• Journal of the Korea Institute of Information and Communication Engineering
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• v.7 no.7
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• pp.1478-1482
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• 2003

In this paper. Rijndael cipher algorithm is implemented by a hardware. It was selected as the AES(Advanced Encryption Standard) by NIST. It has structure that round operation divided into 2 subrounds and subrounds are pipelined to calculate efficiently. It takes 5 clocks for one-round. The AES-128 cipher algorithm is implemented for hardware by ALTERA FPGA, and, analyzed the performance. The AES-128 cipher algorithm has approximately 424 Mbps encryption rate for 166Mhz max clock frequency. In case of decryption, it has 363 Mbps decryption rate fu 142Mhz max clock frequency. In case of cipher core, it has 320Mbps encryptionㆍdecryption rate for 125Mhz max clock frequency.

• Proceedings of the Korean Institute of Information and Commucation Sciences Conference
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• 2003.10a
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• pp.196-198
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• 2003

In this paper, Rijndal cipher algorithm is implemented by a hardware. It is selected as the AES(Advanced Encryption Standard) by NIST. The processor has structure that round operation divided into 2 subrounds and subrounds are pipelined to calculate efficiently. It takes 5 clocks for one-round. The AES-128 cipher algorithm is implemented for hardware by ALTERA FPGA, and then, analyzed the performance. The AES-128 cipher algorithm has approximately 424 Mbps encryption rate for 166Mhz max clerk frequency. In case of decryption, it has 363 Mbps decryption rate for 142Mhz max clock frequency.

• Journal of the Korea Institute of Information Security & Cryptology
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• v.11 no.2
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• pp.3-12
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• 2001

Currently, the superscalar architecture dominates todays microprocessor marketplase. As, more transistors are integrated onto larger die, however, an on-chip multiprocessor is regarded as a promising alternative to the superscalar microprocessor. This paper examines the behavior of the next generation block encryption algorithms RC6 and Rijndael on the on-chip multiprocessing microprocessor. Based on the simulation results by using a program-driven simulator, the on-chip multiprocessor can exploit thread level parallelism effectively and overcome the limitation of instruction level parallelism in the next generation block encryption algorithms.

• Journal of the Korea Institute of Information Security & Cryptology
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• v.12 no.2
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• pp.53-64
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• 2002

This paper describes a design of cryptographic processor that implements the AES (Advanced Encryption Standard) block cipher algorithm, "Rijndael". An iterative looping architecture using a single round block is adopted to minimize the hardware required. To achieve high throughput rate, a sub-pipeline stage is added by dividing the round function into two blocks, resulting that the second half of current round function and the first half of next round function are being simultaneously operated. The round block is implemented using 32-bit data path, so each sub-pipeline stage is executed for four clock cycles. The S-box, which is the dominant element of the round block in terms of required hardware resources, is designed using arithmetic circuit computing multiplicative inverse in GF($2^8$) rather than look-up table method, so that encryption and decryption can share the S-boxes. The round keys are generated by on-the-fly key scheduler. The crypto-processor designed in Verilog-HDL and synthesized using 0.25-$\mu\textrm{m}$ CMOS cell library consists of about 23,000 gates. Simulation results show that the critical path delay is about 8-ns and it can operate up to 120-MHz clock Sequency at 2.5-V supply. The designed core was verified using Xilinx FPGA board and test system.

• Journal of the Korea Institute of Information and Communication Engineering
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• v.6 no.3
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• pp.427-433
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• 2002

This paper describes a design of cryptographic processor that implements the AES(Advanced Encryption Standard) block cipher algorithm "Rijndael". To achieve high throughput rate, a sub-pipeline stage is inserted into the round transformation block, resulting that the second half of current round function and the first half of next round function are being simultaneously operated. For area-efficient and low-power implementation, the round block is designed to share the hardware resources in encryption and decryption. An efficient scheme for on-the-fly key scheduling, which supports the three master-key lengths of 128-b/192-b/256-b, is devised to generate round keys in the first sub-pipeline stage of each round processing. The cryptoprocessor designed in Verilog-HDL was verified using Xilinx FPGA board and test system. The core synthesized using 0.35-${\mu}{\textrm}{m}$ CMOS cell library consists of about 25,000 gates. Simulation results show that it has a throughput of about 520-Mbits/sec with 220-MHz clock frequency at 2.5-V supply.-V supply.

