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Verfahren zum Betrieb eines batterieelektrischen Fahrzeugs mit einer elektrischen Maschine zum Antrieb des Fahrzeugs und einem Inverter (1) zum Ansteuern der elektrischen Maschine, wobei der Inverter (1) eine dreiphasige Brückenschaltung mit einer Anzahl von als Halbleiter ausgebildeten Schaltern (3) umfasst, wobei im Inverter (1) entstehende Verluste zum Heizen eines Innenraums des Fahrzeugs und/oder zum Temperieren einer Batterie und/oder zum Temperieren von Getriebeöl verwendet werden, wobei der Inverter (1) mittels Raumzeigermodulation gesteuert wird, wobei ein nicht-optimales Schaltverhalten des Inverters (1) herbeigeführt wird, indem nicht optimale Spannungs-Raumzeiger (e, eu, ev, ew, e1, e2, -e1, -e2) eingestellt werden, wobei eine Skalierung der Spannungs-Raumzeiger (e, e1, e2) über die Schaltung von Nullspannungsvektoren, die je nach zeitlichem Anteil die Spannung reduzieren, oder durch Zuhilfenahme eines jeweils gegenüberliegenden Spannungs-Raumzeigers (-e1, -e2) erfolgt, so dass eine Schaltfolge mit einer maximalen Anzahl von Schaltzyklen realisiert wird, dadurch gekennzeichnet, dass in der Mitte einer Schaltperiode (Tp) keine Symmetrie erzeugt wird.
An in-depth study of U-net for seismic data conditioning: Multiple removal by moveout discrimination
(2024)
Seismic processing often involves suppressing multiples that are an inherent component of collected seismic data. Elaborate multiple prediction and subtraction schemes such as surface-related multiple removal have become standard in industry workflows. In cases of limited spatial sampling, low signal-to-noise ratio, or conservative subtraction of the predicted multiples, the processed data frequently suffer from residual multiples. To tackle these artifacts in the postmigration domain, practitioners often rely on Radon transform-based algorithms. However, such traditional approaches are both time-consuming and parameter dependent, making them relatively complex. In this work, we present a deep learning-based alternative that provides competitive results, while reducing the complexity of its usage, and, hence simplifying its applicability. Our proposed model demonstrates excellent performance when applied to complex field data, despite it being exclusively trained on synthetic data. Furthermore, extensive experiments show that our method can preserve the inherent characteristics of the data, avoiding undesired oversmoothed results, while removing the multiples from seismic offset or angle gathers. Finally, we conduct an in-depth analysis of the model, where we pinpoint the effects of the main hyperparameters on real data inference, and we probabilistically assess its performance from a Bayesian perspective. In this study, we put particular emphasis on helping the user reveal the inner workings of the neural network and attempt to unbox the model.
Analysing and predicting the advance rate of a tunnel boring machine (TBM) in hard rock is integral to tunnelling project planning and execution. It has been applied in the industry for several decades with varying success. Most prediction models are based on or designed for large-diameter TBMs, and much research has been conducted on related tunnelling projects. However, only a few models incorporate information from projects with an outer diameter smaller than 5 m and no penetration prediction model for pipe jacking machines exists to date. In contrast to large TBMs, small-diameter TBMs and their projects have been considered little in research. In general, they are characterised by distinctive features, including insufficient geotechnical information, sometimes rather short drive lengths, special machine designs and partially concurring lining methods like pipe jacking and segment lining. A database which covers most of the parameters mentioned above has been compiled to investigate the performance of small-diameter TBMs in hard rock. In order to provide sufficient geological and technical variance, this database contains 37 projects with 70 geotechnically homogeneous areas. Besides the technical parameters, important geotechnical data like lithological information, unconfined compressive strength, tensile strength and point load index is included and evaluated. The analysis shows that segment lining TBMs have considerably higher penetration rates in similar geological and technical settings mostly due to their design parameters. Different methodologies for predicting TBM penetration, including state-of-the-art models from the literature as well as newly derived regression and machine learning models, are discussed and deployed for backward modelling of the projects contained in the database. New ranges of application for small-diameter tunnelling in several industry-standard penetration models are presented, and new approaches for the penetration prediction of pipe jacking machines in hard rock are proposed.
This thesis focuses on the development and implementation of a Datagram Transport Layer Security (DTLS) communication framework within the ns-3 network simulator, specifically targeting the LoRaWAN model network. The primary aim is to analyse the behaviour and performance of DTLS protocols across different network conditions within a LoRaWAN context. The key aspects of this work include the following.
Utilization of ns-3: This thesis leverages ns-3’s capabilities as a powerful discrete event network simulator. This platform enables the emulation of diverse network environments, characterized by varying levels of latency, packet loss, and bandwidth constraints.
Emulation of Network Challenges: The framework specifically addresses unique challenges posed by certain network configurations, such as duty cycle limitations. These constraints, which limit the time allocated for data transmission by each device, are crucial in understanding the real-world performance of DTLS protocols.
Testing in Multi-client-server Scenarios: A significant feature of this framework is its ability to test DTLS performance in complex scenarios involving multiple clients and servers. This is vital for assessing the behaviour of a protocol under realistic network conditions.
Realistic Environment Simulation: By simulating challenging network conditions, such as congestion, limited bandwidth, and resource constraints, the framework provides a realistic environment for thorough evaluation. This allows for a comprehensive analysis of DTLS in terms of security, performance, and scalability.
Overall, this thesis contributes to a deeper understanding of DTLS protocols by providing a robust tool for their evaluation under various and challenging network conditions.
"Ad fontes!"
Francesco Petrarca (1301–1374)
In the beginning, there was an idea: the reconstruction of the first "Iron Hand" of the Franconian imperial knight Götz von Berlichingen (1480–1562). We found that with this historical prosthesis, simple actions for daily use, such as holding a wine glass, a mobile phone, a bicycle handlebar grip, a horse’s reins, or some grapes, are possible without effort. Controlling this passive artificial hand, however, is based on the help of a healthy second hand.
Modellprädiktive Regelung findet zunehmend Anwendung im industriellen Umfeld. Durch schnellere Computer und optimierte Programmierung ist es heute möglich, rechenintensive Regelalgorithmen in Echtzeit auf Mikrocontrollern zu berechnen. Eine besondere Herausforderung besteht jedoch darin, diese Technologie in der Realität einzusetzen. Weil exakte Kenntnisse über das reale System vorliegen müssen, können geringfügige Modellierungsfehler bei der Prädiktion für lange Prädiktionshorizonte schwerwiegende Folgen haben. Das ist insbesondere der Fall, wenn Systeme instabil sind und zu chaotischem Verhalten neigen.
Diese Arbeit behandelt ein breites Spektrum systemtheoretischer Inhalte und zielt darauf ab, ein reales Furuta-Pendel durch modellprädiktive Regelung in der instabilen Ruhelage zu stabilisieren. Hierfür wird ein mathematisches Modell als Prädiktionsmodell hergeleitet, welches durch verschiedene Systemidentifikationsmethoden spezifiziert und validiert wird. Es werden verschiedene Filter-Techniken wie das Kalman-Filter zur Zustandsschätzung oder das Exponential Moving Average (EMA)-Filter zur Filterung von Sensordaten eingesetzt.
Das Furuta-Pendel ist ein komplexes mechatronisches System. Die Aufgaben dieser Arbeit beschränken sich daher nicht nur auf theoretische Aspekte. Neben der Auslegung elektrischer Bauelemente und Schaltungen werden zusätzliche Sensoren zu einem bestehenden System hinzugefügt und mechanische Anpassungen vorgenommen. Darüber hinaus werden Entscheidungen zur Softwarearchitektur getroffen sowie die gesamte Implementierung auf einem Mikrocontroller durchgeführt.
Trotz intensiver Bemühungen konnte kein Modell gefunden werden, welches die gemessenen Ein- und Ausgangsdaten vergleichbar simulieren kann, sodass es den Anforderungen der modellprädiktiven Regelung entspricht. Stattdessen gelang es während der Systemidentifikationsphase einen Linear Quadratic Regulator (LQR) mit unterlagertem Proportional–Integral (PI) Stromregler als Kaskade zu entwerfen, der sowohl simulativ als auch in der Realität das Pendel stabilisieren kann.
JavaScript-Frameworks (JSF) sind im Bereich der Webentwicklung seit längerem prominent. Jährlich werden neue JSF entwickelt, um spezifische Probleme zu lösen. In den letzten Jahren hat sich der Trend entwickelt, bei der Wahl des JSF verstärkt auch auf die Performanz der entwickelten Webseite zu achten. Dabei wird versucht, den Anteil an JavaScript auf der Webseite zu reduzieren oder ganz zu eliminieren. Besonders neu ist der Ansatz der "Island Architecture", die erstmals 2019 vorgeschlagen wurde. In dieser Thesis soll die Performanz der meistbenutzten und des performantesten JSF mit dem JSF "Astro" verglichen werden, welches die "Island Architecture" von sich aus unterstützt. Der Schwerpunkt liegt beim Vergleichen der Webseitenperformanz, jedoch werden auch Effizienz und Einfachheit während der Entwicklung untersucht. Das Ziel dieser Arbeit ist es, potenzielle Frameworks zu untersuchen, die die Effizienz und Produktivität für den Nutzer und während der Entwicklung steigern können.
Physical unclonable functions (PUFs) are increasingly generating attention in the field of hardware-based security for the Internet of Things (IoT). A PUF, as its name implies, is a physical element with a special and unique inherent characteristic and can act as the security anchor for authentication and cryptographic applications. Keeping in mind that the PUF outputs are prone to change in the presence of noise and environmental variations, it is critical to derive reliable keys from the PUF and to use the maximum entropy at the same time. In this work, the PUF output positioning (POP) method is proposed, which is a novel method for grouping the PUF outputs in order to maximize the extracted entropy. To achieve this, an offset data is introduced as helper data, which is used to relax the constraints considered for the grouping of PUF outputs, and deriving more entropy, while reducing the secret key error bits. To implement the method, the key enrollment and key generation algorithms are presented. Based on a theoretical analysis of the achieved entropy, it is proven that POP can maximize the achieved entropy, while respecting the constraints induced to guarantee the reliability of the secret key. Moreover, a detailed security analysis is presented, which shows the resilience of the method against cyber-security attacks. The findings of this work are evaluated by applying the method on a hybrid printed PUF, where it can be practically shown that the proposed method outperforms other existing group-based PUF key generation methods.
As the Industry 4.0 is evolving, the previously separated Operational Technology (OT) and Information Technology (IT) is converging. Connecting devices in the industrial setting to the Internet exposes these systems to a broader spectrum of cyber-attacks. The reason is that since OT does not have much security measures as much as IT, it is more vulnerable from the attacker's perspective. Another factor contributing to the vulnerability of OT is that, when it comes to cybersecurity, industries have focused on protecting information technology and less prioritizing the control systems. The consequences of a security breach in an OT system can be more adverse as it can lead to physical damage, industrial accidents and physical harm to human beings. Hence, for the OT networks, certificate-based authentication is implemented. This involves stages of managing credentials in their communication endpoints. In the previous works of ivESK, a solution was developed for managing credentials. This involves a CANopen-based physical demonstrator where the certificate management processes were developed. The extended feature set involving certificate management will be based on the existing solution. The thesis aims to significantly improve such a solution by addressing two key areas that is enhancing functionality and optimizing real-time performance. Regarding the first goal, firstly, an analysis of the existing feature set shall be carried out, where the correct functionality shall be guaranteed. The limitations from the previously implemented system will be addressed and to make sure it can be applied to real world scenarios, it will be implemented and tested in the physical demonstrator. This will lay a concrete foundation that these certificate management processes can be used in the industries in large-scale networks. Implementation of features like revocation mechanism for certificates, automated renewal of the credentials and authorization attribute checks for the certificate management will be implemented. Regarding the second goal, the impact of credential management processes on the ongoing CANopen real-time traffic shall be a studied. Since in real life scenarios, mission-critical applications like Industrial control systems, medical devices, and transportation networks rely on real-time communication for reliable operation, delays or disruptions caused by credential management processes can have severe consequences. Optimizing these processes is crucial for maintaining system integrity and safety. The effect to minimize the disturbance of the credential management processes on the normal operation of the CANopen network shall be characterized. This shall comprise testing real-time parameters in the network such as CPU load, network load and average delay. Results obtained from each of these tests will be studied.
This paper provides a comprehensive overview of approaches to the determination of isocontours and isosurfaces from given data sets. Different algorithms are reported in the literature for this purpose, which originate from various application areas, such as computer graphics or medical imaging procedures. In all these applications, the challenge is to extract surfaces with a specific isovalue from a given characteristic, so called isosurfaces. These different application areas have given rise to solution approaches that all solve the problem of isocontouring in their own way. Based on the literature, the following four dominant methods can be identified: the marching cubes algorithms, the tessellation-based algorithms, the surface nets algorithms and the ray tracing algorithms. With regard to their application, it can be seen that the methods are mainly used in the fields of medical imaging, computer graphics and the visualization of simulation results. In our work, we provide a broad and compact overview of the common methods that are currently used in terms of isocontouring with respect to certain criteria and their individual limitations. In this context, we discuss the individual methods and identify possible future research directions in the field of isocontouring.
