A delta-sigma PLL for 14-b, 50 kSample/s frequency-to-digitalconversion of a 10 MHz FM signal

In many wireless applications, it is necessary to demodulate and digitize frequency or phase modulated signals. Most commonly, this is done using separate frequency discrimination and analog-to-digital (A/D) conversion. In low-cost IC technologies, such as CMOS, precise analog frequented discrimination is not practical, so the A/D conversion is usually performed in quadrature or at a nonzero intermediate frequency (IF) with digital frequency discrimination. While practical, the approach tends to require complicated A/D converters, and accuracy is usually limited by the duality of the A/D conversion. This paper presents an alternative structure, referred to as a delta-sigma frequency-to-digital converter (ΔΣFDC), that simultaneously performs frequency demodulation and digitization. The ΔΣFDC is shown to offer high-precision performance with very low analog complexity. A prototype of the key component of the ΔΣFDC has been fabricated in a 0.6 μm, single-poly, CMOS process. The prototype achieved 50 kSample/s frequency-to-digital conversion of a 10 MHz frequency-modulated signal with a worst case signal-to-noise-and-distortion ratio of 85 dB and a worst case spurious-free dynamic range of 88 dH     

A CMOS analog front-end circuit for an FDM-based ADSL system

A CMOS analog front-end circuit for an FDM-based ADSL system is presented. The circuit contains all analog functions including AGC amplifiers, continuous-time band pass filters, ΣΔ AD/DA converters, and digital decimation and interpolation filters. On-chip automatic tuning of the bandpass filters provides more than 300% center frequency range with 1% frequency accuracy. The higher-order ΣΔ AD/DA converters achieve 12-b data conversion at 1.54 Msamples/s with an oversampling ratio of only 32. The 0.7 μm CMOS circuit measures 65 mm² and consumes 1.9 W from a single 5 V power supply     

A 10.7-MHz IF-to-baseband ΣΔ A/D conversion system forAM/FM radio receivers

ΣΔ modulation with integrated quadrature mixing is used for analog-to-digital (A/D) conversion-of a 10.7-MHz IF input signal in an AM/FM radio receiver. After near-zero IF mixing to a 165 kHz offset frequency, the I and Q signals are digitized by two fifth-order, 32 times oversampling continuous-time ΣΔ modulators. A prototype IC includes digital filters for decimation and the shift of the near-zero-IF to dc. The baseband output signal has maximum carrier-to-noise ratios of 94 dB in 9 kHz (AM) and 79 dB in 200 kHz (FM), with 97 and 82 dB dynamic range, respectively. The IM3 distance is 84 dB at full-scale A/D converter input signal. Including downconversion and decimation filtering, the IF A/D conversion system occupies 1.3 mm² in 0.25-μm standard digital CMOS. The ΣΔ modulators consume 8 mW from a 2.5-V supply voltage, and the digital filters consume 11 mW     

Granular quantization noise in a class of delta-sigma modulators

The trend toward digital signal processing in communication systems has resulted in a large demand for fast accurate analog-to-digital (A/D) converters, and advances in VLSI technology have made ΔΣ modulator-based A/D converters attractive solutions. However, rigorous theoretical analyses have only been performed for the simplest ΔΣ modulator architectures. Existing analyses of more complicated ΔΣ modulators usually rely on approximations and computer simulations. In the paper, a rigorous analysis of the granular quantization noise in a general class of ΔΣ modulators is developed. Under the assumption that some input-referred circuit noise or dither is present, the second-order asymptotic statistics of the granular quantization noise sequences are determined and ergodic properties are derived     

A GMSK modulator using a ΔΣ frequencydiscriminator-based synthesizer

This paper describes a new transmitter architecture suitable for wideband GMSK modulation. The technique uses direct modulation of ΔΣ frequency discriminator (ΔΣFD)-based synthesizer to produce the modulated RF signal without any up-conversion. Digital equalization is used to extend the modulation data rate far beyond the synthesizer closed-loop BW. A prototype 1.9-GHz GSM transmitter was constructed consisting of a ΔΣFD-based synthesizer and a digital transmit filter. The synthesizer consists of an 0.8-μm BiCMOS ΔΣFD chip, a digital signal processor FPGA, and an off-chip D/A converter, filter, and VCO. Measured results, using 271-kbit/s GSM modulation, demonstrate data rates well in excess of the 30-kHz synthesizer closed-loop BW are possible with digital equalization. Without modulation, the synthesizer exhibits a -76-dBc spurious noise level and a close-in phase noise of -74 dBc/Hz     

