Abstract Generated abstract
This paper studies stability criteria for bases in separable Banach spaces and Hilbert spaces under perturbations weaker than classical norm summability conditions. It first proves equivalent characterizations of unconditional convergence, including regular convergence uniform over the dual unit ball, and uses this to strengthen the Krein, Rutman, and Milman stability theorem: an omega-linearly independent system obtained from a normalized basis by an unconditionally convergent perturbation is an equivalent basis. The paper then develops analogous results for Bessel bases and weak quadratic closeness, showing stability under uniformly square-summable dual perturbations and deriving corresponding properties of biorthogonal systems. In Hilbert spaces, it characterizes compact operators through weak quadratic convergence, introduces weakly quadratically close bases to orthonormal bases, and gives internal criteria for such bases in terms of biorthogonal systems and weak quadratability of Gram matrix perturbations.
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B. E. VEITS
ON SOME STABILITY PROPERTIES OF BASES
(Presented by Academician V. I. Smirnov on 2 IV 1964)
Let \(E\) be a separable Banach space over the field of complex numbers. By the method of Shauder \((^{1})\), the unit ball \(S^*\) \((\|f\|\leqslant 1)\) of the space \(E^*\) can be turned into a metric compactum in which convergence of a sequence with respect to the metric is equivalent to its weak convergence.
We shall call the series \(\sum_{k=1}^{\infty} y_k\) regularly convergent if the series \(\sum_{k=1}^{\infty} |f(y_k)|\) converges uniformly with respect to \(f\in S^*\) (such series were called strongly unconditionally convergent by I. M. Gel'fand \((^{2})\)).
Lemma. The following four assertions are equivalent:
a) the series \(\sum_{k=1}^{\infty} y_k\) converges unconditionally;
b) the series \(\sum_{k=1}^{\infty} a_k y_k\) converges uniformly with respect to the choice of real numbers \(a_k\), \(a_k=\pm 1\), \(k=1,2,\ldots\);
c) the series \(\sum_{k=1}^{\infty} y_k\) converges regularly;
d) the series \(\sum_{k=1}^{\infty} \varepsilon_k y_k\) converges uniformly with respect to the choice of complex numbers \(\varepsilon_k\), \(|\varepsilon_k|\leqslant 1\), \(k=1,2,\ldots\).
Proof. The implication a) \(\Rightarrow\) b) follows from Kadec’s lemma \((^{3})\).
b) \(\Rightarrow\) c). Let \(f\in S^*\). Then for any \(x\in E\),
\(f(x)=f_1(x)+i f_2(x)\), where the functionals \(f_1\) and \(f_2\) are real, linear, and \(\|f_1\|\leqslant \|f\|\leqslant 1\), \(\|f_2\|\leqslant \|f\|\leqslant 1\).
Let \(|f_1(y_k)|=a_k f_1(y_k)\), \(|f_2(y_k)|=b_k f_2(y_k)\); \(a_k=\pm 1\), \(b_k=\pm 1\). Then for \(\varepsilon>0\), when \(n>m\geqslant N_\varepsilon\),
\[ \left\|\sum_{k=m}^{n} a_k y_k\right\|<\frac{\varepsilon}{2},\qquad \left\|\sum_{k=m}^{n} b_k y_k\right\|<\frac{\varepsilon}{2}, \]
\[ \sum_{k=m}^{n} |f(y_k)|\leqslant \sum_{k=m}^{n} |f_1(y_k)|+\sum_{k=m}^{n} |f_2(y_k)| = f_1\left(\sum_{k=m}^{n} a_k y_k\right)+ f_2\left(\sum_{k=m}^{n} b_k y_k\right)<\varepsilon. \]
c) \(\Rightarrow\) d). Let \(\varepsilon_k\), \(|\varepsilon_k|\leqslant 1\), be complex numbers. For natural \(n>m\geqslant N_\varepsilon\) there exists \(f_{mn}\in S^*\) such that
\[ \left\|\sum_{k=m}^{n} \varepsilon_k y_k\right\| = f_{mn}\left(\sum_{k=m}^{n} \varepsilon_k y_k\right) = \sum_{k=m}^{n} \varepsilon_k f_{mn}(y_k) \leqslant \sum_{k=m}^{n} |f_{mn}(y_k)|<\varepsilon \]
d) \(\Rightarrow\) a). If \((n_k)\) is an arbitrary increasing sequence of natural numbers, then, choosing \(\varepsilon_{n_k}=1\) and \(\varepsilon_n=0\) for \(n\ne n_k\), we obtain the convergence of the series
\[
\sum_{k=1}^{\infty} y_{n_k}=\sum_{n=1}^{\infty}\varepsilon_n y_n,
\]
and this, by Orlicz’s theorem \((^4)\), also means a).
