An 8-bit 150-MHz CMOS A/D converter

This paper describes an 8-bit 5-stage pipelined and interleaved analog-to-digital converter that performs analog processing only by means of open-loop circuits such as differential pairs and source followers to achieve a high conversion rate. The concept of sliding interpolation is proposed to obviate the need for a large number of comparators or interstage digital-to-analog converters and residue amplifiers. The pipelining scheme incorporates distributed sampling between the stages so as to relax the linearity-speed tradeoffs in the sample-and-hold circuits, A clock edge reassignment technique is also introduced that suppresses timing mismatches in interleaved systems, and a punctured interpolation method is proposed that reduces the integral nonlinearity error with negligible speed or power penalty. Fabricated in a 0.6-μm CMOS technology, the converter achieves differential and integral nonlinearities of 0.62 and 1.24 LSB, respectively, and a signal-to-(noise+distortion) ratio of 43.7 dB at a sampling rate of 150 MHz. The circuit draws 395 mW from a 3.3-V supply and occupies an area of 1.2×1.5 mm²     

An 8-MHz CMOS subranging 8-bit A/D converter

A 8-bit subranging converter (ADC) has been realized in a 3-/spl mu/m silicon gate, double-polysilicon capacitor CMOS process. The ADC uses 31 comparators and is capable of conversion rates to 8 MHz at V/SUB DD/=5 V. Die size is 3.2/spl times/2.2 mm/SUP 2/.     

An 8-bit high-speed CMOS A/D converter

An 8-bit high-speed A/D converter has been developed in a 1.5-/spl mu/m bulk CMOS double-polysilicon process technology. The design, process technology, and performance of the converter are described. In order to achieve high speed and low power, a fine-pattern process technology and a novel capacitor structure have been introduced and the transistor sizes of a chopper-type comparator have been optimized. High speed (30 MS/s) and low power consumption (60 mW) have been obtained. Computerized evaluations such as the histogram test and the fast Fourier transform test have been used to measure dynamic performance. The linearity error in dynamic operation is less than /spl plusmn/1 LSB. Signal-to-peak-noise ratio is 40 dB at a sampling rate of 14.32 MS/s and an input frequency of 1.42 MHz.     

An 8-bit 50-MHz CMOS subranging A/D converter with pipelinedwide-band S/H

An 8-b video-rate subranging analog-to-digital (A/D) converter with pipelined wideband sample-and-hold (S/H) amplifiers is described. The chip architecture is based on a newly developed subranging technique that combines a digital-to-analog subconverter and a subtractor in one body. The development of a bandwidth enhancement technique for the S/H amplifier yields a wide effective resolution bandwidth using 1-μm CMOS technology. An effective resolution bandwidth of 25 MHz was achieved, as well as a small input capacitance of 1.5 pF, due to the high performance of the S/H circuit developed     

A 500-MHz 8-bit D/A converter

An ultrafast monolithic 8-bit DAC is designed and fabricated. To realize this DAC, a new high-speed conversion technique, referred to as the data multiplexing method, and a variation of the segmented DAC (J.A. Shoeff, 1979) for low glitch are developed. The DAC is fabricated with shallow-groove-isolated 3-/spl mu/m VLSI technology with peak f/SUB T/'s of 4.5 GHz. An experimental 8-bit DAC features a conversion rate of over 500 MHz, a full-scale settling time to 1% of 2 ns, rise/fall times of 0.6 ns, and a glitch energy of 20 ps-V without input latches or a deglitcher.     

An 80-MHz, 80-mW, 8-b CMOS folding A/D converter with distributedtrack-and-hold preprocessing

An analog-to-digital converter incorporating a distributed track-and-hold preprocessing combined with folding and interpolation techniques has been designed in CMOS technology. The presented extension of the well known folding concept has resulted in a 75 MHz maximum full-scale input signal frequency. A signal-to-noise ratio of 44 dB is obtained for this frequency. The 8-b A/D converter achieves a clock frequency of 80 MHz with a power dissipation of 80 mW from a 3.3 V supply voltage. The active chip area is 0.3 mm² in 0.5-μm standard digital CMOS technology     

A low glitch 10-bit 75-MHz CMOS video D/A converter

A low glitch 10-bit 75-MHz CMOS current-output video digital-to-analog Converter (DAC) for high-definition television (HDTV) applications is described. In order to achieve monotonicity and low glitch, a special segmented antisymmetric switching sequence and an innovative asymmetrical switching buffer have been used. The video DAC has been fabricated by using 0.8 μm single-poly double-metal CMOS technology. Experimental results indicated that the conversion rate is above 75 MHz, and nearly 50% of samples have differential and integral linearity errors less than 0.24 LSB and 0.6 LSB, respectively. The glitch has been reduced to be less than 3.9 pV·s and the settling time within ±0.1% of the final value is less than 13 ns. The video DAC is operated by a single 5 V power supply and dissipates 1.70 mW at 75 MHz conversion rate (140 mW in the DAC portion). The chip size of video DAC is 1.75 mm×1.2 mm (1.75 mm×0.7 mm for the DAC portion)     

