Analog Self-Interference Cancellation With Practical RF Components for Full-Duplex Radios

One of the main obstacles in full-duplex radios is analog-to-digital converter (ADC) saturation on a receiver due to the strong self-interference (SI). To solve this issue, researchers have proposed two different types of analog self-interference cancellation (SIC) methods-i) passive suppression and ii) regeneration-and-subtraction of SI. For the latter case, the tunable RF component, such as a multi-tap circuit, reproduces and subtracts the SI. The resolutions of such RF components constitute the key factor of the analog SIC. Indeed, they are directly related to how well the SI is imitated. Another major issue in analog SIC is the inaccurate estimation of the SI channel due to the nonlinear distortions, which mainly come from the power amplifier (PA). In this paper, we derive a closed-form expression for the SIC performance of the multi-tap circuit; we consider how the RF components must overcome such practical impairments as digitally-controlled attenuators, phase shifters, and PA. For a realistic performance analysis, we exploit the measured PA characteristics and carry out a 3D ray-tracing-based, system-level throughput analysis. Our results confirm that the non-idealities of the RF components significantly affect the analog SIC performance. We believe our study provides insight into the design of the practical full-duplex system.

Automated summary

One of the main obstacles in full-duplex radios is analog-to-digital converter (ADC) saturation on a receiver due to strong self-interference (SI). To solve this issue, researchers have proposed two different types of analog self-interference cancellation (SIC) methods - passive suppression and regeneration-and-subtraction of SI. The resolution of the tunable RF components is a key factor in analog SIC, and accurate estimation of the SI channel is also a major challenge due to nonlinear distortions from the power amplifier (PA). This study provides insight into the design of practical full-duplex systems by deriving a closed-form expression for the SIC performance of a multi-tap circuit and considering practical impairments.