We've got a data warehouse design with four dimension tables and one fact table:
dimUser id, email, firstName, lastName
dimAddress id, city
dimLanguage id, language
dimDate id, startDate, endDate
factStatistic id, dimUserId, dimAddressId, dimLanguageId, dimDate, loginCount, pageCalledCount
Our problem is: We want to build the fact table which includes calculating the statistics (depending on userId, date range) and filling the foreign keys.
But we don't know how, because we don't understand how to use natural keys (which seems to be the solution to our problem according to the literature we read).
I believe a natural key would be the userId, which is needed in all ETL jobs which calculate the dimension data.
But there are many difficulties:
in the ETL jobs load(), we do bulk inserts with INSERT IGNORE INTO to remove duplicates => we don't know the surrogate keys which were generated
if we create meta data (including a set of dimension_name, surrogate_key, natural_key) this will not work because of the duplicate elimination
The problem seems to be the duplicate elimination strategy. Is there a better approach?
We are using MySQL 5.1, if it makes any difference.
If your fact table is tracking logins and page calls per user, then you should have set of source tables which track these things, which is where you'll load your fact table data from. I would probably build the fact table at the grain of one row per user / login date - or even lower to persist atomic data if at all possible.
Here you would then have a fact table with two dimensions - User and Date. You can persist address and language as dimensions on the fact as well, but these are really just attributes of user.
Your dimensions should have surrogate keys, but also should have the source "business" or "natural" key available - either as an attribute on the dimension itself, or through a mapping table as your colleague suggested. It's not "wrong" to use a mapping table - it does make things easier when there are multiple sources.
If you store the business keys on a mapping table, or in the dimension as an attribue, then for each row to load in the fact, it's a simple lookup (usually via a join) against the dim or mapping table to get the surrogate key for the user (and then from the user to get the user's "current" address / language to persist on the fact). The date dimension usually hase a surrogate key stored in a YYYYMMDD or other "natural" format - you can just generate this from the date information on your source record that you're loading into the fact.
do not force for single query, try to load the data in separated queries and mix the data in some provider...
Related
I am doing a course in BI development, and in order to solidify all the skills I have learned so far, I start a hands-on project (DWH design, ETL application, Data modeling and etc).
During the DWH design, I have encountered a dilemma, so I would appreciate getting some best practices from more experienced pros.
It got 2 dimension tables:
DimWeather - a table that stores weather data. Each row is a day. The primary key is, of course, the date of the corresponding day.
DimDate - a simple calendar table. The Primary key, in this case, is also a date.
Both tables are connected to a Fact table that stores a bike rental log.
Following DWH design best practices, I need to create a surrogate key - let's call it DateKey for both of the tables.
I am wondering, how to execute it in this situation?
To the best of my knowledge, the surrogate key for each table has to be unique but on the other hand this surrogate key has the same logic.
I would be glad to hear what you will do?
Thanks a lot for putting time and effort
In my opinion, DimWeather should be a fact table, if it stores measures and numerical data about the weather on specific date (temperature, air pressure, humidity, etc.) and dateID in this table should reference to "regular" DimDate table.
By definition, dimension tables should contain different attributes/hierarchies in order to put measures from fact table in specific context (time, location, demography, etc.). In your scenario, you would put weather measures in specific context (i.e. AVG temperature in NYC in February 2020; MAX humidity in LA in December 2019, etc. depending of the structure of your Weather table).
Other than that, surrogate key is just a non-meaning value (usually integer value with identity feature, to secure uniqueness of the key), EXCEPT for DimDate dimension, where you can give surrogate key meaning with creating integer values based on date value (for example: 20200311 for '2020-03-11'). Of course, it's not forbidden to use source primary key as a key in dimension table, but it's a bad practice, since it can happen that you have same value in different source systems and that can cause problems when you load data into DWH.
First project using star schema, still in planning stage. We would appreciate any thoughts and advice on the following problem.
We have a dimension table for "product features used", and the set of features grows and changes over time. Because of the dynamic set of features, we think the features cannot be columns but instead must be rows.
We have a fact table for "user events", and we need to know which product features were used within each event.
So it seems we need to have a primary key on the fact table, which is used as a foreign key within the dimension table (exactly the opposite direction from a conventional star schema). We have several different dimension tables with similar dynamics and therefore a similar need for a foreign key into the fact table.
