New multirate bandpass sigma-delta modulators

A new architecture for fourth- and sixth-order bandpass sigma-delta (BP-SD) modulators is proposed here. The basic BP-SD modulator is obtained from its low-pass (LP) counterpart by means of the standard transformation z/sup -1/ /spl rarr/ -z/sup -2/, which transforms the integrators in the LP modulator into resonators in the BP modulator, and places the input signal band at the frequency f/sub s//4, where f/sub s/ is the sampling rate. In the proposed architecture, the second resonator (and the third one for the sixth-order case) is implemented using a two-path strategy, by means of two high-pass filters (whose poles are located at f/sub s//2) operating in a time-interleaved mode. However, unlike other BP-SD modulators using the two-path strategy, in our approach, the effective sampling frequency in the second resonator (and in the third one for the sixth-order case) is increased to 2/spl middot/f/sub s/ by maintaining the clock rate of the high-pass filters to f/sub s/ which, in turn, places their poles at f/sub s//2. The signal band in the input of the second resonator is moved from the center frequency f/sub s//4 to f/sub s//2 by a modulation process that separates the signal into their in-phase and quadrature components. Another demodulation process in the digital domain reverses this frequency translation of the signal band before the output signal is converted to the analog domain and fed back to the modulator input. A detailed theoretical analysis of the architecture is done in the paper. Owing to the multirate nature of the proposed modulators, simulation results show an improvement of approximately 12 dB in the input dynamic range (fourth-order case) when compared to conventional modulators of the same order clocked at the same frequency rate (in the first resonator).     

A multicarrier QAM modulator for WCDMA base-station with on-chip D/A converter

In this paper, design and implementation of a multicarrier quadrature amplitude modulation (QAM) modulator for a wideband code division multiple access (WCDMA) base-station with a 14-bit on-chip D/A converter is described. The modulator is capable of modulating four carriers with four independent in phase (I) and quadrature (Q) data streams. The proposed modulator structure consists of an interpolation chain for data streams and four digital frequency synthesizer/modulators, which are based on a coordinate rotation digital computer (CORDIC) vector rotation algorithm. The interpolation chain consists of a root-raised cosine pulse shaping filter and three half-band filters for image filtering. The modulated carriers are combined to form a multicarrier WCDMA signal. The SINC-attenuation effect of a digital/analog (D/A) converter is canceled by an inverse-SINC predistortion filter. The multicarrier signal is converted to the analog domain with a 14-bit current steering D/A converter, which is integrated on the same silicon chip. The modulator is implemented with a 0.35-mum BiCMOS process with CMOS transistors only     

A 1.5-V direct digital synthesizer with tunable delta-sigma modulator in 0.13-/spl mu/m CMOS

In direct digital synthesizer (DDS) applications, the drawback of the conventional delta sigma (/spl Delta//spl Sigma/) modulator structure is that its signal band is fixed. In the new architecture presented in this paper, the signal band of the /spl Delta//spl Sigma/ modulator is tuned according to the DDS output frequency. We use a hardware-efficient phase-to-sine amplitude converter in the DDS that approximates the first quadrant of the sine function with 16 equal-length piecewise second-degree polynomial segments. The DDS is capable of frequency, phase, and quadrature amplitude modulation. The die area of the chip is 2.02 mm/sup 2/ (0.13 /spl mu/m CMOS technology). The total power consumption is 138 mW at 1.5 V with an output frequency of 63.33 MHz at a clock frequency of 200 MHz (D/A converter full-scale output current: 11.5 mA).     

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 photonic-link millimeter-wave mixer using cascaded optical modulators and harmonic carrier generation

Efficient frequency conversion into and out of the millimeter wave frequency band has been demonstrated using photonic link signal mixing with cascaded optical modulators. By adjusting the modulator bias point and RF drive power to the modulator introducing the local oscillator signal at f/sub LO/=8.8 GHz, frequency conversions from f/sub s/ to f/sub LO//spl plusmn/f/sub s/, sf/sub LO//spl plusmn/f/sub s/, and 4f/sub LO//spl plusmn/f/sub s/ with respective losses of 4.8, 6.3, and 7.5 dB have been demonstrated. The direct phase noise measurement of the optical RF signal at 2f/sub LO/=17.6 GHz with 1 kHz offset shows -89 dBc/Hz, limited by the RF drive source.     

