Selenium Labs provides Best Telecom training in Banglore based on current industry standards that helps attendees to secure placements in their dream jobs at MNCs. Selenium provides best Telecom Training in Banglore. Selenium is one of the most credible Telecom training institute in Banglore offering hands on practical knowledge and full job assistance with basic as well as advanced level Telecom Training courses. At Selenium Labs, Telecom training in Banglore is conducted by subject specialist corporate professionals with 3+ years of experience in managing real-time Telecom projects. Selenium Labs implements a blend of academic learning and practical sessions to give the student optimum exposure that aid in the transformation of naive students into thorough professionals that are easily recruited within the industry.
Telecom course involves “Learning by Doing” using state-of-the-art infrastructure for performing hands-on exercise and real-world simulations. This extensive hands-on experience in Telecom training ensures that you absorb the knowledge and skills that you will need to apply at work after your placements in an MNC
Selenium Labs helps the participants to get hands-on knowledge in 5G Core with this course. And to make this course even more professional, we allow them to work in different real-time projects that include some real-time cases. Therefore, after completing this course, the participants can get complete expertise in both of these topics with practical exposure. Apart from that, the projects on which the students work here comply with the modules offered in the course curriculum.
Duration of Selenium Training
Course Duration
5 Days
Course will be 36 hrs to 45 hrs duration with real-time projects and working models.
Total Learners
2245 Learners
We have already finished 800+ Batches with 100% course completion record.
Skill Level
Beginner & Advance
We are providing Training to the needs from Beginners level to Advance level.
Support
24 / 7 Support
Our Support team are available 24/7 to clear students needs and doubts.
At Selenium Labs, we only choose professionals for our training institute as trainers, who are highly trained in Telecom Training with 5G technologies. Besides, the professional trainers of our institute have years of experience in technologies. Therefore, these experts offer great freedom to all the participants in exploring all the details of this course, who choose our institute to get trained in 5G Core. Besides, these experts help the participants to finish the real-time projects on time and to prepare them for the interview’s possible questions and answers.
Certification
At Selenium Labs, certifications are offered to the participants once they complete the theoretical and practical sessions of this course. Here assessments are offered to the participants depending on online tests offered at the end of the course and the project performance and the result of the online tests conducted at the end of the course. Therefore, the certification offered by our institute enhances the value of the participant’s resume.
5G technology brings significant advancements in coverage, capacity, optimization, and troubleshooting. Here’s how each aspect benefits from 5G:
1. Coverage
Wider Connectivity: 5G uses a mix of low, mid, and high-band frequencies to provide better coverage in both urban and rural areas.
Improved Penetration: Low-band 5G signals can penetrate buildings and reach farther distances, ensuring stable connectivity indoors.
Seamless Mobility: Enhanced handover mechanisms between 5G towers ensure uninterrupted connections for users moving between locations.
Network Slicing: Allows customized network coverage for different applications, such as IoT and smart city solutions.
2. Capacity
High Bandwidth: 5G supports up to 10 Gbps speeds, enabling faster data transfer for high-demand applications like video streaming and gaming.
Massive Device Connectivity: Can handle up to 1 million devices per square kilometer, supporting IoT, smart cities, and dense urban areas.
Reduced Network Congestion: Advanced technologies like beamforming and MU-MIMO (Multi-User, Multiple Input Multiple Output) allow efficient spectrum utilization.
Lower Latency: Provides ultra-low latency (<1ms) for real-time applications such as autonomous vehicles and remote surgery.
3. Optimization
AI and Machine Learning Integration: 5G networks use AI for predictive maintenance, traffic management, and dynamic resource allocation.
Edge Computing: Reduces latency by processing data closer to the user, improving performance for applications like AR/VR and industrial automation.
Dynamic Spectrum Sharing (DSS): Ensures smooth transition between 4G and 5G, allowing operators to optimize existing resources.
Energy Efficiency: 5G networks use smart power management, reducing energy consumption per bit of data transmitted.
4. Troubleshooting
Real-Time Network Analytics: AI-powered analytics provide insights into network performance, detecting issues before they impact users.
Self-Healing Networks: 5G can autonomously detect and fix network failures, minimizing downtime.
Remote Diagnostics: Operators can remotely monitor and troubleshoot issues, reducing the need for on-site maintenance.
Improved Security: 5G includes enhanced encryption and authentication features to prevent cyber threats and unauthorized access.
- All theoretical and practical classes
- Comprehensive and practical knowledge of each of the topics
- The course offered by us is matched with real-time project work for practicing.
- The training program that we offer is run at our institute in Bangalore.
- Based on the preferences of the participants, we arrange both weekday and weekend classes.
- Here students are free to make their course payments in two installments.
- We also offer 24/7 support to the students. So, the students can ask any question to the trainers of our institute about the course.
