低成本宽带90°巴伦的研究与设计

提出并设计了一种低成本宽带90°巴伦电路结构,电路由宽带耦合威尔金森功分器、弱耦合线和扇形阶跃阻抗谐振器级联的宽带90°移相器组成。利用电磁仿真软件HFSS对工作在中心频率为1.65GHz 的微带电路进行建模和仿真。采用PCB工艺制作了电路实物并利用矢量网络分析仪进行测试;对比得出仿真与测试结果十分吻合,该巴伦实测相对带宽大于117.0% (0.65～2.58GHz),带内各端口回波损耗好于12.6 dB,输出端口隔离度大于13.1dB,带内插入损耗小于0.5 dB,相位误差小于90°±7.6°。与现有的结构和设计相比,该巴伦不仅具有更大的工作频带和单层电路布局,而且具有容易加工、成本低的优点。     

Passive broadband millimetre-wave uniplanar MMIC balun

A new uniplanar monolithic microwave integrated circuit (MMIC) balun using lumped circuits is presented. The proposed planar balun consists of a wideband Wilkinson power divider and a broadband 180° phase shifter using novel series and parallel LC reflective terminating circuits. To demonstrate the design methodology, a 24?44 GHz MMIC balun was realised as a 1.4 mm _{GaAs chip. The measured return losses for the unbalanced and balanced ports are better than 212, 210 and 27 dB, respectively. The measured amplitude and phase imbalance between the two output ports are less than 0.5 dB and 7°, respectively, and maximum insertion loss is 5 dB.}     

A Dual-Band Balun Using Partially Coupled Stepped-Impedance Coupled-Line Resonators

In this paper, a recently proposed dual-band resonator structure consisting of a pair of partially coupled stepped-impedance lines is theoretically investigated. The new resonator configuration contains a number of attractive features for dual-band applications. A new type of dual-band balun that is constructed using a pair of such coupled stepped-impedance resonators is fully studied both theoretically and experimentally. Design equations for the balun are derived by an even- and odd-mode approach. A prototype of such dual-band balun operating at 900 MHz and 1.8 GHz is designed, fabricated, and measured. Good agreement between the designed and measured responses proves the concept of the dual-band balun and validates the design formulas.     

A Balun-BPF Using a Dual Mode Ring Resonator

In this letter, a Balun-bandpass filter (BPF) is proposed by using a dual-mode ring resonator. The Balun-BPF is not a simply combined or integrated component of a BPF and a Balun but a single BPF with the balun function. We obtained the proper balanced outputs and two-pole BPF characteristic by symmetrically placing the output ports at lambda/2 distance from each other on the dual-mode ring resonator. The fabricated Balun-BPF has a bandwidth of 40 MHz and an insertion loss of 2.4 dB at a center frequency of 2.45 GHz. The differences between the two outputs are 180-184deg in phase and within 1dB in magnitude. The measured frequency responses agree well with simulated ones.     

LTCC-MLC chip-type balun realised by LC resonance method

A multilayer ceramic balun designed in the 2.4 GHz ISM band frequency is presented. A multilayer structure to realise the low temperature co-fired ceramic (LTCC) balun is proposed. This type of balun comprises an embedded capacitor and meandered or spiral coupled lines. The use of an LC resonator can shrink the length of a coupled transmission line and can be designed very easily to have various balanced output port impedances. Excellent performance of phase and amplitude balance may be achieved by the proposed method. Measured results of the LTCC-multilayer ceramic (MLC) balun match well with the computer simulation     

A novel planar dual balun for Doubly Balanced star mixer

A novel planar dual balun for doubly balanced star mixer is presented. The balun consists of two identical Marchand baluns using coupled microstrip lines. It shows the amplitude imbalance within 1.2 dB and the phase imbalance within 180/spl plusmn/1.5/spl deg/ over 1.2 to 2.8 GHz. The star mixer using a pair of the suggested balun has the conversion loss about 6 dB in the band.     

