DBMS_DATA_MINING_TRANSFORM
implements a set of transformations that are commonly used in data mining.
This chapter contains the following topics:
Using DBMS_DATA_MINING_TRANSFORM
Overview
Operational Notes
Security Model
Types
Constants
This section contains topics that relate to using the DBMS_DATA_MINING_TRANSFORM
package.
A transformation is a SQL expression that modifies the data in one or more columns.
Data must typically undergo certain transformations before it can be used to build a mining model. Many data mining algorithms have specific transformation requirements.
Data that will be scored must be transformed in the same way as the data that was used to create (train) the model.
DBMS_DATA_MINING_TRANSFORM
offers two approaches to implementing transformations. For a given model, you can either:
Create a list of transformation expressions and pass it to the CREATE_MODEL Procedure
or
Create a view that implements the transformations and pass the name of the view to the CREATE_MODEL Procedure
If you create a transformation list and pass it to CREATE_MODEL
, the transformation expressions are embedded in the model and automatically implemented whenever the model is applied.
If you create a view, the transformation expressions are external to the model. You will need to re-create the transformations whenever you apply the model.
Note:
Embedded transformations significantly enhance the model's usability while simplifying the process of model management.Oracle Data Mining supports an Automatic Data Preparation (ADP) mode. When ADP is enabled, most algorithm-specific transformations are automatically embedded. Any additional transformations must be explicitly provided in an embedded transformation list or in a view.
If ADP is enabled and you create a model with a transformation list, both sets of transformations are embedded. The model will execute the user-specified transformations from the transformation list before executing the automatic transformations specified by ADP.
Within a transformation list, you can selectively disable ADP for individual attributes.
See Also:
"Automatic Data Preparation" in Chapter 45, "DBMS_DATA_MINING"
Oracle Data Mining User's Guide for a more information about ADP
The transformations supported by DBMS_DATA_MINING_TRANSFORM
are summarized in this section.
Binning refers to the mapping of continuous or discrete values to discrete values of reduced cardinality.
Supervised Binning (Categorical and Numerical)
Binning is based on intrinsic relationships in the data as determined by a decision tree model.
Top-N Frequency Categorical Binning
Binning is based on the number of cases in each category.
Equi-Width Numerical Binning
Binning is based on equal-range partitions.
Quantile Numerical Binning
Binning is based on quantiles computed using the SQL NTILE
function.
Normalization is the process of scaling continuous values down to a specific range, often between zero and one. Normalization transforms each numerical value by subtracting a number (the shift) and dividing the result by another number (the scale).
x_new = (x_old-shift)/scale
Min-Max Normalization
Normalization is based on the minimum and maximum with the following shift and scale:
shift = min scale = max-min
Scale Normalization
Normalization is based on the minimum and maximum with the following shift and scale:
shift = 0 scale = max{abs(max), abs(min)}
Z-Score Normalization
Normalization is based on the mean and standard deviation with the following shift and scale:
shift = mean scale = standard_deviation
An outlier is a numerical value that is located far from the rest of the data. Outliers can artificially skew the results of data mining.
Winsorizing
Outliers are replaced with the nearest value that is not an outlier.
Trimming
Outliers are set to NULL
.
Missing data may indicate sparsity or it may indicate that some values are missing at random. DBMS_DATA_MINING_TRANSFORM
supports the following transformations for minimizing the effects of missing values:
Missing numerical values are replaced with the mean.
Missing categorical values are replaced with the mode.
Note:
Oracle Data Mining also has default mechanisms for handling missing data. See Oracle Data Mining User's Guide for details.The DBMS_DATA_MINING_TRANSFORM
package offers a flexible framework for specifying data transformations. If you choose to embed transformations in the model (the preferred method), you will create a transformation list object and pass it to the CREATE_MODEL Procedure. If you choose to transform the data without embedding, you will create a view.
When specified in a transformation list, the transformation expressions are executed by the model. When specified in a view, the transformation expressions are executed by the view.
Transformation definitions are used to generate the SQL expressions that transform the data. For example, the transformation definitions for normalizing a numeric column are the shift and scale values for that data.
With the DBMS_DATA_MINING_TRANSFORM
package, you can call procedures to compute the transformation definitions, or you can compute them yourself, or you can do both.
Transformation Definition Tables
DBMS_DATA_MINING_TRANSFORM
provides INSERT
procedures that compute transformation definitions and insert them in transformation definition tables. You can modify the values in the transformation definition tables or populate them yourself.
XFORM
routines use populated definition tables to transform data in external views. STACK
routines use populated definition tables to build transformation lists.
To specify transformations based on definition tables, follow these steps:
Use CREATE
routines to create transformation definition tables.
The tables have columns to hold the transformation definitions for a given type of transformation. For example, the CREATE_BIN_NUM Procedure creates a definition table that has a column for storing data values and another column for storing the associated bin identifiers.
Use INSERT
routines to compute and insert transformation definitions in the tables.
Each INSERT
routine uses a specific technique for computing the transformation definitions. For example, the INSERT_BIN_NUM_EQWIDTH Procedure computes bin boundaries by identifying the minimum and maximum values then setting the bin boundaries at equal intervals.
Use STACK
or XFORM
routines to generate transformation expressions based on the information in the definition tables:
Use STACK
routines to add the transformation expressions to a transformation list. Pass the transformation list to the CREATE_MODEL Procedure. The transformation expressions will be assembled into one long SQL query and embedded in the model.
Use XFORM
routines to execute the transformation expressions within a view. The transformations will be external to the model and will need to be re-created whenever the model is applied to new data.
Transformations Without Definition Tables
STACK
routines are not the only method for adding transformation expressions to a transformation list. You can also build a transformation list without using definition tables.
To specify transformations without using definition tables, follow these steps:
Write a SQL expression for transforming an attribute.
Write a SQL expression for reversing the transformation. (See "Reverse Transformations and Model Transparency".)
Determine whether or not to disable ADP for the attribute. By default ADP is enabled for the attribute if it is specified for the model. (See "Disabling Automatic Data Preparation".)
Specify the SQL expressions and ADP instructions in a call to the SET_TRANSFORM Procedure, which adds the information to a transformation list.
Repeat steps 1 through 4 for each attribute that you wish to transform.
Pass the transformation list to the CREATE_MODEL Procedure. The transformation expressions will be assembled into one long SQL query and embedded in the model.
Note:
SQL expressions that you specify withSET_TRANSFORM
must fit within a VARCHAR2
. To specify a longer expression, you can use the SET_EXPRESSION Procedure. With SET_EXPRESSION
, you can build an expression by appending rows to a VARCHAR2
array.The elements of a transformation list are transformation records. Each transformation record provides all the information needed by the model for managing the transformation of a single attribute.
Each transformation record includes the following fields:
attribute_name
— Name of the column of data to be transformed
attribute_subname
— Name of the nested attribute if attribute_name
is a nested column, otherwise NULL
expression
— SQL expression for transforming the attribute
reverse_expression
— SQL expression for reversing the transformation
attribute_spec
— Identifies special treatment for the attribute during the model build. See Table 46-33, "SET_TRANSFORM Procedure Parameters" for details.
See Also:
Table 46-1 for details about the TRANSFORM_LIST
and TRANSFORM_REC
object types
An algorithm manipulates transformed attributes to train and score a model. The transformed attributes, however, may not be meaningful to an end user. For example, if attribute x has been transformed into bins 1 — 4, the bin names 1, 2 , 3, and 4 are manipulated by the algorithm, but a user is probably not interested in the model details about bins 1 — 4 or in predicting the numbers 1 — 4.
To return original attribute values in model details and predictions, you can provide a reverse expression in the transformation record for the attribute. For example, if you specify the transformation expression 'log(10, y)'
for attribute y, you could specify the reverse transformation expression 'power(10, y)'
.
Reverse transformations enable model transparency. They make internal processing transparent to the user.
Note:
STACK
procedures automatically reverse normalization transformations, but they do not provide a mechanism for reversing binning, clipping, or missing value transformations.
You can use the DBMS_DATA_MINING.ALTER_REVERSE_EXPRESSION
procedure to specify or update reverse transformations expressions for an existing model.
See Also:
Example 46-1, "Stacking a Clipping Transformation"
"ALTER_REVERSE_EXPRESSION Procedure"
"Summary of DBMS_DATA_MINING Subprograms" for links to the model details functions
ADP is controlled by a model-specific setting (PREP_AUTO
). The PREP_AUTO
setting affects all model attributes unless you disable it for individual attributes.
If ADP is enabled and you set attribute_spec
to NOPREP
, only the transformations that you specify for that attribute will be evaluated. If ADP is enabled and you do not set attribute_spec
to NOPREP
, the automatic transformations will be evaluated after the transformations that you specify for the attribute.
If ADP is not enabled for the model, the attribute_spec
field of the transformation record is ignored.
A transformation list is a stack of transformation records. When a new transformation record is added, it is appended to the top of the stack. (See "About Stacking" for details.)
When you use SET_TRANSFORM
to add a transformation record to a transformation list, you can specify values for all the fields in the transformation record.
When you use STACK
procedures to add transformation records to a transformation list, only the transformation expression field is populated. For normalization transformations, the reverse transformation expression field is also populated.
You can use both STACK
procedures and SET_TRANSFORM
to build one transformation list. Each STACK
procedure call adds transformation records for all the attributes in a specified transformation definition table. Each SET_TRANSFORM
call adds a transformation record for a single attribute.
Transformation lists are built by stacking transformation records. Transformation lists are evaluated from bottom to top. Each transformation expression depends on the result of the transformation expression below it in the stack.
STACK
procedures create transformation records from the information in transformation definition tables. For example STACK_BIN_NUM
builds a transformation record for each attribute specified in a definition table for numeric binning. STACK
procedures stack the transformation records as follows:
If an attribute is specified in the definition table but not in the transformation list, the STACK
procedure creates a transformation record, computes the reverse transformation (if possible), inserts the transformation and reverse transformation in the transformation record, and appends the transformation record to the top of the transformation list.
If an attribute is specified in the transformation list but not in the definition table, the STACK
procedure takes no action.
If an attribute is specified in the definition table and in the transformation list, the STACK
procedure stacks the transformation expression from the definition table on top of the transformation expression in the transformation record and updates the reverse transformation. See Example 46-1, "Stacking a Clipping Transformation"and Example 46-4, "Stacking a Nested Normalization Transformation".
Example 46-1 Stacking a Clipping Transformation
This example shows how STACK_CLIP Procedure would add transformation records to a transformation list. Note that the clipping transformations are not reversed in COL1
and COL2
after stacking (as described in "Reverse Transformations and Model Transparency").
Refer to:
CREATE_CLIP Procedure — Creates the definition table
INSERT_CLIP_TRIM_TAIL Procedure — Inserts definitions in the table
INSERT_CLIP_WINSOR_TAIL Procedure — Inserts definitions in the table
Table 46-1 — Describes the structure of the transformation list (TRANSFORM_LIST
object)
Assume a clipping definition table populated as follows.
col | att | lcut | lval | rcut | rval |
---|---|---|---|---|---|
COL1 |
null | -1.5 | -1.5 | 4.5 | 4.5 |
COL2 |
null | 0 | 0 | 1 | 1 |
Assume the following transformation list before stacking.
------------------------- transformation record #1: ------------------------- attribute_name = COL1 attribute_subname = null expression = log(10, COL1) reverse_expression = power(10, COL1) ------------------------- transformation record #2: ------------------------- attribute_name = COL3 attribute_subname = null expression = ln(COL3) reverse_expression = exp(COL3)
After stacking, the transformation list is as follows.
------------------------- transformation record #1: ------------------------- attribute_name = COL1 attribute_subname = null expression = CASE WHEN log(10, COL1) < -1.5 THEN -1.5 WHEN log(10, COL1) > 4.5 THEN 4.5 ELSE log(10, COL1) END; reverse_expression = power(10, COL1) ------------------------- transformation record #2: ------------------------- attribute_name = COL3 attribute_subname = null expression = ln(COL3) reverse_expression = exp(COL3) ------------------------- transformation record #3: ------------------------- attribute_name = COL2 attribute_subname = null expression = CASE WHEN COL2 < 0 THEN 0 WHEN COL2 > 1 THEN 1 ELSE COL2 END; reverse_expression = null
The CREATE
routines create transformation definition tables that include two columns, col
and att
, for identifying attributes. The column col
holds the name of a column in the data table. If the data column is not nested, then att
is null, and the name of the attribute is col
. If the data column is nested, then att
holds the name of the nested attribute, and the name of the attribute is col.att
.
The INSERT
and XFORM
routines ignore the att
column in the definition tables. Neither the INSERT
nor the XFORM
routines support nested data.
Only the STACK
procedures and SET_TRANSFORM
support nested data. Nested data transformations are always embedded in the model.
Nested columns in Oracle Data Mining can have the following types:
DM_NESTED_NUMERICALS DM_NESTED_CATEGORICALS DM_NESTED_BINARY_DOUBLES DM_NESTED_BINARY_FLOATS
See Also:
Oracle Data Mining User's Guide for details about nested attributes in Oracle Data Mining
Specifying Nested Attributes in a Transformation Record
A transformation record (TRANSFORM_REC
) includes two fields, attribute_name
and attribute_subname
, for identifying the attribute. The field attribute_name
holds the name of a column in the data table. If the data column is not nested, then attribute_subname
is null, and the name of the attribute is attribute_name
. If the data column is nested, then attribute_subname
holds the name of the nested attribute, and the name of the attribute is attribute_name.attribute_subname
.
Transforming Individual Nested Attributes
You can specify different transformations for different attributes in a nested column, and you can specify a default transformation for all the remaining attributes in the column. To specify a default nested transformation, specify null in the attribute_name
field and the name of the nested column in the attribute_subname
field as shown in Example 46-2. Note that the keyword VALUE
is used to represent the value of a nested attribute in a transformation expression.
Example 46-2 Transforming a Nested Column
The following statement transforms two of the nested attributes in COL_N1
. Attribute ATTR1
is transformed with normalization; Attribute ATTR2
is set to null, which causes attribute removal transformation (ATTR2
is not used in training the model). All the remaining attributes in COL_N1
are divided by 10.
DECLARE stk dbms_data_mining_transform.TRANSFORM_LIST; BEGIN dbms_data_mining_transform.SET_TRANSFORM( stk,'COL_N1', 'ATTR1', '(VALUE - (-1.5))/20', 'VALUE *20 + (-1.5)'); dbms_data_mining_transform.SET_TRANSFORM( stk,'COL_N1', 'ATTR2', NULL, NULL); dbms_data_mining_transform.SET_TRANSFORM( stk, NULL, 'COL_N1', 'VALUE/10', 'VALUE*10'); END; /
The following SQL is generated from this statement.
CAST(MULTISET(SELECT DM_NESTED_NUMERICAL( "ATTRIBUTE_NAME", DECODE("ATTRIBUTE_NAME", 'ATTR1', ("VALUE" - (-1.5))/20, "VALUE"/10)) FROM TABLE("COL_N1") WHERE "ATTRIBUTE_NAME" IS NOT IN ('ATTR2')) AS DM_NESTED_NUMERICALS)
If transformations are not specified for COL_N1.ATTR1
and COL_N1.ATTR2
, then the default transformation is used for all the attributes in COL_N1
, and the resulting SQL does not include a DECODE
.
CAST(MULTISET(SELECT DM_NESTED_NUMERICAL( "ATTRIBUTE_NAME", "VALUE"/10) FROM TABLE("COL_N1")) AS DM_NESTED_NUMERICALS)
Since DECODE
is limited to 256 arguments, multiple DECODE
functions are nested to support an arbitrary number of individual nested attribute specifications.
You can specify a transformation that adds a nested column to the data, as shown in Example 46-3.
Example 46-3 Adding a Nested Column to a Transformation List
DECLARE v_xlst dbms_data_mining_transform.TRANSFORM_LIST; BEGIN dbms_data_mining_transform.SET_TRANSFORM(v_xlst, 'YOB_CREDLIM', NULL, 'dm_nested_numericals( dm_nested_numerical( ''CUST_YEAR_OF_BIRTH'', cust_year_of_birth), dm_nested_numerical( ''CUST_CREDIT_LIMIT'', cust_credit_limit))', NULL); dbms_data_mining_transform.SET_TRANSFORM( v_xlst, 'CUST_YEAR_OF_BIRTH', NULL, NULL, NULL); dbms_data_mining_transform.SET_TRANSFORM( v_xlst, 'CUST_CREDIT_LIMIT', NULL, NULL, NULL); dbms_data_mining_transform.XFORM_STACK( v_xlst, 'mining_data', 'mining_data_v'); END; / set long 2000 SELECT text FROM user_views WHERE view_name IN 'MINING_DATA_V'; TEXT --------------------------------------------------------------------------------- SELECT "CUST_ID","CUST_POSTAL_CODE",dm_nested_numericals( dm_nested_numerical( 'CUST_YEAR_OF_BIRTH', cust_year_of_birth), dm_nested_numerical( 'CUST_CREDIT_LIMIT', cust_credit_limit)) "YOB_CREDLIM" FROM mining_data SELECT * FROM mining_data_v WHERE cust_id = 104500; CUST_ID CUST_POSTAL_CODE YOB_CREDLIM(ATTRIBUTE_NAME, VALUE) ------- ---------------- --------------------------------------------------------- 104500 68524 DM_NESTED_NUMERICALS(DM_NESTED_NUMERICAL( 'CUST_YEAR_OF_BIRTH', 1962), DM_NESTED_NUMERICAL('CUST_CREDIT_LIMIT', 15000))
Stacking Nested Transformations
Example 46-4 shows how the STACK_NORM_LIN Procedure would add transformation records for nested column COL_N
to a transformation list.
Refer to:
CREATE_NORM_LIN Procedure — Creates the definition table
INSERT_NORM_LIN_MINMAX Procedure — Inserts definitions in the table
INSERT_NORM_LIN_SCALE Procedure — Inserts definitions in the table
INSERT_NORM_LIN_ZSCORE Procedure — Inserts definitions in the table
Table 46-1 — Describes the structure of the transformation list
Example 46-4 Stacking a Nested Normalization Transformation
Assume a linear normalization definition table populated as follows.
col | att | shift | scale |
---|---|---|---|
COL_N |
ATT2 |
0 | 20 |
null |
COL_N |
0 | 10 |
Assume the following transformation list before stacking.
------------------------- transformation record #1: ------------------------- attribute_name = COL_N attribute_subname = ATT1 expression = log(10, VALUE) reverse_expression = power(10, VALUE) ------------------------- transformation record #2: ------------------------- attribute_name = null attribute_subname = COL_N expression = ln(VALUE) reverse_expression = exp(VALUE)
After stacking, the transformation list is as follows.
------------------------- transformation record #1: ------------------------- attribute_name = COL_N attribute_subname = ATT1 expression = (log(10, VALUE) - 0)/10 reverse_expression = power(10, VALUE*10 + 0) ------------------------- transformation record #2: ------------------------- attribute_name = NULL attribute_subname = COL_N expression = (ln(VALUE)- 0)/10 reverse_expression = exp(VALUE *10 + 0) ------------------------- transformation record #3: ------------------------- attribute_name = COL_N attribute_subname = ATT2 expression = (ln(VALUE) - 0)/20 reverse_expression = exp(VALUE * 20 + 0)
The DBMS_DATA_MINING_TRANSFORM
package is owned by user SYS
and is installed as part of database installation. Execution privilege on the package is granted to public. The routines in the package are run with invokers' rights (run with the privileges of the current user).
The DBMS_DATA_MINING_TRANSFORM.INSERT
_* procedures have a data_table_name
parameter that enables the user to provide the input data for transformation purposes. The value of data_table_name
can be the name of a physical table or a view. The data_table_name
parameter can also accept an inline query.
Important:
Because an inline query can be used to specify the data for transformation, Oracle strongly recommends that the calling routine perform any necessary SQL injection checks on the input string.See Also:
"Operational Notes" for a description of theDBMS_DATA_MINING_TRANSFORM.INSERT
_* proceduresDBMS_DATA_MINING_TRANSFORM
defines the datatypes described in Table 46-1.
