Thesis
Thesis info for Cyber Security students
Important Deadlines for January 2023 Defence
- Submission of problem statement and research design document: 22 August 2022
- Submission of the thesis to the reviewer: 12 December 2022
- OIS declaration: 12 December 2022
- Submission of the final version of the thesis: 3 January 2023
- Defences: 12 / 13 January 2023
Moodle: https://moodle.taltech.ee/course/view.php?id=32344
Important Deadlines for May/June 2023 Defence
- Submission of problem statement and research design document: 12 December 2022
- Submission of the thesis to the reviewer: 17 April 2023
- OIS declaration: 8 May 2022
- Submission of the final version of the thesis: 15 May 2023
- Defences: 29-31 May, 1 June 2023
Moodle: https://moodle.taltech.ee/course/view.php?id=32451
Thesis Defence Overview
Writing and defending an MSc thesis is an important part of the Cyber Security curriculum, as it shows that you can go deep into a specific cyber security research area. This page gives a rough overview of the process, but details should be discussed with your supervisor. This overview part is given according to the assumption that you are following a 4-semester study plan and aim to defend in the May period. If you want to defend in January, then you can adjust the planning phases accordingly.
Generally, the process should start during the first year, by finding a topic-area of interest and by identifying a suitable supervisor. At the end of the second semester, it is highly recommended to have an idea about your topic and have discussed this with your supervisor.
In early December, you should submit a problem statement and research design document (please, find the details, below). Sending this document is considered as a registration to the defence that will take place in next term.
The next step in the process would be conducting the research. As the thesis submission deadline is around the third week of April (for students aiming to defend in January, this deadline is early December), please, plan to finish your work early April, so that your supervisor can review your thesis, give you feedback and you have time to address the feedback before your thesis is being sent to the reviewer/opponent. Jointly with your supervisor, you should then make a decision if your work is ready to be submitted for May defence (or if you need more time and prefer to submit for a January defence). The reviewer will review your thesis and give you feedback. Expect that you should receive the review about a week before the final deadline. You can continue to update your work until the final submission date. You can and should, however, incorporate the review feedback into the final copy of your thesis and defence presentation. This will allow you to make modifications, e.g., fix some typos or clarify some sections, which the reviewer pointed out.
At the final submission deadline, you will have to submit your thesis. On the day of defence, you are expected to give a 15-minute presentation of your work, followed by Q&A from the opponent, committee, supervisor & audience. Make sure you prepare your 15-minute presentation well, this should not be left for the evening before the defence.
Below some more detailed information.
Good luck!
Registration and submission of problem statement and research design document
Each student is required to submit a problem statement and research design document having a length up to 10 pages. The document must include your name and also the names of thesis and supervisor (and co-supervisor if exists).
About half a year before the defence, the students are required to indicate their intent to defend by this document. See deadlines above set for each semester. Typically this will be around Early December for May defences and Mid June for January defences. You will need to submit this via the TTU Moodle link given in "important deadlines" section of relevant defence period. You'll have to self-enrol yourself in that link. Feedback on the problem statement and research design document should be received within 3-4 weeks via the email account that you defined in TTU Moodle.
The document should include the following sections and content:
• The topic of the thesis
• The name of the author
• The name of the supervisor
• Motivation: An overview of the addressed problem is given here. It should be explained why the problem is important and deserves a research study.
• Research Problem/Hypothesis/Question: It is imperative to write a proper research problem/hypothesis/question statement(s).
• Scope and Goal: This section defines the goal of the study and describes the main outcomes. It is required to specify the scope, limitations and key assumptions of the study.
• Literature Review: This section includes the analysis of similar studies in the literature and gives a discussion of the research gap. It is important to link this research gap explanation with the research problem.
• Novelty: This section justifies the novelty of your study, explains what the main contribution is and what the differences are when compared to similar studies.
• Research Methods: The research methods that you will apply in your study are given here. The data collection and analysis methods are also covered in this section. It is needed to explain how your research outcome will be validated.
• References: The resources referenced in the document are listed here.
This document is evaluated according to the following criteria:
Whether the author
• has a well-defined problem statement,
• successfully presents the significance of the problem,
• knows the literature and the limits of existing solutions,
• have thought about possible methods,
• have thought about how to validate the proposed solution,
• brings a novelty to the literature.
