summaryrefslogtreecommitdiff
diff options
context:
space:
mode:
-rw-r--r--data/db.bib594
-rw-r--r--data/db.yaml176
2 files changed, 752 insertions, 18 deletions
diff --git a/data/db.bib b/data/db.bib
index 99f52f9..500ff14 100644
--- a/data/db.bib
+++ b/data/db.bib
@@ -3577,7 +3577,7 @@
@inproceedings{carma,
acmid = {236446},
address = {New York, NY, USA},
- author = {Garc{é}s, Rodrigo and Garcia-Luna-Aceves, J. J.},
+ author = {Garcés, Rodrigo and Garcia-Luna-Aceves, J. J.},
booktitle = {Proceedings of the 2Nd Annual International Conference on Mobile Computing and Networking},
doi = {10.1145/236387.236446},
isbn = {0-89791-872-X},
@@ -3760,21 +3760,585 @@
title = {Medium Access Control Protocol for transparent ATM Access in MBS},
year = {1995},
}
+
@article{lmac2009,
- author = {Fu, Chung-Jung and Lee, Ang-Hsi and Jin, Ming-Hui and Kao, Cheng-Yan},
- title = {A Latency MAC Protocol for Wireless Sensor Networks},
- year = {2009},
- journaltitle = {International Journal of Future Generation Communication and Networking},
- number = {1},
- volume = {2},
- month = {March},
- url = {http://www.sersc.org/journals/IJFGCN/vol2_no1/6.pdf},
+ author = {Fu, Chung-Jung and Lee, Ang-Hsi and Jin, Ming-Hui and Kao, Cheng-Yan},
+ journaltitle = {International Journal of Future Generation Communication and Networking},
+ month = {March},
+ number = {1},
+ title = {A Latency MAC Protocol for Wireless Sensor Networks},
+ url = {http://www.sersc.org/journals/IJFGCN/vol2_no1/6.pdf},
+ volume = {2},
+ year = {2009},
}
+
@article{bpmac,
- title={BP-MAC: a high reliable backoff preamble MAC protocol for wireless sensor networks},
- author={Klein, Alexander and Klaue, Jirka and Schalk, Josef},
- journal={Electronic Journal of Structural Engineering (EJSE): Special Issue of Sensor Networks for Building Monitoring: From Theory to Real Application},
- pages={35--45},
- year={2009},
- url={http://www.ejse.org/Archives/Fulltext/2009/Special/2009SP4.pdf}
+ author = {Klein, Alexander and Klaue, Jirka and Schalk, Josef},
+ journaltitle = {Electronic Journal of Structural Engineering (EJSE): Special Issue of Sensor Networks for Building Monitoring: From Theory to Real Application},
+ pages = {35--45},
+ title = {BP-MAC: a high reliable backoff preamble MAC protocol for wireless sensor networks},
+ url = {http://www.ejse.org/Archives/Fulltext/2009/Special/2009SP4.pdf},
+ year = {2009},
+}
+
+@article{fdcmac2015a,
+ author = {W. Cheng and X. Zhang and H. Zhang},
+ doi = {10.1109/JSAC.2014.2361078},
+ issn = {0733-8716},
+ journaltitle = {IEEE Journal on Selected Areas in Communications},
+ keywords = {access protocols;cognitive radio;radio spectrum management;signal detection;synchronisation;wireless channels;FDC-MAC protocol;PU high-throughput transmission;SU channel utilization;cognitive radio network synchronization;full-duplex cognitive medium access control protocol;full-duplex spectrum sensing;multichannel nontime slotted CRN;primary users;primary wireless network;secondary users;secondary wireless network;wireless FD-SS scheme;Media Access Protocol;Sensors;Synchronization;Wireless networks;Wireless sensor networks;Cognitive radio networks (CRNs);Full-duplex spectrum sensing;MAC protocol;full-duplex spectrum sensing;multichannel non-time slotted CRNs;multichannel non-time-slotted CRNs},
+ month = {May},
+ number = {5},
+ pages = {820-831},
+ title = {Full-Duplex Spectrum-Sensing and MAC-Protocol for Multichannel Nontime-Slotted Cognitive Radio Networks},
+ volume = {33},
+ year = {2015},
+}
+
+@article{dsp,
+ author = {K. H. Almotairi and X. (. Shen},
+ doi = {10.1109/TMC.2014.2316822},
+ issn = {1536-1233},
+ journaltitle = {IEEE Transactions on Mobile Computing},
+ keywords = {access protocols;ad hoc networks;frequency hop communication;wireless LAN;IEEE 802.11 MAC strategies;ad hoc wireless networks;analytical model;distributed multi-channel MAC protocol;dual radio interfaces;fast hopping sequences;maximum saturation throughput;medium access control protocol;multi-hop networks;multiple rendezvous approach;network simulator-2;single-hop networks;slow hopping sequences;upper achievable throughput;IEEE 802.11 Standards;Media Access Protocol;Mobile computing;Receivers;Switches;Synchronization;IEEE 802.11 networks;Multi-channel networks;frequency hopping sequence;medium access control},
+ month = {Jan},
+ number = {1},
+ pages = {1-13},
+ title = {A Distributed Multi-Channel MAC Protocol for Ad Hoc Wireless Networks},
+ volume = {14},
+ year = {2015},
+}
+
+@article{hehbmac,
+ abstract = {This paper introduces human energy harvesting medium access control (MAC) protocol (HEH-BMAC), a hybrid polling MAC suitable for wireless body area networks powered by human energy harvesting. The proposed protocol combines two different medium access methods, namely polling (ID-polling) and probabilistic contention access, to adapt its operation to the different energy and state (active/inactive) changes that the network nodes may experience due to their random nature and the time variation of the energy harvesting sources. HEH-BMAC exploits the packet inter-arrival time and the energy harvesting rate information of each node to implement an efficient access scheme with different priority levels. In addition, our protocol can be applied dynamically in realistic networks, since it is adaptive to the topology changes, allowing the insertion/removal of wireless sensor nodes. Extensive simulations have been conducted in order to evaluate the protocol performance and study the throughput and energy tradeoffs.},
+ author = {Ibarra, Ernesto and Antonopoulos, Angelos and Kartsakli, Elli and Verikoukis, Christos},
+ day = {01},
+ doi = {10.1007/s11235-014-9898-z},
+ issn = {1572-9451},
+ journaltitle = {Telecommunication Systems},
+ month = {Feb},
+ number = {2},
+ pages = {111--124},
+ title = {HEH-BMAC: Hybrid polling MAC protocol for WBANs operated by human energy harvesting},
+ url = {https://doi.org/10.1007/s11235-014-9898-z},
+ volume = {58},
+ year = {2015},
+}
+
+@article{camac2015,
