Top five telecom trends to expect in 2021

Top five telecom trends to expect in 2021

Top five telecom trends to expect in 2021

 

28th of December 2020

 

 

2020 has been transformative for businesses around the world; years of digitalization happened within months and service providers were the backbone of this change. The pandemic has also compelled CSPs to rethink their operations and fasttrack their own digital transformation – a phase that has only just begun and will accelerate in 2021.

Operators will reinvent and focus more on customer-centric offerings to meet evolving demands with the work from anywhere culture and to be ready for new lockdowns on notice. AI, machine learning, and automation will facilitate telcos to modernize their network and help create personalized and contextual services. 5G has become a reality and new IoT applications and private 5G will come to fruition.

The increasing reliance on cloud services, digital communication, and digital payments, in addition to increasing network demand, also means added cybersecurity concerns for networks as well as their subscribers. 2020 saw significant hacks, and operators will continue to put in place more enhanced security measures to safeguard their own networks and their customers.

The top 5 trends to watch

5G proliferation

Luckily the pandemic didn’t slow 5G investment, with new network rollouts accelerating. 2020 saw devices like the iPhone12 and lower-priced 5G devices hitting the market, and the adoption is expected to be widespread in 2021. 5G operators will need to turn their attention towards providing a customer experience that’s as modern and advanced as the services it will accompany, as well as solutions for private 5G to facilitate the fourth industrial revolution.

Deloitte forecasts that private 5G deployment over the next five years will largely comprise three types of industries for which private 5G is the most natural choice, delivering unmatched security, low latency, high speed, network slicing for specific resource allocation, cost-efficiency, and flexibility that technologies such as 4G and LTE cannot. The first movers, they predict, will be ports, airports, and other logistics hubs, considering the nature of their operations that require controlling a vast network of equipment to manage heavy loads and tracking each consignment in real-time. Next, the forecast says, will be factories and warehouses looking to replace their existing combination of wired as well as wireless technologies with wireless private 5G networks that can handle high volumes of large and small devices, including everything from a screwdriver to massive industrial equipment. The third section of the market, the forecast says, will include greenfield deployments, especially in smart buildings and campuses, but also temporary sites such as music festivals.

And private 5G holds massive potential for service providers: an Analysys Mason report cites that of all existing and ongoing private 5G deployments, operators hold merely 16%, implying there is much scope for growth. While many large enterprises are considering deploying their own private 5G networks, operators have a competitive edge. Operator-licensed spectrum is currently the only deployment option available for private networks in many countries and is least likely to face interference. This, coupled with their expertise in building network infrastructure and managing operations, makes partnering with operators a reliable and cost-effective route to private 5G.

Internet of Behavior (IoB)

5G has ushered in a new generation of devices connected to the Internet of Things (IoT). The use of IoT devices will be even more widespread as 5G networks become more prevalent globally. We also know that this means that there will be more devices per person, and more devices mean more valuable customer data, for what can be called the Internet of Behaviors (IoB).

IoB means companies will take advantage of their access to increasingly sophisticated data and insights into customer behavior through technologies like big data, location tracking, and facial recognition. Gathering and analyzing this behavioral data helps boost CX by offering increasingly personalized and contextual services – over different channels depending on individual preferences. In addition to gauging demand, these detailed behavior insights will also enable operators to accelerate identifying and tackling service-related and other issues their customers may be facing.

The nature of data that is gathered and used will depend on local privacy laws and regulations in different countries, though often the responsibility will be on individual companies to define the comfort zone for what level of data gathering is acceptable for their customers, in other words, using the data to offer enough value-addition to customers to improve their relationship with the business, without overstepping moral bounds.

Cloud services

The digital shift of working from anywhere is compelling more telcos to invest in IT systems and infrastructure that can support the high volumes of data their networks are processing. Cloud computing is being embraced by telcos more and more as its benefits become known. Operating in the cloud reduces physical infrastructural requirements, lowers operational costs, and helps streamline processes. Further, it enables operators to leverage the full potential of their customer data, making it more easily accessible across the organization.

Among the different cloud computing scenarios, more telcos are likely to favor distributed cloud in 2021. Here, public cloud providers distribute cloud services to various physical locations. Telcos can choose locations close to them to enable low latency and lower costs while operating on the public cloud without having to invest in private cloud infrastructure.

