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1.
李丁  王继安  李威 《微处理机》2005,26(2):14-17,20
本文采用基于硅基的:BiCMOS工艺设计制作了一款带宽为DC到2.6GHZ的低噪声、高增益MMIC放大器。该放大器为了实现从DC到2.6GHz的带宽,保证有足够的增益和理想的增益平坦度,采用了负反馈结构,两级级联,并选用了一种结构新颖的微波晶体管。该放大器具有功率增益高、频带较宽、噪声系数较小的特点。在仿真过程中其3dB带宽约3GHz,增益为26.6dB(1.5GHz时),1dB压缩点输出功率约为1dBm;样品的实测结果为3dB带宽约2.6GHz,增益为26dB(1.5GHz时),1dB压缩点输出功率约为1dBm。  相似文献   

2.
结合电阻并联反馈,利用PCSNIM流程设计了一个用于超宽带(UWB)系统的宽带LNA电路。电阻并联反馈降低了输入电路的Q值,使窄带LNA带宽增加,而对NF的影响很小。用TSMC0.18CMOS工艺进行仿真,结果表明,LNA在3.1-5.1GHz带宽范围内NF小于2.9dB。输入匹配优于-10.5dB,功率增益为12.9dB,带内波动仅为1dB。在1.8V电源电压下,核心电路功耗为7.5mW。  相似文献   

3.
周旭烨 《福建电脑》2008,24(10):155-155
本文介绍一种微型化2GHz微波放大模组,该放大模组通过对微型化的低噪声放大电路、高选择性滤波电路的设计。采用超微细微带薄膜工艺,制作在68×18×0.5mm陶瓷基片上,集成度高,体积小,适合作为无线通信接收电路。本模组在1.8—2.2GHz范围内,增益Gp≥41dB,噪声系数Nf≤0.9dB,带外抑制≥55dB.  相似文献   

4.
基于130 nm RF CMOS工艺,提出了一种可实现上/下双向变频功能的K波段有源混频器.当收发机工作于接收模式时,双向混频器执行下变频功能,将低噪放大器放大后的射频信号转换为中频信号;当收发机工作于发射模式时,双向混频器则实现上变频功能,将输入的基带信号转换为射频信号并输出至功率放大器.后仿真结果表明,在0 dBm的本振驱动下,混频器工作于上变频模式时的转换增益、噪声系数、输出1 dB压缩点在23~25 GHz范围内分别为-1.1~-0.4 dB、12.9~3.3 dB、-8.2 dBm@24 GHz;工作于下变频工作模式时的转换增益、噪声系数、输入1 dB压缩点在23~25 GHz范围内分别为2.4~3.4 dB、15.2~15.6 dB、-3.6 dBm@24 GHz.混频器芯片面积为0.6 mm2;在1.5V供电电压下,消耗功率12 mW.  相似文献   

5.
利用现代计算机数控机床(Computer Numerical Control,CNC)铣削技术实现了中心频率为140 GHz的矩形波导带通滤波器。基于电磁仿真软件HFSS对该滤波器进行了优化设计和容差分析。采用CNC铣削技术完成了该滤波器的加工制备。测试结果与仿真结果吻合良好,表明该滤波器具备优越的性能:其中心频率为140.2 GHz、3 dB相对带宽为10.1%,插入损耗小于0.5 dB,带内回波损耗优于25 dB,距中心频率±20 GHz处带外抑制大于30 dB。该结果进一步验证了利用CNC铣削技术加工140 GHz波段滤波器的可行性。  相似文献   

6.
本文介绍了一种具有片上巴伦的超宽带(UWB)3GHz~5GHz直接转换接收机。它由电容交叉耦合共栅极低噪声放大器(LNA)和改进型吉尔伯特混频器组成,采用SMIC RFCMOS技术。仿真结果表明,本文所设计的UWB接收机具有较好的输入匹配(〈-9dB)、3.9dB~5.5dB的噪声系数和19dB~25dB的功率转换增益。在1.2V供电情况下消耗22mA电流,并占用0.66×0.8mm2芯片面积(包括焊盘)。  相似文献   