You can find detailed information about research methods here.
Submission to Reviewer
Each thesis will be assigned a reviewer or sometimes called opponent. The reviewer must have at least a Master's degree and relevant knowledge or experience in the field of the thesis topic, and they must not have a conflict of interest (such as being members in the same research group). Students and supervisor may recommend reviewer candidates, but the final assignment will be done by the thesis defence committee.
A reviewer will provide written feedback (typically about two pages) on the thesis. The review should cover the following points:
- short description of the thesis
- strengths and weaknesses of the thesis
- recommended grade (0-5, where 0 is a failing thesis and 5 is an excellent thesis) based on the clarity of the problem and the solution, complexity of the problem, suitability of the chosen solution, proper execution of the solution, and the proper formatting and language use in the thesis.
- at least three questions that can be asked during the defence.
Based on the student's performance at the defence the reviewer may change the recommended grade.
The reviewer will receive a copy of the thesis about two-three weeks before the final/hard university deadline for submitting the thesis. The reason for this is that typically reviewers point out the typos and small factual mistakes that can be fixed in short time (about a week). The student will receive the review one week before the final submission deadline and therefore is able to address some of the comments before submitting the final version. The student can also still decide not to submit the thesis this round, but rather work on improving the quality and then submit an improved version in the next defence period.
OIS declaration
Before a student can proceed to the thesis defence, they have to declare the thesis topic in OIS and get approval from their supervisor. Please pay careful attention to the OIS declaration deadline, as without this you will not be permitted to attend the defence. If you will defend your thesis in Tartu University, then you should do your OIS declaration to their systems according to their deadlines.
OIS declaration deadlines can be found in the Academic Calendar!
Submission of Final Copy
Each student will submit the pdf version of the thesis, the relevant thesis metadata and licence information via moodle course page link given in "important deadlines" section of relevant defence period. Please complete the steps 1, 2 and 3 of the thesis submission on this page.
In addition to submission of above materials via Moodle, one paper copy of your thesis will be collected before defence, which you will get back after defence. The details will be announced one or two weeks before the deadline.
If you will defend your thesis in Tartu University, then you should submit final copy according to the procedures and deadlines of Tartu University.
NB! Do not forget that you need to prepare a 15 min presentation for your defence. This should really not be left to the evening before the defence!
The defence procedure
On the day of defence, students will present their theses according to the announced schedule. Generally, the results will be announced at the end of the day.
The defence procedure for each student consists of the following steps:
- the committee Chairman announces the name of the student, the topic of the thesis, and the names of the supervisor(s) and reviewer.
- the student presents his or her thesis in 15 minutes.
- the student answers the reviewer's questions and the reviewer recommends a grade. This recommendation may differ from the preliminary recommendation, based on how successful the defence was.
- the student answers questions from the committee.
- the student answers questions from the audience.
- the supervisor gives his or her opinion of the thesis and recommends a grade.
NB! The recommended grades by the reviewer and the supervisor are not binding to the committee, who makes the final decision.
- After the thesis defence, please visit the Dean's Office for more information about final formalities.
- Upload your thesis if you would like to have it public
Formal Requirements and recommendations
Until further notice, please use the formatting guide from the School of Information Technologies (link to the guide is given here). Please note that you will have to change the title page as of 01.01.2017:
- write "School of Information Technology" instead of "Faculty of Information Technology"
- write "Department of Software Science" instead of "Department of Computer Engineering".
The thesis code for IVCM is ITC70LT.
The following advices can be considered for a master thesis
- a title page, an author declaration, an annotation in English and Estonian, a list of contents, and references are required in the thesis
- 50-80 pages + appendices if needed
- Times New Roman (or similar), font size 12, 1.5 spacing used for the ordinary text
- Headings are numbered and no more than 3 levels used
- Don't forget page numbers
Topic and supervisor
Every student must have a supervisor when writing the thesis. The supervisor's role is to provide guidance on topic selection and research methods, as well as to give feedback on your work. It is not the supervisor's duty to correct spelling mistakes or formatting errors - they may point such things out, but the responsibility remains with you. Before a thesis will be accepted for defence, the supervisor has to agree that it is of sufficient quality.