Table 46-1 Datatypes in DBMS_DATA_MINING_TRANSFORM
List Type | List Elements | Description |
---|---|---|
COLUMN_ LIST |
VARRAY(1000) OF varchar2(32) |
See Oracle Database PL/SQL Language Reference for information about populating |
DESCRIBE_ LIST |
DBMS_SQL.DESC_TAB2 TYPE desc_tab2 IS TABLE OF desc_rec2 INDEX BY BINARY_INTEGER TYPE desc_rec2 IS RECORD ( col_type BINARY_INTEGER := 0, col_max_len BINARY_INTEGER := 0, col_name VARCHAR2(32767):= '', col_name_len BINARY_INTEGER := 0, col_schema_name VARCHAR2(32) := '', col_schema_name_len BINARY_INTEGER := 0, col_precision BINARY_INTEGER := 0, col_scale BINARY_INTEGER := 0, col_charsetid BINARY_INTEGER := 0, col_charsetform BINARY_INTEGER := 0, col_null_ok BOOLEAN := TRUE); |
The The The |
TRANSFORM_ LIST |
TABLE OF transform_rec TYPE transform_rec IS RECORD ( attribute_name VARCHAR2(30), attribute_subname VARCHAR2(4000), expression EXPRESSION_REC, reverse_expression EXPRESSION_REC, attribute_spec VARCHAR2(4000)); TYPE expression_rec IS RECORD ( lstmt DBMS_SQL.VARCHAR2A, lb BINARY_INTEGER DEFAULT 1, ub BINARY_INTEGER DEFAULT 0); TYPE varchar2a IS TABLE OF VARCHAR2(32767) INDEX BY BINARY_INTEGER; |
Each element in a The The The expressions in a The |
DBMS_DATA_MINING_TRANSFORM
defines the constants described in Table 46-2.
Table 46-2 Constants in DBMS_DATA_MINING_TRANSFORM
Constant | Value | Description |
---|---|---|
|
100001 |
Indicates that an attribute in the transformation list comes from a row in a column of Nested numerical attributes are defined as follows: attribute_name VARCHAR2(4000) value NUMBER |
|
100002 |
Indicates that an attribute in the transformation list comes from a row in a column of Nested categorical attributes are defined as follows: attribute_name VARCHAR2(4000) value VARCHAR2(4000) |
|
100003 |
Indicates that an attribute in the transformation list comes from a row in a column of Nested binary double attributes are defined as follows: attribute_name VARCHAR2(4000) value BINARY_DOUBLE |
|
100004 |
Indicates that an attribute in the transformation list comes from a row in a column of attribute_name VARCHAR2(4000) value BINARY_FLOAT |
See Also:
Oracle Data Mining User's Guide for information about nested data in Oracle Data MiningTable 46-3 DBMS_DATA_MINING_TRANSFORM Package Subprograms
Subprogram | Purpose |
---|---|
Creates a transformation definition table for categorical binning |
|
Creates a transformation definition table for numerical binning |
|
Creates a transformation definition table for clipping |
|
Creates a transformation definition table for column removal |
|
Creates a transformation definition table for categorical missing value treatment |
|
Creates a transformation definition table for numerical missing values treatment |
|
Creates a transformation definition table for linear normalization |
|
Describes the transformation list |
|
Returns a |
|
Inserts numeric automatic equi-width binning definitions in a transformation definition table |
|
Inserts categorical frequency-based binning definitions in a transformation definition table |
|
Inserts numeric equi-width binning definitions in a transformation definition table |
|
Inserts numeric quantile binning expressions in a transformation definition table |
|
Inserts supervised binning definitions in numerical and categorical transformation definition tables |
|
Inserts numerical trimming definitions in a transformation definition table |
|
Inserts numerical winsorizing definitions in a transformation definition table |
|
Inserts categorical missing value treatment definitions in a transformation definition table |
|
Inserts numerical missing value treatment definitions in a transformation definition table |
|
Inserts linear min-max normalization definitions in a transformation definition table |
|
Inserts linear scale normalization definitions in a transformation definition table |
|
Inserts linear zscore normalization definitions in a transformation definition table |
|
Adds a |
|
Adds a transformation record to a transformation list |
|
Adds a categorical binning expression to a transformation list |
|
Adds a numerical binning expression to a transformation list |
|
Adds a clipping expression to a transformation list |
|
Adds a column removal expression to a transformation list |
|
Adds a categorical missing value treatment expression to a transformation list |
|
Adds a numerical missing value treatment expression to a transformation list |
|
Adds a linear normalization expression to a transformation list |
|
Creates a view of the data table with categorical binning transformations |
|
Creates a view of the data table with numerical binning transformations |
|
Creates a view of the data table with clipping transformations |
|
Creates a view of the data table with column removal transformations |
|
Creates a view of the data table with the specified numeric transformations |
|
Creates a view of the data table with the specified categorical transformations |
|
Creates a view of the data table with categorical missing value treatment |
|
Creates a view of the data table with numerical missing value treatment |
|
Creates a view of the data table with linear normalization transformations |
|
Creates a view of the transformation list |
This procedure creates a transformation definition table for categorical binning. The columns are described in Table 46-4.
Table 46-4 Columns in a Transformation Definition Table for Categorical Binning
Name | Datatype | Description |
---|---|---|
|
|
Name of a column of categorical data. If the column is not nested, the column name is also the attribute name. For information about attribute names, see Oracle Data Mining User's Guide. |
|
|
The attribute subname if If |
|
|
Values of the attribute |
|
|
Bin assignments for the values |
DBMS_DATA_MINING_TRANSFORM.CREATE_BIN_CAT ( bin_table_name IN VARCHAR2, bin_schema_name IN VARCHAR2 DEFAULT NULL );
See Oracle Data Mining User's Guide for details about categorical data.
See "Nested Data Transformations" for information about transformation definition tables and nested data.
You can use the following procedures to populate the transformation definition table:
INSERT_BIN_CAT_FREQ Procedure — frequency-based binning
INSERT_BIN_SUPER Procedure — supervised binning
The following statement creates a table called bin_cat_xtbl
in the current schema. The table has columns that can be populated with bin assignments for categorical attributes.
BEGIN DBMS_DATA_MINING_TRANSFORM.CREATE_BIN_CAT('bin_cat_xtbl'); END; / DESCRIBE bin_cat_xtbl Name Null? Type ----------------------------------------- -------- ---------------------------- COL VARCHAR2(30) ATT VARCHAR2(4000) VAL VARCHAR2(4000) BIN VARCHAR2(4000)
This procedure creates a transformation definition table for numerical binning. The columns are described in Table 46-6.
Table 46-6 Columns in a Transformation Definition Table for Numerical Binning
Name | Datatype | Description |
---|---|---|
|
|
Name of a column of numerical data. If the column is not nested, the column name is also the attribute name. For information about attribute names, see Oracle Data Mining User's Guide. |
|
|
The attribute subname if If |
|
|
Values of the attribute |
|
|
Bin assignments for the values |
DBMS_DATA_MINING_TRANSFORM.CREATE_BIN_NUM ( bin_table_name IN VARCHAR2, bin_schema_name IN VARCHAR2 DEFAULT NULL );
See Oracle Data Mining User's Guide for details about numerical data.
See "Nested Data Transformations" for information about transformation definition tables and nested data.
You can use the following procedures to populate the transformation definition table:
INSERT_AUTOBIN_NUM_EQWIDTH Procedure — automatic equi-width binning
INSERT_BIN_NUM_EQWIDTH Procedure — user-specified equi-width binning
INSERT_BIN_NUM_QTILE Procedure — quantile binning
INSERT_BIN_SUPER Procedure — supervised binning
The following statement creates a table called bin_num_xtbl
in the current schema. The table has columns that can be populated with bin assignments for numerical attributes.
BEGIN DBMS_DATA_MINING_TRANSFORM.CREATE_BIN_NUM('bin_num_xtbl'); END; / DESCRIBE bin_num_xtbl Name Null? Type ----------------------------------------- -------- ---------------------------- COL VARCHAR2(30) ATT VARCHAR2(4000) VAL NUMBER BIN VARCHAR2(4000)
This procedure creates a transformation definition table for clipping or winsorizing to minimize the effect of outliers. The columns are described in Table 46-8.
Table 46-8 Columns in a Transformation Definition Table for Clipping or Winsorizing
Name | Datatype | Description |
---|---|---|
|
|
Name of a column of numerical data. If the column is not nested, the column name is also the attribute name. For information about attribute names, see Oracle Data Mining User's Guide. |
|
|
The attribute subname if If |
|
|
The lowest typical value for the attribute. If the attribute values were plotted on an xy axis, Any values to the left of |
|
|
Value assigned to an outlier to the left of |
|
|
The highest typical value for the attribute If the attribute values were plotted on an xy axis, Any values to the right of |
|
|
Value assigned to an outlier to the right of |
DBMS_DATA_MINING_TRANSFORM.CREATE_CLIP ( clip_table_name IN VARCHAR2, clip_schema_name IN VARCHAR2 DEFAULT NULL );
See Oracle Data Mining User's Guide for details about numerical data.
See "Nested Data Transformations" for information about transformation definition tables and nested data.
You can use the following procedures to populate the transformation definition table:
INSERT_CLIP_TRIM_TAIL Procedure — replaces outliers with nulls
INSERT_CLIP_WINSOR_TAIL Procedure — replaces outliers with an average value
The following statement creates a table called clip_xtbl
in the current schema. The table has columns that can be populated with clipping instructions for numerical attributes.
BEGIN DBMS_DATA_MINING_TRANSFORM.CREATE_CLIP('clip_xtbl'); END; / DESCRIBE clip_xtbl Name Null? Type ----------------------------------------- -------- ---------------------------- COL VARCHAR2(30) ATT VARCHAR2(4000) LCUT NUMBER LVAL NUMBER RCUT NUMBER RVAL NUMBER
This procedure creates a transformation definition table for removing columns from the data table. The columns are described in Table 46-10.
Table 46-10 Columns in a Transformation Definition Table for Column Removal
Name | Datatype | Description |
---|---|---|
|
|
Name of a column of data. If the column is not nested, the column name is also the attribute name. For information about attribute names, see Oracle Data Mining User's Guide. |
|
|
The attribute subname if If |
DBMS_DATA_MINING_TRANSFORM.CREATE_COL_REM ( rem_table_name VARCHAR2, rem_schema_name VARCHAR2 DEFAULT NULL );
See "Nested Data Transformations" for information about transformation definition tables and nested data.
See "Operational Notes".
The following statement creates a table called rem_att_xtbl
in the current schema. The table has columns that can be populated with the names of attributes to exclude from the data to be mined.
BEGIN DBMS_DATA_MINING_TRANSFORM.CREATE_COL_REM ('rem_att_xtbl'); END; / DESCRIBE rem_att_xtbl Name Null? Type ----------------------------------------- -------- ---------------------------- COL VARCHAR2(30) ATT VARCHAR2(4000)
This procedure creates a transformation definition table for replacing categorical missing values. The columns are described in Table 46-12.
Table 46-12 Columns in a Transformation Definition Table for Categorical Missing Value Treatment
Name | Datatype | Description |
---|---|---|
|
|
Name of a column of categorical data. If the column is not nested, the column name is also the attribute name. For information about attribute names, see Oracle Data Mining User's Guide. |
|
|
The attribute subname if If |
|
|
Replacement for missing values in the attribute |
DBMS_DATA_MINING_TRANSFORM.CREATE_MISS_CAT ( miss_table_name IN VARCHAR2, miss_schema_name IN VARCHAR2 DEFAULT NULL );
See Oracle Data Mining User's Guide for details about categorical data.
See "Nested Data Transformations" for information about transformation definition tables and nested data.
You can use the INSERT_MISS_CAT_MODE Procedure to populate the transformation definition table.
The following statement creates a table called miss_cat_xtbl
in the current schema. The table has columns that can be populated with values for missing data in categorical attributes.
BEGIN
DBMS_DATA_MINING_TRANSFORM.CREATE_MISS_CAT('miss_cat_xtbl'); END; / DESCRIBE miss_cat_xtbl Name Null? Type ----------------------------------------- -------- ---------------------------- COL VARCHAR2(30) ATT VARCHAR2(4000) VAL VARCHAR2(4000)
This procedure creates a transformation definition table for replacing numerical missing values. The columns are described in Table 46-14.
Table 46-14 Columns in a Transformation Definition Table for Numerical Missing Value Treatment
Name | Datatype | Description |
---|---|---|
|
|
Name of a column of numerical data. If the column is not nested, the column name is also the attribute name. For information about attribute names, see Oracle Data Mining User's Guide. |
|
|
The attribute subname if If |
|
|
Replacement for missing values in the attribute |
DBMS_DATA_MINING_TRANSFORM.CREATE_MISS_NUM ( miss_table_name IN VARCHAR2, miss_schema_name IN VARCHAR2 DEFAULT NULL );
See Oracle Data Mining User's Guide for details about numerical data.
See "Nested Data Transformations" for information about transformation definition tables and nested data.
You can use the INSERT_MISS_NUM_MEAN Procedure to populate the transformation definition table.
The following statement creates a table called miss_num_xtbl
in the current schema. The table has columns that can be populated with values for missing data in numerical attributes.
BEGIN DBMS_DATA_MINING_TRANSFORM.CREATE_MISS_NUM('miss_num_xtbl'); END; / DESCRIBE miss_num_xtbl Name Null? Type ----------------------------------------- -------- ---------------------------- COL VARCHAR2(30) ATT VARCHAR2(4000) VAL NUMBER
This procedure creates a transformation definition table for linear normalization. The columns are described in Table 46-16.
Table 46-16 Columns in a Transformation Definition Table for Linear Normalization
Name | Datatype | Description |
---|---|---|
|
|
Name of a column of numerical data. If the column is not nested, the column name is also the attribute name. For information about attribute names, see Oracle Data Mining User's Guide. |
|
|
The attribute subname if If |
|
|
A constant to subtract from the attribute values |
|
|
A constant by which to divide the shifted values |
DBMS_DATA_MINING_TRANSFORM.CREATE_NORM_LIN ( norm_table_name IN VARCHAR2, norm_schema_name IN VARCHAR2 DEFAULT NULL );
See Oracle Data Mining User's Guide for details about numerical data.
See "Nested Data Transformations" for information about transformation definition tables and nested data.
You can use the following procedures to populate the transformation definition table:
INSERT_NORM_LIN_MINMAX Procedure — Uses linear min-max normalization
INSERT_NORM_LIN_SCALE Procedure — Uses linear scale normalization
INSERT_NORM_LIN_ZSCORE Procedure — Uses linear zscore normalization
The following statement creates a table called norm_xtbl
in the current schema. The table has columns that can be populated with shift and scale values for normalizing numerical attributes.
BEGIN DBMS_DATA_MINING_TRANSFORM.CREATE_NORM_LIN('norm_xtbl'); END; / DESCRIBE norm_xtbl Name Null? Type ----------------------------------------- -------- ---------------------------- COL VARCHAR2(30) ATT VARCHAR2(4000) SHIFT NUMBER SCALE NUMBER
This procedure describes the columns of the data table after a list of transformations has been applied. Only the columns that are specified in the transformation list are transformed. The remaining columns in the data table are included in the output without changes.
To create a view of the data table after the transformations have been applied, use the XFORM_STACK Procedure.
DBMS_DATA_MINING_TRANSFORM.DESCRIBE_STACK ( xform_list IN TRANSFORM_LIST, data_table_name IN VARCHAR2, describe_list OUT DESCRIBE_LIST, data_schema_name IN VARCHAR2 DEFAULT NULL);
Table 46-18 DESCRIBE_STACK Procedure Parameters
Parameter | Description |
---|---|
|
A list of transformations. See Table 46-1 for a description of the |
|
Name of the table containing the data to be transformed |
|
Descriptions of the columns in the data table after the transformations specified in |
|
Schema of |
See "Operational Notes" for information about transformation lists and embedded transformations.
This example shows the column name and datatype, the column name length, and the column maximum length for the view dmuser.cust_info
after the transformation list has been applied. All the transformations are user-specified. The results of DESCRIBE_STACK
do not include one of the columns in the original table, because the SET_TRANSFORM
procedure sets that column to NULL
.
CREATE OR REPLACE VIEW cust_info AS
SELECT a.cust_id, c.country_id, c.cust_year_of_birth,
CAST(COLLECT(DM_Nested_Numerical(
b.prod_name, 1))
AS DM_Nested_Numericals) custprods
FROM sh.sales a, sh.products b, sh.customers c
WHERE a.prod_id = b.prod_id AND
a.cust_id=c.cust_id and
a.cust_id between 100001 AND 105000
GROUP BY a.cust_id, country_id, cust_year_of_birth;
describe cust_info
Name Null? Type
----------------------------------------- -------- ----------------------------
CUST_ID NOT NULL NUMBER
COUNTRY_ID NOT NULL NUMBER
CUST_YEAR_OF_BIRTH NOT NULL NUMBER(4)
CUSTPRODS SYS.DM_NESTED_NUMERICALS
DECLARE
cust_stack dbms_data_mining_transform.TRANSFORM_LIST;
cust_cols dbms_data_mining_transform.DESCRIBE_LIST;
BEGIN
dbms_data_mining_transform.SET_TRANSFORM (cust_stack,
'country_id', NULL, 'country_id/10', 'country_id*10');
dbms_data_mining_transform.SET_TRANSFORM (cust_stack,
'cust_year_of_birth', NULL, NULL, NULL);
dbms_data_mining_transform.SET_TRANSFORM (cust_stack,
'custprods', 'Mouse Pad', 'value*100', 'value/100');
dbms_data_mining_transform.DESCRIBE_STACK(
xform_list => cust_stack,
data_table_name => 'cust_info',
describe_list => cust_cols);
dbms_output.put_line('====');
for i in 1..cust_cols.COUNT loop
dbms_output.put_line('COLUMN_NAME: '||cust_cols(i).col_name);
dbms_output.put_line('COLUMN_TYPE: '||cust_cols(i).col_type);
dbms_output.put_line('COLUMN_NAME_LEN: '||cust_cols(i).col_name_len);
dbms_output.put_line('COLUMN_MAX_LEN: '||cust_cols(i).col_max_len);
dbms_output.put_line('====');
END loop;
END;
/
====
COLUMN_NAME: CUST_ID
COLUMN_TYPE: 2
COLUMN_NAME_LEN: 7
COLUMN_MAX_LEN: 22
====
COLUMN_NAME: COUNTRY_ID
COLUMN_TYPE: 2
COLUMN_NAME_LEN: 10
COLUMN_MAX_LEN: 22
====
COLUMN_NAME: CUSTPRODS
COLUMN_TYPE: 100001
COLUMN_NAME_LEN: 9
COLUMN_MAX_LEN: 40
====
This function returns a row from a VARCHAR2
array that stores a transformation expression. The array is built by calls to the SET_EXPRESSION Procedure.
The array can be used for specifying SQL expressions that are too long to be used with the SET_TRANSFORM Procedure.
DBMS_DATA_MINING_TRANSFORM.GET_EXPRESSION ( expression IN EXPRESSION_REC, chunk_num IN PLS_INTEGER DEFAULT NULL); RETURN VARCHAR2;
Table 46-19 GET_EXPRESSION Function Parameters
Parameter | Description |
---|---|
|
An expression record ( There are two See Table 46-1 for a description of the |
|
A |
Chunk numbering starts with one. For chunks outside of the range, the return value is null. When a chunk number is null the whole expression is returned as a string. If the expression is too big, a VALUE_ERROR
is raised.
See "Operational Notes".
See the example for the SET_EXPRESSION Procedure.
This procedure performs numerical binning and inserts the transformation definitions in a transformation definition table. The procedure identifies the minimum and maximum values and computes the bin boundaries at equal intervals.
