CLT for Non-Hermitian Random Band Matrices with Variance Profiles

Abstract

We study the linear eigenvalue statistics of a non-Hermitian random band matrix with a continuous variance profile \(w_{\nu }(x)\) and increasing bandwidth \(b_{n}\). We show that the fluctuations of the linear eigenvalue statistics converges to \(N(0,\sigma _{f}^{2}(\nu ))\), where \(\nu =\lim _{n\rightarrow \infty }(2b_{n}/n)\in [0,1]\) and f is an analytic test function. We obtain explicit formulae of \(\sigma _{f}^{2}(\nu )\) in two different cases, namely when \(\nu \in (0,1]\) and when \(\nu = 0\). In addition, we show that \(\sigma _{f}^{2}(\nu )\rightarrow \sigma _{f}^{2}(0)\) as \(\nu \downarrow 0\). In particular by setting \(\nu =1\), we obtain the result for full non-Hermitian matrices with a constant variance profile, which was previously found by Rider and Silverstein (Ann Probab 34:2118–2143, 2006).

Appendices

Appendix A

In this section, we discuss about the norm of non-Hermitian random matrices. A sharp almost sure bound on the spectral radius of non-Hermitian random matrices can be found in [20, 21].

Theorem A.1

[21] Let \(M=(m_{ij})_{n\times n}\) be a sequence of \(n\times n\) random matrices with \(m_{ij};1\le i,j\le n\) real valued i.i.d. for each n. Assume that for each n,

1. (i)

   \(\mathbb {E}[m_{11}]=0\)

2. (ii)

   \(\mathbb {E}[m_{11}^{2}]=\sigma ^{2}\)

3. (iii)

   \(\mathbb {E}[|m_{11}|^{p}]\le p^{c p}\) for all \(p\ge 2\) and for some \(c>0\).

Let

$$\begin{aligned} \rho _{n}=\max _{1\le i\le n}\{|\lambda _{i}(M/\sqrt{n})|\}. \end{aligned}$$

Then \(\limsup _{n\rightarrow \infty }\rho _{n}\le \sigma \) almost surely.

We see that in our context if a full random matrix satisfies the condition 3.1, then it also satisfies the above condition and as a result, \(\rho _{n}\le 1\) almost surely as \(n\rightarrow \infty \). However, the above theorem does not take a variance profile into account. The following theorem from [7] estimates the norm of a symmetric random matrix with a variance profile.

Theorem A.2

[7, Corollary 3.5] Let X be a \(n\times n\) real symmetric matrix with \(X_{ij}=\xi _{ij}w_{ij}\), where \(\{\xi _{ij}:i\ge j\}\) are independent centered random variables and \(\{w_{ij}:i\ge j\}\) are give scalars. If \(\mathbb {E}[|\xi _{ij}|^{2p}]^{1/2p}\le C p^{\beta /2}\) for some \(C,\beta >0\) and all p, i, j, then

$$\begin{aligned} \mathbb {E}\Vert X\Vert \le C'\max _{i}\sqrt{\sum _{j=1}^{n}w_{ij}^{2}}+C'\max _{i,j}|w_{ij}|\log ^{(\beta \wedge 1)/2}n, \end{aligned}$$

where C depends on \(C,\beta \) only.

Using the above theorem along with Poincaré inequality, we have the following lemma.

Lemma A.3

Let M be an \(n\times n\) random matrix as in the Theorem 3.2. Then there exists \(\rho \ge 1\) such that

$$\begin{aligned} \mathbb {P}\left( \Vert M\Vert>\rho /4+t\right) \le K\exp \left( -\sqrt{\frac{\alpha c_{n}}{2\omega }}t\right) ,\;\;\forall \;t>0, \end{aligned}$$

(A.1)

where \(K>0\) is a universal constant. In particular,

$$\begin{aligned}&\mathbb {P}(\Vert M\Vert >\rho \;\text {infinitely often})=0, \end{aligned}$$

(A.2)

$$\begin{aligned} \text {and}\;&\;\mathbb {E}[\Vert M\Vert ^{l}]\le \rho ^{l}+K\Gamma (l+1)\left( \frac{\alpha c_{n}}{2\omega }\right) ^{-l/2}\exp \left( \sqrt{\frac{\alpha c_{n}}{2\omega }}\frac{\rho }{4}\right) . \end{aligned}$$

(A.3)

