Fall 2011 © 2011 REACH All Rights Reserved. This Test is closed book, closed notes, and closed Excel. However, you may use a pen/pencil, paper, and calculator. The Test is worth a total of 150 points. You will be given 75 minutes to complete the Test. This Test contains questions on: CIS Concepts and the MIS textbook (~60 points) ▪ 10-15 Multiple Choice, True/False, Fill-in-the-Blank ▪ 4-5 Short Answer/Essay MS Excel (~90 points) ▪ 3-5 Multiple Choice ▪ 7-10 Fill-in-the-Blank (with multiple parts) – interpreting and writing formulas ▪ See BB > Course Documents > Class Slides > CIS300-Sample-Test-3 for examples of Excel Questions Extra credit (6 points) ▪ 1-2 Questions of Any Format 2 • 150 points, 75 minutes • Paper Test, no Blackboard • Closed book, closed notes, closed Excel • CAN have a calculator • Arrive early because he’ll start the test early! • Answer the easy questions first • Answer all questions! The Professor gives partial credit on short answer! CIS Concepts, Databases and Data Management (~40%) Questions 1-15 Multiple Choice or True/False Questions 16-17: Short Essay MS Excel (~60%) Questions ??-??: Multiple Choice or True/False Questions ??-??: Fill-in-the-Blank (with multiple parts) Extra credit (9 points) Questions ??-??: Any mix of formats •Mathematical Functions • Statistical Functions • Information Functions • Lookup Functions • Date Functions • Time Functions • Text Functions • Database Functions SUMIF =SUMIF(range,criteria,[sum_range]) Syntax: =SUMIF(range, criteria, [sum_range]) Arguments: •range Required The range of cells that you want evaluated by criteria. oCells in each range must be numbers or names, arrays, or references that contain numbers. oBlank and text values are ignored. criteria Required The criteria in the form of a number, expression, a cell reference, text, or a function that defines which cells will be added. oCriteria can be expressed as 32, ">32", B5, "32", "apples", or TODAY(). •sum_range Optional The actual cells to add, if you want to add cells other than those specified in the range argument. oExcel adds the cells that are specified in the range argument (the same cells to which the criteria is applied). Microsoft® Excel® Mathematical Functions Description: •Sums the values in a range that meet criteria that you specify. Remarks: •See the Microsoft® Excel® help for additional remarks. Errors: None Microsoft® Excel® Mathematical Functions Microsoft® Excel® Mathematical Functions AVERAGEIF =AVERAGEIF(range,criteria,[average_range]) COUNTIF =COUNTIF(range, criteria) Syntax: =AVERAGEIF(range, criteria, [average_range]) Arguments: •range Required One or more cells to average, including numbers or names, arrays, or references that contain numbers. •criteria Required The criteria in the form of a number, expression, cell reference, or text that defines which cells are averaged. •average_range Optional The actual set of cells to average. Microsoft® Excel® Statistical Functions Description: •Returns the average (arithmetic mean) of all the cells in a range that meet a given criteria. Remarks: •If average_range is omitted, range is used. •Cells in range that contain TRUE or FALSE are ignored. •If a cell in average_range is an empty cell, AVERAGEIF ignores it. •If a cell in criteria is empty, AVERAGEIF treats it as a 0 value. Errors: #DIV/0 – If range is a blank or text value. #DIV/0 – If no cells in the range meet the criteria. Microsoft® Excel® Statistical Functions =AVERAGEIF(B2:B5,"<23000") Microsoft® Excel® Statistical Functions =AVERAGEIF(B2:B5,"<23000") =14000 Microsoft® Excel® Statistical Functions =AVERAGEIF(A2:A5,"<95000") Microsoft® Excel® Statistical Functions =AVERAGEIF(A2:A5,"<95000") =#DIV/0 Microsoft® Excel® Statistical Functions =AVERAGEIF(A2:A5,">250000",B2:B5) Microsoft® Excel® Statistical Functions =AVERAGEIF(A2:A5,">250000",B2:B5) =24500 Microsoft® Excel® Statistical Functions Syntax: =COUNTIF(range, criteria) Arguments: •range Required One or more cells to count, including numbers or names, arrays, or references that contain numbers. oBlank and text values are ignored. criteria Required A number, expression, cell reference, or text string that defines which cells will be