2 research outputs found

    Development of a Robust Wideband GNSS RF Frontend With Resilient Interference Blocking

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    Recently, there has been an increasing demand for GNSS systems’ use for numerous applications such as public security, disaster relief, weather forecast, transportation, hydrologic monitoring, aviation, navigation positions and so on. Such systems must have a wideband performance (1.16 GHz to 1.61 GHz), high quality reception (which requires antenna with low AR, high RHCP gain, high F/B ratio, and high RL), portable size, and low cost. Our efforts here are geared towards the receiving side of such communication. The antennas are the first stage of the long receiver chain. Development of such wideband high quality antennas is challenging as most of the available antennas are limited due to their feed networks bandwidth limitations. Here, we will propose, design, and test various wideband GNSS antennas covering 1.16 GHz to 1.61 GHz. Additionally GNSS reception is susceptible to in-band or out of band intentional/unintentional interference. Relatively high power interference can either saturates the front-end of the receiver, or makes the system useless upon reducing the C/N0 of the received signals-- given that the power level of GNSS signals on earth is significantly lower than the noise level. So, it is essential to attenuate any in-band interfering signal, upon using spatial filtering for example. Using an adaptive system that can operate over the entire GNSS band can reduce the power level of the interference significantly by allocating nulls in their direction. In this dissertation we develop a portable low cost adaptive frontend structure. Meanwhile, to reject any out of band interference, SAW filters are popular, but they have very narrow bandwidth and are not reconfigurable, i.e. meaning that the entire GNSS band will not be covered which is a huge disadvantage. Hence, we propose to develop a reconfigurable filter based on N-path structure as well
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