Resilience of Deep Space FSO Communication Scenario Involving SNSPD Receiver to Atmospheric Turbulence

Hristo Danchov Ivanov; Peter Pocta; Frank Marzano; Erich Leitgeb; Gert Freiberger

doi:10.1109/TELSIKS46999.2019.9002366

Resilience of Deep Space FSO Communication Scenario Involving SNSPD Receiver to Atmospheric Turbulence

Hristo Danchov Ivanov, Peter Pocta, Frank Marzano, Erich Leitgeb, Gert Freiberger

Institute of Microwave and Photonic Engineering (4510)

Research output: Chapter in Book/Report/Conference proceeding › Conference paper › peer-review

Abstract

Future ground to deep space communication systems should support Gbps data links, which are resilient to atmospheric impairments. An alternative and in the same time complementary to the conventional RF technology is the emerging deep space Free Space Optical (FSO) system, which can successfully face the challenge. Aligned with this future possibility, the current paper reports on a performance of the deep space FSO system based on detailed simulations considering single-photon communication scenario. Among the several available optical receiver units, a state of the art Superconducting Nanowire Single Photon Detector (SNSPD) technology is implemented. The SNSPD is characterized with a quantum efficiency, dead time, dark count rate and number of channels. The investigation is based on the Poisson channel and well-known Pulse Position Modulation (PPM) deployed as a modulation technique. Moreover, the selected receiver aperture diameter provides the necessary resilience to atmospheric turbulence effect. Addressing the sophisticated parameterization of the current simulations, BER performance of the deep space FSO link based on the SNSPD receiver is provided. On the top of it, an output of the SNSPD in RF domain is considered. The sequence of RF output pulses is presented before and after the applied ideal low-pass filter.

Original language	English
Title of host publication	2019 14th International Conference on Advanced Technologies, Systems and Services in Telecommunications (TELSIKS)
Publisher	IEEEXplore
Pages	235-240
ISBN (Electronic)	978-1-7281-0878-0
DOIs	https://doi.org/10.1109/TELSIKS46999.2019.9002366
Publication status	Published - 2019
Event	14th International Conference on Advanced Technologies, Systems and Services in Telecommunications - Nis, Serbia Duration: 23 Oct 2019 → 25 Oct 2019

Conference

Conference	14th International Conference on Advanced Technologies, Systems and Services in Telecommunications
Abbreviated title	TELSIKS 2019
Country/Territory	Serbia
City	Nis
Period	23/10/19 → 25/10/19

Fields of Expertise

Information, Communication & Computing
Advanced Materials Science

Treatment code (Nähere Zuordnung)

Application
Experimental
Theoretical

Access to Document

10.1109/TELSIKS46999.2019.9002366

1 Active
2 Finished

Optoelectronical Communication Engineering
Zettl, K., Plank, T., Nadeem, F., Iqbal, F., Henkel, M., Leitgeb, E., Pezzei, P., Saleem Awan, M., Pock, C., Unterhuber, P., Gebhart, M., Hinteregger, M., Khan, M. S., Chlestil, C., Brandl, P., Sheikh Muhammad, S., Kraus, D., Bekhrad, P., Ivanov, H. D. & Liu, Y.
1/08/95 → 30/09/29
Project: Research area
TRITON - Heterogeneous Integration of Millimeter-Wave Technology
Gadringer, M. E., Romero Lopera, J., Bösch, W., Pezzei, P., Leitgeb, E., Hatab, Z. & Bekhrad, P.
1/05/17 → 30/04/21
Project: Research project
HybridPDT - System Study of Optical Communications with a Hybridised Optical/RF Payload Data Transmitter
Plank, T., Leitgeb, E., Pezzei, P., Ivanov, H. D., Kraus, D. & Bekhrad, P.
1/11/15 → 31/07/20
Project: Research project

1 Conference or symposium (Participation in/Organisation of)
1 Research at external institution

University of Niš
Erich Leitgeb (Visitor)
23 Oct 2019 → 28 Oct 2019
Activity: Visiting an external academic institution › Research at external institution
14th International Conference on Advanced Technologies, Systems and Services in Telecommunications
Erich Leitgeb (Participant)
20 Oct 2019 → 29 Oct 2019
Activity: Participation in or organisation of › Conference or symposium (Participation in/Organisation of)

Cite this

Ivanov, H. D., Pocta, P., Marzano, F., Leitgeb, E., & Freiberger, G. (2019). Resilience of Deep Space FSO Communication Scenario Involving SNSPD Receiver to Atmospheric Turbulence. In 2019 14th International Conference on Advanced Technologies, Systems and Services in Telecommunications (TELSIKS) (pp. 235-240). IEEEXplore. https://doi.org/10.1109/TELSIKS46999.2019.9002366

Resilience of Deep Space FSO Communication Scenario Involving SNSPD Receiver to Atmospheric Turbulence. / Ivanov, Hristo Danchov; Pocta, Peter; Marzano, Frank et al.
2019 14th International Conference on Advanced Technologies, Systems and Services in Telecommunications (TELSIKS). IEEEXplore, 2019. p. 235-240.

