Error suppressing encode logic of FCDL in a 6-b flash A/D converter

A 6-b, 166-Ms/s BiCMOS flash A/D converter was fabricated using a folded cascoded differential logic (FCDL). This FCDL reduces glitch errors caused by comparator metastability and improves encoder operation speed. The measured error rates of a chip implemented in a 0.7-μm, f _t=12 GHz BiCMOS was less than 10^-10 times/sample. Without power-consuming highspeed track and hold circuit, the FCDL achieved low error rate and low power consumption of 505 mW at a 5.0-V power supply     

A 330?MHz 11?bit 26.4?mW CMOS Low-Hold-Pedestal Fully Differential Sample-and-Hold Circuit

A new technique for realizing a very-high-speed low-power low-voltage fully differential CMOS sample-and-hold circuit with low hold pedestal is presented. To achieve high sampling linearity the circuit utilizes linearized input switches. The fully differential design relaxes the trade-off between sampling speed and the sampling precision. The circuit design of major building blocks is described in detail. A prototype circuit in a 0.35-μm CMOS process is designed and experimental results are presented. The sample-and-hold circuit operates up to 330 MHz of sampling frequency with less than −68.3 dB of total harmonic distortion, corresponding to 11 bits for an input 80.24 MHz sinusoidal amplitude of 1.2V _pp at a 3 V supply. This total harmonic distortion measurement reflects the held values as well as the tracking components of the output waveform. In these conditions, a differential hold pedestal of less than 0.8 mV, 0.8 ns acquisition time at 1.2 V step input, and 1.2V _pp full-scale differential input range are achieved. The circuit dissipates 26.4 mW with a 3 V power supply.     

A 250 MHz 11 bit 22 mW CMOS low-hold-pedestal fully differential sample-and-hold circuit

A new technique for realizing a very-high-speed low-power low-voltage fully differential CMOS sample-and-hold circuit with low hold pedestal is presented. To achieve high sampling linearity the circuit utilizes improved bootstrapped input switches. The fully differential design relaxes the trade-off between sampling speed and the sampling precision. The circuit design of major building blocks is described in detail. A prototype circuit in a 0.35-μm CMOS process is integrated and experimental results are presented. The sample-and-hold circuit operates up to 250 MHz of sampling frequency with less than −70 dB of total harmonic distortion corresponding to 11 bits for an input 60.8 MHz sinusoidal amplitude of 1.8 V _pp at a 3 V supply. The total harmonic distortion measurement reflects the held values as well as the tracking components of the output waveform. In these conditions, a differential hold pedestal of less than 0.8 mV, 0.8 ns acquisition time at 1.8 V step input, and 1.8 V _pp full-scale differential input range are achieved. The circuit dissipates 22 mW with a 3 V power supply.     

A 130-MHz 8-b CMOS video DAC for HDTV applications

In order to achieve monotonicity and a high-speed performance, a current-cell matrix configuration and a parallel decoding circuit with one-stage latches have been used. A deglitching circuit has been introduced in the decoding stages to guarantee a low glitch energy. P-channel devices used as current sources ensure a low noise level and a ground-referenced voltage output in a doubly terminated 75-Ω transmission line. Experimental results have shown that the maximum conversion rate is 130 MHz and the integral and differential linearity errors are less than 0.5 LSB. The maximum glitch energy is 50 pS-V. The DAC has been developed in a 1-μm digital/analog CMOS technology. The entire circuit dissipates 150 mW at a 130-MHz conversion rate while operating from a single 5-V power supply     

A 1.5-V 50-MHz pseudodifferential CMOS sample-and-hold circuit with low hold pedestal

This paper describes the design strategy and implementation of a low-voltage pseudodifferential double-sampled timing-skew-insensitive sample-and-hold (S/H) circuit with low hold pedestal based on the Miller-effect scheme. The S/H circuit employs bootstrapped switches in order to facilitate low voltage operation. The design considerations for each building block are described in detail. The S/H circuit has been designed using a 0.35-/spl mu/m 2P4M CMOS technology and experimental results are presented. The 1.5-V S/H circuit operates up to a sampling frequency of 50 MHz with less than -54.6 dB of total harmonic distortion for an input sinusoidal amplitude of 0.8 V/sub pp/. In these conditions, a differential hold pedestal of less than 0.8 mV, 1.6 ns acquisition time at 0.8-V step input, and 0.8 V/sub pp/ full-scale differential input range are achieved.     

