PDF e-Pub

## Section: Research Program

### Multivariate decompositions

Multivariate decompositions provide a way to model complex data such as brain activation images: for instance, one might be interested in extracting an atlas of brain regions from a given dataset, such as regions exhibiting similar activity during a protocol, across multiple protocols, or even in the absence of protocol (during resting-state). These data can often be factorized into spatial-temporal components, and thus can be estimated through regularized Principal Components Analysis (PCA) algorithms, which share some common steps with regularized regression.

Let $𝐗$ be a neuroimaging dataset written as an $\left({n}_{subjects},{n}_{voxels}\right)$ matrix, after proper centering; the model reads

where $𝐃$ represents a set of ${n}_{comp}$ spatial maps, hence a matrix of shape $\left({n}_{comp},{n}_{voxels}\right)$, and $𝐀$ the associated subject-wise loadings. While traditional PCA and independent components analysis (ICA) are limited to reconstructing components $𝐃$ within the space spanned by the column of $𝐗$, it seems desirable to add some constraints on the rows of $𝐃$, that represent spatial maps, such as sparsity, and/or smoothness, as it makes the interpretation of these maps clearer in the context of neuroimaging. This yields the following estimation problem:

The problem is not jointly convex in all the variables but each penalization given in Eq (2) yields a convex problem on $𝐃$ for $𝐀$ fixed, and conversely. This readily suggests an alternate optimization scheme, where $𝐃$ and $𝐀$ are estimated in turn, until convergence to a local optimum of the criterion. As in PCA, the extracted components can be ranked according to the amount of fitted variance. Importantly, also, estimated PCA models can be interpreted as a probabilistic model of the data, assuming a high-dimensional Gaussian distribution (probabilistic PCA).

Ultimately, the main limitations to these algorithms is the cost due to the memory requirements: holding datasets with large dimension and large number of samples (as in recent neuroimaging cohorts) leads to inefficient computation. To solve this issue, online methods are particularly attractive [1].