This is facilitated through the use of
<term>
phrase boundary heuristics
</term>
based on the placement of
<term>
function words
</term>
, and by
<term>
heuristic rules
</term>
that permit certain kinds of
<term>
phrases
</term>
to be deduced despite the presence of
<term>
unknown words
</term>
.
#22656This is facilitated through the use of phrase boundary heuristics based on the placement of function words, and byheuristic rules that permit certain kinds of phrases to be deduced despite the presence of unknown words.
model,7-5-A92-1027,ak
This is facilitated through the use of
<term>
phrase boundary heuristics
</term>
based on the placement of
<term>
function words
</term>
, and by
<term>
heuristic rules
</term>
that permit certain kinds of
<term>
phrases
</term>
to be deduced despite the presence of
<term>
unknown words
</term>
.
#22643This is facilitated through the use ofphrase boundary heuristics based on the placement of function words, and by heuristic rules that permit certain kinds of phrases to be deduced despite the presence of unknown words.
other,10-2-A92-1027,ak
The
<term>
parser
</term>
gains
<term>
algorithmic efficiency
</term>
through a reduction of its
<term>
search space
</term>
.
#22568The parser gains algorithmic efficiency through a reduction of itssearch space.
other,11-1-A92-1027,ak
We present an efficient
<term>
algorithm
</term>
for
<term>
chart-based phrase structure parsing
</term>
of
<term>
natural language
</term>
that is tailored to the problem of extracting specific
<term>
information
</term>
from
<term>
unrestricted texts
</term>
where many of the
<term>
words
</term>
are unknown and much of the
<term>
text
</term>
is irrelevant to the task .
#22525We present an efficient algorithm for chart-based phrase structure parsing ofnatural language that is tailored to the problem of extracting specific information from unrestricted texts where many of the words are unknown and much of the text is irrelevant to the task.
other,14-6-A92-1027,ak
A further reduction in the
<term>
search space
</term>
is achieved by using semantic rather than
<term>
syntactic categories
</term>
on the
<term>
terminal and non-terminal edges
</term>
, thereby reducing the amount of
<term>
ambiguity
</term>
and thus the number of
<term>
edges
</term>
, since only
<term>
edges
</term>
with a valid
<term>
semantic interpretation
</term>
are ever introduced .
#22688A further reduction in the search space is achieved by using semantic rather thansyntactic categories on the terminal and non-terminal edges, thereby reducing the amount of ambiguity and thus the number of edges, since only edges with a valid semantic interpretation are ever introduced.
other,15-5-A92-1027,ak
This is facilitated through the use of
<term>
phrase boundary heuristics
</term>
based on the placement of
<term>
function words
</term>
, and by
<term>
heuristic rules
</term>
that permit certain kinds of
<term>
phrases
</term>
to be deduced despite the presence of
<term>
unknown words
</term>
.
#22651This is facilitated through the use of phrase boundary heuristics based on the placement offunction words, and by heuristic rules that permit certain kinds of phrases to be deduced despite the presence of unknown words.
other,18-3-A92-1027,ak
As each new
<term>
edge
</term>
is added to the
<term>
chart
</term>
, the
<term>
algorithm
</term>
checks only the topmost of the
<term>
edges
</term>
adjacent to it , rather than all such
<term>
edges
</term>
as in conventional treatments .
#22589As each new edge is added to the chart, the algorithm checks only the topmost of theedges adjacent to it, rather than all such edges as in conventional treatments.
other,18-4-A92-1027,ak
The resulting
<term>
spanning edges
</term>
are insured to be the correct ones by carefully controlling the order in which
<term>
edges
</term>
are introduced so that every final
<term>
constituent
</term>
covers the longest possible span .
#22622The resulting spanning edges are insured to be the correct ones by carefully controlling the order in whichedges are introduced so that every final constituent covers the longest possible span.
other,18-6-A92-1027,ak
A further reduction in the
<term>
search space
</term>
is achieved by using semantic rather than
<term>
syntactic categories
</term>
on the
<term>
terminal and non-terminal edges
</term>
, thereby reducing the amount of
<term>
ambiguity
</term>
and thus the number of
<term>
edges
</term>
, since only
<term>
edges
</term>
with a valid
<term>
semantic interpretation
</term>
are ever introduced .
#22692A further reduction in the search space is achieved by using semantic rather than syntactic categories on theterminal and non-terminal edges, thereby reducing the amount of ambiguity and thus the number of edges, since only edges with a valid semantic interpretation are ever introduced.
other,2-4-A92-1027,ak
The resulting
<term>
spanning edges
</term>
are insured to be the correct ones by carefully controlling the order in which
<term>
edges
</term>
are introduced so that every final
<term>
constituent
</term>
covers the longest possible span .
#22606The resultingspanning edges are insured to be the correct ones by carefully controlling the order in which edges are introduced so that every final constituent covers the longest possible span.
other,22-1-A92-1027,ak
We present an efficient
<term>
algorithm
</term>
for
<term>
chart-based phrase structure parsing
</term>
of
<term>
natural language
</term>
that is tailored to the problem of extracting specific
<term>
information
</term>
from
<term>
unrestricted texts
</term>
where many of the
<term>
words
</term>
are unknown and much of the
<term>
text
</term>
is irrelevant to the task .