• Journal of Advanced Navigation Technology
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• v.23 no.5
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• pp.339-344
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• 2019

In order to prepare for the rise of data security threats caused by the information and communication technology, technology that can guarantee the stability of the data stored in the missile test set is important. For this purpose, encryption should be performed when data is stored so that it cannot be restored even if data is leaked, and integrity should be ensured even after decrypting the data. In this paper, we apply AES algorithm, which is a symmetric key cryptography system, to the missile test set, and Encrypt and decrypt according to the amount of data for each bit of each AES algorithm. We implemented the AES Rijndael algorithm in the existing inspection system to analyze the effect of encryption and apply the proposed encryption algorithm to the existing system. confirmation of suitability. analysis of capacity and Algorithm bits it is confirmed that the proposed algorithm will not affect the system operation and the optimal algorithm is derived. compared with the initial data, we can confirm that the algorithm can guarantee data undulation.

• The KIPS Transactions:PartC
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• v.13C no.1 s.104
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• pp.83-94
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• 2006

This paper describes ATM cell encipherment method using Rijndael Algorithm adopted as an AES(Advanced Encryption Standard) by NIST in 2001. ISO 9160 describes the requirement of physical layer data processing in encryption/decryption. For the description of ATM cell encipherment method, we implemented ATM data encipherment equipment which satisfies the requirements of ISO 9160, and verified the encipherment/decipherment processing at ATM STM-1 rate(155.52Mbps). The DES algorithm can process data in the block size of 64 bits and its key length is 64 bits, but the Rijndael algorithm can process data in the block size of 128 bits and the key length of 128, 192, or 256 bits selectively. So it is more flexible in high bit rate data processing and stronger in encription strength than DES. For tile real time encryption of high bit rate data stream. Rijndael algorithm was implemented in FPGA in this experiment. The boundary of serial UNI cell was detected by the CRC method, and in the case of user data cell the payload of 48 octets (384 bits) is converted in parallel and transferred to 3 Rijndael encipherment module in the block size of 128 bits individually. After completion of encryption, the header stored in buffer is attached to the enciphered payload and retransmitted in the format of cell. At the receiving end, the boundary of ceil is detected by the CRC method and the payload type is decided. n the payload type is the user data cell, the payload of the cell is transferred to the 3-Rijndael decryption module in the block sire of 128 bits for decryption of data. And in the case of maintenance cell, the payload is extracted without decryption processing.

• The Journal of Korean Institute of Communications and Information Sciences
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• v.26 no.10B
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• pp.1491-1500
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• 2001

본 논문에서는 AES Rijndael 암호 알고리즘을 구현하는 암호 프로세서를 설계하였다. 하드웨어 공유를 통해 면적을 감소시키기 위해 1라운드 동작을 2개의 부분 라운드로 나누고 각 부분 라운드를 4 클록으로 구현하였다. 라운드 당 평균 5 클록의 연산 효율을 만들기 위해 인접한 라운드간에 부분 라운드 라이프라인 동작 기법을 적용하고, 키 설정 오버헤드 시간을 배제하기 위해, 암호 및 복호 동작의 라운드 키를 온라인 계산 기법을 사용하여 생성하였다. 그리고 다양한 응용 분야에 적용하기 위해, 128, 192, 256 비트의 3가지 암호 키를 모두 지원할 수 있도록 하였다. 설계된 암호 프로세서는 약 36,000개의 게이트로 구성되며 0.25$\mu\textrm{m}$ CMOS 공정에서 약 200Mhz의 동작 주파수를 가지며, 키 길이가 128 비트인 AES-128 ECB 동작 모드에서 약 512 Mbps의 암.복호 율의 성능을 얻을 수 있었다.

• Proceedings of the IEEK Conference
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• 2002.07b
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• pp.944-947
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• 2002

We implemented a cryptoprocessor with a on-the-fly key scheduler which performs forward key scheduling for encryption and reverse key scheduling for decryption. This scheduler makes the fast generation of the key value and eliminates the memory for software key scheduler. The 128-bit Rijndael processor is implemented based on the proposed architecture using Verilog-HDL and targeted to Xilinx XCV1000E FPGA device. As a result, the 128-bit Rijndael operates at 38.8MHz with on-the-fly key scheduler and consumes 11 cycles for encryption and decryption resulting in a throughput of 451.5Mbps

• Proceedings of the Korea Institutes of Information Security and Cryptology Conference
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• 2003.07a
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• pp.67-70
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• 2003

인터넷과 같은 네트워크와 컴퓨터 이용자의 급격한 증가로 인해 컨텐츠 유출 사고 및 개인 정보유출 사고가 빈번하게 발생되고 있다. 이러한 문제를 해결하기 위한 방법 중의 하나가 컨텐츠를 암호화하는 방법이다. 그러나 이 또한 최근에 암호화의 안전성에 많은 문제점을 안고 있다. 이에 렬 논문에서는 비밀키 암호화 방식의 대표인 DES의 문제점에 대해서 분석하고 차세대 암호표준으로 선정한 대칭형 암호알고리즘인 Rijndael을 이용해서 파일의 암호화를 구현하고자 한다.