk5], where the Poisson–Jensen formula and the second main theorem were proved for noncontinuous tropical meromorphic functions.
In this paper, we will prove the following version of the tropical analogue of the lemma on the logarithmic derivative that generalises it for noncontinuous piecewise linear functions.
Theorem 1.1. Let f be a piecewise linear function and
$f_c(x) \equiv f(x+c)$
. If the hyper-order of f is less than one, then
$$ \begin{align*} m\bigg(r,{\frac{f_c}{f}\oslash}\bigg) = o(T(r,f)) \end{align*} $$
holds outside an exceptional set of finite logarithmic measure as r tends to infinity.
By proving the tropical analogue of the lemma on the logarithmic derivative for noncontinuous piecewise linear functions, several Clunie and Mohon’ko type results [Reference Korhonen, Laine and Tohge7, Reference Laine and Yang9] follow with identical proofs to the continuous case for noncontinuous piecewise linear functions.
2. Basic definitions
The tropical semiring is defined as
${\mathbb {T}} = {\mathbb {R}}\cup \{-\infty \}$
[Reference Maclagan and Sturmfels10], where addition and multiplication are defined by
$$ \begin{align*} a\oplus b = \max\{a,b\} \quad\text{and}\quad a\otimes b = a + b. \end{align*} $$
Additive and multiplicative neutral elements are
$0_\circ = -\infty $
and
$1_\circ = 0$
. Here
${\mathbb {T}}$
is a semiring, because not all elements have an additive inverse element. For example, there is no
$x\in {\mathbb {T}}$
such that
$2\oplus x = 0_\circ $
. For this reason, subtraction is not defined on the tropical semiring. Tropical division is defined as
$a\oslash b = a-b$
and exponentiation as
$a^{\otimes \alpha } = \alpha a$
for
$\alpha \in {\mathbb {R}}$
.
In this paper, we will use the notation
$$ \begin{align*} f(x_0+):= \lim_{x\to x_0^+}f(x) \quad \text{and}\quad f(x_0-):= \lim_{x\to x_0^-}f(x). \end{align*} $$
A tropical meromorphic function is defined as a continuous piecewise linear function. Here we will drop the assumption of continuity and consider piecewise linear functions that may have discontinuities as in [Reference Halonen, Korhonen and Filipuk5]. For piecewise linear functions, we define roots and poles in the same way as for tropical meromorphic functions [Reference Korhonen, Laine and Tohge7]. We say that x is a pole of f if
$$ \begin{align*} \omega_f(x) := f'(x+)-f'(x-) < 0 \end{align*} $$
and a root if
$\omega _f(x)>0$
. The multiplicity of a root or a pole of a tropical meromorphic function f at x is
$\tau _f(x) := |\omega _f(x)|$
.
For a piecewise linear function f, as in [Reference Halonen, Korhonen and Filipuk5], we define
$$ \begin{align*} \Omega_f(x) := f(x+)-f(x-) \end{align*} $$
and we say that
$x\neq 0$
is a positive jump if
$x\Omega _f(x)>0$
and a negative jump if
$x\Omega _f(x) < 0$
. If there is a discontinuity at
$0$
, we say that it is a positive jump if
$f(0) = \max \{f(0+),f(0-)\}$
and a negative jump if
$f(0) = \min \{f(0+),f(0-)\}$
. We call
$h_f(x) = |\omega _f(x)|$
the height of the jump at x. We then define the jump counting function as
$$ \begin{align*} J(r,f) = \frac{1}{2}\sum_{|\beta_\nu|\leq r} h_f(\beta_\nu), \end{align*} $$
where
$\beta _\nu $
are the negative jumps of f. For a piecewise linear function, we define the Nevanlinna proximity function as
