• Proceedings of the Korea Information Processing Society Conference
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• 2023.11a
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• pp.34-36
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• 2023

여러 인공지능 서비스의 보급은 초고성능 컴퓨팅 시스템 아키텍처의 변화를 야기하였고 다양한 계산 자원들의 활용이 모색되고 있다. 본 연구에서는 이러한 계산 자원들의 수용을 위해 범용적으로 사용되는 PCIe 버스를 기반으로 시스템 버스 확장 장치를 설계하고 구현하였다. PCIe 4.0 스위치를 기반으로 하는 확장 보드와 어댑터 카드를 개발하였고 GPU를 활용하여 실제 시스템으로의 활용 가능성을 검증하였다.

• Proceedings of the Korea Information Processing Society Conference
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• 2024.05a
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• pp.2-4
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• 2024

한국과학기술정보연구원(이하 KISTI)의 국가슈퍼컴퓨팅센터에서는 슈퍼컴퓨터 5호기인 Nurion과 Neuron 시스템을 구축하여 국내 연구자들에게 서비스하고 있다. 이 중에서 Neuron 시스템은 GPU 클러스터 시스템으로 SLURM Batch Scheduler를 이용하여 공동활용서비스를 제공하고 있다. 본 논문에서는 Neuron에서 사용 중인 SLURM Batch Scheduler와 리눅스의 crontab 기능을 이용하여 소프트웨어 장애가 발생한 계산노드를 자동으로 복구시키는 기능을 구현하여 장애처리 대기시간을 단축시키는 기법에 대해서 소개한다.

• Journal of Broadcast Engineering
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• v.18 no.6
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• pp.835-849
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• 2013

Joint Collaborative Team on Video Coding (JCT-VC), which have founded ISO/IEC MPEG and ITU-T VCEG, has standardized High Efficiency Video Coding (HEVC). Standardization of HEVC has started with purpose of twice or more coding performance compared to H.264/AVC. However, flexible and hierarchical coding block and recursive coding structure are problems to overcome of HEVC standard. Many fast encoding algorithms for reducing computational complexity of HEVC encoder have been proposed. However, it is hard to implement a real-time HEVC encoder only with those fast encoding algorithms. In this paper, for implementation of software-based real-time HEVC encoder, data-level parallelism using SIMD instructions and CPU/GPU multi-threading methods are proposed. And we also proposed appropriate operations and functional modules to apply the proposed methods on HM 10.0 software. Evaluation of the proposed methods implemented on HM 10.0 software showed 20-30fps for $832{\times}480$ sequences and 5-10fps for $1920{\times}1080$ sequences, respectively.

• Journal of Intelligence and Information Systems
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• v.26 no.4
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• pp.27-65
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• 2020

