Efficient Variable Modulation Scheme Based on Codebook in the MIMO-OFDM System
Because current wireless communication requires high
reliability in a limited bandwidth environment, this paper proposes
the variable modulation scheme based on the codebook. The variable
modulation scheme adjusts transmission power using the codebook in
accordance with channel state. Also, if the codebook is composed of
many bits, the reliability is more improved by the proposed scheme.
The simulation results show that the performance of proposed scheme
has better reliability than the the performance of conventional scheme.
[1] Linglong. D, Zhaocheng. W and Zhixing Y, “Time-Frequency Training
OFDM with High Spectral Efficiency and Reliable Performance in
High Speed Environments,” IEEE Journal on Selected Areas in
Communications, vol.30, no.4, pp.695-707, May 2012.
[2] Char-Dir. C, “Spectral Precoding for Constant-Envelope OFDM,” IEEE
Transacations on Communications, vol.58, no.2, pp.555-567, Feb. 2010.
[3] Guoying. Z, Marc-De. L, Annalisa. M and Biswanath. M, “A Survey
on OFDM-Based Elastic Core Optical Networking,” IEEE Conference
on Control and System Graduate Research Colloquium (ICSGRC), pp.
94-99, July 2012.
[4] Heung-Gyoon. R, “System Design and Analysis of MIMO SFBC
CI-OFDM System against the Nonlinear Distortion and Narrowband
Interference,” IEEE Communications Surveys & Tutorlals, vol.15, pp.368
- 375, no.1, First Quarter 2013.
[5] Xue. L, Steven. H, Vasu. D, Michael. T and Zhiqiang. W, “Intercarrier
Interference Immune Single Carrier OFDM via Magnitude-Keyed
Modulation for High Speed Aerial Vehicle Communication,” IEEE
Transactions on Communications, vol.61, no.2, pp.658-668, Feb. 2013.
[6] Jong-Moon. C, Joonyung. K and Donghyuk. H “Multihop Hybrid Virtual
MIMO Scheme for Wireless Sensor Networks,” IEEE Transacations on
Vehicular Technology, vol.61, no.9, pp.4069-4078, Nov. 2012.
[7] Chong-Yung. C and Chii-Horng. C, “Cumulant-Based Inverse Filter
Criteria for MIMO Blind Deconvolution: Properties, Algorithms, and
Application to DS/CDMA Systems in Multipath,” IEEE Transacations
on Signla Processing, vol.49, no.7, pp.1282-1299, July 2001.
[8] Weiyan. G, Junshan. Z and Guoliang. X, “MIMO-Pipe Modeling and
Scheduling for Efficient Interference Management in Multihop MIMO
Networks,” IEEE Transacations on Vehicular Technology, vol.59, no.8,
pp.3966-3978, Oct. 2010.
[9] Ranga. P, Strkrishana .B and Chockalingam. A, “On the Sum-Rate of the
Gaussian MIMO Z Channel and the Gaussian MIMO X Channel,” IEEE
Transactions on Communications, vol.63, no.2, pp.487-497, Feb. 2015.
[10] Lars-T. B, Abdreas. S, Pascal. P and Daniel-M. S “MIMO Power Line
Communications,” IEEE Communications Surveys & Tutorlals, vol.17,
no.1, pp.106-124, First Quarter 2015.
[11] Victoria. K and Sergey. L, “On Optimum Power Allocation for
the V-BLAST,” IEEE Transactions on Communications, vol.56, no.6,
pp.999-1012, June 2008.
[12] Xin. L and Zaiping. N, “Performance Losses in V-BLAST Due to
Correlation,” IEEE Antennas and Wireless Propagation Letters, vol.3,
pp.291-294, Dec. 2004.
[13] Hairuo. Z, Lin. D, Shidong. Z and Yan. Y, “Low Complexity
Per-Antenna Rate and Power Control Approach for Closed-Loop
V-BLAST,” IEEE Transactions on Communications, vol.51, no.11,
pp.1783-1787, Nov. 2003.