And while telcos will increasingly invest in cloud computing, data volumes are continuing to increase by the minute; Gartner has estimated that by 2023, 43 billion IoT-enabled devices will be in use. Cloud computing falls short in offering enough latency to handle these growing data volumes and the advanced use cases that 5G supports. Telcos can supplement their capacity and support IoT infrastructure by implementing edge computing systems that will pre-process data that it gathers from its sources of origin.

Cybersecurity

The increasing dependence on digital connectivity has also meant that telcos need to account for added security threats to their networks as well as to customer devices, taking additional measures to secure customer data. Forbes reports that the pandemic has resulted in attacks on banks increasing 238 percent, and those on cloud servers increasing by 600 percent, and this is only between January and April 2020.

Telcos must account for the fact that more customers, individuals as well as enterprise clients, are working remotely, and need a security structure in place that safeguards them. This means that cybersecurity strategies, similar to those earlier provided to enterprises, will now be extended to home networks and on mobile devices.

Operators will increasingly employ sophisticated tools such as AI and machine learning techniques to filter out security threats, implement additional firewalls, use cloud and other services with more enhanced in-built security measures, and more.

Confidential computing is another important trend that we are likely to see in 2021, helping operators in ramping up data privacy, encrypting all computing, and adding layers of security around the sensitive customer as well as network data.

Digital payments

Contactless payments were already pervasive pre-pandemic and have since taken even greater strides, enabling secure payments while maintaining hygiene precautions in keeping with global social distancing norms. Forty-six percent of respondents in a global consumer study said they had opted for contactless payment options instead of their cards, and 82 percent view it as a cleaner way to make payments. In another survey conducted by Fiserv on payment methods people considered safest in preventing COVID-19 spread, 42 percent of respondents chose tap-and-pay credit cards and 24 percent chose mobile payments, with only six percent opting for cash. In fact, a report published by global consultancy A.T. Kearney says that we may have the first cashless society in just five years, running only on the card and digital payments.

2021 will mean service providers will introduce more advanced digital payment offerings. These technologies will help improve security through real-time detection and prevention of frauds and security breaches, provide instant round-the-clock-support to prevent payment delays and resolve disputes, automate processes for swift and seamless transactions, and utilize invaluable BI data and advanced analytics to create a more personalized customer experience. AI will also help in evaluating loan eligibility, putting in place rewards systems, optimizing sales and inventory management, and more.

Bring on 2021

2020 has arguably been one of the most mentally and physically challenging years in recent human history – a year that most of us want to move on from. And 2021 brings all the exciting opportunities we’ve been hoping for, especially with technology growing by leaps and bounds.

At Alepo, we’re proud to be building software in these transformative times to help businesses overcome their challenges. We’re thrilled at the prospect of partnering in your success, whether you’re planning to introduce any of our forecasted trends for the year, overhaul your network, introduce new services, or launch a new network. Reach out today to see how we can help you in your network’s journey to success.

Reach out today to see how we can help you in your network’s journey to success.

Gayatri Sarang

Gayatri Sarang

Lead Content and Engagement Specialist – Marketing

Gayatri is part of the content and communications brigade at Alepo. Having locked focus on the telecom domain in recent years, she has vast and diverse experience in writing for leading publications. She moonlights as a volunteer urban wildlife rehabber and is a passionate baker.

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Why 5G standalone core needs to be on every operator’s roadmap

Why 5G standalone core needs to be on every operator’s roadmap

Why 5G standalone core needs to be on every operator’s roadmap

22nd of October 2020

By now we all know that 5G’s ultrafast speeds, high bandwidth, and low latency will open a world of opportunities, its advanced applications transforming virtually every industry. From manufacturing, healthcare, and the Internet of Things (IoT), to AR, VR, and gaming, the possibilities are endless. Service providers have two ways of transitioning to a next-gen network: 5G NSA (non-standalone) and 5G SA (standalone), with SA being the end-goal. 5G NSA (4G LTE EPC plus new RAN) remains the strategy to quickly launch high-speed 5G broadband, yet lacks the new architecture and functionality that will allow 5G to fulfill its visionary use cases.

