Nonlinear Self-Interference Cancellation for Full-Duplex Radios: From Link- and System-Level Performance Perspectives

July 07, 2016 Β· Declared Dead Β· πŸ› IEEE Communications Magazine

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Authors Min Soo Sim, MinKeun Chung, Dongkyu Kim, Jaehoon Chung, Dong Ku Kim, Chan-Byoung Chae arXiv ID 1607.01912 Category cs.IT: Information Theory Cross-listed cs.NI Citations 126 Venue IEEE Communications Magazine Last Checked 4 months ago
Abstract
One of the promising technologies for LTE Evolution is full-duplex radio, an innovation is expected to double the spectral efficiency. To realize full-duplex in practice, the main challenge is overcoming self-interference, and to do so, researchers have developed self-interference cancellation techniques. Since most wireless transceivers use power amplifiers, especially in cellular systems, researchers have revealed the importance of nonlinear self-interference cancellation. In this article, we first explore several nonlinear digital self-interference cancellation techniques. We then propose a low complexity pre-calibration-based nonlinear digital self-interference cancellation technique. Next we discuss issues about reference signal allocation and the overhead of each technique. For performance evaluations, we carry out extensive measurements through a real-time prototype and link-/system-level simulations. For link-level analysis, we measure the amount of cancelled self-interference for each technique. We also evaluate system-level performances through 3D ray-tracing-based simulations. Numerical results confirm the significant performance improvement over a half-duplex system even in interference-limited indoor environments.
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