A 150-mW, 8-bit video-frequency A/D converter

The authors describe an 8-bit, extremely low-power, flash A/D converter LSI for video-frequency image signal processing. This converter uses a shallow-groove-isolated bipolar VLSI technology. It consumes only 150 mW, which is half the amount of the lowest power consumption so far reported. This low level of power consumption is achieved by the use of a comparator circuit, which is newly designed. This converter can digitize video signals of up to 10 MHz at a conversion rate of 30 MHz. A differential gain (DG) error of 1% and a differential phase (DP) error of less than 0.5/spl deg/ were observed.     

GaAs Ultra-High-Speed Prescaler/Phase Frequency Comparator Using LSCFL (Short Paper)

A high-speed, low-power prescaler/phase frequency comparator (PFC) medium scale integration (MSI) circuit for a phase-locked stable oscillator is designed and fabricated using GaAs MESFET low-power source-coupled FET logic (LSCFL) circuitry. The construction of the 1/64 frequency divider prescaler/PFC is designed to obtain high-speed and low-power operation. The fabrication process used is buried p-layer SAINT with a 0.5-µm gate length. The fabricated prescaler/PFC MSI circuit, mounted on a newly developed high-frequency package, operates up to 7.6 GHz with a power dissipation of 730 mW.     

5.7 GHz low-power variable-gain LNA in 0.18 /spl mu/m CMOS

A variable-gain low-noise amplifier (LNA) suitable for low-voltage and low-power operation is designed and implemented in a standard 0.18 /spl mu/m CMOS technology. With a current-reused topology, the common-source gain stages are stacked for minimum power dissipation while achieving high small-signal gain. The fully integrated 5.7 GHz LNA exhibits 16.4 dB gain, 3.5 dB noise figure and 8 dB gain tuning range with good input and output return losses. The LNA consumes 3.2 mW DC power from a supply voltage of 1 V. A gain/power quotient of 5.12 dB/mW is achieved in this work.     

A low-power switched-current CDMA matched filter employing MOS linear matching cell with on-chip A/D converter

A low-power switched-current matched filter (MF) for code-division multiple-access (CDMA) systems has been developed. The front-end voltage-to-current (V/I) converter has been eliminated by merging the function into each matching cell utilizing the MOS linear I-V characteristics. A low-power analog-to-digital (A/D) converter has also been developed to establish smooth interfacing to digital back-end processing for a delayed locked loop (DLL) and a RAKE receiver. A proof-of-concept chip was fabricated in a 0.35-μm standard CMOS technology with a measured power consumption of 1.65 mW at 11 Mchip/s with 2-V power supply including the A/D converter.     

Low-Power Area-Efficient Pipelined A/D Converter Design Using a Single-Ended Amplifier

This paper presents a new scheme of a low-power area-efficient pipelined A/D converter using a single-ended amplifier. The proposed multiply-by-two single-ended amplifier using switched capacitor circuits has smaller DC bias current compared to the conventional fully-differential scheme, and has a small capacitor mismatch sensitivity, allowing us to use a smaller capacitance. The simple high-gain dynamic-biased regulated cascode amplifier also has an excellent switching response. These properties lead to the low-power area-efficient design of high-speed A/D converters. The estimated power dissipation of the 10-b pipelined A/D converter is less than 12 mW at 20 MSample/s.     

An ultralow power CMOS/SIMOX programmable counter LSI

We designed and fabricated an extremely low-power CMOS/SIMOX programmable counter large scale integrated circuits (LSI) for high-speed phase-locked loop (PLL) frequency synthesizer applications. This was to verify the potential usefulness of ultrathin-film 0.24-μm-gate CMOS/SIMOX process technology for creating an extremely low-power LSI containing high-speed circuits operating at frequencies of at least 1 GHz and at low supply voltages. While operating at up to 2.2 GHz and consuming only 4.5 mW at 1.5 V, it is capable of 4-GHz performance with power consumption of 19 mW at 2.5 V. Even at a low supply voltage of 1.5 V, high input-sensitivity was also achieved in the 1- to 2-GHz frequency range. These low-power and high input-sensitivity characteristics outperform those of state-of-the-art BiCMOS PLL LSIs     

1 V power supply, low-power consumption A/D conversion techniquewith swing-suppression noise shaping

A 1 V power supply and low-power consumption A/D conversion technique using swing-suppression noise shaping is proposed. This technique makes it possible to power the on chip A/D converter in digital LSI's directly by a one-cell battery, without a dc-dc converter. Experimental results indicated good performance for the RF-to-baseband analog interface of a digital cordless phone. The A/D converter, fabricated with a 0.5 μm CMOS process, operates on a 1 V power supply, has a 10 bit dynamic-range with a 384 ksps sampling speed and consumes only 1.56 mW     

