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低驱动电压k波段电容耦合式RFMEMS开关的设计 总被引:3,自引:0,他引:3
设计了一种低驱动电压的电容耦合式射频微机械(RF MEMS)开关.RF MEMS开关采用共面波导传输线,双电极驱动,悬空金属膜采用弹性折叠梁支撑.使用MEMS CAD软件CoventorWare、微波CAD软件HFSS,分别仿真了开关的力学性能和电磁性能,仿真结果表明:开关的驱动电压为2.5V,满足低驱动电压的设计目标;开关开态的插入损耗约为0.23 dB@20 GHz,关态的隔离度约为18.1 dB@20 GHz.最后给出了这种RF MEMS开关的微制造工艺. 相似文献
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基于0.2μm SOI RF工艺平台,设计了串联支路、并联支路、单刀单掷、单刀双掷等电路结构,分析研究了单级宽度、级联数目、偏置电阻、偏置电压等设计参数对射频开关小信号特性的影响。通过实验数据,讨论各参数对射频开关小信号特性,主要包括射频开关的插入损耗和隔离度的影响,为射频开关设计提供参考。 相似文献
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在电容式RF MEMS开关的动态工作过程中,会有电磁波产生.根据开关膜桥的动态运动模型,把开关工作分成了四个过程,并通过麦克斯韦方程建立了各个过程中产生的电磁波模型,最后通过单元面叠加的方法验证了这一模型.在开关电容充电和膜桥下拉过程中,开关都是产生了电磁波脉冲.尤其是在充电阶段,电磁波峰值为105 A/m的量级,持续时间为3.15×10-8μs.而在开关电容放电过程中,产生的电磁波是时谐波,其频率为23.4 GHz(落在RF信号的频率范围内了).这就提醒了设计者们要增加特殊的滤波电路来过滤掉RF信号中噪声.此外,辐射的电磁波同样对开关周围的电路和器件有影响,这需要进一步的研究. 相似文献
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一种低驱动电压的SP4T RF MEMS开关 总被引:1,自引:0,他引:1
设计并制备了一种低电压的静电驱动接触式单刀四掷(SP4T)RFMEMS开关。单元开关采用以低应力氮氧化硅(SiON)作为桥膜的双端固定桥式结构,并利用附着的金层形成接触结构。整个SP4T开关包括与50Ω特征阻抗相匹配的共面波导,1个输入端,4个输出端,4个静电驱动的侧拉桥,以及4个驱动引出区(pad)。测试数据表明,开关驱动电压18.8V;插入损耗S21<0.26dB@DC-3GHz,S31<0.46dB@DC-3GHz;隔离度S21>69.5dB@DC-3GHz,S31>69.2dB@DC-3GHz。结果显示,此开关的隔离度在所有输出端有很好的一致性,插损在DC-3GHz的频段内均较小,非常适合低频使用。 相似文献
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设计实现了一款高耐压单刀单掷天线调谐开关,用于Sub-6 GHz的天线孔径调谐、阻抗调谐以及宽带开关.设计采用串-并联和体区自适应偏置结构,兼顾插入损耗和隔离度;此外基于传统的堆叠结构进行改进,通过设计各级晶体管的尺寸不均匀,极大程度地提高了开关并联支路承受电压的能力;通过采用两级偏置网络,减小了栅端和体端的泄露从而削... 相似文献
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Ramesh Ramadoss Simone Lee Y. C. Lee Victor M. Bright K. C. Gupta 《国际射频与微波计算机辅助工程杂志》2007,17(4):387-397
In this article, an RF MEMS capacitive series switch fabricated using printed circuit processing techniques is discussed. Design, modeling, fabrication, and characterization of the CPW series switch are presented. An example CPW series capacitive switch with insertion loss less than 0.5 dB in the frequency range of 13–18 GHz and isolation better than 10 dB up to 18 GHz is discussed. The switch provides a minimum insertion loss of about 0.1 dB at the self‐resonance frequency of 16 GHz and a maximum isolation of about 42 dB at 1 GHz. © 2007 Wiley Periodicals, Inc. Int J RF and Microwave CAE, 2007. 相似文献
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The design, modeling, and optimization of a novel, thermally actuated CMOS‐MEMS switch are presented in this article. This series capacitive MEMS switch solves the substrate loss and down‐state capacitance degradation problems commonly plaguing MEMS switches. The switch uses finger structure for capacitive coupling. The vertical bending characteristic of bimorph cantilever beams under different temperatures is utilized to turn the switch on and off. A set of electrical, mechanical, and thermal models is established, and cross‐domain electro‐thermo‐mechanical simulations are performed to optimize the design parameters of the switch. The fabrication of the switch is completely CMOS‐process compatible. The design is fabricated using the AMI 0.6 μm CMOS process and a maskless reactive‐ion etching process. The measured results show the insertion loss and isolation are 1.67 and 33 dB, respectively, at 5.4 GHz, and 0.36 and 23 dB at 10 GHz. The actuation voltage is 25 V and the power consumption is 480 mW. This switch has a vast number of applications in the RF/microwave field, such as configurable voltage control oscillators, filters, and configurable matching networks. © 2009 Wiley Periodicals, Inc. Int J RF and Microwave CAE, 2009. 相似文献