counted. oCriteria can be expressed as 32, ">32", B4, "apples", or "32". Microsoft® Excel® Statistical Functions Description: •Counts the number of cells within a range that meet a single criterion that you specify. Remarks: •See the Microsoft® Excel® help for additional remarks. •Criteria are case insensitive Errors: None Microsoft® Excel® Statistical Functions Microsoft® Excel® Statistical Functions ISERR =ISERR(value) ISERROR =ISERROR(value) ISNA =ISNA(value) Syntax: =ISERR(value) Arguments: •value Required The value that you want tested Microsoft® Excel® Information Functions Description: •Returns TRUE if value refers to any error value except #N/A. Remarks: •The value arguments of the IS functions are not converted • Any numeric values that are enclosed in double quotation marks are treated as text. • The IS functions are useful in formulas for testing the outcome of a calculation Errors: None Microsoft® Excel® Information Functions Syntax: =ISERROR(value) Arguments: •value Required The value that you want tested Microsoft® Excel® Information Functions Description: •Returns TRUE if value refers to any error value: •#N/A #VALUE! #REF! •#NUM! #NAME? #NULL! #DIV/0! Remarks: •The value arguments of the IS functions are not converted • Any numeric values that are enclosed in double quotation marks are treated as text. • The IS functions are useful in formulas for testing the outcome of a calculation Errors: None Microsoft® Excel® Information Functions Syntax: =ISNA(value) Arguments: •value Required The value that you want tested Microsoft® Excel® Information Functions Description: •Returns TRUE if value refers to the #N/A (value not available) error value. Remarks: •The value arguments of the IS functions are not converted • Any numeric values that are enclosed in double quotation marks are treated as text. • The IS functions are useful in formulas for testing the outcome of a calculation Errors: None Microsoft® Excel® Information Functions Microsoft® Excel® Information Functions Microsoft® Excel® Information Functions VLOOKUP =VLOOKUP(lookup_value, table_array, col_index_num, [range_lookup]) Syntax: =VLOOKUP(lookup_value,table_array,col_index_num,[range_lookup]) Arguments: •lookup_value Required The value to search in the first column of the table or range. •table_array Required The range of cells that contains the data. •col_index_num Required The column number in the table_array argument from which the matching value must be returned. •range_lookup Optional A logical value that specifies whether you want VLOOKUP to find an exact match or an approximate match. Microsoft® Excel® Lookup Functions Description: •Searches the first column of a range of cells, and then returns a value from any cell on the same row of the range. Remarks: • The values in the first column of table_array can be text, numbers, or logical values. •Uppercase and lowercase text are equivalent. • If range_lookup is TRUE, the values in the first column of table_array must be placed in ascending order. • If range_lookup is TRUE or omitted, an approximate match is returned. • If range_lookup is FALSE, an exact match will be attempted. Microsoft® Excel® Lookup Functions Errors: #VALUE! – If col_index_num is less than 1 #REF! – If col_index_num is greater than the number of columns in the table_array #N/A – If range_lookup is FALSE and an exact match cannot be found #N/A – If lookup_value is less than the smallest value in the first column of table_array Microsoft® Excel® Lookup Functions Use IS functions with VLOOKUP functions to avoid seeing errors when your lookup values are not found or when the result are empty cells. Example: =IF(ISNA(VLOOKUP(C2,Customers,2,FALSE)),"",( VLOOKUP(C2,Customers,2,FALSE))) The function above will only return the result of the VLOOKUP when VLOOKUP does not give a #N/A error. If the VLOOKUP function does return a #N/A error, the If statement will return nothing. TODAY =TODAY() NOW =NOW() YEARFRAC =YEARFRAC(start_date,end_date,[basis]) DATEDIF =DATEDIF(startdate,enddate,interval) Syntax: =TODAY() Arguments: None Microsoft® Excel® Date Functions Description: • Returns the serial number of the current date. Remarks: • If the cell format