A Multitone Model-Based Seismic Data Compression

Bo Liu; Mohamed Mohandes; Hilal Nuha; Mohamed Deriche; Faramarz Fekri; James H. Mcclellan

doi:10.1109/TSMC.2021.3077490

A Multitone Model-Based Seismic Data Compression

Bo Liu
, Mohamed Mohandes^*
, Hilal Nuha
, Mohamed Deriche
, Faramarz Fekri
, James H. Mcclellan

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

13 Scopus citations

Abstract

This work develops a model-based compression scheme for seismic data. First, seismic traces are modeled as multitone sinusoidal waves superposition. Each sinusoidal wave is regarded as a model component and is represented by a set of distinct parameters. Second, a parameter estimation algorithm for this model is proposed accordingly. In this algorithm, the parameters are estimated for each component sequentially. A suitable number of model components is determined by the level of the residuals energy. Next, the residuals are compressed using entropy coding or quantization coding techniques. The corresponding compression ratios are presented. Finally, the proposed model-based compression scheme is compared with the linear predictive coding (LPC) algorithm and the distributed principal component analysis (DPCA) algorithm on a real seismic database. The performance of the proposed model based is shown to be superior to that of the LPC and DPCA.

Original language	English
Pages (from-to)	1030-1040
Number of pages	11
Journal	IEEE Transactions on Systems, Man, and Cybernetics: Systems
Volume	52
Issue number	2
DOIs	https://doi.org/10.1109/TSMC.2021.3077490
State	Published - 1 Feb 2022

Bibliographical note

Publisher Copyright:
© 2013 IEEE.

Keywords

Data compression
model-based compression
parameter estimation
seismic traces
sinusoidal waves

ASJC Scopus subject areas

Software
Control and Systems Engineering
Human-Computer Interaction
Computer Science Applications
Electrical and Electronic Engineering

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10.1109/TSMC.2021.3077490

High Impact Paper Award 2022
Liu, B. (Recipient), Mohandes, M. (Recipient), Nuha, H. (Recipient), Deriche, M. (Recipient), Fekri, F. (Recipient) & McClellan, J. H. (Recipient), 2022
Prize

Cite this

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title = "A Multitone Model-Based Seismic Data Compression",

abstract = "This work develops a model-based compression scheme for seismic data. First, seismic traces are modeled as multitone sinusoidal waves superposition. Each sinusoidal wave is regarded as a model component and is represented by a set of distinct parameters. Second, a parameter estimation algorithm for this model is proposed accordingly. In this algorithm, the parameters are estimated for each component sequentially. A suitable number of model components is determined by the level of the residuals energy. Next, the residuals are compressed using entropy coding or quantization coding techniques. The corresponding compression ratios are presented. Finally, the proposed model-based compression scheme is compared with the linear predictive coding (LPC) algorithm and the distributed principal component analysis (DPCA) algorithm on a real seismic database. The performance of the proposed model based is shown to be superior to that of the LPC and DPCA.",

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author = "Bo Liu and Mohamed Mohandes and Hilal Nuha and Mohamed Deriche and Faramarz Fekri and Mcclellan, \{James H.\}",

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AU - Liu, Bo

AU - Mohandes, Mohamed

AU - Nuha, Hilal

AU - Deriche, Mohamed

AU - Fekri, Faramarz

AU - Mcclellan, James H.

PY - 2022/2/1

Y1 - 2022/2/1

N2 - This work develops a model-based compression scheme for seismic data. First, seismic traces are modeled as multitone sinusoidal waves superposition. Each sinusoidal wave is regarded as a model component and is represented by a set of distinct parameters. Second, a parameter estimation algorithm for this model is proposed accordingly. In this algorithm, the parameters are estimated for each component sequentially. A suitable number of model components is determined by the level of the residuals energy. Next, the residuals are compressed using entropy coding or quantization coding techniques. The corresponding compression ratios are presented. Finally, the proposed model-based compression scheme is compared with the linear predictive coding (LPC) algorithm and the distributed principal component analysis (DPCA) algorithm on a real seismic database. The performance of the proposed model based is shown to be superior to that of the LPC and DPCA.

AB - This work develops a model-based compression scheme for seismic data. First, seismic traces are modeled as multitone sinusoidal waves superposition. Each sinusoidal wave is regarded as a model component and is represented by a set of distinct parameters. Second, a parameter estimation algorithm for this model is proposed accordingly. In this algorithm, the parameters are estimated for each component sequentially. A suitable number of model components is determined by the level of the residuals energy. Next, the residuals are compressed using entropy coding or quantization coding techniques. The corresponding compression ratios are presented. Finally, the proposed model-based compression scheme is compared with the linear predictive coding (LPC) algorithm and the distributed principal component analysis (DPCA) algorithm on a real seismic database. The performance of the proposed model based is shown to be superior to that of the LPC and DPCA.

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KW - parameter estimation

KW - seismic traces

KW - sinusoidal waves

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A Multitone Model-Based Seismic Data Compression

Abstract

Bibliographical note

Keywords

ASJC Scopus subject areas

Access to Document

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Prizes

High Impact Paper Award 2022

Cite this