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Relational Data Analysis
Plan
• Introduction
• Structured Methods– Data Flow Modelling– Data Modelling– Relational Data Analysis
• Feasibility
• Maintenance
Relational Data Analysis
• Prepares Business’ data for representation using the relational model
• The relational model is implemented in a number of popular database systems– Access– Oracle– MySQL– DB2
The Relational Model
• A relation is a table of data• A relational database is therefore one in which
tables are used to store data– This implies that there are other ways of storing data
• Tables will be related to each other in some way– Because the data held in them is related– The context of the system we are developing governs
which data items are related and how they are related
Relational Data Analysis
• Relational data analysis therefore involves– Building related tables of data– Retrieval of data from one or more related
tables– Inserting, Updating and Deleting data from
related tables
Relational Data Analysis
• Relational data analysis is quite formal – Based on set theory– Uses Relational Algebra to define operations
on tables
• We will take a less formal approach
Definitions
• A relation corresponds to a table• A tuple is a row in a table• An attribute is a column in a table• A Primary Key is the attribute by which we
uniquely identify each row• The number of rows in a table is called the
cardinality• The number of attributes in a table is called the
degree
Example Relation (Table)
Student ID Student Name Course Module Code Module Name Grade
1000001 Peter Stringfellow BSc Basket Weaving W1001 Flower Arranging A
1001234 Terrence Halfwit BA Surfing Studies S2003 Hazardous Fishes B
1234567 Big John BSc Business B3333 Selling Stuff E
1234567 Big John BSc Business B3334 Buying Stuff A
Student
Example Relation (Table)
• The table can also be described without its data as follows:– Student (Student ID, Student Name, Course,
Module Code, Module Name, Grade)
Example Relation (Tuple)
Student ID Student Name Course Module Code Module Name Grade
1000001 Peter Stringfellow BSc Basket Weaving W1001 Flower Arranging A
1001234 Terrence Halfwit BA Surfing Studies S2003 Hazardous Fishes B
1234567 Big John BSc Business B3333 Selling Stuff E
1234567 Big John BSc Business B3334 Buying Stuff A
Student
Example Relation (Attribute)
Student ID Student Name Course Module Code Module Name Grade
1000001 Peter Stringfellow BSc Basket Weaving W1001 Flower Arranging A
1001234 Terrence Halfwit BA Surfing Studies S2003 Hazardous Fishes B
1234567 Big John BSc Business B3333 Selling Stuff E
1234567 Big John BSc Business B3334 Buying Stuff A
Student
Example Relation (Table)
• Our example has a cardinality of 4 and a degree of 6
• The primary key will be student ID as this will uniquely identify each row– We cannot know this without having an
understanding of the data
• If there is no existing primary key then we must invent one
Exercise
Name Number Town No of contracts Depot
Tom 0050065 Manchester 2 Manchester
Dick 0338178 Leeds 1 Manchester
Harry 1922029 Manchester 3 Stoke
Sue 0002911 Oxford 1 Reading
Frieda 1001001 Cardiff 7 Cardiff
Imran 23455678 Manchester 1 Stoke
Yue 32156545 Manchester 7 London
Exercise
• What is the cardinality of the table?
• What is the degree of the table?
• Identify the Primary Key of the table?
Exercise
Name Number Town No of contracts Depot
Tom 0050065 Manchester 2 Manchester
Dick 0338178 Leeds 1 Manchester
Harry 1922029 Manchester 3 Stoke
Sue 0002911 Oxford 1 Reading
Frieda 1001001 Cardiff 7 Cardiff
Imran 23455678 Manchester 1 Stoke
Yue 32156545 Manchester 7 London
Exercise
• What is the cardinality of the table?– How many rows? 7
• What is the degree of the table?– How many attributes? 5
• Identify the Primary Key of the following table?– Number– But how do we know? Why not Name?
Tables and Entities
• Each table is equivalent to an entity in an ERD
• Each attribute is equivalent to an attribute in an ERD
• Each tuple is an occurrence of an entity in an ERD
• The primary key is equivalent to the key attribute in an ERD entity
Rules
• No two rows in a table are identical– i.e. there are no duplicate tuples/rows
• Every relation has a Primary Key attribute• The sequence of the rows should not be
significant• The sequence of the columns should not
be significant• Each attribute must have a unique name
Problems with Tables
• Problems with tables can be classified into three groups:– Insert Anomalies – Problems caused when
inserting new information– Update Anomalies – Problems caused when
updating existing data– Delete Anomalies – Problems caused when
deleting data
Problems with Tables
• For the student table in the handout:– The primary key doesn’t uniquely describe
each row
• Insert anomaly– We cannot add new courses unless we have
a student ID• Perhaps we chose the wrong primary key?• Try using a different one to see if it helps
Problems with Tables
• Update Anomaly– Big John Changes his name– We now have to find all instances of Big John
and change them– This could take some time– We could miss one– What if there is more than one Big John? Can
we be sure we are changing the right one?
Problems with Tables
• Delete anomaly– Terrence Halfwit decides he no longer wishes
to take Module S2003– If we delete this from Terrence’s row we lose
all information about Module S2003 as no one else is taking it at the moment
The Solution?
