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There was hardly another development which influenced the life on earth as much as the development of the communication technology in the last decades. The advantages of mobile communication brought the branch enormeous growth rates. However, for some years an increasing saturation has been looming in the markets especially in the developed nations and new marketing strategies are needed in order for companies to be able to distance themselves from their competitors. Against the background of this situation ICT companies all over the world started to look for new growth opportunities and found them in the so called “emerging markets” of the developing nations. To exploit this potential will be the one central challenge for the mobile communication industry for the next years. With this book I want to direct the gaze of all readers towards these markets which hold an enormous potential for the whole industry. Furthermore, I want to introduce some generic strategic approaches which can help firms to successfully participate in these markets.
This diploma thesis is devoted to the design and analysis of a radar signal enabling an object classification capability in surveillance radar systems based on high-resolution radar range profiles. It picks up the research results from Kastinger (2006), who investigated classification algorithms for high-resolution radar range profiles, and Meier (2007), who programmed a MATLAB toolbox for the evaluation of radar signals. A classical, brief, introduction to radar fundamentals is given (Chapter 1) as well as the motivation for this thesis and certain basic parameters used. After high-resolution radar range profiles are discussed with special focus on surveillance radar systems (Chapter 2), the results of Kastinger (2006) are picked up (Chapter 3) as far as necessary for the following chapters of this thesis. Following the chapters on radar basics, high-resolution radar range profiles and classification, basic and advanced radar signals are discussed and analysed, especially their range resolution and sidelobe levels (Chapter 4). This includes linear frequency-modulated pulses and nonlinear frequency-modulated pulses as well as phase-coded pulses, coherent trains of identical pulses, and stepped-frequency waveforms. Their analysis is based on Meier's MATLAB toolbox. In Chapter 5 we will bring up additional points that have to be considered in radar system design for implementing a classification capability, before this thesis ends with an overall conclusion (Chapter 6).
This working paper is part of a PhD research project dealing with the topics Social Responsibility, Stakeholder Theory and Network Governance, run by Maud Schmiedeknecht and supervised by Prof. Dr. habil. Josef Wieland, both from the Konstanz Institute for Intercultural Management, Values and Communication at the Konstanz University of Applied Sciences.
Today we live in a world that is characterized by a constantly changing environment. During the last decade, this highly volatile environment forced companies to implement strategies that identify, track and minimise the risks that entrepreneurial activity entails. Unfortunately, risks only account for a part of the insecurity that is connected to future events. The other and not inferior part of this insecurity consists of possible positive developments – so called opportunities. Due to this reason in economic science and in practice the opinion aggravates that solely focusing on risks is not sufficient to fully exploit the potential of markets and companies. In the 16th century, the Dutch Renaissance humanist scholar Desiderius Erasmus (1466-1536) said: “It is well known that among the blind, the one-eyed man is king.” Transferring this statement in the context of Risk Management, the conclusion becomes apparent: The environmental uncertainty that surrounds entrepreneurial actions includes both opportunities and threats. As commonly practiced though, Risk Management tools only address threats. While this approach is surely better than doing nothing, it still can be seen as a major weakness of the traditional Risk Management approach. Nevertheless, in terms of Erasmus, this approach represents the one-eyed man when compared with the blind. To continue this metaphor a little further, it is possible to conclude that the one-eyed king could be easily relieved of his crown by introducing an emperor who is able to see with two eyes. Although this problem is well known in economic science, up to know only little scientific focus was shifted towards the systematic identification and management of opportunities. In fact, most of the present literature focuses on the identification and handling of risk and even though much of the recently published literature captures the term opportunity, none of it proposes a solid idea of following up on the approach. Still, facing the defiances of the present economic environment, it is not sufficient for companies to focus their attention on reducing risks. Instead, it is imperative to deal with the subject of Opportunity Management as well. With this paper, I want to undermine the importance of Opportunity Management for all companies independently of their size or branch that they operate in. Thereby, this paper is dedicated to all managers who strive to improve the professionalism of their companies in terms of strategic thinking. Furthermore, I hope that this paper can facilitate a practical implementation of a working Opportunity Management System.
Volterra and Wiener series
(2011)
Volterra and Wiener series are two classes of polynomial representations of nonlinear systems. They are perhaps the best understood and most widely used nonlinear system representations in signal processing and system identification. A Volterra or Wiener representation can be thought of as a natural extension of the classical linear system representation. In addition to the convolution of the input signal with the system's impulse response, the system representation includes a series of nonlinear terms that contain products of increasing order of the input signal with itself. It can be shown that these polynomial extension terms allow for representing a large class of nonlinear systems which basically encompasses all systems with scalar outputs that are time-invariant and have noninfinite memory.
In automotive a lot of electromagnetically, pyrotechnically or mechanically driven actuators are integrated to run comfort systems and to control safety systems in modern passenger cars. Using shape memory alloys (SMA) the existing systems could be simplified, performing the same function through new mechanisms with reduced size, weight, and costs. A drawback for the use of SMA in safety systems is the lack of materials knowledge concerning the durability of the switching function (long-time stability of the shape memory effect). Pedestrian safety systems play a significant role to reduce injuries and fatal casualties caused by accidents. One automotive safety system for pedestrian protection is the bonnet lifting system. Based on such an application, this article gives an introduction to existing bonnet lifting systems for pedestrian protection, describes the use of quick changing shape memory actuators and the results of the study concerning the long-time stability of the tested NiTi-wires. These wires were trained, exposed up to 4years at elevated temperatures (up to 140°C) and tested regarding their phase change temperatures, times, and strokes. For example, it was found that A P-temperature is shifted toward higher temperatures with longer exposing periods and higher temperatures. However, in the functional testing plant a delay in the switching time could not be detected. This article gives some answers concerning the long-time stability of NiTi-wires that were missing till now. With this knowledge, the number of future automotive applications using SMA can be increased. It can be concluded, that the use of quick changing shape memory actuators in safety systems could simplify the mechanism, reduce maintenance and manufacturing costs and should be insertable also for other automotive applications.
Using multi-camera matching techniques for 3d reconstruction there is usually the trade-off between the quality of the computed depth map and the speed of the computations. Whereas high quality matching methods take several seconds to several minutes to compute a depth map for one set of images, real-time methods achieve only low quality results. In this paper we present a multi-camera matching method that runs in real-time and yields high resolution depth maps. Our method is based on a novel multi-level combination of normalized cross correlation, deformed matching windows based on the multi-level depth map information, and sub-pixel precise disparity maps. The whole process is implemented completely on the GPU. With this approach we can process four 0.7 megapixel images in 129 milliseconds to a full resolution 3d depth map. Our technique is tailored for the recognition of non-technical shapes, because our target application is face recognition.
To master complexity, we can organize it or discard it. The Art of Insight in Science and Engineering first teaches the tools for organizing complexity, then distinguishes the two paths for discarding complexity: with and without loss of information. Questions and problems throughout the text help readers master and apply these groups of tools. Armed with this three-part toolchest, and without complicated mathematics, readers can estimate the flight range of birds and planes and the strength of chemical bonds, understand the physics of pianos and xylophones, and explain why skies are blue and sunsets are red.