Almost any professor and lecturer you have met in your curriculum can act as an supervisor of your thesis. Some of them have some open problems suitable for doing research and writing a thesis, but many may not have a topic to offer right away. It is usually more helpful to have an initial idea of a topic of your thesis and ask someone with interests in the related field to advise you. You can have a supervisor not related to the university, but he can act only as a co-supervisor and you need to agree to somebody related to the curricula or the leading institute of the curriculum to be an official co-supervisor. All (co-)supervisors must have at least a Master's degree.
When refining a topic idea, make sure it has a clear connection with cyber security.
NB! Theses supervised by supervisors from the University of Tartu (UT) have to be defended in UT. Exceptions are possible, but need do be approved by the program manager.
If you will defend your thesis in UT, then you should do your thesis declaration according to the procedures and deadlines of UT. Thesis related guidelines and regulations are available at: https://cs.ut.ee/en/content/thesis-deadlines-and-guidelines In case of any questions contact UT Institute of Computer Science Academic Affairs Specialist Maarja Kungla (maarja.kungla@ut.ee).
Potential supervisors & proposed topics
The topics below are offered by potential (co-)supervisors (in alphabetical order). The list is updated as new offers emerge.
From Marko Arik, Industry PhD student, Talgen Cybersecurity Ltd. maarik@ttu.ee
- Cyber Operations
- Informational Environment
- Individual competences in Cyber
- GNSS jamming and spoofing of the unmanned vehicles
From Hayretdin Bahsi, Tallinn University of Technology, hayretdin.bahsi@taltech.ee
I am interested in various topics which can be categorized as technical and organizational. If you already have specific topics in your mind, we can discuss them and decide to work together.
Technical Topics
- Application of machine learning and data mining methods to the following cyber security problems: Malware detection, botnet identification, code security review, intrusion detection in cyber-physical systems, IoT network or robotic systems
- Cyber security of IoT, cyber-physical systems: Development of a security testbed, threat modelling, honeypots, intrusion detection systems
- Digital Forensics: Forensics issues in cyber-physical systems, IoT networks or robotics systems, mobile forensics, blockchain forensics
Organizational Topics
- Security operation center (SOC) models
- Case studies for the improvement of SOC processes such as threat monitoring, incident handling, vulnerability management or situational awareness
From Aivo Kalu, Cybernetica AS
1. Comparison of identity/authentication/signing APIs from security and architecture viewpoint
This might be suitable for student, who is more interested about software developing/architecture aspects, but still related to security as well. In short, there are many competing API-s in the Baltic/Nordic region, which are used in practice, to request the authentication or signatures. For example:
- https://github.com/SK-EID/smart-id-documentation/blob/master/README.md
- https://github.com/SK-EID/MID
- https://developers.dokobit.com
- https://developer.signicat.com/apis/sign-api/sign-api-v1/
- https://github.com/open-eid/SiGa/wiki/Hashcode-API-description
and also, there are the “canonical” or “standard" ones like OIDC and SAML and DSS (http://docs.oasis-open.org/dss/v1.0/oasis-dss-core-spec-v1.0-os.html). Which one is good? Which one has the best properties from software point of view or security point of view? Which one to use for future integrations? How do we even compare them?
2. Apply Smart-ID authentication and digital signatures (or underlying SplitKey technology) in novel bitcoin/blockchain/SSI/DID use cases.
For example, last year, there was the master thesis https://www.semanticscholar.org/paper/Aleksandr-Ts%C3%B5ganov-Integrating-User-Identity-with-Ts%C3%B5ganov-Pintado/30c653214f5a30ed46343058039d4b53a8d326f9?utm_source=email.
If there’s some additional ideas, about where to apply the Smart-ID authentication services or perhaps to do more deeper integration with the SplitKey technology, we could discuss and see, if some interesting project might come out of this.
3. Compare the attack model of the FIDO with the attack model of Smart-ID.
The current Smart-ID authentication API (https://github.com/SK-EID/smart-id-documentation/blob/master/README.md) specifies how the anonymous session with the web-site becomes the authenticated session. Compare the security properties of this authentication flow with https://www.w3.org/TR/webauthn-2/ and https://fidoalliance.org/specs/fido-v2.0-id-20180227/fido-security-ref-v2.0-id-20180227.html
4. Compare the properties of Smart-ID with framework by Bonneau et al.
Take the https://www.cl.cam.ac.uk/~fms27/papers/2012-BonneauHerOorSta-password--oakland.pdf and the properties described there and analyse, which ones are satisfied by Smart-ID, which ones are not satisfied, which ones are already pointless in the year 2020. Compare with http://fc16.ifca.ai/preproceedings/25_Lang.pdf, which does the same kind exercise for FIDO in the section 6.1.
