International Conference on Electrical, Electronics & Communication Engineering LEECE on February 03-05, 2027 in Lisbon, Portugal - Conference Index

International Conference on Electrical, Electronics & Communication Engineering LEECE on February 03-05, 2027 in Lisbon, Portugal

International Conference on Electrical, Electronics & Communication Engineering (LEECE) February 03, 2027 - Lisbon, Portugal

LISBON 29th International Conference on Electrical, Electronics & Communication Engineering (LEECE-27) scheduled on Feb. 3-5, 2027 Lisbon (Portugal) is for the engineers, practitioners, scientists, researchers, scholars, and students from all around the world and it also includes the industry people to present ongoing research activities, and hence to foster research relations between Academia and industry. The conference is being organized by Emirates Research Publication (ERPUB) operting under Pilares D Elegancia LDA (Portugal). This conference provides opportunities for the delegates to share new ideas and application experiences face to face, to establish business or research relations and to find global partners for future collaboration. All the submitted conference papers will be peer reviewed by the program/technical committees of the Conference. 

Call for papers/Topics

Topics of Interest for Submission include, but are Not Limited to:

1. Core Foundational Disciplines

These topics form the mathematical and physical bedrock for all electrical and electronics engineering branches.

Mathematics for Engineering

Linear Algebra and Matrix Theory

Calculus and Differential Equations

Complex Analysis

Probability, Random Variables, and Stochastic Processes

Numerical Methods and Optimization

Engineering Physics

Electromagnetism and Maxwell's Equations

Quantum Mechanics and Solid-State Physics

Optics and Wave Mechanics

Circuit Theory and Network Analysis

DC and AC Circuit Analysis (KVL, KCL)

Network Theorems (Thevenin, Norton, Superposition, Maximum Power Transfer)

Transient and Steady-State Analysis

Two-Port Networks and Graph Theory

2. Electrical Engineering (Power and Energy Systems)

This domain deals with the generation, transmission, distribution, and utilization of electrical power.

Electrical Machines

Transformers (Single-phase and Three-phase)

DC Generators and Motors

Synchronous Generators and Motors (Alternators)

Induction Motors (Three-phase and Single-phase)

Special Electrical Machines (Stepper motors, BLDC motors, Servo motors)

Power Systems Engineering

Power Generation (Thermal, Hydro, Nuclear)

Transmission and Distribution Systems (HVDC, HVAC, Overhead lines, Cables)

Power System Analysis (Load flow, Fault analysis, Stability)

Power System Protection (Relays, Circuit breakers, Switchgear)

Smart Grids and Microgrids

Renewable Energy Systems

Solar Photovoltaic Systems

Wind Energy Conversion Systems

Energy Storage Systems (Batteries, Fuel cells, Supercapacitors)

Grid Integration of Renewables

Power Electronics

Power Semiconductor Devices (IGBTs, MOSFETs, Thyristors, Wide-Bandgap Devices like GaN/SiC)

AC-DC Converters (Rectifiers)

DC-DC Converters (Buck, Boost, Buck-Boost, Flyback)

DC-AC Converters (Inverters)

AC-AC Converters (Cycloconverters, Matrix converters)

Electric Vehicle (EV) Powertrains and Charging Infrastructure

3. Electronics Engineering (Devices and Circuits)

This area focuses on the behavior of electrons in semiconductors to design components, circuits, and micro-scale systems.

Solid-State Electronic Devices

Semiconductor Physics (Energy bands, Carrier transport)

PN Junction Diodes and Zener Diodes

Bipolar Junction Transistors (BJTs)

Field Effect Transistors (MOSFETs, FINFETs)

Optoelectronic Devices (LEDs, Photodiodes, Laser Diodes)

Analog Electronics

Biasing and Small-Signal Analysis of Transistors

Single-stage and Multi-stage Amplifiers

Feedback Amplifiers and Oscillators

Operational Amplifiers (Op-Amps) and Linear Integrated Circuits

Active Filters and Wave-shaping Circuits

Digital Electronics

Number Systems and Boolean Algebra

Logic Gates and Karnaugh Maps (K-Maps)

Combinational Logic Circuits (Adders, Multiplexers, Decoders)

Sequential Logic Circuits (Flip-Flops, Registers, Counters)

Finite State Machines (FSMs)

Semiconductor Memories (RAM, ROM, Flash)

VLSI Design and Microelectronics (Very Large Scale Integration)

CMOS Technology and Fabrication Processes

Digital VLSI Design (Data paths, Memory arrays)

Analog and Mixed-Signal VLSI Design

Hardware Description Languages (VHDL, Verilog, SystemVerilog)

Asic and FPGA Architecture

Testing and Verification of VLSI Circuits

4. Communication Engineering and Networks

This discipline addresses the transmission of information across various media (copper, air, fiber, space).