7.
线性功率放大器是CDMA直放站的核心模块.本文设计的带自适应控制的线性功放,其功率增益G为48 0.8dB,1db压缩点输出功率≥37dBm,带内渡动≤0.8dB,互调失真IMD3≤-15dBm,IMD5≤-25dBm,输入输出端口驻波比VSWR≤1.3,增益步进衰减ATT范围为31dB,自动电平控制ALC范围为20dB,符合直放站的应用要求.  相似文献   

8.
雍家鹏  张树丹 《微计算机信息》2007,(35):273-275,294
本文设计了一种基于数字音频系统应用的低功耗2-1三阶级联1位△∑调制器。电路采用SMIC 0.25um数字CMOS工艺进行设计。仿真结果表明,当输入幅值为1.5V、频率为1KHz正弦波信号、采样率为3.2MHz时,该调制器的SNR和SNDR分别为104dB和96、2dB.而整个调制器的功耗仅为6.18mw。  相似文献   

9.
北斗卫星导航系统由我国自主研发,其研制目的是为了在日益严峻的世界环境下巩固我国的军事实力。北斗射频接收芯片是北斗卫星导航系统中整个地面端设备的核心,因此,关于射频接收机芯片的研发工作具有十分重要且实际的意义。文中在基于窄带低噪声放大器理论的基础上,采用TSMC0.18μmCMOS工艺设计了一种应用于北斗通信系统中的低噪声放大器。放大器采用改进的单转双电路结构,并通过缓冲级电路对差分信号的幅度和相位偏差进行了有效的校正。实验结果表明该电路在2.45GHz-2.55GHz频带内输入回波损耗小于-28dB,噪声系数小于1.1dB,功率增益大于15dB,电压增益高于32dB。  相似文献   

10.
提出了一种新型的三明治结构MEMS微波功率传感器结构,与传统传感器相比,新结构由于采用了垂直传热方式而具有较小的热损耗。在输入相同功率的情况下,模拟了热电堆的温度分布,三明治结构热电堆的温度高于传统结构,因此具有更高的灵敏度。同时模拟了两种结构的阻抗匹配特性,其差异不大,在1~6GHz的频率范围内,三明治结构的回波损耗小于-30dB;在6~20GHz的频率范围内,其回波损耗小于-20dB,显示了良好的匹配特性。  相似文献   

11.
In this article, a four‐way waveguide power divider is proposed for W‐band applications. The waveguide power divider employs an improved H‐plane T‐junction configuration. With the introduction of a metallic tetrahedral protrusion into the waveguide junction, good impedance matching can be achieved within a wide frequency range. First, a two‐way power divider is designed and analyzed, achieving almost identical amplitude and phase response at its two output ports. Then, other two same T‐junctions are cascaded, respectively, at the two output ports of the two‐way power divider to realize the proposed four‐way power divider. The four‐way power divider has been optimized, fabricated, and measured. The measurement results agree with the simulation ones reasonably, which demonstrates that the input return loss of the proposed four‐way power divider maintains above 14 dB across the entire W‐band with an insertion loss of less than 1.3 dB. Therefore, it could find wide applications in W‐band power splitting and combining modules.  相似文献   

12.
In this article, a broadband coplanar waveguide (CPW) to rectangular waveguide power divider using the dipole slot is proposed. The power divider consists of an input CPW port and two output rectangular waveguide ports. The CPW to rectangular waveguide power divider using the dipole slot has a return loss larger than 15 dB and an insertion loss equal to 3.08–3.27 dB in the whole X‐band (8.2–12.4 GHz). Furthermore, to broaden the bandwidth, the dipole slot is replaced by the bow‐tie slot. The CPW to rectangular waveguide power divider using the bow‐tie slot yields a return loss larger than 16 dB and an insertion loss equal to 3.05–3.29 dB from 8 to 13 GHz, which exceeds the X‐band. To verify our design, power dividers that use the dipole slot or the bow‐tie slot are fabricated and measured. The measurement results of both power dividers are in good agreement with the simulation results. © 2012 Wiley Periodicals, Inc. Int J RF and Microwave CAE, 2013.  相似文献   

