The specialization in Biomedical Electronics will allow you to work to improve devices that improve the quality of life and life expectancy of patients" 

Applying the knowledge of electronics to develop state-of-the-art medical devices is one of the main applications of Biomedical Electronics, an area that has experienced great growth in recent years with the advances in technology. Undoubtedly, this is a fundamental sector in today's society, due to the great benefits it brings to people's health. As a result, more and more computer scientists want to specialize in this field and are looking for high-quality programs to improve their qualifications. This Postgraduate diploma at TECH addresses these academic needs of computer scientists, with a first class program in today's academic field. 

Specifically, the program includes fundamental aspects of microelectronics, analyzing the physical principles that govern the behavior of the fundamental elements of electronics; and delves into the most relevant characteristics and applications of transistors, diodes and amplifiers, among other issues. Likewise, it covers digital processing, which has experienced dramatic development in recent decades with the increasing implementation of devices based on digital electronics. 

Meanwhile, the main focus of this program is on Biomedical Electronics, addressing electrophysiology, origin, conduction and acquisition of bioelectrical signals, as well as their filtering and amplification. In addition, special emphasis is placed on the importance of electrical safety of biomedical instrumentation. 

In short, this is a 100% online Postgraduate diploma that will allow students to distribute their study time, not being conditioned by fixed schedules or having the need to move to another physical location, being able to access all the contents at any time of the day, balancing their work and personal life with their academic life.

Biomedical Electronics has advanced a lot in recent years, so the higher-level specialization of computer scientists in this field becomes highly relevant" 

This Postgraduate diploma in Biomedical Electronics contains the most complete and up-to-date program on the market. Its most notable features are:

• Practical cases presented by experts in information technology
• The graphic, schematic, and practical contents with which they are created, provide scientific and practical information on the disciplines that are essential for professional development
• Practical exercises where self-assessment can be used to improve learning
• Its special emphasis on innovative methodologies in Biomedical Electronics 
• Theoretical lessons, questions to the expert, debate forums on controversial topics, and individual reflection assignments 
• Content that is accessible from any fixed or portable device with an Internet connection

Complete this Postgraduate diploma and quickly increase your job opportunities” 

The teaching staff includes professionals from the information technology sector, who bring their experience to this training program, as well as renowned specialists from leading societies and prestigious universities. 

The multimedia content, developed with the latest educational technology, will provide the professional with situated and contextual learning, i.e., a simulated environment that will provide an immersive training experience designed to train for real-life situations. 

This program is designed around Problem-Based Learning, whereby the student must try to solve the different professional practice situations that arise throughout the program. This will be done with the help of an innovative system of interactive videos made by renowned experts.  

Carrying out the multiple practical cases that TECH provides you with will help you to refine your theoretical knowledge"

The online format of this Postgraduate diploma will give you the opportunity to self-manage your study time"

The content of this Postgraduate diploma in Biomedical Electronics at TECH has been designed with the academic needs of computer engineers in this field in mind, and will provide them with the necessary knowledge to be able to control the electronic part of the devices that can be used in the health field, achieving a better quality of life for patients. Undoubtedly it is a highly valuable area, since it bring notable benefits to people, which is why more and more people are wishing to join this field. 

The most complete syllabus on Biomedical Electronics on the market”  

Module 1. Microelectronics

1.1. Microelectronics vs. Electronics 

1.1.1. Analog Circuits 
1.1.2. Digital Circuits 
1.1.3. Signals and Waves 
1.1.4. Semi-Conductor Materials 

1.2. Semi-Conductor Properties 

1.2.1. Structure of the PN Junction 
1.2.2. Reverse Breakdown 

1.2.2.1. Zener Breakdown 
1.2.2.2. Avalanche Breakdown 

1.3. Diodes 

1.3.1. Ideal Diode 
1.3.2. Rectifier 
1.3.3. Characteristics of the Diode Junction 

1.3.3.1. Direct Polarization Current 
1.3.3.2. Inverse Polarization Current 

1.3.4. Applications 

1.4. Transistors 

1.4.1. Structure and Physics of a Bipolar Transistor 
1.4.2. Operation of a Transistor 

1.4.2.1. Active Mode 
1.4.2.2. Saturation Mode 

1.5. MOS Field-Effect Transistors (MOSFETs) 

1.5.1. Structure 
1.5.2. The I-V Features 
1.5.3. MOSFET Circuits in Continuous Current 
1.5.4. The Body Effect 

1.6. Operational Amplifiers 

1.6.1. Ideal Amplifiers 
1.6.2. Settings 
1.6.3. Differential Amplifiers 
1.6.4. Integrators and Differentiators 

1.7. Operational Amplifiers. Uses 

1.7.1. Bipolar Amplifiers 
1.7.2. CMOS 
1.7.3. Amplifiers as Black Boxes 

1.8. Frequency Response 

1.8.1. Analysis of the Frequency Response 
1.8.2. High Frequency Response 
1.8.3. Low Frequency Repsonse 
1.8.4. Examples: 

