• 대한전기학회:학술대회논문집
• /
• 대한전기학회 2001년도 합동 추계학술대회 논문집 정보 및 제어부문
• /
• pp.153-156
• /
• 2001

This paper analyzes the 74LS381 ALU and designs its equivalent circuit. The 74LS381 ALU is arithmetic logic units(ALUs)/function generators that perform eight binary arithmetic/logic operations on two 4-bit words. However there are only little information to understand and design this circuit. Thus, we not only analyzed it but also designed an equivalent circuit to the 74LS381.

• 대한전자공학회논문지
• /
• 제25권2호
• /
• pp.204-210
• /
• 1988

The residue number system offers the possibility of high-speed operation and error detection/correction because of the separability of arithmetic operations on each digit. A compact residue arithmetic module named the self-checking pulse-train residue arithmetic circuit is effectively employed as the basic module, and an efficient error detection/correction algorithm in which error detection is performed in each basic module and error correction is performed based on the parallelism of residue arithmetic is also employed. In this case, the error correcting circuit is imposed in series to non-redundant system. This design method has an advantage of compact hardware. Following the proposed method, a 2nd-order recursive fault-tolerant digital filter is practically implemented, and its fault-tolerant ability is proved by noise injection testing.

• 대한전자공학회논문지
• /
• 제25권5호
• /
• pp.528-535
• /
• 1988

This paper presents a constructing theory of variable arithmetic operation systems for computing multiplications and multiplicative inverse in GF(2**m) based on a modulo operation of degree on elements in Galois fields. The proposed multiplier is composed of a zero element control part, input element conversion part, inversion circuit, and output element conversion part. These systems can reduce reasonable circuit areas due to the common use of input/output element converison parts, and the PLA and module structure provice a variable property capable of convertible uses as arithmetic operation systems over different finite fields. This type of designs gives simple, regular, expandable, and concurrent properties suitable for VLSI implementation. Expecially, the multiplicative inverse circuit proposed here is expected to offer a characteristics of the high operation speed than conventional method.

• 공학논문집
• /
• 제2권1호
• /
• pp.31-37
• /
• 1997

본 논문에서의 ALU는 덧셈, 뺄셈, 1증가, 1 감소, 2의 보수 등의 산술 연산을 수행하는 산술 연산 회로, 논리합, 논리곱, 배타논리합, 부정과 같은 논리 연산을 수행하는 논리 연산 회로, 쉬프트 연산 및 산술 혹은 논리 연산 회로의 연산 결과를 데이터 버스로 전송하는 기능을 담당하는 쉬프터로 구성되며, 이러한 기본적인 ALU 기능과 관련된 명령어는 Z80 명령어에서 추출하여 ALU의 내부 회로를 설계하였고, 이 설계된 회로를 그래픽 화면으로 구성하여 데이터의 연산이 ALU 내부에서 어떤 과정과 경로를 거쳐 수행되는 가를 비트 및 논리 게이트 단위까지 처리하여 ALU 구조와 단계별 연산 과정을 그래픽 형태로 학습하는 교육 시스템이다.

• 대한전기학회:학술대회논문집
• /
• 대한전기학회 2000년도 추계학술대회 논문집 학회본부 D
• /
• pp.778-780
• /
• 2000

The 74181 is arithmetic logic units(ALU)/function generator. This circuit performs 16 binary arithmetic operations on two 4-bit words. And a full carry look-ahead scheme is made available in this device. The 74181 can also be utilized as a comparator. This circuit has been also designed to provide 16 possible functions of two Boolean variables without the use of external circuitry. This paper analyzes the function of the logic and the implementation adopted in the design of 74181. The understanding of the logic characteristics of this chip enables us to improve future applications.

• 전자공학회논문지C
• /
• 제36C권8호
• /
• pp.35-45
• /
• 1999

본 논문에서는 $GF(p^m)$상에서 두 다항식의 가산 및 승산 알고리즘을 제시하였고, 가산 및 승산 알고리즘을 수행하는 전류 모드 CMOS에 의한 $GF(4^3)$상의 직렬 입력-병렬 출력 모듈 구조의 4치 연산기를 구현하였다. 제시된 전류 모드 CMOS 4치 연산기는 가산/승산 선택 회로, mod(4) 승산 연산 회로, mod(4) 가산 연산 회로를 2개 연결하여 구성한 MOD 연산회로, mod(4) 승산 연산 회로와 동일하게 동작하는 원시 기약 다항식 연산 회로에 의해 구현하였으며, PSpice 시뮬레이션을 통하여 이 회로들에 대하여 동작 특성을 보였다. 제시된 회로들의 시뮬레이션은 $2{\mu}m$ CMOS 기술을 이용하고, 단위 전류를 $15{\mu}A$로 하였으며, VDD 전압은 3.3V을 사용하였다. 본 논문에서 제시한 전류 모드 CMOS의 4치 연산기는 회선 경로 선택의 규칙성, 간단성, 셀 배열에 의한 모듈성의 이점을 가지며, 특히 차수 m이 증가하는 유한체상의 두 다항식의 가산 및 승산에서 확장성을 가지므로 VLSI화 실현에 적합할 것으로 생각된다.

