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Normalization
CSC 3800
Fall 2008
Database Normalization Database normalization is the process of
removing redundant data from your tables to improve storage efficiency, data integrity, and scalability.
In the relational model, methods exist for quantifying how efficient a database is. These classifications are called normal forms (or NF), and there are algorithms for converting a given database between them.
Normalization generally involves splitting existing tables into multiple ones, which must be re-joined or linked each time a query is issued.
History
Edgar F. Codd first proposed the process of normalization and what came to be known as the 1st normal form in his paper A Relational Model of Data for Large Shared Data Banks Codd stated:“There is, in fact, a very simple elimination procedure which we shall call normalization. Through decomposition nonsimple domains are replaced by ‘domains whose elements are atomic (nondecomposable) values.’”
Normal Form
Edgar F. Codd originally established three normal forms: 1NF, 2NF and 3NF. There are now others that are generally accepted, but 3NF is widely considered to be sufficient for most applications. Most tables when reaching 3NF are also in BCNF (Boyce-Codd Normal Form).
Why Normalize?
FlexibilityStructure supports many ways to look at
the dataData Integrity
“Modification Anomalies”Deletion InsertionUpdate
EfficiencyEliminate redundant data and save space
Normalization Defined
“In relational database design, the process of organizing data to minimize duplication.
Normalization usually involves dividing a database into two or more tables and defining relationships between the tables.
The objective is to isolate data so that additions, deletions, and modifications of a field can be made in just one table and then propagated through the rest of the database via the defined relationships.” - Webopedia, http://webopedia.internet.com/TERM/n/normalization.html
The Normal Forms
A series of logical steps to take to normalize data tables
First Normal FormSecondThirdBoyce CoddThere’s more, but beyond scope of
this class
Un-normalized Table
OrderDate Customer Items11/30/1998 Joe Smith Hammer, Saw, Nails
OrderDate Customer Item1 Item2 Item311/30/1998 Joe Smith Hammer Saw Nails
or
First Normal Form
Remove horizontal redundanciesNo two columns hold the same informationNo single column holds more than a single
itemEach row must be unique
Use a primary keyBenefits
Easier to query/sort the dataMore scalableEach row can be identified for updating
First Normal Form
All columns (fields) must be atomicMeans : no repeating items in columns
OrderDate Customer Items11/30/1998 Joe Smith Hammer, Saw, Nails
OrderDate Customer Item1 Item2 Item311/30/1998 Joe Smith Hammer Saw Nails
Solution: make a separate table for each set of attributes with a primary key (parser, append query)
CustomersCustomerIDName
OrdersOrderIDItem CustomerIDOrderDate
First Normal Form Tables
CustomerID Name 1 Joe Smith
Orders
OrderID Item CustomerID OrderDate 1 Hammer 1 11/30/1998 1 Saw 1 11/30/1998 1 Nails 1 11/30/1998
Customers
Second Normal Form (2NF)
In 1NF and every non-key column is fully dependent on the (entire) primary key Means : Do(es) the key field(s) imply the rest of
the fields? Do we need to know both OrderID and Item to know the Customer and Date? Clue: repeating fields
OrderID Item CustomerID OrderDate1 Hammer 1 11/30/19981 Saw 1 11/30/19981 Nails 1 11/30/1998
Orders
Second Normal Form
Table must be in First Normal FormRemove vertical redundancy
The same value should not repeat across rows
Composite keysAll columns in a row must refer to BOTH
parts of the keyBenefits
Increased storage efficiencyLess data repetition
Second Normal Form (2NF)
In 1NF and every non-key column is fully dependent on the (entire) primary key Means : Do(es) the key field(s) imply the rest of the fields? Do we
need to know both OrderID and Item to know the Customer and Date? Clue: repeating fields
Solution: Remove to a separate table (Make Table)
OrderID Item CustomerID OrderDate1 Hammer 1 11/30/19981 Saw 1 11/30/19981 Nails 1 11/30/1998
OrderDetailsOrderIDItem
OrdersOrderIDCustomerIDOrderDate
Second Normal Form Tables
OrderID CustomerID OrderDate 1 1 11/30/1998
Orders
OrderDetails
OrderID Item 1 Hammer 1 Saw 1 Nails
CustomerID Name 1 Joe Smith
Customers
Third Normal Form (3NF)
In 2NF and every non-key column is mutually independent means : Calculations
Item Quantity Price TotalHammer 2 $10 $20Saw 5 $40 $200Nails 8 $1 $8