From Jüri Kivimaa, Tallinn University of Technology
- IT security economics
- security cost optimization
From Shaymaa Khalil, TalTech
Interested in (but not limited to) topics related to:
- Industrial Control Systems: threat modeling, security, testbeds for education, penetration testing and digital forensics
- Digital forensics related topics, especially topics related to IoT, Windows OS and Digital Forensics tools benchmarking
From Toomas Lepik, Tallinn University of Technology
toomas.lepik@taltech.ee
General areas:
- Network Forensic (related data analysis)
- Reverse engineering (including malware analysis)
- SCADA security
- Incident Handling.
- Log Analysis
Specific ideas:
- Implications of DOH on security and availability + next step from https://www.netmeister.org/blog/doh-dot-dnssec.html
- Domain name availability and how DNS registrant and registrar policy changes affect cybercrime
- Heuristics on ip leasing operations
- Defending organization that does not have internal network
- Do applications do what they promise
- Identifying specific applications based network fingerprints
- Evaluation log collecting methods for Microsoft networks considering log poisoning attacks
- Log collecting frameworks for organisations without internal networks
- Information attributes and their influence on the organisational security beyond CIA
- Frame works for cybersecurity devices / software evaluation
- Evaluation specific software /hardware using ATT&CK Framwork
- ATT&CK -Descriptions and false positives
- Anatomy of cyber fractions during the Russian-Ukrainian war
- Forensic Leaked materials of cyber criminal groups.
- ...
From Birgy Lorenz, Tallinn University of Technology
birgy.lorenz@ttu.ee
- human factors in cybersecurity
- cyber awareness and training (kindergarten, schools, laypersons)
- cybersecurity young talents skills and its development and testing
- women in cybersecurity
From Kaie Maennel, Tallinn University of Technology
(kaie.maennel@ttu.ee)
- cyber awareness and hygiene
- cyber security learning and teaching (e.g., serious games, cyber defense exercises, etc.)
- learning analytics in cyber security training context
- human factors in cyber security
- cybersecurity risk assessment and management
- IT and cybersecurity audits
From Olaf Maennel, Tallinn University of Technology, olaf.maennel@ttu.ee
- Network security & network measurements (active & passive)
- WAN-routing & security (IPv6, BGP/BGPsec,...)
From Sten Mäses, Tallinn University of Technology
- Creating educational hands-on virtual labs in rangeforce.com platform
From Andrew Roberts, Tallinn University of Technology
Topics: 1. Evaluation of Methods for Threat and Risk Assessment of Autonomous Self-Driving Vehicles 2. Design and Development of a cyber range for Autonomous self-driving vehicles Contribution:
Topic 1: The outcome of this work will form part of TUT contribution to standards and methods research within the International Alliance for Mobility Testing and Standardisation (IAMTS).
Topic 2: The developed cyber range will be integrated into the EU ECHO-Federated Cyber Range.
From Anna-Maria Osula, Tallinn University of Technology
- legal aspects of cyber security
- international law
From Rain Ottis, Tallinn University of Technology
- national cyber security
- serious games in cyber security/cyber security exercises
From Mauno Pihelgas NATO CCDCOE
- system and network monitoring
- observability and situation awareness
- IDS/IPS systems
- automating cyber defences
From Jaan Priisalu, Tallinn University of Technology
- TBD
From Matthew Sorell, Tallinn University of Technology / Adelaide University Australia
Matthew James Sorell <matthew.sorell@taltech.ee>
1. A risk-based decision approach for handling digital devices at a crime scene.
It is common for electronic devices such as mobile phones to be discovered at a crime scene, but the means for securing the device is becoming increasingly complex. In spite of this, evidence handling procedures are often static and increasingly out of date, leading to the loss of critical evidence in serious crime.
The phone may be remotely wiped; picking it up may activate motion sensors; and in some cases (such as missing persons) the urgency of the evidence needs to be weighed against securing forensic evidence for investigation and prosecution.