$$ \begin{align*} m(r,f) = \frac{f(r)^++f(-r)^+}{2}, \end{align*} $$
where
$f(x)^+ = \max \{f(x),0\}$
. The Nevanlinna counting function is defined as
$$ \begin{align*} N(r,f) = \frac{1}{2}\int_0^rn(t,f)\,dt = \frac{1}{2}\sum_{|b_\nu|<r}\tau_f(b_\nu)(r-|b_\nu|), \end{align*} $$
where
$n(r,f)$
counts the poles
$b_\nu $
of f in
$(-r,r)$
according to their multiplicities. Finally, the Nevanlinna characteristic function for piecewise linear functions is defined as
$$ \begin{align*} T(r,f) := m(r,f) + N(r,f) + J(r,f). \end{align*} $$
From [Reference Halonen, Korhonen and Filipuk5, Theorem 2.5], for noncontinuous piecewise linear functions, the Poisson– Jensen formula is of the form
$$ \begin{align} f(x) & = \frac{1}{2}(f(r)+f(-r)) + \frac{x}{2r}(f(r)-f(-r)) \notag \\ & \quad - \frac{1}{2r}\sum_{|a_\mu|<r}\tau_f(a_\mu)(r^2 - |a_\mu - x|r - a_\mu x) + \frac{1}{2r}\sum_{|b_\nu|<r}\tau_f(b_\nu)(r^2 - |b_\nu - x|r - b_\nu x) \notag \\ & \quad - S_1(x)+S_2(x)-S_3(x)+S_4(x) - \frac{x}{2r}\Omega_f(0) -\frac{1}{2}(A_f(x) + B_f(x)), \end{align} $$
where
$$ \begin{align*} S_1(x) &= \frac{x}{2r}\bigg(\sum_{-r\leq \beta_\nu\leq 0}h_f(\beta_\nu)+\sum_{0\leq \alpha_\mu\leq r}h_f(\alpha_\mu)\bigg),\\ S_2(x) &= \frac{x}{2r}\bigg(\sum_{-r\leq \alpha_\mu\leq 0}h_f(\alpha_\mu)+\sum_{0\leq \beta_\nu\leq r}h_f(\beta_\nu)\bigg),\\ S_3(x) &= \frac{1}{2}\bigg(\sum_{-r\leq \alpha_\mu\leq \min\{0,x\}}\!\!\!\!\!\!\!\!h_f(\alpha_\mu)+\sum_{\max\{x,0\}\leq \alpha_\mu\leq r}\!\!\!\!\!\!\!\!h_f(\alpha_\mu) - \sum_{ x\leq\alpha_\mu\leq 0}\!\!h_f(\alpha_\mu) - \sum_{0\leq\alpha_\mu\leq x}\!\!h_f(\alpha_\mu)\bigg),\\ S_4(x) &= \frac{1}{2}\bigg(\sum_{-r\leq \beta_\nu\leq \min\{0,x\}}\!\!\!\!\!\!\!\!h_f(\beta_\nu)+\sum_{\max\{x,0\}\leq \beta_\nu\leq r}\!\!\!\!\!\!\!\!h_f(\beta_\nu) - \sum_{ x\leq\beta_\nu\leq 0}\!\!h_f(\beta_\nu) - \sum_{0\leq\beta_\nu\leq x}\!\!h_f(\beta_\nu)\bigg), \end{align*} $$
$$ \begin{align*} A_f(x) = \begin{cases} 0 &\text{if }f \text{ is continuous at } x,\\ \Omega _f(x) &\text{if } f \text{ is left-discontinuous at } x,\\ -\Omega _f(x) &\text{if } f \text{ is right-discontinuous at } x \end{cases} \end{align*} $$
and
$$ \begin{align*} B_f(x) = \begin{cases} 0 &\text{if }x = 0,\\ -\Omega _f(0) &\text{if }x< 0,\\ \Omega _f(0) &\text{if }x> 0. \end{cases} \end{align*} $$
With the special case of
$x=0$
, we obtain the Jensen formula
$$ \begin{align*} T(r,f) = T(r,-f) + f(0). \end{align*} $$
The order
$\rho (f)$
and hyper-order
$\rho _2(f)$
of a piecewise linear function f are defined by
$$ \begin{align*} \rho(f):=\limsup_{r\to\infty}\frac{\log T(r,f)}{\log r} \quad\text{and}\quad \rho_2(f):=\limsup_{r\to\infty}\frac{\log\log T(r,f)}{\log r}. \end{align*} $$
3. Lemma on the logarithmic derivative
To prove Theorem 1.1, we need to prove some results for noncontinuous functions. We begin by proving a generalised version of [Reference Halburd, Korhonen and Tohge3, Lemma 8.3]. In this version, the assumption of continuity is replaced with piecewise continuity and the assumption of nondecreasingness with condition (3.1) below. Note that condition (3.1) implies nondecreasingness. The proof closely follows the proof of [Reference Halburd, Korhonen and Tohge3, Lemma 8.3] with some minor changes.
