1 Introduction
In [Reference Handelman1], Handelman investigated eventual positivity of power series and deduced its existence for a wide variety of functions by appealing to a particular maximal function. If
$h:(0,\infty )\rightarrow (0,\infty )$
is continuous, then he defined the maximal function
$$\begin{align*}H_h(a)=\max_{b\geq a}\frac{h(b)}{h(a+b)}. \end{align*}$$
Note that H takes values in
$[0,\infty ]$
. This maximal function was introduced in [Reference Handelman1], where some of its properties are discussed. In particular, it is meaningful to have an understanding of when
$hH_h$
is integrable on
$(0,\infty )$
. It is easy to see that if h is log convex, then
$H_h(x)=h(x)/h(2x)$
. This led Handelman to ask the following question (see [Reference Handelman1, p. 338]):
Question 1.1 If
$h:(0,\infty )\rightarrow (0,\infty )$
is a log convex function that is integrable on
$(0,\infty )$
and satisfies
$\limsup _{n\rightarrow \infty }h(n)^{1/n}=1$
, then is it true that
$h(x)^2/h(2x)$
is also integrable on
$(0,\infty )$
?
One of our main results is a demonstration that the answer to Question 1.1 is “no.” In fact, we will prove the following result:
Theorem 1.2 There is a function
$h:(0,\infty )\rightarrow (0,\infty )$
that is log convex, integrable on
$(0,\infty )$
, satisfies
$\lim _{n\rightarrow \infty }h(n)^{1/n}=1$
, and is such that
$h^{r}(x)/h(rx)$
is not integrable on
$(0,\infty )$
for any
$r>0$
.
Our proof of Theorem 1.2 is constructive in that we will show how to actually create a counterexample.
Also in [Reference Handelman1], Handelman made the following conjecture (see the discussion following [Reference Handelman1, Theorem 9]):
Conjecture 1.3 Suppose
$h:(0,\infty )\rightarrow (0,\infty )$
is a log convex function that satisfies
$$ \begin{align} \lim_{n\rightarrow\infty}\frac{h(n)}{h(n+1)}=1 \end{align} $$
and
$h^2(x)/h(2x)$
is integrable on
$(0,\infty )$
. Then h is also integrable on
$(0,\infty )$
.
Our second main result is the following:
Theorem 1.4 Conjecture 1.3 is true.
Remark We should point out that the hypothesis (1.1) is essential to proving Theorem 1.4, for otherwise, one could take
$h(x)=x^x$
as a counterexample. We also remind the reader of an observation made by Handelman in [Reference Handelman1, p. 338], which is that the condition (1.1) for a log convex function h is equivalent to the condition that the series
$\sum h(j)t^j$
has radius of convergence exactly
$1$
.
In addition to Question 1.1 and Conjecture 1.3, Handelman also asked: if a function h is log convex and integrable on
$(0,\infty )$
, then is
$h^2(x)/h(2x)$
also integrable on
$(0,\infty )$
(see [Reference Handelman1, p. 331])? We believe this question is still open.
The remainder of the paper is devoted to the proofs of Theorems 1.2 and 1.4. Our methods are elementary and require only basic facts about convex functions (see [Reference Simon2] for a discussion of many tools in convexity theory).
2 Proofs
The purpose of this section is to prove all of the results discussed in the Introduction section.
2.1 The construction
In this section, we will resolve Question 1.1. Let us write
$h(x)=\exp (f(x)),$
where
$f(x)$
is convex. Since
$h\in L^1(\mathbb {R}^+)$
, it must be that
$\lim _{x\rightarrow \infty }f(x)=-\infty $
. The remaining condition on h implies
$\lim _{n\rightarrow \infty }f(n)/n=0$
, or equivalently (by the convexity of f)
$\lim _{x\rightarrow \infty }f'(x)=0$
provided
$f'(x)$
exists. In fact, the function f we construct will be piecewise linear and hence
$f'(x)$
will be undefined on a discrete set. We will choose sequences
$\{a_n\}_{n=0}^{\infty }$
,
$\{m_n\}_{n=0}^{\infty }$
, and
$\{b_n\}_{n=0}^{\infty }$
so that
$$ \begin{align} f(x)=m_nx+b_n,\qquad x\in[a_n,a_{n+1}], \end{align} $$
and f is continuous.
To begin our construction, let
$\{m_n\}_{n=0}^{\infty }$
be a fixed sequence of negative real numbers that monotonically increases to
$0$
. With this fixed sequence in hand, we will construct the sequence
$\{a_n\}_{n=0}^{\infty }$
inductively, and the sequence
$\{b_n\}_{n=0}^{\infty }$
will then be defined implicitly in order to make f continuous.
We begin our construction of the sequence
$\{a_n\}_{n\geq 0}$
by defining
$a_0=0$
and we also define
$b_0=0$
. Now, choose
$a_1$
large enough so that
-
•
$$\begin{align*}-\frac{e^{m_0a_1}}{m_1}<\frac{1}{2} \end{align*}$$
-
•
$$\begin{align*}a_1>1=a_0+e^{-b_0}. \end{align*}$$
Now, set
$b_1=m_0a_1-m_1a_1$
and observe that
$m_1a_1+b_1=m_0a_1$
.