An 8-bit 100-MHz full-Nyquist analog-to-digital converter

An 8-bit 100-MHz full-Nyquist analog-to-digital (A/D) converter using a folding and interpolation architecture is presented. In a folding system a multiple use of comparator stages is implemented. A reduction in the number of comparators, equal to the number of times the signal is folded, is obtained. However, every quantization level requires a folding stage, thus no reduction in input circuitry is found. Interpolation between the outputs of the folding stages generates additional folding signals without the need for input stages. A reduction in input circuitry equal to the number of interpolations is obtained. The converter is implemented in an oxide-isolated bipolar process, requiring 800 mW from a single 5.2-V supply. A high-level model describing distortion caused by timing errors is presented. Considering clock timing accuracies needed to obtain the speed requirement, this distortion is thought to be the main speed limitation     

An 8-bit parasitic-insensitive switched-capacitor A/D converter

An algorithmic A/D converter (ADC) is presented which employs switched capacitors. The ADC is insensitive to parasitic capacitances and op-amp offset voltages. Capacitor ratio-mismatch errors and charge injection errors are investigated. System level computer simulations are included to support the theory. The technique is suitable for 8-bit A/D conversion using present CMOS technology.     

An 8-bit 100-MHz CMOS linear interpolation DAC

An 8-bit 100-MHz CMOS linear interpolation digital-to-analog converter (DAC) is presented. It applies a time-interleaved structure on an 8-bit binary-weighted DAC, using 16 evenly skewed clocks generated by a voltage-controlled delay line to realize the linear interpolation function. The linear interpolation increases the attenuation of the DAC's image components. The requirement for the analog reconstruction filter is, therefore, greatly relaxed. The DAC aims for the single-chip integration of a wireless transmitter. The chip was fabricated in a 3.3-V 0.35-/spl mu/m double-poly triple-metal CMOS process. The core size of the chip is 0.67 mm /spl times/ 0.67 mm, and the total power consumption is 54.5 mW with 3.3-V power supplies. The attenuation (in decibels) of image components is doubled compared with a conventional DAC.     

A 16-bit low-voltage CMOS A/D converter

A/D converters used in telemetry, instrumentation, and measurements require high accuracy, excellent linearity, and negligible DC offset, but need not be fast. A simple and robust instrumentation A/D converter, fabricated in a low-voltage 4-/spl mu/m CMOS technology, is described. The measured overall accuracy was 16 bits. Using a digital compensation for parasitic effects, both offset and nonlinearity were below 12 /spl mu/V. With analog compensation, the offset was 60 /spl mu/V and the nonlinearity below 15 /spl mu/V. These results indicate that even higher accuracy can be achieved using higher voltage technology.     

An 8-bit 20-MS/s CMOS A/D converter with 50-mW power consumption

Low power consumption and small chip area (2.09 mm×2.15 mm) are achieved by introducing a new architecture to a subranging A/D converter. In this architecture, both coarse and fine A/D conversions can be accomplished. Consequently, a large number of comparators and processing circuits have been removed from the conventional subranging A/D converter. This architecture has been realized by the introduction of a chopper-type comparator with three input terminals which makes both coarse and fine comparisons by itself. The A/D converter has two 8-b sub/A/D converters which employ this new architecture, and they are pipelined to improve the conversion rate. Good experimental results have been obtained. Both the differential and the integral nonlinearity are less than ±0.5 LSB at a 20-megasample/s sample frequency. The effective resolution at 20-megasample/s sampling frequency is 7.4 b at a 1.97-MHz input frequency and 6.7 b at a 9.79-MHz input frequency. The A/D converter has been fabricated in a 1-μm CMOS technology     

A 25-Ms/s 8-bit CMOS A/D converter for embedded application

The design of an 8-bit CMOS A/D converter is described which is intended for embedded operation in VLSI chips for video applications. The requirements on accuracy are analyzed and a comparator circuit is shown which realizes a high bandwidth. The full-flash architecture operates on wideband signals like CVBS in television systems. The A/D converter core measures 2.8 mm² in a 1 μm CMOS process. The embedded operation of the A/D converter is illustrated on a video line-resizing chip     

一种低功耗10位流水线结构的CMOS A/D转换器的设计

本文设计了一种可满足视频速度应用的低电压低功耗10位流水线结构的CMOS A/D转换器.该转换器由9个低功耗运算放大器和19个比较器组成,采用1.5位/级共9级流水线结构,级间增益为2并带有数字校正逻辑.为了提高其抗噪声能力及降低二阶谐波失真,该A/D转换器采用了全差分结构.全芯片模拟结果表明,在3V工作电压下,以20MHz的速度对2MHz的输入信号进行采样时,其信噪失调比达到53dB,功率消耗为28.7mW.最后,基于0.6μm CMOS工艺得到该A/D转换器核的芯片面积为1.55mm2.     

