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- 2012 (105) (remove)
Due to the complex interactions between the ground, the driving machine, the lining tube and the built environment, the accurate assignment of in-situ system parameters for numerical simulation in mechanized tunneling is always subject to tremendous difficulties. However, the more accurate these parameters are, the more applicable the responses gained from computations will be. In particular, if the entire length of the tunnel lining is examined, then, the appropriate selection of various kinds of ground parameters is accountable for the success of a tunnel project and, more importantly, will prevent potential casualties. In this context, methods of system identification for the adaptation of numerical simulation of ground models are presented. Hereby, both deterministic and probabilistic approaches are considered for typical scenarios representing notable variations or changes in the ground model.
The upper limit of the thermal conductivity and the mechanical strength are predicted for the polyethylene chain, by performing the ab initio calculation and applying the quantum mechanical non-equilibrium Green’s function approach. Specially, there are two main findings from our calculation: (1) the thermal conductivity can reach a high value of 310 Wm−1 K−1 in a 100 nm polyethylene chain at room temperature and the thermal conductivity increases with the length of the chain; (2) the Young’s modulus in the polyethylene chain is as high as 374.5 GPa, and the polyethylene chain can sustain 32.85%±0.05% (ultimate) strain before undergoing structural phase transition into gaseous ethylene.
Die besondere Aggressivität von hochkonzentrierten Magnesiumsulfatlösungen bei Einwirkung auf Beton ist seit vielen Jahrzehnten bekannt. Neben dem Sulfat greift zusätzlich auch das Magnesium den Zementstein an. Bei hohen Lösungskonzentrationen nimmt der Magnesiumangriff gegenüber dem Sulfatangriff sogar eine dominante Rolle ein. Magnesiumgehalte unter 300 mg/l im Grundwasser gelten allerdings bislang als nicht angreifend. In Auslagerungs- und Laborversuchen wurde jedoch festgestellt, dass auch bei praxisrelevanten Magnesium- (<300 mg/l) und Sulfatgehalten (1.500 mg/l) das Magnesium zu einer deutlichen Verschärfung des Sulfatangriffes bei niedrigen Temperaturen führte. Diese Verschärfung trat bei Mörteln und Betonen auf, bei denen der erhöhte Sulfatwiderstand durch einen teilweisen Zementersatz mit 20 % Flugasche zu einem CEM II/A-LL erreicht werden sollte, gemäß der Flugascheregelung nach EN 206-1/DIN 1045-2.
Bei einem teilweisen Zementersatz durch 30 % Flugasche konnte auch in magnesiumhaltigen Sulfatlösungen eine deutliche Verbesserung des Sulfatwiderstandes erreicht werden. Mörtel mit HS-Zement als Bindemittel wiesen keinerlei Schäden auf. Schadensverursachend war eine Kombination mehrerer Einflüsse. Zum einen wurde der Sulfatwiderstand des Zement-Flugasche-Systems durch die unzureichende Reaktion der Flugasche infolge der niedrigen Lagerungstemperatur geschwächt. Zum anderen konnte durch die Einwirkung des Magnesiums in der Randzone vermutlich eine Destabilisierung der C-S-H-Phasen erfolgen, wodurch die Thaumasitbildung an dieser Stelle forciert wurde. Zusätzlich wurde durch den Portlanditverbrauch und die pH-Wert-Absenkung in der Randzone die puzzolanische Reaktion der Flugasche behindert.
This paper presents a novel numerical procedure based on the framework of isogeometric analysis for static, free vibration, and buckling analysis of laminated composite plates using the first-order shear deformation theory. The isogeometric approach utilizes non-uniform rational B-splines to implement for the quadratic, cubic, and quartic elements. Shear locking problem still exists in the stiffness formulation, and hence, it can be significantly alleviated by a stabilization technique. Several numerical examples are presented to show the performance of the method, and the results obtained are compared with other available ones.
Die Arbeit behandelt die Geschichte der Landesplanung in Mitteldeutschland und besteht aus zwei Teilen: den Zeiträumen der 1920 und 1990 Jahre. Dabei wird die Herausbildung der Landesplanung im mitteldeutschen Industriegebiet (um Merseburg) bzw. Thüringen behandelt. Die kognitiven, institutionellen und planerischen Grundlagen der Landesplanung werden herausgearbeitet. Dabei spielen die paradigmatischen Grundlagen (Dezentralisierung) sowie die internationalen Beziehungen (insbes. zu den USA) eine besondere Rolle. Schließlich werden das Wirken von Schlüsselpersonen (u.a. Prager, Luthardt, Langen) und die Bezüge zum Bauhaus untersucht. Die Analyse des Planwerks für Mitteldeutschland (1932) wird umfassend geführt. In der Analyse der Entstehung können erste Ansätze nicht-linearer Planung herausgearbeitet werden. Der zweite Teil der Arbeit widmet sich dem Industriellen Gartenreich, einem Projekt der Stiftung Bauhaus Dessau, das als Korrespondenzregion zur EXPO anerkannt worden war. Hier stehen das Gesamtkonzept, aber auch Projekte wie Ferropolis im Zentrum der Betrachtung. Die Analysen der Landesplanung werden in ihren Bezügen zur gesellschaftlichen und konkret wirtschaftlichen Entwicklung behandelt. Schließlich werden beide Entwicklungsphasen und deren landesplanerischen Resultate übergreifend bewertet und in einem Modell emergent-adaptiver Planung verortet und ein Ausblick auf die Entwicklung der Landesplanung als nicht-lineare Planung gegeben.
The aim of this paper we discuss explicit series constructions for the fundamental solution of the Helmholtz operator on some important examples non-orientable conformally at manifolds. In the context of this paper we focus on higher dimensional generalizations of the Klein bottle which in turn generalize higher dimensional Möbius strips that we discussed in preceding works. We discuss some basic properties of pinor valued solutions to the Helmholtz equation on these manifolds.
