| 리포트 | 기술문서 | 테크-블로그 | 원샷 갤러리 | 링크드인 | 스폰서 컨텐츠 | 네트워크/통신 뉴스 | 인터넷자료실 | 자유게시판    한국 ICT 기업 총람 |

제품 검색

|

통신 방송 통계

 
 
 
섹션 5G 4G LTE C-RAN/Fronthaul Gigabit Internet IPTV/UHD IoT SDN/NFV Wi-Fi Video Streaming KT SK Telecom LG U+ OTT Network Protocol CDN YouTube Data Center
 

2023

5G 특화망

포탈

Private 5G/이음 5G

 포탈홈

  넷매니아즈 5G 특화망 분석글 (128)   5G 특화망 4가지 구축모델   산업계 5G 응용   산업분야별 5G 특화망 활용사례  [5G 특화망 벤더Samsung | HFR | Nokia | more
 

해외

  국가별 사설5G 주파수 [국가별 구축현황] 일본 | 독일 | 미국 | 프랑스 | 영국  [사설5G 사업자] Verizon | AT&T | DT | Telefonica | AWS | Microsoft | NTT동일본 | NTT Com    
 

국내

  5G 특화망 뉴스 | 국내 5G 특화망 구축 현황 | 국내 5G 특화망사업자 현황 (19개사) | 국내 자가구축사례 일람 | 국내 특화망 실증사업사례 일람 | 5G 특화망 정책
 
 

[5G 특화망 구축 사례] 한국식품산업클러스터 | 반월시화산단 삼성서울병원 | 롯데월드 | 한국수력원자력 | 해군본부 | 한국전력공사 | more  [이통사] KT

 
 
스폰서채널 |

 HFR의 5G 특화망 솔루션 (my5G)  Updated   | HFR 5G 특화망 뉴스HFR my5G 자료

  스폰서채널 서비스란?
Progression from 4G to 5G
Progression from 4G to 5G
March 26, 2019 | By Harpreet Kaur @ Hughes Systique (Harpreet.Kaur@hsc.com)
코멘트 (0)
3

We are pleased to share with you all an interesting article contributed by Harpreet Kaur who is currently working as System Design Engineer in the Network Infra Team at Hughes Systique. She has 18 years of experience in telecom industry. She has been leading the SDN/NFV initiatives in the organization. 

 
 

Harpreet Kaur

System Design Engineer at Hughes Systique

 

 

All Articles by Harpreet Kaur

 
     
  How to contribute your article to Netmanias.com !  
     
  List of Contributors  

 

 
     
 

5G, the latest advancement in cellular network evolution, promises pioneering improvements in availability, reliability and performance requirements of the emerging applications in the enterprise segment.

 

Standard bodies like ITU and NGMN have come up with multiple use cases for 5G.

 

Each of these use cases differ in terms of expected data rates, latency, reliability and availability. Hence, they need different treatments by the underlying cellular networks.


This article discusses such use cases, shortcomings in 4G to realize these use cases and how 5G promises to handle their stringent requirements.

 

The article further attempts to show a high level migration from 4G EPC to 5G core network – mapping their network components with respect to functionalities.


5G Usage scenarios


Based on the requirements from the wireless networks, the 5G use cases are classified into three main categories:

  1. Enhanced Mobile Broadband (eMBB): These scenarios require 5G cellular networks to support very high data rates. 5G performance targets recommended by ITU suggest, peak data rate of 20 Gbps in downlink and 10 Gbps in uplink. In dense areas, it expects a throughput of 10-100 Mbps/m2.
  2. Ultra-Reliable and Low Latency Communication (URLLC): These scenarios require low latency and high reliability. 5G networks are expected to support <1 ms latency in access network and <10 ms latency end to end, for low-latency applications such as AR/VR, V2X communication, ehealth services. ITU further recommends a reliability > 99% (meaning that a packet reaches the destination in the allowed latency budget in 99% of the cases) and even close to 99.999% for specific deployment scenarios and use cases.
  3. Massive machine Type Communication (mMTC): In these scenarios, 5G is expected to support very high connection density. Smart cities, Industrial IoT cases fall under this category. They have large number of devices connected to the network – generally these applications expect low data rates. ITU recommended 5G targets expects handling between 10,000 and 1,000,000 devices per km².

