master thesis telecommunication engineering

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To support long-distance communication , telecommunication technology was designed and practically applied through electromagnetic waves / electric signals . At the beginning of telecommunication technologies, it utilizes signal flags, smoke signals, visual signals, semaphore telegraphs, etc. In particular, it utilizes microwaves, radio waves, the internet, telephone medium, a communication satellite, fiber optics, etc. for electromagnetic and electrical telecommunication technologies .

This page is exactly intended to give you up-to-the-minute telecommunication thesis topics along with interesting research areas!!!

Important Components of Telecommunication

In general, the fundamental telecommunication model is made up of the following three significant components . In addition to these components, other entities may include improving the efficiency of the system which majorly depends on project needs.

Transmitter – It collects the data and transforms it into analog / digital signals based on the requirement
Transmission medium – It transmits the data/signal to the physical channel or wireless channel
Receiver – It is the reversible process of the transmitter. It collects the signal from the transmission medium and transforms it back to the original data

If the telecommunication system uses a single dedicated channel among transmitter and receiver for data transmission then it is called point-to-point communication . Similarly, if the telecommunication system establishes communication channels among one transmitter and more low-powered receivers for radio communication, then it is called broadcast communication .

Further, if the telecommunications system uses a physical channel for more number transmitters and receivers for data sharing then it is called a multiplex system . Here, the multiplex signals are moved at nodes for the appropriate receiver (destination). Moreover, it has the main advantage of high-cost reduction for deployment . Below, we have given you the primary layers incorporated in telecommunication systems.

Layers for Telecommunication

For instance: User premises equipment, transmit devices, switches, etc.
For instance: Circuit-switched network
For instance: 0800 services, voice, fax, etc.

To the continuation of layers, now we can see the primary techniques involved in developing telecommunication models . These techniques are globally popular in telecommunication systems. Further, we also support you to develop your techniques (algorithm / pseudo-code for telecommunication thesis topics) to untie the complex knots in code development .

Major Techniques for Telecommunication

Phase Shift Keying
Frequency Shift Keying
Amplitude Shift Keying
Frequency Modulation
Phase Modulation
Amplitude Modulation

In recent days, the revolution of the telecom industry is incredible ranges from plain voice messaging to sophisticated multimedia service regardless of complexity. Nowadays, nearly 5+ billion people are using smartphones. In order to meet the expectation of high storage, high bandwidth, low cost of processing powe r, etc. it enforces to create advanced technologies. Below, we have given you some latest research trends in telecommunication .

Research Trends in Telecommunication

Telco Mobility (For instance: smart apps, smart phones, etc.)
Convergence (For instance: Triple Play, VoIP, Quad Play, etc.)
Terminal-User Mobility (For instance: location-based services)
Social Networking (For instance: social media websites, etc.)
Free Space Optics and Signals (For instance: fading channels)
5G enabled Cloud Services (For instances: KaaS, PaaS, SaaS, IaaS, etc.)
Machine-to-Machine communications (For instance: manufacturing, vehicular sectors, smart logistics, healthcare, etc.)
Trustable Drone Communication (For instance: disaster monitoring, goods delivery, etc.)
Enterprise Mobility (For instance: smart logistics, field based sales enforcement, etc.)
Li-Fi and Wi-Fi
Terahertz (THz) Communication
5G beyond and 6G
Intelligent Small Antennas Design
Optical and Cognitive Radio Communication
Millimeter Wave (mmWave) technology
Enhanced Signal Detection and Modulation schemes

How to Choose Telecommunication Thesis Topics?

So far, we have discussed the telecommunication basics, components, layers, techniques, and recent trends . Now, we can see how effectively we can select the thesis topics. Generally, master’s programs are next-level undergraduate programs. The main of the master’s program is to make your expertise and gain more skills in your interested area like telecommunication. Consequently, it teaches you more than your undergraduate subject knowledge.

In undergraduate project work, you can gain knowledge on basics and provide you different range of job opportunities. In master’s program, it makes you specialize in a particular field of study. So, it increases the job opportunities in your interested field. Also, it makes you create your own contribution to social development in the form of research . As are a result, it will create the add-on status of your professional profile.

Similar to thesis selection, thesis submission is also very important in master’s programs. Since it helps to present your efforts and time on achieving a master’s degree. The telecommunication thesis topics you are choosing for your project will have significant importance in creating the best impression of your thesis in front of your job interviewer. Therefore, keep the following points in mind while selecting a good thesis topic on telecommunication for your master’s program .

Select a topic that is easy to complete fast

The master thesis is the test for your competency in your interested subject area
So, make sure that your handpicked topic is handpicked from your interested area
Also, validate the selected topic for freshness and uniqueness
Check the future scope of the topic for further study

Confirm the concept for topic

Analyze the recent issues and challenges in your interested area
Perform a detailed survey on the previous study related to the topic
Narrow down the topic after an in-depth examination
Finalize the concept for your topic (i.e., what you trying to focus on in research)

Develop the project with passion

Select appropriate research solution and development tool
Fill with excitement to practically implement handpicked topic
Analyze the experimental results through different parameters
Prepare the master thesis in a structured format

Hope now you are familiar with thesis topic selection till the thesis submission. Our resource team will help you in all these phases to complete your research on time. We have individual teams for research, development, and thesis . So, it will be more useful for you to avail yourself of the research services in one place like us to formulate telecommunication topics . Further, we have also included a few 5G enabling technologies for the best telecommunication thesis topics for your benefit.

Massive MIMO
Big Data Analytics
Mobile Cloud Computing
Green IoT-Communications
Network Ultra-Densification
Millimetre Wave (mmWave)
Scalable Internet Of Things (IoT)
Network Function Virtualization (NFV)
New Radio (NR) Access Techniques
Wireless Software-Defined Network (SDN)
Device-To-Device Communication with High Mobility

Research Telecommunication Projects

Due to the vast scientific advancements, wireless communication has become more popular among individual and business sectors. In specific, Cognitive Radio , UWB and 5G NS3 have gained more attention among the research community. Additionally, it also includes some technical challenges to developing or deploying real-world applications . And, some of the research-oriented problems are highlighted as follows,

Modeling of ZIF receivers at the high spectrum
Multiple Radio Frequency bands Co-existence
External of internal interference in communication
Inaccessibility of network components or data
Modeling of radio transmitter and receivers in extensive bands

Our research team has collected numerous research ideas for solving the above-specified issues . Further, we also like to share other forward-thinking technologies that currently we are working for our handhold research scholars. Beyond the below list of technologies, we have also gathered other innovative communication research ideas and telecommunication thesis topics . These ideas surely present you with the new dimension of telecommunication.

What are the interesting topics in Telecommunication?

Enhanced Multiuser MIMO (M-MIMO) Communication Techniques
Adaptive Wireless Networking and Channel Coding
Efficient Spectrum Sharing in Cognitive Radio Networks (CRN)
Designing Energy-Aware Internet Routers for Efficient Transmission
Improved Network Modeling for Controlling Environmental Pollution
Remote Patient Health Monitoring in Wireless Body-Area Networks
Wireless Heterogeneous Communication in 5G-IoT Networks
Design of Aerial base station and Mission-aware path in UAV Systems
Accurate Visible light Positioning System
Employment of Machine Learning Algorithms in VLC-based Applications

Performance Metrics in Telecommunication

Now, we can see the evaluation of developed models for analyzing network performance and the quality of services . On the one hand, network performance is measured through different standardized networking/simulation parameters . For instance: broadcast latency, jitter (delay variation), bit error rate, computing time, etc. On the other hand, quality of service is nothing but excellence of service that user receives at destination point and also it checks whether the received quality is same with original produced quality.

What is QoS in telecommunication?

As mentioned earlier, QOS plays a major role in measuring the whole service performance which the network users specifically receive. For instance: cloud-oriented services, network services, telephony, etc.

At present, several technologies are widely along with telecommunications such as deep learning, artificial intelligence, machine learning, 6G networks, full-duplex communication, spectrum utilization, free-space optical communication , etc. All these technologies are essential to meet the required QoS. And, some of the performance metrics that have high possibilities to influence the QoS are given as follows,

Network lifespan
Bit Error Rate
Energy Utilization
Energy-spectral efficiency
Fault Tolerance

On the whole, we provide you best research, code development, and thesis writing services for any sort of telecommunication thesis topics . Further, if you are interested to know more exciting research perspectives of telecommunication, we are ready to support you in all means of the latest research advancements.

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Telecommunications engineering (ms), telecommunications engineering , ms.

The master’s degree under Option A requires a thesis. Option A is most appropriate for students who are preparing for careers in research and scholarly work or additional academic pursuits beyond the master’s degree. Under this option, a student must earn a minimum of 30 credit hours, consisting of 20 to 24 credit hours of regular course work, plus a thesis equivalent to 6 to 10 credit hours. At least one-half of the credit hours required for the degree, including thesis, must be in the major (at least 18 credit hours for the Master of Education degree). The remaining work may be in supporting courses and may comprise a minor consisting of at least 9 credit hours selected from and approved by the minor department. At least 8 credit hours, excluding thesis, must be earned in courses open exclusively to graduate students (900 level or 800 level without 400 or lower counterparts).

Option A is not available for the Master of Professional Accountancy degree.

Thesis Requirements . The subject of the thesis shall be chosen from the student’s field of major interest and must be approved by the departmental Graduate Committee. The thesis should reveal a capacity to carry on independent study or research and should demonstrate the student’s ability to use the techniques employed in their field of investigation. Research activities involving human subjects or live vertebrate animals may not be conducted at the University of Nebraska-Lincoln unless the research activities have been reviewed and approved by the appropriate board or committee. The Institutional Review Board (IRB) reviews projects involving human subject research and the Institutional Animal Care and Use Committee (IACUC) reviews the use of animals in research. These reviews are in accordance with Federal regulations, state laws and institutional policies. Submission of protocols to conduct human subject or animal research is coordinated by the Research Responsibility offices. Approval must be secured prior to the initiation of the research.

The thesis must conform to the required style and format described in Steps to Degree Completion . A copy of the thesis and abstract must be approved by the student’s major advisor and submitted for preliminary review to the Master’s Programs Coordinator in the Office of Graduate Studies at least two weeks (one week in the summer sessions) before the date of the candidate’s final oral examination. A candidate is not eligible for the oral examination until the thesis is completed and approved. After passing the final oral examination, the thesis must be electronically submitted to the Master’s Programs Coordinator for a final review prior to being uploaded to Digital Commons.

More master's information

The master’s degree under Option B does not require a thesis. Option B is most appropriate for students pursuing practice-based or professional careers in which the master’s degree provides suitable training. Under Option B, a student must earn a minimum of 30 credit hours. At least one-half of the credit hours required for the degree must be in the major. The remaining work may be in supporting courses and may comprise a minor consisting of at least 9 credit hours selected from and approved by the minor department. At least 15 credit hours must be earned in courses open exclusively to graduate students (900 level or 800 level without 400 or lower counterparts).

The Master of Professional Accountancy plan of study may not include a minor.

The Master of Education plan of study may not include a minor, but must include at least 6 credit hours of education courses outside the major.

Accelerated Master's Programs allow University of Nebraska–Lincoln undergraduate students to pursue this degree in an abbreviated timeline.

More Accelerated Master's information

Dual Degree programs allow students to be admitted to two degree programs simultaneously with approval of each Graduate Program Committee and the Dean(s) for Graduate Studies.

More Dual Degree information

The College of Engineering offers a Master of Science in telecommunications engineering.

Description

This graduate program provides advanced education and research to develop a breadth of knowledge and depth of expertise in the engineering of telecommunication networks and systems.

This University of Nebraska-Lincoln program is housed in Omaha, Nebraska at the Peter Kiewit Institute of Information Science, Technology, and Engineering (PKI) which is approximately 50 minutes from the Lincoln campus. Students, however, may take some of the courses through the electrical engineering and computer science departments on the Lincoln campus.

The partnership with PKI provides graduate students with unique opportunities for both academic and career exploration. Specialized state-of-the-art laboratories and computer facilities are available including optical, wireless, and telecommunications laboratories; IBM supercomputer facilities; and high-speed connections to Internet2 and AccessGrid.

For admission to this program, a student must have a bachelor of science in computer engineering, electrical engineering, electronics engineering, or a closely related field. Applicants with undergraduate degrees in other areas may be admitted to the master's degree program with the requirement of additional course work to eliminate the deficiencies.

