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Silver screen printed transmission lines- analyzing the influence of substrate roughness on the RF performance up to 30 GHz

机译：银丝网印刷传输线-分析衬底粗糙度对高达30 GHz的RF性能的影响

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In this paper, the authors investigate the influence of DC conductivity on the RF performance of screen printed traces on a flexible substrate. From literature, much work has been done on the effect of sintering conditions on the electrical resistivity of printed traces. Typically the traces were printed onto substrates with negligible surface roughness. Yet this would not be the case for printing on textiles for wearable electronics applications. In this paper, we investigate the electrical resistivity of screen printed traces on a substrate which is similar to fabrics, in that it is flexible and has non-negligible surface roughness (Ra~1μm). In particular, an accurate simulation model was developed to correlate with the measurement results, which would provide guidelines for the modelling of similar printed traces to predict their RF performances.

机译：在本文中，作者研究了直流电导率对柔性基板上丝网印刷走线的RF性能的影响。根据文献，关于烧结条件对印刷迹线的电阻率的影响已经做了很多工作。通常，将迹线印刷到表面粗糙度可忽略不计的基材上。然而，在可穿戴电子设备的纺织品上印刷并非如此。在本文中，我们研究了与织物相似的基底上的丝网印刷迹线的电阻率，因为它具有柔韧性并且具有不可忽略的表面粗糙度（Ra〜1μm）。特别是，开发了一个精确的仿真模型来与测量结果相关联，这将为建模相似的印刷走线以预测其RF性能提供指导。

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《IEEE Electronics Packaging Technology Conference》|2014年|22-26|共5页
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Ying Ying Lim; Yee Mey Goh; Yoshida Manabu; Tung Thanh Bui; Vincent Tracey; Aoyagi Masahiro; Changqing Liu;
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electrical resistivity; fabrics; microwave materials; printing; silver; sintering; surface roughness; waveguides; Ag; DC conductivity; RF performance; electrical resistivity; flexible substrate; screen printed traces; silver screen printed transmission lines; sintering conditions; substrate roughness; wearable electronics applications; Conductivity; Coplanar waveguides; Printing; Radio frequency; Solid modeling; Substrates; Transmission line measurements;

机译：电阻率;织物;微波材料;印刷;银;烧结;表面粗糙度;波导;银;直流电导率;射频性能;电阻率;柔性基板;丝网印刷迹线;银丝网印刷传输线;烧结条件;基板粗糙度;耐磨电子应用;电导率;共面波导;印刷;射频;固体建模;基板;传输线测量;

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1. Evaluation of screen printed silver trace performance and long-term reliability against environmental stress on a low surface energy substrate [J] . Mikkonen Riikka, Mantysalo Matti Microelectronics & Reliability . 2018,第JULa期

机译：在低表面能基板上评估丝网印刷银的迹线性能和针对环境压力的长期可靠性
2. Trace width effects on electrical performance of screen-printed silver inks on elastomeric substrates under uniaxial stretch [J] . G. Cahn, O. N. Pierron, A. Antoniou Journal of Applied Physics . 2021,第11期

机译：在单轴拉伸下的弹性体基材上的丝网印刷银墨水的电气性能迹线宽度效应
3. 30-GHz High-Frequency Application of Screen Printed Interconnects on an Organic Substrate [J] . Ying Ying Lim, Yee Mey Goh, Manabu Yoshida, Components, Packaging and Manufacturing Technology, IEEE Transactions on . 2017,第9期

机译：丝网印刷互连在有机基板上的30 GHz高频应用
4. Silver screen printed transmission lines- analyzing the influence of substrate roughness on the RF performance up to 30 GHz [C] . Ying Ying Lim, Yee Mey Goh, Yoshida Manabu, IEEE Electronics Packaging Technology Conference . 2014

机译：银屏印刷传输线 - 分析基板粗糙度对射频性能的影响最多30GHz
5. Investigation of active array geometries to improve performance for 30 GHz portable satellite communications terminals. [D] . Mekelburg, Theresa Rae. 1999

机译：研究有源阵列的几何形状以提高30 GHz便携式卫星通信终端的性能。
6. Microstructure and adhesion characteristics of a silver nanopaste screen-printed on Si substrate [O] . Kwang-Seok Kim, Yongil Kim, Seung-Boo Jung 2012

机译：丝网印刷在Si衬底上的银纳米膏的微观结构和粘附特性
7. Silver screen printed transmission lines- influence of substrate porosity on the RF performance and modelling up to 30GHz [O] . Lim Ying Ying, Goh Yee M., Yoshida Manuba, 2014

机译：银丝网印刷传输线-基材孔隙率对RF性能的影响以及高达30GHz的建模

Silver screen printed transmission lines- analyzing the influence of substrate roughness on the RF performance up to 30 GHz

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