was General before the function was entered, Excel changes the cell format to Date. • If you want to view the serial number, you must change the cell format to General or Number. • The TODAY function is useful when you need to have the current date displayed on a worksheet, regardless of when you open the workbook. • The TODAY function is dependent on your computer’s system clock being correct. Errors: None Microsoft® Excel® Date Functions =TODAY() Microsoft® Excel® Date Functions =TODAY() Microsoft® Excel® Date Functions Syntax: =NOW() Arguments: None Microsoft® Excel® Date Functions Description: • Returns the serial number of the current date and time. Remarks: • If the cell format was General before the function was entered, Excel changes the cell format to the same date and time format that is specified in the regional date and time settings in Control Panel. • The NOW function is useful when you need to display the current date and time on a worksheet or calculate a value based on the current date and time, and have that value updated each time you open the worksheet. • Numbers to the right of the decimal point in the serial number represent the time; numbers to the left represent the date. • The results of the NOW function change only when the worksheet is calculated or when a macro that contains the function is run. It is not updated continuously. Errors: None Microsoft® Excel® Date Functions =NOW() Microsoft® Excel® Date Functions =NOW() Microsoft® Excel® Date Functions Syntax: =YEARFRAC(start_date,end_date,[basis]) Arguments: •start_date Required A date that represents the start date. •end_date Required A date that represents the end date. •basis Optional The type of day count basis to use. Microsoft® Excel® Date Functions Description: • Calculates the fraction of the year represented by the number of whole days between two dates (the start_date and the end_date). Remarks: • Use the YEARFRAC worksheet function to identify the proportion of a whole year's benefits or obligations to assign to a specific term. • Dates should be entered by using the DATE function, or as results of other formulas or functions. • All arguments are truncated to integers. Errors: #VALUE – If start_date or end_date are not valid dates #NUM! – If basis < 0 #NUM! – If basis > 4 Microsoft® Excel® Date Functions What is the fraction of the year between the two dates? =YEARFRAC(A2,A3,A4) Microsoft® Excel® Date Functions What is the fraction of the year between the two dates? =YEARFRAC(A2,A3,A4) =0.583333333 Microsoft® Excel® Date Functions Syntax: =DATEDIF(startdate,enddate,interval) Arguments: •startdate Required A date that represents the start date. •enddate Required A date that represents the end date. •interval Required The type of day count basis to use. Microsoft® Excel® Date Functions Syntax: =DATEDIF(startdate,enddate,interval) Arguments: •interval Required The type of day count basis to use. Microsoft® Excel® Date Functions Description: • Computes the difference between two dates in a variety of different intervals. Remarks: • If you have the interval in another cell referenced by the formula, that cell should not have quotes around the interval string. • When calculating date intervals, DATEDIF uses the year of startdate, not enddate when calculating the yd, ym and md intervals Errors: #VALUE – If start_date or end_date are not valid dates #NUM! – If start date is not less than or equal to the end date Microsoft® Excel® Date Functions What is the difference in days between the two dates? =DATEDIF(A2,A3,”d”) Microsoft® Excel® Date Functions What is the difference in days between the two dates? =DATEDIF(A2,A3,”d”) =210 Microsoft® Excel® Date Functions FIND =FIND(find_text,within_text,[start_num]) LEFT =LEFT(text,[num_chars]) LEN =LEN(text) RIGHT =RIGHT(text,[num_chars]) CONCATENATE (including &) =CONCATENATE(text1, [text2], ...) UPPER =UPPER(text) LOWER =LOWER(text) PROPER =PROPER(text) Syntax: =FIND(find_text,within_text,[start_num]) Arguments: •find_text Required The text you want to find. •within_text Required The text string containing the text you want to find. •start_num Optional Specifies the character at which to start the