An integrated 0.35 μm CMOS optical receiver with clock and data recovery circuit

This paper presents an integrated optical receiver that operates at 1 Gb/s in a standard 0.35 μm digital CMOS technology. The receiver consists of an integrated CMOS photodetector, a transimpedance amplifier (TIA) followed by a post-amplification stage and a dual-loop clock and data recovery (CDR) circuit. At a wavelength of 860 nm, the circuit requires an average light input power of −19.7 dBm to obtain a bit-error rate (BER) of 10⁻¹². The complete receiver consumes a total power of approximately 155 mW from a 3.3-V supply. The core circuit area is 0.85×1.32 mm².     

A wide-range all digital DLL for multiphase clock generation

This paper presents a wide-range all digital delay-locked loop (DLL) for multiphase clock generation. Using the phase compensation circuit (PCC), the large phase difference is compensated in the initial step. Thus, the proposed solution can overcome the false-lock problem in conventional designs, and keeps the same benefits of conventional DLLs such as good jitter performance and multiphase clock generation. Furthermore, the proposed all digital multiphase clock generator has wide ranges and is not related to specific process. Thus, it can reduce the design time and design complexity in many different applications. The DLL is implemented in a 0.13 μm CMOS process. The experimental results show that the proposal has a wide frequency range. The peak-to-peak jitter is less than 7.7 ps over the operating frequency range of 200 MHz-1 GHz and the power consumption is 4.8 mW at 1 GHz. The maximum lock time is 20 clock cycles.     

A high-speed four-phase clock generator for low-power on-chip SerDes applications

In this work we present a low-power, low-area and high-speed fully CMOS quadrature clock generator for on-chip SerDes applications. The device utilizes a couple of differential prescalers for high speed frequency division and four duty cycle adjusters to set the duty cycle of the produced clock signals at 50% of the clock period. The circuit was implemented with the STMicroelectronics 65 nm process technology using only 125 transistors and it occupies an active area of under 2.34 μm². With a power supply of 1.1 V the complete circuit consumes 89.56 μW at room temperature.     

A systematic design approach for low-power 10-bit 100 MS/s pipelined ADC

A systematic design approach for low-power 10-bit, 100 MS/s pipelined analog-to-digital converter (ADC) is presented. At architectural level various per-stage-resolution are analyzed and most suitable architecture is selected for designing 10-bit, 100 MS/s pipeline ADC. At Circuit level a modified wide-bandwidth and high-gain two-stage operational transconductance amplifier (OTA) proposed in this work is used in track-and-hold amplifier (THA) and multiplying digital-to-analog converter (MDAC) sections, to reduce power consumption and thermal noise contribution by the ADC. The signal swing of the analog functional blocks (THA and MDAC sections) is allowed to exceed the supply voltage (1.8 V), which further increases the dynamic range of the circuit. Charge-sharing comparator is proposed in this work, which reduces the dynamic power dissipation and kickback noise of the comparator circuit. The bootstrap technique and bottom plate sampling technique is employed in THA and MDAC sections to reduce the nonlinearity error associated with the input signal resulting in a signal-to-noise-distortion ratio of 58.72/57.57 dB at 2 MHz/Nyquist frequency, respectively. The maximum differential nonlinearity (DNL) is +0.6167/−0.3151 LSB and the maximum integral nonlinearity (INL) is +0.4271/−0.4712 LSB. The dynamic range of the ADC is 58.72 dB for full-scale input signal at 2 MHz input frequency. The ADC consumes 52.6 mW at 100 MS/s sampling rate. The circuit is implemented using UMC-180 nm digital CMOS technology.     

An ultra low power QPSK receiver based on super-regenerative oscillator with a novel digital phase detection technique

An original proposal of using SRO-based receiver to demodulate QPSK signals is presented. The receiver is composed of an LNA and a super-regenerative oscillator (SRO), both combined in a single stacked configuration for current reuse. The demodulation of received RF signal is performed via a novel digital circuit capable of detecting phase information embedded in the SRO output. The receiver is able to demodulate incoming signal without the need of an LO, PLL or an ADC. The complete receiver was designed using a 0.13 μm technology and pre-layout simulation confirms proper and efficient operation, where the designed receiver operating in the 402–405 MHz MICS band shows 135 μW power consumption, while being able to properly detect and extract sent information of a −80 dBm, 2 Mbps signal.     