INSERT_AUTOBIN_NUM_EQWIDTH
computes the number of bins separately for each column. If you want to use equi-width binning with the same number of bins for each column, use the INSERT_BIN_NUM_EQWIDTH Procedure.
INSERT_AUTOBIN_NUM_EQWIDTH
bins all the NUMBER
and FLOAT
columns in the data source unless you specify a list of columns to ignore.
DBMS_DATA_MINING_TRANSFORM.INSERT_AUTOBIN_NUM_EQWIDTH ( bin_table_name IN VARCHAR2, data_table_name IN VARCHAR2, bin_num IN PLS_INTEGER DEFAULT 3, max_bin_num IN PLS_INTEGER DEFAULT 100, exclude_list IN COLUMN_LIST DEFAULT NULL, round_num IN PLS_INTEGER DEFAULT 6, sample_size IN PLS_INTEGER DEFAULT 50000, bin_schema_name IN VARCHAR2 DEFAULT NULL, data_schema_name IN VARCHAR2 DEFAULT NULL, rem_table_name IN VARCHAR2 DEFAULT NULL, rem_schema_name IN VARCHAR2 DEFAULT NULL));
Table 46-20 INSERT_AUTOBIN_NUM_EQWIDTH Procedure Parameters
Parameter | Description |
---|---|
|
Name of the transformation definition table for numerical binning. You can use the CREATE_BIN_NUM Procedure to create the definition table. The following columns are required: COL VARCHAR2(30) VAL NUMBER BIN VARCHAR2(4000)
|
|
Name of the table containing the data to be transformed |
|
Minimum number of bins. If The default value of |
|
Maximum number of bins. If The default value of |
|
List of numerical columns to be excluded from the binning process. If you do not specify The format of dbms_data_mining_transform.COLUMN_LIST('col1','col2', ...'coln') |
|
Specifies how to round the number in the When The default value of |
|
Size of the data sample. If The default value of |
|
Schema of |
|
Schema of |
|
Name of a transformation definition table for column removal. The table must have the columns described in "CREATE_COL_REM Procedure".
|
|
Schema of |
See Oracle Data Mining User's Guide for details about numerical data.
INSERT_AUTOBIN_NUM_EQWIDTH
computes the number of bins for a column based on the number of non-null values (COUNT
), the maximum (MAX
), the minimum (MIN
), the standard deviation (STDDEV
), and the constant C=3.49/0.9:
N=floor(power(COUNT,1/3)*(max-min)/(c*dev))
If the sample_size
parameter is specified, it is used instead of COUNT
.
See Oracle Database SQL Language Reference for information about the COUNT
, MAX
, MIN
, STDDEV
, FLOOR
, and POWER
functions.
INSERT_AUTOBIN_NUM_EQWIDTH
uses absolute values to compute the number of bins. The sign of the parameters bin_num
, max_bin_num
, and sample_size
has no effect on the result.
In computing the number of bins, INSERT_AUTOBIN_NUM_EQWIDTH
evaluates the following criteria in the following order:
The minimum number of bins (bin_num
)
The maximum number of bins (max_bin_num
)
The maximum number of bins for integer columns, calculated as the number of distinct values in the range max-min+1
.
The round_num
parameter controls the rounding of column values in the transformation definition table, as follows:
For a value of 308.162:
when round_num = 1 result is 300
when round_num = 2 result is 310
when round_num = 3 result is 308
when round_num = 0 result is 308.162
when round_num = -1 result is 308.16
when round_num = -2 result is 308.2
In this example, INSERT_AUTOBIN_NUM_EQWIDTH
computes the bin boundaries for the cust_year_of_birth
column in sh.customers
and inserts the transformations in a transformation definition table. The STACK_BIN_NUM Procedure creates a transformation list from the contents of the definition table. The CREATE_MODEL Procedure embeds the transformation list in a new model called nb_model
.
The transformation and reverse transformation expressions embedded in nb_model
are returned by the GET_MODEL_TRANSFORMATIONS Function.
CREATE OR REPLACE VIEW mining_data AS SELECT cust_id, cust_year_of_birth, cust_postal_code FROM sh.customers; DESCRIBE mining_data Name Null? Type ----------------------------- -------- ---------------------------- CUST_ID NOT NULL NUMBER CUST_YEAR_OF_BIRTH NOT NULL NUMBER(4) CUST_POSTAL_CODE NOT NULL VARCHAR2(10) BEGIN dbms_data_mining_transform.CREATE_BIN_NUM( bin_table_name => 'bin_tbl'); dbms_data_mining_transform.INSERT_AUTOBIN_NUM_EQWIDTH ( bin_table_name => 'bin_tbl', data_table_name => 'mining_data', bin_num => 3, max_bin_num => 5, exclude_list => dbms_data_mining_transform.COLUMN_LIST('cust_id')); END; / set numwidth 4 column val off SELECT col, val, bin FROM bin_tbl ORDER BY val ASC; COL VAL BIN ------------------------- ---- ----- CUST_YEAR_OF_BIRTH 1913 CUST_YEAR_OF_BIRTH 1928 1 CUST_YEAR_OF_BIRTH 1944 2 CUST_YEAR_OF_BIRTH 1959 3 CUST_YEAR_OF_BIRTH 1975 4 CUST_YEAR_OF_BIRTH 1990 5 DECLARE year_birth_xform dbms_data_mining_transform.TRANSFORM_LIST; BEGIN dbms_data_mining_transform.STACK_BIN_NUM ( bin_table_name => 'bin_tbl', xform_list => year_birth_xform); dbms_data_mining.CREATE_MODEL( model_name => 'nb_model', mining_function => dbms_data_mining.classification, data_table_name => 'mining_data', case_id_column_name => 'cust_id', target_column_name => 'cust_postal_code', settings_table_name => null, data_schema_name => null, settings_schema_name => null, xform_list => year_birth_xform); END; / SELECT attribute_name FROM TABLE(dbms_data_mining.GET_MODEL_TRANSFORMATIONS('nb_model')); ATTRIBUTE_NAME ------------------------ CUST_YEAR_OF_BIRTH SELECT expression FROM TABLE(dbms_data_mining.GET_MODEL_TRANSFORMATIONS('nb_model')); EXPRESSION -------------------------------------------------------------------------------- CASE WHEN "CUST_YEAR_OF_BIRTH"<1913 THEN NULL WHEN "CUST_YEAR_OF_BIRTH"<=1928.4 THEN '1' WHEN "CUST_YEAR_OF_BIRTH"<=1943.8 THEN '2' WHEN "CUST_YEAR_OF_BIRTH" <=1959.2 THEN '3' WHEN "CUST_YEAR_OF_BIRTH"<=1974.6 THEN '4' WHEN "CUST_YEAR_OF_BIRTH" <=1990 THEN '5' END SELECT reverse_expression FROM TABLE(dbms_data_mining.GET_MODEL_TRANSFORMATIONS('nb_model')); REVERSE_EXPRESSION -------------------------------------------------------------------------------- DECODE("CUST_YEAR_OF_BIRTH",'5','(1974.6; 1990]','1','[1913; 1928.4]','2','(1928 .4; 1943.8]','3','(1943.8; 1959.2]','4','(1959.2; 1974.6]',NULL,'( ; 1913), (199 0; ), NULL')
This procedure performs categorical binning and inserts the transformation definitions in a transformation definition table. The procedure computes the bin boundaries based on frequency.
INSERT_BIN_CAT_FREQ
bins all the CHAR
and VARCHAR2
columns in the data source unless you specify a list of columns to ignore.
DBMS_DATA_MINING_TRANSFORM.INSERT_BIN_CAT_FREQ ( bin_table_name IN VARCHAR2, data_table_name IN VARCHAR2, bin_num IN PLS_INTEGER DEFAULT 9, exclude_list IN COLUMN_LIST DEFAULT NULL, default_num IN PLS_INTEGER DEFAULT 2, bin_support IN NUMBER DEFAULT NULL, bin_schema_name IN VARCHAR2 DEFAULT NULL, data_schema_name IN VARCHAR2 DEFAULT NULL);
Table 46-21 INSERT_BIN_CAT_FREQ Procedure Parameters
Parameter | Description |
---|---|
|
Name of the transformation definition table for categorical binning. You can use the CREATE_BIN_CAT Procedure to create the definition table.The following columns are required: COL VARCHAR2(30) VAL VARCHAR2(4000) BIN VARCHAR2(4000)
|
|
Name of the table containing the data to be transformed |
|
The number of bins to fill using frequency-based binning The total number of bins will be The default binning order is from highest to lowest: the most frequently occurring class is assigned to the first bin, the second most frequently occurring class is assigned to the second bin, and so on.You can reverse the binning order by specifying a negative number for If the total number of distinct values (classes) in the column is less than If you specify The default value of |
|
List of categorical columns to be excluded from the binning process. If you do not specify The format of dbms_data_mining_transform.COLUMN_LIST('col1','col2', ...'coln') |
|
The number of class occurrences (rows of the same class) required for assignment to the default bin By default, If you specify The default value of |
|
The number of class occurrences (rows of the same class) required for assignment to a frequency-based bin. By default, Classes that occur less than a positive If you specify The default value of |
|
Schema of |
|
Schema of |
See Oracle Data Mining User's Guide for details about categorical data.
If values occur with the same frequency, INSERT_BIN_CAT_FREQ
assigns them in descending order when binning is from most to least frequent, or in ascending order when binning is from least to most frequent.
In this example, INSERT_BIN_CAT_FREQ
computes the bin boundaries for the cust_postal_code
and cust_city
columns in sh.customers
and inserts the transformations in a transformation definition table. The STACK_BIN_CAT Procedure creates a transformation list from the contents of the definition table, and the CREATE_MODEL Procedure embeds the transformation list in a new model called nb_model
.
The transformation and reverse transformation expressions embedded in nb_model
are returned by the GET_MODEL_TRANSFORMATIONS Function.
CREATE OR REPLACE VIEW mining_data AS SELECT cust_id, cust_year_of_birth, cust_postal_code, cust_city FROM sh.customers; DESCRIBE mining_data Name Null? Type ------------------------------------- -------- ----------------------------- CUST_ID NOT NULL NUMBER CUST_YEAR_OF_BIRTH NOT NULL NUMBER(4) CUST_POSTAL_CODE NOT NULL VARCHAR2(10) CUST_CITY NOT NULL VARCHAR2(30) BEGIN dbms_data_mining_transform.CREATE_BIN_CAT( bin_table_name => 'bin_tbl_1'); dbms_data_mining_transform.INSERT_BIN_CAT_FREQ ( bin_table_name => 'bin_tbl_1', data_table_name => 'mining_data', bin_num => 4); END; / column col format a18 column val format a15 column bin format a10 SELECT col, val, bin FROM bin_tbl_1 ORDER BY col ASC, bin ASC; COL VAL BIN ------------------ --------------- ---------- CUST_CITY Los Angeles 1 CUST_CITY Greenwich 2 CUST_CITY Killarney 3 CUST_CITY Montara 4 CUST_CITY 5 CUST_POSTAL_CODE 38082 1 CUST_POSTAL_CODE 63736 2 CUST_POSTAL_CODE 55787 3 CUST_POSTAL_CODE 78558 4 CUST_POSTAL_CODE 5 DECLARE city_xform dbms_data_mining_transform.TRANSFORM_LIST; BEGIN dbms_data_mining_transform.STACK_BIN_CAT ( bin_table_name => 'bin_tbl_1', xform_list => city_xform); dbms_data_mining.CREATE_MODEL( model_name => 'nb_model', mining_function => dbms_data_mining.classification, data_table_name => 'mining_data', case_id_column_name => 'cust_id', target_column_name => 'cust_city', settings_table_name => null, data_schema_name => null, settings_schema_name => null, xform_list => city_xform); END; / SELECT attribute_name FROM TABLE(dbms_data_mining.GET_MODEL_TRANSFORMATIONS('nb_model')); ATTRIBUTE_NAME ----------------------------------------------------------------------------- CUST_CITY CUST_POSTAL_CODE SELECT expression FROM TABLE(dbms_data_mining.GET_MODEL_TRANSFORMATIONS('nb_model')); EXPRESSION ----------------------------------------------------------------------------- DECODE("CUST_CITY",'Greenwich','2','Killarney','3','Los Angeles','1', 'Montara','4',NULL,NULL,'5') DECODE("CUST_POSTAL_CODE",'38082','1','55787','3','63736','2','78558','4',NULL,NULL,'5') SELECT reverse_expression FROM TABLE(dbms_data_mining.GET_MODEL_TRANSFORMATIONS('nb_model')); REVERSE_EXPRESSION ----------------------------------------------------------------------------- DECODE("CUST_CITY",'2','''Greenwich''','3','''Killarney''','1', '''Los Angeles''','4','''Montara''',NULL,'NULL','5','DEFAULT') DECODE("CUST_POSTAL_CODE",'1','''38082''','3','''55787''','2','''63736''', '4','''78558''',NULL,'NULL','5','DEFAULT')
The binning order in example 1 is from most frequent to least frequent. The following example shows reverse order binning (least frequent to most frequent). The binning order is reversed by setting bin_num
to -4 instead of 4.
BEGIN dbms_data_mining_transform.CREATE_BIN_CAT( bin_table_name => 'bin_tbl_reverse'); dbms_data_mining_transform.INSERT_BIN_CAT_FREQ ( bin_table_name => 'bin_tbl_reverse', data_table_name => 'mining_data', bin_num => -4); END; / column col format a20 SELECT col, val, bin FROM bin_tbl_reverse ORDER BY col ASC, bin ASC; COL VAL BIN -------------------- --------------- ---------- CUST_CITY Tokyo 1 CUST_CITY Sliedrecht 2 CUST_CITY Haarlem 3 CUST_CITY Diemen 4 CUST_CITY 5 CUST_POSTAL_CODE 49358 1 CUST_POSTAL_CODE 80563 2 CUST_POSTAL_CODE 74903 3 CUST_POSTAL_CODE 71349 4 CUST_POSTAL_CODE 5
This procedure performs numerical binning and inserts the transformation definitions in a transformation definition table. The procedure identifies the minimum and maximum values and computes the bin boundaries at equal intervals.
INSERT_BIN_NUM_EQWIDTH
computes a specified number of bins (n
) and assigns (max-min)/n
values to each bin. The number of bins is the same for each column. If you want to use equi-width binning, but you want the number of bins to be calculated on a per-column basis, use the INSERT_AUTOBIN_NUM_EQWIDTH Procedure.
INSERT_BIN_NUM_EQWIDTH
bins all the NUMBER
and FLOAT
columns in the data source unless you specify a list of columns to ignore.
DBMS_DATA_MINING_TRANSFORM.INSERT_BIN_NUM_EQWIDTH ( bin_table_name IN VARCHAR2, data_table_name IN VARCHAR2, bin_num IN PLS_INTEGER DEFAULT 10, exclude_list IN COLUMN_LIST DEFAULT NULL, round_num IN PLS_INTEGER DEFAULT 6, bin_schema_name IN VARCHAR2 DEFAULT NULL, data_schema_name IN VARCHAR2 DEFAULT NULL);
Table 46-22 INSERT_BIN_NUM_EQWIDTH Procedure Parameters
Parameter | Description |
---|---|
|
Name of the transformation definition table for numerical binning. You can use the CREATE_BIN_NUM Procedure to create the definition table. The following columns are required: COL VARCHAR2(30) VAL NUMBER BIN VARCHAR2(4000)
|
|
Name of the table containing the data to be transformed |
|
Number of bins. No binning occurs if The default number of bins is 10. |
|
List of numerical columns to be excluded from the binning process. If you do not specify The format of dbms_data_mining_transform.COLUMN_LIST('col1','col2', ...'coln') |
|
Specifies how to round the number in the When The default value of |
|
Schema of |
|
Schema of |
See Oracle Data Mining User's Guide for details about numerical data.
The round_num
parameter controls the rounding of column values in the transformation definition table, as follows:
For a value of 308.162:
when round_num = 1 result is 300
when round_num = 2 result is 310
when round_num = 3 result is 308
when round_num = 0 result is 308.162
when round_num = -1 result is 308.16
when round_num = -2 result is 308.2
INSERT_BIN_NUM_EQWIDTH
ignores columns with all NULL
values or only one unique value.
In this example, INSERT_BIN_NUM_EQWIDTH
computes the bin boundaries for the affinity_card
column in mining_data_build
and inserts the transformations in a transformation definition table. The STACK_BIN_NUM Procedure creates a transformation list from the contents of the definition table. The CREATE_MODEL Procedure embeds the transformation list in a new model called glm_model
.
The transformation and reverse transformation expressions embedded in glm_model
are returned by the GET_MODEL_TRANSFORMATIONS Function.
CREATE OR REPLACE VIEW mining_data AS SELECT cust_id, cust_income_level, cust_gender, affinity_card FROM mining_data_build; DESCRIBE mining_data Name Null? Type ------------------------- -------- ----------------- CUST_ID NOT NULL NUMBER CUST_INCOME_LEVEL VARCHAR2(30) CUST_GENDER VARCHAR2(1) AFFINITY_CARD NUMBER(10) BEGIN dbms_data_mining_transform.CREATE_BIN_NUM( bin_table_name => 'bin_tbl'); dbms_data_mining_transform.INSERT_BIN_NUM_EQWIDTH ( bin_table_name => 'bin_tbl', data_table_name => 'mining_data', bin_num => 4, exclude_list => dbms_data_mining_transform.COLUMN_LIST('cust_id')); END; / set numwidth 10 column val off column col format a20 column bin format a10 SELECT col, val, bin FROM bin_tbl ORDER BY val ASC; COL VAL BIN -------------------- ---------- ---------- AFFINITY_CARD 0 AFFINITY_CARD .25 1 AFFINITY_CARD .5 2 AFFINITY_CARD .75 3 AFFINITY_CARD 1 4 CREATE TABLE glmsettings( setting_name VARCHAR2(30), setting_value VARCHAR2(30)); BEGIN INSERT INTO glmsettings (setting_name, setting_value) VALUES (dbms_data_mining.algo_name, dbms_data_mining.algo_generalized_linear_model); COMMIT; END; / DECLARE xforms dbms_data_mining_transform.TRANSFORM_LIST; BEGIN dbms_data_mining_transform.STACK_BIN_NUM ( bin_table_name => 'bin_tbl', xform_list => xforms, literal_flag => TRUE); dbms_data_mining.CREATE_MODEL( model_name => 'glm_model', mining_function => dbms_data_mining.regression, data_table_name => 'mining_data', case_id_column_name => 'cust_id', target_column_name => 'affinity_card', settings_table_name => 'glmsettings', data_schema_name => null, settings_schema_name => null, xform_list => xforms); END; / SELECT attribute_name FROM TABLE(dbms_data_mining.GET_MODEL_TRANSFORMATIONS('glm_model')); ATTRIBUTE_NAME ------------------------ AFFINITY_CARD SELECT expression FROM TABLE(dbms_data_mining.GET_MODEL_TRANSFORMATIONS('glm_model')); EXPRESSION -------------------------------------------------------------------------------- CASE WHEN "AFFINITY_CARD"<0 THEN NULL WHEN "AFFINITY_CARD"<=.25 THEN 1 WHEN "AFFINITY_CARD"<=.5 THEN 2 WHEN "AFFINITY_CARD"<=.75 THEN 3 WHEN "AFFINITY_CARD"<=1 THEN 4 END SELECT reverse_expression FROM TABLE(dbms_data_mining.GET_MODEL_TRANSFORMATIONS('glm_model')); REVERSE_EXPRESSION -------------------------------------------------------------------------------- DECODE("AFFINITY_CARD",4,'(.75; 1]',1,'[0; .25]',2,'(.25; .5]',3,'(.5; .75]', NULL,'( ; 0), (1; ), NULL')
This procedure performs numerical binning and inserts the transformation definitions in a transformation definition table. The procedure calls the SQL NTILE
function to order the data and divide it equally into the specified number of bins (quantiles).
INSERT_BIN_NUM_QTILE
bins all the NUMBER
and FLOAT
columns in the data source unless you specify a list of columns to ignore.