A system \((u_k)\) is called \(\omega\)-linearly independent if from the convergence of the series
\[
\sum_{k=1}^{\infty} c_k u_k=\theta
\]
there follow the equalities \(c_k=0,\quad k=1,2,\ldots\)
In the papers \((^5,^6)\) (see also \((^7)\)) the following criterion for the stability of bases was established:
Theorem of M. G. Krein, M. A. Rutman, and D. P. Milman. If \((x_k)\) is a normalized basis of the space \(E\), \((f_k)\) is the system of functionals biorthogonal to \((x_k)\), and an \(\omega\)-linearly independent system \((u_k)\) satisfies the condition
\[
\sum_{k=1}^{\infty}\|u_k-x_k\|\cdot\|f_k\|<+\infty,
\tag{1}
\]
then the system \((u_k)\) is also a basis of the space \(E\), equivalent to the basis \((x_k)\).
We shall prove a stronger criterion for the stability of bases.
Theorem 1. If \((x_k)\) is a normalized basis of the space \(E\), and an \(\omega\)-linearly independent system \((u_k)\) satisfies the condition: the series
\[
\sum_{k=1}^{\infty}(u_k-x_k)
\tag{2}
\]
converges unconditionally, then the system \((u_k)\) is also a basis of the space \(E\), equivalent to the basis \((x_k)\).
Proof. By virtue of the lemma, the unconditional convergence of the series (2) implies the convergence of the series
\[
\sum_{k=1}^{\infty}|f(u_k-x_k)|,
\tag{3}
\]
uniformly with respect to \(f\in S^*\). By a lemma of I. M. Gelfand \((^8)\), from this it is easy to obtain the inequality
\[
\sum_{k=1}^{\infty}|f(u_k-x_k)|\le M\|f\|\le M.
\tag{4}
\]
If \((f_k)\), as above, is the system of functionals biorthogonal to \((x_k)\): \(f_i(x_k)=\delta_{ik}\), \(i,k=1,2,\ldots\), then, in view of the normalizedness of the basis \((x_k)\), \(\|f_k\|\le a,\ k=1,2,\ldots\)
For any \(m\) and \(n\) there is a functional \(\varphi_{mn}\in S^*\) such that
\[
\left\|\sum_{k=m}^{n} f_k(x)(u_k-x_k)\right\|
=
\sum_{k=m}^{n} f_k(x)\varphi_{mn}(u_k-x_k)\le
\]
\[
\le
\sum_{k=m}^{n}|f_k(x)|\,|\varphi_{mn}(u_k-x_k)|
\le
\left(\sum_{k=m}^{n}\|f_k\|\,|\varphi_{mn}(u_k-x_k)|\right)\|x\|\le
\]
\[
\le
a\sum_{k=m}^{n}|\varphi_{mn}(u_k-x_k)|\,\|x\|
\le
a\varepsilon\|x\|.
\]
Consequently, the uniformly convergent series
\[
\sum_{k=1}^{\infty} f_k(x)(u_k-x_k)=Bx
\]
defines a completely continuous operator \(B\). Since the equality
\[
Ax=(I+B)x=\sum_{k=1}^{\infty} f_k(x)u_k=\theta
\]
is possible only (by virtue of the \(\omega\)-linear independence of the system \((u_k)\)) when \(f_k(x)=0,\ k=1,2,\ldots\), i.e., when \(x=\theta\). Hence the operator \(A\) is continuously invertible and, consequently, the system \((u_k)\), where \(u_k=(I+B)x_k=Ax_k,\ k=1,2,\ldots\), forms a basis in \(E\) equivalent to the basis \((x_k)\), as was required to prove.
Remark. By the theorem of Dvoretzky and Rogers \((^9)\), in the space \(E\) there exists a series \(\sum_{k=1}^{\infty} y_k\) which converges unconditionally, but not absolutely:
\[ \sum_{k=1}^{\infty} \|y_k\|=+\infty. \]
Put \(u_k=x_k-y_k\). Then, if \((x_k)\) is a normalized basis in the space \(E\), then, by Theorem 1, \((u_k)\) is a defective basis \((^{10})\) in \(E\), although the series \(\sum_{k=1}^{\infty}\|u_k-x_k\|\) diverges. Consequently, Theorem 1 is a strengthening of the theorem of M. G. Krein, M. A. Rutman, and D. P. Milman.