With the expansion of IoT devices in many aspects of our life, the security of such systems has become an important challenge. Unlike conventional computer systems, any IoT security solution should consider the constraints of these systems such as computational capability, memory, connectivity, and power consumption limitations. Physical Unclonable Functions (PUFs) with their special characteristics were introduced to satisfy the security needs while respecting the mentioned constraints. They exploit the uncontrollable and reproducible variations of the underlying component for security applications such as identification, authentication, and communication security. Since IoT devices are typically low cost, it is important to reuse existing elements in their hardware (for instance sensors, ADCs, etc.) instead of adding extra costs for the PUF hardware. Micro-electromechanical system (MEMS) devices are widely used in IoT systems as sensors and actuators. In this thesis, a comprehensive study of the potential application of MEMS devices as PUF primitives is provided. MEMS PUF leverages the uncontrollable variations in the parameters of MEMS elements to derive secure keys for cryptographic applications. Experimental and simulation results show that our proposed MEMS PUFs are capable of generating enough entropy for a complex key generation, while their responses show low fluctuations in different environmental conditions.
Keeping in mind that the PUF responses are prone to change in the presence of noise and environmental variations, it is critical to derive reliable keys from the PUF and to use the maximum entropy at the same time. In the second part of this thesis, we elaborate on different key generation schemes and their advantages and drawbacks. We propose the PUF output positioning (POP) and integer linear programming (ILP) methods, which are novel methods for grouping the PUF outputs in order to maximize the extracted entropy. To implement these methods, the key enrollment and key generation algorithms are presented. The proposed methods are then evaluated by applying on the responses of the MEMS PUF, where it can be practically shown that the proposed method outperforms other existing PUF key generation methods.
The final part of this thesis is dedicated to the application of the MEMS PUF as a security solution for IoT systems. We select the mutual authentication of IoT devices and their backend system, and propose two lightweight authentication protocols based on MEMS PUFs. The presented protocols undergo a comprehensive security analysis to show their eligibility to be used in IoT systems. As the result, the output of this thesis is a lightweight security solution based on MEMS PUFs, which introduces a very low overhead on the cost of the hardware.
Garbage in, Garbage out: How does ambiguity in data affect state-of-the-art pedestrian detection?
(2024)
This thesis investigates the critical role of data quality in computer vision, particularly in the realm of pedestrian detection. The proliferation of deep learning methods has emphasised the importance of large datasets for model training, while the quality of these datasets is equally crucial. Ambiguity in annotations, arising from factors like mislabelling, inaccurate bounding box geometry and annotator disagreements, poses significant challenges to the reliability and robustness of the pedestrian detection models and their evaluation. This work aims to explore the effects of ambiguous data on model performance with a focus on identifying and separating ambiguous instances, employing an ambiguity measure utilizing annotator estimations of object visibility and identity. Through accurate experimentation and analysis, trade-offs between data cleanliness and representativeness, noise removal and retention of valuable data emerged, elucidating their impact on performance metrics like the log average miss-rate, recall and precision. Furthermore, a strong correlation between ambiguity and occlusion was discovered with higher ambiguity corresponding to greater occlusion prevalence. The EuroCity Persons dataset served as the primary dataset, revealing a significant proportion of ambiguous instances with approximately 8.6% ambiguity in the training dataset and 7.3% in the validation set. Results demonstrated that removing ambiguous data improves the log average miss-rate, particularly by reducing the false positive detections. Augmentation of the training data with samples from neighbouring classes enhanced the recall but diminished precision. Error correction of wrong false positives and false negatives significantly impacts model evaluation results, as evidenced by shifts in the ECP leaderboard rankings. By systematically addressing ambiguity, this thesis lays the foundation for enhancing the reliability of computer vision systems in real-world applications, motivating the prioritisation of developing robust strategies to identify, quantify and address ambiguity.
Immer mehr Unternehmen setzen auf eine Cross-Cloud-Strategie, die es Unternehmen ermöglicht, ihre Anwendungen und Daten über mehrere Cloud-Plattformen hinweg effizient zu verwalten und zu betreiben. Konsistenz und Atomarität zwischen den Cloud-Plattformen zu wahren, stellt eine große Herausforderung dar. Hierzu wird in dieser Arbeit eine Lösung vorgestellt, um Cross-Cloud-Atomarität zu erreichen, welche auf Basis des 2-Phasen-Commit-Protokolls (2PC) beruht. In diesem Zusammenhang wird die Funktionsweise des 2PC-Protokolls erörtert und Erweiterungen sowie Alternativen zum Protokoll kurz angesprochen. Zusätzlich werden alternative Lösungsansätze diskutiert, die für die Erzielung von Cross-Cloud-Atomarität in Betracht gezogen werden können. Dadurch wird ein umfassender Einblick in das Thema sowie mögliche Lösungsansätze für diese Herausforderung gewährt.
In dieser Arbeit wird die Identifikation von Trägheitsparametern von Mehrkörpersystemen, am Beispiel eines ein aus vier Segmenten bestehenden Roboterarms untersucht. Es werden verschiedene neuronale Netzarchitekturen zur Identifikation der Trägheitsparameter des Roboterarms exploriert. Als Referenz für das Abschneiden der Ansätze wird ein vorab implementierter numerischer Optimierungsansatz, welcher mittels der Software „Matalb“ umgesetzt wurde, benutzt. Der Ansatz zum Aufstellen der benötigten Bewegungsgleichungen und die Formulierung des Regressionsproblems unterscheidet sich von den in der Literatur verwendeten Ansätzen, und beruht auf einem neu entwickelten Sensorkonzept der Hochschule Offenburg (des Sweaty Labors).
Der numerische Ansatz, insbesondere nach Linearisierung des Problems, erzielte herausragende Ergebnisse und konnte die idealen Parameterwerte präzise identifizieren. Demgegenüber standen die neuronalen Netzwerke, deren Potenzial trotz umfassender Untersuchung verschiedener Architekturen und Ansätze nicht vollends ausgeschöpft werden konnte. Die Resultate zeigen deutlich die Grenzen und Herausforderungen bei der Anwendung maschineller Lernmethoden in der spezifischen Aufgabenstellung der Trägheitsparameteridentifikation auf.
Diese Arbeit leistet einen Beitrag zum Verständnis der Möglichkeiten und Grenzen bei der Anwendung neuer Messtechnologien und Berechnungsverfahren in der Robotik. Die überlegene Leistung des numerischen Solvers gegenüber den neuronalen Netzansätzen unterstreicht die Bedeutung weiterer Forschungen in diesem Bereich.
Das Ziel in dieser Arbeit ist die Programmierung von einem Mikroprozessor, der als ein Richtmikrofon verwendet wird, um unterschiedlichen Richtcharakteristiken zu erzeugen.
Dabei stellt sich die Frage: Ist es möglich ein Mikroprozessor so zu programmieren, dass er eine Stereoaufnahme so verarbeiten kann, sodass unterschiedliche Richtcharakteristiken erzeugt werden könnten?
Um die Frage zu beantworten, wurde eine technische Ausarbeitung von einem Mikroprozessor und seine Programmierung benötigt. Diese befasst sich mit der Programmierung in C++ / Arduino IDE des Mikrokontrollers und eigene Erstellung von Tests, um die Ergebnisse darzustellen.
Als weitere Basis wurden nur verbraucherorientierten Mikroprozessoren untersucht und die beste Möglichkeit wurde ausgesucht und weiterentwickelt. Zudem lag der Fokus auf der Reproduzierbarkeit der Ergebnisse.
Jeder Mensch ist ständig unfreiwillig von einer Flut akustischer Reize umgeben. Diese Situation stellt für Menschen mit Hörverlust eine besondere Herausforderung dar. Menschen mit Hörverlust hören durch Hörgeräte zwar alles verstärkt, jedoch stellt sich die Frage, ob ein Hörgerät lediglich eine einfache Verstärkung von Schallwellen ist oder ob es darüber hinausgehende Funktionen bieten kann.
Die vorliegende Thesis widmet sich der akustischen Szenenanalyse in Hörgeräten, wobei der Schwerpunkt auf der Integration von Machine Learning liegt. Das Ziel besteht darin, eine automatisierte Erkennung und Anpassung an verschiedene akustische Situationen zu ermöglichen. Die Arbeit konzentriert sich insbesondere auf die Analyse grundlegender Szenarien wie: Sprache in Ruhe, absolute Ruhe, Sprache in Störgeräuschen und Störgeräuschen in Audiodaten.
Das Softwareunternehmen HRworks implementiert eine Personalverwaltungssoftware unter Verwendung der Programmiersprache Smalltalk und des Model-View-Controller (MVC) Musters. Innerhalb des Unternehmens erfordert jede Model-Klasse des Patterns das Vorhandensein einer korrespondierenden Controllerklasse. Controller verfügen über ein wiederkehrendes Grundgerüst, das bei jeder neuen Implementierung umgesetzt werden muss. Die Unterscheidungen innerhalb dieses Grundgerüsts ergeben sich lediglich aus dem Namen und der spezifischen Struktur der korrespondierenden Model-Klasse. Die vorliegende Arbeit adressiert die Herausforderung der automatischen Generierung dieses Controllergrundgerüsts, wobei die Besonderheiten jeder Model-Klasse berücksichtigt wird. Dies wird durch den gezielten Einsatz von Metaprogrammierung in der Programmiersprache Smalltalk realisiert und durch eine Benutzeroberfläche in der Entwicklungsumgebung unterstützt. Zusätzlich wird der Controller um eine Datentypprüfung erweitert, wofür ein spezialisierter Parser implementiert wurde. Dieser extrahiert aus einem definierten Getter der Model-Klasse den entsprechenden Datentyp des Attributes. Im Ergebnis liefert die Arbeit eine Methodik zur automatisierten Generierung und Anpassung von Controllergrundgerüsten sowie dazugehörigen Teststrukturen basierend auf der jeweiligen Model-Klasse. Zusätzlich wird die Funktionalität der Controller durch eine integrierte Datentypprüfung erweitert.
Ultra-low-power passive telemetry systems for industrial and biomedical applications have gained much popularity lately. The reduction of the power consumption and size of the circuits poses critical challenges in ultra-low-power circuit design. Biotelemetry applications like leakage detection in silicone breast implants require low-power-consuming small-size electronics. In this doctoral thesis, the design, simulation, and measurement of a programmable mixed-signal System-on-Chip (SoC) called General Application Passive Sensor Integrated Circuit (GAPSIC) is presented. Owing to the low power consumption, GAPSIC is capable of completely passive operation. Such a batteryless passive system has lower maintenance complexity and is also free from battery-related health hazards. With a die area of 4.92 mm² and a maximum analog power consumption of 592 µW, GAPSIC has one of the best figure-of-merits compared to similar state-of-the-art SoCs. Regarding possible applications, GAPSIC can read out and digitally transmit the signals of resistive sensors for pressure or temperature measurements. Additionally, GAPSIC can measure electrocardiogram (ECG) signals and conductivity.
The design of GAPSIC complies with the International Organization for Standardization (ISO) 15693/NFC (near field communication) 5 standard for radio frequency identification (RFID), corresponding to the frequency range of 13.56 MHz. A passive transponder developed with GAPSIC comprises of an external memory storage and very few other external components, like an antenna and sensors. The passive tag antenna and reader antenna use inductive coupling for communication and energy transfer, which enables passive operation. A passive tag developed with GAPSIC can communicate with an NFC compatible smart device or an ISO 15693 RFID reader. An external memory storage contains the programmable application-specific firmware.
As a mixed-signal SoC, GAPSIC includes both analog and digital circuitries. The analog block of GAPSIC includes a power management unit, an RFID/NFC communication unit, and a sensor readout unit. The digital block includes an integrated 32-bit microcontroller, developed by the Hochschule Offenburg ASIC design center, and digital peripherals. A 16-kilobyte random-access memory and a read-only 16-kilobyte memory constitute the GAPSIC internal memory. For the fabrication of GAPSIC, one poly, six-metal 0.18 µm CMOS process is used.
The design of GAPSIC includes two stages. In the first stage, a standalone RFID/NFC frontend chip with a power management unit, an RFID/NFC communication unit, a clock regenerator unit, and a field detector unit was designed. In the second stage, the rest of the functional blocks were integrated with the blocks of the RFID/NFC frontend chip for the final integration of GAPSIC. To reduce the power consumption, conventional low-power design techniques were applied extensively like multiple power supplies, and the operation of complementary metal-oxide-semiconductor (CMOS) transistors in the sub-threshold region of operation, as well as further innovative circuit designs.
An overvoltage protection circuit, a power rectifier, a bandgap reference circuit, and two low-dropout (LDO) voltage regulators constitute the power management unit of GAPSIC. The overvoltage protection circuit uses a novel method where three stacked transistor pairs shunt the extra voltage. In the power rectifier, four rectifier units are arranged in parallel, which is a unique approach. The four parallel rectifier units provide the optimal choice in terms of voltage drop and the area required.