A fourth-order bandpass sigma-delta modulator

The modulator of a bandpass analog/digital (A/D) converter, with 63 dB signal/noise for broadcast AM bandwidth signals centered at 455 kHz, has been implemented by modifying a commercial digital-audio sigma-delta (ΣΔ) converter. It is the first reported fully monolithic implementation of bandpass noise shaping and has applications to digital radio     

A 13.5-b 1.2-V micropower extended counting A/D converter

This work presents a study of the extended counting technique for a 1.2-V micropower voice-band A/D converter. This extended counting technique is a blend of ΣΔ modulation with its high resolution but relatively low speed and algorithmic conversion with its higher speed but lower accuracy. To achieve this, the converter successively operates first as a first-order ΣΔ modulator to convert the most significant bits, and then the same hardware is used as an algorithmic converter to convert the remaining least significant bits. An experimental prototype was designed in 0.8-μm CMOS. With a 1.2-V power supply, it consumes 150 μW of power at a 16-kHz Nyquist sampling frequency. The measured peak S/(N+THD) was 80 dB and the dynamic range 82 dB. The converter core including the controller and all reconstruction logic occupies about 1.3×1 mm² of chip area. This is considerably less than a complete ΣΔ modulation A/D converter where the digital decimation filter would occupy a significant amount of chip area     

Quadrature bandpass ΔΣ modulation for digital radio

A quadrature bandpass ΔΣ modulator IC facilitates monolithic digital-radio-receiver design by allowing straightforward “complex A/D conversion” of an image reject mixer's I and Q, outputs. Quadrature bandpass ΔΣ modulators provide superior performance over pairs of real bandpass ΔΣ modulators in the conversion of complex input signals, using complex filtering embedded in ΔΣ loops to efficiently realize asymmetric noise-shaped spectra. The fourth-order prototype IC, clocked at 10 MHz, converts narrowband 3.75-MHz I and Q inputs and attains a dynamic range of 67 dB in 200-kHz (GSM) bandwidth, increasing to 71 and 77 dB in 100- and 30-kHz bandwidths, respectively. Maximum signal-to-noise plus distortion ratio (SNDR) in 200-kHz bandwidth is 62 dB. Power consumption is 130 mW at 5 V. Die size in a 0.8-μm CMOS process is 2.4×1.8 mm²      

A 900-mV low-power ΔΣ A/D converter with 77-dB dynamicrange

The design of a low-voltage and low-power ΔΣ analog-to-digital (A/D) converter is presented. A third-order single-loop ΔΣ modulator topology is implemented with the differential modified switched op-amp technique. The modulator topology has been transformed as to accommodate half-delay integrators. Dedicated low-voltage circuit building blocks, such as a class AB operational transconductance amplifier, a common-mode feedback amplifier, and a comparator are treated, as well as low-voltage design techniques. The influence of very low supply voltage on power consumption is discussed. Measurement results of the 900-mV ΔΣ A/D converter show a 77-dB dynamic range in a 16-kHz bandwidth and a 62-dB peak signal-to-noise ratio for a 40-μW power consumption     

CMOS oversampling ΔΣ magnetic-to-digital converters

In this paper, two CMOS oversampling delta-sigma (ΔΣ) magnetic-to-digital converters (MDCs) are proposed. The first MDC consists of the magnetic operational amplifier (MOP) and a first-order switched-capacitor (SC) ΔΣ modulator. The second one directly uses the MOP to realize a first-order SC ΔΣ modulator. They can convert the external magnetic field into digital form. Both circuits were fabricated in a 0.5-μm CMOS double-poly double-metal (DPDM) process and operated at a 5-V supply voltage and the nominal sampling rate of 2.5 MHz. The dynamic ranges of these converters are at least ±100 mT. The gain errors within ±100 mT are less than 3% and the minimum detectable magnetic field can reach as small as 1 mT. The resolutions are 100 μT for both of the two MDCs. The measured sensitivities are 1.327 mv/mT and 0.45 mv/mT for the first and the second MDC, respectively     

The implementation of digital echo cancellation in codecs

The architecture of a codec in which the echo cancellation is done in two stages, an analog hybrid to reduce the echo level at the input of the A/D converter and a programmable digital balance filter, is presented. The design problems connected with this architecture, such as the signal-to-noise performance of the A/D converter and the limiting effects of the variation of the analog components on the echo cancellation performance of the device and on the structure of the digital balance filters, are discussed. These results were used in the design of a single-power-supply CMOS device implemented in 1.5-μm technology using ΣΔ modulation techniques for A/D and D/A conversion. Its echo cancellation performance is sufficiently high that only one set of coefficients per national standard is necessary     