DBMS_DATA_MINING_TRANSFORM.INSERT_BIN_NUM_QTILE ( bin_table_name IN VARCHAR2, data_table_name IN VARCHAR2, bin_num IN PLS_INTEGER DEFAULT 10, exclude_list IN COLUMN_LIST DEFAULT NULL, bin_schema_name IN VARCHAR2 DEFAULT NULL, data_schema_name IN VARCHAR2 DEFAULT NULL);
Table 46-23 INSERT_BIN_NUM_QTILE Procedure Parameters
Parameter | Description |
---|---|
|
Name of the transformation definition table for numerical binning. You can use the CREATE_BIN_NUM Procedure to create the definition table. The following columns are required: COL VARCHAR2(30) VAL NUMBER BIN VARCHAR2(4000)
|
|
Name of the table containing the data to be transformed |
|
Number of bins. No binning occurs if The default number of bins is 10. |
|
List of numerical columns to be excluded from the binning process. If you do not specify The format of dbms_data_mining_transform.COLUMN_LIST('col1','col2', ...'coln') |
|
Schema of |
|
Schema of |
See Oracle Data Mining User's Guide for details about numerical data.
After dividing the data into quantiles, the NTILE
function distributes any remainder values one for each quantile, starting with the first. See Oracle Database SQL Language Reference for details.
Columns with all NULL
values are ignored by INSERT_BIN_NUM_QTILE
.
In this example, INSERT_BIN_NUM_QTILE
computes the bin boundaries for the cust_year_of_birth
and cust_credit_limit
columns in sh.customers
and inserts the transformations in a transformation definition table. The STACK_BIN_NUM Procedure creates a transformation list from the contents of the definition table.
The SQL expression that computes the transformation is shown in STACK_VIEW
. The view is for display purposes only; it cannot be used to embed the transformations in a model.
CREATE OR REPLACE VIEW mining_data AS SELECT cust_id, cust_year_of_birth, cust_credit_limit, cust_city FROM sh.customers; DESCRIBE mining_data Name Null? Type --------------------------------------- -------- ----------------------------- CUST_ID NOT NULL NUMBER CUST_YEAR_OF_BIRTH NOT NULL NUMBER(4) CUST_CREDIT_LIMIT NUMBER CUST_CITY NOT NULL VARCHAR2(30) BEGIN dbms_data_mining_transform.CREATE_BIN_NUM( bin_table_name => 'bin_tbl'); dbms_data_mining_transform.INSERT_BIN_NUM_QTILE ( bin_table_name => 'bin_tbl', data_table_name => 'mining_data', bin_num => 3, exclude_list => dbms_data_mining_transform.COLUMN_LIST('cust_id')); END; / set numwidth 8 column val off column col format a20 column bin format a10 SELECT col, val, bin FROM bin_tbl ORDER BY col ASC, val ASC; COL VAL BIN -------------------- -------- ---------- CUST_CREDIT_LIMIT 1500 CUST_CREDIT_LIMIT 3000 1 CUST_CREDIT_LIMIT 9000 2 CUST_CREDIT_LIMIT 15000 3 CUST_YEAR_OF_BIRTH 1913 CUST_YEAR_OF_BIRTH 1949 1 CUST_YEAR_OF_BIRTH 1965 2 CUST_YEAR_OF_BIRTH 1990 3 DECLARE xforms dbms_data_mining_transform.TRANSFORM_LIST; BEGIN dbms_data_mining_transform.STACK_BIN_NUM ( bin_table_name => 'bin_tbl', xform_list => xforms); dbms_data_mining_transform.XFORM_STACK ( xform_list => xforms, data_table_name => 'mining_data', xform_view_name => 'stack_view'); END; / set long 3000 SELECT text FROM user_views WHERE view_name in 'STACK_VIEW'; TEXT -------------------------------------------------------------------------------- SELECT "CUST_ID",CASE WHEN "CUST_YEAR_OF_BIRTH"<1913 THEN NULL WHEN "CUST_YEAR_O F_BIRTH"<=1949 THEN '1' WHEN "CUST_YEAR_OF_BIRTH"<=1965 THEN '2' WHEN "CUST_YEAR _OF_BIRTH"<=1990 THEN '3' END "CUST_YEAR_OF_BIRTH",CASE WHEN "CUST_CREDIT_LIMIT" <1500 THEN NULL WHEN "CUST_CREDIT_LIMIT"<=3000 THEN '1' WHEN "CUST_CREDIT_LIMIT" <=9000 THEN '2' WHEN "CUST_CREDIT_LIMIT"<=15000 THEN '3' END "CUST_CREDIT_LIMIT" ,"CUST_CITY" FROM mining_data
This procedure performs numerical and categorical binning and inserts the transformation definitions in transformation definition tables. The procedure computes bin boundaries based on intrinsic relationships between predictors and a target.
INSERT_BIN_SUPER
uses an intelligent binning technique known as supervised binning. It builds a single-predictor decision tree and derives the bin boundaries from splits within the tree.
INSERT_BIN_SUPER
bins all the VARCHAR2
, CHAR
, NUMBER
, and FLOAT
columns in the data source unless you specify a list of columns to ignore.
DBMS_DATA_MINING_TRANSFORM.INSERT_BIN_SUPER ( num_table_name IN VARCHAR2, cat_table_name IN VARCHAR2, data_table_name IN VARCHAR2, target_column_name IN VARCHAR2, max_bin_num IN PLS_INTEGER DEFAULT 1000, exclude_list IN COLUMN_LIST DEFAULT NULL, num_schema_name IN VARCHAR2 DEFAULT NULL, cat_schema_name IN VARCHAR2 DEFAULT NULL, data_schema_name IN VARCHAR2 DEFAULT NULL, rem_table_name IN VARCHAR2 DEFAULT NULL, rem_schema_name IN VARCHAR2 DEFAULT NULL);
Table 46-24 INSERT_BIN_SUPER Procedure Parameters
Parameter | Description |
---|---|
|
Name of the transformation definition table for numerical binning. You can use the CREATE_BIN_NUM Procedure to create the definition table. The following columns are required: COL VARCHAR2(30) VAL VNUMBER BIN VARCHAR2(4000)
|
|
Name of the transformation definition table for categorical binning. You can use the CREATE_BIN_CAT Procedure to create the definition table. The following columns are required: COL VARCHAR2(30) VAL VARCHAR2(4000) BIN VARCHAR2(4000)
|
|
Name of the table containing the data to be transformed |
|
Name of a column to be used as the target for the decision tree models |
|
The maximum number of bins. The default is 1000. |
|
List of columns to be excluded from the binning process. If you do not specify The format of dbms_data_mining_transform.COLUMN_LIST('col1','col2', ...'coln') |
|
Schema of |
|
Schema of |
|
Schema of |
|
Name of a column removal definition table. The table must have the columns described in "CREATE_COL_REM Procedure". You can use |
|
Schema of |
See Oracle Data Mining User's Guide for details about numerical and categorical data.
Columns that have no significant splits are not binned. You can remove the unbinned columns from the mining data by specifying a column removal definition table. If you do not specify a column removal definition table, the unbinned columns remain in the mining data.
See Oracle Data Mining Concepts to learn more about decision trees in Oracle Data Mining
In this example, INSERT_BIN_SUPER
computes the bin boundaries for predictors of cust_credit_limit
and inserts the transformations in transformation definition tables. One predictor is numerical, the other is categorical. (INSERT_BIN_SUPER
determines that the cust_postal_code
column is not a significant predictor.) STACK
procedures create transformation lists from the contents of the definition tables.
The SQL expressions that compute the transformations are shown in the views MINING_DATA_STACK_NUM
and MINING_DATA_STACK_CAT
. The views are for display purposes only; they cannot be used to embed the transformations in a model.
CREATE OR REPLACE VIEW mining_data AS SELECT cust_id, cust_year_of_birth, cust_marital_status, cust_postal_code, cust_credit_limit FROM sh.customers; DESCRIBE mining_data Name Null? Type -------------------------------- -------- ------------------------------------ CUST_ID NOT NULL NUMBER CUST_YEAR_OF_BIRTH NOT NULL NUMBER(4) CUST_MARITAL_STATUS VARCHAR2(20) CUST_POSTAL_CODE NOT NULL VARCHAR2(10) CUST_CREDIT_LIMIT NUMBER BEGIN dbms_data_mining_transform.CREATE_BIN_NUM( bin_table_name => 'bin_num_tbl'); dbms_data_mining_transform.CREATE_BIN_CAT( bin_table_name => 'bin_cat_tbl'); dbms_data_mining_transform.CREATE_COL_REM( rem_table_name => 'rem_tbl'); END; / BEGIN COMMIT; dbms_data_mining_transform.INSERT_BIN_SUPER ( num_table_name => 'bin_num_tbl', cat_table_name => 'bin_cat_tbl', data_table_name => 'mining_data', target_column_name => 'cust_credit_limit', max_bin_num => 4, exclude_list => dbms_data_mining_transform.COLUMN_LIST('cust_id'), num_schema_name => 'dmuser', cat_schema_name => 'dmuser', data_schema_name => 'dmuser', rem_table_name => 'rem_tbl', rem_schema_name => 'dmuser'); COMMIT; END; / set numwidth 8 column val off SELECT col, val, bin FROM bin_num_tbl ORDER BY bin ASC; COL VAL BIN -------------------- -------- ---------- CUST_YEAR_OF_BIRTH 1923.5 1 CUST_YEAR_OF_BIRTH 1923.5 1 CUST_YEAR_OF_BIRTH 1945.5 2 CUST_YEAR_OF_BIRTH 1980.5 3 CUST_YEAR_OF_BIRTH 4 column val on column val format a20 SELECT col, val, bin FROM bin_cat_tbl ORDER BY bin ASC; COL VAL BIN -------------------- -------------------- ---------- CUST_MARITAL_STATUS married 1 CUST_MARITAL_STATUS single 2 CUST_MARITAL_STATUS Mar-AF 3 CUST_MARITAL_STATUS Mabsent 3 CUST_MARITAL_STATUS Divorc. 3 CUST_MARITAL_STATUS Married 3 CUST_MARITAL_STATUS Widowed 3 CUST_MARITAL_STATUS NeverM 3 CUST_MARITAL_STATUS Separ. 3 CUST_MARITAL_STATUS divorced 4 CUST_MARITAL_STATUS widow 4 SELECT col from rem_tbl; COL -------------------- CUST_POSTAL_CODE DECLARE xforms_num dbms_data_mining_transform.TRANSFORM_LIST; xforms_cat dbms_data_mining_transform.TRANSFORM_LIST; BEGIN dbms_data_mining_transform.STACK_BIN_NUM ( bin_table_name => 'bin_num_tbl', xform_list => xforms_num); dbms_data_mining_transform.XFORM_STACK ( xform_list => xforms_num, data_table_name => 'mining_data', xform_view_name => 'mining_data_stack_num'); dbms_data_mining_transform.STACK_BIN_CAT ( bin_table_name => 'bin_cat_tbl', xform_list => xforms_cat); dbms_data_mining_transform.XFORM_STACK ( xform_list => xforms_cat, data_table_name => 'mining_data', xform_view_name => 'mining_data_stack_cat'); END; / set long 3000 SELECT text FROM user_views WHERE view_name IN 'MINING_DATA_STACK_NUM'; TEXT -------------------------------------------------------------------------------- SELECT "CUST_ID",CASE WHEN "CUST_YEAR_OF_BIRTH"<1923.5 THEN '1' WHEN "CUST_YEAR_ OF_BIRTH"<=1923.5 THEN '1' WHEN "CUST_YEAR_OF_BIRTH"<=1945.5 THEN '2' WHEN "CUST _YEAR_OF_BIRTH"<=1980.5 THEN '3' WHEN "CUST_YEAR_OF_BIRTH" IS NOT NULL THEN '4' END "CUST_YEAR_OF_BIRTH","CUST_MARITAL_STATUS","CUST_POSTAL_CODE","CUST_CREDIT_L IMIT" FROM mining_data SELECT text FROM user_views WHERE view_name IN 'MINING_DATA_STACK_CAT'; TEXT -------------------------------------------------------------------------------- SELECT "CUST_ID","CUST_YEAR_OF_BIRTH",DECODE("CUST_MARITAL_STATUS",'Divorc.','3' ,'Mabsent','3','Mar-AF','3','Married','3','NeverM','3','Separ.','3','Widowed','3 ','divorced','4','married','1','single','2','widow','4') "CUST_MARITAL_STATUS"," CUST_POSTAL_CODE","CUST_CREDIT_LIMIT" FROM mining_data
This procedure replaces numeric outliers with nulls and inserts the transformation definitions in a transformation definition table.
INSERT_CLIP_TRIM_TAIL
computes the boundaries of the data based on a specified percentage. It removes the values that fall outside the boundaries (tail values) from the data. If you wish to replace the tail values instead of removing them, use the INSERT_CLIP_WINSOR_TAIL Procedure.
INSERT_CLIP_TRIM_TAIL
clips all the NUMBER
and FLOAT
columns in the data source unless you specify a list of columns to ignore.
DBMS_DATA_MINING_TRANSFORM.INSERT_CLIP_TRIM_TAIL ( clip_table_name IN VARCHAR2, data_table_name IN VARCHAR2, tail_frac IN NUMBER DEFAULT 0.025, exclude_list IN COLUMN_LIST DEFAULT NULL, clip_schema_name IN VARCHAR2 DEFAULT NULL, data_schema_name IN VARCHAR2 DEFAULT NULL);
Table 46-25 INSERT_CLIP_TRIM_TAIL Procedure Parameters
Parameter | Description |
---|---|
|
Name of the transformation definition table for numerical clipping. You can use the CREATE_CLIP Procedure to create the definition table. The following columns are required: COL VARCHAR2(30) LCUT NUMBER LVAL NUMBER RCUT NUMBER RVAL NUMBER
|
|
Name of the table containing the data to be transformed |
|
The percentage of non-null values to be designated as outliers at each end of the data. For example, if If The default value of |
|
List of numerical columns to be excluded from the clipping process. If you do not specify The format of dbms_data_mining_transform.COLUMN_LIST('col1','col2', ...'coln') |
|
Schema of |
|
Schema of |
See Oracle Data Mining User's Guide for details about numerical data.
The DBMS_DATA_MINING_TRANSFORM
package provides two clipping procedures: INSERT_CLIP_TRIM_TAIL
and INSERT_CLIP_WINSOR_TAIL
. Both procedures compute the boundaries as follows:
Count the number of non-null values, n
, and sort them in ascending order
Calculate the number of outliers, t
, as n*tail_frac
Define the lower boundary lcut
as the value at position 1+
floor
(t)
Define the upper boundary rcut as the value at position n-
floor
(t)
(The SQL FLOOR
function returns the largest integer less than or equal to t
.)
All values that are <= lcut
or => rcut
are designated as outliers.
INSERT_CLIP_TRIM_TAIL
replaces the outliers with nulls, effectively removing them from the data.
INSERT_CLIP_WINSOR_TAIL
assigns lcut
to the low outliers and rcut
to the high outliers.
In this example, INSERT_CLIP_TRIM_TAIL
trims 10% of the data in two columns (5% from the high end and 5% from the low end) and inserts the transformations in a transformation definition table. The STACK_CLIP Procedure creates a transformation list from the contents of the definition table.
The SQL expression that computes the trimming is shown in the view MINING_DATA_STACK
. The view is for display purposes only; it cannot be used to embed the transformations in a model.
CREATE OR REPLACE VIEW mining_data AS SELECT cust_id, cust_year_of_birth, cust_credit_limit, cust_city FROM sh.customers; DESCRIBE mining_data Name Null? Type ------------------------------- -------- ------------------- CUST_ID NOT NULL NUMBER CUST_YEAR_OF_BIRTH NOT NULL NUMBER(4) CUST_CREDIT_LIMIT NUMBER CUST_CITY NOT NULL VARCHAR2(30) BEGIN dbms_data_mining_transform.CREATE_CLIP( clip_table_name => 'clip_tbl'); dbms_data_mining_transform.INSERT_CLIP_TRIM_TAIL( clip_table_name => 'clip_tbl', data_table_name => 'mining_data', tail_frac => 0.05, exclude_list => DBMS_DATA_MINING_TRANSFORM.COLUMN_LIST('cust_id')); END; / SELECT col, lcut, lval, rcut, rval FROM clip_tbl ORDER BY col ASC; COL LCUT LVAL RCUT RVAL -------------------- -------- -------- -------- -------- CUST_CREDIT_LIMIT 1500 11000 CUST_YEAR_OF_BIRTH 1934 1982 DECLARE xforms dbms_data_mining_transform.TRANSFORM_LIST; BEGIN dbms_data_mining_transform.STACK_CLIP ( clip_table_name => 'clip_tbl', xform_list => xforms); dbms_data_mining_transform.XFORM_STACK ( xform_list => xforms, data_table_name => 'mining_data', xform_view_name => 'mining_data_stack'); END; / set long 3000 SELECT text FROM user_views WHERE view_name IN 'MINING_DATA_STACK'; TEXT -------------------------------------------------------------------------------- SELECT "CUST_ID",CASE WHEN "CUST_YEAR_OF_BIRTH" < 1934 THEN NULL WHEN "CUST_YEAR _OF_BIRTH" > 1982 THEN NULL ELSE "CUST_YEAR_OF_BIRTH" END "CUST_YEAR_OF_BIRTH",C ASE WHEN "CUST_CREDIT_LIMIT" < 1500 THEN NULL WHEN "CUST_CREDIT_LIMIT" > 11000 T HEN NULL ELSE "CUST_CREDIT_LIMIT" END "CUST_CREDIT_LIMIT","CUST_CITY" FROM minin g_data
This procedure replaces numeric outliers with the upper or lower boundary values. It inserts the transformation definitions in a transformation definition table.
INSERT_CLIP_WINSOR_TAIL
computes the boundaries of the data based on a specified percentage. It replaces the values that fall outside the boundaries (tail values) with the related boundary value. If you wish to set tail values to null, use the INSERT_CLIP_TRIM_TAIL Procedure.
INSERT_CLIP_WINSOR_TAIL
clips all the NUMBER
and FLOAT
columns in the data source unless you specify a list of columns to ignore.
DBMS_DATA_MINING_TRANSFORM.INSERT_CLIP_WINSOR_TAIL ( clip_table_name IN VARCHAR2, data_table_name IN VARCHAR2, tail_frac IN NUMBER DEFAULT 0.025, exclude_list IN COLUMN_LIST DEFAULT NULL, clip_schema_name IN VARCHAR2 DEFAULT NULL, data_schema_name IN VARCHAR2 DEFAULT NULL);
Table 46-26 INSERT_CLIP_WINSOR_TAIL Procedure Parameters
Parameter | Description |
---|---|
|
Name of the transformation definition table for numerical clipping. You can use the CREATE_CLIP Procedure to create the definition table. The following columns are required: COL VARCHAR2(30) LCUT NUMBER LVAL NUMBER RCUT NUMBER RVAL NUMBER
|
|
Name of the table containing the data to be transformed |
|
The percentage of non-null values to be designated as outliers at each end of the data. For example, if If The default value of |
|
List of numerical columns to be excluded from the clipping process. If you do not specify The format of dbms_data_mining_transform.COLUMN_LIST('col1','col2', ...'coln') |
|
Schema of |
|
Schema of |
See Oracle Data Mining User's Guide for details about numerical data.
The DBMS_DATA_MINING_TRANSFORM
package provides two clipping procedures: INSERT_CLIP_WINSOR_TAIL
and INSERT_CLIP_TRIM_TAIL
. Both procedures compute the boundaries as follows:
Count the number of non-null values, n
, and sort them in ascending order
Calculate the number of outliers, t
, as n*tail_frac
Define the lower boundary lcut
as the value at position 1+
floor
(t)
Define the upper boundary rcut as the value at position n-
floor
(t)
(The SQL FLOOR
function returns the largest integer less than or equal to t
.)
