TY - THES A1 - Unger, Jörg F. T1 - Neural networks in a multiscale approach for concrete N2 - From a macroscopic point of view, failure within concrete structures is characterized by the initiation and propagation of cracks. In the first part of the thesis, a methodology for macroscopic crack growth simulations for concrete structures using a cohesive discrete crack approach based on the extended finite element method is introduced. Particular attention is turned to the investigation of criteria for crack initiation and crack growth. A drawback of the macroscopic simulation is that the real physical phenomena leading to the nonlinear behavior are only modeled phenomenologically. For concrete, the nonlinear behavior is characterized by the initiation of microcracks which coalesce into macroscopic cracks. In order to obtain a higher resolution of this failure zones, a mesoscale model for concrete is developed that models particles, mortar matrix and the interfacial transition zone (ITZ) explicitly. The essential features are a representation of particles using a prescribed grading curve, a material formulation based on a cohesive approach for the ITZ and a combined model with damage and plasticity for the mortar matrix. Compared to numerical simulations, the response of real structures exhibits a stochastic scatter. This is e.g. due to the intrinsic heterogeneities of the structure. For mesoscale models, these intrinsic heterogeneities are simulated by using a random distribution of particles and by a simulation of spatially variable material parameters using random fields. There are two major problems related to numerical simulations on the mesoscale. First of all, the material parameters for the constitutive description of the materials are often difficult to measure directly. In order to estimate material parameters from macroscopic experiments, a parameter identification procedure based on Bayesian neural networks is developed which is universally applicable to any parameter identification problem in numerical simulations based on experimental results. This approach offers information about the most probable set of material parameters based on experimental data and information about the accuracy of the estimate. Consequently, this approach can be used a priori to determine a set of experiments to be carried out in order to fit the parameters of a numerical model to experimental data. The second problem is the computational effort required for mesoscale simulations of a full macroscopic structure. For this purpose, a coupling between mesoscale and macroscale model is developed. Representative mesoscale simulations are used to train a metamodel that is finally used as a constitutive model in a macroscopic simulation. Special focus is placed on the ability of appropriately simulating unloading. N2 - Makroskopisch betrachtet kann das Versagen von Beton durch die Entstehung und das Wachstum von Rissen beschrieben werden. Im ersten Teil der Arbeit wird eine Methode zur Simulation der makroskopischen Rissentwicklung von Beton unter Verwendung von kohäsiven diskreten Rissen basierend auf der erweiterten Finiten Elemente Methode vorgestellt. Besondere Bedeutung liegt dabei auf der Untersuchung von Kriterien zur Rissentstehung und zum Risswachstum. Ein Nachteil von makroskopischen Simulationen liegt in der nur phänomenologischen Berücksichtigung der tatsächlichen Vorgänge. Nichtlineares Verhalten von Beton ist durch die Entstehung von Mikrorissen gekennzeichnet, die bei weiterer Belastung zu makroskopischen Rissen zusammenwachsen. Um die Versagenszone realitätsnah abbilden zu können, wurde ein Mesoskalenmodell von Beton entwickelt, welches Zuschläge, Matrix und Übergangszone zwischen beiden Materialien (ITZ) direkt abbildet. Hauptmerkmal sind die Simulation der Zuschläge nach einer Sieblinie, eine kohäsive Materialformulierung der ITZ und ein kombiniertes Model aus Schädigung und Plastizität für das Matrixmaterial. Im Gegensatz zu numerischen Simulationen ist die Systemantwort reeller Strukturen eine unscharfe Größe. Dies liegt u.a. an Heterogenitäten innerhalb der Struktur, die im Rahmen der Arbeit durch eine zufällige Verteilung der Zuschläge und über räumlich variierende Materialparameter unter Verwendung von Zufallsfeldern simuliert werden. Zwei Hauptprobleme sind bei den Mesoskalensimulationen aufgetreten. Einerseits sind Materialparameter auf der Mesoskala oft schwer zu bestimmen. Deswegen wurde eine Methode basierend auf Bayes neuronalen Netzen entwickelt, die eine Parameteridentifikation unter Verwendung von makroskopischen Versuchen erlaubt. Diese Methode ist aber universell anwendbar auf alle Parameteridentifikationsprobleme in numerischen Simulationen basierend auf experimentellen Daten. Der Ansatz liefert sowohl Informationen über den wahrscheinlichsten Parametersatz des Models zur numerischen Simulation eines Experiments als auch eine Einschätzung der Genauigkeit dieses Schätzers. Die Methode kann auch verwendet werden, um a priori einen Satz von Experimenten auszuwählen der notwendig ist, um die Parameter eines numerischen Modells zu bestimmen. Ein zweites Problem ist der numerische Aufwand von Mesoskalensimulationen für makroskopische Strukturen. Aus diesem Grund wurde eine Kopplungsstrategie zwischen Meso- und Makromodell entwickelt, bei dem repräsentative Simulationen auf der Mesoebene verwendet werden, um ein Metamodell zu generieren, welches dann die Materialformulierung