In this research, we consider the development of a risk-based approach to advising crime scene investigators to handle digital devices in the least-worst way.
2. Feasible route mapping
When examining timestamped geolocation data, it is often useful to determine feasible routes which could be taken from one location to another.
Google Maps, for example, provides directions and sometimes provides a small number of alternatives. For criminal investigation, a heatmap of feasible routes would support investigators with a means to rapidly evaluate the context of movement in and around a crime.
In this project, we propose to use the Google Maps Platform (https://developers.google.com/maps/gmp-get-started) to build, through statistical sampling, a heatmap of feasible routes subject to time and modes-of-transportation constraints.
From Tiia Sõmer, Tallinn University of Technology
Currently no topics on offer.
From Stefan Sütterlin, Tallinn University of Technology & Østfold University College
(stefan.sutterlin@hiof.no)
- cognitive science and performance in cyber defence
- human factors in cyber security
- cyberpsychology
- decision-making
- cognitive biases
- cybersecurity awareness
From Eneken Tikk, Tallinn University of Technology
- Technical and organizational implementation of the GDPR
- Monetization of personal data
- Economics of cybersecurity (the cost of implementation relative to the anticipated and evidenced gains)
- Cyber insurance
- Non-military strategies for national and international cybersecurity
- Legal aspects of cybersecurity
From Risto Vaarandi, Tallinn University of Technology
Here are potential areas for selecting a thesis topic:
- event log collection
- event log analysis
- event correlation
- network monitoring
- intrusion detection
- data mining methods for security monitoring
- machine learning methods for security monitoring
- any area that is connected to security monitoring
- various other system security engineering topics (for example, system hardening or firewalling)
When applying for supervision, preference is given to students who have either passed the Cyber Defense Monitoring Solutions course with grade 4 or 5, or have previous engineering experience in the research area (for example, writing a thesis on network intrusion detection requires previous experience with network IDS systems). Before applying, make sure you have selected at least one initial thesis topic suggestion with a background research about its validity.
From Adrian Venables, Tallinn University of Technology
- Cyber security aspects of Information Warfare
- Strategic Communications doctrine development
- Information Operations doctrine development
- Influence Operations in the Digital Information Environment
Note: a background in International Relations, Political Science or Strategic Studies is required
From Gabor Visky, NATO CCDCOE / TalTech
Gabor Visky <gabor.visky@ccdcoe.org>
- Network traffic analysis in the maritime cyber-lab
From Mohammad Reza Kave Salamatian, Tallinn University of Technology
- Digital twin for maritime cybersecuirty
Virtual (model-based) techniques, coined as digital twin are nowadays common tools to design, monitor and evaluate cyber-physical systems. A digital twin is defined as a virtual representation of a physical asset enabled through data and simulators for real-time prediction, monitoring, control and optimization of the asset for improved decision making throughout the life cycle of the asset and beyond.
Digital twins mirror a real-world system and let designers and engineers to examine in realistic detail how different conditions, operational but also resulting from cyber-event, will affect it. Digital twin enable to stress-test cyber-physical systems, and the vulnerabilities and capabilities of security controls on computing environments, i.e., attack a live twin of the original system or environment — without putting data or productivity. Digital twins are therefore major component in cybersecurity of cyber-physical systems. The aim of this master thesis proposal is to develop digital twin model of a maritime drone and to use it for cybersecurity assessment of the autonomous navigation of this drone.
The project will involve experimental work with drone, software development and cybersecurity offensive approaches. This master thesis might be continued by a PhD scholarship.
Bibliography-
-K. M. Alam and A. El Saddik, "C2PS: A Digital Twin Architecture Reference Model for the Cloud-Based Cyber-Physical Systems," in IEEE Access, vol. 5, pp. 2050-2062, 2017, doi: 10.1109/ACCESS.2017.2657006.
-Eckhart, Matthias, and Andreas Ekelhart. "Digital twins for cyber-physical systems security: State of the art and outlook." Security and quality in cyber-physical systems engineering(2019): 383-412.
-Pang, Toh Yen, et al. "Developing a digital twin and digital thread framework for an ‘Industry 4.0’Shipyard." Applied Sciences 11.3 (2021): 1097.
