A 10-bit 250-MS/s binary-weighted current-steering DAC

This paper studies the impact of segmentation on current-steering digital-to-analog converters (DACs). Segmentation may be used to improve the dynamic behavior of the converter but comes at a cost. A method for reducing the segmentation degree is given. The presented chip, a 10-bit binary-weighted current-steering DAC, has >60 dB SFDR at 250 MS/s from DC to Nyquist. At 62.5 MHz signal frequency and 250 MS/s, we operated the device in 9-bit unary, 1-bit binary-weighted mode. The obtained 60 dB SFDR in this measurement demonstrates that the binary nature of the converter did not limit the SFDR. The chip draws 4 mW from a dual 1.5 V/1.8 V supply plus load currents. The active area is less than 0.35 mm/sup 2/ in a standard 1P-5M 0.18-/spl mu/m 1.8-V CMOS process. Both INL and DNL are below 0.1 LSB.     

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 14-b 12-MS/s CMOS pipeline ADC with over 100-dB SFDR

A 1.8-V 14-b 12-MS/s pseudo-differential pipeline analog-to-digital converter (ADC) using a passive capacitor error-averaging technique and a nested CMOS gain-boosting technique is described. The converter is optimized for low-voltage low-power applications by applying an optimum stage-scaling algorithm at the architectural level and an opamp and comparator sharing technique at the circuit level. Prototyped in a 0.18-/spl mu/m 6M-1P CMOS process, this converter achieves a peak signal-to-noise plus distortion ratio (SNDR) of 75.5 dB and a 103-dB spurious-free dynamic range (SFDR) without trimming, calibration, or dithering. With a 1-MHz analog input, the maximum differential nonlinearity is 0.47 LSB and the maximum integral nonlinearity is 0.54 LSB. The large analog bandwidth of the front-end sample-and-hold circuit is achieved using bootstrapped thin-oxide transistors as switches, resulting in an SFDR of 97 dB when a 40-MHz full-scale input is digitized. The ADC occupies an active area of 10 mm/sup 2/ and dissipates 98 mW.     

A digitally enhanced 1.8-V 15-bit 40-MSample/s CMOS pipelined ADC

A 1.8-V 15-bit 40-MSample/s CMOS pipelined analog-to-digital converter with 90-dB spurious-free dynamic range (SFDR) and 72-dB peak signal-to-noise ratio (SNR) over the full Nyquist band is presented. Its differential and integral nonlinearities are 0.25 LSB and 1.5 LSB, respectively, and its power consumption is 400 mW. This performance is enabled by digital background calibration of internal digital-to-analog converter (DAC) noise and interstage gain errors. The calibration achieves improvements of better than 12 dB in signal-to-noise plus distortion ratio and 20 dB in SFDR relative to the case where calibration is disabled. Other enabling features of the prototype integrated circuit (IC) include a low-latency, segmented, dynamic element-matching DAC, distributed passive input signal sampling, and asymmetric clocking to maximize the time available for the first-stage residue amplifier to settle. The IC is realized in a 0.18-/spl mu/m mixed-signal CMOS process and has a die size of 4mm/spl times/5 mm.     

A low-Voltage 10-bit CMOS DAC in 0.01-mm/sup 2/ die area

A low-voltage 10-bit digital-to-analog converter (DAC) for static/dc operation is fabricated in a standard 0.18-/spl mu/m CMOS process. The DAC is optimized for large integrated circuit systems where possibly dozens of such DAC would be employed for the purpose of digitally controlled analog circuit calibration. The DAC occupies 110 /spl mu/m/spl times/94 /spl mu/m die area. A segmented R-2R architecture is used for the DAC core in order to maximize matching accuracy for a minimal use of die area. A pseudocommon centroid layout is introduced to overcome the layout restrictions of conventional common centroid techniques. A linear current mirror is proposed in order to achieve linear output current with reduced voltage headroom. The measured differential nonlinearity by integral nonlinearity (DNL/INL) is better than 0.7/0.75 LSB and 0.8/2 LSB for 1.8-V and 1.4-V power supplies, respectively. The DAC remains monotonic (|DNL|<1 LSB) as INL reaches 4 LSB down to 1.3-V operation. The DAC consumes 2.2 mA of current at all supply voltage settings.     