Proof

First of all, we may write \(M=M_{R}+iM_{I}\), where both \(M_{R}\) and \(M_{I}\) are real valued matrices. Then we can estimate \(\Vert M\Vert \le \Vert M_{R}\Vert +\Vert M_{I}\Vert \). Therefore without loss of generality, let us consider M be a real valued matrix. Consider

$$\begin{aligned} \tilde{M}:=\left[ \begin{array}{cc} O &{} M\\ M^{*} &{} O \end{array} \right] , \end{aligned}$$

and apply Theorem A.2 on \({\tilde{M}}\) to obtain the same bound for \(\mathbb {E}\Vert \tilde{M}\Vert (=\mathbb {E}\Vert M\Vert )\). In our case, \(w_{ij}^{2}=\frac{1}{c_{n}}w_{\nu }((i-j)/n)\) or \(w_{ij}^{2}=\frac{1}{c_{n}}w_{0}((i-j)/n)\) as described in Definition 2.1. Since \(c_{n}\ge \log ^{3}n\) and w is a piece-wise continuous function, \(\lim _{n\rightarrow \infty }\sum _{j=1}^{n}w_{ij}^{2}=\int w(x)\;dx=1\) and \(\max _{i,j}|w_{ij}|\log ^{(\beta \wedge 1)/2}n\rightarrow 0\). As a result, there exists \(\rho \ge 1\) such that

$$\begin{aligned} \limsup \mathbb {E}\Vert M\Vert \le \rho /4. \end{aligned}$$

Here we note that we need \(c_{n}\) to grow at least as \(\log n\). In fact, this is a sharp condition. Otherwise, the matrix norm may be unbounded [11, 27].

Secondly, \(\Vert M\Vert \le \sqrt{\sum _{i,j}|m_{ij}|^{2}}\) implies that \(h(M):= \Vert M\Vert \) is a Lipschitz\(_{1}\) function. Therefore applying the properties of Poincaré inequality as described in Definition B.1, we have

$$\begin{aligned}&\mathbb {P}\left( |\Vert M\Vert -\mathbb {E}\Vert M\Vert |>t\right) \le K\exp \left( -\sqrt{\frac{\alpha c_{n}}{2\omega }}t\right) \\ \text {i.e.} \;&\;\mathbb {P}\left( \Vert M\Vert >\rho /4+t\right) \le K\exp \left( -\sqrt{\frac{\alpha c_{n}}{2\omega }}t\right) , \end{aligned}$$

where \(\omega =\sup _{x}w(x)\).

Equation (A.2) can be seen from the equation (A.1) along with the application of Borel–Cantelli lemma with \(t=3\rho /4\). Equation (A.3) can be justified as follows,

$$\begin{aligned} \mathbb {E}[\Vert M\Vert ^{l}]&=\int _{0}^{\rho /4}lu^{l-1}\mathbb {P}(\Vert M\Vert>u)\;du+\int _{\rho /4}^{\infty }lu^{l-1}\mathbb {P}(\Vert M\Vert >u)\;du\\&\le \rho ^{l}+Kl\exp \left( \sqrt{\frac{\alpha c_{n}}{2\omega }}\frac{\rho }{4}\right) \int _{\rho /4}^{\infty }u^{l-1}\exp \left( -\sqrt{\frac{\alpha c_{n}}{2\omega }}u\right) \;du\\&\le \rho ^{l}+K\Gamma (l+1)\left( \frac{\alpha c_{n}}{2\omega }\right) ^{-l/2}\exp \left( \sqrt{\frac{\alpha c_{n}}{2\omega }}\frac{\rho }{4}\right) . \end{aligned}$$

We would like to remark that the lemma is also true for the column removed matrices \(M^{(k)}\), and the same proof will go through. \(\square \)

We finally would like to remark that although the Theorem A.2 gives a constant bound on the norm of the matrix with a variance profile, the constant is not that sharp unlike Theorem A.1. However, we expect that for matrices with continuous variance profile, the correct norm bound should be \(\limsup _{n\rightarrow \infty }\sum _{i=1}^{n}w_{ij}^{2}\). This was remarked in [29, Remark 4.11]. In our case, this limit is equal to 1. We have mentioned in Remark 4.2 that eventually it suffices to take \(z,\eta \in \partial \mathbb {D}_{1}\) only.

Appendix B

Here we list down some key results. Interested readers may find the proofs in the included references.