A 75-dB image rejection IF-input quadrature-sampling SC /spl Sigma//spl Delta/ Modulator

Quadrature sampling of intermediate frequency (IF) signals is subject to the well-known problem of gain and phase mismatches between the in-phase (I) and quadrature (Q) channels. This paper presents an IF-input quadrature-sampling switched-capacitor (SC) /spl Sigma//spl Delta/ modulator that circumvents the I/Q mismatch problem by time-sharing between the I and Q channels the critical circuit components, namely, the sampling capacitor and the capacitor of the first-stage feedback digital-to-analog converter (DAC). In addition, a clocking scheme that is insensitive to I/Q phase imbalance is used. A third-order single-loop 1-bit low-pass modulator has been designed and fabricated in a 0.35-/spl mu/m CMOS process with an active area of 0.57mm/sup 2/. The experimental results show that the modulator achieves an image-rejection ratio (IRR) of greater than 75dB throughout a 200-kHz signal bandwidth.     

A Wideband ΔΣ Digital-RF Modulator for High Data Rate Transmitters

A wideband software-defined digital-RF modulator targeting Gb/s data rates is presented. The modulator consists of a 2.625-GS/s digital DeltaSigma modulator, a 5.25-GHz direct digital-RF converter, and a fourth-order auto-tuned passive LC RF bandpass filter. The architecture removes high dynamic range analog circuits from the baseband signal path, replacing them with high-speed digital circuits to take advantage of digital CMOS scaling. The integration of the digital-RF converter with an RF bandpass reconstruction filter eliminates spurious signals and noise associated with direct digital-RF conversion. An efficient passgate adder circuit lowers the power consumption of the high-speed digital processing and a quadrature digital-IF approach is employed to reduce LO feedthrough and image spurs. The digital-RF modulator is software programmable to support variable bandwidths, adaptive modulation schemes, and multi-channel operation within a frequency band. A prototype IC built in 0.13-mum CMOS demonstrates a data rate of 1.2 Gb/s using OFDM modulation in a bandwidth of 200 MHz centered at 5.25 GHz. In-band LO and image spurs are less than -59 dBc without requiring calibration. The modulator consumes 187 mW and occupies a die area of 0.72 mm².     

Digital Modulator with Bandpass Delta-Sigma Modulator

A digital quadrature modulator with a bandpass -modulator is presented that interpolates orthogonal input carriers by 16 and performs a digital quadrature modulation at carrier frequencies f_s/4, –f_s/4 (f_s is the sampling frequency). After quadrature modulation, the signal is converted into an analogue IF signal using a bandpass modulator and a 1-bit D/A converter. The die area of the chip is 5.2 mm² (0.13 m CMOS technology). The total power consumption is 139 mW at 1.5 V with a clock frequency of 700 MHz (D/A converter full-scale output current 11.5 mA).     

Low-power low-voltage CMOS A/D sigma-delta modulator for bio-potential signals driven by a single-phase scheme

Since the 1970's, the analog switches in switched-capacitor (SC) circuits are operated by nonoverlapping bi-phase control signals (/spl phi//sub 1/, /spl phi//sub 2/). The nonoverlapping of these two phases is essential for successful SC operation since, a capacitor inside an SC circuit can discharge if two switches, driven by /spl phi//sub 1/ and /spl phi//sub 2/, are turned on simultaneously. Moreover, since 1983, two additional phases are generally used in many SC circuits, which consist of advanced versions of /spl phi//sub 1/ and /spl phi//sub 2/. These two additional phases overcome the problem of signal-dependent charge injection. This paper presents a low-power and low-voltage analog-to-digital (A/D) interface module for biomedical applications. This module provides an A/D conversion based on a mixed clock-boosting/switched-opamp (CB/SO) second-order sigma-delta (/spl Sigma//spl Delta/) modulator, capable of interfacing with several different types electrical signals existing in the human body, only by re-programming the output digital filter. The proposed /spl Sigma//spl Delta/ architecture employs a novel single-phase scheme technique, which improves the dynamic performance and highly reduces the clocking circuitry complexity, substrate noise and area. Simulated results demonstrate that the signal integrity can be preserved by exploring the gap between the high conductance region of pMOS and nMOS switches at low power-supply voltages and the fast clock transitions that exist in advanced CMOS technologies. The mixed CB/SO architecture together with the overall distortion reduction resulting from using the proposed single-phase scheme, result that the dynamic range of the modulator is pushed closer to the theoretical limit of an ideal second-order /spl Sigma//spl Delta/ modulator.     