13.
A micro coplanar Wilkinson power divider at X-band on GaAs substrate is presented in this paper. The proposed power divider introduces a size reduction method, and the length of the transmission line is reduced to λ/8 (at 10 GHz). Since the two segments of the two edge coupled quarter-wave asymmetric coplanar striplines (ACPSs) with finite-width ground plane are closed to each other, their characteristic parameters, such as characteristic impedance and attenuation coefficient, are obtained using the quasi-static conformal mapping technique (CMT) of coupled coplanar waveguide (CCPW) with finite-width ground plane. S-parameters for the power divider are deduced in the case of quasi-static TEM even–odd mode. The fabrication process is compatible with the GaAs MMIC process. The measured S-parameters are compared with the simulated results of HFSS v.11 and the calculated results of TEM even–odd analysis. Simulated results show that it has reflection loss less of 16.5 dB and insertion loss less of 3.6 dB. Measured results show that the divider has reflection loss less of 15.0 dB and insertion loss less of 3.5 dB. Compared with conventional Wilkinson power divider, the length of the power divider is shortened from 2,620 to 1,570 μm.  相似文献   

14.
An exact closed‐form design approach for a generalized high‐power n‐way Gysel power divider is proposed. The power divider could be designed to achieve an arbitrary power ratio with the flexible multiway application, arbitrary real terminated impedance, excellent isolation, and easy fabrication through both planar and three‐dimensional structures. Moreover, this improved power divider could maintain high power processing capacity through the coaxial cavity transmission line and grounding resistances. The exact analytical solutions related to ideal port matching and high isolation are obtained based on the circuit and transmission‐line theory. To verify the proposed approach, a compact 3‐way coaxial power divider with a pre‐designed power ratio of 1:1.5:2 and four different real terminated impedances of 50, 55, 60, and 65 Ω is designed and fabricated. Excellent agreement is achieved between the simulated and measured results. Measurements from 4.7 to 5.7 GHz show that the return losses of all input and output ports are better than 15 dB. The maximum insertion loss is 0.5 dB, and the phase imbalance is approximately less than 6.1°. In addition, the isolation between any two output ports is better than 23 dB from 4.5 to 6 GHz. Meanwhile, the power handling capability can reach the maximum power of the commercial 50 Ω SMA connectors (2.098 kW).  相似文献   

15.
Capability of microstrip nonuniform transmission lines (MNTLs) for construction of dual‐band and broadband unequal Wilkinson power dividers with arbitrary‐way, arbitrary frequency band operations, and arbitrary power divisions is evaluated. Also, the MNTL transformers are introduced for dual‐band/broadband matching of the unequal output impedances of the MNTL power divider with arbitrary output terminal impedances. The strip width of MNTLs is considered variable and is written as a truncated Fourier series expansion. To show the validity of the design procedure, three experimental MNTL Wilkinson power dividers, which are dual‐band two‐ and three‐way power dividers with different power divisions working at 1 and 3.4 GHz and one broadband equal power divider working from 0.4 to 1.8 GHz, have been designed and fabricated. In the first ones with power division of 1.5, outputs isolation and ports matching of less than ?30 dB are achieved. Next, an extended recombinant structure is presented for achieving three‐way MNTL power dividers with dual‐band operation. The measured isolation between outputs and ports matching are better than 30 dB and measured forward transmissions are between ?4.87 and ?5.45 in two passbands of the divider. Also, for the proposed broadband divider, the measured isolation between the outputs is better than 13 dB in 127% desired bandwidth. © 2012 Wiley Periodicals, Inc. Int J RF and Microwave CAE, 2013.  相似文献   