2.5Gb/s 16:1MUX IC Design with CMOS

A low-power and high-speed 16:1 MUX IC designed for optical fiber communication based on TSMC 0.25 μm CMOS technology is presented. A tree-type architecture was utilized. The output data bit rate is 2.5 Gb/s at input clock rate of 1.25 GHz. The simulation results show that the output signal has peak-to-peak amplitude of 400 mV, the power dissipation is less than 200 mW and the power dissipation of core circuit is less than 20 mW at the 2.5 Gb/s standard bit rate and supply voltage of 2.5 V. The chip area is 1.8 mm2.     

An 800-MHz low-power direct digital frequency synthesizer with an on-chip D/a converter

An 800-MHz low-power direct digital frequency synthesizer (DDFS) with an on-chip digital-to-analog (D/A) converter is presented. The DDFS consists of a phase accumulator, two phase-to-sine converters, and a D/A converter. The high-speed operation of the DDFS is enabled by applying parallelism to the phase-to-sine converter and by including a D/A converter in a single chip. The on-chip D/A converter saves delay and power consumption due to interchip interconnections. The DDFS considerably reduces power consumption by using several low-power techniques. The pipelined parallel accumulator consumes only 22% power of a conventional pipelined accumulator with the same throughput. The quad line approximation (QLA) and the quantization and error ROM (QE-ROM) minimize the ROM to generate a sine wave. The QLA saves 4 bits of the sine amplitude by approximating the sine function with four lines. The QE-ROM quantizes the ROM data by magnitude and address and then it stores the quantized values and the quantization errors separately. The ROM size for a 9-bit sine output is only 368 bits. A DDFS chip is fabricated in a 0.35-/spl mu/m CMOS process. It consumes only 174 mW at 800 MHz with 3.3 V. The chip core area is 1.47 mm/sup 2/. The spurious-free dynamic range (SFDR) is 55 dBc.     

2.5 Gb／s 16：1 MUX IC Design with CMOS

A low--power and high--speed 16.-1 MUX IC designed for optical fiber communication based on TSMC 0.25μm CMOS technology is presented. A tree—type architecture was utilized. The output data bit rate is 2.5 Gb/s at input clock rate of 1.25 GHz. The simulation results show that the output signal has peak—to—peak amplitude of 400 mV, the power dissipation is less than 200 mW and the power dissipation of core circuit is less than 20 mW at the 2.5 Gb/s standard bit rate and supply voltage of 2.5 V. The chip area is 1.8mm^2.     

Low-power InP/GaAsSb/InP DHBT cascode transimpedance amplifier with GBP/P/sub dc/ of 7.2 GHz/mW

A low-power high gain-bandwidth monolithic cascode transimpedance amplifier using novel InP/GaAsSb/InP DHBT technology was investigated. The amplifier exhibited state-of-the-art performance of 17.3 dB gain, 12 GHz bandwidth, 55 dB/spl Omega/ transimpedance, and a corresponding gain-bandwidth of 6.7 THz/spl Omega/ while consuming only 12.2 mW DC power. It also achieved good gain-bandwidth-product per DC power figure-of-merit (GBP/P/sub dc/) of 7.2 GHz/mW     

A low-power ASIC design for cell search in the W-CDMA system

This paper presents a low-power ASIC design for cell search in the wideband code-division multiple-access (W-CDMA) system. A low-complexity algorithm that is able to work satisfactorily under the effect of large frequency and clock errors is designed first. Then, a set of low-power measures are employed in the design of hardware architecture and circuits. Finally, through power analysis, critical blocks are identified and redesigned so as to further reduce the power consumption. The final design shows that the power is reduced by 51% from the original design of 133.6 mW to 65.49 mW, and its core area is also reduced by 31.9% from 3.4/spl times/3.4 mm/sup 2/ to 2.8/spl times/2.8 mm/sup 2/. The design is implemented and verified in a 3.3-V 0.35-/spl mu/m CMOS technology with clock rate 15.36 MHz.     

