• Title/Summary/Keyword: digital LDO

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Fast-Transient Digital LDO Regulator With Binary-Weighted Current Control (이진 가중치 전류 제어 기법을 이용한 고속 응답 디지털 LDO 레귤레이터)

  • Woo, Ki-Chan;Sim, Jae-Hyeon;Kim, Tae-Woo;Hwang, Seon-Kwang;Yang, Byung-Do
    • Journal of the Korea Institute of Information and Communication Engineering
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    • v.20 no.6
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    • pp.1154-1162
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    • 2016
  • This paper proposes a fast-transient digital LDO(Low dropout) regulator with binary-weighted current control technique. Conventional digital LDO takes a long time to stabilize the output voltage, because it controls the amount of current step by step, thus ringing problem is generated. Binary-weighted current control technique rapidly stabilizes output voltage by removing the ringing problem. When output voltage reliably reaches the target voltage, It added the FRZ mode(Freeze) to stop the operation of digital LDO. The proposed fast response digital LDO is used with a slow response DC-DC converter in the system which rapidly changes output voltage. The proposed digital controller circuit area was reduced by 56% compared to conventional bidirectional shift register, and the ripple voltage was reduced by 87%. A chip was implemented with a $0.18{\mu}F$ CMOS process. The settling time is $3.1{\mu}F$ and the voltage ripple is 6.2mV when $1{\mu}F$ output capacitor is used.

Design of ADC for Dual-loop Digital LDO Regulator (이중 루프 Digital LDO Regulator 용 ADC 설계)

  • Sang-Soon Park;Jeong-Hee Jeon;Jae-Hyeong Lee;Joong-Ho Choi
    • Journal of IKEEE
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    • v.27 no.3
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    • pp.333-339
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    • 2023
  • The global market for wearable devices is growing, driving demand for efficient PMICs. Wearable PMICs must be highly energy-efficient despite limited hardware resources. Advancements in process technology enable low-power consumption, but traditional analog LDO regulators face challenges with reduced power supply voltage. In this paper, a novel ADC design with a 3-bit continuous-time flash ADC for the coarse loop and a 5-bit discrete-time SAR ADC for the fine loop is proposed for digital LDO, achieving a 34.78 dB SNR and 5.39 bits ENOB in a 55-nm CMOS technology.

Low-ripple coarse-fine digital low-dropout regulator without ringing in the transient state

  • Woo, Ki-Chan;Yang, Byung-Do
    • ETRI Journal
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    • v.42 no.5
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    • pp.790-798
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    • 2020
  • Herein, a low-ripple coarse-fine digital low-dropout regulator (D-LDO) without ringing in the transient state is proposed. Conventional D-LDO suffers from a ringing problem when settling the output voltage at a large load transition, which increases the settling time. The proposed D-LDO removes the ringing and reduces the settling time using an auxiliary power stage which adjusts its output current to a load current in the transient state. It also achieves a low output ripple voltage using a comparator with a complete comparison signal. The proposed D-LDO was fabricated using a 65-nm CMOS process with an area of 0.0056 μ㎡. The undershoot and overshoot were 47 mV and 23 mV, respectively, when the load current was changed from 10 mA to 100 mA within an edge time of 20 ns. The settling time decreased from 2.1 ㎲ to 130 ns and the ripple voltage was 3 mV with a quiescent current of 75 ㎂.

250 mV Supply Voltage Digital Low-Dropout Regulator Using Fast Current Tracking Scheme

  • Oh, Jae-Mun;Yang, Byung-Do;Kang, Hyeong-Ju;Kim, Yeong-Seuk;Choi, Ho-Yong;Jung, Woo-Sung
    • ETRI Journal
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    • v.37 no.5
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    • pp.961-971
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    • 2015
  • This paper proposes a 250 mV supply voltage digital low-dropout (LDO) regulator. The proposed LDO regulator reduces the supply voltage to 250 mV by implementing with all digital circuits in a$0.11{\mu}m$ CMOS process. The fast current tracking scheme achieves the fast settling time of the output voltage by eliminating the ringing problem. The over-voltage and under-voltage detection circuits decrease the overshoot and undershoot voltages by changing the switch array current rapidly. The switch bias circuit reduces the size of the current switch array to 1/3, which applies a forward body bias voltage at low supply voltage. The fabricated LDO regulator worked at 0.25 V to 1.2 V supply voltage. It achieved 250 mV supply voltage and 220 mV output voltage with 99.5% current efficiency and 8 mV ripple voltage at $20{\mu}A$ to $200{\mu}A$ load current.

A Design of LORAN Disciplined Oscillator

  • Hwang, Sang-Wook;Choi, Yun Sub;Yeo, Sang-Rae;Park, Chansik;Yang, Sung-Hoon;Lee, Sang Jeong
    • Journal of Positioning, Navigation, and Timing
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    • v.2 no.1
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    • pp.75-80
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    • 2013
  • This article presents the design of long range navigation (LORAN)-disciplined oscillator (LDO), employing the timing information of the LORAN system, which was developed as a backup system that corrects the vulnerability of the global positioning system (GPS)-based timing information utilization. The LDO designed on the basis of hardware generates a timing source synchronized with reference to the timing information of the LORAN-C receiver. As for the LDO-based timing information measurement, the Kalman filter was applied to estimate the measurement of which variance was minimized so that the stability performance could be improved. The oven-controlled crystal oscillator (OCXO) was employed as the local oscillator of the LDO. The controller was operated by digital proportional-integral-derivative (PID) controlling method. The LDO performance evaluation environment that takes into account the additional secondary factor (ASF) of the LORAN signals allows for the relative ASF observation and data collection using the coordinated universal time (UTC). The collected observation data are used to analyze the effect of ASF on propagation delay. The LDO stability performance was presented by the results of the LDO frequency measurements from which the ASF was excluded.