search. Microsoft® Excel® Text Functions Description: • Locates one text string within a second text string, and returns the number of the starting position of the first text string from the first character of the second text string Remarks: • FIND always counts each character. • The first character in within_text is character number 1. • If you omit start_num, it is assumed to be 1. • FIND is case sensitive. • If find_text is "" (empty text), FIND matches the first character in the search string (that is, the character numbered start_num or 1). Microsoft® Excel® Text Functions Errors: #VALUE! – If find_text does not appear in within_text #VALUE! – If start_num is not greater than zero #VALUE! – If start_num is greater than the length of within_text Microsoft® Excel® Text Functions A 11 Miriam McGovern =FIND(“M”,A11) =1 Microsoft® Excel® Text Functions A 11 Miriam McGovern =FIND(“M”,A11,3) =8 Microsoft® Excel® Text Functions A 11 Miriam McGovern =FIND(“m”,A11) =6 Microsoft® Excel® Text Functions Syntax: =LEFT(text,[num_chars]) Arguments: •text Required The text string that contains the characters you want to extract. •num_chars Optional Specifies the number of characters you want LEFT to extract. Microsoft® Excel® Text Functions Description: • Returns the first character or characters in a text string, based on the number of characters you specify Remarks: • LEFT always counts each character. • Num_chars must be => 0. Microsoft® Excel® Text Functions A 1 Data 2 Sale Price =LEFT(A2,4) =Sale Microsoft® Excel® Text Functions A 1 Data 2 Sale Price 3 Sweden =LEFT(A3) =S Microsoft® Excel® Text Functions Syntax: =LEN(text) Arguments: •text Required The text whose length you want to find. Microsoft® Excel® Text Functions Description: • Returns the number of characters in a text string. Remarks: • Spaces count as characters. Microsoft® Excel® Text Functions A 1 2 Data Phoenix, AZ 3 4 5 6 One =LEN(A2) =11 Microsoft® Excel® Text Functions A 1 2 Data Phoenix, AZ 3 4 5 6 One =LEN(A4) =0 Microsoft® Excel® Text Functions A 1 2 Data Phoenix, AZ 3 4 5 6 One =LEN(A6) =8 Microsoft® Excel® Text Functions Syntax: =RIGHT(text,[num_chars]) Arguments: •text Required The text string that contains the characters you want to extract. •num_chars Optional Specifies the number of characters you want RIGHT to extract. Microsoft® Excel® Text Functions Description: • Returns the last character or characters in a text string, based on the number of characters you specify. Remarks: • RIGHT always counts each character. • Num_chars must be => 0. Microsoft® Excel® Text Functions A 1 Data 2 Sale Price 3 4 Stock Number =RIGHT(A2,5) =Price Microsoft® Excel® Text Functions A 1 Data 2 Sale Price 3 4 Stock Number =RIGHT(A2,LEN(A2)-FIND(“ “,A2)) =RIGHT(A2,10-5) =RIGHT(A2,5) =Price Microsoft® Excel® Text Functions A 1 Data 2 Sale Price 3 4 Stock Number =RIGHT(A4) =r Microsoft® Excel® Text Functions Syntax: =CONCATENATE(text1, [text2], ...) Arguments: •text1 Required The first text item to be concatenated. •text2 Optional Additional text items, up to a maximum of 255 items, which must be separated by commas. Microsoft® Excel® Text Functions Description: • Joins up to 255 text strings into one text string. Remarks: • The joined items can be text, numbers, cell references, or a combination of those items. Microsoft® Excel® Text Functions A B C Data Data Data 2 Brook trout Andreas Hauser 3 species Fourth Pine 1 4 32 =CONCATENATE(“Stream Population for “,A2,” “,A3, “ is “,A4,”/mile”) =Stream Population for Brook trout species is 32/mile Microsoft® Excel® Text Functions A B C Data Data Data 2 Brook trout Andreas Hauser 3 species Fourth Pine 1 4 32 =CONCATENATE(B2, “ “, C2) =Andreas Hauser Microsoft® Excel® Text Functions A B C Data Data Data 2 Brook trout Andreas Hauser 3 species Fourth Pine 1 4 32 =CONCATENATE(C2, “, “ , B2) =Hauser, Andreas Microsoft® Excel® Text Functions A B C Data Data Data 2 Brook trout Andreas Hauser 3 species Fourth Pine 1 4 32 =CONCATENATE(B3, “ & “ , C3) =Fourth & Pine Microsoft® Excel® Text Functions A B C Data Data Data 2 Brook trout Andreas Hauser 3 species Fourth Pine 1 4 32 =B3& “ & “ &C3 =Fourth & Pine Microsoft® Excel® Text Functions Syntax: =UPPER(text) Arguments: •text Required The text you want converted to uppercase. Microsoft® Excel® Text Functions Description: • Converts text to uppercase. Remarks: • Text can be a reference or text string. Microsoft® Excel® Text Functions =UPPER(A2) =TOTAL Microsoft® Excel® Text Functions =UPPER(A3) =YIELD Microsoft® Excel® Text Functions Syntax: =LOWER(text) Arguments: •text Required The text you want converted to lowercase. Microsoft® Excel® Text Functions Description: • Converts all uppercase letters in a text string to lowercase. Remarks: • LOWER does not change characters in text that are not letters. Microsoft® Excel® Text Functions =LOWER(A2) =e.e. cummings Microsoft® Excel® Text Functions =LOWER(A3) =apt. 2b Microsoft® Excel® Text Functions Syntax: =PROPER(text) Arguments: •text Required Text enclosed in quotation marks, a formula that returns text, or a reference to a cell containing the text you want to partially capitalize. Microsoft® Excel® Text Functions Description: • Capitalizes the first letter in a text string and any other letters in text that follow any character other than a letter. Remarks: • PROPER converts all other letters to lowercase letters. Microsoft® Excel® Text Functions =PROPER(A2) =This Is A Title Microsoft® Excel® Text Functions =PROPER(A3) =2-Cent’S Worth Microsoft® Excel® Text Functions =PROPER(A4) =76Budget Microsoft® Excel® Text Functions The TRIM function removes leading and trailing spaces from the input. Syntax: =TRIM(text) The CLEAN function removes all non printable characters from the input. Syntax: =CLEAN(text) =Replace(A1, 1, 5, "Beta") would return "Betabet Soup" =Replace(A2, 5, 2, "1234") would return "Tech1234TheNet" =Replace("apples", 2, 5, "te") would return "ate" DAVERAGE =DAVERAGE(database,field,criteria) DCOUNT =DCOUNT(database,field,criteria) DMAX =DMAX(database,field,criteria) DMIN =DMIN(database,field,criteria) DSUM =DSUM(database,field,criteria) Syntax: =DAVERAGE(database,field,criteria) Arguments: •database Required The range of cells that makes up the list or database. •field Required Indicates which column is used in the function. •criteria Required The range of cells that contains the conditions you specify. Microsoft® Excel® Database Functions Description: •Averages the values in a field (column) of records in a list or database that match conditions you specify. Remarks: •You can use any range for the criteria argument, as long as it includes at least one column label and at least one cell below the column label for specifying the condition •Although the criteria range can be located anywhere on the worksheet, do not place the criteria range below the list •Make sure the criteria range does not overlap the list •To perform an operation on an entire column in a database, enter a blank line below the column labels in the criteria range. Errors: None specified Microsoft® Excel® Database Functions The average yield of apple trees over 10 feet in height. =DAVERAGE(A4:E10,"Yield",A1:B2) Microsoft® Excel® Database Functions The average yield of apple trees over 10 feet in height. =DAVERAGE(A4:E10,"Yield",A1:B2) Microsoft® Excel® Database Functions The average yield of apple trees over 10 feet in height. =DAVERAGE(A4:E10,"Yield",A1:B2) Microsoft® Excel® Database Functions The average yield of apple trees over 10 feet in height. =DAVERAGE(A4:E10,"Yield",A1:B2) Microsoft® Excel® Database Functions The average yield of apple trees over 10 feet in height. =DAVERAGE(A4:E10,"Yield",A1:B2) =12 Microsoft® Excel® Database Functions The average age of all trees in the database. =DAVERAGE(A4:E10,3,A4:E10) Microsoft® Excel® Database Functions The average age of all trees in the database. =DAVERAGE(A4:E10, 3,A4:E10) Microsoft® Excel® Database Functions The average age of all trees in the database. =DAVERAGE(A4:E10, 3,A4:E10) Microsoft® Excel® Database Functions The average age of all trees in the database. =DAVERAGE(A4:E10, 3,A4:E10) Microsoft® Excel® Database Functions The average age of all trees in the database. =DAVERAGE(A4:E10, 3,A4:E10) =13 Microsoft® Excel® Database Functions The maximum profit of apple and pear trees. =DMAX(A4:E10,"Profit",A1:A3) Microsoft® Excel® Database Functions The maximum