A CMOS 0.8-μm transistor-only 1.63-MHz switched-current bandpassΣΔ modulator for AM signal A/D conversion

This paper presents a CMOS 0.8-μm switched-current (SI) fourth-order bandpass ΣΔ modulator (BP-ΣΔM) IC capable of handling signals up to 1.63 MHz with 105-bit resolution and 60-mW power consumption from a 5-V supply voltage. This modulator Is intended for direct A/D conversion of narrow-band signals within the commercial AM band, from 530 kHz to 1.6 MHz. Its architecture is obtained by applying a low-pass-to-bandpass transformation (z^-1 →-z^-2) to a 1-bit second-order low-pass ΣΔ modulator (LP-ΣΔM). The design of basic building blocks is based upon a detailed analysis of the influence of SI errors on the modulator performance, followed by design optimization. Memory-cell errors have been identified as the dominant ones. In order to attenuate these errors, fully differential regulated-folded cascode memory cells are employed. Measurements show a best SNR peak of 65 dB for signals of 10-kHz bandwidth and an intermediate frequency (IF) of 1.63 MHz. A correct noise-shaping filtering is achieved with a sampling frequency of up to 16 MHz     

Triangularly weighted zero-crossing detector providingΣΔ frequency-to-digital conversion

It is shown that for delta-sigma (ΣΔ) frequency-to-digital conversion (FDC) there is no need for a ΣΔ modulator, since a limited FM signal itself may be considered as an asynchronous ΣΔ bit-stream. By feeding the limited FM signal directly to a sinc² ΣΔ decimator, a triangularly weighted zero-crossing counter FDC is introduced, providing ΣΔ noise shaping. The results measured confirm the theory     

Digital detection of instability of higher order bandpasssigma-delta converters

A digital method of stabilising higher order sigma-delta converters is presented. Results are given for a third order bandpass ΣΔ converter with three continuous time LC filters tuned to 1/4 of clock frequency f_c     

标准数字工艺下16位精度低压低功耗ΣΔ模数调制器设计

针对输入信号频率在20 Hz～24 kHz范围的音频应用,该文采用标准数字工艺设计了一个1.2 V电源电压16位精度的低压低功耗ΣΔ模数调制器。在6 MHz采样频率下,该调制器信噪比为102.2 dB,整个电路功耗为2.46 mW。该调制器采用一种伪两级交互控制的双输入运算放大器构成各级积分器,在低电源电压情况下实现高摆率高增益要求的同时不会产生更多功耗。另外,采用高线性度、全互补MOS耗尽电容作为采样、积分电容使得整个电路可以采用标准数字工艺实现,从而提高电路的工艺兼容性、降低电路成本。与近期报道的低压低功耗ΣΔ模数调制器相比,该设计具有更高的品质因子FOM。     

Mismatch shaping for a current-mode multibit delta-sigma DAC

Mismatch shaping allows the use of multibit quantization in delta-sigma analog-to-digital converters and digital-to-analog converters (DAC's) since it noise-shapes the error caused by static element mismatch in a multibit DAC. In this paper, mismatch-shaping techniques for low-pass delta-sigma (ΔΣ) modulators are reviewed, and a mismatch-shaping technique for bandpass ΔΣ modulators is described. The dynamic error caused by frequent element switching is identified as a major source of error in a current-mode DAC with a continuous-time output. Modifying the mismatch-shaping algorithm to account for this effect yields a continuous-time ΔΣ DAC that is insensitive to both element mismatch and element switching dynamics. Experimental results confirm the effectiveness of the proposed techniques     

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     

Data converters for communication systems

Data converters are playing an ever increasingly important role in digital communication channels. As VLSI technologies scale, more of the signal processing is performed in the digital domain, making superior converter design critical. Attributes of various modern analog-to-digital converters such as flash and ΣΔ are described     

Design and realization of a digital ΔΣ modulator forfractional-n frequency synthesis

The basic operation of a fractional-n frequency synthesizer has been published, but to date little has been presented on the digital ΔΣ modulators which are required to drive such synthesizers. This paper provides a tutorial overview, which relates digital ΔΣ modulation to other applications of ΔΣ modulation where the literature is more complete. The paper then presents a digital ΔΣ modulator architecture which is economical and efficient and which is practical to realize with commercially available components in comparison with other possible implementations which require extensive custom very large-scale integration (VLSI). A demonstration is made of a 28-b modulator using the architecture presented, which provides a 25-MHz tuning bandwidth and <1-Hz frequency resolution. The modulator is demonstrated in an 800-MHz frequency synthesizer having phase noise of -90 dBC/Hz at a 30-kHz offset