A CMOS line driver for ADSL central office applications

An ADSL central office (CO) line driver utilizing a single 6-V supply is described. The line driver output produces a 20-V/sub ppd/ signal to deliver a 40-V/sub ppd/ swing to a 100-/spl Omega/ line. The adoption of an active termination, a dynamic supply control circuit technique, and deep n-well devices at the output stage of the line driver is key in achieving such a large voltage swing in a 0.25-/spl mu/m CMOS process. In order to ensure reliability of the output devices, the dynamic supply control algorithm is designed to activate only one lift amplifier at each signal path of the differential line driver at any given time. A transformer turns ratio of 1:2.4 ensures both reliability and optimal power dissipation in the presence of system losses. The total power dissipation of the line driver is 700 mW when discrete multitone signals with a crest factor of 15 dB were used to deliver 20.4 dBm to a 100-/spl Omega/ line.     

A 3-V CMOS low-distortion class AB line driver suitable for HDSLapplications

A fully differential CMOS line driver for use in high bit-rate digital subscriber line (HDSL) services Is presented. The circuit is fabricated in a single-poly quad metal 0.35-μm process and achieves <-70-dB total harmonic distortion while driving up to ±2.4-V, 200-kHz signals into 30 Ω with a 3-V supply. The circuit features a closed loop gain of 6.0 with minimal input capacitance (<200 fF). The circuit requires less than 20 mA of quiescent current and is capable of delivering dynamic currents as large as 180 mA. The circuit is a multistage amplifier utilizing nested-Miller compensation and an enhanced class AB output stage     

A CMOS Readout Circuit for SOI Resonant Accelerometer With 4-$mu rm g$ Bias Stability and 20-$ murm g/sqrt{{hbox{Hz}}}$ Resolution

A fully differential CMOS readout circuit for SOI resonant accelerometer is reported. The readout circuit is essentially an oscillator, consisting of an oscillator and a low noise automatic amplitude control (AAC) loop. A differential sense resonator is proposed to facilitate fully differential circuit topology and improves the SNR under a 3.3-V supply. A second-order AAC loop filter and a novel chopper stabilized rectifier are employed in the AAC loop to remove the noises, in particular, the 1/f noise, and to minimize the phase noise caused by the amplitude stiffening effect. The strong driving feedthrough is avoided by separating the drive and sense operation in the time domain, while using the same electrodes. The complete resonant accelerometer operates under a 3.3-V supply and achieves 140-Hz/g scaling factor, 20 mug/radicHz resolution and 4 mug bias stability. The readout circuit draws 7 mA under 3.3-V supply.     

A 2-V/sub pp/ 80-200-MHz fourth-order continuous-time linear phase filter with automatic frequency tuning

A CMOS 80-200-MHz fourth-order continuous-time 0.05/spl deg/ equiripple linear phase filter with an automatic frequency tuning system is presented. An operational transconductance amplifier based on transistors operating in triode region is used and a circuit that combines common-mode feedback, common-mode feedforward, and adaptive bias is introduced. The chip was fabricated in a 0.35-/spl mu/m process; filter experimental results have shown a total harmonic distortion less than -44 dB for a 2-V/sub pp/ differential input with a single 2.3-V power supply. The group delay ripple is less than 4% for frequencies up to 1.5 f/sub c/. The frequency tuning error is below 5%.     

A floating CMOS bandgap voltage reference for differentialapplications

The circuit is suitable for precision mixed-mode systems using the differential approach, especially for the case of single-supply operation. An experimental prototype, realized in a 2-μm CMOS technology, generates a continuous-time low-impedance voltage of 2.48 V±24 mV before trimming. The temperature coefficient measured on 30 samples ranges from -20 to L32 p.p.m./°C in the temperature range from 0 to 100°C. Thanks to the differential approach, a high-frequency power supply rejection of -50 dB at 100 kHz was achieved. The active area of the chip is 1800 mil² and the circuit dissipates 6 mW when operated from a single 5-V supply     

A high speed sampler for sub-sampling IR-UWB receiver

A high speed sampler for a sub-sampling impulse radio UWB receiver is presented. In this design, the sampler uses a time-interleaved topology with a single track and hold circuit, full custom clock generator, and offset cancelled comparator. These three main blocks are also discussed and analyzed. The circuit was fabricated in 0.13 μm CMOS technology. Measurement results indicate that the sampler achieves a maximum 3 GS/s sampling rate. The power consumption of the sampler is 27 mW under a supply voltage of 1.2 V. The total chip area including pads is 1.4 × 0.97 mm2.     

