A 5 GHz 7.2 dB NF low power direct conversion receiver front-end with balun LNA

A 5GHz low power direct conversion receiver radio frequency front-end with balun LNA is presented. A hybrid common gate and common source structure balun LNA is adopted,and the capacitive cross-coupling technique is used to reduce the noise contribution of the common source transistor.To obtain low l/f noise and high linearity,a current mode passive mixer is preferred and realized.A current mode switching scheme can switch between high and low gain modes,and meanwhile it can not only perform good linearity but save power consumption at low gain mode.The front-end chip is manufactured on a 0.13-μm CMOS process and occupies an active chip area of 1.2 mm~2.It achieves 35 dB conversion gain across 4.9-5.1 GHz,a noise figure of 7.2 dB and an IIP3 of -16.8 dBm,while consuming 28.4 mA from a 1.2 V power supply at high gain mode.Its conversion gain is 13 dB with an IIP3 of 5.2 dBm and consumes 21.5 mA at low gain mode.     

采用balun低噪声放大器的5GHz 7.2-dB NF低功耗直接转换接收机前端电路

A 5GHz low power direct conversion receiver radio frequency front-end with balun LNA is presented. A hybrid common gate and common source structure balun LNA is adopted, and the capacitive cross-coupling technique is used to reduce the noise contribution of the common source transistor. To obtain low 1/f noise and high linearity, a current mode passive mixer is preferred and realized. A current mode switching scheme can switch between high and low gain modes, and meanwhile it can not only perform good linearity but save power consumption at low gain mode. The front-end chip is manufactured on a 0.13-μm CMOS process and occupies an active chip area of 1.2 mm². It achieves 35 dB conversion gain across 4.9-5.1 GHz, a noise figure of 7.2 dB and an IIP3 of -16.8 dBm, while consuming 28.4 mA from a 1.2 V power supply at high gain mode. Its conversion gain is 13 dB with an IIP3 of 5.2 dBm and consumes 21.5 mA at low gain mode.     

用于ZigBee的2.4GHz低功耗双增益低噪声放大器

This paper presents a fully differential dual gain low noise amplifier（DGLNA） for low power 2.45-GHz ZigBee/IEEE 802.15.4 applications.The effect of input parasitics on the inductively degenerated cascode LNA is analyzed.Circuit design details within the guidelines of the analysis are presented.The chip was implemented in SMIC 0.18-μm 1P6M RF/mixed signal CMOS process.The DGLNA achieves a maximum gain of 8 dB and a minimum gain of 1 dB with good input return loss.In high gain mode, the measured noise figure（NF） is 2.3-3 dB in the whole 2.45-GHz ISM band.The measured 1-dB compression point, IIP3 and IIP2 is-9, 1 and 33 dBm, respectively.The DGLNA consumes 2 mA of current from a 1.8 V power supply.     

Low power high gain gain-controlled LNA and mixer for GNSS receivers Wei Binbin(魏斌斌)1, Jiang Jinguang(江金光)1,2,3*

A low power high gain gain-controlled LNA ＋ mixer for GNSS receivers is reported. The high gain LNA is realized with a current source load. Its gain-controlled ability is achieved using a programmable bias circuit. Taking advantage of the high gain LNA, a high noise figure passive mixer is adopted. With the passive mixer, low power consumption and high voltage gain of the LNA ＋ mixer are achieved. To fully investigate the performance of this circuit, comparisons between a conventional LNA ＋ mixer, a previous low power LNA ＋ mixer, and the proposed LNA ＋ mixer are presented. The circuit is implemented in 0.18 #m mixed-signal CMOS technology. A 3.8 dB noise figure, an overall 45 dB converge gain and a 10 dB controlled gain range of the two stages are measured. The chip occupies 0.24 mm2 and consumes 2 mA current under 1.8 V supply.     

A low power high gain gain-controlled LNAC＋mixer for GNSS receivers

A low power high gain gain-controlled LNAC+mixer for GNSS receivers is reported. The high gain LNA is realized with a current source load.Its gain-controlled ability is achieved using a programmable bias circuit. Taking advantage of the high gain LNA, a high noise figure passive mixer is adopted. With the passive mixer, low power consumption and high voltage gain of the LNACmixer are achieved. To fully investigate the performance of this circuit, comparisons between a conventional LNAC+mixer, a previous low power LNAC+mixer, and the proposed LNAC+mixer are presented. The circuit is implemented in 0.18 m mixed-signal CMOS technology. A 3.8 dB noise figure, an overall 45 dB converge gain and a 10 dB controlled gain range of the two stages are measured. The chip occupies 0.24 mm2and consumes 2 mA current under 1.8 V supply.     

