Physics:Spatial modulation

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Spatial modulation is a technique that enables modulation over space, across different antennas (radio) at a transmitter.[1][2] Unlike multiple-input and multiple-output (MIMO) wireless (where all the transmitting antennas are active and transmitting digital modulated symbols such as phase-shift keying and quadrature amplitude modulation), in spatial modulation, only a single antenna among all transmitting antennas is active and transmitting, while all other remaining transmitting antennas sit idle. The duty of the receiver (information theory) is: to estimate the active antenna index at the transmitter and to decode the symbol sent by the transmitting antenna.

Both processes carry a message bit. Since only one transmitting antenna is active at a particular instant, one single RF chain for the active antenna is required, unlike MIMO systems in which NT (number of transmitting antennas) antennas are active and correspondingly NT number of RF chains are required. RF chains are costly, which makes spatial modulation (SM) much cheaper to implement. Conventional MIMO systems suffer from problems such as inter-antenna interference and transmit antenna synchronization issues[3] because all transmitting antennas are active.

Procedure

In SM, a series of information bits come to the transmitter. The transmitter divides the incoming bits in a chunk of k+l bits, where k is an exponent of two used for deciding the antenna index from which the l bits will be transmitted after applying an M-ary transmission or modulation scheme. In fact, only l bits are transmitted practically, since the antenna index also carries information of k bits, hence in total k+l bits will be decoded at the receiver.[4]

Example

An SM transmitter with NT=2 antennas uses a binary phase-shift keying (BPSK) modulator. In that case, the transmitter can transmit a BPSK symbol by performing BPSK modulation, which will carry a message bit. The antenna index from which the BPSK symbol is transmitted carries an additional bit of information as illustrated in Table 1.[5]

Table 1: SM mapping table for NT = 2 and M = 2 (BPSK)
Incoming bits Antenna index BPSK symbol transmitted
00 1 1
01 1 -1
10 2 1
11 2 -1

An incoming message bit string 10 matches the third row in the lookup table. In bit numbering, the most significant bit (MSB) is 1 and the least significant bit (LSB) is 0. The MSB indicates the transmitting antenna index while LSB indicates which BPSK symbol to transmit. If MSB=0 the first antenna will transmit the symbol. If MSB=1 then the second antenna will transmit. For LSB=0, BPSK symbol 1 will be transmitted whereas for LSB =1, BPSK symbol -1 will be transmitted. In this case, k = l = 1, so only one message bit is transmitted from the second antenna. The receiver decodes both the message bit as well as the active antenna index, effectively two message bits are decoded. Therefore, the spectral efficiency of the SM transmitter in this case is 2 bit/s/Hz.

The receiver must estimate the antenna index, as well as decode the symbol.[6]

Advanced spatial modulation

In order to improve the spectral efficiency, SM has been modified to various advanced SM schemes:[7]

  • Quadrature Spatial modulation[8]
  • Improved Spatial modulation[9]
  • Generalized Spatial modulation[10]
  • Spatial media Based modulation[11]
  • Enhanced Spatial Modulation[12]

In some of the above advanced SM methods, more than one transmitting antenna is active at a time at the transmitter in order to improve spectral efficiency. SM and its advanced variants are used in free-space optical communication termed as Optical spatial modulation[13] and Advanced Optical Spatial Modulation,[14] respectively.

References

  1. Mesleh, R.Y.; Haas, H.; Sinanovic, S; Ahn, C.W.; Yun, S (15 July 2008). "Spatial Modulation". IEEE Transactions on Vehicular Technology 57 (4): 2228–2241. doi:10.1109/TVT.2007.912136. 
  2. Mesleh, Raed; Abdelhamid, Alhassi (May 2018). Space Modulation Techniques. John Wiley & Sons Inc.. doi:10.1002/9781119375692. ISBN 9781119375654. https://onlinelibrary.wiley.com/doi/book/10.1002/9781119375692. 
  3. Kumbhani, Brijesh; Kshetrimayum, Rakhesh Singh (June 2017). "Spatial Modulation". MIMO Wireless Communications Over Generalized Fading Channels. Boca Raton, Florida: CRC Press. p. 267. ISBN 9781138033009. https://www.routledge.com/MIMO-Wireless-Communications-over-Generalized-Fading-Channels/Kumbhani-Kshetrimayum/p/book/9781138033009. 
  4. Kshetrimayum, Rakhesh Singh (July 2017). "Antenna Selection and Spatial Modulation". Fundamentals of MIMO Wireless Communications. Cambridge, UK: Cambridge University Press. p. 348. ISBN 9781108415699. https://www.cambridge.org/core/books/fundamentals-of-mimo-wireless-communications/76C9B13C9C3379393A9A0DDB9E22B0A2. 
  5. Fu, Yu; Wang, Cheng-Xiang; Mesleh, Raed; Cheng, Xiang; Haas, Harald; He, Yejun. "A Performance Study of Spatial Modulation Systems Under Vehicle-to-Vehicle Channel Models". Seoul, South Korea: IEEE. doi:10.1109/VTCSpring.2014.7022789. https://ieeexplore.ieee.org/document/7022789. 
  6. Renzo, M. D.; Haas, H.; Ghrayeb, A.; Sugiura, S.; Hanjo, L. (17 December 2013). "Spatial Modulation for Generalized MIMO: Challenges, Opportunities, and Implementation". Proceedings of the IEEE 102 (1): 56–103. doi:10.1109/JPROC.2013.2287851. 
  7. Bhowal, Anirban; Kshetrimayum, Rakhesh Singh (Dec 2020). Advanced Spatial Modulation Systems. Singapore: Springer Nature. p. 229. doi:10.1007/978-981-15-9960-6. ISBN 978-981-15-9959-0. https://link.springer.com/book/10.1007%2F978-981-15-9960-6. 
  8. Mesleh, R.Y. (30 July 2014). "Quadrature Spatial Modulation". IEEE Transactions on Vehicular Technology 64 (6): 2738–2742. doi:10.1109/TVT.2014.2344036. 
  9. Luna-Rivera, J.M.; Gonzalez-Perez, M.G.. "An improved spatial modulation scheme for MIMO channels". Prague, Czech Republic: IEEE. doi:10.1109/EuCAP.2012.6206031. https://ieeexplore.ieee.org/document/6206031. 
  10. A., Younis; Serafimovski, N.; Mesleh, R.; Haas, H.. "Generalised spatial modulation". Pacific Grove, CA, USA: IEEE. doi:10.1109/ACSSC.2010.5757786. https://ieeexplore.ieee.org/document/5757786. 
  11. Khandani, A.K.. "Media-based modulation: A new approach to wireless transmission". Istanbul, Turkey: IEEE. doi:10.1109/ISIT.2013.6620786. https://ieeexplore.ieee.org/document/6620786. 
  12. Cheng, C.-C.; Sari, H.; Sezginer, S.; Su, Y.T. (13 April 2015). "Enhanced Spatial Modulation With Multiple Signal Constellations". IEEE Transactions on Communications 63 (3): 2237–2248. doi:10.1109/TCOMM.2015.2422306. 
  13. Mesleh, R.Y.; Elgala, H.; Haas, H. (3 March 2011). "Optical Spatial Modulation". IEEE/OSA Journal of Optical Communications and Networking 3 (3): 234–244. doi:10.1364/JOCN.3.000234. 
  14. Bhowal, A.; Kshetrimayum, R. S. (3 November 2020). "Advanced Optical Spatial Modulation Techniques for FSO Communication". IEEE Transactions on Communications 69 (2): 1163–1174. doi:10.1109/TCOMM.2020.3035400.