All values that are <= lcut
or => rcut
are designated as outliers.
INSERT_CLIP_WINSOR_TAIL
assigns lcut
to the low outliers and rcut
to the high outliers.
INSERT_CLIP_TRIM_TAIL
replaces the outliers with nulls, effectively removing them from the data.
In this example, INSERT_CLIP_WINSOR_TAIL
winsorizes 10% of the data in two columns (5% from the high end, and 5% from the low end) and inserts the transformations in a transformation definition table. The STACK_CLIP Procedure creates a transformation list from the contents of the definition table.
The SQL expression that computes the transformation is shown in the view MINING_DATA_STACK
. The view is for display purposes only; it cannot be used to embed the transformations in a model.
CREATE OR REPLACE VIEW mining_data AS SELECT cust_id, cust_year_of_birth, cust_credit_limit, cust_city FROM sh.customers; describe mining_data Name Null? Type ---------------------------------------- -------- ------------- CUST_ID NOT NULL NUMBER CUST_YEAR_OF_BIRTH NOT NULL NUMBER(4) CUST_CREDIT_LIMIT NUMBER CUST_CITY NOT NULL VARCHAR2(30) BEGIN dbms_data_mining_transform.CREATE_CLIP( clip_table_name => 'clip_tbl'); dbms_data_mining_transform.INSERT_CLIP_WINSOR_TAIL( clip_table_name => 'clip_tbl', data_table_name => 'mining_data', tail_frac => 0.05, exclude_list => DBMS_DATA_MINING_TRANSFORM.COLUMN_LIST('cust_id')); END; / SELECT col, lcut, lval, rcut, rval FROM clip_tbl ORDER BY col ASC; COL LCUT LVAL RCUT RVAL ------------------------------ -------- -------- -------- -------- CUST_CREDIT_LIMIT 1500 1500 11000 11000 CUST_YEAR_OF_BIRTH 1934 1934 1982 1982 DECLARE xforms dbms_data_mining_transform.TRANSFORM_LIST; BEGIN dbms_data_mining_transform.STACK_CLIP ( clip_table_name => 'clip_tbl', xform_list => xforms); dbms_data_mining_transform.XFORM_STACK ( xform_list => xforms, data_table_name => 'mining_data', xform_view_name => 'mining_data_stack'); END; / set long 3000 SQL> SELECT text FROM user_views WHERE view_name IN 'MINING_DATA_STACK'; TEXT -------------------------------------------------------------------------------- SELECT "CUST_ID",CASE WHEN "CUST_YEAR_OF_BIRTH" < 1934 THEN 1934 WHEN "CUST_YEAR _OF_BIRTH" > 1982 THEN 1982 ELSE "CUST_YEAR_OF_BIRTH" END "CUST_YEAR_OF_BIRTH",C ASE WHEN "CUST_CREDIT_LIMIT" < 1500 THEN 1500 WHEN "CUST_CREDIT_LIMIT" > 11000 T HEN 11000 ELSE "CUST_CREDIT_LIMIT" END "CUST_CREDIT_LIMIT","CUST_CITY" FROM mini ng_data
This procedure replaces missing categorical values with the value that occurs most frequently in the column (the mode). It inserts the transformation definitions in a transformation definition table.
INSERT_MISS_CAT_MODE
replaces missing values in all VARCHAR2
and CHAR
columns in the data source unless you specify a list of columns to ignore.
DBMS_DATA_MINING_TRANSFORM.INSERT_MISS_CAT_MODE ( miss_table_name IN VARCHAR2, data_table_name IN VARCHAR2, exclude_list IN COLUMN_LIST DEFAULT NULL, miss_schema_name IN VARCHAR2 DEFAULT NULL, data_schema_name IN VARCHAR2 DEFAULT NULL);
Table 46-27 INSERT_MISS_CAT_MODE Procedure Parameters
Parameter | Description |
---|---|
|
Name of the transformation definition table for categorical missing value treatment. You can use the CREATE_MISS_CAT Procedure to create the definition table. The following columns are required: COL VARCHAR2(30) VAL VARCHAR2(4000)
|
|
Name of the table containing the data to be transformed |
|
List of categorical columns to be excluded from missing value treatment. If you do not specify The format of dbms_data_mining_transform.COLUMN_LIST('col1','col2', ...'coln') |
|
Schema of |
|
Schema of |
See Oracle Data Mining User's Guide for details about categorical data.
If you wish to replace categorical missing values with a value other than the mode, you can edit the transformation definition table.
See Also:
Oracle Data Mining User's Guide for information about default missing value treatment in Oracle Data MiningIn this example, INSERT_MISS_CAT_MODE
computes missing value treatment for cust_city
and inserts the transformation in a transformation definition table. The STACK_MISS_CAT Procedure creates a transformation list from the contents of the definition table.
The SQL expression that computes the transformation is shown in the view MINING_DATA_STACK
. The view is for display purposes only; it cannot be used to embed the transformations in a model.
CREATE OR REPLACE VIEW mining_data AS SELECT cust_id, cust_year_of_birth, cust_city FROM sh.customers; describe mining_data Name Null? Type -------------------------------- -------- ---------------- CUST_ID NOT NULL NUMBER CUST_YEAR_OF_BIRTH NOT NULL NUMBER(4) CUST_CITY NOT NULL VARCHAR2(30) BEGIN dbms_data_mining_transform.create_miss_cat( miss_table_name => 'missc_tbl'); dbms_data_mining_transform.insert_miss_cat_mode( miss_table_name => 'missc_tbl', data_table_name => 'mining_data'); END; / SELECT stats_mode(cust_city) FROM mining_data; STATS_MODE(CUST_CITY) ------------------------------ Los Angeles SELECT col, val from missc_tbl; COL VAL ------------------------------ ------------------------------ CUST_CITY Los Angeles DECLARE xforms dbms_data_mining_transform.TRANSFORM_LIST; BEGIN dbms_data_mining_transform.STACK_MISS_CAT ( miss_table_name => 'missc_tbl', xform_list => xforms); dbms_data_mining_transform.XFORM_STACK ( xform_list => xforms, data_table_name => 'mining_data', xform_view_name => 'mining_data_stack'); END; / set long 3000 SELECT text FROM user_views WHERE view_name IN 'MINING_DATA_STACK'; TEXT -------------------------------------------------------------------------------- SELECT "CUST_ID","CUST_YEAR_OF_BIRTH",NVL("CUST_CITY",'Los Angeles') "CUST_CITY" FROM mining_data
This procedure replaces missing numerical values with the average (the mean) and inserts the transformation definitions in a transformation definition table.
INSERT_MISS_NUM_MEAN
replaces missing values in all NUMBER
and FLOAT
columns in the data source unless you specify a list of columns to ignore.
DBMS_DATA_MINING_TRANSFORM.INSERT_MISS_NUM_MEAN ( miss_table_name IN VARCHAR2, data_table_name IN VARCHAR2, exclude_list IN COLUMN_LIST DEFAULT NULL, round_num IN PLS_INTEGER DEFAULT 6, miss_schema_name IN VARCHAR2 DEFAULT NULL, data_schema_name IN VARCHAR2 DEFAULT NULL);
Table 46-28 INSERT_MISS_NUM_MEAN Procedure Parameters
Parameter | Description |
---|---|
|
Name of the transformation definition table for numerical missing value treatment. You can use the CREATE_MISS_NUM Procedure to create the definition table. The following columns are required by COL VARCHAR2(30) VAL NUMBER
|
|
Name of the table containing the data to be transformed |
|
List of numerical columns to be excluded from missing value treatment. If you do not specify The format of dbms_data_mining_transform.COLUMN_LIST('col1','col2', ...'coln') |
|
The number of significant digits to use for the mean. The default number is 6. |
|
Schema of |
|
Schema of |
See Oracle Data Mining User's Guide for details about numerical data.
If you wish to replace numerical missing values with a value other than the mean, you can edit the transformation definition table.
See Also:
Oracle Data Mining User's Guide for information about default missing value treatment in Oracle Data MiningIn this example, INSERT_MISS_NUM_MEAN
computes missing value treatment for cust_year_of_birth
and inserts the transformation in a transformation definition table. The STACK_MISS_NUM Procedure creates a transformation list from the contents of the definition table.
The SQL expression that computes the transformation is shown in the view MINING_DATA_STACK
. The view is for display purposes only; it cannot be used to embed the transformations in a model.
CREATE OR REPLACE VIEW mining_data AS SELECT cust_id, cust_year_of_birth, cust_city FROM sh.customers; DESCRIBE mining_data Name Null? Type ------------------------------------------ -------- ------------------- CUST_ID NOT NULL NUMBER CUST_YEAR_OF_BIRTH NOT NULL NUMBER(4) CUST_CITY NOT NULL VARCHAR2(30) BEGIN dbms_data_mining_transform.create_miss_num( miss_table_name => 'missn_tbl'); dbms_data_mining_transform.insert_miss_num_mean( miss_table_name => 'missn_tbl', data_table_name => 'mining_data', exclude_list => DBMS_DATA_MINING_TRANSFORM.COLUMN_LIST('cust_id')); END; / set numwidth 4 column val off SELECT col, val FROM missn_tbl; COL VAL -------------------- ---- CUST_YEAR_OF_BIRTH 1957 SELECT avg(cust_year_of_birth) FROM mining_data; AVG(CUST_YEAR_OF_BIRTH) ----------------------- 1957 DECLARE xforms dbms_data_mining_transform.TRANSFORM_LIST; BEGIN dbms_data_mining_transform.STACK_MISS_NUM ( miss_table_name => 'missn_tbl', xform_list => xforms); dbms_data_mining_transform.XFORM_STACK ( xform_list => xforms, data_table_name => 'mining_data', xform_view_name => 'mining_data_stack'); END; / set long 3000 SELECT text FROM user_views WHERE view_name IN 'MINING_DATA_STACK'; TEXT -------------------------------------------------------------------------------- SELECT "CUST_ID",NVL("CUST_YEAR_OF_BIRTH",1957.4) "CUST_YEAR_OF_BIRTH","CUST_CIT Y" FROM mining_data
This procedure performs linear normalization and inserts the transformation definitions in a transformation definition table. INSERT_NORM_LIN_MINMAX
computes the minimum and maximum values from the data and sets the value of shift
and scale
as follows:
shift = min scale = max - min
Normalization is computed as:
x_new = (x_old - shift)/scale
INSERT_NORM_LIN_MINMAX
rounds the value of scale
to a specified number of significant digits before storing it in the transformation definition table.
INSERT_NORM_LIN_MINMAX
normalizes all the NUMBER
and FLOAT
columns in the data source unless you specify a list of columns to ignore.
DBMS_DATA_MINING_TRANSFORM.INSERT_NORM_LIN_MINMAX ( norm_table_name IN VARCHAR2, data_table_name IN VARCHAR2, exclude_list IN COLUMN_LIST DEFAULT NULL, round_num IN PLS_INTEGER DEFAULT 6, norm_schema_name IN VARCHAR2 DEFAULT NULL, data_schema_name IN VARCHAR2 DEFAULT NULL);
Table 46-29 INSERT_NORM_LIN_MINMAX Procedure Parameters
Parameter | Description |
---|---|
|
Name of the transformation definition table for linear normalization. You can use the CREATE_NORM_LIN Procedure to create the definition table. The following columns are required: COL VARCHAR2(30) SHIFT NUMBER SCALE NUMBER
|
|
Name of the table containing the data to be transformed |
|
List of numerical columns to be excluded from normalization. If you do not specify The format of dbms_data_mining_transform.COLUMN_LIST('col1','col2', ...'coln') |
|
The number of significant digits to use for the minimum and maximum. The default number is 6. |
|
Schema of |
|
Schema of |
See Oracle Data Mining User's Guide for details about numerical data.
In this example, INSERT_NORM_LIN_MINMAX
normalizes the cust_year_of_birth
column and inserts the transformation in a transformation definition table. The STACK_NORM_LIN Procedure creates a transformation list from the contents of the definition table.
The SQL expression that computes the transformation is shown in the view MINING_DATA_STACK
. The view is for display purposes only; it cannot be used to embed the transformations in a model.
CREATE OR REPLACE VIEW mining_data AS SELECT cust_id, cust_gender, cust_year_of_birth FROM sh.customers; describe mining_data Name Null? Type ------------------------------------ -------- ---------------- CUST_ID NOT NULL NUMBER CUST_GENDER NOT NULL CHAR(1) CUST_YEAR_OF_BIRTH NOT NULL NUMBER(4) BEGIN dbms_data_mining_transform.CREATE_NORM_LIN( norm_table_name => 'norm_tbl'); dbms_data_mining_transform.INSERT_NORM_LIN_MINMAX( norm_table_name => 'norm_tbl', data_table_name => 'mining_data', exclude_list => dbms_data_mining_transform.COLUMN_LIST( 'cust_id'), round_num => 3); END; / SELECT col, shift, scale FROM norm_tbl; COL SHIFT SCALE ------------------------------ ---------- ---------- CUST_YEAR_OF_BIRTH 1910 77 DECLARE xforms dbms_data_mining_transform.TRANSFORM_LIST; BEGIN dbms_data_mining_transform.STACK_NORM_LIN ( norm_table_name => 'norm_tbl', xform_list => xforms); dbms_data_mining_transform.XFORM_STACK ( xform_list => xforms, data_table_name => 'mining_data', xform_view_name => 'mining_data_stack'); END; / set long 3000 SELECT text FROM user_views WHERE view_name IN 'MINING_DATA_STACK'; TEXT -------------------------------------------------------------------------------- SELECT "CUST_ID","CUST_GENDER",("CUST_YEAR_OF_BIRTH"-1910)/77 "CUST_YEAR_OF_BIRT H" FROM mining_data
This procedure performs linear normalization and inserts the transformation definitions in a transformation definition table. INSERT_NORM_LIN_SCALE
computes the minimum and maximum values from the data and sets the value of shift
and scale
as follows:
shift = 0 scale = max(abs(max), abs(min))
Normalization is computed as:
x_new = (x_old)/scale
INSERT_NORM_LIN_SCALE
rounds the value of scale
to a specified number of significant digits before storing it in the transformation definition table.
INSERT_NORM_LIN_SCALE
normalizes all the NUMBER
and FLOAT
columns in the data source unless you specify a list of columns to ignore.
DBMS_DATA_MINING_TRANSFORM.INSERT_NORM_LIN_SCALE ( norm_table_name IN VARCHAR2, data_table_name IN VARCHAR2, exclude_list IN COLUMN_LIST DEFAULT NULL, round_num IN PLS_INTEGER DEFAULT 6, norm_schema_name IN VARCHAR2 DEFAULT NULL, data_schema_name IN VARCHAR2 DEFAULT NULL);
Table 46-30 INSERT_NORM_LIN_SCALE Procedure Parameters
Parameter | Description |
---|---|
|
Name of the transformation definition table for linear normalization. You can use the CREATE_NORM_LIN Procedure to create the definition table. The following columns are required: COL VARCHAR2(30) SHIFT NUMBER SCALE NUMBER
|
|
Name of the table containing the data to be transformed |
|
List of numerical columns to be excluded from normalization. If you do not specify The format of dbms_data_mining_transform.COLUMN_LIST('col1','col2', ...'coln') |
|
The number of significant digits to use for |
|
Schema of |
|
Schema of |
See Oracle Data Mining User's Guide for details about numerical data.
In this example, INSERT_NORM_LIN_SCALE
normalizes the cust_year_of_birth
column and inserts the transformation in a transformation definition table. The STACK_NORM_LIN Procedure creates a transformation list from the contents of the definition table.
The SQL expression that computes the transformation is shown in the view MINING_DATA_STACK
. The view is for display purposes only; it cannot be used to embed the transformations in a model.
CREATE OR REPLACE VIEW mining_data AS SELECT cust_id, cust_gender, cust_year_of_birth FROM sh.customers; DESCRIBE mining_data Name Null? Type ---------------------------------- -------- ------------------ CUST_ID NOT NULL NUMBER CUST_GENDER NOT NULL CHAR(1) CUST_YEAR_OF_BIRTH NOT NULL NUMBER(4) BEGIN dbms_data_mining_transform.CREATE_NORM_LIN( norm_table_name => 'norm_tbl'); dbms_data_mining_transform.INSERT_NORM_LIN_SCALE( norm_table_name => 'norm_tbl', data_table_name => 'mining_data', exclude_list => dbms_data_mining_transform.COLUMN_LIST( 'cust_id'), round_num => 3); END; / SELECT col, shift, scale FROM norm_tbl; COL SHIFT SCALE -------------------- ----- ----- CUST_YEAR_OF_BIRTH 0 1990 DECLARE xforms dbms_data_mining_transform.TRANSFORM_LIST; BEGIN dbms_data_mining_transform.STACK_NORM_LIN ( norm_table_name => 'norm_tbl', xform_list => xforms); dbms_data_mining_transform.XFORM_STACK ( xform_list => xforms, data_table_name => 'mining_data', xform_view_name => 'mining_data_stack'); END; / set long 3000 SELECT text FROM user_views WHERE view_name IN 'MINING_DATA_STACK'; TEXT -------------------------------------------------------------------------------- SELECT "CUST_ID","CUST_GENDER",("CUST_YEAR_OF_BIRTH"-0)/1990 "CUST_YEAR_OF_BIRTH " FROM mining_data
This procedure performs linear normalization and inserts the transformation definitions in a transformation definition table. INSERT_NORM_LIN_ZSCORE
computes the mean and the standard deviation from the data and sets the value of shift
and scale
as follows:
shift = mean scale = stddev
Normalization is computed as:
x_new = (x_old - shift)/scale
INSERT_NORM_LIN_ZSCORE
rounds the value of scale
to a specified number of significant digits before storing it in the transformation definition table.
INSERT_NORM_LIN_ZSCORE
normalizes all the NUMBER
and FLOAT
columns in the data unless you specify a list of columns to ignore.
DBMS_DATA_MINING_TRANSFORM.INSERT_NORM_LIN_ZSCORE ( norm_table_name IN VARCHAR2, data_table_name IN VARCHAR2, exclude_list IN COLUMN_LIST DEFAULT NULL, round_num IN PLS_INTEGER DEFAULT 6, norm_schema_name IN VARCHAR2 DEFAULT NULL, data_schema_name IN VARCHAR2 DEFAULT NULL);
Table 46-31 INSERT_NORM_LIN_ZSCORE Procedure Parameters
Parameter | Description |
---|---|
|
Name of the transformation definition table for linear normalization. You can use the CREATE_NORM_LIN Procedure to create the definition table. The following columns are required: COL VARCHAR2(30) SHIFT NUMBER SCALE NUMBER
|
|
Name of the table containing the data to be transformed |
|
List of numerical columns to be excluded from normalization. If you do not specify The format of dbms_data_mining_transform.COLUMN_LIST('col1','col2', ...'coln') |
|
The number of significant digits to use for |
|
Schema of |
|
Schema of |
See Oracle Data Mining User's Guide for details about numerical data.
In this example, INSERT_NORM_LIN_ZSCORE
normalizes the cust_year_of_birth
column and inserts the transformation in a transformation definition table. The STACK_NORM_LIN Procedure creates a transformation list from the contents of the definition table.
The SQL expression that computes the transformation is shown in the view MINING_DATA_STACK
. The view is for display purposes only; it cannot be used to embed the transformations in a model.