Applying for Admission

Standard requirements for all graduate programs.

Application for Admission with $50 non-refundable application fee .

If International: Uploads must include all college- or university-level transcripts or mark sheets (records of courses and marks earned), with certiﬁcates, diplomas, and degrees plus certiﬁed English translations.

After admission: Official documents are required from all students who are admitted and enroll. Photocopies of certiﬁed records are not acceptable. International students enrolled in other U.S. institutions may have certiﬁed copies of all foreign records sent directly to the Office of Graduate Studies by their current school’s registrar office.

When sending TOEFL scores, our institution code is 6877 and a department code is not needed.

If applicant is not a US citizen and expects an F or J visa: financial information .
Applicants must also fulfill any additional requirements the department specifies at the time of application.

Program-Specific Admission Requirements

Additional requirements specific to this program.

GRE (optional)
Minimum English proficiency: Paper TOEFL 550, Internet TOEFL 79, IELTS 6.5
Three letters of recommendation
Personal Statement: In 1-2 pages, this statement should describe why you chose this program, your research interests and/or previous research, your qualifications, and your career goals. If you've identified a faculty member with whom you would like to work, name them, describe how your interests align with their work, and indicate whether you've been in contact with them.

Admission Application Deadlines

For full financial consideration, students must apply by January 15 for Fall and September 15 for Spring.

Telecommunications Engineering

Campus Address

Peter Kiewit Institute 1110 S 67th St Omaha NE 68182-0572

Graduate Chair

Hamid Sharif-Kashani

Support Staff

Teresa Ryans

The University of Nebraska does not discriminate based on race, color, ethnicity, national origin, sex, pregnancy, sexual orientation, gender identity, religion, disability, age, genetic information, veteran status, marital status, and/or political affiliation in its programs, activities, or employment.

UNL Graduate Chairs and staff please complete the program update form to provide edits. Updates to graduate program pages are made on an annual basis in conjunction with the Graduate Application for Admission.

College of Engineering

Wireless and network engineering.

The Master of Science in Wireless and Network Engineering is a uniquely integrated program bridging studies in both electrical engineering and computer engineering to prepare students for specialized careers in the rapidly evolving communication networked systems workplace. Offered by the Institute for the Wireless Internet of Things and the Department of Electrical and Computer Engineering, the program aims to prepare highly qualified researchers and a specialized workforce that will lead the future of our hyperconnected society.

Offered by the Institute for the Wireless Internet of Things and the Department of Electrical and Computer Engineering, the MS in Wireless and Network Engineering program equips students to become qualified researchers and specialized professionals in our hyperconnected world. Students will learn to understand, design, implement, and test current and future wireless and wired communication networks. Merging studies from technical fields traditionally pursued separately, this program integrates concepts from both electrical engineering (communications, signal processing, and control) and computer engineering (computer networking, security, and policy). Students will gain a multifaceted skill set in the field through a combination of coursework, master’s thesis research, and/or industry experience. The program also covers policy and ethics concepts relating to communication networks. Extensive co-op and research opportunities are offered through Northeastern’s Institute for the Wireless Internet of Things, as well as major companies in the wireless, defense, computing, and manufacturing fields.

Unique Features

Through an innovative curriculum combining concepts from electrical and computer engineering, students are prepared to cover the protocol stack in its entirety, from communications and signal processing to networking and applications.
Students will find extensive experiential opportunities offered through industry and government collaborations facilitated by the Institute for the Wireless Internet of Things at Northeastern .
Advanced on-campus facilities and their unique provisions, including being among one of the nation’s only FCC-designated Spectrum Innovation Zones, afford access to cutting-edge technologies in the field of communication networks.

Program Objectives

Prepare a highly qualified workforce for careers in the fast-changing, high-growth communication networks field.
Equip students with a comprehensive skill set through integrated computer engineering and electrical engineering studies.
Provide hands-on experiences through industry and government collaborations, as well as Northeastern’s own advanced technology facilities.

Career Outlook

Program experience , testimonials, stefano basagni, professor of electrical and computer engineering, looking for something different.

A graduate degree or certificate from Northeastern—a top-ranked university—can accelerate your career through rigorous academic coursework and hands-on professional experience in the area of your interest. Apply now—and take your career to the next level.

Program Costs

Finance Your Education We offer a variety of resources, including scholarships and assistantships.

How to Apply Learn more about the application process and requirements.

Requirements

Complete online application form
Application fee
Two letters of recommendation
Transcripts from all institutions attended
GRE is not required for terms starting during the 2021-2022, 2022-2023, or 2023-2024 academic years
Statement of purpose
TOEFL, IELTS, or Duolingo for international applicants

The program is suited to students with a background in electrical and/or computer engineering, computer science, or related disciplines. Strong candidates in other STEM disciplines, including both engineering and sciences (e.g., physics, math), with prior exposure to calculus, linear algebra, probability theory and programming, will also be considered.

View the Northeastern University College of Engineering admissions page for details.

Are You an International Student? Find out what additional documents are required to apply.

Admissions Details Learn more about the College of Engineering admissions process, policies, and required materials.

Admissions Dates

Applications received after the stated deadline dates will be accepted and processed as quickly as possible; however it may not be possible to have a decision rendered in time for the applicant to begin taking classes for the desired term if admitted.

Applications submitted by the referenced dates will receive full consideration for the referenced term. Applications received after the referenced dates will be considered on a case-by-case basis.

Industry-aligned courses for in-demand careers.

For 100+ years, we’ve designed our programs with one thing in mind—your success. Explore the current program requirements and course descriptions, all designed to meet today’s industry needs and must-have skills.

View curriculum

Northeastern combines rigorous academics with experiential learning and research to prepare students for real-world engineering challenges. The cooperative education program, also known as co-op, is one of the largest and most innovative in the world, and Northeastern is one of only a few that offers a co-op program for graduate students. Through this program, students gain up to eight months of professional experience employed in their field of interest as part of the academic curriculum, giving them a competitive edge upon graduation. The College of Engineering has over 2,000 co-op employer partners globally. Our dedicated team of co-op coordinators prepare students for the co-op experience through resume building, developing interview skills, and guiding professional development.

Our Faculty

Northeastern University faculty represents a broad cross-section of professional practices and fields, including finance, education, biomedical science, management, and the U.S. military. They serve as mentors and advisors and collaborate alongside you to solve the most pressing global challenges facing established and emerging markets.

Tommaso Melodia

Stefano Basagni

Josep M Jornet

By enrolling in Northeastern, you’ll gain access to students at 13 campus locations, 300,000+ alumni, and 3,000 employer partners worldwide. Our global university system provides students unique opportunities to think locally and act globally while serving as a platform for scaling ideas, talent, and solutions.

master thesis telecommunication engineering

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Master of Science in Telecommunications and Networking

Requirements

Thesis Option

Minimum admissions requirements.

A bachelor’s degree in a related field as judged by the School’s Graduate Committee. The undergraduate degree must have been earned at a regionally accredited university.
‘B’ average or better in all coursework attempted while registered as an upper-division student in the bachelor’s program (3.0 on a 4.0 scale).
For applicants whose native language is not English, English proficiency exam scores of at least 550 (paper-based) or 80 (internet-based) on the TOEFL, 6.5 on the IELTS or 110 on the Duolingo. English proficiency exam exemptions are based on the country in which the applicant completed their undergraduate degree, not on nationality or language of instruction. See the list of exempt countries here: http://gradschool.fiu.edu/toefl-exempt-countries/ .

Required Documents

Online graduate application /application fee.
Josef Silny & Associates 7101 SW 102 Avenue Miami, FL 33171 (t) 305.273.1616 www.silny.com | [email protected]
World Education Services PO Box 745 New York, NY 10113-0745 (t) 212.966.6311 www.wes.org | [email protected]
Educational Credential Evaluators, Inc. PO Box 514070 Milwaukee, WI 53203-3470 (t) 414.289.3400 www.ece.org
The ETS school code for the TOEFL exam is 5206.
IELTS can be verified directly by admissions. Plesae be sure to upload or email a copy of your official IELTS score card.
If admitted, All foreign educated students are required to provide proof of Degree / Diploma. This can be submitted upon arrival at FIU.

Supporting Documents (Recommended)

Statement of purpose
Three letters of recommendation

Immigration Documents

These forms are required for international students only. See https://admissions.fiu.edu/international/submit-documents/#what for more info.

Bank and Sponsor Letter
Declaration and Certification of Finances
F-1 Transfer Form (if currently residing in the U.S. on an F-1 visa)

Step One: Apply Online

All applications and associated fees, with the exception of those for the combined BS/MS program, are submitted online at http://gradschool.fiu.edu/apply/ .

Through the website, applicants will have the opportunity to upload supporting documents, such as a statement of purpose, resume, residency documents for tuition purposes, immigration documents, and the like. They can also provide contact information for recommenders who are then prompted to submit the letters of recommendation through the online portal.

Once submitted, Graduate Admissions will promptly acknowledge receipt of the application via email and will provide a Panther ID as well as further instructions on how to access the MyFIU portal. On MyFIU, students can view the status of their application, including any missing documents. Missing documents are listed under the “To Do List” on the top right-hand corner of the screen.

Once the applicant has been issued a Panther ID, they should include the Panther ID in all communications to the unit representatives, Graduate Admissions, International Student and Scholar Services, and Student Health services.

Step Two: Submit Official Documents

Mailing address for regular U.S. mail:

Mailing address for couriers (typically used for delivering documents from outside the United States):

FIU requires official documents, even for the initial review of the applications. Required official documents include transcripts, course by course evaluation, translations, and test scores (if applicable).

Transcripts must be official. Foreign students must provide a course by course evaluation from a NACES approved agency.

Official test scores must be reported to the University by the testing agency. The University’s ETS code is 5206. IELTS scores may be verified directly by the admissions officer if the applicant provides FIU with a copy of the score report.

Please note that applications are not referred to the unit for review until required documents have been received and the application evaluation can be completed. Uploaded copies of any of these documents are considered unofficial and will not be used in evaluating the application.

Once admitted, international students will also be required to show an official proof of degree, typically a diploma, but can do so upon their arrival to FIU.

For any and all questions regarding admission required documents you must contact the office of international admissions directly at [email protected].

This program admits for the fall, spring, and summer terms.

All international applicants must abide the international applicant deadline. This includes international applicants residing in the United States and/or international applicants who do not require student visas.

Required Courses: 15 credits

TCN 5030 Computer Communications and Networking Technologies (or an alternate course if waived)
TCN 6430 Networks Management and Control Standards
TCN 6275 Mobile Computing
TCN 5080 Secure Telecommunications Transactions (or CIS 5372)
TCN 5640 Telecommunications Enterprise Planning and Strategy

Focus Area Courses or Thesis: 6 credits

Students must complete 6 credits in a single focus area of their choosing from the following options: Business, Communications, Software, Security, Wireless and Sensor Networks. Students enrolled in the Thesis Option will complete 6 thesis credits in lieu of fulfilling the track requirement.

Business Focus

TCN 5010 Telecommunications Technology Applications TCN 6880 Telecommunications Public Policy Development and Standards TCN 6820 Telecommunications Industry Development

Communications Focus

EEL 5500 Digital Communication Systems I EEL 5501 Digital Communication Systems II

Software Focus

TCN 5440 Software Development for Telecommunications Networks COP 5725 Principles of Database Management Systems TCN 5445 Telecommunication Network Programming

Security Focus

CIS 5373 Systems Security CIS 5374 Information Security and Privacy TCN 5455 Information Theory

Wireless and Sensor Network Focus

TCN 6270 Mobile and Wireless Networks TCN 6450 Wireless Information Systems TCN 5155 Wireless Communications with Multimedia Applications

Elective Courses: 9 credits

Elective courses may be selected from SCIS’s graduate course offerings with the exception of courses marked not applicable to SCIS degrees. A list can be found in Section 7.1 of the Graduate Program Booklet.

A maximum of 6 credits can be chosen from courses other than those listed in Section 7.1. Of these 6 credits, a maximum of 3 credits can be taken as either a 3-credit Independent Study or a 3-credit co-op course, but not both.

Students who are interested in relevant courses outside of SCIS that are not on the pre-approved list found in Section 7.2 or on the student’s degree audit should submit a request to the Graduate Program Advisor with the course details and a strong justification. The Graduate Program Director has final discretion over the inclusion of courses in a program of study.

