EEE Curriculum Highlights
 Powering the Future with AI

B.Tech EEE · Curriculum Highlights

A future-ready programme that fuses strong foundations in Electrical Engineering with cutting-edge AI integration — empowering students to excel in emerging domains like EV Technology, Industrial Automation, Smart Grids, Renewable Energy, Robotics and Embedded Systems.

4Years · 8 Sem
170Total Credits
26Elective Options
6Specialisation Tracks
01 · Curriculum Navigator

Core Engineering powering intelligent transformation

The B.Tech in Electrical & Electronics Engineering at Amal Jyothi is engineered to stand apart. Grounded in fundamentals and enhanced with modern interdisciplinary integration, it offers real academic flexibility:

Duration

4 Years · 8 Semesters
Progressive depth from Year 1 fundamentals to Year 4 industry-ready projects.

Total Credits

170 Credits
Balanced across core PCC, professional electives, honours pathways and projects.

Elective Structure

4 Elective Groups · 26 Options
Industry-linked electives bridging engineering and industry needs.

Academic Flexibility

Explore multiple Minor options and pursue distinct Honours pathways aligned with career goals.

Industry Linkage

Industry-linked electives and collaborations with leading companies for internships and co-developed learning.

NBA Re-accredited

B.Tech EEE is NBA re-accredited with validity through 2026, affirming quality outcomes-based education.

02 · Program Philosophy & Focus

A future-ready program that fuses foundations with AI

The programme is designed to deliver excellence through innovation, industry relevance and future-ready skills — empowering students to excel in:

EV Technology

Electric vehicles, battery management, charging infrastructure and electric drive systems.

Industrial Automation

PLC, SCADA, smart manufacturing, robotics and intelligent control systems.

Smart Grids

Intelligent power networks, distributed energy systems and grid analytics.

Renewable Energy

Solar, wind, fuel cells, energy storage and grid-integration technologies.

Robotics & AI

Intelligent systems, automation, AI-driven control and machine learning in power.

Embedded Systems

Microcontrollers, IoT, real-time systems and edge computing applications.

03 · Curriculum Pillars

Engineered to stand apart

The curriculum is built on seven distinct pillars — each aligned with tomorrow's engineering needs:

AI Integration in EEE Domains

Artificial Intelligence woven into electrical, power, control and embedded subjects from early semesters.

Future Power & EV Technologies

Dedicated streams on electric mobility, drive systems, battery tech and charging infrastructure.

Energy-Centric Learning

Renewable energy, smart grids, storage and energy economics anchored in the core curriculum.

Embedded & Intelligent Systems

Microcontrollers, IoT, digital design and FPGA/SOPC platforms for real-time intelligent applications.

Industry-Linked Labs & Collaborations

Centres of Excellence and industry-supported infrastructure bring real-world context into every lab.

Integrated Skill Development

Technical skills + soft skills + teamwork — preparing graduates for professional careers.

Entrepreneurship & Innovation Support

Linkages with incubation centres and start-up ecosystem for students with entrepreneurial ambition.

04 · Core Strength of the Curriculum

Strong foundations, modern interdisciplinary integration

The curriculum is built on a strong foundation of Electrical and Electronics Engineering, enhanced with modern interdisciplinary integration:

  • Strong grounding in core electrical engineering concepts
  • Early integration of Artificial Intelligence in EEE domains
  • Focus on Electric Vehicles and future mobility systems
  • Emphasis on renewable energy and smart grid technologies
  • Hands-on learning through industry-linked laboratories
  • Development of embedded, digital and intelligent systems
  • Continuous focus on practical skills and innovation-driven learning
05 · Future Technologies in Action

Students apply future technologies from day one

AI-Driven Electrical Systems

Applying ML and AI to electrical engineering problems — predictive maintenance, optimisation and intelligent control.

Smart Power & Energy Analytics

Data-driven insights for grid operation, demand forecasting and renewable-energy integration.

Intelligent Control & Automation

Modern control theory applied with AI — from process plants to autonomous systems.

Hands-on AI & Control Labs

Laboratory experiments integrating AI techniques with traditional control and power systems.

Embedded & Digital System Design

Digital hardware design, FPGA, microcontroller-based systems and real-time applications.

