Abstract Generated abstract
The paper studies a boundary value problem for a generalized Laplace equation in Wiener function space, involving the Lévy Laplacian of a functional and a potential term. For domains defined by a smooth functional with constant positive Lévy Laplacian, it constructs solution functionals using Fourier-Hermite expansions and multiple Wiener integrals, first for finite-degree data and potentials. A maximum principle and uniqueness result are established under the condition that the potential is nonpositive. The results give existence and uniqueness formulas for prescribed boundary values, including an extension to data in L2 of Wiener space, and recover the earlier solution of the functional Laplace equation when the potential is identically zero.
Full Text
UDC 517.948
MATHEMATICS
M. N. FELLER
ON THE EQUATION \(\Delta U[x(t)] + P[x(t)]U[x(t)] = 0\) IN FUNCTION SPACE
(Presented by Academician A. Yu. Ishlinskii on 16 IV 1966)
The Laplacian of a functional \(\Delta U[x(t)]\)—the continual analogue of the Laplace operator of a function of a finite number of variables—was defined by P. Lévy \((^{1})\). Laplace and Poisson equations with such Laplacians were studied by P. Lévy, E. M. Polishchuk \((^{2})\), and the author \((^{3,4})\). In this note we consider the boundary-value problem of the “generalized Laplace equation”
\[ \Delta U[x(t)] + P[x(t)]U[x(t)] = 0 \tag{1} \]
for a domain \(\Omega \cup \Gamma\) in the space \(C\), defined by the inequality \(S[x(t)] \leqslant 1\) \((x(t) \in \Omega\), if \(S[x(t)] < 1\); \(x(t) \in \Gamma\), if \(S[x(t)] = 1)\); \(S[x(t)]\) is a twice functionally differentiable functional such that its first and second variations have normal form, and \(\Delta S[x(t)]\) is a constant positive nonzero number; \(C\) is the space of functions \(x(t)\) continuous on \([0,1]\) \((x(0)=0)\), with Wiener measure \((^{5})\).
- Let \(P[x(t)]\) be a functional of finite degree \((^{6})\); \(P_N[x(t)]\) the partial sum of its expansion in the Fourier–Hermite functionals \((^{7})\); \(B_{m_1\ldots m_N}\) its Fourier–Hermite coefficients;
\[ \Psi_{m_1\ldots m_N}[x(t)] = \prod_{i=1}^{N} H_{m_i}\left[\int_{0}^{1}\chi_i(t)\,dx(t)\right] \]
