Distribution of Singular Values of Random Band Matrices; Marchenko–Pastur Law and More

Abstract

We consider the limiting spectral distribution of matrices of the form \(\frac{1}{2b_{n}+1} (R + X)(R + X)^{*}\), where X is an \(n\times n\) band matrix of bandwidth \(b_{n}\) and R is a non random band matrix of bandwidth \(b_{n}\). We show that the Stieltjes transform of ESD of such matrices converges to the Stieltjes transform of a non-random measure. And the limiting Stieltjes transform satisfies an integral equation. For \(R=0\), the integral equation yields the Stieltjes transform of the Marchenko–Pastur law.

Appendix

In this section we list the results which were used in the Sect. 3.

Lemma 8.1

(Lemma 2.3, [21]) Let P, Q be two rectangular matrices of the same size. Then for any \(x,y\ge 0\),

$$\begin{aligned} \mu _{(P+Q)(P+Q)^{*}}(x+y,\infty )\le \mu _{PP^{*}}(x,\infty )+\mu _{QQ^{*}}(y,\infty ). \end{aligned}$$

Lemma 8.2

(Sherman–Morrison formula) Let \(P_{n\times n}\) and \((P+vv^{*})\) be invertible matrices, where \(v\in \mathbb {C}^{n}\). Then we have

$$\begin{aligned} (P+vv^{*})^{-1}=P^{-1}-\frac{P^{-1}vv^{*}P^{-1}}{1+v^{*}P^{-1}v}. \end{aligned}$$

In particular,

$$\begin{aligned} v^{*}(P+vv^{*})^{-1}=\frac{v^{*}P^{-1}}{1+v^{*}P^{-1}v}. \end{aligned}$$

Lemma 8.3

(Lemma 2.6, [21]) Let P, Q be \(n\times n\) matrices such that Q is Hermitian. Then for any \(r\in \mathbb {C}^{n}\) and \(z=E+i\eta \in \mathbb {C}^{+}\) we have

$$\begin{aligned} \left| \text {tr}\left( (Q-zI)^{-1}-(Q+rr^{*}-zI)^{-1}\right) P\right| =\left| \frac{r^{*}(Q-zI)^{-1}P(Q-zI)^{-1}r}{1+r^{*}(Q-zI)^{-1}r}\right| \le \frac{\Vert P\Vert }{\eta }. \end{aligned}$$

Lemma 8.4

([2], Lemma 1) Let \(\{X_{n}\}_{n}\) be a sequence of random variables such that \(|X_{n}|\le K_{n}\) almost surely, and \(\mathbb {E}[X_{i_{1}}X_{i_{2}}\ldots X_{i_{k}}]=0\) for all \(k\in \mathbb {N},\;i_{1}<i_{2}<\cdots <i_{k}\). Then for every \(\lambda \in \mathbb {R}\) we have

$$\begin{aligned} \mathbb {E}\left[ \exp \left\{ \lambda \sum _{i=1}^{n}X_{i}\right\} \right] \le \exp \left\{ \frac{\lambda ^{2}}{2}\sum _{i=1}^{n}K_{i}^{2}\right\} . \end{aligned}$$

In particular, for any \(t>0\) we have

$$\begin{aligned} \mathbb {P}\left( \left| \sum _{i=1}^{n}X_{i}\right| >t\right) \le 2\exp \left\{ -\frac{t^{2}}{2\sum _{i=1}^{n}K_{i}^{2}}\right\} . \end{aligned}$$

Lemma 8.5

Let P, Q be two \(n\times n\) matrices, then

$$\begin{aligned} \Vert \mu _{PP^{*}}-\mu _{QQ^{*}}\Vert \le \frac{2}{n}rank(P-Q), \end{aligned}$$

where \(\Vert \cdot \Vert \) denotes the total variation norm between probability measures.

