Abstract Generated abstract
The paper studies entire functions of several complex variables of prescribed finite type that are positive on the real domain and belong to generalized Lebesgue spaces with mixed norms. It derives Nikolskii-type inequalities comparing mixed norms with different exponent vectors, including sharp constants in the positive case and an extremal example for a limiting case. The note also establishes estimates for norms of such entire functions on lines parallel to the real axis, first in one variable and then for several variables, with refined bounds for classes satisfying a symmetry-type modulus condition in the upper and lower half-planes. These results extend and sharpen earlier inequalities for entire functions and related trigonometric-polynomial settings.
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MATHEMATICS
D. I. MAMEDKHANOV
INEQUALITIES FOR POSITIVE ENTIRE FUNCTIONS IN A GENERALIZED LEBESGUE SPACE
(Presented by Academician I. M. Vinogradov, 19 II 1964)
Let \(\mathscr L_{\mathbf p}^{(n)}(E_n)\), where \(\mathbf p=(p_1,\ldots,p_n)\) and \(1\le p_k\le \infty\) \((k=1,2,\ldots,n)\), denote the class of functions \(f(x_1,\ldots,x_n)\), measurable in the \(n\)-dimensional Euclidean space \(E_n\), satisfying the condition
\[ \|f\|_{\mathbf p}^{(n)} = \left\{ \int_{-\infty}^{\infty} \left[ \int_{-\infty}^{\infty} \cdots \left( \int_{-\infty}^{\infty} |f(x_1,\ldots,x_n)|^{p_1}\,dx_1 \right)^{p_2/p_1} dx_2 \cdots \right]^{p_n/p_{n-1}} dx_n \right\}^{1/p_n} <\infty; \tag{1} \]
this class is called the generalized Lebesgue space (see \((^3)\)).
Denote by \(\widetilde W_{\vec\sigma}^{(\mathbf p)}\) \([\mathbf p=(p_1,\ldots,p_n);\ \vec\sigma=(\sigma_1,\ldots,\sigma_n)]\) the class of entire functions \(f(z_1,\ldots,z_n)\) of finite degree \(\vec\sigma\), positive for real values of the arguments, and belonging to the generalized Lebesgue space \(\mathscr L_{\mathbf p}^{(n)}(E_n)\).
In the present note, for functions of the class \(\widetilde W_{\vec\sigma}^{(\mathbf p)}\), sharp inequalities of the type of S. M. Nikolskii’s inequalities are obtained, which generalize and refine certain known results. In addition, a relation is established between different norms of entire functions of the class \(\widetilde W_{\vec\sigma}^{(\mathbf p)}\) on lines parallel to the real axis.
Theorem 1. If \(f(z_1,\ldots,z_n)\in \widetilde W_{\vec\sigma}^{(\mathbf p)}\), then for \(p_1\ge p_2\ge\cdots\ge p_n\) and \(1\le p_k<p'_k\le\infty\) \((k=1,2,\ldots,n)\), for the function *
\[ \psi(x_n) = \left\{ \int_{-\infty}^{\infty} \left[ \int_{-\infty}^{\infty} \cdots \left( \int_{-\infty}^{\infty} |f(x_1,\ldots,x_n)|^{p_1}\,dx_1 \right)^{p_2/p_1} \cdots \right]^{p_{n-1}/p_{n-2}} dx_{n-1} \right\}^{1/p_{n-1}} \]
we have
\[ \|\psi\|_{p'_n} \le \left(\frac{\sigma_n s_n}{2\pi}\right)^{1/p_{n-1}-1/p'_n} \|\psi\|_{p_n}, \tag{2} \]
where \(s_n=\left|[-p_n/2]\right|\) is the least integer not less than \(p_n/2\), and
\[ \|\psi\|_q = \left( \int_{-\infty}^{\infty} |\psi(x_n)|^q\,dx_n \right)^{1/q}. \]
Theorem 2. If \(f(z_1,\ldots,z_n)\in \widetilde W_{\vec\sigma}^{(\mathbf p)}\), then for \(p_1\ge p_2\ge\cdots\ge p_n\) and \(1\le p_k<p'_k\le\infty\) \((k=1,2,\ldots,n)\) we have
\[ \|f\|_{\mathbf p'}^{(n)} \le \prod_{k=1}^{n} \left(\frac{\sigma_k s_k}{2\pi}\right)^{1/p_k-1/p'_k} \|f\|_{\mathbf p}^{(n)}, \tag{3} \]
where \(s_k=\left|[-p_k/2]\right|\) \((k=1,\ldots,n)\) is the least integer not less than \(p_k/2\), and \(\|f\|_{\mathbf p}^{(n)}\) is defined by equality (1).
