• Proceedings of the Korean Information Science Society Conference
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• 2002.04a
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• pp.4-6
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• 2002

최근 폭발적으로 증가하는 대량의 정보를 효율적으로 관리하기 위해서 서버에 개별적으로 연결되던 저장장치를 고속의 전용 네트워크에 직접 연결하고 이를 여러 서버가 공유하는 SAN(Storage Area Network)이 등장했다. SAN을 보다 효과적으로 활용할 수 있도록 SAN 운영체제들은 여러 저장장치를 하나의 커다란 저장장치로 보이게 하는 저장장치 가상화를 지원한다. 저장장치 가상화의 핵심적인 역할을 하는 것이 바로 논리볼륨 관리자이다. 논리볼륨 관리자는 논리주소 블록을 실제 디스크의 물리블록으로 매핑시키는 매핑 관리자를 통해 가상화를 실현한다. 이 논문에서는 효율적인 논리볼륨 관리자를 위해 매핑 관리자와 자유공간 관리자의 기능 향상에 대한 방법을 찾고 이를 반영한 매핑 관리자와 자유공간 관리자를 설계하고 구현한다. 더불어 이 논문의 매핑 관리기법은 특정 시점의 볼륨이미지를 유지할 수 있는 스냅샷과 시스템을 정지시키지 않고 SAN에 디스크를 추가할 수 있는 온라인 재구성 기능을 지원한다.

• Proceedings of the Korea Society of Information Technology Applications Conference
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• 2002.11a
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• pp.350-362
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• 2002

A new architecture called the Storage Area Network(SAN) was developed in response to the requirements of high availability of data, scalable growth and system performance In order to use SAN more efficiently, must SAN operating systems support storage virtualization concepts that allow users to view physical storage devices attached to SAN as a large volume virtually. A logical volume manager Days a key role in storage virtualization it realizes the storage virtualization by mapping logical addresses to physical addresses. In this paper, we design and implement an efficient and flexible mapping method for logical volume manager. The mapping method in this paper supports a snapshot that preserves a volume image at certain time and on-line reorganization to allow users to add or remove storage devices to SAN even while the system is running.

• Proceedings of the Korea Society for Industrial Systems Conference
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• 2002.11a
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• pp.350-362
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• 2002

A new architecture called the Storage Area Network(SAN) was developed in response to the requirements of high availability of data scalable growth, and system performance. In order to use SAN more efficiently, most SAN operating systems support storage virtualization concepts that allow users to view physical storage devices attached to SAN as a large volume virtually. A logical volume manager plays a key role in storage virtualization. It realizes the storage virtualization by mapping logical addresses to physical addresses. In this paper, we design and implement an efficient and flexible mapping method for logical volume manager. The nin method in this paper supports a snapshot that preserves a volume image at certain time and on-line reorganization to allow users to add or remove storage devices to SAN even while the system is running.

• Journal of KIISE:Computing Practices and Letters
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• v.9 no.6
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• pp.718-731
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• 2003

SAN(Storage Area Network) was developed in response to the requirements of high availability of data, scalable growth, and system performance. In order to use the SAN more efficiently, most of the SAN operating software supports storage virtualization concepts that allow users to view physical storage devices of the SAN as a large volume. A logical volume manager plays a key role in storage virtualization. It realizes the storage virtualization by mapping logical addresses to physical addresses. In this paper, we design and implement an efficient and flexible mapping method for the logical volume manager. Additionally we also design and implement a free space management method for flexible mapping. Our mapping method supports a snapshot that preserves a volume image at certain time and on-line reorganization to allow users to add or remove storage devices to and from the SAN even while the system is running. To justify our mapping method, we compare it with the mapping method of the GFS (Global File System) through various experiments.

• Journal of Internet Computing and Services
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• v.3 no.5
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• pp.73-85
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• 2002

A new architecture coiled the Storage Area Network(SAN) was developed in response to the requirements of high availability of data, scalable growth, and system performance, In order to use SAN more efficiently, most SAN operating system support storage virtualization concepts that allow users to view physical storage devices attached to SAN as a large volume virtually. A logical volume manager plays a key role in storage virtualization. It realizes the storage virtualization by mapping logical addresses to physical addresses, In this paper, we design and implement an efficient and flexible mapping method for logical volume manager. Additionally, to aid flexible mapping, we also design and implement free space management method, The mapping method in this paper supports a snapshot that preserves a volume image at certain time and on-line reorganization to allow users to add or remove storage devices to SAN even while the system is running.

