H. Komurasaki scite author profile

H. Komurasaki

5Publications

66Citation Statements Received

28Citation Statements Given

How they've been cited

169

How they cite others

Affiliations

Mitsubishi Group (Japan), Mitsubishi Electric (Japan), Mitsubishi Electric (United States)

Publications

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A 2.4-GHz-band 1.8-V operation single-chip Si-CMOS T/R-MMIC front-end with a low insertion loss switch

Yamamoto

Heima

Furukawa

et al. 2001

IEEE J. Solid-State Circuits

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This paper describes the design and experimental results of a 1.8-V single-chip CMOS MMIC front-end for 2.4-GHz band short-range wireless communications, such as Bluetooth and wireless LANs. The IC consists of fundamental RF building circuits-a power amplifier (PA), a low-noise amplifier (LNA), and a transmit/receive-antenna switch (SW), including almost all on-chip matching elements. The IC was fabricated using a 0.18-m standard bulk CMOS technology which has no extra processing steps to enhance the RF performances. Two new circuit-design techniques are introduced in the IC in order to minimize the insertion loss of the SW and realize a higher gain for the PA and LNA despite the utilization of the standard bulk CMOS technology. The first is the derivation of an optimum gate width of the SW to minimize the insertion loss based on small-signal equivalent circuit analysis. The other is the revelation of the advantages of interdigitated capacitors (IDCs) over conventional polysilicon to polysilicon capacitors and the successful use of the IDCs in the LNA and PA. The IC achieves the following sufficient characteristics for practical wireless terminals at 2.4 GHz and 1.8 V: a 5-dBm transmit power at a 1-dB gain compression, a 19-dB gain, an 18-mA current for the PA, a 1.5-dB insertion loss, more than 24-dB isolation, an 11-dBm power handling capability for the SW, a 7.5-dB gain, a 4.5-dB noise figure, and an 8-mA current for the LNA.

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A 1.8-v operation RF CMOS transceiver for 2.4-ghz-band GFSK applications

Komurasaki

Sano

Heima

et al. 2003

IEEE J. Solid-State Circuits

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Feasibility of 0.18 μm SOI CMOS technology using hybrid trench isolation with high resistivity substrate for embedded RF/analog applications

Maeda

Wada

Yamamoto

et al. 2001

IEEE Trans. Electron Devices

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A single-chip 2.4 GHz RF transceiver LSI with a wide-range FV conversion demodulator

Komurasaki

Sato²,

Ono³

et al.

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A 2-V 1.9-GHz Si down-conversion mixer with an LC phase shifter

Komurasaki

Sato

Sasaki

et al. 1998

IEEE J. Solid-State Circuits

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H. Komurasaki

A 2.4-GHz-band 1.8-V operation single-chip Si-CMOS T/R-MMIC front-end with a low insertion loss switch

A 1.8-v operation RF CMOS transceiver for 2.4-ghz-band GFSK applications

Feasibility of 0.18 μm SOI CMOS technology using hybrid trench isolation with high resistivity substrate for embedded RF/analog applications

A single-chip 2.4 GHz RF transceiver LSI with a wide-range FV conversion demodulator

A 2-V 1.9-GHz Si down-conversion mixer with an LC phase shifter

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