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INTRODUCTION Increasingly, organizations are analyzing
current and historical data to identify useful patterns and support business strategies (Decision Support).
Emphasis is on complex, interactive, exploratory analysis of very large datasets created by integrating data from across all parts of an enterprise; data is fairly static.
Contrast such On-Line Analytic Processing (OLAP) with traditional On-line Transaction Processing (OLTP): mostly long queries, instead of short update transactions.
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DATA WAREHOUSING A Data Warehouse is a collection of data for
the purpose of decision support that is: subject oriented - Data that gives information
about a particular subject instead of about a company's ongoing operations.
Integrated - Data that is gathered into the data warehouse from a variety of sources and merged into a coherent whole.
time variant - All data in the data warehouse is identified with a particular time period.
non volatile - Data is stable in a data warehouse. More data is added but data is never removed. This enables management to gain a consistent picture of the business.
(Source: "What is a Data Warehouse?" W.H. Inmon, Prism, Volume 1, Number 1, 1995).
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DATA WAREHOUSING Integrates data from several operational
(OLTP) databases. Keeps (relevant part of the) history of the
data. Views data at a more abstract level than OLTP
systems (aggregate over many detail records).
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DBS FOR DECISION SUPPORT Database:
an application that manages data and allows fast storage and retrieval of that data
A transaction makes small changes Data Warehouse:
a centralized database Consolidate data from many sources in one large
repository Loading, periodic synchronization of replicas Semantic integration
OLAP: Complex SQL queries and views Queries based on “multidimensional” view of data
and spreadsheet-style operations. Interactive and “online” (manual) analysis.
Data Mining: Automatic discovery of interesting trends and other patterns.
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OLTP VS DW Data warehouses and OLTP systems have very different
requirements:
Workload DW
designed to accommodate ad hoc queries might not know the workload of your data warehouse in advance should be optimized to perform well for a wide variety of queries
OLTP support only predefined operations (ordering books, searching, etc)
Data modifications DW
Updated on a regular basis by the ETL process (run nightly or weekly) Uses bulk data modification techniques The end users of a data warehouse do not directly update the data
warehouse OLTP
end users routinely issue individual data modification statements always up to date reflects the current state of each business transaction
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OLTP VS DW Data warehouses and OLTP systems have very different
requirements:
Historical data DW
usually store many months or years of data to support historical analysis
OLTP usually store data from only a few weeks or months only historical data as needed to successfully meet the current
transaction
Typical operations DW
A typical query scans thousands or millions of rows For example, "Find the total sales for all customers last month."
OLTP accesses only a handful of records For example, "Retrieve the current order for this customer."
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OLTP VS DW Data warehouses and OLTP systems have very different
requirements:
Schema design DW
denormalized or partially denormalized schemas Optimized for query performance Called a Star schema
OLTP fully normalized schemas to optimize update/insert/delete performance To guarantee data consistency
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STAR VS DB SCHEMA consists of one or more fact tables referencing
any number of dimension tables more effective for handling simpler queries
Fact Table consists of the measurements, metrics or facts of a
business process often located at the centre of a star schema
surrounded by dimension tables Ex: SALES fact table might contain data uniquely
defined by a day, product and store. Dimension tables
provides the means to "slice and dice" data provide structured labeling information to otherwise
unordered numeric measures Ex: "Customer", "Date", and "Product"
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STAR SCHEMA Consists of a collection of dimensions
(independent variables) and (numeric) facts (dependent variables).
Each entry (cell) aggregates the value(s) of the measure(s) for all records that fall into that cell i.e. for all records that in each dimension have
attribute values corresponding to the value of the cell in this dimension.
Example: dimensions Product (pid), Location (locid), and Time (timeid) and measure Sales.