* One can give an example in which the function \(\psi(x_n)\) is not an analytic function, but \(f(z_1,\ldots,z_n)\) belongs to the class \(\widetilde W_{\vec\sigma}^{(\mathbf p)}\).
We note that inequality (3) is sharp*. In the case \(p'=\infty\) and \(p=1\), equality is attained for the function
\[ f_0(x_1,\ldots,x_n)=\prod_{i=1}^n\left(\frac{\sin \sigma_i x_i/2}{x_i}\right)^2 . \]
Let us note that inequality (3) is a refinement of the corresponding inequality of I. I. Ibragimov \((^3)\) for entire functions from the class \(\widetilde W_{\sigma}^{(p)}\).
Denote by \(B_{\sigma}^{(p)}\) the class of functions from the class \(W_{\sigma}^{(p)}\) satisfying the condition
\[ |f(x+iy)|\leq |f(x-iy)|\qquad (y\geq 0). \tag{4} \]
This class is a generalization of the class of functions that are real on the real axis. For this class of entire functions we give the following theorems**.
Theorem 3. For an entire function \(f(z)\) from the class \(B_{\sigma}^{(p)}\), for any \(1\leq p\leq p'\leq \infty\), the inequality
\[ \|f(x+iy)\|_{p',x}\leq \left(\frac{s\sigma}{\pi}\right)^{1/p-1/p'} \bigl[Q_p(\sigma y)\operatorname{ch}\sigma y\bigr]^{p/p'} \bigl[Q_{p/s}(s\sigma y)\operatorname{ch}s\sigma y\bigr]^{(p'-p)/sp'} \times \]
\[ \times \|f(x)\|_{p,x}, \tag{5} \]
holds, where \(s=[-p/2]\) is the smallest integer not less than \(p/2\), and
\[ Q_r(t)= \frac{\displaystyle\int_0^{2\pi}(1-\sin^2\omega\,\operatorname{sh}^2 t)^{r/2}\,d\omega} {2B(1/2r+1/2,\,1/2)}. \tag{6} \]
Theorem 4. For a positive entire function \(f(z)\) from the class \(B_{\sigma}^{(p)*}\), for any \(1\leq p<p'\leq \infty\), the inequality
\[ \|f(x+iy)\|_{p',x}\leq \left(\frac{s\sigma}{2\pi}\right)^{1/p-1/p'} Q_p(\sigma y)\operatorname{ch}\sigma y\,\|f(x)\|_{p,x}, \tag{7} \]
holds, where \(s\) and \(Q_p\) are the same as in Theorem 3.
Inequality (5) is sharp for periodic (and, consequently, trigonometric-sum) functions, if the norms are taken over \((0,2\pi)\) instead of \((-\infty,\infty)\); in this case equality is attained for the function
\[ f(z)=\cos\sigma z \qquad \text{when } p'=p . \]
For entire functions of several variables \(f(z_1,\ldots,z_n)\) from the classes \(W_{\vec\sigma}^{(\mathbf p)}\) and \(\widetilde W_{\vec\sigma}^{(p)}\) we give the following theorems.
Theorem 5. If \(p'_1,\ldots,p'_n\) are distinct numbers not less than one, \(p_1\geq p_2\geq\cdots\geq p_n\), and \(1\leq p_k\leq p'_k\leq \infty\) \((k=1,2,\ldots,n)\), then for an entire function from the class \(W_{\vec\sigma}^{(\mathbf p)}\) the inequality
\[ \|f(x_1+iy_1,\ldots,x_n+iy_n)\|_{\mathbf p'} \leq \prod_{k=1}^n \left(\frac{s_k\sigma_k}{\pi}\right)^{1/p_k-1/p'_k} \exp\left(\sum_{k=1}^n \sigma_k |y_k|\right) \|f(x_1,\ldots,x_n)\|_{\mathbf p} \tag{8} \]
holds.
* Inequality (3) in the case \(p_1=p_2=\cdots=p_n=p\), \(p'_1=\cdots=p'_n=p'\), and \(n=1\) was obtained in \((^1,^5)\). Later a similar inequality was found by P. Boas \((^2)\) in the two-dimensional case with non-sharp constants in the case \(p_1=p_2=1\) and \(p'_1=p'_2=\infty\). This problem in the class of trigonometric polynomials was solved by N. Sabziev \((^4)\).
** These results were reported at the VII All-Union Conference on the Theory of Functions of a Complex Variable in September 1963 in Rostov-on-Don.