A low-power stereo 16-bit CMOS D/A converter for digital audio

A low-power 16-bit CMOS D/A (digital/analog) converter for portable digital audio is described. The converter is based on current division. To guarantee monotonicity and a good small-signal reproduction, a dynamic segmentation technique is used. A geometric averaging technique is used to minimize the harmonic distortion of the converter at high signal levels. The dynamic range is 95 dB. The circuit operates in a time-multiplex mode at a sample frequency of 44 kHz in a power supply range of 2.5-5 V and has a power consumption of 15 mW. A 2-μm CMOS technology is used and the active chip area is 5 mm²      

A versatile bipolar monolithic 6-bit A/D converter for 100 MHz sample frequency

An A/D converter was developed which uses a parallel conversion technique and is designed for manufacture with an ASBC process. The converter SDA 5010 is suitable for a wide range of applications because of its high-conversion rate, its low-power dissipation of 450 mW, large analog input range of up to /spl plusmn/2.5 V, and an overflow output for systems where a higher accuracy than 6 bits is required.     

A 557-mW, 2.5-Gbit/s SONET/SDH regenerator-section terminating LSIchip using low-power bipolar-LSI design

A regenerator-section terminating digital large-scale-integration chip for an STM-16 (2.5-Gbit/s synchronous optical network/synchronous digital hierarchy) regenerator has been developed using low-power bipolar technologies. The high-speed performance of bipolar devices enabled four or more chips, including a demultiplexer and a multiplexer, to be integrated into a single chip. The low-power dissipation of 557 mW, only about one-tenth that of previously reported chips, was achieved through the use of four design steps: one-chip integration architecture, power management, 2.5-V emitter-coupled logic, and power optimization     

A low-power 20-GHz 52-dB/spl Omega/ transimpedance amplifier in 80-nm CMOS

This paper describes the design of a transimpedance amplifier (TIA) for a low-power, short-distance, high-density fiber-optic interconnect communication system. The single-ended circuit has been designed in an 80-nm digital CMOS process and consumes only 2.2 mW from a 1-V supply. The measured results show a transimpedance gain of 52 dB/spl Omega/ and a large bandwidth of 20 GHz. This work presents the highest bandwidth at the lowest power consumption for CMOS transimpedance amplifiers reported to date.     

一个低功耗1G-samples/s,6-bit折叠插值ADC芯片设计

本文提出了一种具有高线性度的折叠,插值结构数模转换器(ADC)。与高速并行数模转换器(Flash ADC)相比较,该结构具有面积小,功耗低的特点,适用于低功耗超宽带(UWB)接收机中。本文对电路各部分进行了设计,并在SMIC 0.18μm工艺下完成了版图设计和后仿真。版图核心电路面积(不包括PAD)仅为0.45mm2,在1G samples/s采样率,输入信号为488.77MHz时,总功耗仅为57mW,有效位(ENOB)达到5.74bits。     

A 70-MS/s 110-mW 8-b CMOS folding and interpolating A/D converter

A CMOS analog to digital converter based on the folding and interpolating technique is presented. This technique is successfully applied in bipolar A/D converters and now also becomes available in CMOS technology. The analog bandwidth of the A/D converter is increased by using a transresistance amplifier at the outputs of the folding amplifiers and, due to careful circuit design, the comparators need no offset compensation. The result is a small area (0.7 mm² in 0.8 μm CMOS), high speed (70 MS/s), and low-power (110 mW at 5 V supply, including reference ladder) A/D converter. A 3.3 V supply version of the circuit runs at 45 MS/s and dissipates 45 mW     

Low-power/low-voltage RF microsystems for wireless sensors networks

This paper presents radio-frequency (RF) microsystems (MSTs) composed by low-power devices for use in wireless sensors networks (WSNs). The RF CMOS transceiver is the main electronic system and its power consumption is a critical issue. Two RF CMOS transceivers with low-power and low-voltage supply were fabricated to operate in the 2.4 and 5.7 GHz ISM bands. The measurements made in the RF CMOS transceiver at 2.4 GHz, which showed a sensitivity of −60 dBm with a power consumption of 6.3 mW from 1.8 V supply. The measurements also showed that the transmitter delivers an output power of 0 dBm with a power consumption of 11.2 mW. The RF CMOS transceiver at 5.7 GHz has a total power consumption of 23 mW. The target application of these RF CMOS transceivers is for MSTs integration and for use as low-power nodes in WSNs to work during large periods of time without human operation, management and maintenance. These RF CMOS transceivers are also suitable for integration in thermoelectric energy scavenging MSTs.     

A 1-V 2.5-mW 5.2-GHz frequency divider in a 0.35-/spl mu/m CMOS process

A 1-V low-power high-speed dynamic-loading frequency divider is proposed using novel D flip-flops with a common-gate topology and with a single clock phase. A simple and accurate small-signal analysis model is provided to estimate the operating frequencies of the divider. Implemented in a standard digital 0.35-/spl mu/m CMOS process and at 1-V supply, the proposed frequency divider measures a maximum operating frequency up to 5.2 GHz with a power consumption of 2.5 mW.