Unlike 5G NSA, which reuses the Evolved Packet Core (EPC), 5G SA uses cloud-based and Service-Based Architecture (SBA) that optimize network infrastructure with virtualized network functions (NFs), enabling operators to launch differentiated services, ensuring a high quality of service.

5G NSA: step one in 5G launch

The most popular choice of service providers to deploy 5G is 5G NSA, which is 5G radio using an existing 4G EPC. This option is considered the most viable and cost-effective. The only condition is that the 4G EPC needs to be 3GPP Release 15-complaint with additional functionalities to support dual-radio connectivity. This will enable operators to seamlessly launch 5G services and offer high-speed internet and improve access capacity.

5G NSA focuses on offering higher data speeds and improved radio coverage in densely populated areas, helping CSPs rapidly market 5G to gain a competitive edge. However, it does not offer many of the advanced use cases possible with 5G SA, such as ultra-reliable and low latency communications (URLLC) and massive machine-type communications (mMTC).

5G-SA: the path to full 5G benefits

The 3rd Generation Partnership Project (3GPP) has revamped core network architecture, having moved away from traditional telecom protocols to more open, modern SBA. The 5G Core comprises multiple NFs, each responsible for specific core network functions. These NFs use REST-based APIs to interface with each other over HTTP/2 protocol, which is collectively referred to as the Service-Based Interface (SBI).

5G SA key components 5G SA key features and components

With the sheer number of use cases it supports and the forecast for devices, traffic is far more dynamic in a 5G network. And so a robust underlying core network is necessary for the network to swiftly respond to demands. 5G SA enables just that. Some of its key features:

Multi-vendor ecosystem opens the doors for new vendors, who are not just restricted to the telecom sector, or in the legacy core. The adoption of new technologies that are in-line with modern infrastructure such as REST-based (HTTP/2 or Open APIs) widens the scope for innovative vendors to contribute and revolutionize network operations and processes.

Service-Based Architecture defines key 5GC components as NFs that integrate with each over modern APIs that support multiple varied core network functions.

Control and User Plane Separation (CUPS) enables independent scaling between the control plane and user plane functions, facilitating flexible network deployment and operation. For instance, if the data traffic load increases, more data plane nodes are added without affecting the functionality of the existing control plane.

Network function virtualization (NFV) allows virtualizing entire network functions and appliances using standard vendor-neutral hardware and IT infrastructure in the 5G network. It helps operators achieve a faster service life cycle, rapid deployment, scalability, operational efficiency, agility, and more.

Network slicing enables operators to build multiple dedicated networks to cater to different business verticals with diverse requirements of high-bandwidth, ultra-reliability, low-latency communication, and more.

Multi-Access Edge Computing (MEC) distributes computing resources along the communication path using decentralized cloud infrastructure. MEC brings data and computational capabilities closer to the source and network edges such as users’ devices, IoT devices, vCPEs, and more.

Some key components include:

Unified Data Management (UDM) enables managing all subscription-related data for authorization and access services.

Unified Data Repository (UDR) stores all structured data on a flexible and highly available platform, enabling the network to readily respond to critical demands in real-time.

Policy Control Function (PCF) is evolved from the PCRF of legacy networks, providing policy assets to handle access mobility related to policies, as well as handling data- and application-related policies. It enables advanced plan and policy customization for 5G use cases.

Network Repository Function (NRF) keeps a record of all network function instances in the network and helps automate the functioning of NFs.

Network Slice Selection Function (NSSF) plays an essential role in network slicing, dynamically selecting slices based on real-time information.

Network Exposure Function (NEF) ensures information is securely translated and communicated from external applications. It is fundamental in the authorization for any access request received outside of the 3GPP network, thus ensuring the network supports use cases like cellular IoT, edge computing, and more.

Business benefits you can derive with a robust 5G SA solution

A 5G SA solution is meant to enable service providers to adapt to key technological changes like a cloud-native and microservice-based architecture, helping achieve operational excellence while maximizing ROI. It can facilitate:

  • Rapid introduction of new services without interfering with existing services
  • Scaling to support changing network demands and growing subscriber bases
  • Offering differentiated services with high QoS
  • Automating functions like network slicing
  • Lowering operational costs

Alepo’s role in your 5G journey

Alepo offers core network solutions and a digital business support system (BSS) to support unified 4G management (EPC, IMS), C-IoT, and non-3GPP networks (such as WiFi).