[14] Serdar. O and Murat. T , “Exact Joint Distribution Analysis of
Zero-Forcing V-BLAST Gains with Greedy Ordering,” IEEE Transcations
on Wireless Communication, vol.12, no.11, pp.5377-5385, Nov. 2013.
[15] Victiria. K and Sergey. L, “Optimum Power and Rate Allocation
for Coded V-BLAST: Average Optimization ,” IEEE Transacations on
Communications, vol.59, no.3, pp.877-887, Mar. 2011.
[16] Yinman. L and Hong-Wei. S “Low-Complexity Groupwise OSIC-ZF
Detection for N N Spatial Multiplexing Systems,” IEEE Transacations
on Vehicular Technology, vol.60, no.4, pp.1930-1937, May 2011.
[17] Donghun. L “Performance Analysis of ZF-Precoded Scheduling System
for MU-MIMO with Generalized Selection Criterion,” IEEE Transcations
on Wireless Communication, vol.12, no.4, pp.1812-1818, Apr. 2013.
[18] Myung-Sun. Baek, Young-Hwn. You and Hyoung-Kyu. Song,
“Combined QRD-M and DFE Detection Technique for Simple and
Efficient Signal Detection in MIMO-OFDM Systems,” IEEE Transcations
on Wireless Communication, vol.8, no.4, pp.1632-1638, Apr. 2009.
[19] Kyeong-Jin. Kim, Tony. R and Ronald-A. I “Iterative Soft-QRD-M
for Turbo Coded MIMO-OFDM Systems,” IEEE Transacations on
Communication, vol.56, no.7, pp.1043-1046, July 2008.
[20] Ping. Y, Yux. X, Shaoqian. L and Lajos. H, “QRD-Assisted Adaptive
Modulation-Aided MIMO Systems,” IEEE Transacations on Vehicular
Technology, vol.63, no.1, pp.446-451, Jan. 2014.
[1] Linglong. D, Zhaocheng. W and Zhixing Y, “Time-Frequency Training
OFDM with High Spectral Efficiency and Reliable Performance in
High Speed Environments,” IEEE Journal on Selected Areas in
Communications, vol.30, no.4, pp.695-707, May 2012.
[2] Char-Dir. C, “Spectral Precoding for Constant-Envelope OFDM,” IEEE
Transacations on Communications, vol.58, no.2, pp.555-567, Feb. 2010.
[3] Guoying. Z, Marc-De. L, Annalisa. M and Biswanath. M, “A Survey
on OFDM-Based Elastic Core Optical Networking,” IEEE Conference
on Control and System Graduate Research Colloquium (ICSGRC), pp.
94-99, July 2012.
[4] Heung-Gyoon. R, “System Design and Analysis of MIMO SFBC
CI-OFDM System against the Nonlinear Distortion and Narrowband
Interference,” IEEE Communications Surveys & Tutorlals, vol.15, pp.368
- 375, no.1, First Quarter 2013.
[5] Xue. L, Steven. H, Vasu. D, Michael. T and Zhiqiang. W, “Intercarrier
Interference Immune Single Carrier OFDM via Magnitude-Keyed
Modulation for High Speed Aerial Vehicle Communication,” IEEE
Transactions on Communications, vol.61, no.2, pp.658-668, Feb. 2013.
[6] Jong-Moon. C, Joonyung. K and Donghyuk. H “Multihop Hybrid Virtual
MIMO Scheme for Wireless Sensor Networks,” IEEE Transacations on
Vehicular Technology, vol.61, no.9, pp.4069-4078, Nov. 2012.
[7] Chong-Yung. C and Chii-Horng. C, “Cumulant-Based Inverse Filter
Criteria for MIMO Blind Deconvolution: Properties, Algorithms, and
Application to DS/CDMA Systems in Multipath,” IEEE Transacations
on Signla Processing, vol.49, no.7, pp.1282-1299, July 2001.
[8] Weiyan. G, Junshan. Z and Guoliang. X, “MIMO-Pipe Modeling and
Scheduling for Efficient Interference Management in Multihop MIMO
Networks,” IEEE Transacations on Vehicular Technology, vol.59, no.8,
pp.3966-3978, Oct. 2010.