This option requires the completion of a master’s thesis (6 credits) in addition to the 8 graduate courses (15 credits of required courses and 9 credits of elective courses). A student may commence work on the master’s thesis at any time; however, thesis credits taken prior to the approval of the M-2 form will not count toward the 6 credits of master’s thesis. (See http://gradschool.fiu.edu/students/#studentforms for the forms).

Thesis Committee

The Thesis Committee must consist of three members with Graduate Faculty Status, at least two of which hold appointments in SCIS. Typically, all three committee members hold appointments in SCIS. The Thesis Advisor is the Chairperson of the Thesis Committee.

Thesis Proposal

A thesis proposal should be submitted after the Thesis Committee has been approved. The proposal will be given by the Thesis Advisor to the student’s Thesis Committee for review. Based on the written recommendations of its members, the Thesis Committee will make a final decision. Upon acceptance of the proposal, the M-2 Form will be completed, to indicate that the proposal has been approved. Before the submission of the M-2 form, the Graduate School requires the M.S. candidate complete an on-line “Responsible Conduct of Research Certification” training course ( http://gradschool.fiu.edu/rcr/#toggle-id-3 ).

The purpose of the thesis proposal is to convince the Committee that the chosen thesis topic and the student’s approach have a reasonable chance of success. SCIS wants to minimize the chance that the thesis will be rejected when almost completed. In particular, the thesis proposal should:

explain the basic idea of the thesis topic
argue why that topic is important
state what kind of results are expected
make plausible that these results are sufficient for a master’s thesis and that they are obtainable within the given timeframe with available resources
demonstrate the student’s academic qualifications for doing the proposed work

Once the M-2 Form has been approved by the University Graduate School, the student is subject to Continuous Enrollment requirements and must enroll in at least one thesis credit every term (including Summer) until he or she graduates. Exceptions to this rule can only be made by the University Graduate School via the approval of a formal leave of absence. Thesis credits taken prior to the approval of the M-2 form will not count toward the minimum 6 credits of the master’s thesis.

Thesis Defense

The master’s thesis must be a written account of a critical and scholarly study in an area in computer science. The Thesis Committee will review it critically for both content and form. The thesis may consist of:

independent research work
a critical study and analysis of known results that provide new significance and insights
a significant and constructive contribution to computer applications such as software development for important applications.

Once the Thesis Committee has approved the student for a final defense, the student should submit the M-3 Form at least 3 weeks prior to the expected defense date. The student and the Thesis Advisor need to coordinate with the Program Specialist to schedule an oral presentation of the thesis in the form of a public lecture. The Thesis Committee makes the final pass or fail decision.

Up-to-date information on tuition and fees is available at http://finance.fiu.edu/controller/UG_Calculator.htm .

Currently, the cost per credit hour for a graduate-level course is $455.64 for Florida residents and $1001.69 for non-Florida residents. The estimated cost of a full-time spring or fall semester (9 credits) is $4,295.15 for Florida residents and $9,209.60 for non-Florida residents. The M.S. in Telecommunications and Networking consists of 30 credits. The estimated total cost for a full-time student is $14,446.76 for Florida residents and $30,828.26 for non-Florida residents. These estimates do not include online course fees. Tuition and fees are paid on a semester basis.

T uition, fees, and the above estimates are subject to change. Estimated costs may not reflect costs paid.

For inquiries related to the M.S. in Telecommunications and Networking, including admissions and academic issues, please contact Rebeca Arocha, the Graduate Program Advisor. Email is preferred.

For information on the M.S. in Telecommunications and Networking, please email [email protected] .

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Browse dissertations / theses on a wide variety of disciplines and organise your bibliography correctly.

Leue, Stefan. "Methods and semantics for telecommunications systems engineering /." [S.l.] : [s.n.], 1994. http://www.ub.unibe.ch/content/bibliotheken_sammlungen/sondersammlungen/dissen_bestellformular/index_ger.html.

Gonçalves, Heidy Christina. "Exploring ESP in electronic engineering and telecommunications." Master's thesis, Universidade de Aveiro, 2009. http://hdl.handle.net/10773/8719.

Wagner, Michael D. Turner Nathan L. "Requirements analysis and course improvements for EO3502 telecommunications systems engineering /." Monterey, Calif. : Springfield, Va. : Naval Postgraduate School ; Available from National Technical Information Service, 2005. http://library.nps.navy.mil/uhtbin/hyperion/05Mar%5FWagner.pdf.

Turner, Nathan L., and Michael D. Wagner. "Requirements analysis and course improvements for EO3502 telecommunications systems engineering." Thesis, Monterey, California. Naval Postgraduate School, 2005. http://hdl.handle.net/10945/2260.

Ng, Trina Tsao-Tin. "Domain transformations for optical telecommunications signals." Thesis, University of Southampton, 2010. https://eprints.soton.ac.uk/301294/.

Correia, Rose Mary. "Legal aspects of multimodal telecommunications." Thesis, McGill University, 1995. http://digitool.Library.McGill.CA:80/R/?func=dbin-jump-full&object_id=23309.

Hoshino, Takashi. "Telecommunications development : policy recommendations for developing countries." Thesis, Massachusetts Institute of Technology, 1996. http://hdl.handle.net/1721.1/39058.

Faci, Mohammed. "Detecting feature interactions in telecommunications systems designs." Thesis, University of Ottawa (Canada), 1995. http://hdl.handle.net/10393/10165.

Knox, David. "Telecommunications call processing on a linear processor array." Thesis, University of Ottawa (Canada), 1996. http://hdl.handle.net/10393/9585.

Dalmia, Atul 1976. "A Web-based laboratory of travel and telecommunications behavior." Thesis, Massachusetts Institute of Technology, 2000. http://hdl.handle.net/1721.1/80976.

Bocci, Matthew. "Concurrent cell rate simulation of ATM telecommunications network." Thesis, Queen Mary, University of London, 1997. http://qmro.qmul.ac.uk/xmlui/handle/123456789/3806.

Zhang, Tong. "Improving the performance of a traffic data management system." Ohio : Ohio University, 1999. http://www.ohiolink.edu/etd/view.cgi?ohiou1175198741.

Bergman, Douglas Robert. "Three essays on economic issues in telecommunications." Diss., The University of Arizona, 2001. http://hdl.handle.net/10150/289730.

Gonnella, Pierpaolo. "Development of a V2X Platform for Predictive Driving Functions Validation." Master's thesis, Alma Mater Studiorum - Università di Bologna, 2020.

Osgoie, Mahtab Ghafari. "A survey of earthquake-induced damage to telecommunications towers (1999-2011)." Thesis, McGill University, 2012. http://digitool.Library.McGill.CA:80/R/?func=dbin-jump-full&object_id=112070.

Cuthbert, David S. (David Scott). "Innovative ordering and distribution of grocery products using advanced telecommunications." Thesis, Massachusetts Institute of Technology, 1994. http://hdl.handle.net/1721.1/12102.

Yeh, Emily. "Technologies and policies for an evolving telecommunications sector in China." Thesis, Massachusetts Institute of Technology, 1995. http://hdl.handle.net/1721.1/36081.

Xiao, Justin (Justin T. ). "Technoeconomic analysis of perovskite photovoltaic manufacturing for powering telecommunications Towers." Thesis, Massachusetts Institute of Technology, 2018. http://hdl.handle.net/1721.1/119698.

Koul, Ashish 1979. "Device-oriented telecommunications customer call center demand forecasting." Thesis, Massachusetts Institute of Technology, 2014. http://hdl.handle.net/1721.1/90787.

Charangwa, Mark. "Evaluating the effectiveness of Cooperative/Coordinated Multipoint (CoMP) LTE feature in uplink and downlink transmissions." Master's thesis, University of Cape Town, 2017. http://hdl.handle.net/11427/27468.

Malila, Bessie. "Architecture of a cognitive non-line-of-sight backhaul for 5G outdoor urban small cells." Doctoral thesis, University of Cape Town, 2017. http://hdl.handle.net/11427/27279.

Shih, Ta-Ming Ph D. Massachusetts Institute of Technology. "Indium phosphide based integrated photonic devices for telecommunications and sensing applications." Thesis, Massachusetts Institute of Technology, 2012. http://hdl.handle.net/1721.1/75449.

Hamdulay, Irfaan. "Investigating critical success factors for project completion in a South African telecommunications company." Master's thesis, University of Cape Town, 2018. http://hdl.handle.net/11427/29725.

Dahlberg, Anders. "Traffic Engineering in a Bluetooth Piconet." Thesis, Blekinge Tekniska Högskola, Institutionen för telekommunikation och signalbehandling, 2002. http://urn.kb.se/resolve?urn=urn:nbn:se:bth-5759.

Bobor-Oyibo, Freeborn. "Dynamic capacity enhancement using a smart antenna in mobile telecommunications networks." Thesis, Northumbria University, 2012. http://nrl.northumbria.ac.uk/5840/.

Chayanam, Kavitha. "Analysis of Telecommunications Outages Due to Power Loss." Ohio University / OhioLINK, 2005. http://www.ohiolink.edu/etd/view.cgi?ohiou1125024491.

Kutluay, Koray. "Fully Digital Parallel Operated Switch-mode Power Supply Modules For Telecommunications." Phd thesis, METU, 2005. http://etd.lib.metu.edu.tr/upload/12606640/index.pdf.

Nappier, Jennifer M. "An FPGA Abstraction Layer for the Space Telecommunications Radio System." Case Western Reserve University School of Graduate Studies / OhioLINK, 2009. http://rave.ohiolink.edu/etdc/view?acc_num=case1227033556.

Haimowitz, Bruce Raymond. "The Telecommunications Act of 1996 : business access, and implications for integrated carriers." Thesis, Massachusetts Institute of Technology, 1997. http://hdl.handle.net/1721.1/42607.

Mian, Azhar Ali, and Sardar Usman Khalid. "Multi-Protocol Label Switching Traffic Engineering with QoS." Thesis, Blekinge Tekniska Högskola, Sektionen för ingenjörsvetenskap, 2010. http://urn.kb.se/resolve?urn=urn:nbn:se:bth-4201.

Cameron, Grant Arthur 1960. "A model and algorithm for sizing and routing DCS switched telecommunications networks." Diss., The University of Arizona, 1998. http://hdl.handle.net/10150/282772.

Sheriff, Ray E. "The 2010 Electronics and Telecommunications Research Seminar Series: 9th Workshop Proceedings." University of Bradford, 2010. http://hdl.handle.net/10454/4355.

Ranatunga, Channa. "Introducing an effect of climate change into global models of rain fade on telecommunications links." Thesis, University of Hull, 2014. http://hydra.hull.ac.uk/resources/hull:11321.

Melcher, Douglas C. "State and local telecommunications networks : institutional and political factors influencing government deployment strategies." Thesis, Massachusetts Institute of Technology, 1996. http://hdl.handle.net/1721.1/39090.

Naeser, Gustaf. "A flexible framework for detection of feature interactions in telecommunication systems." Licentiate thesis, Uppsala universitet, Avdelningen för datorteknik, 2000. http://urn.kb.se/resolve?urn=urn:nbn:se:uu:diva-226515.

Gwandu, B. A. L. "Design and fabrication of advanced fibre gratings and their applications to sensing instrumentations and telecommunications." Thesis, Aston University, 2003. http://publications.aston.ac.uk/8004/.

Gallegos, Martínez Héctor Javier. "The privatization and liberalization of the Mexican telecommunications sector : new technology and policy alternatives." Thesis, Massachusetts Institute of Technology, 1996. http://hdl.handle.net/1721.1/38840.

Mutooni, Philip Kyalo. "Telecommunications @ crossroads : the transition from a voice-centric to a data-centric communication network." Thesis, Massachusetts Institute of Technology, 1997. http://hdl.handle.net/1721.1/43453.

Arvedal, David. "Analyzing network monitoring systems and objects for a telecommunications company." Thesis, Mälardalens högskola, Akademin för innovation, design och teknik, 2017. http://urn.kb.se/resolve?urn=urn:nbn:se:mdh:diva-35610.

Jarahnejad, Mariam, and Ali Zaidi. "Exploring the Potential of Renewable Energy in Telecommunications Industry." Thesis, KTH, Skolan för industriell teknik och management (ITM), 2018. http://urn.kb.se/resolve?urn=urn:nbn:se:kth:diva-231344.

Kawai, Shingo S. M. Massachusetts Institute of Technology. "Strategies to enhance long-term competitiveness in the telecommunications industry : lessons for NTT." Thesis, Massachusetts Institute of Technology, 2014. http://hdl.handle.net/1721.1/105296.