The communication unit is responsible for RFID/NFC communication and incorporates demodulation and load modulation circuitry. The demodulator circuit comprises of an envelope detector, a high-pass filter, and a comparator. Following a new approach, the bandgap reference circuit itself acts as the load for the envelope detector circuit, which minimizes the circuit complexity and area. For the communication between the reader and the RFID/NFC tag, amplitude-shift keying (ASK) is used to modulate signals, where the smallest modulation index can be as low as 10%. A novel technique involving a comparator with a preset offset voltage effectively demodulates the ASK signal. With an effective die area of 0.7 mm² and power consumption of 107 µW, the standalone RFID/NFC frontend chip has the best figure-of-merits compared to the state-of-the-art frontend chips reported in the relevant literature. A passive RFID/NFC tag developed with the standalone frontend chip, as well as temperature and pressure sensors demonstrate the full passive operational capability of the frontend chip. An NFC reader device using a custom-built Android-based application software reads out the sensor data from the passive tag.
The sensor readout circuit consists of a channel selector with two differential and four single-ended inputs with a programmable-gain instrumentation amplifier. The entire sensor readout part remains deactivated when not in use. The internal memory stores the measured offset voltage of the instrumentation amplifier, where a firmware code removes the offset voltage from the measured sensor signal. A 12-bit successive approximation register (SAR) type analog-to-digital-converter (ADC) based on a charge redistribution architecture converts the measured sensor data to a digital value. The digital peripherals include a serial peripheral interface, four timers, RFID/NFC interfaces, sensor readout unit interfaces, and 12-bit SAR logic.
Two sets of studies with custom-made NFC tag antennas for biomedical applications were conducted to ascertain their compatibility with GAPSIC. The first study involved the link efficiency measurements of NFC tag antennas and an NFC reader antenna with porcine tissue. In a separate experiment, the effect of a ferrite compared to air core on the antenna-coupling factor was investigated. With the ferrite core, the coupling factor increased by four times.
Among the state-of-the-art SoCs published in recent scientific articles, GAPSIC is the only passive programmable SoC with a power management unit, an RFID/NFC communication interface, a sensor readout circuit, a 12-bit SAR ADC, and an integrated 32-bit microcontroller. This doctoral research includes the preliminary study of three passive RFID tags designed with discrete components for biomedical and industrial applications like measurements of temperature, pH, conductivity, and oxygen concentration, along with leakage detection in silicone breast implants. Besides its small size and low power consumption, GAPSIC is suitable for each of the biomedical and industrial applications mentioned above due to the integrated high-performance microcontroller, the robust programmable instrumentation amplifier, and the 12-bit analog-to-digital converter. Furthermore, the simulation and measurement data show that GAPSIC is well suited for the design of a passive tag to monitor arterial blood pressure in patients experiencing Peripheral Artery Disease (PAD), which is proposed in this doctoral thesis as an exemplary application of the developed system.
In many application areas, Deep Reinforcement Learning (DRL) has led to breakthroughs. In Curriculum Learning, the Machine Learning algorithm is not randomly presented with examples, but in a meaningful order of increasing difficulty. This has been used in many application areas to further improve the results of learning systems or to reduce their learning time. Such approaches range from learning plans created manually by domain experts to those created automatically. The automated creation of learning plans is one of the biggest challenges.In this work, we investigate an approach in which a trainer learns in parallel and analogously to the student to automatically create a learning plan for the student during this Double Deep Reinforcement Learning (DDRL). Three Reward functions, Friendly, Adversarial, and Dynamic based on the learner’s reward are compared. The domain for evaluation is kicking with variable distance, direction and relative ball position in the SimSpark simulated soccer environment.As a result, Statistic Curriculum Learning (SCL) performs better than a random curriculum with respect to training time and result quality. DDRL reaches a comparable quality as the baseline and outperforms it significantly in shorter trainings in the distance-direction subdomain reducing the number of required training cycles by almost 50%.
Die Arbeit beinhaltet die Konzeption und den Aufbau eines Prüfstandes für den Elektromotor sowie den Antriebsstrang des Hocheffizienzfahrzeugs "Schluckspecht S6" der Hochschule Offenburg. Neben Beschreiben des Vorgehens bei dem Entwerfen von benötigten CAD-Modellen wird auch auf die Auswahl und Implementierung elektronischer Komponenten sowie die Programmierung des verwendeten Mikrocontrollers eingegangen. Die Ergebnisse eines ersten Tests des Prüfstandes werden außerdem aufgezeigt und diskutiert.
This research presents a comprehensive exploration of hydroponic systems and their practical applications, with a focus on innovative solutions for managing environmental and analytical sensors in hydroponic setups. Hydroponic systems, which enable soilless cultivation, have gained increasing importance in modern agriculture due to their resource-efficient and high-yield nature.
The study delves into the development and deployment of the SensVert system, an adaptable solution tailored for hydroponic environments. SensVert offers adaptability and accessibility to farmers across various agricultural domains, addressing contemporary challenges in supervising and managing environmental and analytical sensors within hydroponic setups. Leveraging LoRa technology for seamless wireless data transmission, SensVert empowers users with a feature-rich dashboard for real-time monitoring and control. The study showcases the practical implementation of SensVert through a single sensor node, seamlessly integrating temperature, humidity, pressure, light, and pH sensors. The system automates pH regulation, employing the Henderson-Hasselbalch equation, and precisely controls liquid dosing using a PID controller. At the core of SensVert lies an architecture comprising The Things Stack as the network server, Node-Red as the application server, and Grafana as the user interface. These components synergize within a local network hosted on a Raspberry Pi; effectively mitigating challenges associated with data packet transmission in areas with limited internet connectivity.
As part of ongoing research, this work also paves the way for future advancements. These include the establishment of a wireless sensor network (WSN) utilizing LoRa technology, enabling seamless over-the-air sensor node updates for maintenance or replacement scenarios. These enhancements promise to further elevate the system's reliability and functionality within hydroponic cultivation, fostering sustainable agricultural practices.
In the past ten years, applications of artificial neural networks have changed dramatically. outperforming earlier predictions in domains like robotics, computer vision, natural language processing, healthcare, and finance. Future research and advancements in CNN architectures, Algorithms and applications are expected to revolutionize various industries and daily life further. Our task is to find current products that resemble the given product image and description. Deep learning-based automatic product identification is a multi-step process that starts with data collection and continues with model training, deployment, and continuous improvement. The caliber and variety of the dataset, the design selected, and ongoing testing and improvement all affect the model's effectiveness. We achieved 81.47% training accuracy and 72.43% validation accuracy for our combined text and image classification model. Additionally, we have discussed the outcomes from the other dataset and numerous methods for creating an appropriate model.
The mathematical representations of data in the Spherical Harmonic (SH) domain has recently regained increasing interest in the machine learning community. This technical report gives an in-depth introduction to the theoretical foundation and practical implementation of SH representations, summarizing works on rotation invariant and equivariant features, as well as convolutions and exact correlations of signals on spheres. In extension, these methods are then generalized from scalar SH representations to Vectorial Harmonics (VH), providing the same capabilities for 3d vector fields on spheres.
Team description papers of magmaOffenburg are incremental in the sense that each year we address a different topic of our team and the tools around our team. In this year’s team description paper we focus on the architecture of the software. It is a main factor for being able to keep the code maintainable even after 15 years of development. We also describe how we make sure that the code follows this architecture.
Conceptualization and implementation of automated optimization methods for private 5G networks
(2023)
Today’s companies are adjusting to the new connectivity realities. New applications require more bandwidth, lower latency, and higher reliability as industries become more distributed and autonomous. Private 5th Generation (5G) networks known as 5G Non-Public Networks (5G-NPN), is a novel 3rd Generation Partnership Project (3GPP)- based 5G network that can deliver seamless and dedicated wireless access for a particular industrial use case by providing the mentioned application’s requirements. To meet these requirements, several radio-related aspects and network parameters should be considered. In many cases, the behavior of the link connection may vary based on wireless conditions, available network resources, and User Equipment (UE) requirements. Furthermore, Optimizing these networks can be a complex task due to the large number of network parameters and KPIs that need to be considered. For these reasons, traditional solutions and static network configuration are not affordable or simply impossible. Despite the existence of papers in the literature that address several optimization methods for cellular networks in industrial scenarios, more insight into these existing but complex or unknown methods is needed.
In this thesis, a series of optimization methods were implemented to deliver an optimal configuration solution for a 5G private network. To facilitate this implementation, a testing system was implemented. This system enables remote control over the UE and 5G network, establishment of a test environment, extraction of relevant KPI reports from both UE and network sides, assessment of test results and KPIs, and effective utilization of the optimization and sampling techniques.
The research highlights the advantageous aspects of automated testing by using OFAT, Simulated Annealing, and Random Forest Regressor methods. With OFAT, as a common sampling method, a sensitivity analysis and an impact of each single parameter variation on the performance of the network were revealed. With Simulated Annealing, an optimal solution with MSE of roughly 10 was revealed. And, in the Random Forest Regressor, it was seen that this method presented a significant advantage over the simulated annealing method by providing substantial benefits in time efficiency due to its machine- learning capability. Additionally, it was seen that by providing a larger dataset or using some other machine-learning techniques, the solution might be more accurate.
Ensuring that software applications present their users the most recent version of data is not trivial. Self-adjusting computations are a technique for automatically and efficiently recomputing output data whenever some input changes.
This article describes the software architecture of a large, commercial software system built around a framework for coarse-grained self-adjusting computations in Haskell. It discusses advantages and disadvantages based on longtime experience. The article also presents a demo of the system and explains the API of the framework.
Die Visualisierung von Programmabläufen ist ein zentraler Aspekt für Programmieranfänger, um das Verständnis von Codeabläufen zu erleichtern und den Einstieg in der Softwareentwicklung zu unterstützen. In dieser Masterthesis wird ein speziell auf die Bedürfnisse von Einsteigern zugeschnittenes generisches Framework vorgestellt, wobei der Fokus auf einer einfachen, verständlichen aber auch korrekten Darstellung der Programmausführung liegt. Das Framework integriert das Debugger Adapter Protocol, um den Debugger unterschiedlicher Sprachen ansprechen und verwenden zu können.
In dieser Arbeit werden zunächst die Anforderungen für das generische Framework diskutiert. Anschließend werden bestehende Ansätze zur Visualisierung von Programmabläufen ausführlich untersucht und analysiert. Die Implementierung des Frameworks wird daraufhin detailliert beschrieben, wobei besonderer Wert auf die Erweiterbarkeit unterschiedlicher Sprachen gelegt wird.
Um die Eignung des Frameworks zu evaluieren, werden mehrere Aufgaben aus dem ersten Modul mit der jeweiligen Programmiersprache des Studiengangs Angewandte Informatik der Hochschule Offenburg betrachtet. Die Ergebnisse zeigen, dass das Framework mit den Aufgaben umgehen und diese korrekt und verständlich darstellen kann.
Assessing the robustness of deep neural networks against out-of-distribution inputs is crucial, especially in safety-critical domains like autonomous driving, but also in safety systems where malicious actors can digitally alter inputs to circumvent safety guards. However, designing effective out-of-distribution tests that encompass all possible scenarios while preserving accurate label information is a challenging task. Existing methodologies often entail a compromise between variety and constraint levels for attacks and sometimes even both. In a first step towards a more holistic robustness evaluation of image classification models, we introduce an attack method based on image solarization that is conceptually straightforward yet avoids jeopardizing the global structure of natural images independent of the intensity. Through comprehensive evaluations of multiple ImageNet models, we demonstrate the attack's capacity to degrade accuracy significantly, provided it is not integrated into the training augmentations. Interestingly, even then, no full immunity to accuracy deterioration is achieved. In other settings, the attack can often be simplified into a black-box attack with model-independent parameters. Defenses against other corruptions do not consistently extend to be effective against our specific attack.
Project website: https://github.com/paulgavrikov/adversarial_solarization
Fix your downsampling ASAP! Be natively more robust via Aliasing and Spectral Artifact free Pooling
(2023)
Convolutional neural networks encode images through a sequence of convolutions, normalizations and non-linearities as well as downsampling operations into potentially strong semantic embeddings. Yet, previous work showed that even slight mistakes during sampling, leading to aliasing, can be directly attributed to the networks' lack in robustness. To address such issues and facilitate simpler and faster adversarial training, [12] recently proposed FLC pooling, a method for provably alias-free downsampling - in theory. In this work, we conduct a further analysis through the lens of signal processing and find that such current pooling methods, which address aliasing in the frequency domain, are still prone to spectral leakage artifacts. Hence, we propose aliasing and spectral artifact-free pooling, short ASAP. While only introducing a few modifications to FLC pooling, networks using ASAP as downsampling method exhibit higher native robustness against common corruptions, a property that FLC pooling was missing. ASAP also increases native robustness against adversarial attacks on high and low resolution data while maintaining similar clean accuracy or even outperforming the baseline.
