A wide-band 280-MHz four-path time-interleaved bandpass sigma-delta modulator

This paper describes a 0.35-/spl mu/m CMOS fourth-order bandpass analog-digital sigma-delta (/spl Sigma//spl Delta/) modulator for wide-band base stations receivers. The modulator, based on a time-interleaved four-path architecture, achieves an equivalent sampling frequency of 280 MHz, although the building blocks operate at only 70 MHz. In measurements, the prototype chip achieves a dynamic range of 72 dB (12 bits of resolution) with a signal bandwidth of 4.375 MHz centered around an intermediate frequency of 70 MHz. The measured spurious-free dynamic range is 69 dB. The /spl Sigma//spl Delta/ modulator dissipates 480 mW from a 3.3-V supply, including voltage reference buffers and output pads with high-driving capabilities, and occupies 20 mm/sup 2/ of silicon area.     

Analog signal generator for BIST of wideband IF signals bandpass sigma-delta modulator

This paper presents improvements in generation of wideband and high dynamic range analog signal for area-efficient MADBIST, especially for the on-chip testing of wireless communication IF digitizing sigma-delta modulator chip. Via increasing the order of the one-bit bandpass sigma-delta modulation algorithm up to 12 and using finite repetitious bitstream approximating scheme, it can achieve great improvements in signal bandwidth instead of purity at the cost of very little hardware overhead. Another contribution in this work is to provide the theoretical analysis of the reconstructed signal degradation due to harmonic distortion and clock jitter. Such on-chip analog stimulus generation scheme is especially fit for IF digitizing bandpass sigma-delta modulator chip's production-time testing and in-the-field diagnostics. The technique can also be extended to mixed-signal communication SoC built-in-self-test.     

A 1-MHz-bandwidth second-order continuous-time quadrature bandpass sigma-delta modulator for low-IF radio receivers

This paper presents a quadrature bandpass /spl Sigma//spl Delta/ modulator with continuous-time architecture. Due to the continuous-time architecture and the inherent anti-aliasing filter, the proposed /spl Sigma//spl Delta/ modulator needs no additional anti-aliasing filter in front of the modulator in contrast to quadrature bandpass /spl Sigma//spl Delta/ modulators with switched-capacitor architectures. The second-order /spl Sigma//spl Delta/ modulator digitizes complex analog I/Q input signals at 1-MHz intermediate frequency and operates within a clock frequency range of 25-100 MHz. The modulator chip achieves a peak signal-to-noise-distortion ratio (SNDR) of 56.7 dB and a dynamic range of 63.8 dB within a 1-MHz signal bandwidth and at a clock frequency of 100 MHz. Furthermore, it provides an image rejection of at least 40 dB. The 0.65-/spl mu/m BiCMOS chip consumes 21.8 mW at 2.7-V supply voltage.     

Electromechanical-Filter-Based Bandpass Sigma–Delta Modulator

This brief proposes an electromechanical-filter-based continuous-time (CT) bandpass (BP) sigma-delta modulator for wideband digitization at high intermediate frequency (> 70 MHz). Both the mechanically coupled microelectromechanical system and the longitudinally coupled surface acoustic wave (SAW) filters can be employed as loop filters. The advantages of the electromechanical filter are its low power consumption and accurate center frequency without the need for tuning. As a proof of concept, a fourth-order BP sigma-delta modulator is demonstrated with a 110-MHz SAW filter. Realized in a 0.35- mum SiGe heterojunction-bipolar-transistor bipolar complimentary metal-oxide-semiconductor technology, the prototype chip is clocked at 440 MHz and achieves 65-dB DR and 60-dB SNDR over 1 MHz, as well as 58-dB DR and 53-dB SNDR over the 3.84-MHz signal band. The total power consumption is 57 mW under a 3-V supply.     

