Relevant bibliographies by topics / Mass Market GNSS receiver

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Academic literature on the topic 'Mass Market GNSS receiver'

Author: Grafiati
Published: 14 March 2023

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Journal articles on the topic "Mass Market GNSS receiver"

1

Bhuiyan, Mohammad, Nunzia Ferrara, Amin Hashemi, Sarang Thombre, Michael Pattinson, and Mark Dumville. "Impact Analysis of Standardized GNSS Receiver Testing against Real-World Interferences Detected at Live Monitoring Sites." Sensors 19, no. 6 (March 13, 2019): 1276. http://dx.doi.org/10.3390/s19061276.

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GNSS-based applications are susceptible to different threats, including radio frequency interference. Ensuring that the new applications can be validated against the latest threats supports the wider adoption and success of GNSS in higher value markets. Therefore, the availability of standardized GNSS receiver testing procedures is central to developing the next generation of receiver technologies. The EU Horizon2020 research project STRIKE3 (Standardization of GNSS Threat reporting and Receiver testing through International Knowledge Exchange, Experimentation and Exploitation) proposed standardized test procedures to validate different categories of receivers against real-world interferences, detected at different monitoring sites. This paper describes the recorded interference signatures, their use in standardized test procedures, and analyzes the result for two categories of receivers, namely mass-market and professional grade. The result analysis in terms of well-defined receiver key performance indicators showed that performance of both receiver categories was degraded by the selected interference threats, although there was considerable difference in degree and nature of their impact.
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Yousif, Tasneem, and Paul Blunt. "Interference Mitigation for GNSS Receivers Using FFT Excision Filtering Implemented on an FPGA." Eng 3, no. 4 (October 31, 2022): 439–66. http://dx.doi.org/10.3390/eng3040032.

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GNSS receivers process signals with very low received power levels (<−160 dBW) and, therefore GNSS signals are susceptible to interference. Interference mitigation algorithms have become common in GNSS receiver designs in both professional and mass-market applications to combat both unintentional and intentional (jamming) interference. Interference excision filters using fast Fourier transforms (FFTs) have been proposed in the past as a powerful method of interference mitigation. However, the hardware implementations of this algorithm mostly limited their use to military GNSS receivers where greater power and resources were available. Novel implementation of existing FPGA technology should make interference mitigation feasible with limited hardware resources. This paper details the practicalities of implementing excision filters on currently available FPGAs trading off the achievable performance against the required hardware resources. The hardware implementation of the FFT excision mitigation algorithm is validated with the GNSS software receiver. The results indicate that the desired performance of the developed algorithm has achieved the expectations and can provide significant improvement on mitigation techniques in current GNSS receiver hardware. Two hardware implementation designs (fixed-point and float-point data type format) are developed and compared to achieve the optimal design that can provide the best performance with the possible minimum hardware resources.
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Dabove, Paolo, Vincenzo Di Pietra, and Marco Piras. "GNSS Positioning Using Mobile Devices with the Android Operating System." ISPRS International Journal of Geo-Information 9, no. 4 (April 7, 2020): 220. http://dx.doi.org/10.3390/ijgi9040220.

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The access and the use of the global navigation satellite system (GNSS) pseudo-range and carrier-phase measurements mobile devices as smartphones and tablets with an Android operating system has transformed the concept of accurate positioning with mobile devices. In this work, the comparison of positioning performances obtained with a smartphone and an external mass-market GNSS receiver both in real-time and post-processing is made. Particular attention is also paid to accuracy and precision of positioning results, also analyzing the possibility of estimating the phase ambiguities as integer values (fixed positioning) that it is still challenging for mass-market devices. The precisions and accuracies obtained with the mass-market receiver were about 5 cm and 1 cm both for real-time and post-processing solutions, respectively, while those obtained with a smartphone were slightly worse (few meters in some cases) due to the noise of its measurements.
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Pham, Khai Cong, Hai Van Nguyen, and Nghia Viet Nguyen. "Investigation in designing and developing the GNSS positioning instrumentation used in measurement and mapping by CORS/RTK technology." Journal of Mining and Earth Sciences 63, no. 1 (February 28, 2022): 63–72. http://dx.doi.org/10.46326/jmes.2022.63(1).06.

