Yun-Kai Lai scite author profile

Yun-Kai Lai

4Publications

1Citation Statement Received

72Citation Statements Given

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Affiliations

National Taiwan University, National Yang Ming Chiao Tung University

Publications

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Investigation of 3.3 kV 4H-SiC DC-FSJ MOSFET Structures

et al. 2021

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This research proposes a novel 4H-SiC power device structure—different concentration floating superjunction MOSFET (DC-FSJ MOSFET). Through simulation via Synopsys Technology Computer Aided Design (TCAD) software, compared with the structural and static characteristics of the traditional vertical MOSFET, DC-FSJ MOSFET has a higher breakdown voltage (BV) and lower forward specific on-resistance (Ron,sp). The DC-FSJ MOSFET is formed by multiple epitaxial technology to create a floating P-type structure in the epitaxial layer. Then, a current spreading layer (CSL) is added to reduce the Ron,sp. The floating P-type structure depth, epitaxial layer concentration and thickness are optimized in this research. This structure can not only achieve a breakdown voltage over 3300 V, but also reduce Ron,sp. Under the same conditions, the Baliga Figure of Merit (BFOM) of DC-FSJ MOSFET increases by 27% compared with the traditional vertical MOSFET. Ron,sp is 25% less than that of the traditional vertical MOSFET.

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The Design of Quasi-Super Junction and Novel Edge Termination in Junction Barrier Schottky Diode

Hong

Lai

Tzou

et al. 2019

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An MAP ICI equalizer with variable-width trellis for fast-fading channels

Sang

Lai

Lin

2015

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For fast-moving vehicles, radio channels can be severely fast-fading. Under such circumstances, the performance of multi-carrier communication systems, such as OFDM-based ones, are often limited by the inter-carrier interference (ICI) caused by time variation of the channel within one transmit symbol. The conventional way to mitigate the effect of ICI is to increase the frequency spacing between neighboring sub-carriers; yet it leads to the decrease of spectral efficiency. Many types of ICI cancellation methods have been developed. Most of them are only effective for mild to medium ICI, and the ones that are effective for severe ICI either suffer from heavy computational cost or need transmitter-side modifications and thus may not be standard compatible. In this paper, we report a maximum a posteriori (MAP) ICI equalizer that are effective for severe ICI and with acceptable computational cost. Two advantages make it stand out as a very promising technical choice. First, it utilizes an ICI indicator that we introduced in [1] and [2] to build a variablewidth trellis such that the computational cost can be dramatically reduced. Second, it is possible to loop the MAP equalizer and an outer channel decoder to form an iterative receiver to further enhance the system performance. This receiver-side technique can improve the reliability of communication systems under high mobility or increase spectral efficiency under mild to medium mobility.

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Edge Termination Structures for 3.3 kV 4H-SiC Devices

Dong

Lee

Lai

et al. 2020

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Yun-Kai Lai

Investigation of 3.3 kV 4H-SiC DC-FSJ MOSFET Structures

The Design of Quasi-Super Junction and Novel Edge Termination in Junction Barrier Schottky Diode

An MAP ICI equalizer with variable-width trellis for fast-fading channels

Edge Termination Structures for 3.3 kV 4H-SiC Devices

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