are the Fourier–Hermite functionals \((m_i=0,1,2,\ldots;\ N=1,2,\ldots)\); \(H_m(u)\) are partially normalized Hermite polynomials \((m=0,1,2,\ldots)\); \(\chi_1(t)\equiv \chi_0^{(0)}(t)\), \(\chi_i(t)\equiv \chi_n^{(k)}(t)\) for \(i=2^n+k\) \((n=0,1,2,\ldots;\ k=1,2,\ldots,2^n)\), \(\chi_0^{(0)}(t)\), \(\{\chi_n^{(k)}(t)\}\) are the Haar system of functions. Let
\[ \Psi^{*}_{m_1\ldots m_N}[x(t),y_1(\tau),\ldots,y_N(\tau)] = \]
\[ = \prod_{i=1}^{N} H_{m_i} \left[ \int_{0}^{1}\chi_i(t)\,dx(t) +2(1-S[x])^{1/2}(\Delta S[x])^{-1/2}\,\widetilde y_i(\tau) \right], \]
\[ \widetilde y_1(\tau)\equiv y_1(\tau),\quad \widetilde y_i(\tau)\equiv \widetilde y_n^{(k)}(\tau),\quad \widetilde y_n^{(k)}(\tau) = \sqrt{2^n}\left(2z_{(2k-1)/2^{n+1}}(\tau)-z_{(2k-2)/2^{n+1}}(\tau)-z_{2k/2^{n+1}}(\tau)\right), \]
\[ z_0(\tau)=0,\qquad z_{p_q}(\tau)=y_q(\tau),\qquad (p_q=1,\;1/2,\;1/4,\;3/4,\ldots;\ q=1,2,\ldots,N). \]
Lemma 1. The functional
\[ \Phi_{m_1\ldots m_N,N}[x(t)] = \int_{C_N} \Psi^{*}_{m_1\ldots m_N} [x(t),y_1(1),\ldots,y_N(1)] \times \]
\[ \times \exp\left\{ \frac{1-S[x]}{\Delta S[x]} \int_{0}^{1} \sum_{\mu_1,\ldots,\mu_N=0}^{N} B_{\mu_1\ldots\mu_N} \Psi^{*}_{\mu_1\ldots\mu_N} [x(t),y_1(s),\ldots,y_N(s)]\,ds \right\} \,dw_{y_1}\cdots dw_{y_N}, \]
where the integral is understood as an \(N\)-fold Wiener integral on the product space \(C\), satisfies in \(\Omega\) the equation
\[ \Delta U[x]+P_N[x]U[x]=0. \]
Indeed, having found the second variation and then computed the Laplacian of the functional \(\Phi_{m_1\ldots m_N,N}[x]\), we obtain
\[ \begin{aligned} \Delta \Phi_{(m),N}[x] = \int_{C^N} \Bigg\{& \sum_{i=1}^{N}\left[2^{n_i+1}\sqrt{m_i(m_i-1)}\,a_i\Psi^*_{(m)-2_i}(1)\right.\\ &\left.-(1-S)^{-1/2}(\Delta S)^{1/2}\sqrt{2m_i}\,\widetilde y_i(1)\Psi^*_{(m)-1_i}(1)\right.\\ &\left.+\sum_{\substack{l=1\\ l\ne i}}^{N}\sqrt{2^{n_i+n_l+2}m_i m_l}\,a_{il}\Psi^*_{(m)-1_i-1_l}(1)\right]\\ &+2(1-S)(\Delta S)^{-1}\sqrt{2^{n_i+1}m_i}\,b_i\Psi^*_{(m)-1_i}(1)\\ &\qquad\times\left[\int_0^1\sum_{(\mu)=0}^{N}B_{(\mu)}\sum_{l=1}^{N}\sqrt{2^{n_l+1}\mu_l}\,b_l\Psi^*_{(\mu)-1_l}(s)\,ds\right] -\Psi^*_{(m)}(1)\int_0^1\sum_{(\mu)=0}^{N}B_{(\mu)}\Psi^*_{(\mu)}(s)\,ds\\ &+(1-S)(\Delta S)^{-1}\Psi^*_{(m)}(1) \int_0^1\sum_{(\mu)=0}^{N}B_{(\mu)}\sum_{i=1}^{N} \left[2^{n_i+1}\sqrt{\mu_i(\mu_i-1)}\,a_i\Psi^*_{(\mu)-2_i}(s)\right.\\ &\left.\qquad\qquad\qquad\qquad -(1-S)^{-1/2}(\Delta S)^{1/2}\sqrt{2\mu_i}\,\widetilde y_i(s)\Psi^*_{(\mu)-1_i}(s)\right.