• Title/Summary/Keyword: glitch

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Analysis of PSK Coherent Carrier Signal Recovery Circuit Using Six-Port Phase Correlator (6-단자 위상 상관기를 이용한 PSK 반송파 신호 복원 회로 해석)

  • Kim, Young-Wan;Shin, Choo-Yeon
    • The Journal of Korean Institute of Electromagnetic Engineering and Science
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    • v.19 no.11
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    • pp.1281-1286
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    • 2008
  • The PSK carrier signal recovery circuit using a six-port phase correlator was analyzed and the circuit structure is proposed in this paper. The proposed carrier signal recovery circuit that is made of reflection element and six-port phase correlator, which is comprised of a power divider and three hybrid branch line couplers, give a simple structure and can be fabricated without no difficulty. The circuit recovers the carrier signal of BPSK and QPSK modulation signal. The proposed scheme can be utilized as a basis structure for high-mode PSK carrier signal recovery. By simulation results, the recovered signal by the proposed circuit shows a good carrier signal characteristic with CW signal of a constant phase($23.4^{\circ}$) and ${\pm}0.8^{\circ}$ phase error due to glitch conditions.

Design of a 2.5V 10-bit 300MSPS CMOS D/A Converter (2.5V 10-bit 300MSPS 고성능 CMOS D/A 변환기의 설계)

  • Kwon, Dae-Hoon;Song, Min-Kyu
    • Journal of the Institute of Electronics Engineers of Korea SD
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    • v.39 no.7
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    • pp.57-65
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    • 2002
  • In this paper, a 2.5V 10-bit 300MSPS CMOS D/A Converter is described. The architecture of the D/A Converter is based on a current steering 8+2 segmented type, which reduces non-linearity error and other secondary effects. In order to achieve a high performance D/A Converter, a novel current cell with a low spurious deglitchnig circuit and a novel inverse thermomeer decoder are proposed. To verify the performance, it is integrated with $0.25{\mu}m$ CMOS 1-poly 5-metal technology. The effective chip area is $1.56mm^2$ and power consumption is about 84mW at 2.5V power supply. The simulation and experimental results show that the glitch energy is 0.9pVsec at fs=100MHz, 15pVsec at fs=300MHz in worst case, respectively. Further, both of INL and DNL are within ${\pm}$1.5LSB, and the SFDR is about 45dB when sampling, frequency, is 300MHz and output frequency is 1MHz.

Monolithic and Resolution with design of 10bit Current output Type Digital-to-Analog Converter (개선된 선형성과 해상도를 가진 10비트 전류 출력형 디지털-아날로그 변환기의 설계)

  • Song, Jun-Gue;Shin, Gun-Soon
    • Proceedings of the Korean Institute of Information and Commucation Sciences Conference
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    • 2007.10a
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    • pp.187-191
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    • 2007
  • This paper describes a 3.3V 10 bit CMOS digital-to-analog converter with a divided architecture of a 7 MSB and a 3 LSB, which uses an optimal Thermal-to-Binary Decoding method with monotonicity, glitch energy. The output stage utilizes here implements a return-to-zero circuit to obtain the dynamic performance. Most of D/A converters in decoding circuit is complicated, occupies a large chip area. For these problems, this paper describes a D/A converter using an optimal Thermal-to-Binary Decoding method. the designed D/A converter using the CMOS n-well $0.35{\mu}m$ process0. The experimental data shows that the rise/fall time, settling time, and INL/DNL are 1.90ns/2.0ns, 12.79ns, and a less than ${\pm}2.5/{\pm}0.7$ LSB, respectively. The power dissipation of the D/A converter with a single power supply of 3.3V is about 250mW.

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High Speed Inductive Link Using Complementary Switching Transmitter and Integrating Receiver (상보적으로 스위칭하는 송신기와 적분형 수신기를 이용한 고속 인덕티브 링크)

  • Kim, Hyun-Ki;Roh, Joon-Wan;Chun, Young-Hyun;Kwon, Kee-Won;Chun, Jung-Hoon
    • Journal of the Institute of Electronics Engineers of Korea SD
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    • v.48 no.12
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    • pp.37-44
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    • 2011
  • This paper presents the method of improving the data rate and BER in the inductive coupling link using a BPM signaling method. A complementary switching transmitter is used to remove invalid glitches at transmitted data, and the concept of pre-distortion is introduced to optimize received data. Also, an integrating receiver is used to increase the sampling margin and equalizing transistors are added in the pre-charge path of the integrator and comparator for high frequency operation. The transceiver designed with a 0.13 um CMOS technology operates at 2.4 Gb/s and consumes 5.99 mW from 1.2 V power supply.