Research output: Chapter in Book/Report/Conference proceeding › Conference paper › peer-review

Ivanov, HD, Pocta, P, Marzano, F, Leitgeb, E & Freiberger, G 2019, Resilience of Deep Space FSO Communication Scenario Involving SNSPD Receiver to Atmospheric Turbulence. in 2019 14th International Conference on Advanced Technologies, Systems and Services in Telecommunications (TELSIKS). IEEEXplore, pp. 235-240, 14th International Conference on Advanced Technologies, Systems and Services in Telecommunications, Nis, Serbia, 23/10/19. https://doi.org/10.1109/TELSIKS46999.2019.9002366

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title = "Resilience of Deep Space FSO Communication Scenario Involving SNSPD Receiver to Atmospheric Turbulence",

abstract = "Future ground to deep space communication systems should support Gbps data links, which are resilient to atmospheric impairments. An alternative and in the same time complementary to the conventional RF technology is the emerging deep space Free Space Optical (FSO) system, which can successfully face the challenge. Aligned with this future possibility, the current paper reports on a performance of the deep space FSO system based on detailed simulations considering single-photon communication scenario. Among the several available optical receiver units, a state of the art Superconducting Nanowire Single Photon Detector (SNSPD) technology is implemented. The SNSPD is characterized with a quantum efficiency, dead time, dark count rate and number of channels. The investigation is based on the Poisson channel and well-known Pulse Position Modulation (PPM) deployed as a modulation technique. Moreover, the selected receiver aperture diameter provides the necessary resilience to atmospheric turbulence effect. Addressing the sophisticated parameterization of the current simulations, BER performance of the deep space FSO link based on the SNSPD receiver is provided. On the top of it, an output of the SNSPD in RF domain is considered. The sequence of RF output pulses is presented before and after the applied ideal low-pass filter.",

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year = "2019",

doi = "10.1109/TELSIKS46999.2019.9002366",

language = "English",

pages = "235--240",

booktitle = "2019 14th International Conference on Advanced Technologies, Systems and Services in Telecommunications (TELSIKS)",

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T1 - Resilience of Deep Space FSO Communication Scenario Involving SNSPD Receiver to Atmospheric Turbulence

AU - Ivanov, Hristo Danchov

AU - Pocta, Peter

AU - Marzano, Frank

AU - Leitgeb, Erich

AU - Freiberger, Gert

PY - 2019

Y1 - 2019

N2 - Future ground to deep space communication systems should support Gbps data links, which are resilient to atmospheric impairments. An alternative and in the same time complementary to the conventional RF technology is the emerging deep space Free Space Optical (FSO) system, which can successfully face the challenge. Aligned with this future possibility, the current paper reports on a performance of the deep space FSO system based on detailed simulations considering single-photon communication scenario. Among the several available optical receiver units, a state of the art Superconducting Nanowire Single Photon Detector (SNSPD) technology is implemented. The SNSPD is characterized with a quantum efficiency, dead time, dark count rate and number of channels. The investigation is based on the Poisson channel and well-known Pulse Position Modulation (PPM) deployed as a modulation technique. Moreover, the selected receiver aperture diameter provides the necessary resilience to atmospheric turbulence effect. Addressing the sophisticated parameterization of the current simulations, BER performance of the deep space FSO link based on the SNSPD receiver is provided. On the top of it, an output of the SNSPD in RF domain is considered. The sequence of RF output pulses is presented before and after the applied ideal low-pass filter.

AB - Future ground to deep space communication systems should support Gbps data links, which are resilient to atmospheric impairments. An alternative and in the same time complementary to the conventional RF technology is the emerging deep space Free Space Optical (FSO) system, which can successfully face the challenge. Aligned with this future possibility, the current paper reports on a performance of the deep space FSO system based on detailed simulations considering single-photon communication scenario. Among the several available optical receiver units, a state of the art Superconducting Nanowire Single Photon Detector (SNSPD) technology is implemented. The SNSPD is characterized with a quantum efficiency, dead time, dark count rate and number of channels. The investigation is based on the Poisson channel and well-known Pulse Position Modulation (PPM) deployed as a modulation technique. Moreover, the selected receiver aperture diameter provides the necessary resilience to atmospheric turbulence effect. Addressing the sophisticated parameterization of the current simulations, BER performance of the deep space FSO link based on the SNSPD receiver is provided. On the top of it, an output of the SNSPD in RF domain is considered. The sequence of RF output pulses is presented before and after the applied ideal low-pass filter.

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DO - 10.1109/TELSIKS46999.2019.9002366

M3 - Conference paper

SP - 235

EP - 240

BT - 2019 14th International Conference on Advanced Technologies, Systems and Services in Telecommunications (TELSIKS)

PB - IEEEXplore

T2 - 14th International Conference on Advanced Technologies, Systems and Services in Telecommunications

Y2 - 23 October 2019 through 25 October 2019

ER -

Resilience of Deep Space FSO Communication Scenario Involving SNSPD Receiver to Atmospheric Turbulence

Abstract

Conference

Fields of Expertise

Treatment code (Nähere Zuordnung)

Access to Document

Fingerprint

Projects

Optoelectronical Communication Engineering

TRITON - Heterogeneous Integration of Millimeter-Wave Technology

HybridPDT - System Study of Optical Communications with a Hybridised Optical/RF Payload Data Transmitter

Activities

University of Niš

14th International Conference on Advanced Technologies, Systems and Services in Telecommunications

Cite this