Multi-beam Directional Antennas Research Articles

Optimal Multicasting in Dual mmWave/μ Wave 5G NR Deployments With Multi-Beam Directional Antennas

Optimal Multicasting in Dual mmWave/μ Wave 5G NR Deployments With Multi-Beam Directional Antennas

Optimal Multicasting in Millimeter Wave 5G NR With Multi-Beam Directional Antennas

Optimal Multicasting in Millimeter Wave 5G NR With Multi-Beam Directional Antennas

A novel routing protocol for reducing packet delay with multi-beam antennas

Ad hoc networks are infrastructureless networks consisting of static and/or mobile nodes. These networks are deployed for a wide range of applications. Having an efficient routing protocol for communication between the nodes can be critical. Our goal in this paper is to design a routing protocol that capitalizes on Multi-Beam directional Antennas (MBAs) to significantly reduce the end-to-end (E2E) delay in multi-hop ad hoc networks that service multiple traffic flows. Previously, we proposed a multi-beam directional antenna MAC protocol, and a Mixed Integer Linear Programming model that exploits MBAs’ capabilities for delay minimization. Solving this model showed that the routes that are selected for different flows need to have certain key characteristics that depart from the traditional shortest-route philosophy. Based on these characteristics, we design, in this paper, an MBA-Delay-Reducing Routing protocol (MBA-DRR) that fully harnesses the benefits of MBAs for delay reduction. The benefits of this protocol apply to all types of multi-hop MBA-based ad hoc networks, both mobile and static. The evaluation on a multi-flow static scenario shows that MBA-DRR, with a delay of just 4.4 ms, gets very close to the optimal solution with a delay of 2.5 ms. Comparatively, Reactive-Geographic hybrid Routing, a shortest-route protocol, has a delay of 48 ms. An evaluation on a representative multi-flow mobile scenario shows that, while a single-beam directional MAC reduces the E2E delay from 700 ms to 40 ms, and a multi-beam directional MAC halves this to 20 ms, our proposed routing protocol further cuts it to 9 ms.

Volcano Routing: A Multi-Pipe High-Throughput Routing Protocol with Hole Avoidance for Multi-Beam Directional Mesh Networks

The emergence of multi-beam directional antennas (MBDAs) has paved the way for fast and high-throughput data communications by providing concurrent multi-directional transmissions. However, the existing routing protocols are not capable of utilizing the advantages of MBDAs. In this paper, we have developed a new routing scheme, called volcano routing, which can exploit the concurrent packet dispatching capability of MBDAs for high-throughput data delivery. Its topology resembles the flow of volcano lava and several routing “pipes” are used, which can detour around the network “holes” or blocked areas. The routing process consists of two phases: 1) Main path search phase: There is a main path at the core of each pipe. Multiple optimal main paths are formed that have a high potential of adding side nodes to enable multi-beam communications. A hierarchical scoring system and the performance metrics are used to evaluate the quality of the main paths. 2) Volcano establishment phase: The top-quality main paths are selected, and side paths are formed around each main path to establish the volcano pipes. A multi-beam traffic scheduling and dispatching policy is also proposed to achieve better performance. Our results show that the volcano routing scheme can exploit the advantages of MBDAs for achieving high data rates.

Enhanced OLSR routing for airborne networks with multi-beam directional antennas

This research targets the robust routing protocols in airborne networks (ANs). Particularly, we target the AN which is equipped with the latest antenna technology, called Multi-Beam Directional Antenna (MBDA) [1]. MBDA allows the simultaneously packet delivery in multiple directions without RF interference between directions/beams. We have found that MBDAs can actually bring new opportunities to enhance a popularly used AN routing scheme, i.e., optimized link state routing protocol (OLSR). In particular, MBDAs enable OLSR to better achieve low probability of detection (LPD), a critical requirement in many military applications with adversary nodes nearby which try to eavesdrop the signals. Therefore, we propose a multi-path enhanced OLSR, which is able to exploit the advantages of multi-beam transmissions and select the proper multi-point relays (MPRs) to easily reach all nodes by using only a small number of message broadcasts. An innovative method based on social network concept is used for the selection of MPRs in multi-beam OLSR. Finally, we have conducted the simulations and showed that the enhanced OLSR is suitable for mobile and dense airborne networks with LPD requirements.

