• Proceedings of the IEEK Conference
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• 2001.06b
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• pp.301-304
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• 2001

The analog multiplier is very useful building block in many circuits such as filter, frequency-shifter, and modulators. In recent year, The main design issue of circuit designer is low-voltage/low-power system design, because of all systems are recommended very integrated system and portable system In this paper, the proposed the four-quadrant analog multiplier is using the bulk-driven techniques. The bulk-driven technique is very useful technique in low-voltage system, compare with gate-driven technique. therefore the proposed analog multiplier is operated in 1V supply voltage. And the proposed analog multiplier is low power dissipation compare with the others. therefor the proposed analog multiplier is convenient in low-voltage/low-power in system.

• Proceedings of the KIEE Conference
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• 2005.05a
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• pp.144-147
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• 2005

This paper is proposed an 8$\times$8 bit parallel multiplier for low power consumption. The 8$\times$8 bit parallel multiplier is used for the comparison between the proposed Low-Swing CVSL full adder with conventional CVSL full adder. Comparing tile previous works, this circuit is reduced the power consumption rate of 8.2% and the power-delay-product of 11.1%. The validity and effectiveness of the proposed circuits are verified through the HSPICE under Hynix 0.35$\{\mu}m$ standard CMOS process.

• Proceedings of the KIEE Conference
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• 2003.11b
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• pp.79-82
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• 2003

This paper describes a new low-swing inverter for low power consumption. To reduce a power consumption, an output voltage swing is in the range from 0 to $V_{ref}-V_{TH}$, where $V_{ref}=V_{DD}-nV_{TH}$. This can be done by the inverter structure that allow a full swing or a swing on its input terminal without leakage current. Using this low-swing voltage technology, we propose a low-power $4\times4$ bit parallel multiplier. The proposed circuits are simulated with HSPICE under $0.35{\mu}m$ CMOS standard technology. Compare to the previous works, this circuit can reduce the power consumption rate of 11.2% and the power-delay product of 10.3%.

• The Journal of the Acoustical Society of Korea
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• v.18 no.3E
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• pp.44-48
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• 1999

The CMOS four-quadrant analog multiplier for low-voltage low-power applications are presented in this thesis. The circuit approach is based on the characteristic of the LV (Low-Voltage) composite transistor which is one of the useful analog building block. SPICE simulations are carried out to examine the performances of the designed multiplier. Simulation results are obtained by 0.6㎛ CMOS parameters with 2V power supply. The basic configuration of the multiplier is the CMOS Gilbert cell with two LV composite transistors. The linear input range of the multiplier is over ±0.4V with a linearity error of less than 1.3%. The measured -3dB bandwidth is 288MHz and the power dissipation is 255 ㎼.

• The Journal of Korean Institute of Communications and Information Sciences
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• v.30 no.11A
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• pp.1092-1097
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• 2005

In this paper, we propose a low-power Booth multiplication which reduces the switching activities of partial products during multiplication process. Radix-4 Booth algorithm has a characteristic that produces the Booth encoded products with zero when input data have sequentially equal values (0 or 1). Therefore, partial products have higher chances of being zero when an input with a smaller effective dynamic range of two multiplication inputs is used as a multiplier data instead of a multiplicand. The proposed multiplier divides a multiplication expression into several multiplication expressions with smaller bits than those of an original input data, and each multiplication is computed independently for the Booth encoding. Finally, the results of each multiplication are added. This means that the proposed multiplier has a higher chance to have zero encoded products so that we can implement a low power multiplier with the smaller switching activity. Implementation results show the proposed multiplier can save maximally about $20\%$ power dissipation than a previous Booth multiplier.