Third Normal Form
Table must be in Second Normal Form If your table is 2NF, there is a good chance
it is 3NFAll columns must relate directly to the
primary keyBenefits
No extraneous data
Third Normal Form (3NF)
In 2NF and every non-key column is mutually independent means : Calculations
•Solution: Put calculations in queries and forms
Item Quantity Price TotalHammer 2 $10 $20Saw 5 $40 $200Nails 8 $1 $8
OrderDetailsOrderIDItemQuantityPrice
Put expression in text control or in query:=Quantity * Price
Third Normal Form (3NF)
OrderID Item Quantity Price 1 Hammer 2 $10 1 Saw 5 $40 1 Nails 8 $1
OrderDetails
Put expression in text control or in query:=Quantity * Price
SELECT OrderID, Item, Quantity, Price, Price*Quantity FROM OrderDetails
2/16/98 10MGS 404
2/16/98 10
Boyce-Codd Form (3NF) - Examples
A more restricted version of 3NF (known as Boyce-Codd Normal Form) requires that the determinant of every functional dependency in a relation be a key - for every FD: X => Y, X is a key
Consider the following relation:STU-MAJ-ADV (Student-Id, Major, Advisor)Advisor => Major, but Advisor is not a key
Boyce-Codd Normal Form for above:STU-ADV (Student-Id, Advisor)ADV-MAJ (Advisor, Major)
Kumar Madurai: http://www.mgt.buffalo.edu/courses/mgs/404/mfc/lecture4.ppt
Primary Key
Unique Identifier for every row in the table Integers vice Text to save memory,
increase speedCan be “composite”Surrogate is best bet!
Meaningless, numeric column acting as primary key in lieu of something like SSN or phone number - (both can be reissued!)
Relationships
One to many to enforce “Referential Integrity”
Two “foreign” keys make a composite primary key and “relate” many to many tables
A look up table - it doesn’t reference any others
Table Prefixes Aid Development
First, we’ll get replace text PK with number The Items table is a “look up” with tlkp prefix
tlkp “lookup” table (no “foreign keys”)
OrderDetails is renamed “trelOrderItem” a “relational” table trel “relational” (or junction or linking)
two foreign keys make a primary
tblOrdersOrderIDCustomerIDOrderDate
OrderDetailsOrderIDItem trelOrderItem
OrderIDItemID
tlkpItemsItemIDItemName
Referential Integrity
Every piece of “foreign” key data has a primary key on the one site of the relationship No “orphan” records. Every child has a parent Can’t delete records from primary table if in related table
Benefits - Data Integrity and Propagation If update fields in main table, reflected in all queries Can’t add a record in related table without adding it to main Cascade Delete: If delete record from primary table, all
children deleted - use with care! Better idea to “archive” Cascade Update: If change the primary key field, will change
foreign key
When Not to Normalize
Want to keep tables simple so user can make their own queries Avoid processing multiple tables
Archiving Records If no need to perform complex queries or “resurrect” Flatten and store in one or more tables
Testing shows Normalization has poorer performance “Sounds Like” field example Can also try temp tables produced from Make Table queries
Real World - School Data
Student Student Previous CurrentLast First Parent 1 Parent 2 Teacher TeacherSmith Renee Ann Jones Theodore Smith Hamil BurkeMills Lucy Barbara Mills Steve Mills Hamil Burke Jones Brendan Jennifer Jones Stephen Jones Hamil Burke ….
Street Address City State Postal Code Home Phone5551 Private Hill Annandale Virginia 22003- (703) 323-08934902 Acme Ct Annandale Virginia 22003- (703) 764-58295304 Gains Street Fairfax Virginia 22032- (703) 978-1083 ….
First Year Last Year AgeProgram Enrolled Attended Birthday inSept Map Coord NotesPF / 0 0 6/25/93 5 22 A-3PF 96/97 0 8/14/93 5 21 F-3PH 96/97 0 6/13/94 4 21 A-4
One Possible Design
Examples
1. Eliminate Repeating Groups In the original member list, each member name is followed by any databases that
the member has experience with. Some might know many, and others might not know any. To answer the question, "Who knows DB2?" we need to perform an awkward scan of the list looking for references to DB2. This is inefficient and an extremely untidy way to store information.
Moving the known databases into a seperate table helps a lot. Separating the repeating groups of databases from the member information results in first normal form. The MemberID in the database table matches the primary key in the member table, providing a foreign key for relating the two tables with a join operation. Now we can answer the question by looking in the database table for "DB2" and getting the list of members.