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Currently, in addition to GNSS receivers manufactured by foreign companies and imported into Vietnam, there are some domestically produced products with lower prices on the market. This paper presents an investigation on the design and development of a low-cost and high-precision GNSS device, used for CORS/RTK measurement in establishing topographic and cadastral maps. The developed GNSS device consists of a GNSS satellite antenna, a receiver, and an electronic field-book (using a smartphone device) installed with a self - developed software. The GNSS receiver is developed based on the technology and equipment of Drotek company (France). The components of the GNSS receiver have been selected and designed with functionality for both dynamic and static measurement modes. The GNSS receiver and electronic field-book are connected wirelessly via the Bluetooth module, allowing convenient operation with the receiver. Experiments were conducted to measure the parallel points of an established geodetic network using GPS technology. The possitioning data was measured by two receivers, South’s S82 (China) and self-developed KX20-R, using RTK method with a single CORS station installed at the University of Mining and Geology. The results showed that the developed GNSS positioning device provides an accuracy of centimeters and completely meet the requirements of large-scale topographic and cadastral surveying and mapping.
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Hernández-Pajares, Manuel, Germán Olivares-Pulido, Victoria Graffigna, Alberto García-Rigo, Haixia Lyu, David Roma-Dollase, M. de Lacy, et al. "Wide-Area GNSS Corrections for Precise Positioning and Navigation in Agriculture." Remote Sensing 14, no. 16 (August 9, 2022): 3845. http://dx.doi.org/10.3390/rs14163845.

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This paper characterizes, with static and roving GNSS receivers in the context of precision agriculture research, the hybrid ionospheric-geodetic GNSS model Wide-Area Real-Time Kinematics (WARTK), which computes and broadcasts real-time corrections for high-precision GNSS positioning and navigation within sparse GNSS receiver networks. This research is motivated by the potential benefits of the low-cost precise WARTK technique on mass-market applications such as precision agriculture. The results from two experiments summarized in this work, the second one involving a working spraying tractor, show, firstly, that the corrections from the model are in good agreement with the corrections provided by IGS (International GNSS Services) analysis centers computed in post-processing from global GNSS data. Moreover, secondly and most importantly, we have shown that WARTK provides navigation solutions at decimeter-level accuracy, and the ionospheric corrections significantly reduce the computational time for ambiguity estimation: up to convergence times for the 50%, 75% and 95% of cases equal or below 30 s (single-epoch), 150 s and 600 s approximately, vs. 1000 s, 2750 s and 4850 s without ionospheric corrections, everything for a roving receiver at more than 100 km far away from the nearest permanent receiver. The real-time horizontal position errors reach up to 3 cm, 5 cm and 12 cm for 50%, 75% and 95% of cases, respectively, by constraining and continuously updating the ambiguities without updating the permanent receiver coordinates, vs. the 6 cm, 12 cm and 32 cm, respectively, in the same conditions but without WARTK ionospheric corrections.
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Marcinek, Krzysztof, and Witold A. Pleskacz. "GNSS-ISE: Instruction Set Extension for GNSS Baseband Processing." Sensors 20, no. 2 (January 14, 2020): 465. http://dx.doi.org/10.3390/s20020465.

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This work presents the results of research toward designing an instruction set extension dedicated to Global Navigation Satellite System (GNSS) baseband processing. The paper describes the state-of-the-art techniques of GNSS receiver implementation. Their advantages and disadvantages are discussed. Against this background, a new versatile instruction set extension for GNSS baseband processing is presented. The authors introduce improved mechanisms for instruction set generation focused on multi-channel processing. The analytical approach used by the authors leads to the introduction of a GNSS-instruction set extension (ISE) for GNSS baseband processing. The developed GNSS-ISE is simulated extensively using PC software and field-programmable gate array (FPGA) emulation. Finally, the developed GNSS-ISE is incorporated into the first-in-the-world, according to the authors’ best knowledge, integrated, multi-frequency, and multi-constellation microcontroller with embedded flash memory. Additionally, this microcontroller may serve as an application processor, which is a unique feature. The presented results show the feasibility of implementing the GNSS-ISE into an embedded microprocessor system and its capability of performing baseband processing. The developed GNSS-ISE can be implemented in a wide range of applications including smart IoT (internet of things) devices or remote sensors, fostering the adaptation of multi-frequency and multi-constellation GNSS receivers to the low-cost consumer mass-market.
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Tunini, Lavinia, David Zuliani, and Andrea Magrin. "Applicability of Cost-Effective GNSS Sensors for Crustal Deformation Studies." Sensors 22, no. 1 (January 4, 2022): 350. http://dx.doi.org/10.3390/s22010350.