+ author = {C. Shao and S. Leng and Y. Zhang and A. Vinel and M. Jonsson},
+ doi = {10.1109/TVT.2015.2479942},
+ issn = {0018-9545},
+ journaltitle = {IEEE Transactions on Vehicular Technology},
+ keywords = {Markov processes;access protocols;energy consumption;fuel economy;probability;road safety;vehicular ad hoc networks;wireless channels;connectivity probability performance analysis;connectivity-aware MAC protocol design;fuel consumption reduction;medium access control protocol;multichannel reservation scheme;multipriority Markov model;passenger comfort;passenger safety;platoon-based VANET;road safety improvement;variable traffic status;vehicle-to-infrastructure communication scenario;vehicle-to-vehicle communication scenario;vehicular ad hoc network;Connected vehicles;Media Access Protocol;Throughput;Vehicular ad hoc networks;Connectivity probability;V2I;V2V;VANETs;connectivity probability;medium access control;medium access control (MAC);one-way;oneway;platoon;two-way;vehicle-to-infrastructure (V2I);vehicle-to-vehicle (V2V);vehicular ad hoc networks (VANETs)},
+ month = {Dec},
+ number = {12},
+ pages = {5596-5609},
+ title = {Performance Analysis of Connectivity Probability and Connectivity-Aware MAC Protocol Design for Platoon-Based VANETs},
+ volume = {64},
+ year = {2015},
+}
+
+@article{delcmac,
+ author = {X. Wang and J. Li},
+ doi = {10.1109/TPDS.2013.110},
+ issn = {1045-9219},
+ journaltitle = {IEEE Transactions on Parallel and Distributed Systems},
+ keywords = {access protocols;mobile ad hoc networks;radio transceivers;CMAC protocol;MANET;circuitry energy consumption;cooperative MAC protocol design;cooperative communication;energy consumption model;innovative network allocation vector setting;medium access interactions;mobile ad-hoc networks;network lifetime;relay selection strategy;transceiver circuitry;transmit amplifier;wireless networks;Cooperative communication;Information sharing;Lifetime estimation;Media Access Protocol;Relays;Network lifetime;cooperative communication;medium access control protocol;relay selection},
+ month = {April},
+ number = {4},
+ pages = {1010-1020},
+ title = {Improving the Network Lifetime of MANETs through Cooperative MAC Protocol Design},
+ volume = {26},
+ year = {2015},
+}
+
+@article{cehmac,
+ abstract = {In this paper, we introduce a cooperative medium access control (MAC) protocol, named cooperative energy harvesting (CEH)-MAC, that adapts its operation to the energy harvesting (EH) conditions in wireless body area networks (WBANs). In particular, the proposed protocol exploits the EH information in order to set an idle time that allows the relay nodes to charge their batteries and complete the cooperation phase successfully. Extensive simulations have shown that CEH-MAC significantly improves the network performance in terms of throughput, delay and energy efficiency compared to the cooperative operation of the baseline IEEE 802.15.6 standard.},
+ author = {Esteves, Volker and Antonopoulos, Angelos and Kartsakli, Elli and Puig-Vidal, Manel and Miribel-Català, Pere and Verikoukis, Christos},
+ doi = {10.3390/s150612635},
+ issn = {1424-8220},
+ journaltitle = {Sensors},
+ number = {6},
+ pages = {12635--12650},
+ pubmedid = {26029950},
+ title = {Cooperative Energy Harvesting-Adaptive MAC Protocol for WBANs},
+ url = {http://www.mdpi.com/1424-8220/15/6/12635},
+ volume = {15},
+ year = {2015},
+}
+
+@article{dfdmac,
+ author = {Y. Liao and K. Bian and L. Song and Z. Han},
+ doi = {10.1109/LCOMM.2015.2424696},
+ issn = {1089-7798},
+ journaltitle = {IEEE Communications Letters},
+ keywords = {access protocols;radio networks;radiofrequency interference;FD communication systems;PHY layer;RSI;band full duplex communications;double spectral efficiency;full-duplex MAC protocol design;hardware design techniques;medium access control;residual self-interference;self-interference cancellation;transmitters;High definition video;Media Access Protocol;Multiaccess communication;Sensors;Simulation;Throughput;Cognitive radio;MAC protocol design;full-duplex communications},
+ month = {July},
+ number = {7},
+ pages = {1185-1188},
+ title = {Full-Duplex MAC Protocol Design and Analysis},
+ volume = {19},
+ year = {2015},
+}
+
+@article{lodmac,
+ author = {Temel, Samil and Bekmezci, Ilker},
+ doi = {10.1016/j.comnet.2015.03.001},
+ journaltitle = {Computer Networks},
+ pages = {76--84},
+ publisher = {Elsevier},
+ title = {LODMAC: Location oriented directional MAC protocol for FANETs},
+ volume = {83},
+ year = {2015},
+}
+
+@article{imac,
+ abstract = {Targeting the medical monitoring applications of wireless body area networks (WBANs), a hybrid medium access control protocol using an interrupt mechanism (I-MAC) is proposed to improve the energy and time slot utilization efficiency and to meet the data delivery delay requirement at the same time. Unlike existing hybrid MAC protocols, a superframe structure with a longer length is adopted to avoid unnecessary beacons. The time slots are mostly allocated to nodes with periodic data sources. Short interruption slots are inserted into the superframe to convey the urgent data and to guarantee the real-time requirements of these data. During these interruption slots, the coordinator can break the running superframe and start a new superframe. A contention access period (CAP) is only activated when there are more data that need to be delivered. Experimental results show the effectiveness of the proposed MAC protocol in WBANs with low urgent traffic.},
+ author = {Shu, Minglei and Yuan, Dongfeng and Zhang, Chongqing and Wang, Yinglong and Chen, Changfang},
+ doi = {10.3390/s150612906},
+ issn = {1424-8220},
+ journaltitle = {Sensors},
+ number = {6},
+ pages = {12906--12931},
+ pubmedid = {26046596},
+ title = {A MAC Protocol for Medical Monitoring Applications of Wireless Body Area Networks},
+ url = {http://www.mdpi.com/1424-8220/15/6/12906},
+ volume = {15},
+ year = {2015},
+}
+
+@article{rcmac,
+ author = {P. Huang and C. Wang and L. Xiao},
+ doi = {10.1109/TC.2014.2308174},
