5G and Electrical Infrastructure: 5-Day Professional Training Course

Course Overview

This cutting-edge 5G and Electrical Infrastructure Training provides comprehensive knowledge of 5G technology deployment, power requirements, electrical system design for cellular networks, smart grid applications, and critical infrastructure connectivity. This intensive 5-day program covers 5G fundamentals, base station power systems, backup power solutions, electromagnetic compatibility, IoT integration, and infrastructure planning for telecommunications and electrical professionals.

Who Should Attend This 5G Infrastructure Course?

• Electrical Engineers designing telecom infrastructure

• Telecommunications Engineers planning 5G networks

• Power System Engineers supporting cellular networks

• Network Planners in telecom operators

• Facility Managers hosting cellular equipment

• Smart Grid Engineers implementing 5G connectivity

• Project Managers overseeing 5G deployments

• Infrastructure Developers in telecommunications

• Utilities Engineers exploring 5G for grid automation

Course Objectives

Participants will master 5G technology fundamentals, electrical power requirements for 5G infrastructure, base station and small cell power design, backup power and energy storage, electromagnetic interference mitigation, smart grid 5G applications, network slicing for utilities, and infrastructure deployment strategies.

Day 1: 5G Technology Fundamentals and Infrastructure Overview

Morning Session: Introduction to 5G Technology

Topics Covered:

• 5G definition and evolution from 1G to 5G

• 5G New Radio (NR) specifications and standards

• Frequency bands: low-band (sub-1GHz), mid-band (1-6GHz), high-band (mmWave 24-100GHz)

• 5G performance targets: 10Gbps speed, 1ms latency, massive connectivity

• Network architecture: standalone (SA) vs. non-standalone (NSA)

• Core network: 5G Core (5GC) and network functions

• Radio Access Network (RAN) components

• Use cases: enhanced mobile broadband (eMBB), ultra-reliable low-latency (URLLC), massive IoT (mMTC)

Key Technologies:

• Massive MIMO (Multiple Input Multiple Output)

• Beamforming and beam steering

• Network slicing for dedicated services

• Edge computing and Multi-access Edge Computing (MEC)

• Software-Defined Networking (SDN) and Network Function Virtualization (NFV)

Afternoon Session: 5G Infrastructure Components

Topics Covered:

• 5G base station types: macro cells, small cells, femtocells

• Cell tower infrastructure and rooftop installations

• Distributed Antenna Systems (DAS)

• Remote Radio Heads (RRH) and baseband units

• Fronthaul and backhaul connectivity

• Fiber optic requirements and deployment

• Microwave and millimeter-wave backhaul

• Equipment shelters and outdoor cabinets

Infrastructure Requirements:

• Site selection and RF planning

• Physical space and mounting requirements

• Environmental considerations: temperature, weather protection

• Access and maintenance provisions

• Zoning regulations and permitting

Workshop:
Understanding 5G network topology and infrastructure deployment scenarios.

Day 2: Electrical Power Requirements for 5G Infrastructure

Morning Session: 5G Power Consumption Analysis

Topics Covered:

• 5G base station power requirements

• Macro cell power consumption: 2-10kW typical

• Small cell power consumption: 50-500W

• mmWave equipment higher power density

• Power consumption comparison: 4G vs. 5G

• Massive MIMO power demands

• Cooling and HVAC requirements

• Power consumption optimization strategies

• Energy efficiency initiatives

Power System Components:

• AC/DC power conversion and rectifiers

• DC distribution systems: -48VDC standard

• Power Distribution Units (PDU)

• Cable sizing for telecom loads

• Grounding and bonding requirements

Afternoon Session: Base Station Electrical Design

Topics Covered:

• Electrical service requirements for cell sites

• Single-phase vs. three-phase power supply

• Voltage levels and utility interconnection

• Load calculations and demand factors

• Circuit protection: circuit breakers, fuses, surge protection

• Power quality requirements: voltage regulation, harmonics

• Lightning protection systems for towers

• Electromagnetic compatibility (EMC) considerations

Design Standards:

• ANSI/TIA telecommunications standards

• NEC Article 645: Information Technology Equipment

• IEEE standards for telecom power

• Local electrical codes and utility requirements

Practical Exercise:
Calculating electrical load and designing power distribution for 5G macro cell site.

Day 3: Backup Power and Energy Storage Systems

Morning Session: Backup Power Solutions

Topics Covered:

• Backup power requirements for 5G networks

• Uptime requirements: 99.999% (five nines) availability

• Battery backup systems for telecom applications

• Battery technologies: VRLA, lithium-ion, lithium iron phosphate

• Battery sizing calculations for runtime requirements

• Battery monitoring and management systems (BMS)

• Temperature compensation and battery life

• Maintenance and replacement strategies

Backup Power Configurations:

• DC battery backup systems (-48VDC)

• Uninterruptible Power Supply (UPS) systems

• Hybrid power solutions

• Battery cabinet design and installation

Afternoon Session: Generator Systems and Renewable Integration

Topics Covered:

• Diesel generator backup for extended outages

• Generator sizing for telecom loads

• Automatic Transfer Switch (ATS) operation

• Fuel storage and runtime calculations

• Generator maintenance and testing

• Solar PV integration for off-grid and hybrid sites

• Wind energy for remote cell sites

• Energy storage system (ESS) integration

• Hybrid renewable solutions for cost reduction

Green Energy Solutions:

• Solar-powered small cells

• Wind-solar hybrid systems

• Fuel cell backup power

• Energy harvesting technologies

• Carbon footprint reduction initiatives

Case Study:
Designing off-grid 5G site with solar, battery storage, and backup generator.