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STAR SCHEMA
In order to see the total sales for a particular month for a particular category, a SQL query would look something like this:
SELECT Sum(SalesFact.SalesDollars) AS SumOfSalesDollars
FROM TimeDimension INNER JOIN (ProductDimension INNER JOIN
SalesFact ON ProductDimension.ProductID = SalesFact.ProductID)
ON TimeDimension.TimeID = SalesFact.TimeID
WHERE ProductDimension.Category='Brass Goods'
AND TimeDimension.Month=3
AND TimeDimension.Year=1999
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MULTIDIMENSIONAL DATA MODEL
11 1 1 25
11 2 1 8
11 3 1 15
12 1 1 30
12 2 1 20
12 3 1 50
13 1 1 8
13 2 1 10
13 3 1 10
11 1 2 35
pid
tim
eid
loci
dsa
les
8 10 10
30 20 50
25 8 15
1 2 3 timeid
p
id11
12
13
locid
Slice locid=1is shown
Tabular representation
Multidimensional representation
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DATA WAREHOUSING ISSUES Semantic integration: When getting data
from multiple sources, must eliminate mismatches, e.g., different currencies, DB schemas.
Heterogeneous sources: Must access data from a variety of source formats and repositories. Replication capabilities can be exploited here.
Load, refresh, purge: Must load data, periodically refresh it, and purge too-old data.
Metadata management: Must keep track of source, loading time, and other information for all data in the warehouse.
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MULTIDIMENSIONAL DATA MODEL For each dimension, the set of values can be
organized in a concept hierarchy (subset relationship), e.g.
PRODUCT TIME LOCATION
category week month state
pname date city
year
quarter country
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MULTIDIMENSIONAL DATA MODEL Multidimensional data can be stored
physically in a (disk-resident, persistent) array; called MOLAP (multi-dimensional OLAP) systems.
Alternatively, can store as a relation; called ROLAP (relational OLAP) systems.
The main relation, which relates dimensions to a measure, is called the fact table.
Each dimension can have additional attributes and an associated dimension table.
E.g., fact table Transactions(pid, locid, timeid, sales) and (one of the) dimension table Products(pid, pname, category, price)
Fact tables are much larger than dimensional tables.
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OLAP QUERIES Influenced by SQL and by spreadsheets. A common operation is to aggregate a
measure over one or more dimensions. Find total sales. Find total sales for each city, or for each state. Find top five products ranked by total sales.
We can aggregate at different levels of a dimension hierarchy. A roll-up operation aggregates along the next higher level of the dimension hierarchy. E.g., given total sales by city, we can roll-up to
get sales by state.
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OLAP QUERIES Drill-down: The inverse of roll-up.
E.g., given total sales by state, can drill-down to get total sales by city.
E.g., can also drill-down on different dimension to get total sales by product for each state.
Pivoting: Aggregation on selected dimensions. E.g., pivoting on Location and Time
yields this cross-tabulation:
Slicing and Dicing: Equality and range selections on one or more dimensions.
63 81 144
38 107 145
75 35 110
WI CA Total
1995
1996
1997
176 223 339Total
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COMPARISON WITH SQL QUERIES The cross-tabulation obtained by pivoting can
also be computed using a collection of SQL queries, e.g.
SELECT SUM(S.sales)FROM Sales S, Times T, Locations LWHERE S.timeid=T.timeid AND S.timeid=L.timeidGROUP BY T.year, L.state
SELECT SUM(S.sales)FROM Sales S, Times TWHERE S.timeid=T.timeidGROUP BY T.year
SELECT SUM(S.sales)FROM Sales S, Location LWHERE S.timeid=L.timeidGROUP BY L.state
SELECT SUM(S.sales) FROM Sales S
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THE CUBE OPERATOR Generalizing the previous example, if there
are d dimensions, we have 2d possible SQL GROUP BY queries that can be generated through pivoting on a subset of dimensions (without considering selections of specific values for certain dimensions).
A Data Cube is a multi-dimensional model of a datawarehouse where the domain of each dimension is extended by the special value „ALL“ with the semantics of aggregating over all values of the corresponding dimension.
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THE CUBE OPERATOR The Cube Operator computes the measures
for all cells (evaluates all possible GROUP BY queries) at the same time.
It can be much more efficiently processed than the set of all corresponding (independent) SQL GROUP BY queries.
Observation: The results of more generalized queries (with fewer GROUP BY attributes) can be derived from more specialized queries (with more GROUP BY attributes) by aggregating over the irrelevant GROUP BY attributes.