Many companies on information and communication technology make public their own developed AI technology, for example, Google's TensorFlow, Facebook's PyTorch, Microsoft's CNTK. By releasing deep learning open source software to the public, the relationship with the developer community and the artificial intelligence (AI) ecosystem can be strengthened, and users can perform experiment, implementation and improvement of it. Accordingly, the field of machine learning is growing rapidly, and developers are using and reproducing various learning algorithms in each field. Although various analysis of open source software has been made, there is a lack of studies to help develop or use deep learning open source software in the industry. This study thus attempts to derive a strategy for adopting the framework through case studies of a deep learning open source framework. Based on the technology-organization-environment (TOE) framework and literature review related to the adoption of open source software, we employed the case study framework that includes technological factors as perceived relative advantage, perceived compatibility, perceived complexity, and perceived trialability, organizational factors as management support and knowledge & expertise, and environmental factors as availability of technology skills and services, and platform long term viability. We conducted a case study analysis of three companies' adoption cases (two cases of success and one case of failure) and revealed that seven out of eight TOE factors and several factors regarding company, team and resource are significant for the adoption of deep learning open source framework. By organizing the case study analysis results, we provided five important success factors for adopting deep learning framework: the knowledge and expertise of developers in the team, hardware (GPU) environment, data enterprise cooperation system, deep learning framework platform, deep learning framework work tool service. In order for an organization to successfully adopt a deep learning open source framework, at the stage of using the framework, first, the hardware (GPU) environment for AI R&D group must support the knowledge and expertise of the developers in the team. Second, it is necessary to support the use of deep learning frameworks by research developers through collecting and managing data inside and outside the company with a data enterprise cooperation system. Third, deep learning research expertise must be supplemented through cooperation with researchers from academic institutions such as universities and research institutes. Satisfying three procedures in the stage of using the deep learning framework, companies will increase the number of deep learning research developers, the ability to use the deep learning framework, and the support of GPU resource. In the proliferation stage of the deep learning framework, fourth, a company makes the deep learning framework platform that improves the research efficiency and effectiveness of the developers, for example, the optimization of the hardware (GPU) environment automatically. Fifth, the deep learning framework tool service team complements the developers' expertise through sharing the information of the external deep learning open source framework community to the in-house community and activating developer retraining and seminars. To implement the identified five success factors, a step-by-step enterprise procedure for adoption of the deep learning framework was proposed: defining the project problem, confirming whether the deep learning methodology is the right method, confirming whether the deep learning framework is the right tool, using the deep learning framework by the enterprise, spreading the framework of the enterprise. The first three steps (i.e. defining the project problem, confirming whether the deep learning methodology is the right method, and confirming whether the deep learning framework is the right tool) are pre-considerations to adopt a deep learning open source framework. After the three pre-considerations steps are clear, next two steps (i.e. using the deep learning framework by the enterprise and spreading the framework of the enterprise) can be processed. In the fourth step, the knowledge and expertise of developers in the team are important in addition to hardware (GPU) environment and data enterprise cooperation system. In final step, five important factors are realized for a successful adoption of the deep learning open source framework. This study provides strategic implications for companies adopting or using deep learning framework according to the needs of each industry and business.

• Journal of Internet Computing and Services
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• v.12 no.3
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• pp.131-137
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• 2011

GPUs were originally designed for graphic processing, and GPGPUs are general-purpose GPUs for numerical computation with high performance and low electric power. In this paper, we implemented the parallel LU factorization program for GPGPUs. In CUDA, which is computational environment for Nvidia GPGPUs, domains are divided into blocks, and multi-threads compute each sub-blocks Simultaneously. In LU factorization program, computation order should be artificially decided due to the data dependence. To resolve the data dependancy, we suggested a parallel LU program for GPGPUs, and also explained parallel reduction algorithm for partial pivoting of LU factorization. We finally present performance analysis to show efficiency of the parallel LU factorization program based on multi-threads on GPGPUs.

• Proceedings of the Korean Society of Broadcast Engineers Conference
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• 2013.06a
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• pp.119-122
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• 2013

ITU-T VCEG 과 ISO/IEC MPEG 이 공동으로 구성한 JCT-VC (Joint Collaborative Team on Video Coding)이 표준화를 진행 중인 HEVC (High Efficiency Video Coding)은 H.264/AVC 대비 약 2 배의 압축효율을 갖는다. 하지만, 계층적 구조를 갖는 가변크기 블록의 사용과 재귀적 부호화 구조에 따른 인코더의 복잡도 증가는 개선해야 할 문제점으로 지적되고 있다. 본 논문에서는 현재 표준화가 진행 중인 HEVC 인코더의 실시간 구현을 위한 SIMD 명령어를 이용한 data-level 병렬화 기법, CPU 및 GPU 를 이용한 multi-threading 기법과 같은 다양한 병렬화 기법을 소개한다. 또한, 이러한 병렬화 기법들을 HEVC 인코더에 적용하기 위해 적합한 연산 및 기능 모듈에 대하여 소개한다. 본 연구를 통하여 HM (HEVC reference model)에 적용한 결과 $832{\times}480$ 영상의 경우 20-30fps 의 부호화 속도를 나타냈으며, $1920{\times}1080$ 영상의 경우 5-10fps 의 부호화 속도를 나타내었다.

