Overview of 5G Security Challenges and Solutions

Ahmad, Ijaz; Kumar, Tanesh; Liyanage, Madhusanka; Okwuibe, Jude; Ylianttila, Mika; Gurtov, Andrei

doi:10.1109/mcomstd.2018.1700063

Cited by 369 publications

(216 citation statements)

References 14 publications

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“…While rolling out 5G networks in the nextgeneration smart cities in general and UK in particular, due to many new features of 5G networks and the fact that 5G will envelop almost all dimensions of human life, business, and government affairs with ultra-high-speed access to services, anywhere, anytime and any type, 5G security requirements have to be thoroughly researched [55]. 5G rollout will also bring a wide range of threats and a greatly expanded attack surface [56]. For example, 5G physical layer security at the RAN [55] is susceptible to new types of attacks and performance bottlenecks such as eavesdropping, contaminating, spoofing, and jamming.…”

Section: Security Challengesmentioning

confidence: 99%

“…New 5G paradigms will have to be handled by the UK MNO businesses. For example, security challenges related to network slicing; such as on-demand security isolation of network slices, the security of interslice communications, impersonation attack, security policy mismatch, DoS attack, side-channel attacks, privacy attacks, resource harmonization between inter-domain slice segments and hypervisor attacks have to be considered [56,61]. New types of 5G-based verticals, e.g., IoT, need to establish secure 5G-based network slicing technique with secure key establishment among IoT devices, MEC, and IoT cloud server [67].…”

Section: Security Challengesmentioning

confidence: 99%

“…Hence, UK MNOs have to ensure data exchange security for network function (NF) service registration and de-registration, NF service discovery, NF service authorization and authentication in the presence of different attack vectors that may cause loss of NF availability, loss of data integrity, and attack from the insiders [70]. 5G advocates the use of MEC, which offers heterogeneous network nodes inter-operating in an open ecosystem where distributed computing and virtualization may be exploited by service providers to extend the provisions of different applications to the end-users [56]. Hence, at the time of rolling out 5G networks, MEC threats have to be considered at the frontend (UE/IoT to MEC network), backend (MEC network to cloud), and 5G MEC core network [56,67].…”

Section: Security Challengesmentioning

confidence: 99%

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The Potential Short- and Long-Term Disruptions and Transformative Impacts of 5G and Beyond Wireless Networks: Lessons Learnt From the Development of a 5G Testbed Environment

et al. 2020

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The capacity and coverage requirements for 5G and beyond wireless connectivity will be significantly different from the predecessor networks. To meet these requirements, the anticipated deployment cost in the UK is predicted to be in between £30bn-£50bn, whereas the current annual capital expenditure (CapEX) of the mobile network operators (MNOs) is £2.5bn. This prospect has vastly impacted and has become one of the major delaying factors for building the 5G physical infrastructure, whereas other areas of 5G developments are progressing at their speeds. Due to the expensive and complicated nature of the physical network infrastructure and spectrum, the second-tier operators, widely known as mobile virtual network operators (MVNO), are entirely dependent on the MNOs. In this paper, an extensive study is conducted to explore the possibilities of reducing the 5G deployment cost and developing business models. This study suggests that the use of existing public infrastructure (e.g., streetlights, telephone poles, etc.) has a great potential to contribute to a reduction of about 40% to 60% anticipated cost for the 5G network. This paper also reviews the recent Ofcom initiatives to release location-based licenses of the 5G-compatible radio spectrum at a nominal cost. Our study suggests that simplification of infrastructure and spectrum will encourage the exponential growth of scenario-specific cellular networks and will potentially disrupt the current business models of telecommunication business stakeholders -specifically MNOs and TowerCos. These scenario-specific networks are expected to be: a) private networks, b) community networks, and c) microoperators. Furthermore, due to the feasibility of dense device connectivity with 5G, the resolution of traditional and nontraditional data availability will increase significantly. This will encourage extensive data harvesting as a business opportunity and function within small and medium-sized enterprises (SMEs) as well as within large social networks. Consequently, the rise of new infrastructures and spectrum stakeholders is anticipated. This will fuel the development of a 5G data exchange ecosystem where data transactions are deemed to be high-value business commodities. The privacy and security of such data, as well as definitions of the associated revenue models and ownership, are challenging areas -and these have yet to emerge and mature fully. In this direction, this paper proposes the development of a unified data hub with layered structured privacy and security along with blockchain and encrypted off-chain based ownership/royalty

