共查询到20条相似文献,搜索用时 31 毫秒
1.
Fourier series are considered on the one-dimensional torus for the space of periodic distributions that are the distributional
derivative of a continuous function. This space of distributions is denoted
Ac(\mathbb T){\mathcal{A}}_{c}(\mathbb{T}) and is a Banach space under the Alexiewicz norm,
|| f|| \mathbbT=sup |I| £ 2p|ò I f|\|f\|_{\mathbb{T}}=\sup_{|I|\leq2\pi}|\int_{I} f|, the supremum being taken over intervals of length not exceeding 2 π. It contains the periodic functions integrable in the sense of Lebesgue and Henstock–Kurzweil. Many of the properties of
L
1 Fourier series continue to hold for this larger space, with the L
1 norm replaced by the Alexiewicz norm. The Riemann–Lebesgue lemma takes the form [^( f)]( n)= o( n)\hat{f}(n)=o(n) as | n|→∞. The convolution is defined for
f ? Ac(\mathbb T)f\in{\mathcal{A}}_{c}(\mathbb{T}) and g a periodic function of bounded variation. The convolution commutes with translations and is commutative and associative.
There is the estimate
|| f* g|| ¥ £ || f|| \mathbbT || g|| BV\|f\ast g\|_{\infty}\leq\|f\|_{\mathbb{T}} \|g\|_{\mathcal{BV}}. For
g ? L1(\mathbb T)g\in L^{1}(\mathbb{T}),
|| f* g|| \mathbbT £ || f|| \mathbb T || g|| 1\|f\ast g\|_{\mathbb{T}}\leq\|f\|_{\mathbb {T}} \|g\|_{1}. As well, [^( f* g)]( n)=[^( f)]( n) [^( g)]( n)\widehat{f\ast g}(n)=\hat{f}(n) \hat{g}(n). There are versions of the Salem–Zygmund–Rudin–Cohen factorization theorem, Fejér’s lemma and the Parseval equality. The
trigonometric polynomials are dense in
Ac(\mathbb T){\mathcal{A}}_{c}(\mathbb{T}). The convolution of f with a sequence of summability kernels converges to f in the Alexiewicz norm. Let D
n
be the Dirichlet kernel and let
f ? L1(\mathbb T)f\in L^{1}(\mathbb{T}). Then
|| Dn* f- f|| \mathbbT?0\|D_{n}\ast f-f\|_{\mathbb{T}}\to0 as n→∞. Fourier coefficients of functions of bounded variation are characterized. The Appendix contains a type of Fubini theorem. 相似文献
2.
In this paper, we study the planar Hamiltonian system = J (A(θ)x + ▽f(x, θ)), θ = ω, x ∈ R2 , θ∈ Td , where f is real analytic in x and θ, A(θ) is a 2 × 2 real analytic symmetric matrix, J = (1-1 ) and ω is a Diophantine vector. Under the assumption that the unperturbed system = JA(θ)x, θ = ω is reducible and stable, we obtain a series of criteria for the stability and instability of the equilibrium of the perturbed system. 相似文献
3.
Let L
p
, 1 ≤ p< ∞, be the space of 2π-periodic functions f with the norm
|| f ||p = ( ò - pp | f |p )1 \mathord | / |
\vphantom 1 p p {\left\| f \right\|_p} = {\left( {\int\limits_{ - \pi }^\pi {{{\left| f \right|}^p}} } \right)^{{1 \mathord{\left/{\vphantom {1 p}} \right.} p}}} , and let C = L
∞ be the space of continuous 2π-periodic functions with the norm
|| f ||¥ = || f || = maxe ? \mathbbR | f(x) | {\left\| f \right\|_\infty } = \left\| f \right\| = \mathop {\max }\limits_{e \in \mathbb{R}} \left| {f(x)} \right| . Let CP be the subspace of C with a seminorm P invariant with respect to translation and such that
P(f) \leqslant M|| f || P(f) \leqslant M\left\| f \right\| for every f ∈ C. By ?k = 0¥ Ak (f) \sum\limits_{k = 0}^\infty {{A_k}} (f) denote the Fourier series of the function f, and let l = { lk }k = 0¥ \lambda = \left\{ {{\lambda_k}} \right\}_{k = 0}^\infty be a sequence of real numbers for which ?k = 0¥ lk Ak(f) \sum\limits_{k = 0}^\infty {{\lambda_k}} {A_k}(f) is the Fourier series of a certain function f
λ ∈ L
p
. The paper considers questions related to approximating the function f
λ by its Fourier sums S
n
(f
λ) on a point set and in the spaces L
p
and CP. Estimates for || fl - Sn( fl ) ||p {\left\| {{f_\lambda } - {S_n}\left( {{f_\lambda }} \right)} \right\|_p} and P(f
λ − S
n
(f
λ)) are obtained by using the structural characteristics (the best approximations and the moduli of continuity) of the functions
f and f
λ. As a rule, the essential part of deviation is estimated with the use of the structural characteristics of the function f.