4G shortfalls and how 5G helps


Performance requirements needed to satisfy the aforementioned scenarios can’t be fulfilled by the 4G networks:

  1. For 4G networks, ITU's International Mobile Telecommunications Advanced program indicates peak data rate of 1000 Mbps in downlink and 500 Mbps in uplink. This data rate is insufficient to support the eMBB scenarios. 5G networks are expected to use much wider frequency spectrum than 4G – with 5G NR mmWave running close to 30 GHz. Wider channel bandwidths and massive MIMO enable 5G to achieve data rates of 20 Gbps in downlink and 10 Gbps in uplink.
  2. Multiplayer gaming applications, industrial robots, self-driving cars and many such time-critical applications demand quick response – at times requiring network latency less than 1 ms, which 4G networks struggle to achieve or can't manage at all. 5G cellular technology is a key enabler to ‘edge computing’, thus bringing the compute power(applications) closer to the user and hence help reducing the network latency.
  3. Different network characteristics are required for each category of applications mentioned above. But it’s monetarily infeasible to have separate physical networks for each of them. Existing QoS solutions can classify and manage different types of IP traffic flowing over a given network but they are deficient in multiple ways. For instance, they can’t differentially treat same type of traffic from different tenants. At times, there is a need to provide mobile virtual network operators their own virtual infrastructures. In nutshell, there is a need to separate users, devices and applications that require a different quality of service for different use cases. This is where 5G network slicing offers cross-application, cross-service and cross-tenant segmentation of a network. It provides logical, self-contained networks comprising of a mixture of shared and dedicated resource instances - which includes network, compute, and storage capacity resources, virtualized network functions, and radio resources

Key principles of 5G


5G architecture is significantly different from its predecessors. This is crucial to meet the expected business and performance objectives, with respect to latency and reliability Following are some key principles that 5G networks will follow:


Separation of user plane and control plane: This separation will enable independent scaling and flexible deployments for each of the planes. Resource assignments can be done based on needs. For instance, applications needing high bandwidth, like video surveillance, can scale user plane functions. Whereas, IoT application which require few bytes of data exchange but more frequently, might require scaling of control plane functions more frequently. This separation also allows independent movement of some functions closer to the user while keeping others centralized in the cloud.


Services based architecture (SBA) for network functions: 5G core network functions use services-based interfaces for their interactions. Each of these network functions provide services to another network function. A service consists of operations, based on either a request-response or a subscribe-notify model. With SBA, same operations can be reused by other existing functions or new functions.


Stateless network functions: 5G network functions are designed to be stateless. Separating state from the control, allows control to run on a compute resource and state can be saved at a separate storage node. Apart from enhancing reliability by maintaining redundancy of storage nodes, this statelessness also aids in dynamic instantiation/scaling of virtual network functions corresponding to the 5G network functions.


Support for capability exposure: 5G allows external functions to interact with their core network functions using ‘capability exposure’ function. This function allows the external functions to retrieve state/status/events from the 5G core and to pass configurations/policies to the 5G core. This 5G feature is a key enabler for multi-access edge computing paradigm.


Local and centralized access: To handle the mission-critical and low latency applications, 5G allows one PDU session to have multiple user plane anchors towards the data networks. This lets 5G support concurrent access through local compute servers (at edge) as well as centralized cloud servers. Compute capability at the edge help in reducing the network latency enormously.


Introducing 5G


5G relies heavily on virtualization – it plays a key role in the flexibility and scalability requirements that 5G expects. It allows movement to vendor-agnostic implementations and efficient sharing of hardware.


At the core side, 5G is a collection of network functions, expected to be virtualized and run on a cloud infrastructure. In transition from 4G to 5G, 4G EPC functions have been modularized to form multiple 5G core network functions, thus re-architecting them as cloud-native applications. Following are some examples of the partitioning done:

 

  1. The 4G Mobility management entity (MME) functionality has been divided into 5G Access and Mobility management Function (AMF), session management function (SMF) and Authentication Server Function (AUSF):
    • AMF handles the UE registration and mobility management
    • SMF handles the PDU session management
    • AUSF handles the UE authentication part based on authentication vectors from Unified Data Management (which stores the UE subscription data and user-context).
  2. The 4G S-GW and P-GW have been divided into session management function (SMF) and user plane function (UPF):
    • SMF handles the UE IP address assignment and UPF selection
    • UPF acts as PDU session anchor – it is responsible for packet routing, QoS enforcement and charging functionality

The diagram underneath gives a high level mapping of 4G EPC functions to 5G core network functions.