A Low Power Realization by Eliminating Glitch-Propagation in an ALU with P/G blocks (P/G블록을 가진 ALU에서 글리치 전파제거에 의한 저전력 실현)

  • Ryu, Beom-Seon;Lee, Seong-Hyeon;Lee, Gi-Yeong;Jo, Tae-Won
    • Journal of the Institute of Electronics Engineers of Korea SD
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    • v.38 no.1
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    • pp.55-68
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    • 2001
  • This paper presents a new ALU architecture to minimize glitching power consumption which is appeared in the conventional one with P(carry propagation)/G(carry generation) blocks. In general, A lot of glitches generated once are propagating into the next stage of circuits to make unnecessary power dissipation. Therefore, a new ALU architecture which removes the glitches at the output of P/G blocks is presented in this paper. If a lot of glitches at the output of P/G blocks are removed, then the signal transitions caused by glitches are reduced in the sum generation block and hence power consumption is also reduced. A latch is inserted into the conventional P/G blocks to remove the glitches at the output of P/G blocks. Latch enable signal can make a role in eliminating a lot of glitches at the P/G's outputs by controlling output enable time. Experimental results from HSPICE simulations with implementing 16-b ALU show 28% reduction in glitching power consumption with negligible delay penalty.

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A Design of 10bit current output Type Digital-to-Analog converter with self-Calibration Techique for high Resolution (고해상도를 위한 DAC 오차 보정법을 가진 10-비트 전류 출력형 디지털-아날로그 변환기 설계)

  • Song, Jung-Gue;Shin, Gun-Soon
    • Journal of the Korea Institute of Information and Communication Engineering
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    • v.12 no.4
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    • pp.691-698
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    • 2008
  • This paper describes a 3.3V 10 bit CMOS digital-to-analog converter with a divided architecture of a 7 MSB and a 3 LSB, which uses an optimal Thermal-to-Binary Decoding method with monotonicity, glitch energy. The output stage utilizes here implements a return-to-zero circuit to obtain the dynamic performance. Most of D/A converters in decoding circuit is complicated, occupies a large chip area. For these problems, this paper describes a D/A converter using an optimal Thermal-to-Binary Decoding method. the designed D/A converter using the CMOS n-well $0.35{\mu}m$ process0. The experimental data shows that the rise/fall time, settling time, and INL/DNL are 1.90ns/2.0ns, 12.79ns, and a less than ${\pm}2.5/{\pm}0.7\;LSB$, respectively. The power dissipation of the D/A converter with a single power supply of 3.3V is about 250mW.

Design of Low-Noise and High-Reliability Differential Paired eFuse OTP Memory (저잡음 · 고신뢰성 Differential Paired eFuse OTP 메모리 설계)

  • Kim, Min-Sung;Jin, Liyan;Hao, Wenchao;Ha, Pan-Bong;Kim, Young-Hee
    • Journal of the Korea Institute of Information and Communication Engineering
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    • v.17 no.10
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    • pp.2359-2368
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    • 2013
  • In this paper, an IRD (internal read data) circuit preventing the reentry into the read mode while keeping the read-out DOUT datum at power-up even if noise such as glitches occurs at signal ports such as an input signal port RD (read) when a power IC is on, is proposed. Also, a pulsed WL (word line) driving method is used to prevent a DC current of several tens of micro amperes from flowing into the read transistor of a differential paired eFuse OTP cell. Thus, reliability is secured by preventing non-blown eFuse links from being blown by the EM (electro-migration). Furthermore, a compared output between a programmed datum and a read-out datum is outputted to the PFb (pass fail bar) pin while performing a sensing margin test with a variable pull-up load in consideration of resistance variation of a programmed eFuse in the program-verify-read mode. The layout size of the 8-bit eFuse OTP IP with a $0.18{\mu}m$ process is $189.625{\mu}m{\times}138.850{\mu}m(=0.0263mm^2)$.