Nyström, Jan. "A formalisation of the ITU-T Intelligent Network standard." Licentiate thesis, Uppsala universitet, Avdelningen för datorteknik, 2000. http://urn.kb.se/resolve?urn=urn:nbn:se:uu:diva-226522.

Menafra, Valentina Francesca. "Advanced business models for beyond 5G and 6G network architectures." Master's thesis, Alma Mater Studiorum - Università di Bologna, 2021. http://amslaurea.unibo.it/23835/.

Cruz, Alemán Guillermo Alberto. "The drivers of foreign direct investment in telecommunications among developing countries : the role of government." Thesis, Massachusetts Institute of Technology, 2009. http://hdl.handle.net/1721.1/58168.

Robinson, Brian E. "A System Dynamics Approach to Planning Systems-of-Systems Modernization| A Wireless Telecommunications Interface Standard Case Study." Thesis, The George Washington University, 2018. http://pqdtopen.proquest.com/#viewpdf?dispub=10845319.

For decades, the United States (U.S.) Department of Defense (DoD) has developed, deployed, and operated hundreds of different types of systems as components of systems-of-systems. Achieving and maintaining joint systems-of-systems interoperability as new systems are added is a constant problem. The Army, Navy, U.S. Marine Corps, and Air Force each develop requirements, budgets, and acquire, field and operate systems that function as part of joint systems-of-systems. Technology and threats are rapidly evolving. These globally deployed systems and systems-of-systems employed by combatant commanders must be continuously modernized or risk becoming obsolete, resulting in potential mission failure and loss of life.

Using a wireless telecommunications interface standard case study, this research developed a unique method of planning systems-of-systems modernization using a system dynamics (SD) approach. This approach: a) accounts for key factors that influence the dynamic behavior of systems-of-systems modernization, impacting the ability to modernize systems-of-systems, and b) enables what-if analysis, and decision-making support of systems-of-systems modernization planning options. This research used a mixed-methods approach to demonstrate that the SD model is measurably superior to past practice. Quantitative statistical analysis was performed on 20 years’ (2001–2020) of data. A qualitative, scenario-based approach was used to develop an SD model. The results demonstrate that engineers, managers, and senior decision makers in the DoD can realize statistically significant gains by using an SD model to develop and explore systems-of-systems modernization planning options. This research’s original contribution to knowledge is the development and validation of an SD model for planning systems-of-systems modernization using a mixed-methods research approach.

Sheriff, Ray E. "The 2009 Electronics and Telecommunications Research Seminar Series: 8th Workshop Proceedings." University of Bradford, 2009. http://hdl.handle.net/10454/3559.

Pereira, Lucas Santos. "Estudo de antenas de microfita com dupla-banda e dupla-polarização para aplicação em redes retro-diretivas." Universidade Federal do Pampa, 2015. http://dspace.unipampa.edu.br:8080/xmlui/handle/riu/746.

Al-Debei, Mutaz M. "The design and engineering of innovative mobile data services : an ontological framework founded on business model thinking." Thesis, Brunel University, 2010. http://bura.brunel.ac.uk/handle/2438/4397.

Takeuchi, Takaaki. "Strategic issues for Japanese electric utilities in the telecommunications business : can utilities light up on the information superhighway?" Thesis, Massachusetts Institute of Technology, 1995. http://hdl.handle.net/1721.1/35452.

Grego-Nagel, Anne C. "An exploratory study of the adoption of mobile telecommunications service in order to improve mobile health service development." Diss., Kansas State University, 2016. http://hdl.handle.net/2097/34554.

Master’s degree in Telecommunications Engineering (MET)

Master's degree in Telecommunications Engineering (MET)

Barcelona school of telecommunications engineering (etsetb).

The master’s degree in Telecommunications Engineering ( master's degree website ) is a training proposal that is adaptable to the needs of two types of students: those who wish to focus on a professional career and those who wish to pursue a doctoral degree in the area of telecommunications engineering.

This master’s degree provides graduates with a broad profile that includes skills and expertise in communications systems, networks, electronics and audiovisual systems to ensure that they have the professional competencies that they need to practise as telecommunications engineers. After the first, compulsory subject area, students can choose from a wide variety of subjects to acquire a general profile, specialise in a field, or engage in research and pursue a doctoral degree.

The aim is for the graduates to enter modern industry as benchmark professionals in the new multidisciplinary work and production scenario. To increase their employability, students can take both the master’s thesis and some of the ECTS credits for optional subjects in a company or laboratory.

MET has a strong international character. It is taught entirely in English as it is expected that a large number of students will be from other countries. There is also the possibility of obtaining a joint degree with another internationally renowned university.

Specialisations

Antennas, Microwaves and Photonics for Communications and Earth Observation
Electronics
Fibre Optic Communications
Internet Networks and Technologies
Wireless Communications

General details

Everis: 2 scholarships with a grant of €3,000 each, and carrying out practices in Everis during a semester..
Fòrum TIC : 1 scholarship of €3,000.
HP : 1 scholarship with a grant of €2,773.35 and an additional employment contract linked to the duration of the scholarship .
Telecogresca : 1 scholarship for the 1st.

Information on language use in the classroom and students’ language rights .

Bachelor’s degree in Telecommunications Technologies and Services Engineering
Bachelor’s degree in Telecommunications Science and Technology
Bachelor’s degree in Audiovisual Systems Engineering
Bachelor’s degree in Electronic Systems Engineering
Bachelor’s degree in Telecommunications Systems Engineering
Bachelor’s degree in Network Engineering.
Bachelor's degree in Electrical Engineering.
Pre-EHEA five-year degree in Telecommunications Engineering: 60 ECTS credits may be recognised if the degree is homologated in Spain.
Pre-EHEA five-year degree in Electronic Engineering: 45 ECTS credits may be recognised if the degree is homologated in Spain.
Pre-EHEA diploma in Telecommunications Engineering: an additional 30 ECTS credits must be passed.
Bachelor's degree in Engineering Physics: an additional 60 ECTS credits must be passed (30 of them can be taken as optional courses on the bachelor's degree in Engineering Physics).

Language requirements: CEFR English Level B2, which you can demonstrate in one of the following ways:

Your mother tongue is English.
You have studied in an English-speaking country (for at least one semester).
You have taken an academic university programme taught in English (for at least one semester).
You hold a European Higher Education Area degree that includes English Level B2.
You hold one of the following English language certificates:

- Cambridge: FCE - TOEFL PBT: >= 567; CBT: >= 227; IBT: >= 87 - IELTS: 5.5 - TOEIC: 750 - Escuela Oficial de Idiomas: Certificado de nivel avanzado (Level 5)

You obtain a B2 English certificate at the UPC

Knowledge of Catalan and Spanish may be helpful for daily life.

Find more information on the Language services and resources at the UPC website.

MET Curriculum

Master MET offers 3 types of academic paths:

Academic path without specialization: If you want maximum flexibility in the elective subjects, choose this option. There are 45 compulsory ECTS credits, 15 ECTS credits from one intensification and you will have 30 more ECTS to choose among the different elective options. The final thesis has 30 ECTS.

Academic path with specialization: If you want to be a specialist in one of the multiple areas of the electrical engineering, choose this option. There are 45 compulsory ECTS credits, 30 ECTS credits from the intensification that you prefer, and you will still have 15 more ECTS to choose among the different elective options. The final thesis has 30 ECTS.

The different specialisations are:

Networks and Internet Technologies
Wireless comunications

Academic path with double-degree (limited places): If you prefer maximum internationalization and another master degree, choose this option. You will have to enrol 45 compulsory ECTS credits, 15 ECTS credits from one intensification and 60 or 90 ECTS credits (that include the 30 ECTS of the thesis) at the foreign university.

Subjects are structured in different blocks:

Bridge subjects: To be taken by students whose academic profile is not a general bachelor of telecommunications engineering. The Academic Commission of Masters assigns these courses to new students. These subjects do not extend the master, they use elective credits.

Core subjects: Compulsory subjects.

Intensification subjects (Academic path without specialization): The student must choose one intensification (Communications, Electronics, Multimedia or Networks) and take 3 subjects from a choice of 9. These subjects can be enrolled in different semesters, but the student must have passed 3 of the same intensification before finishing the master.
Specialization subjects (Academic path with specialization): The student will take 4 specialization compulsory subjects and 2 specialization elective subjects.

Elective credits: These credits can be divided between:

Elective subjects

And one of the following three options:

Introduction to research subjects

Internships in companies or laboratories (15 ECTS).

Recognized for professional experience (10 ECTS maximum)

Master's Thesis

Enrolment guide:

IMPORTANT NOTICE: Students willing to take a double degree or a mobility stay should:

Take the intensification path.
Pass all core subjects + 3 intensification subjects before the mobility.
Should you have to enroll bridge courses during the first semester, set up a meeting with Vice-Dean Head of Master Studies ([email protected]) to plan the enrolment for first and second semesters.

First semester (30 ECTS).

All bridge subjects that have been assigned to you.

Core subjects. Any of them except MTP.

None or one elective/intensification/specialization subject. Any except IT and having into account these restrictions:

AFOC requires to simultaneously enrol TSYS.
AMC requires to simultaneously enrol TSYS.
QSN requires to simultaneously enrol CN and OVNET.
WAN requires to simultaneously enrol CN.

Second semester (30 ECTS): The rest of core subjects except MTP + intensification subjects + elective subjects. Without restrictions.

Third semester (30 ECTS): MTP + intensification subjects + elective subjects. Without restrictions.

Fourth semester (30 ECTS): Master's thesis.

In case that bridge subjects are required, these will be enrolled in first and second semesters depending on the subject availability and the academic profile of each applicant.

Students can make mobility stays of half or full year to choose among a great number of foreign universities. Usually, the period is the third semester and/or the master's thesis during the fourth semester.

In case that the student is taking a double degree or a mobility stay in the second year, MTP and the 3 intensification subjects must be passed during first and second semesters.

Internships in companies:

It is also possible to perform internships in companies . In the master's framework, these internships can be curricular equivalent to 15 elective ECTS, curricular to do the master's thesis or extracurricular (do not recognize credits).

The ETSETB has a long collaboration tradition with companies. In this link you may see the companies that have offered internships during the last years.

