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Returns a linear prediction Tensor
based on given feature_columns
.
tf.compat.v1.feature_column.linear_model(
features,
feature_columns,
units=1,
sparse_combiner='sum',
weight_collections=None,
trainable=True,
cols_to_vars=None
)
This function generates a weighted sum based on output dimension units
.
Weighted sum refers to logits in classification problems. It refers to the
prediction itself for linear regression problems.
Note on supported columns: linear_model
treats categorical columns as
indicator_column
s. To be specific, assume the input as SparseTensor
looks
like:
shape = [2, 2]
{
[0, 0]: "a"
[1, 0]: "b"
[1, 1]: "c"
}
linear_model
assigns weights for the presence of "a", "b", "c' implicitly,
just like indicator_column
, while input_layer
explicitly requires wrapping
each of categorical columns with an embedding_column
or an
indicator_column
.
Example of usage:
price = numeric_column('price')
price_buckets = bucketized_column(price, boundaries=[0., 10., 100., 1000.])
keywords = categorical_column_with_hash_bucket("keywords", 10K)
keywords_price = crossed_column('keywords', price_buckets, ...)
columns = [price_buckets, keywords, keywords_price ...]
features = tf.io.parse_example(..., features=make_parse_example_spec(columns))
prediction = linear_model(features, columns)
The sparse_combiner
argument works as follows
For example, for two features represented as the categorical columns:
# Feature 1
shape = [2, 2]
{
[0, 0]: "a"
[0, 1]: "b"
[1, 0]: "c"
}
# Feature 2
shape = [2, 3]
{
[0, 0]: "d"
[1, 0]: "e"
[1, 1]: "f"
[1, 2]: "f"
}
with sparse_combiner
as "mean", the linear model outputs consequently
are:
y_0 = 1.0 / 2.0 * ( w_a + w_b ) + w_d + b
y_1 = w_c + 1.0 / 3.0 * ( w_e + 2.0 * w_f ) + b
where y_i
is the output, b
is the bias, and w_x
is the weight
assigned to the presence of x
in the input features.
Args | |
---|---|
features
|
A mapping from key to tensors. _FeatureColumn s look up via these
keys. For example numeric_column('price') will look at 'price' key in
this dict. Values are Tensor or SparseTensor depending on
corresponding _FeatureColumn .
|
feature_columns
|
An iterable containing the FeatureColumns to use as inputs
to your model. All items should be instances of classes derived from
_FeatureColumn s.
|
units
|
An integer, dimensionality of the output space. Default value is 1. |
sparse_combiner
|
A string specifying how to reduce if a categorical column
is multivalent. Except numeric_column , almost all columns passed to
linear_model are considered as categorical columns. It combines each
categorical column independently. Currently "mean", "sqrtn" and "sum" are
supported, with "sum" the default for linear model. "sqrtn" often achieves
good accuracy, in particular with bag-of-words columns.
|
weight_collections
|
A list of collection names to which the Variable will be
added. Note that, variables will also be added to collections
tf.GraphKeys.GLOBAL_VARIABLES and ops.GraphKeys.MODEL_VARIABLES .
|
trainable
|
If True also add the variable to the graph collection
GraphKeys.TRAINABLE_VARIABLES (see tf.Variable ).
|
cols_to_vars
|
If not None , must be a dictionary that will be filled with a
mapping from _FeatureColumn to associated list of Variable s. For
example, after the call, we might have cols_to_vars = {
_NumericColumn(
key='numeric_feature1', shape=(1,):
[ |
Returns | |
---|---|
A Tensor which represents predictions/logits of a linear model. Its shape
is (batch_size, units) and its dtype is float32 .
|
Raises | |
---|---|
ValueError
|
if an item in feature_columns is neither a _DenseColumn
nor _CategoricalColumn .
|