A 1.8-mW CMOS ΣΔ modulator with integrated mixer forA/D conversion of IF signals

In this paper, the design of a continuous-time baseband sigma-delta (ΣΔ) modulator with an integrated mixer for intermediate-frequency (IF) analog-to-digital conversion is presented. This highly linear IF ΣΔ modulator digitizes a GSM channel at intermediate frequencies up to 50 MHz. The sampling rate is not related to the input IF and is 13.0 MHz in this design. Power consumption is 1.8 mW from a 2.5-V supply. Measured dynamic range is 82 dB, and third-order intermodulation distortion is -84 dB for two -6-dBV IF input tones. Two modulators in quadrature configuration provide 200-kHz GSM bandwidth. Active area of a single IF ΣΔ modulator is 0.2 mm² in 0.35-μm CMOS     

An I/Q-Channel Time-Interleaved Bandpass Sigma–Delta Modulator for a Low-IF Receiver

This brief proposes a multiplexing scheme to realize an I/Q-channel time-interleaved (TI) bandpass sigma-delta modulator that shares operational transconductance amplifiers to minimize power consumption and silicon area for a low-intermediate-frequency (IF) wireless receiver. The test chip was fabricated for a 10.7-MHz IF system with a 0.35-mum CMOS process. The measured peak signal-to-noise distortion ratio for a 200-kHz bandwidth is approximately 73 dB. The power consumption of the fabricated chip is 61 mW with a 3.3-V supply, and the silicon area is 1.78 mm². The measured channel crosstalk is about -48 dB     

A Power-Efficient Two-Channel Time-Interleaved ΣΔ Modulator for Broadband Applications

A two-channel time-interleaved second-order sigma-delta modulator for broadband applications including asymmetrical digital subscriber line (ADSL) is presented. The proposed two-channel SigmaDelta modulator uses a single integrator channel which does not require additional active elements for the quantizer input generation, since the integrator outputs are directly used as the input of the quantizers. As a result, the entire modulator can be implemented using only two op-amps, which is beneficial for both power consumption and area. Furthermore, this architecture is robust to channel mismatch effects and can operate with a simple clocking scheme. The SigmaDelta modulator achieves a dynamic range of 85 dB over a 1.1-MHz signal bandwidth with an effective clock frequency of 132 MHz. The circuit is implemented in 0.18-mum CMOS technology using metal-insulator-metal capacitors. The total power consumption of the SigmaDelta modulator is 5.4mW from a 1.8-V supply and occupies an active area of 1.1 mm²     

A 1-V 10.7-MHz switched-opamp bandpass /spl Sigma//spl Delta/ modulator using double-sampling finite-gain-compensation technique

A 1 V switched-capacitor (SC) bandpass sigma-delta (/spl Sigma//spl Delta/) modulator is realized using a high-speed switched-opamp (SO) technique with a sampling frequency of up to 50 MHz, which is improved ten times more than prior 1 V SO designs and comparable to the performance of the state-of-the-art SC circuits that operate at much higher supply voltages. On the system level, a fast-settling double-sampling SC biquadratic filter architecture is proposed to achieve high-speed operation. A low-voltage double-sampling finite-gain-compensation technique is employed to realize a high-resolution /spl Sigma//spl Delta/ modulator using only low-DC-gain opamps to maximize the speed and to reduce power dissipation. On the circuit level, a fast-switching methodology is proposed for the design of the switchable opamps to achieve a switching frequency up to 50 MHz. Implemented in a 0.35-/spl mu/m CMOS process (V/sub TP/=0.82 V and V/sub TN/=0.65 V) and at 1 V supply, the modulator achieves a measured peak signal-to-noise-and-distortion ratio (SNDR) of 42.3 dB at 10.7 MHz with a signal bandwidth of 200 kHz, while dissipating 12 mW and occupying a chip area of 1.3 mm/sup 2/.     

A 16-b 160-kHz CMOS A/D converter using sigma-delta modulation

The design and measured performance of a third-order sigma-delta analog-to-digital (A/D) converter sampling at 10.24 MHz that achieves a 91-dB signal-to-noise-plus-distortion ratio (RMS/RMS) with a 160-kHz output rate are discussed. The converter consists of three cascaded first-order sigma-delta modulators and a fourth-order comb decimation filter. A special autozeroed integrator having low pole error is required to achieve the 10.24-MHz sampling rate and high S/N. The modulator is implemented with fully differential switched-capacitor circuits and is manufactured using a 1.5-μm double-metal double-poly CMOS process     

Low-distortion bandpass /spl Sigma/-/spl Delta/ modulator for wireless radio receivers

A low-distortion bandpass sigma-delta modulator is proposed. It was found that the key to improving linearity is to add a feedforward signal path in a double-delay resonator bandpass structure. The proposed technique improves the tonal behaviour even at low oversampling ratio and can be applied for any order of modulator. Based on the proposed architecture, a fourth-order single-bit sigma-delta modulator can achieve a dynamic range of 84 dB and a spurious free dynamic range of 98 dB at 10.71 MHz with a signal bandwidth of 200 kHz, making it ideal for a narrowband IF-sampled wireless receiver designed for compliance with GSM/GPRS standards.     