+ issn = {0018-9340},
+ journaltitle = {IEEE Transactions on Computers},
+ keywords = {Zigbee;access protocols;channel allocation;energy conservation;radio transceivers;signal detection;telecommunication congestion control;telecommunication power management;telecommunication scheduling;wireless channels;wireless sensor networks;IEEE 802.15.4 RF transceiver;RC-MAC protocol;TelosB mote;TinyOS mote;WSN MAC protocol;collision reduction;contention-based MAC protocol;data gathering tree;distributed channel assignment;duty cycling;energy efficiency;event detection;event-driven wireless sensor network throughput;light traffic load;multichannel technique;ns-2 simulations;receiver centric MAC protocol;receiver-centric medium access scheduling;Bandwidth;Data communication;Media Access Protocol;Receivers;Schedules;Throughput;Wireless sensor networks;Wireless sensor networks;medium access control;multichannel;receiver-centric scheduling},
+ month = {April},
+ number = {4},
+ pages = {1149-1161},
+ title = {RC-MAC: A Receiver-Centric MAC Protocol for Event-Driven Wireless Sensor Networks},
+ volume = {64},
+ year = {2015},
+}
+
+@article{bsmac,
+ author = {A. N. Alvi and S. H. Bouk and S. H. Ahmed and M. A. Yaqub and N. Javaid and D. Kim},
+ doi = {10.1109/JCN.2015.000046},
+ issn = {1229-2370},
+ journaltitle = {Journal of Communications and Networks},
+ keywords = {access protocols;telecommunication power management;wireless sensor networks;BS-MAC;SJF algorithm;WSN;adaptive data control;adaptive time division multiple access based medium access control protocol;adaptive traffic loads;bitmap-assisted shortest job first based MAC;control overhead;enhanced TDMA based MAC protocol;hierarchical wireless sensor networks;member nodes;short node address;shortest job first algorithm;time slots;Delays;Energy consumption;Media Access Protocol;Steady-state;Time division multiple access;Wireless sensor networks;Contention free;medium access control (MAC);time division multiple access (TDMA);wireless sensor networks},
+ month = {June},
+ number = {3},
+ pages = {247-255},
+ title = {Enhanced TDMA based MAC protocol for adaptive data control in wireless sensor networks},
+ volume = {17},
+ year = {2015},
+}
+
+@article{rrscmac,
+ author = {Liu, Kai and Chang, Xiaoying and Liu, Feng and Wang, Xin and Vasilakos, Athanasios V},
+ doi = {10.1016/j.comnet.2015.08.020},
+ journaltitle = {Computer Networks},
+ pages = {262--282},
+ publisher = {Elsevier},
+ title = {A cooperative MAC protocol with rapid relay selection for wireless ad hoc networks},
+ volume = {91},
+ year = {2015},
+}
+
+@article{qsps,
+ author = {J. Liu and M. Li and B. Yuan and W. Liu},
+ doi = {10.1109/CC.2015.7084398},
+ issn = {1673-5447},
+ journaltitle = {China Communications},
+ keywords = {body area networks;energy conservation;telecommunication power management;time division multiple access;Q-sleep mode;QS-PS;TDMA;WBAN;allocated slots;awakening message;emergency packets;energy efficient MAC protocol;normal packets;quasisleep-preempt-supported;wireless body area network;Clocks;Delays;Energy efficiency;Receivers;Resource management;Sensors;Topology;Quasi-Sleep;TDMA;WBAN;delay;energy efficient;preemption},
+ month = {Feb},
+ number = {2},
+ pages = {11-20},
+ title = {A novel energy efficient MAC protocol for Wireless Body Area Network},
+ volume = {12},
+ year = {2015},
+}
+
+@article{pamac,
+ abstract = {In wireless body area networks (WBANs), various sensors and actuators are placed on/inside the human body and connected wirelessly. WBANs have specific requirements for healthcare and medical applications, hence, standard protocols like the IEEE 802.15.4 cannot fulfill all the requirements. Consequently, many medium access control (MAC) protocols, mostly derived from the IEEE 802.15.4 superframe structure, have been studied. Nevertheless, they do not support a differentiated quality of service (QoS) for the various forms of traffic coexisting in a WBAN. In particular, a QoS-aware MAC protocol is essential for WBANs operating in the unlicensed Industrial, Scientific, and Medical (ISM) bands, because different wireless services like Bluetooth, WiFi, and Zigbee may coexist there and cause severe interference. In this paper, we propose a priority-based adaptive MAC (PA-MAC) protocol for WBANs in unlicensed bands, which allocates time slots dynamically, based on the traffic priority. Further, multiple channels are effectively utilized to reduce access delays in a WBAN, in the presence of coexisting systems. Our performance evaluation results show that the proposed PA-MAC outperforms the IEEE 802.15.4 MAC and the conventional priority-based MAC in terms of the average transmission time, throughput, energy consumption, and data collision ratio.},
+ articlenumber = {401},
+ author = {Bhandari, Sabin and Moh, Sangman},
+ doi = {10.3390/s16030401},
+ issn = {1424-8220},
+ journaltitle = {Sensors},
+ number = {3},
+ title = {A Priority-Based Adaptive MAC Protocol for Wireless Body Area Networks},
+ url = {http://www.mdpi.com/1424-8220/16/3/401},
+ volume = {16},
+ year = {2016},
+}
+
+@article{bestmac,
+ author = {A. N. Alvi and S. H. Bouk and S. H. Ahmed and M. A. Yaqub and M. Sarkar and H. Song},
+ doi = {10.1109/ACCESS.2016.2515096},
+ issn = {2169-3536},
+ journaltitle = {IEEE Access},
+ keywords = {energy consumption;knapsack problems;quality control;smart cities;telecommunication power management;telecommunication scheduling;telecommunication traffic;time division multiple access;wireless sensor networks;BEST-MAC;ICT;Information and Communication Technologies;adaptive traffic load;average packet delay minimization;bitmap-assisted efficient and scalable TDMA-based WSN MAC protocol;control overhead reducetion;data traffic;delay sensitive applications;energy consumption;knapsack algorithm;medium access control protocol;member node identification;quality control improvement;short node address;small size time slot scheduling;smart cities;time division multiple access;wireless communication;wireless sensor network;Delays;Media Access Protocol;Smart cities;Time division multiple access;Wireless communication;Wireless sensor networks;Contention Free;MAC;Smart Cities;Smart cities;TDMA;Wireless Sensor Networks;contention free;wireless sensor networks},