- The instructors of our company have several years of experience in Technology.
- At Selenium Labs, we only encourage the participants to work on real-time projects to be industry-ready. Apart from that, we also organize mock interviews for the participants that can help them to develop their confidence level.
- Besides, backup classes are offered to the students to make sure that they don’t have to miss anything.
Course Content
” 5G Essential” typically refers to the core elements and fundamental components that are necessary for the deployment and effective use of 5G technology. These elements help enable the promises of 5G, such as ultra-fast speeds, low latency, massive device connectivity, and network flexibility.
- Basic / Introduction 5G concept and its use cases
- Evolution from 2G to 5G
- What is 5G Technology? (Includes What is spectrum || 5G bands & mmW details & Electromagnetic field || What is 5G New radio || 5G New technologies: Massive MIMO, Beamforming, DSS) and etc.
- 5G Architecture, 5G Identities, 5G Protocol Stack, 5G QoS, 5G Networking Slicing, Mobility Concepts, LTE & IMS Architecture, End to End Telco Cloud
- 5G promises as per 3GPP & 3GPP position with 5G along with 5G market updates.
- 5G use case families: eMBB, URLLC, mMTC
- Services and requirements for vertical sector
- 5G (SA & NSA) architecture & New radio
- Key difference between 4G & 5G in terms of Protocol Layer (L1,L2,L3+) of gNodeB
- What is Interface Radio NR
- 5G End to end architecture / QoS architecture / Service architecture / Radio architecture
- Standalone Vs Non standalone architectures & its difference and use.
- 5G deployment options, How & What is 4G to 5G migration strategies across the globe.
- 5G Core architecture, Network Slicing and use cases around it
- 5G Frame structure, Numerology, Channel structure
- MEC in 5G network Deployment
- Transport Connectivity
- 5G KPIs Counters and 5G mobility Management
- KPI definition in SA and NSA
- Key parameters in messages and its significance
- Counters in NSA with call flow procedures
- NSA Mobility Management
- Radio, Core, Transmission, etc. domains KPIs.
- Practical Call flow in NSA & SA Mode
- 5G Attach procedure call flow with traces
- Different use cases of 4G in correlation to 5G flow
- 5G Attach failed and call flow
- 5G Mobility call flow in different use cases
- Roaming and inter and intra working call flow.
- Dual connectivity (MR-DC, NR-DC)
- 5G NSA Practical Features applications in real networks
- Split Bearer in NSA Mode
- 5G DSS with practical deployments and constraints
- 5G Logo Icon & upper layer indication
- Feature optimization for high-speed mobility in 5G (with DMRS, RACH, Hyper cell etc.)
- SIBs in 5G, which are important SIBs and what & Why SRB 3 activation in 5G is required
- Introduction of O-RAN
- Overview of O-RAN
- From traditional RAN to O-RAN
- O-RAN alliance
- Goal of O-RAN
- What O-RAN optimizes
- O-RAN Architecture Overview & Split Architecture in detail
- O-RAN disaggregated components (CU,DU,RU,SMO,RIC) and its functionalities
- 5G NR : RAN Upper layer Protocols
- RRC procedures in detail as per 3GPP standard
- RRC States
- SDAP procedures in detail as per 3GPP standard
- PDCP procedures in detail as per 3GPP standard
- RLC procedures in detail as per 3GPP standard
- NRUP procedures in detail as per 3GPP standard
- PSUP procedures in detail as per 3GPP standard
- Inter protocol layer interactions
- Release 15,16,17,18 and later release main features and difference
- 5G NR : RAN Lower level protocols
- PHYSICAL AND MAC LAYER PROCEDURES
- RACH
- UL Power Control
- HARQ
- CQI, RI and PMI
- SR & BSR
- PHR
- DRX
- 5G MAC Scheduler
- Scheduler & Scheduling types
- Scheduling Flows
- TB size & MCS Calculation
- Concept of MIMO, MU-MIMO
- Layer 2 to layer 1 interface procedures
- 5G NR performers
- Link budget calculation
- 5G performance measurements
- OPEN RAN
- O-RAN interfaces , its procedures and purpose
- A1 Interface
- O1 Interface
- O2 Interface
- E2 Interface
- Open Front haul Interface
- E1 Interface
- F1-c Interface
- F1-u Interface
- NG-c Interface
- X2-c Interface
- X2-u Interface
- Xn-c Interface
- Xn-u Interface
- Uu Interface
- CPRI and eCPRI Interface
Different types of Planes in O-RAN
- Control plane
- User Planes
- Synchronization plane
- Management plane
O-RAN functions
- Virtualization
- Containerisation
- CU-DU call flow
- Near RT-RIC xAPPs, Interfaces and APIs
- Use cases
- O- Cloud
- Work group and standardisation activities
- Basics of 5G Coverage
- Basic of 5G Planning & its Dimensioning
- Radio planning steps, stages of planning during deployment / field trial
- 5G Practical Coverage Vs 4G Coverage comparison
- Massive MIMO planning & Beamforming and Initial Access
- Basic of Massive MIMO planning / Beam pattern basic & its optimization
- 5G NR Initial Access
- SS Burst principle
- Beam Management in NR (Beam sweeping, Beam measurement & etc.)