Following N. K. Bari \((^{11})\), we shall call a complete minimal system \((x_k)\subset E\) a Bessel system if, for every \(x\),
\[ \sum_{k=1}^{\infty} |f_k(x)|^2<\infty, \]
and a Hilbert system if, for any sequence \((\alpha_k)\in l^2\), there exists, and moreover uniquely, an element \(x\in E\) for which \(f_k(x)=\alpha_k,\ k=1,2,\ldots\), where \(f_i(x_k)=\delta_{ik},\ i,k=1,2,\ldots\). We shall call systems of elements \((x_k)\) and \((u_k)\) of the Banach space \(E\) weakly quadratically close if the series
\[ \sum_{k=1}^{\infty} |f(u_k-x_k)|^2 \tag{5} \]
converges uniformly with respect to \(f\in S^*\).
Theorem 2. If \((x_k)\) is a Bessel basis in the Banach space \(E\), then every \(l^2\)-linearly independent system of elements \((u_k)\subset E, *weakly quadratically close to the basis* \((x_k)\), is also a Bessel basis equivalent to the given basis \((x_k)\).
Corollary. If, in the space \(E\), the Bessel bases \((x_k)\) and \((u_k)\) are weakly quadratically close, then their biorthogonal systems are also weakly quadratically close.
Let now the space \(E=H\) be a separable Hilbert space. In the sequel, the main role is played by the following
Lemma. In order that a linear operator \(T\) be completely continuous, it is necessary and sufficient that, for every orthonormal basis \((e_k)\subset H\), the series
\[ \sum_{k=1}^{\infty} |(Te_k,x)|^2 \tag{6} \]
converge uniformly with respect to \(x\in H\) and \(\|x\|\le 1\).
If \(A\) is a linear continuous operator in \(H\), and \((e_k)\) is some orthonormal basis in \(H\), then in this basis the operator \(A\) is assigned the matrix \((a_{ik})_{1}^{\infty}\), \(a_{ik}=(Ae_k,e_i)\), \(i,k=1,2,\ldots\), and since
\[ |(Ae_k,x)|^2 = \left|\sum_{i=1}^{\infty} (x,e_i)(Ae_k,e_i)\right|^2 = \left|\sum_{i=1}^{\infty} a_{ik}(x,e_i)\right|^2, \]
* The system \((u_k)\) is called \(l^2\)-linearly independent if from the relations \(\sum c_k u_k=\theta\) and \(\sum |c_k|^2<+\infty\) it follows that \(c_k=0,\ k=1,2,\ldots\).
then a necessary and sufficient condition for the complete continuity of the operator \(A\) is the convergence, uniformly with respect to \(x \in H\) and \(\|x\| \leqslant 1\), of the series
\[ \sum_{k=1}^{\infty} \left| \sum_{i=1}^{\infty} a_{ik}(x,e_i) \right|^2 . \tag{7} \]
Condition (7) may be called the weak quadratability of the matrix \((a_{ik})_1^\infty\).
For brevity, let us call a basis weakly quadratically close to some orthonormal basis a \((W)\)-basis. Obviously, \((W)\)-bases are Riesz bases \({}^{(11)}\).
Theorems 3, 4, and 5 establish some properties and internal criteria for \((W)\)-bases.
Theorem 3. If \((x_k)\) is a \((W)\)-basis, then the biorthogonal system to it also forms a \((W)\)-basis, weakly quadratically close to the same orthonormal basis as the given basis \((x_k)\).
Theorem 4. In order that a Bessel basis \((x_k)\) be a \((W)\)-basis, it is necessary and sufficient that the biorthogonal systems \((x_k)\) and \((y_k)\), \((x_i,y_k)=\delta_{ik}\), \(i=1,2,\ldots\), be weakly quadratically close.
Corollary. In order that a Bessel basis \((x_k)\) be a \((W)\)-basis, it is necessary and sufficient that the operator \(I-C\) be completely continuous, where \(C\) is the operator carrying the biorthogonal system \((y_k)\) into the basis \((x_k)\):
\[ x_k = Cy_k,\quad k=1,2,\ldots \]
Theorem 5 (cf. \({}^{(12)}\)). In order that a complete system \((x_k)\) in \(H\) be a \((W)\)-basis, it is necessary and sufficient that: 1) the elements \((x_k)\), \(k=1,2,\ldots\), be \(l^2\)-linearly independent; 2) the matrix \(\bigl((x_i,x_k)-\delta_{ik}\bigr)_1^\infty\) be weakly quadratable.
Murmansk Pedagogical Institute
Received
19 III 1964
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