From Project to Production provides a detailed account of project development in industrial engineering, with emphasis on the administrative procedure along which creative effort should be channeled. This book highlights the necessity for, and the use of, the industrial designer and points out where the machine element analysis and synthesis, circuit calculations, design, and drafting fit into the general industrial pattern. This book is comprised of 11 chapters and begins with an overview of the difficulties involved producing a satisfactory guide to design and development work, along with the importance of training and the chain of command in project development. The next chapter explains how a project is conceived and considers the economic principles, development policy, engineering products, the development effort on production plant, and project implementation. The reader is methodically introduced to the rationalization of project work; engineering design, industrial design, and optimum design; and inventions, patents, and design registration. The remaining chapters focus on design realization; materials and stress analysis; development of models and prototype; and the technical activity of an engineering company. This monograph will be a useful resource for students, teachers, and practitioners of engineering.
How to achieve a happier and healthier game design process by connecting the creative aspects of game design with techniques for effective project management. This book teaches game designers, aspiring game developers, and game design students how to take a digital game project from start to finish—from conceptualizing and designing to building, playtesting, and iterating—while avoiding the uncontrolled overwork known among developers as “crunch.” Written by a legendary game designer, A Playful Production Process outlines a process that connects the creative aspects of game design with proven techniques for effective project management. The book outlines four project phases—ideation, preproduction, full production, and post-production—that give designers and developers the milestones they need to advance from the first glimmerings of an idea to a finished game.
This book gathers the proceedings of the EPPM 2019 conference, and highlights innovative work by researchers and practitioners active in various industries around the globe. Recent advances in science and technology have made it possible to seamlessly connect and integrate various elements of engineering systems, and opened the door for innovations that have transformed how we live and work. While these developments have yielded enhanced efficiency and numerous improvements in our current practices, the problems caused by the increased complexity of these integrated systems can be extremely difficult. Accordingly, solving these problems involves applying cross-disciplinary expertise to address the heterogeneity of the various elements inherent in the system. These proceedings address four main themes: (I) Smart and Sustainable Construction, (II) Advances in Project Management Practices, (III) Toward Safety and Productivity Improvement, and (IV) Smart Manufacturing, Design, and Logistics. As such, they will be of interest to and valuable to researchers and practitioners in a range of industries seeking an update on the translational fields of engineering, project, and production management.
Our economy and future way of life depend on how well American manufacturing managers adapt to the dynamic, globally competitive landscape and evolve their firms to keep pace. A major challenge is how to structure the firms environment so that it attains the speed and low cost of high-volume flow lines while retaining the flexibility and customization potential of a low-volume job shop. The books three parts are organized according to three categories of skills required by managers and engineers: basics, intuition, and synthesis. Part I reviews traditional operations management techniques and identifies the necessary components of the science of manufacturing. Part II presents the core concepts of the book, beginning with the structure of the science of manufacturing and a discussion of the systems approach to problem solving. Other topics include behavioral tendencies of manufacturing plants, push and pull production systems, the human element in operations management, and the relationship between quality and operations. Chapter conclusions include main points and observations framed as manufacturing laws. In Part III, the lessons of Part I and the laws of Part II are applied to address specific manufacturing management issues in detail. The authors compare and contrast common problems, including shop floor control, long-range aggregate planning, workforce planning and capacity management. A main focus in Part III is to help readers visualize how general concepts in Part II can be applied to specific problems. Written for both engineering and management students, the authors demonstrate the effectiveness of a rule-based and data driven approach to operations planning and control. They advance an organized framework from which to evaluate management practices and develop useful intuition about manufacturing systems.
Get more out of your legacy systems: more performance, functionality, reliability, and manageability Is your code easy to change? Can you get nearly instantaneous feedback when you do change it? Do you understand it? If the answer to any of these questions is no, you have legacy code, and it is draining time and money away from your development efforts. In this book, Michael Feathers offers start-to-finish strategies for working more effectively with large, untested legacy code bases. This book draws on material Michael created for his renowned Object Mentor seminars: techniques Michael has used in mentoring to help hundreds of developers, technical managers, and testers bring their legacy systems under control. The topics covered include Understanding the mechanics of software change: adding features, fixing bugs, improving design, optimizing performance Getting legacy code into a test harness Writing tests that protect you against introducing new problems Techniques that can be used with any language or platform—with examples in Java, C++, C, and C# Accurately identifying where code changes need to be made Coping with legacy systems that aren't object-oriented Handling applications that don't seem to have any structure This book also includes a catalog of twenty-four dependency-breaking techniques that help you work with program elements in isolation and make safer changes.
In the complex world today, the foreign project planning and development is faced with a chancing flow of decision situations. Added to this must be Covid 19 virus with its world wide impact that complicate the situation further. The degree of impact varies on case basis, the location, activity or sub disciplines associated with the scope and the partners' role in the project. In the changing world situation it is not realistic to outline a detailed blanked coved impact to all typical project activities. Rather, in more general terms and strong foreign field experience create awareness of important project planning issues for engineers and responsible managers. The book is a Rare and Unique introduction to the topic with illustrations to clarify the issues. The outlined method is for a complex project with combination of strong practical engineering, management skills, field experience and need-based analytical techniques. The approach can be tailored and employed in the management of any kind international project development and planning consideration and in the project management training.