Schwerpunkt Kollektiv
(2012)
Die neuere und höchst produktive Konjunktur des »Kollektiv«-Begriffs in Soziologie und Kulturtheorie, wie sie sich insbesondere durch die Ent-faltung der Akteur-Netzwerk-Theorie herausgebildet hat, ist zunächst durch vier miteinander zusammenhängende Eigentümlichkeiten gekennzeichnet. Erstens bezeichnet das »Kollektiv« in diesem Sinne vor allem anderen eine Ansammlung von Entitäten zu einem als Ganzem operativen, möglicherweise sogar handlungs- und reflexionsfähigen Komplex. Die Operationen werden dabei erstens im »Kollektiv« und durch das »Kollektiv« ausgeführt, gleichzeitig jedoch sind sie es, die das »Kollektiv« überhaupt erst aufspannen und relationieren und so zusammenhalten und reproduzieren bzw. variieren. Das Besondere daran ist zweitens – und das unterscheidet den »Kollektiv«-Begriff etwa von demjenigen des Systems –, dass es keine Subsumption der beteiligten Entitäten unter das kollektive Gebilde gibt. Die Operationsfähigkeit und der Zusammenschluss führen weder zu einem Aufgehen des Einzelnen im Ganzen, noch zerfällt im Rückfall das Ganze in eine bloße Gesamtheit aufsummierbarer Teile und Effekte. Kurz: Das »Kollektiv« kann nicht über die Beziehung von Ganzem und Teil definiert und schon gar nicht nach einer dieser beiden Seiten hin aufgelöst werden. Drittens, und das ist der vermutlich plakativste Zug des neuen »Kollektiv«-Begriffs, umfasst das »Kollektiv« Entitäten völlig heterogener Art, genauer: Es bringt solche Gegebenheiten zusammen, die nach klassischer ontologischer Tradition verschiedenen Seinsbezirken zugerechnet worden wären. Das sind vor allem die berühmten menschlichen und nichtmenschlichen Akteure Bruno Latours, das sind also Personen und Artefakte, Kultur- und Naturdinge, Intelligibles und Sensibles, Reflexives und Irreflexives, Technisches und Ästhetisches, Bilder und Objekte oder sogar Materielles und Immaterielles wie Geister, Götter und Ahnen, so bei Descola oder Gell. Und viertens schließlich ist der »Kollektiv«-Begriff speziell ein Kontrastbegriff , der innerhalb der »neuen Soziologie« der Akteur-Netzwerk-Theorie an die Stelle des Gesellschaftsbegriff s treten soll, eben um dessen humanozentrische Prägung einerseits und seine subsumptive, generalisierende und anti-partikulare Tradition
andererseits abzustreifen.
Schwerpunkt Entwerfen
(2012)
Entwerfen ist ein äusserst unscharfer Begriff. Mit ihm kann je nach Kontext ebenso Zeichnen, Planen, Modellieren, Projektieren oder Darstellen gemeint sein wie Erfi nden, Entwickeln, Konzipieren, Komponieren und ähnliches. Wenn Architekten vom Entwurf reden, verwenden sie das Wort meist in einer Bedeutung, die auf den kunsttheoretischen Diskurs zurückgeht, der im Florenz des 16. Jahrhunderts entstanden ist: Entwurf als disegno. Dementsprechend konnte Entwerfen in der kunsthermeneutischen Rezeption schließlich mit dem ›künstlerischen Schaff ensprozess‹ selbst synonym werden. Im Entwerfen meint man der geistigen Vermögen und Prozesse im künstlerischen Subjekt habhaft zu werden.
An diese Tradition soll hier bewusst nicht angeknüpft werden. Um das Entwerfen als Kulturtechnik in seiner historischen Bedingtheit zu beschreiben, muss es aus dem anthropozentrischen Ursprung herausgerückt werden, an den es der florentinische kunsttheoretische Diskurs versetzt hat. Statt das Entwerfen als fundamentalen Akt künstlerischen Schaff ens zu begreifen und als anthropologische Konstante der Geschichte zu entziehen, wäre eben diese Konzeption als historisches Resultat von diskursiven, technischen und institutionellen Praktiken zu befragen.
In this paper experimental studies and numerical analysis carried out on reinforced concrete beam are partially reported. They aimed to apply the rigid finite element method to calculations for reinforced concrete beams using discrete crack model. Hence rotational ductility resulting from crack occurrence had to be determined. A relationship for calculating it in static equilibrium was proposed. Laboratory experiments proved that dynamic ductility is considerably smaller. Therefore scaling of the empirical parameter was carried out. Consequently a formula for its value depending on reinforcement ratio was obtained.
The topic of structural robustness is covered extensively in current literature in structural engineering. A few evaluation methods already exist. Since these methods are based on different evaluation approaches, the comparison is difficult. But all the approaches have one in common, they need a structural model which represents the structure to be evaluated. As the structural model is the basis of the robustness evaluation, there is the question if the quality of the chosen structural model is influencing the estimation of the structural robustness index. This paper shows what robustness in structural engineering means and gives an overview of existing assessment methods. One is the reliability based robustness index, which uses the reliability indices of a intact and a damaged structure. The second one is the risk based robustness index, which estimates the structural robustness by the usage of direct and indirect risk. The paper describes how these approaches for the evaluation of structural robustness works and which parameters will be used. Since both approaches needs a structural model for the estimation of the structural behavior and the probability of failure, it is necessary to think about the quality of the chosen structural model. Nevertheless, the chosen model has to represent the structure, the input factors and reflect the damages which occur. On the example of two different model qualities, it will be shown, that the model choice is really influencing the quality of the robustness index.
This thesis explores how architecture aids in the performance of open-ended narratives by engaging both actively and passively with memory, i.e. remembering and forgetting. I argue that architecture old and new stems from specific cultural and social forms, and is dictated by processes of remembering and forgetting. It is through interaction (between inhabitant and object) that architecture is given innate meanings within an urban environment that makes its role in the interplay one of investigative interest.
To enable the study of this performance, I develop a framework based on various theoretical paradigms to investigate three broad questions: 1) How does one study the performance of memory and forgetting through architecture in dynamic urban landscapes? 2) Is there a way to identify markers and elements within the urban environment that enable such a study? 3) What is the role that urban form plays within this framework and does the transformation of urban form imply the transformation of memory and forgetting?
The developed framework is applied to a macro (an urban level study of Bangalore, India) and micro level study (a singular or object level study of Stari Most/ Old Bridge, Mostar, BiH), to analyse the performance of remembering and forgetting in various urban spheres through interaction with architecture and form. By means of observations, archival research, qualitative mapping, drawings and narrative interviews, the study demonstrates that certain sites and characteristics of architecture enable the performance of remembering and the questioning of forgetting by embodying features that support this act.
Combining theory and empirical studies this thesis is an attempt to elucidate on the processes through which remembering and forgetting is initiated and experienced through architectural forms. The thesis argues for recognising the potential of architecture as one that embodies and supports the performance of memory and forgetting, by acting as an auratic contact zone.
The process of analysis and design in structural engineering requires the consideration of different partial models, for example loading, structural materials, structural elements, and analysis types. The various partial models are combined by coupling several of their components. Due to the large number of available partial models describing similar phenomena, many different model combinations are possible to simulate the same aspects of a structure. The challenging task of an engineer is to select a model combination that ensures a sufficient, reliable prognosis. In order to achieve this reliable prognosis of the overall structural behavior, a high individual quality of the partial models and an adequate coupling of the partial models is required. Several methodologies have been proposed to evaluate the quality of partial models for their intended application, but a detailed study of the coupling quality is still lacking. This paper proposes a new approach to assess the coupling quality of partial models in a quantitative manner. The approach is based on the consistency of the coupled data and applies for uni- and bidirectional coupled partial models. Furthermore, the influence of the coupling quality on the output quantities of the partial models is considered. The functionality of the algorithm and the effect of the coupling quality are demonstrated using an example of coupled partial models in structural engineering.