Detecting Images Generated by Deep Diffusion Models using their Local Intrinsic Dimensionality
(2023)
Diffusion models recently have been successfully applied for the visual synthesis of strikingly realistic appearing images. This raises strong concerns about their potential for malicious purposes. In this paper, we propose using the lightweight multi Local Intrinsic Dimensionality (multiLID), which has been originally developed in context of the detection of adversarial examples, for the automatic detection of synthetic images and the identification of the according generator networks. In contrast to many existing detection approaches, which often only work for GAN-generated images, the proposed method provides close to perfect detection results in many realistic use cases. Extensive experiments on known and newly created datasets demonstrate that the proposed multiLID approach exhibits superiority in diffusion detection and model identification.Since the empirical evaluations of recent publications on the detection of generated images are often mainly focused on the "LSUN-Bedroom" dataset, we further establish a comprehensive benchmark for the detection of diffusion-generated images, including samples from several diffusion models with different image sizes.The code for our experiments is provided at https://github.com/deepfake-study/deepfake-multiLID.
Erlang is a functional programming language with dynamic typing. The language offers great flexibility for destructing values through pattern matching and dynamic type tests. Erlang also comes with a type language supporting parametric polymorphism, equi-recursive types, as well as union and a limited form of intersection types. However, type signatures only serve as documentation; there is no check that a function body conforms to its signature.
Set-theoretic types and semantic subtyping fit Erlang’s feature set very well. They allow expressing nearly all constructs of its type language and provide means for statically checking type signatures. This article brings set-theoretic types to Erlang and demonstrates how existing Erlang code can be statically type checked without or with only minor modifications to the code. Further, the article formalizes the main ingredients of the type system in a small core calculus, reports on an implementation of the system, and compares it with other static type checkers for Erlang.
In recent years, predictive maintenance tasks, especially for bearings, have become increasingly important. Solutions for these use cases concentrate on the classification of faults and the estimation of the Remaining Useful Life (RUL). As of today, these solutions suffer from a lack of training samples. In addition, these solutions often require high-frequency accelerometers, incurring significant costs. To overcome these challenges, this research proposes a combined classification and RUL estimation solution based on a Convolutional Neural Network (CNN) and a Long Short-Term Memory (LSTM) network. This solution relies on a hybrid feature extraction approach, making it especially appropriate for low-cost accelerometers with low sampling frequencies. In addition, it uses transfer learning to be suitable for applications with only a few training samples.
With the rising necessity of explainable artificial intelligence (XAI), we see an increase in task-dependent XAI methods on varying abstraction levels. XAI techniques on a global level explain model behavior and on a local level explain sample predictions. We propose a visual analytics workflow to support seamless transitions between global and local explanations, focusing on attributions and counterfactuals on time series classification. In particular, we adapt local XAI techniques (attributions) that are developed for traditional datasets (images, text) to analyze time series classification, a data type that is typically less intelligible to humans. To generate a global overview, we apply local attribution methods to the data, creating explanations for the whole dataset. These explanations are projected onto two dimensions, depicting model behavior trends, strategies, and decision boundaries. To further inspect the model decision-making as well as potential data errors, a what-if analysis facilitates hypothesis generation and verification on both the global and local levels. We constantly collected and incorporated expert user feedback, as well as insights based on their domain knowledge, resulting in a tailored analysis workflow and system that tightly integrates time series transformations into explanations. Lastly, we present three use cases, verifying that our technique enables users to (1)~explore data transformations and feature relevance, (2)~identify model behavior and decision boundaries, as well as, (3)~the reason for misclassifications.
Entity Matching (EM) defines the task of learning to group objects by transferring semantic concepts from example groups (=entities) to unseen data. Despite the general availability of image data in the context of many EM-problems, most currently available EM-algorithms solely rely on (textual) meta data. In this paper, we introduce the first publicly available large-scale dataset for "visual entity matching", based on a production level use case in the retail domain. Using scanned advertisement leaflets, collected over several years from different European retailers, we provide a total of ~786k manually annotated, high resolution product images containing ~18k different individual retail products which are grouped into ~3k entities. The annotation of these product entities is based on a price comparison task, where each entity forms an equivalence class of comparable products. Following on a first baseline evaluation, we show that the proposed "visual entity matching" constitutes a novel learning problem which can not sufficiently be solved using standard image based classification and retrieval algorithms. Instead, novel approaches which allow to transfer example based visual equivalent classes to new data are needed to address the proposed problem. The aim of this paper is to provide a benchmark for such algorithms.
Information about the dataset, evaluation code and download instructions are provided under https://www.retail-786k.org/.
Following the traditional paradigm of convolutional neural networks (CNNs), modern CNNs manage to keep pace with more recent, for example transformer-based, models by not only increasing model depth and width but also the kernel size. This results in large amounts of learnable model parameters that need to be handled during training. While following the convolutional paradigm with the according spatial inductive bias, we question the significance of \emph{learned} convolution filters. In fact, our findings demonstrate that many contemporary CNN architectures can achieve high test accuracies without ever updating randomly initialized (spatial) convolution filters. Instead, simple linear combinations (implemented through efficient 1×1 convolutions) suffice to effectively recombine even random filters into expressive network operators. Furthermore, these combinations of random filters can implicitly regularize the resulting operations, mitigating overfitting and enhancing overall performance and robustness. Conversely, retaining the ability to learn filter updates can impair network performance. Lastly, although we only observe relatively small gains from learning 3×3 convolutions, the learning gains increase proportionally with kernel size, owing to the non-idealities of the independent and identically distributed (\textit{i.i.d.}) nature of default initialization techniques.
Modern CNNs are learning the weights of vast numbers of convolutional operators. In this paper, we raise the fundamental question if this is actually necessary. We show that even in the extreme case of only randomly initializing and never updating spatial filters, certain CNN architectures can be trained to surpass the accuracy of standard training. By reinterpreting the notion of pointwise ($1\times 1$) convolutions as an operator to learn linear combinations (LC) of frozen (random) spatial filters, we are able to analyze these effects and propose a generic LC convolution block that allows tuning of the linear combination rate. Empirically, we show that this approach not only allows us to reach high test accuracies on CIFAR and ImageNet but also has favorable properties regarding model robustness, generalization, sparsity, and the total number of necessary weights. Additionally, we propose a novel weight sharing mechanism, which allows sharing of a single weight tensor between all spatial convolution layers to massively reduce the number of weights.
This paper presents the new Deep Reinforcement Learning (DRL) library RL-X and its application to the RoboCup Soccer Simulation 3D League and classic DRL benchmarks. RL-X provides a flexible and easy-to-extend codebase with self-contained single directory algorithms. Through the fast JAX-based implementations, RL-X can reach up to 4.5x speedups compared to well-known frameworks like Stable-Baselines3.
We have developed a methodology for the systematic generation of a large image dataset of macerated wood references, which we used to generate image data for nine hardwood genera. This is the basis for a substantial approach to automate, for the first time, the identification of hardwood species in microscopic images of fibrous materials by deep learning. Our methodology includes a flexible pipeline for easy annotation of vessel elements. We compare the performance of different neural network architectures and hyperparameters. Our proposed method performs similarly well to human experts. In the future, this will improve controls on global wood fiber product flows to protect forests.
TSN, or Time Sensitive Networking, is becoming an essential technology for integrated networks, enabling deterministic and best effort traffic to coexist on the same infrastructure. In order to properly configure, run and secure such TSN, monitoring functionality is a must. The TSN standard already has some preparations to provide such functionality and there are different methods to choose from. We implemented different methods to measure the time synchronisation accuracy between devices as a C library and compared the measurement results. Furthermore, the library has been integrated into the ControlTSN engineering framework.
In der vorliegenden Arbeit wird die Auswirkung der biomechanischen Stimulation (BMS) der Beinmuskulatur auf die Herzfrequenzvariabilität (HRV) untersucht. Die HRV charakterisiert die Variabilität der Intervalle aufeinanderfolgender Herzaktionen (beeinflusst durch das vegetative Nervensystem) und liefert Aussagen über die Qualität der Herz-Kreislaufregulation. Eine erhöhte körperliche Aktivität führt zu einer höheren HRV und einem besseren Gesundheitszustand. Die BMS ermöglicht das Hervorrufen einer natürlichen Muskelarbeit, die viel effektiver als ein konventionelles Training ist. Bei 8 Probanden im Alter zwischen 21 und 32 Jahren und mit Sinusrhythmus wurde der Einfluss der BMS (durchgeführt mit 12 Hz oder 16 Hz) auf die HRV analysiert. In der Arbeit werden 16 verschiedene HRV-Parameter (zeitbezogen, frequenzbezogen und nicht linear) auf Veränderungen hin untersucht.
Bei der Auswertung ergab sich eine signifikante Reduktion der mittleren Herzfrequenz nach der Stimulation bei 7 von 8 Testpersonen (p: 0,00687 < 0,5) und zeigte somit eine positive hämodynamische Wirksamkeit der BMS. Die LF-Power (Spektralleistung im niederfrequenten Bereich) mittels FFT reduzierte sich bei 7 von 8 Probanden (p: 0,3181 < 0,5), mittels AR sogar bei 8 von 8 Testpersonen (p: 0,03082 < 0,5). Anhand beider Parameter konnte somit eine Reduktion der sympathischen und parasympathischen Aktivität beobachtet werden. Eine Erhöhung der Tätigkeit des Parasympathikus konnte bei dem VLF% (prozentualer Anteil des sehr niederfrequenten Bereichs bezogen auf das Gesamtspektrum) beider Berechnungsmethoden nachgewiesen werden. Dort hat sich der Wert in beiden Fällen bei 7 von 8 Personen vergrößert. Der SD1-Wert (Standardabweichung der Punktabstände im Poincaré Plot - Querdurchmesser) hat sich bei 2 von 8 Testpersonen erhöht und dementsprechend auch die parasympathische Aktivität (p: 0,1292 < 0,5).
Go ist eine 2009 veröffentlichte Programmiersprache mit einem statischen Typsystem. Seit Version 1.18 sind auch Generics ein Teil der Sprache. Deren Übersetzung wurde im de facto Standard-Compiler mittels Monomorphisierung umgesetzt. Diese bringt neben einigen Vorteilen auch Nachteile mit sich. Aus diesem Grund beschäftigt sich diese Arbeit mit einer alternativen Übersetzungsstrategie für Generics in Go und implementiert diese in einem neuen Compiler für Featherweight Generic Go, einem Subset von Go. Zum Schluss steht damit ein nahezu funktionierender Compiler, welcher schließlich Racket-Code ausgibt. Eine Evaluierung der Performanz der Übersetzungsstrategie ist allerdings noch ausstehend.
Das Ziel der Arbeit ist zu erforschen, ob die Erstellung eines Digital Twin des Hamburger Hafens durch Open Source Lösungen realisierbar ist. Die Grundlagen führen in die Themen Digital Twin und Smart City ein. Es wird darauf eingegangen, welche Vorteile durch die Verwendung eines Digital Twins gewonnen werden können und wie sich die verschiedenen Digital Twin-Typen unterscheiden. Es werden verschiedene Architekturen anhand eines Smart City Index weltweit evaluiert, um ein geeignetes Digital Twin-Framework zu finden. FIWARE hat sich als geeignetes Frame- work erwiesen und wird im Anschluss analysiert. Anhand der Evaluierung wird ebenfalls das 3D-Visualisierungs Framework CesiumJS als Open Source Lösung ermit- telt. Das Unternehmen Hamburg Port Authority wird vorgestellt und die interne IT- Infrastruktur betrachtet. Anhand der Architekturdokumentation arc42 werden die Anforderungen und die erforderliche Architektur in Zusammenarbeit mit der Hamburg Port Authority ermittelt. Im Anschluss wird der Architekturentwurf anhand eines Prototyps implementiert. Probleme oder Anforderungen, die nicht erfüllt werden können, werden beschrieben. Abschließend werden die Ergebnisse und das Fazit der Hamburg Port Authority zusammengefasst.
Im Rahmen dieser Arbeit wurde das elektrisch / elektronische System des Hocheffizienzfahrzeugs „Schluckspecht 6“ hinsichtlich seiner Übersichtlichkeit und Modularität optimiert. Essenziell war die Vernetzung der durch verschiedene Projektgruppen erstellten Teilsysteme mittels des neu integrierten CAN-Bus. Im Zuge der Überarbeitung des E/E-Systems wurde auch ein neuer Gesamtfahrzeugschaltplan angefertigt.
Im Rahmen der Optimierung des E-Antriebsstrangs wurde eine neue Motorsteuerung entwickelt, die aufgrund des verbauten Vierquadrantenstellers neben einem zuverlässigen Antrieb des Schluckspecht 6 zukünftig auch die Steuerung und Regelung von Lastmaschinen in – für den Schluckspecht 6 neu entwickelten – Testständen erlaubt. Für die Messdatenerfassung, während Test- und Rennläufen sowie in den Testständen, wurden diverse Messsysteme realisiert. Dazu gehören die Messung des Motorstroms, der Zwischenkreisspannung und der Motordrehzahl. Basierend auf der Motorstrommessung und Zwischenkreisspannungsmessung wurde eine Stromregelung implementiert, um die Bedienfreundlichkeit und Effizienz des S6 im Rennbetrieb zu erhöhen.