• The Journal of the Korea institute of electronic communication sciences
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• v.17 no.4
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• pp.671-678
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• 2022

Approximate computing is an computational technique that is acceptable degree of inaccurate results of accurate results. Approximate multiplication is one of the approximate computing methods for high-performance and low-power computing. In this paper, we propose a high-density, low-power, and high-speed approximate multiplier using approximate 4-2 compressor and improved full adder. The approximate multiplier with approximate 4-2 compressor consists of three regions of the exact, approximate and constant correction regions, and we compared them by adjusting the size of region by applying an efficient partial product reduction. The proposed approximate multiplier was designed with Verilog HDL and was analyzed for area, power and delay time using Synopsys Design Compiler (DC) on a 25nm CMOS process. As a result of the experiment, the proposed multiplier reduced area by 10.47%, power by 26.11%, and delay time by 13% compared to the conventional approximate multiplier.

• ETRI Journal
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• v.39 no.4
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• pp.570-581
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• 2017

Multiplication in finite fields is used in many applications, especially in cryptography. It is a basic and the most computationally intensive operation from among all such operations. Several systolic multipliers are proposed in the literature that offer low hardware complexity or high speed. In this paper, a bit-parallel polynomial basis systolic multiplier for generic irreducible polynomials is proposed based on a modified interleaved multiplication method. The hardware complexity and delay of the proposed multiplier are estimated, and a comparison with the corresponding multipliers available in the literature is presented. Of the corresponding multipliers, the proposed multiplier achieves a reduction in the hardware complexity of up to 20% when compared to the best multiplier for m = 163. The synthesis results of application-specific integrated circuit and field-programmable gate array implementations of the proposed multiplier are also presented. From the synthesis results, it is inferred that the proposed multiplier achieves low power consumption and low area complexitywhen compared to the best of the corresponding multipliers.

• Journal of the Korea Institute of Information and Communication Engineering
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• v.6 no.2
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• pp.323-329
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• 2002

This paper describes an efficient error-compensation technique for designing a low-error truncated Booth multiplier which produces an N-bit output from a two's complement multiplication of two N bit inputs by eliminating the N least-significant bits. Applying the proposed method, a truncated Booth multiplier for area-efficient and low-power applications has been designed, and its performance(truncation error, area) was analyzed. Since the truncated Booth multiplier does not have about half the partial product generators and adders, it results an area reduction of about 35％, compared with no-truncated parallel multipliers. Error analysis shows that the proposed approach reduces the average truncation error by approximately 60％, compared with conventional methods. A 16-b$\times$16-b truncated Booth multiplier core is designed on full-custom style using 0.35-${\mu}{\textrm}{m}$ CMOS technology. It has 3,000 transistors on an area of 330-${\mu}{\textrm}{m}$$\times$262-${\mu}{\textrm}{m}$ and 20-㎽ power dissipation at 3.3-V supply with 200-MHz operating frequency.

• Proceedings of the KIEE Conference
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• 2005.07d
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• pp.3058-3060
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• 2005

In this paper, the CMOS four-quadrant analog multipliers for low-voltage low-power applications are presented. The circuit approach is based on the characteristic of the LV (Low-Voltage) composite transistor which is one of the useful analog building blocks. SPICE simulations are carried out to examine the performances of the designed multipliers. Simulation results are obtained by $0.25{\mu}m$ CMOS parameters with 2V power supply. The LV composite transistor can easily be extended to perform a four-quadrant multiplication. The multiplier has a linear input range up to ${\pm}0.5V$ with a linearity error of less than 1%. The measured -3dB bandwidth is 290MHz and the power dissipation is $37{\mu}W$. The proposed multiplier is expected to be suitable for analog signal processing applications such as portable communication equipment, radio receivers, and hand-held movie cameras.

• Proceedings of the IEEK Conference
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• 2000.06b
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• pp.141-144
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• 2000

In this paper, a new parallel array structure for the asynchronous array multiplier is introduced. This structure is designed for a data dependent asynchronous multiplier to reduces power which is wasted in conventional array structure. Simulation shows that this structure saves 30％ of power and 55％ of computation time comparing to conventional booth encoded array multiplier.