带高速电流舵DAC的直接数字频率合成器

本文给出了一种高速SiGe BiCMOS直接数字频率合成器设计。该数字频率合成器单片集成了高速DDS数字核,10位差分电流舵 DAC,串/并接口和时钟控制逻辑。芯片采用0.35μm SiGe BiCMOS标准工艺流片,工作在1GHz系统频率。测试结果显示,该DDS能够生成高达400+ MHz的捷变模拟sine波形。     

A direct digital frequency synthesizer with high-speed current-steering DAC

A high-speed SiGe BiCMOS direct digital frequency synthesizer (DDS) is presented. The design in tegrates a high-speed digital DDS core, a high-speed differential current-steering mode 10-bit D/A converter, a serial/parallel interface, and clock control logic. The DDS design is processed in 0.35 μm SiGe BiCMOS standard process technology and worked at 1 GHz system frequency. The measured results show that the DDS is capable of generating a frequency-agile analog output sine wave up to 400+ MHz.     

A 1.76-GHz 22.6-mW /spl Delta//spl Sigma/ fractional-n frequency synthesizer

A /spl Delta//spl Sigma/ fractional-N frequency synthesizer for the 2-GHz-range wireless communication applications is implemented in a 0.35-/spl mu/m BiCMOS process, using only CMOS components. The synthesizer achieves a close-in phase noise of -81 dBc/Hz, while the spurious tones are at -85 dBc. The synthesizer features a multiple-modulus prescaler employing the phase-switching architecture to minimize the power dissipation. The entire prescaler, including the gigahertz-speed first stages, is implemented using full-swing logic. The current source structure employed in the charge pump provides a constant output current over a wide, almost rail-to-rail output voltage range. The power dissipation of the synthesizer chip is 22.6 mW from a 2.7-V supply.     

IF-sampling fourth-order bandpass /spl Delta//spl Sigma/ modulator for digital receiver applications

Bandpass modulators sampling at high IFs (/spl sim/200 MHz) allow direct sampling of an IF signal, reducing analog hardware, and make it easier to realize completely software-programmable receivers. This paper presents the circuit design of and test results from a continuous-time tunable IF-sampling fourth-order bandpass /spl Delta//spl Sigma/ modulator implemented in InP HBT IC technology for use in a multimode digital receiver application. The bandpass /spl Delta//spl Sigma/ modulator is fabricated in AlInAs-GaInAs heterojunction bipolar technology with a peak unity current gain cutoff frequency (f/sub T/) of 130 GHz and a maximum frequency of oscillation (f/sub MAX/) of 130 GHz. The fourth-order bandpass /spl Delta//spl Sigma/ modulator consists of two bandpass resonators that can be tuned to optimize both wide-band and narrow-band operation. The IF is tunable from 140 to 210 MHz in this /spl Delta//spl Sigma/ modulator for use in multiple platform applications. Operating from /spl plusmn/5-V power supplies, the fabricated fourth-order /spl Delta//spl Sigma/ modulator sampling at 4 GSPS demonstrates stable behavior and achieves a signal-to-(noise + distortion) ratio (SNDR) of 78 dB at 1 MHz BW and 50 dB at 60 MHz BW. The average SNDR performance measured on over 250 parts is 72.5 dB at 1 MHz BW and 47.7 dB at 60 MHz BW.     

A 2-GS/s 3-bit /spl Delta//spl Sigma/-modulated DAC with tunable bandpass mismatch shaping

Direct digital synthesis of signals in the hundreds of megahertz can lead to simpler, smaller transceivers, free of images and LO feedthrough that plague systems requiring analog upconversion. We present a 3-bit, 2 GS/s, /spl Delta//spl Sigma/-modulated DAC in InP HBT technology. The DAC is linearized using bandpass mismatch shaping. The mismatch shaper uses seven tunable 1.5-bit discrete-time bandpass /spl Delta//spl Sigma/ modulators to dynamically route the digital signals to the DACs. These /spl Delta//spl Sigma/ modulators operate in the analog domain to decrease system complexity and power consumption. The mismatch-shaped DAC can generate narrowband signals between 250-750 MHz with >68 dB SNR in a 1-MHz bw, >74-dB SFDR, and <-80-dBc intermodulation distortion with an 8.1-W power consumption.     

