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 pipelined 5-Msample/s 9-bit analog-to-digital converter

A pipelined, 5-Msample/s, 9-b analog-to-digital converter with digital correction has been designed and fabricated in 3-/spl mu/m CMOS technology. It requires 8500 mil/SUP 2/, consumes 180 mW, and has an input capacitance of 3 pF. A fully differential architecture is used; only a two-phase nonoverlapping clock is required, and an on-chip sample-and-hold amplifier is included.     

A 10-b 120-Msample/s time-interleaved analog-to-digital converter with digital background calibration

Digital calibration using adaptive signal processing corrects for offset mismatch, gain mismatch, and sample-time error between time-interleaved channels in a 10-b 120-Msample/s pipelined analog-to-digital converter (ADC). Offset mismatch between channels is overcome with a random chopper-based offset calibration. Gain mismatch and sample-time error are overcome with correlation-based algorithms, which drive the correlation between a signal and its chopped image or its chopped and delayed image to zero. Test results show that, with a 0.99-MHz sinusoidal input, the ADC achieves a peak signal-to-noise-and-distortion ratio (SNDR) of 56.8 dB, a peak integral nonlinearity of 0.88 least significant bit (LSB), and a peak differential nonlinearity of 0.44 LSB. For a 39.9-MHz sinusoidal input, the ADC achieves a peak SNDR of 50.2 dB. The active area is 5.2 mm/sup 2/, and the power dissipation is 234 mW from a 3.3-V supply.     

A 15-b 40-MS/s CMOS pipelined analog-to-digital converter with digital background calibration

This study presents a 15-b 40-MS/s switched-capacitor CMOS pipelined analog-to-digital converter (ADC). High resolution is achieved by using a correlation-based background calibration technique that can continuously monitor the transfer characteristics of the critical pipeline stages and correct the digital output codes accordingly. The calibration can correct errors associated with capacitor mismatches and finite opamp gains. The ADC was fabricated using a 0.25-/spl mu/m 1P5M CMOS technology. Operating at a 40-MS/s sampling rate, the ADC attains a maximum signal-to-noise-plus-distortion ratio of 73.5 dB and a maximum spurious-free-dynamic-range of 93.3 dB. The chip occupies an area of 3.8/spl times/3.6 mm/sup 2/, and the power consumption is 370 mW with a single 2.5-V supply.     

A 12-bit 100 MS/s pipelined ADC with digital background calibration

This paper presents a 12-bit 100 MS/s CMOS pipelined analog-to-digital converter (ADC) with digital background calibration. A large magnitude calibration signal is injected into the multiplying digital-to-analog converter (MDAC) while the architecture of the MDAC remains unchanged. When sampled at 100 MS/s, it takes only 2.8 s to calibrate the 12-bit prototype ADC and achieves a peak spurious-free dynamic range of 85 dB and a peak signal-to-noise plus distortion ratio of 66 dB with 2 MHz input. Integral nonlinearity is improved from 1.9 to 0.6 least significant bits after calibration. The chip is fabricated in a 0.18μm CMOS process, occupies an active area of 2.3×1.6 mm~2, and consumes 205 mW at 1.8 V.     

采用后台数字校准的12位100MHz流水线模数转换器

This paper presents a 12-bit 100 MS/s CMOS pipelined analog-to-digital converter （ADC） with digital background calibration. A large magnitude calibration signal is injected into the multiplying digital-to-analog converter （MDAC） while the architecture of the MDAC remains unchanged. When sampled at 100 MS/s, it takes only 2.8 s to calibrate the 12-bit prototype ADC and achieves a peak spurious-free dynamic range of 85 dB and a peak signal-to-noise plus distortion ratio of 66 dB with 2 MHz input. Integral nonlinearity is improved from 1.9 to 0.6 least significant bits after calibration. The chip is fabricated in a 0.18μm CMOS process, occupies an active area of 2.3 × 1.6 mm^2, and consumes 205 mW at 1.8 V.     