+ month = {},
+ number = {},
+ pages = {312-322},
+ title = {BEST-MAC: Bitmap-Assisted Efficient and Scalable TDMA-Based WSN MAC Protocol for Smart Cities},
+ volume = {4},
+ year = {2016},
+}
+
+@article{upcmac,
+ author = {Su, Yishan and Zhu, Yibo and Mo, Haining and Cui, Jun-Hong and Jin, Zhigang},
+ doi = {10.1016/j.adhoc.2014.10.014},
+ journaltitle = {Ad Hoc Networks},
+ pages = {36--49},
+ publisher = {Elsevier},
+ title = {A joint power control and rate adaptation MAC protocol for underwater sensor networks},
+ volume = {26},
+ year = {2015},
+}
+
+@article{hmmac,
+ abstract = {In a regular wireless ad hoc network, the Medium Access Control (MAC) protocol coordinates channel access among nodes, and the throughput of the network is limited by the bandwidth of a single channel. The multi-channel MAC protocols can exploit multiple channels to achieve high network throughput by enabling more concurrent transmissions. In this paper, we propose a hybrid and adaptive protocol, called H-MMAC, which utilizes multi-channel resources more efficiently than other multi-channel MAC protocols. The main idea is to adopt the IEEE 802.11 Power Saving Mechanism and to allow nodes to transmit data packets while other nodes try to negotiate the data channel during the Ad hoc Traffic Indication Message window based on the network traffic load. The analytical and simulation results show that the proposed H-MMAC protocol improves the network performance significantly in terms of the aggregate throughput, average delay, fairness and energy efficiency.},
+ author = {Dang, Duc Ngoc Minh and Hong, Choong Seon and Lee, Sungwon},
+ day = {01},
+ doi = {10.1007/s11276-014-0789-8},
+ issn = {1572-8196},
+ journaltitle = {Wireless Networks},
+ month = {Feb},
+ number = {2},
+ pages = {387--404},
+ title = {A hybrid multi-channel MAC protocol for wireless ad hoc networks},
+ url = {https://doi.org/10.1007/s11276-014-0789-8},
+ volume = {21},
+ year = {2015},
+}
+
+@inproceedings{kim2015,
+ author = {J. K. Kim and W. K. Kim and J. H. Kim},
+ booktitle = {2015 IEEE Globecom Workshops (GC Wkshps)},
+ doi = {10.1109/GLOCOMW.2015.7414143},
+ issn = {},
+ keywords = {access protocols;power consumption;wireless LAN;MAC protocol data unit;WLAN;asymmetric transmission time;full duplex MAC protocol;full duplex communication;power consumption;primary transmission time;secondary transmission time;wireless local area network;Degradation;Media Access Protocol;Performance evaluation;Radiation detectors;Schedules;Throughput;Wireless LAN},
+ month = {Dec},
+ number = {},
+ pages = {1-5},
+ title = {A New Full Duplex MAC Protocol to Solve the Asymmetric Transmission Time},
+ volume = {},
+ year = {2015},
+}
+
+@article{sywim,
+ author = {T. N. Le and A. Pegatoquet and O. Berder and O. Sentieys},
+ doi = {10.1109/JSEN.2015.2472566},
+ issn = {1530-437X},
+ journaltitle = {IEEE Sensors Journal},
+ keywords = {access protocols;energy conservation;energy harvesting;quality of service;synchronisation;telecommunication power management;wireless sensor networks;battery-powered WSN node;energy neutral operation condition;energy-efficient power manager;multihop wireless sensor network;periodic energy harvesting source;quality of service;synchronized wake-up interval MAC protocol;Batteries;Media Access Protocol;Sensors;Spread spectrum communication;Synchronization;Wireless communication;Wireless sensor networks;Wireless sensor networks;energy harvesting;energy neutral operation;multi-hop communications;power manager},
+ month = {Dec},
+ number = {12},
+ pages = {7208-7220},
+ title = {Energy-Efficient Power Manager and MAC Protocol for Multi-Hop Wireless Sensor Networks Powered by Periodic Energy Harvesting Sources},
+ volume = {15},
+ year = {2015},
+}
+
+@article{smcmac,
+ author = {S. Pandit and G. Singh},
+ doi = {10.1109/TVT.2014.2334605},
+ issn = {0018-9545},
+ journaltitle = {IEEE Transactions on Vehicular Technology},
+ keywords = {access protocols;cognitive radio;telecommunication control;telecommunication scheduling;SMC-MAC protocol;backoff algorithm;cognitive users;control channel protocol;data transmission;distributed cognitive radio network;medium access control protocol;self-scheduled multichannel cognitive radio MAC;sensing-sharing;throughput enhancement;unutilized licensed channels;Cognitive radio;Data communication;Media Access Protocol;Sensors;Throughput;Backoff algorithm;cognitive radio;contention;medium access control (MAC) protocol;self-scheduled;sensing and sharing;throughput},
+ month = {May},
+ number = {5},
+ pages = {1991-2000},
+ title = {Backoff Algorithm in Cognitive Radio MAC Protocol for Throughput Enhancement},
+ volume = {64},
+ year = {2015},
+}
+
+@inproceedings{echoring,
+ author = {C. Dombrowski and J. Gross},
+ booktitle = {Proceedings of European Wireless 2015; 21th European Wireless Conference},
+ doi = {},
+ issn = {},
+ keywords = {},
+ month = {May},
+ number = {},
+ pages = {1-8},
+ title = {EchoRing: A Low-Latency, Reliable Token-Passing MAC Protocol for Wireless Industrial Networks},
+ volume = {},
+ year = {2015},
+}
+
+@article{fdcmac2015b,
+ author = {L. T. Tan and L. B. Le},
+ doi = {10.1109/ACCESS.2015.2509449},
+ issn = {2169-3536},
+ journaltitle = {IEEE Access},
+ keywords = {access protocols;cognitive radio;interference suppression;radio networks;radio spectrum management;signal detection;FD SUs;FD transceiver;FD transmission modes;FDC-MAC configuration optimization;FDC-MAC protocol;adaptive medium access control protocol;channel contention;full-duplex MAC protocol;full-duplex cognitive radio networks;half-duplex transmission;mathematical model;secondary users;self-interference mitigation;spectrum sensing duration;transmit power level;High definition video;Media Access Protocol;Sensors;Standards;Throughput;White spaces;Asynchronous MAC;full-duplex MAC;full-duplex cognitive radios;full-duplex spectrum sensing;fullduplex spectrum sensing;optimal sensing duration;self-interference control;throughput analysis;throughput maximization},