A 12-bit sigma-delta analog-to-digital converter with a 15-MHz clock rate

A sigma-delta analog-to-digital converter that achieves 12-bit integral and differential linearity and nearly 13-bit resolution without trimming is described. The baseband width is 120 kHz with a first filter pole at 60 kHz, the clock frequency is 15 MHz, and only one 5-V power supply is needed. The circuit was realized in a p-well CMOS technology with 3-/spl mu/m minimum feature size. Compared with previous sigma-delta modulators, the input signal frequency and clock rate limit have been increased by one order of magnitude. To achieve this increase, a novel integrator concept was developed using bidirectional current sources. The circuit is fully self-contained, requiring only a 15-MHz crystal and one blocking capacitor as external elements. This converter was developed as the analog front end of a digital echo cancellation circuit for an integrated services digital network.     

A one-path subsampling quadrature receiver based on a ΣΔ modulator with distributed resonators

This article presents experimental results of a quadrature bandpass sigma–delta (ΣΔ) modulator based on distributed resonators. The modulator employs transmission lines and transconductors as main components and does not require switches in the loop filter as in the case of switched-capacitor (discrete-time) filters. In addition, the proposed complex modulator does not require a quadrature mixer in the receiver. As main feature, the modulator architecture introduces an innovative way to produce the I and Q outputs that is immune to path mismatch due to the sharing of all the analog circuitry for both paths. The one-bit second-order modulator ADC is able to convert IF signals at fs/2 and 3fs/2 (fs = 50 MHz), achieving an ENOB = 10 bits within a 1 MHz signal bandwidth. Therefore the modulator may be feasible for the typical IF frequencies used in cellular base stations. Furthermore, it provides an image rejection grater than 70 dB. The 0.35 μm BiCMOS chip consumes 28 mW at 3.3 V supply voltage.     

A two-path bandpass ΣΔ modulator for digital IFextraction at 20 MHz

Oversampled bandpass A/D converters based on sigma-delta (ΣΔ) modulation can be used to robustly digitize the types of narrowband intermediate frequency (IF) signals that arise in radios and cellular systems. This paper proposes a two-path architecture for a fourth-order, bandpass modulator that is more tolerant of analog circuit limitations at high sampling speeds than conventional implementations based on the use of switched-capacitor biquadratic filters. An experimental prototype employing the two-path topology has been integrated in a 0.6-μm, single-poly, triple-metal CMOS technology with capacitors synthesized from a stacked metal structure. Two interleaved paths clocked at 40 MHz digitize a 200-kHz bandwidth signal centered at 20 MHz with 75 dB of dynamic range while suppressing the undesired mirror image signal by 42 dB. At low input signal levels, the mixing of spurious tones at DC and f_s/2 with the input appears to degrade the performance of the modulator; out-of-band sinusoidal dither is shown to be an effective means of avoiding this degradation. The experimental modulator dissipates 72 mW from a 3.3 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 sixth-order continuous-time bandpass sigma-delta modulator fordigital radio IF

This paper presents a sixth-order continuous-time bandpass sigma-delta modulator (SDM) for analog-to-digital conversion of intermediate-frequency signals. An important aspect in the design of this SDM is the stability analysis using the describing function method. The key to the analysis is the extension of the linear gain model for the sampled quantizer with a phase uncertainty. The single-loop, one-bit SDM is tuned at 10.7 MHz, is sampled at 40 MHz, and achieves 67-dB signal-to-(noise+distortion) ratio in 200 kHz and 80 dB in 9 kHz. The third order intermodulation is at -82 dBc for a -13-dBFS input level. The 0.5-μm CMOS chip occupies 0.9×0.4 mm² and consumes 60 mW at 3.3 V (digital) and 5.0 V (analog). The sample frequency is variable and can be set from 30 to 80 MHz     

A cascaded continuous-time /spl Sigma//spl Delta/ Modulator with 67-dB dynamic range in 10-MHz bandwidth

This paper presents the design of a 2-2 cascaded continuous-time sigma-delta modulator. The cascaded modulator comprises two stages with second-order continuous-time resonator loopfilters, 4-bit quantizers, and feedback digital-to-analog converters. The digital noise cancellation filter design is determined using continuous-time to discrete-time transformation of the sigma-delta loopfilter transfer functions. The required matching between the analog and digital filter coefficients is achieved by means of simple digital calibration of the noise cancellation filter. Measurement results of a 0.18-/spl mu/m CMOS prototype chip demonstrate 67-dB dynamic range in a 10-MHz bandwidth at 8 times oversampling for a single continuous-time cascaded modulator. Two cascaded modulators in quadrature configuration provide 20-MHz aggregate bandwidth. Measured anti-alias suppression is over 50 dB for input signals in the band from 150 to 170 MHz around the sampling frequency of 160 MHz.     