This result is obtained directly from \((^3,\,^5)\).
Theorem 6. Under the hypotheses of Theorem 5, for an entire function of the class \(\widetilde W_{\vec\sigma}^{(\mathbf p)}\) we have
\[ \|f(x_1+iy_1,\ldots,x_n+iy_n)\|_{\mathbf p'} \le \prod_{k=1}^{n}\left(\frac{s_k\sigma_k}{2\pi}\right)^{1/p_k-1/p'_k} \exp\left(\sum_{k=1}^{n}\sigma_k|y_k|\right) \|f(x_1,\ldots,x_n)\|_{\mathbf p}. \tag{9} \]
The collection of all entire functions of several variables \(f(z_1,\ldots,z_n)\) from the class \(W_{\vec\sigma}^{(\mathbf p)}\) satisfying the condition
\[ |f(x_1+iy_1,\ldots,x_n+iy_n)| \le |f(x_1-iy_1,\ldots,x_n-iy_n)| \tag{10} \]
where \(y_1,\ldots,y_n \ge 0\), will be denoted by \(B_{\vec\sigma}^{(\mathbf p)}\), and all positive entire functions from \(B_{\vec\sigma}^{(\mathbf p)}\) by \(\widetilde B_{\vec\sigma}^{(\mathbf p)}\). For these classes of entire functions one can sharpen inequalities (8) and (9).
Theorem 7. Under the hypotheses of Theorem 5, for an entire function of the class \(B_{\vec\sigma}^{(\mathbf p)}\) the inequality
\[ \|f(x_1+iy_1,\ldots,x_n+iy_n)\|_{\mathbf p'} \le \prod_{k=1}^{n} \left(\frac{s_k\sigma_k}{\pi}\right)^{1/p_k-1/p'_k} \left[Q_{p_k}(\sigma_k,y_k)\operatorname{ch}\sigma_ky_k\right]^{p_k/p'_k} \times \]
\[ \times \left[Q_{p_k/s_k}(s_k,\sigma_k,y_k)\operatorname{ch}(s_k\sigma_ky_k)\right]^{(p'_k-p_k)/s_kp'_k} \|f(x_1,\ldots,x_n)\|_{\mathbf p}, \tag{11} \]
where \(s_k\) and \(Q_{p_k}\) are the same as in Theorem 3.
Theorem 8. Under the hypotheses and notation of the preceding theorem, for an entire function of the class \(\widetilde B_{\vec\sigma}^{(\mathbf p)}\) we have
\[ \|f(x_1+iy_1,\ldots,x_n+iy_n)\|_{\mathbf p'} \le \prod_{k=1}^{n} \left(\frac{s_k\sigma_k}{2\pi}\right)^{1/p_k-1/p'_k} \left[Q_{p_k}(\sigma_ky_k)\operatorname{ch}\sigma_ky_k\right]^{p_k/p'_k} \times \]
\[ \times \left[Q_{p_k/s_k}(s_k,\sigma_k,y_k)\operatorname{ch}s_k\sigma_ky_k\right]^{(p'_k-p_k)/p'_ks_k} \|f(x_1,\ldots,x_n)\|_{\mathbf p}. \tag{12} \]
Let us also note that inequalities (5) and (7) remain valid for the functions
\[ \psi(x_n,y_n)= \left\{ \int_{-\infty}^{\infty} \left[ \int_{-\infty}^{\infty} \cdots \left( \int_{-\infty}^{\infty} |f(x_1,\ldots,x_{n-1},z_n)|^{p_1}\,dx_1 \right)^{p_2/p_1} \cdots \right]^{p_{n-1}/p_{n-2}} dx_{n-1} \right\}^{1/p_{n-1}}, \]
if \(f(z_1,\ldots,z_n)\) is taken respectively from \(B_{\vec\sigma}^{(\mathbf p)}\) or \(\widetilde B_{\vec\sigma}^{(\mathbf p)}\).
Received
17 II 1964
CITED LITERATURE
\(^1\) I. I. Ibragimov, Extremal Properties of Entire Functions, Baku, 1962.
\(^2\) R. Boas, Proc. Am. Math. Soc., 13, No. 4 (1962).
\(^3\) I. I. Ibragimov, DAN, 152, No. 5 (1963).
\(^4\) N. Sabziev, Abstracts of Reports, All-Union Conference on the Constructive Theory of Functions, Baku, 1962.
\(^5\) I. I. Ibragimov, A. S. Jafarov, Izv. AN AzerbSSR, series of physical and mathematical sciences, No. 5 (1962).