Clock buffer with duty cycle corrector

A clock buffer with duty cycle corrector circuit is presented. The proposed circuit can generate either 50% duty cycle or conserve the duty cycle as input clock. It corrects the input duty cycle of 10-90% for generated 50% duty cycle of output clock with error less than 0.9%. Moreover, it enhances the input clock signal driving ability and keeps the same duty cycle as input clock within range from 20% to 80% with a maximum duty error of 0.5%. The proposed circuit operation frequency range is from 100 MHz to 1 GHz. The proposed circuit has been fabricated in a 0.18 μm CMOS technology.     

CMOS 5 Gb/s串行接收器

设计了一个使用0.13μm CMOS工艺制造的低电压低功耗串行接收器。它的核心电路工作电压为1V,工作频率范围从2.5 GHz到5 GHz。接收器包括两个1:20的解串器、一个输入信号预放大器以及时钟恢复电路。在输入信号预放大器中设计了一个简单新颖的电路,利用前馈均衡来进一步消除信号的码间串扰,提高接收器的灵敏度。测试表明,接收器功耗45 mW。接收器输入信号眼图闭合0.5UI,信号差分峰-峰值150 mV条件下误码率小于10~(-12)。接收器还包含了时钟数据恢复电路,其中的相位插值器通过改进编码方式,使得输出信号的幅度能够保持恒定,并且相位具有良好的线性度。     

Low-voltage CMOS current-mode exponential circuit with 70 dB output dynamic range

The paper proposes new accurate exponential circuits, having a multitude of practical applications in analog signal processing. The original method for obtaining the exponential function is based on the utilization of new superior-order approximation functions. The accuracy of the proposed structures is excellent and the output dynamic range is strongly extended as a result of the fourth-order approximation and of the independence of implemented function on technological errors and on temperature variations (the best original proposed architecture of the exponential generator has an output dynamic range of 70 dB for an approximation error smaller than ±1 dB). The exponential circuits are designed for implementing in 0.18 µm CMOS technology, having a low-voltage operation (a minimal supply voltage of 1 V). The power consumptions of the proposed exponential circuits are smaller than 0.08 mW, for a supply voltage of 1 V. As application of the new exponential circuit, a dB-linear VGA circuit with high output dynamic range will be presented. The new computational structures have the possibility of generating any continuous mathematical function, presenting also an increased modularity and controllability and reduced design costs per implemented function.     

A high-speed sample-and-hold circuit based on CMOS transmission lines

We introduce the design of a high-speed sample-and-hold circuit (SHC) based on spatial sampling with CMOS transmission lines (TLs). Signal propagation analysis shows that periodically loaded CMOS TLs exhibit filter properties, which cause attenuation and deformation of signal pulses. Nevertheless, the dispersion effects on clock pulse propagation are minimal since clock lines are short, much shorter than the meandered input-signal line. Design considerations on clock pulse generator, sampling switches, and charge amplifiers are presented. Compared with other CMOS approaches, the proposed SHC generates clock pulses on chip and avoids clock jitter difficulties. The SHC is implemented in a 0.13 μm digital CMOS process with standard on-chip coplanar waveguides (CPW) as signal and clock pulse propagation TLs, silicon N-type field effect transistors (NFET) as sampling switches, and high-frequency charge amplifiers for charge amplification. Clock pulse signals of ~50 ps width with ~17 ps fall edge are generated on-chip. Simulation analysis with Cadence Spectre shows that a sampling rate of 20 Giga-sample/s with a 25 dB spurious free dynamic range (SFDR) can be achieved. With shorter clock pulses, both sampling rate and SFDR can be improved in future design.     

Implementation of a low power 16-bit radix-4 pipelined SRT divider using a modified Split-Path Data Driven Dynamic Logic (SPDL) structure

In this paper a 16-bit radix-4 pipelined divider implemented in a modified version of SPD³L family structure (SPCD³L: Split-Path Clock-Data driven Dynamic Logic) is presented. Through the modification, the clock signal is also used to pre-charge some critical parts of the circuit. Performance of the circuit is evaluated at different simulation corners. The results show that, compared with Domino structure, the proposed circuit has lower power consumption and higher speed. Latency of the divider is equal to 10 half clock cycles. The design is simulated using HSPICE in a 1.8-V TSMC_180 nm CMOS process.     