Alepo’s 5G Core solution includes AUSF, subscriber data management (SDM), UDM, UDR, EIR, PCF, and Charging Function (CHF). It also includes a unified and highly scalable subscriber repository that holds identities and subscription profiles for both 4G and 5G. The 5G Core employs cloud- and PaaS-agnostic microservice-based software architecture and supports public, private, and hybrid deployment options. And it supports both containerized and NFV-based deployment.

Alepo also supports operators who are not yet ready to move to 5G, bridging the gap by creating a modern next-gen omnichannel experience for subscribers by adding WiFi offload into the operator’s network as well as enabling unique and advanced IoT offerings on the legacy network.

Tell us your business needs, and we’ll help design network innovations to drive ROI. Connect with an Alepo expert today.

Rajesh Mhapankar

Rajesh Mhapankar

Director, Innovations

A seasoned professional, technologist, innovator, and telecom expert. With over 20 years of experience in the software industry, Rajesh brings a strong track record of accelerating product innovations and development at Alepo. He supports the company’s mission-critical BSS/OSS projects in LTE, WiFi and broadband networks, including core policy, charging, and control elements.

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5G SA vs 5G NSA: What Are The Differences?

5G SA vs 5G NSA: What Are The Differences?

5G SA vs 5G NSA: What Are The Differences?

October 19, 2020

Introduction

For leading mobile network operators (MNOs), 5G is mainly about offering high-speed connectivity to consumers, on devices that support fifth-gen network services. To smoothly transition from the existing legacy core to 5G, MNOs have two pathways: Non-Standalone (NSA) or Standalone (SA) architecture. And while they are both means to the same end, NSA and SA are structurally and functionally different.

NSA allows operators to leverage their existing network investments in communications and mobile core instead of deploying a new core for 5G. 5G Radio Access Network (RAN) can be deployed and supported by the existing Evolved Packet Core (EPC), lowering CAPEX and OPEX. To further lower network operating costs, operators can adopt the virtualization of Control and User Plane Separation (CUPS) along with software-defined networking (SDN). These initial steps will help quickly unlock new 5G revenue streams and offer faster data speeds.

5G SA is a completely new core architecture defined by 3GPP that introduces major changes such as a Service-Based Architecture (SBA) and functional separation of various network functions. Its architecture has the definite advantage of end-to-end high-speed and service assurance, particularly useful for MNOs who are set to commence new enterprise 5G services such as smart cities, smart factories, or other vertically integrated market solutions. The deployment model enables the rapid introduction of new services with quick time-to-market. However, it means additional investment and complexities of running multiple cores in the network.

Architecturally, NSA includes a new RAN, deployed alongside the 4G or LTE radio with the existing 4G Core or EPC. 5G SA, on the other hand, includes a new radio along with the 5G Core (5GC), comprising completely virtualized cloud-native architecture (CNA) that introduces new ways to develop, deploy, and manage services. 5GC supports high-throughput for accelerated performance than the 5G network demands. Its virtualized service-based architecture (SBA) makes it possible to deploy all 5G software network functions using edge computing.

5G software network functions using edge computingAn overview of 5G SA and 5G NSA deployment options (Source: GSMA) 

5G Standalone (SA) vs 5G Non-Standalone (NSA)

5G SA Architecture

According to a survey, 37% of MNOs will deploy 5G SA within two years; 27% of operators plan to deploy 5G SA within 12 to 18 months with an additional 10% increase within 24 months. 5G SA architecture will allow operators to address the fifth generation of mobile communications, including enhanced mobile broadband, massive machine-to-machine communications, massive IoT, and ultra-low latency communications.

Standalone 5G NR comprises a new end-to-end architecture that uses mm-Waves and sub-GHz frequencies and this mode will not make use of the existing 4G LTE infrastructure. The SA 5G NR will use enhanced mobile broadband (eMBB), Ultra-Reliable and Low Latency Communications (URLLC), and huge machine-type communications (mMTC) to implement multi-gigabit data rates with improved efficiency and lower costs.

