Bachelor's theses of year 2021
Theses and projects (PhD, MSc, BSc, Project)
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Dokumentation von Softwaresystemen am Beispiel von WebMaDa.
7
2021.
BibTeX Entry
@misc{uvar21, author = {Dmitry Uvarov}, title = {{Dokumentation} von {Softwaresystemen} am {Beispiel} von {WebMaDa}}, year = {2021}, key = {uvar21}, month = {7}, school = {Ludwig-Maximilians-Universität München}, supervisors = {Corinna Schmitt and Jan Schmidt}, type = {Bachelorthesis}, } -
Comparison of auditory virtual humans and audiovisual virtual humans.
9
2021.
BibTeX Entry
@misc{maie21, author = {Patricia Maier}, title = {{Comparison} of auditory virtual humans and audiovisual virtual humans}, year = {2021}, key = {maie21}, month = {9}, school = {Ludwig-Maximilians-Universität München}, supervisors = {Daniel Kolb and Fabio Genz}, type = {Bachelorthesis}, } -
Portierung und Optimierung der NAS Parallel Benchmarks in OpenCL für FPGAs.
4
2021.
BibTeX Entry
@misc{schm21, author = {Jakob Schmid}, title = {{Portierung} und {Optimierung} der {NAS} {Parallel} {Benchmarks} in {OpenCL} für {FPGAs}}, year = {2021}, key = {schm21}, month = {4}, school = {Ludwig-Maximilians-Universität München}, supervisors = {Pascal Jungblut}, type = {Bachelorthesis}, } -
Trustworthiness Check of Environmental Measurements on CoMaDa.
2
2021.
BibTeX Entry
@misc{pfef21, author = {Philipp Pfefferkorn}, title = {{Trustworthiness} {Check} of {Environmental} {Measurements} on {CoMaDa}}, year = {2021}, key = {pfef21}, month = {2}, school = {Ludwig-Maximilians-Universität München}, supervisors = {Corinna Schmitt}, type = {Bachelorthesis}, } -
Adversarial Malware Generation using Reinforcement Learning.
3
2021.
BibTeX Entry
@misc{fran21, author = {Sebastian Franz}, title = {{Adversarial} {Malware} {Generation} using {Reinforcement} {Learning}}, year = {2021}, key = {fran21}, month = {3}, school = {Ludwig-Maximilians-Universität München}, supervisors = {Raphael Labaca Castro and Christian Mailer (Iteratec GmbH)}, type = {Bachelorthesis}, } -
Vergleich zweier Frameworks für Informationssicherheitsmanagementsysteme in kommunalen Einrichtungen.
3
2021.
BibTeX Entry
@misc{wieg21, author = {Maximilian Wiegand}, title = {{Vergleich} zweier {Frameworks} für {Informationssicherheitsmanagementsysteme} in kommunalen {Einrichtungen}}, year = {2021}, key = {wieg21}, month = {3}, school = {Ludwig-Maximilians-Universität München}, supervisors = {Stefan Metzger}, type = {Bachelorthesis}, } -
Spacecraft Operator Scheduling with Grovers Algorithm.
1
2021.