Power efficient asynchronous multiplexer for X-ray sensors in medical imaging analog front-end electronics

This paper presents a new power efficient asynchronous multiplexer (MUX) for application in analog front-end electronics (AFE) used in X-ray medical imaging systems. Contrary to typical synchronous MUXes that have to be controlled by a clock, this circuit features a simple structure, as the clock is not required. The circuit dissipates power only while detecting the active signals and then automatically turns back to the power down mode. Medical imaging systems usually consist of several dozen to even several hundreds of channels that operate asynchronously. The proposed MUX enables an unambiguous choice of the active channel. In case of two or more channels that become active at the same time the MUX serializes the reading out data from particular channels. This characteristic leads to 100% effectiveness in data processing and no impulses’ loss. The proposed MUX together with an experimental readout ASIC has been implemented in the CMOS 0.18 μm process and occupies 1100 μm²/channel area. It works properly in a wide range of the voltage supply in between 0.8 and 1.8 V. Energy consumed during the detection of one active channel is below 1 pJ, while the detection time is about 1 ns.     

Ultra low power phase detector and phase-locked loop designs and their application as a receiver

In this paper, we present a new low power down-conversion mixer design with single RF and LO input topology which consumes 48 μW power. Detailed analysis of the mixer has been provided. Using the presented mixer as a phase-detector, a low power phase-locked loop (PLL) has been designed and fabricated. A PLL based receiver architecture has been developed and analyzed. The circuit has been fabricated through 0.13 μm CMOS technology. Dissipating 0.26 mW from a 1.2 V supply, the fabricated PLL can track signals between 1.62 and 2.49 GHz. For receiver applications, the energy per bit of the receiver is only 0.26 nJ making it attractive for low power applications including wireless sensor networks.     

RF Band‐Pass Sampling Frontend for Multiband Access CR/SDR Receiver

Radio frequency (RF) subsampling can be used by radio receivers to directly down‐convert and digitize RF signals. A goal of a cognitive radio/software defined ratio (CR/SDR) receiver design is to place the analog‐to‐digital converter (ADC) as near the antenna as possible. Based on this, a band‐pass sampling (BPS) frontend for CR/SDR is proposed and verified. We present a receiver architecture based second‐order BPS and signal processing techniques for a digital RF frontend. This paper is focused on the benefits of the second‐order BPS architecture in spectrum sensing over a wide frequency band range and in multiband receiving without modification of the RF hardware. Methods to manipulate the spectra are described, and reconstruction filter designs are provided. On the basis of this concept, second‐order BPS frontends for CR/SDR systems are designed and verified using a hardware platform.     

一种应用于流水线ADC采样保持电路的设计

介绍了一种应用于12位、10MS/s流水线模数转换器前端的高性能采样保持（SH）电路的设计。该电路采用全差分电容翻转型结构及下极板采样技术,有效地减少噪声、功耗及电荷注入误差。采用一种改进的栅源电压恒定的自举开关,极大地减小电路的非线性失真。运算放大器为增益增强型折叠式共源共栅结构,能得到较高的带宽和直流增益。该采样保...     

软件无线电跳频电台接收机射频前端设计

基于软件无线电的基本要求和发展趋势,提出了一种应用在软件无线电跳频电台中接收机射频前端电路结构,分析了接收机射频前端的总体设计方案,包括前端各部分增益的分配、动态范围的分配、噪声系数及灵敏度的计算,讨论了对器件选择的考虑.实际测试结果表明,该射频前端性能指标满足设计要求.     

