OVERVIEW
Virtual Assistants
Kore.ai Platform
Key Concepts
Natural Language Processing (NLP)
Accessing Platform
VIRTUAL ASSISTANTS
Virtual Assistant Builder
Virtual Assistant Types
Getting Started
Creating a Simple Bot
SKILLS
Storyboard
Dialog Task
Introduction
Dialog Builder (New)
Dialog Builder (Legacy)
User Intent Node
Dialog Node
Entity Node
Supported Entity Types
Composite Entities
Supported Colors
Supported Company Names
Form Node
Logic Node
Message Nodes
Confirmation Nodes
Bot Action Node
Service Node
Custom Authentication
2-way SSL for Service nodes
Script Node
Agent Transfer Node
WebHook Node
Grouping Nodes
Connections & Transitions
Manage Dialogs
User Prompts
Knowledge Graph
Terminology
Building
Generation
Importing and Exporting
Analysis
Knowledge Extraction
Build
Alert Tasks
Introduction
Ignore Words and Field Memory
How to Schedule a Smart Alert
Small Talk
Digital Views
Overview
Configuring Digital Views
Digital Forms
Overview
How to Configure Digital Forms
NATURAL LANGUAGE
Overview
Machine Learning
Introduction
Model Validation
Fundamental Meaning
Introduction
NLP Guidelines
Knowledge Graph
Traits
Introduction
How to Use Traits
Ranking and Resolver
Advanced NLP Configurations
INTELLIGENCE
Overview
Context Management
Overview
Session and Context Variables
Context Object
How to Manage Context Switching
Manage Interruptions
Dialog Management
Sub-Intents & Follow-up Intents
Amend Entity
Multi-Intent Detection
Sentiment Management
Tone Analysis
Sentiment Management
Event Based Bot Actions
Default Conversations
Default Standard Responses
TEST & DEBUG
Talk to Bot
Utterance Testing
Batch Testing
Conversation Testing
CHANNELS
PUBLISH
ANALYZE
Overview
Dashboard
Custom Dashboard
Overview
How to Create Custom Dashboard
Conversation Flows
NLP Metrics
ADVANCED TOPICS
Universal Bots
Overview
Defining
Creating
Training
Customizing
Enabling Languages
Store
Smart Bots
Defining
koreUtil Libraries
SETTINGS
Authorization
Language Management
PII Settings
Variables
Functions
IVR Integration
General Settings
Management
Import & Export
Delete
Versioning
Collaborative Development
PLAN & USAGE
Overview
Usage Plans
Support Plans
Invoices
API GUIDE
API Overview
API List
API Collection
SDKs
SDK Overview
SDK Security
SDK App Registration
Web SDK Tutorial
Message Formatting and Templates
Mobile SDK Push Notification
Widget SDK Tutorial
Widget SDK – Message Formatting and Templates
Web Socket Connect & RTM
Using the BotKit SDK
Installing
Configuring
Events
Functions
BotKit SDK Tutorial – Agent Transfer
BotKit SDK Tutorial – Flight Search Sample Bot
Using an External NLP Engine
ADMINISTRATION
HOW TOs
Creating a Simple Bot
Creating a Banking Bot
Context Switching
Using Traits
Schedule a Smart Alert
Configure UI Forms
Add Form Data into Data Tables
Configuring Digital Views
Add Data to Data Tables
Update Data in Data Tables
Custom Dashboard
Custom Tags to filter Bot Metrics
Patterns for Intents & Entities
Build Knowledge Graph
Global Variables
Content Variables
Using Bot Functions
Configure Agent Transfer
Update Balance Task
Transfer Funds Task
RELEASE NOTES
  1. Docs
  2. Virtual Assistants
  3. Natural Language
  4. Ranking and Resolver

Ranking and Resolver

The Kore.ai NLP engine uses Machine Learning, Fundamental Meaning, and Knowledge Graph (if any) models to match intents. All the three Kore.ai engines finally deliver their findings to the Kore.ai Ranking and Resolver component as either exact matches or probable matches. Ranking and Resolver determines the final winner of the entire NLP computation.

