A 4-GHz clock system for a high-performance system-on-a-chip design

A digital system's clocks must have not only low jitter, but also well-controlled duty cycles in order to facilitate versatile clocking techniques. Power-supply noise is often the most common and dominant source of jitter on a phase-locked loop's (PLL) output clock. Jitter can be minimized by regulating the supply to the PLL's noise-sensitive analog circuit blocks in order to filter out supply noise. This paper introduces a PLL-based clock generator intended for use in a high-speed highly integrated system-on-a-chip design. The generator produces clocks with accurate duty cycles and phase relationships by means of a high-speed divider design. The PLL also achieves a power-supply rejection ratio (PSRR) greater than 40 dB while operating at frequencies exceeding 4 GHz. The high level of noise rejection exceeds that of earlier designs by using a combination of both passive and active filtering of the PLL's analog supply voltage. The PLL system has been integrated in a 0.15-μm single-poly 5-metal digital CMOS technology. The measured performance indicates that at a 4-GHz output frequency the circuit achieves a PSRR greater than 40 dB. The peak cycle-to-cycle jitter is 25 ps at 700 MHz and a 2.8-GHz VCO frequency with a 500-mV step on the regulator's 3.3-V supply. The total power dissipated by the prototype is 130 mW and its active area is 1.48×1.00 mm²     

A Phase‐Locked Loop with Embedded Analog‐to‐Digital Converter for Digital Control

A phase‐locked loop (PLL) is described which is operable from 0.4 GHz to 1.2 GHz. The PLL has basically the same architecture as the conventional analog PLL except the locking information is stored as digital code. An analog‐to‐digital converter is embedded in the PLL, converting the analog loop filter output to digital code. Because the locking information is stored as digital code, the PLL can be turned off during power‐down mode while avoiding long wake‐up time. The PLL implemented in a 0.18 µm CMOS process occupies 0.35 mm² active area. From a 1.8 V supply, it consumes 59 mW and 984 µW during the normal and power‐down modes, respectively. The measured rms jitter of the output clock is 16.8 ps at 1.2 GHz.     

An all-band TV tuner IC with 10-GHz 100-V mixed analog/digital Sibipolar technology

An all-band TV tuner IC with an on-chip PLL and a high-voltage output stage is developed. The use of a self-aligned bipolar technology called high-voltage compatible sidewall base contact structure (HV-SICOS) allows the integration of 1-GHz analog circuits, 1-GHz low-power ECL-I²L PLL circuits, and a 0.5- to 30-V tuning diode bias current on the same chip. The analog block has a VCO and mixer pair for the VHF/CATV and another pair for the UHF bands, a UHF input amplifier, an IF amplifier, and a VCO signal switching circuit. To suppress the digital noise level for mixed analog/digital mode operation, the PLL is constructed with high-speed ECL circuits for divide-by-four and dual modulus prescalers, and low-power I²L circuits. An isolation area is placed between the analog and digital blocks. Conversion gain of 24 dB for VHF/CATV and 33 dB for UHF, a noise figure of 10 dB, and 1% cross modulation of 95 dB-μV are obtained. This IC operates with a total power dissipation of 200 mW on a 3-mm×4-mm chip     

Toward Wide-Band High-Resolution Analog-to-Digital Converters Using Hybrid Filter Bank Architecture

The paper presents the problem of design and simulation of a high-speed wide-band high-resolution analog-to-digital (ADC) converter working in a bandpass scenario. Such converters play a crucial role in software-defined radio and in cognitive radio technology. One way to circumvent the limits of today’s ADC technologies is to split the analog input signal into multiple components and then sample them with ADCs in parallel. The two main split approaches, time interleaved and frequency splitting, can be modeled using a filter bank paradigm, where each of these two architectures requires a specific analysis for its design. In this research, the frequency splitting approach was implemented with the use of a hybrid filter bank ADC, which requires an output digital filter bank perfectly matched to the input analog filter bank. To achieve this end, an analog transfer function, together with an assumption of strictly band-limited input signal, has been used to design the digital filter bank so far. In contrast, the author proposes dropping the band-limit assumption and shows that the out-of-band input signal has to be taken into account when designing a hybrid filter bank.     