Definition B.1

(Poincaré inequality). A complex random variable \(\xi \) is said to satisfy Poincaré inequality with constant \(\alpha \in (0,\infty )\) if for any differentiable function \(h:\mathbb {C}\rightarrow \mathbb {C}\), we have \(\text {Var}(h(\xi ))\le \frac{1}{\alpha }\mathbb {E}[|h'(\xi )|^{2}]\). Here \(\mathbb {C}\) is identified with \(\mathbb {R}^{2}\).

Here are some properties of Poincaré inequality

1. (1)

   If \(\xi \) satisfies Poincaré inequality with constant \(\alpha \), then \(c\xi \) also satisfies Poincaré inequality with constant \(\alpha / c^{2}\) for any \(c\in \mathbb {R}\backslash \{0\}\).

2. (2)

   If two independent random variables \(\xi _{1},\xi _{2}\) satisfy the Poincaré inequality with the same constant \(\alpha \), then for any differentiable function \(h:\mathbb {C}^{2}\rightarrow \mathbb {C}\), \(\text {Var}(h(\xi ))\le \frac{1}{\alpha }\mathbb {E}[\Vert \nabla h\Vert _{2}^{2}]\) i.e. \(\xi :=(\xi _{1},\xi _{2})\) also satisfies Poincaré inequality with the same constant \(\alpha \).

3. (3)

   [4, Lemma 4.4.3] If \(\xi \in \mathbb {C}^{N}\) satisfies Poincaré inequality with constant \(\alpha \), then for any differentiable function \(h:\mathbb {C}^{N}\rightarrow \mathbb {C}\)

   $$\begin{aligned} \mathbb {P}(|h(\xi )-\mathbb {E}[h(\xi )]|>t)\le K\exp \left\{ -\frac{\sqrt{\alpha }t}{\sqrt{2}\Vert \Vert \nabla h\Vert _{2}\Vert _{\infty }} \right\} , \end{aligned}$$

   where \(K=-2\sum _{i=1}^{\infty }2^{i}\log (1-2^{-2i-1})\). Here \(\mathbb {C}^{N}\) is identified with \(\mathbb {R}^{2N}\). In the above, \(\Vert \nabla h(x)\Vert _{2}\) denotes the \(\ell ^{2}\) norm of the N-dimensional vector \(\nabla h(x)\) at \(x\in \mathbb {C}^{N}\); and \(\Vert \Vert \nabla h\Vert _{2}\Vert _{\infty }=\sup _{x\in \mathbb {C}^{N}}\Vert \nabla h(x)\Vert _{2}\). In particular if \(h:\mathbb {C}^{N}\rightarrow \mathbb {C}\) is a Lipschitz function with lipschitz constant \(\Vert h\Vert _{Lip}\), then \(\Vert \Vert \nabla h\Vert _{2}\Vert _{\infty }\le \Vert h\Vert _{Lip}\).

For example, Gaussian random variables and compactly supported continuous random variables satisfy Poincaré inequality.

Lemma B.2

[10, Theorem 35.12] Let \(\{\xi _{n,k}\}_{1\le k\le n}\) be a martingale difference array with respect to a filtration \(\{\mathcal {F}_{k,n}\}_{1\le k\le n}\). Suppose for any \(\delta >0\),

1. (i)

   \(\lim _{n\rightarrow \infty }\sum _{k=1}^{n}\mathbb {E}[\xi _{n,k}^{2}\mathbf{1} _{|\xi _{n,k}|>\delta }]=0\),

2. (ii)

   \(\sum _{k=1}^{n}\mathbb {E}[\xi _{n,k}^{2}|\mathcal {F}_{n,k-1}]{\mathop {\rightarrow }\limits ^{p}}\sigma ^{2}\) as \(n\rightarrow \infty \).

Then \(\sum _{k=1}^{n}\xi _{n,k}{\mathop {\rightarrow }\limits ^{d}}\mathcal {N}_{1}(0,\sigma ^{2})\).

Lemma B.3

([41], Sherman-Morrison formula). Let A and \(A+ve_{k}^{t}\) be two invertible matrices, where \(v\in \mathbb {C}^{n}\). Then

$$\begin{aligned} (A+ve_{k}^{t})^{-1}v=\frac{A^{-1}v}{1+e_{k}^{t}A^{-1}v}. \end{aligned}$$