- Beam Management SA and NSA
- Initial Beam establishment
- 4G/5G planning difference and comparison
- Coverage comparison for 4T4R, 8T8R and 64T64
- Capacity planning and Dimensioning
- 5G Capacity and Shannon Law
- 5G NR Throughput Calculation
- 5G Capacity Limiting factors
- 5G Dimensioning
- 3D Monte Carlo Simulation
- Real-World 5G Optimization Issues and Solutions
- 5G Coverage comparison and Optimization in SA & NSA mode
- Anchor and Mobility optimization cases
- SCG failure & NR Radio Timers optimization
- 5G Access common issues
- 5G Summary analysis process
- Introduction to important Parameter & Feature and Optimization process based on Parameter tuning & Feature implementation
- Low Throughput Troubleshooting
- 5G NR Throughput Calculation
- Factors & Perquisites to reach max 5G Throughput
- Number of Grant and RB Troubleshooting
- Troubleshooting & Optimization low Throughput scenario (Low RI samples, MCS, High BLER – Packet loss, Poor Quality, Poor KPI, Poor RF performance, Core Issues, etc. other correlations)
- Radio level checks & parameters to be monitored
The 5G Core online training offered by Selenium Labs helps the participants to master in telecom training from scratch with the help of a hands-on training coupled with real-time examples. This online training also offers thorough knowledge to the participants on the ways a Service-Based Architecture where different network functions communicate with each other using APIs.
- 5G Network Function
- Access and Mobility Management Function (AMF),
- Authentication Server Function (AUSF),
- NF Repository Function (NRF),
- Network Slice Selection Function (NSSF),
- Policy Control Function (PCF),
- Session Management Function (SMF),
- User Plane Function (UPF),
- CHF (Charging Function),
- Unified Data Management (UDM)
- Unified Data Repository (UDR)
- Network Exposure Function (NEF)
- Service Based Architecture
- SBA Overview,
- REST Principles,
- NR Services Authorization,
- NF Discovery and Selection,
- Network Slicing and Slice Allocation
- 5G QoS, Policy and Billing
- 5G QOS to QFI to DRB mapping
- AM and SM Policies,
- UE Policies (URSP for Slicing),
- PDR (Packet Detection Rule),
- URR (Usage Reporting Rule),
- How Billing in 5G is different from 4G,
- Billing call flow
- 5G Network Slicing
- What is Network Slicing and why do we need it?
- Slicing use cases
- Need of Slicing
- What is Network Slicing?
- Network Slicing in 5G Networks
- Support of Slicing in Core Network
- Transport Network Slicing
- RAN Slicing – Different use cases and configurations
- How do we manage Network Slicing?
- How a UE selects Network Slice?
- Slicing during Registration
- Slicing during Session establishment
- Network Slicing Life Cycle
- Network Slice Management
- Deployment of Network Slices
- Network Orchestration
- Need of Orchestration in 5G Networks
- Distributed cloud is an essential element for low-latency services and applications
- Benefits of distributed clouds
- Deployment options in distributed cloud for 5G
- Need of Network Orchestrator
- Role of Network Orchestrator in Management of Resources.
- Open Source Initiatives for Network Orchestration -ONAP, ETSI
- MANO, OSM, OP-NFV
- Role of AI/ML in network orchestration
- MEC- Multi Access Edge Computing
- Multi-Access Edge Computing (MEC)
- What is MEC?
- Need for MEC
- Benefits of MEC
- MEC in 5G network Deployment
- MEC Architecture
- Architecture of LTE and 5G for MEC
- MEC Enablers
- Enablers for MEC-Edge cloud, NFC, SDN
- MEC in 5G RAN and Core Networks
- MEC Orchestration
- 5G Security
- Security Framework in 5G
- UE Security Framework (SUPI, SUCI, AAA)
- Networks Security
- Transport layer Security
- Application (NF) level Security
- Inter-PLMN security
- Understanding SDN and NFV
• Modularity, Abstraction and Virtualization in IT
• Virtual Machines (VM)
• Understanding VM with Mininet Appliance
• Virtual Switch
• Virtual Router, Virtual Device
• Virtual Network Function
• SDN, SDN with Virtualization
• Benefits/Issues of SDN and NFV
• Installing and SDN VM
2. SDN Overview with Mininet Demo
• What is SDN?
• What problem does it solve and what are its benefits?