Bibliography: 11 titles. 相似文献
4.
We consider the space
A(\mathbb T)A(\mathbb{T}) of all continuous functions f on the circle
\mathbb T\mathbb{T} such that the sequence of Fourier coefficients
[^( f)] = { [^( f)]( k ), k ? \mathbb Z }\hat f = \left\{ {\hat f\left( k \right), k \in \mathbb{Z}} \right\} belongs to l
1(ℤ). The norm on
A(\mathbb T)A(\mathbb{T}) is defined by
|| f || A(\mathbbT) = || [^( f)] || l1 (\mathbbZ)\left\| f \right\|_{A(\mathbb{T})} = \left\| {\hat f} \right\|_{l^1 (\mathbb{Z})}. According to the well-known Beurling-Helson theorem, if
f:\mathbb T ? \mathbb T\phi :\mathbb{T} \to \mathbb{T} is a continuous mapping such that
|| einf || A(\mathbbT) = O(1)\left\| {e^{in\phi } } \right\|_{A(\mathbb{T})} = O(1), n ∈ ℤ then φ is linear. It was conjectured by Kahane that the same conclusion about φ is true under the assumption that
|| einf || A(\mathbbT) = o( log| n | )\left\| {e^{in\phi } } \right\|_{A(\mathbb{T})} = o\left( {\log \left| n \right|} \right). We show that if $\left\| {e^{in\phi } } \right\|_{A(\mathbb{T})} = o\left( {\left( {{{\log \log \left| n \right|} \mathord{\left/
{\vphantom {{\log \log \left| n \right|} {\log \log \log \left| n \right|}}} \right.
\kern-\nulldelimiterspace} {\log \log \log \left| n \right|}}} \right)^{1/12} } \right)$\left\| {e^{in\phi } } \right\|_{A(\mathbb{T})} = o\left( {\left( {{{\log \log \left| n \right|} \mathord{\left/
{\vphantom {{\log \log \left| n \right|} {\log \log \log \left| n \right|}}} \right.
\kern-\nulldelimiterspace} {\log \log \log \left| n \right|}}} \right)^{1/12} } \right), then φ is linear. 相似文献
5.
Let
W ì \mathbb Cd{\Omega \subset{\mathbb C}^{d}} be an irreducible bounded symmetric domain of type ( r, a, b) in its Harish–Chandra realization. We study Toeplitz operators Tng{T^{\nu}_{g}} with symbol g acting on the standard weighted Bergman space Hn2{H_\nu^2} over Ω with weight ν. Under some conditions on the weights ν and ν
0 we show that there exists C( ν, ν
0) > 0, such that the Berezin transform [( g)\tilde] n0{\tilde{g}_{\nu_{0}}} of g with respect to H2n0{H^2_{\nu_0}} satisfies:
|
\labele0||[(g)\tilde]n0||¥ £ C(n,n0)||Tng||,\label{e0}\|\tilde{g}_{\nu_0}\|_\infty \leq C(\nu,\nu_0)\|T^\nu_g\|, 相似文献
6.