On the other hand, most of our dimension tables are more conventional and the fact table can just store a foreign key into these conventional dimension tables. We don't like that this means that some joins (many-to-one) will use the dimension table's primary key, but other joins (one-to-many) will use the fact table's primary key. We have considered using the fact table key as a foreign key in all the dimension tables, just for consistency, although the storage requirements increase.
Is there a better way to implement the keys for the "dynamic" dimension tables?
Here's an example that's not exactly what we're doing but similar:
Suppose our app searches for restaurants.
Optional features that a user may specify include price range, minimum star rating, or cuisine. The set of optional features changes over time (for example we may get rid of the option to specify cuisine, and add an option for most popular). For each search that is recorded in the database, the set of features used is fixed.
Each search will be a row in the fact table.
We are currently thinking that we should have a primary key in the fact table, and it should be used as a foreign key in the "features" dimension table. So we'd have:
fact_table(search_id, user_id, metric1, metric2)
feature_dimension_table(feature_id, search_id, feature_attribute1, feature_attribute2)
user_dimension_table(user_id, user_attribute1, user_attribute2)
Alternatively, for consistent joins and ignoring storage requirements for the sake of argument, we could use the fact table's primary key as a foreign key in all the dimension tables:
fact_table(search_id, metric1, metric2) /* no more user_id */
feature_dimension_table(feature_id, search_id, feature_attribute1, feature_attribute2)
user_dimension_table(user_id, search_id, user_attribute1, user_attribute2)
What are the pitfalls with these key schemas? What would be better ways to do it?
You need a Bridge table, it is the recommended solution for many-to-many relationships between fact and dimension.
http://www.kimballgroup.com/data-warehouse-business-intelligence-resources/kimball-techniques/dimensional-modeling-techniques/multivalued-dimension-bridge-table/
Edit after example added to question:
OK, maybe it is not a bridge, the example changes my view.
A fundamental requirement of dimensional modelling is to correctly identify the grain of your fact table. A common example is invoice and line-item, where the grain is usually line-item.
Hypothetical examples are often difficult because you can never be sure that the example mirrors the real use case, but I think that your scenario might be search-and-criteria, and that your grain should be at the criteria level.
For example, your fact table might look like this:
fact_search (date_id,time_id,search_id,criteria_id,criteria_value)
Thinking about the types of query I might want to do against search data, this design is my best choice. The only issue I see is with the data type of criteria_value, it would have to be a choice/text value, and would definitely be non-additive.
I'm trying to design my first data mart with a star schema from an Excel Sheet containing informations about a Help Desk Service calls, this sheet contains 33 fields including different informations and I can't identify the fact table because I want to do the reporting later based on different KPI's.
I want to know how to identify the fact table measures easily and I have another question which is : Can a fact table contain only foreign keys of dimensions and no measures? Thanks in advance guys and sorry for my bad English.
You can have more than one fact table.
A fact table represents an event or process that you want to analyze.
The structure of the fact tables depend on the process or event that you are trying to analyze.
You need to tell us the events or processes that you want to analyze before we can help you further.
Can a fact table contain only foreign keys of dimensions and no measures?
Yes. This is called a factless fact table.
Let's say you want to do a basic analysis of calls:
Your full table might look like this
CALL_ID
START_DATE
DURATION
AGENT_NAME
AGENT_TENURE (how long worked for company)
CUSTOMER_NAME
CUSTOMER_TENURE (how long a customer)
PRODUCT_NAME (the product the customer is calling about)
RESOLVED
You would turn this into a fact table like this:
CALL_ID
START_DATE_KEY
AGENT_KEY
CUSTOMER_KEY
PRODUCT_KEY
DURATION (measure)
RESOLVED (quasi-measure)
And you would have a DATE dimension table, AGENT dimension table, CUSTOMER dimension table and PRODUCT dimension table.
Agile Data Warehouse Design is a good book, as are the ones by Kimball.
In general, the way I've done it (and there are a number of ways to do anything) is that the categorical data is referenced with a FKey in the fact table, but anything you want to perform aggregations on (typically as data types $/integers/doubles etc) can be in the fact table as well. So for example, a fact table might contain a hierarchy of types, such as product_category >> product_name, and it usually contains a time and/or location field as well; all of which would be referenced by a FKEY to a lookup table. The measure columns are usually integer based or money data, and are used in aggregate functions grouped by the other fields like this:
select sum(measureOne) as sum, product_category from facttable
where timeCol between X and Y group by product_category...etc
At one time a few years ago, I did have a fact table that had no measure column... because the only measure I had was based on count, which I would do dynamically by grouping different dimensions in the fact table.