Methods for model quality assessment are aiming to find the most appropriate model with respect to accuracy and computational effort for a structural system under investigation. Model error estimation techniques can be applied for this purpose when kinematical models are investigated. They are counted among the class of white box models, which means that the model hierarchy and therewith the best model is known. This thesis gives an overview of discretisation error estimators. Deduced from these, methods for model error estimation are presented. Their general goal is to make a prediction of the inaccuracies that are introduced using the simpler model without knowing the solution of a more complex model. This information can be used to steer an adaptive process. Techniques for linear and non-linear problems as well as global and goal-oriented errors are introduced. The estimation of the error in local quantities is realised by solving a dual problem, which serves as a weight for the primal error. So far, such techniques have mainly been applied in
material modelling and for dimensional adaptivity. Within the scope of this thesis, available model error estimators are adapted for an application to kinematical models. Their applicability is tested regarding the question of whether a geometrical non-linear calculation is necessary or not. The analysis is limited to non-linear estimators due to the structure of the underlying differential equations. These methods often involve simplification, e.g linearisations. It is investigated to which extent such assumptions lead to meaningful results, when applied to kinematical models.
Increasingly powerful hard- and software allows for the numerical simulation of complex physical phenomena with high levels of detail. In light of this development the definition of numerical models for the Finite Element Method (FEM) has become the bottleneck in the simulation process. Characteristic features of the model generation are large manual efforts and a de-coupling of geometric and numerical model. In the highly probable case of design revisions all steps of model preprocessing and mesh generation have to be repeated. This includes the idealization and approximation of a geometric model as well as the definition of boundary conditions and model parameters. Design variants leading to more resource-efficient structures might hence be disregarded due to limited budgets and constrained time frames.
A potential solution to above problem is given with the concept of Isogeometric Analysis (IGA). Core idea of this method is to directly employ a geometric model for numerical simulations, which allows to circumvent model transformations and the accompanying data losses. Basis for this method are geometric models described in terms of Non-uniform rational B-Splines (NURBS). This class of piecewise continuous rational polynomial functions is ubiquitous in computer graphics and Computer-Aided Design (CAD). It allows the description of a wide range of geometries using a compact mathematical representation. The shape of an object thereby results from the interpolation of a set of control points by means of the NURBS functions, allowing efficient representations for curves, surfaces and solid bodies alike. Existing software applications, however, only support the modeling and manipulation of the former two. The description of three-dimensional solid bodies consequently requires significant manual effort, thus essentially forbidding the setup of complex models.
This thesis proposes a procedural approach for the generation of volumetric NURBS models. That is, a model is not described in terms of its data structures but as a sequence of modeling operations applied to a simple initial shape. In a sense this describes the "evolution" of the geometric model under the sequence of operations. In order to adapt this concept to NURBS geometries, only a compact set of commands is necessary which, in turn, can be adapted from existing algorithms. A model then can be treated in terms of interpretable model parameters. This leads to an abstraction from its data structures and model variants can be set up by variation of the governing parameters.
The proposed concept complements existing template modeling approaches: templates can not only be defined in terms of modeling commands but can also serve as input geometry for said operations. Such templates, arranged in a nested hierarchy, provide an elegant model representation. They offer adaptivity on each tier of the model hierarchy and allow to create complex models from only few model parameters. This is demonstrated for volumetric fluid domains used in the simulation of vertical-axis wind turbines. Starting from a template representation of airfoil cross-sections, the complete "negative space" around the rotor blades can be described by a small set of model parameters, and model variants can be set up in a fraction of a second.
NURBS models offer a high geometric flexibility, allowing to represent a given shape in different ways. Different model instances can exhibit varying suitability for numerical analyses. For their assessment, Finite Element mesh quality metrics are regarded. The considered metrics are based on purely geometric criteria and allow to identify model degenerations commonly used to achieve certain geometric features. They can be used to decide upon model adaptions and provide a measure for their efficacy. Unfortunately, they do not reveal a relation between mesh distortion and ill-conditioning of the equation systems resulting from the numerical model.
A phantom-node method is developed for three-node shell elements to describe cracks. This method can treat arbitrary cracks independently of the mesh. The crack may cut elements completely or partially. Elements are overlapped on the position of the crack, and they are partially integrated to implement the discontinuous displacement across the crack. To consider the element containing a crack tip, a new kinematical relation between the overlapped elements is developed. There is no enrichment function for the discontinuous displacement field. Several numerical examples are presented to illustrate the proposed method.
It is well known that complex quaternion analysis plays an important role in the study of higher order boundary value problems of mathematical physics. Following the ideas given for real quaternion analysis, the paper deals with certain orthogonal decompositions of the complex quaternion Hilbert space into its subspaces of null solutions of Dirac type operator with an arbitrary complex potential. We then apply them to consider related boundary value problems, and to prove the existence and uniqueness as well as the explicit representation formulae of the underlying solutions.
Der Nachbehandlung eines Fahrbahndeckenbetons kommt zum Erzielen eines hohen Frost-Tausalz-Widerstandes der fertigen Betondecke eine besondere Bedeutung zu. Bei der Waschbetonbauweise erfolgt die Nachbehandlung in mehreren Schritten. Eine erste Nachbehandlung gewährleistet den Verdunstungsschutz des Betons bis zum Zeitpunkt des Ausbürstens des verzögerten Oberflächenmörtels. Daran schließt sich die zweite Nachbehandlung an, in der Regel durch Aufsprühen eines flüssigen Nachbehandlungsmittels.
Der zweite Nachbehandlungsschritt ist entscheidend für den Frost-Tausalz-Widerstand der Betondecke. Im Rahmen eines Forschungsprojektes wurde daher untersucht, inwiefern durch eine Optimierung der zweiten Nachbehandlung der Frost-Tausalz-Widerstand von Waschbetonoberflächen erhöht werden kann, insbesondere bei Verwendung hüttensandhaltiger Zemente. Schon durch eine einmalige Nassnachbehandlung wurde eine deutlich höherer Widerstand der Waschbetons gegen Frost-Tausalz-Angriff erzielt.
