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Database Design Theory
Which tables to have in a database
Normalization
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Database Design Theory
Given some body of data to be represented in a database, as modelled in an E-R diagram, what is the most suitable logical structure for that data?
How do we decide on the appropriate tables and the attributes of the tables?
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Requirements
Accommodate data integrity. General integrity constraints
E.g., referential integrity Domain specific integrity constraints
E.g., no user can borrow more than 4 books.
Robust in the sense that the design should be application independent.
We try to achieve this through the elimination of redundancy.
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The Danger of Redundancy
Consider the example For students, we want to know student ID, name
and address. For courses, we need to know course ID, title and
lecturer. For employees, we need to know the employee ID,
name and department. For each department, we need to know the
department ID, the name and the location. For each enrollment, we need to know the grade.
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The Danger of Redundancy Continued One solution store everything in one big table
Appl(sid,name,addr,
cid,title,
eid, ename,
deptID, dname, loc,
grade) Clearly, this leads to redundancy.
For example, we need to store the student’s address for every course they have been registered for.
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The Danger of Redundancy. Conclusion If everything in one table, then
Greater space requirements Insertion anomalies
Cannot store information on student who has not passed a course yet.
Deletion anomalies We may want to delete a course but some student may be
registered only for that course. Update anomalies
If a student changes their address, many tuples need to be updated.
Danger of inconsistency in database.
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Good Database Design
The basic idea: A “good” database is one in which each table
consists of a primary key and a set of mutually independent attributes.
Strategy for achieving a good database design: Identify undesirable dependencies in a table and
decompose by projection.
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Functional Dependencies (FD’s)
Attribute (set) Y is functionally dependent on attribute (set) X if, whenever two tuples have the same value for X, they also have the same value for Y.
Notation: X Y X is called the determinant. An FD A B is non-trivial if and only if B A and
BA.
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Functional Dependencies in Our Example.
If everything is in one table, then these FD’s exist: sid name, addr cid title eid ename deptid dname, loc sid, cid grade
Note we also have sid, cid, eid, deptid
All other attributes
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Keys Again
A set of attributes X in a relation R is a superkey if every attribute in R is functionally dependent on X.
A candidate key is a minimal superkey. Alternate keys are candidate keys that have not
been selected as primary keys. A prime attribute is a member of a candidate key.
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Armstrong’s Axioms
Let X,Y and Z be sets of attributes of a relation R Reflexivity: (X Y) (X Y)
Augmentation
(X Y) (XZ YZ)
Transitivity
((X Y) & (Y Z)) (X Z)
Axioms are sound and complete Can derive all FDs that follow from a given set of
FDs. Derive only true FDs
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Some Consequences of Armstrong’s Axioms The following are implied by Armstrong’s axioms:
Decomposition
(X YZ) (X Y) Union
((X Y)&(X Z)) (X YZ) Pseudo transitivity
((X Y)&(WY Z)) (WX Z)
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Closure of a Set of Functional Dependencies If F is a set of functional dependencies, the
closure of F, F+, is the set of all functional dependencies logically implied by those in F.
Useful since it allows us to determine candidate keys (there must be functional dependency to all other attributes), but very expensive to compute.
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Closure Under a Set of Functional Dependencies Since F+ is too expensive to compute, we use
closure of X under a set of functional dependencies, X+.
(X Y) in F if and only if
Y X+. Since X+ is relatively easy to compute, we can
now verify whether X is a superkey.
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Computing X+.
To compute X+ under a set of FDs F:INPUT: X, F
OUTPUT: X+
S := X
WHILE
there is a (ZY) in F with Z S and Y S DO S := SY
ENDWHILE
X+ = S
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Decomposition
Recall that having identified undesirable FDs, we now need to decompose.
Decomposition: Let U be a relation scheme. A set of {R1,..,Rn} of
relation schemes is a decomposition of U if
R1 … Rn = U Every attribute of U occurs in at least one Ri.
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Desirable Properties of Decomposition
Decompositions should be Lossless Dependency preserving No redundancy Minimal number of tables
Sometimes, not all properties can be achieved simultaneously.
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Lossless Decomposition
Let {R1,..,Rn} a decomposition of U u relation instance over U Pi = Ri(u) for i from 1 to n
Then {R1,..,Rn} is a lossless decomposition if
u = P1 … P n
In other words, the original relation can be reconstructed.
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Dependency Preserving Decompositions
In decomposing a table, ensure that any FDs are easily enforceable.
Example: Relation U(A,B,C) FDs: A B, A C, B C If we decompose U into R(A,B) and S(B,C), then A
B, B C can be easily enforced when changing R or S.
Because of transitivity, A C is automatically enforced.
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Non-Dependency Preserving Decomposition
If we decompose U into R’(A,B) and S’(A,C), then enforcing A B and A C is easy.
However, B C becomes an interrelational constraint and can only be enforced through a join.
This decomposition is not dependency preserving.
