Kimball methodology is intended for for designing, developing, and deploying data warehouse/business intelligence systems, as described in The Data Warehouse Lifecycle Toolkit. There are other names for the Kimball approach that we will be discussion shortly.
- Bottom-up approach for data warehousing
- Kimball's dimensional modelling
- Data warehouse lifecycle model by Kimball
Summary of Kimball methodology
- Starts with one data mart (ex. sales); later on additional data marts are added (ex. collection, marketing, etc.)
- Data flows from source into data marts, then into the data warehouse
- Kimball approach is faster to implement as it is implemented in stages
Before we go ahead with details of the methodology, let us take a quick view on some essential definitions of the terms used.
Data mart is a specific, subject-oriented repository of data that was designed to answer specific questions. Usually, multiple data marts exist to serve the needs of multiple business units (sales, marketing, operations, collections, accounting, etc.)
Data warehouse is a single organizational repository of enterprise wide data across many or all subject areas. Data warehouse is an enterprise wide collection of data marts. Data warehouse is the foundation for business intelligence.
Business Intelligence refers to reporting and analysis of data stored in the warehouse.
The Kimball Lifecycle Diagram
Kimball lifecycle diagram illustrates the flow of data warehouse implementation. It identifies task sequencing and highlights activities that should happen concurrently. Activities may need to be customized to address the unique needs of the organization. Also,not every detail of every lifecycle task will be required on every project - this has to be decided as per need.
As per Kimball Lifecycle, we start building a data warehouse with understanding business requirements and determining how best to add value to the organization. The organization must agree on what the value of this data is before deciding to build a data warehouse to hold it. Once the requirements are gathered, implementation phase begins with design steps across three different tracks - technology, data, and BI applications. Once we are done with this implementation, the Lifecycle comes back together to deploy the query tools, reports, and applications to the user community.
The incremental approach of the Lifecycle helps to deliver business value in a short span of time and at the same time helps to build a enterprise wide information resource in a long term.
Lets get little deeper into the Kimball guideline as per the Lifecycle diagram.
Business Requirements Definition
Success of the project depends on a solid understanding of the business requirements. Understanding the key factors driving the business is crucial for successful translation of the business requirements into design considerations. There are many methods and tools to ensure requirement gathering is best done - we will not dwell more into it now.
What follows business requirement definition is three concurrent tracks focusing on
- Business intelligence applications
Technical Architecture Design
Objective here is to finalize overall architectural framework and vision. We do this based on consider business requirements, current technical environment, and planned strategic technical directions of the organization. Based on the technical architecture, we do:
- Evaluation and selection of
Products that will deliver needed capabilities
Database management system
Extract-transformation-load (ETL) tools
Data access query tools
Reporting tools must be evaluated
- Installation of selected products/components/tools
- Testing of installed products to ensure appropriate end-to-end integration within the data warehouse environment.
Data track - Dimensional modeling
Data track primaraly deals with design of the dimensional model. Dimensional modeling is a vast subject area comprising of many methods, suggestions, and best practices. Here, a detailed data analysis of a single business process is performed to identify the fact table granularity, associated dimensions and attributes, and numeric facts. Primary constructs of a dimensional model are fact tables and dimension tables. Two important design menthods in dimension modeling are - star schema and snowflake schema.
Star schema contains a central fac table directly connected to dimension table. The snowflake schema is a variation of the star schema used in a data warehouse. The snowflake schema is a more complex schema than the star schema because the tables which describe the dimensions are normalized
We start with a logical data model definition and then proceed to physical design of the model. In physical design, we define the data structures. Some key activities include:
- setting up the database environment
- setting up appropriate security
- preliminary performance tuning strategies, from indexing to partitioning and aggregations.
- if required, OLAP databases are also designed during this process.
ETL design and development
This is by far the most important stage of the lifecycle and it take 70% of the effort to achieve. In this stage, we perform extraction, transformation, and loading (ETL) of source data into the target models. Raw data is extracted from the operational source systems and is being transformed into meaningful information for the business. Data quality conditions are continuously monitored.
Kimball calls ETL a “data warehouse back room”. ETL system strives to deliver high throughput, as well as high quality output.
BI Application track
BI applications deliver business value from the DW/BI solution, rather than just delivering the data. The goal is to deliver capabilities that are accepted by the business to support and enhance their decision making.
First, we start to identify the candidate BI applications and appropriate navigation interfaces to address the users’ needs and needed capabilities. This will give desired specification of the tool required. Later, we configure the business metadata and tool infrastructure. This is followed by construction and validation of the specified analytic and operational BI applications and the navigational portal.
Deployment should be deferred until all the pieces such as training, documentation, and validated data are not ready for production release. Also, it is critical that deployment be well orchestrated and adequately planned.
Deployment should ensure the results of technology, data, and BI application tracks are tested and fit together properly. While deploying the solution, appropriate education and support infrastructure has to be in place.
Maintenance begins once the system is deployed into production. Maintenance work ensures ongoing support, education, and communication with business users. Also, technical operational tasks that are necessary to keep the system performing optimally are conducted as needed. Usage monitoring, performance tuning, index maintenance, and system backup are done periodically by technical experts.
Organization has to reason to be happy if the data warehouse system tends to grow. DW growth is considered as a symbol of success. There may be new requests which requires attention. The key here is to build upon the foundation that has already been established.
The Data Warehouse Toolkit by Ralph Kimball