Meshfree methods (MMs) such as the element free Galerkin (EFG)method have gained popularity because of some advantages over other numerical methods such as the finite element method (FEM). A group of problems that have attracted a great deal of attention from the EFG method community includes the treatment of large deformations and dealing with strong discontinuities such as cracks. One efficient solution to model cracks is adding special enrichment functions to the standard shape functions such as extended FEM, within the FEM context, and the cracking particles method, based on EFG method. It is well known that explicit time integration in dynamic applications is conditionally stable. Furthermore, in enriched methods, the critical time step may tend to very small values leading to computationally expensive simulations. In this work, we study the stability of enriched MMs and propose two mass-lumping strategies. Then we show that the critical time step for enriched MMs based on lumped mass matrices is of the same order as the critical time step of MMs without enrichment. Moreover, we show that, in contrast to extended FEM, even with a consistent mass matrix, the critical time step does not vanish even when the crack directly crosses a node.
Monogenic functions play a role in quaternion analysis similarly to that of holomorphic functions in complex analysis. A holomorphic function with nonvanishing complex derivative is a conformal mapping. It is well-known that in Rn+1, n ≥ 2 the set of conformal mappings is restricted to the set of Möbius transformations only and that the Möbius transformations are not monogenic. The paper deals with a locally geometric mapping property of a subset of monogenic functions with nonvanishing hypercomplex derivatives (named M-conformal mappings). It is proved that M-conformal mappings orthogonal to all monogenic constants admit a certain change of solid angles and vice versa, that change can characterize such mappings. In addition, we determine planes in which those mappings behave like conformal mappings in the complex plane.
The Bernstein polynomials are used for important applications in many branches of Mathematics and the other sciences, for instance, approximation theory, probability theory, statistic theory, num- ber theory, the solution of the di¤erential equations, numerical analysis, constructing Bezier curves, q-calculus, operator theory and applications in computer graphics. The Bernstein polynomials are used to construct Bezier curves. Bezier was an engineer with the Renault car company and set out in the early 1960’s to develop a curve formulation which would lend itself to shape design. Engineers may …nd it most understandable to think of Bezier curves in terms of the center of mass of a set of point masses. Therefore, in this paper, we study on generating functions and functional equations for these polynomials. By applying these functions, we investigate interpolation function and many properties of these polynomials.
New foundations for geometric algebra are proposed based upon the existing isomorphisms between geometric and matrix algebras. Each geometric algebra always has a faithful real matrix representation with a periodicity of 8. On the other hand, each matrix algebra is always embedded in a geometric algebra of a convenient dimension. The geometric product is also isomorphic to the matrix product, and many vector transformations such as rotations, axial symmetries and Lorentz transformations can be written in a form isomorphic to a similarity transformation of matrices. We collect the idea that Dirac applied to develop the relativistic electron equation when he took a basis of matrices for the geometric algebra instead of a basis of geometric vectors. Of course, this way of understanding the geometric algebra requires new definitions: the geometric vector space is defined as the algebraic subspace that generates the rest of the matrix algebra by addition and multiplication; isometries are simply defined as the similarity transformations of matrices as shown above, and finally the norm of any element of the geometric algebra is defined as the nth root of the determinant of its representative matrix of order n×n. The main idea of this proposal is an arithmetic point of view consisting of reversing the roles of matrix and geometric algebras in the sense that geometric algebra is a way of accessing, working and understanding the most fundamental conception of matrix algebra as the algebra of transformations of multilinear quantities.
Civil engineers take advantage of models to design reliable structures. In order to fulfill the design goal with a certain amount of confidence, the utilized models should be able to predict the probable structural behavior under the expected loading schemes. Therefore, a major challenge is to find models which provide less uncertain and more robust responses. The problem gets even twofold when the model to be studied is a global model comprised of different interacting partial models. This study aims at model quality evaluation of global models with a focus on frame-wall systems as the case study. The paper, presents the results of the first step taken toward accomplishing this goal. To start the model quality evaluation of the global frame-wall system, the main element (i.e. the wall) was studied through nonlinear static and dynamic analysis using two different modeling approaches. The two selected models included the fiber section model and the Multiple-Vertical-Line-Element-Model (MVLEM). The influence of the wall aspect ratio (H=L) and the axial load on the response of the models was studied. The results from nonlinear static and dynamic analysis of both models are presented and compared. The models resulted in quite different responses in the range of low aspect ratio walls under large axial loads due to different contribution of the shear deformations to the top displacement. In the studied cases, the results implied that careful attention should be paid to the model quality evaluation of the wall models specifically when they are supposed to be coupled to other partial models such as a moment frame or a soil-footing substructure which their response is sensitive to shear deformations. In this case, even a high quality wall model would not result in a high quality coupled system since it fails to interact properly with the rest of the system.
MODEL DESCRIBING STATIC AND DYNAMIC DISPLACEMENTS OF SILOS WALL DURING THE FLOW OF LOOSE MATERIAL
(2012)
Correct evaluation of wall displacements is a key matter when designing silos. This issue is important from both the standpoint of design engineer (load-bearing capacity of structures) and end-consumer (durability of structures). Commonplace methods of silo design mainly focus on satisfying limit states of load-bearing capacity. Current standards fail to specify methods of dynamic displacements analysis. Measurements of stressacting on silo walls prove that the actual stress is sum of static and dynamic stresses. Janssen came up with differential equation describing state of static equilibrium in cross-section of a silo. By solving the equation static stress of granular solid on silo walls can be determined. Equations of motion were determined from equilibrium equations of feature objects. General solution, describing dynamic stresses was presented as parametric model. This paper presents particular integrals of differential equation, which enable analysing displacements and vibrations for different rigidities of silo walls, types of granular solid and its flow rate.
Long-span cable supported bridges are prone to aerodynamic instabilities caused by wind and this phenomenon is usually a major design criterion. If the wind speed exceeds the critical flutter speed of the bridge, this constitutes an Ultimate Limit State. The prediction of the flutter boundary therefore requires accurate and robust models. This paper aims at studying various combinations of models to predict the flutter phenomenon.
Since flutter is a coupling of aerodynamic forcing with a structural dynamics problem, different types and classes of models can be combined to study the interaction. Here, both numerical approaches and analytical models are utilised and coupled in different ways to assess the prediction quality of the hybrid model. Models for aerodynamic forces employed are the analytical Theodorsen expressions for the motion-enduced aerodynamic forces of a flat plate and Scanlan derivatives as a Meta model. Further, Computational Fluid Dynamics (CFD) simulations using the Vortex Particle Method (VPM) were used to cover numerical models.
The structural representations were dimensionally reduced to two degree of freedom section models calibrated from global models as well as a fully three-dimensional Finite Element (FE) model. A two degree of freedom system was analysed analytically as well as numerically.
Generally, all models were able to predict the flutter phenomenon and relatively close agreement was found for the particular bridge. In conclusion, the model choice for a given practical analysis scenario will be discussed in the context of the analysis findings.
Metakaolin made from kaolin is used around the world but rarely in Vietnam where abundant deposits of kaolin is found. The first studies of producing metakaolin were conducted with high quality Vietnamese kaolins. The results showed the potential to produce metakaolin, and its effect has on strength development of mortars and concretes. However, utilisation of a low quality kaolin for producing Vietnamese metakaolin has not been studied so far.