A production strategy enables companies to effectively manage the different challenges that the production function face in a competitive environment. A production strategy helps a company to make operational and strategic decisions that follow a logical pattern and supports the corporate strategy and the competitive priorities of the company. When no strategy exists the decisions may be arbitrary and unpredictable leading to an under-achieving production system. Production strategy involves decisions that shape the long term capabilities of a producing company. For the traditional production industry there are a number of production strategy frameworks that facilitates the process of designing production systems. However, these frameworks typically leave project based production out of the scope or treat project based production as one type of production system, when in fact project based production systems can be multifaceted depending on product design and market requirements. This thesis focus on project based manufacturing in a house-building context. Houses can be produced by different types of production systems, and depending on how the production systems are designed they have strengths and weaknesses in different areas of competition. To be able to meet the increasing demand for residential houses, and improve performance in the house-building industry, the way houses are produced have to match different market requirements in a more effective and efficient way. To do this a production strategy has to exist. Typically there is a trade-off between productivity and flexibility, hence a production system designed to meet customer requirements concerning product design is probably not the best process choice if the customer thinks price and delivery time are the most important. A production strategy helps a company to make decisions so that the output of the production system meets customer requirements in the best possible way. Due to the fact that project based production is typically left out of the scope in traditional production strategy literature and that there is a lack of research concerning production strategy in a house-building context, the purpose of this research is: … to extend the production strategy body of knowledge concerning project based production in a house-building context. To fulfil the purpose the following four research questions are studied and answered: RQ1: What aspects can be useful in a classification matrix contrasting different production systems for house-building? RQ2: Which competitive priorities are important to measure when evaluating different production systems on a production strategy level in a house-building context, and how can they quantitatively be measured? RQ3: How does the characteristics of the production system, i.e. the process choice, affect information exchange in a house-building context? RQ4: How can a new production strategy be formulated and implemented in an industrialised house-building context and what challenges are important to consider in that process? To answer RQ1 a classification matrix was developed that classify production systems along two dimensions: a product dimension (degree of product standardisation) and a process dimension (degree of off-site assembly). The two dimensions are related, for example a high degree of standardisation should be matched with a high degree of off-site assembly and consequently a low degree of product standardisation should be matched with a low degree of off-suite assembly. A mismatch, e.g. high degree of off-site assembly and low degree of standardisation, typically leads to poor performance and should hence be avoided. To be able to see how different types of production systems perform in different areas of competition key performance indicators (KPIs) were developed. The KPIs presented in this research can be used to measure quality, delivery (speed and dependability), cost (level and dependability), and flexibility (volume and mix) at a production strategic level (RQ2). Furthermore, to answer RQ3, a production strategy perspective was taken on information exchange by relating information exchange to the design of the production system. The results indicate that employing different types of production systems leads to different approaches to information exchange. Employing a production systems using traditional production methods on-site and a low degree of product standardisation lead to a traditional approach to information exchange, e.g. project meetings, telephone and mail. Production systems employing some degree of off-site assembly have less complex and more stable supply chains and use ICT-solutions to a higher extent, which facilitates information exchange. The findings also indicate that a high degree of product standardisation facilitates the use of ICT-solutions such as ERP and BIM. RQ4 concerns the production strategy process, i.e. formulation and implementation. Failure in this processes can jeopardise the whole business. Based on a longitudinal case study of an industrialised house-builder a suggested production strategy process was developed, including both production strategy formulation and implementation. The study also identified context specific challenges that have to be considered in an industrialised house-building context, e.g. the complexity that comes with using two different production processes (off-site and on-site) in the same production system. The research is case based and a total number of eight different production systems have been studied. Data has been collected through interviews, observations, and review of company documents.
Management and administrative processes within the construction industry have been undergoing major changes in the last several decades. These changes have involved significant adjustments in management science and manage ment techniques, brought about by the need for contemporary valid informa tion with which to manage the construction process. In short, management in the construction industry is changing significantly; change will continue at an accelerated pace at least through the next decade. The responses required of construction industry management are now resulting in a movement away from an entrepreneurial management style to professional management tech niques and procedures. THE COMPELLING ECONOMIC ISSUES The issues forcing these changes are economic. The rising costs of construction and of money are forcing the buyers of construction services to be more demanding. Their demands are for more construction economies, more pro duction, and more productivity than at any time in the past. Nowhere has this been more evident than in the Business Roundtable on construction and in the response of the construction industry to it.· To be successfully responsive, management in the construction industry will be required to use the best project management methods available for cost control, schedule control, and for financial and accounting controls. But responsive professional management can survive and will flourish within this more demanding eco nomic environment.
This fifth edition provides a comprehensive resource for project managers. It describes the latest project management systems that use critical path methods.
"Presented in full color, Engineering Production-Grade Shiny Apps helps people build production-grade shiny applications, by providing advice, tools, and a methodology to work on web applications with R. This book starts with an overview of the challenges which arise from any big web application project: organizing work, thinking about the user interface, challenges of teamwork & production environment. Then, it moves to a step by step methodology that goes from the idea to the end application. Each part of this process will cover in detail a series of tools and methods to use while building production-ready shiny applications. Finally, the book will end with a series of approaches and advice about optimizations for production"--
