Become an expert in professional master’s degree and be able to solve those problems in the field of Engineering that enable the development of successful industrial processes” 

 Electronics are 

Electronics are part of daily life for societies, since they are present in basic aspects, such as turning on a television or putting on a washing machine, but also in morerelevant issues such as the creation of medical devices that favor the rise in life expectancy. For this reason, there are many computer scientists who decide to specialize in this field, contributing all their knowledge to continue advancing in a field that is totally relevant to society. 

In this sense, the professional master’s degree in Electronic Systems Engineering at TECH addresses all those issues that are fundamental in everyday life, both personally and professionally. In this way, the program develops specialized knowledge in the design of Electronic Systems Engineering and in the world of microelectronics, with special emphasis on instrumentation and sensors that make it possible to control, for example, the presence of a person in a room. 

In addition, it addresses power electronic converters, digital processing and biomedical electronics, which contribute to a better quality of life and longer life expectancy; while in the area of sustainability, it focuses on energy efficiency, network architectures, the integration of renewable energy sources and the systems required for energy storage. Lastly, it aims to specialize students in industrial communications and industrial marketing. 

A 100% online professional master’s degree that will allow students to distribute their study time, not being conditioned by fixed schedules or 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.  

Learn how to apply Electronic Systems in the field of energy efficiency and sustainability, and minimize environmental impacts” 

This professional master’s degree in Electronic Systems Engineering contains the most complete and up-to-date program on the market. The most important features include:

• Practical cases presented by experts in IT 
• 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
• Special emphasis on innovative methodologies in Electronic Systems Engineering 
• 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

The multitude of case studies offered by TECH in this professional master’s degree will be very useful for effective learning in this field”

The teaching staff includes professionals from the IT sector, who contribute their experience to this 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.  

Knowing the features of Electronic Systems Engineering will be a key element for your professional growth"

By enrolling in this professional master’s degree, you will have unlimited access to all the theoretical and practical resources"

The professional master’s degree in Electronic Systems Engineering at TECH has been designed to offer students the most complete education in this field, which will allow them to develop the necessary skills to design and analyze Electronic Systems that are part of citizens’ daily life. A first-class program that will be essential for computer scientists to enter a labor market that demands professionals with extensive experience and higher qualifications.  

The completion of this program will give you the keys to work effectively in the design of Electronic Systems” 

General Objectives

• Analyze current techniques to implement sensor networks  
• Determine real-time requirements for embedded systems  
• Evaluate microprocessor processing times 
• Propose solutions adapted to the specific requirements of IoT 
• Determine the stages of an electronic system 
• Analyze the schematics of an electronic system 
• Develop the schematics of an electronic system by virtually simulating its behavior 
• Examine the behavior of an electronic system 
• Design the implementation support of an electronic system 
• Implement a prototype electronic system 
• Test and validate the prototype 
• Propose the prototype for commercialization 
• Compile the main materials involved in microelectronics, properties and applications 
• Identify the operation of the fundamental structures of microelectronic devices 
• Understand the mathematical principles that govern microelectronics 
• Analyze signals and modify them 
• Analyze technical documentation by examining the characteristics of different types of projects in order to determine the data necessary for their development 
• Identify standardized symbology and plotting techniques in order to analyze drawings and diagrams of automatic systems and installations 
• Identify breakdowns and malfunctions in order to supervise and/or maintain installations and associated equipment 
• Determine quality parameters in the work carried out in order to develop the culture of evaluation and quality, and to be able to assess the quality management procedures 
• Determine the need for power electronic converters in most real-world applications 
• Analyze the different types of converters that can be found, based on their function 
• Design and implement power electronic converters according to the need of use 
• Analyze and simulate the behavior of the most commonly used electronic converters in electronic circuits 
• Examine the current techniques in digital processing 
• Implement solutions for the processing of digital signals (images and audio) 
• Simulating digital signals and devices capable of processing them 
• Program elements for signal processing 
• Design filters for digital processing 
• Operate with mathematical tools for digital processing 
• Value the different options for signal processing 
• Identify and evaluate bioelectrical signals involved in a biomedical application 
• Determine a design protocol of a biomedical application 
• Analyze and evaluate biomedical instruments designs 
• Identify and define the interferences and noise of a biomedical application 
• Evaluate and apply electrical safety regulations 
• Determine the advantages of Smart grids deployment 
• Analyze each one of the technologies on which Smart grids are based 
• Examine the standards and safety mechanisms valid for the Smart grids 
• Determine the characteristics of real type systems and recognize the complexity of programming these types of systems 
• Analyze the different types of communication networks available 
• Assess which type of communications network is the most suitable in certain scenarios 
• Determine the keys to effective marketing in the industrial marketplace 
• Develop commercial management to create profitable and long-lasting relationships with customers 
• Generate specialized knowledge to compete in a globalized and increasingly complex environment 

