Jarris Kuo scite author profile

Jarris Kuo

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Advanced Semiconductor Engineering (Taiwan)

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Higher Efficiency Power Module Solutions by Chip Embedding

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The development in communication handheld devices has pushed the demand for packages with high level of functionality and complexity at the same time smaller package outline and decreased package thickness. Embedding active dies and/or passive components into the substrate is fulfilling these integration requirements, but embedding can have further beneficial effects (electrical performance, thermal dissipation, shielding) that deliver more benefit for embedding (1). Whereas embedding dies in substrates seems a simple concept, it can come with strong advantages as found in the described case for Power Modules in terms of electrical performance and thermal dissipation. In this paper we shall report the development of embedded technologies for Power Modules and compare electrical performance, thermal dissipation and reliability results with other Power Module package types. We shall report on an intelligent power module for server applications up to 1.5kW consisting of a driver IC and 2 MOSFETs using embedded die in substrate technology in high volume manufacturing. We will describe the development of next generation embedding technologies for Power Modules, their expected benefits and respective application targets together with simulation results. We conclude with a brief overview of the challenges that come with embedded packaging supply chain.

High efficiency power solutions by chip embedding

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Higher efficiency Power Module solutions by chip embedding

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High efficient mid power modules by next generation chip embedding technology

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Next Generation Chip Embedding Technology for High Efficient Mid Power Modules

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Embedding active dies into the substrate is fulfilling integration requirements for modern communication devices, and furthermore embedding was shown to have beneficial effects on electrical performance and thermal dissipation, especially for mid power modules (from a few hundred watts to 5kW) [1–3]. It comes with strong advantages as the power modules operate at higher frequencies (MHz range) and aim to apply smaller capacitors and inductors. This approach reduces the overall PCB size and weight from system point of view. These beneficial effects were observed especially for embedded power dies that were already mounted in a lead frame cavity when embedding [3]. In this paper we shall report the development of embedded technologies for power modules mounted in a lead frame cavity and compare electrical performance, thermal dissipation and reliability results with conventional PQFN packaging [3]. We shall also report electrical performance in various operation frequency ranges from a few kHz to MHz to address the benefit on high switching frequency power modules for SiC or GaN applications. We will also address if the EMI effect can be eliminated by using chip embedded technology instead of wire bonding connection from driver to gate pad of power MOSFET chip. We will conclude that the challenges of electrical performance and thermal dissipation required for today's power modules can successfully be overcome by next generation power modules based on lead frame chip embedding.

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