A wideband CMOS VGLNA based on single-to-differential stage and resistive attenuator for TV tuners

A wideband CMOS variable gain low noise amplifier(VGLNA) based on a single-to-differential(S2D) stage and resistive attenuator is presented for TV tuner applications.Detailed analysis of input matching,noise figure(NF) and linearity for S2D is given.A highly linear passive resistive attenuator is proposed to provide 6 dB attenuation and input matching for each gain stage.The chip was fabricated by a 0.18μm 1P6M CMOS process, and the measurements show that the VGLNA covers a gain range over 36.4 dB and achieves a maximum gain of 21.3 dB,a minimum NF of 3.0 dB,an IIP3 of 0.9 dBm and an IIP2 of 26.3 dBm at high gain mode with a power consumption less than 10 mA from a 1.8 V supply.     

A 2.4GHz CMOS Monolithic Transceiver Front-End for IEEE 802.11b Wireless LAN Applications

A 2.4GHz CMOS monolithic transceiver front-end for IEEE 802.11b wireless LAN applications is presented.The receiver and transmitter are both of superheterodyne structure for good system performance.The front-end consists of five blocks:low noise amplifier,down-converter,up-converter, pre-amplifier,and LO buffer.Their input/output impedance are all on-chip matched to 50Ω except the down-converter which has open-drain outputs.The transceiver RF front-end has been implemented in a 0.18μm CMOS process.When the LNA and the down-converter are directly connected,the measured noise figure is 5.2dB,the measured available power gain 12.5dB,the input 1dB compression point -18dBm,and the third-order input intercept point -7dBm.The receiver front-end draws 13.6mA currents from the 1.8V power supply.When the up-converter and pre-amplifier are directly connected,the measured noise figure is 12.4dB,the power gain is 23.8dB,the output 1dB compression point is 15dBm,and the third-order output intercept point is 16dBm.The transmitter consumes 276mA current from the 1.8V power supply.     

Design and optimization of a 2.4 GHz RF front-end with an on-chip balun

A 2.4 GHz low-power,low-noise and highly linear receiver front-end with a low noise amplifier(LNA) and balun optimization is presented.Direct conversion architecture is employed for this front-end.The on-chip balun is designed for single-to-differential conversion between the LNA and the down-conversion mixer,and is optimized for the best noise performance of the front-end.The circuit is implemented with 0.35μm SiGe BiCMOS technology.The front-end has three gain steps for maximization of the input dynamic range.The overall maximum gain is about 36 dB.The double-sideband noise figure is 3.8 dB in high gain mode and the input referred third-order intercept point is 12.5 dBm in low gain mode.The down-conversion mixer has a tunable parallel R-C load at the output and an emitter follower is used as the output stage for testing purposes.The total front-end dissipation is 33 mW under a 2.85 V supply and occupies a 0.66 mm~2 die size.     

An RF front-end with an automatic gain control technique for a U/V band CMMB receiver

This paper presents a fully integrated RF front-end with an automatic gain control(AGC) scheme and a digitally controlled radio frequency varied gain amplifier(RFVGA) for a U/V band China Mobile Multimedia Broadcasting(CMMB) direct conversion receiver.The RFVGA provides a gain range of 50 dB with a 1.6 dB step. The adopted AGC strategy could improve immunity to adjacent channel signal,which is of importance for CMMB application.The front-end,composed of a low noise amplifier(LNA),an RFVGA,a mixer and AGC,achieves an input referred 3rd order intercept point(IIP3) of 4.9 dBm with the LNA in low gain mode and the RFVGA in medium gain mode,and a less than 4 dB double side band noise figure with both the LNA and the RFVGA in high gain mode.The proposed RF front-end is fabricated in a 0.35μm SiGe BiCMOS technology and consumes 25.6 mA from a 3.0 V power supply.     

