using query patterns to learn the durations of events
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Using Query Patterns to Learn the Durations of Events
Andrey Gusev
joint work withNate Chambers, Pranav Khaitan, Divye Khilnani, Steven Bethard, Dan Jurafsky
Examples of Event Durations• Talk to a friend – minutes• Driving – hours• Study for an exam – days• Travel – weeks• Run a campaign – months• Build a museum – years
Why are we interested in durations?• Event Understanding
• Duration is an important aspectual property• Can help build timelines and events
• Event coreference• Duration may be a cue that events are coreferent
• Gender (learned from the web) helps nominal coreference
• Integration into search products• Query: “healthy sleep time for age groups”• Query: “president term length in [country x]”
Approach1: Supervised System
How can we learn event durations?
Dataset (Pan et al., 2006)• Labeled 58 documents from TimeBank with event
durations• Average of minimum and maximum labeled durations
• A Brooklyn woman who was watching her clothes dry in a laundromat.• Min duration – 5 min• Max Duration – 1 hour• Average – 1950 seconds
Original Features (Pan et al., 2006)• Event Properties
• Event token, lemma, POS tag
• Subject and Object• Head word of syntactic subject and objects of the event,
along with their lemmas and POS tags.
• Hypernyms• WordNet hypernyms for the event, its subject and its object.• Starting from the first synset of each lemma, three
hyperhyms were extracted from the WordNet hierarchy.
New Features• Event Attributes
• Tense, aspect, modality, event class
• Named Entity Class of Subjects and Objects• Person, organization, locations, or other.
• Typed Dependencies• Binary feature for each typed dependency
• Reporting Verbs• Binary feature for reporting verbs (say, report, reply, etc.)
Limitations of the Supervised ApproachNeed explicitly annotated datasets
• Sparse and limited data
• Limited to the annotated domain
• Low inter-annotator agreement• More than a Day and Less Than a Day– 87.7%• Duration Buckets – 44.4%• Approximate Duration Buckets– 79.8%
Overcoming Supervised LimitationsStatistical Web Count approach
• Lots of text/data that can be used
• Not limited to the annotated domain
• Implicit annotations from many sources
• Hearst(1998), Ji and Lin (2009)
Approach 2: Statistical Web Counts
How can we learn event durations?
Terms - Durations Buckets and Distributions• “talked for * seconds”• “talked for * minutes”• “talked for * hours”• “talked for * days”• “talked for * weeks”• “talked for * months”• “talked for * years”
Duration Bucket
Distribution
- 1638 hits- 61816 hits- 68370 hits- 4361 hits- 3754 hits- 5157 hits- 103336 hits
Two Duration Prediction Tasks• Coarse grained prediction
• “Less than a day” or “Longer than a day”
• Fine grained prediction• Second, minute, hour, etc.
Task 1: Coarse Grained Prediction
Yesterday Pattern for Coarse Grained Task
• <eventpast> yesterday
• <eventpastp> yesterday
• eventpast = past tense
• eventpastp= past progressive tense
• Normalize yesterday event pattern counts with counts of event occurrence in general
• Average the two ratios • Find threshold on the training set
Example: “to say” with Yesterday Pattern• “said yesterday” – 14,390,865 hits
• “said” – 1,693,080,248 hits• “was saying yesterday” – 29,626 hits
• “was saying” – 14,167,103 hits
• Average Ratio = 0.0053€
Ratiopastp =29,626
14,167,103= 0.0021
€
Ratiopast =14,390,865
1,693,080,248= 0.0085
Threshold for Yesterday Pattern
0.000
50.0
01
0.001
50.0
02
0.002
50.0
03
0.003
50.0
04
0.004
50.0
05
0.005
50.650.660.670.680.690.700.710.720.730.740.75
Ratio
Acc
urac
y
t = 0.002
Task 2: Fine Grained Prediction
Fine Grained Durations from Web Counts
• How long does the event
“X” last?