A 10-b 20-Msample/s analog-to-digital converter

A 10-b 20-Msample/s analog-to-digital converter fabricated in a 0.9-μm CMOS technology is described. The converter uses a pipelined nine-stage architecture with fully differential analog circuits and achieves a signal-to-noise-and-distortion ratio (SNDR) of 60 dB with a full-scale sinusoidal input at 5 MHz. It occupies a 8.7 mm² and dissipates 240 mW     

A 12-bit 80-MSample/s pipelined ADC with bootstrapped digital calibration

This paper presents a prototype analog-to-digital converter (ADC) that uses a calibration algorithm to adaptively overcome constant closed-loop gain errors, closed-loop gain variation, and slew-rate limiting. The prototype consists of an input sample-and-hold amplifier (SHA) that can serve as a calibration queue, a 12-bit 80-MSample/s pipelined ADC, a digital-to-analog converter (DAC) for calibration, and an embedded custom microprocessor, which carries out the calibration algorithm. The calibration is bootstrapped in the sense that the DAC is used to calibrate the ADC, and the ADC is used to calibrate the DAC. With foreground calibration, test results show that the peak differential nonlinearity (DNL) is -0.09 least significant bits (LSB), and the peak integral nonlinearity (INL) is -0.24LSB. Also, the maximum signal-to-noise-and-distortion ratio (SNDR) and spurious-free dynamic range (SFDR) are 71.0 and 79.6dB with a 40-MHz sinusoidal input, respectively. The prototype occupies 22.6 mm/sup 2/ in a 0.25-/spl mu/m CMOS technology and dissipates 755 mW from a 2.5-V supply.     

A 12-bit 1-Msample/s capacitor error-averaging pipelined A/Dconverter

A capacitor error-averaging technique is applied to perform an accurate multiply-by-two (×2) function required in high-resolution pipelined analog-to-digital (A/D) converters. Errors resulting from capacitor mismatch and switch feedthrough are corrected in the analog domain without using digital calibration and/or trimming. A differential pipelined A/D converter that achieves a throughput rate of 1 Msample/s with 12 bits of linearity has been made and evaluated. A prototype pipelined A/D converter implemented using a double-poly 1.75-μm CMOS process consumes 400 mW with a 5-V single supply and occupies 14 mm², including all digital logic and output buffers     

A pipelined 13-bit 250-ks/s 5-V analog-to-digital converter

A pipelined, 13-bit, 250-ksample/s (ks/s), 5-V, analog-to-digital (A/D) converter has been designed and fabricated in a 3-μm, CMOS technology. Monotonicity is achieved using a reference-feedforward correction technique instead of (self-) calibration of trimming to minimize the overall cost. The prototype converter requires 3400 mil², and consumes 15 mW     

A power-efficient 10-bit 40-MS/s sub-sampling pipelined CMOS analog-to-digital converter

This paper presents a 10-bit 40-MS/s pipelined analog-to-digital converter (ADC) in a 0.13-μm CMOS process for subsampling applications. A simplified opamp-sharing scheme between two successive pipelined stages is proposed to reduce the power consumption. For subsampling, a cost-effective fast input-tracking switch with high linearity is introduced to sample the input signal up to 75 MHz. A two-stage amplifier with hybrid frequency compensation is developed to achieve both high bandwidth and large swing with low power dissipation. The measured result shows that the ADC achieves over 77 dB spurious free dynamic range (SFDR) and 57.3 dB signal-to-noise-plus-distortion ratio (SNDR) within the first Nyquist zone and maintains over 70 dB SFDR and 55.3 dB SNDR for input signal up to 75 MHz. The peak differential nonlinearity (DNL) and integral nonlinearity (INL) are ±0.2 LSB and ±0.3 LSB, respectively. The ADC consumes 15.6 mW at the sampling rate of 40 MHz from a 1.2-V supply voltage, and achieves a figure-of-merit (FOM) value of 0.22 pJ per conversion step.     