A 1.5-V 12-bit power-efficient continuous-time third-order /spl Sigma//spl Delta/ modulator

This paper presents the design strategy, implementation, and experimental results of a power-efficient third-order low-pass /spl Sigma//spl Delta/ analog-to-digital converter (ADC) using a continuous-time (CT) loop filter. The loop filter has been implemented by using active RC integrators. Several power optimizations, design requirements, and performance limitations relating to circuit nonidealities in the CT modulator are presented. The influence of the low supply voltage on the various building blocks such as the amplifier as well as on the overall /spl Sigma//spl Delta/ modulator is discussed. The ADC was implemented in a 3.3-V 0.5-/spl mu/m CMOS technology with standard threshold voltages. Measurements of the low-power 1.5-V CT /spl Sigma//spl Delta/ ADC show a dynamic range and peak signal-to-noise-plus-distortion ratio of 80 and 70 dB, respectively, in a bandwidth of 25 kHz. The measured power consumption is only 135 /spl mu/W from a single 1.5-V power supply.     

A novel noise efficient feedback DAC within a switched capacitor /spl Sigma//spl Delta/ ADC

Efficient sampling of the reference noise within a bilinear switched capacitor /spl Sigma//spl Delta/ analog-to-digital converter (ADC), resulting in improved thermal noise performance is presented. Bilinear integrators contain a zero at the Nyquist frequency, with the result that no charge is transferred from the reference when a transition occurs in the modulator output. The average noise power added by the reference digital-to-analog converter (DAC) can be reduced substantially if the reference DAC is sampled only when charge is to be transferred. For midscale inputs, the sampled noise from a single bit reference DAC is reduced by more than 5 dB. When multibit quantization and feedback is used the reference noise can be further suppressed, in the case of 5 bits of feedback the reference noise is reduced by more than 20 dB.     

A multiband /spl Delta//spl Sigma/ fractional-N frequency synthesizer for a MIMO WLAN transceiver RFIC

This work presents a shared fractional-N synthesizer used by two dual-band 802.11 radios integrated on a single chip for 2/spl times/2 multiple-input multiple-output (MIMO) applications. Additional 2/spl times/2 MIMO chips can be used in a system by phase synchronizing the signal paths through a bidirectional LO porting scheme developed for this application. This synthesizer was fully integrated with the exception of an off-chip loop filter. The synthesizer is a /spl Delta//spl Sigma/-based fractional-N frequency synthesizer with three on-chip LC tuned VCOs to cover the entire frequency bands specified in the IEEE 802.11a/b/g and Japanese WLAN standards. The radio uses a variable IF frequency so that both the RF LO and IF LO can be derived from a single synthesizer saving chip area and power. The synthesizer includes a programmable second/third-order /spl Delta//spl Sigma/ noise shaper, a phase frequency detector, a differential charge pump, and a 6-bit multimodulus divider (MMD). The nominal jitter from 100 Hz to 10 MHz is 0.63-0.86/spl deg/ rms in the 5-GHz band and 0.35-0.43/spl deg/ rms in the 2.4-GHz band. The maximum frequency deviation of the synthesizer when enabling the transmitter is less than 150 kHz and the frequency error settles to 2 kHz in less than 12 /spl mu/s. For MIMO applications requiring more than two full paths, a single synthesizer on one die can be used to generate the LOs for all other radios integrated in different dies.     

A fourth-order /spl Sigma//spl Delta/ interface for micromachined inertial sensors

This paper presents the design and implementation of a high-order /spl Sigma//spl Delta/ interface for micromachined inertial sensors, which employs an electronic filter in series with the mechanical sensor element to reject the excessive in-band quantization noise inherently present in state-of-the-art second-order solutions. A fourth-order prototype was fabricated in a standard 0.5-/spl mu/m CMOS process. The active circuit area measures 0.9 mm/sup 2/, and the interface consumes 13 mW from a 5-V supply and achieves resolution of 1/spl deg//s//spl radic/Hz with a gyroscope and 150/spl mu/g//spl radic/Hz with an accelerometer. Comparison between the measured and simulated behavior of the system shows that the contribution of the quantization error to the total noise is negligible.     

