Application of GIS Technology in Electrical Distribution

Application of GIS Technology in Electrical Distribution ABSTRACT Electric utilities have a need to keep a comprehensive and accurate inventory of their physical assets, both as a part of normal service provision (extending the network, undertaking maintenance, etc.) and as a part of their obligation to inform third parties about their facilities. Complexity of electrical distribution power system is a good reason for introducing new information technology GIS (Geographic Information System) that carries out complex power system analyses (e.g., fault analysis, optimization of networks, load forecasting) in acceptable amount of time. By using modern GIS, in conjunction with his own in-house developed software, in less time and more accurately, the utility engineer is able to design and to analyze electrical distribution network. This paper presents the idea of the project CADDiN © (Computer Aided Design of Distribution Network) currently under development at the Power Systems Department of the Faculty of Electrical Engineering, University of Zagr eb. INTRODUCTION Importance of Distribution Network in Energy Supply One of the primary contribution to the advancements and improvements in mans life-style over the years has been the ability to use and control energy. Mans use of energy can be seen in everyday operations such as mechanical motion and the production of heat and light. Large amounts of power are generated at power plants and sent to a network of high-voltage (400, 220 or 110 kV) transmission lines. These transmission lines supply power to medium voltage (e.g. 10 or 20 kV) distribution networks (distribution primary system), which supply power to still lower voltage (0.4 kV) distribution networks (distribution secondary system). Both distribution network lines supply power to customers directly. Thus, the total network is a complex grid of interconnected lines. This network has the function of transmitting power from the points of generation to the points of consumption. The distribution system is particularly important to an electrical utility for two reasons: its proximity to the ultimate customer and its high investment cost. The objective of distribution system planning is to ensure that the growing demand for electricity, with growing rates and high load densities, can be satisfied in an optimum way, mainly to achieve minimum of total cost of the distribution system expansion. Therefore, the distribution system planner partitions the total distribution system planning problem into a set of subproblems that can be handled by using available, usually heuristic methods and techniques [T.Gonen, 1986]. The design of electrical distribution networks is an everyday task for electric utility engineers, specially in RD department. Such design was carried out few years ago manually. This classical approach usually result in overdesign distribution system, which is now considered as a waste of capacity that can be used instead of investing in system expansion. Four years ago a PC program package (CADDiN ©) for optimal planning of distribution network was put in operation in Elektra Zagreb (Electric Utility of City of Zagreb). It is a result of joint RD of Power System Department of Faculty of Electrical Engineering and Elektra Zagreb. Based on the experience or PC-CADDiN ©, at the end or 1992. the prototype of new project CADDiN © was started conceptually organized as a part of the Geographic Information System. The role of GIS in Distribution Networks Database plays a central role in the operation of planning, where analysis programs form a part of the system supported by a database management system which stores, retrieves, and modifies various data on the distribution systems. The thing that distinguishes an electrical utility information system from an other information system such as those used in banking, stock control, or payroll systems is needed to record geographical information in the database. Electrical utility companies need two types of geographical information: details on the location of facilities, and information on the spatial interrelations between them. The integration of geographically referenced database, analytical tools and in-house developed software tools will allow the system to be designed more economically and to be operated much closer to its limits resulting in more efficient, low-cost power distribution systems. Additional benefits such as improved material management, inventory control, preventiv e maintenance and system performance can be accomplished in a systematic and cost-effective manner (Z.Sumic, et al, 1993). Before graphical workstations were developed, many electric utilities have built technical information systems based on relational database management systems (E.Jorum, et al, 1993.). Technical information system is designed to cover the requirements of power supply utilities considering network expansion and operation planning, maintenance management and system documentation. In advanced utilities all information systems are built around same RDBMS and constantly updated. Establishing links between these information systems and geographical information system is only in defining relationship between objects in the two systems. The problem that has risen is in a number of different information systems in the same utility (technical information system, customer information system, etc.) or even several overlapping technical information systems and some of these a re not updated. Objective The objective of the distribution network design process can be divided into three independent parts. These parts are: Load forecasting load growth of the geographical area served by substation; determination of load magnitude and its geographic location; customer load characteristics; Design of secondary system (low voltage distribution network) optimal substation allocation and transformer sizing; secondary circuitry routing and sizing; Design of primary system (medium voltage distribution network) optimal substation allocation; primary circuitry routing and sizing; To reduce a problem complexity each part of the design process is divided in functional subproblems. Each of these subproblems can be then much easier to manage. Although only independent some parts of design process interact, i.e. placement of substation will influence secondary routing which in turn will influence primary routing. The number of possible design solutions that might satisfy a given set of spatial, technical and economic constraints is