A Dual-Antenna Collaborative Communication Strategy for Flying Ad Hoc Networks

Existing communication protocols for mobile ad hoc networks (MANETs) mis-fit flying ad hoc networks (FANETs) due to their exclusive design challenges on the typical long communication distance and high mobility degree of nodes. To tackle them, we introduce a hybrid omnidirectional and multi-beam directional antenna structure for gradient-elastic control-data separation. Based on dual antennas, we further propose a novel communication strategy, which combines location prediction with target tracing, to catch and trace communication targets by adaptively exchanging heartbeat locations for stable data transmission. The performance evaluation shows that our proposal achieves 35.8% increase in data link robustness.

AI-Augmented, Ripple-Diamond-Chain Shaped, Rateless Routing in Wireless Mesh Networks With Multibeam Directional Antennas

Use of multibeam directional antennas (MBDAs) allows a node to simultaneously communicate in multiple directions on its different beams, which can significantly improve the data throughput compared with omni-directional or single-beam directional antennas. However, conventional multihop wireless routing protocols cannot effectively exploit the benefits of MBDAs. In this paper, we present a novel routing scheme for a wireless mesh network (WMN) equipped with MBDAs, which has the following two features: 1) Ripple-Diamond-Chain (RDC) shaped routing: To exploit the multidirection transmission capability of MBDAs, we use rateless codes to obtain loss-resilient symbols for data packets, which can be simultaneously transmitted on multiple beams of a node. Then we use ripples to differentiate the nodes in each hop in the tree topology of WMN. While the symbols are dispatched on multiple beams of a main path node in one ripple, they converge into another main path node in the next ripple. The entire route thus looks like a diamond chain, which can exploit the MBDA benefits. 2) Artificial Intelligence (AI)-Augmented Path Selection : Our routing scheme is augmented by using two AI algorithms. The fuzzy logic is used to define a weighted link quality, in order to adapt to different quality-of-service requirements. The reinforcement learning is used to select the best main path based on the cumulative reward in all the links. In the simulations, we use the video as well as other time-sensitive traffic to evaluate efficiency of RDC routing, as well as intelligent path determination in WMN.

Capacity of Social-Aware Wireless Networks With Directional Antennas

The widespread of smart phones has brought new social-aware features to wireless networks. Users prefer to forward traffic to their social contacts in social-aware networks, which is highly different from the traditional uniform traffic pattern. To this end, we analyze a social-aware wireless network, which is modeled by the social contacts between nodes, and explore its impact on network throughput capacity. We present that it can refine social contacts, thus improving the network capacity. Moreover, directional antennas are applied to further enhance the capacity performance, which can reduce the interference brought by other simultaneous communications. We derive the throughput capacity for social-aware networks with single-beam and multi-beam directional antenna, respectively. For single-beam directional antenna, we prove that when wireless networks are dominated by traffics of short-distance social contact, the throughput capacity can be promoted from order of $(\Theta ({1}/{\theta ^{2}}n\,\text {log}\,n)^{1/2})$ to $\Theta ({1}/{\theta ^{2} \text {log}\,n})$ . In addition, when the beamwidth $\theta $ is at order of $\Omega ({1}/{({\log {n}})^{1/2}})$ , the throughput capacity is a constant. Thus, the wireless network is scalable. For multi-beam antennas, we prove that when sidelobe gain $G_{s}$ is at order of $o(G_{m})$ , where $G_{m}$ is main lobe gain, compared with the single-beam case, the network capacity can achieve the order of $\Theta ({1}/{\theta ^{2}\text {log}\,n})$ .

Neighbor Discovery Algorithm in Wireless Local Area Networks Using Multi-beam Directional Antennas

Neighbor discovery is an important step for Wireless Local Area Networks (WLAN) and the use of multi-beam directional antennas can greatly improve the network performance. However, most neighbor discovery algorithms in WLAN, based on multi-beam directional antennas, can only work effectively in synchronous system but not in asynchro-nous system. And collisions at AP remain a bottleneck for neighbor discovery. In this paper, we propose two asynchrono-us neighbor discovery algorithms: asynchronous hierarchical scanning (AHS) and asynchronous directional scanning (ADS) algorithm. Both of them are based on three-way handshaking mechanism. AHS and ADS reduce collisions at AP to have a good performance in a hierarchical way and directional way respectively. In the end, the performance of the AHS and ADS are tested on OMNeT++. Moreover, it is analyzed that different application scenarios and the factors how to affect the performance of these algorithms. The simulation results show that AHS is suitable for the densely populated scenes around AP while ADS is suitable for that most of the neighborhood nodes are far from AP.