-Alcaraz, Cristina, and Javier Lopez. "Digital Twin: A Comprehensive Survey of Security Threats." IEEE Communications Surveys & Tutorials (2022).
- Root Cause Analysis
Description- Maritime systems are evolving to be more intelligent and connected, and thus cybersecurity has become a big concern for the maritime domain and raises new and challenging issues. Thus, we need to detect, understand, and respond to a wide and unknown variety of cyberattacks and dysfunctions. Nowadays, Cybersecurity Maritime Situational Awareness is based on indicators, metrics, data collected from sensors and alarms. Currently it’s not possible to fully understand the root causes of all the potential cybersecurity events. One of the main reasons is because only the consequences of those events are directly experienced or observed. For example, we can know that the GNSS (Global Navigation Satellite System) position has been lost because of an ECDIS’s (Electronic Chart Display and Information System) alert, but we cannot determine if the cause is a jamming attack or an internal dysfunction or if the ship is in a white zone. Also, a single dysfunction can trigger numerous alarms making difficult to understand the situation.
Root cause analysis (RCA) is a technique that looks for the origin of an actual problem, applying a methodological approach to determine how it is produced, by differentiating the causal factors. RCA in maritime cybersecurity incidents will be helpful to SIEMs (Security Information & Event Management) to aggregate events, produce pertinent responses, and provide initial feedbacks and explanations that will help the crew and cybersecurity experts to make the right decisions. To achieve this goal, SIEMs should consider Information Technology (IT) and Operational Technology (OT) maritime systems, transmission bandwidth, known vulnerabilities, past incidents in the maritime domain, and adapted risky situations in operational conditions, among others.
The proposed thesis topic is directly related to security of cyber physical systems for ships through RCA. It will address the following research questions:
- Cartography of existing alarms and indicators that participate in a maritime cyber-crisis scenario.
- Define adapted event aggregation and propagation strategies.
- Establish the function of knowledge representation about technical infrastructure components and its integration to the model.
- Define security strategies based on RCA.
- Combine defined indicators with existing standards as the NMEA protocol [11] or S-100 cartography [12].
- Develop, verify, and test a tool using the cyber-attack scenarios, to experiment if the defined model can contribute to enhance operators’ reactions and/or be used in training.
This topic
Bibliography [1] Andersen, B., & Fagerhaug, T. (2006). Root cause analysis: simplified tools and techniques. Quality Press. [2] Hellesen, N., Torres, H., & Wangen, G. (2018). Empirical case studies of the root-cause analysis method in information security. International Journal On Advances in Security, 11 (pp. 26-33). [3] Baalisampang, T., Abbassi, R., Garaniya, V., Khan, F., & Dadashzadeh, M. (2018). Review and analysis of fire and explosion accidents in maritime transportation. Ocean Engineering, 158, 350366. [4] Kececi, T., & Arslan, O. (2017). SHARE technique: A novel approach to root cause analysis of ship accidents. Safety science, 96, 1-21. [5] Barnett, M. L. (2005). Searching for the root causes of maritime casualties. WMU Journal of Maritime affairs, 4(2), 131-145. [6] Parra Jimenez, M. F. Application of Root Cause Analysis in Marine Accident Investigation: Case Study SMIT Transport & Heavy Lift Europe, Master of Science thesis, Erasmus University Rotterdam, 2010. [7] Advanced database of maritime cyber incidents. URL: https://gitlab.com/m-cert/admiral/ [8] Bahrami, P. N., Dehghantanha, A., Dargahi, T., Parizi, R. M., Choo, K. K. R., & Javadi, H. H. (2019). Cyber kill chain-based taxonomy of advanced persistent threat actors: Analogy of tactics, techniques, and procedures. Journal of information processing systems, 15(4), 865-889. [9] Adversarial Tactics, Techniques, and Common Knowledge. URL: https://attack.mitre.org/ [10] Zhao, H., & Silverajan, B. (2020, October). A Dynamic Visualization Platform for Operational Maritime Cybersecurity. In International Conference on Cooperative Design, Visualization and Engineering (pp. 202-208). Springer, Cham. [11] National Marine Electronics Association (NMEA). URL: https://www.nmea.org/ [12] S100 project. URL: https://iho.int/fr/s100-project