Theorem 3.1. Let
$s>0$
and
$T:[0,\infty )\to [0,\infty )$
be a piecewise continuous function such that
$$ \begin{align} T(r)\leq \frac{R}{r}T(R) \end{align} $$
for all
$R\geq r>0$
. If the hyper-order of T is strictly less than one, then
$$ \begin{align*} T(r+s) = T(r) + o(T(r)) \end{align*} $$
outside of a set of finite logarithmic measure as r tends to infinity.
Proof. Let
$\eta>0$
and assume that the set
$F_\eta := \{r\in {\mathbb {R}}^+:T(r+s)\geq (1+\eta )T(r)\} \subset [1,\infty )$
is of infinite logarithmic measure. Define
$G:[0,\infty )\to [0,\infty )$
such that
$G(r) := T(r+)$
for all
$r\in [0,\infty ).$
Then
$G(r)$
is right-continuous at every point and, therefore,
$$ \begin{align*} H_\eta = \{r\in{\mathbb{R}}^+:G(r+s)\geq (1+\eta)G(r)\} \end{align*} $$
contains the smallest element
$r_0$
. Set
$r_n=\min \{H_\eta \cap [r_{n-1}+s,\infty )\}$
for all
$n\in {\mathbb {N}}$
. Then the sequence
$\{r_n\}_{n\in {\mathbb {N}}}$
satisfies
$r_{n+1}-r_n\geq s$
for all
$n\in {\mathbb {N}}$
,
$H_\eta \subset \bigcup _{n=0}^\infty [r_n,r_n+s]$
and then
$$ \begin{align} (1+\eta)G(r_n)\leq G(r_n+s)\leq \frac{r_{n+1}}{r_n+s}G(r_{n+1})\leq \frac{r_{n+1}}{r_n}G(r_{n+1}) \end{align} $$
for all
$n\in {\mathbb {N}}$
. Let
$\varepsilon>0$
and suppose that there exists an integer
$m\in {\mathbb {N}}$
such that
$r_n\geq n^{1+\varepsilon }$
for all
$r_n\geq m$
. Then
$$ \begin{align*} \int_{H_\eta\cap[1,\infty)}\frac{dt}{t} \leq \sum_{n=0}^\infty\int_{r_n}^{r_n+s}\frac{dt}{t} & \leq\int_1^m\frac{dt}{t}+\sum_{n=1}^\infty \log\bigg(1+\frac{s}{r_n}\bigg)\\ &\leq \sum_{n=1}^\infty \log(1+sn^{-(1+\varepsilon)}) + O(1)<\infty, \end{align*} $$
which contradicts the assumption that
$H_\eta \cap [1,\infty )$
has infinite logarithmic measure. Therefore, the sequence
$\{r_n\}_{n\in {\mathbb {N}}}$
has a subsequence
$\{r_{n_j}\}_{j\in {\mathbb {N}}}$
such that
$r_{n_j}\leq n_j^{1+\varepsilon }$
for all
$j\in {\mathbb {N}}$
. By iterating (3.2) along the sequence
$\{r_{n_j}\}_{j\in {\mathbb {N}}}$
,
$$ \begin{align*} G(r_{n_j})\geq G(r_0)\prod_{\nu = 0}^{n_j-1}\bigg(\frac{r_\nu}{r_{\nu+1}}(1+\eta)\bigg) = \frac{r_0}{r_{n_j}}G(r_0)(1+\eta)^{n_j} \end{align*} $$
for all
$j\in {\mathbb {N}}$
. Denote the hyper-order of G by
$\rho _2$
. Then we can see that
$$ \begin{align*} \rho_2 &= \limsup_{r\to\infty} \frac{\log\log G(r)}{\log r} \geq \limsup_{j\to\infty}\frac{\log(\log G(r_0)+n_j\log(1+\eta)+\log r_0 - \log r_{n_j})}{\log r_{n_j}}\\ &\geq \limsup_{j\to\infty}\frac{\log(\log G(r_0)+ n_j\log(1+\eta)+\log r_0 - (1+\varepsilon)\log n_j)}{(1+\varepsilon)\log n_j}\\ &=\limsup_{j\to\infty}\frac{\log(n_j({(\log G(r_0)+\log r_0 - (1+\varepsilon)\log n_j)}/{n_j} + \log(1+\eta)))}{(1+\varepsilon)\log n_j}\\ &=\limsup_{j\to\infty}\frac{\log n_j+\log({(\log G(r_0)+\log r_0 - (1+\varepsilon)\log n_j)}/{n_j} + \log(1+\eta))}{(1+\varepsilon)\log n_j}\\ &= \frac{1}{1+\varepsilon}. \end{align*} $$
Since the hyper-order of T is less than one and
$G(r)\neq T(r)$
for at most countably many r, we must have
$\rho _2<1$
. We can now choose
$\varepsilon>0$
such that
$1>{1}/{(1+\varepsilon )}>\rho _2$
which leads to a contradiction. Therefore,
$H_\eta $
has finite logarithmic measure. As a piecewise continuous function, T has at most countably many discontinuities, so that
$H_\eta $
and
$ F_\eta $
differ at at most countably many points and thus also
$F_\eta $
has finite logarithmic measure.
