CPW has powerful resources support from CCID and IDG.
《电脑商报》背后有来自CCID和IDG强大的资源支持。
In chapter IV, two novel wide-slot antennas fed by CPW and Microstrip line have been designed.
第四章设计了微带馈电和共面波导馈电的平面宽槽超宽带天线。
The transmission loss properties of CPW on different substrates are investigated systematically.
研究了不同衬底上共面波导(CPW)的损耗特性。
The transition effect of the via-free transition from coplanar waveguide (CPW) to microstrip is analyzed.
分析了无通孔接地板对共面波导(CPW)至微带转换过渡的影响。
In order to realize thin dielectric structure of the transmission line and combined the principle of the design of CPW, a cavity structure has also been studied.
为了实现射频传输线的薄衬底结构,根据共面波导的设计思想,设计了腔体式共面波导型射频微机械开关。
The temperature distribution on the coplanar waveguide(CPW)and the terminal resistors was simulated, and so did the impact of approach of the thermopile on the CPW.
模拟结果包括共面波导(CPW)与终端电阻上的温度分布,以及热电堆的接近对CPW性能的影响。
Conclusion. CPW is a feasible procedure for anterior decompression and fusion, with safety, complete decompression, and high fusion rate, as long as indicatie patients are selected.
结论:CPW是一种可行的前路减压融合的方法。只要选择了合适的病例,那么就能安全彻底的减压而且可以获得高融合率。
Coplanar transmission lines and integrated inductors are fabricated on different SOI substrates with standard CMOS processes. The attenuation mechanism of the CPW and inductor is analyzed.
采用标准CMOS工艺在不同soi衬底上制备了微带和微带集成电感器件,分析了CPW和集成电感的损耗机制。
This paper presents a novel unequal cross-slot coupled circularly polarized microstrip antenna excited by coplanar waveguide (CPW), which is convenient to be integrated with active circuits.
提出一种新型的圆极化微带天线形式,采用共面波导、不等长十字槽耦合馈电,易于与有源电路集成。
The hexagon fractional slot structure is chosen, the gradually changed CPW feed is adopted. Not only the bandwidth of matched impedance is expanded, but also the antenna's miniaturization is realized.
选择正六边形分形缝隙结构,采用渐变的共面波导馈电,不仅拓宽了阻抗带宽,而且实现了天线的小型化。
The hexagon fractional slot structure is chosen, the gradually changed CPW feed is adopted. Not only the bandwidth of matched impedance is expanded, but also the antenna's miniaturization is realized.
选择正六边形分形缝隙结构,采用渐变的共面波导馈电,不仅拓宽了阻抗带宽,而且实现了天线的小型化。
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