Two-dimensional singular-value decomposition

2DSVD computes the low-rank approximation of a set of matrices such as 2D images or weather maps in a manner almost identical to SVD (singular value decomposition) computes the low-rank approximation of a single matrix (or a set of 1D vectors).

Let matrix ${\displaystyle X=(x_{1},...,x_{n})}$ contains the set of 1D vectors. In SVD, we construct covariance and Gram matrices

${\displaystyle F=XX^{T}}$ , ${\displaystyle F=X^{T}X}$,

and compute their eigenvectors ${\displaystyle U}$ and ${\displaystyle V}$. In SVD, we approximate ${\displaystyle X}$ as

${\displaystyle X=UU^{T}XVV^{T}=U(U^{T}XV)V^{T}=U\Sigma V^{T}}$

If we retain only ${\displaystyle K}$ principal eigenvectors in ${\displaystyle U,V}$, this gives low-rank approximation of ${\displaystyle X}$.

In 2DSVD, we deal with a set of 2D matrices ${\displaystyle (X_{1},...,X_{n})}$ . We construct row-row and colum-column covariance matrices

${\displaystyle F=\sum _{i}X_{i}^{T}X_{i}}$ , ${\displaystyle G=\sum _{i}X_{i}^{T}X_{i}}$

in exact same manner as in SVD, and compute their eigenvectors ${\displaystyle U}$ and ${\displaystyle V}$. We approximate ${\displaystyle X_{i}}$ as

${\displaystyle X_{i}=UU^{T}X_{i}VV^{T}=U(U^{T}X_{i}V)V^{T}=UM_{i}V^{T}}$

in identical fasion as in SVD. This gives a near optimal low-rank approximation of ${\displaystyle (X_{1},...,X_{n})}$ with the objective function

${\displaystyle J=\sum _{i}||X_{i}-LM_{i}R^{T}||^{2}}$

Error bounds similar to Eckard-Young Theorem also exist.

2DSVD is mostly used in image compression and representation.

• Chris Ding and Jieping Ye. "Two-dimensional Singular Value Decomposition (2DSVD) for 2D Maps and Images". Proc. SIAM Int'l Conf. Data Mining (SDM'05), pp:32-43, April 2005.
• Jieping Ye. "Generalized Low Rank Approximations of Matrices". Machine Learning Journal. Vol. 61, pp. 167—191, 2005.