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@ -143,7 +143,7 @@
isbn = {978-1-4503-4139-4}
}
@inproceedings{arpPrivacyThreatsUltrasonic2017,
@inproceedings{arpPrivacyThreatsUltrasonic2017a,
title = {Privacy {{Threats}} through {{Ultrasonic Side Channels}} on {{Mobile Devices}}},
booktitle = {2017 {{IEEE European Symposium}} on {{Security}} and {{Privacy}} ({{EuroS}}\&{{P}})},
author = {Arp, Daniel and Quiring, Erwin and Wressnegger, Christian and Rieck, Konrad},
@ -1033,7 +1033,7 @@
file = {/home/jaseg/Sync/Research/Zotero/Couteau et al_2021_Silver.pdf}
}
@article{cuellarStaticFatigueLifetime1987a,
@article{cuellarStaticFatigueLifetime1987,
title = {Static Fatigue Lifetime of Optical Fibers in Bending},
author = {Cuellar, E. and Roberts, D. and Middleman, L.},
date = {1987-01-01},
@ -2013,16 +2013,16 @@
@online{IEEEXploreFullTexta,
title = {{{IEEE Xplore Full-Text PDF}}:},
url = {https://ieeexplore.ieee.org/stamp/stamp.jsp?arnumber=8558378},
url = {https://ieeexplore.ieee.org/stamp/stamp.jsp?arnumber=6520632},
urldate = {2024-09-10},
file = {/home/jaseg/Zotero/storage/HJJK32NF/stamp.html}
file = {/home/jaseg/Zotero/storage/PQYCW7K7/stamp.html}
}
@online{IEEEXploreFullTextb,
title = {{{IEEE Xplore Full-Text PDF}}:},
url = {https://ieeexplore.ieee.org/stamp/stamp.jsp?arnumber=6520632},
url = {https://ieeexplore.ieee.org/stamp/stamp.jsp?arnumber=8558378},
urldate = {2024-09-10},
file = {/home/jaseg/Zotero/storage/PQYCW7K7/stamp.html}
file = {/home/jaseg/Zotero/storage/HJJK32NF/stamp.html}
}
@online{ImpactPolarizationMode,
@ -2516,11 +2516,11 @@
issn = {2511-9044, 2511-9044},
doi = {10.1002/qute.201800011},
url = {http://arxiv.org/abs/1703.09278},
urldate = {2024-05-02},
urldate = {2024-05-27},
abstract = {Quantum key distribution using weak coherent states and homodyne detection is a promising candidate for practical quantum-cryptographic implementations due to its compatibility with existing telecom equipment and high detection efficiencies. However, despite the actual simplicity of the protocol, the security analysis of this method is rather involved compared to discrete-variable QKD. In this article we review the theoretical foundations of continuous-variable quantum key distribution (CV-QKD) with Gaussian modulation and rederive the essential relations from scratch in a pedagogical way. The aim of this paper is to be as comprehensive and self-contained as possible in order to be well intelligible even for readers with little pre-knowledge on the subject. Although the present article is a theoretical discussion of CV-QKD, its focus lies on practical implementations, taking into account various kinds of hardware imperfections and suggesting practical methods to perform the security analysis subsequent to the key exchange. Apart from a review of well known results, this manuscript presents a set of new original noise models which are helpful to get an estimate of how well a given set of hardware will perform in practice.},
langid = {english},
keywords = {Quantum Physics},
file = {/home/jaseg/Zotero/storage/A2BQHUUW/Laudenbach et al. - 2018 - Continuous-Variable Quantum Key Distribution with .pdf}
file = {/home/jaseg/Zotero/storage/I7UL2SKX/Laudenbach et al. - 2018 - Continuous-Variable Quantum Key Distribution with .pdf}
}
@article{laudenbachContinuousVariableQuantumKey2018a,
@ -2538,11 +2538,11 @@
issn = {2511-9044, 2511-9044},
doi = {10.1002/qute.201800011},
url = {http://arxiv.org/abs/1703.09278},
urldate = {2024-05-27},
urldate = {2024-05-02},
abstract = {Quantum key distribution using weak coherent states and homodyne detection is a promising candidate for practical quantum-cryptographic implementations due to its compatibility with existing telecom equipment and high detection efficiencies. However, despite the actual simplicity of the protocol, the security analysis of this method is rather involved compared to discrete-variable QKD. In this article we review the theoretical foundations of continuous-variable quantum key distribution (CV-QKD) with Gaussian modulation and rederive the essential relations from scratch in a pedagogical way. The aim of this paper is to be as comprehensive and self-contained as possible in order to be well intelligible even for readers with little pre-knowledge on the subject. Although the present article is a theoretical discussion of CV-QKD, its focus lies on practical implementations, taking into account various kinds of hardware imperfections and suggesting practical methods to perform the security analysis subsequent to the key exchange. Apart from a review of well known results, this manuscript presents a set of new original noise models which are helpful to get an estimate of how well a given set of hardware will perform in practice.},
