Your search keyword '"Low-voltage oscillator"' showing total 5 results

1. A Fully Integrated Bluetooth Low-Energy Transmitter in 28 nm CMOS With 36% System Efficiency at 3 dBm.

Author

Babaie, Masoud, Kuo, Feng-Wei, Chen, Huan-Neng Ron, Cho, Lan-Chou, Jou, Chewn-Pu, Hsueh, Fu-Lung, Shahmohammadi, Mina, and Staszewski, Robert Bogdan

Subjects

COMPLEMENTARY metal oxide semiconductors, POWER amplifiers, ELECTRONIC amplifiers, INTEGRATED circuit design, BLUETOOTH technology

Abstract

We propose a new transmitter architecture for ultra-low power radios in which the most energy-hungry RF circuits operate at a supply just above a threshold voltage of CMOS transistors. An all-digital PLL employs a digitally controlled oscillator with switching current sources to reduce supply voltage and power without sacrificing its startup margin. It also reduces 1/f noise and supply pushing, thus allowing the ADPLL, after settling, to reduce its sampling rate or shut it off entirely during a direct DCO data modulation. The switching power amplifier integrates its matching network while operating in class-E/F2 to maximally enhance its efficiency at low voltage. The transmitter is realized in 28 nm digital CMOS and satisfies all metal density and other manufacturing rules. It consumes 3.6 mW/5.5 mW while delivering 0 dBm/3 dBm RF power in Bluetooth Low-Energy mode. [ABSTRACT FROM PUBLISHER]

Published

2016

2. A 475 mV, 4.9 GHz Enhanced Swing Differential Colpitts VCO With Phase Noise of -136 dBc/Hz at a 3 MHz Offset Frequency.

Author

Brown, Thomas W., Farhabakhshian, Farhad, Guha Roy, Ankur, Fiez, Terri S., and Mayaram, Kartikeya

Subjects

VOLTAGE-controlled oscillators, ELECTRIC potential, ELECTRIC inductors, ENERGY consumption, ELECTRICAL engineering, FREQUENCY response, POWER resources

Abstract

A new enhanced swing differential Colpitts VCO architecture enables oscillations to go beyond both the supply voltage and ground making it suitable for low voltage operation. Analysis for the oscillation frequency, differential- and common-mode oscillations, amplitude of oscillation, and start-up condition provides insight into oscillator operation and design considerations. Operating at 4.9 GHz, the VCO consumes from 1.9 mW to 3 mW for supply voltages of 400 mV and 500 mV, respectively. The 130 nm CMOS VCO's measured phase noise ranges from -132.6 to -136.2 dBc/Hz at a 3 MHz offset frequency. [ABSTRACT FROM AUTHOR]

Published

2011

3. High-Voltage Analog System for a Mobile NAND Flash.

Author

Yong Hoon Kang, Jin-Kook Kim, Sang Won Hwang, Joon Young Kwak, Jun-yong Park, Daeyong Kim, Chan Ho Kim, Jong Yeol Park, Yong-taek Jeong, Jong Nam Buek, Su Chang Jeon, Pyungmoon Jang, Sang Hoon Lee, You-Sang Lee, Min-seok Kim, Jin-Yub Lee, and Yun Ho Choi

Subjects

HIGH voltages, FLASH memory, VOLTAGE regulators, ELECTRONIC circuit design, ELECTRIC oscillators, ELECTRONIC circuits, SIMULATION methods & models, ELECTRIC controllers, POWER resources

Abstract

High-voltage analog circuits, including a novel high-voltage regulation scheme, are presented with emphasis on low supply voltage, low power consumption, low area overhead, and low noise, which are key design metrics for implementing NAND Flash memory in a mobile handset. Regulated high voltage generation at low supply voltage is achieved with optimized oscillator, high-voltage charge pump, and voltage regulator circuits. We developed a design methodology for a high-voltage charge pump to minimize silicon area, noise, and power consumption of the circuit without degrading the high-voltage output drive capability. Novel circuit techniques are proposed for low supply voltage operation. Both the oscillator and the regulator circuits achieve 1.5 V operations, while the regulator includes a ripple suppression circuit that is simple and robust. Through the paper, theoretical analysis of the proposed circuits is provided along with Spice simulations. A mobile NAND Flash device is realized with an advanced 63 nm technology to verify the operation of the proposed circuits. Extensive measurements show agreement with the results predicted by both analysis and simulation. [ABSTRACT FROM AUTHOR]

