THine, NICT And Hiroshima University Announced The Development Of 20Gb/s QPSK Wireless Transmission Technology With The World's First Mixed-Signal Baseband Demodulator Technology

THine Electronics, Inc, National Institute of Information and Communications Technology (“NICT”), and Hiroshima University, a national university corporation (“Hiroshima University”), jointly announced the successful development of 20 gigabits per second (20Gb/s) QPSK wireless transmission technology with the world's first mixed-signal baseband demodulator technology, which would have a great advantage to achieve more power-efficient wireless data transmission for higher-speed appreciations.

THine was responsible for overall design and measurement, Hiroshima University for discussions on design and measurement, and NICT for discussions and measurement assistance.

Details of the technology was presented at the 2024 IEEE custom Integrated Circuits Conference (CICC) held from April 21^st to April 24^th in Denver, Colorado ^[1].

The results of this research pave the way of practical circuit implementations by newly-developed mixed-signal architectures for various applications that require higher-performance and more power-efficiency.

Newly developed technology

• Mixed-signal architecture realizes ultra-high-speed data transmission, improving power efficiency
  The research group has developed the world's first mixed-signal baseband demodulator circuit consisting of a high-speed, low-resolution ADC and a small-scale DSP. This technology is expected to realize higher-data communications exceeding tens of Gb/s, achieving a superior power-efficient baseband demodulator circuit. In general baseband demodulation circuits in high-speed wireless communications consist of a high-speed, high-resolution ADC and a large-scale DSP and, if used for such high-speed communications, the required performance of ADC and DSP results in extremely distorting power efficiency. The developed technology solves these problems.

• The receiver circuits with the baseband demodulator enables 20Gb/s QPSK data transmission
  The developed receiver circuits the baseband demodulator and an FPGA with logic circuits have achieved data transmission of 20Gb/s QPSK modulated signals. The functions implemented in FPGAs will be integrated into baseband receiver circuits in its practical application.

• Outline of the achieved circuits
  The achieved technology simplifies the circuits by making the carrier frequency an integer multiple of the symbol carrier frequency, achieving ultra-high-speed data transmission by a unique circuit configuration with a mixed-signal QPSK Costas loop that integrates carrier, timing, and data recovery functions. The research group has achieved the high-speed, low-resolution ADC by implementing an 8-way interleaved 3-bit ADC (8x speed-up as the total circuits) with the sampling rate of 40-gigasample-per-second (40GS/s) and recovered data with the FPGA.

Background of the MIC R&D Project
The Ministry of Internal Affairs and Communications (“MIC”) of Japan aims to support the expansion of radio wave resources by conducting the program “Research and Development for the Expansion of Radio Wave Resources” to alleviate frequency congestion and for the effective use of radio waves, to enable ultra-large capacity wireless communications, and to promote the use of new frequency bands in order to meet the growing needs for new radio wave applications.

A part of this achievement is funded by MIC (JPJ000254).

Project name: “Research and development of terahertz wave transmission technology for ultra-large-capacity wireless LAN”

Sub-project theme (i) “Research and development of transceiver technology”

Reference
^[1] Shunichi Kubo1, Yuji Gendai¹, Satoshi Miura¹, Shinsuke Hara^2,3, Satoru Tanoi², Akifumi Kasamatsu², Takeshi Yoshida³, Satoshi Tanaka³, Shuhei Amakawa³, Minoru Fujishima³, “A 20Gb/s QPSK Receiver with Mixed-Signal Carrier, Timing, and Data Recovery Using 3-bit ADCs”, 2024 IEEE Custom Integrated Circuits Conference.
¹THine Electronics, Inc., ²National Institute of Information and Communications Technology, ³Hiroshima University