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。     

Deterministic analysis of oversampled A/D conversion and decodingimprovement based on consistent estimates

Discusses the deterministic analysis of oversampled A/D conversion (ADC), the properties derivable from such an analysis, and the consequences on reconstruction using nonlinear decoding. Given a band-limited input X producing a quantized version C, the authors consider the set of all input signals that are band-limited and produce C. They call any element of this set a consistent estimate of X. Regardless of the type of encoder (simple, predictive, or noise-shaping), they show that this set is convex, and as a consequence, any nonconsistent estimate can be improved. They also show that the classical linear decoding estimates are not necessarily consistent. Numerical tests performed on simple ADC, single-loop, and multiloop ΣΔ modulation show that consistent estimates yield a mean square error (MSE) that decreases asymptotically with the oversampling ratio faster than the linear decoding MSE by approximately 3 dB/octave. This implies an asymptotic MSE of the order of 𝒪(R/sup -(2n+2/)) instead of 𝒪(R/sup -(2n+1/)) in linear decoding, where R is the oversampling ratio and n the order of the modulator. Methods of improvement of nonconsistent estimates based on the deterministic knowledge of the quantized signal are proposed for simple ADC, predictive ADC, single-loop, and multiloop ΣΔ modulation     

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 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     

Optimal decoding for data acquisition applications of sigma deltamodulators

A class of optimal nonlinear decoding algorithms is proposed for data acquisition applications of sigma-delta (ΣΔ) modulators. The technique is applicable to all current ΣΔ structures, including single and double-loop, cascade, and interpolative modulators. While the performance of the technique is identical to that of other optimal nonlinear decoding schemes such as table lookup, it is considerably simpler to implement. Numerical results are presented to compare its performance to that of linear decoders. Effects of circuit imperfections on performance are examined     

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     

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     

Direct projection decoding algorithm for sigma-delta modulated signals

Usually, sigma-delta modulators (/spl Sigma//spl Delta/M) are modeled by replacing the quantizer with an additive white noise source. Based on this linear model, linear decoder structures can be designed. However, the /spl Sigma//spl Delta/M is a nonlinear system, and corresponding nonlinear decoder structures may be able to achieve a better signal-to-quantization-noise ratio (SQNR) performance. In this paper, a new nonlinear decoding algorithm is presented. It is based on the projection onto complex sets (POCS) algorithm developed by Hein and Zakhor. Our algorithm reduces the decoding problem to the solution of a single quadratic programming problem based on the state equations of the modulator and the condition that the modulator input signal is bandlimited. The bandlimitation constraint is directly applied to the state equations. Thus, the resulting quadratic programming problem needs to be solved only once.     

A double-sampling pseudo-two-path bandpass ΔΣ modulator

A double-sampling pseudo-two-path bandpass ΔΣ modulator is proposed. This modulator has an output rate equal to twice the clock rate, uses n/2 operational amplifiers (op-amps) for an nth-older noise transfer function, and has reduced clock feedthrough in the signal path band. The required clocks can be simpler to implement than the conventional pseudo-two-path techniques. The measured signal-to-noise ratio and dynamic range of the fourth-order double-sampling pseudo-two-path bandpass ΔΣ modulator in a 30-kHz bandwidth at a center frequency of 2.5 MHz (at a clock frequency of 5 MHz) are 62 and 68 dB, respectively     

A 1.95-V, 0.34-mW, 12-b sigma-delta modulator stabilized by localfeedback loops

The design of a low-power, low-voltage, 12-b 8-kHz bandwidth ΣΔ modulator for high-quality voice that consumes only 0.34 mW at 1.95 V supply is described. The modulator employs a special architecture in which a third-order modulator is stabilized by a local feedback loop around each integrator. Unlike multistage ΣΔ modulators, this architecture is very tolerant to the modest dc gain of low voltage op-amps. The architecture, together with special circuit techniques, permits a low-voltage switched capacitor implementation at 1.95 V-3.3 V supply using standard 1.2-μm CMOS technology     

Signal-dependent timing jitter in continuous-time ΣΔmodulators

A previously unpublished mechanism of signal-to-noise ratio (SNR) loss specific to continuous-time ΣΔ modulators is illustrated. It arises from increased quantiser resolution time for small-amplitude quantiser inputs, and is related to metastability     

