Refine
Year of publication
- 2018 (76) (remove)
Document Type
- Conference Proceeding (38)
- Article (reviewed) (18)
- Article (unreviewed) (8)
- Letter to Editor (4)
- Book (2)
- Part of a Book (2)
- Contribution to a Periodical (1)
- Doctoral Thesis (1)
- Other (1)
- Patent (1)
Conference Type
- Konferenzartikel (29)
- Konferenz-Abstract (6)
- Sonstiges (3)
Is part of the Bibliography
- yes (76) (remove)
Keywords
- RoboCup (3)
- 5G mobile communication (2)
- Access protocols (2)
- Decoding (2)
- Defibrillator (2)
- Götz von Berlichingen (2)
- Multiuser detection (2)
- Payloads (2)
- Physical layer (2)
- access protocols (2)
Institute
- Fakultät Elektrotechnik und Informationstechnik (E+I) (bis 03/2019) (76) (remove)
Open Access
- Open Access (37)
- Closed Access (32)
- Bronze (5)
- Closed (1)
- Gold (1)
The growing demand for active medical implantable devices requires data and or power links between the implant and the outside world. Every implant has to be encapsulated from the body by a specific housing and one of the most common materials used is titanium or titanium alloy. Titanium thas the necessary properties in terms of mechanical and chemical stability and biocompatibility. However, its electrical conductivity presents a challenge for the electromagnetic transmission of data and power. The proposed paper presents a fast and practical method to determine the necessary transmission parameters for titanium encapsulated implants. Therefore, the basic transformer-transmission-model is used with measured or calculated key values for the inductances. Those are then expanded with correction factors to determine the behavior with the encapsulation. The correction factors are extracted from finite element method simulations. These also enable the analysis of the magnetic field distribution inside of the housing. The simulated transmission properties are very close to the measured values. Additionally, based on lumped elements and magnetic field distribution, the influential parameters are discussed in the paper. The parameter discussion describes how to enhance the transmitted power, data-rate or distance, or to reduce the size of the necessary coils. Finally, an example application demonstrates the usage of the methods.
This paper describes the Sweaty II humanoid adult size robot trying to qualify for the RoboCup 2018 adult size humanoid competition. Sweaty came 2nd in RoboCup 2017 adult size league. The main characteristics of Sweaty are described in the Team Description Paper 2017. The improvements that have been made or are planned to be implemented for RoboCup 2018 are described in this paper.
Wir haben die erste „Eiserne Hand“ des Götz von Berlichingen mit 3D-Computer-Aided Design rekonstruiert und über einen Multimaterial-3D-Drucker ausgedruckt. Dabei ließ sich feststellen, dass die 500 Jahre alte Technik keinesfalls veraltet ist: Das Innenleben der „Eisernen Hand“ ist ausgefeilter als bisher angenommen. Sie könnte sogar spannende Impulse für die Entwicklung neuer künstlicher Handprothesen liefern.
A simple measuring method for acquiring the radiation pattern of an ultrawide band Vivaldi antenna is presented. The measuring is performed by combining two identical Vivaldi antennas and some of the intrinsic properties of a stepped-frequency continue wave radar (SFCW radar) in the
range from 1.0 GHz to 6.0 GHz. A stepper-motor provided the azimuthal rotation for one of the antennas from 0 ◦ to 360 ◦. The tests have been performed within the conventional environment (laboratory / office) without using an anechoic chamber or absorbing materials. Special measuring devices have not been used either. This method has been tested with different pairs of Vivaldi antennas and it can be also used for different ones (with little or no change in the system), as long as their operational
bandwidth is within the frequency range of the SFCW radar.
Keywords — SFCW Radar, Antenna Gain Characterization,
Azimuthal Radiation Pattern
In this paper, we establish a simple model for the exchange of messages in a vehicular network and we consider fundamental limits on the achievable data rate. For a vehicular network, the exchange of data with other nearby vehicles is particularly important for traffic safety, e.g. for collision avoidance, but also for cooperative applications like platooning. These use cases are currently addressed by standards building on IEEE 802.11p, namely ITS-G5 and DSRC (dedicated short range communication), which encounter saturation problems at high vehicle densities. For this reason, we take a step back and ask for the fundamental limits for the common data rate in a vehicular network. After defining a simple single-lane model and the corresponding capacity limits for some basic multiple- access schemes, we present results for a more realistic setting. For both scenarios, non-orthogonal multiple-access (NOMA) yields the best results.
This paper evaluates the implementation of Medium Access Control (MAC) protocols suitable for massive access connectivity in 5G multi-service networks. The access protocol extends multi-packet detection receivers based on Physical Layer Network Coding (PLNC) decoding and Coded Random Access protocols considering practical aspects to implement one-stage MAC protocols for short packet communications in mMTC services. Extensions to enhance data delivery phase in two- stage protocols are also proposed. The assessment of the access protocols is extended under system level simulations where a suitable link to system interface characterization has been taken into account.