Apprenticeship Learning Based Spectrum Decision in Multi-Channel Wireless Mesh Networks with Multi-Beam Antennas

We propose a novel spectrum decision scheme (i.e., channel selection and handoff) for wireless mesh networks (WMN) which use multiple channels and nodes equipped with multi-beam directional antennas. Our scheme has the following features: (i) It performs spectrum decision by considering various WMN parameters, including the channel quality, beam orientation, antenna-caused deafness and capture effects, and application priority level. (ii) It uses the reinforcement learning (RL)-based spectrum decision process to achieve the optimal quality of multimedia transmission in the long term. However, a newly-joined WMN node could take a long time to make a correct spectrum decision due to the difficult choice of initial RL parameters. Therefore, our scheme uses the apprenticeship learning in conjunction with the RL model, to speed up the spectrum decision process by choosing a suitable neighboring node (called “expert”) to teach a newly-joined node (called “apprentice”). Our experiments demonstrate that the proposed spectrum decision scheme improves the network performance and multimedia transmission quality.

IEEE 802.15.4 MAC for clustered WSNs with a directional framework

This paper exploits the directionality in the wireless sensor network (WSN) by using single-beam and multibeam directional antennas. We mount a multibeam smart antenna (MBSA) with a main sink cluster head (CH), whereas other child sink CHs and end devices use single-beam sector antennas. The unique reception and transmission property of these antennas requires a sufficient modification to suit omni mode MAC protocols. We choose IEEE 802.15.4 as the platform for the proposed MAC design and analyse the effects of these antennas on the current superframe structure. We simulate the modified MAC protocol by using the OPNET modeller under varying traffic loads and an increasing number of nodes. We find an increase in network performance in terms of delays and energy consumption and a simultaneous decrease in the level of urgency.

A new QoS-aware TDMA/FDD MAC protocol with multi-beam directional antennas

With the ever-increasing demand for wireless real-time services and continuing emergence of new multimedia applications especially for mobile users, it is necessary for the network to support various levels of quality of service (QoS) while maximizing the utilization of scarce and expensive wireless channel resources. Considering this fact, a new TDMA/FDD MAC protocol integrating a novel QoS management algorithm and multi-beam Directional Antennas (DAs) to efficiently exploit wireless resources has been developed and presented in this paper. It supports all ATM CBR, VBR, ABR and UBR service classes by adopting a well-managed dynamic guarantee-based QoS scheduling algorithm. The work mainly aims at increasing the wireless system throughput as well as improving the call-blocking ratios and end-to-end delays for real-time applications. This seamless communication enables both handling real-time multimedia traffics in a fair manner and granting call requests on the basis of the connection types. The system has been developed, modeled and simulated using OPNET Modeler. The simulation results show that the QoS-aware TDMA/FDD MAC with multi-beam DAs has substantially increased the system throughput and that the call-blocking ratio has been reduced from 86% to 18%, when the proposed MAC with 8-Beam antennas is employed instead of the regular MAC.

Enhancing the performance of medium access control for WLANs with multi-beam access point

Wireless LANs with multi-beam directional antennas have received intensive attention lately due to the potential gain in throughput performance. However, when the multi-beam directional antennas are introduced in this system, the ever popular contention-based medium access control protocol such as IEEE 802.11 MAC is no longer effective, and many challenging problems, such as beam-synchronization problem, beam-overlapping problem, mobility and receiver blocking problem (deafness problem), need to be resolved. In this paper, we propose a novel MAC protocol to carefully address these problems. In addition to improving communication efficiency, we also consider the backward compatibility in our design, whereby an IEEE 802.11 terminal can transparently access a multi-beam access point. Furthermore, we present an analytical model to evaluate the performance of multi-beam wireless LANs. Extensive simulation studies are used to validate the analytical model and show that our scheme can significantly improve the throughput performance

Multibeam antenna-based topology control with directional power intensity for ad hoc networks

This paper proposes a new approach that applies multibeam directional antennas to controlling topology by reducing the power intensity directionally instead of omnidirectionally. In contrast to omnidirectional topology control, which reduces transmission power (and, thus, the resulting transmission range) in all directions, the proposed approach maintains the original power range in certain directions while clearing the power intensity in other directions. This paper shows that the proposed approach and the. omnidirectional topology control approach are equivalent in terms of the probability distribution of the number of symmetric neighbors in their resulting topologies. Major benefits of this approach include reduced and steady hop count, power saving independent of the number of neighbors within the original power range, and symmetric link in terms of SNR quality, as compared to omnidirectional topology control approaches. Simulation studies have demonstrated these benefits and highlighted its trade-offs.