Ground-Based Radar Interferometry for Monitoring the Dynamic Performance of a Multitrack Steel Truss High-Speed Railway Bridge

Huang, Qihuan; Wang, Yian; Luzi, G.; Crosetto, Michele; Monserrat, Oriol; Jiang, Jianfeng; Zhao, Hanwei

doi:10.3390/rs12162594

Cited by 19 publications

(16 citation statements)

References 33 publications

(43 reference statements)

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“…A radar interferometer can measure the phase with a sensibility that is a small fraction of its wavelength, while a conventional radar is only capable of measuring the amplitude of the signal received. Therefore, sub-millimeter displacements can be measured by radar interferometry [21]. Fundamentally, GB-radar originates from its spaceborne counterparts [36,37], and it is developed on the basis of two fundamental techniques: Interferometry [38] and Frequency Modulated Continuous Wave (FM-CW) [39,40].…”

Section: Ground-based Radar Interferometrymentioning

confidence: 99%

“…IBIS-S Plus, the most recent version of IBIS-S, is now equipped with a built-in accelerometer to mitigate the effects of possible movement of the radar head, enabling future researchers to acquire data with improved quality. The radar sensor is essentially an FM-CW radar, transmitting a microwave electromagnetic signal at a frequency range of 17.07-17.35 GHz (Ku band) with a maximum bandwidth of 300 MHz, corresponding to a range resolution of 0.5 m [21]. The basic parameters of IBIS-S are listed in Table 3.…”

Section: Ground-based Radar Interferometrymentioning

confidence: 99%

“…Generally, the real aperture GB-radar is only able to real-time acquire 1-dimensional displacement data due to its inability to detect the direction of arrival (DOA) of the echo signal [10] whereas the synthetic aperture GB-radar enables the acquisition of 2-dimensional images [14]. Therefore, the real aperture GB-radar is commonly used to measure spot or line-shaped targets such as chimneys [15,16], high-rise buildings [17,18], and bridges [19][20][21] while the synthetic aperture GB-radar is usually applied to large-scale area targets such as dams [13,22], glaciers [23,24], landslides and rockfalls [25,26]. However, the image acquisition of a synthetic aperture GB-radar takes several seconds or even minutes while a real aperture GB-radar is able to perform hundreds of acquisitions per second, allowing them to monitor vibration frequencies of the target [19].…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

A Comprehensive Analysis of Static and Dynamic Load Tests of a Long-Span Cable-Stayed Bridge with a Ground-Based Radar Interferometer

Chen¹,

Huang²,

Zhang³

et al. 2023

Preprint

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Bridge load testing is crucial in evaluating bridge load-carrying capacity and construction quality. However, conventional techniques have many limitations such as the need for direct contact and low acquisition frequency. This study provides a comprehensive examination of the static and dynamic load tests of a multi-span cable-stayed bridge utilizing a ground-based radar inter-ferometer (GB-radar). The case study was conducted at the Fifth Nanjing Yangtze River Bridge (FNYRB), which is recognized as the world's first lightweight steel-concrete composite cable-stayed bridge, with two spans measuring 600 m. To enhance measurement accuracy, a method was proposed to detect and recover radar phase jumps caused by vehicle motion. Furthermore, precise geometry projection was employed to acquire vertical displacements from GB-radar which were taken along the line-of-sight (LOS) direction. Moreover, during the static load test, a continuous deformation was observed with a maximum pace of 0.31 mm/min, indicating a post-construction settlement caused by soft soil consolidation. This case study highlights the high sampling frequency, high measurement accuracy, and exceptional weatherproof ability of GB-radar, thereby demonstrating its potential to be an alternative to the structural health monitoring (SHM) system.

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Section: Ground-based Radar Interferometrymentioning

confidence: 99%

Section: Ground-based Radar Interferometrymentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

A Comprehensive Analysis of Static and Dynamic Load Tests of a Long-Span Cable-Stayed Bridge with a Ground-Based Radar Interferometer

Chen¹,

Huang²,

Zhang³

et al. 2023

Preprint

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“…For the application of microwave interferometry, good overviews are given by Gentile and Bernardini [ 12 ], Bernardini et al [ 13 ], Rödelsperger et al [ 24 ]. Microwave interferometry has also been applied to various types of structures in recent years: bridges [ 8 , 25 , 26 , 27 , 28 , 29 , 30 , 31 ], wind power plants [ 21 ], telecommunication towers [ 32 , 33 ], chimneys [ 24 ] or urban buildings [ 34 , 35 , 36 ]. Publications dealing with the performance evaluation through comparisons with conventional sensors are, for example, [ 8 , 35 , 37 , 38 ].…”

Section: Investigated Sensorsmentioning

confidence: 99%

Contactless Deformation Monitoring of Bridges with Spatio-Temporal Resolution: Profile Scanning and Microwave Interferometry

Schill

Michel

Firus³

2022

Sensors

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Against the background of an aging infrastructure, the condition assessment process of existing bridges is becoming an ever more challenging task for structural engineers. Short-term measurements and structural monitoring are valuable tools that can lead to a more accurate assessment of the remaining service life of structures. In this context, contactless sensors have great potential, as a wide range of applications can already be covered with relatively little effort and without having to interrupt traffic. In particular, profile scanning and microwave interferometry, have become increasingly important in the research field of bridge measurement and monitoring in recent years. In contrast to other contactless displacement sensors, both technologies enable a spatially distributed detection of absolute structural displacements. In addition, their high sampling rate enables the detection of the dynamic structural behaviour. This paper analyses the two sensor types in detail and discusses their advantages and disadvantages for the deformation monitoring of bridges. It focuses on a conceptual comparison between the two technologies and then discusses the main challenges related to their application in real-world structures in operation, highlighting the respective limitations of both sensors. The findings are illustrated with measurement results at a railway bridge in operation.

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“…GBRAR systems can be suitable for continuously monitoring fast structural displacements, such as mechanical vibration, with a data acquisition rate of a fraction of a second (Rodrigues and Li, 2021). To this end, various case studies, such as bridges (Huang et al, 2020) and buildings (Alva et al, 2020), have been investigated to evaluate GBRAR capabilities for SHM. A study on the feasibility of vibration monitoring of tall structures by combining a laser scanner and GBRAR was presented by Artese and Nico (2020).…”

Section: Introductionmentioning

confidence: 99%

Structural displacement monitoring using ground-based synthetic aperture radar

Hosseiny

Amini

Aghababaei

2023

International Journal of Applied Earth Observation and Geoinfor

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Ground-Based Radar Interferometry for Monitoring the Dynamic Performance of a Multitrack Steel Truss High-Speed Railway Bridge

Cited by 19 publications

References 33 publications

A Comprehensive Analysis of Static and Dynamic Load Tests of a Long-Span Cable-Stayed Bridge with a Ground-Based Radar Interferometer

A Comprehensive Analysis of Static and Dynamic Load Tests of a Long-Span Cable-Stayed Bridge with a Ground-Based Radar Interferometer

Contactless Deformation Monitoring of Bridges with Spatio-Temporal Resolution: Profile Scanning and Microwave Interferometry

Structural displacement monitoring using ground-based synthetic aperture radar

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