The objectives of this study were to produce a good quality metakaolin made from low quality Vietnamese kaolin and to facilitate the utilisation of Vietnamese metakaolin in composite cements.
In order to reach such goals, the optimal thermal conversion of Vietnamese kaolin into metakaolin was carried out by many investigations, and as such the optimal conversion is found using the analysis results of DSC/TGA, XRD and CSI. During the calcination in a range of 500 – 800 oC lasting for 1 – 5 hours, the characterisation of calcinated kaolin was also monitored for mass loss, BET surface, PSD, density as well as the presence of the residual water. It is found to have a well correlation between residual water and BET surface.
The pozzolanic activity of metakaolin was tested by various methods regarding to the saturated lime method, mCh and TGA-CaO method. The results of the study showed which method is the most suitable one to characterise the real activity of metakaolin and can reach the greatest agreement with concrete performance. Furthermore, the pozzolanic activity results tested using methods were also analysed and compared to each other with respect to the BET surface.
The properties of Vietnam metakaolin was established using investigations on water demand, setting time, spread-flowability, and strength. It is concluded that depending on the intended use of composite cement and weather conditions of cure, each Vietnamese metakaolin can be used appropriately to produce (1) a composite cement with a low water demand (2) a high strength of composite cement (3) a composite cement that aims to reduce CO2 emissions and to improve economics of cement products (4) a high performance mortar.
The durability of metakaolin mortar was tested to find the needed metakaolin content against ASR, sulfat and sulfuric acid attacks successfully.
We study the Weinstein equation u on the upper half space R3+. The Weinstein equation is connected to the axially symmetric potentials. We compute solutions of the Weinstein equation depending on the hyperbolic distance and x2. These results imply the explicit mean value properties. We also compute the fundamental solution. The main tools are the hyperbolic metric and its invariance properties.
Lesen - Schreiben - Apparate
(2012)
Die im vorliegenden Buch dokumentierten Untersuchungen befassen sich mit der Entwicklung von Methoden zur algorithmischen Lösung von Layoutaufgaben im architektonischen Kontext. Layout bezeichnet hier die gestalterisch und funktional sinnvolle Anordnung räumlicher Elemente, z.B. von Parzellen, Gebäuden, Räumen auf bestimmten Maßstabsebenen. Die vorliegenden Untersuchungen sind im Rahmen eines von der Deutschen Forschungsgemeinschaft geförderten Forschungsprojekts entstanden.
Architektonisches Entwerfen ist ein kreativer Prozess, der eine Lösung hervorbringt, die in ihrer Form und ihrer Funktionalität so noch nicht bestand. Resultat eines architektonischen Entwurfes ist ein Original, dessen Entstehen eine schöpferische Komponente erfordert. Dieser kreative Prozess ist nicht systematisierbar und kann auch nicht als Methode wiederholbar gemacht werden. Im Rahmen der architektonischen Lehre ist die Vermittlung von Methoden zur Entwurfsfindung jedoch ein wesentlicher Aspekt. Der hier vorgestellte Entwurf möchte zeigen, dass der Auffassung, allein intuitive Methoden als Entwurfsgrundlage zu nutzen, die Auffassung entgegen steht, eine reglementierte Methode zur Entwurfs- und Formfindung anzuwenden.
Eine solche reglementierte Methode wird hierbei als Entwurfsgrammatik bezeichnet.
In den 1950er Jahren entstehen zwei revolutionäre Werke des Komponisten und Architekten Iannis Xenakis: die Komposition Metastaseis und der Philips-Pavillon für die Weltausstellung in Brüssel. Basierend auf diesen Arbeiten wird eine Methode vorgestellt, welche musikalische Parameter in architektonischen Parameter transformiert.
Diese Methode bildet die Grundlage für ein exaktes räumliches Transformation-Modell, welches aus mathematischen Funktionen abgeleitet ist. Dabei weißt das Transformations-Modell eine starke Ähnlichkeit mit der Architektur des Pavillons auf.
Die Vorstellung des Gesamtwerkes der halleschen Architekten Julius Kallmeyer und Wilhelm Facilides, die sich Anfang der 1920er Jahre zu einer Zusammenarbeit entschlossen und eine Vielzahl interessanter Gebäude für die Saalestadt schufen, ist in der Fokussierung der Gesamtthematik der Lebens- und Werksdarstellung das Grundanliegen dieser Ausarbeitung. Dieses bisher nicht in Angriff genommene architekturgeschichtliche Anliegen beschäftigt sich mit den Ergebnissen der Bürogeschichte einer- und der Lebensgeschichte der Persönlichkeiten andererseits. Bis heute gelten die klassisch modernen Architekturen Kallmeyers & Facilides ́, gerade für den gehobenen Wohnhausbau in Halle an der Saale, als herausragende Leistungen.
Thin-walled cylindrical composite shell structures are often applied in aerospace for lighter and cheaper launcher transport system. These structures exhibit sensitivity to geometrical imperfection and are prone to buckling under axial compression. Today the design is based on NASA guidelines from the 1960’s [1] using a conservative lower bound curve embodying many experimental results of that time. It is well known that the advantages and different characteristics of composites as well as the evolution of manufacturing standards are not considered apporopriately in this outdated approach. The DESICOS project was initiated to provide new design guidelines regarding all the advantages of composites and allow further weight reduction of space structures by guaranteeing a more precise and robust design.
Therefore it is necessary among other things to understand how a cutout with different dimensions affects the buckling load of a thin-walled cylindrical shell structure in combination with initial geometric imperfections. This work is intended to identify a ratio between the cutout characteristic dimension (in this case the cutout diameter) and the structure characteristic dimension (in this case the cylinder radius) that can be used to tell if the buckling structure is dominated by initial imperfections or is dominated by the cutout.
The 19th International Conference on the Applications of Computer Science and Mathematics in Architecture and Civil Engineering will be held at the Bauhaus University Weimar from 4th till 6th July 2012. Architects, computer scientists, mathematicians, and engineers from all over the world will meet in Weimar for an interdisciplinary exchange of experiences, to report on their results in research, development and practice and to discuss. The conference covers a broad range of research areas: numerical analysis, function theoretic methods, partial differential equations, continuum mechanics, engineering applications, coupled problems, computer sciences, and related topics. Several plenary lectures in aforementioned areas will take place during the conference.
We invite architects, engineers, designers, computer scientists, mathematicians, planners, project managers, and software developers from business, science and research to participate in the conference!
