Efficient IoT Gateway over 5G Wireless: A New Design with Prototype and Implementation Results

Saxena, Navrati; Roy, Abhishek; Sahu, Bharat J. R.; Kim, Hanseok

doi:10.1109/mcom.2017.1600437cm

Cited by 82 publications

(51 citation statements)

References 13 publications

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“…Saxena et al [22] propose implementing an IoT gateway which is expected to operate over 5G networks, with the main focus being on resolving the challenge of resource constrained wireless networks. However, this approach does not address the core security concerns, and similar to Mozzami et al [21], does not evaluate its feasibility.…”

Section: Related Workmentioning

confidence: 99%

EclipseIoT: A secure and adaptive hub for the Internet of Things

Anthi

Ahmad

Rana

et al. 2018

Computers & Security

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With the proliferation in the quantity and types of devices that may be included in an Internet of Things (IoT) ecosystem, particularly in the context of a smart home, it is essential to provide mechanisms to deal with the heterogeneity which such devices encompass. Variations can occur in data formats, frequency of operation, or type of communication protocols supported. The ability to support integration between sensors using a "hub" has become central to address many of these issues. The implementation of such a hub can provide both the ability to act as an aggregator for various sensors, and also limit an attacker's visibility into locally provisioned sensing capability. This paper introduces EclipseIoT, an adaptive hub which uses dynamically loadable add-on modules to communicate with diverse IoT devices, provides policy-based access control, limits exposure of local IoT devices through cloaking, and offers a canary-function based capability to monitor attack behaviours. Its architecture and implementation are discussed, along with its use within a smart home testbed consisting of commercially available devices such as Phillips Hue Bridge, Samsung Smart Things Hub, TP-Link Smart Plug, and TP-Link Smart Camera. The effectiveness of EclipseIoT is further evaluated by simulating various attacks such as Address Resolution Protocol (ARP) spoofing, Media Access Control (MAC) address spoofing, Man-In-The-Middle (MITM), port scanning, capturing handshakes, sniffing, and Denial of Service (DoS). It is demonstrated that direct attacks upon EclipseIoT components are mitigated due to the security techniques being used.

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Section: Related Workmentioning

confidence: 99%

EclipseIoT: A secure and adaptive hub for the Internet of Things

Anthi

Ahmad

Rana

et al. 2018

Computers & Security

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“…There are numerous papers dealing with IoT Gateways, built on embedded devices such as Raspberry PI [24] or standalone servers (as in the proposed solution) [25]. However, to the best of the authors' knowledge, there is no work presented in creating Secure AAA solution for Internet of Things devices.…”

Section: Human Interactionmentioning

confidence: 99%

Secure gateway for Internet of Things with internal AAA mechanism

Samociuk

Adamczyk

2017

Theor. Appl. Inform.

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In this paper, we describe secure gateway for Internet of Things (IoT) devices with internal AAA mechanism, implemented to connect IoT sensors with Internet users. Secure gateway described in this paper allows to (1) authenticate each connected device, (2) authorise connection or reconfiguration performed by the device and (3) account each action. The same applies to Internet users who want to connect, download data from or upload data to an IoT device. Secure Gateway with internal AAA mechanism could be used in Smart Cities environments and in other IoT deployments where security is a critical concern. The mechanism presented in this paper is a new concept and has been practically validated in Polish national research network PL-LAB2020.

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“…In this scenario, device-to-device (D2D) communication presents one favorable solution to enhance spectral efficiency and augment capacity with minimal operational and capital expenditures. In D2D communication, the communication between two or more nearby mobile users takes place directly, i.e., without the intermediary of any infrastructure or base station (BS), which reduces communication delay, increases network throughput, and creates a cyber-physical space in a cellular environment [4][5][6][7]. In D2D, a D2D device can use one of the following mechanisms to operate.…”

Section: Introductionmentioning

confidence: 99%

Incentive and Penalty Mechanism for Power Allocation in Cooperative D2D-Cellular Transmissions

Noreen

Saxena

Roy³

2020

Electronics

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In cellular communication systems, the introduction of device-to-device (D2D) communications provides a reasonable solution to facilitate high data rate services in short-range communication. However, it faces a challenging issue of interference management, where the cross-tier interference from D2D users to licensed cellular users (CUs) degrades their quality-of-service (QoS) requirements. D2D communications can also assist in offloading some nearby CUs to enhance the cellular operator's benefit. To encourage the D2D transmitters (D2DT) to provide service to CUs in the dead zone, the cellular base station (CBS) needs to incentivize it with some monetary benefits. In this paper, a Stackelberg game-based joint pricing framework for interference management and data offloading is presented to illustrate the effects of cooperation between the D2D user and CBS. Specifically, a singular price is used to incentivize the D2DT to share its resources with the far-off CUs along with penalizing them for interference created at CBS. Simulation results illustrate the performance of the proposed technique in terms of the utilities of CUs and D2D users for varying distances of D2DT.Electronics 2020, 9, 408 2 of 13 is not used by proximal cellular users (CU). This technique perhaps may not increase spectrum usage considering that D2D devices use a distinct resource with the CUs. (ii) Underlay mode: In underlay or reuse mode, D2D devices can use the same spectrum resource as the cellular users, on the condition of creating tolerable interference to their communication. This mode can substantially enhance system capacity. Moreover, the cellular operators can also make more profit through additional charges obtained from CUs for providing D2D service. In this paper, the focus is on the underlay spectrum sharing mode, where the D2D pairs reuse the spectrum of the CUs. One of the fundamental research challenges in reuse mode is the severe interference created in the cellular network by D2D communication due to the usage of shared spectrum resources. To ensure the quality-of-service (QoS) of cellular users, various interference mitigation techniques have been studied in the literature. In [8], the authors proposed a power control mechanism to control the peak transmission power of D2D transmitters (D2DT) by the base station. In [9], a more innovative technique was introduced, where resource allocation along with the power control technique was used to combat the interference from D2D to cellular users and vice versa. A spectrum splitting framework was developed in [10] to minimize interference in the D2D-cellular network. To assist in the uplink transmission of CUs to BS, relay nodes were selected in [11], and network coding was applied for the actual transmission. In [12], a multiple-input and multiple-output (MIMO) beamforming technique for the multiple-antenna D2D underlying cellular network based on estimated channel state information (CSI) was presented.In addition to interference management using power control, our scheme essenti...

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Efficient IoT Gateway over 5G Wireless: A New Design with Prototype and Implementation Results

Cited by 82 publications

References 13 publications

EclipseIoT: A secure and adaptive hub for the Internet of Things

EclipseIoT: A secure and adaptive hub for the Internet of Things

Secure gateway for Internet of Things with internal AAA mechanism

Incentive and Penalty Mechanism for Power Allocation in Cooperative D2D-Cellular Transmissions

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