• Open Network Foundation (ONF)
• OpenFlow Architecture
• SDN controller as Network Hypervisor or NOS
• Open VSwitch, Mininet, OVS Controllers
• Commercial/Open Source Controllers
• Demo/Hands-on: Mininet with OpenFlow Controller
•Demo/Hands-on: OpenFlow message with wireshark
3. Introduction to SDN & OpenFlow
• OpenFlow Switch Architecture
• OpenFlow Ports
• OpenFlow Pipeline Processing
• Flow Table Instructions and Actions
• Flow Table counters and Meters
• Group Table and Group Entry
• Ingress and Egress Processing
• Channels, Auxiliary Connection
• OpenFlow Control Messages and Message Formats
• Multiple Controllers
• Bootstrapping a new switch
• Capturing and understanding Controller-Switch interaction with Wireshark
• OpenFlow utilities: DPCTL, OFCTL, VSCTL
• Demonstration of some simple controllers developed Python
• Operation of OVS, Proactive Controller and Reactive Controller
4. Mininet
• What is Mininet?
• Launching Mininet-Command line arguments
• Information Commands
• Configuration Host
• Ping and Xterm commands
• Configuring Link, Link Performance with Iperf
• Exit and cleanup
5. Mininet with Python Script
• Creating a network with Mininet Python Scripting
• Two different ways to use the Script
• Some simple networks with Python Scripts
• Scripts to create more complex networks
6. SDN Eco System
• Initiatives, Standards (ONF)
• NFV, Cloud and SD-WAN
• Enterprise Solutions
• Service Provider Solutions – Open Day Light, ONOS OpenStack, Taker, ONAP
Demonstration with 4-port SDN Switch
7. Virtualizing PE and CPE Functions
• Understanding Virtualization with Border Gateway Virtualization
• Various Architectural options with Virtualized CPE – Pros/Cons
• Choosing CPE functions to Virtualize with some examples
• Options to deploying Virtualized functions – Pros/Cons
• Virtualizing and adding Software Defined Controls to PE and CPE
8. Developing Orchestration with Virtualized PE and CPE Functions
• ETSI NFV MANO – Reference Architecture – Scope – Single Provider
• Functional Components – MANO, NFVM, VIM, …
• Realization of those functional components with
• OpenStack, OpenTacker, EMS, Controllers (SDN, …), TOSCA, and
• TOSCA NFV Templates and their use in orchestration Some TOSCA NFV Examples
• Reference Points and realization of those interfaces
• SDN OpenFlow, NetConf, SNMP, REST API, …
9. MEF LSO – Reference Architecture – Scope – Multi Provider
• MEF LSO – Functional components – Edge, Gateway, Controller, Orchestrator,
OSS/BSS, UI
• Realization of those functional components with PE/CPE
• Orchestration with multi-level controllers
• OSS/BSS Interaction
• Use Case
Telco Cloud is the transformation of traditional telecommunications infrastructure into a cloud-based architecture. It enables telecom operators to deliver network functions and services more efficiently by leveraging cloud computing, virtualization, and automation.
- Introduction to Virtualization
- Why Virtualization
- Understanding the Physical servers
- Server Virtualization
- Hypervisors
2. Introduction to OpenStack
- Cloud Computing- laaS/Paas/Saas,
- OpenStack Overview,
- OpenStack Services,
- OpenStack Objects Creation,
- OpenStack Deployment Models
3. NFVi Concept
- Nova Scheduling,
- Open Virtual Switch,
- Hyper Threading,
- NUMA,
- CPU Pinning,
- Huge Pages,
- PCIe Passthrough and SR-IOV,
- Data Plane Development Kit (DPDK)
4. ETSI NFV MANO Architecture
- NFV MANO Architecture,
- Reference points in NFV,
- Telco Cloud,
- Availability Zones and Host Aggregates,
- OpenStack CLI,
- NFV case study
5. NFVi Networking and SDN introduction
- Data center 2 tier Architecture,
- Data center ToR and EoR Switches Overview,
6. Cloud Security
7. Open Cloud
The RAN Intelligent Controller (RIC) is a key component in Open RAN (O-RAN) architecture, designed to optimize and manage radio access networks (RANs) using artificial intelligence (AI) and machine learning (ML).
1. Introduction to RIC Architecture
- Near-Real Time RIC
- Non-Real Time RIC
2. Near RT Architecture
- Overview of Platform
- Overview of External Interfaces
- A1
- O1
- E2
- Design principle of xAPPs
- Design principle of RIC API
3. Deep Dive into Platform Functions
- Databases
- xAPP management
- API Enablement
- AI/ML
4. Deep Dive into RIC APIs and Procedures
- Databases
- A1 related APIs
- E2 related APIs
- O1 related APIs
- SDL APIs
- Enablement APIs
