TY - GEN
T1 - A two-phase and two-period spectrum sensing scheme using high-layer information for cognitive radio networks
AU - Chen, Sheng Chang
AU - Chang, Chung Ju
AU - Gau, Rung-Hung
PY - 2012/5/7
Y1 - 2012/5/7
N2 - Spectrum sensing is important for dynamic spectrum allocation in cognitive radio networks (CRNs). Spectrum sensing algorithms are used to determine the frequency of spectrum sensing and the order for the channels to be scanned. In this paper, we propose a two-phase and two-period spectrum sensing (TTSS) scheme using high-layer information for CRNs. Benefiting from advanced physical-layer technologies, the TTSS scheme uses the results of coarse sensing to predict the best candidate channels for fine sensing and it adopts two types of sensing periods to optimize the network performance. When a node is not transmitting data, a long sensing period is used to reduce the sensing overhead. When a node is transmitting data, a short sensing period is used to reduce the average time interval where secondary users collide with primary users. Moreover, high-layer information is used to adjust the two sensing periods to further reduce the sensing overhead and increase the sensing accuracy. On average, simulation results show that the TTSS scheme with smaller short sensing period has lower packet dropping rate of primary users by 3.6% than coarse sensing scheme and by 1.17% than fine sensing scheme. Also, the TTSS scheme has medium sensing overhead and higher throughput of secondary user by 14% than coarse sensing scheme and by 197.21% than fine sensing scheme.
AB - Spectrum sensing is important for dynamic spectrum allocation in cognitive radio networks (CRNs). Spectrum sensing algorithms are used to determine the frequency of spectrum sensing and the order for the channels to be scanned. In this paper, we propose a two-phase and two-period spectrum sensing (TTSS) scheme using high-layer information for CRNs. Benefiting from advanced physical-layer technologies, the TTSS scheme uses the results of coarse sensing to predict the best candidate channels for fine sensing and it adopts two types of sensing periods to optimize the network performance. When a node is not transmitting data, a long sensing period is used to reduce the sensing overhead. When a node is transmitting data, a short sensing period is used to reduce the average time interval where secondary users collide with primary users. Moreover, high-layer information is used to adjust the two sensing periods to further reduce the sensing overhead and increase the sensing accuracy. On average, simulation results show that the TTSS scheme with smaller short sensing period has lower packet dropping rate of primary users by 3.6% than coarse sensing scheme and by 1.17% than fine sensing scheme. Also, the TTSS scheme has medium sensing overhead and higher throughput of secondary user by 14% than coarse sensing scheme and by 197.21% than fine sensing scheme.
KW - coarse sensing
KW - cognitive radio networks
KW - fine sensing
KW - high-layer information
KW - sensing period
KW - spectrum sensing
UR - http://www.scopus.com/inward/record.url?scp=84860486468&partnerID=8YFLogxK
U2 - 10.1109/ComComAp.2012.6154852
DO - 10.1109/ComComAp.2012.6154852
M3 - Conference contribution
AN - SCOPUS:84860486468
SN - 9781457717178
T3 - 2012 Computing, Communications and Applications Conference, ComComAp 2012
SP - 250
EP - 255
BT - 2012 Computing, Communications and Applications Conference, ComComAp 2012
T2 - 2012 Computing, Communications and Applications Conference, ComComAp 2012
Y2 - 11 January 2012 through 13 January 2012
ER -