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The geodetic monitoring of the continuous crustal deformation in a particular region has traditionally been the prerogative of the scientific communities capable of affording high-price geodetic-class instruments to track the tiny movements of tectonic plates without losing precision. However, GNSS technology has been continuously and rapidly growing, and in the last years, new cost-efficient instruments have entered the mass market, gaining the attention of the scientific community for potentially being high-performing alternative solutions. In this study, we match in parallel a dual-frequency low-cost receiver with two high-price geodetic instruments, all connected to the same geodetic antenna. We select North-East Italy as testing area, and we process the data together with the observations coming from a network of GNSS permanent stations operating in this region. We show that mm-order precision can be achieved by cost-effective GNSS receivers, while the results in terms of time series are largely comparable to those obtained using high-price geodetic receivers.
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Dimc, Franc, Polona Pavlovčič-Prešeren, and Matej Bažec. "Robustness against Chirp Signal Interference of On-Board Vehicle Geodetic and Low-Cost GNSS Receivers." Sensors 21, no. 16 (August 4, 2021): 5257. http://dx.doi.org/10.3390/s21165257.

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Robust autonomous driving, as long as it relies on satellite-based positioning, requires carrier-phase-based algorithms, among other types of data sources, to obtain precise and true positions, which is also primarily true for the use of GNSS geodetic receivers, but also increasingly true for mass-market devices. The experiment was conducted under line-of-sight conditions on a straight road during a period of no traffic. The receivers were positioned on the roof of a car travelling at low speed in the presence of a static jammer, while kinematic relative positioning was performed with the static reference base receiver. Interference mitigation techniques in the GNSS receivers used, which were unknown to the authors, were compared using (a) the observed carrier-to-noise power spectral density ratio as an indication of the receivers’ ability to improve signal quality, and (b) the post-processed position solutions based on RINEX-formatted data. The observed carrier-to-noise density generally exerts the expected dependencies and leaves space for comparisons of applied processing abilities in the receivers, while conclusions on the output data results comparison are limited due to the non-synchronized clocks of the receivers. According to our current and previous results, none of the GNSS receivers used in the experiments employs an effective type of complete mitigation technique adapted to the chirp jammer.
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Wang, Shengliang, Xianshu Dong, Genyou Liu, Ming Gao, Wenhao Zhao, Dong Lv, and Shilong Cao. "Low-Cost Single-Frequency DGNSS/DBA Combined Positioning Research and Performance Evaluation." Remote Sensing 14, no. 3 (January 26, 2022): 586. http://dx.doi.org/10.3390/rs14030586.