Sensor Node Circuit with Solar Energy Harvesting (빛 에너지 수확을 이용한 센서 노드 회로)

  • Seo, Dong-hyeon;Jo, Yong-min;Woo, Dae-keon;Yoon, Eun-jung;Yu, Chong-gun
    • Proceedings of the Korean Institute of Information and Commucation Sciences Conference
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    • 2013.10a
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    • pp.371-374
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    • 2013
  • In this paper, a sensor node circuit using solar energy harvesting is proposed. PMU(Power Management Unit) manages the energy converted from a solar cell. In order to supply a constant voltage to the sensor node, an LDO (Low Drop Out Regulator) is used. The LDO drives a temperature sensor and a SAR ADC(Successive Approximate Register Analog-to-Digital Converter). The circuit has been designed in 0.35um CMOS process.

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A Multi-Harvested Self-Powered Sensor Node Circuit (다중 에너지 수확을 이용한 자가발전 센서노드 회로)

  • Seo, Yo-han;Lee, Myeong-han;Jung, Sung-hyun;Yang, Min-Jae;Yoon, Eun-jung;Yu, Chong-gun
    • Proceedings of the Korean Institute of Information and Commucation Sciences Conference
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    • 2014.10a
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    • pp.585-588
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    • 2014
  • This paper presents a self-powered sensor node circuit using photovoltaic and vibration energy harvesting. The harvested energy from a solar cell and a vibration device(PZT) is stored in a storage capacitor. The stored energy is managed by a PMU(Power Management Unit). In order to supply a stable voltage to the sensor node, an LDO(Low Drop Out Regulator) is used. The LDO drives a temperature sensor and a SAR ADC(Successive Approximate Register Analog-to-Digital Converter), and 10-bit digital output data corresponding to current temperature is obtained. The proposed circuit is designed in a 0.35um CMOS process, and the designed chip size including PADs is $1.1mm{\times}0.95mm$.

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Full CMOS PLC SoC ASIC with Integrated AFE (Analog Frond-End 내장형 전력선 통신용 CMOS SoC ASIC)

  • Nam, Chul;Pu, Young-Gun;Park, Joon-Sung;Hur, Jeong;Lee, Kang-Yoon
    • Journal of the Institute of Electronics Engineers of Korea SD
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    • v.46 no.10
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    • pp.31-39
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    • 2009
  • This paper presents the single supply power line communication(PLC) SoC ASIC with built-in analog frond-end circuit. To achieve the low power consumption along with low chip cost, this PLC SoC ASIC employs fully CMOS analog front-end(AFE) and several built-in Regulators(LDOs) powering for Core logic, ADC, DAC and IP Pad driver. The AFE includes RX of pre-amplifier, Programmable gain amplifier and 10 bit ADC and TX of 10bit Digital Analog Converter and Line driver. This PLC Soc was implemented with 0.18um 1 Poly 5 Metal CMOS process. The single power supply of 3.3V is required for the internal LDOs. The total power consumption is below 30mA at standby and 300mA at active which meets the eco-design requirement. The chips size is $3.686\;{\times}\;2.633\;mm^2$.

Full CMOS Single Supply PLC SoC ASIC with Integrated Analog Front-End

  • Nam, Chul;Pu, Young-Gun;Kim, Sang-Woo;Lee, Kang-Yoon
    • JSTS:Journal of Semiconductor Technology and Science
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    • v.9 no.2
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    • pp.85-90
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    • 2009
  • This paper presents a single supply PLC SoC ASIC with a built-in analog Front-end circuit. To achieve the low power consumption along with low cost, this PLC SoC employs fully CMOS Analog Front End (AFE) and several LDO regulators (LDOs) to provide the internal power for Logic Core, DAC and Input/output Pad driver. The receiver part of the AFE consists of Pre-amplifier, Gain Amplifier and 1 bit Comparator. The transmitter part of the AFE consists of 10 bit Digital Analog Converter and Line Driver. This SoC is implemented with 0.18 ${\mu}m$ 1 Poly 5 Metal CMOS Process. The single supply voltage is 3.3 V and the internal powers are provided using LDOs. The total power consumption is below 30 mA at stand-by mode to meet the Eco-Design requirement. The die size is 3.2 $\times$ 2.8 $mm^{2}$.

Behavioral design aad verification of electronic circuits using CPPSIM (CPPSIM을 이용한 동작 레벨에서의 회로 설계 및 검증)

  • Han, Jin-Seop
    • Journal of the Korea Institute of Information and Communication Engineering
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    • v.12 no.5
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    • pp.893-899
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    • 2008
  • Behavioral level simulations of LDO voltage regulator and phase locked loop(PLL) are performed with CPPSIM, a behavioral-level simulation tool based on C language. The validity of the simulation tool is examined by modeling analog circuits and simulating the circuits. In addition, the designed PLL adopted digital architecture to possess advantages of digital circuits.