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Learning the Structure of Task-Oriented Conversations from the Corpus

Learning the Structure of Task-Oriented Conversations from the Corpus. Ananlada Chotimongkol Language Technologies Institute School of Computer Science Carnegie Mellon University. Outline. Introduction Form-based dialog structure Task structure Dialog mechanisms

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Learning the Structure of Task-Oriented Conversations from the Corpus

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  1. Learning the Structure of Task-Oriented Conversations from the Corpus Ananlada Chotimongkol Language Technologies Institute School of Computer Science Carnegie Mellon University

  2. Outline • Introduction • Form-based dialog structure • Task structure • Dialog mechanisms • Dialog structure learning • Concept identification and clustering • Form identification • Operation Classification

  3. Outline • Introduction • Form-based dialog structure • Task structure • Dialog mechanisms • Dialog structure learning • Concept identification and clustering • Form identification • Operation Classification

  4. Building a new dialog system “When would you like to leave?” “I would like to fly to Seattle tomorrow.” Domain Knowledge Speech Recognizer Speech Synthesizer Dialog Manager Natural Language Understanding Natural Language Generator

  5. Domain knowledge • Steps in the task • Specify the desired flight • Search for flights that match the criteria • Negotiate the flights • Make a reservation • Important information, keywords • Destination, date, time, airlines, etc. • Domain language: how do people talk

  6. What is the problem? “When would you like to leave?” “I would like to fly to Seattle tomorrow.” • Can’t reuse • Time consuming • May need an expert Domain Knowledge Speech Recognizer Speech Synthesizer Dialog Manager Natural Language Understanding Natural Language Generator

  7. Research goal • Reduce human effort on acquiring domain knowledge when create a dialog system in a new domain • By learning the domain knowledge from data

  8. Observations • Task-oriented conversations have a clear structure • Reflects domain information e.g. a task is divided into sub-tasks • Has recurring patterns that are observable through the language

  9. The solutions • To learn domain knowledge from data • Specify the structure of task-oriented conversations • Capture sufficient domain knowledge • Domain-independent • Learnable • Learn the structure from a corpus of human-human conversations

  10. Dialogue structure • Task Structure (data representation) • Necessary information for achieving a task goal • Steps in the task • Domain keywords • Dialog mechanism (operations) • The ways that the participants communicate and perform the task

  11. Outline • Introduction • Form-based dialog structure • Task structure • Dialog mechanisms • Dialog structure learning • Concept identification and clustering • Form identification • Operation Classification

  12. Existing dialog structures: Theoretical-oriented • Examples: • Theory of Discourse Structure (Grosz and Sidner, 1986) • Discourse Representation Theory (DRT) (Kamp and Reyle, 1993) • Focus on developing a theory that helps interpret discourse meaning • Might be too complex to be implemented in a dialog system • Use hand-written rules to recognize the structure

  13. Existing dialog structures: Engineering-oriented • Examples: • Plan-based theory (Allen and Perrault, 1980) • The theory of Conversation Acts (Traum and Hinkelman, 1992) • Focus on practical issues: • Predictability of each dialog component • The implementation of the structure in a dialog system

  14. What are missing? • Don’t describe key domain information that the participants communicate in a dialog. • The role of city names in a travel domain • It is not clear how to apply the structure in a dialog system • The relations between dialog structure components and dialog system components • How a dialog manager should treat each component

  15. Form-based dialog structure • Describe a dialog structure with an existing dialog manger frameworks • Have a concrete mapping between dialog structure components and dialog system components • A form-based architecture has been used successfully in many dialog systems • A form-based structure consists of: • A task structure (forms and slots) • Dialogue mechanisms (form operators) that advance the dialog

  16. Outline • Introduction • Form-based dialog structure • Task structure • Dialog mechanisms • Dialog structure learning • Concept identification and clustering • Form identification • Operation Classification

  17. Task Structure 3-level of organization • Task: a subset of conversations that has a specific goal • Sub-task: a step in a task that contributes toward a task goal => form • Concept: key information => slot

  18. Task Structure: Bus schedule enquiry domain • Task (multiple tasks): • Which bus runs between A and B? • When will the bus X arrive? • Sub-tasks: no further decomposition • Concepts: • Bus Number={61C, 28X, …} • Location={CMU, airport, …}

  19. Departure time query form F: Query_Departure_Time Depart_Location: carnegie_mellon Arrive_Location: the airport Arrive_Time: Hour:four Minute: thirty Bus_Number: 28X

  20. Task Structure: Travel planning domain • Task: create travel itinerary • Sub-tasks: • Flight reservation • Hotel reservation • Car rental reservation • Concepts: • airlines={Continental, US-Airways, …} • hotel={Hilton, Marriott, …}

  21. Task Structure: Map reading domain • Task: draw a line (a route) • Sub-tasks: • Draw a segment of a line • Concepts: • Landmark = {white_mountain, Machete, …} • Orientation = {down, left, …} • Distance = {a couple of centimeters, an inch, …}

  22. Outline • Introduction • Form-based dialog structure • Task structure • Dialog mechanisms • Dialog structure learning • Concept identification and clustering • Form identification • Operation Classification

  23. Dialogue mechanisms • Operations that the participants use to advance the dialog toward the goal • Task-oriented operations • Manipulate a form (data structure) • Examples: init_form, fill_form • Discourse-oriented operations • Manage the flow of a conversation • Examples: acknowledgement, greeting

  24. Dialogue mechanisms (2) • Have a unique consequence on the state of the conversation • init_form causes a system to create a new form • Domain independent, only operation parameters that are different • Fill city_name in flight_information form • Fill bus_number in bus_information form

