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Managing data Resources:

Managing data Resources: . An information system provides users with timely, accurate, and relevant information. The information is stored in computer files. When files are properly arranged and maintained, users can easily access and retrieve the information when they need.

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Managing data Resources:

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  1. Managing data Resources: • An information system provides users with timely, accurate, and relevant information. • The information is stored in computer files. • When files are properly arranged and maintained, users can easily access and retrieve the information when they need. • If the files are not properly managed, they can lead to chaos in information processing. • Even if the hardware and software are excellent, the information system can be very inefficient because of poor file management.

  2. File Organization Terms and Concepts • A computer system organizes data in a hierarchy that starts with the bit. • Bit represents 0 or 1. • 8 bits are grouped to form a byte. Each byte represents one character, number , or symbol. • Bytes can be grouped to form a field. It can represents a person’s name or age. • Related fields can be grouped to form a record. Related fields can be student’s name, course taken and the grade. • Related records can be grouped to form a file. • Related files can be grouped to form a database

  3. The Data Hierarchy Course File Financial File Database Student database Personal History File Cynthia Lokker CIS 500 A Daniel Boles IST 203 B File attribute NAME COURSE GRADE Record Cynthia Lokker CIS 500 A Field Cynthia Lokker (NAME field) Byte 01000001 (letter A in ASCII) 0 or 1 Bit

  4. Key field NAME STUDENT # COURSE GRADE Cynthia Lokker 959010054 CIS 500 A Daniel Boles 969010055 IST 203 B More File Organization Terms Key field Every record in a file should contain at least one field that uniquely identifies that record so that the record can be retrieved, updated, or sorted. This identifier field is called a key field. Entity A person, place, thing, or event on which we maintain information.

  5. Accessing Records from Computer Files • Computer stores files on secondary storage devices. • Records can be arranged in several ways on storage media. • How individual record scan be accessed or retrieved depends on how they are arranged on storage media. • There are mainly two ways to organize records: sequentially or randomly. • In sequential file organization, data records must be retrieved in the same physical sequence in which they are stored. • In direct or random file organization, data records can be accessed in any sequence as users desire, without regard to actual physical order on the storage media. • Sequential file organization is the only file organization that can be used on magnetic tape. Example: Payroll • Direct or random file organization is utilized with magnetic disk. • Most computer applications utilize this method.

  6. Problems of the Traditional File Environment • Data redundancy is the presence of duplicate data in multiple data files. • In this situation confusion results because the data can have different meanings in different files. • Program-data dependence is the tight relationship between data stored in files and the specific programs required to update and maintain those files. This dependency is very inefficient, resulting in the need to make changes in many programs when a common piece of data (such as zip code) changes. • Lack of flexibility refers to the fact that it is very difficult to create new reports from the data when needed. Ad hoc reports are impossible; a new report could require several weeks of work by more than one programmer and the creation of intermediate files to combine data from disparate files. • Poor security is a problem resulting from the lack of control over the data because it is widespread and distributed into so many files.

  7. Database and Database Management System • Database => A database is a collection of data organized to service many applications efficiently by centralizing the data and minimizing redundant data. • Database management System => A database management system is a special software that permits an organization to centralize data, manage it efficiently, and provide access to the stored data by application programs.

  8. The Components of a DBMS • The data definition language which is the formal language used by programmer to specify the content and structure of the database. • The data manipulation language, which is used to manipulate the data in database. It contains commands that permit end-users and programming specialists to extract data from the database to satisfy information requests and develop applications. • The data dictionary, which is an automated or manual file that stores definitions of data elements and data characteristics such as usage, physical representation, ownership and security.

  9. Logical and Physical View of Data • A logical view of data is the way data is perceived by end users or business specialists. • A physical view of data is the way the data are actually organized and structured on physical storage media.

  10. Advantages of a DBMS • Complexity of the information system environment can be reduced. • Data redundancy and inconsistency can be reduced. • Data confusion can be eliminated. • Program-data dependency can be reduced. • Program development and maintenance costs can be reduced. • Flexibility of IS can be enhanced. • Access and availability of information system can be increased.