We define a generalized Li coefficient for the L-functions attached to the Rankin–Selberg convolution of two cuspidal unitary automorphic representations π and π
′ of
GLm(\mathbb AF)GL_{m}(\mathbb{A}_{F})
and
GLm¢(\mathbb AF)GL_{m^{\prime }}(\mathbb{A}_{F})
. Using the explicit formula, we obtain an arithmetic representation of the n th Li coefficient
l p,p¢( n)\lambda _{\pi ,\pi ^{\prime }}(n)
attached to
L( s,p f×[(p)\tilde] f¢)L(s,\pi _{f}\times \widetilde{\pi}_{f}^{\prime })
. Then, we deduce a full asymptotic expansion of the archimedean contribution to
l p,p¢( n)\lambda _{\pi ,\pi ^{\prime }}(n)
and investigate the contribution of the finite (non-archimedean) term. Under the generalized Riemann hypothesis (GRH) on non-trivial
zeros of
L( s,p f×[(p)\tilde] f¢)L(s,\pi _{f}\times \widetilde{\pi}_{f}^{\prime })
, the nth Li coefficient
l p,p¢( n)\lambda _{\pi ,\pi ^{\prime }}(n)
is evaluated in a different way and it is shown that GRH implies the bound towards a generalized Ramanujan conjecture for
the archimedean Langlands parameters μ
π
( v, j) of π. Namely, we prove that under GRH for
L( s,p f×[(p)\tilde] f)L(s,\pi _{f}\times \widetilde{\pi}_{f})
one has
|Rem p( v, j)| £ \frac14|\mathop {\mathrm {Re}}\mu_{\pi}(v,j)|\leq \frac{1}{4}
for all archimedean places v at which π is unramified and all j=1,…, m. 相似文献
7.
Let B denote the unit ball in [(?)\tilde] \widetilde{\nabla\hskip-4pt}\hskip4pt
denote the volume measure and gradient with respect to the Bergman metric on B. In the paper we consider the weighted Dirichlet spaces
Dg{{\cal D}_{\gamma}}
,
$\gamma > (n-1)$\gamma > (n-1)
, and weighted Bergman spaces
Apa{A^p_{\alpha}}
,
0 < p < ¥0 < p < \infty
,
$\alpha > n$\alpha > n
, of holomorphic functions f on B for which
Dg( f)D_{\gamma}(\,f)
and
|| f|| Apa\Vert\, f\Vert_{A^p_{\alpha}}
respectively are finite, where
Dg( f)=ò B (1-| z| 2) g|[(?)\tilde] f( z)| 2dt( z),D_{\gamma}(\,f)=\int_B (1-\vert z\vert^2)^{\gamma}\vert\widetilde{\nabla\hskip-4pt}\hskip4pt f(z)\vert^2d\tau(z),
and
|| f|| pApa=ò B(1-| z| 2) a| f( z)| pdt( z).\Vert\, f\Vert^p_{A^p_{\alpha}}=\int_B(1-\vert z\vert^2)^{\alpha}\vert\, f(z)\vert^pd\tau(z).
The main result of the paper is the following theorem. Theorem 1. Let f be holomorphic on B and
$\alpha > n$\alpha > n
. 相似文献
8.
Let a\alpha and b\beta be bounded measurable functions on the unit circle T. The singular integral operator Sa, bS_{\alpha ,\,\beta } is defined by Sa, b f = a Pf + b Qf( f ? L2 ( T))S_{\alpha ,\,\beta } f = \alpha Pf + \beta Qf(f \in L^2 (T)) where P is an analytic projection and Q is a co-analytic projection. In the previous paper, the norm of Sa, bS_{\alpha ,\,\beta } was calculated in general, using a,b\alpha ,\beta and a[`(b)] + H¥\alpha \bar {\beta } + H^\infty where H¥H^\infty is a Hardy space in L¥ ( T).L^\infty (T). In this paper, the essential norm || Sa, b || e\Vert S_{\alpha ,\,\beta } \Vert _e of Sa, bS_{\alpha ,\,\beta } is calculated in general, using a[`(b)] + H¥ + C\alpha \bar {\beta } + H^\infty + C where C is a set of all continuous functions on T. Hence if a[`(b)]\alpha \bar {\beta } is in H¥ + CH^\infty + C then || Sa, b || e = max(||a|| ¥ , ||b|| ¥ ).\Vert S_{\alpha ,\,\beta } \Vert _e = \max (\Vert \alpha \Vert _\infty , \Vert \beta \Vert _\infty ). This gives a known result when a, b\alpha , \beta are in C. 相似文献
9.
(w, c) ? R 2, u ? Lloc3 (R N, C)\font\Opr=msbm10 at 8pt \def\Op#1{\hbox{\Opr{#1}}}(\omega, c)\in {\Op R}^2, {\upsilon} \in L_{\rm loc}^3 ({\Op R}^N, {\bf C}) and x||j|| L¥(RN×R)2 £ max{0, 1-w+[( c2)/4]}.\font\Opr=msbm10 at 8pt \def\Op#1{\hbox{\Opr{#1}}}\Vert\varphi\Vert_{L^\infty({\Op R}^N\times{\Op R})}^2 \le \max\bigg\{0, 1-\omega+{c^2\over 4}\bigg\}. 相似文献
10.