From Kaido Kikkas, Tallinn University of Technology, IT College. kaido.kikkas@taltech.ee
- Cyber security risks in telepresence robotics and their mitigation (practical experimenting is possible at IT College; see [1]
- Cyber security lessons from the COVID-19 pandemic (incl. surveys in Estonia)
- Evolution of Cyberwar (Estonia 2007, Georgia 2007, Ukraine 2014/2022
- Total defence in cyberspace (might try to suggest a strategy for Estonia)
- Specific traits of cyber capabilities in totalitarian societies
Some more possible keywords to spark Thesis topic ideas:
(e-)learning/training, FLOSS/Linux, smart devices, IoT, social engineering, usability/accessibility vs security/privacy
Also might study cyber counterparts to (legal) self-defence and citizen's arrest
From the TalTech IT office
- Security implications in Migrating Taltech Campus LAN to IPv6; Toomas Lepik
- Improving SOC and Information security processes; Toomas Lepik
- Auditing Taltech EITS compliance based on public information; Toomas Lepik
- Improving Log analysis pipelines; Toomas Lepik
From the University of Tartu
NB! Theses supervised by supervisors from the University of Tartu (UT) have to be defended in UT. Exceptions are possible, but need do be approved by the program manager. If you will defend your thesis in UT, then you should do your thesis declaration according to the procedures and deadlines of UT. Thesis related guidelines and regulations are available at: https://cs.ut.ee/en/content/thesis-deadlines-and-guidelines In case of any questions contact UT Institute of Computer Science Academic Affairs Specialist Maarja Kungla (maarja.kungla@ut.ee).
Cybersecurity-related research in the University of Tartu is conducted by the following persons:
- Arnis Paršovs, University of Tartu, <arnis.parsovs@ut.ee>
- Danielle Morgan, University of Tartu, <danielle.morgan@ut.ee>
- Alo Peets, University of Tartu, <alo.peets@ut.ee>
- Dominique Unruh, University of Tartu, <dominique.unruh@ut.ee>
- Vitaly Skachek, University of Tartu, <vitaly.skachek@ut.ee>
- Mubashar Iqbal, University of Tartu, <mubashar.iqbal@ut.ee>
- Abasi-Amefon Obot Affia, University of Tartu, <amefon.affia@ut.ee>
- Mari Seeba, University of Tartu, <mari.seeba@ut.ee>
- Sabah Suhail, University of Tartu,
- Raimundas Matulevicius, University of Tartu, <raimundas.matulevicius@ut.ee>
Some topics are provided at <https://infosec.cs.ut.ee/Main/ThesisTopics>.
For other topics, students can contact directly the supervisors and course lecturers.
A full list of thesis topics offered by the Applied Cyber Security Group (UT)
is available in the thesis topics database.
Students can also get access to various hardware that can be used for research experiments.
From Estonian Police
- Vaatlustarkvarade EnCase ja Autopsy võrdlus (selgituseks, et Autopsy on EnCase analoog, kuid tasuta. Vajalik oleks täpne analüüs, et mida Autopsy võimaldab ja mida mitte võrreldes EnCase ja/või FTKga).
- Erinevate suhtlustarkvarade (WhatsApp, Viber, FB Messenger, Skype jt) jäljed mobiiltelefonides ja nende analüüsimine (selgituseks, et üldjuhul loovad suhtlustarkvarad mingi andmebaasi vestlustega ka telefoni, kas see on krüpteeritud või mitte? Osad vestlused XRY tuvastab, aga millistel juhtudel? Millised võimalused oleks neid faile nö käsitsi uurida?).
- Tõendiahela kirjeldamine elektrooniliste tõendite fikseerimisel (chain of custody)/Elektroonilise sisu erikohtlemine asitõendi vaatlusel/Digitaaltõendite vaatluse kord – erinevate riikid analüüs ja võrdlus.
- P2P võrkudes lastest ebasündsate piltide levitajate tuvastamine/P2P võrkudes illegaalse internetisisu levitajate tuvastamine.
- Koolituskava väljatöötamine uurijale/menetlejale, kes puutub kokku digitaalsete tõenditega- erinevate riikide praktika võrdlus.
- Ask Rain Ottis for a POC on these topics.
Useful links
Format requirements of a thesis and MS-Word Template (TalTech)
LATEX template for master thesis (TalTech) (accessible by UNI-ID)
Databases, books, research papers accessible from the TTU network