Multiple stage uncompensated Marchand balun with 7:1 bandwidth ratio on double side PCB

Proposed is the design of a multiple stage uncompensated Marchand balun. A coplanar waveguide with a ground plane is used as the coupled line structure providing tight coupling by shielding the centre line from the ground. Wide bandwidth is achieved by the combination of a wideband impedance matching L-section and multiple stages of lambda/4 step transformers. Measurements indicate an approximate -20 dB return loss from 1 to 7.5 GHz, and less than 4deg phase imbalance from DC to 7.2 GHz.     

Surface acoustic wave characteristics of ZnO films grown on a polycrystalline 3C-SiC buffer layer

Zinc oxide (ZnO) thin films were deposited onto a polycrystalline (poly) 3C-SiC buffer layer for surface acoustic wave (SAW) applications using a magnetron sputtering system. Atomic force microscopy (AFM) and X-ray diffraction (XRD) showed that the ZnO grown on 3C-SiC/Si had a smooth surface, a dominant c-axis orientation and a lower residual stress in ZnO thin film compared to that grown directly onto Si substrate. In order to evaluate the SAW characteristics of ZnO films on a 3C-SiC buffer layer, the two-port SAW resonators, based on inter-digital transducer (IDT)/ZnO/3C-SiC/Si and IDT/ZnO/Si structures, were fabricated and measured within a temperature range of 25-135 °C. The resulting 3C-SiC buffer layer improved the insertion loss by approximately 7.3 dB within the SAW resonator and enhanced the temperature stability with TCF = −22 ppm/°C up to 135 °C in comparison to that of TCF = −45 ppm/°C within a temperature range of 25-115 °C of the ZnO/Si structure.     

无线收发前端小型化巴伦的研究

针对射频前端的小型化巴伦展开研究,在理论分析上,从变压器型巴伦的原理出发,将电磁场数值方法和微波网络理论相结合,将标准散射（S）参数和混合散射（S）参数相结合,提出了新颖的巴伦特性的理论研究方法;在实际应用上,利用高阻性硅基集成无源器件（Integrated Passive Device,IPD）技术,经过电磁仿真和优化,设计和制作了基于交叉耦合平面螺旋线结构的小型化变压器型巴伦.巴伦的尺寸仅为1.85 mm×1.6 mm,10 dB单端回波损耗带宽为2.07~2.80 GHz,频带内插入损耗小于0.98 dB,差分对幅度失配小于0.43 dB,相位失配小于3.8°,仿真结果得到了实验验证.     

Multiband BPF with wide upper stop band using asymmetrically positioned stub loaded open loop resonators

In this paper, asymmetrically positioned stub loaded open loop resonators with pseudo interdigital coupling are used to design compact multiband planar bandpass filters. The first design pertains to a dualband BPF that operates at 3.5 GHz and 5.7 GHz. The parameters like position of stub, which quantifies the asymmetry, and length of stub are further optimised using real coded genetic algorithm to evolve a triband BPF. The evolutionary design procedure is supported with an example of triband BPF having passband at 3.5 GHz, 5.5 GHz and 6.8 GHz, respectively. The transmission line models for both filters are developed as well as fabricated prototypes are realised and tested. There is a good agreement between the measured and simulated results. The measured insertion loss at first and second band centred around 3.5 GHz and 5.7 GHz of the dual band BPF are 1.5 dB and 1.25 dB, respectively. For the triband BPF the values are 1.24 dB, 1.6 dB and 1.8 dB at 3.5, 5.5 and 6.8 GHz, respectively. The dualband design covers the WiMAX and IEEE 802.11a bands where as the triband design also covers the 6.8 GHz RFID frequency.     

Design and fabrication of 94 GHz MMIC single balanced resistive mixer without IF balun

In this paper, a 94 GHz microwave monolithic integrated circuit (MMIC) single balanced resistive mixer affording high LO-to-RF isolation was designed without an IF balun. The single balanced resistive mixer, which does not require an external IF balun, was designed using a 0.1 μm InGaAs/InAlAs/GaAs metamorphic high electron mobility transistor (HEMT). The designed MMIC single balanced resistive mixer was fabricated using the 0.1 μm MHEMT MMIC process. From the measurement, conversion loss of the single balanced resistive mixer was 14.7 dB at an LO power of 10 dBm. The P_1 dB (1 dB compression point) values of the input and output were 10 dBm and −5.3 dBm, respectively. The LO-to-RF isolation of the single balanced resistive mixer was −35.2 dB at 94.03 GHz. The single balanced resistive mixer in this work provided high LO-to-RF isolation without an IF balun.     