A 12 bit 100 MS/s pipelined analog to digital converter without calibration

A 1.8 V 12 bit 100 MS/s pipelined analog to digital converter(ADC) in a 0.18μm complementary metal-oxide semiconductor process is presented.The first stage adopts a 3.5 bit structure to relax the capacitor matching requirements.A bootstrapped switch and a scaling down technique are used to improve the ADC's linearity and save power dissipation,respectively.With a 15.5 MHz input signal,the ADC achieves 79.8 dB spurious-free dynamic range and 10.5 bit effective number of bits at 100 MS/s.The power consumpt...     

一个没有采用校准技术的12位分辨率100兆采样率的流水线模数转换器

本文给出了一个基于0.18um CMOS工艺的12bit 100MS/s的流水线ADC。其中第一级采用了3.5比特结构以降低对电容匹配的要求,采样保持放大器、第一级和第二级均采用了自举开关以改善ADC线性度,后级采用级缩减技术节省了功耗和面积。当输入信号频率为15.5MHz、采样率为100MHz时,该ADC达到了79.8dB的SFDR和10.5bit的有效位数。芯片采用1.8V电压供电,包含输出驱动的总功耗为112mW, 芯片面积为3.51mm2 。     

Least mean square adaptive digital background calibration of pipelined analog-to-digital converters

We present an adaptive digital technique to calibrate pipelined analog-to-digital converters (ADCs). Rather than achieving linearity by adjustment of analog component values, the new approach infers component errors from conversion results and applies digital postprocessing to correct those results. The scheme proposed here draws close analogy to the channel equalization problem commonly encountered in digital communications. We show that, with the help of a slow but accurate ADC, the proposed code-domain adaptive finite-impulse-response filter is sufficient to remove the effect of component errors including capacitor mismatch, finite op-amp gain, op-amp offset, and sampling-switch-induced offset, provided they are not signal-dependent. The algorithm is all digital, fully adaptive, data-driven, and operates in the background. Strong tradeoffs between accuracy and speed of pipelined ADCs are greatly relaxed in this approach with the aid of digital correction techniques. Analog precision problems are translated into the complexity of digital signal-processing circuits, allowing this approach to benefit from CMOS device scaling in contrast to most conventional correction techniques.     

一种基于数字后台校准技术的14 bit 500 MS/s 数模转换器

Thelinearityofcurrent-steeringdigital-to-analogconverters（DACs）atlowsignalfrequenciesismainly limited by matching properties of current sources, so large-size current source arrays are widely used for better matching. This, however, results in large gradient errors and parasitic capacitance, which degrade the spurious free dynamic range（SFDR） for high-frequency signals. To overcome this problem, calibration is an effective method.In this paper, a digital background calibration technique for current-steering DACs is presented and verified by a 14-bit DAC in a 0.13 m standard CMOS process. The measured differential nonlinearity（DNL） and integral nonlinearity（INL） are 0.4 LSB and 1.2 LSB, respectively. At 500-MS/s, the SFDR is 70 dB and 50.3 dB for signals of 5.4 MHz and 224 MHz, respectively. The core area is 0.69 mm2and the power consumption is 165 mW from a mixed power supply with 1.2 V and 3.3 V.     

A 12-bit 200-MS/s pipelined A/D converter with sampling skew reduction technique

This paper presents a 12-bit 200-MS/s dual channel pipeline analog-to-digital converter (ADC). The ADC is featured with a digital timing correction for reducing a sampling skew and the capacitor swapping for suppressing nonlinearities at the first stage in the pipelined ADC. The prototype ADC occupies 0.8×1.4 mm² in a 65-nm CMOS technology. The differential nonlinearity is less than 1.0 least significant bit with a 200 MHz sampling frequency. With a sampling frequency of a 200-MS/s and an input of a 2.4 MHz, the ADC, respectively, achieves a signal to noise-and-distortion ratio and a spurious-free dynamic range of 61.49 dB–70.71 dB while consuming of 112 mW at a supply voltage of 1.1 V.     