Original Table
1NF Tables
2. Eliminate Redundant Data In the Database Table, the primary key is made up of the MemberID and the DatabaseID. This makes sense
for other attributes like "Where Learned" and "Skill Level" attributes, since they will be different for every member/database combination. But the database name depends only on the DatabaseID. The same database name will appear redundantly every time its associated ID appears in the Database Table.
Suppose you want to reclassify a database - give it a different DatabaseID. The change has to be made for every member that lists that database! If you miss some, you'll have several members with the same database under different IDs. This is an update anomaly.
Or suppose the last member listing a particular database leaves the group. His records will be removed from the system, and the database will not be stored anywhere! This is a delete anomaly. To avoid these problems, we need second normal form.
To achieve this, separate the attributes depending on both parts of the key from those depending only on the DatabaseID. This results in two tables: "Database" which gives the name for each DatabaseID, and "MemberDatabase" which lists the databases for each member.
Now we can reclassify a database in a single operation: look up the DatabaseID in the "Database" table and change its name. The result will instantly be available throughout the application.
3. Eliminate Columns Not Dependent On Key
The Member table satisfies first normal form - it contains no repeating groups. It satisfies second normal form - since it doesn't have a multivalued key. But the key is MemberID, and the company name and location describe only a company, not a member. To achieve third normal form, they must be moved into a separate table. Since they describe a company, CompanyCode becomes the key of the new "Company" table.
The motivation for this is the same for second normal form: we want to avoid update and delete anomalies. For example, suppose no members from the IBM were currently stored in the database. With the previous design, there would be no record of its existence, even though 20 past members were from IBM!
BCNF. Boyce-Codd Normal Form
Boyce-Codd Normal Form states mathematically that:A relation R is said to be in BCNF if whenever X -> A holds in R, and A is not in X, then X is a candidate key for R.BCNF covers very specific situations where 3NF misses inter-dependencies between non-key (but candidate key) attributes. Typically, any relation that is in 3NF is also in BCNF. However, a 3NF relation won't be in BCNF if (a) there are multiple candidate keys, (b) the keys are composed of multiple attributes, and (c) there are common attributes between the keys.
Basically, a humorous way to remember BCNF is that all functional dependencies are:"The key, the whole key, and nothing but the key, so help me Codd."
Example 2
Example 2
Name Address Phone
Sally Singer123 Broadway New York, NY, 11234
(111) 222-3345
Jason Jumper456 Jolly Jumper St. Trenton NJ, 11547
(222) 334-5566
The First Normal Form
For a table to be in first normal form, data must be broken up into the smallest units possible. For example, the following table is not in first normal form.
Example 2
To conform to first normal form, this table would require additional fields. The name field should be divided into first and last name and the address should be divided by street, city state, and zip like this.
ID First Last Street City State Zip Phone
564 Sally Singer 123 Broadway New York NY 11234 (111) 222-3345
565 Jason Jumper 456 Jolly Jumper St. Trenton NJ 11547 (222) 334-5566
Example 2
In addition to breaking data up into the smallest meaningful values, tables in first normal form should not contain repetitions groups of fields such as in the following table.
Rep ID Representative Client 1 Time 1 Client 2 Time 2 Client 3 Time 3
TS-89 Gilroy Gladstone US Corp. 14 hrs Taggarts 26 hrs Kilroy Inc. 9 hrs
RK-56 Mary Mayhem Italiana 67 hrs Linkers 2 hrs
Example 2
The problem here is that each representative can have multiple clients not all will have three. Some may have less as is the case in the second record, tying up storage space in your database that is not being used, and some may have more, in which case there are not enough fields. The solution to this is to add a record for each new piece of information.
Rep IDRep First Name
Rep Last Name
ClientTime With Client
TS-89 Gilroy Gladstone US Corp 14 hrs
TS-89 Gilroy Gladstone Taggarts 26 hrs
TS-89 Gilroy Gladstone Kilroy Inc. 9 hrs
RK-56 Mary Mayhem Italiana 67 hrs
RK-56 Mary Mayhem Linkers 2 hrs
Notice the splitting of the first and last name fields again.
Example 2
This table is now in first normal form. Note that by avoiding repeating groups of fields, we have created a new problem in that there are identical values in the primary key field, violating the rules of the primary key. In order to remedy this, we need to have some other way of identifying each record. This can be done with the creation of a new key called client ID.