A 3.1-4.8 GHz transmitter with a high frequency divider in 0.18μm CMOS for OFDM-UWB

A fully integrated low power RF transmitter for a WiMedia 3.1-4.8 GHz multiband orthogonal frequency division multiplexing ultra-wideband system is presented. With a separate transconductance stage, the quadrature up-conversion modulator achieves high linearity with low supply voltage. The co-design of different resonant frequencies of the modulator and the differential to single （D2S） converter ensures in-band gain flatness. By means of a series inductor peaking technique, the D2S converter obtains 9 dB more gain without extra power consumption. A divided-by-2 divider is used for carrier signal generation. The measurement results show an output power between -10.7 and -3.1 dBm with 7.6 dB control range, an OIP3 up to 12 dBm, a sideband rejection of 35 dBc and a carrier rejection of 30 dBc. The ESD protected chip is fabricated in the Jazz 0.18μm RF CMOS process with an area of 1.74 mm^2 and only consumes 32 mA current （at 1.8 V） including the test associated parts.     

Traffic Characteristics Based Dynamic Radio Resource Management in Heterogeneous Wireless Networks

The traffic with tidal phenomenon in Heterogeneous Wireless Networks （HWNs） has radically increased the complexity of radio resource management and its performance analysis. In this paper, a Simplified Dynamic Hierarchy Resource Management （SDHRM） algorithm exploiting the resources dynami- cally and intelligently is proposed with the consideration of tidal traffic. In network-level resource allocation, the proposed algorithm first adopts wavelet neural network to forecast the traffic of each sub-area and then allocates the resources to those sub-areas to maximise the network utility. In connection-level net- work selection, based on the above resource allocation and the pre-defined QoS require- ment, three typical network selection policies are provided to assign traffic flow to the most appropriate network. Furthermore, based on multidimensional Markov model, we analyse the performance of SDHRM in HWNs with heavy tailed traffic. Numerical results show that our theoretical values coincide with the simulation results and the SDHRM can im- prove the resource utilization.     

Location Verification Systems in Emerging Wireless Networks

As location-based techniques and applications have become ubiquitous in emerging wireless networks, the verification of location information has become more important. In recent years, there has been an explosion of activity related to lo- cation-verification techniques in wireless networks. In particular, there has been a specific focus on intelligent transport systems because of the mission-critical nature of vehicle location verification. In this paper, we review recent research on wireless location verification related to vehicular networks. We focus on location verification systems that rely on for- mal mathematical classification frameworks and show how many systems are either partially or fully encompassed by such frameworks.     

An Introduction to Transmit Antenna Selection in MIMO Wiretap Channels

This paper is a survey of transmit antenna selection-a low-complexity, energy-efficient method for improving physical layer security in multiple-input multiple-output wiretap channels. With this method, a single antenna out of multiple antennas is selected at the transmitter. We review a general analytical framework for analyzing exact and asymptotic secrecy of transmit antenna selection with receive maximal ratio combining, selection combining, or generalized selection combining. The analytical results prove that secrecy is significantly improved when the number of transmit antennas increases.     

Ranking Potential Reply-Providers in Community Question Answering System

Community Question Answering （CQA） websites have greatly facilitated users＇ lives, with an increasing number of people seeking help and exchanging ideas on the Internet. This newlymerged community features two characteristics： social relations and an ask-reply mechanism. As users＇ behaviours and social statuses play a more important role in CQA services than traditional answer retrieving websites, researchers＇ concerns have shifted from the need to passively find existing answers to actively seeking potential reply providers that may give answers in the near future. We analyse datasets derived from an online CQA system named ＂Quora＂, and observed that compared with traditional question answering services, users tend to contribute replies rather than questions for help in the CQA system. Inspired by the findings, we seek ways to evaluate the users＇ ability to offer prompt and reliable help, taking into account activity, authority and social reputation char- acteristics. We propose a hybrid method that is based on a Question-User network and social network using optimised PageRank algorithm. Experimental results show the efficiency of the proposed method for ranking potential answer-providers.     

一个全差分可编程的多通道神经信号记录芯片

A multi-channel,fully differential programmable chip for neural recording application is presented.The integrated circuit incorporates eight neural recording amplifiers with tunable bandwidth and gain,eight 4thorder Bessel switch capacitor filters,an 8-to-1 analog time-division multiplexer,a fully differential successive approximation register analog-to-digital converter(SAR ADC),and a serial peripheral interface for communication.The neural recording amplifier presents a programmable gain from 53 dB to 68 dB,a tunable low cut-off frequency from 0.1 Hz to 300 Hz,and 3.77 μVrms input-referred noise over a 5 kHz bandwidth.The SAR ADC digitizes signals at maximum sampling rate of 20 kS/s per channel and achieves an ENOB of 7.4.The integrated circuit is designed and fabricated in 0.18-μm CMOS mix-signal process.We successfully performed a multi-channel in-vivo recording experiment from a rat cortex using the neural recording chip.     