The present research analyses the error on prediction obtained under different data availability scenarios to determine which measurements contribute to an improvement of model prognosis and which not. A fully coupled 2D hydromechanical model of a water retaining dam is taken as an example. Here, the mean effective stress in the porous skeleton is reduced due to an increase in pore water pressure under drawdown conditions. Relevant model parameters are ranked by scaled sensitivities, Particle Swarm Optimization is applied to determine the optimal parameter values and model validation is performed to determine the magnitude of error forecast. We compare the predictions of the optimized models with results from a forward run of the reference model to obtain actual prediction errors.
The analyses presented here were performed to 31 data sets of 100 observations of varying data types. Calibrating with multiple information types instead of only one sort, brings better calibration results and improvement in model prognosis. However, when using several types of information the number of observations have to be increased to be able to cover a representative part of the model domain; otherwise a compromise between data availability and domain
coverage prove best. Which type of information for calibration contributes to the best prognoses, could not be determined in advance. For the error in model prognosis does not depends on the error in calibration, but on the parameter error, which unfortunately can not be determined in reality since we do not know its real value. Excellent calibration fits with parameters’ values near the limits of reasonable physical values, provided the highest prognosis errors. While models which included excess pore pressure values for calibration provided the best prognosis, independent of the calibration fit.
This work describes an algorithm and corresponding software for incorporating general nonlinear multiple-point equality constraints in a implicit sparse direct solver. It is shown that direct addressing of sparse matrices is possible in general circumstances, circumventing the traditional linear or binary search for introducing (generalized) constituents to a sparse matrix. Nested and arbitrarily interconnected multiple-point constraints are introduced by processing of multiplicative constituents with a built-in topological ordering of the resulting directed graph. A classification of discretization methods is performed and some re-classified problems are described and solved under this proposed perspective. The dependence relations between solution methods, algorithms and constituents becomes apparent. Fracture algorithms can be naturally casted in this framework. Solutions based on control equations are also directly incorporated as equality constraints. We show that arbitrary constituents can be used as long as the resulting directed graph is acyclic. It is also shown that graph partitions and orderings should be performed in the innermost part of the algorithm, a fact with some peculiar consequences. The core of our implicit code is described, specifically new algorithms for direct access of sparse matrices (by means of the clique structure) and general constituent processing. It is demonstrated that the graph structure of the second derivatives of the equality constraints are cliques (or pseudo-elements) and are naturally included as such. A complete algorithm is presented which allows a complete automation of equality constraints, avoiding the need of pre-sorting. Verification applications in four distinct areas are shown: single and multiple rigid body dynamics, solution control and computational fracture.
Modern digital material approaches for the visualization and simulation of heterogeneous materials allow to investigate the behavior of complex multiphase materials with their physical nonlinear material response at various scales. However, these computational techniques require extensive hardware resources with respect to computing power and main memory to solve numerically large-scale discretized models in 3D. Due to a very high number of degrees of freedom, which may rapidly be increased to the two-digit million range, the limited hardware ressources are to be utilized in a most efficient way to enable an execution of the numerical algorithms in minimal computation time. Hence, in the field of computational mechanics, various methods and algorithms can lead to an optimized runtime behavior of nonlinear simulation models, where several approaches are proposed and investigated in this thesis.
Today, the numerical simulation of damage effects in heterogeneous materials is performed by the adaption of multiscale methods. A consistent modeling in the three-dimensional space with an appropriate discretization resolution on each scale (based on a hierarchical or concurrent multiscale model), however, still contains computational challenges in respect to the convergence behavior, the scale transition or the solver performance of the weak coupled problems. The computational efficiency and the distribution among available hardware resources (often based on a parallel hardware architecture) can significantly be improved. In the past years, high-performance computing (HPC) and graphics processing unit (GPU) based computation techniques were established for the investigationof scientific objectives. Their application results in the modification of existing and the development of new computational methods for the numerical implementation, which enables to take advantage of massively clustered computer hardware resources. In the field of numerical simulation in material science, e.g. within the investigation of damage effects in multiphase composites, the suitability of such models is often restricted by the number of degrees of freedom (d.o.f.s) in the three-dimensional spatial discretization. This proves to be difficult for the type of implementation method used for the nonlinear simulation procedure and, simultaneously has a great influence on memory demand and computational time.
In this thesis, a hybrid discretization technique has been developed for the three-dimensional discretization of a three-phase material, which is respecting the numerical efficiency of nonlinear (damage) simulations of these materials. The increase of the computational efficiency is enabled by the improved scalability of the numerical algorithms. Consequently, substructuring methods for partitioning the hybrid mesh were implemented, tested and adapted to the HPC computing framework using several hundred CPU (central processing units) nodes for building the finite element assembly. A memory-efficient iterative and parallelized equation solver combined with a special preconditioning technique for solving the underlying equation system was modified and adapted to enable combined CPU and GPU based computations.
Hence, it is recommended by the author to apply the substructuring method for hybrid meshes, which respects different material phases and their mechanical behavior and which enables to split the structure in elastic and inelastic parts. However, the consideration of the nonlinear material behavior, specified for the corresponding phase, is limited to the inelastic domains only, and by that causes a decreased computing time for the nonlinear procedure. Due to the high numerical effort for such simulations, an alternative approach for the nonlinear finite element analysis, based on the sequential linear analysis, was implemented in respect to scalable HPC. The incremental-iterative procedure in finite element analysis (FEA) during the nonlinear step was then replaced by a sequence of linear FE analysis when damage in critical regions occured, known in literature as saw-tooth approach. As a result, qualitative (smeared) crack initiation in 3D multiphase specimens has efficiently been simulated.
Helsinki Central
(2012)
Als zentraler Ort und Eingangstor in die finnische Hauptstadt bietet der Bereich um den Bahnhof, in dem sich das Baufeld befindet zu wenig räumliche Qualitäten und bildet gleichzeitig eine Barriere zwischen dem historischen Stadtkern und dem politischen und kulturellem Zentrum der Stadt.
Der historische Bahnhof aus der Epoche des Jugendstils ist momentan eingeschlossen von einer hochfrequentierten Straße im Süden und den flankierenden Stationen des Busbahnhofs an der Ost- und Westseite.
Die fußläufigen Verbindungen in die Altstadt sind gestört und das Regierungsviertel mit
dem Reichstagsgebäude werden links liegen gelassen. Eine Orientierung als Neuankömmling ist schwer möglich.
Darüber hinaus kommt etwa die Hälfte der Züge, vor allem die Regionalzüge nicht in der Bahnhofshalle des Kopfbahnhofes an, weil die Begrenzung durch die
Seitenflügel nur eine Erweiterung des Bahnhofs nach Norden hin zuließ.