1-V 9-bit pipelined switched-opamp ADC

A 9-bit 1.0-V pipelined analog-to-digital converter has been designed using the switched-opamp technique. The developed low-voltage circuit blocks are a multiplying analog-to-digital converter (MADC), an improved common-mode feedback circuit for a switched opamp, and a fully differential comparator. The input signal for the converter is brought in using a novel passive interface circuit. The prototype chip, implemented in a 0.5-μm CMOS technology, has differential nonlinearity and integral nonlinearity of 0.6 and 0.9 LSB, respectively, and achieves 50.0-dB SNDR at 5-MHz clock rate. As the supply voltage is raised to 1.5 V, the clock frequency can be increased to 14 MHz. The power consumption from a 1.0-V supply is 1.6 mW     

A 0.5-V 8-bit 10-Ms/s Pipelined ADC in 90-nm CMOS

This paper presents a pipelined analog-to-digital converter (ADC) operating from a 0.5-V supply voltage. The ADC uses true low-voltage design techniques that do not require any on-chip supply or clock voltage boosting. The switch OFF leakage in the sampling circuit is suppressed using a cascaded sampling technique. A front-end signal-path sample-and-hold amplifier (SHA) is avoided by using a coarse auxiliary sample and hold (S/H) for the sub-ADC and by synchronizing the sub-ADC and pipeline-stage sampling circuit. A 0.5-V operational transconductance amplifier (OTA) is presented that provides inter-stage amplification with an 8-bit performance for the pipelined ADC operating at 10 Ms/s. The chip was fabricated on a standard 90 nm CMOS technology and measures 1.2 mm times 1.2 mm. The prototype chip has eight identical stages and stage scaling was not used. It consumes 2.4 mW for 10-Ms/s operation. Measured peak SNDR is 48.1 dB and peak SFDR is 57.2 dB for a full-scale sinusoidal input. Maximal integral nonlinearity and differential nonlinearity are 1.19 and 0.55 LSB, respectively.     

Precise CMOS current sample/hold circuits using differential clockfeedthrough attenuation techniques

New CMOS current sample/hold (CSH) circuits capable of overcoming the accuracy limitations in conventional circuits without significantly reducing operating speed are proposed and analyzed. A novel differential clock feedthrough attenuation (DCFA) technique is developed to attenuate the signal-dependent clock feedthrough errors. Unlike conventional techniques, the DCFA circuit allows the use of dynamic mirror techniques, and results in no additional finite output resistance errors or device mismatch errors. The test chip of the proposed fully differential CSH circuit with multiple outputs has been fabricated in 1.2-μm CMOS technology. Using a single 5-V power supply, experimental results show that the signal-dependent clock feedthrough error current is less than ±0.4 μA for the input currents from -550 μA to 550 μA. The acquisition time for a 900-μA step transition to 0.1% settling accuracy is 150 ns. For a 410-μA_p-p input at 250 MHz with the fabricated fully-differential CSH circuit clocked at 4 MHz, a total harmonic distortion of -60 dB, and a signal-to-noise ratio of 79 dB have been obtained. The active chip area and power consumption of the fabricated CSH circuit are 0.64 mm² and 20 mW, respectively. Both simulation and experimental results have successfully verified the functions and performance of the proposed CSH circuits     

A low-voltage switched-current delta-sigma modulator

This paper presents the design of a fully differential switched-current delta-sigma modulator using a single 3.3-V power-supply voltage. At system level, we tailor the modulator structure considering the similarity and difference of switched-capacitor and switched-current realizations. At circuit level, we propose a new switched-current memory cell and integrator with improved common mode feedback, without which low power-supply-voltage operation would not be possible. The whole modulator was implemented in a 0.8-μm double-metal digital CMOS process. It occupies an active area of 0.53×0.48 mm² and consumes a current of 0.6 mA from a single 3.3-V power supply. The measured dynamic range is over 10 b     

