Development of a networked photonic‐enabled staring radar testbed for urban surveillance

Mohammed Jahangir; Darren Griffiths; Daniel White; Gwynfor Donlan; Xiaofei Ren; Jithin Kannanthara; Yeshpal Singh; Joseph P. Wayman; Chris J. Baker; Jon P. Sadler; Jim Reynolds; Michail Antoniou

doi:10.1049/rsn2.12524

Development of a networked photonic‐enabled staring radar testbed for urban surveillance

Mohammed Jahangir^*, Darren Griffiths, Daniel White, Gwynfor Donlan, Xiaofei Ren, Jithin Kannanthara, Yeshpal Singh, Joseph P. Wayman, Chris J. Baker, Jon P. Sadler, Jim Reynolds, Michail Antoniou

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

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Abstract

Urban surveillance of slow-moving small targets such as drones and birds in low to medium airspace using radar presents significant challenges. Detecting, locating and identifying such low observable targets in strong clutter requires both innovation in radar hardware design and optimisation of processing algorithms. To this end, the University of Birmingham (UoB) has set-up a testbed of two L-band staring radars to support performance benchmarking using datasets of target and clutter from realistic urban environment. This testbed is also providing the vehicle to understand how novel radar architectures can enhance radar capabilities. Some of the challenges in installing the radar at the UoB campus are highlighted. Detailed benchmarking results are provided from urban monostatic and bistatic field trials that form the basis for performance comparison against future hardware modification. The solution to the challenge of interfacing the radar to the external oscillators is described and stand-alone bench tests with the candidate oscillators are reported. The testbed provides a valuable capability to undertake detailed analysis of performance of Quantum photonic-enabled radar and allows for its comparison with conventional oscillator technology for surveillance of low observable targets in the presence of urban clutter.

Original language	English
Number of pages	15
Journal	IET Radar, Sonar & Navigation
Early online date	19 Dec 2023
DOIs	https://doi.org/10.1049/rsn2.12524
Publication status	E-pub ahead of print - 19 Dec 2023

Bibliographical note

ACKNOWLEDGEMENTS
The work is funded by the UK National Quantum Technology Hub in Sensing and Timing (EP/T001046/1) and the EPSRC MEFA (EP/T011068/1) projects. The authors are grateful to Thales for helping with installing the radar and their ongoing engagement with the research work supported by the testbed.

Keywords

Doppler radar
micro Doppler
radar clutter
radar target recognition
radar
doppler radar
micro doppler

Access to Document

10.1049/rsn2.12524Licence: Creative Commons: Attribution (CC BY)

JahangirM2023DevelopmentFinal published version, 7.56 MBLicence: Creative Commons: Attribution (CC BY)

1 Finished
1 Active

UK National Quantum Technology Hub in Sensing and Timing
Attallah, M., Jones, R., Metje, N., Constantinou, C., Roberts, C., Faramarzi, A., Singh, Y., Holynski, M., Bongs, K., Baker, C. & Antoniou, M.
Engineering & Physical Science Research Council
1/12/19 → 30/11/24
Project: Research Councils
MEFA: Mapping and Enabling Future Airspace
Reynolds, J., Antoniou, M., Sadler, J., Baker, C. & Baker, C.
Engineering & Physical Science Research Council
1/04/20 → 31/03/24
Project: Research Councils

Cite this

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title = "Development of a networked photonic‐enabled staring radar testbed for urban surveillance",

abstract = "Urban surveillance of slow-moving small targets such as drones and birds in low to medium airspace using radar presents significant challenges. Detecting, locating and identifying such low observable targets in strong clutter requires both innovation in radar hardware design and optimisation of processing algorithms. To this end, the University of Birmingham (UoB) has set-up a testbed of two L-band staring radars to support performance benchmarking using datasets of target and clutter from realistic urban environment. This testbed is also providing the vehicle to understand how novel radar architectures can enhance radar capabilities. Some of the challenges in installing the radar at the UoB campus are highlighted. Detailed benchmarking results are provided from urban monostatic and bistatic field trials that form the basis for performance comparison against future hardware modification. The solution to the challenge of interfacing the radar to the external oscillators is described and stand-alone bench tests with the candidate oscillators are reported. The testbed provides a valuable capability to undertake detailed analysis of performance of Quantum photonic-enabled radar and allows for its comparison with conventional oscillator technology for surveillance of low observable targets in the presence of urban clutter. ",