Neural networks have a number of shortcomings. Amongst the severest ones is the sensitivity to distribution shifts which allows models to be easily fooled into wrong predictions by small perturbations to inputs that are often imperceivable to humans and do not have to carry semantic meaning. Adversarial training poses a partial solution to address this issue by training models on worst-case perturbations. Yet, recent work has also pointed out that the reasoning in neural networks is different from humans. Humans identify objects by shape, while neural nets mainly employ texture cues. Exemplarily, a model trained on photographs will likely fail to generalize to datasets containing sketches. Interestingly, it was also shown that adversarial training seems to favorably increase the shift toward shape bias. In this work, we revisit this observation and provide an extensive analysis of this effect on various architectures, the common L_2-and L_-training, and Transformer-based models. Further, we provide a possible explanation for this phenomenon from a frequency perspective.
Seismic data processing relies on multiples attenuation to improve inversion and interpretation. Radon-based algorithms are often used for multiples and primaries discrimination. Deep learning, based on convolutional neural networks (CNNs), has shown encouraging applications for demultiple that could mitigate Radon-based challenges. In this work, we investigate new strategies to train a CNN for multiples removal based on different loss functions. We propose combined primaries and multiples labels in the loss for training a CNN to predict primaries, multiples, or both simultaneously. Moreover, we investigate two distinctive training methods for all the strategies: UNet based on minimum absolute error (L1) training, and adversarial training (GAN-UNet). We test the trained models with the different strategies and methods on 400 synthetic data. We found that training to predict multiples, including the primaries …
The goal of this thesis is to thoroughly investigate the concepts of stand-alone and decarbonization of optical fiber networks. Because of their dependability, fast speed, and capacity, optical fiber networks are vital inmodern telecommunications. Their considerable energy consumption and carbon emissions, on the other hand, constitute a danger to global sustainability objectives and must be addressed.
The first section of the thesis presents a summary of the current state of optical fiber networks, their
components, and the energy consumption connected with them. This part also goes over the difficulties of lowering energy usage and carbon emissions while preserving network performance and dependability.
The second section of the thesis focuses on the stand-alone idea, which entails powering the optical fiber network with renewable energy sources and energy-efficient technology. This section investigates and explores the possibilities of renewable energy sources like solar and wind power to power the network. It also investigates energy-efficient technologies like virtualization and cloud computing, as well as their potential to minimize network energy usage.
The third section of the thesis focuses on the notion of decarbonization, which entails lowering carbon emissions linked with the optical fiber network. This section looks at various carbon-reduction measures, such as employing low-carbon energy sources and improving energy efficiency. It also covers the relevance of carbon offsets and the difficulties associated with adopting decarbonization measures in the context of optical fiber networks.
The fourth section of the thesis compares the ideas of stand-alone and decarbonization. It investigates the advantages and disadvantages of each strategy, as well as their potential to minimize energy consumption and carbon emissions in optical fiber networks. It also explores the difficulties in applying these notions as well as potential hurdles to their wider adoption.
Finally, the need of addressing the energy consumption and carbon emissions connected with optical fiber networks is emphasized in this thesis.
It outlines important obstacles and potential impediments to adopting these initiatives and gives insights into potential ways for decreasing them.
It also makes suggestions for further study in this area.
Die Thesis beschäftigt sich mit dem Kommunikationsprotokoll Lightweight Machine to Machine, welches für das Internet of Things entwickelt wurde. Es soll untersucht werden, wie das Protokoll funktioniert und wie es eingesetzt werden kann. Ebenfalls soll die Thesis zeigen, wie und ob Lightweight Machine to Machine über Long Term Evolution for Machines für Anwendungen mit begrenzten Ressourcen geeignet ist. Um diese Fragestellung zu beantworten, wurde das Protokoll auf Grund seiner Spezifikation und seinen Softwareimplementationen untersucht. Daraufhin wurde ein Versuchssystem entworfen und dieses anschließend auf sein Laufzeitverhalten und auf sein Energieverbrauch getestet. Die Evaluation des Protokolls ergab, dass es viele sinnvolle Funktionen zugeschnitten auf Geräte im Internet of Things besitzt und diese Funktionen kompakt und verständlich umsetzt. Da das Protokoll noch relativ jung ist, stellt es an verschiedenen Punkten eine Herausforderung dar. Die Tests des Versuchssystems ergaben, dass Lightweight Machine to Machine sich unter bestimmten Bedingungen für ressourcenbegrenzte Anwendungen eignet.
Sweaty has already participated several times in RoboCup soccer competitions (Adult Size). Now the work is focused coordinating the play of two robots. Moreover, we are working on stabilizing the gait by adding additional sensor information. An ongoing work is the optimization of the control strategy by balancing between impedance and position control. By minimizing the jerk, gait and overall gameplay should improve significantly.
Die Impedanzkardiografie ist ein nicht-invasives Verfahren zur Messung der Funktion des Herzens, welche wiederum auf der Erfassung von elektrischen Impedanzänderungen im Thorax basiert. Die Verbindung der Impedanzkardiografie mit der biomechanischen Stimulation der Beinmuskulatur hat das Potenzial, die kardiale Ausgangsleistung zu verbessern und somit die körperliche Leistungsfähigkeit zu steigern. In dieser Bachelorarbeit wurden die Auswirkungen der biomechanischen Stimulation der Beinmuskulatur und der Stimulationsfrequenz auf die Impedanzkardiografie untersucht. Zu diesem Zweck wurden Messungen an überwiegend gesunden Probanden durchgeführt, bei denen die Impedanzkardiografie in Ruhe vor und in Ruhe nach der biomechanischen Stimulation der Wade, der Fußsohlen, der Taille und des Gesäßes durchgeführt wurde. Die Ergebnisse zeigen, dass die biomechanische Stimulation der Beinmuskulatur vor allem die Arbeitsparameter und somit die Leistungsfähigkeit verbessert hat. Der mittlere arterielle Blutdruck zeigt einen signifikanten Unterschied, mit Werten von 94,53 ± 6,52 mmHg vor der Stimulation bis 86,46 ± 6,98mmHg nach der Stimulation. Die mittlere linksventrikuläre Arbeitszeit zeigt ebenfalls einen großen Unterschied von 7,95 ± 1,06 kg*m vor der Stimulation zu 7,17 ± 1,04 kg*m nach der Stimulation. Diese Ergebnisse können in der zukünftigen Forschung zur Entwicklung von Trainingsprogrammen zur Leistungssteigerung genutzt werden. Darüber hinaus könnten diese Ergebnisse bei der Schmerzbehandlung eingesetzt werden, da es Hinweise darauf gibt, dass die biomechanische Stimulation die Mikrozirkulation fördert.
When a patient with hearing aids needs to partake in audiometry procedures they need to visit a specialist which costs both time and money. Ideally, the patient should be able to conduct these tests alone, during their own time, and without additional costs. With this idea comes the question of if whether this is possible or not, and, if it is, how.
This thesis explores the throughput of Bluetooth Low Energy and if it is configurable to have a high enough data rate to send high quality audio data with a lossless audio codec while communicating with a low end device. Additionally, this thesis will show that using Rust to develop embedded software is possible and how using it can make the process of doing so easier.
In dieser Arbeit wird der Bildbearbeitungsprozess von Dokumenten mithilfe von einem schlicht gehaltenem Neuronalen Netzwerk und Bearbeitungsoperationen optimiert. Ziel ist es, abfotografierte Dokumente zum Drucken aufzubereiten, sodass die Schrift gut lesbar, gerade und nicht verzerrt ist und Störfaktoren herausgefiltert werden. Als API zur Verfügung gestellt, können Bilder von Dokumenten beliebiger Größe und Schriftgröße bearbeitet werden. Während ein unter schlechten Bedingungen schräg aufgenommenes Bild nach Tesseract keine Buchstaben enthält, wird mit dem bearbeiteten Bild davon eine Buchstabenfehlerrate von 0,9% erreicht.
In this paper, the performance of different continuous-time and discrete-time models of the electrical subsystem of induction machines and permanent-magnet synchronous machines as well as methods based on them for decoupling the direct and
quadrature axis components of the stator current are investigated and compared. The focus here is on inverter-fed, pulse width modulated drives when operated with a relatively large product of stator frequency and sampling time, where significant
differences between the models and decoupling methods used come to light. Recommendations for a discrete-time model to be used uniformly in the future are made, as well as statements on whether feedforward or feedback decoupling structures are better suited and whether state controllers improve decoupling measures for very steep speed ramps. Simulation studies and measurement results support the statements made above.
Das Ziel dieser Arbeit ist die technische Konstruktion eines Prototyps für einen Kopf-und Rumpfsimulator aus dem 3D-Druck mit integriertem Zwei-Kanal-System zur Freifeldmessung akustischer Signale. Die akustischen Eigenschaften sind abhängig von der anatomischen Geometrie eines menschlichen Schädels und des Gehörs, somit soll die Konstruktion des Prototyps möglichst realitätsgetreu nachgeahmt werden. Der Prototyp soll technische Anforderungen wie den Ein- und Ausbau von unterschiedlichen Mikrofonen und Pinna-Modellen gewährleisten.
Das Ziel dieser Arbeit ist es, eine Schnittstelle zu erstellen, die es erlaubt, dem vom Unternehmen produzierten modulbasierten ERP-System Module zu integrieren, die
mit der aktuellen Version der Programmiersprache Delphi erstellt wurden.
Die Schwierigkeit hierbei ist, dass die momentane Implementation des Systems auf
einer Jahrzehnte alten Version der Sprache basiert, die in mehreren Bereichen keine
Kompatibilität mit der neuen Version besitzt.
Um dieses Ziel zu erreichen wurden zunächst die konkreten Anforderungen an die
Lösung formuliert und daraufhin verschiedene Lösungsansätze für eine Schnittstelle
konzipiert.
Durch Testen an einer prototypisch vereinfachten Version des ERP-Systems konnte
festgestellt werden, dass eine Lösung über eine auf Datenbanktransaktionen basierende Schnittstelle für das Projekt am ehesten geeignet war.
Nach weiterer Planung des exakten Aufbaus wurden die nötigen Funktionalitäten dann
umgesetzt, wobei zuerst in groben Zügen die essentiellen Aspekte realisiert wurden,
welche dann in weiteren Durchläufen auf die exakten Spezifikationen verfeinert und
auf Fehler geprüft wurden.
Nachdem dieser Lösungsansatz einen ausreichenden Vervollständigungsgrad erreicht
hatte, wurde das Projekt zu Testzwecken in firmeninternem Umfeld in Betrieb genommen.
Durch anschließendes weiteres Beheben von noch ausstehenden Fehlern wurde das
Projekt dann in einen Zustand gebracht, in dem es allgemein in Verwendung genommen werden kann und somit die gewünschten Vorgaben erfüllt.
AI-based Ground Penetrating Radar Signal Processing for Thickness Estimation of Subsurface Layers
(2023)
This thesis focuses on the estimation of subsurface layer thickness using Ground Penetrating Radar (GPR) A-scan and B-scan data through the application of neural networks. The objective is to develop accurate models capable of estimating the thickness of up to two subsurface layers.
Two different approaches are explored for processing the A-scan data. In the first approach, A-scans are compressed using Principal Component Analysis (PCA), and a regression feedforward neural network is employed to estimate the layers’ thicknesses. The second approach utilizes a regression one-dimensional Convolutional Neural Network (1-D CNN) for the same purpose. Comparative analysis reveals that the second approach yields superior results in terms of accuracy.
Subsequently, the proposed 1-D CNN architecture is adapted and evaluated for Step Frequency Continuous Wave (SFCW) radar, expanding its applicability to this type of radar system. The effectiveness of the proposed network in estimating subsurface layer thickness for SFCW radar is demonstrated.
Furthermore, the thesis investigates the utilization of GPR B-scan images as input data for subsurface layer thickness estimation. A regression CNN is employed for this purpose, although the results achieved are not as promising as those obtained with the 1-D CNN using A-scan data. This disparity is attributed to the limited availability of B-scan data, as B-scan generation is a resource-intensive process.
Hintergrund:
Die Versorgung von Patienten mit Cochleaimplantaten erfordert im Rahmen der Rehabilitation nicht nur Hörtrainings, sondern auch regelmäßige Erfassungen des Hörvermögens. Diese Tests konzentrieren sich hierbei meist auf das Vertehen von Sprache. Hierbei müssen Patienten Wörter oder Zahlen unter Vorhandensein von Störgeräuschen verstehen. Diese Störgeräusche sind in der Regel künstlicher Natur wie Rauschen. Das Ziel dieser Arbeit ist es, diese künstlichen Störgeräusche durch realistischere zu ersetzen und zusätzlich einen Raumklang sowohl für die Störgeräusche als auch für die zu verstehenden Wörter oder Zahlen zu implementieren. Um die Erfassung der multimodalen Sprachwahrnehmung zu verbessern, wird nicht nur eine virtuelle auditive Umgebung geschaffen, sondern auch eine visuelle Komponente integriert, die auf einem Head-Mounted Display (HMD) wiedergegeben werden kann. Das Ziel ist es, eine audiovisuelle virtuelle Realität zu schaffen, die alltagsrelevante Kommunikationssituationen widerspiegelt und somit die Validität und Relevanz von Hörtests erhöht.
