Your search keyword '"Kukreja, Navjot"' showing total 2 results

1. Lossy checkpoint compression in full waveform inversion: a case study with ZFPv0.5.5 and the overthrust model.

Author

Kukreja, Navjot, Hückelheim, Jan, Louboutin, Mathias, Washbourne, John, Kelly, Paul H. J., and Gorman, Gerard J.

Subjects

*GEOPHYSICAL prospecting, *LOSSY data compression, *APPROXIMATION error, *ADJOINT differential equations, *INVERSE problems

Abstract

This paper proposes a new method that combines checkpointing methods with error-controlled lossy compression for large-scale high-performance full-waveform inversion (FWI), an inverse problem commonly used in geophysical exploration. This combination can significantly reduce data movement, allowing a reduction in run time as well as peak memory. In the exascale computing era, frequent data transfer (e.g., memory bandwidth, PCIe bandwidth for GPUs, or network) is the performance bottleneck rather than the peak FLOPS of the processing unit. Like many other adjoint-based optimization problems, FWI is costly in terms of the number of floating-point operations, large memory footprint during backpropagation, and data transfer overheads. Past work for adjoint methods has developed checkpointing methods that reduce the peak memory requirements during backpropagation at the cost of additional floating-point computations. Combining this traditional checkpointing with error-controlled lossy compression, we explore the three-way tradeoff between memory, precision, and time to solution. We investigate how approximation errors introduced by lossy compression of the forward solution impact the objective function gradient and final inverted solution. Empirical results from these numerical experiments indicate that high lossy-compression rates (compression factors ranging up to 100) have a relatively minor impact on convergence rates and the quality of the final solution. [ABSTRACT FROM AUTHOR]

Published

2022

2. Lossy Checkpoint Compression in Full Waveform Inversion.

Author

Kukreja, Navjot, Hückelheim, Jan, Louboutin, Mathias, Washbourne, John, Kelly, Paul H. J., and Gorman, Gerard J.

Subjects

*LOSSY data compression, *GEOPHYSICAL prospecting, *APPROXIMATION error, *INVERSE problems, *GRAPHICS processing units

Abstract

This paper proposes a new method that combines check -pointing methods with error-controlled lossy compression for large-scale high-performance Full-Waveform Inversion (FWI), an inverse problem commonly used in geophysical exploration. This combination can signif- icantly reduce data movement, allowing a reduction in run time as well as peak memory. In the Exascale computing era, frequent data transfer (e.g., memory bandwidth, PCIe bandwidth for GPUs, or network) is the performance bottleneck rather than the peak FLOPS of the processing unit. Like many other adjoint-based optimization problems, FWI is costly in terms of the number of floating-point operations, large memory foot- print during backpropagation, and data transfer overheads. Past work for adjoint methods has developed checkpointing methods that reduce the peak memory requirements during backpropagation at the cost of additional floating-point computations. Combining this traditional checkpointing with error-controlled lossy compression, we explore the three-way tradeoff between memory, precision, and time to solution. We investigate how approximation errors introduced by lossy compression of the forward solution impact the objective function gradient and final inverted solution. Empirical results from these numerical experiments indicate that high lossy-compression rates (compression factors ranging up to 100) have a relatively minor impact on convergence rates and the quality of the final solution. [ABSTRACT FROM AUTHOR]

Published

2020