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In recent years, low-cost single-frequency GNSS receivers have been widely used in many fields such as mass navigation and deformation monitoring; however, due to the poor signal quality of low-cost patch antennae, it is difficult for carrier phase real-time kinematic (RTK) technology to fix the integer ambiguity. Differential GNSS (DGNSS) positioning with pseudorange can effectively meet the high robustness and reliability requirements for the submeter to the meter level positioning accuracy of UVA/vehicle/aerospace users. To improve the DGNSS positioning accuracy and reliability of low-cost single-frequency GNSS receivers in complex environments, we propose a differential barometric altimetry (DBA)-assisted DGNSS positioning algorithm, which solves the DGNSS observation equations jointly and rigorously with the Earth ellipsoidal constraint equations constructed by the DBA altitude. The DBA altitude accuracy at different baseline lengths was evaluated in detail, and the DGNSS positioning performance of the single-frequency low-cost u-blox receiver NEO-M8T with a patch antenna and DGNSS/DBA combined positioning performance with the BMP280 barometer was analyzed by several sets of static and dynamic experiments under different environments. The results show that the single-frequency NEO-M8T receiver with patch antenna DGNSS positioning accuracy is submeter level in the static environment and drops to meter level in the dynamic environment. GPS+BDS dual system has higher positioning accuracy than single GPS or single BDS. DGNSS/DBA combination has higher positioning accuracy than DGNSS, especially the root mean square error (RMSE) can be improved by 30% to 80% in the U direction and slightly improved in the N and E directions. This study can provide an effective solution reference for various applications of low-cost sensor fusion positioning in the mass consumer market.
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Ding, Wei, Wei Sun, Yang Gao, and Jiaji Wu. "Carrier Phase-Based Precise Heading and Pitch Estimation Using a Low-Cost GNSS Receiver." Remote Sensing 13, no. 18 (September 12, 2021): 3642. http://dx.doi.org/10.3390/rs13183642.

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Attitude and heading estimation methods using the global navigation satellite system (GNSS) are generally based on multi-antenna deployment, where the installation space and system cost increase with the increase in the number of antennas. Since the single-antenna receiver is still the major choice of the mass market, we focus on precise and reliable heading and pitch estimation using a low-cost GNSS receiver. Carrier phase observations are precise but have an ambiguity problem. A single difference between consecutive epochs can eliminate ambiguity and reduce the measurement errors. In this work, a measurement model based on the time-differenced carrier phases (TDCPs) is utilized to estimate the precise delta position of the antenna between two consecutive epochs. Then, considering the motion constraint, the heading and pitch angles of a moving land vehicle can be determined by the components of the estimated receiver delta position. A threshold on the length of the delta position is selected to avoid large errors in static periods. To improve the reliability of the algorithm, the Doppler-aided cycle slip detection method is applied to exclude carrier phases with possible cycle slips. A real vehicular dynamic experiment using a low-cost, single-frequency GNSS receiver is conducted to evaluate the proposed algorithm. The experimental results show that the proposed algorithm is capable of providing precise vehicular heading and pitch estimates, with both the root mean square errors being better than 1.5°. This also indicates that the cycle slip exclusion is indispensable to avoid unexpected large errors.
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Book chapters on the topic "Mass Market GNSS receiver"

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Dabove, Paolo, Ambrogio M. Manzino, Alberto Cina, Marco Piras, and Iosif H. Bendea. "Toward Real-time Geodetic Monitoring of Landslides with GNSS Mass-market Devices." In Applied Geology, 227–43. Cham: Springer International Publishing, 2020. http://dx.doi.org/10.1007/978-3-030-43953-8_14.

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Chen, Jinpei, Jun Wang, Denghui Wang, Wen Zhao, Hua Chang, and Shaojun Feng. "Instantaneous Centimeter-Level PPP-RTK Positioning Technology Based on Low-Cost Mass Market GNSS Devices." In Lecture Notes in Electrical Engineering, 384–92. Singapore: Springer Nature Singapore, 2022. http://dx.doi.org/10.1007/978-981-19-2588-7_36.

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Grombein, Thomas, Martin Lasser, Daniel Arnold, Ulrich Meyer, and Adrian Jäggi. "Determination and Combination of Monthly Gravity Field Time Series from Kinematic Orbits of GRACE, GRACE-FO and Swarm." In International Association of Geodesy Symposia. Berlin, Heidelberg: Springer Berlin Heidelberg, 2022. http://dx.doi.org/10.1007/1345_2022_163.

