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"This study assesses the environmental and economic impacts of the immediate shutdownof all Japan's nuclear reactor fleet. For the assessment, we regard a gradual nuclear powerphase-out scenario as the basis for a 40-year operational time limit of plants as a reference sce-nario. A multi-regional, recursive dynamic computable general equilibrium model based onVersion 8.1 of the Global Trade Analysis Project database is constructed. The simulation re-sults indicate that an immediate nuclear shutdown increases CO2 emissions through an in-crease in fossil fuel electricity generation and decreases real GDP losses in Japan. From a sec-toral view, an immediate nuclear power shutdown has a negative impact on Japan's energy in-tensive and trade-exposed sectors. In addition, we find that an immediate nuclear shutdownhas a negative after-effect on the economy. This is caused by shrinking investment spendingduring the immediate nuclear power shutdown. Overall, we find that the Japanese economywould face significant economic and environmental impacts from an immediate nuclear powershutdown. However, our model does not incorporate potential negative costs associated withnuclear usage, such as the risk of a nuclear accident or the cost of final disposal sites for nucle-ar waste, which may be sizeable. To derive conclusions for Japanese energy policy, we mustconsider the potential negative costs of nuclear usage. The results of this simulation study rep-resent the first step in answering key questions on energy policy."

"This study assesses the environmental and economic impacts of the immediate shutdownof all Japan's nuclear reactor fieet. For the assessment, we regard a gradual nuclear powerphase-out scenario as the basis for a 40-year operational time limit of plants as a reference sce-nario, A multi-regional, recursive dynamic computable general equilibrium model based onVersion 841 of the Global Trade Analysis Project database is constructed. The simulation re-sults indicate that an immediate nuclear shutdown increases CO2 emissions through an in-crease in fossil fuel electricity generation and decreases real GDP losses in Japan. From a sec-toral view, an immediate nuclear power shutdown has a negative impact on Japan's energy in-tensive and trade-exposed sectors. In addition, we find that an immediate nuclear shutdownhas a negative after-effect on the economy. This is caused by shrinking investment spendingduring the immediate nuclear power shutdown. Overall, we find that the Japanese economywould face significant economic and environmental impacts from an immediate nuclear powershutdown. However, our model does not incorporate potential negative costs associated withnuclear usage, such as the risk of a nuclear accident or the cost of final disposal sites for nucle-ar waste, which may be sizeable. To derive conclusions for Japanese energy policy, we mustconsider the potential negative costs of nuclear usage. The results of this simulation study rep-resent the first step in answering key questions on energy policy."

"In future the UK's energy supplies, for both heat and power, will come from much more diverse sources. In many cases this will mean local energy projects serving a local community or even a single house. What technologies are available? Where and at what scale can they be used? How can they work effectively with our existing energy networks? This book explores these power and heat sources, explains the characteristics of each and examines how they can be used."

"Sistem distribusi listrik adalah suatu sistem yang menunjukkan penyaluran energi listrik dari pusat distribusi ke konsumen melalui jaringan distribusi. Jaringan distribusi mengandung resistansi dan reaktansi yang bervariasi sehingga mengakibatkan terjadi losses (kehilangan energi listrik) pada jaringan tersebut. Pada jaringan distribusi juga akan dilihat kehandalan sistemnya dalam menyalurkan energi listrik ke konsumen ketika terjadi gangguan di jaringan tersebut. Kehandalan sistem adalah kemampuan sistem untuk melakukan fungsinya dalam menyalurkan energi listrik. Pada proses penyaluran energi listrik ke konsumen diharapkan dapat memberikan sistem yang lebih handal dan jumlah losses sekecil mungkin. Salah satu cara untuk menangani masalah penyaluran energi listrik dari pusat distribusi ke konsumen dengan losses minimum dan kehandalan sistem yang baik adalah dengan membangun Distributed Generation (DG). DG didefinisikan sebagai pembangkit kecil berkapasitas beberapa kilowatt sampai 50 MW yang diletakkan pada sisi konsumen. Pemasangan DG akan memberikan hasil optimal jika DG dengan kapasitas tertentu dipasang di lokasi yang tepat. Permasalahan penentuan kapasitas dan lokasi DG disebut dengan Distributed Generation Allocation (DG Allocation). Pada skripsi ini, masalah DG allocation akan diselesaikan dengan menggunakan pemrograman dinamik untuk menentukan kapasitas dan lokasi optimal DG dengan losses yang minimum atau meningkatnya kehandalan sistem.

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An electricity distribution system is a system that shows the distribution of electrical energy from the distribution center to customers through a distribution network. A distribution network contain various resistance and reactance so that losses (lost of electrical energy) is resulted in the network. In distribution network will also be seen its system reliability within distributing electrical energy to consumers when there is happened a fault. System reliability is capability of system for doing its function in distributing electrical energy. The process of distribution of electrical energy to consumers is expected to provide a more reliable system and the amount of losses as small as possible. Both of them are important to be noted because most of consumers in distribution system are spread.

One way to overcome problem of distribution of electrical energy from the distribution center to customers with minimum losses and good system reliability is to build a Distributed Generation (DG). DG is defined as generation from a few kilowatts up to 50 MW which is placed on the costumer side. The installation of DG will provide optimal results if the DG with a certain capacity installed in the proper location. The determination of the capacity and location of DG is called Distributed Generation Allocation (DG Allocation). In this mini thesis, the problem will be solved by using dynamic programming to determine capacity and location of DG that produce lowest losses and highest system reliability."

"Summary:This work aims to dispel anti-urban prejudices and policies by proposing new, residential and mixed-use development clusters that are designed as pedestrian zones, richly landscaped and accessible by shuttles and loops to peripheral parking. It features case studies from Asia, Europe and the USA"

"Contents :- Chapter One Executive Summary - Chapter Two Introduction to Application Service Providers - Chapter Three ASP Market Status - Chapter Four Technologies and Architectures for ASPs - Chapter Five ASP Vendors, Services,and Case Studies - Chapter Six Profiles of ASP Companies - Chapter Seven Strategies for Success - Chapter Eight Final Analysis and Conclusions - Appendix A Survey on ASPs and Its Results - Appendix B:Sources of Information on ASPs - Appendix C:Acronym Guide - Appendix D:Glossary - Appendix E:Selected Bibliography "