+ month = {},
+ number = {},
+ pages = {2715-2729},
+ title = {Design and Optimal Configuration of Full-Duplex MAC Protocol for Cognitive Radio Networks Considering Self-Interference},
+ volume = {3},
+ year = {2015},
+}
+
+@article{lcsma,
+ author = {C. Buratti and R. Verdone},
+ doi = {10.1109/TVT.2015.2391302},
+ issn = {0018-9545},
+ journaltitle = {IEEE Transactions on Vehicular Technology},
+ keywords = {access protocols;carrier sense multiple access;wireless sensor networks;L-CSMA;MAC protocol;carrier-sensing multiple access;carrier-sensing phase;medium access control protocol;multihop linear wireless sensor network;packet success probability;protocol overhead;Mathematical model;Media Access Protocol;Multiaccess communication;Relays;Sensors;Throughput;CSMA;MAC protocols;linear networks;mathematical modelling;multihop;wireless sensor networks},
+ month = {Jan},
+ number = {1},
+ pages = {251-265},
+ title = {L-CSMA: A MAC Protocol for Multihop Linear Wireless (Sensor) Networks},
+ volume = {65},
+ year = {2016},
+}
+
+@inproceedings{cfmac,
+ author = {L. Sanabria-Russo and F. Gringoli and J. Barcelo and B. Bellalta},
+ booktitle = {2015 IEEE International Conference on Communications (ICC)},
+ doi = {10.1109/ICC.2015.7248459},
+ issn = {1550-3607},
+ keywords = {access protocols;firmware;wireless LAN;CF-MAC protocol;WLAN;collision-free MAC protocol;contention mechanism;legacy firmware;wireless local area networks;wireless network cards;IEEE 802.11 Standard;Media Access Protocol;Multiaccess communication;Radiation detectors;Schedules;Throughput;Collision-Free;Multiaccess Communication;OpenFWWF;Wireless LAN},
+ month = {June},
+ number = {},
+ pages = {1036-1042},
+ title = {Implementation and experimental evaluation of a Collision-Free MAC protocol for WLANs},
+ volume = {},
+ year = {2015},
+}
+
+@article{cmac2015,
+ author = {Y. Kim and M. Lee and T. J. Lee},
+ doi = {10.1109/TVT.2015.2475165},
+ issn = {0018-9545},
+ journaltitle = {IEEE Transactions on Vehicular Technology},
+ keywords = {Internet of Things;access protocols;broadcasting;energy harvesting;multi-access systems;multiuser channels;probability;road safety;telecommunication control;telecommunication scheduling;vehicular ad hoc networks;C-MAC protocol;Internet-of-Things devices;RSU;VANET;WAVE;contention-free broadcasting;control messages;coordinated multichannel medium access control protocol;roadside units;safety messages;service channels;vehicle nodes;vehicular ad hoc networks;wireless access in vehicular environments;Broadcasting;Delays;Media Access Protocol;Safety;Vehicles;Vehicular ad hoc networks;Energy harvesting;medium access control (MAC) protocol;safety message;vehicular ad hoc network (VANET);vehicular environment},
+ month = {Aug},
+ number = {8},
+ pages = {6508-6517},
+ title = {Coordinated Multichannel MAC Protocol for Vehicular Ad Hoc Networks},
+ volume = {65},
+ year = {2016},
+}
+
+@article{adamac,
+ abstract = {With the increasing demands for high-quality health-care services, medical cyber-physical systems over wireless body sensor networks have emerged as a promising solution for vital life signals monitoring. These systems require the communication protocols to be both reliable and real-time in data transmissions. IEEE 802.15.4 can be regarded as the canonical protocols in this area owing to its low-power and low-cost features. However, it falls short of reliability and timeliness guarantees. To address this issue, we propose an adaptive MAC protocol based on IEEE 802.15.4, namely Ada-MAC. The proposed protocol combines schedule-based on time-triggered protocol and contention-based CSMA/CA mechanism. It can not only enable dynamic Guaranteed Time Slots allocation but also provide differentiated services for different nodes according to their data types. The proposed protocol is implemented on the OMNeT++ platform. Extensive simulations are conducted to evaluate the performance of Ada-MAC in comparison with the traditional IEEE 802.15.4 MAC. The results show the superiority of the proposed protocol in terms of reliability and timeliness.},
+ author = {Xia, Feng and Wang, Linqiang and Zhang, Daqiang and He, Daojing and Kong, Xiangjie},
+ day = {01},
+ doi = {10.1007/s11235-014-9895-2},
+ issn = {1572-9451},
+ journaltitle = {Telecommunication Systems},
+ month = {Feb},
+ number = {2},
+ pages = {125--138},
+ title = {An adaptive MAC protocol for real-time and reliable communications in medical cyber-physical systems},
+ url = {https://doi.org/10.1007/s11235-014-9895-2},
+ volume = {58},
+ year = {2015},
+}
+
+@article{sdmac,
+ author = {Y. Liu and R. Yu and M. Pan and Y. Zhang and S. Xie},
+ doi = {10.1109/TVT.2016.2555084},
+ issn = {0018-9545},
+ journaltitle = {IEEE Transactions on Vehicular Technology},
+ keywords = {access protocols;cognitive radio;dynamic programming;fading channels;interference suppression;iterative methods;CM2M;SD-MAC;access processes;adaptive sensing;cognitive machine-to-machine networks;cognitive radio technology;diverse communication applications;fading channel scenario;interference reduction;iterative adaptive dynamic programming algorithm;local sensing process;low-power communications;medium access control protocol;network throughput maximization;optimal decision processes;primary systems;spectrum channels;spectrum database-driven MAC protocol;spectrum scarcity;ubiquitous connectivity;Adaptation models;Databases;Fading channels;Media Access Protocol;Sensors;Signal to noise ratio;Cognitive machine-to-machine (CM2M) networks;medium access control (MAC);spectrum database;spectrum sensing},
+ month = {Feb},
+ number = {2},
+ pages = {1456-1467},
+ title = {SD-MAC: Spectrum Database-Driven MAC Protocol for Cognitive Machine-to-Machine Networks},
+ volume = {66},
+ year = {2017},
+}
+