  11. Database Models • Three principal database models are: • Hierarchical database model • Network data model • Relational database model

  12. Hierarchical Database Model • The hierarchical database model stores data logically in a vertical hierarchy resembling a tree-like structure. • An upper record is connected logically to a lower record in a parent-child relationship. • A parent segment can have more than one child but a child can only have one parent. • This model is good for treating one-to-many relationships. • They can store large numbers of segments and process efficiently, but they can only deliver information if a request follows the linkages of the hierarchy. • The disadvantages are their low user-friendliness, inflexibility, and complexity of programming . • Advantages: They are good for high volume rapid response systems, such as airline reservation systems.

  13. Network Database Model • The network model stores data logically in a structure that permits many-to-many relationships. • Through extensive use of pointers, child segment can have more than one parent. • Network DBMS reduce redundancy and they process information efficiently. • However, they are inflexible and very complex to maintain and program.

  14. Relational Database Model • The relational model overcomes many of the limitations of the previous models. • Data are organized into two-dimensional tables, each of which can be considered a file. • The relational model can relate any piece of information in one file to any piece in another file as long as the two tables share a common data element. • For this reason, they are very flexible. • Access paths to data are not predefined, so that they can easily respond to ad-hoc queries with less programming. • The main problem with RDBMS is poor processing efficiency. Response time can be very slow if large number of accesses are required to select, join, and extract data from tables.

  15. Normalization • Normalization is used to streamline the database design by removing redundant data, such as repeating groups. • A database that is not normalized will have inefficient queries and will delete information when it should not or update only part of the information.

  16. Distributed Database • A distributed database is partitioned, or distributed among more than one physical locations. • Parts of the database are stored in one location and other parts are stored and maintained in other locations. • One main central database can be partitioned into multiple local databases. • These databases can be updated locally and later justified with the central database. • Alternately, the central database can be duplicated at various remote locations. • Another possibility is to maintain a central index and have complete records stored at local levels

  17. Distributed Data Processing • Distributed data processing means using microcomputers, minicomputers and small mainframes at remote locations to process information in a central database rather than relying on a central mainframe. • However, unless the database itself is distributed, the data are still stored in one central location.

  18. Object-Oriented, Hypermedia, and Multidimensional Databases • Traditional databases store only homogeneous data that can be easily structured into predefined data fields and records. They are not well suited for handling other types of data such as procedures or graphics. • Object-oriented databases store data and procedures together as objects. • Hypermedia databases store chunks of data in linked nodes. These nodes can contain text, graphics, sound, full-motion video, or executable computer programs. These databases are less structured than traditional DBMS and contain a wider array of data.

  19. OLAP and Multidimensional data Analysis • On-line analytical processing and multidimensional data analysis allow the analysis of large volumes of data from many perspectives. • For example, sales by item by department by store by region, in order to find patterns in the data. • Such patterns are difficult to find with normal database methods.

  20. Data Warehouse • A data warehouse is a read-only analytical database that is used as the foundation of a decision support system. • It is subject-oriented, integrated, nonvolatile, and time-variant • Subject-oriented=> It is organized around the major subjects of the enterprise while operational world is designed around applications, functions, and process. • Integrated=> Data from different sources is stored in data warehouse in a single, easy to understand, globally accepted fashion. • Non-volatile=>Generally , updating is not done in data warehouse environment; update is done in operational environment. • Time-variant=> It is a time variant collection of data. Time variant means that every unit of data in the warehouse is relevant to some moment of time.

  21. Successful Database Environment • Data administration=> the policies, procedures, and tools for managing and planning for information as a corporate source. • A data planning and modeling methodology from an enterprise-wide perspective. • Users=> end users have a wide role with DBMS than in traditional systems and they must be trained. • Database technology and management=> DBMS software maintained by firm’s database administration group.

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