A 6-GSamples/s multi-level decision feedback equalizer embedded in a 4-bit time-interleaved pipeline A/D converter

A 4-bit 6-GS/s pipeline A/D converter with 10-way time-interleaving is demonstrated in a 0.18-/spl mu/m CMOS technology. The A/D converter is designed for a serial-link receiver and features an embedded adjustable single-tap DFE for channel equalization. The ISI subtraction of the DFE is performed at the output of each pipeline stage; hence the effective feedback delay requirement is relaxed by 6/spl times/. Code-overlapping of the 1.5-bit pipeline stage along with digital error correction is used to absorb and remove the remainder of the ISI. The measured A/D converter performance at 6-GSamples/s shows 22.5 dB of low-frequency input SNDR for the calibrated A/D converter with /spl plusmn/0.25 LSB and /spl plusmn/0.4 LSB of INL and DNL, respectively. The input capacitance is 170 fF for each A/D converter. The DFE tap coefficient is adjustable from 0 to 0.25 with 6-bits of programmable weight. With a DFE coefficient of 0.2, the measured DFE performance shows 2.5 dB of amplitude boosting for a 3-GHz input sinusoid. The 1.8/spl times/1.6 mm/sup 2/ chip consumes 780 mW of power from a 1.8-V power supply.     

A 2.5-V 10-b 120-MSample/s CMOS pipelined ADC based on merged-capacitor switching

This work describes a 10-b multibit-per-stage pipelined CMOS analog-to-digital converter (ADC) incorporating the merged-capacitor switching (MCS) technique. The proposed MCS technique improves the signal processing speed and resolution of the ADC by reducing the required number of unit capacitors by half in comparison to a conventional ADC. The ADC resolution based on the proposed MCS technique can be extended further by employing a commutated feedback-capacitor switching (CFCS) technique. The prototype ADC achieves better than 53-dB signal-to-noise-and-distortion ratio (SNDR) at 120 MSample/s and 54-dB SNDR and 68-dB spurious-free dynamic range (SFDR) for input frequencies up to Nyquist at 100 MSample/s. The measured differential and integral nonlinearities of the prototype are within /spl plusmn/0.40 LSB and /spl plusmn/0.48 LSB, respectively. The ADC fabricated in a 0.25-/spl mu/m CMOS occupies 3.6 mm/sup 2/ of active die area and consumes 208 mW under a 2.5-V power supply.     

A 1-GHz signal bandwidth 6-bit CMOS ADC with power-efficient averaging

A 2-GS/s 6-bit ADC with time-interleaving is demonstrated in 0.18-/spl mu/m one-poly six-metal CMOS. A triple-cross connection method is devised to improve the offset averaging efficiency. Circuit techniques, enabling a state-of-the-art figure-of-merit of 3.5 pJ per conversion step, are discussed. The peak DNL and INL are measured as 0.32 LSB and 0.5 LSB, respectively. The SNDR and SFDR have achieved 36 and 48dB, respectively, with 4 MHz input signal. Near Nyquist input frequencies, the SNDR and SFDR maintain above 30 and 35.5dB, respectively, up to 941 MHz. The complete ADC, including front-end track-and-hold amplifiers and clock buffers, consumes 310 mW from a 1.8-V supply while operating at 2-GHz conversion rate. The prototype ADC occupies an active chip area of 0.5 mm/sup 2/.     

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.     

An 11b 70-MHz 1.2-mm/sup 2/ 49-mW 0.18-/spl mu/m CMOS ADC with on-chip current/voltage references

This work proposes an 11b 70-MHz CMOS pipelined analog-digital converter (ADC) as one of core circuit blocks for very high speed digital subscriber line system applications. The proposed ADC for the internal use has the strictly limited number of externally connected I/O pins while the ADC employs on-chip CMOS current/voltage references and a merged-capacitor switching technique to improve ADC performances. The ADC implemented in a 0.18-/spl mu/m 1P4M CMOS technology shows the maximum signal-to-noise distortion ratio (SNDR) of 60 dB at 70 MSample/s. The ADC maintains the SNDR of 58 dB and the spurious-free dynamic resistance of 68 dB for input frequencies up to the Nyquist rate at 60 MSample/s. The measured differential and integral nonlinearities of the ADC are within /spl plusmn/0.63 and /spl plusmn/1.21 LSB, respectively. The active chip area is 1.2 mm/sup 2/ and the ADC consumes 49 mW at 70 MSample/s at 1.8 V.     

