Design and Analysis of a novel fan-out WLCSP structure

C. Yuan, G.Q. Zhang, Ching-Shun Huang, Chun-Hui Yu, Chin-Cheng Yang, Wen-Kung Yang, M. Yew, C. Chou, K. Chiang
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引用次数: 10

Abstract

A novel wafer level chip scaled packaging (WLCSP) having the capability of the redistributing the electrical circuit is proposed herein to resolve the problem of assembling a fine pitched chip to a coarse pitched substrate. In the fan-out WLCSP, the chip is first attached to a specific 8" chip carrier, and then the trench between the chips are filled by the filler polymer. The solder bumps could be located on both the filler polymer and chip surface, but the fabrication of the fan-out WLCSP is similar to the conventional 8" WLCSP process. Because the packaging structure of the fan-out WLCSP differs from the conventional one, a series of coplanity and solder joint height experiment is conducted to verify the capability of mounting the said structure to the substrate. The experimental results indicated that the derivation of the fan-out WLCSP is approximated plusmn0.01 mm, which is acceptable in the surface mount technology of the substrate. Moreover, the nonlinear finite element (FE) method is applied to analyze the mechanical characteristics of the fan-out WLCSP. Moreover, both the solder joint reliability and the trace stress while the external thermal cycling loading is considered. The simulation result indicates that the distance between the solder joint and the edge of the chip and filler polymer was more sensitive than other the design parameters, and the said distance parameter would dominate the mechanical characteristic of the fan-out WLCSP
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一种新型扇出式WLCSP结构的设计与分析
本文提出了一种具有电路再分配能力的晶圆级芯片缩放封装(WLCSP),以解决将细坡芯片组装到粗坡衬底上的问题。在扇形输出的WLCSP中,芯片首先连接到特定的8”芯片载体上,然后芯片之间的沟槽由填充聚合物填充。焊料凸起可以位于填充聚合物和芯片表面,但扇形WLCSP的制造与传统的8”WLCSP工艺相似。由于扇出式WLCSP封装结构与传统的封装结构不同,为了验证该封装结构在基板上的安装能力,进行了一系列的共平面度和焊点高度实验。实验结果表明,扇形输出WLCSP的导数近似为±0.01 mm,在衬底表面贴装技术中是可以接受的。此外,采用非线性有限元法对扇形外露式悬臂梁的力学特性进行了分析。此外,还考虑了外部热循环加载时焊点的可靠性和痕迹应力。仿真结果表明,焊点与芯片和填充聚合物边缘之间的距离比其他设计参数更为敏感,并且该距离参数将主导扇形WLCSP的力学特性
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