Day 4: Smart Grid and Utility Applications of 5G

Morning Session: 5G for Smart Grid Communication

Topics Covered:

• 5G applications in electrical utilities

• Smart grid communication requirements: latency, reliability, security

• Distribution automation with 5G connectivity

• Advanced Metering Infrastructure (AMI) using 5G

• Substation automation and IEC 61850 over 5G

• Grid monitoring and control applications

• Fault detection and self-healing grids

• Wide Area Monitoring Systems (WAMS) with 5G

5G Advantages for Utilities:

• Network slicing for dedicated utility services

• Ultra-reliable low-latency communication (URLLC)

• Massive IoT connectivity for millions of sensors

• Mobile private networks for utilities

• Edge computing for real-time processing

• Enhanced security and data isolation

Afternoon Session: Advanced Utility Use Cases

Topics Covered:

• Distributed Energy Resources (DER) management with 5G

• Electric vehicle charging infrastructure connectivity

• Demand response and load management

• Outage management and crew coordination

• Drone inspection and autonomous vehicles for utilities

• Augmented Reality (AR) for field maintenance

• Remote asset monitoring and predictive maintenance

• Worker safety applications with real-time connectivity

Network Slicing for Utilities:

• Dedicated network slice configuration

• Quality of Service (QoS) guarantees

• Service Level Agreement (SLA) management

• Spectrum allocation and priority

Workshop:
Designing 5G network slice for utility distribution automation application.

Day 5: Deployment, Testing, and Future Trends

Morning Session: 5G Infrastructure Deployment

Topics Covered:

• 5G rollout strategies: densification and coverage

• Small cell deployment: street furniture, building facades, utility poles

• Fiber backhaul deployment and dark fiber utilization

• Co-location with existing infrastructure

• Power utility partnership opportunities

• Leveraging utility poles and substations for 5G sites

• Shared infrastructure models and revenue opportunities

• Municipal regulations and right-of-way management

Deployment Challenges:

• Site acquisition and permitting delays

• Power availability in dense urban areas

• Fiber connectivity limitations

• Cost optimization strategies

• Community acceptance and aesthetics

Afternoon Session: Testing, Maintenance, and Emerging Trends

Topics Covered:

• 5G installation testing and commissioning

• Electrical system testing: voltage, grounding, protection

• RF testing and network optimization

• Power quality measurements

• Battery load testing procedures

• Preventive maintenance programs

• Remote monitoring and diagnostics

• Predictive maintenance with AI/ML

• Energy management and optimization

Testing Equipment:

• Power quality analyzers

• Battery testers and load banks

• Grounding resistance testers

• Infrared thermography

• Remote monitoring systems

Future Trends:

• 5G Advanced and 6G development outlook

• Private 5G networks for industries

• O-RAN (Open Radio Access Network) architecture

• Virtualized RAN and cloud-native deployments

• AI-powered network optimization

• Integrated 5G and satellite connectivity

• Terahertz communication research

• Energy-efficient 5G technologies

• Edge AI for intelligent infrastructure

Business Opportunities:

• Infrastructure-as-a-Service (IaaS) models

• Neutral host solutions for multi-operator sharing

• Smart city infrastructure integration

• Industrial IoT and Industry 4.0 connectivity

• Critical communication for public safety

Final Project and Assessment

Comprehensive 5G Infrastructure Design Project:
Develop complete 5G site design including:

• Site survey and requirements analysis

• RF coverage planning and equipment selection

• Electrical load calculations

• Power distribution system design

• Backup power sizing: battery and generator

• Renewable energy integration plan

• Grounding and lightning protection

• Smart grid application integration

• Cost estimation and ROI analysis

• Implementation schedule and milestones

Assessment Activities:

• Written examination on 5G and electrical infrastructure

• Practical design exercise: 5G base station power system

• Load calculation and battery sizing problem

• Case study analysis: utility 5G network deployment

• Group presentation: end-to-end 5G infrastructure solution

• Certificate of Professional Training in 5G and Electrical Infrastructure

Course Benefits and Learning Outcomes

Participants will understand 5G technology and architecture, design electrical systems for 5G infrastructure, size backup power and energy storage, integrate renewable energy, apply 5G for smart grid applications, plan network deployments, ensure EMC compliance, and calculate infrastructure costs.

Training Methodology

Instructor-led sessions with hands-on design exercises, site visit opportunities (where available), equipment demonstrations, real deployment case studies, vendor presentations, calculation workshops, and project-based learning.

Course Materials

Comprehensive training handbook, electrical design templates, load calculation spreadsheets, battery sizing tools, standards excerpts (NEC, TIA, IEEE), deployment checklists, vendor catalogs, and professional certificate.

Software and Tools

Introduction to RF planning tools, electrical design software, load calculation templates, battery sizing calculators, AutoCAD for site layouts, and project management tools.

Prerequisites

Bachelor’s degree in Electrical, Telecommunications, or related engineering, understanding of AC/DC power systems, familiarity with telecommunications basics, knowledge of electrical codes (NEC) helpful, and field experience beneficial.

Keywords: 5G infrastructure, 5G electrical systems, 5G base station power, telecommunications power systems, 5G network deployment, small cell power design, 5G backup power, smart grid 5G, 5G for utilities, cellular network infrastructure, 5G energy storage, telecom electrical design, 5G power requirements, network slicing utilities, 5G smart grid applications, private 5G networks, 5G tower power, telecommunications infrastructure training