+@article{iqueuemac,
+ author = {S. Zhuo and Z. Wang and Y. Q. Song and Z. Wang and L. Almeida},
+ doi = {10.1109/TMC.2015.2473852},
+ issn = {1536-1233},
+ journaltitle = {IEEE Transactions on Mobile Computing},
+ keywords = {carrier sense multiple access;queueing theory;resource allocation;synchronisation;telecommunication traffic;time division multiple access;wireless sensor networks;CoSenS;Ri-MAC-MC;SIM32W108 chips;WSN protocols;carrier sense multiple access;contention-based CSMA mechanism;contention-free TDMA mechanism;dynamic slot allocation;hybrid CSMA-TDMA MAC;iQueue-MAC;packet buffering;packet delay;time division multiple access;traffic adaptive multichannel MAC protocol;transmission slots;variable-bursty traffic;wireless sensor networks;Media Access Protocol;Resource management;Routing protocols;Time division multiple access;Wireless sensor networks;CSMA/TDMA;MAC protocol;Wireless sensor networks;multi-channel;queue-length;traffic adaptation},
+ month = {July},
+ number = {7},
+ pages = {1600-1613},
+ title = {A Traffic Adaptive Multi-Channel MAC Protocol with Dynamic Slot Allocation for WSNs},
+ volume = {15},
+ year = {2016},
+}
+
+@inproceedings{mmacda,
+ author = {Duc Ngoc Minh Dang and Huong Tra Le and Hyo Sung Kang and Choong Seon Hong and Jongwon Choe},
+ booktitle = {2015 International Conference on Information Networking (ICOIN)},
+ doi = {10.1109/ICOIN.2015.7057861},
+ issn = {1550-445X},
+ keywords = {ad hoc networks;carrier sense multiple access;channel allocation;directive antennas;omnidirectional antennas;telecommunication traffic;wireless channels;ATIM;CSMA-based access protocol;CSMA/CA;DCF;IEEE 802.11;MMAC-DA;PSM;aggregate throughput;announcement traffic indication message;carrier sense multiple access with collision avoidance;data exchange;data window;distributed coordination function;energy efficiency;flow starvation;multichannel MAC protocol;multiple channel resources;omnidirectional antenna;packet delivery ratio;power saving mechanism;spatial reusability;wireless ad hoc network;wireless channel;Data communication;Directional antennas;Directive antennas;IEEE 802.11 Standards;Media Access Protocol;Receivers;Ad hoc networks;MAC protocol;Multi-channel;directional antennas},
+ month = {Jan},
+ number = {},
+ pages = {81-86},
+ title = {Multi-channel MAC protocol with Directional Antennas in wireless ad hoc networks},
+ volume = {},
+ year = {2015},
}
+
+@article{tars,
+ acmid = {3105149},
+ articleno = {27},
+ author = {Han, Yu and Fei, Yunsi},
+ doi = {10.1145/3105149},
+ issn = {1550-4859},
+ issue_date = {September 2017},
+ journaltitle = {ACM Trans. Sen. Netw.},
+ keywords = {Medium access control, receiver synchronization, traffic adaptation, underwater sensor networks, utility optimization},
+ location = {New York, NY, USA},
+ month = {09},
+ number = {4},
+ numpages = {25},
+ pages = {27:1--27:25},
+ publisher = {ACM},
+ title = {TARS: A Traffic-Adaptive Receiver-Synchronized MAC Protocol for Underwater Sensor Networks},
+ url = {http://doi.acm.org/10.1145/3105149},
+ volume = {13},
+ year = {2017},
+}
+
+@article{dact,
+ author = {Tarchi, Daniele and Fantacci, Romano and Marabissi, Dania},
+ doi = {10.1002/ett.2955},
+ issn = {2161-3915},
+ journaltitle = {Transactions on Emerging Telecommunications Technologies},
+ note = {e2955 ett.2955},
+ number = {3},
+ pages = {e2955--n/a},
+ title = {An M2M cognitive MAC protocol for overlaid OFDMA environments},
+ url = {http://dx.doi.org/10.1002/ett.2955},
+ volume = {28},
+ year = {2017},
+}
+
+@article{csmaeca,
+ acmid = {3068733},
+ author = {Sanabria-Russo, Luis and Barcelo, Jaume and Bellalta, Boris and Gringoli, Francesco},
+ doi = {10.1109/TNET.2016.2587907},
+ issn = {1063-6692},
+ issue_date = {February 2017},
+ journaltitle = {IEEE/ACM Trans. Netw.},
+ location = {Piscataway, NJ, USA},
+ month = {02},
+ number = {1},
+ numpages = {14},
+ pages = {492--505},
+ publisher = {IEEE Press},
+ title = {A High Efficiency MAC Protocol for WLANs: Providing Fairness in Dense Scenarios},
+ url = {https://doi.org/10.1109/TNET.2016.2587907},
+ volume = {25},
+ year = {2017},
+}
+
+@article{dcdmac,
+ abstract = {Directional communication in wireless sensor networks minimizes interference and thereby increases reliability and throughput of the network. Hence, directional wireless sensor networks (DWSNs) are fastly attracting the interests of researchers and industry experts around the globe. However, in DWSNs the conventional medium access control protocols face some new challenges including the synchronization among the nodes, directional hidden terminal and deafness problems, etc. For taking the advantages of spatial reusability and increased coverage from directional communications, a low duty cycle directional Medium Access control protocol for mobility based DWSNs, termed as DCD-MAC, is developed in this paper. To reduce energy consumption due to idle listening, duty cycling is extensively used in WSNs. In DCD-MAC, each pair of parent and child sensor nodes performs synchronization with each other before data communication. The nodes in the network schedule their time of data transmissions in such a way that the number of collisions occurred during transmissions from multiple nodes is minimized. The sensor nodes are kept active only when the nodes need to communicate with each other. The DCD-MAC exploits localized information of mobile nodes in a distributed manner and thus it gives weighted fair access of transmission slots to the nodes. As a final point, we have studied the performance of our proposed protocol through extensive simulations in NS-3 and the results show that the DCD-MAC gives better reliability, throughput, end-to-end delay, network lifetime and overhead comparing to the related directional MAC protocols.},
+ author = {Nur, Fernaz Narin and Sharmin, Selina and Razzaque, Md. Abdur and Islam, Md. Shariful and Hassan, Mohammad Mehedi},
+ day = {01},
+ doi = {10.1007/s11277-016-3728-4},
+ issn = {1572-834X},
+ journaltitle = {Wireless Personal Communications},
