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An investigation of tropospheric refractive effects on Ka-band terrestrial linksVowles, Mark Christopher January 2007 (has links)
No description available.
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Digital radio and its application in the HF (2-30 MHz) bandDavies, Nigel Clement January 2004 (has links)
The propagation environment at high frequencies (HF, 2-30 MHz) has a significant impact on the performance of radio systems (especially data communications). However, the ability to communicate information over very long ranges using ionospheric propagation paths without any intermediate infrastructure makes the use of HF attractive for many applications. In order to increase the utility of HF communications there is a strong desire to increase HF data rates. Currently data rates of up to -2400 bps can be reliably achieved in standard 3 kHz HF channel allocations. Whilst further increases in data rate within the confines of these narrowband frequency allocations is likely, the use of larger bandwidths (contiguous or otherwise) appears to offer potential for much greater throughputs. This requires a greater understanding of the characteristics of wideband channels and also requires transmitting and receiving equipment capable of wideband/multi-channel operation. New waveforms have been proposed for the transmission of higher data rates in extended channel bandwidths (6 kHz). The results of laboratory measurements and analysis of data collected during on-air trials of a number of 16 kbps waveforms are presented. Analysis indicates that operation over surface wave and benign skywave channels is possible, demonstrating the benefit of exploiting greater channel bandwidths. Suitable architectures for the implementation of wideband and multi-channel digital HF radios (software radios) have been investigated. The work presented indicates that it is now possible, for the first time, to construct high performance, direct sampling wideband digital HF receivers. In such a receiver the entire HF band is digitised and then all subsequent processing is undertaken digitally. Conceptually this would allow an arbitrary number of channels to be simultaneously received using a single RF frontend and digitiser. With careful design performance comparable with that of the high performance conventional super-heterodyne single channel receivers can be obtained. A prototype wideband multi-channel digital HF transceiver with this architecture has been implemented and its performance shown to agree with that predicted. A particular challenge in complex systems such as software radios is the deployment of software across a number of heterogeneous processors. A new asynchronous, eventbased, processing architecture which employs messaging to allow processing tasks to be effectively distributed across a multiple processors and buses is proposed. It has been implemented on the digital transceiver platform and its effectiveness has been demonstrated. A new low-power pulse-compression oblique HF ionospheric sounder, known as WHISPER, has been developed. This sounder has been implemented as a software application on the wideband HF digital transceiver. Waveforms suitable for making wideband (-80 kHz) measurements of the channel time varying complex impulse response have been designed. These have been used to make measurements on a 170 km path in the UK during Spring 2001. The results of these measurements have been analysed and confirm the ability of the sounding instrument to measure the channel scattering function and the amplitude and phase within individual modes. A number of possible directions for further analysis, pertinent to the design of wideband HF modems, have been proposed.
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Conception d'une solution RFID UHF pour l'optimisation de la logistique de bouteilles métalliques / Design of an UHF RFID solution for optimisation of metal cylinder logisticsSafraou, Ahcine 04 April 2018 (has links)
Dans le contexte actuel de transformation numérique, Air Liquide souhaite moderniser le suivi logistique de ses bouteilles de gaz à l'aide de la technologie d'identification radio (RFID) à ultra haute fréquence (UHF) qui remplacerait la solution code-barres actuelle et permettrait de dépasser certaines de ses limites. La numérisation de la traçabilité aura pour conséquence en outre d'enrichir l'interaction entre les actifs industriels et le système de gestion et de production pour ainsi créer l'écosystème IOT (Internet Of Things) spécifique à l'entreprise. Le recours à la RFID UHF est de nos jours largement répandu pour la logistique et la gestion de stocks. Cependant, les environnements métalliques, comme celui que l'on trouve avec les bouteilles de gaz, induisent des perturbations qui dégradent fortement la qualité de la communication radio fréquence (RF). Cela constitue un frein au déploiement de cette technologie dans un tel cadre. Il est nécessaire de comprendre les perturbations induites par les milieux conducteurs afin de s'en affranchir et ainsi proposer une solution efficiente. En plus de cela, les faibles niveaux d'énergie mis en jeu impliquent qu'une étude de l'ensemble des points d'amélioration des dispositifs RFID UHF tant au niveau matériel que logiciel soit réalisée. De cette étude théorique, nous avons fait le choix de concentrer nos efforts sur la conception d'un tag RFID UHF pour objets métalliques répondant au cahier des charges spécifique de l'industriel. Pour aller plus loin dans l'optimisation de la logistique et de la gestion des stocks, nous nous sommes également penchés sur l'étude et la réalisation d'un circuit de récupération d'énergie RFID UHF pour tag augmenté passif équipé d'un capteur. L'objectif est d'apporter une information sur l'état de l'actif en plus de son identité tout en évitant les contraintes liées à la présence d'une batterie ou d'une pile. / In the current context of digital transformation, Air Liquide explores the use of Ultra High Frequency (UHF) Radio Frequency IDentification (RFID) in the gas cylinders supply chain, as a replacement for the current, barcode-based, tracking and inventory solution. Digitalization will also provide the company an opportunity to develop its IOT ecosystem through enriched interaction between assets and their management system. UHF RFID is nowadays commonplace in logistics. However, metal surroundings as found in the gas cylinder's case, yield disturbances in the RF communication, and decreased inventory performances. Therefore, it is necessary to understand the adverse effects of metal surroundings to propose an ad-hoc solution. In addition, dealing with low levels of energy in the RF communication suggests leveraging both hardware and software aspects of RFID devices for potential performance improvements. On the basis of our theoretical study, we focus on the design and testing of an industrial UHF RFID tag suitable for the gas cylinder use case. To enable an even richer, more interactive supply chain, we also design and test an energy harvesting device for the UHF band, to power a tag enriched with an active sensor, without the logistic burden of a battery of limited durability.
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