Collaborative Communication Interruption Management System (C-CIMS): Modeling Interruption Timings via Prosodic and Topic Modelling for Human-Machine Teams

Peters, Nia S.

01 December 2017

Human-machine teaming aims to meld human cognitive strengths and the unique capabilities of smart machines to create intelligent teams adaptive to rapidly changing circumstances. One major contributor to the problem of human-machine teaming is a lack of communication skills on the part of the machine. The primary objective of this research is focused on a machine’s interruption timings or when a machine should share and communicate information with human teammates within human-machine teaming interactions. Previous work addresses interruption timings from the perspective of single human, multitasking and multiple human, single task interactions. The primary aim of this dissertation is to augment this area by approaching the same problem from the perspective of a multiple human, multitasking interaction. The proposed machine is the Collaborative Communication Interruption Management System (C-CIMS) which is tasked with leveraging speech information from a human-human task and making inferences on when to interrupt with information related to an orthogonal human-machine task. This study and previous literature both suggest monitoring task boundaries and engagement as candidate moments of interruptibility within multiple human, multitasking interactions. The goal then becomes designing an intermediate step between human teammate communication and points of interruptibility within these interactions. The proposed intermediate step is the mapping of low-level speech information such as prosodic and lexical information onto higher constructs indicative of interruptibility. C-CIMS is composed of a Task Boundary Prosody Model, a Task Boundary Topic Model, and finally a Task Engagement Topic Model. Each of these components are evaluated separately in terms of how they perform within two different simulated human-machine teaming scenarios and the speed vs. accuracy tradeoffs as well as other limitations of each module. Overall the Task Boundary Prosody Model is tractable within a real-time system because of the low-latency in processing prosodic information, but is less accurate at predicting task boundaries even within human-machine interactions with simple dialogue. Conversely, the Task Boundary and Task Engagement Topic Models do well inferring task boundaries and engagement respectively, but are intractable in a real-time system because of the bottleneck in producing automatic speech recognition transcriptions to make interruption decisions. The overall contribution of this work is a novel approach to predicting interruptibility within human-machine teams by modeling higher constructs indicative of interruptibility using low-level speech information.

human machine teaming

interruption management system

prosody modeling

topic modeling

Prediction of Pilot Skill Level and Workload for Sliding-Scale Autonomous Systems

Nittala, Sai Kameshwar Rao

January 2017

No description available.

Electrical Engineering

Engineering

Computer Science

Big Brother Meets the Wizard of Oz: The Unlikely Pair that Revealed Insights intoHuman-Machine Teaming Effectiveness in the Presence of Mismatches

Johnson, Jaelyn A.

January 2022

No description available.

Industrial Engineering

Systems Science

Engineering

Design

human-machine teaming

heterogeneous tasking

human factors

human machine teaming design

study design

usability study

intelligence analysis

joint-activity

joint-performance

autonomous systems

human-computer interaction

cognitive systems engineering

Addressing the Recommender System Data Solicitation Problem with Engaging User Interfaces

Quang Dao (9873176)

18 December 2020

<p>With autonomous systems bringing greater demand for user data, in some applications, this also brings an opportunity to solicit data from users. To exploit this, a user interface will need to be designed to coax the user into achieving system goals, like data solicitation. One approach is to design a system to leverage an already present tendency for people to socially interact with technology. In this thesis, I argue that such an approach would involve incorporating interaction concepts that facilitate engagement into the design of recommender system interfaces that will improve the likelihood of obtaining data from users. To support this claim, I synthesize past work on human-computer interaction and recommender systems to derive a framework to guide scientific investigations into interface design concepts that will address the data solicitation problem.<br></p>

Computer-Human Interaction

Recommender Systems

Anthropomorphism

Engagement

Data Solicitation

Human Machine Teaming

Autonomy

Trust

Joint Activity

Discourse Planning

Breaking away from brittle machines: Evaluating simultaneous inference and data (SID) displays to facilitate machine fitness assessment

Morey, Dane Anthony

January 2021

No description available.

Systems Design

Systems Science

Industrial Engineering

Artificial Intelligence

human-machine teaming

joint cognitive systems

machine fitness assessment

Development of Real-Time Systems for Supporting Collaborations in Distributed HumanAnd Machine Teams

Bositty, Aishwarya

January 2020

No description available.

Computer Science

real-time distributed systems

Human-Machine Teaming

human-machine collaboration

A Design Thinking Framework for Human-Centric Explainable Artificial Intelligence in Time-Critical Systems

Stone, Paul Benjamin

January 2022

No description available.

Design

Artificial Intelligence

Engineering

Experiments

Industrial Engineering

Explainable Artificial Intelligence

Design Framework

Transparency

Trust

Human-Machine Teaming

Human-Centric AI

Eye-Tracking

Empathy

Design Thinking

Simulation Studies and Benchmarking of Synthetic Voice Assistant Based Human-Machine Teams (HMT)

Damacharla, Praveen Lakshmi Venkata Naga

January 2018

No description available.

Computer Science

Robotics

Artificial Intelligence

Systems Design

Systems Science