We study the long-term behaviour of the parabolic evolution equation $\[u'(t)=A(t)u(t)+f(t), t>s,\quad u(s)=x. \]$\[u'(t)=A(t)u(t)+f(t), t>s,\quad u(s)=x. \] If A( t) A(t) converges to a sectorial operator A with s( A)? i \Bbb R = ? \sigma(A)\cap i \Bbb R =\emptyset as t?¥ t\to\infty , then the evolution family solving the homogeneous problem has exponential dichotomy. If also f( t)? f¥ f(t)\to f_\infty , then the solution u converges to the 'stationary solution at infinity', i.e., lim t?¥u( t) = - A\sp-1 f¥=: u¥, lim t?¥u¢( t)=0, lim t?¥A( t) u( t)= Au¥. \lim_{t\to\infty}u(t)= -A\sp{-1}f_\infty=:u_\infty, \qquad \lim_{t\to\infty}u'(t)=0, \qquad \lim_{t\to\infty}A(t)u(t)=Au_\infty. . 相似文献
11.
In Finsler geometry, minimal surfaces with respect to the Busemann-Hausdorff measure and the Holmes-Thompson measure are called
BH-minimal and HT-minimal surfaces, respectively. In this paper, we give the explicit expressions of BH-minimal and HT-minimal
rotational hypersurfaces generated by plane curves rotating around the axis in the direction of
[(b)\tilde] \sharp{\tilde{\beta}^{\sharp}} in Minkowski ( α, β)-space
(\mathbb Vn+1,[( Fb)\tilde]){(\mathbb{V}^{n+1},\tilde{F_b})} , where
\mathbb Vn+1{\mathbb{V}^{n+1}} is an (n+1)-dimensional real vector space, [( Fb)\tilde]=[(a)\tilde]f([(b)\tilde]/[(a)\tilde]), [(a)\tilde]{\tilde{F_b}=\tilde{\alpha}\phi(\tilde{\beta}/\tilde{\alpha}), \tilde{\alpha}} is the Euclidean metric, [(b)\tilde]{\tilde{\beta}} is a one form of constant length
b:=||[(b)\tilde]|| [(a)\tilde], [(b)\tilde] \sharp{b:=\|\tilde{\beta}\|_{\tilde{\alpha}}, \tilde{\beta}^{\sharp}} is the dual vector of [(b)\tilde]{\tilde{\beta}} with respect to [(a)\tilde]{\tilde{\alpha}} . As an application, we first give the explicit expressions of the forward complete BH-minimal rotational surfaces generated
around the axis in the direction of
[(b)\tilde] \sharp{\tilde{\beta}^{\sharp}} in Minkowski Randers 3-space
(\mathbb V3,[(a)\tilde]+[(b)\tilde]){(\mathbb{V}^{3},\tilde{\alpha}+\tilde{\beta})} . 相似文献
12.
A Toeplitz operator TfT_\phi with symbol f\phi in
L¥(\mathbb D)L^{\infty}({\mathbb{D}}) on the Bergman space
A2(\mathbb D)A^{2}({\mathbb{D}}), where
\mathbb D\mathbb{D} denotes the open unit disc, is radial if f( z) = f(| z|)\phi(z) = \phi(|z|) a.e. on
\mathbb D\mathbb{D}. In this paper, we consider the numerical ranges of such operators. It is shown that all finite line segments, convex hulls
of analytic images of
\mathbb D\mathbb{D} and closed convex polygonal regions in the plane are the numerical ranges of radial Toeplitz operators. On the other hand,
Toeplitz operators TfT_\phi with f\phi harmonic on
\mathbb D\mathbb{D} and continuous on
[`(\mathbb D)]{\overline{\mathbb{D}}} and radial Toeplitz operators are convexoid, but certain compact quasinilpotent Toeplitz operators are not. 相似文献
13.
We study the well-posedness of the fractional differential equations with infinite delay ( P
2): Da u( t)= Au( t)+ò t-¥a( t- s) Au( s) ds + f( t), (0 £ t £ 2p){D^\alpha u(t)=Au(t)+\int^{t}_{-\infty}a(t-s)Au(s)ds + f(t), (0\leq t \leq2\pi)}, where A is a closed operator in a Banach space ${X, \alpha > 0, a\in {L}^1(\mathbb{R}_+)}${X, \alpha > 0, a\in {L}^1(\mathbb{R}_+)} and f is an X-valued function. Under suitable assumptions on the parameter α and the Laplace transform of a, we completely characterize the well-posedness of ( P
2) on Lebesgue-Bochner spaces
Lp(\mathbb T, X){L^p(\mathbb{T}, X)} and periodic Besov spaces
B p,qs(\mathbb T, X){{B} _{p,q}^s(\mathbb{T}, X)} . 相似文献
14.