Design of an 1.8V 8-bit 500MSPS Low-Power CMOS D/A Converter for UWB System (UWB 시스템을 위한 1.8V 8-bit 500MSPS 저 전력 CMOS D/A 변환기의 설계)

  • Lee, Jun-Hong;Hwang, Sang-Hoon;Song, Min-Kyu
    • Journal of the Institute of Electronics Engineers of Korea SD
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    • v.43 no.12 s.354
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    • pp.15-22
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    • 2006
  • In this paper, 1.8V 8-bit 500MSPS Low-power CMOS Digital-to-Analog Converter(DAC) for UWB(Ultra Wide Band) Communication Systeme is proposed. The architecture of the DAC is based on a current steering 6+2 full matrix type which has low glitch and high linearity. In order to achieve a high speed and good performance, a current cell with a high output impedance and wide swing output range is designed. Further a thermometer decoder with same delay time and low-power switching decoder for high efficiency performance are proposed. The proposed DAC was implemented with TSMC 0.18um 1-poly 6-metal N-well CMOS technology. The measured SFDR was 49dB when the output frequency was 50MHz at 500MS/s sampling frequency. The measured INL and DNL were 0.9LSB and 0.3LSB respectively. The DAC power dissipation was 20mW and the effective chip area was $0.63mm^2$.

Design of a Small Area 12-bit 300MSPS CMOS D/A Converter for Display Systems (디스플레이 시스템을 위한 소면적 12-bit 300MSPS CMOS D/A 변환기의 설계)

  • Shin, Seung-Chul;Moon, Jun-Ho;Song, Min-Kyu
    • Journal of the Institute of Electronics Engineers of Korea SD
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    • v.46 no.4
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    • pp.1-9
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    • 2009
  • In this paper, a small area 12-bit 300MSPS CMOS Digital-to-Analog Converter(DAC) is proposed for display systems. The architecture of the DAC is based on a current steering 6+6 segmented type, which reduces non-linearity error and other secondary effects. In order to improve the linearity and glitch noise, an analog current cell using monitoring bias circuit is designed. For the purpose of reducing chip area and power dissipation, furthermore, a noble self-clocked switching logic is proposed. To verify the performance, it is fabricated with $0.13{\mu}m$ thick-gate 1-poly 6-metal N-well Samsung CMOS technology. The effective chip area is $0.26mm^2$ ($510{\mu}m{\times}510{\mu}m$) with 100mW power consumption. The measured INL (Integrated Non Linearity) and DNL (Differential Non Linearity) are within ${\pm}3LSB$ and ${\pm}1LSB$, respectively. The measured SFDR is about 70dB, when the input frequency is 15MHz at 300MHz clock frequency.

A 12b 200KHz 0.52mA $0.47mm^2$ Algorithmic A/D Converter for MEMS Applications (마이크로 전자 기계 시스템 응용을 위한 12비트 200KHz 0.52mA $0.47mm^2$ 알고리즈믹 A/D 변환기)

  • Kim, Young-Ju;Chae, Hee-Sung;Koo, Yong-Seo;Lim, Shin-Il;Lee, Seung-Hoon
    • Journal of the Institute of Electronics Engineers of Korea SD
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    • v.43 no.11 s.353
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    • pp.48-57
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    • 2006
  • This work describes a 12b 200KHz 0.52mA $0.47mm^2$ algorithmic ADC for sensor applications such as motor controls, 3-phase power controls, and CMOS image sensors simultaneously requiring ultra-low power and small size. The proposed ADC is based on the conventional algorithmic architecture with recycling techniques to optimize sampling rate, resolution, chip area, and power consumption. The input SHA with eight input channels for high integration employs a folded-cascode architecture to achieve a required DC gain and a sufficient phase margin. A signal insensitive 3-D fully symmetrical layout with critical signal lines shielded reduces the capacitor and device mismatch of the MDAC. The improved switched bias power-reduction techniques reduce the power consumption of analog amplifiers. Current and voltage references are integrated on the chip with optional off-chip voltage references for low glitch noise. The employed down-sampling clock signal selects the sampling rate of 200KS/s or 10KS/s with a reduced power depending on applications. The prototype ADC in a 0.18um n-well 1P6M CMOS technology demonstrates the measured DNL and INL within 0.76LSB and 2.47LSB. The ADC shows a maximum SNDR and SFDR of 55dB and 70dB at all sampling frequencies up to 200KS/s, respectively. The active die area is $0.47mm^2$ and the chip consumes 0.94mW at 200KS/s and 0.63mW at 10KS/s at a 1.8V supply.