Your search keyword '"Jiun Terng Liew"' showing total 2 results

1. Pseudorandom sequence contention algorithm for IEEE 802.11ah based internet of things network.

Author

Mohammed A Raouf, Fazirulhisyam Hashim, Jiun Terng Liew, and Kamal Ali Alezabi

Subjects

Medicine, Science

Abstract

The IEEE 802.11ah standard relies on the conventional distributed coordination function (DCF) as a backoff selection method. The DCF is utilized in the contention-based period of the newly introduced medium access control (MAC) mechanism, namely restricted access window (RAW). Despite various advantages of RAW, DCF still utilizes the legacy binary exponential backoff (BEB) algorithm, which suffers from a crucial disadvantage of being prone to high probability of collisions with high number of contending stations. To mitigate this issue, this paper investigates the possibility of replacing the existing exponential sequence (i.e., as in BEB) with a better pseudorandom sequence of integers. In particular, a new backoff algorithm, namely Pseudorandom Sequence Contention Algorithm (PRSCA) is proposed to update the CW size and minimize the collision probability. In addition, the proposed PRSCA incorporates a different approach of CW freezing mechanism and backoff stage reset process. An analytical model is derived for the proposed PRSCA and presented through a discrete 2-D Markov chain model. Performance evaluation demonstrates the efficiency of the proposed PRSCA in reducing collision probability and improving saturation throughput, network throughput, and access delay performance.

Published

2020

2. Pseudorandom sequence contention algorithm for IEEE 802.11ah based internet of things network

Author

Jiun Terng Liew, Mohammed A. Raouf, Kamal Ali Alezabi, and Fazirulhisyam Hashim

Subjects

Physiology, Computer science, Intelligence, Internet of Things, Social Sciences, 02 engineering and technology, 01 natural sciences, Automation, 0202 electrical engineering, electronic engineering, information engineering, Psychology, Computer Networks, Sequence, Multidisciplinary, Applied Mathematics, Simulation and Modeling, Markov Chains, Physical Sciences, Telecommunications, Engineering and Technology, Medicine, Wireless Technology, Algorithm, Algorithms, Network Analysis, Research Article, IEEE 802.11ah, Computer and Information Sciences, Markov Models, Exponential backoff, Science, Access control, Throughput, Research and Analysis Methods, Distributed coordination function, Industrial Engineering, Markov chain, business.industry, ComputerSystemsOrganization_COMPUTER-COMMUNICATIONNETWORKS, 010401 analytical chemistry, Cognitive Psychology, Biology and Life Sciences, 020206 networking & telecommunications, Control Engineering, Probability Theory, Signaling Networks, 0104 chemical sciences, Cognitive Science, Wireless Sensor Networks, Physiological Processes, Sleep, business, Reset (computing), Mathematics, Neuroscience

Abstract

The IEEE 802.11ah standard relies on the conventional distributed coordination function (DCF) as a backoff selection method. The DCF is utilized in the contention-based period of the newly introduced medium access control (MAC) mechanism, namely restricted access window (RAW). Despite various advantages of RAW, DCF still utilizes the legacy binary exponential backoff (BEB) algorithm, which suffers from a crucial disadvantage of being prone to high probability of collisions with high number of contending stations. To mitigate this issue, this paper investigates the possibility of replacing the existing exponential sequence (i.e., as in BEB) with a better pseudorandom sequence of integers. In particular, a new backoff algorithm, namely Pseudorandom Sequence Contention Algorithm (PRSCA) is proposed to update the CW size and minimize the collision probability. In addition, the proposed PRSCA incorporates a different approach of CW freezing mechanism and backoff stage reset process. An analytical model is derived for the proposed PRSCA and presented through a discrete 2-D Markov chain model. Performance evaluation demonstrates the efficiency of the proposed PRSCA in reducing collision probability and improving saturation throughput, network throughput, and access delay performance.

Published

2020