Abstract
A two-way tunable power divider for Simultaneous Wireless Information and Power Transfer (SWIPT) is proposed in this paper. The power divider divides the incoming power in such a way that maximum power is utilized for energy harvesting purposes and the rest of the power is used for information decoding purposes. This unequal distribution of power is realized by tuning the varactor diode's reverse biasing voltages. A good matching performance is attained using the radial and short stubs at the input and one of the output ports, respectively. High isolation is achieved with the help of the resistor used for connecting the output ports of the power divider. The achieved power division ratios vary from 13:1 to 28:1. The tunable power divider is designed and fabricated at 2.4 GHz. The bandwidth measured at 10 dB return loss is 3.2 GHz and the isolation better than 12 dB is achieved between the output ports. The designed structure is compact and good consistency is observed between the simulated and measured results. The designed power divider may be used for future 5G wireless networks.
Highlights
Simultaneous wireless information and power transfer (SWIPT) systems are becoming one of the appealing technology because of its ability to extend the lifespan of energy controlled wireless networks
An efficient tunable power divider operating at 2.4 GHz is designed in this paper
The presented power divider is designed for the SWIPT system and it helps in dividing the incoming signal into two signals with unequal power distribution
Summary
Simultaneous wireless information and power transfer (SWIPT) systems are becoming one of the appealing technology because of its ability to extend the lifespan of energy controlled wireless networks. Power splitting technique demands the optimization of the power splitting factor and higher complexity of the receiver but it helps in achieving instantaneous SWIPT because the incoming signal is used for both energy harvesting and information decoding purposes. Tunable power dividers are presented in [5] and [6]; though, they have low tuning capability due to fixed power division ratio.
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