The following result is a noncontinuous version of [Reference Korhonen, Laine and Tohge7, Theorem 3.24].
Theorem 3.2. Let f be a piecewise linear function. Then for all
$\alpha> 1$
, as r tends to infinity,
$$ \begin{align*} m\bigg(r,{\frac{f(x+c)}{f(x)}\oslash}\bigg)&\leq \frac{16|c|}{r+|c|}\frac{1}{\alpha -1} (T(\alpha(r+|c|),f) + |f(0)|/2) \\ &\quad + J(r+c,f)-J(r-c,f) + J(r+c,-f)-J(r-c,-f) + O(1). \end{align*} $$
Proof. Suppose that
$\rho> r + |c|$
and
$x\in [-r,r]$
. Denote by
$a_\mu ,b_\nu ,\alpha _\mu ,\beta _\nu $
the roots, poles, positive and negative jumps of f in
$[-\rho ,\rho ]$
. By the Poisson–Jensen formula,
$$ \begin{align*} &f(x+c) - f(x) = \frac{c}{2\rho}(f(\rho)-f(-\rho))\\ & \quad + \frac{1}{2\rho}\sum_{|a_\mu|<\rho}\tau(a_\mu)((|a_\mu - x - c|-|a_\mu - x|)\rho + ca_\mu) \\ & \quad - \frac{1}{2\rho}\sum_{|b_\nu|<\rho}\tau(b_\nu)((|b_\nu - x - c|-|b_\nu - x|)\rho + cb_\nu)\\ & \quad - \frac{c}{2\rho}\bigg(\sum_{-\rho\leq\beta_\nu\leq 0}h_f(\beta_\nu) + \sum_{0\leq\alpha_\mu\leq \rho}h_f(\alpha_\mu)\bigg) + \frac{c}{2\rho}\bigg(\sum_{-\rho\leq\alpha_\mu\leq 0}h_f(\alpha_\mu) + \sum_{0\leq\beta_\nu\leq \rho}h_f(\beta_\nu)\bigg)\\ & \quad + \frac{1}{2}\bigg(\sum_{\alpha_\mu\in(x,x+c]\cap(-\infty,0]}\!\!\!\!\!\!\!\!\!\!h_f(\alpha_\mu) - \sum_{\alpha_\mu\in[x,x+c)\cap[0,\infty)}\!\!\!\!\!\!\!\!\!h_f(\alpha_\mu) + \sum_{ \alpha_\mu\in[x,x+c)\cap(-\infty,0]}\!\!\!\!\!\!\!\!h_f(\alpha_\mu) - \sum_{ \alpha_\mu\in(x,x+c]\cap[0,\infty)}\!\!\!\!\!\!\!\!h_f(\alpha_\mu)\bigg)\\ & \quad - \frac{1}{2}\bigg(\sum_{\beta_\nu\in(x,x+c]\cap(-\infty,0]}\!\!\!\!\!\!\!\!\!\!h_f(\beta_\nu) - \sum_{\beta_\nu\in[x,x+c)\cap[0,\infty)}\!\!\!\!\!\!\!\!h_f(\beta_\nu) + \sum_{ \beta_\nu\in[x,x+c)\cap(-\infty,0]}\!\!\!\!\!\!\!\!\!\!h_f(\beta_\nu) - \sum_{ \beta_\nu\in(x,x+c]\cap[0,\infty)}\!\!\!\!\!\!\!\!h_f(\beta_\nu)\bigg)\\ &\quad - \frac{c}{2\rho}\Omega _f(0) -\frac{1}{2}(A_f(x+c)-A_f(x) + B_f(x+c)-B_f(x)). \end{align*} $$
By the definition of
$h_f$
,