Rep ID*Rep First Name
Rep Last Name
Client ID*
ClientTime With Client
TS-89 Gilroy Gladstone 978 US Corp 14 hrs
TS-89 Gilroy Gladstone 665 Taggarts 26 hrs
TS-89 Gilroy Gladstone 782 Kilroy Inc. 9 hrs
RK-56 Mary Mayhem 221 Italiana 67 hrs
RK-56 Mary Mayhem 982 Linkers 2 hrs
This new field can now be used in conjunction with the Rep ID field to create a multiple field primary key. This will prevent confusion if ever more than one Representative were to serve a single client.
Example 2
Second Normal Form
The second normal form applies only to tables with multiple field primary keys. Take the following table for example.
Rep ID*Rep First Name
Rep Last Name
Client ID*
ClientTime With Client
TS-89 Gilroy Gladstone 978 US Corp 14 hrs
TS-89 Gilroy Gladstone 665 Taggarts 26 hrs
TS-89 Gilroy Gladstone 782 Kilroy Inc. 9 hrs
RK-56 Mary Mayhem 221 Italiana 67 hrs
RK-56 Mary Mayhem 982 Linkers 2 hrs
RK-56 Mary Mayhem 665 Taggarts 4 hrs
This table is already in first normal form. It has a primary key consisting of Rep ID and Client ID since neither alone can be considered a unique value.
Example 2 The second normal form states that each field in a multiple field
primary key table must be directly related to the entire primary key. Or in other words, each non-key field should be a fact about all the fields in the primary key. Only fields that are absolutely necessary should show up in our table, all other fields should reside in different tables. In order to find out which fields are necessary we should ask a few questions of our database. In our preceding example, I should ask the question "What information is this table meant to store?" Currently, the answer is not obvious. It may be meant to store information about individual clients, or it could be holding data for employees time cards. As a further example, if my database is going to contain records of employees I may want a table of demographics and a table for payroll. The demographics will have all the employees personal information and will assign them an ID number. I should not have to enter the data twice, the payroll table on the other hand should refer to each employee only by their ID number. I can then link the two tables by a relationship and will then have access to all the necessary data.
Example 2
In the table of the preceding example we are devoting three field to the identification of the employee and two to the identification of the client. I could identify them with only one field each -- the primary key. I can then take out the extraneous fields and put them in their own table. For example, my database would then look like the following.
Rep ID* Client ID* Time With Client
TS-89 978 14 hrs
TS-89 665 26 hrs
TS-89 782 9 hrs
RK-56 221 67 hrs
RK-56 982 2 hrs
RK-56 665 4 hrs
The above table contains time card information.
Example 2
Rep ID* First Name Last Name
TS-89 Gilroy Gladstone
RK-56 Mary Mayhem
The above table contains Employee Information.
Example 2
Client ID* Client Name
978 US Corp
665 Taggarts
782 Kilroy Inc.
221 Italiana
982 Linkers
The above table contains Client Information
These tables are now in normal form. By splitting off the unnecessary information and putting it in its own tables, we have eliminated redundancy and put our first table in second normal form. These tables are now ready to be linked through relationship to each other.
Example 2
Third Normal Form Third normal form is the same as second
normal form except that it only refers to tables that have a single field as their primary key. In other words, each non-key field in the table should be a fact about the primary key. Either of the preceding two tables act as an example of third normal form since all the fields in each table are necessary to describe the primary key.
Once all the tables in a database have been taken through the third normal form, we can begin to set up relationships.
Example 3
Repeating Groups And Normalization To First Normal Form (1nf)
Invoice# Date Customer#Salesperson
Region
Item# PriceDescription
INVOICES (2NF)
Invoice# Quantity
INVOICE-ITEMS (1NF)
100110021003
7/1/927/1/927/1/92
456329897
JohnMaryAl
WestEastWest
121348540
45105
$2.25$3.70$0.40
WidgetGearBolt
Invoice# Date Customer#Salesperson
Region Item# QuantityPriceDescription
SALES-INFORMATION
What Is The Problem With Description/Price?
Insert anomaliesDelete anomaliesUpdate anomalies
Decomposition Of A First-normal-form (1nf) Table
Item# PriceDescriptionInvoice# Quantity
INVOICE-ITEMS (1NF)
Item# PriceDescription
ITEMS (2NF)
Item#Invoice# Quantity
INVOICE-ITEMS-QTY (2NF)
You can only have a 2nd Normal Form problem if there is a composite primary Key
Database Normalization
Functional dependency is key in understanding the process of normalization. Functional dependency means that if there is only one possible value of Y for every value of X, then Y is functionally dependent on X.
Database Normalization
Think of an invoice table. Two fields would be invoice # and date. Which field is functionally dependent on the other?
INVOICE # DATE
Date is functionally dependent on invoice number.