CREATE OR REPLACE VIEW mining_data AS SELECT cust_id, cust_gender, cust_year_of_birth FROM sh.customers; DESCRIBE mining_data Name Null? Type ----------------------------------- -------- -------------------- CUST_ID NOT NULL NUMBER CUST_GENDER NOT NULL CHAR(1) CUST_YEAR_OF_BIRTH NOT NULL NUMBER(4) BEGIN dbms_data_mining_transform.CREATE_NORM_LIN( norm_table_name => 'norm_tbl'); dbms_data_mining_transform.INSERT_NORM_LIN_ZSCORE( norm_table_name => 'norm_tbl', data_table_name => 'mining_data', exclude_list => dbms_data_mining_transform.COLUMN_LIST( 'cust_id'), round_num => 3); END; / SELECT col, shift, scale FROM norm_tbl; COL SHIFT SCALE -------------------- ----- ----- CUST_YEAR_OF_BIRTH 1960 15 DECLARE xforms dbms_data_mining_transform.TRANSFORM_LIST; BEGIN dbms_data_mining_transform.STACK_NORM_LIN ( norm_table_name => 'norm_tbl', xform_list => xforms); dbms_data_mining_transform.XFORM_STACK ( xform_list => xforms, data_table_name => 'mining_data', xform_view_name => 'mining_data_stack'); END; / set long 3000 SQL> SELECT text FROM user_views WHERE view_name IN 'MINING_DATA_STACK'; TEXT -------------------------------------------------------------------------------- SELECT "CUST_ID","CUST_GENDER",("CUST_YEAR_OF_BIRTH"-1960)/15 "CUST_YEAR_OF_BIRT H" FROM mining_data
This procedure appends a row to a VARCHAR2
array that stores a SQL expression. The array can be used for specifying a transformation expression that is too long to be used with the SET_TRANSFORM Procedure.
The GET_EXPRESSION Function returns a row in the array.
When you use SET_EXPRESSION
to build a transformation expression, you must build a corresponding reverse transformation expression, create a transformation record, and add the transformation record to a transformation list.
DBMS_DATA_MINING_TRANSFORM.SET_EXPRESSION ( expression IN OUT NOCOPY EXPRESSION_REC, chunk VARCHAR2 DEFAULT NULL);
Table 46-32 SET_EXPRESSION Procedure Parameters
Parameter | Description |
---|---|
|
An expression record ( There are two See Table 46-1 for a description of the |
|
A |
You can pass NULL
in the chunk
argument to SET_EXPRESSION
to clear the previous chunk. The default value of chunk
is NULL
.
See "Operational Notes".
In this example, two calls to SET_EXPRESSION
construct a transformation expression and two calls construct the reverse transformation.
Note:
This example is for illustration purposes only. It shows howSET_EXPRESSION
appends the text provided in chunk
to the text that already exists in expression
. The SET_EXPRESSION
procedure is meant for constructing very long transformation expressions that cannot be specified in a VARCHAR2
argument to SET_TRANSFORM
.
Similarly while transformation lists are intended for embedding in a model, the transformation list v_xlst
is shown in an external view for illustration purposes.
CREATE OR REPLACE VIEW mining_data AS SELECT cust_id, cust_year_of_birth, cust_postal_code, cust_credit_limit FROM sh.customers; DECLARE v_expr dbms_data_mining_transform.EXPRESSION_REC; v_rexp dbms_data_mining_transform.EXPRESSION_REC; v_xrec dbms_data_mining_transform.TRANSFORM_REC; v_xlst dbms_data_mining_transform.TRANSFORM_LIST := dbms_data_mining_transform.TRANSFORM_LIST(NULL); BEGIN dbms_data_mining_transform.SET_EXPRESSION( EXPRESSION => v_expr, CHUNK => '("CUST_YEAR_OF_BIRTH"-1910)'); dbms_data_mining_transform.SET_EXPRESSION( EXPRESSION => v_expr, CHUNK => '/77'); dbms_data_mining_transform.SET_EXPRESSION( EXPRESSION => v_rexp, CHUNK => '"CUST_YEAR_OF_BIRTH"*77'); dbms_data_mining_transform.SET_EXPRESSION( EXPRESSION => v_rexp, CHUNK => '+1910'); v_xrec := null; v_xrec.attribute_name := 'CUST_YEAR_OF_BIRTH'; v_xrec.expression := v_expr; v_xrec.reverse_expression := v_rexp; v_xlst.TRIM; v_xlst.extend(1); v_xlst(1) := v_xrec; dbms_data_mining_transform.XFORM_STACK ( xform_list => v_xlst, data_table_name => 'mining_data', xform_view_name => 'v_xlst_view'); dbms_output.put_line('===='); FOR i IN 1..v_xlst.count LOOP dbms_output.put_line('ATTR: '||v_xlst(i).attribute_name); dbms_output.put_line('SUBN: '||v_xlst(i).attribute_subname); FOR j IN v_xlst(i).expression.lb..v_xlst(i).expression.ub LOOP dbms_output.put_line('EXPR: '||v_xlst(i).expression.lstmt(j)); END LOOP; FOR j IN v_xlst(i).reverse_expression.lb.. v_xlst(i).reverse_expression.ub LOOP dbms_output.put_line('REXP: '||v_xlst(i).reverse_expression.lstmt(j)); END LOOP; dbms_output.put_line('===='); END LOOP; END; / ==== ATTR: CUST_YEAR_OF_BIRTH SUBN: EXPR: ("CUST_YEAR_OF_BIRTH"-1910) EXPR: /77 REXP: "CUST_YEAR_OF_BIRTH"*77 REXP: +1910 ====
This procedure appends the transformation instructions for an attribute to a transformation list.
DBMS_DATA_MINING_TRANSFORM.SET_TRANSFORM ( xform_list IN OUT NOCOPY TRANSFORM_LIST, attribute_name VARCHAR2, attribute_subname VARCHAR2, expression VARCHAR2, reverse_expression VARCHAR2, attribute_spec VARCHAR2 DEFAULT NULL);
Table 46-33 SET_TRANSFORM Procedure Parameters
Parameter | Description |
---|---|
|
A transformation list. See Table 46-1for a description of the |
|
Name of the attribute to be transformed |
|
Name of the nested attribute if |
|
A SQL expression that specifies the transformation of the attribute. |
|
A SQL expression that reverses the transformation for readability in model details and in the target of a supervised model (if the attribute is a target) |
|
One or more keywords that identify special treatment for the attribute during model build. Values are:
|
See "Operational Notes". The following sections are especially relevant:
As shown in the following example, you can eliminate an attribute by specifying a null transformation expression and reverse expression. You can also use the STACK interface to remove a column (CREATE_COL_REM Procedure and STACK_COL_REM Procedure).
This example uses SET_TRANSFORM
to append transformations to cust_stack
for the data set cust_info
and displays one row of the transformed data.
SET_TRANSFORM
divides the country_id
column by 10, removes the cust_year_of_birth
column, and multiplies the nested attribute custprods.mouse pad
by 10. (See "DESCRIBE_STACK Procedure" for the definition of cust_info
.)
describe cust_info Name Null? Type ----------------------------------------- -------- ---------------------------- CUST_ID NOT NULL NUMBER COUNTRY_ID NOT NULL NUMBER CUST_YEAR_OF_BIRTH NOT NULL NUMBER(4) CUSTPRODS SYS.DM_NESTED_NUMERICALS DECLARE cust_stack dbms_data_mining_transform.TRANSFORM_LIST; BEGIN dbms_data_mining_transform.SET_TRANSFORM (cust_stack, 'country_id', NULL, 'country_id/10', 'country_id*10'); dbms_data_mining_transform.SET_TRANSFORM (cust_stack, 'cust_year_of_birth', NULL, NULL, NULL); dbms_data_mining_transform.SET_TRANSFORM (cust_stack, 'custprods', 'Mouse Pad', 'value*100', 'value/100'); dbms_data_mining_transform.XFORM_STACK (cust_stack, 'cust_info', 'xform_cust_view'); END; / select * from xform_cust_view where cust_id = 100004; CUST_ID COUNTRY_ID CUSTPRODS(ATTRIBUTE_NAME, VALUE) ------- ---------- ---------------------------------------------- 100004 5279 DM_NESTED_NUMERICALS(DM_NESTED_NUMERICAL ('External 8X CD-ROM', 1), DM_NESTED_NUMERICAL('Keyboard Wrist Rest', 1))
This procedure adds categorical binning transformations to a transformation list.
DBMS_DATA_MINING_TRANSFORM.STACK_BIN_CAT ( bin_table_name IN VARCHAR2, xform_list IN OUT NOCOPY TRANSFORM_LIST, literal_flag IN BOOLEAN DEFAULT FALSE, bin_schema_name IN VARCHAR2 DEFAULT NULL);
Table 46-34 STACK_BIN_CAT Procedure Parameters
Parameter | Description |
---|---|
|
Name of the transformation definition table for categorical binning. You can use the CREATE_BIN_CAT Procedure to create the definition table. The table must be populated with transformation definitions before you call See Table 46-4, "Columns in a Transformation Definition Table for Categorical Binning" |
|
A transformation list. See Table 46-1 for a description of the |
|
Indicates whether the values in the Set See "INSERT_BIN_NUM_EQWIDTH Procedure" for an example. |
|
Schema of |
See "Operational Notes". The following sections are especially relevant:
This example shows how a binning transformation for the categorical column cust_postal_code
could be added to a stack called mining_data_stack
.
Note:
This example invokes the XFORM_STACK Procedure to show how the data is transformed by the stack.XFORM_STACK
simply generates an external view of the transformed data. The actual purpose of the STACK
procedures is to assemble a list of transformations for embedding in a model. The transformations are passed to CREATE_MODEL
in the xform_list
parameter. See INSERT_BIN_NUM_EQWIDTH Procedure for an example.CREATE or REPLACE VIEW mining_data AS SELECT cust_id, cust_postal_code, cust_credit_limit FROM sh.customers WHERE cust_id BETWEEN 100050 AND 100100; BEGIN dbms_data_mining_transform.CREATE_BIN_CAT ('bin_cat_tbl'); dbms_data_mining_transform.INSERT_BIN_CAT_FREQ ( bin_table_name => 'bin_cat_tbl', data_table_name => 'mining_data', bin_num => 3); END; / DECLARE MINING_DATA_STACK dbms_data_mining_transform.TRANSFORM_LIST; BEGIN dbms_data_mining_transform.STACK_BIN_CAT ( bin_table_name => 'bin_cat_tbl', xform_list => mining_data_stack); dbms_data_mining_transform.XFORM_STACK ( xform_list => mining_data_stack, data_table_name => 'mining_data', xform_view_name => 'mining_data_stack_view'); END; / -- Before transformation column cust_postal_code format a16 SELECT * from mining_data WHERE cust_id BETWEEN 100050 AND 100053 ORDER BY cust_id; CUST_ID CUST_POSTAL_CODE CUST_CREDIT_LIMIT ---------- ---------------- ----------------- 100050 76486 1500 100051 73216 9000 100052 69499 5000 100053 45704 7000 -- After transformation SELECT * FROM mining_data_stack_view WHERE cust_id BETWEEN 100050 AND 100053 ORDER BY cust_id; CUST_ID CUST_POSTAL_CODE CUST_CREDIT_LIMIT ---------- ---------------- ----------------- 100050 4 1500 100051 1 9000 100052 4 5000 100053 4 7000
This procedure adds numerical binning transformations to a transformation list.
DBMS_DATA_MINING_TRANSFORM.STACK_BIN_NUM ( bin_table_name IN VARCHAR2, xform_list IN OUT NOCOPY TRANSFORM_LIST, literal_flag IN BOOLEAN DEFAULT FALSE, bin_schema_name IN VARCHAR2 DEFAULT NULL);
Table 46-35 STACK_BIN_NUM Procedure Parameters
Parameter | Description |
---|---|
|
Name of the transformation definition table for numerical binning. You can use the CREATE_BIN_NUM Procedure to create the definition table. The table must be populated with transformation definitions before you call See Table 46-6, "Columns in a Transformation Definition Table for Numerical Binning". |
|
A transformation list. See Table 46-1 for a description of the |
|
Indicates whether the values in the Set See "INSERT_BIN_NUM_EQWIDTH Procedure" for an example. |
|
Schema of |
See "Operational Notes". The following sections are especially relevant:
This example shows how a binning transformation for the numerical column cust_credit_limit
could be added to a stack called mining_data_stack
.
Note:
This example invokes the XFORM_STACK Procedure to show how the data is transformed by the stack.XFORM_STACK
simply generates an external view of the transformed data. The actual purpose of the STACK
procedures is to assemble a list of transformations for embedding in a model. The transformations are passed to CREATE_MODEL
in the xform_list
parameter. See INSERT_BIN_NUM_EQWIDTH Procedure for an example.CREATE OR REPLACE VIEW mining_data AS SELECT cust_id, cust_postal_code, cust_credit_limit FROM sh.customers WHERE cust_id BETWEEN 100050 and 100100; BEGIN dbms_data_mining_transform.create_bin_num ('bin_num_tbl'); dbms_data_mining_transform.insert_bin_num_qtile ( bin_table_name => 'bin_num_tbl', data_table_name => 'mining_data', bin_num => 5, exclude_list => dbms_data_mining_transform.COLUMN_LIST('cust_id')); END; / DECLARE MINING_DATA_STACK dbms_data_mining_transform.TRANSFORM_LIST; BEGIN dbms_data_mining_transform.STACK_BIN_CAT ( bin_table_name => 'bin_num_tbl', xform_list => mining_data_stack); dbms_data_mining_transform.XFORM_STACK ( xform_list => mining_data_stack, data_table_name => 'mining_data', xform_view_name => 'mining_data_stack_view'); END; / -- Before transformation SELECT cust_id, cust_postal_code, ROUND(cust_credit_limit) FROM mining_data WHERE cust_id BETWEEN 100050 AND 100055 ORDER BY cust_id; CUST_ID CUST_POSTAL_CODE ROUND(CUST_CREDIT_LIMIT) ------- ----------------- ------------------------- 100050 76486 1500 100051 73216 9000 100052 69499 5000 100053 45704 7000 100055 74673 11000 100055 74673 11000 -- After transformation SELECT cust_id, cust_postal_code, ROUND(cust_credit_limit) FROM mining_data_stack_view WHERE cust_id BETWEEN 100050 AND 100055 ORDER BY cust_id; CUST_ID CUST_POSTAL_CODE ROUND(CUST_CREDIT_LIMITT) ------- ---------------- ------------------------- 100050 76486 100051 73216 2 100052 69499 1 100053 45704 100054 88021 3 100055 74673 3
This procedure adds clipping transformations to a transformation list.
DBMS_DATA_MINING_TRANSFORM.STACK_CLIP ( clip_table_name IN VARCHAR2, xform_list IN OUT NOCOPY TRANSFORM_LIST, clip_schema_name IN VARCHAR2 DEFAULT NULL);
Table 46-36 STACK_CLIP Procedure Parameters
Parameter | Description |
---|---|
|
Name of the transformation definition table for clipping.You can use the CREATE_CLIP Procedure to create the definition table. The table must be populated with transformation definitions before you call See Table 46-8, "Columns in a Transformation Definition Table for Clipping or Winsorizing" |
|
A transformation list. See Table 46-1 for a description of the |
|
Schema of |
See "Operational Notes". The following sections are especially relevant:
This example shows how a clipping transformation for the numerical column cust_credit_limit
could be added to a stack called mining_data_stack
.
Note:
This example invokes the XFORM_STACK Procedure to show how the data is transformed by the stack.XFORM_STACK
simply generates an external view of the transformed data. The actual purpose of the STACK
procedures is to assemble a list of transformations for embedding in a model. The transformations are passed to CREATE_MODEL
in the xform_list
parameter. See INSERT_BIN_NUM_EQWIDTH Procedure for an example.CREATE OR REPLACE VIEW mining_data AS SELECT cust_id, cust_postal_code, cust_credit_limit FROM sh.customers WHERE cust_id BETWEEN 100050 AND 100100; BEGIN dbms_data_mining_transform.create_clip ('clip_tbl'); dbms_data_mining_transform.insert_clip_winsor_tail ( clip_table_name => 'clip_tbl', data_table_name => 'mining_data', tail_frac => 0.25, exclude_list => dbms_data_mining_transform.COLUMN_LIST('cust_id')); END; / DECLARE MINING_DATA_STACK dbms_data_mining_transform.TRANSFORM_LIST; BEGIN dbms_data_mining_transform.STACK_CLIP ( clip_table_name => 'clip_tbl', xform_list => mining_data_stack); dbms_data_mining_transform.XFORM_STACK ( xform_list => mining_data_stack, data_table_name => 'mining_data', xform_view_name => 'mining_data_stack_view'); END; / -- Before transformation SELECT cust_id, cust_postal_code, round(cust_credit_limit) FROM mining_data WHERE cust_id BETWEEN 100050 AND 100054 ORDER BY cust_id; CUST_ID CUST_POSTAL_CODE ROUND(CUST_CREDIT_LIMIT) ------- ---------------- ------------------------ 100050 76486 1500 100051 73216 9000 100052 69499 5000 100053 45704 7000 100054 88021 11000 -- After transformation SELECT cust_id, cust_postal_code, round(cust_credit_limit) FROM mining_data_stack_view WHERE cust_id BETWEEN 100050 AND 100054 ORDER BY cust_id; CUST_ID CUST_POSTAL_CODE ROUND(CUST_CREDIT_LIMIT) ------- ---------------- ------------------------ 100050 76486 5000 100051 73216 9000 100052 69499 5000 100053 45704 7000 100054 88021 11000
This procedure adds column removal transformations to a transformation list.
DBMS_DATA_MINING_TRANSFORM.STACK_COL_REM ( rem_table_name IN VARCHAR2, xform_list IN OUT NOCOPY TRANSFORM_LIST, rem_schema_name IN VARCHAR2 DEFAULT NULL);
Table 46-37 STACK_COL_REM Procedure Parameters
Parameter | Description |
---|---|
|
Name of the transformation definition table for column removal. You can use the CREATE_COL_REM Procedure to create the definition table. See Table 46-10, "Columns in a Transformation Definition Table for Column Removal". The table must be populated with column names before you call |
|
A transformation list. See Table 46-1 for a description of the |
|
Schema of |
See "Operational Notes". The following sections are especially relevant:
This example shows how the column cust_credit_limit
could be removed in a transformation list called mining_data_stack
.
Note:
This example invokes the XFORM_STACK Procedure to show how the data is transformed by the stack.XFORM_STACK
simply generates an external view of the transformed data. The actual purpose of the STACK
procedures is to assemble a list of transformations for embedding in a model. The transformations are passed to CREATE_MODEL
in the xform_list
parameter. See INSERT_BIN_NUM_EQWIDTH Procedure for an example.CREATE OR REPLACE VIEW mining_data AS SELECT cust_id, country_id, cust_postal_code, cust_credit_limit FROM sh.customers; BEGIN dbms_data_mining_transform.create_col_rem ('rem_tbl'); END; / INSERT into rem_tbl VALUES (upper('cust_postal_code'), null); DECLARE MINING_DATA_STACK dbms_data_mining_transform.TRANSFORM_LIST; BEGIN dbms_data_mining_transform.stack_col_rem ( rem_table_name => 'rem_tbl', xform_list => mining_data_stack); dbms_data_mining_transform.XFORM_STACK ( xform_list => mining_data_stack, data_table_name => 'mining_data', xform_view_name => 'mining_data_stack_view'); END; / SELECT * FROM mining_data WHERE cust_id BETWEEN 100050 AND 100051 ORDER BY cust_id; CUST_ID COUNTRY_ID CUST_POSTAL_CODE CUST_CREDIT_LIMIT ------- ---------- ---------------- ----------------- 100050 52773 76486 1500 100051 52790 73216 9000 SELECT * FROM mining_data_stack_view WHERE cust_id BETWEEN 100050 AND 100051 ORDER BY cust_id; CUST_ID COUNTRY_ID CUST_CREDIT_LIMIT ------- ---------- ----------------- 100050 52773 1500 100051 52790 9000
This procedure adds categorical missing value transformations to a transformation list.
DBMS_DATA_MINING_TRANSFORM.STACK_MISS_CAT ( miss_table_name IN VARCHAR2, xform_list IN OUT NOCOPY TRANSFORM_LIST, miss_schema_name IN VARCHAR2 DEFAULT NULL);
Table 46-38 STACK_MISS_CAT Procedure Parameters
Parameter | Description |
---|---|
|
Name of the transformation definition table for categorical missing value treatment. You can use the CREATE_MISS_CAT Procedure to create the definition table. The table must be populated with transformation definitions before you call See Table 46-12, "Columns in a Transformation Definition Table for Categorical Missing Value Treatment". |
|
A transformation list. See Table 46-1 for a description of the |
|
Schema of |
See "Operational Notes". The following sections are especially relevant:
This example shows how the missing values in the column cust_marital_status
could be replaced with the mode in a transformation list called mining_data_stack
.
