高精度倒装焊机光学对位系统研制及算法研究 -

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高精度倒装焊机光学对位系统研制及算法研究

doi:10.37188/CO.2022-0101

1.
中国科学院长春光学精密机械与物理研究所, 吉林长春 130033
2.
中国电子科技集团公司第二研究所, 山西太原 030024
3.
吉林江机特种工业有限公司, 吉林吉林 132000

基金项目:吉林省重点科技研发项目（No. 20200401047GX）

详细信息

作者简介:
韩　冰（1981—），男，吉林长春人，现任中国科学院长春光学精密机械与物理研究所质检中心副主任，副研究员，主要从事光学测试技术研究和检测仪器的开发工作。E-mail：hanbing@ciomp.ac.cn
许洪刚（1991—），男，山东临沂人，硕士，助理研究员，2014年、2018年于东北林业大学分别获得学士、硕士学位，主要从事光电测量技术方面的研究。E-mail：nefuxhg@163.com

中图分类号:TN605
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- 被引次数:0
出版历程
- 收稿日期:2022-05-23
- 修回日期:2022-06-14
- 网络出版日期:2022-09-29

Development and algorithm research of optical alignment system for a high precision flip chip bonder

1.
Changchun Institute of Optics, Fine Mechanics and Physics, Chinese Academy of Sciences, Changchun 130033, China
2.
The Second Research Institute of CETC, Taiyuan 030024, China
3.
Jilin Jiangji Special Industries Co Ltd, Jilin 132000, China

Funds:Supported by Science and Technology R&D Project of Jilin Province (No. 20200401047GX)

摘要

摘要:
针对国内红外焦平面倒装焊机对高精度光学对位系统的迫切需求，对光学对位系统进行了设计及验证，并对该系统用到的平行调整、光学对位及坐标系误差补偿算法进行研究。文章首先对倒装焊接光学对位工艺进行分析；然后对平行性调整及光学对位算法进行介绍，并根据光学对位系统测试流程，提出更加合理的误差补偿算法；最后，以上述算法为理论依据，设计光学对位系统，其包括准直系统、显微成像系统和测距三部分。所设计的光学系统可实现平行性粗调，特征点识别及平行性精调功能。试验结果表明，准直系统准直效果较好，显微成像系统分辨率高，成像质量较好，测距系统的测距精度为0.084 μm。设计的高精度光学对位系统解决了国内红外焦平面倒装焊机对高精度光学对位系统的迫切需求，已经在国内某型号的倒装焊机中得到应用，对于提高国产高端集成电路的自主研发和生产能力具有非常重要的意义。
- 红外焦平面倒装焊机/
- 光学对位系统/
- 平行调整/
- 测距
Abstract:
Aiming at the urgent demand of high-precision optical alignment systems for a domestic infrared focal plane flip chip bonder, an optical alignment system was designed and verified, and the parallel adjustment, optical alignment and coordinate system error compensation algorithms applied to the system were researched. Firstly, this paper analysed the optical alignment process of a flip chip bonder, then introduced the parallelism adjustment and optical alignment algorithm, and proposed a more reasonable error compensation algorithm according to the test process of the optical alignment system. Finally, based on the above calculation algorithm, the optical alignment system was designed including three parts: a collimation system, a microscopic imaging system and a laser ranging system. The functions of parallel coarse adjustment, feature point recognition and parallel fine adjustment were realized. The experimental results show that the collimation system has a good collimation effect, the microscopic imaging system has high resolution and good imaging quality, and the ranging accuracy of the laser ranging system is 0.084 μm. The designed high-precision optical alignment system solves the urgent need of a domestic infrared focal plane flip chip bonder for high-precision optical alignment systems. It has been applied in a certain types of flip chip bonders, and has very important social significance for improving the independent research and development and production capacity of domestic high-end large-scale integrated circuits.
- infrared focal plane flip chip bonder/
- optical alignment system/
- parallel adjustment/
- laser ranging

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图 1倒装焊接工艺流程图

Figure 1.The flow chart of the flip chip bonder process

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图 2倒装焊接机工作坐标系

Figure 2.The working coordinate system of the flip chip bonder

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图 3平面旋转模型

Figure 3.The plane rotation model

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图 4光学对位模型

Figure 4.The optical alignment model

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图 5基板平台坐标系与光学对位系统坐标系误差模型

Figure 5.The error model of the coordinate systems of the substrate platform and the optical alignment system

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图 6焊接后坐标系误差模型

Figure 6.The error model of the coordinate system after bonding

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图 7光学对位系统图

Figure 7.The optical alignment system

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图 8光学对位系统装机图

Figure 8.The diagram of the optical alignment system assembly

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图 9准直系统测试效果

Figure 9.Test effects of the collimation system

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图 10显微成像效果

Figure 10.The effect of microscopic imaging

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图 11 测距验证系统

Figure 11.The laser ranging verification system

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表 1 测距结果

Table 1.Results of laser ranging

位置参数（μm）	探测器参数
位置参数（μm）	第1次	第2次	第3次	第4次	第5次	第6次
0	1.396	1.433	1.417	1.425	1.415	1.402
2	1.622	1.638	1.643	1.639	1.615	1.645
4	1.813	1.858	1.826	1.844	1.832	1.822
6	2.123	2.206	2.143	2.189	2.168	2.202
8	2.615	2.704	2.687	2.712	2.667	2.711
10	3.247	3.345	3.316	3.335	3.356	3.268
12	3.858	3.941	3.854	3.903	3.884	3.862
14	4.234	4.404	4.302	4.297	4.483	4.333
16	4.654	4.699	4.684	4.725	4.655	4.708
18	4.613	4.621	4.59	4.625	4.592	4.564
20	4.221	4.585	4.339	4.502	4.458	4.48
22	3.778	3.786	3.623	3.682	3.698	3.631
24	2.402	2.516	2.529	2.515	2.564	2.488
26	1.115	1.116	1.252	1.212	1.203	1.415
聚焦点（μm）	15.55	15.56	15.61	15.57	15.58	15.63

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