profit of apple and pear trees. =DMAX(A4:E10,"Profit",A1:A3) Microsoft® Excel® Database Functions The maximum profit of apple and pear trees. =DMAX(A4:E10,"Profit",A1:A3) Microsoft® Excel® Database Functions The maximum profit of apple and pear trees. =DMAX(A4:E10,"Profit",A1:A3) Microsoft® Excel® Database Functions The maximum profit of apple and pear trees. =DMAX(A4:E10,"Profit",A1:A3) =105 Microsoft® Excel® Database Functions The minimum profit of apple trees over 10 in height. =DMIN(A4:E10,"Profit",A1:B2) Microsoft® Excel® Database Functions The minimum profit of apple trees over 10 in height. =DMIN(A4:E10,"Profit",A1:B2) Microsoft® Excel® Database Functions The minimum profit of apple trees over 10 in height. =DMIN(A4:E10,"Profit",A1:B2) Microsoft® Excel® Database Functions The minimum profit of apple trees over 10 in height. =DMIN(A4:E10,"Profit",A1:B2) Microsoft® Excel® Database Functions The minimum profit of apple trees over 10 in height. =DMIN(A4:E10,"Profit",A1:B2) =75 Microsoft® Excel® Database Functions This function looks at the records of apple trees between a height of 10 and 16 and counts how many of the Age fields in those records contain numbers. =DCOUNT(A4:E10,"Age",A1:F2) Microsoft® Excel® Database Functions This function looks at the records of apple trees between a height of 10 and 16 and counts how many of the Age fields in those records contain numbers. =DCOUNT(A4:E10,"Age",A1:F2) Microsoft® Excel® Database Functions This function looks at the records of apple trees between a height of 10 and 16 and counts how many of the Age fields in those records contain numbers. =DCOUNT(A4:E10,"Age",A1:F2) Microsoft® Excel® Database Functions This function looks at the records of apple trees between a height of 10 and 16 and counts how many of the Age fields in those records contain numbers. =DCOUNT(A4:E10,"Age",A1:F2) Microsoft® Excel® Database Functions This function looks at the records of apple trees between a height of 10 and 16 and counts how many of the Age fields in those records contain numbers. =DCOUNT(A4:E10,"Age",A1:F2) =1 Microsoft® Excel® Database Functions The total profit from apple trees. =DSUM(A4:E10,"Profit",A1:A2) Microsoft® Excel® Database Functions The minimum profit of apple trees over 10 in height. =DSUM(A4:E10,"Profit",A1:A2) Microsoft® Excel® Database Functions The minimum profit of apple trees over 10 in height. =DSUM(A4:E10,"Profit",A1:A2) Microsoft® Excel® Database Functions The minimum profit of apple trees over 10 in height. =DSUM(A4:E10,"Profit",A1:A2) Microsoft® Excel® Database Functions The minimum profit of apple trees over 10 in height. =DSUM(A4:E10,"Profit",A1:A2) =225 Microsoft® Excel® Database Functions Study the review questions at the textbook websites for the chapters covered in the final exam. http://wps.prenhall.com/bp_kroenke_experie ncing_1/62/16106/4123157.cw/index.html Databases and Data Warehouses There are two overall approaches to maintaining data: the traditional file approach—which has no mechanism for tagging, retrieving, and manipulating data—and the ____, which does have this mechanism. A) B) C) D) database approach data approach datafile approach indexed file approach There are two overall approaches to maintaining data: the traditional file approach—which has no mechanism for tagging, retrieving, and manipulating data—and the ____, which does have this mechanism. A) B) C) D) database approach data approach datafile approach indexed file approach Ref. p 234 Traditional file approach: no mechanism for tagging, retrieving, or manipulating data Database approach: provides powerful mechanism for managing and manipulating data Traditional approach is inconvenient: Program-data dependency High data redundancy Low data integrity Data redundancy: duplication of data Data integrity: accuracy of data Management Information Systems, Sixth Edition 135 Management Information Systems, Sixth Edition 136 A database itself is a collection of several related files, but DBMSs do all the work—structuring files, storing data, and linking records. A) B) True False A database itself is a collection of several related files, but DBMSs do all the work—structuring files, storing data, and