• 대한전자공학회:학술대회논문집
• /
• 대한전자공학회 1999년도 하계종합학술대회 논문집
• /
• pp.821-824
• /
• 1999

In distributed arithmetic-based architecture for an inner product between two length-N vectors, the size of the ROM increases exponentially with N. Moreover, the ROMs are generally the bottleneck of speed, especially when their sire is large. In this paper, a ROM size reduction technique for DA (Distributed Arithmetic) is proposed. The proposed method is based on modified OBC (Offset Binary Coding) and control circuit reduction technique. By simulations, it is shown that the use of the proposed technique can result in reduction in the number of gates up to 50%.

• Progress in Superconductivity
• /
• 제6권2호
• /
• pp.104-107
• /
• 2005

We have developed and tested an RSFQ 4-bit Arithmetic Logic Unit (ALU) based on half adder cells and de switches. ALU is a core element of a computer processor that performs arithmetic and logic operations on the operands in computer instruction words. The designed ALU had limited operation functions of OR, AND, XOR, and ADD. It had a pipeline structure. We have simulated the circuit by using Josephson circuit simulation tools in order to reduce the timing problem, and confirmed the correct operation of the designed ALU. We used simulation tools of $XIC^{TM},\;WRspice^{TM}$, and Julia. The fabricated 4-bit ALU circuit had a size of $\3000{\ cal}um{\times}1500{\cal}$, and the chip size was $5{\cal} mm{\times}5{\cal}mm$. The test speeds were 1000 kHz and 5 GHz. For high-speed test, we used an eye-diagram technique. Our 4-bit ALU operated correctly up to 5 GHz clock frequency. The chip was tested at the liquid-helium temperature.

• Progress in Superconductivity
• /
• 제7권2호
• /
• pp.109-113
• /
• 2006

The Arithmetic Logic Unit (ALU) is a core element of a computer processor that performs arithmetic and logic operations on the operands in computer instruction words. We have developed and tested an RSFQ multi-bit ALU constructed with half adder unit cells. To reduce the complexity of the ALU, We used half adder unit cells. The unit cells were constructed of one half adder and three de switches. The timing problem in the complex circuits has been a very important issue. We have calculated the delay time of all components in the circuit by using Josephson circuit simulation tools of XIC, $WRspice^{TM}$, and Julia. To make the circuit work faster, we used a forward clocking scheme. This required a careful design of timing between clock and data pulses in ALU. The designed ALU had limited operation functions of OR, AND, XOR, and ADD. It had a pipeline structure. The fabricated 1-bit, 2-bit, and 4-bit ALU circuits were tested at a few kilo-hertz clock frequency as well as a few tens giga-hertz clock frequency, respectively. For high-speed tests, we used an eye-diagram technique. Our 4-bit ALU operated correctly at up to 5 GHz clock frequency.

• Smart Structures and Systems
• /
• 제14권6호
• /
• pp.1131-1150
• /
• 2014

One of the issues in extending the range of applicable problems of real-time hybrid simulation is the computation speed of the simulator when large-scale computational models with a large number of DOF are used. In this study, functionality of real-time dynamic simulation of MDOF systems is achieved by creating a logic circuit that performs the step-by-step numerical time integration of the equations of motion of the system. The designed logic circuit can be implemented to an FPGA-based system; FPGA (Field Programmable Gate Array) allows large-scale parallel computing by implementing a number of arithmetic operators within the device. The operator splitting method is used as the numerical time integration scheme. The logic circuit consists of blocks of circuits that perform numerical arithmetic operations that appear in the integration scheme, including addition and multiplication of floating-point numbers, registers to store the intermediate data, and data busses connecting these elements to transmit various information including the floating-point numerical data among them. Case study on several types of linear and nonlinear MDOF system models shows that use of resource sharing in logic synthesis is crucial for effective application of FPGA to real-time dynamic simulation of structural response with time step interval of 1 ms.