Now, let us assume that
$\{a_j\}_{j=0}^n$
and
$\{b_j\}_{j=0}^n$
have already been defined. We will now show how one can choose
$a_{n+1}$
and then
$b_{n+1}$
to complete the construction. Indeed, as above, we will choose
$a_{n+1}$
large enough so that
$$ \begin{align*} -\frac{e^{m_na_{n+1}+b_n}}{m_{n+1}}<\frac{1}{2^{n+1}}, \end{align*} $$
$$ \begin{align*} a_{n+1}>\max\left\{a_n+e^{(1-t)b_n}:t\in[0,n]\right\}. \end{align*} $$
Then define
$$\begin{align*}b_{n+1}=m_na_{n+1}+b_n-m_{n+1}a_{n+1} \end{align*}$$
and observe that
$$ \begin{align} m_{n+1}a_{n+1}+b_{n+1}=m_na_{n+1}+b_n. \end{align} $$
Proceeding inductively, we arrive at two sequences
$\{a_n\}_{n=0}^{\infty }$
and
$\{b_n\}_{n=0}^{\infty }$
. It is clear from our construction that
$a_{n+1}>a_n+1$
(since
$1\in [0,n]$
) and so each
$a_n$
is positive (except
$a_0$
) and
$\lim _{n\rightarrow \infty }a_n=\infty $
. Therefore, this procedure defines f on all of
$(0,\infty )$
if we define f by (2.1). Notice also that
$a_{n}>0$
and
$m_n>m_{n-1}$
inductively implies that each
$b_n<0$
when
$n>0$
.
Now, let us check that this function has the desired properties. First of all, since
$m_n\rightarrow 0$
monotonically, it is clear that
$f(n)/n\rightarrow 0$
and also that f is convex. Now we calculate
$$ \begin{align*} \int_0^{\infty}h(x)dx&=\int_0^{\infty}e^{f(x)}dx=\sum_{n=0}^{\infty}\int_{a_n}^{a_{n+1}}e^{m_nx+b_n}dx\\ &\leq\sum_{n=0}^{\infty}\int_{a_n}^{\infty}e^{m_nx+b_n}dx\\ &=\sum_{n=0}^{\infty}-\frac{e^{m_na_n+b_n}}{m_n}\\ &=-\frac{1}{m_0}+\sum_{n=1}^{\infty}-\frac{e^{m_{n-1}a_n+b_{n-1}}}{m_n}\qquad\qquad\mbox{(we use}\ (2.2)\ \mbox{here)} \\&<-\frac{1}{m_0}+\sum_{n=1}^{\infty}2^{-n}, \end{align*} $$
which is clearly finite. Therefore,
$h\in L^1(\mathbb {R}^+)$
as desired.
Finally, fix
$r\in (0,\infty )$
and choose
$N\in \mathbb {N}$
so that
$r<N$
. Notice that
$$\begin{align*}\frac{h^r(x)}{h(rx)}=e^{(r-1)b_n},\qquad x\in[a_n,a_{n+1}]. \end{align*}$$
Therefore,
$$ \begin{align*} \int_0^{\infty}\frac{h^r(x)}{h(rx)}dx&=\sum_{n=0}^{\infty}e^{(r-1)b_n}(a_{n+1}-a_n)>\sum_{n=N}^{\infty}e^{(r-1)b_n}(a_{n+1}-a_n)>\sum_{n=N}^{\infty}1, \end{align*} $$
by construction, so
$\frac {h^r(x)}{h(rx)}\not \in L^1(\mathbb {R}^+)$
. This completely answers Question 1.1.
2.2 The conjecture
In this section, we will prove Theorem 1.4. The log convexity of h implies that h is either monotone increasing on
$(A,\infty )$
for some
$A\geq 0$
or monotone decreasing on
$(0,\infty )$
. In the latter case, we have
$h(x)\geq h(2x)$
and so
$$\begin{align*}\int_0^{\infty}h(x)dx\leq\int_0^{\infty}\frac{h^2(x)}{h(2x)}dx<\infty, \end{align*}$$
so h is integrable.
If h is monotone increasing on
$(A,\infty )$
, then
$\log (h(x))$
is also increasing on
$(A,\infty )$
. Note that the convexity implies that we can choose A so that
$\log (h(x))$
is strictly monotone increasing on
$(A,\infty )$
, for otherwise h would be constant on some interval
$[B,\infty )$
. This would contradict the assumption that
$h^2(x)/h(2x)$
is integrable on
$(0,\infty )$
. Since
$\log (h(x))$
is convex, it must be that there is some constant
$c>0$
so that
$$ \begin{align*} \log(h(n+1))-\log(h(n))\geq c,\qquad n>A. \end{align*} $$
This implies
$h(n+1)/h(n)\geq e^c$
, which means h cannot satisfy (1.1). Therefore, this case cannot occur, and we have proven Theorem 1.4.
