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Primeur weekly 2016-02-01

Crowd computing

The DATA4 Group has acquired a stake in Qarnot computing to support its development both in France and abroad ...

Quantum computing

A new quantum approach to big data ...

Focus on Europe

Bright Computing receives 1,5 million euro Horizon 2020 grant from the European Commission ...

Energy-saving minicomputers for the 'Internet of Things' ...

AppliedMicro selected as the exclusive server provider for the Horizon 2020-funded UniServer project ...

New GBP 20.4 million project set to transform UK pharmaceutical development and manufacturing ...

Swiss National Supercomputing Centre to organize the 2016 CSCS-USI Summer School ...

SISSA and ICTP Master in High Performance Computing to organize MHPC Workshop on High Performance Computing ...

Middleware

Bright and Turkish solution provider BitNet celebrate joint customer win at FNSS ...

Hardware

A step towards keeping up with Moore's Law ...

Nagaoka University of Technology selects SGI to deliver advanced information processing for students and researchers ...

SGI reports fiscal second quarter 2016 financial results ...

Tokyo Institute of Technology and Fujitsu achieve wireless transmission speeds of 56 Gbps, world's fastest ...

Fujitsu and Socionext develop next-generation 56 Gbps transceiver circuit with world's lowest power consumption for optical communications between servers ...

Applications

NSF's iPlant Collaborative rebrands to CyVerse ...

IBM Watson health companies awarded five Best in KLAS designations ...

ANSYS unveils release 17.0 ...

Titan targets tumors ...

Supercomputer services give honey bee researchers critical insight ...

PPPL team wins 80 million processor hours on US' fastest supercomputer ...

The Cloud

IBM enhances LinuxONE for hybrid Cloud environments ...

Tokyo Institute of Technology and Fujitsu achieve wireless transmission speeds of 56 Gbps, world's fastest


Transceiver CMOS chip and module.
1 Feb 2016 Tokyo, Kawasaki - In an effort to further enlarge the capacity of wireless equipment, Tokyo Institute of Technology and Fujitsu Laboratories Ltd. have developed a CMOS wireless transceiver chip that can process signals at high speeds with little loss across a broad range of frequencies, from 72 to 100 gigahertz (GHz). They also developed technology to modularize it. With these developments, they succeeded in achieving wireless transmission speeds of 56 Gigabits per second (Gbps), the world's fastest.

In recent years, to cope with the large increase in data traffic resulting from the widespread use of smartphones and other devices, networks that link base stations use optical fiber. One issue with this approach, however, is that it is difficult to expand service in areas where it is difficult to install a network of optical fiber cables, such as in urban areas or areas surrounded by rivers or mountains. To deal with this issue, Tokyo Institute of Technology and Fujitsu Laboratories have now developed high-speed wireless transceiver technologies that use the millimeter-waveband (30-300 GHz), where there are few competing wireless applications, and which are capable of large-capacity communications.

This technology makes it possible to have high-capacity wireless communications equipment that can be installed outdoors in applications where fiber-optic networks would be difficult to lay.

The details of this technology will be announced at the IEEE International Solid-State Circuits Conference 2016 (ISSCC 2016), the largest conference related to semiconductor technology, which opened in San Francisco on January 31 (ISSCC Presentation Number 13.3).

With sharp increases in data communications traffic resulting from the proliferation of smartphones, the expansion in the capacity of backbone networks - which connect wireless base stations to core networks, and base stations to each other - is accelerating. In the past, macro-cell base stations were mainly used, each of which can cover an area with several kilometers of range, but in recent years these have been supplemented with large quantities of small-cell base stations, each of which has a range of only a few hundred meters, to accommodate the increase in communications traffic.

Also, fiber-optic lines, which can transmit large volumes of data, are currently the most common way to handle communications between base stations. But laying new fiber-optic cables can be difficult in tightly packed urban areas, or in places hemmed in by mountains or rivers, so it has been hoped that high-capacity wireless equipment could be created that can easily be installed outdoors.

High-capacity wireless transmissions need to use broad frequency ranges. This makes the use of the millimeter-waveband a suitable option, as few competing wireless applications use it. But because the millimeter-waveband uses such high frequencies, designing CMOS integrated circuits for that purpose has been a challenge, as the circuits need to be designed to operate near their limits. It has also been difficult to develop low-loss transceiver circuits that modulate and demodulate broadband signals into and out of the millimeter-waveband with high quality, and low-loss interface circuits, which connect the circuit board to the antenna.