\\ &\left.\qquad\qquad\qquad\qquad +\sum_{\substack{l=1\\ l\ne i}}^{N}\sqrt{2^{n_i+n_l+2}\mu_i\mu_l}\,a_{il}\Psi^*_{(\mu)-1_i-1_l}(s)\right]ds\\ &+(1-S)^2(\Delta S)^{-2}\Psi^*_{(m)}(1) \left[\int_0^1\sum_{(\mu)=0}^{N}B_{(\mu)} \sum_{i=1}^{N}\sqrt{2^{n_i+1}\mu_i}\,B_i\Psi^*_{(\mu)-1_i}(s)\,ds\right]^2 \Bigg\}E_N\,dw y_1\ldots dw y_N, \end{aligned} \tag{2} \]
where
\[
\Psi^*_{m_1\ldots m_N}(\tau)=\Psi^*_{m_1\ldots m_N}[x(t),y_1(\tau),\ldots,y_N(\tau)],\qquad
(m)=(m_1,\ldots,m_N),
\]
\[
(m)-q_i=(m_1,\ldots,m_{i-1},m_i-q,m_{i+1},\ldots,m_N),
\]
and \(a_i,a_{il},b_i\) are the sums of the coefficients at the corresponding \([\delta x]^2\),
\[ E_N=\exp\left\{\frac{1-S}{\Delta S}\int_0^1\sum_{(\mu)=0}^{N}B_{(\mu)}\Psi^*_{(\mu)}(s)\,ds\right\}. \]
Computing, by P. Cameron’s theorem \((8)\), the Wiener integral of the first partial variation with respect to \(y_i\) of the functional
\[
(i-S)^{-1/2}(\Delta S)^{1/2}\sqrt{2m_i}\Psi^*_{(m)-1_i}(1)E_N,
\]
we have
\[ \begin{aligned} &(i-S)^{-1/2}(\Delta S)^{1/2} \int_{C^N}\sum_{i=1}^{N}\sqrt{2m_i}\,\widetilde y_i(1)\Psi^*_{(m)-1_i}(1)E_N\,dw y_1\ldots dw y_N\\ &=\int_{C^N}\sum_{i=1}^{N}\Bigg\{ 2^{n_i+1}\sqrt{m_i(m_i-1)}\,a_i\Psi^*_{(m)-2_i}(1) +\sum_{\substack{l=1\\ l\ne i}}^{N}\sqrt{2^{n_i+n_l+2}m_i m_l}\,a_{il}\Psi^*_{(m)-1_i-1_l}(1)\\ &\qquad +(1-S)(\Delta S)^{-1}\sqrt{2^{n_i+1}m_i}\,b_i\Psi^*_{(m)-1_i}(1) \int_0^1 s\sum_{(\mu)=0}^{N}B_{(\mu)} \sum_{l=1}^{N}\sqrt{2^{n_l+1}\mu_l}\,b_l\Psi^*_{(\mu)-1_l}(s)\,ds \Bigg\}\\ &\qquad\times E_N\,dw y_1\ldots dw y_N, \end{aligned} \tag{3} \]
and by M. Ouchard’s theorem \((9,10)\)—for the partial variational derivative of the functional
\[
(1-S)^{1/2}(\Delta S)^{-1/2}\Psi^*_{(m)}(1)\sqrt{2\mu_i}\Psi^*_{(\mu)-1_i}(s)E_N
\]
with respect to \(y_i\)—we obtain
\[ \begin{aligned} &(1-S)^{1/2}(\Delta S)^{-1/2} \int_{C^N}\Psi^*_{(m)}(1) \left[\int_0^1\sum_{(\mu)=0}^{N}B_{(\mu)} \sum_{i=1}^{N}\sqrt{2\mu_i}\,\widetilde y_i(s)\Psi^*_{(\mu)-1_i}(s)\,ds\right]E_N\,dw y_1\ldots dw y_N\\ &=\int_{C^N}\Bigg\{ -2(1-S)^2(\Delta S)^{-2}\Psi^*_{(m)}(1) \int_0^s\sum_{(\mu)=0}^{N}B_{(\mu)} \sum_{i=1}^{N}\sqrt{2^{n_i+1}\mu_i}\,b_i\Psi^*_{(\mu)-1_i}(s)\\ &\qquad\times \int_1^s\sum_{(\mu)=0}^{N}B_{(\mu)} \sum_{l=1}^{N}\sqrt{2^{n_l+1}\mu_l}\,b_l\Psi^*_{(\mu)-1_l}(v)\,dv\,ds + \end{aligned} \]