  25. 1st leg Form Dept_Loc: City: PITTSBURGH Dept_Date: Month: FEBRUARY Date: TWENTIETH Dept_Time: Flight_ref: 1st leg Form Dept_Loc: City: PITTSBURGH Dept_Date: Month: FEBRUARY Date: TWENTIETH Dept_Time: EARLY TimeP: MORNING NOT BEFORE Hour: SEVEN Flight_ref: Arr_Loc: City: HOUSTON State: TEXAS Airport: INTERCONTINENTAL Arr_Date: Arr_Time: Airline_company: Arr_Loc: City: HOUSTON State: TEXAS Airport: INTERCONTINENTAL Arr_Date: Arr_Time: Airline_company: Air travel-planning domain PT8:     request_form_info: WHAT TIME WOULD YOU LIKE TO DEPART DepLoc:[PITTSBURGH ] PT8:     request_form_info: WHAT TIME WOULD YOU LIKE TO DEPART DepLoc:[PITTSBURGH ]X9:     fill_form_info: /UM/ EARLY DepT:[MORNING ]NOT BEFORE DepT:[H:[SEVEN ]] PT8:     request_form_info: WHAT TIME WOULD YOU LIKE TO DEPART DepLoc:[PITTSBURGH ]X9:     fill_form_info: /UM/ EARLY DepT:[MORNING ]NOT BEFORE DepT:[H:[SEVEN ]]PT10:   acknowledge: OKAY PT8:     request_form_info: WHAT TIME WOULD YOU LIKE TO DEPART DepLoc:[PITTSBURGH ]X9:     fill_form_info: /UM/ EARLY DepT:[MORNING ]NOT BEFORE DepT:[H:[SEVEN ]]PT10:   acknowledge: OKAY access_DB inform_result:U.S. AIRWAYS HAS A NON-STOP …

  26. Bus schedule enquiry domain U2: fill_form_info:  i wanted to take the 28X bus from /um/ DepLoc:[forbes avenue] to ArLoc:[the airport] F: Query_Departure_Time Depart_Location: Arrive_Location: Arrive_Time: Bus_Number: F: Query_Departure_Time Depart_Location: forbes avenue Arrive_Location: the airport Arrive_Time: Bus_Number: 28X

  27. Outline • Introduction • Form-based dialog structure • Task structure • Dialog mechanisms • Dialog structure learning • Concept identification and clustering • Form identification • Operation Classification

  28. Learning framework • Goal: minimize human effort • Use unsupervised learning when possible • Incorporating information from existing knowledge sources • If additional knowledge from a human is required • Train an initial model with a small amount of annotated data • Use unsupervised learning or active learning to selectively explore un-annotated data • A human can correct a mistake

  29. Dialog structure components • Domain-dependent -> have to learn in every domain • Task structure (forms, slots) • Expression for task-oriented operations • Domain-independent -> infrastructure or have to learn only once • List of operations • Expression for discourse-oriented operations

  30. Outline • Introduction • Form-based dialog structure • Task structure • Dialog mechanisms • Dialog structure learning • Concept identification and clustering • Form identification • Operation Classification

  31. Concept identification and clustering • Goal: Identify concept members cluster together the ones that belong to the same concept • City={Pittsburgh, Boston, Austin, …} • Assumption: • Word boundaries include compound word boundaries are given

  32. Concept identification steps • Identify potential concept members • Filter out noise, function words • Cluster similar words together • Statistical-based clustering: Mutual information-based and Kullback-Liebler-based • Knowledgebase clustering: WordNet • Select clusters that represent domain concepts • Use the same criteria as (1), but work on a cluster level

  33. Outline • Introduction • Form-based dialog structure • Task structure • Dialog mechanisms • Dialog structure learning • Concept identification and clustering • Form identification • Operation Classification

  34. Form Identification • Goal: determine different types of forms that occur in the domain • Assumption: • A dialog may be annotated with concept labels

  35. Approach • Segment a dialog into a sequence of sub-tasks (form boundaries identification) • Train a classifier on lexicon cohesion (Hearst, 1994) and prosodic features • Group together the sub-tasks that belong to the same form type • Use unsupervised clustering based on cosine similarity • Identify a set of slots that associated with each form type • Analyze a cluster of similar form instances

  36. Outline • Introduction • Form-based dialog structure • Task structure • Dialog mechanisms • Dialog structure learning • Concept identification and clustering • Form identification • Operation Classification

  37. Operation Classification • Goal: Learn the expressions that associate with each operation • by classifying an utterance into a pre-defined set of operations • Assumption • A dialog may be annotated with concepts labels • List of operation types are given • Operation boundaries are known

  38. Supervised classification • Use a Markov model (Woszczyna and Waibel, 1994) • States = operation types • Transition probability = dependency between operation types • Emission probability = P(W|operation_type) • Enhanced models • Use domain concepts as word classes to reduce a data sparseness problem • Add prosodic features

  39. Unsupervised learning and active learning • Train an initial classifier from human-labeled data • Apply the current classifier to an unlabeled operation • (Unsupervised learning) if the confidence is high, add this instance and the predicted label into the training set • (Active learning) if the confidence is low, ask a human to label this instance and then add it into the training set • Train a new classifier on all labeled data (both machined-labeled and human-labeled) Step 2-3 can be iterated

  40. Classifier confidence score • Difference in probability between the first rank and the second rank • The entropy of the classifier output • High entropy = low confidence

  41. Suggestion?

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