16.
In this paper, a half‐mode substrate integrated waveguide (HMSIW) power divider with bandpass response and good frequency selectivity is proposed. The proposed power divider includes input/output microstrip lines, four HMSIW resonators, cross‐coupling circuits, and an isolation resistor. The dual‐band bandpass‐filtering response is obtained by using the dual‐mode slotted HMSIW. To get good frequency selectivity, the input/output cross‐coupling circuits have been used, and several transmission zeros can be observed. A dual‐band filtering‐response HMSIW power divider is designed, fabricated and measured. The total size of the fabricated power divider is 0.58λg × 0.45λg. The measured results show a reasonable agreement with the simulated ones. The measured central operating frequencies of the dual‐band HMSIW power divider are at 2.43 and 3.50 GHz, respectively. The measured 3‐dB fractional bandwidth is about 13.3% and 6.3% in the two passbands, and the measured output isolation is about 20 dB.  相似文献   

17.
In this article, a broadband microstrip‐to‐waveguide transition with antisymmetric tapered probe as well as a W‐band power divider/combiner using dual proposed antisymmetric tapered probes is presented. Because of tapered microstrip shapes and metallic steps, the proposed transition is proved to be broadband, efficient, and compact. The insertion loss of the transition sample is less than 0.56 dB between 75 GHz and 100 GHz. Under the assistance of the gradually changed waveguide and dual parallel tapered probes, the operating band of the power divider/combiner has been significantly improved, which is adequate to work in the whole W‐band. A back‐to‐back prototype of the divider/combiner is fabricated and measured. The measured insertion loss of the single divider/combiner is less than 0.29 dB between 90 GHz and 100 GHz, and agrees well with the simulations. Because the circuit size is smaller than 8.0 mm × 2.2 mm (Thanks to the excellent performance and compact size), the proposed design can find wide applications in miniaturized MCM/MMIC systems.  相似文献   

18.
In this paper, a new neuro‐based approach using a feed‐forward neural network is presented to design a Wilkinson power divider. The proposed power divider is composed of symmetrical modified T‐shaped resonators, which are a replacement for quarter‐wave transmission lines in the conventional structure. The proposed technique reduces the size of the power divider by 45% and suppresses unwanted bands up to the fifth harmonics. To verify the concept, a prototype of the power divider has been fabricated and tested, exhibiting good agreement between the predicted and measured results. The results show that the insertion loss and the isolation at the center frequency are about 3.3 ± 0.1 dB and 23 dB, respectively.  相似文献   

19.
In this article, a compact double‐layer microstrip ultra‐wideband (UWB) filtering power divider with high selectivity and isolation is proposed. The filtering power divider consists of a multimode resonator at the top layer coupled with a pair of branch lines at the bottom through a slotline in the middle ground. The slotline provides strong coupling between the two layers and equally distributes the power to two branch lines. The resistor loaded about a quarter‐wavelength away from the slotline achieves high isolation within UWB range. The UWB filtering properties with controllable transmission poles and zeros as well as power splitting with enhanced isolation have been analyzed. The adjustable transmission zeros of the filter unit enables the bandwidth control of the filtering power divider. Finally, a UWB filtering power divider operating at 3.1 to 10.6 GHz has been designed, fabricated, and measured. It achieves a compact size of only 26 × 28 mm2, high isolation about 20 dB, and good out‐of‐band suppression of 40 dB.  相似文献   

20.
新型小型化超宽带功率分配器的设计   总被引:1,自引:1,他引:0  
利用四分之三波长折叠微带线与四分之一波长微带线级联,并在输入端口引入四分之一波长短路线,设计出一种新型的超宽带功率分配器.采用奇偶模的方法进行理论分析,导出设计参数方程,并通过HFSS进行仿真优化.仿真和测量结果表明,输入回波损耗从3 GHz~10.9 GHz均大于10 dB.插入损耗从2.6 GHz~9.5 GHz均...  相似文献   

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