Working

The NLP engine uses a hybrid approach using Machine Learning, Fundamental Meaning, and Knowledge Graph (if the bot has one) models to score the matching intents on relevance. The model classifies user utterances as either being Possible Matches or Definitive Matches.

Definitive Matches get high confidence scores and are assumed to be perfect matches for the user utterance. In published bots, if user input matches with a single Definitive Match, the bot directly executes the task. If the utterances match with multiple Definitive Matches, they are sent as options for the end-user to choose one.

On the other hand, Possible Matches are intents that score reasonably well against the user input but do not inspire enough confidence to be termed as exact matches. Internally the system further classifies possible matches into good and unsure matches based on their scores. If the end-user utterances were generating possible matches in a published bot, the bot sends these matches as Did you mean? suggestions for the end-user.

Based on the ranking and resolver, the winning intent between the engines is ascertained. If the platform finds ambiguity, then an ambiguity dialog is initiated. The platform initiates one of these two system dialogs when it cannot ascertain a single winning intent for a user utterance:

  • Disambiguation Dialog: Initiated when there are more than one Definitive matches returned across engines. In this scenario, the bot asks the user to choose a Definitive match to execute. You can customize the message shown to the user from the NLP Standard Responses.
  • Did You Mean Dialog: Initiated if the Ranking and Resolver returns more than one winner or the only winning intent is an FAQ whose KG engine score is between lower and upper thresholds. This dialog lets the user know that the bot found a match to an intent that it is not entirely sure about and would like the user to select to proceed further. In this scenario, the developer should identify these utterances and train the bot further. You can customize the message shown to the user from the NLP Standard Responses.

Learn more about model scores and resolver.

Thresholds & Configuration

To configure a Ranking and Resolver Engine, follow the below steps:

  • Open the bot for which you want to configure thresholds.
  • Select the Build tab from the top menu.
  • From the left navigation click Natural Language > Thresholds & Configurations.
  • The Ranking & Resolver Engine section allows you to set the threshold:
    • Prefer Definitive Matches can be used to prioritize definitive matches over probable matches so that all the matches are considered for rescoring and the end-user gets to choose the right intent in case of any ambiguity. This setting is enabled by default and you can disable it. If enabled (default behavior), definitive matches will win and the probable matches would be discarded, in case of no definitive match, then probable matches would get rescored. If disabled, all the matches – definitive and probable, would be rescored.
    • Rescoring of Intents can be turned off so that all the qualified intents from the different intent engines are assumed winning intents and are sent to the end-users to choose the required intent. If only one intent is qualified, then it is considered a winner, if more than one is qualified then the user will be presented with results for disambiguation.
    • Proximity of Probable Matches which defines the maximum difference to be allowed between top-scoring and immediate next possible intents to consider them as equally important. Before v7.3 of the platform, this setting was under the Fundamental Meaning section.
    • Dependency Parsing Model for enabling rescoring the intents by the Ranking and Resolver engine as well as for the intent recognition by the Fundamental Meaning model. This configuration is disabled by default and needs to be set implicitly. See below for details.

Dependency Parsing Model

The platform has two models for scoring intents by the Fundamental Meaning Engine and the Ranking & Resolver Engine:

  1. The first model predominantly relies on the presence of words, the position of words in the utterance, etc. to determine the intents and is scored solely by the Fundamental Meaning Engine. This is the default setting.
  2. The second model is based on the dependency matrix where the intent detection is based on the words, their relative position, and most importantly the dependency between the keywords in the sentence. Under this model, intents are scored by the Fundamental Meaning Engine and then rescored by the Ranking and Resolver Engine.

Dependency Parsing Model can be enabled and configured from the Ranking and Resolver section under Training > Thresholds & Configurations.

Note: This feature is supported only for select languages, see here for supported languages.

