Oriented crossover in genetic algorithms for computer networks optimization

Optimization using genetic algorithms (GA) is a well-known strategy in several scientific disciplines. The crossover is an essential operator of the genetic algorithm. It has been an active area of research to develop sustainable forms for this operand. In this work, a new crossover operand is proposed. This operand depends on giving an elicited description for the chromosome with a new structure for alleles of the parents. It is suggested that each allele has two attitudes, one attitude differs contrastingly with the other, and both of them complement the allele. Thus, in case where one attitude is good, the other should be bad. This is suitable for many systems which contain admired parameters and unadmired parameters. The proposed crossover would improve the desired attitudes and dampen the undesired attitudes. The proposed crossover can be achieved in two stages: The first stage is a mating method for both attitudes in one parent to improving one attitude at the expense of the other. The second stage comes after the first improvement stage for mating between different parents. Hence, two concurrent steps for improvement would be applied. Simulation experiments for the system show improvement in the fitness function. The proposed crossover could be helpful in different fields, especially to optimize routing algorithms and network protocols, an application that has been tested as a case study in this work

Radio frequency channel characterization for energy harvesting in factory environments

This thesis presents ambient energy data obtained from a measurement campaign carried out at an automobile plant. At the automobile plant, ambient light, ambient temperature and ambient radio frequency were measured during the day time over two days. The measurement results showed that ambient light generated the highest DC power. For plant and operation managers at the automobile plant, the measurement data can be used in system design considerations for future energy harvesting wireless sensor nodes at the plant. In addition, wideband measurements obtained from a machine workshop are presented in this thesis. The power delay profile of the wireless channel was obtained by using a frequency domain channel sounding technique. The measurements were compared with an equivalent ray tracing model in order to validate the suitability of the commercial propagation software used in this work. Furthermore, a novel technique for mathematically recreating the time dispersion created by factory inventory in a radio frequency channel is discussed. As a wireless receiver design parameter, delay spread characterizes the amplitude and phase response of the radio channel. In wireless sensor devices, this becomes paramount, as it determines the complexity of the receiver. In reality, it is sometimes difficult to obtain full detail floor plans of factories for deterministic modelling or carry out spot measurements during building construction. As a result, radio provision may be suboptimal. The method presented in this thesis is based on 3-D fractal geometry. By employing the fractal overlaying algorithm presented, metallic objects can be placed on a floor plan so as to obtain similar radio frequency channel effects. The environment created using the fractal approach was used to estimate the amount of energy a harvesting device can accumulate in a University machine workshop space

Systematic survey on evolution of cloud architectures

Cloud architectures are becoming an active area of research. The quality and durability of a software system are defined by its architecture. The architecture approaches that are used to build cloud-based systems are not available in a blended fashion to achieve an effective universal architecture solution. The paper aims to contribute to the systematic literature review (SLR) to assist researchers who are striving to contribute in this area. The main objective of this review is to systematically identify and analyse the recently published research topics related to software architecture for cloud with regard to research activity, used tools and techniques, proposed approaches, domains. The applied method is SLR based on four selected electronic databases proposed by (Kitchenham and Charters, 2007). Out of 400 classified publications, we regard 121 as relevant for our research domain. We outline taxonomy of their topics and domains, provide lists of used methods and proposed approaches. At present, there is little research coverage on software architectures for cloud, while other disciplines have become more active. The future work is to develop a secure architecture to achieve quality of service and service level agreements

Analysis and Life Cycle Assessment of Printed Antennas for Sustainable Wireless Systems

Siirretty Doriast

Fractal Image Editing with PhotoFrac

In this paper, we describe the development and use of PhotoFrac, an application that allows artists and designers to turn digital images into fractal patterns interactively. Fractal equations are a rich source of procedural texture and detail, but controlling the patterns and incorporating traditional media has been difficult. Additionally, the iterative nature of fractal calculations makes implementation of interactive techniques on mobile devices and web apps challenging. We overcome these problems by using an image coordinate based orbit trapping technique that permits a user-selected image to be embedded into the fractal. Performance challenges are addressed by exploiting the processing power of graphic processing unit (GPU) and precomputing some intermediate results for use on mobile devices. This paper presents results and qualitative analyses of the tool by four artists (the authors) who used the PhotoFrac application to create new artworks from original digital images. The final results demonstrate a fusion of traditional media with algorithmic art

Directional Spectral Solar Energy for Building Performance: From Simulation to Cyber-physical Prototype