PDF
Abstract
The application of quantum algorithms on some problems in NP promises a significant reduction of time complexity. This thesis uses Grover's Algorithm, originally designed to search an unstructured database with quadratic speedup, to find valid solution bit-strings to the NP-hard personnel scheduling problem. Under consideration of various hard and soft constraints, we implement this by using the IBMQ backend and Qiskit to optimize the German Aerospace Center's spacecraft on-call operator scheduling. We seek an optimal assignment for 52 operators to 17 positions over a period of 180 days under constraints on schedule and personnel. Further, we evaluate the solution quality and compare the performance with classical and quantum alternatives. While still restricted by intermediate-scale quantum devices in the near term, we explore new approaches in encoding and batching the problem to reduce the required number of qubits. In the end, a feasible near-term solution that scales well with the quantum devices of the upcoming years is presented.BibTeX Entry
@misc{sche21, author = {Antonius Benedikt Anani Scherer}, title = {{Spacecraft} {Operator} {Scheduling} with {Grovers} {Algorithm}}, year = {2021}, pdf = {https://bib.nm.ifi.lmu.de/pdf/sche21.pdf}, abstract = {The application of quantum algorithms on some problems in NP promises a significant reduction of time complexity. This thesis uses Grover's Algorithm, originally designed to search an unstructured database with quadratic speedup, to find valid solution bit-strings to the NP-hard personnel scheduling problem. Under consideration of various hard and soft constraints, we implement this by using the IBMQ backend and Qiskit to optimize the German Aerospace Center's spacecraft on-call operator scheduling. We seek an optimal assignment for 52 operators to 17 positions over a period of 180 days under constraints on schedule and personnel. Further, we evaluate the solution quality and compare the performance with classical and quantum alternatives. While still restricted by intermediate-scale quantum devices in the near term, we explore new approaches in encoding and batching the problem to reduce the required number of qubits. In the end, a feasible near-term solution that scales well with the quantum devices of the upcoming years is presented.}, key = {sche21}, month = {1}, school = {Ludwig-Maximilians-Universität München}, supervisors = {Tobias Guggemos and Sophia Grundner-Culemann and Sven Prüfer (DLR) and Andreas Spörl (DLR)}, type = {Bachelorthesis}, } -
Comparison of virtual reality social platforms under the aspect of digital teaching.
4
2021.
BibTeX Entry
@misc{fuch21, author = {Niklas Fuchs}, title = {{Comparison} of virtual reality social platforms under the aspect of digital teaching}, year = {2021}, key = {fuch21}, month = {4}, school = {Ludwig-Maximilians-Universität München}, supervisors = {Daniel Kolb and Fabio Genz}, type = {Bachelorthesis}, } -
Angriffserkennung auf Layer2/3 in WLAN-Netzen des Münchner Wissenschaftsnetzes.
5
2021.
BibTeX Entry
@misc{rink21, author = {Tim Rinke}, title = {{Angriffserkennung} auf {Layer2/3} in {WLAN-Netzen} des {Münchner} {Wissenschaftsnetzes}}, year = {2021}, key = {rink21}, month = {5}, school = {Ludwig-Maximilians-Universität München}, supervisors = {Tobias Appel}, type = {Bachelorthesis}, } -
Nutzerfreundliche Visualisierung von Netzwerkaktivitäten in Echtzeit.
5
2021.
BibTeX Entry
@misc{wern21, author = {Christian Werner}, title = {{Nutzerfreundliche} {Visualisierung} von {Netzwerkaktivitäten} in {Echtzeit}}, year = {2021}, key = {wern21}, month = {5}, school = {Ludwig-Maximilians-Universität München}, supervisors = {Tobias Appel}, type = {Bachelorthesis}, } -
Raspberry Pi CoMaDa Instance Supporting Different Operating Systems and Features in Parallel.
5
2021.
BibTeX Entry
@misc{al-s21, author = {Yanal Al-School}, title = {{Raspberry} {Pi} {CoMaDa} {Instance} {Supporting} {Different} {Operating} {Systems} and {Features} in {Parallel}}, year = {2021}, key = {al-s21}, month = {5}, school = {Ludwig-Maximilians-Universität München}, supervisors = {Corinna Schmitt}, type = {Bachelorthesis}, } -
Managing Multicast Group Membership in IoT Networks.
5
2021.
BibTeX Entry
@misc{ried21, author = {Bettina Riedl}, title = {{Managing} {Multicast} {Group} {Membership} in {IoT} {Networks}}, year = {2021}, key = {ried21}, month = {5}, school = {Ludwig-Maximilians-Universität München}, supervisors = {Tobias Guggemos and Jan Schmidt}, type = {Bachelorthesis}, } -
Bedrohungsmodellierung im Kontext Informationssicherheit.
6
2021.
BibTeX Entry
@misc{fran21a, author = {Nina Franze}, title = {{Bedrohungsmodellierung} im {Kontext} {Informationssicherheit}}, year = {2021}, key = {fran21a}, month = {6}, school = {Ludwig-Maximilians-Universität München}, supervisors = {Jule Ziegler and Michael Schmidt}, type = {Bachelorthesis}, } -
Integration eines automatisierten Malware Analyse-Systems in das Security Monitoring des Münchner Wissenschaftsnetzes.