Umsetzung:
Für die Umsetzung wurden Werkzeuge zur Simulation von Raumakustik und eine hochwertige visuelle Darstellung auf einem HMD benötigt. An der Technischen Universität München wurde das Tool "real-time Simulated Open Field Environment" (rtSOFE) entwickelt, das durch die Berechnung von Raumimpulsantworten Raumakustik simuliert und die direkte Wiedergabe von Schallquellen in virtuellen Klangfeldern ermöglicht. Für die visuelle Umgebung wurde die Unreal Engine 5 gewählt, die sehr realistische Darstellungen virtueller Räume ermöglicht und hauptsächlich in der Videospielindustrie verwendet wird.
Ergebnisse:
Mit den Tools rtSOFE und Unreal Engine wurden drei realistische Umgebungen geschaffen: Ein Pub, ein Wohnzimmer und eine U-Bahn-Station. Diese Umgebungen enthalten realitätsnahe Störgeräusche, die zur jeweiligen Umgebung passen. Probanden können sich dank des HMD in diesen Umgebungen frei bewegen. Zudem wurde ein Testsetup unter Verwendung von Sätzen aus dem Oldenburger Satztest innerhalb dieser audiovisuellen Umgebung umgesetzt.
Fazit:
Das entwickelte Testsetup in der audiovisuellen Umgebung ermöglicht eine realistischere und alltagsnähere Erfassung des Hörvermögens im Vergleich zu herkömmlichen Hörtests. Die visuelle Komponente trägt zur Steigerung der Realitätsnähe bei. Allerdings fehlt im aktuellen Setup die Synchronisation zwischen der auditiven und visuellen Umgebung, insbesondere in Form von Lippenbewegungen (Lip Syncing), um eine umfassende Erfassung der multimodalen Sprachwahrnehmung zu ermöglichen.
Die Komplexität von Softwareprojekten hat in den letzten Jahren stetig zugenommen. Um den gleichzeitig steigenden Anforderungen an die Codequalität gerecht zu werden, setzen auch ursprünglich dynamisch typisierte Programmiersprachen zuhnemend auf statische Typisierung. Dies kann in Form von externen Werkzeugen geschehen, die zusätzlich zum eigentlichen Compiler den Code auf Typsicherheit überprüfen, oder alternativ durch Erweiterung der Compiler selbst, um die Unterstützung für statische Typisierung direkt in der Sprache zu verankern. Ziel des etylizer-Projekts ist es, für die Programmiersprache Erlang zunächst ein solches externes Tool bereitzustellen und langfristig Teil der Compiler-Toolchain zu werden.In dieser Arbeit wird der Typchecker um die Fähigkeit erweitert, Erlang-Projekte vollständig zu verifizieren. Dafür wird zunächst die interne Symboltabelle erweitert, die etylizer nutzt, um Verweise auf Funktionen und Typen aus anderen Modulen aufzulösen. Die Implementierung der Symboltabelle wird so angepasst,dass sie zur Laufzeit um alle für das aktuell geprüfte Modul benötigten Symbole erweitert wird. Um die Laufzeit im Rahmen zu halten, wird ein Algorithmus entwickelt, der die Abhängigkeiten zwischen den Source-Code Dateien des Erlang-Projekts erkennt und anhand dieser entscheidet, welche Dateien sich seit dem letzten Durchlauf geändert haben und deshalb erneut überprüft werden müssen.
Bildung für nachhaltige Entwicklung (BNE) hat einen festen Platz im deutschen Bildungssystem gefunden. BNE setzt sich die Ziele, Lernende zu informierten und verantwortungsbewussten Konsumenten zu befähigen sowie sie darauf vorzubereiten und das eigene Verhalten sowie das Verhalten anderer kritisch zu reflektieren. Der Nachhaltigkeitsbegriff von BNE orientiert sich hierbei an den drei Perspektiven, Soziales, Ökonomisches und Ökologisches, und an deren Wechselwirkungen untereinander.
Um Lernenden Nachhaltigkeitsthemen nach der Definition von BNE zu vermitteln, bieten sich Photovoltaik-Systeme (PV), vor allem in Off-Grid-Ausführungen, an, da sie aufgrund ihrer Eigenschaften als erneuerbare Energieerzeuger einen rücksichtsvolleren Umgang mit den vorhandenen Ressourcen fordern, Reflexion des eigenen Verhaltens anregen und sich in verschiedenen Situationen unter den drei Perspektiven der Nachhaltigkeit betrachten lassen.
Für eine Projektarbeit an allgemeinbildenden sowie beruflichen Schulen wurde außerhalb dieser Arbeit ein Off-Grid-PV-System entworfen, anhand dessen Lernende Fragestellungen der elektrischen Energieerzeugung aus Sonneneinstrahlung sowie allgemeine Nachhaltigkeitsthemen erforschen. Das didaktische Konzept zur Begleitung des PV-Systems wurde anhand von den Anforderungen der BNE entwickelt und gliedert sich in die Bereiche einleitende Workshops, Lern- und Arbeitsmaterial, weiterführendes Material sowie einen abschließenden Workshop zur Reflexion des erlernten. Die getroffenen Entscheidungen im Bereich der Technik sowie des Lehr-Lern-Materials werden jeweils didaktisch begründet.
Complex tourism products with intangible service components are difficult to explain to potential customers. This research elaborates the use of virtual reality (VR) in the field of shore excursions. A theoretical research model based on the technology acceptance model was developed, and hypotheses were proposed. Cruise passengers were invited to test 360° excursion images on a landing page. Data was collected using an online questionnaire. Finally, data was analyzed using the PLS-SEM method. The results provide theoretical implications on technology acceptance model (TAM) research in the field of cruise tourism. Furthermore, the results and implications indicate the potential of virtual 360° shore excursion presentations for the cruise industry.
The paper compares different anti-windup strategies for the current control of inverter-fed permanent magnet synchronous machines (PMSM) controlled by pulse-width modulation. In this respect, the focus is on the drive behavior with a relatively large product of stator frequency and sampling time. A requirement for dynamically high-quality anti-windup measures is, among other things, a sufficiently accurate decoupling of the stator current direct axis and quadrature axis components even at high stator frequencies. Discrete-time models of the electrical subsystem of the PMSM are well suited for this purpose, of which the method found to be the most accurate in a preliminary investigation is used as the basis for all anti-windup methods examined. Simulation studies and measurement results document the performance of the compared methods.
Featherweight Generic Go (FGG) is a minimal core calculus modeling the essential features of the programming language Go. It includes support for overloaded methods, interface types, structural subtyping, and generics. The most straightforward semantic description of the dynamic behavior of FGG programs is to resolve method calls based on runtime type information of the receiver. This article shows a different approach by defining a type-directed translation from FGG− to an untyped lambda-calculus. FGG− includes all features of FGG but type assertions. The translation of an FGG− program provides evidence for the availability of methods as additional dictionary parameters, similar to the dictionary-passing approach known from Haskell type classes. Then, method calls can be resolved by a simple lookup of the method definition in the dictionary. Every program in the image of the translation has the same dynamic semantics as its source FGG− program. The proof of this result is based on a syntactic, step-indexed logical relation. The step index ensures a well-founded definition of the relation in the presence of recursive interface types and recursive methods. Although being non-deterministic, the translation is coherent.
Eine reine Passwortauthentifizierung, wie sie im Hochschulumfeld eingesetzt wird, bringt Sicherheitsrisiken mit sich. Ziel dieser Arbeit ist es zu analysieren, wie die Sicherheit in der Praxis mittels einer Zwei-Faktor-Authentifizierung erhöht werden kann und in welcher Weise die Einführung eines Single-Sign-On Konzept zum Erreichen dieses Ziels beiträgt. Es konnte gezeigt werden, dass eine Shibboleth IdP Installation als zentraler Zugangspunkt für Single-Sign-On sowie eine daran angebundene privacyIDEA-Instanz die Umsetzung der Zwei-Faktor-Authentifizierung für einige aber nicht alle Dienste ermöglicht.
Im Rahmen dieser Abschlussarbeit wurde ein automatisertes Test-Framework für eine Datenanalyse-Software namens MARS entwickelt. Der Zweck der Entwicklung dieses Frameworks ist es, die von der Software, zurückgegebenen Ergebnisse zu testen und zu vergleichen. In Zukunft soll dieses Framework verwendet werden, um den Start von Tests bei jeder neuen Version von MARS zu automatisieren.
Darüber hinaus ist dieses Framework in zwei Versionen erhältlich. Die erste ist eine grafische Version, um bestimmte Tests gezielt auszuführen und zu evaluieren. Die zweite Version ist eine Kommandozeilenversion, die es ermöglicht, schnell mehrere Tests zu generieren. Diese Version kann bspw. von einem Jenkins-Server aus gestartet werden.
Das Test-Framework wurde mit der Programmiersprache Python erstellt und mit dem Qt-Framework grafisch unterstützt. Die Vielzahl an Modulen und die große Anzahl an Nutzern machen Python zu einer beliebten Sprache für diese Art von Anwendungen. Die hohe Modularität von Qt für Python und die einfache Handhabung machen es zu einem reichhaltigen Werkzeug für die Erstellung von grafischen Benutzeroberflächen.
Extensible Authentication Protocol (EAP) bietet eine flexible Möglichkeit zur Authentifizierung von Endgeräten und kann in Kombination mit TLS für eine zertifikatsbasierte Authentifizierung verwendet werden. Motiviert wird diese Arbeit von einer potenziellen Erweiterung für PROFINET, die diese Protokolle einsetzen soll.
Dabei soll eine sicherer EAP-TLS-Protokollstacks für eingebettete Systeme in der Programmiersprache Rust entwickelt werden. Durch das Ownership-System von Rust können Speicherfehler eliminiert werden, ohne dabei auf die positiven Eigenschaften von nativen Sprachen zu verzichten. Es wird ein besonderes Augenmerk auf wie die Verwendung klassischer Rust-Bibliotheken im Umfeld von eingebetteten Systemen, den Einfluss des Speichermodells auf das Design, sowie die Integration von C-Bibliotheken für automatisierte Interoperabilitätstests gelegt.
The increasingly stringent CO2 emissions standards require innovative solutions in the vehicle development process. One possibility to reduce CO2 emissions is the electrification of powertrains. The resulting increased complexity, as well as the increased competition and time pressure make the use of simulation software and test benches indispensable in the early development phases. This publication therefore presents a methodology for test bench coupling to enable early testing of electrified powertrains. For this purpose, an internal combustion engine test bench and an electric motor test bench are virtually interconnected. By applying and extending the Distributed Co-Simulation Protocol Standard for the presented hybrid electric powertrain use case, real-time-capable communication between the two test benches is achieved. Insights into the test bench setups, and the communication between the test benches and the protocol extension, especially with regard to temperature measurements, enable the extension to be applied to other powertrain or test bench configurations. The shown results from coupled test bench operations emphasize the applicability. The discussed experiences from the test bench coupling experiments complete the insights.
Current Harmonics Control Algorithm for inverter-fed Nonlinear Synchronous Electrical Machines
(2023)
Current harmonics are a well known challenge of electrical machines. They can be undesirable as they can cause instabilities in the control, generate additional losses and lead to torque ripples with noise. However, they can also be specifically generated in new methods in order to improve the machine behavior. In this paper, an algorithm for controlling current harmonics is proposed. It can be described as a combination of different PI controllers for defined angles of the machine with repetitive control characteristics for whole revolutions. The controller design is explained and important points where linearization is necessary are shown. Furthermore, the limits are analyzed and, for validation, measurement results with a permanently excited synchronous machine on the test bench are considered.
The nonlinear behavior of inverters is largely impacted by the interlocking and switching times. A method for online identifying the switching times of semiconductors in inverters is presented in the following work. By being able to identify these times, it is possible to compensate for the nonlinear behavior, reduce interlocking time, and use the information for diagnostic purposes. The method is first theoretically derived by examining different inverter switching cases and determining potential identification possibilities. It is then modified to consider the entire module for more robust identification. The methodology, including limitations and boundary conditions, is investigated and a comparison of two methods of measurement acquisition is provided. Subsequently the developed hardware is described and the implementation in an FPGA is carried out. Finally, the results are presented, discussed, and potential challenges are encountered.
The present work describes an extension of current slope estimation for parameter estimation of permanent magnet synchronous machines operated at inverters. The area of operation for current slope estimation in the individual switching states of the inverter is limited due to measurement noise, bandwidth limitation of the current sensors and the commutation processes of the inverter's switching operations. Therefore, a minimum duration of each switching state is necessary, limiting the final area of operation of a robust current slope estimation. This paper presents an extension of existing current slope estimation algorithms resulting in a greater area of operation and a more robust estimation result.