• To remove these anomalies we must re-arrange the data and create new tables
• The process for doing this is called Normalisation
Normalisation
• First Three Stages– First Normal Form (1NF)– Second Normal Form (2NF)– Third Normal Form (3NF)
• 1NF can be considered as Normalised– But there will still be problems– All common problems are solved by 3NF– Further Normalisation will solve rarer problems
First Normal Form
• All data in a table must be dependant on the key
• In order to do this we must remove “repeating groups”
• This is done by analysing the relationship between the primary key and the rest of the data
Example 1 - Students
• Student ID• Student Name• Course• Course ID• Module Code• Module Name• Grade
• Attributes are moved if there is more than one for each instance of the primary key
Example 1 - Students
• Student ID• Student Name• Course• Course ID• Module Code• Module Name• Grade
• For each Student ID• How many Student
names are there?• 1 or Many?
Example 1 - Students
• Student ID• Student Name• Course• Course ID• Module Code• Module Name• Grade
• For each Student ID• How many Courses
are there?• 1 or Many?
Example 1 - Students
• Student ID• Student Name• Course• Course ID• Module Code• Module Name• Grade
• For each Student ID• How many Course
IDs are there?
Example 1 - Students
• Student ID• Student Name• Course• Course ID• Module Code• Module Name• Grade
• For each Student ID• How many Module
Codes are there?
Example 1 - Students
• Student ID• Student Name• Course• Course ID
– Module Code• Module Name• Grade
• For each Student ID• How many Module
Codes are there?
Example 1 - Students
• Student ID• Student Name• Course• Course ID
– Module Code• Module Name• Grade
• For each Student ID• How many Module
Names are there?
Example 1 - Students
• Student ID• Student Name• Course• Course ID
– Module Code– Module Name
• Grade
• For each Student ID• How many Module
Names are there?
Example 1 - Students
• Student ID• Student Name• Course• Course ID
– Module Code– Module Name
• Grade
• For each Student ID• How many Grades
are there?
Example 1 - Students
• Student ID• Student Name• Course• Course ID
– Module Code– Module Name– Grade
• For each Student ID• How many Grades
are there?
Example 1 - Students
• Student ID• Student Name• Course• Course ID
– Module Code– Module Name– Grade
• Indented data is a repeating group
• We need to put it into a new table
• This table will describe the module a student is taking
• We will call it Student Module
Example 1 - Students
• Student ID• Student Name• Course• Course ID
• Student ID• Module Code• Module Name• Grade
• We now have two tables
• Student details– Primary Key = Student ID
• Student’s module details– PK = Student ID, Module
Code– Called a compound Key
Does this help?
• Insert– We can now add students who have no modules
• Delete– We can now keep students when they leave modules– We can keep Terrence’s details even if he leaves the
module
• Update– We now only need to change student details once– Big John’s Name could be changed easily without
error
Yes… But… No… But…
• There are still Anomalies…
• Update– If Creative Accounting name is changed…
• Insert– Cannot add a new module unless we have a student enrolled
• Delete– When a student leaves we could lose module information
• These are dealt with by later Normal Forms
Example 2 - Library
• Student ID• Name• Faculty• Book ID• Title• Author• Return Date
• Put this data into First Normal Form
Example 2 - Library
• Student ID• Name• Faculty
– Book ID– Title– Author– Return Date
• Identify Repeating group
Example 2 - Library
• Student ID• Name• Faculty
• Student ID • Book ID• Title• Author• Return Date
• Create a New table
• Remember to keep the original PK in that of the new table
• This maintains the relationship between the two tables
Example 3
• Customer ID• Customer Name• Address• Branch No• Branch Manager• Stock ID• Title• Format
• Put this data into First Normal Form
Example 3
• Customer ID• Customer Name• Address• Branch No• Branch Manager
– Stock ID– Title– Format
• Identify Repeating group
Example 3 – Borrowing Videos
• Customer ID• Customer Name• Address• Branch No• Branch Manager
• Customer ID• Stock ID• Title• Format
• Create New table
Remember
• 1NF can be considered as Normalised
• But it doesn’t solve all of our problems
• Need to go through second and third Normal Forms in Tutorials and next week
Second Normal Form
• Only Applies to tables with compound keys
• Data in a table must depend on the whole key
• We must remove any partial dependencies
References
• Whiteley, D. (2004) Introduction to Information Systems, Palgrave, 2004.
• Lejk, M. and D. Deeks (2002) Systems Analysis Techniques, Addison Wesley 2002
• Mason, D. and L. Willcocks (1994), Systems Analysis, Systems Design, Alfred Waller, 1994.
References
• Yeates, D. and T. Wakefield (2004) Systems Analysis and Design, FT/Prentice Hall 2004
• Gane, C. and T. Sarson (1979) Structured Systems Analysis, Prentice Hall, 1979
• Eva, M (1994) SSADM Version 4: A users guide, McGraw hill, 1994
References
• DeMarco, T. (1979) Structured Analysis and System Specification, Yourdon, 1979
• Royce, W. (1970) Managing the development of large software systems, In: Proceedings of IEEE WESCON, 1970 pp1-9.
• Connolly, T. and C. Begg (2000) Database Solutions, Addison-Wesley, 2000
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