Specialisation in Specialisation in Antennas, Microwaves and Photonics for Communications and Earth Observation
Specialisation in Specialisation in Electronics
Specialisation in Specialisation in Fiber Optic Communications
Specialisation in Specialisation in Multimedia
Specialisation in Specialisation in Networks and Internet Technologies
Specialisation in Specialisation in Wireless Communications
Advanced Communications for Wireless Systems 5
Communication Networks 5
Electronic Instrumentation and Optoelectronics 5
Electronic System Design for Communications 5
Innovation Based Service Management 5
Laboratory of Antennas, Microwaves and Photonics for Communications Systems 5
Management of Telecommunications Projects 5
Microwaves and Photonics for Communications and Earth Observation 5
Overlay Networks 5
Radar, Radionavigation and Location Systems 5
Remote Sensing for Earth Observation 5
Telecommunications Systems 5
Wireless Communication Links and Antennas 5
Advanced Analog Circuit Techniques 5
Design of Analog Microelectronic Circuits 5
Electronics for Communications Systems 5
Fundamentals of Semiconductor Devices 5
Introduction to Measurement Systems 5
Introduction to Microelectronic Design 5
Introduction to Microelectronic Technologies 5
Sensors, Instruments and Measurement Systems 5
Advanced Fiber Optical Communications 5
Optical Fiber Telecommunications 5
Optical Fiber Telecommunications Lab 5
Optical Networks 5
Biometrics 5
Digital Image and Video Processing 5
Digital Speech and Audio Processing 5
Machine Learning From Data 5
Distributed Systems, Internet and Web Technologies 5
Network Science 5
Network Security 5
Quality of Service in Networks 5
Web & Mobile App Development 5
5G Mobile Communications Systems 5
Advanced Mobile Communications 5
Advanced Signal Processing: Tools and Applications 5
Short Range Communications 5
Wireless Laboratory 5
Alternative Computing Strategies with Emerging Nanoelectronic Devices 3
Antennas and Microwaves 5
Array Processing and Smart Antennas 5
Artificial Intelligence and Internet of Things (Iot) 3
Automotive Embedded Systems 5
Basic Mathematics for Algebraic Coding Theory with Applications to Cryptography 2.5
Beam Propagation and Fourier Optics 5
Big Gnss Data: From Remote Sensing to Space Weather 3
Blockchain 5
Brief Course on The Mathematics Behind Coding Theory and Cryptography 3
Building Your Career. From Academia to Startups & Beyond 2.5
Coding of Audiovisual Contents 5
Cognitive Radio and Spectrum Sharing: a Key Technology of 5G Networks 2.5
Configurable Digital Electronics 5
Control and Applications in Power Electronics 5
Control Theory and Applications 5
Critical Thinking and Creativity 5
Cubesat-Based Mission Design and Testing 5
Data Transmission Protocols 5
Deep Learning for Computer Vision 2.5
Deep Learning for Speech and Language 2.5
Deep Learning for Vision 3
Digital Communications 5
Earth and Cosmos 5
Entrepreneurship for World Challenges 5
Fiber Optic Infrastructure for 5G Networks 2.5
Fibers and Telecommunications 3
Financial Engineering: Applications to Information Technology Projects 2.5
Future Trends in Mobile Communications: From 5G to 6g 2.5
GPS and Galileo Data Processing: From Fundamentals to High Accuracy Navigation 5
Graph Signal Processing 3
Graphene and Carbon Nanotubes Introduction and Fundamentals 2.5
Hands-On Quantum Computing and Artificial Intelligence 3
Integrated Photonics 3
Integrated Satellite-Terrestrial Communications for 6g 3
Interdisciplinary Innovation Project 5
Introduction to Photonics. Optics and Lasers 5
Introduction to Research 1 5
Introduction to Research 2 5
Introduction to Research 3 5
Laboratory on Ultrasonic Electronics 3
Laser Applications in Remote Sensing: Lidar 3
Laser, Terahertz and Microwave Research and Applications 5
Lidar Processing and Inversion: Applications to Remote Sensing of Physical Parameters 2.5
Lidar Remote Sensing 2.5
Marine Technology Instrumentation 5
Matlab Programed Arduino for Control Applications 2.5
Matrix Algebra, Accelerated Program 3
Microwave Imaging for Remote Sensing 5
Microwave Photonics 2.5
Modern Channel Coding 3
Natural Language Processing with Deep Learning 3
Network Performance Analysis and Evaluation 5
Networking and Future Internet Opportunities 5
New Telecom Markets 3
Numerical Methods for Electromagnetic Engineering 5
Optical Remote Sensing: Lidar (Laser Radar) 5
Optoelectronics and Photovoltaic Technology 3
Photonic Systems in Telecommunications: Lidar (Laser Radar) 3
Photonics Systems in Telecommunications 3
Power Control and Processing 5
Power Electronic Circuits 5
Principles of Control and Power Electronics 5
Printed Circuit Board Design 2.5
Programmable Electronics 5
Quantum Communication and Computation 3
Quantum Cryptography 5
Quantum Information Theory 2.5
Secure Optical Networks 3
Seminar on Advanced Telecommunication Technologies 3
Seminar on Blockchain 3
Service Management with Fitsm 3
Signal Processing 5
Social Networks: Theory and Implementation 5
Software Architecture 5
Software-Based Digital Control Applications 2.5
Solar Cells for Dummies 2.5
Stochastic Processes 2.5
Systems Based on Microprocessors 5
Technology Asset Management 5
Telecommunication Markets 5
Telecommunication Systems Fundamentals 5
Telecommunications and Electronics Seminar 2.5
The Connected Vehicle 2.5
The Way to 6g: Future Trends in Mobile Communications 3
Transoceanic Communications 2.5
Waves and Systems 5
Advanced Digital Systems 5
Digital Nanoelectronic Design 5
Electronic Measurement Science and Technology 5
High-Level Digital Design 5
Instrumentation and Sensors 5
Micro and Nano Electronic Design 5
Micro and Nanotechnologies 5
Nanotechnologies and Electron Devices 5
Future (Inter)Net(Works) 5
Matlab: Fundamentals And/Or Applications 5
Optical Fiber Sensor Technologies 5
Photonic Integrated Devices for Telecom & Iot 5
Secure Communications in Fiber-Optic Networks 5
Advanced Human Language Technologies 5
Computer Vision with Deep Learning 5
Cybersecurity Management 5
Deep Learning for Artificial Intelligence 5
Speech and Language Processing with Deep Learning 5
Cybersecurity Usecases 5
Data Protection 5
Internet and Networked Economy 5
Network Security - Authentication and Authorization 5
Optimization and Artificial Intelligence Techniques in Network Management 5
Wireless Access Networks 5
Applied Convex Optimization 5
Artificial Intelligence-Enabled 5G Radio Networks 5
Information Theory 5
Resource Management in Wireless Communications 5
Master's Thesis 30
Compulsory ECTS
Optional ECTS
Project ECTS

Professional opportunities

The areas in which graduates of this master’s degree may find employment are similar to those for graduates of the five-year degree in Telecommunications Engineering, although their profiles are enhanced by an extra academic year. Their careers may lead them to practise as: Telecommunications engineers in any of the following areas:

Telecommunications operations.
Telecommunications equipment industry.
Electronic equipment industry.
Semiconductor industry.
IT consulting firms (network solution designers, network planners and designers, network project leaders, etc.).
IT companies, from content producers and distributors to service providers.
Regulatory bodies.
Software editing firms.
Other industries such as cars manufacturers and consumer and industrial electronics companies, and areas such as health, energy, intelligent transport systems, logistics and mobility, agricultural and food, air and maritime transport, railway infrastructure, control systems and security of facilities and electronic services transactions, as well as rapidly expanding areas such as smart cities, smart homes, smart grids and smart health.

Freelance professionals acting as telecommunications engineering advisors and consultants.

Sales engineers.

Civil servants or employees of public administrations at EU, national, regional and local level in the field of telecommunications and ICT innovation.

Research, development and innovation specialists in public and private companies.

Researchers and academics at public or private universities.

In addition to professionally oriented topics, the master’s degree offers highly specialised optional subjects intended for those students who are looking to pursue a doctoral degree in Telecommunications Engineering . Labour Market Every three years, the Catalan University Quality Assurance Agency (AQU) publishes a study about the employability of Catalan university graduates.

The last of these studies, Universites and Employment in Catalonia 2014 analyses the employability of students who graduated in the 2009-2010 academic year. The most significant labour market data for telecommunication engineers are the following:

The graduate employment rate is 92.6%.
It takes 84% of graduates less than three months to find their first job.
Of students who graduated in the 2009-2010 academic year, 78.5% earn over €2000 a month.
Telecommunications engineering is in fourth place in the ranking of degree courses according to the Job Quality Index.

The Everis Foundation has issued a ranking of universities based on companies' views on the employability of new graduates. The UPC is the top Spanish university in the area of software and telecommunications engineering.

Generic competencies

Generic competencies are the skills that graduates acquire regardless of the specific course or field of study. The generic competencies established by the UPC are capacity for innovation and entrepreneurship, sustainability and social commitment, knowledge of a foreign language (preferably English), teamwork and proper use of information resources.

Specific competencies On completion of the course, students will have achieved competence in the following areas:

Communication systems: wired and wireless, optical fibre.
Computer networks, internet, local area networks (Ethernet, Wi-Fi).
Voice networks, video distribution and television streaming, P2P, mobile networks.
Security in communication networks: encryption, user authentication, digital signatures.
Radio navigation, global positioning systems (GPS).
Information processing: encoding, compression, error correction, image recognition, video clip recognition, voice recognition, voice generation.
Electronic components and circuits: microprocessor devices (routers, switches, etc.), sensors, actuators, transducers.
Technology and electronics, analogue and digital electronic instrumentation, medical electronics, consumer electronics, control systems, robotics, automation.
Micro- and nanotechnologies.
Bioengineering applications, telemedicine, e-commerce platforms, smart cities, smart metering, sensor networks, smart homes, green computing, cloud computing.

Double-degree agreements

Master's degree in Telecommunications Engineering (en endavant MET , ETSETB) + Master's degree of Science in Engineering (To choose between 4 masters) (School of Electrical Engineering, KTH Royal Institute of Technology, Stockholm, Sweden)
MET + Master in Management Grande Ecole Degree de l'HEC (École Des Hautes Études Commerciales (HEC), París) (Only ETSETB students to HEC, not vice versa)
MET + Diplôme d'Ingénieur ISAE-SUPAERO (Institut Supérieur de l'Aeronautique et de l'Espace, Université Fédérale Toulouse Midi-Pyrénnés, Toulouse, França)
MET + Maestría en Ingeniería de las Telecomunicaciones (Escuela de Postgrado, Pontificia Universidad Católica del Perú (PUCP), Lima, Perú)
MET + Maestría en Sistema de Información (Facultad de Ingerniería, Universidad Católica Andrés Bello (UCAB), Caracas, Venezuela)
MET + Master's degree of Science in Engineering ( Illinois Institute of Technology (IIT), Chicago, USA) (To choose between 4 masters) (Only ETSETB students to Illinois, not vice versa)
MET + Master's degree in Electrical Engineering and Information Technology / Master's degree in Information and Communication Engineering (Department of Electrical Engineering and Information Technology, Technische Universität Darmstadt, Darmstadt, Germany)
MET + / Master of Science in Telecommunications Engineering o Master of Science in Electronics Engineering (Ingegnieria Industriale e dell'Informazione, Politecnico di Milano (POLIMI), Milan, Italy)

Quality accreditation

Organisation: academic calendar and regulations.

Organizing teaching center

Technical School of Telecommunications Engineering of Barcelona (ETSETB)

Academic program manager

Marcos Postigo

Academic calendar

General academic calendar for degrees, masters and doctorates

Current course (class schedules, master's calendar, exams, teachers, ...)

Academic regulations

Academic regulations of the masters of the UPC

Specific academic regulations for the MET and MEE masters

Academic and administrative procedures

Pre-enrollment, registration, master's thesis, ...

Mobility agreements to carry out the master's thesis at universities and foreign companies

Business practices

List of courses and teaching guides

Intensification

Specialization

Master's degree website

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Master Thesis Telecommunication Engineering Projects

Master Thesis Telecommunication Engineering Projects is an everlasting research stadium to uprising high-tech knowledgeable research generation . Our worldwide scientists launch our ‘World’s No. 1’ research organization with the dream of make knowledge revolution among students and research scholars. We give 1000+ evergreen research topics for you to accomplish your daydream of world-stunning research. For more information, you can approach us at 24/7 365 service.

Superlative Projects Titles in Telecommunication Engineering:

Ultracompact On-Chip Multiplexed Sensor Array Based on Dense Integration of Flexible 1-D Photonic Crystal Nanobeam Cavity with Large Free Spectral Range and High Q-Factor
Combinational Auction Based Service Provider Selection in Mobile Edge Computing Networks [ Master Thesis Telecommunication Engineering Projects ]
ABER Performance of LDPC Coded OFDM Free-Space Optical Communication System over Exponentiated Weibull Fading Channels with Pointing Errors
Implementation of a Virtual Training Simulator Based on 360° Multi-view Human Action Recognition
Energy Efficiency Maximization of Full-Duplex Two-Way Relay with Non-ideal Power Amplifiers and Non-negligible Circuit Power
Local Mesh Deformation for accelerated parametric studies based on the Finite Element Method
R&D projects selection in telecommunications under uncertainty and resource restrictions using scheduling
Towards SDN/NFV-enabled satellite ground segment systems: End-to-End Traffic Engineering use case
HMM-based gesture recognition system using kinect sensor for improvised human-computer interaction
Social-aware distributed joint mode selection and link allocation for mobile D2D communications
Adaptive mode selection in cognitive buffer-aided full-duplex relay networks with imperfect self-interference cancellation for power and delay limited cases
A deep learning enabled subspace spectral ensemble clustering approach for web anomaly detection
Detailed Analytical Modeling of Fractional-Slot Concentrated-Wound Interior Permanent Magnet Machines for Prediction of Torque Ripple
Distributed Mobility Management for the Future Mobile Networks: A Comprehensive Analysis of Key Design Options [ Master Thesis Telecommunication Engineering Projects ]
Jointly Optimal Pre- and Post-Channel Equalization and Distributed Beam forming in Asynchronous Bidirectional Relay Networks

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Search for dissertations about: "theses on telecommunications engineering"

Showing result 1 - 5 of 503 swedish dissertations containing the words theses on telecommunications engineering .