Die vorliegende Erfindung betrifft Vorrichtungen zum Überwachen und Optimieren einer zeitlichen Triggerstabilität einer extrakorporalen Kreislaufunterstützung sowie Steuer- und Regeleinheiten zur extrakorporalen Kreislaufunterstützung, umfassend eine solche Vorrichtung und entsprechende Verfahren. Entsprechend wird eine Vorrichtung (10) zum Überwachen einer zeitlichen Triggerstabilität einer extrakorporalen Kreislaufunterstützung vorgeschlagen, welche dazu eingerichtet ist, einen ersten Datensatz (14) einer Messung eines EKG-Signals eines unterstützten Patienten über einen vorgegebenen Zeitraum zu empfangen. Die Vorrichtung (10) umfasst eine Auswerteeinheit (16), welche dazu eingerichtet ist, mehrere R-Trigger (26) aus dem ersten Datensatz (14) zu bestimmen oder zu identifizieren, wobei die Auswerteeinheit (16) weiterhin dazu eingerichtet ist, einen zweiten Datensatz (20) mit ausgewerteten EKG-Signalen und mehreren R-Triggern (28) zu empfangen oder bereitzustellen und den zweiten Datensatz (20) selektiv auf dem ersten Datensatz (14) abzubilden. Die Vorrichtung ist weiterhin dazu eingerichtet, ein Signal (22) auszugeben, welches kennzeichnend für einen zeitlichen Abstand sukzessiver R-Trigger (26) aus dem ersten Datensatz (14) und darauf abgebildeten sukzessiven R-Trigger (28) aus dem zweiten Datensatz (20) ist.
Design and Implementation of a Camera-Based Tracking System for MAV Using Deep Learning Algorithms
(2023)
In recent years, the advancement of micro-aerial vehicles has been rapid, leading to their widespread utilization across various domains due to their adaptability and efficiency. This research paper focuses on the development of a camera-based tracking system specifically designed for low-cost drones. The primary objective of this study is to build up a system capable of detecting objects and locating them on a map in real time. Detection and positioning are achieved solely through the utilization of the drone’s camera and sensors. To accomplish this goal, several deep learning algorithms are assessed and adopted because of their suitability with the system. Object detection is based upon a single-shot detector architecture chosen for maximum computation speed, and the tracking is based upon the combination of deep neural-network-based features combined with an efficient sorting strategy. Subsequently, the developed system is evaluated using diverse metrics to determine its performance for detection and tracking. To further validate the approach, the system is employed in the real world to show its possible deployment. For this, two distinct scenarios were chosen to adjust the algorithms and system setup: a search and rescue scenario with user interaction and precise geolocalization of missing objects, and a livestock control scenario, showing the capability of surveying individual members and keeping track of number and area. The results demonstrate that the system is capable of operating in real time, and the evaluation verifies that the implemented system enables precise and reliable determination of detected object positions. The ablation studies prove that object identification through small variations in phenotypes is feasible with our approach.
Due to its performance, the field of deep learning has gained a lot of attention, with neural networks succeeding in areas like Computer Vision (CV), Neural Language Processing (NLP), and Reinforcement Learning (RL). However, high accuracy comes at a computational cost as larger networks require longer training time and no longer fit onto a single GPU. To reduce training costs, researchers are looking into the dynamics of different optimizers, in order to find ways to make training more efficient. Resource requirements can be limited by reducing model size during training or designing more efficient models that improve accuracy without increasing network size.
This thesis combines eigenvalue computation and high-dimensional loss surface visualization to study different optimizers and deep neural network models. Eigenvectors of different eigenvalues are computed, and the loss landscape and optimizer trajectory are projected onto the plane spanned by those eigenvectors. A new parallelization method for the stochastic Lanczos method is introduced, resulting in faster computation and thus enabling high-resolution videos of the trajectory and secondorder information during neural network training. Additionally, the thesis presents the loss landscape between two minima along with the eigenvalue density spectrum at intermediate points for the first time.
Secondly, this thesis presents a regularization method for Generative Adversarial Networks (GANs) that uses second-order information. The gradient during training is modified by subtracting the eigenvector direction of the biggest eigenvalue, preventing the network from falling into the steepest minima and avoiding mode collapse. The thesis also shows the full eigenvalue density spectra of GANs during training.
Thirdly, this thesis introduces ProxSGD, a proximal algorithm for neural network training that guarantees convergence to a stationary point and unifies multiple popular optimizers. Proximal gradients are used to find a closed-form solution to the problem of training neural networks with smooth and non-smooth regularizations, resulting in better sparsity and more efficient optimization. Experiments show that ProxSGD can find sparser networks while reaching the same accuracy as popular optimizers.
Lastly, this thesis unifies sparsity and neural architecture search (NAS) through the framework of group sparsity. Group sparsity is achieved through ℓ2,1-regularization during training, allowing for filter and operation pruning to reduce model size with minimal sacrifice in accuracy. By grouping multiple operations together, group sparsity can be used for NAS as well. This approach is shown to be more robust while still achieving competitive accuracies compared to state-of-the-art methods
Convolutional neural networks (CNN) define the state-of-the-art solution on many perceptual tasks. However, current CNN approaches largely remain vulnerable against adversarial perturbations of the input that have been crafted specifically to fool the system while being quasi-imperceptible to the human eye. In recent years, various approaches have been proposed to defend CNNs against such attacks, for example by model hardening or by adding explicit defence mechanisms. Thereby, a small “detector” is included in the network and trained on the binary classification task of distinguishing genuine data from data containing adversarial perturbations. In this work, we propose a simple and light-weight detector, which leverages recent findings on the relation between networks’ local intrinsic dimensionality (LID) and adversarial attacks. Based on a re-interpretation of the LID measure and several simple adaptations, we surpass the state-of-the-art on adversarial detection by a significant m argin and reach almost perfect results in terms of F1-score for several networks and datasets. Sources available at: https://github.com/adverML/multiLID
An important step in seismic data processing to improve inversion and interpretation is multiples attenuation. Radon-based algorithms are often used for discriminating primaries and multiples. Recently, deep learning (DL), based on convolutional neural networks (CNNs) has shown promising results in demultiple that could mitigate the challenges of Radon-based methods. In this work, we investigate new different strategies to train a CNN for multiples removal based on different loss functions. We propose combined primaries and multiples labels in the loss for training a CNN to predict primaries, multiples, or both simultaneously. We evaluate the performance of the CNNs trained with the different strategies on 400 clean and noisy synthetic data, considering 3 metrics. We found that training a CNN to predict the multiples and then subtracting them from the input image is the most effective strategy for demultiple. Furthermore, including the primaries labels as a constraint during the training of multiples prediction improves the results. Finally, we test the strategies on a field dataset. The CNNs trained with different strategies report competitive results on real data compared with Radon demultiple. As a result, effectively trained CNN models can potentially replace Radon-based demultiple in existing workflows.
Neural networks tend to overfit the training distribution and perform poorly on out-ofdistribution data. A conceptually simple solution lies in adversarial training, which introduces worst-case perturbations into the training data and thus improves model generalization to some extent. However, it is only one ingredient towards generally more robust models and requires knowledge about the potential attacks or inference time data corruptions during model training. This paper focuses on the native robustness of models that can learn robust behavior directly from conventional training data without out-of-distribution examples. To this end, we study the frequencies in learned convolution filters. Clean-trained models often prioritize high-frequency information, whereas adversarial training enforces models to shift the focus to low-frequency details during training. By mimicking this behavior through frequency regularization in learned convolution weights, we achieve improved native robustness to adversarial attacks, common corruptions, and other out-of-distribution tests. Additionally, this method leads to more favorable shifts in decision-making towards low-frequency information, such as shapes, which inherently aligns more closely with human vision.
In this paper, we describe a first publicly available fine-grained product recognition dataset based on leaflet images. Using advertisement leaflets, collected over several years from different European retailers, we provide a total of 41.6k manually annotated product images in 832 classes. Further, we investigate three different approaches for this fine-grained product classification task, Classification by Image, by Text, as well as by Image and Text. The approach "Classification by Text" uses the text extracted directly from the leaflet product images. We show, that the combination of image and text as input improves the classification of visual difficult to distinguish products. The final model leads to an accuracy of 96.4% with a Top-3 score of 99.2%. We release our code at https://github.com/ladwigd/Leaflet-Product-Classification.
Seismic data processing involves techniques to deal with undesired effects that occur during acquisition and pre-processing. These effects mainly comprise coherent artefacts such as multiples, non-coherent signals such as electrical noise, and loss of signal information at the receivers that leads to incomplete traces. In this work, we employ a generative solution, since it can explicitly model complex data distributions and hence, yield to a better decision-making process. In particular, we introduce diffusion models for multiple removal. To that end, we run experiments on synthetic and on real data, and we compare the deep diffusion performance with standard algorithms. We believe that our pioneer study not only demonstrates the capability of diffusion models, but also opens the door to future research to integrate generative models in seismic workflows.
It is common practice to apply padding prior to convolution operations to preserve the resolution of feature-maps in Convolutional Neural Networks (CNN). While many alternatives exist, this is often achieved by adding a border of zeros around the inputs. In this work, we show that adversarial attacks often result in perturbation anomalies at the image boundaries, which are the areas where padding is used. Consequently, we aim to provide an analysis of the interplay between padding and adversarial attacks and seek an answer to the question of how different padding modes (or their absence) affect adversarial robustness in various scenarios.
Die Erfindung betrifft ein Verfahren zum Betrieb eines batterieelektrischen Fahrzeugs mit einer elektrischen Maschine zum Antrieb des Fahrzeugs und einem Inverter (1) zum Ansteuern der elektrischen Maschine, wobei der Inverter (1) eine dreiphasige Brückenschaltung mit einer Anzahl von als Halbleiter ausgebildeten Schaltern (3) umfasst, wobei im Inverter (1) entstehende Verluste zum Heizen eines Innenraums des Fahrzeugs und/oder zum Temperieren einer Batterie und/oder zum Temperieren von Getriebeöl verwendet werden, wobei der Inverter (1) mittels Raumzeigermodulation gesteuert wird, wobei ein nicht-optimales Schaltverhalten des Inverters (1) herbeigeführt wird, indem nicht optimale Spannungs-Raumzeiger (e, eu, ev, ew, e1, e2, -e1, -e2) eingestellt werden, wobei eine Skalierung der Spannungs-Raumzeiger (e, e1, e2) über die Schaltung von Nullspannungsvektoren, die je nach zeitlichem Anteil die Spannung reduzieren, oder durch Zuhilfenahme eines jeweils gegenüberliegenden Spannungs-Raumzeigers (-e1, - e2) erfolgt, so dass eine Schaltfolge mit einer maximalen Anzahl von Schaltzyklen realisiert wird, wobei in der Mitte einer Schaltperiode (Tp) keine Symmetrie erzeugt wird.
Die Erfindung betrifft ein Verfahren zum Betrieb eines batterieelektrischen Fahrzeugs mit einer elektrischen Maschine zum Antrieb des Fahrzeugs und einem Inverter (1) zum Ansteuern eine Stators (2) der elektrischen Maschine, wobei der Inverter (1) eine dreiphasige Brückenschaltung mit einer Anzahl von als Halbleiter ausgebildeten Schaltern (3) umfasst, wobei im Inverter (1) und/oder in der elektrischen Maschine entstehende Verluste zum Heizen eines Innenraums des Fahrzeugs und/oder zum Temperieren einer Batterie und/oder zum Temperieren von Getriebeöl verwendet werden, wobei während des Stillstands des Fahrzeugs ein von einem Permanentmagneten der elektrischen Maschine verursachter Permanentmagnetfluss durch Einstellen einer nichtdrehmomentbildenden Statorstromkomponente (Id) in Höhe des negativen Quotienten aus einem Statorfluss (&psgr;PM) und einer d-Komponente einer Statorinduktivität (Ld) so stark geschwächt wird, dass der magnetische Fluss kompensiert wird, wobei ein sehr hochfrequenter Wechselstrom als drehmomentbildende Statorstromkomponente (Iq) eingestellt wird.
Modern industrial production is heavily dependent on efficient workflow processes and automation. The steady flow of raw materials as well as the separation of vital parts and semi-finished products are at the core of these automated procedures. Commonly used systems for this work are bowl feeders, which separate the parts and material by a combination of mechanical vibration and friction. The production of these tools, especially the design of the ramping spiral, is delicate and time-consuming work, as the shape, slope, and material must be carefully adjusted for the corresponding parts. In this work, we propose an automated approach, making use of optimization procedures from artificial intelligence, to design the spiral ramps of the bowl feeders. Therefore, the whole system and considered parts are physically simulated and the optimized geometry is subsequently exported into a CAD system for the actual building, respectively printing. The employment of evolutionary optimization gives the need to develop a mathematical model for the whole setup and find an efficient representation of integral features.