quite numerous. Multiple, interdependent goals and constraints make conventional procedural optimization methods inappropriate for distribution network design. Due to the complexity of the design process, heuristic methods and AI techniques must be applied to find near optimal [S.Krajcar, 1988] or satisfying solutions [Z.Sumic, 1993]. The main reason for this simplification is regarding work-force and computer time for finding optimal solution that in high percentage could not be applicable in real situation. [End Page 1858] GENERAL DESCRIPTION OF GEOGRAPHIC INFORMATION SYSTEM OF PROJECT CADDIN Pilot-project CADDiN was started at the beginning of 1993 as a research project inside the main research project Research and Development of Electric Power System supported by the Ministry of Science and Technology of the Republic of Croatia. The development of optimization and design procedures of electric distribution network is a parallel process with building database by Cadastral Office of the City of Zagreb, and therefore some other available examples of basic map databases are used for research purposes (see Figure 1). The strategy employed emphasized only the data composed of basic map databases for technical applications (scales of 1:500 to 1:5000). There is no unique definition for Geographic Information System (GIS) but a commonly accepted one is that it is a system with computer hardware and software functions for the spatial data input, storage, analysis, and output [T. Bernhardsen 1992]. Many textbook definitions go further and identify analysis as the one activity which differentiates GIS from other computer-based systems for handling geographic data, such as automated cartography. Modern GIS, stores information on the geometry, attributes and topology of geographic features in one relational database management system. SYSTEM 9 used in the pilot-project CADDiN is a feature-oriented GIS which organizes geography-related information into a topology-structured, object-oriented, relational database system. A project is the highest level of data organization of GIS used in CADDiN [Computervision, 1992]. It represents the entire database that has been set up for a particular geographic area for example, a town, a municipality, or a service district. It comprises two components: a data store that contains all the geographic and attribute data relating to features; and a database definition that specifies the structure of the project through feature classes and themes. Theme definition determines which features and attributes are to be used and the ways in which are to be displayed. Independently stored geometry of a feature, and its graphic representation enables position and representational data to be changed without reference to each other. The link between the geometry and the representation is provided by the theme. It comprises a list of feature classes, feature class attributes, and a link to a separate list of graphic transforms. An important safety aspect of used GIS is that it does not allow users to make changes to the database at project level. A user may only query it. The database is created and updated by means of the next lower level of data structure: the partition. This is a copied, working subset, or portion of a project. It is at this level that a user interacts with the system to enter, edit, update and manipulate data. Partitions are extracted from a project based on the type of work to be done and the data that will be required to perform that work. When editing is completed, the partition is merged into the project database, effecting the update. Partitions are created by means of a partition definition that describes the spatial extent, the contents, and the representation. The system uses the partition definition to extract the required geometric and attribute data and then allocates them into the required partition. The merit of the partition structure is that it allows different department s within an organization to work safely on the data from the same project. All geometric features in the data model are built up from geometric primitives, referred to as nodes, lines, surfaces and spaghetti. A node is stored as a set of X, Y, and optionally Z coordinates in 3D database, and might be used to represent e.g. transformers, switchgears, MV LV buses, etc. A line primitive is a geometric element defined by two end-nodes (allowing intermediate points), and might be used to describe transmission lines, cables, etc. A surface consists of one or more line segments that together form a closed polygon. A forest, lakes, parks, a portion of network, or area covered by a lot of buildings could be described by this kind of polygon. Spaghetti enables to model features where no topological structure is required. Nodes are the only geometric primitives that have coordinate information directly associated with them. Lines are not defined in terms of geographic coordinates, but by pointers to their topological nodes. Surfaces are defined by pointers to the lin es surrounding the surface. All these pointers are created and maintained automatically. Geographic objects are stored as collections of nodes, lines, surfaces or spaghetti, but they can be referred to as geometric primitives as well as some group of objects which can be identified and named in the real world roads. cables, transformers, buildings, and so on. These categories are represented by `feature classes, and the individual instances of geographic objects as `features. Such features at last consist of one or more geometric primitives. All features within a particular feature class will have the same topological structure, and the same set of attributes. Feature classes could be also identified as objects in groupings of related objects that may be established on the basis of location, spatial relationships or common attributes. These logical groupings of features are called complex features. They are defined as features that contain other features. All complex features of particular type, comprise a complex feature class. A useful application of complex feature classification would be in forming logical groupings such as MV bus, transformer, LV bus, protection devices into substation. Complex features can also have attributes associated with them (for example name, number). It would eliminate duplicating of feature attributes which properly relate to the substation. Definition of complex feature is not restricted to include only simple features as constituent components. For example, distribution network could be defined as a complex