A Study of GPS Carrier-Phase Time Transfer Noise Based on NIST GPS Receivers

Yao, Jian; Levine, Judah

doi:10.6028/jres.121.017

Cited by 2 publications

(2 citation statements)

References 21 publications

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“…However, the current PPP-based time and frequency transfer techniques cannot meet the standard of optical clocks. To better understand the potential of GNSS in time and frequency, it is necessary to study the impacts of the GNSS algorithm and equipment (Yao and Levine 2016), as this will determine whether GNSS can serve the optical clocks in the future.…”

Section: Introductionmentioning

confidence: 99%

On the potential of undifferenced and uncombined GNSS time and frequency transfer with integer ambiguity resolution and satellite clocks estimated

Zhang

El‐Mowafy

et al. 2022

GPS Solut

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The use of global navigation satellite systems (GNSS) has been a competitive way to provide high-precision and low-cost time and frequency transfer results. However, the traditional GNSS method, the precise point positioning (PPP), is usually based on the ionosphere-free (IF) combination, which is not flexible when applying multi-frequency scenarios. In addition, PPP relies on precise satellite clock products with an accuracy of tens of picoseconds, limiting the time and frequency transfer performance. More importantly, achieving integer ambiguity resolution (IAR) is challenging, which makes high-precision phase observations underutilized. To achieve a better time transfer performance, we must consider all those factors from the GNSS end. In this contribution, a new GNSS time and frequency model at the undifferenced and uncombined (UDUC) level is first derived. In the UDUC model, the satellite clocks are estimated together with other parameters, and the integer ambiguities are resolved in the double-differenced (DD) form for their reliable estimation. Our numerical tests suggest three major findings. First, with integer ambiguities resolved, the UDUC model with satellite clocks fixed showed a 20% to 50% improvement compared with the UDUC PPP model. Second, with IAR and satellite clocks estimated, the proposed UDUC model shows a 10%–40% improvement over the model with satellite clocks fixed. Third, with integer ambiguities resolved and satellite clocks estimated, GPS, Galileo, and BDS-3 all have the potential to achieve frequency transfer in the low-mid $$10^{ - 17}$$ 10 - 17 range for averaging times within one day.

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Section: Introductionmentioning

confidence: 99%

On the potential of undifferenced and uncombined GNSS time and frequency transfer with integer ambiguity resolution and satellite clocks estimated

Zhang

El‐Mowafy

et al. 2022

GPS Solut

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“…While the code-based method is reliable, it is often not very accurate and needs to be supported by other means such as measuring the phase of the carrier wave of the wireless signal if high accuracy is needed [3,4]. Phase measurements have one significant disadvantage in that they are associated with ambiguities that need to be resolved before the delay can be accurately determined.…”

Section: Introductionmentioning

confidence: 99%

Solution for wireless time synchronization using sub-Nyquist sampling rates

Christensen¹,

Merayo²

2020

Meas. Sci. Technol.

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This article presents an accurate low-cost solution for wireless time synchronization between different systems. The results are obtained using commercial-off-the-shelf 2.4 GHz transceiver components and a novel approach to the sampling of pseudo-random number code modulated signals that enables highly accurate estimation of signal arrival times using simple hardware. The method consists of sampling incoming signals at a sub-bit-rate frequency and subsequent data processing that estimates the shape of the pulse-form of each individual data bit. Based on this, the arrival time of the signal can be determined, with estimates achieving higher accuracy with increasing code lengths regardless of bit-rate. This means that accurate measurements can be achieved with modest hardware running at sample rates in the low megahertz range. The developed solution is thereby able to achieve sub-nanosecond resolution using a 32767-bit Gold code modulated signal with a chirp-rate of 3.2767 MHz.

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A Study of GPS Carrier-Phase Time Transfer Noise Based on NIST GPS Receivers

Cited by 2 publications

References 21 publications

On the potential of undifferenced and uncombined GNSS time and frequency transfer with integer ambiguity resolution and satellite clocks estimated

On the potential of undifferenced and uncombined GNSS time and frequency transfer with integer ambiguity resolution and satellite clocks estimated

Solution for wireless time synchronization using sub-Nyquist sampling rates

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