Björn Debaillie scite author profile

In-band full-duplex sets challenging requirements for wireless communication radios, in particular their capability to prevent receiver sensitivity degradation due to self-interference (transmit signals leaking into its own receiver). Previously published self-interference rejection designs require bulky components and/or antenna structures. This paper addresses this form-factor issue. First, compact radio transceiver feasibility bottlenecks are identified analytically, and tradeoff equations in function of link budget parameters are presented. These derivations indicate that the main bottlenecks can be resolved by increasing the isolation in analog/RF. Therefore, two design ideas are proposed, which provide attractive analog/RF-isolation and allow integration in compact radios. The first design proposal targets compact radio devices, such as small-cell base stations and tablet computers, and combines a dual-port polarized antenna with a self-tunable cancellation circuit. The second design proposal targets even more compact radio devices such as smartphones and sensor network nodes. This design builds on a tunable electrical balance isolator/duplexer in combination with a single-port miniature antenna. The electrical balance circuit can be implemented for scaled CMOS technology, facilitating low cost and dense integration.Index Terms-In-band full-duplex, self-interference isolation, dual polarized antenna, tunable duplexer, electrical balance, transceiver macro-modeling.

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Flexible power modeling of LTE base stations

Desset

et al. 2012

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Abstract-With the explosion of wireless communications in number of users and data rates, the reduction of network power consumption becomes more and more critical. This is especially true for base stations which represent a dominant share of the total power in cellular networks. In order to study power reduction techniques, a convenient power model is required, providing estimates of the power consumption in different scenarios. This paper proposes such a model, accurate but simple to use. It evaluates the base station power consumption for different types of cells supporting the 3GPP LTE standard. It is flexible enough to enable comparisons between state-of-the-art and advanced configurations, and an easy adaptation to various scenarios. The model is based on a combination of base station components and sub-components as well as power scaling rules as functions of the main system parameters.

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A Flexible and Future-Proof Power Model for Cellular Base Stations

2015

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A 40 nm CMOS 0.4–6 GHz Receiver Resilient to Out-of-Band Blockers

Borremans

Mandal

Giannini

et al. 2011

IEEE J. Solid-State Circuits

144

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Modeling the hardware power consumption of large scale antenna systems

Desset

Debaillie

Louagie

2014

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RF Self-Interference Cancellation for Full-Duplex

Liempd

Debaillie

Craninckx

et al. 2014

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This paper proposes two RF self-interference cancellation techniques. Their small form-factor enables full-duplex communication links for small-to-medium size portable devices and hence promotes the adoption of full-duplex in mass-market applications and next-generation standards, e.g. IEEE802.11 and 5G. Measured prototype implementations of an electrical balance duplexer and a dual-polarized antenna both achieve >50dB self-interference suppression at RF, operating in the ISM band at 2.45GHz.

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A 2-mm$^{2}$ 0.1–5 GHz Software-Defined Radio Receiver in 45-nm Digital CMOS

Giannini

Nuzzo

Soens

et al. 2009

IEEE J. Solid-State Circuits

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A 5 mm$^{2}$ 40 nm LP CMOS Transceiver for a Software-Defined Radio Platform

Ingels

Giannini

Borremans

et al. 2010

IEEE J. Solid-State Circuits

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