[9] Ranga. P, Strkrishana .B and Chockalingam. A, “On the Sum-Rate of the
Gaussian MIMO Z Channel and the Gaussian MIMO X Channel,” IEEE
Transactions on Communications, vol.63, no.2, pp.487-497, Feb. 2015.
[10] Lars-T. B, Abdreas. S, Pascal. P and Daniel-M. S “MIMO Power Line
Communications,” IEEE Communications Surveys & Tutorlals, vol.17,
no.1, pp.106-124, First Quarter 2015.
[11] Victoria. K and Sergey. L, “On Optimum Power Allocation for
the V-BLAST,” IEEE Transactions on Communications, vol.56, no.6,
pp.999-1012, June 2008.
[12] Xin. L and Zaiping. N, “Performance Losses in V-BLAST Due to
Correlation,” IEEE Antennas and Wireless Propagation Letters, vol.3,
pp.291-294, Dec. 2004.
[13] Hairuo. Z, Lin. D, Shidong. Z and Yan. Y, “Low Complexity
Per-Antenna Rate and Power Control Approach for Closed-Loop
V-BLAST,” IEEE Transactions on Communications, vol.51, no.11,
pp.1783-1787, Nov. 2003.
[14] Serdar. O and Murat. T , “Exact Joint Distribution Analysis of
Zero-Forcing V-BLAST Gains with Greedy Ordering,” IEEE Transcations
on Wireless Communication, vol.12, no.11, pp.5377-5385, Nov. 2013.
[15] Victiria. K and Sergey. L, “Optimum Power and Rate Allocation
for Coded V-BLAST: Average Optimization ,” IEEE Transacations on
Communications, vol.59, no.3, pp.877-887, Mar. 2011.
[16] Yinman. L and Hong-Wei. S “Low-Complexity Groupwise OSIC-ZF
Detection for N N Spatial Multiplexing Systems,” IEEE Transacations
on Vehicular Technology, vol.60, no.4, pp.1930-1937, May 2011.
[17] Donghun. L “Performance Analysis of ZF-Precoded Scheduling System
for MU-MIMO with Generalized Selection Criterion,” IEEE Transcations
on Wireless Communication, vol.12, no.4, pp.1812-1818, Apr. 2013.
[18] Myung-Sun. Baek, Young-Hwn. You and Hyoung-Kyu. Song,
“Combined QRD-M and DFE Detection Technique for Simple and
Efficient Signal Detection in MIMO-OFDM Systems,” IEEE Transcations
on Wireless Communication, vol.8, no.4, pp.1632-1638, Apr. 2009.
[19] Kyeong-Jin. Kim, Tony. R and Ronald-A. I “Iterative Soft-QRD-M
for Turbo Coded MIMO-OFDM Systems,” IEEE Transacations on
Communication, vol.56, no.7, pp.1043-1046, July 2008.
[20] Ping. Y, Yux. X, Shaoqian. L and Lajos. H, “QRD-Assisted Adaptive
Modulation-Aided MIMO Systems,” IEEE Transacations on Vehicular
Technology, vol.63, no.1, pp.446-451, Jan. 2014.
@article{"International Journal of Information, Control and Computer Sciences:70714", author = "Yong-Jun Kim and Jae-Hyun Ro and Chang-Bin Ha and Hyoung-Kyu Song", title = "Efficient Variable Modulation Scheme Based on Codebook in the MIMO-OFDM System", abstract = "Because current wireless communication requires high
reliability in a limited bandwidth environment, this paper proposes
the variable modulation scheme based on the codebook. The variable
modulation scheme adjusts transmission power using the codebook in
accordance with channel state. Also, if the codebook is composed of
many bits, the reliability is more improved by the proposed scheme.
The simulation results show that the performance of proposed scheme
has better reliability than the the performance of conventional scheme.", keywords = "MIMO-OFDM, variable modulation, codebook,
channel state.", volume = "9", number = "7", pages = "1719-4", }