Dependency Parsing Model can be configured as follows:

  • Minimum Match Score to define the minimum score to qualify an intent as a probable match. It can be set to a value between 0.0 to 1.0 with the default set to 0.5.
  • Advanced Configurations are used to customize the model by changing the weights and scores associated with various parameters. This opens a JSON editor where you can enter the valid code. You can click the restore to default configurations to get the default threshold settings in a JSON structure, you can change the settings provided you are aware of the consequences.

NLP Detection

The Natural Language Analysis will result in the following scenarios:

  • NLP Analysis identifying a Definitive match with FM or ML or KG engines.
  • NLP Analysis with multiple engines returning probable match and selecting a single match.
  • NLP Analysis with multiple engines returning probable match and resolver returning multiple results.
  • NLP Analysis with no match.

Each of the above cases is discussed in this section.

To understand NLP detection, let us use the example of a Bank bot with the following details:

  • The bot consists of 5 Dialog Tasks and a Default Dialog.
  • The intents are trained with Synonyms, Patterns, and ML utterances.
  • The bot consists of a knowledge graph defined with 86 FAQs distributed in 4 top-level terms.

Scenario 1 – FM Identifying a Definitive Match

  • The Fundamental Meaning (FM) model identified the utterance as a Definitive match.
  • The Machine Learning (ML) model also identified it as a Possible match.
  • The score returned for the task identified is 6 times more than other intent scores. Also, all the words in the intent name are present in the user utterance. Thus the FM model termed it a Definitive match.
  • The ML model matches the Find ATM intent as a Probable match.

Scenario 2 – ML Identifying a Definitive Match

  • The ML Model returns a Definitive match with other models returning no match.
  • The FM model could not identify this task as none of the words in the task name Transfer Funds matched the words in the user utterance.

Scenario 3 – KG Identifying a Definitive Match

  • The user utterance is How do I make transfer money to a London account?
  • The user utterance contains all the terms required to match this Knowledge Graph intent path Transfer, Money, International.
  • The term international is identified as a synonym of London that the user used in the utterance.
  • As 100% path term matched the path was qualified. As part of confidence scoring, the terms in the user query are similar to that of the actual Knowledge Graph question. Thus, it returns a score of 100.
  • As the score returned is above 100, the intent is marked as a Definitive match and selected.
  • FM engine found it a Probable match as the key term Transfer is present in the user utterance
  • ML engine found the utterance as a Probable match as the utterance did not fully match any trained utterance.

Scenario 4 – Multiple Engines Returning Probable Match

  • All the 3 engines returned a possible match and no definitive match.
  • ML Model has 1 possible match and FM Model has 2 possible matches, of which 1 is common. Knowledge Graph has 1 possible match. All possible matches identified are re-ranked in the Ranking and Resolver.
  • The Ranking and Resolver component returned the highest score for the single match (Task name – When can I start making payments using BillPay plus?) from the Knowledge graph engine. The scores for other probable match come out to be lower than 2 percentile of the top score and are thus ignored. The winner, in this case, is the ‘KG’ returned query and is presented to the user.
  • Though most of the keywords in the user utterance map to the keywords in the KG query, still this is not a definitive match because
    • The number of path terms matched is not 100%.
    • The KG engine returned the score with a 64.72% probability. Had we used the word Billpay instead of bill pay the score must have been 87.71%. (still not a 100% match)
    • Now as the score is between the 60%-80%, a threshold of the Query is presented as part of the Did-you-mean dialog and not as a complete winner. If the score was above 80%, the platform would have given out the response without re-confirming with the Did-you-mean dialog.

Scenario 5 – Resolver Returning Multiple Results

  • All the engines detected probable matches.
  • KG returned with 2 possible paths.
  • Ranking and resolver found the 2 queries with a score of less than 2% apart.
  • Both the Knowledge Graph intents are selected and presented to the user as Did-you-mean.
  • Both the paths were selected as terms in both matches and the score for both the paths is more than 60%.

Scenario 6 – No match

  • None of the engines could identify any trained intent or Knowledge Graph intent.
  • In this scenario, the default intent is triggered.
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