Coefficient Elimination Algorithm for Low Energy Distributed Arithmetic DCT Architectures

Darwish, T.; Bayoumi, Magdy

doi:10.1007/s11265-005-5270-6

Cited by 2 publications

(2 citation statements)

References 11 publications

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“…So a larger compression ratio can be got after quantization and coding. Discrete Cosine Transform (DCT) [3][4][5][6][7] is the most commonly used transform coding, it is considered as sub-optimal performance which is close to K-L transform.…”

Section: The Basic Principle Of Dct and Run-length Encoding 11 The Dct Transform Principlementioning

confidence: 99%

A Method of Lossy Compression for RGB565 Format True Color Image

Yan¹,

Lei²

2015

IJSIP

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In order to solve the issue of embedded image processing, a method of mixed compression for RGB565 format true color image is proposed. According to the inherent correlation of image data, the method adopts the discrete cosine transform and rearrangement to centralize the data that have higher correlation. Finally, it achieves the image compression by improving the run-length coding combined with statistical coding. Experiments show that the method can compress the true color images with RGB565 format effectively on the platform of ARM-Linux, and achieve a good compression ratio.

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Section: The Basic Principle Of Dct and Run-length Encoding 11 The Dct Transform Principlementioning

confidence: 99%

A Method of Lossy Compression for RGB565 Format True Color Image

Yan¹,

Lei²

2015

IJSIP

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“…A common practice towards the reduction of power consumption is the substitution of multipliers by distributed arithmetic (DA) [15,16] or coordinate rotation digital computer (CORDIC) circuits [17]. The implementations based on the aforementioned techniques are difficult to pipeline and, in addition, the required silicon area raises significantly with the transform length N [18] and the internal precision [19].…”

Section: Introductionmentioning

confidence: 99%

High throughput and energy efficient two‐dimensional inverse discrete cosine transform architecture

Tziortzios

Dokouzyannis

2013

IET Image Processing

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This study presents an energy efficient and high throughput two-dimensional inverse discrete cosine transform (IDCT) architecture, suitable for high speed and high quality image and video processing applications. The proposed architecture is based on the Arai-Agui-Nakajima IDCT algorithm. The high throughput rate is accomplished through the high degree of pipelining in the multipliers of the architecture. The distribution properties of the input signal, that is, the high percentage of zero coefficients, are exploited in order to lower power consumption. In particular, whenever an all zero column enters the architecture, the corresponding pipeline stages are adjacently deactivated in order to lower switching activity. Furthermore, a novel approach, regarding the transposition structure, is introduced. The all zero columns are not loaded in the transposition memory. Instead, they are encoded through a single bit in a parallel data path, thereby reducing the power consumption of the transposition process by 19%. The proposed architecture, implemented in a 65 nm field programmable gate array, provides a throughput rate of 2.722 Gpixel/s for a power consumption of 0.831 W. The experimental results and the comparison with previous work validate the efficiency and the suitability of the proposed implementation for high speed and high quality video decoding applications.

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Coefficient Elimination Algorithm for Low Energy Distributed Arithmetic DCT Architectures

Cited by 2 publications

References 11 publications

A Method of Lossy Compression for RGB565 Format True Color Image

A Method of Lossy Compression for RGB565 Format True Color Image

High throughput and energy efficient two‐dimensional inverse discrete cosine transform architecture

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