Let X be a complex Banach space and let B( X){\mathcal{B}(X)} be the space of all bounded linear operators on X. For x ? X{x \in X} and T ? B( X){T \in \mathcal{B}(X)}, let rT( x) = limsup n ? ¥ || Tnx|| 1/n{r_{T}(x) =\limsup_{n \rightarrow \infty} \| T^{n}x\| ^{1/n}} denote the local spectral radius of T at x. We prove that if j: B( X) ? B( X){\varphi : \mathcal{B}(X) \rightarrow \mathcal{B}(X)} is linear and surjective such that for every x ? X{x \in X} we have r
T
( x) = 0 if and only if rj(T)( x) = 0{r_{\varphi(T)}(x) = 0}, there exists then a nonzero complex number c such that j( T) = cT{\varphi(T) = cT} for all T ? B( X){T \in \mathcal{B}(X) }. We also prove that if Y is a complex Banach space and j: B( X) ? B( Y){\varphi :\mathcal{B}(X) \rightarrow \mathcal{B}(Y)} is linear and invertible for which there exists B ? B( Y, X){B \in \mathcal{B}(Y, X)} such that for y ? Y{y \in Y} we have r
T
( By) = 0 if and only if rj( T) ( y)=0{ r_{\varphi ( T) }(y)=0}, then B is invertible and there exists a nonzero complex number c such that j( T) = cB-1TB{\varphi(T) =cB^{-1}TB} for all T ? B( X){T \in \mathcal{B}(X)}. 相似文献
15.
We solve the truncated complex moment problem for measures supported on the variety K o \mathcal{K}\equiv { z ? \in C: z [( z)\tilde]\widetilde{z} = A+Bz+C [(z)\tilde]\widetilde{z} +Dz 2 ,D 1 \neq 0}. Given a doubly indexed finite sequence of complex numbers g o g (2n):g 00,g 01,g 10,?,g 0,2n,g 1,2n-1,?,g 2n-1,1,g 2n,0 \gamma\equiv\gamma^{(2n)}:\gamma_{00},\gamma_{01},\gamma_{10},\ldots,\gamma_{0,2n},\gamma_{1,2n-1},\ldots,\gamma_{2n-1,1},\gamma_{2n,0} , there exists a positive Borel measure m\mu supported in K \mathcal{K} such that g ij=ò[`( z)] izj dm (0 £ 1+ j £ 2 n) \gamma_{ij}=\int\overline{z}^{i}z^{j}\,d\mu\,(0\leq1+j\leq2n) if and only if the moment matrix M(n)( g\gamma ) is positive, recursively generated, with a column dependence relation Z [(Z)\tilde]\widetilde{Z} = A1+BZ +C [(Z)\tilde]\widetilde{Z} +DZ 2, and card V(g) 3\mathcal{V}(\gamma)\geq rank M(n), where V(g)\mathcal{V}(\gamma) is the variety associated to g \gamma . The last condition may be replaced by the condition that there exists a complex number g n,n+1 \gamma_{n,n+1} satisfying g n+1,n o [`(g)] n,n+1= Ag n,n-1+ Bg n,n+ Cg n+1,n-1+ Dg n,n+1 \gamma_{n+1,n}\equiv\overline{\gamma}_{n,n+1}=A\gamma_{n,n-1}+B\gamma_{n,n}+C\gamma_{n+1,n-1}+D\gamma_{n,n+1} . We combine these results with a recent theorem of J. Stochel to solve the full complex moment problem for K \mathcal{K} , and we illustrate the connection between the truncated and full moment problems for other varieties as well, including the variety z k = p(z, [(Z)\tilde] \widetilde{Z} ), deg p < k. 相似文献
16.