Proof

By Cauchy’s interlacing property,

$$\begin{aligned} \Vert \mu _{PP^{*}}-\mu _{QQ^{*}}\Vert\le & {} \frac{1}{n}\text {rank}(PP^{*}-QQ^{*})\\\le & {} \frac{1}{n}\text {rank}((P-Q)P^{*})+\frac{1}{n}\text {rank}(Q(P-Q)^{*})\\\le & {} \frac{2}{n}\text {rank}(P-Q). \end{aligned}$$

\(\square \)

Lemma 8.6

([4, Lemma C.3]) Let P and Q be \(n\times n\) Hermition matrices, and \(I\subset \{1,2,\ldots , n\}\), then

$$\begin{aligned} \left| \sum _{k\in I}(P-zI)^{-1}_{kk}-\sum _{k\in I}(Q-zI)_{kk}^{-1}\right| \le \frac{2}{\mathfrak {I}(z)}\text {rank}(P-Q). \end{aligned}$$

Lemma 8.7

Let \(C_{j}\) and \(B_{j}\) be defined in (6), \(r_{j}\) be the jth column of R, and \(I_{j}\subset \{1,2,\ldots , n\}\) be same as (1), and \(z\in \mathbb {C}^{+}\). Then

$$\begin{aligned}&\mathbb {P}\left( \left| \sum _{k\in I_{j}}(C_{j}^{-1})_{kk}-\mathbb {E}\sum _{k\in I_{j}}(C_{j}^{-1})_{kk}\right|>t\right) \le 2\exp \left\{ -\frac{\mathfrak {I}(z)^{2}t^{2}}{32n}\right\} \\&\mathbb {P}\left( \left| \sum _{k\in I_{j}}(C_{j}^{-1}B_{j}^{-1})_{kk}-\mathbb {E}\sum _{k\in I_{j}}(C_{j}^{-1}B_{j}^{-1})_{kk}\right|>t\right) \le 2\exp \left\{ -\frac{\mathfrak {I}(z)^{2}t^{2}}{32n}\right\} \\&\mathbb {P}\left( \left| \sum _{k\in I_{j}}(C_{j}^{-1}r_{j}r_{j}^{*}C_{j}^{-1*})_{kk}-\mathbb {E}\sum _{k\in I_{j}}(C_{j}^{-1}r_{j}r_{j}^{*}C_{j}^{-1*})_{kk}\right|>t\right) \le 2\exp \left\{ -\frac{\mathfrak {I}(z)^{2}t^{2}}{32n}\right\} \\&\mathbb {P}\left( \left| \sum _{k\in I_{j}}(C_{j}^{-1}B_{j}^{-1}r_{j}r_{j}^{*}B^{-1*}C_{j}^{-1*})_{kk}-\mathbb {E}\sum _{k\in I_{j}}(C_{j}^{-1}B_{j}^{-1}r_{j}r_{j}^{*}B^{-1*}C_{j}^{-1*})_{kk}\right| >t\right) \\&\qquad \le 2\exp \left\{ -\frac{\mathfrak {I}(z)^{2}t^{2}}{32n}\right\} . \end{aligned}$$

Proof

Let \(\mathcal {F}_{l}=\sigma \{y_{1},\ldots ,y_{l}\}\) be the \(\sigma \)-algebra generated by the column vectors \(y_{1},\ldots , y_{l}\). Then, we can write

$$\begin{aligned}&\sum _{k\in I_{j}}(C_{j}^{-1})_{kk}-\mathbb {E}\sum _{k\in I_{j}}(C_{j}^{-1})_{kk}=\sum _{l=1}^{n}\left[ \mathbb {E}\left\{ \left. \sum _{k\in I_{j}}(C_{j}^{-1})_{kk}\right| \mathcal {F}_{l}\right\} -\mathbb {E}\left\{ \left. \sum _{k\in I_{j}}(C_{j}^{-1})_{kk}\right| \mathcal {F}_{l-1}\right\} \right] . \end{aligned}$$

Notice that for any two matrices P, Q, we have \(\text {rank}(PP^{*}-QQ^{*})\le 2\text {rank}(P-Q)\) (from Lemma 8.5). Therefore, using the Lemmas 8.6 and 8.4, we can conclude the result. The remaining three equations can also be proved in the same way. \(\square \)