linking records. A) B) True False Ref. P. 236 The very fact that manipulation of the data requires a programmer is probably the greatest disadvantage of the ____. A) B) C) D) information file approach file approach database approach indexed file approach The very fact that manipulation of the data requires a programmer is probably the greatest disadvantage of the ____. A) B) C) D) information file approach file approach database approach indexed file approach Ref. p 234 Database approach: data organized as entities Entity: an object about which an organization chooses to collect data, such as: People Events Products Character: smallest piece of data A single letter or a digit Field: single piece of information about entity Management Information Systems, Sixth Edition 141 Record: collection of related fields File: collection of related records Database fields can hold images, sounds, video clips, etc. Field name allows easy access to the data Database management system (DBMS): program used to: Build databases Populate a database with data Manipulate data in a database Management Information Systems, Sixth Edition 142 Management Information Systems, Sixth Edition 143 Database administrator (DBA): the person responsible for managing the database Sets user limits for access to data in the database DBMS is usually bundled with a programming language Management Information Systems, Sixth Edition 144 Relational Model: consists of tables Based on relational algebra Tuple: record (or row) Attribute: field (or column) Relation: table of records To design a relational database, you must understand the entities to be stored in the database and how they relate Tables are independent of each other, but can be related to each other Management Information Systems, Sixth Edition 145 To link records from one table with records of another table, the tables must have at least one field in common, and that field must be a ____ field for one of the tables. A) B) C) D) composite key main key foreign key primary key To link records from one table with records of another table, the tables must have at least one field in common, and that field must be a ____ field for one of the tables. A) B) C) D) composite key main key foreign key primary key Ref. p 240 Key: a field whose values identify records Used to retrieve records Primary key: a field by which records are uniquely identified Each record in the table must have a unique key value Composite key: combination of fields that serve as a primary key Management Information Systems, Sixth Edition 148 Management Information Systems, Sixth Edition 149 Data is accessed in a database by sending messages called “protocols,” which request data from specific records and/or fields and direct the computer to display the results. A) B) True False Data is accessed in a database by sending messages called “protocols,” which request data from specific records and/or fields and direct the computer to display the results. A) B) True False Ref. P. 237 Query: a message to the database requesting data from specific records and/or fields Database must be properly secured Not everyone should have access to all data Users will have different views of the database, based on the data they are allowed to see Management Information Systems, Sixth Edition 152 Foreign key: a field that is common to two tables Used to link the tables This field is a primary key in one table and a foreign key in the other Join table: composite of tables Two types of table relationships: One-to-many relationship: one item in a table is linked to many items in the other table Many-to-many relationship: many items in a table are linked to many items of the other table Management Information Systems, Sixth Edition 153 Object-oriented database model: uses objectoriented approach for the database structure Encapsulation: combined storage of data and relevant procedures to process it Allows object to be “planted” in different data sets Inheritance: the ability to create a new object by replicating the characteristics of an existing (parent) object Object-oriented databases (ODBs) store data objects, not records Management Information Systems, Sixth Edition 