A multicarrier GMSK modulator with on-chip D/A converter for base stations

A multicarrier Gaussian minimum shift keying (GMSK) modulator with a 14-bit on-chip digital-to-analog (D/A) converter is presented. The design contains four GMSK modulators, which generate GMSK modulated carriers at the user-defined center frequencies. In wireless base stations, the modulated transmit signals are usually combined at the RF frequency after power amplification. The multicarrier modulator combines four GMSK modulated signals in the digital domain, thereby eliminating the need for an antenna microwave combiner. A new digital ramp generator and output power-level controller performs both the burst ramping and the dynamic power control in the digital domain. The maximum dynamic performance is obtained by multiplexing two D/A converters with output sampling switches. The digital multicarrier GMSK modulator is designed to fulfill the derived spectrum and phase-error specifications of the GSM 900/1800/1900 base stations for pico-, micro-, and macrocells. The die area of the chip is 26.8 mm/sup 2/ in 0.35-/spl mu/m CMOS (in BiCMOS) technology. Power consumption is 706 mW at 3.3 V with 52 MHz.     

A new interpolation technique for time interleaved \Upsigma\Updelta A/D converters

Time interleaved sigma-delta converter is a potential candidate for multi-mode wideband analog to digital (A/D) converters dedicated for multistandard receivers. However, the interpolation by zeros to compress the useful signal bandwidth at the input of the sigma-delta modulator imposes constraints on the implementation of the analog part leading to a very large die area due to the high value required for the sampling capacitor. This paper proposes a new interpolation technique using extra samples instead of zeros resulting from the oversampling of the input signal. This new technique not only reduces the die area and the order of the anti-alias filter but also improves A/D converter performance. The proposed technique was simulated and implemented in a four channel time interleaved sigma-delta designed in a 1.2 V 65?nm CMOS process.     

On the development of a multifunction millimeter-wave sensor for displacement sensing and low-velocity measurement

A new multifunction millimeter-wave sensor operating at 35.6 GHz has been developed and demonstrated for measurement of displacement and low velocity. The sensor was realized using microwave integrated circuits and monolithic microwave integrated circuits. Measured displacement results show unprecedented resolution of only 10 /spl mu/m, which is approximately equivalent to /spl lambda//sub 0//840 in terms of free-space wavelength /spl lambda//sub 0/, and maximum error of only 27 /spl mu/m. A polynomial curve-fitting method was also developed for correcting the error. Results indicate that multiple reflections dominate the displacement measurement error. The sensor was able to measure speed as low as 27.7 mm/s, corresponding to 6.6 Hz in Doppler frequency, with an estimated velocity resolution of 2.7 mm/s. A digital quadrature mixer (DQM) was configured as a phase-detecting processor, employing a quadrature sampling signal-processing technique, to overcome the nonlinear phase response problem of a conventional analog quadrature mixer. The DQM also enables low Doppler frequency to be measured with high resolution. The Doppler frequency was determined by applying linear regression on the phase sampled within only fractions of the period of the Doppler frequency. Short-term stability of the microwave signal source was also considered to predict its effect on measurement accuracy.     

A double Nyquist digital product detector for quadrature sampling

A technique for digitally obtaining the in-phase (I) and quadrature (Q) components of an IF signal is presented. Initially, the input bandpass signal is mixed to a carrier frequency that is one-fourth of the sampling rate of a single A/D converter. The digitized bandpass signal is converted into its I and Q components at one-half the A/D sample rate by a digital product detector (DPD) composed of a commutator, two sign alternators, and two FIR fractional-phase interpolator filters. This simple structure can yield image performance that is limited by A/D quantization using relatively low interpolator filter orders and IF bandwidths as large as one-half the sampling rate of the A/D converter. The DPD performs Nyquist limit demodulation of the sampled bandpass signal and, therefore, requires a minimal sampling rate. The theory of operation, an analytic proof, design methodology, and simulated performance results are presented. Simulated results show that -86 dB images can be obtained with 8-tap FIR interpolators and a 12 bit A/D converter. A VLSI implementation is also presented     

Gain and offset mismatch calibration in time-interleaved multipath A/D sigma-delta modulators

We propose a digital background adaptive calibration technique for correcting offset and gain mismatches in time-interleaved multipath analog-digital (A/D) sigma-delta (/spl Sigma//spl Delta/) modulators. The proposed technique allows us to cancel the spurious tones introduced by offset and gain mismatches among the paths only by processing the digital output, without interfering with the operation of the modulator. This solution is also effective for any other time-interleaved A/D converter topology. Simulation results on a high-performance four-path bandpass /spl Sigma//spl Delta/ modulator, operating on a 5-MHz band at a clock frequency of 320 MHz, demonstrate the effectiveness of the proposed calibration technique, which allows us to achieve significant improvements of the signal-to-noise ratio and the spurious-free dynamic range in the presence of mismatches.     

