Bert Bierman scite author profile

Social robots have the potential to provide support in a number of practical domains, such as learning and behaviour change. This potential is particularly relevant for children, who have proven receptive to interactions with social robots. To reach learning and therapeutic goals, a number of issues need to be investigated, notably the design of an effective child-robot interaction (cHRI) to ensure the child remains engaged in the relationship and that educational goals are met. Typically, current cHRI research experiments focus on a single type of interaction activity (e.g. a game). However, these can suffer from a lack of adaptation to the child, or from an increasingly repetitive nature of the activity and interaction. In this paper, we motivate and propose a practicable solution to this issue: an adaptive robot able to switch between multiple activities within single interactions. We describe a system that embodies this idea, and present a case study in which diabetic children collaboratively learn with the robot about various aspects of managing their condition. We demonstrate the ability of our system to induce a varied interaction and show the potential of this approach both as an educational tool and as a research method for long-term cHRI.

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Design and evaluation of a personal robot playing a self-management education game with children with diabetes type 1

Henkemans

Bierman

Janssen

et al. 2017

International Journal of Human-Computer Studies

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Using a robot to personalise health education for children with diabetes type 1: A pilot study

Henkemans¹,

Bierman²,

Janssen³

et al. 2013

Patient Education and Counseling

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Friendship with a robot: Children’s perception of similarity between a robot’s physical and virtual embodiment that supports diabetes self-management

Sinoo¹,

Pal²,

Henkemans³

et al. 2018

Patient Education and Counseling

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Socio-Cognitive Engineering of a Robotic Partner for Child's Diabetes Self-Management

Neerincx

Vught²,

Henkemans³

et al. 2019

Front. Robot. AI

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Social or humanoid robots do hardly show up in "the wild," aiming at pervasive and enduring human benefits such as child health. This paper presents a socio-cognitive engineering (SCE) methodology that guides the ongoing research & development for an evolving, longer-lasting human-robot partnership in practice. The SCE methodology has been applied in a large European project to develop a robotic partner that supports the daily diabetes management processes of children, aged between 7 and 14 years (i.e., Personal Assistant for a healthy Lifestyle, PAL). Four partnership functions were identified and worked out (joint objectives, agreements, experience sharing, and feedback & explanation) together with a common knowledge-base and interaction design for child's prolonged disease self-management. In an iterative refinement process of three cycles, these functions, knowledge base and interactions were built, integrated, tested, refined, and extended so that the PAL robot could more and more act as an effective partner for diabetes management. The SCE methodology helped to integrate into the human-agent/robot system: (a) theories, models, and methods from different scientific disciplines, (b) technologies from different fields, (c) varying diabetes management practices, and (d) last but not least, the diverse individual and context-dependent needs of the patients and caregivers. The resulting robotic partner proved to support the children on the three basic needs of the Self-Determination Theory: autonomy, competence, and relatedness. This paper presents the R&D methodology and the human-robot partnership framework for prolonged "blended" care of children with a chronic disease (children could use it up to 6 months; the robot in the hospitals and diabetes camps, and its avatar at home). It represents a new type of human-agent/robot systems with an evolving collective intelligence. The underlying ontology and design rationale can be used as foundation for further developments of long-duration human-robot partnerships "in the wild."

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PS21 - 98. A personalized robot contributing to enjoyment and health knowledge ofchildren with diabetes at the clinic: a pilot study

Henkemans

Bierman

Janssen

et al. 2012

NED. TIJDSCHR. DIABET.

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Child-robot interaction in the wild

Greeff

Henkemans²,

Fraaije³

et al. 2014

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A field study was conducted in which CRI activities developed by the ALIZ-E project were tested with the project's primary user group: children with diabetes. This field study resulted in new insights in the modalities and roles a robot aimed at CRI in a healthcare setting might utilise, while in addition (re-)assessed some practises and technologies established within the project. Furthermore, it served as a means of strengthening the bonds with the project's principal stakeholders. The study illustrates on the one hand the feasibility of the activities that were developed within the project, while on the other hand highlights the importance of engaging with primary users in an ongoing, incremental fashion.

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A Cloud-based Robot System for Long-term Interaction: Principles, Implementation, Lessons Learned

Kaptein

Kiefer²,

Cully

et al. 2021

J. Hum.-Robot Interact.

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Making the transition to long-term interaction with social-robot systems has been identified as one of the main challenges in human-robot interaction. This article identifies four design principles to address this challenge and applies them in a real-world implementation: cloud-based robot control, a modular design, one common knowledge base for all applications, and hybrid artificial intelligence for decision making and reasoning. The control architecture for this robot includes a common Knowledge-base (ontologies), Data-base, “Hybrid Artificial Brain” (dialogue manager, action selection and explainable AI), Activities Centre (Timeline, Quiz, Break and Sort, Memory, Tip of the Day, \ldots ), Embodied Conversational Agent (ECA, i.e., robot and avatar), and Dashboards (for authoring and monitoring the interaction). Further, the ECA is integrated with an expandable set of (mobile) health applications. The resulting system is a Personal Assistant for a healthy Lifestyle (PAL), which supports diabetic children with self-management and educates them on health-related issues (48 children, aged 6–14, recruited via hospitals in the Netherlands and in Italy). It is capable of autonomous interaction “in the wild” for prolonged periods of time without the need for a “Wizard-of-Oz” (up until 6 months online). PAL is an exemplary system that provides personalised, stable and diverse, long-term human-robot interaction.

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Bert Bierman

Towards Long-Term Social Child-Robot Interaction: Using Multi-Activity Switching to Engage Young Users

Design and evaluation of a personal robot playing a self-management education game with children with diabetes type 1

Using a robot to personalise health education for children with diabetes type 1: A pilot study

Friendship with a robot: Children’s perception of similarity between a robot’s physical and virtual embodiment that supports diabetes self-management

Socio-Cognitive Engineering of a Robotic Partner for Child's Diabetes Self-Management

PS21 - 98. A personalized robot contributing to enjoyment and health knowledge ofchildren with diabetes at the clinic: a pilot study

Child-robot interaction in the wild

A Cloud-based Robot System for Long-term Interaction: Principles, Implementation, Lessons Learned

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