154 Relational operation: creates a temporary subset of a table or tables Used to create a limited list or a joined table list Three important relational operations: Select: a selection of records based on conditions Project: a selection of certain columns from a table Join: join data from multiple tables to create a temporary table Management Information Systems, Sixth Edition 155 Structured Query Language (SQL): query language of choice for DBMSs Advantages of SQL: It is an international standard It is provided with most relational DBMSs It has easy-to-remember, intuitive commands Management Information Systems, Sixth Edition 156 A ____ is the general logical structure in which records are stored within a database and the method used to establish relationships among the records. A) B) C) D) database relationship database model database list database catalog A ____ is the general logical structure in which records are stored within a database and the method used to establish relationships among the records. A) B) C) D) database relationship database model database list database catalog Ref. p 238 A schema describes the structure of the database being designed: the names and types of fields in each record type and the general relationships among different sets of records or files. A) B) True False A schema describes the structure of the database being designed: the names and types of fields in each record type and the general relationships among different sets of records or files. A) B) True False Ref. p 244 Schema: a plan that describes the structure of the database, including: Names and sizes of fields Identification of primary keys Relationships Data dictionary: a repository of information about the data and its organization Also called metadata: the data about the data Management Information Systems, Sixth Edition 161 While a transactional database contains current data, which is disposed of after some time, the data in ____ is accumulated and might reflect many years of business activities. A) B) C) D) data warehouses data carts information bases information repositories While a transactional database contains current data, which is disposed of after some time, the data in ____ is accumulated and might reflect many years of business activities. A) B) C) D) data warehouses data carts information bases information repositories Ref. p 248 Most data collections are used for transactions Accumulation of transaction data is useful Data warehouse: a large repository database that supports management decision making Typically relational Data is collected from transactional databases Data mart: a smaller collection of data focusing on a particular subject or department Management Information Systems, Sixth Edition 164 Because of capacity needs, organizations often choose ____ to store and manage data warehouses. A) B) C) D) midrange servers high speed networks mainframe computers with multiple CPUs workstations Because of capacity needs, organizations often choose ____ to store and manage data warehouses. A) B) C) D) midrange servers high speed networks mainframe computers with multiple CPUs workstations Ref. p 250 Transactional databases are not suitable for business analysis Contain only current, not historical data Data warehouse requires large storage capacity: Mainframe computers are often used Scalability is an issue Data warehouses grow continually Management Information Systems, Sixth Edition 167 There are two phases involved in building a data warehouse from transactional data: extraction and transforming. A) B) True False There are two phases involved in building a data warehouse from transactional data: extraction and transforming. A) B) True False Ref. p 251 Three phases in transferring data from a transactional database to a data warehouse: Extraction phase: create files from transactional database Transformation phase: cleanse and modify the data format Loading phase: transfer files to data warehouse A properly built data warehouse becomes a single source for all data required for analysis Data mining and online analytical processing (OLAP) use data in data warehouses Management Information Systems, Sixth Edition 170