ATTO: Wireless Networking at Fiber Speed

ATTO targets wireless networking at fiber speed: 100 Gb/s/m2 with latencies smaller than 10 μs. To provide this tremendous wireless capacity, ultrasmall floor-integrated cells are proposed. In this way, short-reach communication can be established, reducing the effect of interference and providing full frequency reuse in the wireless domain. Radio frequency (RF)-over-fiber coherent communication and a dedicated 2-D passive optical network structure support the interconnection and selection of the cells and minimize the required transceiver electronics. To evaluate the feasibility of the proposed architecture, key principles are validated at lower frequency bands. Two main building blocks are addressed in this paper: a fully passive opto-antenna to prove that a passive remote antenna head can be realized owing to the short transmission distances. Furthermore, a low-cost RF-over-fiber system is demonstrated: sigma–delta modulation drives nonlinear optical modulators, such as electroabsorption modulators and vertical-cavity surface-emitting lasers, using a digital transmitter while remaining compatible with the passive opto-antenna. Finally, two important properties of the ATTO floor are evaluated. The exposure of a human body model to RF fields by the antenna floor is evaluated. Measurements ensure a 200-fold margin with respect to the International Commission on Non-Ionizing Radiation Protection basic restriction. To guarantee that multiple devices can communicate with the ATTO floor simultaneously, the interference between cells spaced 300 mm apart was evaluated.

[1]  J. Vanfleteren,et al.  Highly Efficient Impulse-Radio Ultra-Wideband Cavity-Backed Slot Antenna in Stacked Air-Filled Substrate Integrated Waveguide Technology , 2018, IEEE Transactions on Antennas and Propagation.

[2]  P. Verheyen,et al.  Active Components for 50 Gb/s NRZ-OOK Optical Interconnects in a Silicon Photonics Platform , 2017, Journal of Lightwave Technology.

[3]  Xin Yin,et al.  Resonant optical receiver design by series inductive peaking for sub‐6 GHz RoF , 2017 .

[4]  P. Demeester,et al.  SIW cavity-backed slot (multi-)antenna systems for the next generation IoT applications , 2016, 2016 IEEE Topical Conference on Wireless Sensors and Sensor Networks (WiSNet).

[5]  J. Verbist,et al.  Real-time 100 Gb/s NRZ-OOK transmission with a silicon photonics GeSi electro-absorption modulator , 2017, 2017 IEEE Optical Interconnects Conference (OI).

[6]  Jr. R. Wyndrum Microwave filters, impedance-matching networks, and coupling structures , 1965 .

[7]  Gerhard P. Fettweis,et al.  The Tactile Internet: Applications and Challenges , 2014, IEEE Vehicular Technology Magazine.

[8]  AKHIL GUPTA,et al.  A Survey of 5G Network: Architecture and Emerging Technologies , 2015, IEEE Access.

[9]  Piet Demeester,et al.  Comparison Between Analog Radio-Over-Fiber and Sigma Delta Modulated Radio-Over-Fiber , 2017, IEEE Photonics Technology Letters.

[10]  Sam Lemey,et al.  SIW antennas as hybrid energy harvesting and power management platforms for the internet of things , 2016, International Journal of Microwave and Wireless Technologies.

[11]  Sam Agneessens,et al.  ATTO: Wireless Networking at Fiber Speed , 2018, 2017 European Conference on Optical Communication (ECOC).

[12]  D. Novak,et al.  Radio-Over-Fiber Technologies for Emerging Wireless Systems , 2016, IEEE Journal of Quantum Electronics.

[13]  Lochan Verma,et al.  Wifi on steroids: 802.11AC and 802.11AD , 2013, IEEE Wireless Communications.

[14]  国際非電離放射線防護委員会 ICNIRP statement on the "Guidelines for limiting exposure to time-varying electric, magnetic, and electromagnetic fields (up to 300 GHz)". , 2009, Health physics.