feature containing a number of substations, cables, which are themselves complex features. A strength of this approach is that it can be used to minimize the level of data redundancy of both attribute and geometric information. Users interact with the database via an object handler, and they are assisted in that interaction by a structured query language that incorporates extended spatial and reference operators. Behind analytical tools available inside GIS environment, a set of standalone functions is available from UNIX shell. This set of functions is called Application Tool Box (ATB). ATB offers an environment in which data can be managed directly, without first having to extract meaning from map representations of those data. Under this approach a user can develop analytical models according to specific requirements by integration of ATB functions, in-house developed software (C and FORTRAN programs) and shell programming. To speed up complex analysis by Development Libraries of ATB new processing functions of ATB could be developed. Applications of project CADDiN are developing by ATB functions in conjunction with C and Corn shell programs. ATB data management and viewing comprise processing functions, dataflow management and graphics viewing system. Processing functions perform the actual analysis operations on sets of data called data flows, each of which corresponds to a relational table in the database. All manipulation of data flows takes place in a special temporary work area called a clipboard. Processing functions involve the following operations: information management (i.e. selecting information from database and placing it into a dataflow, communicating with external software packages), attribute processing (i.e. generating values for attributes based on classification rules or formula), geometry processing (spatial functions union, adjacent, etc.) and arithmetic processing (i.e. calculating the area of surface entities, or length of linear entities). Dataflow management is used to create, display and delete data flows and views. Graphic viewing system allows user to see the intermediate or final results and generate a plot of those results. Compatible to ATB functions are standalone functions of Network Trace Analysis module. By those functions network tracing can be carried out using the information on network connectivity and component characteristics that are already stored in database. Special function is used for network generation that is stored as dataflow on the clipboard. On this dataflow several networks tracing functions can be performed (path optimization, range finding, path finding) or can be used by external software. As a result of that analysis a dataflow is produced on the clipboard. Original and resultant networks can be queried simultaneously. The user can keep or delete resulting data flow on the clipboard or retrieved in database. OPTIMIZATION OF DISTRIBUTION NETWORKS IN GIS Optimal Location of TS x/0.4 kV in Secondary Distribution Network The procedure for finding optimal configuration of secondary system consists of two possible optimization steps: optimization of new area secondary system and optimal connection of the particular customer(s) to existing secondary system. Regarding urbanistic plans, ecological and esthetic constraints as well as previous load growth analyses possible locations of substations are known in advance. These assumptions make planning of secondary system more simple because only routing process must be applied for several locations of substations and fixed locations of customers. The first step of routing process begins by connecting customer to the nearest routing corridor. After that procedure, the secondary system network is generated by network module. On this network any path analysis is applied and as results of analysis there are all possible connections between substation and customers. These results are used as input for external, CADDiN module of optimization of radial structured networks. During this process of optimization the set of rules is used to satisfy standard practices employed by designers. The optimized network is then saved on clipboard in dataflow and can be graphically viewed. The cost for the secondary system is mainly the capital investment cost consisting of cable laying cost and cost of cables. For each location of substation optimization process must be repeated. Solution with minimal investment costs and satisfactory technical constraints is the best regarding secondary network. All solutions that are technically satisfied must be taken into account during the primary network optimization. It is necessary because the local optimum of secondary system does not imply the optimum of primary system, and global optimum of distribution network. The optimal connection of the particular customer to existing secondary system must fulfill next two technical as well as economical constraints: the shortest possible length of connection due to voltage drop that may be permitted; reserve in load capacity of substation due to customer load. The new customer must be connected to the nearest neighbor customer satisfying previously mentioned constraints. The few nearest customers are found in a buffer zone with new customer as a center of this zone. The shortest path between new customer and possible connection node is found in two steps: both nodes are connected to the nearest routing corridor, and after that by GIS network function find best path analysis shortest path between nodes is found. Optimal Structuring of Predefined Primary Distribution Network Configuration Due to the load characteristics, requested availability and quality of energy supply two main configurations of secondary system are used in optimal planning There is a ring structure (starting and ending node is the same HV/MV substation and routing nodes are MV/LV substations) and a link structure (starting node is one HV/MV substation routing nodes are MV/LV substations and ending node is other HV/MV substation). Regarding the usage of GIS technology the optimization procedure of these two network configurations is very similar. In optimization process three different problems are considered: optimization of the new primary system; reconfiguration of the existing primary system regarding predefined structure, and reinforcement of the existing primary system with defined structure by installing additional capacity in demand nodes or including the new MV/LV substation in the network. The first problem is similar to the problems in optimization of secondary