in einer makroskopischen Simulation darstellt. Ein Fokus liegt dabei auf der korrekten Abbildung von Entlastungen. T2 - Neuronale Netze in einem Multiskalenansatz für Beton T3 - ISM-Bericht // Institut für Strukturmechanik, Bauhaus-Universität Weimar - 2009,1 KW - Beton KW - Mehrskalenmodell KW - Mehrskalenanalyse KW - Neuronales Netz KW - Monte-Carlo-Simulation KW - Simulation KW - Monte-Carlo-Integration KW - Kontinuierliche Simul KW - Bayes neuronale Netze KW - Parameteridentification KW - Bayesian neural networks KW - parameter identification Y1 - 2009 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:gbv:wim2-20090626-14763 ER - TY - CHAP A1 - Taha, M. M. Reda A1 - Sherif, Alaa A1 - Hegger, Josef T1 - A nouvelle approach for predicting the shear cracking angle in RC and PC beams using artificial neural networks N2 - The truss model for predicting shear resistance of reinforced concrete beams has usually been criticized because of its underestimation of the concrete shear strength especially for beams with low shear reinforcement. Two challengers are commonly encountered in any truss model and are responsible for its inaccurate shear strength prediction. First: the cracking angle is usually assumed empirically and second the shear contribution of the arching action is usually neglected. This research introduces a nouvelle approach, by using Artificial Neural Network (ANN) for accurately evaluating the shear cracking angle of reinforced and prestressed concrete beams. The model inputs include the beam geometry, concrete strength, the shear reinforcement ratio and the prestressing stress if any. ... KW - Neuronales Netz KW - Wasserbau KW - Scherung KW - Rissbildung Y1 - 2004 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:gbv:wim2-20111215-1071 ER - TY - CHAP A1 - Swaddiwudhipong, Somsak A1 - Tho, Kee Kiat A1 - Liu, Zishun T1 - Material characterization using artificial neural network N2 - Indentation experiments have been carried out over the past century to determine hardness of materials. Modern indentation machines have the capability to continuously monitor load and displacement to high precision and accuracy. In recent years, research interests have focussed on methods to extract material properties from indentation load-displacement curves. Analytical methods to interpret the indentation load-displacement curves are difficult to formulate due to material and geometric nonlinearities as well as complex contact interactions. In the present study, an artificial neural network model was constructed for interpretation of indentation load-displacement curves. Large strain-large deformation finite element analyses were first carried out to simulate indentation experiments. The data from finite element analyses were then used to train the artificial neural network model. The artificial neural network model was able to accurately determine the material properties when presented with load-displacement curves which were not used in the training process. The proposed artificial neural network model is robust and directly relates the characteristics of the indentation loaddisplacement curve to the elasto-plastic material properties. KW - Neuronales Netz KW - Wasserbau KW - Werkstoffprüfung Y1 - 2004 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:gbv:wim2-20111215-1550 ER - TY - CHAP A1 - Korsunov, Nikolay A1 - Youriev, Alexander A1 - Nikitinskiy, Dmitry T1 - Use of neuron nets by definition deflected mode of constructions T1 - Primenenie nejronnych setej pri rascete konstrukcij N2 - At present time neuronet's technologies have got a wide application in a different fields of technique. At the same time they give insufficient consideration to using neuron nets in the field of building. Use of approximating neuron nets will allow to definite the deflected mode of constructions elements using noticeably less computing facilities then by using universal methods, finite-element method for instance. Today neuron nets are used for calculation separate elements of building constructions. In this work use of neuron nets for calculation deflected mode of construction which consists of many elements is consider. The main idea of suggested analysis is using neuron nets for calculation internal intensities and transferences pieces of model which are selected by there functional destination. For example, a plate is destine for adoption intensity distributed among area, the purpose of core is taking up surface distributed intensity. Elements involved as intensity converter. Plate serve for intensities dispersion and their transfer. A template is associated with functional destination. A template regards as composition of model elements which has define functional destinations. A single template can incarnate several functional destinations. On receipt values of components transference the estimation of their permissibility is put into practice. In the case of detection a violation of permissible limit, in the component database is making a search for component with analogous functional destination, according to the type of violation. If such component is found than a change a previous component into new one is realized. Thus besides control a condition of construction by components there is a possibility to make a search for decisions of revealed problem.... KW - Baustatik KW - Neuronales Netz Y1 - 2003 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:gbv:wim2-20111215-3247 ER -