A 10-b 15-MHz CMOS recycling two-step A/D converter

A two-step recycling technique is applied to implement a 10-b CMOS analog-to-digital (A/D) converter with a video conversion rate of 15 Msample/s. In a prototype digitally corrected converter, one capacitor-array multiplying digital-to-analog converter (MDAC) is used repeatedly as a sample-and-hold (S/H) amplifier, a DAC, and a residue amplifier so that the proposed converter may obtain linearity with the capacitor-array matching. An experimental fully differential A/D converter implemented using a double-poly 1-μm CMOS technology consumes 250 mW with a 5-V single supply, and its active die area, including all digital logic and output buffers, is 1.75 mm² (2700 mil²). Because the conversion accuracy of the proposed architecture relies on a capacitor-array MDAC linearity, high-resolution CMOS A/D conversions are feasible at high frequencies if sophisticated circuit techniques are further developed. For high-speed two-phase versions, the system can be easily modified to use multiplexing and/or pipelining techniques with a separate S/H amplifier and/or two separate flash converters     

An 8-bit, 5 ns monolithic D/A converter subsystem

Describes a 5 ns settling time digital-to-analog converter device, which has been designed for use in video speed successive approximation analog to digital converters. The chip includes a precision reference source with a 25 ppm per degree C average temperature coefficient and a high-speed comparator. The successive approximation approach, restricted to low-speed converters until now, has the advantages of low cost and straightforward drive requirements. The achievement of the operating speeds described is dependent both on the circuit techniques used and the process employed. The DAC circuit, unlike most other devices, uses a multiple-matched current source array technique, which leads to a very linear, low glitch output. Without any form of trimming, most functional devices meet a /spl plusmn//SUP 1///SUB 2/ LSB differential and integral linearity specification, and many are /spl plusmn//SUP 1///SUB 4/ LSB or better.     

An 8-bit 80-Msample/s pipelined analog-to-digital converter withbackground calibration

An 8-bit 80-Msample/s pipelined analog-to-digital converter (ADC) uses monolithic background calibration to reduce the nonlinearity caused by interstage gain errors. Test results show that the ADC achieves a peak signal-to-noise-and-distortion ratio of 43.8 dB, a peak integral nonlinearity of 0.51 least significant bit (LSB), and a peak differential nonlinearity of 0.32 LSB with active background calibration. It dissipates 268 mW from a 3 V supply and occupies 10.3 mm ² in a single-poly 0.5 μm CMOS technology     

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

A complete monolithic stereo 16-bit D/A converter primarily intended for use in compact-disc players and digital audio tape recorders is described. The D/A converter achieves 16-bit resolution by using a code-conversion technique based upon oversampling and noise shaping. The band-limiting filters required for waveform smoothing and out-of-band noise reduction are included. Owing to the oversampling principle most applications will require only a few components for an analog postfilter. The converter has a linear characteristic and linear phase response. The chip is processed in a 2-/spl mu/m CMOS process and the die size is 44 mm/SUP 2/. Only a single 5-V supply is needed.     

A single chip all-MOS 8-bit A/D converter

A new analog-to-digital (A/D) conversion technique compatible with standard single channel MOS technology is described. This technique uses a string of equal value diffused resistors and a matrix of analog switches to perform high-speed successive approximation conversion. The comparator function is realized by a chopper-type amplifier to reduce the inherently high input offset voltages of MOS differential stages. Typical performance characteristics taken from a large sample of ICs are presented; a resolution of 8 bits has been achieved with a conversion time of 20 /spl mu/s. The complete system is fabricated on a 14000 mil/SUP 2/ die. Due to its small relative size, this A/D technique has been incorporated as part of a larger CODEC system.     

A 10-bit 20-MHz two-step parallel A/D converter with internal S/H

A 10-bit 20-MHz A/D converter for high-quality video systems such as high-definition television, video tape recorders for business use, and digital video cameras is described. This LSI circuit uses a standard two-step parallel architecture, includes automatic gain adjustment and digital two-bit error correction, and has a sample-and-hold circuit on the chip. It is fabricated by a 4.5-GHz f_T. 3-μm-rule standard bipolar technology. Its die size is 25 mm² , and its power consumption is 900 mW, which is about half of the lowest values reported to date. The converter can digitize video signals of up to 8.5 MHz at a conversion frequency of 20 MHz. The error in differential gain is 0.5 percent, and the error in differential phase is 0.5°