system. There must be known all possible connections and distances between HV/LV substation (source node) and MV/LV substations (demand nodes) as well as themselves. Therefore, all network nodes must be connected to the nearest routing corridor. By any path analysis and heuristic algorithms (presently genetic algorithms are tested) initial solution or zero-iteration is generated. After that by the union of GIS network function find best path analysis and other heuristic methods optimal solution is found. The second problem is more complicated than the first one because existing connections in network must be considered in optimization procedure. Otherwise, same procedures are used as in the first problem. Example of this optimization procedure can be shown in the Figure 3. In the third problem, optimization procedure is similar to the procedure of adding the new customer to the second system. Slight differences are in a way of connecting new substation to the existing network. In the primary system, regarding the constraint of reliability of supply of energy to the customer, each MV/LV substation must have a possibility to be supplied from two sides. Therefore, the nearest existing cable between two substations must be found for the connection of the new station, or the nearest routing corridor by which the new station could be connected to the nearest substations that are found in a buffer zone around it. When a better type of connection is found, solution is tested on several technical constraints (voltage drop, cable and route load, investment costs, etc.). Load forecasting of TS x/0.4 kV Small area or spatial, forecasting is the prediction of both the amounts and locations of future electric load growth in a manner suitable for distribution planning which really means with geographic resolution adequate for planning a new distribution network or extensions to the existing one. The procedure is based on dividing a utility service area into a number of sufficiently small areas and projecting the future load in each one. This is usually accomplished by dividing a utility service area into either a grid of uniformly sized rectangular cells, or into equipment oriented areas corresponding to feeder or substation areas (H.L. Willis, 1983,1992). Methods for computerized small area load forecasting, regarding their data requirements and analysis methods, fall into three categories: trending multivariate (multivariable) simulation. Essentially these methods analyze past and present load growth to identify trends, patterns, or information about the process of load growth that is then used to project future load growth. Trending methods require minimal data (they work only with historical load data, usually annual peak load) and computer resources, and are relatively straightforward in use. Because of their simplicity and generally the lowest expenses, they were the most widely used techniques in the past. Multivariate methods require considerably more data (historical loads, geographic and demographic data on customers and usage) and much more extensive computer resources, but in return they generally provide more accurate forecasts. Simulation methods in addition to historical loads require extensive and comprehensive data that include land use type, geographic and demographic data on a small area basis, transportation and other diverse factors that may affect load growth. They also require considerable computer resources and work-force. On the other hand they offer advantages in accuracy and analysis of load growth under changing conditions. Because of their complexity and requirements simulation models have been beyond the scope of many electric utilities. So far one can see that the nature of small area forecasting requires heavy use of computerized analyses and manipulation of large quantity of data. With its possibilities GIS is an excellent mean for developing and applying simulation forecast models. Of course, there is no limitation to use GIS for trending methods, at least for some very fast qualitative review, or for short range (less than five years ahead) predictions. A service zone of a substation may be defined as a complex feature which comprises parcels, buildings on those parcels, electrical connections for every building or customer, existing interconnections between customers hookups and associated substation etc. Parcels, buildings and streets are modeled as polygons, and cadastral lot code is attached to them as one of the attributes. Statistical and census districts based on approximately equal number of inhabitants and cadastral districts are polygons, too. Second very important information is address, modeled as complex feature class comprising a street name and number. Polygonal analysis and polygon processing, which is possible in GIS, and address as a common link enables the planner to determine a substation service zone and calculate its area. Via features attributes all necessary customers data (annual electricity consumption, annual peak loads, type of customers, some special requests and interfering factors, etc.) are obtainable . In that way it is possible to track amounts and sort of energy used by individual customer, or substation service area or some other region. Upon these information load densities (kWh/m ²) or kWh sales per customer can be computed. Procedure with built-in clustering algorithm detects groups (classes, clusters) of customers with similar past energy consumption behavior. For distribution load forecasting K-means algorithm [Hartigan, 1986] is recommended, with a minimum of 6-year load history [H.L. Willis, 1983]. The K-means algorithm searches for a partition, that is, a set of clusters that minimizes the total difference between small areas and their assigned clusters (the error of the partition). It works by moving small areas from one cluster to another. The search ends when no such movements of small areas reduce the error value. CONCLUSION This paper presents the concept of the pilot project CADDiN for optimization of electric distribution networks based on GIS technology. The architecture of CADDiN consists of the heuristic methods implemented within GIS and procedural programs. In such a hybrid environment, the GIS principal task is to model real world, perform spatial analyses and ensure the high accuracy of optimization procedures. The first results obtained by the prototype database and developed procedures encourage that concepts and ideas established in this paper can be applied on the real problems that exist in the distribution system planning.

