Reliability Testing and Stress Measurement of QFN Packages Encapsulated by an Open-Ended Microwave Curing System

Adamietz, R.; Desmulliez, Marc Phillipe Yves; Pavuluri, Sumanth Kumar; Tilford, T.; Bailey, C.; Schreier-Alt, Thomas; Warmuth, Jens

doi:10.1109/tcpmt.2018.2859031

Cited by 6 publications

(3 citation statements)

References 21 publications

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“…The polymer substrates used in the fabrication process are effectively transparent to the microwave radiation, so they are not directly affected by the process. While the adoption of microwave processing techniques for the fabrication of microelectronics packaging is relatively rare, studies have demonstrated that the technique can be highly advantageous [24][25][26][27].…”

Section: Reviewmentioning

confidence: 99%

Comparative Reliability of Inkjet-Printed Electronics Packaging

Tilford

Stoyanov

Braun

et al. 2021

IEEE Trans. Compon., Packag. Manufact. Technol.

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This paper compares the thermomechanical behavior of 3D inkjet printed microelectronics devices relative to those fabricated from traditional methods. It discusses the benefits and challenges in the adoption of additive manufacturing methods for microelectronics manufacture relative to conventional approaches. The critical issues related to the design and reliability of additively manufactured parts and systems stem from the change in the manufacturing process and the change in materials utilized. This study uses numerical modelling techniques to gain insight into these issues. This article is an extension of a paper on the same topic presented at the 2018 IEEE Electronics Packaging Technology Conference [1]An introduction providing an overview of the area, covering salient academic research activities and discussing progress towards commercialization is presented. The state-of-the-art modular microelectronics fabrication system developed within the EU NextFactory project is introduced. This system has been used to manufacture several test samples, which were assessed both experimentally and numerically. A full series of JEDEC tests showed that the samples were reliable, successfully passing all tests.The numerical model assessing the mechanical behavior of an inkjet-printed structure during layer-by-layer fabrication is presented. This analysis predicts that the stresses induced by the UV cure process are concentrated toward the extremities of the part and, in particular, in the lower layers which are constrained by the print platform.Subsequently, a model of a multilayer microelectronics structure undergoing JEDEC thermal cycling is presented. The model assesses the differences in mechanical properties between a conventional FR4/copper structure and an inkjet-printed acrylic/silver structure. The model identified that the influence of the sintering process on subsequent material properties, behavior of the inject-printed structure, and reliability of the inject-printed structure is significant.Key findings are that while stresses in the conventional and inkjet boards are relatively similar, the inkjet-printed board exhibits significantly greater deformation than the standard board. Furthermore, the mechanical stresses in the inkjet fabricated board are strongly dependent on the elastic modulus of the sintered silver material, which, in turn, is dependent on the sintering process.

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Section: Reviewmentioning

confidence: 99%

Comparative Reliability of Inkjet-Printed Electronics Packaging

Tilford

Stoyanov

Braun

et al. 2021

IEEE Trans. Compon., Packag. Manufact. Technol.

Self Cite

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“…Therefore, for the QFN, the conductive path between the internal pins and the bottom pads is short, and the selfinductance coefficient and the wiring resistance in the package are low. These characteristics give the QFN package outstanding electrical performance [18][19][20][21][22][23]. In addition, it also provides excellent thermal performance through exposed lead frame pads, which are direct thermal channels for dissipating heat within the package.…”

Section: Introductionmentioning

confidence: 99%

A Ku-Band Miniaturized System-in-Package Using HTCC for Radar Transceiver Module Application

Yang

Zhang²,

Song³

2022

Micromachines

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This paper introduces a miniaturized system in package (SIP) for a Ku-band four-channel RF transceiver front-end. The SIP adopts the packaging scheme of an inner heat-dissipation gasket and multi-layer substrate in the high temperature co-fired ceramics (HTCC) shell with a metal heat sink at the bottom. The gasket effectively solves the heat-dissipation problem of high-power transceiver chips, and the multi-layer substrate achieves the interconnection between multiple chips. Within the limited size of 14.0 × 14.0 × 2.5 mm3, the SIP integrates five bidirectional amplifier chips, an amplitude-phase control multi-function chip, and two power modulation chips to realize the Ku-band four-channel RF transceiver front-end. Transmitting power over 0.5 W (27dBm) and receiving noise figure of 3.4 dB are achieved in the Ku-band. The efficient heat dissipation, high air tightness, and excellent integration are simultaneously realized in this SIP. The measurement results show that the performance is stable in the receiving and transmitting states, and the SIP based on HTCC technology has specific prospects for radar transceiver application.

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“…For instance, in the design of microwave and millimeter wave planar circuits, the dielectric constant of the substrate material has to be known as a priori. With the fast evolving of electronic technologies, materials are involved in many areas such as manufacturing processing, antenna design, and aerospace technology [2][3][4][5]. Therefore, precision measurement of the dielectric constant is becoming more and more critical.…”

Section: Introductionmentioning

confidence: 99%

A Dual-Band Non-destructive Dielectric Measurement Sensor Based on Complementary Split-Ring Resonator

2021

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A dual-band non-destructive dielectric constant sensor based on the complementary split ring resonators is presented. The resonators for both bands use the complementary split ring structure of different sizes. Numerical simulation demonstrates that the resonating frequency and quality factor is dependent on the variation of dielectric constant and loss tangent, making it a potential structure for dielectric measurement. To search for the optimal thickness for measurement, parametric study is conducted and the retrieval expressions are obtained for both bands. The measured results indicate an accuracy of 1.5% in comparison with the data in the literature. In addition, the effect of air gap has been analyzed, showing that it is an important error source and eliminating such effect can improve the measurement accuracy.

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Reliability Testing and Stress Measurement of QFN Packages Encapsulated by an Open-Ended Microwave Curing System

Cited by 6 publications

References 21 publications

Comparative Reliability of Inkjet-Printed Electronics Packaging

Comparative Reliability of Inkjet-Printed Electronics Packaging

A Ku-Band Miniaturized System-in-Package Using HTCC for Radar Transceiver Module Application

A Dual-Band Non-destructive Dielectric Measurement Sensor Based on Complementary Split-Ring Resonator

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