Comparison frequency doubling and charge pump matching techniques for dual-band /spl Delta//spl Sigma/ fractional-N frequency synthesizer

The frequency synthesizer with two LC-VCOs is fully integrated in a 0.35-/spl mu/m CMOS technology. In supporting dual bands, all building blocks except VCOs are shared. A current compensation scheme using a replica charge pump improves the linearity of the frequency synthesizer and, thus, suppresses spurious tones. To reduce the quantization noise from a /spl Delta//spl Sigma/ modulator and the noise from the building blocks except the VCO, the proposed architecture uses a frequency doubler with a noise-insensitive duty-cycle correction circuit (DCC) in the reference clock path. Power consumption is 37.8 mW with a 2.7-V supply. The proposed frequency synthesizer supports 10-kHz channel spacing with the measured phase noise of -114 dBc/Hz and -141 dBc/Hz at 100-kHz and 1.25-MHz offsets, respectively, in the PCS band. The fractional spurious tone at 10-kHz offset is under -54 dBc.     

A 14-bit high-temperature /spl Sigma//spl Delta/ modulator in standard CMOS

Experimental verification is given for the use of /spl Sigma//spl Delta/ modulation for high-temperature applications (/spl ges/approximately 150/spl deg/C) in a standard CMOS process. Switched-capacitor circuits are used to implement a second-order single-stage and a third-order 2-1 MASH /spl Sigma//spl Delta/ modulator with single-bit quantization. The two modulators have an oversampling ratio of 256 with an input signal bandwidth of 500 Hz. The modulators were fabricated in a 1.5-/spl mu/m standard CMOS technology. A fully differential signal path and near minimum sized switches are used to mitigate the effect of large junction-to-substrate leakage current present at high temperatures. Experimental results show both modulators are capable of over 14 bits of resolution at 225/spl deg/C and over 13 bits of resolution at 255/spl deg/C. Results show that the single-stage modulator is more resistant to high-temperature circuit impairment than is the MASH cascaded structure.     

11 GHz CMOS /spl Sigma//spl Delta/ frequency synthesiser

A fully integrated 11 GHz fractional-N PLL with a three-stage MASH SigmaDelta modulator with DC dither in all stages is implemented in a standard 0.13 mum CMOS technology. The synthesiser generates no fractional spurs at frequency offsets outside the loop bandwidth and a small number of fractional spurs with the power not exceeding -44 dBc within the loop bandwidth at the carrier frequency of 11 GHz     

A high-frequency and high-resolution fourth-order /spl Sigma//spl Delta/ A/D converter in BiCMOS technology

A high-performance cascaded sigma-delta modulator is presented. It has a new three-stage fourth-order topology and provides functionally a maximum signal to quantization noise ratio of 16 bits and 16.5-bit dynamic range with an oversampling ratio of only 32. This modulator is implemented with fully differential switch-capacitor circuits and is manufactured in a 2-/spl mu/m BiCMOS process. The converter, operated from +/-2.5 V power supply, +/-1.25 V reference voltage and oversampling clock of 48 MHz, achieves 97 dB resolution at a Nyquist conversion rate of 1.5 MHz after comb-filtering decimation. The power consumption of the converter is 180 mW.<>     

Accurate modeling of noise in switched-C /spl Delta//spl Sigma/ analog-to-digital converters

An accurate physical model of switched-capacitor /spl Delta//spl Sigma/ analog-to-digital converters (ADCs) noise is presented. Noise artifacts for various ADC blocks are captured using simple equations. Model is verified against measured 0.25-/spl mu/m high dynamic range ADC test chip for a wireless receiver. Design guidelines based on the proposed model are discussed.     

A high-frequency double-sampling second-order /spl Delta//spl Sigma/ modulator

As the minimum feature size of VLSI technologies scales down, more of the signal processing tasks are performed in the digital domain. This results in increased speed, resolution, and dynamic range requirements for the analog-to-digital converter (ADC). High-speed and high-accuracy designs can be achieved by using oversampling ADC structures, which demand amplifiers with a high gain and a high unity-gain frequency. Due to the difficulty to meet both of these specifications, the ADC resolution at a frequency in the megahertz range appears to be limited by amplifier settling requirements. Design techniques to improve the ADC performance are presented. The proposed modulator structure uses the double-sampled technique, which increases by a factor of two the maximum speed of operation and correctly operates even with low dc gain amplifiers. Furthermore, the signal-to-noise ratio is significantly improved by a calibration stage, which dynamically estimates the offset errors to be removed by a simple subtraction from the output signal.     