$$ \begin{align*} &\sum_{-\rho \leq\beta_\nu\leq 0} -h_f(\beta_\nu) + \sum_{0\leq\alpha_\mu\leq \rho}-h_f(\alpha_\mu) + \sum_{-\rho\leq\alpha_\mu\leq 0}h_f(\alpha_\mu) + \sum_{0\leq\beta_\nu\leq \rho}h_f(\beta_\nu)\\ &\quad =\sum_{-\rho\leq\beta_\nu\leq 0}-\Omega_f(\beta_\nu) + \sum_{0\leq\alpha_\mu\leq \rho}-\Omega_f(\alpha_\mu) + \sum_{-\rho\leq\alpha_\mu\leq 0}-\Omega_f(\alpha_\mu) + \sum_{0\leq\beta_\nu\leq \rho}-\Omega_f(\beta_\nu)\\ &\quad =-\bigg(\sum_{|\alpha_\mu|\leq \rho}\Omega_f(\alpha_\mu) + \sum_{|\beta_\nu|\leq \rho}\Omega_f(\beta_\nu)\bigg). \end{align*} $$
By combining terms and by the definition of
$h_f$
,
$$ \begin{align*} &\sum_{\alpha_\mu\in(x,x+c]\cap(-\infty,0]}\!\!\!\!\!\!\!\!\!\!h_f(\alpha_\mu) - \sum_{\alpha_\mu\in[x,x+c)\cap[0,\infty)}\!\!\!\!\!\!\!\!h_f(\alpha_\mu) + \sum_{ \alpha_\mu\in[x,x+c)\cap(-\infty,0]}\!\!\!\!\!\!\!\!\!\!h_f(\alpha_\mu) - \sum_{ \alpha_\mu\in(x,x+c]\cap[0,\infty)}\!\!\!\!\!\!\!\!h_f(\alpha_\mu)\\ &\quad=2\sum_{\alpha_\mu\in[x,x+c]\cap(-\infty,0]}\!\!\!\!\!\!\!\!\!\!h_f(\alpha_\mu) - \sum_{\alpha_\mu\in\{x,x+c\}\cap(-\infty,0]}\!\!\!\!\!\!\!\!\!\!h_f(\alpha_\mu) - 2 \sum_{\alpha_\mu\in[x,x+c]\cap[0,\infty)}\!\!\!\!\!\!\!\!h_f(\alpha_\mu)+ \sum_{\alpha_\mu\in\{x,x+c\}\cap[0,\infty)}\!\!\!\!\!\!\!\!h_f(\alpha_\mu)\\ &\quad =-2\sum_{\alpha_\mu\in[x,x+c]}\Omega _f(\alpha_\mu) + \sum_{\alpha_\mu\in\{x,x+c\}}\Omega _f(\alpha_\mu). \end{align*} $$
Similarly, for the negative jumps,
$$ \begin{align*} & \sum_{\beta_\nu\in(x,x+c]\cap(-\infty,0]} \!\!\!\!\!\!\!\!\!\! h_f(\beta_\nu) - \sum_{\beta_\nu\in[x,x+c)\cap[0,\infty)}\!\!\!\!\!\!\!\!h_f(\beta_\nu) + \sum_{ \beta_\nu\in[x,x+c)\cap(-\infty,0]}\!\!\!\!\!\!\!\!\!\!h_f(\beta_\nu) - \sum_{ \beta_\nu\in(x,x+c]\cap[0,\infty)}\!\!\!\!\!\!\!\!h_f(\beta_\nu)\\ &\quad =2\sum_{\beta_\nu\in[x,x+c]}\Omega _f(\beta_\nu) - \sum_{\beta_\nu\in\{x,x+c\}}\Omega _f(\beta_\nu). \end{align*} $$
By combining these equations,
$$ \begin{align*} &f(x +c) - f(x) = \frac{c}{2\rho}(f(\rho)-f(-\rho))\\ &\quad + \frac{1}{2\rho}\sum_{|a_\mu|<\rho}\tau(a_\mu)((|a_\mu - x - c|-|a_\mu - x|)\rho + ca_\mu)\\ &\quad - \frac{1}{2\rho}\sum_{|b_\nu|<\rho}\tau(b_\nu)((|b_\nu - x - c|-|b_\nu - x|)\rho + cb_\nu)\\ &\quad - \frac{c}{2\rho}\bigg(\sum_{|\alpha_\mu|\leq\rho}\Omega_f(\alpha_\mu) + \sum_{|\beta_\nu|\leq\rho}\Omega_f(\beta_\nu)\bigg)\\ &\quad - \sum_{\alpha_\mu\in[x,x+c]}\Omega _f(\alpha_\mu) + \frac{1}{2} \sum_{\alpha_\mu\in\{x,x+c\}}\Omega _f(\alpha_\mu) - \sum_{\beta_\nu\in[x,x+c]}\Omega _f(\beta_\nu) + \frac{1}{2}\sum_{\beta_\nu\in\{x,x+c\}}\Omega _f(\beta_\nu)\\ &\quad - \frac{c}{2\rho}\Omega _f(0) -\frac{1}{2}(A_f(x+c)-A_f(x) + B_f(x+c)-B_f(x)). \end{align*} $$
By taking the proximity function on both sides and by the proof of [Reference Korhonen, Laine and Tohge7, Theorem 3.23],
$$ \begin{align*} &m(r,f(x+c) -f(x)) \leq |c|\bigg(\frac{1}{\rho} (m(\rho,f)+m(\rho,-f)) + n(\rho,f) + n(\rho,-f)\bigg)\\ &\quad + m\bigg(r,- \frac{c}{2\rho}\bigg(\sum_{|\alpha_\mu|\leq\rho}\Omega_f(\alpha_\mu) + \sum_{|\beta_\nu|\leq\rho}\Omega_f(\beta_\nu)\bigg)\bigg)\\ &\quad + m\bigg(r,- \bigg(\sum_{\alpha_\mu\in[x,x+c]}\Omega _f(\alpha_\mu) + \sum_{\beta_\nu\in[x,x+c]}\Omega _f(\beta_\nu)\bigg)\bigg) \\ &\quad + m\bigg(r,\frac{1}{2} \sum_{\alpha_\mu\in\{x,x+c\}}\Omega _f(\alpha_\mu)\bigg) + m\bigg(r,\frac{1}{2}\sum_{\beta_\nu\in\{x,x+c\}}\Omega _f(\beta_\nu)\bigg)\\ &\quad + m\bigg(r,- \frac{c}{2\rho}\Omega _f(0) -\frac{1}{2}(A_f(x+c)-A_f(x) + B_f(x+c)-B_f(x))\bigg). \end{align*} $$
Since the quantity below inside the proximity function is constant with respect to x,
$$ \begin{align*} m\bigg(r,- \frac{c}{2\rho}\bigg(\sum_{|\alpha_\mu|\leq\rho}\Omega_f(\alpha_\mu) + \sum_{|\beta_\nu|\leq\rho}\Omega_f(\beta_\nu)\bigg)\bigg) &= \bigg(- \frac{c}{2\rho}\bigg(\sum_{|\alpha_\mu|\leq\rho}\Omega_f(\alpha_\mu) + \sum_{|\beta_\nu|\leq\rho}\Omega_f(\beta_\nu)\bigg)\bigg)^+\\&\leq \frac{|c|}{2\rho}\bigg|\sum_{|\alpha_\mu|\leq\rho}\Omega_f(\alpha_\mu) + \sum_{|\beta_\nu|\leq\rho}\Omega_f(\beta_\nu)\bigg|\\&\leq \frac{|c|}{2\rho}\bigg(\sum_{|\alpha_\mu|\leq\rho}|\Omega_f(\alpha_\mu)| + \sum_{|\beta_\nu|\leq\rho}|\Omega_f(\beta_\nu)|\bigg)\\& = \frac{|c|}{2\rho}(J(\rho,f) + J(\rho,-f)). \end{align*} $$
By the definition of the proximity function,
