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Published
Jul 11, 2014
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Abstract

Now a days the need for wireless data transmission is being widely used for communication purpose. Orthogonal frequency division multiplexing (OFDM) which is multi carrier communication technique can be used for wireless mobile communication as it has the property to overcome channel fading. While multiple inputs multiple outputs (MIMO) is the technique of implementing multiple antennas at the transmitter as well as receiver side to increase the data rates.In this paper, by taking the advantage of OFDM & MIMO a system has been implemented to get the data rates up to several hundred mbps.The first stage will be verification of each block using matlab. After the algorithm is verified, the hardware implementation will be obtained by constructing block diagram in Simulink. Then a VHDL code will be imported into Simulink via Xilinx system generator block set which will create bit true and cycle accurate hardware model. The resultant hardware model will be programmed into FPGA prototyping board.

Index terms— MIMO, OFDM

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Author Biographies

Madhuri Harish Jadhav, Siddhant College of Engineering, Sudumbare, Pune India Pune University

Dept. of Electronics & Telecommunication

Prof .Inamdar M U, Siddhant College of Engineering, Sudumbare, Pune India

Dept. of Electronics & Telecommunication
How to Cite
Jadhav, M. H., & M U, P. .Inamdar. (2014). Implementation of MIMO OFDM Transcreceiver for Increasing Data Rates. International Journal of Emerging Trends in Science and Technology, 1(05). Retrieved from https://igmpublication.org/ijetst.in/index.php/ijetst/article/view/203

References

1. http://gaussianwaves.blogspot.com/2011/07/simulation-of-ofdm-system-in-matlab-ber.html
2. ZohaPajoudi, SiedHamidreza, “Hardware Implementation of an 802.11n MIMO OFDM Transceiver,” in IEEE Jour. 978-1-4244-2750-5. (2008)
3. Yu Wei Lin, Chen Yi Lin, “Design of FFT/IFFT Processor for MIMO OFDM Systems,” IEEE Transaction on circuit and system, Vo1.54, no. 4 pp. 807-815, 2007.
4. Ashok Jhunjhunwala, “Next Generation wireless for rural areas,” in Indian Journal of Radio and Space Physics, Vol.36. pp 165-167, 2007.
5. K. C. Chang, G E Sobelman, “FPGA Based Design of a Pulsed-OFDM system," in IEEE Jour. 1-4244-0387-1/2006.
6. Z. Y. Ding, C Y Chen, T D Chiueh, "Design of a MIMO-OFDM baseband receiver for next generation wireless LAN ," in Proc. of ISCAS 06, vol. 1 , pp. 5650-5654, Island of Kos, Greece, 2006.
7. K.C.Chang G.E. Sobelman, E Saberinia, and A.H. Tewfik, “Transmitter architecture for pulsed OFDM,” IEEE APCCAS, 6-9 Dec. 2004, pp 693-696
8. K. F. Lee, D B William, "A space-frequency transmitter diversity technique for OFDM systems," in Proc. Globecom 03, San Francisco, USA, vol.3, pp.24-28, 2003.
9. D. Getsberg, Shafi, M.,Da-shanShiu,Smith, P.J., " From theory to practice: An overview of MIMO space-time coded wireless systems," in IEEE Jour. Sel. Areas in Commun.,vo1.21, no. 38 pp. 281-301, 2003.
10. V. Tarokh, H Jafarkhani, A R Calderbank, "Space-time block coding for wireless communications: performance results," in IEEE Jour. On Sel. Areas in Commun.,vol 17, no. 3.pp. 451-460, 1999.
11. S. M. Alamouti, “A simple transmit diversity scheme for wireless communications," in IEEE Jour. Sel. Areas in Commun., vo1.16, no. 8 pp. 1451-1458, 1998.
12. Ramjee Prasad “OFDM for wireless communication system” Artech House, Inc. Boston, London.
13. Hujun Yin, Sivash Alamouti, " OFDMA: A Broadband wireless Access Technology," Intel Corporation, Santa Clara CA 95054