Cultural advice

The Australian National University acknowledges, celebrates and pays our respects to the Ngunnawal and Ngambri people of the Canberra region and to all First Nations Australians on whose traditional lands we meet and work, and whose cultures are among the oldest continuing cultures in human history.

Aboriginal and Torres Strait Islander peoples are advised that ANU Library collections may include images, names, voices, and other representations of deceased persons.

Material in the collection may contain terms, language or views that reflect the period in which the item was created and may be considered inappropriate today.

Scalability and fault tolerance of the alternating direction method of multipliers for sparse grids

Loading...
Thumbnail Image

Date

Authors

Khakhutskyy, Valeriy
Pflüger, Dirk
Hegland, Markus

Journal Title

Journal ISSN

Volume Title

Publisher

IOS Press BV

Access Statement

Research Projects

Organizational Units

Journal Issue

Abstract

In this work we investigate the alternating direction method of multipliers (ADMM) for the solution of regression problems using sparse grids on parallel and distributed systems. This method was successfully used in a number of applications for the parallel processing of large datasets. While the method allows for both parallelization in the data and in the degrees of freedom, research was mostly focused on the first approach so far. In this work we consider and compare both approaches. On the one hand, we present the grid-splitting algorithm for hierarchical sparse grids which we employ to deal with vast datasets and high dimensions. The hierarchical basis of sparse grids is inherently difficult to parallelize in the degrees of freedom as ignoring the hierarchical structure affects stability. Here we use the property that a regular sparse grid with the maximum level n in d dimensions can be split into two d-dimensional grids with level n-1 and one d-1-dimensional grid with level n. The method also converges if asynchronous one-sided communication is used. It thus increases the robustness of the algorithm and introduces fault tolerance-the essential properties of parallel algorithms for next-generation supercomputers. On the other hand, we study the data parallelization of the sparse grid ADMM algorithm using one-sided communication. While the reduction of the parallel runtime is lower than for grid splitting, this method does not require changes of the sparse grid learning algorithm and can be used with existing software. Due to its fast convergence the method is suited for dealing with large datasets.

Description

Citation

Source

Book Title

Parallel Computing: Accelerating Computational Science and Engineering (CSE)

Entity type

Publication

Access Statement

License Rights

Restricted until