1. Antenna Evaluation for Vehicular Applications in Multipath Environment

Author : Edith Condo Neira ; Erik G. Ström ; Kristian Karlsson ; Claes Beckman ; RISE ; [] Keywords : TEKNIK OCH TEKNOLOGIER ; ENGINEERING AND TECHNOLOGY ; TEKNIK OCH TEKNOLOGIER ; ENGINEERING AND TECHNOLOGY ; TEKNIK OCH TEKNOLOGIER ; ENGINEERING AND TECHNOLOGY ; TEKNIK OCH TEKNOLOGIER ; ENGINEERING AND TECHNOLOGY ; Vehicular antenna evaluation ; V2V measurements ; LTE. ; multipath environment ; IEEE 802.11p ; V2V simulations ;

Abstract : Antennas are essential components in any wireless communication system. To evaluate them is challenging, especially when new technologies are emerging.Future intelligent transport systems, where vehicular communications play an important role will cover important aspects such as traffic safety and traffic efficiency. READ MORE

2. Data-driven Performance Prediction and Resource Allocation for Cloud Services

Author : Rerngvit Yanggratoke ; Rolf Stadler ; Gunnar Karlsson ; Filip De Turck ; KTH ; [] Keywords : TEKNIK OCH TEKNOLOGIER ; ENGINEERING AND TECHNOLOGY ; TEKNIK OCH TEKNOLOGIER ; ENGINEERING AND TECHNOLOGY ; TEKNIK OCH TEKNOLOGIER ; ENGINEERING AND TECHNOLOGY ; NATURVETENSKAP ; NATURAL SCIENCES ; TEKNIK OCH TEKNOLOGIER ; ENGINEERING AND TECHNOLOGY ; Electrical Engineering ; Elektro- och systemteknik ;

Abstract : Cloud services, which provide online entertainment, enterprise resource management, tax filing, etc., are becoming essential for consumers, businesses, and governments. The key functionalities of such services are provided by backend systems in data centers. This thesis focuses on three fundamental problems related to management of backend systems. READ MORE

3. Modeling and Estimation of Phase Noise in Oscillators with Colored Noise Sources

Author : M Reza Khanzadi ; Chalmers tekniska högskola ; [] Keywords : TEKNIK OCH TEKNOLOGIER ; ENGINEERING AND TECHNOLOGY ; TEKNIK OCH TEKNOLOGIER ; ENGINEERING AND TECHNOLOGY ; TEKNIK OCH TEKNOLOGIER ; ENGINEERING AND TECHNOLOGY ; TEKNIK OCH TEKNOLOGIER ; ENGINEERING AND TECHNOLOGY ; TEKNIK OCH TEKNOLOGIER ; ENGINEERING AND TECHNOLOGY ; Phase Noise Model ; Bayesian Cramer-Rao Bound ; Voltage-controlled Oscillator ; Extended Kalman Filter Smoother ; Maximum a Posteriori Estimator ; Colored Phase Noise ; Oscillator Phase Noise ; Phase-Locked Loop ; Mean Square Error. ;

Abstract : The continuous increase in demand for higher data rates due to applications with massive number of users motivates the design of faster and more spectrum efficient communication systems. In theory, the current communication systems must be able to operate close to Shannon capacity bounds. READ MORE

4. mm-Wave Data Transmission and Measurement Techniques: A Holistic Approach

Author : Dhecha Nopchinda ; Chalmers tekniska högskola ; [] Keywords : TEKNIK OCH TEKNOLOGIER ; ENGINEERING AND TECHNOLOGY ; TEKNIK OCH TEKNOLOGIER ; ENGINEERING AND TECHNOLOGY ; TEKNIK OCH TEKNOLOGIER ; ENGINEERING AND TECHNOLOGY ; TEKNIK OCH TEKNOLOGIER ; ENGINEERING AND TECHNOLOGY ; TEKNIK OCH TEKNOLOGIER ; ENGINEERING AND TECHNOLOGY ; estimation theory ; data transmission experiment ; spectral efficiency ; microwave network analysis ; communication system ; millimeter wave mm-wave system ; mutual coupling effects ; spectrally efficient frequency division multiplexing SEFDM ; vector network analyzer ; wideband measurement. ; coherent optical system ; impairment compensation algorithm ; identification theory ; multiplier based transmitter ; digital signal processing ; Active load pull ; linear measurement technique ;

Abstract : The ever-increasing demand on data services places unprecedented technical requirements on networks capacity. With wireless systems having significant roles in broadband delivery, innovative approaches to their development are imperative. READ MORE

5. Aspects of Power Allocation in Massive MIMO

Author : Hei Victor Cheng ; Erik G. Larsson ; Daniel Persson ; Emil Björnson ; Carlo Fischione ; Linköpings universitet ; [] Keywords : TEKNIK OCH TEKNOLOGIER ; ENGINEERING AND TECHNOLOGY ; TEKNIK OCH TEKNOLOGIER ; ENGINEERING AND TECHNOLOGY ; NATURVETENSKAP ; NATURAL SCIENCES ; TEKNIK OCH TEKNOLOGIER ; ENGINEERING AND TECHNOLOGY ; TEKNIK OCH TEKNOLOGIER ; ENGINEERING AND TECHNOLOGY ;

Abstract : The past decades have seen a rapid growth of mobile data trac, both in terms of connected devices and data rate. To satisfy the ever growing data trac demand in wireless communication systems, the current cellular systems have to be redesigned to increase both spectral eciency and energy eciency. READ MORE

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Telecommunications Engineering Technology Master of Science Degree

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Overview for Telecommunications Engineering Technology MS

The MS in telecommunications engineering technology is no longer accepting applications for admission. Students interested in studying telecommunications, wireless communications, or fiber optic communications should refer to the MS program in communication networks .

The telecommunications industry has driven technological innovation and provided outstanding career opportunities for people with the right technical and leadership skills. New services offered through the internet, mobility via wireless technology, and extreme capacity created by fiber optics, as well as the evolution of policy and regulation, are shaping the telecommunication network of the future. The MS in telecommunications engineering technology focuses on developing an advanced level of skill and knowledge needed by future leaders in the industry. This program is designed for individuals who seek advancement into managerial roles in the dynamic telecommunications environment.

The telecommunications engineering technology program requires 33 credit hours of study and includes eight core courses that introduce essential fundamental concepts and skills. Students are required to complete a comprehensive exam, a capstone project, or a thesis. The remaining credits consist of technical electives or other approved graduate courses.

Students may take three credit hours of elective course work from other graduate programs subject to the approval of the graduate program director. Students often choose courses from Saunders College of Business , Golisano College of Computing and Information Sciences , or Kate Gleason College of Engineering . The number of elective credits depends upon the student's choice of a thesis, project, or comprehensive exam.

Research and Cooperative Education

Students have the opportunity to apply for research projects or participate in a cooperative education experience. While not a requirement, these opportunities increase the value of the program and the marketability of its graduates. Full-time students may choose to complete cooperative education after completing two semesters (a minimum of 18 credit hours of study), students may request approval to complete up to one year of cooperative education employment related to their field of study.

Comprehensive Exam/Project/Thesis Options

All students are required to complete a comprehensive exam at the conclusion of their course work. The comprehensive exam focuses on knowledge of the core competencies, theory and foundation principles, and application of this knowledge to a variety of scenarios. Students who wish to complete a graduate project or a thesis in place of the comprehensive exam must have the approval of the faculty and the graduate program director.

This program is no longer accepting new student applications.

Careers and Salary Info

Typical job titles, curriculum for 2023-2024 for telecommunications engineering technology ms.

Current Students: See Curriculum Requirements

Telecommunications Engineering Technology (thesis option), MS degree, typical course sequence

* TCET-601 is a bridge course that can be waived by qualification exam. If completed, credits do not count toward degree.

Telecommunications Engineering Technology (graduate project option), MS degree, typical course sequence

Telecommunications engineering technology (comprehensive exam option), ms degree, typical course sequence.

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July 2, 2023

Women Reshaping The Cybersecurity Industry: Comcast’s Shena Seneca Tharnish On The Five Things You Need To Create A Highly Successful Career In The Cybersecurity Industry

Medium features an interview with Shena Seneca Tharnish '96 (telecommunication engineering technology).

August 8, 2022

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RIT Certified and Foundry collaborate on cryptocurrency course

Underserved students from the city of Rochester with a strong interest in cryptocurrency and blockchain technology recently participated in an immersive, weeklong course at RIT to learn the latest about digital currency through its RIT Certified initiative.

April 23, 2021

College of Engineering Technology 2020-2021 Distinguished Alumna: Laureen R. Cook

The Distinguished Alumni Awards are presented annually by each of RIT’s nine colleges and the School of Individualized Study to alumni who have performed at the highest levels of their profession or who have contributed to the advancement and leadership of civic, philanthropic, or service organizations.

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In addtion to the regular courses that will be offered, there is also a set of research topics available for the students undertaking their Master Thesis. These topics allow for both fundamental and applied research, as well as technology transfer, depending on the case. These research directions will be availabe for two purposes:

a) research work to be done during the Master Thesis. b) for those students deciding later to pursue a PhD. within the Doctoral Program "Information Technologies, Communications and Computational Mathematics" of Universitat de València or the Doctoral Program "Information, Communication and Audiovisual Technologies" at Universitat Pompeu Fabra, in which case the Master Thesis will be ideally a preliminary work for the subsequent PhD. research.

This is a preliminary list of updated generic research topics that are available for the students:

Collaborative signal processing in Networks
Decentralized, Self-Organized and Adaptive Communications
Communication Algorithms and Protocols for Wireless Sensor Networks
Software Architectures for Wireless Sensor Networks
Testbed Design and Deployment of Wireless Sensor Networks
Modeling Tools and Analysis of Decentralized Large-scale Networks
Advanced Iterative Coding Systems
Code Design on Graphs for Communication channels
Multi-antenna Space-Time Coding for Wireless MIMO Systems
Co-operative Diversity Techniques in Communications
Advanced array signal processing and Beamforming techniques
Statistical Inference and Estimation under communication constraints
Advanced Optimization for problems in Communications and Signal Processing
Adaptive processing algorithms for Communication Systems
Advanced Multidimensional Signal, Image and Video Processing
Novel Statistical Processing Algorithms for Wireless Communications
Advanced Channel estimation Techniques
Cognitive Radios
Optimization of Self-Organized networks based on Game Theory
Software-Defined Radios
Wide-Band and Ultra-Wide-Band Communications
Fundamental performance limits in Communications
Network Information Theory
Robust and Adaptive algorithms for Capacity maximization in Communications
Stochastic Modeling and Exact Stochastic Simulation
Cross-Layer design for ad-hoc Networks
Distributed Algorithms for Detection, Estimation and Control in Networks
Heterogeneous Networks, Interconnection and Network Co-operation
Decentralized MAC and Synchronization Algorithms
Intelligent and Adaptive Routing Algorithms
Advanced Network Tomography and Network Traffic Sampling
Design and Analysis of novel compact antennas for wireless networks

Electrical and Electronic Engineering Theses

Permanent uri for this collection.

This collection is made up of doctoral and master theses by research, which have been received in accordance with university regulations.

For more information, please visit the UCD Library Theses Information guide .