C波段锁相变频器模块

设计了一种采用锁相环技术的C波段变频器模块,其原理是输入的信号与压控振荡器(VCO)信号相混频,产生两个信号频率差的信号,这个信号与差频信号IF进行鉴频鉴相,产生的误差信号经环路滤波送入压控振荡器(VCO)的调谐端完成锁相,这时压控振荡器输出的信号就是需要的信号。采用这种技术,模块输出的有用信号与输入信号泄漏到输出端口的功率比在83dB以上,可以达到较好的效果,同时可有效避免使用体积较大的腔体带通滤波器。     

Optical homodyne receiver based on an improved balance phase-lockedloop with the date-to-phaselock crosstalk suppression

An improved balanced phase-locked loop (PLL) with postdetection processing is proposed to eliminate the data-to-phaselock crosstalk which potentially limits the usable ratio of laser linewidth to bit rate in pilot-carrier phase-shift keying (PSK) optical homodyne systems. The phase-lock current is first subtracted from the output signal of the data receiver before input to the loop filter. An attenuator is used to ensure the equilibrium of the feedback output signal and data-to-phaselock crosstalk. A shaping filter is introduced to simulate the distortion of data signals at the output of the preamplifier. The homodyne receivers based on this kind of PLL have the advantage of a large tolerance for the laser linewidth compared with the conventional balanced PLL receivers     

Phase-Locked Loop Coherent Combiners for Phased Array Sensor Systems

Phase-locked loops (PLL's) may be used to implement signal combiners which coherently sum multiple signals from an array of sensors. In each combiner channel, the sensor signal is simultaneously downconverted to an intermediate frequency (IF) signal and phase-locked to an appropriately generated reference signal by a "long-loop" PLL. This loop maintains a nominal 90° phase difference between the IF signal and the reference signal irrespective of phase of the channel input (sensor output) signal. The channel IF signals are summed to generate the combiner output signal. The reference signal may be a locally generated sine wave or a delayed version of the combiner output signal. Imperfect phase control and, thus, imperfect signal combining results when noise voltages are associated with the channel signals. In this paper, a lincarized model of a PLL coherent combiner is developed. This model applies when the desired channel signals are equal amplitude and angle modulated; the channel noise voltages are equal level, Gaussian distributed, and independent; and the combiner phase errors are appropriately small. This model is then used to derive equations for the variance of differential phase errors associated with combiner operation and to show the effect of these phase errors on the average power in the combiner output signal. Relevant experimental results from a four-channel combiner are compared with the performance predicted by the linear model.     

A 2-V, 1.8-GHz BJT phase-locked loop

This paper describes the design of a bipolar junction transistor phase-locked loop (PLL) for ΣΔ fractional-N frequency-synthesis applications. Implemented in a 0.8-μm BiCMOS technology, the PLL can operate up to 1.8 GHz while consuming 225 mW of power from a single -2-V supply. The entire LC-tuned negative-resistance variable-frequency oscillator is integrated on the same chip. A differential low-voltage current-mode logic circuit configuration is used in most of the PLL's functional blocks to minimize phase jitter and achieve low-voltage operation. The multimodulus frequency divider is designed to support multibit digital modulation. The new phase and frequency detector and loop filter contain only npn transistors and resistors and thus achieve excellent resolution in phase comparison. When phase locked to a 53.4-MHz reference clock, the measured phase noise of the 16-GHz output is -91 dBc/Hz at 10-kHz offset. The frequency switching time from 1.677 to 1.797 GHz is 150 μs. Die size is 4300×4000 μm², including the passive loop filter     