The original research and development in this dissertation contributes to the field of building performance by actively harnessing a wider spectrum of directional solar radiation for use in buildings. Solar radiation (energy) is often grouped by wavelength measurement into the spectra ultraviolet (UV), visible (light), and short and long-wave infrared (heat) on the electromagnetic spectrum. While some of this energy is directly absorbed or deflected by our atmosphere, most of it passes through, scatters about, and collides with our planet. Modern building performance simulations, tools, and control systems often oversimplify this energy into scalar values for light and heat, when in reality they are interrelated directional spectral quantities of energy that are diffused and attenuated by clouds before colliding with surfaces. In addition to this, live building monitoring and control systems in-the-wild often do not track the location of the sun, separate direct sun energy from scattered sky energy, account for overcast clouds, considering occluded energy, etc. The work in this dissertation provides building energy simulations and control systems with finer-grain control over lighting and heating in order to optimize energy use and improve occupant well-being. We first present a data-driven machine learned sky model for predicting spectral radiance, and show how this technique can be used to produce spectral radiance maps for the entire hemispherical sky. We then integrate these predicted spectral radiance maps and other validated predictions into a custom radiosity engine in order to predict spectral daylighting and heating energy in building interiors. Finally, we present the design and prototyping of a cyber-physical building control system that monitors the sky and occupants in order to harness natural light and heat more effectively. We present ongoing and future work recommendations, such as sky cover projections to help reduce cooling recovery costs, and the use of spectral radiance maps in physically-based rendering engines

Towards Synthetic Dataset Generation for Semantic Segmentation Networks

Recent work in semantic segmentation research for autonomous vehicles has shifted towards multimodal techniques. The driving factor behind this is a lack of reliable and ample ground truth annotation data of real-world adverse weather and lighting conditions. Human labeling of such adverse conditions is oftentimes erroneous and very expensive. However, it is a worthwhile endeavour to identify ways to make unimodal semantic segmentation networks more robust. It encourages cost reduction through reduced reliance on sensor fusion. Also, a more robust unimodal network can be used towards multimodal techniques for increased overall system performance. The objective of this thesis is to converge upon a synthetic dataset generation method and testing framework that is conducive towards rapid validation of unimodal semantic segmentation network architectures. We explore multiple avenues of synthetic dataset generation. Insights gained through these explorations guide us towards designing the ProcSy method. ProcSy consists of a procedurally-created, virtual replica of a real-world operational design domain around the city of Waterloo, Ontario. Ground truth annotations, depth, and occlusion data can be produced in real-time. The ProcSy method generates repeatable scenes with quantifiable variations of adverse weather and lighting conditions. We demonstrate experiments using the ProcSy method on DeepLab v3+, a state-of-the-art network for unimodal semantic segmentation tasks. We gain insights about the behaviour of DeepLab on unseen adverse weather conditions. Based on empirical testing, we identify optimization techniques towards data collection for robustly training the network

Biomimetic design and fabrication of tissue engineered scaffolds using computer aided tissue engineering

The field of tissue engineering brings together the multidisciplinary research of life sciences and engineering to seek man-made substitutes for the regeneration of damaged tissue or organs. A key component in tissue engineering is the use of porous scaffolds to guide cells for attachment, proliferation and differentiation in the tissue regenerative process. Upon satisfactory in-vitro culture, this engineered living scaffold is implanted into the regeneration site of the patient to function as the tissue substitute. Conventional processing techniques for the fabrication of scaffolds often encounter difficulties in the precise control of the internal architecture, interconnectivity and distribution of pores within the scaffold. These challenges, along with the advances in biology, medicine, and information technology for tissue engineering applications, have led to the development of a new field of Computer Aided Tissue Engineering (CATE).CATE enables a systematic application of computer-aided technologies, i.e., computer-aided design (CAD), image processing, computer-aided manufacturing (CAM), and solid freeform fabrication (SFF) for modeling, designing, simulation, and manufacturing of biological tissue and organ substitutes. Through the use of CATE, the design of intricate three dimensional architecture of scaffold can be realized and these scaffolds can be fabricated with reproducible accuracy to assist biologists in studying complex tissue engineering problems. This thesis reports a research addressing some of the challenges in applying the CATE approach for the biomimetic design and freeform fabrication of tissue scaffolds. The major research accomplishments reported in this thesis include: a) The development of a BioCAD modeling technique for the design and representation of patient specific 3D tissue models based on non-invasive medical image data. b) The development of a biomimetic design approach for design of load bearing tissue scaffold subject to multiple biophysical, geometrical and manufacturing requirements. This includes the design of the unit cell micro-architecture based on tissue morphologies, unit cell characterization and evaluation of the mechanical and transport properties, and the use of unit cells as building block to design anatomic tissue scaffold replacements. c) The development of a CAD based path planning procedure through a direct slicing algorithm which can convert a neutral ISO (International Standards Organization) standardized STEP (Standard for the Exchange of Product Data) formatted NURBS (Non-Uniform Rational B-Spline) geometric representation to a tool path instruction set for layered freeform fabrication. d) The development of a novel Internal Architecture Design (IAD) approach for the mapping of characteristic patterns of the unit cell micro-architectures designed within the 3D scaffold. This design approach is implemented into a process algorithm that converts these 2D patterns to tool path datasets for the 3DP™ (threedimensional printing) and extrusion based freeform fabrication.CATE enables many novel approaches in modeling, design, and fabrication of complex tissue substitutes with enhanced functionality for research in patient specific implant analysis and simulation, image guided surgical planning and scaffold guided tissue engineering. The research will also enable cell biologists and engineers to expand their scope of research and study in the field of tissue engineering and regenerative medicine.Ph.D., Mechanical Engineering -- Drexel University, 200