A 55-mW, 10-bit, 40-Msample/s Nyquist-rate CMOS ADC

A low-power 10-bit converter that can sample input frequencies above 100 MHz is presented. The converter consumes 55 mW when sampling at f_s=40 MHz from a 3-V supply, which also includes a bandgap and a reference circuit (70 mW if including digital drivers with a 10-pF load). It exhibits higher than 9.5 effective number of bits for an input frequency at Nyquist (f_in=f_s/2=20 MHz). The differential and integral nonlinearity of the converter are within ±0.3 and ±0.75 LSB, respectively, when sampling at 40 MHz, and improve to a 12-bit accuracy level for lower sampling rates. The overall performance is achieved using a pipelined architecture without a dedicated sample/hold amplifier circuit at the input. The converter is implemented in double-poly, triple-metal 0.35-μm CMOS technology and occupies an area of 2.6 mm²     

A 14-b, 100-MS/s CMOS DAC designed for spectral performance

A 14-bit, 100-MS/s CMOS digital-to-analog converter (DAC) designed for spectral performance corresponding more closely to the 14-bit specification than current implementations is presented. This DAC utilizes a nonlinearity-reducing output stage to achieve low output harmonic distortion. The output stage implements a return-to-zero (RZ) action, which tracks the DAC once it has settled and then returns to zero. This RZ circuit is designed so that the resulting RZ waveform exhibits high dynamic linearity. It also avoids the use of a hold capacitor and output buffer as in conventional track/hold circuits. At 60 MS/s, DAC spurious-free dynamic range is 80 dB for 5.1-MHz input signals and is down only to 75 dB for 25.5-MHz input signals. The chip is implemented in a 0.8-μm CMOS process, occupies 3.69×3.91 mm ² of die area, and consumes 750 mW at 5-V power supply and 100-MS/s clock speed     

An accurate CMOS sample-and-hold circuit

An accurate sample-and-hold (S/H) circuit implemented with a 2-μm double-poly CMOS process is described. Competitive performance in terms of output swing, linearity, and clock feedthrough compensation was obtained using a new circuit topology. The sample and hold operates up to 1 MHz of sampling frequency with less than -60 dB of total harmonic distortion. The accuracy of the held step is better than 0.2 mV. The circuit dissipates 4 mW with a 5-V power supply     

A 2.7-V 300-MS/s track-and-hold amplifier

A fully differential bipolar track-and-hold amplifier (THA) employs an open-loop linearization technique compatible with low supply voltage. A feedthrough reduction method utilizes the junction capacitance of a replica switch to provide a close match to the junction capacitance of the main switch. The differential full-scale (FS) input range is 0.5 V. In the track mode, with f_in=10 MHz, FS sinewave input, the measured total harmonic distortion (THD) is less than -72 dB. With f_s=300 MS/s and f_in=10-50 MHz, FS sinewave input, the measured THD is less than -65 dB. This THD measurement reflects the held values as well as the tracking components of the output waveform. With f_s<10 MS/s and f_in=10-50 MHz, FS sinewave input, the measured feedthrough is less than -60 dB. The hold capacitance is 2.5 pF and the differential droop rate is 16 mV/μs. The THA consumes 32 mW from a 2.7-V power supply and is fabricated in a 0.5-μm, 18-GHz BiCMOS process     

Adaptively biased linear transconductor

This paper describes a new circuit topology of a linear transconductor. The conventional differential pair (CDP), with a constant tail current, is linearized by an adaptive biasing scheme , and the only extra elements added to the differential pair are source followers. Compared to the CDP, the proposed circuit achieves similar speed and noise performance, but the common-mode rejection is compromised at the expense of tremendous improvement in linearity. While operating from a 1.8-V power supply in a 0.18-/spl mu/m CMOS process, the simulated variation in g/sub m/ for 1-V/sub p-p/ and 2-V/sub p-p/ differential input is 1.2% and 22%, respectively. Also, the THD performance for a 1-V/sub p-p/, 1-MHz differential sinusoidal input is -65 dB, which is about a 40-dB improvement over the CDP.