A frequency steered phase-locked loop

Narrow bandwidth phase-locked loops (PLLs) can have difficulty acquiring lock reliably when there is a significant difference between the input signal and the free run frequency of the PLL's voltage-controlled oscillator (VCO). The new technique presented here incorporates an accurate local reference frequency into the PLL structure. The range of frequencies to which the new PLL structure can lock can be confined to a desired small region around the accurate local reference frequency. The new PLL structure also provides other benefits such as reduction of VCO phase noise. The new technique does not require any monitoring nor any switching of the local frequency reference signal which is always acting. The key parameters of the new PLL structure are identified and the performance characterized     

基亏DSP的多路音／视频采集处理系统设计

采用TI公司的TMS320DM642型数字媒体数字信号处理器（DSP）设计多路音／视频采集处理系统，实现实时处理4路模拟视频和音频输入、1路模拟／数字视频和1路模拟音频信号输出的功能，该系统可适应PAL／NTSC标准复合视频CVBS或分量视频Y／C格式的模拟信号和标准麦克风或立体声音频模拟输入，具有PAL／NTSC标准S端子或数字RGB模拟／数字信号输出和标准立体声音频模拟输出。并给出软／硬件设计原理和电路。     

用90nm CMOS数字工艺实现的低抖动时钟锁相环设计

用90nmCMOS数字工艺设计实现了一个低抖动的时钟锁相环.锁相环不需要"模拟"的电阻和电容,采用金属间的寄生电容作为环路滤波器的电容.测试结果显示,锁相环锁定在1.989GHz时的均方抖动为3.7977ps,周期峰峰值抖动为31.225ps,核心功耗约为9mW.锁相环可稳定输出的频率范围为125MHz到2.7GHz.     

用90nm CMOS数字工艺实现的低抖动时钟锁相环设计

用90nmCMOS数字工艺设计实现了一个低抖动的时钟锁相环.锁相环不需要"模拟"的电阻和电容,采用金属间的寄生电容作为环路滤波器的电容.测试结果显示,锁相环锁定在1.989GHz时的均方抖动为3.7977ps,周期峰峰值抖动为31.225ps,核心功耗约为9mW.锁相环可稳定输出的频率范围为125MHz到2.7GHz.     

A Wide-Tracking Range Clock and Data Recovery Circuit

A hybrid analog-digital quarter-rate clock and data recovery circuit (CDR) that achieves a wide-tracking range and excellent frequency and phase tracking resolution is presented in this paper. A split-tuned analog phase-locked loop (PLL) provides eight equally spaced phases needed for quarter-rate data recovery and the digital CDR loop adjusts the phase of the PLL output clocks in a precise manner to facilitate plesiochronous clocking. The CDR employs a second-order digital loop filter and combines delta-sigma modulation with the analog PLL to achieve sub-picosecond phase resolution and better than 2 ppm frequency resolution. A test chip fabricated in a 0.18 mum CMOS process achieves BER <10^-12 and consumes 14 mW power while operating at 2 Gb/s. The tracking range is greater than plusmn5000 ppm and plusmn2500 ppm at 10 kHz and 20 kHz modulation frequencies, respectively, making this CDR suitable for systems employing spread-spectrum clocking.     

Linear processing of PWM signals using a RC time encoded integrator

This paper describes a delay-and-addition cell that enables direct signal processing of pulse with modulation (PWM) encoded signals. The cell can be considered functionally equivalent to a switched capacitor integrator. However, both its input and output are synchronous PWM signals. As a difference to a switched capacitor integrator, the circuit does not require operational amplifiers and is composed of passive RC circuits, switches, comparators and digital logic. Circuit implementation non idealities such as offset and propagation delays have also been analyzed. The main advantage of this circuit is the possibility to operate at a low voltage. The paper shows measurements of a demonstration circuit implementing a first order filter. As an application example, the filter is used to attenuate the quantization noise of a sigma-delta signal, delivering a continuously varying PWM waveform from a synchronous bitstream.     