Specific Objectives

Module 1. Embedded Systems   

• Analyze current embedded system platforms focused on signal analysis and IoT management 
• Analyze the diversity of simulators for configuring distributed embedded systems 
• Generate wireless sensor networks 
• Verify and assess risks of violation of sensor networks 
• Process and analyze data using distributed systems platforms 
• Programming microprocessors 
• Identify and correct errors in a real or simulated system 

Module 2. Electronic Systems Design 

• Identify possible problems in the distribution of circuit elements 
• Establish the necessary stages for an electronic circuit 
• Evaluate the electronic components to be used in the design 
• Simulate the behavior of the electronic components as a whole 
• Show the correct operation of an electronic system 
• Transfer the design to a Printed Circuit Board (PCB) 
• Implement the electronic system by compiling those modules that require it 
• Identify potential weak points in the design 

Module 3. Microelectronics

• Generate specialized knowledge on microelectronics 
• Examine analog and digital circuits 
• Determine the fundamental characteristics and uses of a diode 
• Determine how an amplifier works 
• Develop proficiency in the design of transistors and amplifiers according to the desired use 
• Demonstrate the mathematics behind the most common components in electronics 
• Analyze signals from their frequency response 
• Evaluating the stability of a control 
• Identify the main lines of technology development 

Module 4. Instruments and Sensors  

• Determine measuring and control devices according to their functionality 
• Evaluate the different technical characteristics of measurement and control systems 
• Develop and propose measurement and regulation systems 
• Specify the variables that intervene in a process 
• Justify the type of sensor involved in a process according to the physical or chemical parameter to be measured 
• Establish appropriate control system performance requirements in accordance with system requirements 
• Analyze the operation of typical measurement and control systems in industries 

Module 5. Power Electronic Converters  

• Analyze the converter function, classification and characteristic parameters 
• Identify real applications that justify the use of power electronic converters 
• Approach the analysis and study of the main converter circuits: rectifiers, inverters, switched-mode converters, voltage regulators and cycloconverters 
• Analyze the different figures of merit as a measure of quality in a converter system 
• Determine the different control strategies and the improvements provided by each of them 
• Examine the basic structure and components of each of the converter circuits 
• Develop performance requirements for generating specialized knowledge in order to be able to select the appropriate electronic circuit according to the system requirements 
• Propose solutions to the design of power converters 

Module 6. Digital Processing 

• Convert an analog signal into a digital one 
• Differentiate between the types of digital systems and their properties 
• Analyze the frequency behavior of a digital system 
• Process, code and de-code images 
• Simulate digital processors for voice recognition 

Module 7. Biomedical Electronics 

• Analyze the signals, direct or indirect, that can be measured with non-implantable devices 
• Apply the acquired knowledge of sensors and transduction in biomedical applications 
• Determine the use of electrodes in bioelectrical signal measurements 
• Develop the use of signal amplification, separation and filtering systems 
• Examine the different physiological systems of the human body and signals for behavioral analysis 
• Carry out a practical application of the knowledge of physiological systems in the measurement instrumentation of the most important systems: ECG, EEG, EMG, spirometry, and oximetry 
• Establish the necessary electrical safety of biomedical instruments 

Module 8. Energy Efficiency. Smart Grid 

• Develop specialized knowledge on energy efficiency and smart grids 
• Establish the need for the deployment of Smart grids 
• Analyze the functioning of a Smart Meter and its requirement in Smart grids 
• Determine the importance of power electronics in different network architectures 
• Assess the advantages and disadvantages of integrating renewable sources and energy storage systems 
• Study automation and control tools required in smart grids 
• Evaluate the security mechanisms that allow Smart grids to become reliable grids 

Module 9. Industrial Communications  

• Establish the basis of real-time systems and their main characteristics in relation to industrial communications 
• Examine the need for distributed systems and their programming 
• Determine the specific characteristics of industrial communications networks 
• Analyze the different solutions for the implementation of a communications network in an industrial environment 
• Gain in-depth knowledge of the OSI communications model and the TCP protocol 
• Develop the different mechanisms to convert this type of networks into reliable networks 
• Address the basic protocols on which the different mechanisms of information transmission in industrial communication networks are based 

Module 10. Industrial Marketing 

• Determine the particularities of marketing in the industrial sector 
• Analyze what a marketing plan is, the importance of planning, setting objectives and developing strategies 
• Examine the different techniques to obtain information and learn from the market in the industrial environment 
• Manage positioning and segmentation strategies. 
• Assess the value of services and customer loyalty 
• Establish the differences between transactional marketing and relationship marketing in industrial markets 
• Value the power of the brand as a strategic asset in a globalized market 
• Apply industrial communication tools 
• Determine the different distribution channels of industrial companies in order to design an optimal distribution strategy 
• Address the importance of the sales force in industrial markets 

A state-of-the-art program for professionals who want to achieve professional excellence”