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AbstractDedicated gravity field missions like GRACE and GRACE-FO use ultra-precise inter-satellite ranging observations to derive time series of monthly gravity field solutions. In addition, any (non-dedicated) Low Earth Orbiting (LEO) satellite with a dual-frequency GNSS receiver may also serve as a gravity field sensor. To this end, GPS-derived kinematic LEO orbit positions are used as pseudo-observations for gravity field recovery. Although less sensitive, this technique can provide valuable information for the monitoring of large-scale time-variable gravity signals, particularly for those months where no inter-satellite ranging measurements are available. Due to a growing number of LEO satellites that collect continuous and mostly uninterrupted GPS data, the value of a combined multi-LEO gravity field time series is likely to increase in the near future.In this paper, we present monthly gravity field time series derived from GPS-based kinematic orbit positions of the GRACE, GRACE-FO and Swarm missions. We analyze their individual contribution as well as the additional benefit of their combination. For this purpose, two combination strategies at solution level are studied that are based on(i) least-squares variance component estimation, and(ii) stochastic properties of the gravity field solutions.By evaluating mass variations in Greenland and the Amazon river basin, the resulting gravity field time series are assessed with respect to superior solutions based on inter-satellite ranging.
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Conference papers on the topic "Mass Market GNSS receiver"

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Kappen, G., C. Haettich, and M. Meurer. "Towards a robust multi-antenna mass market GNSS receiver." In 2012 IEEE/ION Position, Location and Navigation Symposium - PLANS 2012. IEEE, 2012. http://dx.doi.org/10.1109/plans.2012.6236894.

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Overbeck, Matthias, Gunter Rohmer, Elmar Wasle, Hans-Jurgen Euler, and Andreas Kahmann. "Galileo receiver for Mass Market Applications in the automotive area." In European Workshop on GNSS Signals and Signal Processing. IEEE, 2010. http://dx.doi.org/10.1109/navitec.2010.5708064.

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Linty, Nicola, and Paolo Crosta. "Code and frequency estimation in Galileo mass market receivers." In 2013 International Conference on Localization and GNSS (ICL-GNSS). IEEE, 2013. http://dx.doi.org/10.1109/icl-gnss.2013.6577262.

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Di Grazia, Domenico, Damien Cardineau, and Fabio Pisoni. "A NAVIC Enabled Hardware Receiver for the Indian Mass Market." In 32nd International Technical Meeting of the Satellite Division of The Institute of Navigation (ION GNSS+ 2019). Institute of Navigation, 2019. http://dx.doi.org/10.33012/2019.16979.

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Chaloupka, Zdenek, Lionel Ries, Andrea Samperi, Pierre Waller, and Massimo Crisci. "Phase synchronization for 5G using mass market GNSS receivers." In 2018 European Frequency and Time Forum (EFTF). IEEE, 2018. http://dx.doi.org/10.1109/eftf.2018.8409030.

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McBurney, Paul, Norman Krasner, Dominic Farmer, Chang Row, Lalit Daita, and Nagaraj Shivaramaiah. "Characteristics of a Mass Market GNSS Receiver Using Signals in the E5 Band." In 35th International Technical Meeting of the Satellite Division of The Institute of Navigation (ION GNSS+ 2022). Institute of Navigation, 2022. http://dx.doi.org/10.33012/2022.18412.

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Diep, Johann, David Gomez-Casco, Xurxo Otero Villamide, Richard Dennis Swinden, and Paolo Crosta. "Performance Analysis of Mass-Market GNSS Receivers in UAV Applications." In 2022 10th Workshop on Satellite Navigation Technology (NAVITEC). IEEE, 2022. http://dx.doi.org/10.1109/navitec53682.2022.9847551.

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Henkel, Patrick, Philipp Berthold, and Jane Jean Kiam. "Calibration of magnetic field sensors with two mass-market GNSS receivers." In 2014 11th Workshop on Positioning, Navigation and Communication (WPNC). IEEE, 2014. http://dx.doi.org/10.1109/wpnc.2014.6843306.

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Cina, A., P. Dabove, A. M. Manzino, and M. Piras. "Augmented positioning with CORSs network services using GNSS mass-market receivers." In 2014 IEEE/ION Position, Location and Navigation Symposium - PLANS 2014. IEEE, 2014. http://dx.doi.org/10.1109/plans.2014.6851393.

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Hoque, M. Mainul, Norbert Jakowski, Okuary Osechas, and Jens Berdermann. "Fast and Improved Ionospheric Correction for Galileo Mass Market Receivers." In 32nd International Technical Meeting of the Satellite Division of The Institute of Navigation (ION GNSS+ 2019). Institute of Navigation, 2019. http://dx.doi.org/10.33012/2019.17106.

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