Browsing by Subject "GNSS receivers"
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Item Advances in GNSS Equipment(2010) Humphreys, Todd E.Item Civilian GPS Spoofing Detection based on DualReceiver Correlation of Military Signals(2011) Psiaki, Mark L.; O'Hanlon, Brady W.; Bhatti, Jahshan A.; Shepard, Daniel P.; Humphreys, Todd E.Cross-correlations of unknown encrypted signals between two civilian GNSS receivers are used to detect spoofing of known open-source signals. This type of detection algorithm is the strongest known defense against sophisticated spoofing attacks if the defended receiver has only one antenna. The attack strategy of concern starts by overlaying false GNSS radio-navigation signals exactly on top of the true signals. The false signals increase in power, lift the receiver tracking loops off of the true signals, and then drag the tracking loops and the navigation solution to erroneous, but consistent results. This paper develops codeless and semi-codeless spoofing detection methods for use in inexpensive, narrow-band civilian GNSS receivers. Detailed algorithms and analyses are developed that use the encrypted military P(Y) code on the L1 GPS frequency in order to defend the open-source civilian C/A code. The new detection techniques are similar to methods used in civilian dualfrequency GPS receivers to track the P(Y) code on L2 by cross-correlating it with P(Y) on L1. Successful detection of actual spoofing attacks is demonstrated by off-line processing of digitally recorded RF data. The codeless technique can detect attacks using 1.2 sec of correlation, and the semi-codeless technique requires correlation intervals of 0.2 sec or less. This technique has been demonstrated in a narrow-band receiver with a 2.5 MHz bandwidth RF front-end that attenuates the P(Y) code by 5.5 dB.Item GNSS Receiver Implementation on a DSP: Status, Challenges, and Prospects(2006) Humphreys, Todd E.; Psiaki, Mark L.; Kintner, Paul M.; Ledvina, Brent M.A real-time GPS L1 C/A-code software receiver has been implemented on a Digital Signal Processor (DSP). The receiver exploits FFT-based techniques to perform autonomous acquisition down to a threshold of C/N0 = 33 dB-Hz. Efficient correlation algorithms and robust tracking loops enable the receiver to track an equivalent of 43 L1 C/A-code channels in real time with a tracking threshold of 25 dB-Hz. This accomplishment represents a milestone in an ongoing effort to develop a low-cost, flexible, and capable GNSS receiver for use as a scientific instrument and for GNSS receiver technology development. This paper reports on the current design and capability of the DSPbased receiver, provides an overview of the challenges that are particular to embedded GNSS software receiver design, and discusses the prospects of DSP-based GNSS software receivers in relation to the multiple frequencies and higher bandwidths offered by modernized GNSS.Item The GPS Assimilator: a Method for Upgrading Existing GPS User Equipment to Improve Accuracy, Robustness, and Resistance to Spoofing(2011) Humphreys, Todd E.; Bhatti, Jahshan A.; Ledvina, Brent M.A conceptual method is presented for upgrading existing GPS user equipment, without requiring hardware or software modifications to the equipment, to improve the equipment’s position, velocity, and time (PVT) accuracy, to increase its PVT robustness in weak-signal or jammed environments, and to protect the equipment from counterfeit GPS signals (GPS spoofing). The method is embodied in a device called the GPS Assimilator that couples to the radio frequency (RF) input of an existing GPS receiver. The Assimilator extracts navigation and timing information from RF signals in its environment—including non-GNSS signals—and from direct baseband aiding provided, for example, by an inertial navigation system, a frequency reference, or the GPS user. The Assimilator optimally fuses the collective navigation and timing information to produce a PVT solution which, by virtue of the diverse navigation and timing sources on which it is based, is highly accurate and inherently robust to GPS signal obstruction and jamming. The Assimilator embeds the PVT solution in a synthesized set of GPS signals and injects these into the RF input of a target GPS receiver for which an accurate and robust PVT solution is desired. A prototype software-defined Assimilator device is presented with three example applications.Item Opportunistic Frequency Stability Transfer for Extending the Coherence Time of GNSS Receiver Clocks(2010-09-24) Wesson, Kyle D.; Pesyna, Kenneth M. Jr; Bhatti, Jahshan A.; Humphreys, Todd E.