1.9. Feedback 

1.9.1. General Structure of Feedback 
1.9.2. Properties and Methodology for the Analysis of Feedback 
1.9.3. Stability: Bode Method 
1.9.4. Compensation in Frequency 

1.10. Sustainable Microelectronics and Future Trends 

1.10.1. Sustainable Energy Sources 
1.10.2. Bio-Compatible Sensors 
1.10.3. Future Trends in Microelectronics

Module 2. Digital Processing 

2.1. Discrete Systems  

2.1.1. Discrete Signals  
2.1.2. Stability of Discrete Systems  
2.1.3. Frequency Response  
2.1.4. Fourier Transform  
2.1.5. Z Transform  
2.1.6. Signal Sample  

2.2. Convolution and Correlation 

2.2.1. Signal Correlation  
2.2.2. Signal Convolution  
2.2.3. Examples of Application  

2.3. Digital Filters  

2.3.1. Classes of Digital Filters  
2.3.2. Hardware Used for Digital Filters  
2.3.3. Frequential Analysis  
2.3.4. Effects of the Filtering on the Signals  

2.4. Finite Impulse Response (FIR) Filters  

2.4.1. Non-Infinite Impulse Response  
2.4.2. Linearity  
2.4.3. Determination of Poles and Zeros  
2.4.4. Design of FIR Filters  

2.5. Infinite Impulse Response (IIR) Filters  

2.5.1. Recursive Filters  
2.5.2. Infinite Impulse Response  
2.5.3. Determination of Poles and Zeros  
2.5.4. Design of IIR Filters  

2.6. Signal Modulation  

2.6.1. Amplitude Modulation  
2.6.2. Frequency Modulation  
2.6.3. Phase Modulation  
2.6.4. Demodulators  
2.6.5. Simulators  

2.7. Digital Processing of Images  

2.7.1. Color Theory  
2.7.2. Sampling and Quantification  
2.7.3. Digital Processing with OpenCV  

2.8. Advanced Techniques in Digital Processing of Images  

2.8.1. Image Recognition  
2.8.2. Evolutionary Algorithms for Images  
2.8.3. Image Databases  
2.8.4. Machine Learning Applied to Writing  

2.9. Digital Processing of Voice  

2.9.1. Digital Model of the Voice  
2.9.2. Representation of the Voice Signal   
2.9.3. Voice Codification  

2.10. Advanced Processing of Voice  

2.10.1. Voice Recognition  
2.10.2. Voice Signal Processing for Diction  
2.10.3. Digital Speech Therapy Diagnosis

Module 3. Biomedical Electronics 

3.1. Biomedical Electronics 

3.1.1. Biomedical Electronics   
3.1.2. Characteristics of Biomedical Electronics  
3.1.3. Biomedical Instruments Systems 
3.1.4. Structure of a Biomedical Instrument System  

3.2. Bioelectrical Signals   

3.2.1. Origin of Biomedical Signals 
3.2.2. Conduction 
3.2.3. Potentials 
3.2.4. Propagation of Potentials 

3.3. Treatment of Bioelectrical Signals    

3.3.1. Collecting Bioelectrical Signals 
3.3.2. Amplification Techniques 
3.3.3. Security and Isolating 

3.4. Filtering Bioelectrical Signals 

3.4.1. Noise 
3.4.2. Noise Detection 
3.4.3. Noise Filtering 

3.5. Electrocardiogram 

3.5.1. The Cardiovascular System 

3.5.1.1. Action Potentials 

3.5.2. ECG Waveform Nomenclature 
3.5.3. Cardiac Electrical Activity  
3.5.4. Electrocardiography Module Instrumentation  

3.6. Electroencephalogram 

3.6.1. Neurological System 
3.6.2. Brain Electrical Activity 

3.6.2.1. Cerebal Waves 

3.6.3. Electroencephalography Module Instruments 

3.7. Electromyogram 

3.7.1. The Muscular System 
3.7.2. Muscular Electrical Activity 
3.7.3. Electromyography Module Instrumentation 

3.8. Spirometry 

3.8.1. Respiratory System 
3.8.2. Spirometric Parameters 

3.8.2.1. Interpretation of the Spirometric Test 

3.8.3. Spirometry Module Instrumentation 

3.9. Oximetry   

3.9.1. Circulatory System 
3.9.2. Operation Principle
3.9.3. Accuracy of Measurements 
3.9.4. Oximetry Module Instrumentation 

3.10. Safety and Electric Regulations 

3.10.1. Effects of Electrical Currents in Living Beings 
3.10.2. Electrical Accidents 
3.10.3. Electromedical Equipment Electrical Safety  
3.10.4. Classification of the Electromedical Equipment

A first class program with which to expand your knowledge and training in Biomedical Electronics”