High-Level System Design of IEEE 802.11b Standard-Compliant Link Layer for MATLAB-Based SDR

High-Level System Design of IEEE 802.11b Standard-Compliant Link Layer for MATLAB-Based SDR

Software-defined radio (SDR) allows the unprecedented levels of flexibility by transitioning the radio communication system from a rigid hardware platform to a more user-controlled software paradigm. However, it can still be time-consuming to design and implement such SDRs as they typically require...

Full description

Bibliographic Details
Main Authors: Ramanathan Subramanian, Benjamin Drozdenko, Eric Doyle, Rameez Ahmed, Miriam Leeser, Kaushik Roy Chowdhury
Format: Article
Language:English
Published: IEEE 2016-01-01
Series:IEEE Access
Subjects:
Software Defined Radio
IEEE 802.11b
CSMA/CA/ACK
Energy Detection
Exponential Random Back-off
MEX
Online Access:https://ieeexplore.ieee.org/document/7454680/
id doaj-809d06aa3106406d98be98457b3a0cc0
record_format Article
spelling doaj-809d06aa3106406d98be98457b3a0cc02021-03-29T19:37:19ZengIEEEIEEE Access2169-35362016-01-0141494150910.1109/ACCESS.2016.25536717454680High-Level System Design of IEEE 802.11b Standard-Compliant Link Layer for MATLAB-Based SDRRamanathan Subramanian0Benjamin Drozdenko1Eric Doyle2Rameez Ahmed3Miriam Leeser4Kaushik Roy Chowdhury5Department of Electrical and Computer Engineering, Northeastern University, Boston, MA, USADepartment of Electrical and Computer Engineering, Northeastern University, Boston, MA, USADepartment of Electrical and Computer Engineering, Northeastern University, Boston, MA, USADepartment of Electrical and Computer Engineering, Northeastern University, Boston, MA, USADepartment of Electrical and Computer Engineering, Northeastern University, Boston, MA, USADepartment of Electrical and Computer Engineering, Northeastern University, Boston, MA, USASoftware-defined radio (SDR) allows the unprecedented levels of flexibility by transitioning the radio communication system from a rigid hardware platform to a more user-controlled software paradigm. However, it can still be time-consuming to design and implement such SDRs as they typically require thorough knowledge of the operating environment and a careful tuning of the program. In this paper, our contribution is the design of a bidirectional transceiver that runs on the commonly used USRP platform and implemented in MATLAB using standard tools like MATLAB Coder and MEX to speed up the processing steps. We outline strategies on how to create a state-action-based design, wherein the same node switches between transmitter and receiver functions. Our design allows the optimal selection of the parameters toward meeting the timing requirements set forth by various processing blocks associated with a differential binary phase shift keying physical layer and CSMA/CA/ACK MAC layer, so that all the operations remain functionally compliant with the IEEE 802.11b standard for the 1 Mb/s specification. The code base of the system is enabled through the Communications System Toolbox and incorporates channel sensing and exponential random back-off for contention resolution. The current work provides an experimental testbed that enables the creation of new MAC protocols starting from the fundamental IEEE 802.11b standard. Our design approach guarantees consistent performance of the bi-directional link, and the three-node experimental results demonstrate the robustness of the system in mitigating packet collisions and enforcing fairness among nodes, making it a feasible framework in higher layer protocol design.https://ieeexplore.ieee.org/document/7454680/Software Defined RadioIEEE 802.11bCSMA/CA/ACKEnergy DetectionExponential Random Back-offMEX
collection DOAJ
language English
format Article
sources DOAJ
author Ramanathan Subramanian
Benjamin Drozdenko
Eric Doyle
Rameez Ahmed
Miriam Leeser
Kaushik Roy Chowdhury
spellingShingle Ramanathan Subramanian
Benjamin Drozdenko
Eric Doyle
Rameez Ahmed
Miriam Leeser
Kaushik Roy Chowdhury
High-Level System Design of IEEE 802.11b Standard-Compliant Link Layer for MATLAB-Based SDR
IEEE Access
Software Defined Radio
IEEE 802.11b
CSMA/CA/ACK
Energy Detection
Exponential Random Back-off
MEX
author_facet Ramanathan Subramanian
Benjamin Drozdenko
Eric Doyle
Rameez Ahmed
Miriam Leeser
Kaushik Roy Chowdhury
author_sort Ramanathan Subramanian
title High-Level System Design of IEEE 802.11b Standard-Compliant Link Layer for MATLAB-Based SDR
title_short High-Level System Design of IEEE 802.11b Standard-Compliant Link Layer for MATLAB-Based SDR
title_full High-Level System Design of IEEE 802.11b Standard-Compliant Link Layer for MATLAB-Based SDR
title_fullStr High-Level System Design of IEEE 802.11b Standard-Compliant Link Layer for MATLAB-Based SDR
title_full_unstemmed High-Level System Design of IEEE 802.11b Standard-Compliant Link Layer for MATLAB-Based SDR
title_sort high-level system design of ieee 802.11b standard-compliant link layer for matlab-based sdr
publisher IEEE
series IEEE Access
issn 2169-3536
publishDate 2016-01-01
description Software-defined radio (SDR) allows the unprecedented levels of flexibility by transitioning the radio communication system from a rigid hardware platform to a more user-controlled software paradigm. However, it can still be time-consuming to design and implement such SDRs as they typically require thorough knowledge of the operating environment and a careful tuning of the program. In this paper, our contribution is the design of a bidirectional transceiver that runs on the commonly used USRP platform and implemented in MATLAB using standard tools like MATLAB Coder and MEX to speed up the processing steps. We outline strategies on how to create a state-action-based design, wherein the same node switches between transmitter and receiver functions. Our design allows the optimal selection of the parameters toward meeting the timing requirements set forth by various processing blocks associated with a differential binary phase shift keying physical layer and CSMA/CA/ACK MAC layer, so that all the operations remain functionally compliant with the IEEE 802.11b standard for the 1 Mb/s specification. The code base of the system is enabled through the Communications System Toolbox and incorporates channel sensing and exponential random back-off for contention resolution. The current work provides an experimental testbed that enables the creation of new MAC protocols starting from the fundamental IEEE 802.11b standard. Our design approach guarantees consistent performance of the bi-directional link, and the three-node experimental results demonstrate the robustness of the system in mitigating packet collisions and enforcing fairness among nodes, making it a feasible framework in higher layer protocol design.
topic Software Defined Radio
IEEE 802.11b
CSMA/CA/ACK
Energy Detection
Exponential Random Back-off
MEX
url https://ieeexplore.ieee.org/document/7454680/
work_keys_str_mv AT ramanathansubramanian highlevelsystemdesignofieee80211bstandardcompliantlinklayerformatlabbasedsdr
AT benjamindrozdenko highlevelsystemdesignofieee80211bstandardcompliantlinklayerformatlabbasedsdr
AT ericdoyle highlevelsystemdesignofieee80211bstandardcompliantlinklayerformatlabbasedsdr
AT rameezahmed highlevelsystemdesignofieee80211bstandardcompliantlinklayerformatlabbasedsdr
AT miriamleeser highlevelsystemdesignofieee80211bstandardcompliantlinklayerformatlabbasedsdr
AT kaushikroychowdhury highlevelsystemdesignofieee80211bstandardcompliantlinklayerformatlabbasedsdr
_version_ 1724195940594614272

Similar Items