Ultra Wideband Bandpass Filter Using Embedded Stepped Impedance Resonators on Multilayer Liquid Crystal Polymer Substrate

This letter proposes an ultra wideband (UWB) bandpass filter (BPF) based on embedded stepped impedance resonators (SIRs). In this study, broad side coupled patches and high impedance microstrip lines are adopted as quasi-lumped elements for realizing the coupling between adjacent SIRs, which are used to suppress stopband harmonic response. An eight-pole UWB BPF is developed from lump-element bandpass prototype and verified by full-wave simulation. The proposed filter is fabricated using multilayer liquid crystal polymer (LCP) process and measured using vector network analyzer. Good agreement between simulated and measured response is observed. The measurement results show that the fabricated filter has a low insertion loss of 0.18 dB at center frequency 6.05 GHz, an ultra wide fractional bandwidth of 127.3% and excellent stopband rejection level higher than 32.01 dB from 10.9 to 18.0 GHz.      

Low-Loss and Broadband Asymmetric Broadside-Coupled Balun for Mixer Design in 0.18-$mu{hbox {m}}$ CMOS Technology

This study presents an asymmetric broadside coupled balun with low-loss broadband characteristics for mixer designs. The correlation between balun impedance and a 3D multilayer CMOS structure are discussed and analyzed. Two asymmetric multilayer meander coupled lines are adopted to implement the baluns. Three balanced mixers that comprise three miniature asymmetric broadside coupled Marchand baluns are implemented to demonstrate the applicability to MOS technology. Both a single and dual balun occupy an area of only 0.06 mm². The balun achieves a measured bandwidth of over 120%, an insertion loss of better than 4.1 dB (3 dB for an ideal balun) at the center frequency, an amplitude imbalance of less than 1 dB, and a phase imbalance of less than 5deg from 10 to 60 GHz. The first demonstrated circuit is a Ku-band mixer, which is implemented with a miniaturized balun to reduce the chip area by 80%. This 17-GHz mixer yields a conversion loss of better than 6.8 dB with a chip size of 0.24 mm². The second circuit is a 15-60-GHz broadband single-balanced mixer, which achieves a conversion loss of better than 15 dB and occupies a chip area of 0.24 mm². A three-conductor miniaturized dual balun is then developed for use in the third mixer. This star mixer incorporates two miniature dual baluns to achieve a conversion loss of better than 15 dB from 27 to 54 GHz, and occupies a chip area of 0.34 mm².     

Three-solenoid windings transformer baluns on CMOS-grade silicon substrate

Several novel on-chip three-solenoid windings transformer baluns were designed and fabricated using post-CMOS compatible concave-suspending micromachining process, which are applicable in the design of radio-frequency integrated circuits (RFICs). A generalized lumped-element circuit model (LECM) is developed to accurately characterize input and output characteristics of these three-port signal conversion devices, with the partial element equivalent circuit (PEEC) method implemented for capturing skin and proximity effects in them. Satisfactory agreements are obtained among the measured, simulated, and modeled S-parameters of the fabricated baluns over the frequency range of 500 MHz-10 GHz. Measurements show that these baluns exhibit less than 1 dB amplitude imbalance and less than 1° phase imbalance up to 6 GHz. Their power transfer and impedance matching are also examined in details.     

High linearity technique for ultra-wideband low noise amplifier in 0.18 μm CMOS technology

A linearization technique for ultra-wideband low noise amplifier (UWB LNA) has been designed and fabricated in standard 0.18 μm CMOS technology. The proposed technique exploits the complementary characteristics of NMOS and PMOS to improve the linearity performance. A two-stage UWB LNA is optimized to achieve high linearity over the 3.1-10.6 GHz range. The first stage adopts inverter topology with resistive feedback to provide high linearity and wideband input matching, whereas the second stage is a cascode amplifier with series and shunt inductive peaking techniques to extend the bandwidth and achieve high gain simultaneously. The proposed UWB LNA exhibits a measured flat gain of 15 dB within the entire band, a minimum noise figure of 3.5 dB, and an IIP3 of 6.4 dBm while consuming 8 mA from a 1.8 V power supply. The total chip area is 0.39 mm², including all pads. The measured input return loss is kept below −11 dB, and the output return loss is −8 dB, from 3.1 to 10.6 GHz.     