Entstanden ist ein Entwurf der versucht, dem gesamten Bereich um den Bahnhof ein neues Gesicht zu geben und eine Verbesserung auf unterschiedlichen Ebenen zu erreichen. Er bündelt zum einen die verschiedenen Verkehrsströme und stellt eine bisher unterbrochene Querverbindung zwischen den benachbarten Stadtvierteln entlang des Bahnhofsareals her. Zum anderen trägt er dem Erfordernis nach einem städtebaulichen Gegenüber für das
Regierungsgebäude Rechnung, welches damit in den Verbund der kulturellen Einrichtungen auf dem Töölönlahti Gelände aufgenommen wird. Darüber hinaus belebt er eine Besonderheit von Helsinki. Zu Beginn des 20. Jahrhunderts bestand die Notwendigkeit den Hafen an das Schienennetz anzubinden. Da der Stadtkern bereits sehr dicht bebaut war, wurde ein Eisenbahnring entlang der Küste, einmal um das Stadtzentrum herum gebaut. Seitdem die Verbindung stillgelegt wurde liegt dieser Ring brach, was nun die große Chance bietet, eine kreuzungsfreien Rad- und Fußweg zu etablieren, der durch den Entwurf eines Mobilityhubs geschlossen würde.
In der vorliegenden Broschüre werden die städtebaulichen Rahmenbedingungen, die Analyse der gegenwärtigen Situation und der eigentliche Entwurfsprozess, der zu dieser Lösung führte dokumentiert.
Gaze based human-computer-interaction has been a research topic for over a quarter century. Since then, the main scenario for gaze interaction has been helping handicapped people to communicate an interact with their environment. With the rapid development of mobile and wearable display technologies, a new application field for gaze interaction has appeared, opening new research questions.
This thesis investigates the feasibility of mobile gaze based interaction, studying deeply the use of pie menus as a generic and robust widget for gaze interaction as well as visual and perceptual issues on head mounted (wearable) optical see-through displays.
It reviews conventional gaze-based selection methods and investigates in detail the use of pie menus for gaze control. It studies and discusses layout issues, selection methods and applications. Results show that pie menus can allocate up to six items in width and multiple depth layers, allowing a fast and accurate navigation through hierarchical levels by using or combining multiple selection methods. Based on these results, several text entry methods based on pie menus are proposed. Character-by-character text entry, text entry with bigrams and with text entry with bigrams derived by word prediction, as well as possible selection methods, are examined in a longitudinal study. Data showed large advantages of the bigram entry methods over single character text entry in speed and accuracy. Participants preferred the novel selection method based on saccades (selecting by borders) over the conventional and well established dwell time method.
On the one hand, pie menus showed to be a feasible and robust widget, which may enable the efficient use of mobile eye tracking systems that may not be accurate enough for controlling elements on conventional interface. On the other hand, visual perception on mobile displays technologies need to be examined in order to deduce if the mentioned results can be transported to mobile devices.
Optical see-through devices enable observers to see additional information embedded in real environments. There is already some evidence of increasing visual load on the respective systems. We investigated visual performance on participants with a visual search tasks and dual tasks presenting visual stimuli on the optical see-through device, only on a computer screen, and simultaneously on both devices. Results showed that switching between the presentation devices (i.e. perceiving information simultaneously from both devices) produced costs in visual performance. The implications of these costs and of further perceptual and technical factors for mobile gaze-based interaction are discussed and solutions are proposed.
This paper presents a strain smoothing procedure for the extended finite element method (XFEM). The resulting “edge-based” smoothed extended finite element method (ESm-XFEM) is tailored to linear elastic fracture mechanics and, in this context, to outperform the standard XFEM. In the XFEM, the displacement-based approximation is enriched by the Heaviside and asymptotic crack tip functions using the framework of partition of unity. This eliminates the need for the mesh alignment with the crack and re-meshing, as the crack evolves. Edge-based smoothing (ES) relies on a generalized smoothing operation over smoothing domains associated with edges of simplex meshes, and produces a softening effect leading to a close-to-exact stiffness, “super-convergence” and “ultra-accurate” solutions. The present method takes advantage of both the ES-FEM and the XFEM. Thanks to the use of strain smoothing, the subdivision of elements intersected by discontinuities and of integrating the (singular) derivatives of the approximation functions is suppressed via transforming interior integration into boundary integration. Numerical examples show that the proposed method improves significantly the accuracy of stress intensity factors and achieves a near optimal convergence rate in the energy norm even without geometrical enrichment or blending correction.
We present an extended finite element formulation for dynamic fracture of piezo-electric materials. The method is developed in the context of linear elastic fracture mechanics. It is applied to mode I and mixed mode-fracture for quasi-steady cracks. An implicit time integration scheme is exploited. The results are compared to results obtained with the boundary element method and show excellent agreement.
The aim of this study is to show an application of model robustness measures for soilstructure interaction (henceforth written as SSI) models. Model robustness defines a measure for the ability of a model to provide useful model answers for input parameters which typically have a wide range in geotechnical engineering. The calculation of SSI is a major problem in geotechnical engineering. Several different models exist for the estimation of SSI. These can be separated into analytical, semi-analytical and numerical methods. This paper focuses on the numerical models of SSI specific macro-element type models and more advanced finite element method models using contact description as continuum or interface elements. A brief description of the models used is given in the paper. Following this description, the applied SSI problem is introduced. The observed event is a static loaded shallow foundation with an inclined load. The different partial models to consider the SSI effects are assessed using different robustness measures during numerical application. The paper shows the investigation of the capability to use these measures for the assessment of the model quality of SSI partial models. A variance based robustness and a mathematical robustness approaches are applied. These different robustness measures are used in a framework which allows also the investigation of computational time consuming models. Finally the result shows that the concept of using robustness approaches combined with other model–quality indicators (e.g. model sensitivity or model reliability) can lead to unique model–quality assessment for SSI models.
Different types of data provide different type of information. The present research analyzes the error on prediction obtained under different data type availability for calibration. The contribution of different measurement types to model calibration and prognosis are evaluated. A coupled 2D hydro-mechanical model of a water retaining dam is taken as an example. Here, the mean effective stress in the porous skeleton is reduced due to an increase in pore water pressure under drawdown conditions. Relevant model parameters are identified by scaled sensitivities. Then, Particle Swarm Optimization is applied to determine the optimal parameter values and finally, the error in prognosis is determined. We compare the predictions of the optimized models with results from a forward run of the reference model to obtain the actual prediction errors. The analyses presented here were performed calibrating the hydro-mechanical model to 31 data sets of 100 observations of varying data types. The prognosis results improve when using diversified information for calibration. However, when using several types of information, the number of observations has to be increased to be able to cover a representative part of the model domain. For an analysis with constant number of observations, a compromise between data type availability and domain coverage proves to be the best solution. Which type of calibration information contributes to the best prognoses could not be determined in advance. The error in model prognosis does not depend on the error in calibration, but on the parameter error, which unfortunately cannot be determined in inverse problems since we do not know its real value. The best prognoses were obtained independent of calibration fit. However, excellent calibration fits led to an increase in prognosis error variation. In the case of excellent fits; parameters' values came near the limits of reasonable physical values more often. To improve the prognoses reliability, the expected value of the parameters should be considered as prior information on the optimization algorithm.