5G SA also enables more advanced network slicing capabilities, helping operators rapidly transition to both 5G New Radio (NR) and 5G as the core network. Network slicing, URLLC, and mMTC bring ultra-low latency along with a wide range of next-gen use cases like remote control of critical infrastructure, self-driving vehicles, advanced healthcare, and more. However, the NR advanced cases are not backward compatible with the EPC, which is the framework that provides converged voice and data on a 4G LTE network. The level of reliability and latency that 5G provides will be indispensable for handling smart-grid control machines, industrial automation, robotics, and drone control and coordination.

5G NSA Architecture

NSA 5G NR is considered as the early version of SA 5G NR mode, in which 5G networks are supported by existing LTE infrastructure. It fundamentally concentrates on eMBB, where 5G-supported handsets and devices will make use of mmWave frequencies for increased data capacity but will continue to use existing 4G infrastructure for voice communications.

NSA helps MNOs launch 5G quickly for eMBB to get a competitive edge in the telecom market. NSA also helps leverage its existing LTE/VoLTE footprint to maximize the LTE installed base and boost capacity while increasing delivery efficiency. It will not support network slicing, URLLC, and mMTC, but its higher broadband speeds will enable services such as video streaming, augmented reality (AR), virtual reality (VR), and an immersive media experience.

Non-Standalone 5G NR will provide increased data-bandwidth by using the following two new radio frequency ranges:

  • Frequency range 1 (450 MHz to 6000 MHz) – overlaps with 4G LTE frequencies and is termed as sub-6 GHz. The bands are numbered from 1 to 255.
  • Frequency range 2 (24 GHz to 52 GHz) – is the main mmWave frequency band. The bands are numbered from 257 to 511.

Technical Differences between 5G SA and 5G NSA

The main difference between NSA and SA is that NSA provides control signaling of 5G to the 4G base station, whereas in SA the 5G base station is directly connected to the 5G core network and the control signaling does not depend on the 4G network. In simple terms, NSA is like adding a solid-state drive to an old computer, which can improve the system’s performance, while SA is like replacing it with a new computer that has newer technologies and optimum performance.

Some benefits include:

  • NSA is extremely low in cost compared to SA.
  • NSA eases 5G network deployments as it reuses existing 4G facilities, thus allowing rapid time to market for 5G mobile broadband.
  • With NSA, the deployment is faster and time-to-market is lower, as 4G locations can be used to install 5G radio. SA requires building 5G base stations and the back-end 5G core network to fully realize the characteristics and functions of 5G.
  • SA involves a 5G core with SBA for scalability and flexibility to deliver a superfast network with ultra-low latency for advanced 5G use cases.

5G Usage Scenarios in NSA and SA Operation

The requirements of 5G NR for the SA provide a complete set of specifications for the 5G core network that goes beyond NSA. The three major usage scenarios defined for 5G by the 3GPP and GSMA include:

  1. Enhanced mobile broadband (eMBB)
  2. Ultra-reliable and low latency communications (URLLC)
  3. Massive machine-type communications (mMTC)

Enhanced Mobile Broadband with 5G Major 5G usage scenarios

The Future of 5G Includes NSA and SA

Early adopters of 5G primarily focus on NSA deployments as they compete to deliver 5G speeds with a quick time to market. These MNOs can move to SA-based architecture over a period of time, which most plan to do. NSA deployment remains a mainstream solution given its ability to handle both 4G- and 5G-based traffic, keeping these early adopters ahead of their competition as they undertake their network transformation. 5G devices are not widespread so the need for SA-based architecture is still nascent.

In the future, the convergence of NSA and SA will help operators move to a full 5G network. A complete virtualized 5G architecture will allow MNOs to migrate and choose varied functionalities of their existing NSA solution to the 5GC platform, as new 5G services are launched, allowing them to monetize their investment gradually rather than move all at once and enabling them to recover their costs over time.

Although SA is a more mature network architecture compared to NSA, NSA will continue to be the more commonly chosen path to 5G. All NSA single-mode 5G phones launched this year or early next year will be valid for a decade, and as SA architecture permeates, more and more 5G SA devices will be in our homes and businesses.

