This study guide is a collection of my notes for the class CS 6400 (Database Systems Concepts And Design) at Georgia Tech.

Chapter 1 - Databases and Database Users

1.1 | Introduction

The word database is so commonly used that we must first begin by defining what a database is.

In the simplest, most general terms, a database is a collection of data. By data, we mean known facts that can be recorded and have implicit meaning.

For example, people’s names, telephone numbers, addresses, etc..

However (for our needs) this definition of a database is too general; for example, we may consider the collection of words that make up this post to be related and hence to constitute a database. However, the common use of the term database is usually more restricted. A database has the following implicit properties:

• A database represents some aspect of the real world, sometimes called the miniworld or the universe of discourse (UoD). Changes to the miniworld are reflected in the database
• A database is a logically coherent collection of data with some inherent meaning. A random assortment of data cannot be correctly referred to as a database
• A database is designed, built, and populated with data for a specific purpose. It has an intended group of users and some application(s) that interact with it. The users themselves interact with the application (user -> application -> database)

In other words, a database has some source from which data is derived, some degree of interaction with events in the real world, and an audience that is actively interested in its contents. In order for the database to be accurate and reliable at all times, it must be a true reflection of the miniworld that it represents. Therefore, changes must be reflected in the database as soon as possible.

A database may be generated and maintained manually or it may be computerized. A computerized database may be created and maintained either by a group of application programs written specifically for that task or by a database management system.

A database management system (DBMS) is a computerized system than enables users to create and maintain a database. The DBMS is a general-purpose software system that facilitates the processes of defining, constructing, manipulating, and sharing databases among users and applications.

• Defining a database involves specifying the data types, structures, and constraints of the data to be stored in the database. The database definition is itself stored by the DBMS in the form of a database “catalog” or “dictionary”; it is callied metadata
• Constructing the database is the process of storing the data on some storage medium that is controlled by the DBMS
• Manipulating a database includes querying the database, updating the database to reflect changes in the miniworld, and generating reports from the data
• Sharing a database means allowing multiple users and programs to access the database concurrently

An application accesses the database by sending queries to the DBMS. A query causes some data to be retrieved; a transaction may cause some data to be read and some data to be written to the database.

Other important functions provided by the DBMS include protecting the database and maintaining it over time. Protection includes system protection against hardware or software malfunctions (crashes) or security protections against unauthorized access.

It is not absolutely necessary to use general-purpose DBMS software to implement a computerized database. It is possible to write a customized set of programs to create and maintain the database, in effect creating a special-purpose DBMS software for a specific application, such as airlines reservations.

Finally, to complete our initial definitions, we will call the database and DBMS software together a database system.

1.2 | Example

Consider an example, a university database to maintain information concerning:

• students
• courses
• sections
• grade report
• course prerequisites

The database is organized as five files, each of which stores data records of the same type.

First we need to define the database. For this, we must specify the structure of the records of each file by specifying the different types of data elements to be stored for each record as well as their data types (e.g., string, integer, decimal, etc..).

To construct the university database we store data to represent each student, course, section, grade report, and prerequisite as a record in the appropriate file. Notice that records in the various files may be related. For example the record for student Smith in the STUDENT file is related to records in the GRADE_REPORT file that specify Smith’s grades in two sections. Most databases include records that have many relationships between them.

Database manipulation involves querying and updating.

The design of a new application for an existing database or design of a brand new database starts off with a phase called requirements specification and analysis.

These requirements are documented in detail and transformed into a conceptual design that can be represented and manipulated using some computerized tools so that it can be easily maintained, modified, and transformed into a database implementation (Entity-Relationship model).

The design is then translated to a logical design that can be expressed in a data model implemented in a commercial DBMS.

The final stage is physical design, during which further specifications are provided for storing and accessing the database. The database design is implemented, populated with actual data, and continuously maintained to reflect the state of the miniworld.

1.3 | Characteristics of the Database Approach

A number of characteristics separate the database approach from the much older approach of writing custom programs to access data stored in files.

In traditional file processing each user defines and implements the files needed for a specific software application as part of programming the application. For example, one user, the grade reporting office, may keep files on students and their grades. Custom features like printing a student’s transcript and to enter new grades are implemented as part of that application. A second user, the accounting office, may keep track of student’s fees and their payments. Although both users are interested in data about students, each maintains their own separate files – because each requires some data not available from the other user’s files. This workflow results in redundancy and wasted storage space on top of making it more complicated to maintain common data.

In the database approach, the source of data is in a single source of truth. In other words, a single repository maintains our data. This data is defined once and can be accessed by various users repeatedly through queries, transactions, and programs.

The main characteristics of the database approach vs the file-processing approach are the following:

• Self-describing nature of a database system
• Isolation between programs and data, and data abstraction
• Support of multiple views of the data
• Sharing of data and multi-user transaction processing

1.3.1 | Self-Describing Nature of a Database System

A fundamental characteristic of the database approach is that the database system not only contains the database itself but also a complete description of the database structure and constraints (structure of each file, type and format of each data item, etc). This description is stored in the DBMS catalog and is called the meta-data – which (again) is describing the structure of the primary database.

It is important to note that some newer types of database systems, known as NOSQL systems, do not require meta-data. Rather the data is stored as self-describing data that includes the data item names and data values together in one structure (e.g., JSON).