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A novel DMTL capacitive switch with electrostatic actuation metal–air–metal (MAM) capacitors is presented. The top board of MAM capacitors will be pulled down together with the switch bridge. It has higher isolation in down-state than DMTL capacitive switch and has lower insert loss and higher self-actuation RF power comparing with MEMS shunt capacitive switch. Two of the novel DMTL capacitive switches are designed for high isolation and high self-actuation RF power, respectively. The calculated result shows that both of the two novel switches have lower insert loss than the MEMS shunt capacitive switch. The self-actuation RF power of them are 4 and 2.4 times that of MEMS shunt capacitive switch, respectively, at the cost of ?6.23 and ?3.54?dB reduction in isolation (30?GHz). 相似文献
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Ramadoss R. Lee S. Lee Y. C. Bright V. M. Gupta K. C. 《Journal of microelectromechanical systems》2006,15(6):1595-1604
This paper presents radio frequency microelectromechanical systems (RF-MEMS) capacitive switches fabricated using printed circuit processing techniques. The key feature of this approach is the use of most commonly used flexible circuit film, Kapton E polyimide film, as the movable switch membrane. The physical dimensions of these switches are in the mesoscale range. For example, electrode area of a typical capacitive shunt switch on coplanar waveguide (CPW) is 2 mmtimes1 mm, respectively. A CPW shunt switch with insertion loss <0.4 dB and isolation >10 dB in the frequency range of 8 to 30 GHz is reported. K-band, Ku-band, and X-band high-isolation CPW shunt switches designed by inductive compensation of the switch down-position capacitance are also presented. Inductance compensation has been implemented by introducing inductive step-in-width junctions in the MEMS switch electrode. The K-band switch provides a maximum isolation value of 54 dB at 18 GHz. For the K-band switch, the insertion loss is less than 0.3-0.4 dB in the frequency range of 1-30 GHz and the isolation values are better than 20 dB in the frequency range of 12 to 30 GHz. The Ku-band switch provides a maximum isolation of 46 dB at 16.5 GHz. For the Ku-band switch, the insertion loss is less than 0.4-0.45 dB in the frequency range of 1-30 GHz and the isolation is greater than 20 dB in the frequency range of 12 to 22 GHz. The X-band switch provides a maximum isolation value of 32 dB at 10.6 GHz. The insertion loss is less than 0.25-0.3 dB in the frequency range of 1-18 GHz and the isolation is better than 20 dB in the frequency range of 8.5 to 13.5 GHz for the X-band switch. The measured typical pull-down voltage is in the range of 100-120 for this type of switches. These switches are uniquely suitable for monolithic integration with printed circuits and antennas on organic laminate substrates 相似文献
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Microsystem Technologies - In this paper, a novel RF MEMS shunt capacitive switch with application in the Ka frequency band is proposed. The spring design and the step structure added to the beam... 相似文献