Fully-integrated ultra-wide band LNA in 0.18μm CMOS technology for 3-10 GHz applications

The paper presents a fully integrated ultra-wide band(UWB)low noise amplifier(LNA)for 3-10 GHz applications.It employs self-biased resistive-feedback and current-reused technique to achieve wide input matching and low power characteristics.An improved biased architecture is adopted in the second stage to attain a better gain-compensation performance.The design is verified with TSMC standard 1 P6 M 0.18μm RF CMOS process.The measurement results show that the parasitic problem of the transistors at high frequencies is solved.A high and flat S21 of 9.7±1.5 dB and the lowest NF 3.5 dB are achieved in the desired frequency band.The power consumption is only 7.5 mA under 1.6 V supply.The proposed LNA achieves broadband flat gain,low noise,and high linearity performance simultaneously,allowing it to be used in 3-10 GHz UWB applications.

一种复杂环境下UWB测距误差预测方法

针对复杂室内环境中,多径干扰和视距遮挡影响室内定位精度的问题,提出一种复杂环境下UWB测距误差的预测方法:根据超宽带(UWB)室内定位方法抗干扰能力强、定位精度高的特点,从理论上分析影响超宽带信号测距精度的因素;然后通过模型量化分析每种影响因素对测距误差的影响程度,改进以往通过信道脉冲响应特征分析单一的视距遮挡参数来提高定位精度的补偿算法;最后从数据挖掘和机器学习的角度出发,将多径效应、视距遮挡、标签与基站的距离、标签移动速度、标签与基站天线俯仰角以及气象因素(温度、湿度、压强)等对测距精度造成影响的重要因素作为特征进行分类和归类,并使用梯度提升决策树模型对数据集进行训练和预测。实验结果表明,该模型可以根据当前状态下的组合特征值估计出测距误差值,将当前预测的误差值补偿到测量值上,可以有效提高超宽带室内定位的精度。

A Novel Ultra-Wideband Monopole Antenna with Band-Stop Characteristic

In this letter, a simple monopole antenna with variable band-notched characteristic for ultra wide band (UWB) function is proposed. Two L-shaped quarter-waveguide resonators coupled to the ground plane with two shorting tracks at the sides of the antenna are used to generate stop-band performance around 5.5 GHz (WLAN). The proposed antenna is fabricated on the substrate FR4 (relative permittivity of 4.7) and has a compact size of 16 × 28.5 × 1.6 mm. The designed antenna has a good impedance matching in 3.1 - 11.4 GHz frequency range with VSWR < 2, except the band 5 - 5.85 GHz.

Optimization of band-notched UWB antenna using micro-genetic algorithm combined with FDTD

The micro-genetic algorithm (MGA) optimization combined with the finite-difference time-domain (FDTD) method is applied to design a band-notched ultra wide-band (UWB) antenna. A U-type slot on a stepped U-type UWB monopole is used to obtain the band-notched characteristic for 5 GHz wireless local area network (WLAN) band. The measured results show that voltage standing wave ration (VSWR) less than 2 covers 3.1-10.6 GHz operating band and VSWR more than 2 is within 5.150-5.825 GHz notched one with the highest value of 5.6. Agreement among the calculated, HFSS simulated and measured results validates the effiectiveness of this MGA-FDTD method, which is efficient for UWB antennas design.

Compact Bluetooth/UWB Antenna with Multi-Band Notched Characteristics

A small-sized, low-profile, and planar dual band antenna for Bluetooth (2.4 - 2.484 GHz) and ultra-wideband (UWB) (3.1 - 10.6 GHz) with multi-band notched antennas is presented. Two antennas A and B with different types of slots are used to obtain tri-band notched characteristic. In antenna A notched bands, 5 - 6 GHz for WLAN, and 3.3 - 4 GHz for WiMAX, are achieved using a U-slot in ground structure and in the radiating patch. In antenna B two notched bands at 3.3 - 4 GHz, for WiMAX and 7.2 GHz for C-band satellite communication systems are achieved by using a U-slot in ground structure and a H-shaped slot in the radiating patch. The radiation characteristics of the two antennas are calculated using a commercial EM simulator based on Finite Element Method (FEM) and the Finite Integration Technique (FIT). The two antennas show acceptable gain flatness with stable omnidirectional radiation patterns across the integrated Bluetooth and UWB bands.

Evaluation of System Performance of Ultra-Wide Band Jointing in MC Signaling in Correlated Environments

The evaluation of System Performance of UWB (ultra-wide band) jointing in MC (multi-carrier) signaling in correlated environments is presented in the report. The correlated Nakagami-m statistical distribution for the multipath fading model is assumed in this scenario. In fact to establish the model for analyzing in this article is using MC-CDMA (multi-carrier code-division multiple-access) system characterization combined with a UWB scheme. The average BER (bit error rate) is calculated and compared to a special case of previously published results. Studied results from this paper can be implied to approve the system performance for a UWB system combined with a MC-CDMA wireless communication system. It is worth noting that the Nakagami-m distributed fading parameter significantly dominates UWB system performance when it cooperates with MC signaling under a fading environment. Finally, it is worthy of noting that when the SNR (signal-to-noise ratio) at system’s receiver reaches a preset high threshold value, the parameter of power decay ratio effect could be not included.