The newly developed CMOS wireless transceiver chip and the wireless module that includes it are comprised of two key technologies.

1. Low-loss, high-bandwidth transceiver circuit

Tokyo Institute of Technology developed a technology for broadband, low-loss transceiver circuits in which data signals are split in two, with each converted to different frequency ranges, and then recombined. Each signal is modulated into a band 10-GHz wide, with the low-band occupying the 72-82 GHz range, and the high-band occupying the 89-99 GHz range. This technology enables modulation on an ultra-wideband signal of 20 GHz, with low noise and a similar range in the ratio between input and output power as existing 10 GHz band methods, which results in high-quality signal transmissions.

Tokyo Institute of Technology also developed an amplifier to send and receive as radio waves signals converted to the millimeter-waveband. The ultra-wideband amplifier for 72 to 100 GHz was designed with circuit technologies that stabilize the amplification ratio by feeding the amplitude of the output signal back to the input side for signal components whose amplification ratio decreases based on frequency.

2. Modularization technology

The signal converted to the millimeter-waveband by the semiconductor chip is transported over the circuit board's signal path and supplied to the antenna. Because the antenna is made out of a waveguide - a metallic cylinder, there needs to be an ultra-wideband, low-loss connection between the printed circuit board and the waveguide. Fujitsu Laboratories and Tokyo Institute of Technology developed an interface between the circuit board and waveguide that uses a specially designed pattern of interconnects on the printed circuit board to adjust the impedance for the ultra-wideband range, enabling loss in the desired frequency range to be greatly reduced.

In this development project, Tokyo Institute of Technology was primarily responsible for reducing transceiver-circuit losses and developing broadband technologies, while Fujitsu Laboratories mainly handled modularization technologies.

Indoor data-transfer tests were conducted, with two modules facing each other separated by a distance of 10 cm. These tests achieved data-transfer rates of 56 Gbps, the fastest wireless transmission speeds in the world, with loss of maximum 10% between the waveguide and circuit board.

By combining the technologies developed in this project with high-output amplifier technology, used to amplify the signal and increase the transport range, and baseband-circuit technology, used to process ultra-wideband signals, it is possible to increase the capacity of wireless equipment that can be installed outdoors. By doing so, even in places where new fiber-optic lines are difficult to install, such as urban areas and places surrounded by mountains or rivers, a high-capacity wireless base station network can be deployed, thereby contributing to the provision of a comfortable communications environment in those places.

Fujitsu Laboratories aims to have a commercial implementation of wireless trunk lines for cellular base stations around 2020.
Source: Fujitsu

Back to Table of contents

Primeur weekly 2016-02-01

Crowd computing

The DATA4 Group has acquired a stake in Qarnot computing to support its development both in France and abroad ...

Quantum computing

A new quantum approach to big data ...

Focus on Europe

Bright Computing receives 1,5 million euro Horizon 2020 grant from the European Commission ...

Energy-saving minicomputers for the 'Internet of Things' ...

AppliedMicro selected as the exclusive server provider for the Horizon 2020-funded UniServer project ...

New GBP 20.4 million project set to transform UK pharmaceutical development and manufacturing ...

Swiss National Supercomputing Centre to organize the 2016 CSCS-USI Summer School ...

SISSA and ICTP Master in High Performance Computing to organize MHPC Workshop on High Performance Computing ...

Middleware

Bright and Turkish solution provider BitNet celebrate joint customer win at FNSS ...

Hardware

A step towards keeping up with Moore's Law ...

Nagaoka University of Technology selects SGI to deliver advanced information processing for students and researchers ...

SGI reports fiscal second quarter 2016 financial results ...

Tokyo Institute of Technology and Fujitsu achieve wireless transmission speeds of 56 Gbps, world's fastest ...

Fujitsu and Socionext develop next-generation 56 Gbps transceiver circuit with world's lowest power consumption for optical communications between servers ...

Applications

NSF's iPlant Collaborative rebrands to CyVerse ...

IBM Watson health companies awarded five Best in KLAS designations ...

ANSYS unveils release 17.0 ...

Titan targets tumors ...

Supercomputer services give honey bee researchers critical insight ...

PPPL team wins 80 million processor hours on US' fastest supercomputer ...

The Cloud

IBM enhances LinuxONE for hybrid Cloud environments ...