• Proceedings of the Korea Information Processing Society Conference
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• 2013.11a
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• pp.824-827
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• 2013

블록암호를 사용하여 암호화 할 때 이를 효율적이고 안전하게 암호화하기 위해서 운영모드를 이용한다. 이 때 유효한 암호문이 블록길이와 일치하지 않을 경우 패딩을 사용하게 된다. 만약 공격자가 이 패딩의 옳고 그름을 판단하는 오라클을 알 수 있다면 임의의 암호문에 대응하는 평문을 찾는 공격을 할 수 있는데 이를 패딩 오라클 공격이라 한다. 본 논문에서는 각 패딩방법에 대해 알아보고 CBC 운영 모드의 패딩 오라클 공격에 대한 안전성에 대해 논한다.

• Journal of the Korea Academia-Industrial cooperation Society
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• v.19 no.3
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• pp.1-7
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• 2018

The IoT environment provides an infinite variety of services using many different devices and networks. The development of the IoT environment is directly proportional to the level of security that can be provided. In some ways, lightweight cryptography is suitable for IoT environments, because it provides security, higher throughput, low power consumption and compactness. However, it has the limitation that it must form a new cryptosystem and be used within a limited resource range. Therefore, it is not the best solution for the IoT environment that requires diversification. Therefore, in order to overcome these disadvantages, this paper proposes a method suitable for the IoT environment, while using the existing block cipher algorithm, viz. the lightweight cipher algorithm, and keeping the existing system (viz. the sensing part and the server) almost unchanged. The proposed BCL architecture can perform encryption for various sensor devices in existing wire/wireless USNs (using) lightweight encryption. The proposed BCL architecture includes a pre/post-processing part in the existing block cipher algorithm, which allows various scattered devices to operate in a daisy chain network environment. This characteristic is optimal for the information security of distributed sensor systems and does not affect the neighboring network environment, even if hacking and cracking occur. Therefore, the BCL architecture proposed in the IoT environment can provide an optimal solution for the diversified IoT environment, because the existing block cryptographic algorithm, viz. the lightweight cryptographic algorithm, can be used.

• Journal of the Korea Institute of Information and Communication Engineering
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• v.20 no.12
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• pp.2333-2340
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• 2016

A LEA (Lightweight Encryption Algorithm) crypto-processor was designed, which supports three master key lengths of 128/ 192/256-bit, ECB and CTR modes of operation. To achieve high throughput rate, the round transformation block was designed with 128 bits datapath and a pipelined structure of 16 stages. Encryption/decryption is carried out through 12/14/16 pipelined stages according to the master key length, and each pipelined stage performs round transformation twice. The key scheduler block was optimized to share hardware resources that are required for encryption, decryption, and three master key lengths. The round keys generated by key scheduler are stored in 32 round key registers, and are repeatedly used in round transformation until master key is updated. The pipelined LEA processor was verified by FPGA implementation, and the estimated performance is about 8.3 Gbps at the maximum clock frequency of 130 MHz.

• Journal of the Korea Institute of Information and Communication Engineering
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• v.22 no.10
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• pp.1398-1404
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• 2018

The Blockchain technology could represent a solution to unexpected problems. In modern society, the domain of value has become diversified. The Crypto currency would replace the area that conventional currency could not function. The Japanese government recognized the Bitcoin as an official currency from April 2017 through amendment of the Money Transfer Act in 2016, and has been leading the related regulation policy recently. This paper examines the policy strategy of the Japanese government that is leading the current policy related to the Crypto currency market. The sequence of this paper is as follows: Coordination Process of Japanese Government's Crypto currency Policy of Special Mission Committee on IT Strategy as a Coordinator, Amendment of the Fund Settlement Act and the Establishment of a Self-Regulation Organizations in Crypto currency and Japan's Crypto currency Taxation and Supplementary System.

• Journal of the Korea Institute of Information Security & Cryptology
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• v.15 no.1
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• pp.29-40
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• 2005

In this paper we consider the security of recently proposed software-orienred stram cipher HELIX, SCREAM, MUGI, and PANAMA against algebraic attacks. Algebraic attack is a key recovery attack by solving an over-defined system of multi-variate equations with input-output pairs of an algorithm. The attack was firstly applied to block ciphers with some algebraic properties and then it has been mon usefully applied to stream ciphers. However it is difficult to obtain over-defined algebraic equations for a given cryptosystem in general. Here we analyze recently proposed software-oriented stream ciphers by constructing a system of equations for each cipher. furthermore we propose three design considerations of software-oriented stream ciphers.