 


 

Figure 1: 4G EPC vs 5G Core


Following are the new 5G core functions introduced:

  1. Network Slice Selection Function (NSSF): NSSF helps in setting up multiple virtual network slices of the RAN, core and transport networks to meet specific service requirements.
  2. Network Exposure Function (NEF): This is the capability exposure function used by the external network entities to interface with 5G core network.
  3. Network Repository Function (NRF): It aids the 5G services based architecture. It acts as repository of all services offered by the different network functions.

In order to support high data rates and low latency needs of 5G, the access network and fronthaul have been revamped. At the access side, the 4G eNodeB (eNB) is now called 5G gNB (next-generation node B):

  1. The gNB is split into two parts – gNB centralized unit (gNB-CU) and gNB distributed unit (gNB-DU). Both are connected to each other using ethernet based IP midhaul network.
  2. Generally, gNB-CU is virtualized and runs in context of virtualized core or virtualized edge.
  3. gNB-DU might be integrated with the radio head or can be virtualized and run on the edge or cloud.

Conclusion


5G is opening up a new business opportunities from diverse market segments like healthcare, smart cities, connected devices, industrial IoT etc. Each of the 5G use cases differ in terms of requirements with respect to data rates, latency, connection density and reliability.

 

Virtualized access and core networks, modularized network functions and varied deployment options of 5G will actively help in realization of apt cellular connectivity for these diversified markets.

 
     
Thank you for visiting Netmanias! Please leave your comment if you have a question or suggestion.
View All (1195)
5G (127) 5G 특화망 (40) AI (16) ALTO (1) AR (2) ARP (6) AT&T (1) Akamai (5) Authentication (5) BT (1) Backhaul (2) Big Data (2) Bridging (5) C-RAN/Fronthaul (19) CDN (20) CIoT (2) CPRI (6) Carrier Aggregation (5) Charging (2) China Mobile (2) Cisco (6) CoMP (3) Comcast (1) DHCP (6) DNS (15) Data Center (15) EDGE (14) EMM (1) EPS Bearer (7) Ethernet (3) FTTH (8) GSLB (5) Gigabit Internet (17) Google (17) Google Global Cache (8) Google TV (1) HLS (5) HTTP (5) HTTP Adaptive Streaming (7) HTTP Progressive Download (2) Handover (5) Huawei (1) IGMP (3) IP (6) IP Allocation (8) IP Routing (20) IPSec (4) IPTV (25) IoST (2) IoT (63) KT (46) Korea (8) Korea ICT Vendor (1) L3 Switch (5) LG U+ (24) LTE (99) LTE-A (10) LTE-A Pro (1) LTE-M (1) LTE-U (3) LoRa (5) MEC (15) MPLS (3) MWC 2013 (1) MWC 2015 (3) MWC 2016 (2) MWC 2017 (1) Mobile IPTV (1) Multi-Screen (1) Multicast (2) NAT (9) NB-IoT (6) NTT Docomo (1) Netflix (5) Network Protocol (49) Network Slicing (3) O-RAN (2) OSPF (3) OTT (20) Operator CDN (1) P2P (3) PS-LTE (3) Pooq (2) Private 5G (51) QoS (5) RCS (1) RRH (1) Request Routing (3) SD-WAN (8) SDN/NFV (42) SK Broadband (1) SK Telecom (38) Samsung (2) Security (8) Self-Driving (3) Shortest Path Tree (2) Small Cell (3) Spectrum Sharing (1) TAU (2) Transparent Caching (9) UHD (7) VLAN (2) VPN (3) VR (3) Video Streaming (22) VoLTE (1) VoWiFi (1) WAN Optimization (1) Wi-Fi (30) WiBro(WiMAX) (2) YouTube (16) eICIC (1) eMBMS (1) ePDG (6) u+ tv G (4) 로컬 5G (3) 이음 5G (21)

 

 

     
         
     

 

     
     

넷매니아즈 회원 가입 하기

2023년 6월 현재 넷매니아즈 회원은 55,000+분입니다.

 

넷매니아즈 회원 가입을 하시면,

► 넷매니아즈 신규 컨텐츠 발행 소식 등의 정보를

   이메일 뉴스레터로 발송해드립니다.

► 넷매니아즈의 모든 컨텐츠를 pdf 파일로 다운로드

   받으실 수 있습니다. 

     
     

 

     
         
     

 

 

비밀번호 확인
코멘트 작성시 등록하신 비밀번호를 입력하여주세요.
비밀번호