A hybrid computational approach to anticipate individuals in sequential problem solving

Giacomo Zamprogno; Emmanuelle Dietz; Linda Heimisch; Nele Russwinkel

doi:10.3389/frai.2023.1223251

A hybrid computational approach to anticipate individuals in sequential problem solving

Front Artif Intell. 2023 Dec 18:6:1223251. doi: 10.3389/frai.2023.1223251. eCollection 2023.

Authors

Giacomo Zamprogno^{1

2}, Emmanuelle Dietz², Linda Heimisch³, Nele Russwinkel^{3

4}

Affiliations

¹ Department of Computer Science and Engineering, University of Bologna, Bologna, Italy.
² Airbus Central Research and Technology, Hamburg, Germany.
³ Department of Psychology and Ergonomics, Technische Universität Berlin, Berlin, Germany.
⁴ Group Human-Aware AI, Institut of information Systems, Universität zu Lübeck, Lübeck, Germany.

Abstract

Human-awareness is an ever more important requirement for AI systems that are designed to assist humans with daily physical interactions and problem solving. This is especially true for patients that need support to stay as independent as possible. To be human-aware, an AI should be able to anticipate the intentions of the individual humans it interacts with, in order to understand the difficulties and limitations they are facing and to adapt accordingly. While data-driven AI approaches have recently gained a lot of attention, more research is needed on assistive AI systems that can develop models of their partners' goals to offer proactive support without needing a lot of training trials for new problems. We propose an integrated AI system that can anticipate actions of individual humans to contribute to the foundations of trustworthy human-robot interaction. We test this in Tangram, which is an exemplary sequential problem solving task that requires dynamic decision making. In this task the sequences of steps to the goal might be variable and not known by the system. These are aspects that are also recognized as real world challenges for robotic systems. A hybrid approach based on the cognitive architecture ACT-R is presented that is not purely data-driven but includes cognitive principles, meaning heuristics that guide human decisions. Core of this Cognitive Tangram Solver (CTS) framework is an ACT-R cognitive model that simulates human problem solving behavior in action, recognizes possible dead ends and identifies ways forward. Based on this model, the CTS anticipates and adapts its predictions about the next action to take in any given situation. We executed an empirical study and collected data from 40 participants. The predictions made by CTS were evaluated with the participants' behavior, including comparative statistics as well as prediction accuracy. The model's anticipations compared to the human test data provide support for justifying further steps built upon our conceptual approach.

Keywords: anticipation; cognitive modeling; human-robot collaboration (HRC); hybrid (symbolic sub-symbolic) approach; sequential problem solving.