Partially Informed Transmitter-Based Optical Space Shift Keying Under Atmospheric Turbulence

In this paper, a partially informed transmitter-based optical space shift keying (PIT-OSSK) scheme is proposed, wherein the transmitter only possesses the knowledge of channel gain ordering. This partial information is used to adapt the OSSK constellation and power allocation (PA). The adaptation of...

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Bibliographic Details
Published in:IEEE transactions on wireless communications 2019-08, Vol.18 (8), p.3781-3796
Main Authors: Jaiswal, Anshul, Bhatnagar, Manav R., Jain, Virander Kumar
Format: Article
Language:English
Subjects:
Adaptive optics
Apertures
Atmospheric models
Atmospheric turbulence
Average bit error rate
Bit error rate
Channel models
Closed form solutions
Computer simulation
Constellations
diversity order
Exact solutions
feedback link
free-space optical (FSO) communication
Keying
Mathematical analysis
Monte Carlo simulation
Optical feedback
Optical receivers
optical space shift keying (OSSK)
optical spatial modulation (OSM)
Optical transmitters
Power management
Transmitters
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Summary:In this paper, a partially informed transmitter-based optical space shift keying (PIT-OSSK) scheme is proposed, wherein the transmitter only possesses the knowledge of channel gain ordering. This partial information is used to adapt the OSSK constellation and power allocation (PA). The adaptation of OSSK constellation reduces the number of bits in error between two consecutive constellation points, which in turn lowers the overall bit error rate (BER) of the proposed scheme. On the other hand, it is demonstrated by a mathematical analysis that the PA achieves improved diversity order as compared to the conventional OSSK scheme. These modifications make the PIT-OSSK scheme significantly better than the conventional OSSK scheme in terms of the BER under both indoor and outdoor conditions. For a single receiver aperture, accurate closed-form expressions of average BER (ABER) for two and four transmitter aperture-based PIT-OSSK schemes are derived under negative-exponential channel model. Moreover, a very tight approximate closed-form expression of the ABER for an arbitrary number of transmitter apertures is also developed. All the derived expressions are verified via Monte-Carlo simulations. Furthermore, the proposed strategy is extended and examined for an arbitrary number of receiver apertures by the simulation-based results under different channel models.
ISSN:1536-1276
1558-2248
DOI:10.1109/TWC.2019.2911612