Rajesh Mhapankar

Rajesh Mhapankar

Director, Innovations

A seasoned professional, technologist, innovator, and telecom expert. With over 20 years of experience in the software industry, Rajesh brings a strong track record of accelerating product innovations and development at Alepo. He supports the company’s mission-critical BSS/OSS projects in LTE, WiFi and broadband networks, including core policy, charging, and control elements.

Subscribe to the Alepo Newsletter

Envisioning Private 5G Success with Compact Core

Envisioning Private 5G Success with Compact Core

Envisioning private 5G success with Compact Core

 

8th of July 2020

 

 

 

5G is set to change the way large and small enterprises operate; from universities, ports, smart cities, factories, farms, and buildings, its use cases can meet all business needs. And the key network component that will enable all the unique features of 5G for these enterprises: Compact Core.

The Compact Core is an industrialized solution designed for enterprises that need carrier-grade network connectivity with a limited resource footprint to deliver services to their users. It is especially useful for those who want private network connectivity, whether it is over LTE or 5G. The deployment involves pre-integrated access and core network components for quick setup and less complex operations.

How the Compact Core benefits an enterprise

The Compact Core is a complete pre-integrated and self-contained solution that includes the network core and other networking infrastructure, which seamlessly works with end devices and the radio access network. It does not impact and is not dependent on external systems or organizations.

Swift deployment

In terms of time, Compact Core deployment is highly efficient. Enterprises can launch a private LTE or 5G network along with mobile broadband and voice services in a single project, saving on the time they would otherwise need to deploy these services individually. Since the solution is pre-integrated, no extensive development, customization, or testing is needed to go live.

Cloud-native benefits

The Compact Core is a modernized software solution that leverages the power of cloud, abstracting the underlying complex functionality. It is the smartest choice when upgrading from legacy telco infrastructure to modern, web-scale, 5G architecture. Capable of serving multiple enterprises, it uses SaaS-based multi-tenant architecture. Each tenant has a dedicated configuration, user management, and can self-service through web portals. This setup offers automated, cost-efficient, and hassle-free operations with dynamic provisioning of core capacity based on individual business requirements.

Flexible footprint

Whether the enterprise wants to deploy securely on-premise or on the public cloud, the modern compact core solution has a small resource footprint and flexibility of deployment modes. An in-memory database and ability to scale up and down sets it apart from legacy telco core solutions.

Role of Alepo’s Compact Core in private 5G enablement

Alepo is a software company that offers Subscriber Data Management and policy network functions for the Compact Core. It manages subscriber identities, service subscriptions, and is responsible for authentication, authorizing secure access to network services. It also includes the web-based Enterprise Self-Service (ESS) Portal that enables enterprises to self-manage SIM cards, end-to-end subscription and device lifecycles, and real-time connection and usage monitoring. Alepo’s pre-integrated partners bring the RAN, end devices, and other infrastructure needed to flip the switch and turn on the 5G network.

Ready for real 5G launch

The Compact Core equips an enterprise to launch its private LTE or 5G services. Essential services include enhanced Mobile Broadband (eMBB), voice calls, and video calls. It can also include services such as push-to-talk or walkie-talkie. Further, users can get 5G benefits such as ultra-reliable and low-latency communication (URLLC) for M2M and IoT applications.

Most existing 5G networks are powered by 4G core/EPC and 5G RAN (non-standalone 5G). They are dependent on the 4G core and therefore are not end-to-end 5G networks. Alepo’s new-generation Compact Core, along with the ESS Portal, is 5G-compliant. All elements are pre-integrated to rapidly enable enterprises to set up a new standalone 5G network with zero dependence on the 4G core.

Nitish Muley

Nitish Muley

Senior Engineer

Nitish has spent years building mobile apps for technologies like VR, AR, IoT, and is currently working on Alepo’s newest products. Always up to speed with the latest in the industry, Nitish is a voracious reader – and fervent writer – about all things related to tech and wireless standards. After hours, he wears a traveler’s hat, pursuing his love for photography as he explores different countries.