A third-order /spl Sigma//spl Delta/ modulator in 0.18-/spl mu/m CMOS with calibrated mixed-mode integrators

This paper describes a third-order sigma-delta (/spl Sigma//spl Delta/) modulator that is designed and implemented in 0.18-/spl mu/m CMOS process. In order to increase the dynamic range, this modulator takes advantage of mixed-mode integrators that consist of analog and digital integrators. A calibration technique is applied to the digital integrator to mitigate mismatch between analog and digital paths. It is shown that the presented modulator architecture can achieve a 12-dB better dynamic range than conventional structures with the same oversampling ratio (OSR). The experimental prototype chip achieves a 76-dB dynamic range for a 200-kHz signal bandwidth and a 55-dB dynamic range for a 5-MHz signal bandwidth. It dissipates 4 mW from 1.8-V supply voltages and occupies 0.7-mm/sup 2/ silicon area.     

Design of a high-order single-loop ∑△ ADC followed by a decimator in 0.18 μm CMOS technology

This work presents an oversampled high-order single-loop single-bit sigma-delta analog-to-digital con verter followed by a multi-stage decimation filter. Design details and measurement results for the whole chip are presented for a TSMC 0.18 μm CMOS implementation to achieve virtually ideal 16-b performance over a baseband of 640 kHz. The modulator in this work is a fully differential circuit that operates from a single 1.8 V power supply. With an oversampling ratio of 64 and a clock rate of 81.92 MHz, the modulator achieves a 94 dB dynamic range. The decimator achieves a pass-band ripple of less than 0.01 dB, a stop-band attenuation of 80 dB and a transition band from 640 to 740 kHz. The whole chip consumes only 56 mW for a 1.28 MHz output rate and occupies a die area of 1×2 mm~2.     

A two-path bandpass sigma-delta modulator with extended noiseshaping

A three-stage bandpass sigma-delta (ΣΔ) analog-to-digital converter has been designed specifically for operation at low oversampling ratios. In the proposed architecture, the center frequency of the third stage is shifted slightly from that of the first two stages to achieve more efficient noise shaping across the signal band. An experimental modulator based on the proposed topology has been integrated in a 0.25-μm CMOS technology and achieves a dynamic range of 75 dB with a maximum signal-to-noise-plus-distortion ratio (SNDR) of 70 dB when digitizing a 2-MHz signal band centered at 16 MHz. This circuit implements an f_s/4 bandpass architecture and thus operates at 64-MHz clock rate. It dissipates 110 mW from a 2.5-V supply, and its active area is 4 mm²     

Cascaded Complex ADCs With Adaptive Digital Calibration for $I/Q$ Mismatch

A complex analog-to-digital converter (ADC) intended for digital intermediate frequency (IF) receiver applications digitizes analog signals at IFs with excellent power/bandwidth efficiency. However, it is vulnerable to mismatches between its in-phase and quadrature (I/Q) paths that can dramatically degrade its performance. The proposed solution mitigates I/Q mismatch effects using a complex sigma-delta (SigmaDelta) modulator cascaded with 9-bit pipeline converters in each of the I and Q paths. The quantization noise of the first stage complex modulator is eliminated using an adaptive scheme to calibrate finite-impulse response digital filters in the digital noise-cancellation logic block. Although low-pass SigmaDelta cascade ADCs are widely used because of their inherent stability and high-order noise shaping, the complex bandpass cascade architecture introduced herein maintains these advantages and doubles the noise shaping bandwidth. Digital calibration also reduces the effects of analog circuit limitations such as finite operational amplifier gain, which enables high performance and low power consumption with high-speed deep-submicrometer CMOS technology. Behavioral simulations of the complex SigmaDelta/pipeline cascade bandpass ADC using the adaptive digital calibration algorithm predict a signal-to-noise ratio (SNR) of 78 dB over a 20-MHz signal bandwidth at a sampling rate of 160 MHz in the presence of a 1% I/Q mismatch.