keywords = "Doppler radar, micro Doppler, radar clutter, radar target recognition, radar, doppler radar, micro doppler",

author = "Mohammed Jahangir and Darren Griffiths and Daniel White and Gwynfor Donlan and Xiaofei Ren and Jithin Kannanthara and Yeshpal Singh and Wayman, {Joseph P.} and Baker, {Chris J.} and Sadler, {Jon P.} and Jim Reynolds and Michail Antoniou",

note = "ACKNOWLEDGEMENTS The work is funded by the UK National Quantum Technology Hub in Sensing and Timing (EP/T001046/1) and the EPSRC MEFA (EP/T011068/1) projects. The authors are grateful to Thales for helping with installing the radar and their ongoing engagement with the research work supported by the testbed.",

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doi = "10.1049/rsn2.12524",

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journal = "IET Radar, Sonar & Navigation",

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AU - Jahangir, Mohammed

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AU - Donlan, Gwynfor

AU - Ren, Xiaofei

AU - Kannanthara, Jithin

AU - Singh, Yeshpal

AU - Wayman, Joseph P.

AU - Baker, Chris J.

AU - Sadler, Jon P.

AU - Reynolds, Jim

AU - Antoniou, Michail

N1 - ACKNOWLEDGEMENTS The work is funded by the UK National Quantum Technology Hub in Sensing and Timing (EP/T001046/1) and the EPSRC MEFA (EP/T011068/1) projects. The authors are grateful to Thales for helping with installing the radar and their ongoing engagement with the research work supported by the testbed.

PY - 2023/12/19

Y1 - 2023/12/19

N2 - Urban surveillance of slow-moving small targets such as drones and birds in low to medium airspace using radar presents significant challenges. Detecting, locating and identifying such low observable targets in strong clutter requires both innovation in radar hardware design and optimisation of processing algorithms. To this end, the University of Birmingham (UoB) has set-up a testbed of two L-band staring radars to support performance benchmarking using datasets of target and clutter from realistic urban environment. This testbed is also providing the vehicle to understand how novel radar architectures can enhance radar capabilities. Some of the challenges in installing the radar at the UoB campus are highlighted. Detailed benchmarking results are provided from urban monostatic and bistatic field trials that form the basis for performance comparison against future hardware modification. The solution to the challenge of interfacing the radar to the external oscillators is described and stand-alone bench tests with the candidate oscillators are reported. The testbed provides a valuable capability to undertake detailed analysis of performance of Quantum photonic-enabled radar and allows for its comparison with conventional oscillator technology for surveillance of low observable targets in the presence of urban clutter.

AB - Urban surveillance of slow-moving small targets such as drones and birds in low to medium airspace using radar presents significant challenges. Detecting, locating and identifying such low observable targets in strong clutter requires both innovation in radar hardware design and optimisation of processing algorithms. To this end, the University of Birmingham (UoB) has set-up a testbed of two L-band staring radars to support performance benchmarking using datasets of target and clutter from realistic urban environment. This testbed is also providing the vehicle to understand how novel radar architectures can enhance radar capabilities. Some of the challenges in installing the radar at the UoB campus are highlighted. Detailed benchmarking results are provided from urban monostatic and bistatic field trials that form the basis for performance comparison against future hardware modification. The solution to the challenge of interfacing the radar to the external oscillators is described and stand-alone bench tests with the candidate oscillators are reported. The testbed provides a valuable capability to undertake detailed analysis of performance of Quantum photonic-enabled radar and allows for its comparison with conventional oscillator technology for surveillance of low observable targets in the presence of urban clutter.

KW - Doppler radar

KW - micro Doppler

KW - radar clutter

KW - radar target recognition

KW - radar

KW - doppler radar

KW - micro doppler

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DO - 10.1049/rsn2.12524

M3 - Article

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JO - IET Radar, Sonar & Navigation

JF - IET Radar, Sonar & Navigation

ER -

Development of a networked photonic‐enabled staring radar testbed for urban surveillance

Abstract

Bibliographical note

Keywords

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Projects

UK National Quantum Technology Hub in Sensing and Timing

MEFA: Mapping and Enabling Future Airspace

Cite this