Recent Submissions

Publication RF Amplification and Filtering Techniques for Cellular Receivers ( University College Dublin. School of Electrical and Electronic Engineering, 2021 ) Bozorg, Amir The usage of various wireless standards, such as Bluetooth, Wi-Fi, GPS, and 4G/5G cellular, has been continually increasing. In order to utilize the frequency bands efficiently and to support new communication standards with lower power consumption, lower occupied volume and at reduced costs, multimode transceivers, software defined radios (SDRs), cognitive radios, etc., have been actively investigated. Broadband behavior of a wireless receiver is typically defined by its front-end low-noise amplifier (LNA), whose design must consider trade-offs between input matching, noise figure (NF), gain, bandwidth, linearity, and voltage headroom in a given process technology. Moreover, monolithic RF wireless receivers have been trending toward high intermediatefrequency (IF) or superhetrodyne radios thanks to recent breakthroughs in silicon integration of band-pass channel-select filters. The main motivation is to avoid the common issues in the currently predominant zero/low-IF receivers, such as poor 2nd-order nonlinearity, sensitivity to 1/f (i.e. flicker) noise and time-variant dc offsets, especially in the fine CMOS technology. To avoid interferers and blockers at the susceptible image frequencies that the high-IF entails, band-pass filters (BPF) with high quality (Q) factor components for sharp transfer-function transition characteristics are now required. In addition, integrated low-pass filters (LPF) with strong rejection of out-of-band frequency components are essential building blocks in a variety of applications, such as telecommunications, video signal processing, anti-aliasing filtering, etc. Attention is drawn toward structures featuring low noise, small area, high in-/out-of-band linearity performance, and low-power consumption. This thesis comprises three main parts. In the first part (Chapters 2 and 3), we focus on the design and implementation of several innovative wideband low-noise (transconductance) amplifiers [LN(T)A] for wireless cellular applications. In the first design, we introduce new approaches to reduce the noise figure of the noise-cancellation LNAs without sacrificing the power consumption budget, which leads to NF of 2 dB without adding extra power consumption. The proposed LNAs also have the capability to be used in current-mode receivers, especially in discrete-time receivers, as in the form of low noise transconductance amplifier (LNTA). In the second design, two different two-fold noise cancellation approaches are proposed, which not only improve the noise performance of the design, but also achieve high linearity (IIP3=+4.25 dBm). The proposed LN(T)As are implemented in TSMC 28-nm LP CMOS technology to prove that they are suitable for applications such as sub-6 GHz 5G receivers. The second objective of this dissertation research is to invent a novel method of band-pass filtering, which leads to achieving very sharp and selective band-pass filtering with high linearity and low input referred (IRN) noise (Chapter 4). This technique improves the noise and linearity performance without adding extra clock phases. Hence, the duty cycle of the clock phases stays constant, despite the sophisticated improvements. Moreover, due to its sharp filtering, it can filter out high blockers of near channels and can increase the receiver’s blocker tolerance. With the same total capacitor size and clock duty cycle as in a 1st-order complex charge-sharing band-pass filter (CS BPF), the proposed design achieves 20 dB better out-of-band filtering compared to the prior-art 1st-order CS BPF and 10 dB better out-of-band filtering compared to the conventional 2nd-order C-CS BPF. Finally, the stop-band rejection of the discrete-time infinite-impulse response (IIR) lowpass filter is improved by applying a novel technique to enhance the anti-aliasing filtering (Chapter 5). The aim is to introduce a 4th-order charge rotating (CR) discrete-time (DT) LPF, which achieves the record of stop-band rejection of 120 dB by using a novel pseudolinear interpolation technique while keeping the sampling frequency and the capacitor values constant. 75
Publication Frequency Control of Virtual Power Plants ( University College Dublin. School of Electrical and Electronic Engineering, 2022 ) Zhong, Weilin ; 0000-0001-6737-4873 The Virtual Power Plant (VPP) concept refers to the aggregation of Distributed Energy Resources (DERs) such as solar and wind power plants, Energy Storage Systems (ESSs), flexible loads, and communication networks, all coordinated to operate as a single generating unit. Using as starting point a comprehensive literature review of the VPP concept and its frequency regulation technologies, the thesis proposes a variety of frequency control and state estimation approaches of VPPs, as follows. First, the thesis studies the impact of coordinated frequency control of VPPs on power system transients, in which ESSs are utilized to provide fast frequency regulation. The thesis also proposes a simple yet effective coordinated control of DERs and ESSs able to integrate the total active power output of the DERs, and, thus, to improve the overall power system dynamic performance. The impact of topology on the primary frequency regulation of VPPs is also investigated. With this regard, two types of VPPs topologies are considered, that is, a topology where the DERs that compose the VPP are scattered all-over the transmission grid; and a topology where the DERs are all connected to the same distribution system that is connected to the rest of the transmission grid through a single bus. Next, the thesis proposes a control scheme to improve the dynamic response of power systems through the automatic regulators of converter-based DERs. In this scheme, both active and reactive power control of DERs are varied to regulate both frequency and voltage, as opposed to current practice where frequency and voltage controllers are decoupled. To properly compare the proposed control with conventional schemes, the thesis also defines a metric that captures the combined effect of frequency/voltage response at any given bus of the network. Finally, the thesis presents an on-line estimation method to track the equivalent, time-varying inertia as well as the fast frequency control droop gain provided by VPPs. The proposed method relies on the estimation of the rate of change of the active and reactive power at the point of connection of the VPP with the rest of the grid. It provides, as a byproduct, an estimation of the VPP’s internal equivalent reactance based on the voltage and reactive power variations at the point of connection. Throughout the thesis, the proposed techniques are duly validated through time domain simulations and Monte Carlo simulations, based on real-world network models that include stochastic processes as well as communication delays. 137
Publication Low-Complexity Digital Predistortion for 5G Massive MIMO and Handset Transmitters ( University College Dublin. School of Electrical and Electronic Engineering, 2022 ) Wang, Xiaoyu The demand for new wireless communication systems to support high mobility and low latency necessitates a rethink of the architecture of wireless communication systems as well as the design of their key components. This thesis presents several novel techniques to solve the major challenges in digital predistortion (DPD) for millimeter wave multi-input multi-output (MIMO) and handset transmitters to lower the hardware cost and computational complexity of the fifth generation (5G) communication systems. The first part of the thesis focuses on the architecture of the MIMO DPD solution for 5G transmitters. To extract DPD model coefficients, a feedback data acquisition path is required. In conventional single-input single-output (SISO) systems, the output is usually acquired directly from the power amplifier (PA) with a coupler. In massive MIMO systems, the number of RF chains is large. Using dedicated feedback paths for each PA separately is not feasible. To lower the hardware cost, a novel data acquisition scheme is proposed to obtain the output signals in far field over the air (OTA) using a single antenna and feedback loop, and then reconstruct the output of each PA. Simulation and experimental results demonstrate that the proposed OTA data acquisition can accurately reconstruct the output of each PA in the MIMO systems and the DPD solutions derived from the reconstructed data can successfully linearize the nonlinear MIMO transmitters. In the multi-user scenario, the nonlinearity of the transmitters varies with the movement of user equipments (UEs), and the DPD model coefficients need to be updated accordingly. To meet the requirement of high mobility, the complexity of the system update must be low. In the second part of the thesis, we present a new DPD system, where DPD model can be updated fast and accurately without capturing PA output or applying costly model extraction algorithms. In the proposed method, nonlinear characteristics of the PA are encoded into low-dimensional PA features using feature extraction algorithms. To identify DPD model coefficients, PA features are extracted first and the DPD model coefficients are then generated directly by DPD generator with PA features. Experimental results show that the proposed DPD solution can linearize PA with very low complexity compared to that using the conventional solutions. Finally, the focus shifts to handset transmitters. Conventionally, DPD is usually deployed for high power base stations. With the continuously increasing bandwidth, DPD may also be required for handset PAs in 5G communication systems. Different from the models used for base stations, DPD model for handset PAs must have very low complexity because of the stringent power budget limit. At the same time, the tolerance for load mismatch must also be considered. The third part of the thesis analyzes the characteristics of handset PAs with load mismatch and introduces a low-complexity DPD model based on magnitude-selective affine (MSA) function. Experimental results demonstrate that the extended MSA (EMSA) model shows better linearization performance while keeping much lower complexity than the conventional DPD models. 9
Publication Circularly Polarized Antennas for 5G Millimetre-Wave Communications ( University College Dublin. School of Electrical and Electronic Engineering, 2022 ) Sadeghi-Marasht, Samaneh The need of a higher data rate, lower latency, and cost efficiency led to the fifth-generation (5G) emerging as a new communication standard. This generation includes many unused frequencies with high available bandwidth channels that can provide higher capacities such as millimeter-wave (mm-wave) bands. One of the main challenges of working at high frequencies of this generation is path loss that needs to be addressed. To overcome this issue, a high gain antenna with a small size is required. Consequently, the first major question arises: how to effectively increase the gain and efficiency of the antenna at a high frequency with a small size. Importantly, it is vital to transport as much as data is possible without any sensitivity to the alignment of the transmitter or receiver antenna that can be satisfied by using circularly polarized (CP) radiating waves. Thus, the second research question emerges: how to provide high gain small size antenna with CP at high frequencies. To address the first two major research questions in this thesis we designed a miniature dual-band CP antenna that works at 28 GHz and 38 GHz with high gain. This antenna can be implemented in mobile devices, unmanned aerial vehicles (UAVs), and base stations (BSs) because of the small sizes of 11 × 14 × 0.508 mm3. For getting a deep insight into the structure and the design procedures of the dual-band antenna, characteristic mode analysis (CMA) is employed. Note that the CMA is not sensitive to the feeding position and the material in this analysis is not lossy. Therefore, after using CMA, the optimization is conducted in the full-wave simulation as the feeding is added to the structure, and the material is lossy. The single CP antenna covered the bands of 27-28.4 GHz and 34.7-40 GHz, with a maximum gain of 6.3 dBiC and 5.51 dBiC at 28 GHz and 38 GHz, respectively, whereas the radiation efficiency is 94% and 96% with the ARBW of 2.5% and 1.5%. A phased antenna array is then constructed to provide a higher gain for this designed dual-band antenna. In a phased antenna array we consider four designed single element antennas close to each other to create a 2 × 2 antenna array with high gain at 28 GHz and 38 GHz. For a 4 × 4 antenna array, an electromagnetic band-gap (EBG) is used to reduce the mutual coupling between elements in the array. The radiating signals will be sent to different users with circular polarization via electronic beamforming. The position of each antenna element is also optimized to provide the constructive radiating wave towards our desired directions. The array was able to steer the beam between -26.5 to 29.5 degrees for the lower band and -29.5 to 35.5 degrees for the higher band with the maximum gain of 12.8 dBiC and 11.5 dBiC, respectively. Another method to enhance the gain is implementing a lens structure in front of the radiating antenna. Here, a significant challenge is to maintain the CP of the incoming CP wave while the gain is increased. Therefore, the third research question is how to design a lens with the capability of enhancing the gain and keeping the CP when the lens is fed by a CP antenna source. Concerning the third major research question, in this thesis, we designed a CP lens structure. First, a multi-layer lens with a thickness of 2.03 mm was designed, and then a one-layer lens structure with a thickness of just 0.508 mm was made. The lens was located in front of different radiating antennas. These lens structures resulted in significant gain enhancement for various feeding antennas working at 28 GHz. The unit cell of the one-layer lens can provide a broad phase shift compared to the multi-layer counterpart. The proposed lens structures not only increased the gain of the incoming CP wave but also kept its polarization to overcome the issues of reflectivity, absorption, inclement weather, and mis 16
Publication Contributions to the theory and development of low-jitter bang-bang integrated frequency synthesizers ( University College Dublin. School of Electrical and Electronic Engineering, 2022 ) Avallone, Luca The advent of next-generation wireless standards demands ever-increasing data-rate communication systems. It mainly involves a higher carrier frequency to take advantage of wider bandwidth channels and more complex modulation schemes to pack more information into each symbol. In this context, the bottleneck is represented by the frequency synthesizer used to generate the local oscillator signal for the transceiver, which has to operate under stringent low output jitter requirements. Such performance must be provided at low power dissipation and area consumption in order to meet the requirements of low-cost and high integration level of the modern communication systems. The digital phase locked loop architecture can meet the required jitter performance while synthesizing fractional-N frequencies. Such PLLs offer significant advantages over their traditional analog counterpart in terms of area occupation, flexibility and scalability in advanced deep sub-µm CMOS technologies. The digital PLL topology based on a bang-bang phase detector, denoted bang-bang PLL, which is a single bit digital phase detector, leads to a less complex and more power-efficient architecture, but, on the other hand, it also introduces a hard nonlinearity in the loop, making the analysis of the bang-bang topology more challenging than in the multi-bit case. A comprehensive phase noise analysis of bang-bang digital PLLs is presented which overcomes the limitations of previous models and it is valid in all cases where physical noise sources (i.e. reference and DCO) are dominant with respect to quantization errors. In particular, (i) input-referred jitter is estimated by means of a linear time-domain analysis derived from a nonlinear DPLL model, and (ii) phase noise spectra are predicted using a discrete-time domain model that accounts for time-variant effects that arise from the intrinsic multirate nature of the DPLL. The possibility of accurately determining the DPLL jitter and phase noise spectra, enabled by the novel analysis presented in this thesis, is key to significantly speeding up the design-space exploration phase, since it allows one to perform quick and precise parametric sweeps. However, even when designed properly, bang-bang PLLs are affected by the unavoidable bang-bang phase detector quantization noise, which is added on top of the intrinsic reference and DCO phase noise. The quantization noise can be appreciated in the PLL's output spectrum as increased in band noise with respect to the analog counterpart, that, in fact, still achieves superior performance in terms of jitter-power. This results in worse integrated jitter performance for the same intrinsic levels of reference and oscillator phase noise. To overcome the binary phase detector quantization noise in DPLLs, state-of-the-art works rely on a multi-bit time-to-digital converter to digitize the PLL phase error with a physical resolution below the input jitter, leading to increased design complexity, with an associated area and power penalty. In order to overcome the ultimate limit of the bang-bang PLL, a digital PLL based on a bang-bang phase detector with adaptively optimized noise shaping has been fabricated in a 28nm CMOS process. The prototype occupies a core area of 0.21 mm2 and draws 10.8 mW power from a 0.9 V supply. The integrated jitter is 69.52 fs and 80.72 fs for the integer-N and the fractional-N case, respectively. Achieving a jitter-power figure-of-merit of -251.5 dB in fractional-N mode, the proposed system effectively bridges the gap to analog implementations. The first chapter of this work is introductory, and is intended to give some background information needed to underpin the remaining part of the thesis. The following chapters, 2, 3 and 4, collect the results achieved during the PhD activity, and each of them is associated with a publication. In the last chapter, conclusions are drawn and the open points are discussed in order to be considered for future work. 199
1 (current)

General remarks regarding student theses

This page lists all student theses, on the one hand available ones and on the other hand already assigned or finished works. If you are interested in one of the topics, please contact the corresponding tutor whose contact information can be found in the staff section of our homepage. Of course, you are also free to suggest own topics which should be part of our general research and teaching foci.