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THE CUBE OPERATOR Process more specialised queries first and,
based on their results, determine the outcome of more generalised queries.
Significant reduction of I/O cost, since intermediate results are much smaller than original (fact) table.
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THE CUBE OPERATOR Lattice of GROUP-BY queries of a CUBE query
w.r.t. derivability of the results Example
{pid, locid, timeid}
{pid, locid} {pid, timeid} {locid, timeid}
{pid} {locid} {timeid}
{}
{A,B,. . .}: set of GROUP BY attributes, X Y: Y derivable from X
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THE CUBE OPERATOR An entry of a data cube is called a cell. The number of cells of a datacube with d
dimensions is
Each SQL group corresponds to a datacube cell.
A single GROUP BY of the 2d different SQL GROUP BY queries can compute the measures for multiple datacube cells.
)1|(|1
d
iiDomain
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IMPLEMENTATION ISSUES In the following, adopting a ROLAP
implementation. Fact table normalized (redundancy free). Dimension tables un-normalized. Dimension tables are small;
updates/inserts/deletes are rare. So, anomalies less important than query performance.
This kind of schema is very common in OLAP applications, and is called a star schema; computing the join of all these relations is called a star join.
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IMPLEMENTATION ISSUES Example star schema
price
category
pname
pid country
statecitylocid
sales
locidtimeid
pid
holiday_flag
weekdate
timeid month
quarter
year
SALES
TIMES
PRODUCTS LOCATIONS
Fact table: SalesDimension tables: Times, Products, Locations
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BITMAP INDEXES New indexing techniques: Bitmap indexes,
Join indexes, array representations, compression, precomputation of aggregations, etc.
Example Bitmap index: (maps the index to a bit)
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112 Joe M 3115 Ram M 5
119 Sue F 5
112 Woo M 4
00100000010000100010
sex custid name sex rating ratingM
FBit-vector:1 bit for eachpossible value.
One row per record.
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BITMAP INDEXES Selections can be processed using (efficient!)
bit-vector operations. Example 1: Find all male customers
Example 2: Find all male customer with a rating of 3 AND the relevant bit-vectors from the bitmap indexes for sex and rating
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112 Joe M 3115 Ram M 5
119 Sue F 5
112 Woo M 4
00100000010000100010
sex custid name sex rating rating
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JOIN INDEXES Consider the join of Sales, Products, Times,
and Locations, possibly with additional selection conditions (e.g., country=“USA”).
A join index can be constructed to speed up such joins (in a relatively static data warehouse). It basically materializes the result of a join.
The index contains [s,p,t,l] if there are tuples with sid s in Sales, pid p in Products, timeid t in Times and locid l in Locations that satisfy the join (and selection) conditions.
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JOIN INDEXES Problem: Number of join indexes can grow
rapidly. In order to efficiently support all possible
selections in a data cube, you need one join index for each subset of the set of dimensions.
E.g, one join index each for[s,p,t,l], [s,p,t], [s,p,l], [s,t,l], [s,p], [s,t], [s,l]
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BITMAPPED JOIN INDEXES A variation of join indexes addresses this
problem, using the concept of Bitmap indexes.
For each attribute of each dimension table with an additional selection (e.g., country), build a Bitmap index.
Index contains, e.g., entry [c,s] if a dimension table tuple with value c in the selection column joins with a Sales tuple with sid s. Note that s denotes the compound key of the fact table, e.g. [pid, timeid, locid].
The Bitmap index version is especially efficient (Bitmapped Join Index).
Makes sense? Good!
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BITMAPPED JOIN INDEXES
Consider a query with conditions price=10 and country=“USA”. Suppose tuple (with sid) s in Sales joins with a tuple p with price=10 and a tuple l with country =“USA”. There are two (Bitmap) join indexes; one containing [10,s] and the other [USA,s].