#22536We present an efficient algorithm for chart-based phrase structure parsing of natural language that is tailored to the problem of extracting specificinformation from unrestricted texts where many of the words are unknown and much of the text is irrelevant to the task.
other,24-1-A92-1027,ak
We present an efficient
<term>
algorithm
</term>
for
<term>
chart-based phrase structure parsing
</term>
of
<term>
natural language
</term>
that is tailored to the problem of extracting specific
<term>
information
</term>
from
<term>
unrestricted texts
</term>
where many of the
<term>
words
</term>
are unknown and much of the
<term>
text
</term>
is irrelevant to the task .
#22538We present an efficient algorithm for chart-based phrase structure parsing of natural language that is tailored to the problem of extracting specific information fromunrestricted texts where many of the words are unknown and much of the text is irrelevant to the task.
other,25-4-A92-1027,ak
The resulting
<term>
spanning edges
</term>
are insured to be the correct ones by carefully controlling the order in which
<term>
edges
</term>
are introduced so that every final
<term>
constituent
</term>
covers the longest possible span .
#22629The resulting spanning edges are insured to be the correct ones by carefully controlling the order in which edges are introduced so that every finalconstituent covers the longest possible span.
other,27-3-A92-1027,ak
As each new
<term>
edge
</term>
is added to the
<term>
chart
</term>
, the
<term>
algorithm
</term>
checks only the topmost of the
<term>
edges
</term>
adjacent to it , rather than all such
<term>
edges
</term>
as in conventional treatments .
#22598As each new edge is added to the chart, the algorithm checks only the topmost of the edges adjacent to it, rather than all suchedges as in conventional treatments.
other,27-5-A92-1027,ak
This is facilitated through the use of
<term>
phrase boundary heuristics
</term>
based on the placement of
<term>
function words
</term>
, and by
<term>
heuristic rules
</term>
that permit certain kinds of
<term>
phrases
</term>
to be deduced despite the presence of
<term>
unknown words
</term>
.
#22663This is facilitated through the use of phrase boundary heuristics based on the placement of function words, and by heuristic rules that permit certain kinds ofphrases to be deduced despite the presence of unknown words.
other,28-6-A92-1027,ak
A further reduction in the
<term>
search space
</term>
is achieved by using semantic rather than
<term>
syntactic categories
</term>
on the
<term>
terminal and non-terminal edges
</term>
, thereby reducing the amount of
<term>
ambiguity
</term>
and thus the number of
<term>
edges
</term>
, since only
<term>
edges
</term>
with a valid
<term>
semantic interpretation
</term>
are ever introduced .
#22702A further reduction in the search space is achieved by using semantic rather than syntactic categories on the terminal and non-terminal edges, thereby reducing the amount ofambiguity and thus the number of edges, since only edges with a valid semantic interpretation are ever introduced.
other,3-2-A92-1027,ak
The
<term>
parser
</term>
gains
<term>
algorithmic efficiency
</term>
through a reduction of its
<term>
search space
</term>
.
#22561The parser gainsalgorithmic efficiency through a reduction of its search space.
other,3-3-A92-1027,ak
As each new
<term>
edge
</term>
is added to the
<term>
chart
</term>
, the
<term>
algorithm
</term>
checks only the topmost of the
<term>
edges
</term>
adjacent to it , rather than all such
<term>
edges
</term>
as in conventional treatments .
#22574As each newedge is added to the chart, the algorithm checks only the topmost of the edges adjacent to it, rather than all such edges as in conventional treatments.
other,30-1-A92-1027,ak
We present an efficient
<term>
algorithm
</term>
for
<term>
chart-based phrase structure parsing
</term>
of
<term>
natural language
</term>
that is tailored to the problem of extracting specific
<term>
information
</term>
from
<term>
unrestricted texts
</term>
where many of the
<term>
words
</term>
are unknown and much of the
<term>
text
</term>
is irrelevant to the task .
#22544We present an efficient algorithm for chart-based phrase structure parsing of natural language that is tailored to the problem of extracting specific information from unrestricted texts where many of thewords are unknown and much of the text is irrelevant to the task.
other,34-6-A92-1027,ak
A further reduction in the
<term>
search space
</term>
is achieved by using semantic rather than
<term>
syntactic categories
</term>
on the
<term>
terminal and non-terminal edges
</term>
, thereby reducing the amount of
<term>
ambiguity
</term>
and thus the number of
<term>
edges
</term>
, since only
<term>
edges
</term>
with a valid
<term>
semantic interpretation
</term>
are ever introduced .
#22708A further reduction in the search space is achieved by using semantic rather than syntactic categories on the terminal and non-terminal edges, thereby reducing the amount of ambiguity and thus the number ofedges, since only edges with a valid semantic interpretation are ever introduced.