\[ \begin{aligned} &+(1-S)(\Delta S)^{-1}\Psi^*_{(m)}(1)\left\{\int_0^1 s\sum_{(\mu)=0}^N B_{(\mu)}\sum_{i=1}^N \left[2^{n_i+1}\sqrt{\mu_i(\mu_i-1)}\,a_i\Psi^*_{(\mu)-2_i}(s)+\right.\right.\\ &\left.\left.+\sum_{\substack{l=1\\ l\ne i}}^N \sqrt{2^{n_i+n_l+2}\mu_i\mu_l}\,a_{il}\Psi^*_{(\mu)-1_i-1_l}(s)\right]\,ds\right\}\\ &+(1-S)(\Delta S)^{-1}\sum_{i=1}^N \sqrt{2^{n_i+1}}\,m_i b_i\Psi^*_{(m)-1_i}(1)\times\\ &\times\left\{\int_0^1 s\sum_{(\mu)=0}^N B_{(\mu)}\sum_{l=1}^N \sqrt{2^{n_l+1}}\mu_l b_l\Psi^*_{(\mu)-1_l}(s)\,ds\right\}E_N^2\,dwy_1\ldots dwy_N . \end{aligned} \tag{4} \]
Extending lemma \((10)\) to the \(N\)-dimensional case and using E. Ouchar’s theorem, it is not difficult to obtain the relation
\[ \begin{aligned} &\int_{C^N}\Psi^*_{(m)}(1)\int_0^1 \sum_{(\mu)=0}^N B_{(\mu)}\Psi^*_{(\mu)}(s)\,ds\,E_N\,dwy_1\ldots dwy_N = P_N[x]\Phi_{(m),N}[x]-\\ &-\int_{C^N}\left\{2(1-S)^2(\Delta S)^{-2}\Psi^*_{(m)}(1)\int_0^1(1-s)\sum_{(\mu)=0}^N B_{(\mu)}\sum_{i=1}^N \sqrt{2^{n_i+1}}\mu_i b_i\Psi^*_{(\mu)-1_i}(s)\times\right.\\ &\left.\times\int_1^s \sum_{(\mu)=0}^N B_{(\mu)}\sum_{l=1}^N \sqrt{2^{n_l+1}}\mu_l b_l\Psi^*_{(\mu)-1_l}(v)\,dv\,ds-\right.\\ &\left.-(1-S)(\Delta S)^{-1}\Psi^*_{(m)}(1)\int_0^1(1-s)\sum_{(\mu)=0}^N B_{(\mu)}\sum_{i=1}^N \left[2^{n_i+1}\sqrt{\mu_i(\mu_i-1)}\,a_i\Psi^*_{(\mu)-2_i}(s)+\right.\right.\\ &\left.\left.+\sum_{\substack{l=1\\ l\ne i}}^N \sqrt{2^{n_i+n_l+2}\mu_i\mu_l}\,a_{il}\Psi^*_{(\mu)-1_i-1_l}(s)\right]\,ds-\right.\\ &\left.-2(1-S)(\Delta S)^{-1}\sum_{i=1}^N \sqrt{2^{n_i+1}}\,m_i b_i\Psi^*_{(m)-1_i}(1)\times\right.\\ &\left.\times\int_0^1(1-s)\sum_{(\mu)=0}^N B_{(\mu)}\sum_{l=1}^N \sqrt{2^{n_l+1}}\mu_l b_l\Psi^*_{(\mu)-1_l}(s)\,ds\right\} E_N\,dwy_1\ldots dwy_N . \end{aligned} \tag{5} \]
Substituting now (3), (4), and (5) into (2), we obtain that \(\Phi_{(m),N}[x]= -P_N(x)\Phi_{(m),N}[x]\) in the domain \(\Omega\).
From Lemma 2 and Corollary 1 \((^3)\) it follows that
Lemma 2. If \(P[x(t)]<0\), \(\Omega_h\cup\Gamma_h\) is the closure of the set of functions
\[ x_h(t)=\frac{1}{2h}\int_{t-h}^{t+h} x(s)\,ds,\qquad x(t)\in\Omega\cup\Gamma,\qquad x(t)=0\quad \text{outside }[0,1], \]
then a functional \(V[x(t)]\), satisfying equation (1) in \(\Omega_h\) and continuous in \(\Omega_h\cup\Gamma_h\) for any \(h>0\), cannot attain a positive maximum and a negative minimum in \(\Omega_h\).