7
2021.
BibTeX Entry
@misc{poin21, author = {Max Emanuel Pointner}, title = {{Integration} eines automatisierten {Malware} {Analyse-Systems} in das {Security} {Monitoring} des {Münchner} {Wissenschaftsnetzes}}, year = {2021}, key = {poin21}, month = {7}, school = {Ludwig-Maximilians-Universität München}, supervisors = {Tobias Appel}, type = {Bachelorthesis}, } -
Educational Analysis of an Identity-Based Signature Security Proof.
7
2021.
BibTeX Entry
@misc{bier21, author = {Julian Bierwirth}, title = {{Educational} {Analysis} of an {Identity-Based} {Signature} {Security} {Proof}}, year = {2021}, key = {bier21}, month = {7}, school = {Ludwig-Maximilians-Universität München}, supervisors = {Tobias Guggemos and Sophia Grundner-Culemann}, type = {Bachelorthesis}, } -
Evaluation of the difference between monoscopic andstereoscopic digital testimonies regarding immersion and emotional reaction.
7
2021.
BibTeX Entry
@misc{maio21, author = {Simona Maiolo}, title = {{Evaluation} of the difference between monoscopic andstereoscopic digital testimonies regarding immersion and emotional reaction}, year = {2021}, key = {maio21}, month = {7}, school = {Ludwig-Maximilians-Universität München}, supervisors = {Daniel Kolb and Fabio Genz}, type = {Bachelorthesis}, } -
Virtualization on Smartphones using Xen on Arm.
9
2021.
BibTeX Entry
@misc{vogg21, author = {Maxi Voggenauer}, title = {{Virtualization} on {Smartphones} using {Xen} on {Arm}}, year = {2021}, key = {vogg21}, month = {9}, school = {Ludwig-Maximilians-Universität München}, supervisors = {Tobias Lindinger and Jan Schmidt}, type = {Bachelorthesis}, } -
Entwicklung eines Zertifikatsmanagementsystems für Infrastrukturkomponenten am Beispiel von VMware vCenter und ESXi.
9
2021.
BibTeX Entry
@misc{diet21, author = {Christian Dietze}, title = {{Entwicklung} eines {Zertifikatsmanagementsystems} für {Infrastrukturkomponenten} am {Beispiel} von {VMware} {vCenter} und {ESXi}}, year = {2021}, key = {diet21}, month = {9}, school = {Ludwig-Maximilians-Universität München}, supervisors = {Tobias Lindinger and Jan Schmidt}, type = {Bachelorthesis}, } -
Hardware Topology Awareness Through a Graph Query API.
9
2021.
BibTeX Entry
@misc{orlo21, author = {Jakub Orlowski}, title = {{Hardware} {Topology} {Awareness} {Through} a {Graph} {Query} {API}}, year = {2021}, key = {orlo21}, month = {9}, school = {Ludwig-Maximilians-Universität München}, supervisors = {Karl Fuerlinger and Tobias Fuchs}, type = {Bachelorthesis}, } -
Development of a ML-based framework for anomaly detection and gap filling.
9
2021.
BibTeX Entry
@misc{ke21, author = {Junxi Ke}, title = {{Development} of a {ML-based} framework for anomaly detection and gap filling}, year = {2021}, key = {ke21}, month = {9}, school = {Ludwig-Maximilians-Universität München}, supervisors = {Hayk Shoukourian}, type = {Bachelorthesis}, } -
Controller based Routing in Mobile Ad-hoc Networks.
9
2021.
BibTeX Entry
@misc{trae21, author = {Max Traenkler}, title = {{Controller} based {Routing} in {Mobile} {Ad-hoc} {Networks}}, year = {2021}, key = {trae21}, month = {9}, school = {Ludwig-Maximilians-Universität München}, supervisors = {Corinna Schmitt}, type = {Bachelorthesis}, } -
Entwicklung der Gatewaykomponente für SecureWSN auf einem Raspberry Pi.
11
2021.
BibTeX Entry
@misc{gabr21, author = {Jan Gabriel}, title = {{Entwicklung} der {Gatewaykomponente} für {SecureWSN} auf einem {Raspberry} {Pi}}, year = {2021}, key = {gabr21}, month = {11}, school = {Ludwig-Maximilians-Universität München}, supervisors = {Corinna Schmitt}, type = {Bachelorthesis}, } -
Real Time Based Point Clouds Generation and Mapping Using Stereo Images.