A 64-MHz clock-rate /spl Sigma//spl Delta/ ADC with 88-dB SNDR and -105-dB IM3 distortion at a 1.5-MHz signal frequency

A 64-MHz clock rate sigma-delta (/spl Sigma//spl Delta/) analog-to-digital converter (ADC) with -105-dB intermodulation distortion (IMD) at a 1.5-MHz signal frequency is reported. A linear replica bridge sampling network enables the ADC to achieve high linearity for high signal frequencies. Operating at an oversampling ratio of 29, a 2-1-1 cascade with a 2-b quantizer in the last stage reduces the quantization noise level well below that of the thermal noise. The measured signal-to-noise and distortion ratio (SNDR) in 1.1-MHz bandwidth is 88 dB, and the spurious-free-dynamic-range (SFDR) is 106 dB. The modulator and reference buffers occupy a 2.6-mm/sup 2/ die area and have been implemented with thick oxide devices, with minimum channel length of 0.35 /spl mu/m, in a dual-gate 0.18-/spl mu/m 1.8-V single-poly five-metal (SP5M) digital CMOS process. The power consumed by the ADC is 230 mW, including the decimation filters.     

A 12-bit 20-Msample/s pipelined analog-to-digital converter with nested digital background calibration

A 12-bit 20-Msample/s pipelined analog-to-digital converter (ADC) is calibrated in the background using an algorithmic ADC, which is itself calibrated in the foreground. The overall calibration architecture is nested. The calibration overcomes the circuit nonidealities caused by capacitor mismatch and finite operational amplifier (opamp) gain both in the pipelined ADC and the algorithmic ADC. With a 58-kHz sinusoidal input, test results show that the pipelined ADC achieves a peak signal-to-noise-and-distortion ratio (SNDR) of 70.8 dB, a peak spurious-free dynamic range (SFDR) of 93.3 dB, a total harmonic distortion (THD) of -92.9 dB, and a peak integral nonlinearity (INL) of 0.47 least significant bit (LSB). The total power dissipation is 254 mW from 3.3 V. The active area is 7.5 mm/sup 2/ in 0.35-/spl mu/m CMOS.     

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.     

一种数字CMOS工艺制造的10位100MS/s流水线ADC

介绍了采用0.18μm数字工艺制造、工作在3.3V下、10位100MS/s转换速率的流水线模数转换器。提出了一种适用于1.5位MDAC的新的金属电容结构,并且使用了高带宽低功耗运算放大器、对称自举开关和体切换的PMOS开关来提高电路性能。芯片已经通过流片验证,版图面积为1.35mm×0.99mm,功耗为175mW。14.7MS/s转换速率下测得的DNL和INL分别为0.2LSB和0.45LSB,100MS/s转换速率下测得的DNL和INL分别为1LSB和2.7LSB,SINAD为49.4dB,SFDR为66.8dB。     

A 10-b, 500-MSample/s CMOS DAC in 0.6 mm2

A 10-b current steering CMOS digital-to-analog converter (DAC) is described, with optimized performance for frequency domain applications. For sampling frequencies up to 200 MSample/s, the spurious free dynamic range (SFDR) is better than 60 dB for signals from DC to Nyquist. For sampling frequencies up to 400 MSample/s, the SFDR is better than 55 dB for signals from DC to Nyquist. The measured differential nonlinearity and integral nonlinearity are 0.1 least significant bit (LSB) and 0.2 LSB, respectively. The circuit is fabricated in a 0.35-μm, single-poly, four-metal, 3.3 V, standard digital CMOS process and occupies 0.6 mm². When operating at 500 MSample/s, it dissipates 125 mW from a 3.3 V power supply. This DAC is optimized for embedded applications with large amounts of digital circuitry     