This paper is discussing the development of a wireless Indoor Smart Gardening System with the focus on energy autonomous working. The Smart Gardening System, which is presented in this paper consists of a network of energy autonomous wireless sensor nodes which are used for monitoring important plant parameters like air temperature, soil moisture, pressure or humidity and in future to control an actuator for the plant irrigation and to measure further parameter as light and fertilizer level. Solar energy harvesting is used for powering the wireless nodes without the usage of a battery. Comparable Smart Gardening Systems are usually battery-powered. Furthermore, the overall Smart Gardening System consists of a battery powered gateway based on a Raspberry Pi 3 system, which controls the wireless nodes and collects their sensor data. The gateway is able to send the information to an internet server application and via Wi-Fi to mobile devices. Particularly the architecture of the energy autonomous wireless nodes will be considered because fully energy autonomous wireless networks could not be implemented without special concepts for the energy supply and architecture of the wireless nodes.
Der Entwurf und die Realisierung gedruckter Schaltungen oder Elektronikkomponenten stellt ein intensives Thema der Forschung dar. Forschungsgruppen beschäftigen sich zunehmend mit der Entwicklung von gedruckten Energy Harvestern, weil diese kostengünstig und einfach herstellbar sind. Das Energy Harvesting (EH) oder auch das ”Mikro Energy Harvesting“ (MEH) bezeichnet die Gewinnung von elektrischer Energie aus der Umgebung, um elektronische Verbraucher zu versorgen, kontinuierliche Leistungen zu erzeugen, das System energieeffizienter zu machen, sowie die Energiespeicherung im Mikrowattbereich zu gewährleisten. Energy Harvesting-Systeme stellen eine Alternative gegenüber der Energieversorgung autarker Low-Power-Elektronik mit Batterien dar. Das Energiemanagement solcher EH-Systeme ist jedoch eine Herausforderung aufgrund der Energieverfügbarkeit und der im Zeitablauf nicht konstanten Verlustleistung. Dieser Beitrag gibt einen Überblick über die derzeit existierenden ultra low-power Energiemanagement Schaltungen für Energy Harvester. Dabei wird insbesondere der Fokus auf gedruckte Energy Harvester gelegt. Es soll aufgezeigt werden, welche Aspekte der vorgestellten Energieversorgungsschaltungen bei der Entwicklung eines Energieversorgungschips für gedruckte Energy Harvester berüucksichtigt werden sollen.
Implementierung von Softcore-Prozessoren und/oder weiteren IPs (Intellectual Property) in FPGAs
(2018)
Die zunehmende Integration von kompletten Systemen auf einem Chip (System-on-Chip, SoC) erfordert auch immer die Integration einer Recheneinheit bzw. eines Prozessorkerns. Möchte man insbesondere Low-Power-SoC-Systeme entwickeln, z.B. drahtlose Sensor-SoC-Systeme für Anwendungen im Rahmen von Industrie 4.0, ist die Implementierung eines solchen Prozessorkerns mit hohen Herausforderungen verbunden. Prinzipiell können hierfür verschiedene Ansätze verfolgt werden, nämlich die Implementierung einer Hardcore Prozessor-IP (IP = Intellectual Property) oder einer Softcore-Prozessor-IP. Im vorliegenden Beitrag wird zunächst auf den derzeitigen Stand der Technik verfügbarer Hardcore- oder Softcore-Prozessoren unter den Randbedingungen der Low-Power-Anforderungen und der weiten Verbreitung des Cores in industriellen Anwendungen eingegangen. Schließlich werden die Ergebnisse der Implementierung und Evaluierung eines derzeit frei verfügbaren 16-bit MSP430-kompatiblen Softcore Prozessors auf einem Altera-Cyclon-FPGA vorgestellt. Aus den Ergebnissen wird ein entsprechendes Fazit für die Implementierung von Low-Power-SoC-Systeme gegeben.
Optische Navigationssysteme weisen bisher eine eindeutige Trennung zwischen nachverfolgendem Gerät (Tool Tracker) und nachverfolgten Geräten (Tracked Tools) auf. In dieser Arbeit wird ein neues Konzept vorgestellt, dass diese Trennung aufhebt: Jedes Tracked Tool ist gleichzeitig auch Tool Tracker und besteht aus Marker-LEDs sowie mindestens einer Kamera, mit deren Hilfe andere Tracker in Lage und Orientierung nachverfolgt werden können. Bei Verwendung von nur einer Kamera geschieht dies mittels Pose Estimation, ab zwei Kameras werden die Marker-LEDs trianguliert. Diese Arbeit beinhaltet die Vorstellung des neuen Peer-To-Peer-Tracking-Konzepts, einen sehr schnellen Pose-Estimation-Algorithmus für beliebig viele Marker sowie die Klärung der Frage, ob die mit Pose Estimation erreichbare Genauigkeit vergleichbar mit der eines Stereo-Kamera-Systems ist und den Anforderungen an die chirurgische Navigation gerecht wird.
Nowadays, robotic systems are an integral part of many orthopedic interventions. Stationary robots improve the accuracy but also require adapted surgical workflows. Handheld robotic devices (HHRDs), however, are easily integrated into existing workflows and represent a more economical solution. Their limited range of motion is compensated by the dexterity of the surgeon. This work presents control algorithms for HHRDs with multiple degrees of freedom (DOF). These algorithms protect pre- or intraoperatively defined regions from being penetrated by the end effector (e.g., a burr) by controlling the joints as well as the device’s power. Accuracy tests on a stationary prototype with three DOF show that the presented control algorithms produce results similar to those of stationary robots and much better results than conventional techniques. This work presents novel and innovative algorithms, which work robustly, accurately, and open up new opportunities for orthopedic interventions.