@inproceedings{50273, abstract = {{The Polynomial-Time Hierarchy ($\mathsf{PH}$) is a staple of classical complexity theory, with applications spanning randomized computation to circuit lower bounds to ''quantum advantage'' analyses for near-term quantum computers. Quantumly, however, despite the fact that at least \emph{four} definitions of quantum $\mathsf{PH}$ exist, it has been challenging to prove analogues for these of even basic facts from $\mathsf{PH}$. This work studies three quantum-verifier based generalizations of $\mathsf{PH}$, two of which are from [Gharibian, Santha, Sikora, Sundaram, Yirka, 2022] and use classical strings ($\mathsf{QCPH}$) and quantum mixed states ($\mathsf{QPH}$) as proofs, and one of which is new to this work, utilizing quantum pure states ($\mathsf{pureQPH}$) as proofs. We first resolve several open problems from [GSSSY22], including a collapse theorem and a Karp-Lipton theorem for $\mathsf{QCPH}$. Then, for our new class $\mathsf{pureQPH}$, we show one-sided error reduction for $\mathsf{pureQPH}$, as well as the first bounds relating these quantum variants of $\mathsf{PH}$, namely $\mathsf{QCPH}\subseteq \mathsf{pureQPH} \subseteq \mathsf{EXP}^{\mathsf{PP}}$.}}, author = {{Agarwal, Avantika and Gharibian, Sevag and Koppula, Venkata and Rudolph, Dorian}}, booktitle = {{Proceedings of 49th International Symposium on Mathematical Foundations of Computer Science (MFCS)}}, number = {{7}}, pages = {{7--17}}, title = {{{Quantum Polynomial Hierarchies: Karp-Lipton, error reduction, and lower bounds}}}, doi = {{10.4230/LIPIcs.MFCS.2024.7}}, volume = {{306}}, year = {{2024}}, } @inproceedings{53811, abstract = {{Persistent security challenges plague DevOps teams due to a deficiency in expertise regarding security tools and methods, as evidenced by frequent security incidents. Existing maturity models fail to adequately address the specific needs of DevOps teams. In response, this paper proposes "Security Belts," a novel maturity model inspired by martial arts ranking systems. This model aims to assist DevOps teams in enhancing their security capabilities by providing a structured approach, starting with fundamental activities and progressing to more advanced techniques. Drawing from the experiences of monitoring 21 teams, the paper presents lessons learned and offers actionable advice for refining maturity models tailored to software quality improvement.}}, author = {{Taaibi, Samira and Dziwok, Stefan and Hermerschmidt, Lars and Koch, Thorsten and Merschjohann, Sven and Vollmary, Mark}}, booktitle = {{AMCIS 2024 Proceedings. 13.}}, keywords = {{Software security, maturity model}}, location = {{Salt Lake City}}, title = {{{Security Belts: A Maturity Model for DevOps Teams to Increase the Software Security of their Product - An Experience Report}}}, year = {{2024}}, } @inbook{65592, author = {{Pauls, Karina and Musehold, Thomas}}, booktitle = {{Schnittstelle Kunstunterricht: Skulptur - Material - Prozess}}, editor = {{Pauls, Karina}}, isbn = {{9783763977253}}, title = {{{3D-Druck in Kunst und Lehre - Thomas Musehold und Karina Pauls im Gespräch}}}, year = {{2024}}, } @inbook{65590, author = {{Pauls, Karina}}, booktitle = {{Schnittstelle Kunstunterricht: Skulptur - Material - Prozess}}, editor = {{Pauls, Karina}}, isbn = {{9783763977253}}, title = {{{Skulptur und Prozesse im Material}}}, doi = {{10.3278/9783763977246}}, year = {{2024}}, } @inbook{65591, author = {{Pauls, Karina}}, booktitle = {{Schnittstelle Kunstunterricht: Skulptur - Material - Prozess}}, editor = {{Pauls, Karina}}, isbn = {{9783763977253}}, title = {{{Beispiel aus der Lehrpraxis: Keramik + X}}}, year = {{2024}}, } @book{65589, editor = {{Pauls, Karina}}, isbn = {{9783763977253}}, title = {{{Schnittstelle Kunstunterricht: Skulptur - Material - Prozess}}}, doi = {{10.3278/9783763977246}}, year = {{2024}}, } @misc{57860, abstract = {{BloKK-Beitrag für das ZeKK, 07.06.2024}}, author = {{Lebock, Sarah}}, title = {{{"Auf der Suche nach Frieden"}}}, year = {{2024}}, }