Signals and Systems

Continuous-Time and Discrete-Time Signals

Linear Time-Invariant (LTI) Systems

Fourier Analysis (Fourier Series, Fourier Transform, DTFT, DFT, FFT)

Laplace Transform and Z-Transform

Analog Communication Systems

Amplitude Modulation (AM, DSB-SC, SSB, VSB)

Angle Modulation (Frequency Modulation, Phase Modulation)

Transmitters and Receivers (Superheterodyne architecture)

Noise Performance in Analog Modulation

Digital Communication Systems

Pulse Code Modulation (PCM) and Delta Modulation

Digital Modulation Techniques (ASK, FSK, PSK, QAM, OFDM)

Baseband Data Transmission and Inter-Symbol Interference (ISI)

Error Control Coding (Block codes, Convolutional codes, Turbo codes, LDPC)

Information Theory and Shannon Capacity

Telecommunication Networks and Wireless Systems

Cellular Networks (4G, 5G, and emerging 6G)

Mobile Radio Propagation and Fading Channels

Multiple Access Techniques (FDMA, TDMA, CDMA, OFDMA)

Computer Networks and Protocols (OSI model, TCP/IP, Routing)

Satellite Communication and Global Positioning Systems (GPS)

Electromagnetics, Antennas, and Microwave Engineering

Transmission Lines and Smith Charts

Waveguides and Cavity Resonators

Antenna Theory and Design (Dipole, Microstrip Patch, Phased Arrays)

Microwave Passive and Active Components (Couplers, Circulators, Amplifiers)

Radar Systems and Remote Sensing

Optical Communication

Optical Fibers (Light propagation, Attenuation, Dispersion)

Optical Sources (Lasers, LEDs) and Detectors (PIN, APD)

Wavelength Division Multiplexing (WDM)

Optical Networks and Coherent Communication

5. Control Systems and Automation

This branch deals with the mathematical modeling and regulation of dynamic engineering systems.

Linear Control Systems

Mathematical Modeling of Physical Systems (Transfer Functions, State-space)

Block Diagrams and Signal Flow Graphs

Time-Domain Analysis (Transient response, Steady-state error)

Stability Criteria (Routh-Hurwitz, Nyquist Stability Criterion)

Root Locus Technique and Bode Plots

Design of Compensators and PID Controllers

Advanced Control Systems

Digital Control and Discrete-Time Systems

Nonlinear Control Systems

Optimal Control and Adaptive Control

State-Space Analysis and Observer Design

Industrial Automation and Robotics

Programmable Logic Controllers (PLCs) and SCADA Systems

Distributed Control Systems (DCS)

Robotic Kinematics, Dynamics, and Control

Sensors and Actuators in Automation

6. Signal Processing and Computing Infrastructure

The hardware and software architectures that process real-world data and manage computing execution.

Digital Signal Processing (DSP)

Digital Filter Design (IIR and FIR filters)

Multirate Signal Processing (Decimation, Interpolation)

Adaptive Signal Processing

Image, Video, and Speech Processing

Computer Architecture and Embedded Systems

Microprocessor and Microcontroller Architectures (8051, ARM, RISC-V, x86)

Assembly and Embedded C Programming

Real-Time Operating Systems (RTOS)

Memory Interfacing and Input/Output (I/O) Management

Hardware-Software Co-design

Internet of Things (IoT) Edge Nodes and Architecture

7. Major Interrelated and Converging Areas

These subtopics demonstrate how the fields interconnect to power modern technological systems.

Cyber-Physical Systems (CPS): Merging Control Systems, Embedded Systems, and Communication Networks for applications like autonomous driving and industrial automation.

Edge Computing and AI Hardware: Intersecting VLSI Design, Computer Architecture, and Digital Signal Processing to run artificial intelligence algorithms directly on low-power silicon chips.

Bioelectronics and Biomedical Engineering: Applying Analog Electronics, Sensors, and Signal Processing to medical diagnostic tools like pacemakers, EEGs, and MRI machines.

Hardware Security: Merging Cryptography with VLSI/Digital Design to protect integrated circuits against physical attacks and intellectual property theft.

Quantum Computing Hardware: The convergence of Solid-State Physics, Microelectronics, and Microwave Engineering to build and control physical qubits.

Name: EARET
Website: http://earet.org

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