In this paper, we reprove that: (i) the Aluthge transform of a complex symmetric operator
[( T)\tilde] = | T| \frac12 U| T| \frac12\tilde{T} = |T|^{\frac{1}{2}} U|T|^{\frac{1}{2}} is complex symmetric, (ii) if T is a complex symmetric operator, then ([( T)\tilde]) *(\tilde{T})^{*} and [( T*)\tilde]\widetilde{T^{*}} are unitarily equivalent. And we also prove that: (iii) if T is a complex symmetric operator, then [(( T*))\tilde] s,t\widetilde{(T^{*})}_{s,t} and ([( T)\tilde] t,s) *(\tilde{T}_{t,s})^{*} are unitarily equivalent for s, t > 0, (iv) if a complex symmetric operator T belongs to class wA( t, t), then T is normal. 相似文献
17.
Let
\mathbb F\mathbb{F} be a p-adic field, let χ be a character of
\mathbb F*\mathbb{F}^{*}, let ψ be a character of
\mathbb F\mathbb{F} and let g y-1\gamma_{\psi}^{-1} be the normalized Weil factor associated with a character of second degree. We prove here that one can define a meromorphic
function [(g)\tilde](c, s,y)\widetilde{\gamma}(\chi ,s,\psi) via a similar functional equation to the one used for the definition of the Tate γ-factor replacing the role of the Fourier transform with an integration against y·g y-1\psi\cdot\gamma_{\psi}^{-1}. It turns out that γ and [(g)\tilde]\widetilde{\gamma} have similar integral representations. Furthermore, [(g)\tilde]\widetilde{\gamma} has a relation to Shahidi‘s metaplectic local coefficient which is similar to the relation γ has with (the non-metalpectic) Shahidi‘s local coefficient. Up to an exponential factor, [(g)\tilde](c, s,y)\widetilde{\gamma}(\chi,s,\psi) is equal to the ratio
\fracg(c 2,2 s,y)g(c, s+\frac12,y)\frac{\gamma(\chi^{2},2s,\psi)}{\gamma(\chi,s+\frac{1}{2},\psi)}. 相似文献
18.
We consider the model of atmosphere dynamics and prove the uniqueness of a solution in a bounded domain
W ì \mathbb R3 \Omega \subset {\mathbb{R}^3} in the space V( Q) of weak solutions equipped with the finite norm
|
|| f ||V(Q)2 = \textvrai supt ? [ 0,T ] || f ||L2( W)2 + || ?3f ||L2(Q)2. \left\| f \right\|_{V(Q)}^2 = \mathop {{\text{vrai}}\,{ \sup }}\limits_{t \in \left[ {0,T} \right]} \left\| f \right\|_{{L_2}\left( \Omega \right)}^2 + \left\| {{\nabla_3}f} \right\|_{{L_2}(Q)}^2. 相似文献
19.
In this paper, it is shown that the dual
[(\text Qord)\tilde]\mathfrak A \widetilde{\text{Qord}}\mathfrak{A} of the quasiorder lattice of any algebra
\mathfrak A \mathfrak{A} is isomorphic to a sublattice of the topology lattice
á( \mathfrak A ) \Im \left( \mathfrak{A} \right) . Further, if
\mathfrak A \mathfrak{A} is a finite algebra, then
[(\text Qord)\tilde]\mathfrak A @ á( \mathfrak A ) \widetilde{\text{Qord}}\mathfrak{A} \cong \Im \left( \mathfrak{A} \right) . We give a sufficient condition for the lattices
[(\text Con)\tilde]\mathfrak A\text, [(\text Qord)\tilde]\mathfrak A \widetilde{\text{Con}}\mathfrak{A}{\text{,}} \widetilde{\text{Qord}}\mathfrak{A} , and
á( \mathfrak A ) \Im \left( \mathfrak{A} \right) . to be pairwise isomorphic. These results are applied to investigate topology lattices and quasiorder lattices of unary algebras. 相似文献
20.
We prove that the Jacobi algorithm applied implicitly on a decomposition A = XDX
T of the symmetric matrix A, where D is diagonal, and X is well conditioned, computes all eigenvalues of A to high relative accuracy. The relative error in every eigenvalue is bounded by O(ek( X)){O(\epsilon \kappa (X))} , where e{\epsilon} is the machine precision and k( X) o || X|| 2·|| X-1|| 2{\kappa(X)\equiv\|X\|_2\cdot\|X^{-1}\|_2} is the spectral condition number of X. The eigenvectors are also computed accurately in the appropriate sense. We believe that this is the first algorithm to compute
accurate eigenvalues of symmetric (indefinite) matrices that respects and preserves the symmetry of the problem and uses only
orthogonal transformations. 相似文献
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