11
2021.
BibTeX Entry
@misc{sent21, author = {Willyam Sentosa}, title = {{Real} {Time} {Based} {Point} {Clouds} {Generation} and {Mapping} {Using} {Stereo} {Images}}, year = {2021}, key = {sent21}, month = {11}, school = {Ludwig-Maximilians-Universität München}, supervisors = {Simone Müller and Daniel Kolb and Fabio Genz}, type = {Bachelorthesis}, } -
Computer-based Object Recognition and Calculation of their Physical Properties.
11
2021.
BibTeX Entry
@misc{rasc21, author = {Philip Raschdorf}, title = {{Computer-based} {Object} {Recognition} and {Calculation} of their {Physical} {Properties}}, year = {2021}, key = {rasc21}, month = {11}, school = {Ludwig-Maximilians-Universität München}, supervisors = {Simone Müller and Daniel Kolb and Fabio Genz}, type = {Bachelorthesis}, } -
Training the Cognitive Perception of an Artificial Intelligence to Recognize Reflections on Surfaces.
12
2021.
BibTeX Entry
@misc{teof21, author = {Tudor Teofanescu}, title = {{Training} the {Cognitive} {Perception} of an {Artificial} {Intelligence} to {Recognize} {Reflections} on {Surfaces}}, year = {2021}, key = {teof21}, month = {12}, school = {Ludwig-Maximilians-Universität München}, supervisors = {Simone Müller and Daniel Kolb and Fabio Genz}, type = {Bachelorthesis}, } -
Variance of Photon Mapping with Stratification.
11
2021.
PDF
Abstract
This thesis studies the theoretical aspect of the photon mapping algorithm based on the framework laid out in the paper from Rubén Jesús García-Hernández "Description and Solution of an Unreported Intrinsic Bias in Photon Mapping Density Estimation with Constant Kernel" by applying order statistics to the algorithm to derive theoretical results. We start by recapping the previous results while deriving a first-order approximation to the results. We explain how to reduce the over bias while keeping the variance the same. Furthermore, to reduce variance, we apply stratification to our model and look at the results. We are building upon the previous works: Kathrin Hartmann, in her bachelor thesis - "Theoretical study of photon mapping with stratification" - calculates the expectation values of the irradiance. Zhiming Gan, in his bachelor thesis - "Variance of photon mapping density estimation" - calculates the variances for different filtering kernels. We extend this work by calculating the variance and derive an approximation to expectation values and variance. In the last part of the work, we provide a proof of concept. We show that our theoretical results are in good agreement with experimental values from our simulation.BibTeX Entry
@misc{scha21, author = {Stephan Schaller}, title = {{Variance} of {Photon} {Mapping} with {Stratification}}, year = {2021}, pdf = {https://bib.nm.ifi.lmu.de/pdf/scha21.pdf}, abstract = {This thesis studies the theoretical aspect of the photon mapping algorithm based on the framework laid out in the paper from Rubén Jesús García-Hernández ``Description and Solution of an Unreported Intrinsic Bias in Photon Mapping Density Estimation with Constant Kernel'' by applying order statistics to the algorithm to derive theoretical results. We start by recapping the previous results while deriving a first-order approximation to the results. We explain how to reduce the over bias while keeping the variance the same. Furthermore, to reduce variance, we apply stratification to our model and look at the results. We are building upon the previous works: Kathrin Hartmann, in her bachelor thesis -- ``Theoretical study of photon mapping with stratification'' -- calculates the expectation values of the irradiance. Zhiming Gan, in his bachelor thesis -- "Variance of photon mapping density estimation" -- calculates the variances for different filtering kernels. We extend this work by calculating the variance and derive an approximation to expectation values and variance. In the last part of the work, we provide a proof of concept. We show that our theoretical results are in good agreement with experimental values from our simulation.}, key = {scha21}, month = {11}, school = {Ludwig-Maximilians-Universität München}, supervisors = {Ruben Garcia Hernandez}, type = {Bachelorthesis}, }
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