• Ask the web:• “X for * seconds”• “X for * minutes”• …
• Output distribution over time units
Said
Not All Time Units are Equal • Need to look at the base
distribution• “for * seconds”• “for * minutes”• …
• In habituals, etc. people like to say “for years”
Conditional Frequencies for Buckets
• Divide• “X for * seconds”
• By• “for * seconds”
• Reduce credit for seeing “X for years”
Said
Double Peak Distribution• Two interpretations
• Durative• Iterative
• Distributions show that with two peaks S M H D W M Y D
0.0
0.1
0.2
0.3
0.4
0.5to smile to run
Merging Patterns • Multiple patterns
• Distributions averaged
• Reduces noise from individual patterns
• Pattern needs to have greater than 100 and less 100,000 hits
Said
Fine Grained Patterns• Used Patterns
• <eventpast> for * <bucket>
• <eventpastp> for * <bucket>
• spent * <bucket> <eventger>
• Patterns not used• <eventpast> in * <bucket>• takes * <bucket> to <event>• <eventpast> last <bucket>
Evaluation and Results
Evaluation• TimeBank annotations (Pan, Mulkar and Hobbs 2006)
• Coarse Task: Greater or less than a day• Fine Task: Time units (seconds, minutes, hours, …, years)
• Counted as correct if within 1 time unit• Baseline: Majority Class
• Fine Grained – months• Coarse Grained – greater than a day
• Compare with re-implementation of supervised (Pan, Mulkar and Hobbs 2006)
New Split for TimeBank Dataset• Train – 1664 events (714 unique verbs)
• Test – 471 events (274 unique verbs)
• TestWSJ – 147 events (84 unique verbs)
• Split info is available at • http://cs.stanford.edu/~agusev/durations/
Web Counts System Scoring• Fine grained
• Smooth over the adjacent buckets and select top bucketscore(bi) = bi-1 + bi + bi+1
• Coarse grained• “Yesterday” classifier with a threshold (t = 0.002)• Use fine grained approach
• Select coarse grained bucket based on fine grained bucket
Results
Coarse - Test Fine - Test Coarse - WSJ Fine - WSJ
Baseline 62.4 59.2 57.1 52.4
Supervised 73.0 62.4 74.8 66.0
Bucket Counts 72.4 66.5 73.5 68.7
Yesterday Counts 70.7 N/A 74.8 N/A
Web counts perform as well as the fully supervised system
Backoff Statistics (“Spent” Pattern)
Both Subject Object None356 446 195 548
• Events in training dataset
• Had at least 10 hits
Both Subject Object None3 86 84 1372
Effect of the Event Context• Supervised classifier use context in their features
• Web counts system doesn’t use context of the events• Significantly fewer hits when including context• Better accuracy with more hits than with context
• What is the effect of subject/object context on the understanding of event duration?
Human Annotation:Mechanical Turk
Can humans do this task without context?
MTurk Setup • 10 MTurk workers for each event
• Without the context
• Event – choice for each duration bucket
• With the context
• Event with subject/object – choice for each duration bucket
Sometimes Context Doesn’t Matter
Exploded Intolerant
Web counts vs. Turk distributions“said” (web count) “said” (MTurk)
Web counts vs. Turk distributions“looking” (web count) “looking” (MTurk)
Web counts vs. Turk distributions“considering” (web count) “considering” (MTurk)
Compare accuracy– Event with context– Event without context
Coarse - Test Fine - Test Coarse - WSJ Fine - WSJ
Baseline 62.4 59.2 57.1 52.4
Event only 52.0 42.1 49.4 43.8
Event and context 65.0 56.7 70.1 59.9
Results: Mechanical Turk Annotations
Context significantly improves accuracy of MTurk annotations
Event Duration Lexicon• Distributions for 1000 most frequent verbs from the
NYT portion of the Gigaword with 10 most frequent grammatical objects of each verb
• Due to thresholds not all the events have distributions
EVENT=to use,ID=e13-7,OBJ=computer,PATTERNS=2,DISTR=[0.009;0.337;0.238;0.090;0.130;0.103;0.092;0.002;]
http://cs.stanford.edu/~agusev/durations/
Summary• We learned aspectual information from the web• Event durations from the web counts are as accurate
as a supervised system• Web counts are domain-general, work well even
without context• New lexicon with 1000 most frequent verbs with 10
most frequent objects • MTurk suggests that context can improve accuracy of
event duration annotation
Thanks! Questions?
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