06 · Flexible Specialisation Tracks

Six tracks · choose a career-aligned pathway

Flexible pathways that allow students to specialise in areas aligned with their interests and career goals:

Track 1 · Mobility

Electric Mobility & Vehicle Technologies

  • Fundamentals of Electric Vehicles
  • Battery Management Systems & Charging Infrastructure
  • Electric Drive Systems and Control
  • EV Simulation and Modelling
Track 2 · Green Energy

Renewable & Clean Energy Systems

  • Solar PV and Thermal Energy Systems
  • Wind Energy and Fuel Cell Technologies
  • Advanced Energy Storage Systems
  • Energy System Modelling and Simulation
Track 3 · Grid

Smart Microgrid & Distributed Energy Systems

  • Advanced Power System Analysis
  • Renewable Energy Integration
  • Power Electronics for Grid Applications
  • Microgrid Control and Dynamics
Track 4 · Digital Power

Digital Control & Power Converter Systems

  • Integrated Circuit Applications
  • Digital Hardware Design using VHDL
  • Power Electronic Circuit Design and Simulation
  • SOPC-Based Power Converter Design
Track 5 · Biomed

Biomedical & Healthcare Engineering

  • Medical Instrumentation Fundamentals
  • Medical Image Processing
  • Hospital Systems Engineering and Management
  • Biomedical Safety and Risk Management
Track 6 · Storage

Energy Storage & Sustainable Management

  • Renewable Energy Resources
  • Energy Systems and Economics
  • Industrial Energy Management
  • Energy Storage Technologies and Electric Mobility
07 · Industry-Sponsored Centres of Excellence

Advanced, industry-supported facilities beyond the curriculum

The department offers advanced, industry-supported facilities that provide hands-on learning beyond the classroom:

C2S Programme

Access to EDA tools for VLSI, FPGA and high-frequency design — industry-grade chip-design exposure.

MATLAB & Simulation Lab

System modelling, signal processing and control analysis with industry-standard simulation tools.

Specialised Labs

Dedicated facilities for IoT, Biomedical (SCBMI) and Project Prototyping.

Infrastructure

Microcontroller kits, fabrication facilities and solar PV systems for experiential learning.

Utilisation

  • Laboratory sessions integrated across semesters
  • Mini & major student projects
  • Research and consultancy work
08 · In-Demand Engineering Domains

Expertise in high-growth, industry-relevant areas

Students gain expertise in high-growth, industry-relevant domains — preparing them for diverse and future-ready career opportunities across core and emerging sectors:

Electric Vehicle Technology

EV systems, battery technology and drive control.

Smart Grid Systems

Intelligent power networks and energy analytics.

Industrial Automation

PLC, SCADA and smart manufacturing systems.

Robotics & Intelligent Systems

Automation and AI-driven control.

AI in Power Systems

Machine learning for energy systems and analytics.

Embedded Systems

Microcontrollers, IoT and real-time applications.

Renewable Energy Technologies

Solar, wind and energy storage systems.

Semiconductor Technology

VLSI design, FPGA systems and chip development.

09 · Career Opportunities

Pathways across core engineering, public sector & global industries

The programme prepares students for diverse career pathways — ensuring strong employability and long-term growth:

Core Engineering Roles

  • Power Systems Engineer
  • Electrical Design Engineer
  • Control Systems Engineer
  • Embedded Systems Engineer

Public Sector Opportunities

  • PSUs: NTPC, BHEL, ONGC, PowerGrid
  • Indian Railways Engineering Services
  • State Electricity Boards (KSEB)
  • DRDO, ISRO and research organisations

Private & MNC Careers

  • ABB, Siemens, Schneider Electric, Bosch
  • Electric Vehicle & Automotive Industry
  • Energy & Power Sector Companies
  • Automation, Robotics & AI Firms
  • Semiconductor & Electronics Industry
Strong employability outcomes. The programme combines core engineering fundamentals with industry-relevant specialisations and hands-on labs — giving graduates the technical depth and practical exposure that employers across the energy, mobility, automation and semiconductor sectors are actively looking for.
10 · Why Choose This Program

Five reasons to choose B.Tech EEE at AJCE

Placement-focused learning

A learning approach centred on employability — from core roles to emerging industries.

Strong industry partnerships

Collaborations with leading power, automation, EV and semiconductor companies.

Hands-on, project-based

Every semester pairs theory with design-first labs and mini / major projects.

Real-world engineering

Exposure to industry challenges through consultancy, industry visits and collaborative projects.

Future-ready with AI

AI integration across the curriculum prepares graduates for where the industry is heading next.

Ready to apply? Visit the B.Tech admissions page for eligibility, application process and key dates. For programme-specific queries, reach the department via the contact page.
At a Glance

Programme snapshot

170Total Credits
8Semesters
4Elective Groups
26Elective Options
6Spec. Tracks
NBARe-accredited
AIIntegrated
2001Established