High-Gain N-Face AlGaN Solar-Blind Avalanche Photodiodes Using a Heterostructure as Separate Absorption and Multiplication Regions

It is well known that Ⅲ-nitride semiconductors can generate the magnitude of MV/cm polarization electric field which is comparable with their ionization electric fields. To take full advantage of the polarization electric field, we design an N-face AlGaN solar-blind avalanche photodiode(APD) with an Al_(0.45)Ga_(0.55)N/Al_(0.3)Ga_(0.7)N heterostructure as separate absorption and multiplication(SAM) regions. The simulation results show that the N-face APDs are more beneficial to improving the avalanche gain and reducing the avalanche breakdown voltage compared with the Ga-face APDs due to the effect of the polarization electric field. Furthermore, the Al_(0.45)Ga_(0.55)N/Al_(0.3)Ga_(0.7)N heterostructure SAM regions used in APDs instead of homogeneous Al_(0.45)Ga_(0.55)N SAM structure can increase significantly avalanche gain because of the increased hole ionization coefficient by using the relatively low Al-content AlGaN in the multiplication region. Meanwhile, a quarter-wave AlGaN/AIN distributed Bragg reflector structure at the bottom of the device is designed to remain a solar-blind characteristic of the heterostructure SAM-APDs.

High-Gain Array Antenna Based on Composite Right/Left-Handed Transmission Line

In this paper a metamaterial-inspired antenna with high gain and good directivity is designed. Based on the concept of composite right/left-handed transmission line (CRLH-TL), the proposed antenna is realized based on three leakage wave unit cell and a left handed circular ring slot incorporated on the surface. The maximum achievable gain at the resonant frequency of 5.6GHz is 6.933 dBi, and the return loss at 5.6 GHz can be –20 db. This proposed design has a simple structure and a compact dimension of 35 mm*40 mm*1 mm, which is suitable for particular wireless communication application such as WiFi and WLAN.

Fault diagnosis based on high-gain observer with an update law for a class of nonlinear systems

In this paper,by using the well-known high-gain observer design,an update law for the gain and an adaptive estimation of parameters,a new method of fault diagnosis for a class of nonlinear systems is presented.Without resort to any transformation for the parameters,the estimation errors of the states and the parameters are guaranteed to be globally exponentially convergent by a persistent excitation condition.Compared to the existing results,it can be applied to nonlinear systems with nonlinear terms admitting an incremental rate depending on the measured output.A case study further verifies the validity of the proposed research.

High-Gain Approach Based Full-Order Observers for Linear Systems with Unknown Inputs

In this paper, a full-order observer which can be fully decoupled from the unknown inputs as the conventional full-order observer does is designed by using auxiliary outputs, but the requirement of the matching condition is removed. The procedure of calculating the parameter matrices of the full-order observer is also presented. Compared with the existing auxiliary outputs based sliding-mode observers, the designed observer has a simpler design procedure, which is systematic and does not involve solving linear matrix inequalities. The simulation results show that the proposed method is effective.

STUDY ON THE WIDE-BAND AND HIGH-GAIN MICROSTRIP ANTENNA ELEMENT

A novel three layers microstrip antenna element that has the advantages of wideband and high-gain is proposed. The eigenvalue equation and the frequency characteristic formulas of the input Voltage Stand Wave Ratio ( VSWR ) are obtained by using the spectral domain method and equivalent circuit method, respectively. With the aid of the numerical results, a C-band microstrip antenna element with bandwidth of 16% (VSWR【1.5) or 25% (VSWR【2) and gain of 10.2-11.3 dB is developed, which are much larger than the bandwidth of 5-6% and the gain of 6-7 dB of the common microstrip antenna element.