High-speed, burst-mode, packet-capable optical receiver andinstantaneous clock recovery for optical bus operation

This paper describes an enhanced performance version of a high-speed burst-mode compatible optical receiver and its application to 622-Mb/s optical bus operation in conjunction with an instantaneous clock recovery scheme. The receiver is fabricated in a 12 GHz f_t silicon bipolar technology and consists of a differential transimpedance amplifier with an auto-threshold level controller and a high-speed quantizer. Using an InGaAs avalanche photodiode, the typical burst mode sensitivity is around -34 dBm (10^-9 BER) at bit rates up to 1.5 Gb/s with a dynamic range of 26 db for both pseudorandom and burst signals. The results using a laser beam modulated by a high-speed external modulator indicate that the receiver can be operated at bit rates higher than 2 Gb/s. With a worst-case self-resetting time <50 ns for the threshold control circuit, the receiver is usable for optical packet communication where data signals with varying optical power are employed. This receiver was demonstrated in a 622-Mb/s optical bus application where the clock signal was recovered from the packet data signal using a novel high-speed CMOS instantaneous clock recovery IC     

A dual mode UHF EPC Gen 2 RFID tag in 0.18 μm CMOS

A dual mode UHF RFID transponder in 0.18 μm CMOS conforming to the EPC Gen 2 standard is presented. Low voltage design of the analog and digital blocks enables the chip to operate with a 1 V regulated voltage and thus to reduce the power consumption. The novel dual mode architecture enables the chip to work in passive and battery-assisted modes controlled by the reader. A custom Gen 2 based command switches the operation mode of the circuit. By using a special clock calibration method the chip operates from 1.2 to 5 MHz clock frequency. Several low power techniques are employed to reduce the power consumption of the chip which is essential in passive RFID tags. Measurement results show that the chip consumes 12 μW at 1 V supply voltage when it communicates with the reader. The chip is fabricated in 0.18 μm standard CMOS technology and occupies 0.95 mm² die area.     

Design of a digital FM demodulator based on a 2nd-order all-digital phase-locked loop

Software-defined radio (SDR) is a revolution in radio design due to the ability to create radios that can self-adapt on the fly. In SDR devices, all of the signal processing is implemented in the digital domain, mainly on DSP blocks or by DSP software. By simply downloading a new program, a SDR device is able to interoperate with different wireless protocols, incorporate new services, and upgrade to new standards. Therefore, massively parallel signal processing at higher frequencies are needed to implement a realistic SDR. Thus, FPGAs have been used extensively for implementing essential functions in SDR architectures at lower frequencies. In this paper, we explore the design of a digital FM receiver using the approach of an All-Digital Phase Locked-Loop (ADPLL). The circuit is designed in VHDL, then synthesized and simulated using LeonardoSpectrum Level 3 and ModelSim SE 6, respectively. It operates at a frequency up to 150 MHz and occupies the area of roughly 15 K logic gates.     

Low-power wake-up receiver with subthreshold CMOS circuits for wireless sensor networks

We developed a wake-up receiver comprised of subthreshold CMOS circuits. The proposed receiver includes an envelope detector, a high-gain baseband amplifier, a clock and data recovery (CDR) circuit, and a wake-up signal recognition circuit. The drain nonlinearity in the subthreshold region effectively detects the baseband signal with a microwave carrier. The offset cancellation method with a biasing circuit operated by the subthreshold produces a high gain of more than 100 dB for the baseband amplifier. A pulse-width modulation (PWM) CDR drastically reduces the power consumption of the receiver. A 2.4-GHz detector, a high-gain amplifier and a PWM clock recovery circuit were designed and fabricated with 0.18-μm CMOS process with one poly and six metal layers. The fabricated detector and high-gain amplifier achieved a sensitivity of ?47.2 dBm while consuming only 6.8 μW from a 1.5 V supply. The fabricated clock recovery circuit operated successfully up to 500 kbps.     

A 1.33 μW 10-bit 200KS/s SAR ADC with a tri-level based capacitor switching procedure

A 10-bit successive approximation register (SAR) analog-to-digital converter (ADC) using an energy-efficient tri-level based capacitor switching procedure is presented. The proposed switching procedure achieves 97.66% less switching energy when compared to the conventional method. The number of unit capacitors is reduced by a factor of 4 over that of conventional architecture as well. To make the power consumption of the comparator scale down with respect to the comparison rate, the fully dynamic comparator is used. Moreover, the dynamic logic circuit is implemented to further reduce the power of digital circuits. The ADC is implemented in a 0.18 μm 1P6M CMOS technology. At 1.0-V power supply and 200KS/s, the ADC achieves an SNDR of 60.54 dB and consumes 1.33 μW, resulting in a figure-of-merit (FOM) of 7.7 fJ/conversion-step. The ADC core occupies an active area of only 230×400 µm².