$$ \begin{align*} m\bigg(r,&- \bigg(\sum_{\alpha_\mu\in[x,x+c]}\Omega _f(\alpha_\mu) + \sum_{\beta_\nu\in[x,x+c]}\Omega _f(\beta_\nu)\bigg)\bigg)\\ &=\frac{1}{2}\bigg( \sum_{\alpha_\mu\in[r,r+c]}\!\!\Omega _f(\alpha_\mu) + \sum_{\beta_\nu\in[r,r+c]}\!\!\Omega _f(\beta_\nu)\bigg)^+ +\frac{1}{2}\bigg(\!\sum_{\alpha_\mu\in[-r,-r+c]}\!\!\Omega _f(\alpha_\mu) +\!\! \sum_{\beta_\nu\in[-r,-r+c]}\!\!\Omega _f(\beta_\nu)\bigg)^+\\ &\leq \frac{1}{2} \sum_{\alpha_\mu\in[r,r+c]}|\Omega _f(\alpha_\mu)| + \frac{1}{2}\sum_{\beta_\nu\in[r,r+c]}|\Omega _f(\beta_\nu)| \\ &\quad +\frac{1}{2}\sum_{\alpha_\mu\in[-r,-r+c]}|\Omega _f(\alpha_\mu)| + \frac{1}{2}\sum_{\beta_\nu\in[-r,-r+c]}|\Omega _f(\beta_\nu)|\\ &\leq \frac{1}{2} \sum_{\alpha_\mu\in[r-c,r+c]}|\Omega _f(\alpha_\mu)| + \frac{1}{2}\sum_{\beta_\nu\in[r-c,r+c]}|\Omega _f(\beta_\nu)| \\ &\quad +\frac{1}{2}\sum_{\alpha_\mu\in[-r-c,-r+c]}|\Omega _f(\alpha_\mu)| + \frac{1}{2}\sum_{\beta_\nu\in[-r-c,-r+c]}|\Omega _f(\beta_\nu)|\\ &=J(r+c,f)-J(r-c,f) + J(r+c,-f)-J(r-c,-f). \end{align*} $$
The remaining terms are constant almost everywhere, so overall,
$$ \begin{align*} &m(r, f(x+c)-f(x)) \\ & \quad \leq |c|\bigg(\frac{1}{\rho}\bigg(m(\rho,f)+m(\rho,-f) + \frac{1}{2} J(\rho,f) + \frac{1}{2}J(\rho,-f)\bigg) + n(\rho,f) + n(\rho,-f)\bigg) \\ &\qquad+ J(r+c,f)-J(r-c,f) + J(r+c,-f)-J(r-c,-f) + O(1). \end{align*} $$
We may choose
$\rho = \tfrac 12(\alpha + 1)(r+|c|)<\alpha (r+|c|)$
. Now by [Reference Korhonen, Laine and Tohge7, Lemma 3.21],
$$ \begin{align*} n(\rho,f) + n(\rho,-f)\leq \frac{4}{\alpha - 1}\frac{1}{r+|c|}(T(\alpha(r+|c|),f) + T(\alpha(r+|c|),-f)). \end{align*} $$
Since
${1}/{(\alpha + 1)}\leq {2}/{(\alpha - 1)}$
, the Jensen formula implies that
$$ \begin{align*} &m(r,f(x+c)-f(x))\\& \quad \leq |c|\bigg(\frac{2}{(\alpha + 1)(r+|c|)}(T(\alpha(r+|c|),f) + T(\alpha(r+|c|),-f))\bigg)\\&\qquad + |c|\bigg(\frac{4}{\alpha - 1}\frac{1}{r+|c|}(T(\alpha(r+|c|),f) + T(\alpha(r+|c|),-f))\bigg) \\&\qquad + J(r+c,f)-J(r-c,f) + J(r+c,-f)-J(r-c,-f) + O(1)\\& \quad \leq\frac{16|c|}{\alpha - 1}\frac{1}{r+|c|}\bigg(T(\alpha(r+|c|),f) + \frac{|f(0)|}{2}\bigg)\\&\qquad+ J(r+c,f)-J(r-c,f) + J(r+c,-f)-J(r-c,-f) + O(1).\\[-35pt] \end{align*} $$
The following result is a generalisation of [Reference Cherry and Ye2, Theorem 3.3.1]. It replaces the assumption of continuity with piecewise continuity.