langid = {english},
keywords = {Quantum Physics},
file = {/home/jaseg/Zotero/storage/I7UL2SKX/Laudenbach et al. - 2018 - Continuous-Variable Quantum Key Distribution with .pdf}
file = {/home/jaseg/Zotero/storage/A2BQHUUW/Laudenbach et al. - 2018 - Continuous-Variable Quantum Key Distribution with .pdf}
}
@article{laudenbachContinuousVariableQuantumKey2018b,
@ -2588,7 +2588,7 @@
file = {/home/jaseg/Zotero/storage/SPNJ8KBL/Launchbury et al. - 2014 - Application-Scale Secure Multiparty Computation.pdf}
}
@article{leePrintedSpiralWinding2011,
@article{leePrintedSpiralWinding2011a,
title = {Printed {{Spiral Winding Inductor With Wide Frequency Bandwidth}}},
author = {Lee, Chi Kwan and Su, Y. P. and Ron Hui, S. Y.},
date = {2011-10},
@ -2790,7 +2790,7 @@
file = {/home/jaseg/Zotero/storage/WBSKAYAN/Long et al. - 2024 - EM Eye Characterizing Electromagnetic Side-channe.pdf}
}
@article{lopeFirstSelfresonantFrequency2021,
@article{lopeFirstSelfResonant2021,
title = {First Selfresonant Frequency of Power Inductors Based on Approximated Corrected Stray Capacitances},
author = {Lope, Ignacio and Carretero, Claudio and Acero, Jesus},
date = {2021-02},
@ -3002,6 +3002,13 @@
file = {/home/jaseg/Zotero/storage/Y24TQ9UT/Maurer - 1997 - Information-Theoretically Secure Secret-Key Agreem.pdf}
}
@book{meeekerFiniteElementMethod2015,
title = {Finite {{Element Method Magnetics}}. {{User}}'s {{Manual}}.},
author = {Meeeker, David},
date = {2015-10-25},
pagetotal = {161}
}
@article{mehicNovelApproachQualityofService2020,
title = {A {{Novel Approach}} to {{Quality-of-Service Provisioning}} in {{Trusted Relay Quantum Key Distribution Networks}}},
author = {Mehic, Miralem and Fazio, Peppino and Rass, Stefan and Maurhart, Oliver and Peev, Momtchil and Poppe, Andreas and Rozhon, Jan and Niemiec, Marcin and Voznak, Miroslav},
@ -3164,7 +3171,7 @@
file = {/home/jaseg/Zotero/storage/EBAXQHG5/Mosavirik et al. - 2022 - ImpedanceVerif On-Chip Impedance Sensing for Syst.pdf}
}
@article{mosavirikSiliconEchoesNonInvasive2023,
@article{mosavirikSiliconEchoesNonInvasive2023a,
title = {Silicon {{Echoes}}: {{Non-Invasive Trojan}} and {{Tamper Detection}} Using {{Frequency-Selective Impedance Analysis}}},
shorttitle = {Silicon {{Echoes}}},
author = {Mosavirik, Tahoura and Monfared, Saleh Khalaj and Safa, Maryam Saadat and Tajik, Shahin},
@ -4420,7 +4427,7 @@
isbn = {978-1-119-64468-2},
langid = {english},
keywords = {banking community,FPGAs,hardware security modules,security engineer,smartcards,tamper resistance},
file = {/home/jaseg/Sync/Research/Zotero/2020_Tamper Resistance.pdf;/home/jaseg/Zotero/storage/EMWJABZF/9781119644682.html}
file = {/home/jaseg/Zotero/storage/DSFCQBZB/9781119644682.html}
}
@incollection{TamperResistance2020a,
@ -4436,7 +4443,7 @@
isbn = {978-1-119-64468-2},
langid = {english},
keywords = {banking community,FPGAs,hardware security modules,security engineer,smartcards,tamper resistance},
file = {/home/jaseg/Zotero/storage/DSFCQBZB/9781119644682.html}
file = {/home/jaseg/Sync/Research/Zotero/2020_Tamper Resistance.pdf;/home/jaseg/Zotero/storage/EMWJABZF/9781119644682.html}
}
@article{tangMeasurementDeviceIndependentQuantumKey2016,
@ -5095,6 +5102,24 @@
file = {/home/jaseg/Zotero/storage/SXDU6E5J/Zhang et al. - 2017 - DolphinAttack Inaudible Voice Commands.pdf}
}
@article{zhangDynamicWirelessPower2025,
title = {A {{Dynamic Wireless Power Transfer System Using DC-Controlled Variable Inductor}} for {{Segment Transmitter Automatic Switching}}},
author = {Zhang, Zeheng and Li, Zheng and Zhang, Xiaojun and Yang, Bin and He, Zhengyou and Mai, Ruikun and Chen, Yang},
date = {2025-01},
journaltitle = {IEEE Transactions on Power Electronics},
volume = {40},
number = {1},
pages = {23--27},
issn = {1941-0107},
doi = {10.1109/TPEL.2024.3426100},