• IEMEK Journal of Embedded Systems and Applications
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• v.15 no.2
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• pp.51-60
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• 2020

Optical character recognition (OCR) has been studied for decades because it is very useful in a variety of places. Nowadays, OCR's performance has improved significantly due to outstanding deep learning technology. Thus, there is an increasing demand for commercial-grade but affordable OCR systems. We have developed a low-cost, high-performance OCR system for the industry with the cheapest embedded developer kit that supports GPU acceleration. To achieve high accuracy for industrial use on limited computing resources, we chose a state-of-the-art text recognition algorithm that uses an end-to-end deep learning network as a baseline model. The model was then improved by replacing the feature extraction network with the best one suited to our conditions. Among the various candidate networks, EfficientNet-B3 has shown the best performance: excellent recognition accuracy with relatively low memory consumption. Besides, we have optimized the model written in TensorFlow's Python API using TensorFlow-TensorRT integration and TensorFlow's C++ API, respectively.

• Proceedings of the Korea Information Processing Society Conference
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• 2016.04a
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• pp.189-191
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• 2016

실시간 물리 기반 3D 시뮬레이션에서 연산속도는 매우 중요한 요소이다. 객체의 움직임이나 변형과 같은 현상들은 복잡한 연산을 통해서 계산되기 때문에 일반적으로 시뮬레이션의 정확도와 연산속도는 반비례 관계에 있다. 현재 출시되고 있는 대부분의 게임에서는 물체의 움직임을 정확하게 표현하기보다 연산량을 줄이기 위해 물체의 움직임이나 변형을 비슷하게 표현하는데 중점을 두고 있다. 본 논문에서는 이러한 문제를 해결하기 위하여 OpenGL 4.3의 Compute shader를 사용하여 다이내믹 시뮬레이션의 연산 작업을 GPU 병렬처리로 처리하였다. Compute shader에서 파티클의 움직임을 계산하고 Shader storage buffer object에 저장하고 파티클들의 작업량을 적절한 Workgroup의 크기로 나누어 할당하여 최적의 처리속도를 제공하도록 구현하였다. Compute shader에서 파티클의 움직임을 표현하기 위해서 수치해법 중의 하나인 Euler method를 사용하였으며 실험 결과 파티클의 수가 4,194,304개일 때 CPU 방법에 비해 약 182배 빠른 연산속도 결과를 보였다. 추후 Compute shader를 활용하여 연산량이 많은 분야에 적용 가능할 수 있을 것으로 기대한다.

• Journal of IKEEE
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• v.20 no.3
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• pp.303-306
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• 2016

In this paper, we propose a method to accelerate convolutional neural network by utilizing a GPGPU. Convolutional neural network is a sort of the neural network learning features of images. Convolutional neural network is suitable for the image processing required to learn a lot of data such as images. The convolutional layer of the conventional CNN required a large number of multiplications and it is difficult to operate in the real-time on the embedded environment. In this paper, we reduce the number of multiplications through Winograd convolution operation and perform parallel processing of the convolution by utilizing SIMT-based GPGPU. The experiment was conducted using ModelSim and TestDrive, and the experimental results showed that the processing time was improved by about 17%, compared to the conventional convolution.

• Journal of Korea Society of Digital Industry and Information Management
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• v.9 no.4
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• pp.59-67
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• 2013

Compared to the conventional Hardware-oriented base stations, Software Defined Radio (SDR)-based base station provides various advantages especially in flexibility and expandability. It enables the multimode capability required in 4th-generation (4G) environment which aims at a convergence network of various kinds of communication standards. However, since a single base station processes all data required in various multiple waveforms, the SDR base station faces a problem of data processing speed. In this paper, we propose a new concept of SDR base station system which adopts a parallel processing technology of clustering environment. We implemented a WiMAX system with SDR concept which adopts the Message Passing Interface (MPI) technology which enables the speed-up operations. In order to maximize the efficiency of parallel processing in signal processing, we analyze how the algorithm at each of modules is related to data to be processed. Through the implemented system, we show a drastic improvement in operation time due to parallel processing using the proposed MPI technology. In addition, we demonstrate a feasibility of SDR system for 4G or even beyond-4G as well.