BUDAPEST 5th International Conference on Electrical, Electronics & Biomedical Engineering: EEBE-27

Call for papers/Topics

All Abstracts, Reviews, short articles, Full articles, Posters are welcomed related with any of the following research fields:

Foundational & Independent Topics

These topics represent the core pillars of each distinct engineering discipline.

1. Electrical Engineering (Power and Systems)

Focuses on the generation, transmission, and management of electrical energy and large-scale systems.

  • Power Systems and Smart Grids: Grid integration, power distribution, high-voltage engineering, and smart grid automation.

  • Renewable Energy Systems: Solar photovoltaics, wind turbines, energy storage (batteries/supercapacitors), and microgrids.

  • Electrical Machines and Drives: Transformers, DC/AC motors, generators, and motor control circuits.

  • Control Systems: Linear and non-linear control, feedback loops, PID controllers, and state-space analysis.

2. Electronics Engineering (Components and Circuitry)

Focuses on processing information using electrical currents through semiconductor devices and microchips.

  • Analog Electronics: Operational amplifiers (Op-Amps), transistors (BJTs, MOSFETs), filters, and oscillators.

  • Digital Electronics and VLSI: Logic gates, microcontrollers, FPGAs, CMOS technology, and Very Large Scale Integration (VLSI) chip design.

  • Embedded Systems: Real-time operating systems (RTOS), firmware development, and Internet of Things (IoT) hardware architecture.

  • Telecommunications and RF Engineering: Radiofrequency circuits, antenna design, wireless communication protocols (5G/6G), and satellite communication.

3. Biomedical Engineering (Healthcare and Life Sciences)

Focuses on applying engineering principles strictly to biology and medicine for healthcare purposes.

  • Biomechanics: Kinematics of human movement, prosthetics design, bone mechanics, and fluid dynamics of blood.

  • Biomaterials: Biocompatible implants, tissue scaffolds, drug delivery systems, and dental materials.

  • Cellular and Tissue Engineering: Stem cell differentiation, organ-on-a-chip technologies, and regenerative medicine.

  • Rehabilitation Engineering: Wheelchair technology, assistive devices for sensory impairments, and exoskeletons.

Interrelated & Applied Topics

These fields represent the overlap where Electrical, Electronics, and Biomedical Engineering merge to create modern medical technologies and smart systems.

1. Bioinstrumentation and Biosensors

The intersection of analog/digital electronics and biomedical engineering.

  • Medical Sensors: Electrodes, optical sensors, and electrochemical biosensors for detecting glucose, oxygen, or specific proteins.

  • Amplification and Isolation: Low-noise instrumentation amplifiers and isolation circuits to safely capture weak human bio-signals.

  • Wearable Health Tech: Smartwatches, continuous glucose monitors (CGMs), and fitness trackers.

2. Biomedical Signal Processing

The intersection of electrical systems engineering, computer science, and medicine.

  • Electrocardiogram (ECG/EKG) Processing: Filtering noise and detecting abnormalities in heart rhythms.

  • Electroencephalogram (EEG) Analysis: Processing brainwaves for sleep studies, epilepsy detection, and Brain-Computer Interfaces (BCIs).

  • Digital Filtering: Fourier transforms, wavelet transforms, and adaptive filtering to clean messy biological data.

3. Medical Imaging Systems

A massive convergence of high-power electrical systems, electronics, physics, and signal processing.

  • X-Ray and CT Scanners: High-voltage generation for X-ray tubes and rotational imaging algorithms.

  • Magnetic Resonance Imaging (MRI): High-power RF pulses, superconducting magnets, and gradient coil control.

  • Ultrasound Imaging: Piezoelectric transducer arrays, beamforming, and Doppler echo processing.

4. Bionics, Neuroengineering, and Robotics

The combination of control systems (Electrical), microcontrollers (Electronics), and neural anatomy (Biomedical).

  • Neural Implants: Deep Brain Stimulators (DBS) for Parkinson's disease, and cochlear implants for hearing loss.

  • Robotic Surgery Systems: High-precision robotic arms (e.g., da Vinci surgical system) with haptic feedback.

  • Myoelectric Prosthetics: Artificial limbs controlled by the electrical signals generated by a user's remaining muscles.

5. Clinical Engineering and Healthcare Safety

The systems engineering side of managing technology within hospital ecosystems.

  • Electrical Safety in Hospitals: Isolation transformers, grounding systems, and preventing microshocks to patients.

  • Telehealth and Medical IoT (IoMT): Secure wireless transmission of patient data from home to hospital.

  • Medical Device Regulation: Navigating FDA regulations, CE marking, and ISO standards for hardware safety