用前反馈剩余补偿提高转换器分辨率的研究

介绍了一种使用调制器回路的前反馈补偿技术,以提高转换器的分辨率,从而大大降低了高位Ａ／Ｄ转换器电路结构的复杂程度,为开发高精度Ａ／Ｄ转换器提供了一条新的途径。．     

A 56 mW Continuous-Time Quadrature Cascaded Σ∆ Modulator With 77 dB DR in a Near Zero-IF 20 MHz Band

A quadrature cascaded modulator with continuous-time loop filters is presented for a digital multi-stream FM radio receiver. The ADC achieves a dynamic range of 77 dB and 20 MHz bandwidth centered on an intermediate frequency of 10.5 MHz and is sampling at 340 MHz. The cascaded modulator comprises programmable analog second-order quadrature filters and a digital quadrature noise cancellation filter. The 0.5 chip in 90 nm CMOS consumes 56 mW from a 1.2 V supply.     

A monolithic 14 bit A/D converter

A 14 bit monolithic successive approximation A/D converter with 7 /spl mu/s conversion time is described. A special system called `dynamic element matching' is used to construct the high-accuracy D/A converter needed in the system. The high linearity of the converter (/spl plusmn//SUP 1///SUB 4/ LSB) results in an 84 dB S/N ratio. The high-speed comparator consists of a wide-band (75 MHz) clamped operational amplifier followed by a strobed flip-flop to freeze the output data. In the digital part, current mode logic (CML) is used for speed and low interference generation with respect to the analog circuitry. Digital input and outputs are TTL compatible. A low-noise, high-stability reference source with a temperature dependence of /spl plusmn/0.5 ppm//spl deg/C over -20 to +85/spl deg/C completes the A/D function. The chip is processed in a standard bipolar process using double layer interconnection. The die size is 3.5/spl times/4.4 mm/SUP 2/.     

Improved four-channel direct-conversion SiGe receiver IC for UMTS base stations

This work presents the design and measurement results of an improved four-channel, direct down conversion receiver (DCR) for the application in universal mobile telecommunications system base stations. The whole analog receiver functionality including low noise amplifier, variable gain amplifier, local oscillator frequency divider, in-phase and quadrature DCR mixers and seventh-order active lowpass filter is integrated using Atmel's 50-GHz f/sub t/, 50-GHz f/sub max/ SiGe foundry technology (Atmel, 1998). Important cascaded design parameters of the fully ESD-protected device are a noise figure 1.5 to 2 dB; IIP3 (third-order intercept point) -20.3 to -15.8 dBm and a voltage gain of 51 to 57 dB into a 1000-/spl Omega/ /spl par/ 2.5-pF differential load [analog to digital converter].     

A general purpose differential digital modulator implementationincorporating a direct digital synthesis method

A highly versatile digital modulator that uses a direct digital synthesis method to perform signal modulation is described. In contrast to the customary methods of implementing I-Q modulation schemes utilizing in-phase and quadrature branches, this design approach is based on directly accessing many of the digitally stored carrier modulating symbols according to the information bearing input signals. Apart from the digital-to-analog converter, all the previous stages are digital. To demonstrate the concept, a differential 16-QAM modulator was implemented. The technique lends itself to VLSI implementation. It can be considered as a digital implementation of a digital modulator     

A 2.2-mW CMOS bandpass continuous-time multibit /spl Delta/-/spl Sigma/ ADC with 68 dB of dynamic range and 1-MHz bandwidth for wireless applications

A delta-sigma (/spl Delta//spl Sigma/) analog-to-digital converter featuring 68-dB dynamic range and 64-dB signal-to-noise ratio in a 1-MHz bandwidth centered at an intermediate frequency of 2 MHz with a 48-MHz sample rate is reported. A second-order continuous-time modulator employing 4-bit quantization is used to achieve this performance with 2.2 mW of power consumption from a 1.8-V supply. The modulator including references occupies 0.36 mm/sup 2/ of die area and is implemented in a 0.18-/spl mu/m five-metal single-poly digital CMOS process.