A 700-kHz bandwidth /spl Sigma//spl Delta/ fractional synthesizer with spurs compensation and linearization techniques for WCDMA applications

A /spl Sigma//spl Delta/ fractional-N frequency synthesizer targeting WCDMA receiver specifications is presented. Through spurs compensation and linearization techniques, the PLL bandwidth is significantly extended with only a slight increase in the integrated phase noise. In a 0.18-/spl mu/m standard digital CMOS technology a fully integrated prototype with 2.1-GHz output frequency and 35 Hz resolution has an area of 3.4 mm/sup 2/ PADs included, and it consumes 28 mW. With a 3-dB closed-loop bandwidth of 700 kHz, the settling time is only 7 /spl mu/s. The integrated phase noise plus spurs is -45 dBc for the first WCDMA channel (1 kHz to 1.94 MHz) and -65 dBc for the second channel (2.5 to 6.34 MHz) with a worst case in-band (unfiltered) fractional spur of -60 dBc. Given the extremely large bandwidth, the synthesizer could be used also for TX direct modulation over a broad band. The choice of such a large bandwidth, however, still limits the spur performance. A slightly smaller bandwidth would fulfill WCDMA requirements. This has been shown in a second prototype, using the same architecture but employing an external loop filter and VCO for greater flexibility and ease of testing.     

Hybrid /spl Sigma//spl Delta/ modulators with adaptive calibration

This paper describes an architecture for stable high-order /spl Sigma//spl Delta/ modulation. The architecture is based on a hybrid /spl Sigma//spl Delta/ modulator, wherein hybrid integrators replace conventional analog integrators. The hybrid integrator, which is a combination of an analog integrator and a digital integrator, offers an increased dynamic range and helps make the resulting high-order /spl Sigma//spl Delta/ modulator stable. However, the hybrid /spl Sigma//spl Delta/ modulator relies on precise matching of analog and digital paths. In this paper, a calibration technique to alleviate possible mismatch between analog and digital paths is proposed. The calibration adaptively adjusts the digital integrators so that their transfer functions match the transfer functions of corresponding analog integrators. Through behavioral-level simulations of fourth-order /spl Sigma//spl Delta/ modulators, the calibration technique is verified.     

Cascade /spl Sigma//spl Delta/ modulator with digital correction for finite amplifier gain effects

A simple and fully digital solution to correct the effect of amplifier finite gain in cascade /spl Sigma//spl Delta/ modulators is presented. The main contribution of this study is a simple digital method to evaluate the integrator pole errors, which are further taken into account to modify the reconstruction filter. The method is applied to a 2-1 cascade modulator.     

A 1-V 10.7-MHz fourth-order bandpass /spl Delta//spl Sigma/ modulators using two switched op amps

A 1-V 10.7-MHz fourth-order bandpass delta-sigma modulator using two switched opamps (SOPs) is presented. The 3/4 sampling frequency and the double-sampling techniques are adapted for this modulator to relax the required clocking rate. The presented modulator can not only reduce the number of SOPs, but also the number of capacitors. It has been implemented in 0.25-/spl mu/m 1P5M CMOS process with MIM capacitors. The modulator can receive 10.7-MHz IF signals by using a clock frequency of 7.13 MHz. A dynamic range of 62 dB within bandwidth of 200 kHz is achieved and the power consumption of 8.45 mW is measured at 1-V supply voltage. The image tone can be suppressed by 44 dB with respect to the carrier. The in-band third-order intermodulation (IM3) distortion is -65 dBc below the desired signal.     

Efficient sampling of reference noise in switched capacitor /spl Sigma//spl Delta/ ADC

Efficient sampling of the reference leg noise within a bilinear switched capacitor /spl Sigma//spl Delta/ ADC is presented, resulting in improved thermal noise performance. Whenever a transition occurs in the feedback of a /spl Sigma//spl Delta/ ADC, implemented using bilinear integrators, zero charge is transferred from the reference leg. Consequently the average noise power added by the reference leg can be reduced substantially if the reference leg is only sampled when there is a corresponding charge transfer. For mid-scale inputs, the sampled noise from the reference leg is reduced by more than 6 dB.