A robust autofocusing technique for applications in synthetic aperture stripmap imaging radars - Design and simulation

Pace, Phillip E.

January 1986

No description available.

Robust Autofocusing Technique

Computational approach to anti-cancer drug discovery

Rana, Ambar.

09 July 2011

Access to abstract permanently restricted to Ball State community only / Access to thesis permanently restricted to Ball State community only / Department of Chemistry

Lungs--Cancer--Chemotherapy.

A Substructure Based Parallel Solution Framework for Solving Linear Structural Systems with Multiple Loading Conditions

Kurc, Ozgur

21 April 2005

This study presented a substructure based parallel linear solution framework for the static analysis of linear structural engineering problems having multiple loading conditions. The framework was composed of two separate programs designed to work on PC Clusters having the Windows operating system. The first program was responsible for creating the optimum substructures for the parallel solution and first partitioned the structure in such a way that the number of substructures was equal to the number of processors. Then, the estimated condensation time imbalance of the initial substructures was adjusted by iteratively transferring nodes from the substructures with slower estimated condensation times to the substructures with faster estimated condensation times. Once the final substructures were created, the second program started the solution. Each processor assembled its substructures stiffness matrix and condensed it to the interface with other substructures. The interface problem was solved by a parallel variable band solver. After computing the interface unknowns, each processor calculated the internal displacements and element stresses or forces. Examples which illustrate the applicability and efficiency of this approach were also presented. In these examples, the number of processors was varied from one to twelve to demonstrate the performance of the overall solution framework.

Partitioning

Direct solution

Substructuring

Structural

Parallel

Repartitioning

Structural analysis (Engineering)

Load factor design Computer simulation

A virtual prototyping system with reconfigurable manipulators for layered manufacturing

Cai, Yi, 蔡毅

January 2011

published_or_final_version / Industrial and Manufacturing Systems Engineering / Master / Master of Philosophy

Rapid prototyping.

Virtual reality.

Agent-based simulation of socio-technical systems : software architecture and timing mechanisms

Lee, Seung Man

08 1900

No description available.

System design Computer simulation

System analysis Computer programs

Computer simulation

Automatic timers

Computational antiviral drug design

Liu, Lishan

24 July 2010

This study designed and computational docked a group of ligands intended to find potent inhibitors for Neuraminidase 4 which would have strong interactions with 8 conserved amino acids in the active site. Several trials of ligands were designed based on derivatives of neuraminic acid and evaluated as inhibitors of influenza neuraminidase. Optimized geometries of those ligands were determined using HF/B3LYP/6-311++G** techniques. Binding energies of the ligands bound to the N4 subtype of the neuraminidase protein were determined using AutoDock 4.0. Currently used inhibitors for influenza viruses will also be analyzed in the exactly same way. Comparing the binding information of those candidates and current ligands can provide a useful data about the potential of these species as antiviral drugs. / Department of Chemistry

Neuraminidase--Inhibitors

Influenza A virus

Influenza--Treatment

Design of a High Altitude Wind Power Generation System

Aziz, Imran

January 2013

One of the key points to reduce the world dependence on fossil fuels and the emissions of greenhouse gases is the use of renewable energy sources. Recent studies showed that wind energy is a significant source of renewable energy which is capable to meet the global energy demands. However, such energy cannot be harvested by today’s technology, based on wind towers, which has nearly reached its economical and technological limits. The major part of the atmospheric wind is inaccessible to the conventional wind turbines and wind at higher altitude is the major source of potential energy which has not been fully exploited yet. The thesis paper has presented a study aimed to devise a new class of wind generator based on extracting energy from high altitude wind.A brief theoretical study is presented to evaluate the potential of an innovative high altitude wind power technology which exploits a tethered airfoil to extract energy from wind at higher altitude. Among the various concepts proposed over last few decades, a kite power system with a single kite is selected for the design purpose.The designed ground station is an improvisation over existing prototypes with an energy reservoir for having a continuous power output. A flywheel is used as the energy storage system which stores the extra energy during traction phases and supplies it during recovery phases and thus giving a continuous power generation regardless of the kite’s motion and keeping the rotor speed in a permissible range defined by the design constraints. Manufacturability of the structure, availability of the components, safety and maintenance criteria have been taken into account while building the ground station CAD model.A dynamic simulation model is developed to investigate the power transmission system of the kite power unit which reflects the torque, speed and power behaviour of the modelled ground station driveline. The functionality of the designed model for the selected concept is tested with several numerical and graphical examples.