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Normalization
Normal forms, as defined in relational database theory, are guidelines for the design of the tables in the database.
Normalization reduces redundancy. Important to remember why we want to avoid
redundancy Space requirements Insertion, deletion and update anomalies.
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The Normal Forms
First normal form Second normal form Third normal form Boyce-Codd normal form Fourth normal form Fifth normal form The normal forms are ordered in that everything in
2NF is also in 1NF. We ignore 5NF, as violations hardly occur in practice.
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First Normal Form
A relation is in 1NF iff the value of each attribute in a tuple is atomic.
A relation which is not in 1NF
sid cid grade
123 CS51S A
CS51T B
234 CS51S C
CS52S B
CS52T B
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Getting Tables into 1NF
Normalizing a table which is not in 1NF is easy: Simply repeat the other fields.
Thussid cid grade
123 CS51S A
123 CS51T B
234 CS51S C
234 CS52S B
234 CS52T B
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Second and Third Normal Form
Second and third normal form concern relationship between non-key and prime attributes.
Recall that a prime attribute is a member of a candidate key.
Under 2NF and 3NF, a non-key attribute value must provide a fact about the key, the whole key and nothing but the key.
Every non-prime attribute must be fully functionally dependent on a candidate key.
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Second Normal Form
2NF is violated when a non-key attribute depends on a proper subset of a candidate key.
The following violates 2NF
Result(cid, sid, name, grade)
as name is functionally dependent on sid alone.
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Dangers of Violating 2NF
Note that name is repeated for every course that a student has a grade for.
Problems: Danger of inconsistency if a student changes their
name, e.g., by getting married. If a student has not passed any courses yet, then
the student’s name cannot be stored.
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Getting Tables into 2NF
Decompose the table intoResult(cid, sid, grade)
Student(sid, name)
This decomposition leads to longer retrieval times for queries which involve joins.
Normalization is necessary to avoid anomalies which arise because of changes to attributes.
If little chance of changes, then sometimes do not normalize.
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Third Normal Form
Third normal form is violated when a non-prime attribute depends on another non-prime attribute.
The following violates 3NF
Empl(eid, dept, loc)
loc is a fact about dept. Danger same as violation of 2NF.
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Getting Tables into 3NF
Again, decomposeEmpl(eid, dept)
Department(dept, loc)
We can always restore 3NF through a lossless and dependency preserving decomposition.
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Boyce-Codd Normal Form (BCNF)
A relation scheme R is in BCNF if every determinant of a FD over R is a candidate key.
In other words, the determinant of every FD is a superkey.
Violation of BCNF R(A,B,C,D,E,F) { A BC, D AEF } D+ = ABCDEF
D is a good primary key. A+ = ABC
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Another Violation of BCNF
Assume that we give each registration for a course a unique registration number
Reg(rid, sid, cid, sname, grade)
FDs rid sid, cid sid, cid rid, grade sid sname rid+ = All attributes
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Getting Tables into BCNF
Decompose according to the FD whose determinant is not a superkey.
In our example, sid sname This gives
Reg(rid, sid, cid, grade) Stud(sid, sname)
Not always possible to get tables into BCNF while preserving all functional dependencies.
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Example where BCNF is not possible
Consider R(A,B,C) { AB C, C B}
Not in BCNF because C is not a superkey. However, every decomposition of R fails to be
dependency preserving as we have to split up the attributes in AB C
Have to settle for 3NF.
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Multivalued Dependencies (MVDs)
In an FD, X Y, knowing the value of X means that you know the unique value for Y.
In an MVD, X Y, knowing the value of X means that you know the set of values from which Y can come.
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Example of MVD
Assume we have two streams for some course, taught by different instructors, and that for each course, we use two textbooks.
Example:course instructor text
CS51T Rao Date
Mansingh Korth
CS52S Rao Jackson
Stitt Rich
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Example of MVD Continued
Putting table in 1NF givescourse instructor text
CS51T Rao Date
CS51T Rao Korth
CS51T Mansingh Date
CS51T Mansingh Korth
CS52S Rao Jackson
CS52S Rao Rich
CS52S Stitt Jackson
CS52S Stitt Rich
With primary key course, instructor, text
Since no FD, in BCNF.
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Redundancy because of MVDs
However, still redundancy in the table because if <c,p,x> and <c,p’,x’> in table <c,p’,x> and
<c,p,x’> in table too. The table contains two multivalued dependencies:
course instructor course text
Danger of insertion and update anomalies
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Fourth Normal Form
Under 4NF, a relation should not contain two or more independent MVDs.
In other words, if there is a MVD, X Y, then X should be a superkey.
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Getting Tables into 4NF
Again, get a table into 4NF through decomposition so that each MVD is captured in a separate table.
Example: CP(course, instructor) CT(course, text)
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Normalization Reconsidered
Normalization helps avoid: Insertion anomalies Update anomalies Deletion anomalies
Normalization increases retrieval time for some queries.