url = {https://ieeexplore.ieee.org/document/10592813/?arnumber=10592813},
urldate = {2024-12-11},
abstract = {Segmented transmitter coils are commonly employed in dynamic wireless power transfer, and automatic switching is a preferred function to limit the transmitter current. This letter proposes a method for segment transmitter automatic switching utilizing a dc-controlled variable inductor (DCCVI), where the dc current can change the ac side's self-inductance. When the coils are decoupled, the dc current is small, so the inductance of the DCCVI is relatively large, leading to the suppression of the transmitter current. When the coils meet certain coupling conditions, the dc current becomes large, leading to a significant reduction in the ac inductance of the DCCVI, resulting in higher transmission power, thereby enabling segment transmitter automatic switching. The proposed method is straightforward and does not need additional position feedback. The experimental results demonstrate that the proposed system can automatically limit the coil current within the range of [0, 0.15] and achieve higher power transmission with higher efficiency within the coupling range of [0.165, 0.3].},
eventtitle = {{{IEEE Transactions}} on {{Power Electronics}}},
keywords = {Automatic switching,Coils,Couplings,dynamic wireless power transfer (DWPT),Inductance,Inductors,Receivers,Switches,Transmitters,variable inductor},
file = {/home/jaseg/Sync/Research/Zotero/2025_Zhang et al_A Dynamic Wireless Power Transfer System Using DC-Controlled Variable Inductor.pdf;/home/jaseg/Zotero/storage/6G27HTPY/10592813.html}
}
@article{zhangEnergyEncryptionWireless2015,
title = {Energy {{Encryption}} for {{Wireless Power Transfer}}},
author = {Zhang, Zhen and Chau, K. T. and Qiu, Chun and Liu, Chunhua},
@ -5113,6 +5138,24 @@
file = {/home/jaseg/Sync/Research/Zotero/Zhang et al_2015_Energy Encryption for Wireless Power Transfer.pdf;/home/jaseg/Zotero/storage/AYSH2G8F/6928497.html}
}
@article{zhangImprovedCompensationMethod2025,
title = {An {{Improved Compensation Method Reducing Displacement Current Loss}} for {{Multilayer Coils}} in {{IPT System}}},
author = {Zhang, Yiming and Cheng, Hao and Chen, Yang and Luo, Bo and Zhou, Wei and Mai, Ruikun and He, Zhengyou},
date = {2025-01},
journaltitle = {IEEE Transactions on Power Electronics},
volume = {40},
number = {1},
pages = {87--91},
issn = {1941-0107},
doi = {10.1109/TPEL.2024.3462669},
url = {https://ieeexplore.ieee.org/document/10681322/?arnumber=10681322},
urldate = {2024-12-11},
abstract = {Dual-layer or multilayer coils are often used to increase the power density of inductive power transfer systems. However, compared to single-layer coils, multilayer coils suffer from additional loss caused by interlayer displacement current (IDC), which can reduce system transmission efficiency. Therefore, this letter establishes a general mathematical model for IDC loss in multilayer coils regardless of whether the adjacent layers are symmetric. The traditional centralized compensation capacitor is split into two capacitors (interlayer and auxiliary capacitors), and a novel parameteric design method for the interlayer capacitor is proposed to optimize the IDC losses. The auxiliary capacitor is used to adjust the resonance state of the circuit. The experimental results show that compared to the traditional method, the prototype with the double-layer symmetrical coil achieves efficiency improvements of 0.5\% under light load and 2.27\% under heavy load. The double-layer asymmetrical coil prototype achieves efficiency improvements of 0.58\% under light load and 2.11\% under heavy load compared to the traditional method.},
eventtitle = {{{IEEE Transactions}} on {{Power Electronics}}},
keywords = {Capacitors,Coils,Dielectrics,Inductance,Inductive power transfer (IPT),interlayer displacement current (IDC) loss,multilayer coil,Nonhomogeneous media,Resistance,Wire},
file = {/home/jaseg/Sync/Research/Zotero/2025_Zhang et al_An Improved Compensation Method Reducing Displacement Current Loss for.pdf;/home/jaseg/Zotero/storage/Y3LF7826/10681322.html}
}
@article{zhangLargeScaleQuantum2018,
title = {Large Scale Quantum Key Distribution: Challenges and Solutions [{{Invited}}]},
shorttitle = {Large Scale Quantum Key Distribution},