The catalog is used by the DBMS software and by users who need info on the database structure.

In traditional file processing, data definition is part of the program itself. Therefore programs are tightly coupled with that definition. This is not the case with using a database which provides an abstraction over reading the actual data and we simply interact with the database. It handles all the details of how to read the data based on its structure and format using the description it has stored in the data catalog.

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Lecture Notes

Conceptual schema -> refers to meaning of data

• Describes structural aspects of reality. For example, the table name, column names

External schema -> refers to use of data

• External schema here basically refers to a database “view”. It is derived from the “conceptual schema” in the sense that we use information like the underlying table name and column names to define the view definition (i.e., the query to create the view)
• Note a view is not an actual table, it is created in memory at run time

Internal schema -> refers to storage of data

• Describes how the info in the conceptual schema is physically stored to provide the best performance (e.g., defining an index, or multiple, using a datastructure like a B+ tree which allows logarithmic time access to data which helps run queries faster)

These three schema levels in the ANSI-SPARC architecture allows for two types of independence

1. Physical data independence: a measure of how much the internal schema can change without affecting the application programs. Basically, we can add more indexes, insert/remove rows and still our application is completely decoupled and does not care or need to know about the internal logic and rules of how this data is read off the disk – this is also known as separation of concerns. There is a similar concept in object oriented programming called encapsulation. As long as the method signatures remain the same, the implementation can change and the consumers will not be affected.

2. Logical data independence: a measure of how much you can change the conceptual schema without changing the application that run on top of the external schema. It is more difficult to provide logical data independence than logical data independence because the external schema is directly linked to the definition of the conceptual schema. If we change the underlying table definition the view (which uses that) is also affected and needs to be changed

Entity Relationship Model (ER) and Extended Entity Relationship Model (EER)

Entity Types

• Represented as a box in an ER diagram
• An entity is a thing that we are representing in our miniworld
• Entity type names must be unique

Single Valued Properties

Properties of an entity are represented by an ellipsis and are connected to their respective entity via a line.

As the name implies, a single valued property is a property than can only take a single value.

Property values can be lexical (string), visible (picture), audible (song), etc..

They are things that name other things

Identifying properties

Represented on the ER diagram as a property type but its name is underlined via a solid line.

The implication of a property type being an “identifying property” is that for a value v only one entity can have this value for this property.

Therefere this makes our entity uniquely referenceable

Composite Properties

A property that is composed of multiple other properties. For example a property name can be composed of two other properties: first name and last name

Composite properties are represented as ellipses connected by a line to the main property

Multivalued Properties

Represented by a double ellipsis. A multivalued property has multiple values as its value.

For example a multivalue property “interests” could take the values of “math, chess, and reading”.

1-1 Relationship Type

A one-to-one relationship is a relationship where a record in one table is associated with exactly one record in another table.

Denoted as 1:1

A relationship is represented as a diamond with the relationship name inside.

An example relationship of this type is Male <--- marriage ---> Female where marriage is the relationship.

What this says is that a Male entity can be married to exactly one Female entity and a Female is married to exactly one Male.

A one to one relationship type is a partial function. It is a function because every record in one table is related to at most one record in the other table. It is partial because some entities may not necesarily have a relationship between them.

Note: the names of multiple relationship types between the same two entity types must be unique

1-many Relationship Type

A ONE-TO-MANY RELATIONSHIP is where a record in one entity (table) can be referenced by multiple records in another entity (table).

Denoted as 1:N

For example, a relationship between Employer and RegularUser. A single employer can be referenced by many users. And a regular user is only going to reference one employer.

This is still a partial function going from regular user to employer because each user is going to reference at most one employer. It is not a function from employer to user because a single employer can map to many users. It is partial because it is not neccesary for all users to have an employer

Mandatory 1-many relationship types

Represented by a bold or double line connecting the entity with a mandatory relationship to the relationship “diamond” figure. In our previous example with Employer and Regular User, if we set the relationshop “employs” to have a mandatory relaionship with user then every user in our entity list MUST have a reference to an Employer. And because of this, it would be a total function going from RegularUser to Employer

N-M Relationship Type (N:M)

By definition, a many-to-many relationship is where more than one record in a table is related to more than one record in another table.

It is rare to see relationships combining more than three entities.

Unfortunately, it is not always possible to split an N-ary relationship into a conjunction of multiple binary relationships.

Identifying relationships / weak entity types

A weak entity type is an entity that cannot exist without another entity present.

A wek entity is represented by a double rectangle.

An identifying relationship is a relationship that connects a weak entity type to another entity. This type of relationship is represented by a double diamond.

For example, consider an entity type StatusUpdate which has a property DateAndTime. This entity cannot exist without being related to a RegularUser because many StatusUpdates can have the same DateAndTime, so we need RegularUser to tie a StatusUpdate to a regular user which has a primary key of Email to help us uniquely identify a RegularUser. Thus, <Email, DateAndTime> uniquely identifies a StatusUpdate and DateAndTime is a partial identifier.

Constraints

Keys

Primary keys:

• An attribute that uniquely identifies a row in a table
• No other entry in the database can have the same value for this attribute
• Primary keys CANNOT be NULL
• When an attribute that is a primary key in one table is used in another table, the following must be obeyed: the list of all the attributes used in the other table must be a subset of the values of the primary key attribute in the main table

Entity integrity

Referential integrity