Dependencies
Functional Dependency is “good”. With functional dependency the primary key (Attribute A) determines the value of all the other non-key attributes (Attributes B,C,D,etc.)
Transitive dependency is “bad”. Transitive dependency exists if the primary key (Attribute A) determines non-key Attribute B, and Attribute B determines non-key Attribute C.
Decomposition Of A Second-normal-form (2nf) Table
Invoice# Date Customer# Salesperson
INVOICES (3NF)
Salesperson Region
SALESPERSON-REGION (3NF)
Invoice# Date Customer# Salesperson Region
SALES (2NF)
This is a transitive dependency which must be eliminated for 3NF
Summary Of 3nf Relations For Sales Database
Item# PriceDescription
ITEMS (3NF)
Salesperson Region
SALESPERSON-REGION (3NF)
Invoice# Date Customer# Salesperson
INVOICES (3NF)
Item# Quantity
INVOICE-ITEMS-QTY (3NF)
100110021003
7/1/927/1/927/1/92
456329897
JohnMaryAl
WestEastWest
121348540
45105
$2.25$3.70$0.40
WidgetGearBolt
Invoice#
100110021003
121348540
JohnMaryAl
END
Other Slides
Table 1
Title Author1 Author2
ISBN Subject Pages Publisher
Database System Concepts
Abraham Silberschatz
Henry F. Korth
0072958863 MySQL, Computers
1168 McGraw-Hill
Operating System Concepts
Abraham Silberschatz
Henry F. Korth
0471694665 Computers 944 McGraw-Hill
Orders Table Problems
This table is not very efficient with storage.
This design does not protect data integrity.
Third, this table does not scale well.
First Normal Form
In our Table, we have two violations of First Normal Form:
First, we have more than one author field,
Second, our subject field contains more than one piece of information. With more than one value in a single field, it would be very difficult to search for all books on a given subject.
First Normal Table
Table 2
Title Author ISBN Subject Pages Publisher
Database System Concepts
Abraham Silberschatz
0072958863 MySQL 1168 McGraw-Hill
Database System Concepts
Henry F. Korth
0072958863 Computers 1168 McGraw-Hill
Operating System Concepts
Henry F. Korth
0471694665 Computers 944 McGraw-Hill
Operating System Concepts
Abraham Silberschatz
0471694665 Computers 944 McGraw-Hill
We now have two rows for a single book. Additionally, we would be violating the Second Normal Form…
A better solution to our problem would be to separate the data into separate tables- an Author table and a Subject table to store our information, removing that information from the Book table:
Additional Problems
Subject_ID Subject
1 MySQL
2 Computers
Author_ID Last Name First Name
1 Silberschatz Abraham
2 Korth Henry
ISBN Title Pages Publisher
0072958863 Database System Concepts
1168 McGraw-Hill
0471694665 Operating System Concepts
944 McGraw-Hill
Subject Table Author Table
Book Table
Second Normal Tables
Each table has a primary key, used for joining tables together when querying the data. A primary key value must be unique with in the table (no two books can have the same ISBN number), and a primary key is also an index, which speeds up data retrieval based on the primary key.
Now to define relationships between the tables
Additional Problems
Relationships
ISBN Author_ID
0072958863 1
0072958863 2
0471694665 1
0471694665 2
ISBN Subject_ID
0072958863 1
0072958863 2
0471694665 2
Book_Author Table Book_Subject Table
Second Normal Form
As the First Normal Form deals with redundancy of data across a horizontal row, Second Normal Form (or 2NF) deals with redundancy of data in vertical columns.
As stated earlier, the normal forms are progressive, so to achieve Second Normal Form, the tables must already be in First Normal Form.
The Book Table will be used for the 2NF example
2NF Table
Publisher_ID Publisher Name
1 McGraw-Hill
ISBN Title Pages Publisher_ID
0072958863 Database System Concepts
1168 1
0471694665 Operating System Concepts
944 1
Publisher Table
Book Table
2NF
Here we have a one-to-many relationship between the book table and the publisher. A book has only one publisher, and a publisher will publish many books. When we have a one-to-many relationship, we place a foreign key in the Book Table, pointing to the primary key of the Publisher Table.
The other requirement for Second Normal Form is that you cannot have any data in a table with a composite key that does not relate to all portions of the composite key.
Third Normal Form
Third normal form (3NF) requires that there are no functional dependencies of non-key attributes on something other than a candidate key.
A table is in 3NF if all of the non-primary key attributes are mutually independent
There should not be transitive dependencies
Boyce-Codd Normal Form
BCNF requires that the table is 3NF and only determinants are the candidate keys