High-gain planar TEM horn antenna fed by balanced microstrip line

A printed TEM horn antenna with high gain fed by balanced microstrip line is proposed. The radiation part of the antenna consists of two symmetrical triangular metal slice branches printed on the FR-4 substrate with 15 mm thickness. The two branches are fed by balanced microstrip line. The antenna is simulated by software CST MICROWAVE STUDIO and the equivalent adopted dipole model is proposed to describe the radiation characteristic of the antenna. The simulation results indicate that the frequency range is from 164 GHz to 5 GHz with reflection coefficient less than -6 dB, and the typical gain value is 8 dB in the operating bandwidth. In order to improve antenna gain without influencing the bandwidth, the length of the dielectric slab should be extended appropriately in the main radiation direction. By extending the length of the dielectric slab appropriately in the main radiation direction, the antenna gain can be improved significantly without the influence on the bandwidth. Besides, a metal disc loaded in the radiation direction makes the gain in band be more stable. The prototype has been fabricated and measured in microwave anechoic chamber which is coincident with the simulation results. This antenna can be widely applied in the UWB field.

一种交叉倍压型高增益DC/DC变换器

针对光伏发电、燃料电池发电等领域对高增益直流变换器的需求,以两相交错并联升压变换器为研究对象,由2个含有电感的倍压单元组合设计出实现电压提升的交叉倍压结构,据此提出了一种新颖的交叉倍压型高增益DC/DC变换器。该变换器可实现(3n+4)/(1-d)倍的高电压增益(1∶n为耦合电感匝数比,d为变换器占空比),且具有电路器件的低电压应力特性。对于漏感引起的开关管电压尖峰问题,引入了钳位电容构成释放漏感能量通道,同时提升了输出电压。介绍了新型交叉倍压型高增益变换器的拓扑结构,分析了变换器各模态的工作过程,推导了电压增益、输入电流纹波及各器件电压应力等稳态特性,并搭建样机进行实验研究,验证了该直流变换技术方案的可行性和先进性。

用于微波无线输能的高增益柔性天线研究

为克服传统有线供能方式的接入不便问题,提出了一种用于5.8 GHz微波无线输能(MWPT)高增益柔性天线。天线以聚酰亚胺(PI)为基底,采用广义迭代设计方法得到3层圆环结构,并选用共面波导(CPW)方式馈电。此外,为提高天线增益,在天线背面加载空气层和柔性反射板,并对天线性能进行了测试。测量结果显示:该天线在频率5.8 GHz处的峰值增益为9.51 dBi;当天线弯曲在曲率半径为85,60,45 mm时,增益始终保持在8.89 dBi以上,S_(11)幅值始终小于-10 dB。最后,通过微波无线输能实验测得该天线最大能量捕获效率可达71.3%,在弯曲状态下也能保持59%以上的捕获效率。该天线的高增益、高能量捕获效率以及稳定性证明了其在微波无线输能中具有潜在的应用价值。

一种低电流纹波高增益软开关直流变换器

提出了一种应用于新能源发电系统的低电流纹波高增益软开关直流变换器。在传统交错Boost变换器基础上,该变换器通过引入耦合电感和二极管、电容升压单元提高电压增益,耦合电感在整个开关周期过程中都传递能量,提高了磁芯利用率。输入侧工作在交错模式,两相电感电流纹波可以相互抵消,从而获得较低的输入电流纹波。由于耦合电感自身漏感的存在,减轻了整流二极管反向恢复问题,同时采用有源钳位电路回收利用漏感能量,实现了所有开关管零电压软开关,抑制了开关管关断电压尖峰,提高了变换器转换效率。详细分析了变换器的工作原理、电路特性以及软开关实现方法。最后,搭建了一台200 W的试验样机验证了理论分析的正确性。

基于SEPIC的新型高增益DC-DC变换器及衍生拓扑分析

针对光伏并网系统中单开关升压变换器(如SEPIC、Boost、准Z源、二次型)电压增益低和半导体器件电压应力大的问题,提出1种基于SEPIC的外部升压型高增益DC-DC变换器。首先对所提变换器在电感电流连续导通模式和断续导通模式下的工作原理和稳态特性进行详细分析,并与其他新型拓扑进行性能对比。在此基础上,给出了基于外部升压网络的衍生拓扑。最后,通过搭建1台400 V/200 W的实验样机证明了理论分析的准确性。所提变换器利用阻抗网络和开关电容单元构成的外部升压网络提升了SEPIC变换器的电压增益,并改善了半导体器件电压应力大的缺点。