A 600-MS/s 5-bit pipeline A/D converter using digital reference calibration

The design of a 600-MS/s 5-bit analog-to-digital (A/D) converter for serial-link receivers has been investigated. The A/D converter uses a closed-loop pipeline architecture. The input capacitance is only 170 fF, making it suitable for interleaving. To maintain low power consumption and increase the sampling rate beyond the amplifier settling limit, the paper proposes a calibration technique that digitally adjusts the reference voltage of each pipeline stage. Differential input swing is 400 mV/sub p-p/ at 1.8-V supply. Measured performance includes 25.6 dB and 19 dB of SNDR for 0.3-GHz and 2.4-GHz input frequencies at 600 MS/s for the calibrated A/D converter. The suggested calibration method improves SNDR by 4.4 dB at 600 MS/s with /spl plusmn/0.35 LSB of DNL and /spl plusmn/0.15 LSB of INL. The 180 /spl times/ 1500 /spl mu/m/sup 2/ chip is fabricated in a 0.18-/spl mu/m standard CMOS technology and consumes 70 mW of power at 600 MS/s.     

A wideband calibration-free 1.5-GS/s 8-bit analog-to-digital converter with low latency

This article presents a wideband calibration-free 8-bit analog-to-digital converter (ADC) with low latency. The ADC employs a two-stage cascaded folding and interpolating architecture. A high-linearity and wideband track-and-hold amplifier combined with a low-parasitic-capacitance folding amplifier is employed to improve the performance. A binary-ROM with “keep-alive” current is proposed to guarantee no miscode when large bit-rate is input. When the sampling frequency is 1.5 GHz, the ADC achieves +0.29/?0.20 LSB DNL and 0.90 LSB INL. The ADC’s effective-number-of-bit and spur-free-dynamic-range are 7.0 bit and 51.8 dB respectively at 230 MHz input. The effective-resolution-bandwidth exceeds the second Nyquist zone up to 1.8 GHz. All of this makes this ADC suitable for wideband digital receiver system.     

Digital background calibration for memory effects in pipelined analog-to-digital converters

Memory errors can occur in the stages of a pipelined analog-to-digital converter (ADC) due to several effects. These include capacitor dielectric absorption/relaxation, incomplete stage reset at high clock rates, and parasitic capacitance effects when opamps are shared between subsequent pipeline stages. This paper describes these sources of memory errors and the effect they have on overall ADC linearity. It is shown how these errors relate to and differ from interstage gain errors. Two new calibration algorithms are proposed that correct for memory errors by digital post-processing of the ADC output. Both algorithms operate in the background and so do not require conversion to be interrupted in order to track changes due to temperature and supply variations. The two algorithms are compared in terms of their system costs and their dependence on input signal statistics.     

A 10-bit 100-MS/s CMOS pipelined folding A/D converter

This paper presents a 10-bit 100-MSample/s analog-to-digital（A/D） converter with pipelined folding architecture.The linearity is improved by using an offset cancellation technique and a resistive averaging interpolation network.Cascading alleviates the wide bandwidth requirement of the folding amplifier and distributed interstage track/hold amplifiers are used to realize the pipeline technique for obtaining high resolution.In SMIC 0.18μm CMOS,the A/D converter is measured as follows:the peak integral nonlinearity and differential nonlinearity are±0.48 LSB and±0.33 LSB,respectively.Input range is 1.0 V_P-P with a 2.29 mm² active area.At 20 MHz input @ 100 MHz sample clock,9.59 effective number of bits,59.5 dB of the signal-to-noise-and-distortion ratio and 82.49 dB of the spurious-free dynamic range are achieved.The dissipation power is only 95 mW with a 1.8 V power supply.