Intersecting these indexes tells us which tuples in Sales are in the join and satisfy the given selection.
price
category
pname
pid country
statecitylocid
sales
locidtimeid
pid
holiday_flag
weekdate
timeid month
quarter year
SALES
TIMES
PRODUCTS LOCATIONS
10
s
USA
10,s,USA
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SEQUENCES IN SQL SQL-92 supports only (unordered) sets of
tuples. Trend analysis is difficult to do in SQL-92, e.g.:
Find the % change in monthly salesFind the top 5 product by total salesFind the trailing n-day moving average of sales
The first two queries can be expressed with difficulty, but the third cannot even be expressed in SQL-92 if n is a parameter of the query.
The WINDOW clause in SQL:1999 allows us to formulate such queries over a table viewed as a sequence of tuples based on user-specified sort keys
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THE WINDOW CLAUSE A window is an ordered group of tuples
around each (reference) tuple of a table.
The order within a window is determined based on an attribute specified by the SQL statement.
The width of the window is also specified by the SQL statement.
The tuples of the window can be aggregated using the standard (set-oriented) SQL aggregate functions (SUM, AVG, COUNT, . . .).
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THE WINDOW CLAUSE
Let the result of the FROM and WHERE clauses be “Temp”.
Conceptually, Temp is partitioned according to the PARTITION BY clause.
Similar to GROUP BY, but the answer has one tuple for each tuple in a partition, not one tuple per partition!
Each partition is sorted according to the ORDER BY clause.
SELECT L.state, T.month, AVG(S.sales) OVER W AS movavgFROM Sales S, Times T, Locations LWHERE S.timeid=T.timeid AND S.locid=L.locidWINDOW W AS (PARTITION BY L.state
ORDER BY T.monthRANGE BETWEEN INTERVAL `1’ MONTH PRECEDINGAND INTERVAL `1’ MONTH FOLLOWING);
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THE WINDOW CLAUSE
For each tuple in a partition, the WINDOW clause creates a “window” of nearby (preceding or succeeding) tuples. Definition of window width can be value-based, as in
example, using RANGE. Can also be based on number of tuples to include in
the window, using ROWS clause. The aggregate function is evaluated for each
tuple in the partition based on the corresponding window.
SELECT L.state, T.month, AVG(S.sales) OVER W AS movavgFROM Sales S, Times T, Locations LWHERE S.timeid=T.timeid AND S.locid=L.locidWINDOW W AS (PARTITION BY L.state
ORDER BY T.monthRANGE BETWEEN INTERVAL `1’ MONTH PRECEDINGAND INTERVAL `1’ MONTH FOLLOWING);
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TOP N QUERIES Sometimes, want to find only the „best“
answers (e.g., web search engines). If you want to find only the 10 (or so)
cheapest cars, the DBMS should avoid computing the costs of all cars before sorting to determine the 10 cheapest.
Idea: Guess a cost c such that the 10 cheapest cars all cost less than c, and that not too many other cars cost less than c.
Then add the selection cost<c and evaluate the query.
If the guess is right: we avoid computation for cars that cost more than c.
If the guess is wrong: need to reset the selection and recompute the original query.
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TOP N QUERIES
„Cut-off value“ c is chosen by query optimizer
SELECT TOP 10 P.pid, P.pname, S.salesFROM Sales S, Products PWHERE S.pid=P.pid AND S.locid=1 AND S.timeid=3ORDER BY S.sales DESC
SELECT P.pid, P.pname, S.salesFROM Sales S, Products PWHERE S.pid=P.pid AND S.locid=1 AND S.timeid=3
AND S.sales > cORDER BY S.sales DESC
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ONLINE AGGREGATION Consider an aggregate query, e.g., finding the
average sales by state. If we do not have a corresponding
(materialized) data cube, processing this query from scratch can be very expensive.
In general, we have to scan the entire fact table.
But the user expects interactive response time.
An approximate result may be acceptable to the user.
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ONLINE AGGREGATION Can we provide the user with some
approximate results before the exact average is computed for all states?
Can show the current “running average” for each state as the computation proceeds.
Even better, we can use statistical techniques and sample tuples to aggregate instead of simply scanning the aggregated table.
E.g., we can provide bounds such as “the average for Wisconsin is 2000 ± 102 with 95% probability“.
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