Coping with Change in My Kinsman, Major Molineux :: Kinsman Molineux

Coping with Change in My Kinsman, Major Molineux My Kinsman, Major Molineux is about Robin a young and sheltered youth. This story opens with Robin trying to find his kinsman Major Molineux. He approaches many people trying to find his kinsman. Of all the people he approaches none are helpful in locating his kinsman. Finally he gets an answer and finds his kinsman to have been tarred and feathered. This is a shock to him, however, he deals with that surprise and goes on with his life. This story is about change and coping with the fact that change is inevitable. The first man, that Robin asks about his kinsman, was gruff and unhelpful. Even though Robin asked the whereabouts of his kinsman in a polite way "Good evening to you honored sir, I pray you tell me whereabouts is the dwelling of my kinsman..." He received no answer from this man. Later in the story he meets with the same man again. At the second meeting Robin asserted himself differently and received an answer from the man. This time he was more confident "No, no, neighbor! No, no I am not the fool you take me for, nor do you pass till I have an answer to my question." This transformation in Robin shows that experience breeds change and that change is inevitable. This change in Robin can be paralleled to societies and governments. Drawing from change any sentient structure can learn that new measures are required in order to succeed. When Robin found his kinsman it was under less than desirable circumstances. Robin was in severe shock; "His knees shook and his hair bristled with a mixture of pity and terror." The crowd that followed his kinsman was overwhelming when it grasped Robin into it's clutches his shouts of laughter where the loudest there. This illustrates that each generation must make up its own mind on protocol for handling the situations that come its way. Each government and society must make new policies and rules for the unexpected situations that occur. Also the physical similarities between Robin and his kinsman show that change does not have to be a completely new beginning, but a "younger" way of looking at the world for that day's society, government or individual. At the very end Robin was getting ready to leave for his home in the country.

The Outbreak of the HIV Virus, AIDS in 1980s

Who would have ever thought that a disease, possibly brought to America by infected African monkeys, would affect the country forever? This is exactly what happened in the late nineteenth century when the Acquired Immune Deficiency Syndrome (AIDS) was introduced to America. The unpredictable epidemic caused a huge outrage for years to come. The outbreak of the HIV virus, AIDS, in the early 1980†³s resulted in medical research, public misconceptions, and ultimately growing awareness. Appearing first only in homosexual men, AIDS was an unfamiliar virus to the entire United States. Reports of unknown and unexplainable symptoms caused much confusion among patients and even doctors. In 1981, the first reports explained that 41 homosexual men in the San Fransisco area had â€Å"†¦ a rare and often rapidly fatal form of cancer† (Altman n. p. ). After years of researching these cases and millions of others appearing later in the decade, scientists discovered that it was not cancer they were dealing with. They called it HIV (Human Immune Virus) which leads to AIDS (Acquired Immune deficiency Syndrome) that â€Å"†¦ rogressively destroys the body†s ability to fight infections and certain cancers† (ARIC n. p. ). With minimal research there was nothing to initially â€Å"combat† the virus; but, thanks to time and funding, there were some drugs that seemed to help stop the spread of the virus in ones body. These anti-retroviral drugs still don't constitute as cures ! for the virus, but have definitely helped and continue to help patients live longer (ARIC n. p. ). Since a vaccine to â€Å"†¦ evoke an immune system response that will prevent infection or disease development† still has not been found, other treatments have been tested. Accupuncture, stress management, hypnosis, exercise, good nutrition, and an overall positive attitude all seem to alleviate symptoms even if they are not proven cures of the virus (Packer 78-88). Although AIDS is a life threatening disease, there were many people living with it by keeping healthy and staying safe. Scott Fried had not tried any of the aniviral drugs; however, practices such as taking 80 herbs and vitamins a day, staying physically fit, visiting the doctor every three months, and being happy have kept him alive with the virus for thirteen years (Fried speach). Most victims have not lived as long as he which is why AIDS has lead to some extensive research. Investigators supported by private and public funds continued to search for a cure or even an explanation of HIV/AIDS for two decades because like the â€Å"b! lack plague†, AIDS has killed off millions of people in a short time. Also like the black plague did, AIDS carried with it a long string of misconceptions. In the Middle Ages anyone carrying the â€Å"black plague† was to be avoided. Similarly, the public would often avoid people with AIDS. There were fabrications that AIDS could be caught by another human being from sneezing, coughing, hugging, kissing or even any â€Å"casual contact† ; so, people stayed away from those who were infected by AIDS. Another lie was that AIDS was caused by something magical or mystical (Taylor 23-24). Though some were overly careful of â€Å"catching† the virus, others were not careful enough. Since the initial outbreak was among gay men it was simply assumed that only gay men could be affected. Then reports of IV drug users having the disease still seemed to eliminate the chance of the common person being infected. Next, hemophiliacs and people who had had blood transfusions were reported followed by blacks, Hispanics, lesbians, straight women and finally white, heterosexual, males. Still everyone said â€Å"It can†t happen to me,† until it did (Fried speech). This assumption that AIDS only affected few amounts of people and only minorities was the basis of all misconceptions about that virus. People did not believe the virus could have any impact on their lives; but, it did impact everyones lives directly and or indirectly. Now that â€Å"AIDS is the second leading cause of death in the United States among people aged 25 to 44†³ (ARIC n. p. ), the misconceptions have been proven to be false. Although it was statistically correct that 66% of people infected by AIDS were homosexual males, 24% were IV drug users, and only 4% were heterosexual males or females (Packer 17) it was still a fact that AIDS can affect anyone. After years of research and statistical reports there were finally people relaying these messages to the public. Motivational speakers, like Scott Fried, continue to reach out to teens and adults about AIDS and sex. Information about these subjects can also be found easily, not only at hospitals or doctors† offices; but in books, magazines, pamphlets, and even on the internet. Conducting a simple search on http://www. yahoo. com came up with 164 â€Å"category matches,† 1,206 â€Å"web site matches,† and 237,000 web page matches. This means that HIV/AIDS appears at least 238,370 times on th! e world wide web and it shows that AIDS in an important component of modern life. Not only are people becoming aware of the AIDS epidemic, but they are becoming aware of sexuality through learning about AIDS. Before the outbreak of this fatal virus sex was only spoken about discretely. Now even kids are being made aware of the dangers of sex and spreading HIV. In this way HIV/AIDS had a positive affect on the country. People are aware of the facts and probably make better decisions. Some experts have said that AIDS will remain the way it is now and others predict it growing into a â€Å"huge epidemic† (Taylor 28). Hopefully due to this expansion of knowledge and recognition, he AIDS virus will not spread as quickly and infect as many people as it has in the past. HIV positive, homosexual, male, Scott Fried, said, â€Å"Ironically one of the blessings that HIV/AIDS has brought me is the abundance of love. . . † and perhaps that is true. Pertaining to the eighties and the early onset of the virus, AIDS caused much more commotion than love. However, every cloud has a silver lining and the hysteria has finally cleared up some myths. It has opened up the public to not only HIV/AIDS awareness, but sexual cognizance as well.