Note:
This example invokes the XFORM_STACK Procedure to show how the data is transformed by the stack.XFORM_STACK
simply generates an external view of the transformed data. The actual purpose of the STACK
procedures is to assemble a list of transformations for embedding in a model. The transformations are passed to CREATE_MODEL
in the xform_list
parameter. See INSERT_BIN_NUM_EQWIDTH Procedure for an example.CREATE OR REPLACE VIEW mining_data AS SELECT cust_id, country_id, cust_marital_status FROM sh.customers where cust_id BETWEEN 1 AND 10; BEGIN dbms_data_mining_transform.create_miss_cat ('miss_cat_tbl'); dbms_data_mining_transform.insert_miss_cat_mode ('miss_cat_tbl', 'mining_data'); END; / DECLARE MINING_DATA_STACK dbms_data_mining_transform.TRANSFORM_LIST; BEGIN dbms_data_mining_transform.stack_miss_cat ( miss_table_name => 'miss_cat_tbl', xform_list => mining_data_stack); dbms_data_mining_transform.XFORM_STACK ( xform_list => mining_data_stack, data_table_name => 'mining_data', xform_view_name => 'mining_data_stack_view'); END; / SELECT * FROM mining_data ORDER BY cust_id; CUST_ID COUNTRY_ID CUST_MARITAL_STATUS ------- ---------- -------------------- 1 52789 2 52778 3 52770 4 52770 5 52789 6 52769 single 7 52790 single 8 52790 married 9 52770 divorced 10 52790 widow SELECT * FROM mining_data_stack_view ORDER By cust_id; CUST_ID COUNTRY_ID CUST_MARITAL_STATUS ------- ----------- -------------------- 1 52789 single 2 52778 single 3 52770 single 4 52770 single 5 52789 single 6 52769 single 7 52790 single 8 52790 married 9 52770 divorced 10 52790 widow
This procedure adds numeric missing value transformations to a transformation list.
DBMS_DATA_MINING_TRANSFORM.STACK_MISS_NUM ( miss_table_name IN VARCHAR2, xform_list IN OUT NOCOPY TRANSFORM_LIST, miss_schema_name IN VARCHAR2 DEFAULT NULL);
Table 46-39 STACK_MISS_NUM Procedure Parameters
Parameter | Description |
---|---|
|
Name of the transformation definition table for numerical missing value treatment. You can use the CREATE_MISS_NUM Procedure to create the definition table. The table must be populated with transformation definitions before you call See Table 46-14, "Columns in a Transformation Definition Table for Numerical Missing Value Treatment". |
|
A transformation list. See Table 46-1 for a description of the |
|
Schema of |
See "Operational Notes". The following sections are especially relevant:
This example shows how the missing values in the column cust_credit_limit
could be replaced with the mean in a transformation list called mining_data_stack
.
Note:
This example invokes the XFORM_STACK Procedure to show how the data is transformed by the stack.XFORM_STACK
simply generates an external view of the transformed data. The actual purpose of the STACK
procedures is to assemble a list of transformations for embedding in a model. The transformations are passed to CREATE_MODEL
in the xform_list
parameter. See INSERT_BIN_NUM_EQWIDTH Procedure for an example.describe mining_data Name Null? Type ----------------------------------------------------- -------- ----- CUST_ID NOT NULL NUMBER CUST_CREDIT_LIMIT NUMBER BEGIN dbms_data_mining_transform.create_miss_num ('miss_num_tbl'); dbms_data_mining_transform.insert_miss_num_mean ('miss_num_tbl','mining_data'); END; / SELECT * FROM miss_num_tbl; COL ATT VAL -------------------- ----- ------ CUST_ID 5.5 CUST_CREDIT_LIMIT 185.71 DECLARE MINING_DATA_STACK dbms_data_mining_transform.TRANSFORM_LIST; BEGIN dbms_data_mining_transform.STACK_MISS_NUM ( miss_table_name => 'miss_num_tbl', xform_list => mining_data_stack); dbms_data_mining_transform.XFORM_STACK ( xform_list => mining_data_stack, data_table_name => 'mining_data', xform_view_name => 'mining_data_stack_view'); END; / -- Before transformation SELECT * FROM mining_data ORDER BY cust_id; CUST_ID CUST_CREDIT_LIMIT ------- ----------------- 1 100 2 3 200 4 5 150 6 400 7 150 8 9 100 10 200 -- After transformation SELECT * FROM mining_data_stack_view ORDER BY cust_id; CUST_ID CUST_CREDIT_LIMIT ------- ----------------- 1 100 2 185.71 3 200 4 185.71 5 150 6 400 7 150 8 185.71 9 100 10 200
This procedure adds linear normalization transformations to a transformation list.
DBMS_DATA_MINING_TRANSFORM.STACK_NORM_LIN ( norm_table_name IN VARCHAR2, xform_list IN OUT NOCOPY TRANSFORM_LIST, norm_schema_name IN VARCHAR2 DEFAULT NULL);
Table 46-40 STACK_NORM_LIN Procedure Parameters
Parameter | Description |
---|---|
|
Name of the transformation definition table for linear normalization. You can use the CREATE_NORM_LIN Procedure to create the definition table. The table must be populated with transformation definitions before you call See Table 46-16, "Columns in a Transformation Definition Table for Linear Normalization". |
|
A transformation list. See Table 46-1 for a description of the |
|
Schema of |
See "Operational Notes". The following sections are especially relevant:
This example shows how the column cust_credit_limit
could be normalized in a transformation list called mining_data_stack
.
Note:
This example invokes the XFORM_STACK Procedure to show how the data is transformed by the stack.XFORM_STACK
simply generates an external view of the transformed data. The actual purpose of the STACK
procedures is to assemble a list of transformations for embedding in a model. The transformations are passed to CREATE_MODEL
in the xform_list
parameter. See INSERT_BIN_NUM_EQWIDTH Procedure for an example.CREATE OR REPLACE VIEW mining_data AS SELECT cust_id, country_id, cust_postal_code, cust_credit_limit FROM sh.customers; BEGIN dbms_data_mining_transform.create_norm_lin ('norm_lin_tbl'); dbms_data_mining_transform.insert_norm_lin_minmax ( norm_table_name => 'norm_lin_tbl', data_table_name => 'mining_data', exclude_list => dbms_data_mining_transform.COLUMN_LIST('cust_id', 'country_id')); END; / SELECT * FROM norm_lin_tbl; COL ATT SHIFT SCALE -------------------- ----- ------ ------ CUST_CREDIT_LIMIT 1500 13500 DECLARE MINING_DATA_STACK dbms_data_mining_transform.TRANSFORM_LIST; BEGIN dbms_data_mining_transform.stack_norm_lin ( norm_table_name => 'norm_lin_tbl', xform_list => mining_data_stack); dbms_data_mining_transform.XFORM_STACK ( xform_list => mining_data_stack, data_table_name => 'mining_data', xform_view_name => 'mining_data_stack_view'); END; / SELECT * FROM mining_data WHERE cust_id between 1 and 10 ORDER BY cust_id; CUST_ID COUNTRY_ID CUST_POSTAL_CODE CUST_CREDIT_LIMIT ------- ---------- -------------------- ----------------- 1 52789 30828 9000 2 52778 86319 10000 3 52770 88666 1500 4 52770 87551 1500 5 52789 59200 1500 6 52769 77287 1500 7 52790 38763 1500 8 52790 58488 3000 9 52770 63033 3000 10 52790 52602 3000 SELECT * FROM mining_data_stack_view WHERE cust_id between 1 and 10 ORDER BY cust_id; CUST_ID COUNTRY_ID CUST_POSTAL_CODE CUST_CREDIT_LIMIT ------- ---------- -------------------- ----------------- 1 52789 30828 .55556 2 52778 86319 .62963 3 52770 88666 0 4 52770 87551 0 5 52789 59200 0 6 52769 77287 0 7 52790 38763 0 8 52790 58488 .11111 9 52770 63033 .11111 10 52790 52602 .11111
This procedure creates a view that implements the categorical binning transformations specified in a definition table. Only the columns that are specified in the definition table are transformed; the remaining columns from the data table are present in the view, but they are not changed.
DBMS_DATA_MINING_TRANSFORM.XFORM_BIN_CAT ( bin_table_name IN VARCHAR2, data_table_name IN VARCHAR2, xform_view_name IN VARCHAR2, literal_flag IN BOOLEAN DEFAULT FALSE, bin_schema_name IN VARCHAR2 DEFAULT NULL, data_schema_name IN VARCHAR2 DEFAULT NULL, xform_schema_name IN VARCHAR2 DEFAULT NULL);
Table 46-41 XFORM_BIN_CAT Procedure Parameters
Parameter | Description |
---|---|
|
Name of the transformation definition table for categorical binning. You can use the CREATE_BIN_CAT Procedure to create the definition table. The table must be populated with transformation definitions before you call See Table 46-4, "Columns in a Transformation Definition Table for Categorical Binning". |
|
Name of the table containing the data to be transformed. |
|
Name of the view to be created. The view presents columns in |
|
Indicates whether the values in the Set See "INSERT_BIN_NUM_EQWIDTH Procedure" for an example. |
|
Schema of |
|
Schema of |
|
Schema of |
See "Operational Notes".
This example creates a view that bins the cust_postal_code
column. The data source consists of three columns from sh.customer.
describe mining_data Name Null? Type -------------------------------------- -------- ------------------------ CUST_ID NOT NULL NUMBER CUST_POSTAL_CODE NOT NULL VARCHAR2(10) CUST_CREDIT_LIMIT NUMBER SELECT * FROM mining_data WHERE cust_id between 104066 and 104069; CUST_ID CUST_POSTAL_CODE CUST_CREDIT_LIMIT --------- -------------------- ----------------- 104066 69776 7000 104067 52602 9000 104068 55787 11000 104069 55977 5000 BEGIN dbms_data_mining_transform.create_bin_cat( bin_table_name => 'bin_cat_tbl'); dbms_data_mining_transform.insert_bin_cat_freq( bin_table_name => 'bin_cat_tbl', data_table_name => 'mining_data', bin_num => 10); dbms_data_mining_transform.xform_bin_cat( bin_table_name => 'bin_cat_tbl', data_table_name => 'mining_data', xform_view_name => 'bin_cat_view'); END; / SELECT * FROM bin_cat_view WHERE cust_id between 104066 and 104069; CUST_ID CUST_POSTAL_CODE CUST_CREDIT_LIMIT ---------- -------------------- ----------------- 104066 6 7000 104067 11 9000 104068 3 11000 104069 11 5000 SELECT text FROM user_views WHERE view_name IN 'BIN_CAT_VIEW'; TEXT -------------------------------------------------------------------------------- SELECT "CUST_ID",DECODE("CUST_POSTAL_CODE",'38082','1','45704','9','48346','5',' 55787','3','63736','2','67843','7','69776','6','72860','10','78558','4','80841', '8',NULL,NULL,'11') "CUST_POSTAL_CODE","CUST_CREDIT_LIMIT" FROM mining_data
This procedure creates a view that implements the numerical binning transformations specified in a definition table. Only the columns that are specified in the definition table are transformed; the remaining columns from the data table are present in the view, but they are not changed.
DBMS_DATA_MINING_TRANSFORM.XFORM_BIN_NUM ( bin_table_name IN VARCHAR2, data_table_name IN VARCHAR2, xform_view_name IN VARCHAR2, literal_flag IN BOOLEAN DEFAULT FALSE, bin_schema_name IN VARCHAR2 DEFAULT NULL, data_schema_name IN VARCHAR2 DEFAULT NULL, xform_schema_name IN VARCHAR2 DEFAULT NULL);
Table 46-42 XFORM_BIN_NUM Procedure Parameters
Parameter | Description |
---|---|
|
Name of the transformation definition table for numerical binning. You can use the CREATE_BIN_NUM Procedure to create the definition table. The table must be populated with transformation definitions before you call See "Columns in a Transformation Definition Table for Numerical Binning". |
|
Name of the table containing the data to be transformed |
|
Name of the view to be created. The view presents columns in |
|
Indicates whether the values in the Set See "INSERT_BIN_NUM_EQWIDTH Procedure" for an example. |
|
Schema of |
|
Schema of |
|
Schema of |
See "Operational Notes".
This example creates a view that bins the cust_credit_limit
column. The data source consists of three columns from sh.customer.
describe mining_data Name Null? Type -------------------------------------- -------- ------------------------ CUST_ID NOT NULL NUMBER CUST_POSTAL_CODE NOT NULL VARCHAR2(10) CUST_CREDIT_LIMIT NUMBER column cust_credit_limit off SELECT * FROM mining_data WHERE cust_id between 104066 and 104069; CUST_ID CUST_POSTAL_CODE CUST_CREDIT_LIMIT --------- ------------------ -------------------- 104066 69776 7000 104067 52602 9000 104068 55787 11000 104069 55977 5000 BEGIN dbms_data_mining_transform.create_bin_num( bin_table_name => 'bin_num_tbl'); dbms_data_mining_transform.insert_autobin_num_eqwidth( bin_table_name => 'bin_num_tbl', data_table_name => 'mining_data', bin_num => 5, max_bin_num => 10, exclude_list => dbms_data_mining_transform.COLUMN_LIST('cust_id')); dbms_data_mining_transform.xform_bin_num( bin_table_name => 'bin_num_tbl', data_table_name => 'mining_data', xform_view_name => 'mining_data_view'); END; / describe mining_data_view Name Null? Type ------------------------------------ -------- ------------------------ CUST_ID NOT NULL NUMBER CUST_POSTAL_CODE NOT NULL VARCHAR2(10) CUST_CREDIT_LIMIT VARCHAR2(2) col cust_credit_limit on col cust_credit_limit format a25 SELECT * FROM mining_data_view WHERE cust_id between 104066 and 104069; CUST_ID CUST_POSTAL_CODE CUST_CREDIT_LIMIT ---------- -------------------- ------------------------- 104066 69776 5 104067 52602 6 104068 55787 8 104069 55977 3 set long 2000 SELECT text FROM user_views WHERE view_name IN 'MINING_DATA_VIEW'; TEXT -------------------------------------------------------------------------------- SELECT "CUST_ID","CUST_POSTAL_CODE",CASE WHEN "CUST_CREDIT_LIMIT"<1500 THEN NULL WHEN "CUST_CREDIT_LIMIT"<=2850 THEN '1' WHEN "CUST_CREDIT_LIMIT"<=4200 THEN '2' WHEN "CUST_CREDIT_LIMIT"<=5550 THEN '3' WHEN "CUST_CREDIT_LIMIT"<=6900 THEN '4' WHEN "CUST_CREDIT_LIMIT"<=8250 THEN '5' WHEN "CUST_CREDIT_LIMIT"<=9600 THEN '6' WHEN "CUST_CREDIT_LIMIT"<=10950 THEN '7' WHEN "CUST_CREDIT_LIMIT"<=12300 THEN ' 8' WHEN "CUST_CREDIT_LIMIT"<=13650 THEN '9' WHEN "CUST_CREDIT_LIMIT"<=15000 THEN '10' END "CUST_CREDIT_LIMIT" FROM mining_data
This procedure creates a view that implements the clipping transformations specified in a definition table. Only the columns that are specified in the definition table are transformed; the remaining columns from the data table are present in the view, but they are not changed.
DBMS_DATA_MINING_TRANSFORM.XFORM_CLIP ( clip_table_name IN VARCHAR2, data_table_name IN VARCHAR2, xform_view_name IN VARCHAR2, clip_schema_name IN VARCHAR2 DEFAULT NULL, data_schema_name IN VARCHAR2,DEFAULT NULL, xform_schema_name IN VARCHAR2,DEFAULT NULL);
Table 46-43 XFORM_CLIP Procedure Parameters
Parameter | Description |
---|---|
|
Name of the transformation definition table for clipping. You can use the CREATE_CLIP Procedure to create the definition table. The table must be populated with transformation definitions before you call See Table 46-8, "Columns in a Transformation Definition Table for Clipping or Winsorizing". |
|
Name of the table containing the data to be transformed |
|
Name of the view to be created. The view presents columns in |
|
Schema of |
|
Schema of |
|
Schema of |
This example creates a view that clips the cust_credit_limit
column. The data source consists of three columns from sh.customer.
describe mining_data Name Null? Type ------------------------------ -------- ------------------------- CUST_ID NOT NULL NUMBER CUST_POSTAL_CODE NOT NULL VARCHAR2(10) CUST_CREDIT_LIMIT NUMBER BEGIN dbms_data_mining_transform.create_clip( clip_table_name => 'clip_tbl'); dbms_data_mining_transform.insert_clip_trim_tail( clip_table_name => 'clip_tbl', data_table_name => 'mining_data', tail_frac => 0.05, exclude_list => dbms_data_mining_transform.COLUMN_LIST('cust_id')); dbms_data_mining_transform.xform_clip( clip_table_name => 'clip_tbl', data_table_name => 'mining_data', xform_view_name => 'clip_view'); END; / describe clip_view Name Null? Type ----------------------------- -------- -------------------------- CUST_ID NOT NULL NUMBER CUST_POSTAL_CODE NOT NULL VARCHAR2(10) CUST_CREDIT_LIMIT NUMBER SELECT MIN(cust_credit_limit), MAX(cust_credit_limit) FROM mining_data; MIN(CUST_CREDIT_LIMIT) MAX(CUST_CREDIT_LIMIT) ---------------------- ---------------------- 1500 15000 SELECT MIN(cust_credit_limit), MAX(cust_credit_limit) FROM clip_view; MIN(CUST_CREDIT_LIMIT) MAX(CUST_CREDIT_LIMIT) ---------------------- ---------------------- 1500 11000 set long 2000 SELECT text FROM user_views WHERE view_name IN 'CLIP_VIEW'; TEXT -------------------------------------------------------------------------------- SELECT "CUST_ID","CUST_POSTAL_CODE",CASE WHEN "CUST_CREDIT_LIMIT" < 1500 THEN NU LL WHEN "CUST_CREDIT_LIMIT" > 11000 THEN NULL ELSE "CUST_CREDIT_LIMIT" END "CUST _CREDIT_LIMIT" FROM mining_data
This procedure creates a view that implements the column removal transformations specified in a definition table. Only the columns that are specified in the definition table are removed; the remaining columns from the data table are present in the view.
DBMS_DATA_MINING_TRANSFORM.XFORM_COL_REM ( rem_table_name IN VARCHAR2, data_table_name IN VARCHAR2, xform_view_name IN VARCHAR2, rem_schema_name IN VARCHAR2 DEFAULT NULL, data_schema_name IN VARCHAR2 DEFAULT NULL, xform_schema_name IN VARCHAR2 DEFAULT NULL);
Table 46-44 XFORM_COL_REM Procedure Parameters
Parameter | Description |
---|---|
|
Name of the transformation definition table for column removal. You can use the CREATE_COL_REM Procedure to create the definition table. See Table 46-10, "Columns in a Transformation Definition Table for Column Removal". The table must be populated with column names before you call |
|
Name of the table containing the data to be transformed |
|
Name of the view to be created. The view presents the columns in |
|
Schema of |
|
Schema of |
|
Schema of |
See "Operational Notes".