+ month = {Oct},
+ number = {4},
+ pages = {5035--5059},
+ title = {A Low Duty Cycle MAC Protocol for Directional Wireless Sensor Networks},
+ url = {https://doi.org/10.1007/s11277-016-3728-4},
+ volume = {96},
+ year = {2017},
+}
+
+@article{lach,
+ abstract = {Using multiple channels in wireless networks improves spatial reuse and reduces collision probability and thus enhances network throughput. Designing a multi-channel MAC protocol is challenging because multi-channel-specific issues such as channel assignment, the multi-channel hidden terminal problem, and the missing receiver problem, must be solved. Most existing multi-channel MAC protocols suffer from either higher hardware cost or poor throughput. Some channel hopping multi-channel protocols achieve pretty good performance in certain situations but fail to adjust their channel hopping mechanisms according to varied traffic loads. In this paper, we propose a load-aware channel hopping MAC protocol (LACH) that solves all the multi-channel-specific problems mentioned above.LACH enables nodes to dynamically adjust their schedules based on their traffic loads. In addition to load awareness, LACH has several other attractive features: (1) Each node is equipped with a single half-duplex transceiver. (2) Each node's initial hopping sequence is generated by its ID. Knowing the neighbor nodes' IDs, a node can calculate its neighbors' initial channel hopping sequences without control packet exchanges. (3) Nodes can be evenly distributed among available channels. Through performance analysis, simulations, and real system implementation, we verify that LACH is a promising protocol suitable for a network with time-varied traffic loads.},
+ author = {Chao, Chih-Min and Tsai, Hsien-Chen and Huang, Chao-Ying},
+ day = {01},
+ doi = {10.1007/s11276-015-1139-1},
+ issn = {1572-8196},
+ journaltitle = {Wireless Networks},
+ month = {Jan},
+ number = {1},
+ pages = {89--101},
+ title = {Load-aware channel hopping protocol design for mobile ad hoc networks},
+ url = {https://doi.org/10.1007/s11276-015-1139-1},
+ volume = {23},
+ year = {2017},
+}
+
+@article{ddcmac,
+ abstract = {In this paper, a dynamic cooperative MAC protocol (DDC-MAC) based on cluster network topology is proposed, which has the capability of differentiated service mechanisms and long-range communication. In DDC-MAC, heterogeneous communications are classified according to service types and quality of service (QoS) requirements, i.e., periodic communication mode (PC mode) is extracted with a QoS guarantee for high-frequency periodic information exchange based on adapt-TDMA mechanisms, while other services are classified as being in on-demand communication mode (OC mode), which includes channel contention and access mechanisms based on a multiple priority algorithm. OC mode is embedded into the adapt-TDMA process adaptively, and the two communication modes can work in parallel. Furthermore, adaptive array hybrid antenna systems and cooperative communication with optimal relay are presented, to exploit the opportunity for long-range transmission, while an adaptive channel back-off sequence is deduced, to mitigate packet collision and network congestion. Moreover, we developed an analytical framework to quantify the performance of the DDC-MAC protocol and conducted extensive simulation. Simulation results show that the proposed DDC-MAC protocol enhances network performance in diverse scenarios, and significantly improves network throughput and reduces average delay compared with other MAC protocols.},
+ articlenumber = {14},
+ author = {Gao, Chao and Zeng, Bin and Lu, Jianhua and Zhao, Guorong},
+ doi = {10.3390/jsan6030014},
+ issn = {2224-2708},
+ journaltitle = {Journal of Sensor and Actuator Networks},
+ number = {3},
+ title = {Dynamic Cooperative MAC Protocol for Navigation Carrier Ad Hoc Networks: A DiffServ-Based Approach},
+ url = {http://www.mdpi.com/2224-2708/6/3/14},
+ volume = {6},
+ year = {2017},
+}
+
+@article{omac2017,
+ author = {A. Rajandekar and B. Sikdar},
+ doi = {10.1109/LCOMM.2017.2659725},
+ issn = {1089-7798},
+ journaltitle = {IEEE Communications Letters},
+ keywords = {Data communication;IEEE 802.11 Standard;Machine-to-machine communications;Media Access Protocol;Radio frequency;White spaces;IoT;M2M communication;MAC protocols;WiFi;opportunistic communication},
+ month = {},
+ number = {99},
+ pages = {1-1},
+ title = {O-MAC: Opportunistic MAC Protocol for M2M Communication in WiFi White Spaces},
+ volume = {PP},
+ year = {2017},
+}
+
+@article{eecomac,
+ abstract = {This paper presents an energy-efficient cooperative MAC (EECO-MAC) protocol using power control in mobile ad hoc networks. Cooperative communications improve network performance by taking full advantage of the broadcast nature of wireless channels. The power control technique improves the network lifetime by adjusting the transmission power dynamically. We propose the best partnership selection algorithm, which takes energy consumption into consideration for selection of the optimal cooperative helper to join in the transmission. Through exchanging control packets, the optimal transmission power is allocated for senders to transmit data packets to receivers. In order to enhance energy saving, space--time backoff and time--space backoff algorithms are proposed. Simulation results show that EECO-MAC consumes less energy and prolongs the network lifetime compared to IEEE 802.11 DCF and CoopMAC at the cost of delay. Performance improvement offered by our proposed protocol is apparent in congested networks where nodes have low and limited energy.},
+ author = {Zhang, Xiaoying and Guo, Lei and Anpalagan, Alagan and Khwaja, Ahmed Shaharyar},
+ day = {01},
+ doi = {10.1007/s11277-016-3580-6},
+ issn = {1572-834X},
+ journaltitle = {Wireless Personal Communications},
+ month = {Feb},
+ number = {3},
+ pages = {843--861},
+ title = {Performance of Energy-Efficient Cooperative MAC Protocol with Power Backoff in MANETs},
+ url = {https://doi.org/10.1007/s11277-016-3580-6},