Designing a Carbon Nanotube Field-Effect Transistor with High Transition Frequency for Ultra-Wideband Application

Theoretical calculations predict transition frequencies in the terahertz range for the field-effect transistors based on carbon nanotubes, and this shows their suitability for being used in high frequency applications. In this paper, we have designed a field-effect transistor based on carbon nanotube with high transition frequency suitable for ultra-wide band applications. We did this by optimizing nanotube diameter, gate insulator thickness and dielectric constant. As a result, we achieved the transition frequency about 7.45 THz. The environment of open source software FETToy is used to simulate the device. Also a suitable model for calculating the transition frequency is presented.

A Novel Bow-Tie Antenna with Triple Band-Notched Characteristics for UWB Applications

This paper presents the design of a compact bow-tie antenna with triple band notched characteristics for UWB applications. The proposed antenna can operate from 3.1 to 10.6 GHz with VSWR - 8.4 GHz) centered at 8.1 GHz, the CSRR2 rejects the WLAN band (5.15 - 5.85 GHz) centered at 5.6 GHz, and the CSRR3 rejects the band (4.10 - 4.47 GHz) centered at 4.32 GHz. Compared with recent design, this antenna is more compact, and presents better simulation results of its characteristics. Our newly designed antenna is a potential candidate for application in UWB communication systems.

New band-notched UWB antenna

A simple and compact ultra wideband （UWB） printed monopole antenna with band-notched performance is proposed in this paper. The antenna is partially grounded so that the Q value is depressed and the impedance bandwidth is broadened. A small strip bar is loaded on each arm of the similar U-shaped radiator. The impedance bandwidth of the antenna overlap with IEEE 802.11a is rejected consequently. The geometry parameters of the antenna are investigated and optimized with HFSS. The measured bandwidth of the proposed antenna occupies about 7.89 GHz covering from 3.05 GHz to 10.94 GHz with expected notched band from 4.96 GHz to 5.98 GHz. A quasi-omnidirectional and quasi-symmetrical radiation pattern in the whole band is also obtained. As a result, a UWB wireless communication system can be simplified with the band-notched UWB antenna presented.

Miniaturized Planar Ultra-Wideband Bandpass Filter with Notched Band

This paper presents a planar ultra-wideband (UWB) bandpass filter with sharp out-of-band rejection performance. The filter is formed by a folded multiple-mode resonator to realize high performance in an operation band from 3.3 to 10 GHz with a very compact size of 20 mm × 20 mm × 0.5 mm. An extra notched band centered at 5.8 GHz is further accomplished by etching a Hilbert fractal curve slit on the filter without the necessity of readjusting the geometrical parameters. The simulated and measured results are in good agreement.

A U-Shaped UWB Antenna with Band-Notched Performance

An ultra-wideband antenna with controllable band-notched is presented. Two semi-ellipses with different radiuses are subtracted to result in the main patch. By varying inner and outer radiuses, much more enhancement in bandwidth occurred. A U-shaped slot is used to make band-stop performance. Measured S11 is ≤-10 dB over 2.3 - 5 GHz and 6.1 - 15.1 GHz.

基于UWB定位技术的煤矿机械装备防碰撞系统研究

随着煤矿机械装备的广泛应用,机械装备的防碰撞已经成为煤炭行业重要的研究课题。文章主要研究了基于超宽带(Ultra Wide Band,UWB)定位技术的煤矿机械装备防碰撞系统,通过开发定位算法、防碰撞算法、数据处理与分析等功能模块,实现系统的实时监控与报警功能。实验表明,该系统能够有效避免机械装备之间发生碰撞,进而提升煤矿生产的安全性。

Triple Notched Band Characteristics UWB Antenna Using C-Shaped Slots and Slot-Type Capacitively-Loaded Loop (CLL)

Ultra wide bands antennas with notched bands characteristics have recently been considered for efficient communication between devices. In this paper, a compact ultra-wideband antenna (UWB) for UWB applications with triple bandnotched characteristics is presented. The proposed antenna consists of a square patch with four truncated corners and a partial ground plane with a rectangular slit. The operation bandwidth of the designed antenna is from 2.66 GHz to more than 13.5 GHz. Band-notched characteristics of antenna to reject the frequency band of 3.18 - 3.59 GHz and 4.70 - 5.88 GHz, is realized by inserting two C-shaped slots in the patch, the third band of 9.54 - 12.22 GHz is achieved by slottype capacitively-loaded loop (CLL) inserted in the patch near the feed line. Details of the proposed antenna design and simulated results are presented and discussed.