• Journal of KIISE:Computing Practices and Letters
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• v.10 no.1
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• pp.99-113
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• 2004

A new architecture called SAN(Storage Area Network) was developed in response to the requirements of high availability of data, scalable growth, and system performance. In order to use SAN more efficiently, most of SAN operating softwares support storage virtualization concepts that allow users to view physical storage devices attached to SAN as a large volume virtually h logical volume manager plays a key role in storage virtualization. It realizes the storage virtualization by mapping logical addresses to physical addresses. A logical volume manager also supports a snapshot that preserves a volume image at certain time and on-line reorganization to allow users to add/remove storage devices to/from SAN even while the system is running. To support the snapshot and the on-line reorganization, most logical volume managers have used table based mapping methods. However, it is very difficult to manage mapping table because the mapping table is large in proportion to a storage capacity. In this paper, we design and implement an efficient and flexible hybrid mapping method based on mathematical equations. The mapping method in this paper supports a snapshot and on-line reorganization. The proposed snapshot and on-line reorganization are performed on the reserved area which is separated from data area of a volume. Due to this strategy normal I/O operations are not affected by snapshot and reorganization. Finally, we show the superiority of our proposed mapping method through various experiments.

• Proceedings of the Korea Society of Information Technology Applications Conference
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• 2002.11a
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• pp.520-532
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• 2002

A new architecture called the Storage Area Network(SAN) was developed in response to the requirements of high availability of data scalable growth and system performance. In order to use SAN more efficiently, most SAN operating systems support storage virtualization concepts that allow users to view physical storage devices attached to SAN as a large volume virtually. A logical volume manager plays a key role in storage virtualization. In order for mapping managers to process snap-shots and reorganizations, an efficient freespace manager is required, and it affects the overall performance of logical volume. In this thesis, we design and implement a freespace manager for logical volume manager. The freespace manager efficiently allocates physical blocks for logical blocks. Also, it processes space allocation requests for suports snapshots and reorganizations.

• Proceedings of the Korea Society for Industrial Systems Conference
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• 2002.11a
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• pp.520-532
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• 2002

A new architecture called the Storage Area Network(SAN) was developed in response to the requirements of high availability of data, scalable growth, and system performance. In order to use SAN more efficiently, most SAN operating systems support storage virtualization concepts that allow users to view physical storage devices attached to SAN as a large volume virtually. A logical volume manager plays a key role in storage virtualization. In order for mapping managers to process snap-shots and reorganizations, an efficient freespace manager is required, and it affects the overall performance of logical volume. In this thesis, we design and implement a freespace manager for logical volume manager. The freespace manager efficiently allocates physical blocks for logical blocks. Also, it processes space allocation requests for supports snapshots and reorganizations.

• Proceedings of the Korean Information Science Society Conference
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• 1998.10b
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• pp.359-361
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• 1998

MIDAS-II(Multiuser Index-based Data Access System II)는 한국전자통신연구원에서 개발한 바다 DBMS의 저장 시스템이다. MIDAS-II에서 데이터의 논리적 저장 단위인 파일을 저장하는 디스크 영역을 볼륨(volume)이라 부른다. 본 논문에선,s MIDAS-II가 대용량 멀티미디어 데이터 서버의 저장 시스템으로 가능하도록 광 디스크 쥬크박스 또는 테이프 라이브러리와 같이 복수 개의 자장매체(platter, 예를 들어 디스크 또는 카트리지 테이프)로 구성된 Tera 바이트 급의 3차 저장장치를 장착할 경우 이를 위한 볼륨 구조를 제안한다. 제안된 볼륨 구조에서는 3차 저장장치를 활용할 경우 발생되는 성능 저하를 극복하기 위하여 디스크 캐쉬 영역을 두고 있으며, 이를 활용하여 3차 저장장치에 저장된 데이터를 읽지 전용 모드로 검색하는 것 뿐 아니라 LOB을 비롯한 새로운 데이터를 생성하여 3차 저장장치에 저장하는 과정을 모두 효율적으로 지원한다. 그리고, 응용 프로그램에게 볼륨이 저장된 저장장치에 대한 투명성을 제공하기 위하여 기존 MIDAS-II API를 그대로 유지하였으므로 기존의 디스크 볼륨과 제안된 3차 저장장치 볼륨이 모두 기존 API를 통해 접근이 가능하다. 또한, 3차 저장장치의 각 저장매체로서 WORM의 사용도 가능하며, 각 저장매체는 데이터와 해당 메타 데이터를 함께 저장하여 저장매체로서의 독립성을 지니게 됨으로써 개별적으로 저장장치에/로부터 삽입/제거할 수 있게 하였다

• Proceedings of the Korea Information Processing Society Conference
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• 2002.04a
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• pp.691-694
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• 2002

현재 인터넷 환경은 다양한 멀티미디어 정보의 폭발적인 증가로 인해 정보의 효율적인 저장 및 관리, 가공을 위한 볼륨 관리자가 요구되고 있다. 따라서 본 논문은 대용량의 데이터 관리를 요구하는 SAN (Storage Area Network)환경에서 대용량 저장 장치 구성을 위한 LDP(Logical Disk Pool)를 설계하고 그 성능을 평가하였다. LDP는 여러 개의 물리적 디스크를 물리적 개념이 아닌 논리적 저장 공간의 개념을 사용하여 관리함으로써, 기존 물리 디스크의 크기 제한과 확장성 문제를 해결하여 SAN환경에 적합한 대용량 저장장치 구성을 가능하게 한다.