A small perturbation based optimization approach for the frequency placement of

Goltsch, Mandy.

January 2009

Thesis (M. S.)--Aerospace Engineering, Georgia Institute of Technology, 2009. / Committee Chair: Mavris, Dimitri; Committee Member: Bauchau, Olivier; Committee Member: Schrage, Daniel; Committee Member: Volovoi, Vitali; Committee Member: Yu, Wenbin.

Design and Analysis of Shipping Container made of Honeycomb Sandwich Panels

Chawa, Prashanth Kumar, Mukkamala, Sai Kushal

January 2018

This paper applies to the design and simulation of a shipping container made of sandwich panels. The amount of stresses acting on the body of the container is calculated and is optimized to reduce stresses for the better design output of the structure. The design aims to produce an application to reduce the tare weight of the container in order to increase the payload. Finite Element Analysis (FEA) is performed to evaluate the strength of structures of both old and new models helps us to compare which model is better and more efficient. Complete design and analysis is performed using Autodesk Inventor. / no

Finite Element Analysis

Autodesk Inventor

Honeycomb structures

Design and Simulation.

Mechanical Engineering

Maskinteknik

An integrated framework for developing generic modular reconfigurable platforms for micro manufacturing and its implementation

Sun, Xizhi

January 2009

The continuing trends of miniaturisation, mass customisation, globalisation and wide use of the Internet have great impacts upon manufacturing in the 21st century. Micro manufacturing will play an increasingly important role in bridging the gap between the traditional precision manufacturing and the emerging technologies like MEMS/NEMS. The key requirements for micro manufacturing in this context are hybrid manufacturing capability, modularity, reconfigurability, adaptability and energy/resource efficiency. The existing design approaches tend to have narrow scope and are largely limited to individual manufacturing processes and applications. The above requirements demand a fundamentally new approach to the future applications of micro manufacturing so as to obtain producibility, predictability and productivity covering the full process chains and value chains. A novel generic modular reconfigurable platform (GMRP) is proposed in such a context. The proposed GMRP is able to offer hybrid manufacturing capabilities, modularity, reconfigurablity and adaptivity as both an individual machine tool and a micro manufacturing system, and provides a cost effective solution to high value micro manufacturing in an agile, responsive and mass customisation manner. An integrated framework has been developed to assist the design of GMRPs due to their complexity. The framework incorporates theoretical GMRP model, design support system and extension interfaces. The GMRP model covers various relevant micro manufacturing processes and machine tool elements. The design support system includes a user-friendly interface, a design engine for design process and design evaluation, together with scalable design knowledge base and database. The functionalities of the framework can also be extended through the design support system interface, the GMRP interface and the application interface, i.e. linking to external hardware and/or software modules. The design support system provides a number of tools for the analysis and evaluation of the design solutions. The kinematic simulation of machine tools can be performed using the Virtual Reality toolbox in Matlab. A module has also been developed for the multiscale modelling, simulation and results analysis in Matlab. A number of different cutting parameters can be studied and the machining performance can be subsequently evaluated using this module. The mathematical models for a non-traditional micro manufacturing process, micro EDM, have been developed with the simulation performed using FEA. Various design theories and methodologies have been studied, and the axiomatic design theory has been selected because of its great power and simplicity. It has been applied in the conceptual design of GMRP and its design support system. The implementation of the design support system is carried out using Matlab, Java and XML technologies. The proposed GMRP and framework have been evaluated through case studies and experimental results.

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