超表面宽带天线的仿真与设计

仿真设计了一款基于超表面的宽带贴片天线,通过在矩形辐射贴片上刻蚀“工”字型缝隙展宽了天线的带宽,在不改变天线尺寸和工作频段的基础上,距离天线介质基板为H的正上方加载了5×5正方形单元结构组成的单层超表面,改善了天线的阻抗匹配,提高了天线的增益。仿真结果显示,该天线的工作频段为4.7~7.9 GHz,带宽为3.2 GHz,实现了宽带化,在工作频段内辐射方向稳定,最大增益达到了6.83 dBi。

新型高增益耦合电感二次型变换器

将开关-耦合电感单元引入二次型变换器,采用一个耦合电感和两个独立电感,在开关管关断时,电感为电容充电;导通时,利用电容为负载供电。与传统变换器相比,所提出的变换器采用更少的器件,能得到高电压增益效果与低占空比。采用了降低电压应力的电容,二极管和半导体开关,开关管应力更低。提出了稳态和比较性能分析,制作了一台140W实验平台,给出实验数据与结论,验证了理论分析的正确性。

雷达抗前门耦合攻击防护能力对比分析

针对雷达遭受高功率微波武器攻击时容易损伤的问题,理论分析了雷达最远防护边界和雷达天线增益及接收机限幅器能力的关系,从空间滤波的角度,对比了反射面雷达和有源相控阵雷达抗前门耦合攻击的能力。分析得出只有高功率微波武器处于反射面雷达天线的主瓣范围附近时,对其前门耦合攻击效果才强于有源相控阵雷达;反之,要弱于有源相控阵雷达。由于反射面天线雷达主波束很窄,造成攻击的时机很短,所以反射面雷达在面对高功率微波武器时防护能力更强。

恒功率负载条件下Boost变换器复合控制技术

直流微电网中大量接入变换器驱动负载,因其输入阻抗往往表现出负阻抗特性,易与供电单元产生交互作用,极大地衰减了系统阻尼,激发了系统振荡。为此,针对直流微电网源侧Boost变换器,此处提出一种无源控制(PBC)和扩张高增益状态观测器(EHGSO)相结合的复合控制方法,首先建立了考虑多因素影响的Boost变换器模型,然后结合无源理论及观测器理论设计了复合控制器,确保了系统在不同负载工况下的全局稳定性,并在实验室内建立了含两台120W原理样机及一台恒功率负载的实验微电网系统,通过实验验证了所提方法的有效性和正确性。

高轻载效率少功率器件的可模块化扩展ZVS高增益变换器

提出一种高轻载效率且少功率器件的可模块化扩展零电压开关高增益Boost变换器。该变换器可以通过增加升压模块数量n,极大地提高变换器的升压能力;具有2个开关管和n+1个二极管,且各功率管承受相同的电压应力,均为[(n+1)U_(in)+U_(o)]/(n+2);输入电感工作在连续导通模式,其余电感工作在双向导通模式,且反向峰值电流之和大于输入电感电流的谷值,从而实现所有功率管的软开关。所提变换器采用柔性开关频率控制策略,即根据输入电压和负载大小适当地调整开关频率,使电感电流脉动量维持在合适的范围内,既确保实现功率管的软开关,又具有较小的通态损耗,因此在整个负载范围内均具有较高的运行效率。以一个扩展模块为例,对所提变换器的工作原理、稳态特性、软开关条件、控制方法进行深入分析,并通过一台250 W的样机实验验证了理论分析的正确性。

弱光触发下GaAs光电导开关的载流子输运和热失效机制

弱光触发下高倍增砷化镓光电导开关(GaAs PCSS)内以丝状电流为表现形式的载流子输运机制对其瞬态工作特性和寿命研究有重要意义。该文基于有限元方法构建了GaAs PCSS的物理模型,结合丝状电流的生热机制对1.5μJ弱光触发下开关的瞬态输出电流和晶格温度进行了仿真分析,考察了偏置电场对GaAs PCSS输出特性的影响。通过不同时刻开关内部的瞬态电场、电子浓度和晶格温度等方面研究了高倍增模式下GaAs PCSS的光生载流子输运过程和损伤机理。结果表明,高密度丝状电流的存在伴随于高场畴的产生和发展。开关内部电场越高,负微分效应引起的载流子聚束现象越明显,相应的电子浓度和晶格温度值也越高;在浓度达1017 cm^(-3)数量级的等离子体通道中,阳极附近电场强度和晶格温度最大值分别为220 kV/cm和821.92 K。

