Optimized Memory Allocation and Power Minimization for FPGA-Based Image Processing

Garcia, Paulo; Bhowmik, Deepayan; Stewart, Robert; Michaelson, Greg; Wallace, Andrew M.

doi:10.3390/jimaging5010007

Cited by 24 publications

(11 citation statements)

References 40 publications

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“…To address this issue, assume that the ' X ' image or frame will be stored as an array (A) of 8-bit elements. The 'A' array has columns and rows and is usually stored in BRAM [11] like a row by row or a column by column manner (ixj). Generally, the computer or processor does not keep track of each element of an array's address.…”

Section: Dark Channel Prior Methods (Dcm)mentioning

confidence: 99%

Fast and memory efficient de-hazing technique for real-time computer vision applications

2020

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Some features of an image may spoil due to fog or haze, smoke. These images lose their brightness due to air-light scattering. It offers troublesomeness to the people lives in hill and fog regions of the world. This paper proposed two key aspects. One is a modified dark-channel method based on the median for eliminating the refine the transmission map as well as halos and artifacts, another important aspect is a memory-efficient row-based arrangement of the pixels for real-time applications. The advantage of this method is air-light can be predicted directly from the modified dark channel and also accurate transmission map can be estimated. This method is compared with other existing four algorithms. Our proposed method analyzed in terms of Peak Signal to Noise Ratio (PSNR), Average Time cost (ATC), percentage of haze improvement (PHI), average contrast of output image (ACOI), Mean Squared Error (MSE) and Structural Similarity Index (SSIM). The quality of the output de-haze image of our algorithm over existing algorithms is more. It has taken less computation time, equal MSE, with higher SSIM and has more percentage of haze improved over existing methods.Keywords Real-time image/video de-hazing · Median filter · Blocked random access memory (BRAM) · Row based pixel arrangement · Dark channel prior · Guided filter * Prathap Soma, prathap.

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Section: Dark Channel Prior Methods (Dcm)mentioning

confidence: 99%

Fast and memory efficient de-hazing technique for real-time computer vision applications

2020

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“…As a rule, it is very important to choose the state codes leading to minimizing the values of L( f i ) [8]. There are a lot of methods of state assignment targeting FPGA-based design [17][18][19][20][21]24,25]. There is an opinion that JEDI [8] is the best of them [4].…”

Section: Y T Embermentioning

confidence: 99%

Encoding of Terms in EMB-Based Mealy FSMs

et al. 2020

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A method is proposed targeting implementation of FPGA-based Mealy finite state machines. The main goal of the method is a reduction for the number of look-up table (LUT) elements and their levels in FSM logic circuits. To do it, it is necessary to eliminate the direct dependence of input memory functions and FSM output functions on FSM inputs and state variables. The method is based on encoding of the terms corresponding to rows of direct structure tables. In such an approach, only terms depend on FSM inputs and state variables. Other functions depend on variables representing terms. The method belongs to the group of the methods of structural decomposition. The set of terms is divided by classes such that each class corresponds to a single-level LUT-based circuit. An embedded memory block (EMB) generates codes of both classes and terms as elements of these classes. The mutual using LUTs and EMB allows diminishing chip area occupied by FSM circuit (as compared to its LUT-based counterpart). The simple sequential algorithm is proposed for finding the partition of the set of terms by a determined number of classes. The method is based on representation of an FSM by a state transition table. However, it can be used for any known form of FSM specification. The example of synthesis is shown. The efficiency of the proposed method was investigated using a library of standard benchmarks. We compared the proposed with some other known design methods. The investigations show that the proposed method gives better results than other discussed methods. It allows the obtaining of FSM circuits with three levels of logic and regular interconnections.

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“…Garcia et al [ 2 ] worked on the thesis that the image processing operations which require random access to the whole frame (including iterative algorithms) are particularly difficult to realise in FPGAs. They investigate the mapping of a frame buffer onto the memory resources of an FPGA, and explore the optimal mapping onto combinations of configurable on-chip memory blocks.…”

Section: Contributionsmentioning

confidence: 99%

Image Processing Using FPGAs

Bailey

2019

J. Imaging

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Nine articles have been published in this Special Issue on image processing using field programmable gate arrays (FPGAs). The papers address a diverse range of topics relating to the application of FPGA technology to accelerate image processing tasks. The range includes: Custom processor design to reduce the programming burden; memory management for full frames, line buffers, and image border management; image segmentation through background modelling, online K-means clustering, and generalised Laplacian of Gaussian filtering; connected components analysis; and visually lossless image compression.

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Optimized Memory Allocation and Power Minimization for FPGA-Based Image Processing

Cited by 24 publications

References 40 publications

Fast and memory efficient de-hazing technique for real-time computer vision applications

Fast and memory efficient de-hazing technique for real-time computer vision applications

Encoding of Terms in EMB-Based Mealy FSMs

Image Processing Using FPGAs

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