Industrial Revolution Essay - 1623 Words

The most far-reaching, influential transformation of human culture since the advent of agriculture eight or ten thousand years ago, was the industrial revolution of eighteenth century Europe. The consequences of this revolution would change irrevocably human labor, consumption, family structure, social structure, and even the very soul and thoughts of the individual. This revolution involved more than technology; to be sure, there had been industrial quot;revolutionsquot; throughout European history and non-European history. In Europe, for instance, the twelfth and thirteenth centuries saw an explosion of technological knowledge and a consequent change in production and labor. However, the industrial revolution was more than†¦show more content†¦Another reason given for the Industrial Revolution is the substantial increase in the population of Europe; this is such an old chestnut of historians that we dont question it. Population growth, however, is a mysterious affair to ex plain; it most often occurs when standards of production rise. So whether the Industrial Revolution was started off by a rise in population, or whether the Industrial Revolution started a rise in population is hard to guess. Its clear, though, that the transition to an industrial, manufacturing economy required more people to labor at this manufacture. While the logic of a national economy founded centrally on the family economy and family production is more or less a subsistence economy-most production is oriented around keeping the family alive, the logic of a manufacturing economy is a surplus economy. In a manufacturing economy, a persons productive labor needs to produce more than they need to keep life going. This surplus production is what produces profits for the owners of the manufacture. This surplus economy not only makes population growth possible, it makes it desirable. England nbsp;nbsp;nbsp;nbsp;nbsp;While its hard to pinpoint a beginning to the Industrial Revolution, historians generally agree that it basically originated in England, both in a series of technological and social innovations. Historians propose a number of reasons. Among the most compelling is the exponential increase inShow MoreRelatedIndustrial Of The Industrial Revolution1666 Words   |  7 PagesMartinez English IV, 1st hour 4/29/16 The Industrial Revolution The Industrial Revolution set people away from farms and small villages and moved them to cities and towns because of the job opportunities that arose in the cities. The Industrial Revolution not only helped people move along in the late 1700s and early 1800s but also it has made the people what they are today. 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Their careers, living situations, location, values, and daily routines all changed, and they needed it desperatelyRead MoreThe Industrial Revolution1097 Words   |  5 PagesBefore the advent of the Industrial Revolution, most people resided in small, rural communities where their daily existences revolved around farming. Life for the average person was difficult, as incomes were meager, and malnourishment and disease were common. People produced the bulk of their own food, clothing, furniture and tools. Most manufacturing was done in homes or small, rural shops, using hand tools or simple machines. Did You Know? The word luddite refers to a person who is opposedRead MoreThe Industrial Revolution1090 Words   |  5 PagesShort Term Misery†¦ Long Term Gain There are two major industrializations that have occurred through out history, both which began in England. The Industrial Revolution was from 1750 until 1800. The first and second industrialization were filled with many inventions, new societal ideas, new raw materials, new sources of power, also new ideas and societal implements were made enabling the world and society to evolve. Overall these industrialization was filled with death, neglect, and disease but endedRead MoreThe Industrial Revolution936 Words   |  4 Pageseconomist Robert Emerson Lucas wrote in regards to the Industrial revolution: For the first time in history, the living standards of the masses of ordinary people have begun to undergo sustained growth. The novelty of the discovery that a human society has this potential for generating sustained improvement in the material aspects of the lives of all its members, not just the ruling elite, cannot be overstressed.† (Lucas 2002). The revolution itself was ce ntred in Britain before spreading to theRead MoreThe Industrial Revolution705 Words   |  3 PagesThe Industrial Revolution was the quintessence of capitalistic ideals; it bred controversy that led to Karl Marx’s idea of communism as a massive grass roots reaction to the revolution’s social abuses. Firstly, the Industrial Revolution featured the construction of machines, systems and factories that allowed goods to be manufactured at a faster rate with a lower cost. The seed drill made it so there could be â€Å"a semi-automated, controlled distribution and plantation of wheat seed†(Jones 2013). SecondlyRead MoreIndustrial Revolution1160 Words   |  5 Pagesend of the 19th century, a significant change took place in the fundamental structure of the economy. That change was industrialization. During this time period, the United States of America changed from a large, agricultural country, to an urban industrial society. The process of industrialization began to take place in America, and eventually took over the economy during this period. Entrepreneurs and inventors put together various machines and businesses to help better the country function on aRead MoreThe Industrial Revolution Essay2099 Words   |  9 PagesThe Industrial Revolution was one of the largest social and cultural movements that changed the methods of manufacturing of metal and textiles, the transportation system, economic policies and social structure as well. Before the Industrial Revolution, people used to live by season due to agriculture. They thrived on whatever food was in season. Now, as a result of the Industrial Revolution, we live regimented and almost everything that is made, is mass produced. I will discuss three major topics