一种无桥高增益单级LED驱动电路及其混合控制策略

中小功率的LED驱动电源中,传统两级LED驱动电源存在体积大、成本高以及传统Boost PFC电路在低压输入时导通损耗大等问题。为此提出一种由无桥二次型Boost PFC电路和DC-DC LLC电路集成的无桥高增益单级LED驱动电路,实现了高电压增益、功率开关器件软开关、一套控制电路和高电路转换效率。针对单级电路在电网输入电压变化引起直流母线电压变动范围大等问题,设计一种适用于所提电路的APWM-PFM混合控制策略,并对混合控制原理和控制过程进行详细分析。最后设计一台200 W的实验样机,在输入电压80~120 Vrms范围内,占空比最大为0.5,最大电压增益为6.7,直流母线电压基于网侧特性和LLC电路特性设计在700 V以内,样机的功率因数值均高于0.990,THD均低于15%。在满载条件下,110 Vrms输入时,样机效率为93.20%,相比于传统无桥PFC,电压增益提高了2.21倍,实现了高电压增益和软开关,有效提升了在低压输入条件下的电路转换效率。仿真和实验结果验证了所提出电路和控制方法的有效性。

燃料电池-锂电池混合供电系统的无源控制策略及参数设计方法

多源混合供电技术可有效地利用不同供电单元性能,在电气化交通系统中得到广泛应用。然而,随着越来越多的恒功率特性及强脉动特性负载接入供电系统,系统的稳定性难以得到保证。针对传统线性控制方法难以保证系统的大信号稳定性,而现有非线性控制的研究仍缺乏兼顾稳定性和动态性能的控制参数设计方法的问题,该文对燃料电池-锂电池混合供电系统设计基于无源控制和扩张高增益状态观测器的复合控制方法,并对控制器和观测器参数进行了设计,有效地保证了系统的动静态性能。在实验室搭建一套额定功率为3 kW的燃料电池-锂电池混合供电系统实验平台进行测试,结果验证了所提控制策略和参数设计方法的有效性和正确性。

双频一体化超宽带探地雷达天线设计

针对目前探地雷达(Ground Penetrating Radar,GPR)产品单一频段工作所导致的耗时费力、效率低等缺点,文中设计实现了一种中心频率分别为400 MHz、1000 MHz且带宽为200~1500 MHz的双频一体化复合阵列天线,并将其应用于超宽带(Ultra-Wide Band,UWB)探地雷达系统中。阵列天线包含3个中心频率为400 MHz和6个中心频率为1000 MHz的蝶形天线,具备双频段同时探测能力,可实现一条测线含两种不同频段的探测结果,克服了传统探地雷达不同频率的重复探测问题,增强了探地雷达系统的实用性。所提出的双频一体化探地雷达天线具有超宽带、高增益、波束窄等特点,其相对带宽为153%,整个带宽内最高实现17.6 dBi峰值增益,半功率波束宽度最窄为7.6°,为高分辨率、高效率探地雷达应用提供了一种新的天线方案。

宽增益高效谐振型直流变换器技术

直流变换器广泛应用于电动汽车充电系统与光伏发电系统,如何适应输入/输出电压大范围变化,实现直流变换器的宽增益和高传输效率为学术界和工业界所关注。其中,LLC、LLC_LC、LLCLC谐振变换器虽具有高功率密度、低电磁干扰等特性,但存在磁元件与谐振网络参数设计难度大,造成变换器输出不稳定等不足,难以满足实际应用的要求。为此,提出了宽增益高效谐振型直流变换器技术。首先总结了谐振型直流变换器的基本原理,围绕其拓扑结构及调制策略的国内外研究进展,重点就宽增益与高效谐振型直流变换器应用需求进行阐述。然后分析了LLC_LC、LLCLC多模式PWM倍压整流变换器拓扑及调制策略。最后结合仿真与实验验证结果,证明了该宽增益高效谐振型直流变换器拓扑及其调制策略的有效性,最高可实现输出电压范围为1~6.2,转换效率达96.1%,具有较宽广的应用前景。