A low power 12-b 40-MS/s pipeline ADC

This paper describes a 12-bit, 40-MS/s pipelined A/D converter (ADC) which is implemented in 0.18-μm CMOS process drawing 76-mW power from 3.3-V supply. Multi-bit architectures as well as telescopic operational transconductance amplifiers (OTAs) are adopted in all pipeline stages for good power efficiency. In the first two stages,particularly, 3-bit/stage architectures are used to improve the ADC's linearity performance. The ADC is calibration-free and achieves a DNL of less than 0.51 LSB and an INL of less than 1 LSB. The SNDR performance is above 67 dB below Nyquist. The 80-dB SFDR performance is maintained within 1 dB for input frequencies up to 49 MHz at full sampling rate.     

一个高线性13位流水线CMOS A/D转换器

介绍了一个采用多种电路设计技术来实现高线性13位流水线A/D转换器.这些设计技术包括采用无源电容误差平均来校准电容失配误差、增益增强(gain-boosting)运放来降低有限增益误差和增益非线性,自举(bootstrapping)开关来减小开关导通电阻的非线性以及抗干扰设计来减弱来自数字供电的噪声.电路采用0.18μm CMOS工艺实现,包括焊盘在内的面积为3.2mm2.在2.5MHz采样时钟和2.4MHz输入信号下测试,得到的微分非线性为-0.18/0.15LSB,积分非线性为-0.35/0.5LSB,信号与噪声加失真比(SNDR)为75.7dB,无杂散动态范围(SFDR)为90.5dBc;在5MHz采样时钟和2.4MHz输入信号下测试,得到的SNDR和SFDR分别为73.7dB和83.9dBc.所有测试均在2.7V电源下进行,对应于采样率为2.5MS/s和5Ms/s的功耗(包括焊盘驱动电路)分别为21mW和34mW.     

A low voltage-power 13-bit 16 MSPS CMOS pipelined ADC

A low voltage-power, 13-bit and 16 MSPS analog-to-digital converter (ADC) was implemented in 0.25-/spl mu/m one-poly five-metal standard CMOS process with MIM capacitors. This ADC used a constant-gm switch to improve the nonlinear effect and a telescopic operational transconductance amplifier with a wide-swing biasing technique for power saving and low supply voltage operation. The converter achieved a peak SNDR of 59.2 dB with 16.384 MSPS, a low supply voltage of 1.3V, and Nyquist input frequency of 8.75 MHz. The static INL of /spl plusmn/2.0 LSB and DNL of /spl plusmn/0.5 LSB were obtained. The total power consumption of this converter was 78 mW. This chip occupied 3.4 mm /spl times/ 3.6 mm area.     

一种低功耗嵌入式14位400MHz数模转换器

设计了一个14位刷新频率达400MHz,用于高速频率合成器的低功耗嵌入式数模转换器。该数模转换器采用5+4+5分段式编码结构,其电流源控制开关输出驱动级采用归零编码以提高DAC动态特性。该数模转换器核采用0.18μm1P6M混合信号CMOS工艺实现,整个模块面积仅为1.1mm×0.87mm。测试结果表明,该DAC模块的微分非线性误差是-0.9～+0.5LSB,积分非线性误差是-1.4～+1.3LSB,在400MHz工作频率下,输出信号频率为80MHz时的无杂散动态范围为76.47dB,并且功耗仅为107.2mW。     

A 10-bit 1-GSample/s Nyquist current-steering CMOS D/A converter

In this paper, a 10-bit 1-GSample/s current-steering CMOS digital-to-analog (D/A) converter is presented. The measured integral nonlinearity is better than ±0.2 LSB and the measured differential nonlinearity lies between -0.08 and 0.14 LSB proving the 10-bit accuracy. The 1-GSample/s conversion rate has been obtained by an, at transistor level, fully custom-designed thermometer decoder and synchronization circuit. The layout has been carefully optimized. The parasitic interconnect loads have been estimated and have been iterated in the circuit design. A spurious-free dynamic range (SFDR) of more than 61 dB has been measured in the interval from dc to Nyquist. The power consumption equals 110 mW for a near-Nyquist sinusoidal output signal at a 1-GHz clock. The chip has been processed in a standard 0.35-μm CMOS technology and has an active area of only 0.35 mm²