Theorem 3.3. Let
$F(r)$
be a positive, nondecreasing and piecewise continuous function defined for
$r_0\leq r <\infty $
, and let
$\phi (r)$
be a positive, nondecreasing, continuous function defined for
$r_0\leq r <\infty $
, and assume that
$F(r)\geq e$
for
$r\geq r_0$
. Let
$\xi (x)$
be a positive, nondecreasing, continuous function defined for
$e\leq x < \infty $
. Let
$C>1$
be a constant and let E be the subset of
$[r_0,\infty )$
defined by
$$ \begin{align*} E=\bigg\{r\in[r_0,\infty):F\bigg(r+\frac{\phi(r)}{\xi(F(r))}\bigg)\geq CF(r)\bigg\}. \end{align*} $$
Then for all
$R<\infty $
,
$$ \begin{align*} \int_{E\cap[r_0,R]}\frac{dr}{\phi(r)}\leq \frac{1}{\xi(e)} + \frac{1}{\log C}\int_e^{F(R+)}\frac{dx}{x\xi(x)}. \end{align*} $$
Proof. Define
$G(r) := F(r+)$
for all
$r\in [r_0,\infty )$
so that
$F(r) = G(r)$
outside the set of discontinuities of F. Define
$$ \begin{align*} \hat{E}=\bigg\{r\in[r_0,\infty):G\bigg(r+\frac{\phi(r)}{\xi(G(r))}\bigg)\geq CG(r)\bigg\}. \end{align*} $$
We can now find the smallest element in
$\hat {E}$
and thus we can prove the theorem for
$G(r)$
and
$\hat {E}$
by following the steps of the proof of [Reference Cherry and Ye2, Theorem 3.3.1]. Then we can conclude that the statement holds also for the function
$F(r)$
, since it differs from
$G(r)$
only at countably many points.
Now we have all the tools to prove Theorem 1.1.
Proof of Theorem 1.1
To apply Theorem 3.3, define
$\phi (r) := r, \xi (x) := (\log x)^{1+\varepsilon }$
and
$$ \begin{align*} \alpha = 1 + \frac{\phi(r + |c|)}{(r + |c|)\xi(T(r + |c|,f))} = 1 + \frac{1}{(\log T(r+|c|,f))^{1+\varepsilon}}. \end{align*} $$
By Theorem 3.2,
$$ \begin{align*} m\bigg(r,{\frac{f(x+c)}{f(x)}\oslash}\bigg) &\leq \frac{16|c|}{r+|c|}\frac{1}{\alpha - 1}\bigg(T(\alpha(r+|c|),f) + \frac{|f(0)|}{2}\bigg) \\ &\quad+ J(r+c,f)-J(r-c,f) + J(r+c,-f)-J(r-c,-f) + O(1)\\ &=\frac{16|c|}{r+|c|}(\log T(r+|c|,f))^{1+\varepsilon}\bigg(T(\alpha(r+|c|),f) + \frac{|f(0)|}{2}\bigg) \\ &\quad+ J(r+c,f)-J(r-c,f) + J(r+c,-f)-J(r-c,-f) + O(1) \end{align*} $$
outside of an exceptional set of finite logarithmic measure. To proceed, fix
$\varepsilon> 0$
so that
$(\rho _2(f) \kern1.3pt{+}\kern1.3pt \varepsilon )(1\kern1.2pt{+}\kern1.2pt\varepsilon )\kern1.3pt{\leq}\kern1.3pt 1\kern1.3pt{-}\kern1.3pt\gamma $
for some
$\gamma \kern1.2pt{<}\kern1.2pt1$
. Then, since
$(\log T(r+|c|,f))^{1+\varepsilon }\kern1.2pt{\leq}\kern1.2pt (r+|c|)^{1-\gamma }$
,
$$ \begin{align*} \frac{(\log T(r+|c|,f))^{1+\varepsilon}}{r+|c|}\leq (r+|c|)^{-\gamma}\to 0 \end{align*} $$
as r approaches to infinity. For the term
$$ \begin{align*} T(\alpha(r+|c|),f) = T\bigg(r+|c|+\frac{r+|c|}{(\log T(r+|c|,f))^{1+\varepsilon}},f\bigg) \end{align*} $$
above, we may apply Theorem 3.3 to conclude that
$$ \begin{align*} T(\alpha(r+|c|),f)\leq CT(r+|c|,f) \end{align*} $$
outside an exceptional set of finite logarithmic measure, and further by Theorem 3.1,
$$ \begin{align*} T(\alpha(r+|c|),f)\leq CT(r,f) \end{align*} $$
and
$$ \begin{align*} J(r+c,f)-J(r-c,f) + J(r+c,-f)-J(r-c,-f) = o(T(r,f)) \end{align*} $$
as r tends to infinity outside an exceptional set of finite logarithmic measure. Therefore, outside an exceptional set of finite logarithmic measure,
$$ \begin{align*} m\bigg(r,{\frac{f(x+c)}{f(x)}\oslash}\bigg)\leq 32 C(r+|c|)^{-\gamma}T(r,f) + o(T(r,f)) = o(T(r,f)).\\[-40pt] \end{align*} $$
Open access