+ volume = {92},
+ year = {2017},
+}
+
+@article{prin,
+ abstract = {Wireless sensor networks (WSNs) are used in a variety of applications to sense and transfer information to the centralized node with energy efficiency increasing the network's lifespan. Other factors, such as quality of service (QoS) is also important to improve the performance of the WSNs, by increasing throughput and reducing end-to-end delay. In this paper, we evaluate the importance of QoS in the Medium Access Control (MAC) protocol for WSNs using different metrics and parameters such as energy efficiency, throughput, delay, and the network lifespan. We propose a new QoS MAC protocol, ``PRIority in Node'' (PRIN), using static priority in the source and the intermediate node and priority among the node which is one hop from the sink node to achieve QoS in WSNs. Simulation results are compared with those of the synchronous MAC protocol in terms of QoS parameters to show the improved performance of the proposed MAC protocol.},
+ author = {Subramanian, Ananda Kumar and Paramasivam, Ilango},
+ day = {01},
+ doi = {10.1007/s11277-016-3581-5},
+ issn = {1572-834X},
+ journaltitle = {Wireless Personal Communications},
+ month = {Feb},
+ number = {3},
+ pages = {863--881},
+ title = {PRIN: A Priority-Based Energy Efficient MAC Protocol for Wireless Sensor Networks Varying the Sample Inter-Arrival Time},
+ url = {https://doi.org/10.1007/s11277-016-3581-5},
+ volume = {92},
+ year = {2017},
+}
+
+@article{ahmac,
+ author = {Al-Sulaifanie, Adnan Ismail and Biswas, Subir and Khorsheed Al-Sulaifanie, Bayez},
+ doi = {10.1155/2017/8105954},
+ journaltitle = {Journal of Sensors},
+ publisher = {Hindawi Publishing Corporation},
+ title = {AH-MAC: Adaptive Hierarchical MAC Protocol for Low-Rate Wireless Sensor Network Applications},
+ volume = {2017},
+ year = {2017},
+}
+
diff --git a/data/db.yaml b/data/db.yaml
index b2d4e1f..df467d4 100644
--- a/data/db.yaml
+++ b/data/db.yaml
@@ -65,8 +65,10 @@ features:
name: Vehicular mobile ad hoc network
application.console:
name: Serial console
- application.iwsan:
- name: Industrial wireless sensor actuator network
+ application.industrial:
+ name: Industrial
+ application.underwater:
+ name: Underwater
time:
name: Time model
@@ -682,7 +684,8 @@ algos:
name: PriorityMAC
ref: [priomac]
features:
- application.iwsan:
+ application.industrial:
+ application.wsn:
# access to the medium is contended for AM1/2, with exponential
# backoff
access.random:
@@ -1631,4 +1634,171 @@ algos:
name: LMAC
longname: Latency MAC
ref: [lmac2009]
+ fdcmac2015a:
+ name: FDC-MAC
+ longname: Full-Duplex Cognitive Medium Access Control
+ ref: [fdcmac2015a]
+ dsp:
+ name: DSP
+ longname: Dynamic Switching Protocol
+ ref: [dsp]
+ hehbmac:
+ name: HEH-BMAC
+ longname: Human Energy Harvesting Medium Access Control
+ ref: [hehbmac]
+ camac2015:
+ name: CA MAC
+ longname: Connectivity-Aware MAC
+ ref: [camac2015]
+ features:
+ application.vanet:
+ delcmac:
+ name: DEL-CMAC
+ longname: Distributed Energy-Adaptive Location-Based Cooperative MAC
+ ref: [delcmac]
+ cehmac:
+ name: CEH-MAC
+ longname: Cooperative Energy Harvesting MAC
+ ref: [cehmac]
+ dfdmac:
+ name: Distributed FD-MAC
+ longname: Distributed Full-Duplex MAC
+ ref: [dfdmac]
+ lodmac:
+ name: LODMAC
+ longname: Location Oriented Directional MAC
+ ref: [lodmac]
+ imac:
+ name: I-MAC
+ longname: Interrupt MAC
+ ref: [imac]
+ rcmac:
+ name: RC-MAC
+ longname: Receiver-centric MAC
+ ref: [rcmac]
+ bsmac:
+ name: BS-MAC
+ longname: Bitmap-assisted Shortest Job First MAC
+ ref: [bsmac]
+ rrscmac:
+ name: RRS-CMAC
+ longname: Rapid Relay Selection Cooperative MAC
+ ref: [rrscmac]
+ qsps:
+ name: QS-PS
+ longname: Quasi-Sleep-Preempt-Supported
+ ref: [qsps]
+ pamac:
+ name: PA-MAC
+ longname: Priority-based Adaptive MAC
+ ref: [pamac]
+ bestmac:
+ name: BEST-MAC
+ longname: Bitmap-assisted Efficient and Scalable TDMA-based MAC
+ ref: [bestmac]
+ upcmac:
+ name: UPC-MAC
+ longname: Underwater Power Control MAC
+ ref: [upcmac]
+ features:
+ application.wsn:
+ application.underwater:
+ hmmac:
+ name: H-MMAC
+ longname: Hybrid and Adaptive Multi-Channel MAC
+ ref: [hmmac]
+ features:
+ channels.multi:
+ kim2015:
+ name: Kim’s proposal
+ ref: [kim2015]
+ sywim:
+ name: SyWiM
+ longname: Synchronized Wake-up Interval MAC
+ ref: [sywim]
+ smcmac:
+ name: SMC-MAC
+ longname: Self-Scheduled Multichannel Cognitive Radio MAC
+ ref: [smcmac]
+ echoring:
+ name: EchoRing
+ ref: [echoring]
+ features:
+ access.token-passing:
+ application.industrial:
+ fdcmac2015b:
+ name: FDC-MAC
+ longname: Full Duplex Cognitive MAC
+ ref: [fdcmac2015b]
+ lcsma:
+ name: L-CSMA
+ longname: Linear CSMA
+ ref: [lcsma]
+ cfmac:
+ name: CF-MAC
+ longname: Collision-Free MAC
+ ref: [cfmac]
+ cmac2015:
+ name: C-MAC
+ longname: Coordinated Multichannel MAC
+ ref: [cmac2015]
+ adamac:
+ name: Ada-MAC
+ longname: Adaptive MAC
+ ref: [adamac]
+ sdmac:
+ name: SD-MAC
+ longname: Spectrum Database-Driven MAC
+ ref: [sdmac]
+ iqueuemac:
+ name: iQueue-MAC
+ ref: [iqueuemac]
+ mmacda:
+ name: MMAC-DA
+ longname: Multi-channel MAC with Directional Antennas
+ ref: [mmacda]
+ tars:
+ name: TARS
+ longname: Traffic-Adaptive Receiver-Synchronized underwater MAC
+ ref: [tars]
+ features:
+ application.underwater:
+ application.wsn:
+ dact:
+ name: DACT
+ longname: Data Aided Cognitive Technique
+ ref: [dact]
+ features:
+ application.industrial:
+ csmaeca:
+ name: CSMA/ECA
+ longname: Carrier Sense Multiple Access with Enhanced Collision Avoidance
+ ref: [csmaeca]
+ dcdmac:
+ name: DCD-MAC
+ ref: [dcdmac]
+ lach:
+ name: LACH
+ longname: Load-aware Channel Hopping MAC
+ ref: [lach]
+ ddcmac:
+ name: DDC-MAC
+ longname: Dynamic Cooperative MAC
+ ref: [ddcmac]
+ omac2017:
+ name: O-MAC
+ longname: Opportunistic MAC
+ ref: [omac2017]
+ eecomac:
+ name: EECO-MAC
+ longname: Energy-Efficient Cooperative MAC
+ ref: [eecomac]
+ prin:
+ name: PRIN
+ longname: Priority in Node
+ ref: [prin]
+ ahmac:
+ name: AH-MAC
+ longname: Adaptive Hierarchical MAC
+ ref: [ahmac]