A high-throughput and area-efficient video transform core with a time division strategy

Yuan Ho Chen; Ruei Yuan Jou; Tsin Yuan Chang; Chih Wen Lu

doi:10.1109/TVLSI.2013.2290136

A high-throughput and area-efficient video transform core with a time division strategy

Yuan Ho Chen^*
, Ruei Yuan Jou
, Tsin Yuan Chang
, Chih Wen Lu

^*Corresponding author for this work

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

4 Scopus citations

Abstract

In this paper, a 2-D forward discrete cosine transform (FDCT) and inverse DCT (IDCT) core are presented. The proposed DCT core uses a single 1-D transform core and a transpose memory in order to achieve an area-efficient design. By exploiting the even and odd symmetrical properties of the FDCT and IDCT computations, the DCT core can share hardware resources. Furthermore, first-dimensional (1st-D) and second-dimensional (2nd-D) operations can be run simultaneously (1st-D FDCT, 2nd-D FDCT, 1st-D IDCT, 2nd-D IDCT) in the proposed 1-D core by using the proposed time division strategy, which shares hardware resources achieving a high-throughput design. Measurement results show that the DCT core achieves a throughput of 250 MP/s when simultaneously operating FDCT and IDCT, consuming only 19650 logic gates when fabricated using the TSMC 0.18-μ m} CMOS process. The DCT core achieves superior hardware efficiency compared to the existing cores.

Original language	English
Article number	6674066
Pages (from-to)	2268-2277
Number of pages	10
Journal	IEEE Transactions on Very Large Scale Integration (VLSI) Systems
Volume	22
Issue number	11
DOIs	https://doi.org/10.1109/TVLSI.2013.2290136
State	Published - 01 11 2014
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2014 IEEE.

Keywords

Area efficiency
forward and inverse discrete cosine transform
high throughput
time division strategy.

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10.1109/TVLSI.2013.2290136

Cite this

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title = "A high-throughput and area-efficient video transform core with a time division strategy",

abstract = "In this paper, a 2-D forward discrete cosine transform (FDCT) and inverse DCT (IDCT) core are presented. The proposed DCT core uses a single 1-D transform core and a transpose memory in order to achieve an area-efficient design. By exploiting the even and odd symmetrical properties of the FDCT and IDCT computations, the DCT core can share hardware resources. Furthermore, first-dimensional (1st-D) and second-dimensional (2nd-D) operations can be run simultaneously (1st-D FDCT, 2nd-D FDCT, 1st-D IDCT, 2nd-D IDCT) in the proposed 1-D core by using the proposed time division strategy, which shares hardware resources achieving a high-throughput design. Measurement results show that the DCT core achieves a throughput of 250 MP/s when simultaneously operating FDCT and IDCT, consuming only 19650 logic gates when fabricated using the TSMC 0.18-μ m\} CMOS process. The DCT core achieves superior hardware efficiency compared to the existing cores.",

keywords = "Area efficiency, forward and inverse discrete cosine transform, high throughput, time division strategy.",

author = "Chen, \{Yuan Ho\} and Jou, \{Ruei Yuan\} and Chang, \{Tsin Yuan\} and Lu, \{Chih Wen\}",

note = "Publisher Copyright: {\textcopyright} 2014 IEEE.",

year = "2014",

month = nov,

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doi = "10.1109/TVLSI.2013.2290136",

language = "英语",

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AU - Jou, Ruei Yuan

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Y1 - 2014/11/1

N2 - In this paper, a 2-D forward discrete cosine transform (FDCT) and inverse DCT (IDCT) core are presented. The proposed DCT core uses a single 1-D transform core and a transpose memory in order to achieve an area-efficient design. By exploiting the even and odd symmetrical properties of the FDCT and IDCT computations, the DCT core can share hardware resources. Furthermore, first-dimensional (1st-D) and second-dimensional (2nd-D) operations can be run simultaneously (1st-D FDCT, 2nd-D FDCT, 1st-D IDCT, 2nd-D IDCT) in the proposed 1-D core by using the proposed time division strategy, which shares hardware resources achieving a high-throughput design. Measurement results show that the DCT core achieves a throughput of 250 MP/s when simultaneously operating FDCT and IDCT, consuming only 19650 logic gates when fabricated using the TSMC 0.18-μ m} CMOS process. The DCT core achieves superior hardware efficiency compared to the existing cores.

AB - In this paper, a 2-D forward discrete cosine transform (FDCT) and inverse DCT (IDCT) core are presented. The proposed DCT core uses a single 1-D transform core and a transpose memory in order to achieve an area-efficient design. By exploiting the even and odd symmetrical properties of the FDCT and IDCT computations, the DCT core can share hardware resources. Furthermore, first-dimensional (1st-D) and second-dimensional (2nd-D) operations can be run simultaneously (1st-D FDCT, 2nd-D FDCT, 1st-D IDCT, 2nd-D IDCT) in the proposed 1-D core by using the proposed time division strategy, which shares hardware resources achieving a high-throughput design. Measurement results show that the DCT core achieves a throughput of 250 MP/s when simultaneously operating FDCT and IDCT, consuming only 19650 logic gates when fabricated using the TSMC 0.18-μ m} CMOS process. The DCT core achieves superior hardware efficiency compared to the existing cores.

KW - Area efficiency

KW - forward and inverse discrete cosine transform

KW - high throughput

KW - time division strategy.

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JF - IEEE Transactions on Very Large Scale Integration (VLSI) Systems

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M1 - 6674066

ER -

A high-throughput and area-efficient video transform core with a time division strategy

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