A Continuous-Time ADC/DSP/DAC System With No Clock and With Activity-Dependent Power Dissipation

A continuous-time system that converts its analog input to a continuous-time digital representation without sampling, then processes the information digitally without the aid of a clock, is presented. Without sampling there is no aliasing, which reduces the in-band distortion power by not aliasing into band out-of-band distortion components. The 8-bit system, fabricated in a 90 nm CMOS process, utilizes continuous delay elements as part of a programmable transversal FIR filter. The input is encoded by a delta modulator without a clock into a series of non-uniformly spaced tokens, which are processed by the digital continuous-time filter and converted to an analog output using a custom DAC that guarantees there are no glitches in the output waveform. All activity is signal driven, automatically affording dynamic power scaling that tracks input activity.      

The First Fully Integrated Quad-Band GSM/GPRS Receiver in a 90-nm Digital CMOS Process

We present the receiver in the first single-chip GSM/GPRS transceiver that incorporates full integration of quad-band receiver, transmitter, memory, power management, dedicated ARM processor and RF built-in self test in a 90-nm digital CMOS process. The architecture uses Nyquist rate direct RF sampling in the receiver and an all-digital phase-locked loop (PLL) for generating the local oscillator (LO). The receive chain uses discrete-time analog signal processing to down-convert, down-sample, filter and analog-to-digital convert the received signal. A feedback loop is provided at the mixer output and can be used to cancel DC-offsets as well to study linearization of the receive chain. The receiver meets a sensitivity of$-$110 dBm at 60mA in a 1.4-V digital CMOS process in the presence of more than one million digital gates.     

A 19.2 GOPS mixed-signal filter with floating-gate adaptation

We have built a 48-tap, mixed-signal adaptive FIR filter with 8-bit digital input and an analog output with 10 bits of resolution. The filter stores its tap weights in nonvolatile analog memory cells using synapse transistors, and adapts using the least mean square (LMS) algorithm. We run the input through a digital tapped delay line, multiply the digital words with the analog tap weights using mixed-signal multipliers, and adapt the tap coefficients using pulse-based feedback. The accuracy of the weight updates exceeds 13 bits. The total die area is 2.6 mm/sup 2/ in a 0.35-/spl mu/m CMOS process. The filter delivers a performance of 19.2 GOPS at 200 MHz, and consumes 20 mW providing a 6-mA differential output current.     

频谱分析仪的数字中频设计方案

为了提高频谱分析仪的频率分辨率,同时降低模拟中频、视频电路组件的生产难度,现代频谱分析仪大多采用数字中频技术,利用模数转换器把模拟中频信号转换为数字信号,经过数字下变频、数字滤波、数字检波或快速傅里叶变换运算后得到射频信号的幅度和频率信息,再经过视频滤波处理后得到清晰的信号频谱.文中论述的信号处理方案实现了频谱的数字分析,在实际应用中验证了其指标的稳定.     

Phase Lock for Correlation Detection of a Periodic Pulse

The detection of the presence of a periodic pulse with uncertain pulse rate and low duty cycle is a common biotelemetry problem. Modern phase-lock and correlation techniques have provided more efficient means of making the presence decision than that provided by energy detection methods. A local signal is cross correlated with the input in a phase-locked loop (PLL) to provide phase reference. Upon lock, a local duplicate signal is generated and correlated with the input. A decision threshold operates on the correlator output. The PLL with filter F(s) = (s+a)/s and three appropriate nonlinearities are analyzed for acquisition time and maximum frequency error that will lock.     

带有自适应频率校准单元的26~41 GHz锁相环

采用45 nm SOI CMOS工艺,设计了一种带有自适应频率校准单元的26~41 GHz 锁相环。该锁相环包括输入缓冲器、鉴频鉴相器、电荷泵、环路滤波器、压控振荡器、高速时钟选通器、分频器和频率数字校准单元。采用了基于双LC-VCO的整数分频锁相环,使用了自适应频率选择的数字校准算法,使得锁相环能在不同参考时钟下自适应地调整工作频率范围。仿真结果表明,该锁相环的输出频率能够连续覆盖26~41 GHz。输出频率为26 GHz时,相位噪声为-103 dBc/Hz@10 MHz,功耗为34.64 mW。输出频率为41 GHz时,相位噪声为-96 dBc/Hz@10 MHz,功耗为35.44 mW。