Abstract
One of the major impediments in the design and operation of a full-duplex radio transceiver is the presence of self-interference (SI), that is, the transceiver’s transmitted signal, 60–100 dB stronger than the desired signal of interest. To reduce the SI signal below the receiver’s sensitivity before coupling it to the receiver, radio frequency (RF)/analog domain cancellation is carried out. Even after SI cancellation to the required level in the analog domain, the residual SI signal still exits and lowers the transceiver’s performance. For residual SI cancellation, a digital domain cancellation is carried out. RF impairments are the major obstacle in the residual SI cancellation path in the digital domain. Linearization of RF impairments such as IQ mixer imbalance in the transmitter and receiver chain, non-linear PA with memory, and non-linear LNA are also carried out. Performance evaluation of the proposed techniques is carried out based on SINR, the power of different SI signal components, PSD, output to input relationship, SNR vs. BER, spectrum analyzer, constellation diagram, and link budget analysis. The proposed techniques provide attractive RF/analog SI cancellation of up to 80–90 dB, digital residual SI cancellation of up to 35 to 40 dB, total SI cancellation of up to 110 to 130 dB, and an SINR improvement of up to 50 dB.
Highlights
A full-duplex (FD) communication system represents an attractive substitute to halfduplex (HD) communication systems
In our previous work [69], we investigated the performance and digital SI cancellation using the extended Kalman filter (EKF) and achieved signal to interference plus noise ratio (SINR)
Non-idealities simulated with their linearization techniques are in-phase and quadrature (IQ) mixer imbalance and power amplifier (PA) nonlinearity in the Tx chain and low noise amplifier (LNA) linearity and IQ mixer imbalance in the Rx chain
Summary
A full-duplex (FD) communication system represents an attractive substitute to halfduplex (HD) communication systems. The FD communication system has some advantages over frequency division duplexing (FDD) and time division duplexing (TDD) These include increased spectral efficiency by almost double, sharing single frequency between uplink and downlink, sensing the network traffic during its transmission, improved throughput, and lowering transmission delay. Despite these advantages, the practical realization and implementation of FD radio transceivers still have many challenges. FD technology can be used for the security of civilian wireless communications, i.e., through the use of jamming and receiving wireless signals simultaneously, which can in turn prevent eavesdropping It can help in the prevention of unauthorized usage of the radio spectrum [14]. The FD communication system can be used for military and defense purposes such as Radio Detection and Ranging (RADAR) sensing and RF backscatter
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