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Section: Security Challengesmentioning

confidence: 99%

Section: Security Challengesmentioning

confidence: 99%

Section: Security Challengesmentioning

confidence: 99%

See 1 more Smart Citation

The Potential Short- and Long-Term Disruptions and Transformative Impacts of 5G and Beyond Wireless Networks: Lessons Learnt From the Development of a 5G Testbed Environment

et al. 2020

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“…The attacks and vulnerabilities of attacks, like DoS, are considerable issues for the future mobile generations. Ahmad et al [45] presented the review of the challenges, and privacy and security issues in the clouds, softwaredefined networking, and network function virtualization along with their perspective security solutions. The major contribution of the authors includes the analysis of the attack-vulnerabilities and mitigation for making a secure 5G network.…”

Section: Existing Surveys and Their Applicabilitymentioning

confidence: 99%

“…The authors discuss the challenges and research directions on the 5G security. Ahmad et al [45] 2018 5G Networks The authors review the challenges and issues of privacy and security in the clouds, software defined networking, and network functions virtualization and presents respective solution for these issues. Wu et al [21] 2018 5G Wireless Networks…”

Section: Key Contributionmentioning

confidence: 99%

A Survey on the Security and the Evolution of Osmotic and Catalytic Computing for 5G Networks

Choudhary

Sharma

2019

5G Enabled Secure Wireless Networks

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The 5G networks have the capability to provide high compatibility for the new applications, industries, and business models. These networks can tremendously improve the quality of life by enabling various use cases that require high data-rate, low latency, and continuous connectivity for applications pertaining to eHealth, automatic vehicles, smart cities, smart grid, and the Internet of Things (IoT). However, these applications need secure servicing as well as resource policing for effective network formations. There have been a lot of studies, which emphasized the security aspects of 5G networks while focusing only on the adaptability features of these networks. However, there is a gap in the literature which particularly needs to follow recent computing paradigms as alternative mechanisms for the enhancement of security. To cover this, a detailed description of the security for the 5G networks is presented in this article along with the discussions on the evolution of osmotic and catalytic computing based security modules. The taxonomy on the basis of security requirements is presented, which also includes the comparison of the existing state-of-the-art solutions. This article also provides a security model, "CATMOSIS", which idealizes the incorporation of security features on the basis of catalytic and osmotic computing in the 5G networks. Finally, various security challenges and open issues are discussed to emphasize the works to follow in this direction of research. and vulnerabilities have been evolving continuously with the networks because of an increase in the number of users where attackers try to exploit the potential weaknesses. To easily follow these issues and aspects, an overview of 5G applications, technologies, features and performance challenges and standardization are presented in Fig.1 and Fig.2. Current 5G networks are supported by different technology enablers, which include Fig 2. An illustration of 5G evolution, standardization and known security attacks. Applications of 5G networks:The major applications of the 5G networks are provided below:1. Autonomous Vehicle: The automatic controlled driving car and vehicles are key enablers of Vehicle-to-Vehicle (V2V), Vehicle-to-Infrastructure (V2I) and other Intelligent Transport Systems (ITS). The 5G network supports large bandwidth and low latency for these applications with high connection reliability. This network supports collision avoidance and intelligent navigation for the reliable transportation systems [6] [7]. Public Safety Communications (PSCs):The PSCs facilitated various communication services in case of emergencies when the primary communication infrastructure is not available. The PSCs incorporated rapid deployment and accessibility of communication set-up. Therefore, 5G enabled communications supports a wide range of applications and long-term connectivity for the services in case of emergencies [12]. 3. Military Applications: The Military involved mission-critical control application which requires high data rate and long-term c...

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5G Mobile Networks Security Landscape and Major Risks

Mitra

Marina

2021

Wiley 5G Ref

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The 5G is all set to create a paradigm shift in the telecommunication network architecture by introducing a millimeter‐wave‐based customizable radio network and a redesigned cloud‐native core network to offer high‐speed, low‐latency mobile broadband anytime anywhere. The key enabling technologies of the 5G are massive MIMO, beamforming, Software‐Defined Networking (SDN), Network Functions Virtualization (NFV), and Mobile Edge Computing (MEC). However, the network agility, connection to billions of smart things, and blind adoption of machine learning models and open‐source software in the networked systems bring in a unique set of security threats and privacy concerns to the network and its stakeholders. This article provides a comprehensive analysis of the evolving security threat landscape of 5G, recommended security measures, current state‐of‐the‐art solutions, and open research areas.

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Overview of 5G Security Challenges and Solutions

Cited by 369 publications

References 14 publications

The Potential Short- and Long-Term Disruptions and Transformative Impacts of 5G and Beyond Wireless Networks: Lessons Learnt From the Development of a 5G Testbed Environment

The Potential Short- and Long-Term Disruptions and Transformative Impacts of 5G and Beyond Wireless Networks: Lessons Learnt From the Development of a 5G Testbed Environment

A Survey on the Security and the Evolution of Osmotic and Catalytic Computing for 5G Networks

5G Mobile Networks Security Landscape and Major Risks

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