15?60 GHz asymmetric broadside coupled balun in 0.18 lm CMOS technology

A 15-60 GHz asymmetric broadside coupled balun fabricated in the standard TSMC 0.18 mum CMOS process is demonstrated. Using the broadside tight coupling technique, the balun is achieved with wide bandwidth and low insertion loss and utilises the inherent three-dimensional multilayer structure in CMOS technology. The balun achieves bandwidth of over 120%, the minimum insertion loss is better than 1.1 dB, amplitude difference is less than 1 dB and phase difference is less than 5deg (15-60 GHz). The occupied chip area is only 0.06 mm².     

Compact CMOS Baluns for the 4–10 GHz Band Applications

In this paper, we proposed two baluns, a compact balun and a compact balun with imbalance compensation; both are implemented using the one-poly six-metal (1P6M) 0.18 μ m CMOS process. Both baluns have good performance from 4 to 10 GHz, and consume less silicon area due to their compact structure. The self-resonant frequency is increased by properly selecting metal layer for each spiral winding. The compact balun has a magnitude imbalance of 1 dB and a phase imbalance of 4.6 degree from 4 to 10 GHz. With the imbalance compensation, the balun has a magnitude imbalance of 0.6 dB and a phase imbalance of 1.1 degree from 4–10 GHz. Much better results have been achieved for the compact balun with our proposed imbalance compensation method. Both baluns can be used to perform both single-ended/differential and differential/single-ended conversions in different configurations.     

On-chip micromachined solenoid balun for RF-SOC applications

A transformer balun is fabricated by using a post-CMOS compatible MEMS process. The novel concave-suspended solenoid balun can be integrated with radio-frequency system-on-chips (RF-SOCs). In the frequency range 0.5-10 GHz, the tested balun shows less than 0.7 dB amplitude imbalance and less than 1.5deg phase imbalance. After tuning, the transformer balun can match between a 100 Omega single-ended port and two 50 Omega differential ports. At the two differential ports, insertion losses of -1.5 and -0.8 dB are obtained at 5-GHz centre frequency, more than 40% bandwidth of S ₁₁ is achieved.     

小型LTCC巴伦的设计

提出了一种基于Marchand巴伦结构的小型化半集总参数巴伦.通过加载端电容和谐振电容减小巴伦耦合线电长度,LTCC多层布线的实现方式进一步减小了巴伦的实际体积.采用奇偶模分析方法对该结构进行分析,给出了设计曲线,采用A6——M材料仿真并制作出尺寸为2.5 mm×2.0 mm×1.0 mm的巴伦.测得在2.7～2.9 ...     

Compact microstrip lowpass filter with very sharp roll-off using meandered line resonators

In this paper, a new compact size microstrip lowpass filter (LPF) with a very sharp roll-off is presented to apply in the modern wireless networks. The proposed LPF is designed using the series main resonators with meandered lines based on inductor-capacitor (LC) equivalent circuit analysis. The main goal is to achieve maximum-sharp roll-off by maintaining a wide stopband bandwidth and high return loss (RL). The main resonator of the proposed filter is consisted of two meandered line hairpin resonators (MLHR), and a meandered line T-shaped resonator (MLTR). The designed suppressor is composed of two coupled radial stubs to create a wide stopband. Low return loss in the passband, which has been created by the main resonator, is resolved by the suppressor structure with high return loss. The measured results show a ??3 dB cut-off frequency of 1.93 GHz. The very sharp transition band starts at 1.93 to 1.97 GHz (from ??3 to ??20 dB). The stopband is from 1.97 to 19.9 GHz (with the suppression level of ??20 dB). Also, the total size of the proposed LPF is only 13.3?×?10.1 mm².