Dynamic range extension technique for high-order ΣΔADCs by digital level control

A new architecture is presented for a high-order multi-bit ΣΔ ADC which does not require a precision multi-bit DAC in the feedback loop. Local digital level control is employed to extend integrator output dynamic range. A prototype fourth-order modulator is simulated with circuit non-idealities, showing an SNR of ~110 dB     

A 1.8-V MOSFET-only ΣΔ modulator using substrate biaseddepletion-mode MOS capacitors in series compensation

A low-voltage high-linearity MOSFET-only ΣΔ modulator for speech band applications is presented. The modulator uses substrate biased MOSFETs in the depletion region as capacitors, linearized by a series compensation technique. A second-order fully differential single-loop architecture has been realized in a conventional 0.25-μm digital n-well CMOS process without extra layers for capacitors. An SNDR of 72 dB and an SNR of 77 dB is obtained with 8-kHz signal bandwidth at an oversampling ratio of 64. The circuit consumes about 1 mW from a single 1.8-V power supply and occupies a core area of 0.08 mm²     

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     

A 3.2-GHz second-order delta-sigma modulator implemented in InP HBTtechnology

This paper presents a second-order delta-sigma (ΔΣ) modulator fabricated in a 70 GHz (f_T), 90 GHz (f_max) AlInAs-GaInAs heterojunction bipolar transistor (HBT) process on InP substrates. The modulator is a continuous time, fully differential circuit operated from ±5 volt supplies and dissipates 1 W. At a sample rate of 3.2 GHz and a signal bandwidth of 50 MHz (OSR=32100 MSPS Nyquist rate) the modulator demonstrates a Spur Free Dynamic Range (SFDR) of 71 dB (12-b dynamic range). The modulator achieves the ideal signal-to-noise ratio (SNR) of 55 dB for a second-order modulator at an oversampling ratio (OSR) of 32. The design of a digital decimation filter for this modulator is complete and the filter is currently in fabrication in the same technology. This work demonstrates the first ΔΣ modulator in III-V technology with ideal performance and provides the foundation for extending the use of ΔΣ modulator analog-to-digital converters (ADC's) to radio frequencies (RF)     

Effects of non-ideal Hadamard modulators on the performance ofΠΔΣ ADC

A non-ideal Hadamard modulator in the front-end of ΠΔΣ ADC can be modelled as an ideal Hadamard modulator with gain error in parallel with an offset error. The effects of non-ideal Hadamard modulators can be partially removed by using chopper stabilisation and adaptive channel gain equalisation     

Multi-bit cascade ΣΔ modulator for high-speed A/Dconversion with reduced sensitivity to DAC errors

The authors present a ΣΔ modulator (ΣΔM) which combines single-bit and multi-bit quantisation in a cascade architecture to obtain high resolution with a low oversampling ratio. It is less sensitive to the nonlinearity of the digital-to-analogue (DAC) than those previously reported, thus enabling the use of very simple analogue circuitry with neither calibration nor trimming required     

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     

CMOS fully-differential bandpass ΣΔ modulator usingswitched-current circuits

The authors present a fourth-order bandpass ΣΔ switched-current modulator IC in 0.8 μm CMOS single-poly technology. It is the first reported integrated circuit realisation of a bandpass ΣΔ modulator using switched-current circuits. Its architecture is obtained by applying a lowpass to bandpass transformation (z¹→-z²) to a second-order lowpass modulator. It has been realised using fully-differential circuitry with common-mode feedback. Measurements show 8 bit dynamic range up to 5 MHz clock frequency     

Error-driven edge selection for ΣΔ modulated signals tosuppress in-band noise due to non-uniform sampling

A method for suppressing the in-band noise of ΣΔ-modulated signals due to non-uniform sampling is proposed. This method enables the use of the over-sampling clock generated from a fractional programmable generator without significant degradation in the signal-to-(noise+distortion) ratio (SNDR). The sampling frequency is controlled with a frequency resolution of 5.4 Hz without an analogue PLL. Experimental results for the voice band application of the ΣΔ-modulated 1 bit DAC show that the SNDR can be maintained at >70 dB, for sampling rates in the range 7.1-7.8 kHz