The following thesis topics are not complete but rather examples of current topics. On the projects website you can find an overview of the research activities conducted in our institute. If you are interested in one of the general topics it should always be possible to create a mini project or master thesis topic. Just contact the accordant staff.

To help you working on your thesis, we compiled a few templates and general help files on a separate page , which includes LaTeX and Power Point templates.

Templates and help files

Student Theses

1 / 0 Elektrotechnische Projekte (BSc.)
1 / 0 Vertiefungsprojekte (BSc.)
1 / 1 Bachelor theses (BSc.)
7 / 14 Projects (MSc)
8 / 7 Master theses (MSc)
10 / 22 Overall

available / in progress

2002 2003 2004 2005 2006 2007 2008 2009 2010 2011 2012 2013 2014 2015 2016 2017 2018 2019 2020 2021 2022 2023 2024

International prospective students
Laurea Magistrale Programmes (equivalent to Master of Science)
Programme Catalogue

Telecommunication Engineering

Academic year: 2024/2025, programme duration: 2 years.

Milano Leonardo

Industrial and Information Engineering

Eligibility

A Bachelor Degree in a related field. Preference is accorded to graduates in Information Technology, Electrical Engineering, Computer Science and Computer Engineering. A solid background in Mathematics, Physics, Telecommunications disciplines, Computer Science, Electronics is requested.

Mission and goals

The Laurea Magistrale (equivalent to Master of Science) programme in Telecommunications Engineering features an advanced and innovative curriculum with multidisciplinary courses in the areas of internet services and applications, communication systems, multimedia signal processing, optical and radio technologies and remote sensing. Students can select five possible tracks (all taught in English): Networks; Communications; Signals; Technologies; Internet Engineering (the last one in cooperation with the Laurea Magistrale in Computer Science and Engineering); or define their personalized study program through a large set of available courses.

Five specialisations are available: Communication Networks and Internet; Data Communications; Signals and Data Analysis; Microwaves and Photonics; Internet Engineering (joint degree with Computer Science Eng.). Mandatory courses Traffic theory, Network design, Digital communications, Digital signal processing, Operations Resarch. Optional specialising courses Wireless Networks, Multimedia Internet, Internet of Things, Audio and video signals, Wireless systems, Antennas and propagation, Network security and cryptography, Radar and localisation systems, Optical Communications.

Career opportunities

Our graduates are engineers that are expert in the design of communication systems, in organizing and managing communication networks that are part of the big internet and in the defining and customizing communication services. Career opportunities are available not only in the traditional sector of Telecommunications (operators and manufacturers) but in many others for which the communication services are crucial (like finance, energy, production, public services, commerce, etc.).

Employment Statistics

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Know more about the programme through a current student’s experience . Book your online one-to-one meeting through #Askastudent – Our voice for your choice project.

Watch this video (in Italian) to know more about this programme.

Browse the programme website

Know more about the Tracks and courses and the Programme description

100 Best universities for Mechanical Engineering in Russia

Updated: February 29, 2024

Art & Design
Computer Science
Engineering
Environmental Science
Liberal Arts & Social Sciences
Mathematics

Below is a list of best universities in Russia ranked based on their research performance in Mechanical Engineering. A graph of 714K citations received by 136K academic papers made by 158 universities in Russia was used to calculate publications' ratings, which then were adjusted for release dates and added to final scores.

We don't distinguish between undergraduate and graduate programs nor do we adjust for current majors offered. You can find information about granted degrees on a university page but always double-check with the university website.

1. Moscow State University

For Mechanical Engineering

2. Tomsk State University

3. St. Petersburg State University

4. Bauman Moscow State Technical University

5. Ufa State Aviation Technical University

6. Peter the Great St.Petersburg Polytechnic University

7. Tomsk Polytechnic University

8. Ural Federal University

9. South Ural State University

10. National Research University Higher School of Economics

11. Moscow Aviation Institute

12. Novosibirsk State University

13. ITMO University

14. N.R.U. Moscow Power Engineering Institute

15. National Research Nuclear University MEPI

16. Kazan Federal University

17. National University of Science and Technology "MISIS"

18. Moscow Institute of Physics and Technology

19. Samara National Research University

20. Moscow State Technological University "Stankin"

21. Novosibirsk State Technical University

22. RUDN University

23. Southern Federal University

24. Saratov State University

25. Ufa State Petroleum Technological University

26. Samara State Technical University

27. Siberian Federal University

28. Kazan National Research Technical University named after A.N. Tupolev - KAI

29. Perm State Technical University

30. Omsk State Technical University

31. Saint Petersburg State Electrotechnical University

32. Moscow Polytech

33. Saint-Petersburg Mining University

34. Magnitogorsk State Technical University

35. Saratov State Technical University

36. Moscow State University of Railway Engineering

37. Lobachevsky State University of Nizhni Novgorod

38. Nizhny Novgorod State Technical University

39. Tula State University

40. Belgorod State Technological University

41. Far Eastern Federal University

42. Novgorod State University

43. belgorod state university.

44. Finance Academy under the Government of the Russian Federation

45. Moscow Medical Academy

46. Kazan State Technological University

47. Russian State University of Oil and Gas

48. siberian state aerospace university.

49. Tambov State Technical University

50. Voronezh State University

51. Siberian State Industrial University

52. Saint Petersburg State Institute of Technology

53. Kalashnikov Izhevsk State Technical University

54. St. Petersburg State University of Architecture and Civil Engineering

55. Mendeleev University of Chemical Technology of Russia

56. Murmansk State Technical University

57. South-Western State University

58. Ogarev Mordovia State University

59. Tomsk State University of Control Systems and Radioelectronics

60. south-russian state university of economics and service.

61. Perm State University

62. Kuzbass State Technical University

63. Russian National Research Medical University

64. Plekhanov Russian University of Economics

65. Ulyanovsk State Technical University

66. Ulyanovsk State University

67. Penza State University

68. Kuban State University of Technology

69. Polzunov Altai State Technical University

70. Chelyabinsk State University

71. Yaroslavl State University

72. University of Tyumen

73. National Research University of Electronic Technology

74. Leningrad State University

75. Moscow State Pedagogical University

76. Udmurt State University

77. Irkutsk State University

78. North-Eastern Federal University

79. Bashkir State University

80. Russian Presidential Academy of National Economy and Public Administration

81. Kuban State University

82. Kuban State Agricultural University

83. St. Petersburg State University of Aerospace Instrumentation

84. Kemerovo State University

85. Immanuel Kant Baltic Federal University

86. Orenburg State University

87. Baltic State Technical University "Voenmeh"

88. Tomsk State University of Architecture and Building

89. Chuvash State University

90. ivanovo state power university.

91. Irkutsk National Research Technical University

92. Orel State University

93. State University of Management

94. Tomsk State Pedagogical University

95. Volgograd State University

96. Petrozavodsk State University

97. Tver State University

98. Northern Arctic Federal University

99. Omsk State Transport University

100. Kaliningrad State Technical University

The best cities to study Mechanical Engineering in Russia based on the number of universities and their ranks are Moscow , Tomsk , Saint Petersburg , and Ufa .

Engineering subfields in Russia

Victor Mukhin

Scientific Program

Title : Active carbons as nanoporous materials for solving of environmental problems

However, up to now, the main carriers of catalytic additives have been mineral sorbents: silica gels, alumogels. This is obviously due to the fact that they consist of pure homogeneous components SiO2 and Al2O3, respectively. It is generally known that impurities, especially the ash elements, are catalytic poisons that reduce the effectiveness of the catalyst. Therefore, carbon sorbents with 5-15% by weight of ash elements in their composition are not used in the above mentioned technologies. However, in such an important field as a gas-mask technique, carbon sorbents (active carbons) are carriers of catalytic additives, providing effective protection of a person against any types of potent poisonous substances (PPS). In ESPE “JSC "Neorganika" there has been developed the technology of unique ashless spherical carbon carrier-catalysts by the method of liquid forming of furfural copolymers with subsequent gas-vapor activation, brand PAC. Active carbons PAC have 100% qualitative characteristics of the three main properties of carbon sorbents: strength - 100%, the proportion of sorbing pores in the pore space – 100%, purity - 100% (ash content is close to zero). A particularly outstanding feature of active PAC carbons is their uniquely high mechanical compressive strength of 740 ± 40 MPa, which is 3-7 times larger than that of such materials as granite, quartzite, electric coal, and is comparable to the value for cast iron - 400-1000 MPa. This allows the PAC to operate under severe conditions in moving and fluidized beds. Obviously, it is time to actively develop catalysts based on PAC sorbents for oil refining, petrochemicals, gas processing and various technologies of organic synthesis.

Victor M. Mukhin was born in 1946 in the town of Orsk, Russia. In 1970 he graduated the Technological Institute in Leningrad. Victor M. Mukhin was directed to work to the scientific-industrial organization "Neorganika" (Elektrostal, Moscow region) where he is working during 47 years, at present as the head of the laboratory of carbon sorbents. Victor M. Mukhin defended a Ph. D. thesis and a doctoral thesis at the Mendeleev University of Chemical Technology of Russia (in 1979 and 1997 accordingly). Professor of Mendeleev University of Chemical Technology of Russia. Scientific interests: production, investigation and application of active carbons, technological and ecological carbon-adsorptive processes, environmental protection, production of ecologically clean food.

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Top 10 Latest Telecommunication Thesis Topics [Research Ideas]
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Master of Science in Telecommunications and Networking
Thesis credits taken prior to the approval of the M-2 form will not count toward the minimum 6 credits of the master's thesis. Thesis Defense. The master's thesis must be a written account of a critical and scholarly study in an area in computer science. The Thesis Committee will review it critically for both content and form.
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The telecommunications engineering technology program requires 33 credit hours of study and includes eight core courses that introduce essential fundamental concepts and skills. Students are required to complete a comprehensive exam, a capstone project, or a thesis. The remaining credits consist of technical electives or other approved graduate ...
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This is a preliminary list of updated generic research topics that are available for the students: Collaborative signal processing in Networks. Decentralized, Self-Organized and Adaptive Communications. Communication Algorithms and Protocols for Wireless Sensor Networks. Software Architectures for Wireless Sensor Networks.
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School of Electrical and Electronic Engineering, 2021) The usage of various wireless standards, such as Bluetooth, Wi-Fi, GPS, and 4G/5G cellular, has been continually increasing. In order to utilize the frequency bands efficiently and to support new communication standards with lower power consumption, lower occupied volume and at reduced ...
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PDF Istanbul Technical University Graduate School of Science Engineering
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Student Theses
The following thesis topics are not complete but rather examples of current topics. On the projects website you can find an overview of the research activities conducted in our institute. If you are interested in one of the general topics it should always be possible to create a mini project or master thesis topic. Just contact the accordant staff.
Telecommunication Engineering: polimi
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