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How operators can leverage network slicing for 5G monetization

How operators can leverage network slicing for 5G monetization

How operators can leverage network slicing for 5G monetization

 

18th of June 2020

Mobile communication technology has been driving digitization and is now an essential pillar across industries such as manufacturing, automobile, retail, supply chain, transport, healthcare, and more. Different business verticals have varying needs: one sector could require high-bandwidth communication, another may demand ultra-reliable communication, while a third needs extremely low-latency communication. The ideal 5G network will fulfill these diverse requirements at the same time, and this is possible through network slicing.

What is network slicing?

It is theoretically possible to build multiple dedicated networks where each is customized to support the needs of one type of business customer, but this is economically unviable. The most efficient approach is to segment a single physical network into multiple logical networks, each catering to unique service needs. This technique is called network slicing.

Network segmentation is available to an extent in legacy networks through Access Point Names (APNs) and dedicated core networks. But it is now more seamless and practical to use with advances in virtualization technology that is adopted by 5G. 5G networks, along with network slicing, allow business customers to enjoy connectivity in line with unique business specifications that are negotiated with a mobile operator in a Service Level Agreement (SLA). The parameters of customization include data speed, quality of service (QoS), latency, reliability, security, and services.

A network slice is an autonomous end-to-end logical network operating on shared physical infrastructure capable of providing the agreed QoS. The scope of the network slice could cover multiple parts of the network, such as a terminal, core network, access network, and transportation network. One network slice includes dedicated and/or shared resources, which can vary in terms of bandwidth, storage, processing power, and more.

From the end-user perspective, the network slice serves as a normal mobile network. A slice often offers seamless and uninterrupted service when a device roams outside the home network.

Potential vertical applications

Network slices can be used for many use cases in several industries such as:

Consumer: enhanced Mobile Broadband (eMBB) for high bandwidth users.

Automotive: ultra-low latency (1 ms), high-availability, and effective isolation from other services for autonomous vehicles.

Logistics: high availability to track goods.

Healthcare: ultra-low latency and high availability for remote surgeries.

Warehouse: low-latency and high-availability for efficient collaboration between smart robots.

Media (entertainment/AR/VR): high-bandwidth for an immersive and seamless experience.

Smart cities, governments, SOS services: dedicated QoS to ensure connectivity of first responders.

Detailed network slicing use cases

Slices have limitless possibilities for industry, some of which include:

Slice for automobiles
Designed for a modern connected vehicle, it enables a highly versatile network that can deliver ultra-reliable and low-latency communication (URLLC) service for self-driving, car-to-car communication, and emergency services as well as high-throughput for in-car entertainment using high-bandwidth.

Slice for industry automation
A smart factory can use the operator’s URLLC slice for industrial automation, allowing monitoring and control of robotic parts. An edge computing data center (as network resource service) is used to deploy the system.

Slice for massive IoT
An operator can deploy a dedicated slice for IoT users to manage the complex network requirements for a massive IoT device ecosystem. It can have lower latency, and a separate charging and control function to simplify network management and speed-up deployment. This slice can support one million devices per square kilometer.

Slice for live broadcasts in AR/VR
A dedicated high-bandwidth slice can be used by an operator to transmit news and events such as sports and concerts. To manage AR/VR video processing, it can support one-to-many downlink connections with high-density computing. The slice will ensure high-bandwidth and lower-latency QoS.

What capabilities do Alepo’s solutions extend?

Alepo’s 5G Core solution offers converged subscriber data management, policy, charging functions, and 3GPP AAA. It empowers the operator’s network team to create and manage slice profiles, their technical attributes, and associate them with subscriptions or group subscriptions. As a device connects to the network, slice profile details are provisioned towards the network to connect the device to a specific slice based on its service subscription. This empowers operators to create, manage, and charge different slices based on each customer’s business requirements.

Nitish Muley

Nitish Muley

Senior Engineer

Nitish has spent years building mobile apps for technologies like VR, AR, IoT, and is currently working on Alepo’s newest products. Always up to speed with the latest in the industry, Nitish is a voracious reader – and fervent writer – about all things related to tech and wireless standards. After hours, he wears a traveler’s hat, pursuing his love for photography as he explores different countries.

Subscribe to the Alepo Newsletter