Published

2008

4. A Fully Integrated Bluetooth Low-Energy Transmitter in 28 nm CMOS With 36% System Efficiency at 3 dBm

Author

Feng Wei Kuo, Chewn-Pu Jou, Lan-Chou Cho, Fu-Lung Hsueh, Mina Shahmohammadi, Masoud Babaie, Robert Bogdan Staszewski, and Huan-Neng Ron Chen

Subjects

Engineering, oscillators, supply voltage reduction, Internet of Things, 1/f noise reduction, low-voltage oscillator, 02 engineering and technology, Hardware_PERFORMANCEANDRELIABILITY, 7. Clean energy, Radio transmitters, law.invention, Bluetooth, class-E/F 2 power amplifier, MOSFET circuits, law, Radio frequency, 0202 electrical engineering, electronic engineering, information engineering, Inductors, sampling rate reduction, direct DCO data modulation, class-E-F2 switching power amplifier, RF power amplifier, Transmitter, Electrical engineering, Q-factor, CMOS digital integrated circuits, all-digital PLL, Switching current-source oscillator, digital phase locked loops, Low-voltage oscillator, CMOS, constant current sources, ultra-low power radios, switching current sources, All-digital PLL, efficiency 36 percent, fully integrated Bluetooth low-energy transmitter architecture, metal density, power 5.5 mW, CMOS transistors, low-power transmitter, Low-power transmitter, energy-hungry RF circuits, Hardware_GENERAL, Electronic engineering, Hardware_INTEGRATEDCIRCUITS, Digitally controlled oscillator, Electrical and Electronic Engineering, power 3.6 mW, threshold voltage, switching current-source oscillator, business.industry, Amplifier, radiofrequency power amplifiers, 020208 electrical & electronic engineering, size 28 nm, 020206 networking & telecommunications, CMOS integrated circuits, radiofrequency integrated circuits, Internet of Things (IoT), Phase-locked loop, Bluetooth Low-Energy, low-power electronics, Bluetooth low-energy mode, business, digitally controlled oscillator, Low voltage, Switches

Abstract

We propose a new transmitter architecture for ultra-low power radios in which the most energy-hungry RF circuits operate at a supply just above a threshold voltage of CMOS transistors. An all-digital PLL employs a digitally controlled oscillator with switching current sources to reduce supply voltage and power without sacrificing its startup margin. It also reduces 1/f noise and supply pushing, thus allowing the ADPLL, after settling, to reduce its sampling rate or shut it off entirely during a direct DCO data modulation. The switching power amplifier integrates its matching network while operating in class-E/F2 to maximally enhance its efficiency at low voltage. The transmitter is realized in 28 nm digital CMOS and satisfies all metal density and other manufacturing rules. It consumes 3.6 mW/5.5 mW while delivering 0 dBm/3 dBm RF power in Bluetooth Low-Energy mode. European Research Council

Published

2016

5. A Fully Integrated Bluetooth Low-Energy Transmitter in 28 nm CMOS With 36% System Efficiency at 3 dBm

Author

Babaie, M. (author), Kuo, F (author), Chen, H (author), Cho, L (author), Jou, C. P. (author), Hsueh, F. L. (author), Shahmohammadi, M. (author), Staszewski, R.B. (author), Babaie, M. (author), Kuo, F (author), Chen, H (author), Cho, L (author), Jou, C. P. (author), Hsueh, F. L. (author), Shahmohammadi, M. (author), and Staszewski, R.B. (author)

Abstract

We propose a new transmitter architecture for ultra-low power radios in which the most energy-hungry RF circuits operate at a supply just above a threshold voltage of CMOS transistors. An all-digital PLL employs a digitally controlled oscillator with switching current sources to reduce supply voltage and power without sacrificing its startup margin. It also reduces 1/f noise and supply pushing, thus allowing the ADPLL, after settling, to reduce its sampling rate or shut it off entirely during a direct DCO data modulation. The switching power amplifier integrates its matching network while operating in class-E/F2 to maximally enhance its efficiency at low voltage. The transmitter is realized in 28 nm digital CMOS and satisfies all metal density and other manufacturing rules. It consumes 3.6 mW/5.5 mW while delivering 0 dBm/3 dBm RF power in Bluetooth Low-Energy mode., Electronics

Published

2016