If you have a relational database and you want to start making reports, you might do the following (please let me know if this is incorrect).
Go through your relational database and make a list of all the columns that you want to include in your report.
Group related columns together and then split those (normalise) into additional tables. These are the dimensions.
The dimensions then have a primary key (possibly a combination of two rows), and the fact table has a foreign key to reference each dimension, plus fields that you don't separate out in the first place such as sales value.
The question:
I was originally seeing dimensions as data marts that referenced data from external sources, and a fact table that in turn referenced data in the dimensions.. that's incorrect, isn't it? It's the other way around...
Or in general, if you were to normalise a database you would always replace the columns you take out a table with a foreign key, and add a primary key to the new table?
A fact table represents a process or event that you want to analyze.
Step 1: What is the process or event that you want to analyze?
The columns in the fact table represent all of the variables that are pertinent to your analysis.
Step 2: What variables are pertinent to the analysis?
Whether you "split-out" columns into dimension tables is irrelevant to your understanding. It's an optimization to minimize the space taken up by fact tables.
If you want to discriminate between measures and dimensions, ask
Step 3: What are the (true) numeric values in my fact table? These are your measures.
An example of a true numeric value is a dollar amount, like Sales Order Line Item Extended Price. You can sum it up or take an average of it.
An example of a not true numeric value is Customer ID 12345. It's a number, but represents something that isn't a number (a customer). The sum of customer ids makes no sense, nor does the average. Dig?
Regarding your questions:
Fact tables do not need foreign keys to dimension tables. (hint: see Hot-Swappable Dimensions)
"dimensions as data marts that referenced data from external sources". Hm...maybe, but don't worry about data marts for now. A dimension is just a column in your fact table (that isn't a measure). A dimension table is just a collection of dimensions that are related.
Just start with Excel. Figure out the columns you need in your analysis. Put them in Excel. That's your fact table. If you expect your fact table to get large (100s of MB), then do ONE level of normalization:
Figure out your measures. Leave them in the fact table.
Figure out your dimensions. Group them together (Customer info into one group, Store info into another).
Put them in their own tables. Give them meaningless surrogate keys. Put those keys in the fact table.
I currently have a model Feature that is used by various other models; in this example, it will be used by customer.
To keep things flexible, Feature is used to store things such as First Name, Last Name, Name, Date of Birth, Company Registration Number, etc.
You will have noticed a problem with this - while most of these are strings, features such as Date of Birth would ideally be stored in a column of type Date (and would be a datepicker rather than a text input in the view).
How would this best be handled? At the present time I simply have a string column "value"; I have considered using multiple value columns (e.g. string_value, date_value) but this doesn't seem particularly efficient as there will always be a null column in every record.
Would appreciate any advice on how to handle this - thanks!
There are a couple of ways I could see you going with this, depending on your needs. I'm not completely satisfied with any of these, but perhaps they can point you in the right direction:
Serialize Everything
Rails can store any object as a byte stream, and in Ruby everything is an object. So in theory you could store string representations of any object, including Strings, DateTimes, or even your own models in a database column. The Marshal module handles this for you most of the time, and allows you to write your own serialization methods if your objects have special needs.
Pros: Really store anything in a single database column.
Cons: Ability to work with data in the database is minimal - It's basically impossible to use this column as anything other than storage - you (probably) wouldn't be able to sort or filter your data based on it, since the format won't be anything the database will recognize.
Columns for every datatype
This is basically the solution you suggested in the question - figure out exactly which datatypes you might need to store - you mention strings and datestamps. If there aren't too many of those, it's feasible to simply have a column of each type and only store data in one of them. You can override the attribute accessor functions to use the proper column, and from the outside, Feature will act as though .value is whatever you need it to be.
Pros: Only need one table.
Cons: At least one null value in every record.
Multiple Models/Tables
You could make a model for each of the sorts of Feature you might need - TextFeature, DateFeature, etc. This guide on Multiple Table Inheritance conveys the idea and methodology.
Pros: No null values - every record contains only the columns it needs.
Cons: Complexity. In addition to needing multiple models, you may find yourself doing complex joins and unions if you need to work directly with features of different kinds in the database.