TY - GEN
T1 - An integrated signaling-encryption mechanism to reduce error propagation in wireless communications
T2 - 2015 IEEE International Workshop Technical Committee on Communications Quality and Reliability, CQR 2015
AU - Olama, Mohammed M.
AU - Matalgah, Mustafa M.
AU - Bobrek, Miljko
N1 - Publisher Copyright:
© 2015 IEEE.
PY - 2015/6/19
Y1 - 2015/6/19
N2 - Traditional encryption techniques require packet overhead, produce processing time delay, and suffer from severe quality of service deterioration due to fades and interference in wireless channels. These issues reduce the effective transmission data rate (throughput) considerably in wireless communications, where data rate with limited bandwidth is the main constraint. In this paper, performance evaluation analyses are conducted for an integrated signaling-encryption mechanism that is secure and enables improved throughput and probability of bit-error in wireless channels. This mechanism eliminates the drawbacks stated herein by encrypting only a small portion of an entire transmitted frame, while the rest is not subject to traditional encryption but goes through a signaling process (designed transformation) with the plaintext of the portion selected for encryption. We also propose to incorporate error correction coding solely on the small encrypted portion of the data to drastically improve the overall bit-error rate performance while not noticeably increasing the required bit-rate. We focus on validating the signaling-encryption mechanism utilizing Hamming and convolutional error correction coding by conducting an end-to-end system-level simulation-based study. The average probability of bit-error and throughput of the encryption mechanism are evaluated over standard Gaussian and Rayleigh fading-type channels and compared to the ones of the conventional advanced encryption standard (AES).
AB - Traditional encryption techniques require packet overhead, produce processing time delay, and suffer from severe quality of service deterioration due to fades and interference in wireless channels. These issues reduce the effective transmission data rate (throughput) considerably in wireless communications, where data rate with limited bandwidth is the main constraint. In this paper, performance evaluation analyses are conducted for an integrated signaling-encryption mechanism that is secure and enables improved throughput and probability of bit-error in wireless channels. This mechanism eliminates the drawbacks stated herein by encrypting only a small portion of an entire transmitted frame, while the rest is not subject to traditional encryption but goes through a signaling process (designed transformation) with the plaintext of the portion selected for encryption. We also propose to incorporate error correction coding solely on the small encrypted portion of the data to drastically improve the overall bit-error rate performance while not noticeably increasing the required bit-rate. We focus on validating the signaling-encryption mechanism utilizing Hamming and convolutional error correction coding by conducting an end-to-end system-level simulation-based study. The average probability of bit-error and throughput of the encryption mechanism are evaluated over standard Gaussian and Rayleigh fading-type channels and compared to the ones of the conventional advanced encryption standard (AES).
KW - Monte Carlo simulations
KW - Rayleigh fading
KW - advanced encryption standard (AES)
KW - bit-error rate
KW - cryptography
KW - error correction coding
KW - quality of service (QoS)
KW - throughput
UR - http://www.scopus.com/inward/record.url?scp=84939454818&partnerID=8YFLogxK
U2 - 10.1109/CQR.2015.7129081
DO - 10.1109/CQR.2015.7129081
M3 - Conference contribution
AN - SCOPUS:84939454818
T3 - Proceedings - CQR 2015: 2015 IEEE International Workshop Technical Committee on Communications Quality and Reliability
BT - Proceedings - CQR 2015
PB - Institute of Electrical and Electronics Engineers Inc.
Y2 - 11 May 2015 through 14 May 2015
ER -