Greedy randomized and maximal weighted residual Kaczmarz methods with oblique projection

Fang Wang; Weiguo Li; Wendi Bao; Li Liu; Fang Wang; Weiguo Li; Wendi Bao; Li Liu

doi:10.3934/era.2022062

Electronic Research Archive

2022, Volume 30, Issue 4: 1158-1186. doi: 10.3934/era.2022062

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Greedy randomized and maximal weighted residual Kaczmarz methods with oblique projection

China University of Petroleum, Qingdao 266580, China

Academic Editor: Xian-Ming Gu

Received: 08 January 2022 Revised: 21 February 2022 Accepted: 01 March 2022 Published: 14 March 2022

For solving large-scale consistent linear system, a greedy randomized Kaczmarz method with oblique projection and a maximal weighted residual Kaczmarz method with oblique projection are proposed. By using oblique projection, these two methods greatly reduce the number of iteration steps and running time to find the minimum norm solution, especially when the rows of matrix are highly linearly correlated. Theoretical proof and numerical results show that the greedy randomized Kaczmarz method with oblique projection and the maximal weighted residual Kaczmarz method with oblique projection are more effective than the greedy randomized Kaczmarz method and the maximal weighted residual Kaczmarz method respectively.
- oblique projection,
- convergence property,
- Kaczmarz method,
- correlation,
- large linear system
Citation: Fang Wang, Weiguo Li, Wendi Bao, Li Liu. Greedy randomized and maximal weighted residual Kaczmarz methods with oblique projection[J]. Electronic Research Archive, 2022, 30(4): 1158-1186. doi: 10.3934/era.2022062

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Abstract

For solving large-scale consistent linear system, a greedy randomized Kaczmarz method with oblique projection and a maximal weighted residual Kaczmarz method with oblique projection are proposed. By using oblique projection, these two methods greatly reduce the number of iteration steps and running time to find the minimum norm solution, especially when the rows of matrix are highly linearly correlated. Theoretical proof and numerical results show that the greedy randomized Kaczmarz method with oblique projection and the maximal weighted residual Kaczmarz method with oblique projection are more effective than the greedy randomized Kaczmarz method and the maximal weighted residual Kaczmarz method respectively.

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