Tuesday, 31 May 2016: 14:50
Aqua 307 (Hilton San Diego Bayfront)
M. Fujishima (Hiroshima University)
Over hundred years have passed since Marconi sent the first Atlantic
wireless transmission in 1901. Over the years, frequency used for
wireless communication has been increasing by ten folds every 20 years.
According to the trend, frequency used for wireless communication will
reach at terahertz band in 2020. In the research on terahertz wireless
communication, transceivers with compound semiconductor were
reported[1-2]. However, integration of large-scale digital circuits in a
compound semiconductor is so difficult that complex modulation and
demodulation for high-speed communication and frequency-domain
equalization including propagation environment are unrealistic. On the
other hand, although CMOS integrated circuits can realize complex
modulation and frequency domain equalization, terahertz transceivers
with CMOS are challenging since typical maximum operation frequency in
advanced process is still around 300GHz. To overcome relatively low
operation frequency with CMOS transistors, we have adopted a tripler in a
transmitter, where the tripler utilizes cubic nonlinearity in a
transistor[3]. Generally, when modulated signal is given to the tripler,
its carrier frequency triples but original constellation is distorted.
Therefore, in [4], the tripler was used only for QPSK (quadrature phase
shift keying) where the amplitude of symbols is constant and the shape
of constellation is not affected by tripler’s nonlinearity.
Nevertheless, in order to realize higher communication speed with more
bits per symbol such as 16 QAM or higher, how should the tripler be
utilized? To solve the nonlinearity issue in the tripler, local
oscillation signal (LO) as well as the modulated intermediate-frequency
signal (IF) is given to the tripler simultaneously. When the two types
of spectral components are given to the tripler, intermodulation between
two signals occurs. As a result, spectral components of appear at the
output. Since the second term maintains linearity for the IF,
modulation information in the IF is preserved when only the second term
is properly filtered. Adopting this technique, 300GHz-band CMOS
transmitter is fabricated with 40nm process. Measured results show that
17.5Gbps per channel is realized over 6 channels with 32 QAM. As a
result, total bit rate reaches at 105Gbps when all the 6 channels can be
bonded.
[1] H-J. Song et al., "50-Gb/s Direct Conversion QPSK Modulator and
Demodulator MMICs for Terahertz Communications at 300 GHz," IEEE Trans.
Microwave Theory & Tech., vol. 62, no. 3, pp. 600 - 609, March 2014.
[2] C. Wang et al., "0.34-THz Wireless Link Based on High-Order
Modulation for Future Wireless Local Area Network Applications ," IEEE
Trans. Terahertz Science & Tech., vol. 4, no. 1, pp. 75 - 85, Jan.
2014.
[3] K. Katayama et al., "A 300GHz 40nm CMOS Transmitter with
32-QAM 17.5Gb/s/ch Capability over 6 Channels," 2016 IEEE International
Solid-State Circuits Conf. Dig. (in press).
[4] S. Kang et al., "A 240GHz wideband QPSK transmitter in 65nm
CMOS," 2014 IEEE Radio Frequency Integrated Circuits Symp., pp. 353 -
356, 1-3 June 2014.
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