基于Taylor-Chan算法的改进UWB室内三维定位方法

[目的]针对室内三维空间环境复杂导致传统超宽带(ultra wide band,UWB)定位算法精度低、稳定性差的问题对UWB室内三维定位方法进行研究.[方法]在Chan和Taylor算法基础上,设计了一种基于距离误差筛选机制的Taylor-Chan定位算法.首先使用简化Taylor算法求解得到标签初定位结果,再结合初定位结果和测距信息根据所设计筛选函数剔除误差较大的基站数据,最后基于筛选得到的数据,使用Chan算法得到最终标签定位结果.[结果]在室内视距和非视距两种场景下进行仿真,Taylor-Chan算法相比于Chan和Taylor定位精度都有一定的提高,且测距误差越大的情况下,Taylor-Chan算法的定位效果越明显.[结论]仿真结果表明,对比现有方法,本文所提出的Taylor-Chan算法在室内三维空间的视距和非视距环境下都能有效改善定位精度.

改进抗差卡尔曼滤波的UWB定位模型

针对超宽带(UWB)技术已在室内定位、智能交通等领域广泛应用,但由于障碍物遮挡或其他原因,使得UWB测距值可能存在误差,从而大幅度降低UWB的定位精度和可靠性的问题,分析抗差卡尔曼滤波(RKF)在UWB定位中的特点,在此基础上,提出改进的RKF算法(RKF-SW)进行粗差检测,根据预测残差进行第一次样本异常值检验探测,采用1/4样本分位数进行第二次样本异常值探测。实验结果表明,与RKF算法相比,RKF-SW算法具有较强的异常值识别能力,能够提升UWB系统的定位精度,开阔场景下定位精度可提高约80.0%,遮挡物干扰情况下可提高约82.1%。

抗差Helmert方差分量估计在GPS/BDS/UWB融合定位中的应用

针对卫星信号受限环境下,全球定位系统(GPS)/北斗卫星导航系统(BDS)组合定位出现较大偏差的问题,引入超宽带(UWB)技术作为定位性能增强技术。GPS/BDS伪距测量值与UWB测距值作为原始观测值,提出了基于抗差赫尔默特(Helmert)方差分量估计的GPS/BDS/UWB融合定位方法,实现合理定权,抵御粗差影响。分别进行了静态实验和动态实验,结果表明:没有粗差情况下,GPS/BDS/UWB融合定位相对于GPS/BDS的定位精度在静态实验和动态实验中均有所提升;引入粗差后,定位结果可抵御粗差,精度提升较为明显。

基于WSN+UWB的室内人员定位系统设计

随着社会发展,家长对幼儿安全越来越重视,幼儿园环境安全与否直接关系到儿童的健康及生命。为保障园区内幼儿状况及安全,文章提出了一种室内人员定位系统设计,该系统在满足基本定位需求的同时,采用了超宽带(Ultra Wide Band,UWB)技术,具有穿透性强、抗干扰和功耗低等优势,其性能表现已超过蓝牙和Wi-Fi,并以UWB技术作为主要技术依据,将无线传感网络(Wireless Sensor Network,WSN)技术与UWB技术相结合,设计了一款智能化的人员看护及定位系统,测试结果证明了该系统设计可满足园区内人员监测及定位警报的需求。

DGPS与UWB混合精确无缝定位技术研究

差分全球定位系统(DGPS)是一种精确的定位系统,但在室内或有障碍物的情况下,其定位精度很低甚至不能进行定位。超宽带(UWB)定位系统在室内有很高的定位精度,但受其测量范围的影响,不适合室外定位。将DGPS和UWB结合定位,利用Kalman滤波器对UWB非视距误差(NLOS)进行消除,采用粒子滤波器对不同传感器进行数据融合,并使用GPRS通信模块进行无线数据传输。实验表明:该方法能够使系统整体定位精度提高19%,既能满足室内外无缝定位,又具有很高的定位精度。

时间平均改进的UWB精确定位算法

超宽带(UWB)技术在无线定位的应用上具有很大的优势.针对UWB定位算法在短距离时精度不高的问题,提出了时间平均的改进算法.仿真结果表明,采用不同的时间平均次数,改进算法可使定位精度由传统算法的1.1 m提高到0.2～0.6 m.

UWB MIMO生物雷达多静止人体目标成像方法研究

由于临近多静止人体目标之间存在较强的相互干扰,仅利用单通道生物雷达的距离像难以区分多个静止人体目标。为解决上述问题,该文利用超宽带多输入多输出(UWB MIMO)生物雷达获取多静止人体目标的2维高分辨图像,从空间上更好地分隔多静止人体目标,然后基于UWB MIMO图像的慢时间序列对人体生理信号进行增强,有效抑制人体目标间的相互干扰。实测数据结果证明该文所提方法能够获得相互靠近的多静止人体目标的高分辨图像,使后续的多静止人体目标高性能检测与定位成为可能。