In vorliegender Studie werden die Wohnstandortpräferenzen der Sinus-Milieugruppen in Dresden über eine standardisierte Befragung (n=318) untersucht. Es wird unterschieden zwischen handlungsleitenden Wohnstandortpräferenzen, die durch Anhaltspunkte auf der Handlungsebene stärker in Betracht gezogen werden sollten, und Wohnstandortpräferenzen, welche eher orientierenden Charakter haben. Die Wohnstandortpräferenzen werden untersucht anhand der Kategorien Ausstattung/Zustand der Wohnung/des näheren Wohnumfeldes, Versorgungsstruktur, soziales Umfeld, Baustrukturtyp, Ortsgebundenheit sowie des Aspektes des Images eines Stadtviertels. Um die Befragten den Sinus-Milieugruppen zuordnen zu können, wird ein Lebensweltsegment-Modell entwickelt, welches den Anspruch hat, die Sinus-Milieugruppen in der Tendenz abzubilden. Die Studie kommt zu dem Ergebnis, dass die Angehörigen der verschiedenen Lebensweltsegmente in jeder Kategorie - wenn auch z.T. auf geringerem Niveau - signifikante Unterschiede in der Bewertung einzelner Wohnstandortpräferenzen aufweisen.
Entwurf eines Spieler-Modells für eine erweiterbare Spielplattform zur Ausbildung in der Bauphysik
(2012)
Im Projekt Intelligentes Lernen beschäftigen sich die Professuren Content Management und Web-Technologien, Systeme der Virtuellen Realität und Bauphysik der Bauhaus- Universität Weimar mit der Entwicklung innovativer Informationstechnologien für eLearning- Umgebungen. In den Teilbereichen Retrieval, Extraktion und Visualisierung großer Dokumentkollektionen, sowie simulations- und planbasierter Wissensvermittlung werden Algorithmen und Werkzeuge erforscht, um eLearning-Systeme leistungsfähiger zu machen und um somit den Lernerfolg zu optimieren.
Ziel des Projekts, auf dem Gebiet des simulationsbasierten Wissenstransfers, ist die Entwicklung eines Multiplayer Online Games (MOG) zur Ausbildungsunterstützung in der Bauphysik.
Im Rahmen der vorliegenden Bachelorarbeit wird für diese digitale Lernsoftware ein Spieler- Modell zur Verwaltung der spielerspezifischen Daten entworfen und in das bestehende Framework integriert. Der Schwerpunkt der Arbeit liegt in der Organisation der erlernten Fähigkeiten des Spielers und in der an den Wissensstand angepassten Auswahl geeigneter Spielaufgaben. Für die Anwendung im eLearning-Bereich ist die Erweiterbarkeit des Modells um neue Lernkomplexe eine wesentliche Anforderung.
Eine der jüngsten Entwicklungen in der Games Branche sind sogenannte Social Games. Hierbei handelt es sich um digitale Spiele, die innerhalb von sozialen Netzwerken, wie z.B. Facebook und Myspace, gespielt werden.
Studien zeigen, dass kommerzielle digitale Spiele mehr als nur ein Zeitvertreib sind. Sie fördern sowohl kognitive, als auch affektive
und psychomotorische Kompetenzen. Aus diesem Grund werden seit Jahrzehnten digitale Spiele in der Pädagogik eingesetzt, um ihre Motivationskraft zu nutzen, um Lerneffekte zu erzielen.
Ziel dieser Arbeit ist es Spielmechaniken für ein bauphysikalisches Social Game zu entwickeln. Ausgehend von der Identifikation von Spielmechaniken, basierend auf einer Analyse der Funktionsweisen existierender populärer Social Games, und einem grundlegenden pädagogischen Verständnis bezüglich Digital Game Based Learning (DGBL), werden Spielmechaniken entwickelt, mit deren Hilfe bauphysikalische Fachkompetenzen vermittelt werden können.
Im Rahmen dieser Arbeit wurde die Entscheidungsfindung im Herstellungsprozess von Brückenkappen untersucht. Es stellte sich heraus, dass die Fuzzy-Methode ein geeignetes Werkzeug sein könnte, die Teilprozesse auf die Möglichkeit ihrer Parallelisierung hin zu untersuchen. Um diese Theorie zu testen, wurde auf den Grundlagen von Arbeiten der Professur Baubetrieb und Bauverfahren der Prozess näher analysiert und unterstützend durch eigene Recherchen ein UML-Diagramm erstellt, welches als Aktivitätsdiagramm ausgebildet wurde. Aufbauend auf diesem Ablauf und den gewonnenen Kenntnissen zur Herstellung einer Brückenkappe, konnten die einzelnen Prozesse zu Teilprozessen, sogenannten Bausteinen, zusammengefasst werden. Diese Bausteine sind entstanden, um die Simulation möglich zu machen, indem der Ablauf weniger komplex wird und nur die Prozesse zu beurteilen sind, die beeinflusst bzw. in ihrer Reihenfolge bis zu einem gewissen Grad variabel sind. Eine erleichterte Interaktion mit den Bausteinen und deren Überführung in ein Simulationsprogramm wurde über Templates realisiert. So besitzt jeder Baustein eine einheitliche Struktur. Unter anderem beinhalten die Bausteine die jeweiligen Ressourcen und Parameter, sowie die Abhängigkeiten der Prozesse untereinander und die zugehörige Priorität. Zur Entscheidungsfindung wurde die Fuzzylogik herangezogen und die Problemstellung der Parallelisierung zum Ziel gesetzt. Die Realisierung wurde über einen Entscheidungsbaum und das daraus resultierende Regelwerk erreicht. Somit ließen sich, ausgehend von einem festgelegten Prozess und durch die Fuzzifizierung der Eingangsparameter Priorität, Prozessdauer und Verfügbarkeit der Ressourcen und Arbeitskräfte, verschiedene Pfade identifizieren, allerdings nur in Verbindung mit den vorher analysierten Abhängigkeiten. Für jeden der Eingangsparameter wurden so Fuzzy-Sets erstellt. Über den Entscheidungsbaum, welcher mit den linguistischen Variablen versehen wurde, konnte über sogenannte "und" - Verknüpfungen das Regelwerk aufgestellt werden. Das gekürzte Regelwerk in dieser Arbeit beinhaltet grundsätzlich nur die Regeln, die auch zu einer wirklichen Entscheidung führen. Daraus folgt, dass es möglich ist mittels der Fuzzy-Methode eine Entscheidung darüber zu fällen, ob zwei Prozesse zu parallelisieren sind oder nicht und aufgetretene Verzögerungen wieder eingeholt werden können.