• Proceedings of the Korean Institute of Information and Commucation Sciences Conference
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• 2015.10a
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• pp.409-411
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• 2015

본 논문은 128/192/256-비트의 마스터키 길이를 지원하는 경량 블록 암호 알고리즘 CLEFIA-128/192/256의 FPGA 설계에 대하여 기술한다. 라운드키 생성을 위한 중간키 생성과 라운드 변환이 단일 데이터 프로세싱 블록으로 처리되도록 설계하였으며, 변형된 GFN(Generalized Feistel Network) 구조와 키 스케줄링 방법을 적용하여 데이터 프로세싱 블록과 키 스케줄링 블록의 회로를 단순화시켰다. Verilog HDL로 설계된 CLEFIA 크립토 프로세서를 FPGA로 구현하여 정상 동작함을 확인하였다. Vertex5 XC5VSX50T FPGA에서 1,563개의 LUT FilpFlop pairs로 구현되었으며, 최대 112 Mhz 81.5/69/60 Mbps의 성능을 갖는 것으로 예측되었다.

• Proceedings of the Korea Information Processing Society Conference
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• 2018.10a
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• pp.288-291
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• 2018

블록체인은 암호화폐의 기반이 되는 기술로 데이터를 P2P 분산 방식으로 체인 형태로 기록하여 보안성과 안전성을 갖?다. 중앙 집권화에서 벗어나 사용자들의 네트워크에서 자유롭고 안전한 거래를 가능하게 하는 블록체인은 현재 스마트 계약, 암호화폐, 개인 정보 인증 등 다양한 방법으로 활용되고 있다. 블록체인 사용자들은 거래의 안전성을 위해 채굴이라는 과정으로 블록을 인증하는데 절반 이상의 해시파워를 가진 공격자가 거래내역을 조작하는 것이 51% attack이다. 채굴자들은 채굴을 위해 전문 장비를 개발하고 이익을 도모하기 위해 모이면서 큰 집단으로 모이면서 51% attack에 대한 공격가능성이 높아졌고 실제로 엄청난 피해를 입힌 공격 사례가 있다. 따라서 본 논문은 51% attack의 사례와 기존 대응방안인 PoS 방식과 dPoW 방식 및 각 방식에 대한 한계를 분석하였고 이를 보완한 새로운 블록체인 모델을 제안한다.

• Proceedings of the Korean Institute of Information and Commucation Sciences Conference
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• 2016.10a
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• pp.155-157
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• 2016

한국 표준 블록암호 알고리듬 ARIA(Academy, Research Institute, Agency)와 미국 표준인 AES(Advanced Encryption Standard) 알고리듬은 128-비트 블록 길이를 지원하고 SPN(substitution permutation network) 구조를 특징으로 가져 서로 유사한 형태를 지닌다. 본 논문에서는 ARIA와 AES를 선택적으로 수행하는 ARIA-AES 통합 프로세서를 효율적으로 구현하였다. Verilog HDL로 설계된 ARIA-AES 통합 프로세서를 Virtex5 FPGA로 구현하여 정상 동작함을 확인하였고, $0.18{\mu}m$ 공정의 CMOS 셀 라이브러리로 100KHz의 동작주파수에서 합성한 결과 39,498 GE로 구현되었다.

• Journal of the Korea Institute of Information Security & Cryptology
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• v.29 no.3
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• pp.477-489
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• 2019

In this paper, we experimentally verify the expected differential probability under the markov cipher assumption and the distribution of the differential probability. Firstly, we validate the expected differential probability of 6round-PRESENT of the lightweight block cipher under the markov cipher assumption by analyzing the empirical differential probability. Secondly, we demonstrate that even though the expected differential probability under the markov cipher assumption seems valid, the empirical distribution does not follow the well-known distribution of the differential probability. The results was deduced from the 4round-GIFT. Finally, in order to analyze whether the key-schedule affects the mis-matching phenomenon, we collect the results while changing the XOR positions of round keys on GIFT. The results show that the key-schedule is not the only factor to affect the mis-matching phenomenon. Leveraging on GPGPU technology, the data collection process can be performed about 157 times faster than using CPU only.

• Journal of the Korea Institute of Information Security & Cryptology
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• v.32 no.5
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• pp.751-763
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• 2022

With the recent increase in spending growth in the IoT sector worldwide, the importance of lightweight block ciphers to encrypt them is also increasing. The lightweight block cipher PIPO algorithm proposed in ICISC 2020 is an SPN-structured cipher using an unbalanced bridge structure. The white box attack model refers to a state in which an attacker may know the intermediate value of the encryption operation. As a technique to cope with this, Chow et al. proposed a white box implementation technique and applied it to DES and AES in 2002. In this paper, we propose a white box PIPO applying a white box implementation to a lightweight block cipher PIPO algorithm. In the white box PIPO, the size of the table decreased by about 5.8 times and the calculation time decreased by about 17 times compared to the white box AES proposed by Chow and others. In addition, white box PIPO was used for mobile security products, and experimental results for each test case according to the scope of application are presented.