This example creates a view that includes all but one column from the table customers
in the current schema.
describe customers Name Null? Type ----------------------------------------- -------- ---------------------------- CUST_ID NOT NULL NUMBER CUST_MARITAL_STATUS VARCHAR2(20) OCCUPATION VARCHAR2(21) AGE NUMBER YRS_RESIDENCE NUMBER BEGIN DBMS_DATA_MINING_TRANSFORM.CREATE_COL_REM ('colrem_xtbl'); END; / INSERT INTO colrem_xtbl VALUES('CUST_MARITAL_STATUS', null); BEGIN DBMS_DATA_MINING_TRANSFORM.XFORM_COL_REM ( rem_table_name => 'colrem_xtbl', data_table_name => 'customers', xform_view_name => 'colrem_view'); END; / describe colrem_view Name Null? Type ----------------------------------------- -------- ---------------------------- CUST_ID NOT NULL NUMBER OCCUPATION VARCHAR2(21) AGE NUMBER YRS_RESIDENCE NUMBER
This procedure creates a view that implements the specified numeric transformations. Only the columns that you specify are transformed; the remaining columns from the data table are present in the view, but they are not changed.
DBMS_DATA_MINING_TRANSFORM.XFORM_EXPR_NUM ( expr_pattern IN VARCHAR2, data_table_name IN VARCHAR2, xform_view_name IN VARCHAR2, exclude_list IN COLUMN_LIST DEFAULT NULL, include_list IN COLUMN_LIST DEFAULT NULL, col_pattern IN VARCHAR2 DEFAULT ':col', data_schema_name IN VARCHAR2 DEFAULT NULL, xform_schema_name IN VARCHAR2 DEFAULT NULL);
Table 46-45 XFORM_EXPR_NUM Procedure Parameters
Parameter | Description |
---|---|
|
A numeric transformation expression |
|
Name of the table containing the data to be transformed |
|
Name of the view to be created. The view presents columns in |
|
List of numerical columns to exclude. If The format of dbms_data_mining_transform.COLUMN_LIST('col1','col2', ...'coln') |
|
List of numeric columns to include. If The format of dbms_data_mining_transform.COLUMN_LIST('col1','col2', ...'coln') |
|
The value within The default value of |
|
Schema of |
|
Schema of |
The XFORM_EXPR_NUM
procedure constructs numeric transformation expressions from the specified expression pattern (expr_pattern
) by replacing every occurrence of the specified column pattern (col_pattern
) with an actual column name.
XFORM_EXPR_NUM
uses the SQL REPLACE
function to construct the transformation expressions.
REPLACE (expr_pattern,col_pattern,'"column_name"') || '"column_name"'
If there is a column match, then the replacement is made in the transformation expression; if there is not a match, then the column is used without transformation.
Because of the include and exclude list parameters, the XFORM_EXPR_NUM
and XFORM_EXPR_STR
procedures allow you to easily specify individual columns for transformation within large data sets. The other XFORM_
* procedures support an exclude list only. In these procedures, you must enumerate every column that you do not want to transform.
This example creates a view that transforms the datatype of numeric columns.
describe customers Name Null? Type ----------------------------------- -------- ------------------------ CUST_ID NOT NULL NUMBER CUST_MARITAL_STATUS VARCHAR2(20) OCCUPATION VARCHAR2(21) AGE NUMBER YRS_RESIDENCE NUMBER BEGIN DBMS_DATA_MINING_TRANSFORM.XFORM_EXPR_NUM( expr_pattern => 'to_char(:col)', data_table_name => 'customers', xform_view_name => 'cust_nonum_view', exclude_list => dbms_data_mining_transform.COLUMN_LIST( 'cust_id'), include_list => null, col_pattern => ':col'); END; / describe cust_nonum_view Name Null? Type ----------------------------------- -------- ------------------------ CUST_ID NOT NULL NUMBER CUST_MARITAL_STATUS VARCHAR2(20) OCCUPATION VARCHAR2(21) AGE VARCHAR2(40) YRS_RESIDENCE VARCHAR2(40)
This procedure creates a view that implements the specified categorical transformations. Only the columns that you specify are transformed; the remaining columns from the data table are present in the view, but they are not changed.
DBMS_DATA_MINING_TRANSFORM.XFORM_EXPR_STR ( expr_pattern IN VARCHAR2, data_table_name IN VARCHAR2, xform_view_name IN VARCHAR2, exclude_list IN COLUMN_LIST DEFAULT NULL, include_list IN COLUMN_LIST DEFAULT NULL, col_pattern IN VARCHAR2 DEFAULT ':col', data_schema_name IN VARCHAR2 DEFAULT NULL, xform_schema_name IN VARCHAR2 DEFAULT NULL);
Table 46-46 XFORM_EXPR_STR Procedure Parameters
Parameter | Description |
---|---|
|
A character transformation expression |
|
Name of the table containing the data to be transformed |
|
Name of the view to be created. The view presents columns in |
|
List of categorical columns to exclude. If The format of dbms_data_mining_transform.COLUMN_LIST('col1','col2', ...'coln') |
|
List of character columns to include. If The format of dbms_data_mining_transform.COLUMN_LIST('col1','col2', ...'coln') |
|
The value within The default value of |
|
Schema of |
|
Schema of |
The XFORM_EXPR_STR
procedure constructs character transformation expressions from the specified expression pattern (expr_pattern
) by replacing every occurrence of the specified column pattern (col_pattern
) with an actual column name.
XFORM_EXPR_STR
uses the SQL REPLACE
function to construct the transformation expressions.
REPLACE (expr_pattern,col_pattern,'"column_name"') || '"column_name"'
If there is a column match, then the replacement is made in the transformation expression; if there is not a match, then the column is used without transformation.
Because of the include and exclude list parameters, the XFORM_EXPR_STR
and XFORM_EXPR_NUM
procedures allow you to easily specify individual columns for transformation within large data sets. The other XFORM_
* procedures support an exclude list only. In these procedures, you must enumerate every column that you do not want to transform.
This example creates a view that transforms character columns to upper case.
describe customers Name Null? Type ----------------------------------- -------- ------------------------ CUST_ID NOT NULL NUMBER CUST_MARITAL_STATUS VARCHAR2(20) OCCUPATION VARCHAR2(21) AGE NUMBER YRS_RESIDENCE NUMBER SELECT cust_id, cust_marital_status, occupation FROM customers WHERE cust_id > 102995 ORDER BY cust_id desc; CUST_ID CUST_MARITAL_STATUS OCCUPATION ------- -------------------- --------------------- 103000 Divorc. Cleric. 102999 Married Cleric. 102998 Married Exec. 102997 Married Exec. 102996 NeverM Other BEGIN DBMS_DATA_MINING_TRANSFORM.XFORM_EXPR_STR( expr_pattern => 'upper(:col)', data_table_name => 'customers', xform_view_name => 'cust_upcase_view'); END; / describe cust_upcase_view Name Null? Type ----------------------------- -------- -------------------- CUST_ID NOT NULL NUMBER CUST_MARITAL_STATUS VARCHAR2(20) OCCUPATION VARCHAR2(21) AGE NUMBER YRS_RESIDENCE NUMBER SELECT cust_id, cust_marital_status, occupation FROM cust_upcase_view WHERE cust_id > 102995 ORDER BY cust_id desc; CUST_ID CUST_MARITAL_STATUS OCCUPATION ------- -------------------- --------------------- 103000 DIVORC. CLERIC. 102999 MARRIED CLERIC. 102998 MARRIED EXEC. 102997 MARRIED EXEC. 102996 NEVERM OTHER
This procedure creates a view that implements the categorical missing value treatment transformations specified in a definition table. Only the columns that are specified in the definition table are transformed; the remaining columns from the data table are present in the view, but they are not changed.
DBMS_DATA_MINING_TRANSFORM.XFORM_MISS_CAT ( miss_table_name IN VARCHAR2, data_table_name IN VARCHAR2, xform_view_name IN VARCHAR2, miss_schema_name IN VARCHAR2 DEFAULT NULL, data_schema_name IN VARCHAR2 DEFAULT NULL, xform_schema_name IN VARCHAR2 DEFAULT NULL;
Table 46-47 XFORM_MISS_CAT Procedure Parameters
Parameter | Description |
---|---|
|
Name of the transformation definition table for categorical missing value treatment. You can use the CREATE_MISS_CAT Procedure to create the definition table. The table must be populated with transformation definitions before you call See Table 46-12, "Columns in a Transformation Definition Table for Categorical Missing Value Treatment". |
|
Name of the table containing the data to be transformed |
|
Name of the view to be created. The view presents columns in |
|
Schema of |
|
Schema of |
|
Schema of |
See "Operational Notes".
This example creates a view that replaces missing categorical values with the mode.
SELECT * FROM geog; REG_ID REGION ------ ------------------------------ 1 NE 2 SW 3 SE 4 SW 5 6 NE 7 NW 8 NW 9 10 11 SE 12 SE 13 NW 14 SE 15 SE SELECT STATS_MODE(region) FROM geog; STATS_MODE(REGION) ------------------------------ SE BEGIN DBMS_DATA_MINING_TRANSFORM.CREATE_MISS_CAT('misscat_xtbl'); DBMS_DATA_MINING_TRANSFORM.INSERT_MISS_CAT_MODE ( miss_table_name => 'misscat_xtbl', data_table_name => 'geog' ); END; / SELECT col, val FROM misscat_xtbl; COL VAL ---------- ---------- REGION SE BEGIN DBMS_DATA_MINING_TRANSFORM.XFORM_MISS_CAT ( miss_table_name => 'misscat_xtbl', data_table_name => 'geog', xform_view_name => 'geogxf_view'); END; / SELECT * FROM geogxf_view; REG_ID REGION ------ ------------------------------ 1 NE 2 SW 3 SE 4 SW 5 SE 6 NE 7 NW 8 NW 9 SE 10 SE 11 SE 12 SE 13 NW 14 SE 15 SE
This procedure creates a view that implements the numerical missing value treatment transformations specified in a definition table. Only the columns that are specified in the definition table are transformed; the remaining columns from the data table are present in the view, but they are not changed.
DBMS_DATA_MINING_TRANSFORM.XFORM_MISS_NUM ( miss_table_name IN VARCHAR2, data_table_name IN VARCHAR2, xform_view_name IN VARCHAR2, miss_schema_name IN VARCHAR2 DEFAULT NULL, data_schema_name IN VARCHAR2 DEFAULT NULL, xform_schema_name IN VARCHAR2 DEFAULT NULL;
Table 46-48 XFORM_MISS_NUM Procedure Parameters
Parameter | Description |
---|---|
|
Name of the transformation definition table for numerical missing value treatment. You can use the CREATE_MISS_NUM Procedure to create the definition table. The table must be populated with transformation definitions before you call See Table 46-14, "Columns in a Transformation Definition Table for Numerical Missing Value Treatment". |
|
Name of the table containing the data to be transformed |
|
Name of the view to be created. The view presents columns in |
|
Schema of |
|
Schema of |
|
Schema of |
See "Operational Notes".
This example creates a view that replaces missing numerical values with the mean.
SELECT * FROM items; ITEM_ID QTY ---------- ------ aa 200 bb 200 cc 250 dd ee ff 100 gg 250 hh 200 ii jj 200 SELECT AVG(qty) FROM items; AVG(QTY) -------- 200 BEGIN DBMS_DATA_MINING_TRANSFORM.CREATE_MISS_NUM('missnum_xtbl'); DBMS_DATA_MINING_TRANSFORM.INSERT_MISS_NUM_MEAN ( miss_table_name => 'missnum_xtbl', data_table_name => 'items' ); END; / SELECT col, val FROM missnum_xtbl; COL VAL ---------- ------ QTY 200 BEGIN DBMS_DATA_MINING_TRANSFORM.XFORM_MISS_NUM ( miss_table_name => 'missnum_xtbl', data_table_name => 'items', xform_view_name => 'items_view'); END; / SELECT * FROM items_view; ITEM_ID QTY ---------- ------ aa 200 bb 200 cc 250 dd 200 ee 200 ff 100 gg 250 hh 200 ii 200 jj 200
This procedure creates a view that implements the linear normalization transformations specified in a definition table. Only the columns that are specified in the definition table are transformed; the remaining columns from the data table are present in the view, but they are not changed.
DBMS_DATA_MINING_TRANSFORM.XFORM_NORM_LIN ( norm_table_name IN VARCHAR2, data_table_name IN VARCHAR2, xform_view_name IN VARCHAR2, norm_schema_name IN VARCHAR2 DEFAULT NULL, data_schema_name IN VARCHAR2 DEFAULT NULL, xform_schema_name IN VARCHAR2 DEFAULT NULL);
Table 46-49 XFORM_NORM_LIN Procedure Parameters
Parameter | Description |
---|---|
|
Name of the transformation definition table for linear normalization. You can use the CREATE_NORM_LIN Procedure to create the definition table. The table must be populated with transformation definitions before you call See Table 46-12, "Columns in a Transformation Definition Table for Categorical Missing Value Treatment". |
|
Name of the table containing the data to be transformed |
|
Name of the view to be created. The view presents columns in |
|
Schema of |
|
Schema of |
|
Schema of |
See "Operational Notes".
This example creates a view that normalizes the cust_year_of_birth
and cust_credit_limit
columns. The data source consists of three columns from sh.customer.
CREATE OR REPLACE VIEW mining_data AS SELECT cust_id, cust_year_of_birth, cust_credit_limit FROM sh.customers; describe mining_data Name Null? Type -------------------------------------- -------- -------------------------- CUST_ID NOT NULL NUMBER CUST_YEAR_OF_BIRTH NOT NULL NUMBER(4) CUST_CREDIT_LIMIT NUMBER SELECT * FROM mining_data WHERE cust_id > 104495 ORDER BY cust_year_of_birth; CUST_ID CUST_YEAR_OF_BIRTH CUST_CREDIT_LIMIT -------- ------------------ ----------------- 104496 1947 3000 104498 1954 10000 104500 1962 15000 104499 1970 3000 104497 1976 3000 BEGIN dbms_data_mining_transform.CREATE_NORM_LIN( norm_table_name => 'normx_tbl'); dbms_data_mining_transform.INSERT_NORM_LIN_MINMAX( norm_table_name => 'normx_tbl', data_table_name => 'mining_data', exclude_list => dbms_data_mining_transform.COLUMN_LIST( 'cust_id'), round_num => 3); END; / SELECT col, shift, scale FROM normx_tbl; COL SHIFT SCALE ------------------------------ -------- -------- CUST_YEAR_OF_BIRTH 1910 77 CUST_CREDIT_LIMIT 1500 13500 BEGIN DBMS_DATA_MINING_TRANSFORM.XFORM_NORM_LIN ( norm_table_name => 'normx_tbl', data_table_name => 'mining_data', xform_view_name => 'norm_view'); END; / SELECT * FROM norm_view WHERE cust_id > 104495 ORDER BY cust_year_of_birth; CUST_ID CUST_YEAR_OF_BIRTH CUST_CREDIT_LIMIT -------- ------------------ ----------------- 104496 .4805195 .1111111 104498 .5714286 .6296296 104500 .6753247 1 104499 .7792208 .1111111 104497 .8571429 .1111111 set long 2000 SQL> SELECT text FROM user_views WHERE view_name IN 'NORM_VIEW'; TEXT --------------------------------------------------------------------------- SELECT "CUST_ID",("CUST_YEAR_OF_BIRTH"-1910)/77 "CUST_YEAR_OF_BIRTH",("CUST _CREDIT_LIMIT"-1500)/13500 "CUST_CREDIT_LIMIT" FROM mining_data
This procedure creates a view that implements the transformations specified by the stack. Only the columns and nested attributes that are specified in the stack are transformed. Any remaining columns and nested attributes from the data table appear in the view without changes.
To create a list of objects that describe the transformed columns, use the DESCRIBE_STACK Procedure.
See Also:
Oracle Data Mining User's Guide for more information about data mining attributes
DBMS_DATA_MINING_TRANSFORM.XFORM_STACK ( xform_list IN TRANSFORM_list, data_table_name IN VARCHAR2, xform_view_name IN VARCHAR2, data_schema_name IN VARCHAR2 DEFAULT NULL, xform_schema_name IN VARCHAR2 DEFAULT NULL);
Table 46-50 XFORM_STACK Procedure Parameters
Parameter | Description |
---|---|
|
The transformation list. See Table 46-1 for a description of the |
|
Name of the table containing the data to be transformed |
|
Name of the view to be created. The view applies the transformations in |
|
Schema of |
|
Schema of |
See "Operational Notes". The following sections are especially relevant:
This example applies a transformation list to the view dmuser.cust_info
and shows how the data is transformed.The CREATE
statement for cust_info
is shown in "DESCRIBE_STACK Procedure".
BEGIN dbms_data_mining_transform.CREATE_BIN_NUM ('birth_yr_bins'); dbms_data_mining_transform.INSERT_BIN_NUM_QTILE ( bin_table_name => 'birth_yr_bins', data_table_name => 'cust_info', bin_num => 6, exclude_list => dbms_data_mining_transform.column_list( 'cust_id','country_id')); END; / SELECT * FROM birth_yr_bins; COL ATT VAL BIN -------------------- ----- ------ ---------- CUST_YEAR_OF_BIRTH 1922 CUST_YEAR_OF_BIRTH 1951 1 CUST_YEAR_OF_BIRTH 1959 2 CUST_YEAR_OF_BIRTH 1966 3 CUST_YEAR_OF_BIRTH 1973 4 CUST_YEAR_OF_BIRTH 1979 5 CUST_YEAR_OF_BIRTH 1986 6 DECLARE cust_stack dbms_data_mining_transform.TRANSFORM_LIST; BEGIN dbms_data_mining_transform.SET_TRANSFORM (cust_stack, 'country_id', NULL, 'country_id/10', 'country_id*10'); dbms_data_mining_transform.STACK_BIN_NUM ('birth_yr_bins', cust_stack); dbms_data_mining_transform.SET_TRANSFORM (cust_stack, 'custprods', 'Mouse Pad', 'value*100', 'value/100'); dbms_data_mining_transform.XFORM_STACK( xform_list => cust_stack, data_table_name => 'cust_info', xform_view_name => 'cust_xform_view'); END; / -- Two rows of data without transformations SELECT * from cust_info WHERE cust_id BETWEEN 100010 AND 100011; CUST_ID COUNTRY_ID CUST_YEAR_OF_BIRTH CUSTPRODS(ATTRIBUTE_NAME, VALUE) ------- ---------- ------------------ ----------------------------------------- 100010 52790 1975 DM_NESTED_NUMERICALS( DM_NESTED_NUMERICAL( '18" Flat Panel Graphics Monitor', 1), DM_NESTED_NUMERICAL( 'SIMM- 16MB PCMCIAII card', 1)) 100011 52775 1972 DM_NESTED_NUMERICALS( DM_NESTED_NUMERICAL( 'External 8X CD-ROM', 1), DM_NESTED_NUMERICAL( 'Mouse Pad', 1), DM_NESTED_NUMERICAL( 'SIMM- 16MB PCMCIAII card', 1), DM_NESTED_NUMERICAL( 'Keyboard Wrist Rest', 1), DM_NESTED_NUMERICAL( '18" Flat Panel Graphics Monitor', 1), DM_NESTED_NUMERICAL( 'O/S Documentation Set - English', 1)) -- Same two rows of data with transformations SELECT * FROM cust_xform_view WHERE cust_id BETWEEN 100010 AND 100011; CUST_ID COUNTRY_ID C CUSTPRODS(ATTRIBUTE_NAME, VALUE) ------- ---------- - -------------------------------------------------------- 100010 5279 5 DM_NESTED_NUMERICALS( DM_NESTED_NUMERICAL( '18" Flat Panel Graphics Monitor', 1), DM_NESTED_NUMERICAL( 'SIMM- 16MB PCMCIAII card', 1)) 100011 5277.5 4 DM_NESTED_NUMERICALS( DM_NESTED_NUMERICAL( 'External 8X CD-ROM', 1), DM_NESTED_NUMERICAL( 'Mouse Pad', 100), DM_NESTED_NUMERICAL( 'SIMM- 16MB PCMCIAII card', 1), DM_NESTED_NUMERICAL( 'Keyboard Wrist Rest', 1), DM_NESTED_NUMERICAL( '18" Flat Panel Graphics Monitor', 1), DM_NESTED_NUMERICAL( 'O/S Documentation Set - English', 1))