This study focuses on the autonomous navigation and mapping of indoor environments using a drone equipped only with a monocular camera and height measurement sensors. A visual SLAM algorithm was employed to generate a preliminary map of the environment and to determine the drone's position within the map. A deep neural network was utilized to generate a depth image from the monocular camera's input, which was subsequently transformed into a point cloud to be projected into the map. By aligning the depth point cloud with the map, 3D occupancy grid maps were constructed by using ray tracing techniques to get a precise depiction of obstacles and the surroundings. Due to the absence of IMU data from the low-cost drone for the SLAM algorithm, the created maps are inherently unscaled. However, preliminary tests with relative navigation in unscaled maps have revealed potential accuracy issues, which can only be overcome by incorporating additional information from the given sensors for scale estimation.
Die Erfindung betrifft ein Verfahren zum Betrieb eines batterieelektrischen Fahrzeugs mit einer elektrischen Maschine zum Antrieb des Fahrzeugs und einem Inverter (1) zum Ansteuern eines Stators (2) der elektrischen Maschine, wobei der Inverter (1) eine dreiphasige Brückenschaltung mit einer Anzahl von als Halbleiter ausgebildeten Schaltern (3) umfasst, wobei im Inverter (1) und/oder in der elektrischen Maschine entstehende Verluste zum Heizen eines Innenraums des Fahrzeugs und/oder zum Temperieren einer Batterie und/oder zum Temperieren von Getriebeöl verwendet werden, wobei eine als Wechselstrom ausgebildete nichtdrehmomentbildende Statorstromkomponente (Id) in die elektrische Maschine eingeprägt wird, wobei im Stillstand eine drehmomentbildende Statorstromkomponente (Iq) zu Null geregelt wird, wobei im Fahrbetrieb ein Kompensationsstrom als drehmomentbildende Statorstromkomponente (Iq) eingeprägt wird, der ein durch die Variation der nichtdrehmomentbildenden Statorstromkomponente (Id) entstehendes Drehmoment kompensiert.
Blockchain interoperability: the state of heterogenous blockchain-to-blockchain communication
(2023)
Blockchain technology has been increasingly adopted over the past few years since the introduction of Bitcoin, with several blockchain architectures and solutions being proposed. Most proposed solutions have been developed in isolation, without a standard protocol or cryptographic structure to work with. This has led to the problem of interoperability, where solutions running on different blockchain platforms are unable to communicate, limiting the scope of use. With blockchains being adopted in a variety of fields such as the Internet of Things, it is expected that the problem of interoperability if not addressed quickly, will stifle technology advancement. This paper presents the current state of interoperability solutions proposed for heterogenous blockchain systems. A look is taken at interoperability solutions, not only for cryptocurrencies, but also for general data-based use cases. Current open issues in heterogenous blockchain interoperability are presented. Additionally, some possible research directions are presented to enhance and to extend the existing blockchain interoperability solutions. It was discovered that though there are a number of proposed solutions in literature, few have seen real-world implementation. The lack of blockchain-specific standards has slowed the progress of interoperability. It was also realized that most of the proposed solutions are developed targeting cryptocurrency-based applications.
Precisely synchronized communication is a major precondition for many industrial applications. At the same time, hardware cost and power consumption need to be kept as low as possible in the Internet of Things (IoT) paradigm. While many wired solutions on the market achieve these requirements, wireless alternatives are an interesting field for research and development. This article presents a novel IEEE802.11n/ac wireless solution, exhibiting several advantages over state-of-the-art competitors. It is based on a market-available wireless System on a Chip with modified low-level communication firmware combined with a low-cost field-programmable gate array. By achieving submicrosecond synchronization accuracy, our solution outperforms the precision of low-cost products by almost four orders of magnitude. Based on inexpensive hardware, the presented wireless module is up to 20 times cheaper than software-defined-radio solutions with comparable timing accuracy. Moreover, it consumes three to five times less power. To back up our claims, we report data that we collected with a high sampling rate (2000 samples per second) during an extended measurement campaign of more than 120 h, which makes our experimental results far more representative than others reported in the literature. Additional support is provided by the size of the testbed we used during the experiments, composed of a hybrid network with nine nodes divided into two independent wireless segments connected by a wired backbone. In conclusion, we believe that our novel Industrial IoT module architecture will have a significant impact on the future technological development of high-precision time-synchronized communication for the cost-sensitive industrial IoT market.
PROFINET Security: A Look on Selected Concepts for Secure Communication in the Automation Domain
(2023)
We provide a brief overview of the cryptographic security extensions for PROFINET, as defined and specified by PROFIBUS & PROFINET International (PI). These come in three hierarchically defined Security Classes, called Security Class 1,2 and 3. Security Class 1 provides basic security improvements with moderate implementation impact on PROFINET components. Security Classes 2 and 3, in contrast, introduce an integrated cryptographic protection of PROFINET communication. We first highlight and discuss the security features that the PROFINET specification offers for future PROFINET products. Then, as our main focus, we take a closer look at some of the technical challenges that were faced during the conceptualization and design of Security Class 2 and 3 features. In particular, we elaborate on how secure application relations between PROFINET components are established and how a disruption-free availability of a secure communication channel is guaranteed despite the need to refresh cryptographic keys regularly. The authors are members of the PI Working Group CB/PG10 Security.
One of the most important questions about smart metering systems for the end users is their data privacy and security. Indeed, smart metering systems provide a lot of advantages for distribution system operators (DSO), but functionalities offered to users of existing smart meters are still limited and society is becoming increasingly critical. Smart metering systems are accused of interfering with personal rights and privacy, providing unclear tariff regulations which not sufficiently encourage households to manage their electricity consumption in advance. In the specific field of smart grids, data security appears to be a necessary condition for consumer confidence without which they will not be able to give their consent to the collection and use of personal data concerning them.
Device and method for monitoring and optimising a temporal trigger stability (WO2023094554A1)
(2023)
The present invention relates to devices for monitoring and optimising a temporal trigger stability of an extracorporeal circulatory support means, and to open-loop and closed-loop control units for the extracorporeal circulatory support means comprising such a device, and to corresponding methods. A device (10) for monitoring a temporal trigger stability of an extracorporeal circulatory support means is accordingly proposed, which device is designed to receive a first dataset (14) of a measurement of an ECG signal of a supported patient over a predefined period of time. The device (10) comprises an evaluation unit (16), which is designed to determine or identify a plurality of R triggers (26) from the first dataset (14), wherein the evaluation unit (16) is also designed to receive or provide a second dataset (20) having evaluated ECG signals and a plurality of R triggers (28) and to selectively map the second dataset (20) on the first dataset (14). The device is also designed to emit a signal (22) that characterises a temporal gap between successive R triggers (26) from the first dataset (14) and successive R triggers (28) from the second dataset (20) which are mapped on the first dataset.
Unterschiedliche Stimulationszeitpunkte bei bimodaler Versorgung mit Hörgerät und Cochleaimplantat
(2023)
Die bimodale Versorgung von Patienten mit Hörgerät (HG) ipsilateral und Cochleaimplantat (CI) kontralateral bei asymmetrischem Hörverlust ist aufgrund vieler inhärenter Variablen die komplizierteste Versorgungsart im Kontext der Versorgung mit CI. Im vorliegenden Übersichtsartikel werden alle systematischen interauralen Unterschiede zwischen elektrischer und akustischer Stimulation dargestellt, die bei dieser Versorgungsart auftreten können. Darüber hinaus werden Methoden zur Quantifizierung des interauralen Latenzoffsets, also des Zeitunterschieds zwischen der akustischen und elektrischen Stimulation des Hörnervs, mittels Registrierung auditorisch evozierter Potenziale – erzeugt durch akustische bzw. elektrische Stimulation – und Messungen an den Sprachprozessoren und Hörgeräten vorgestellt. Die technische Kompensation des interauralen Latenzoffsets und ihre positive Auswirkung auf die Schalllokalisationsfähigkeit bimodal mit CI und HG versorgter Patienten wird ebenfalls beschrieben. Zuletzt werden neueste Erkenntnisse diskutiert, die Gründe dafür aufzeigen, warum die Kompensation des interauralen Latenzoffsets das Sprachverstehen im Störgeräusch bei bimodal versorgten CI-/HG-Trägern nicht verbessert.
eLetter zum Artikel "Condiciones neuropsi-quiátricas y probable causa de muerte de Maurice Ravel" von Gómez-Carvajal AM, Botero-Meneses JS, Palacios-Espinosa X und Palacios-Sánchez L., veröffentlicht in Iatreia 35(3), Seite 341-8 (DOI: https://doi.org/10.17533/udea.iatreia.154).
Seismic data processing involves techniques to deal with undesired effects that occur during acquisition and pre-processing. These effects mainly comprise coherent artefacts such as multiples, non-coherent signals such as electrical noise, and loss of signal information at the receivers that leads to incomplete traces. In the past years, there has been a remarkable increase of machine-learning-based solutions that have addressed the aforementioned issues. In particular, deep-learning practitioners have usually relied on heavily fine-tuned, customized discriminative algorithms. Although, these methods can provide solid results, they seem to lack semantic understanding of the provided data. Motivated by this limitation, in this work, we employ a generative solution, as it can explicitly model complex data distributions and hence, yield to a better decision-making process. In particular, we introduce diffusion models for three seismic applications: demultiple, denoising and interpolation. To that end, we run experiments on synthetic and on real data, and we compare the diffusion performance with standardized algorithms. We believe that our pioneer study not only demonstrates the capability of diffusion models, but also opens the door to future research to integrate generative models in seismic workflows.
Skin cancer detection proves to be complicated and highly dependent on the examiner’s skills. Millimeter-wave technologies seem to be a promising aid for the detection of skin cancer. The different water content of the skin area affected by cancer compared to healthy skin changes its reflective property. Due to limited available resources on the dielectric properties of skin cancer, especially in comparison to surrounding healthy skin, accurate simulations and evaluations are quite challenging. Therefore, comparing different results for different approaches and starting points can be difficult. In this paper, the Effective Medium Theory is applied to model skin cancer, which provides permittivity values dependent on the water content.
A method for evaluating skin cancer detection based on millimeter-wave technologies is presented. For this purpose, the relative permittivities are calculated using the effective medium theory for the benign and cancerous lesion, considering the change in water content between them. These calculated relative permittivities are further used for the simulation and evaluation of skin cancer detection using a substrate-integrated waveguide probe. A difference in the simulated scattering parameters S 11 of up to 13dB between healthy and cancerous skin can be determined in the best-case.
Investigation on Bowtie Antennas Operating at Very Low Frequencies for Ground Penetrating Radar
(2023)
The efficiency of Ground Penetrating Radar (GPR) systems significantly depends on the antenna performance as the signal has to propagate through lossy and inhomogeneous media. GPR antennas should have a low operating frequency for greater penetration depth, high gain and efficiency to increase the receiving power and should be compact and lightweight for ease of GPR surveying. In this paper, two different designs of Bowtie antennas operating at very low frequencies are proposed and analyzed.
The Transport Layer Security protocol is a widespread cryptographic protocol designed to provide secure communication over insecure networks by providing authenticity, integrity, and confidentiality. As a first step, in the TLS Handshake Protocol a common master secret is negotiated. In many configurations, this step makes considerable use of asymmetric cryptographic algorithms. It seems to be a prevalent assumption that the use of such asymmetric cryptographic algorithms is unsuitable for resource-constrained devices. Therefore, the work at hand analyzes the runtime performance of the TLS vl.2 session establishments on an embedded ARM Cortex-M4 platform. We measure the execution time to generate and parse session establishment messages for the client and server sides. In particular, we study the impact of different elliptic curves used for the ephemeral Diffie-Hellman key exchange and the impact of different lengths and subject public key algorithms of certification paths. Our analysis shows that the use of asymmetric cryptographic algorithms is well possible on resource-constrained devices, if carefully chosen and well implemented. This allows the use of the well-proven TLS protocol also for applications from the (Industrial) Internet of Things, including Fieldbus communication.
In recent times, 5G has found applications in several public as well as private networks. There is a growing need to make it compatible with diverse services without compromising security. Current security options for authenticating devices into a home network are 5G Authentication and Key Agreement (5G-AKA) and Extensible Authentication Protocol (EAP)-AKA'. However, for specific use cases such as private networks, more customizable and convenient authentication mechanisms are required. The current mobile networks use authentication based only on SIM cards, but as 5G is being applied in fields like IIoT and automation, even in Non-Public-Networks (NPNs), there is a need for a simpler method of authentication. Certificate-based authentication is one such mechanism that is passwordless and works solely on the information present in the digital certificate that the user holds. The paper suggests an authentication mechanism that performs certificate-based mutual authentication between the UE and the Home network. The proposed concept identifies both the user and network with digital certificates and intends to carry out primary authentication with the help of it. In this work we conduct a study on presently available authentication protocols for 5G networks, both theoretically and experimentally in hardware as well as virtual environments. On the basis of the analysis a series of proposed steps for certificate primary authentication are presented.