Double junction photodiode for X-ray CMOS sensor IC

A CMOS compatible P＋/Nwell/Psub double junction photodiode pixel was proposed, which can effi- ciently detect fluorescence from CsI（T1） scintillation in an X-ray sensor. Photoelectric and spectral responses of P＋/Nwell, NweE1/Psub and P＋/Nwell/Psub photodiodes were analyzed and modeled. Simulation results show P＋/Nweu/Psub photodiode has larger photocurrent than P＋/Nwetl photodiode and Nweu/Psub photodiode, and its spectral response is more in accordance with CsI（T1） fluorescence spectrum. Improved P＋/Nweu/Psub photodiode detecting CsI（T1） fluorescence was designed in CSMC 0.5 #m CMOS process, CTIA （capacitive transimpedance amplifier） architecture was used to readout photocurrent signal. CMOS X-ray sensor IC prototype contains 8 × 8 pixel array and pixel pitch is 100 × 100 μm2. Testing results show the dark current of the improved P＋/Nwell/Psub photodiode （6.5 pA） is less than that of P＋/Nwell and P＋/Nwell/Psub photodiodes （13 pA and 11 pA respectively）. The sen- sitivity of P＋/Nwell/Psub photodiode is about 20 pA/lux under white LED. The spectrum response of P＋/Nwell/Psub photodiode ranges from 400 nm to 800 nm with a peak at 532 nm, which is in accordance with the fluorescence spectrum of Csl（T1） in an indirect X-ray sensor. Preliminary testing results show the sensitivity of X-ray sensor IC under Cu target X-ray is about 0.21 V.m^2/W or 5097e-/pixel @ 8.05 keV considering the pixel size, integration time and average energy of X-ray photons.     

A power-efficient 12-bit analog-to-digital converter with a novel constant-resistance CMOS input sampling switch

Apower-efficient 12-bit40-MS/spipelineanalog-to-digitalconverter（ADC）implementedina0.13 μm CMOS technology is presented. A novel CMOS bootstrapping switch, which offers a constant on-resistance over the entire input signal range, is used at the sample-and-hold front-end to enhance the dynamic performance of the pipelined ADC. By implementing with 2.5-bit-per-stage and a simplified amplifier sharing architecture between two successive pipeline stages, a very competitive power consumption and small die area can be achieved. Meanwhile, the substrate-biasing-effect attenuated T-type switches are introduced to reduce the crosstalk between the two op- amp sharing successive stages. Moreover, a two-stage gain boosted recycling folded cascode （RFC） amplifier with hybrid frequency compensation is developed to further reduce the power consumption and maintain the ADC＇s performance simultaneously. The measured results imply that the ADC achieves a spurious-free dynamic range （SFDR） of 75.7 dB and a signal-to-noise-plus-distortion ratio （SNDR） of 62.74 dB with a 4.3 MHz input signal; the SNDR maintains over 58.25 dB for input signals up to 19.3MHz. The measured differential nonlinearity （DNL） and integral nonlinearity （INL） are -0.43 to ＋0.48 LSB and -1.62 to ＋ 1.89 LSB respectively. The prototype ADC consumes 28.4 mW under a 1.2-V nominal power supply and 40 MHz sampling rate, transferring to a figure- of-merit （FOM） of 0.63 pJ per conversion-step.     

一种应用于GPS接收机的高线性度SiGe HBT低噪声放大器

A high linearity 1.575 GHz SiGe：HBT low noise amplifier （LNA） for global positioning system applications is described. The bipolar cascoded with an MOSFET LNA was fabricated in a commercial 0.18 μm SiGe BiCMOS process, A resistor bias feed circuit with a feedback resistor was designed for the LNA input transistor to improve its intermodulation and compression performance. The packaged chip tested on board has displayed a noise figure of 1. I 1 dB, a power gain of 18 dB, an output 1 dB compression point of ＋7.8 dBm and an input third-order intercept point of ＋1.8 dBm. The chip occupies a 500 × 560μm^2 area and consumes 3.6 mA from a 2.85 V power supply.