Corollary. If \(P[x(t)]\leq 0\), and the functionals \(V_1[x(t)]\) and \(V_2[x(t)]\) satisfy equation (1) in \(\Omega\) and \(\Omega_h\), are continuous in \(\Omega\cup\Gamma\) and \(\Omega_h\cup\Gamma_h\), and \(V_1|_{\Gamma}=V_2|_{\Gamma}=H[x]\), then \(V_1\equiv V_2\) in \(\Omega\).
2. Theorem 1. Suppose a finite-degree functional \(G[x(t)]\) is given; \(A_{m_1\ldots m_N}\) are its Fourier–Hermite coefficients; \(P[x(t)]\) is a finite-degree functional, \(P[x(t)]\leq 0\). Then in the domain \(\Omega\) there exists a unique solution of equation (1), coinciding with the given functional \(G[x(t)]\) on the surface \(\Gamma\), which is equal to
\[ U[x(t)]=\lim_{N\to\infty}\sum_{m_1,\ldots,m_N=0}^{N} A_{m_1\ldots m_N}\Phi_{m_1\ldots m_N,N}[x(t)] \tag{6} \]
for almost all \(x(t)\in\Omega\cup\Gamma\).
Let us now consider the solution of equation (1) in the space \(L_2(C)\).
Theorem 2. Let a functional \(G[x(t)] \in L_2(C)\) be given; let \(A_{m_1\ldots m_N}\) be its Fourier–Hermite coefficients; let \(P[x(t)]\) be a functional of finite degree, bounded below almost everywhere, \(P[x(t)] \leqslant 0\). Then in the domain \(\Omega\) there exists a unique solution \(U[x(t)] \in L_2(C)\)
\[ U[x(t)] = \underset{N\to\infty}{\mathrm{L.I.M.}}\, \sum_{m_1,\ldots,m_N=0}^{N} A_{m_1\ldots m_N}\, \Phi_{m_1\ldots m_N,N}[x(t)] \tag{7} \]
of equation (1), equal to the prescribed functional \(G[x(t)]\) on the surface \(\Gamma\).
The proof of the theorems follows from the properties of the functionals \(G[x(t)]\), \(P[x(t)]\), Lemma 1, and the corollary.
We note that, putting \(P[x(t)] \equiv 0\) in (6) and (7), we obtain the solution of the boundary-value problem for the “Laplace equation.” It coincides with the solution given in the author’s paper \((^3)\), if one computes the multiple Wiener integral of the functional concentrated at a point and then uses the Paley–Wiener formula \((^{11})\).
In conclusion I express my sincere gratitude to Yu. L. Daletskii for his great attention to the present work.
Ukrainian Scientific-Research Institute
of Mechanical Wood Processing
Received
8 IV 1966
CITED LITERATURE
\(^{1}\) P. Levy, Problèmes concrets d’analyse fonctionnelle, Paris, 1951.
\(^{2}\) E. M. Polishchuk, UMN, 19, no. 2 (116), 155 (1964).
\(^{3}\) M. N. Feller, Dop. AN URSR, 12, 1558 (1965).
\(^{4}\) M. N. Feller, Dop. AN URSR, 4, 426 (1966).
\(^{5}\) N. Wiener, Acta Math., 55, 117 (1930).
\(^{6}\) R. E. Graves, Proc. Am. Math. Soc., 4, 1, 95 (1953).
\(^{7}\) R. H. Cameron, W. T. Martin, Ann. Math., 48, 2, 385 (1947).
\(^{8}\) R. H. Cameron, Proc. Am. Math. Soc., 2, 6, 944 (1951).
\(^{9}\) M. Ovchar, Proc. Am. Math. Soc., 3, 3, 459 (1952).
\(^{10}\) R. H. Cameron, Ann. Math., 59, 3, 434 (1954).
\(^{11}\) H. Wiener, R. Paley, The Fourier Transform in the Complex Domain, Moscow, 1964.