Tablet interaction techniques for viewport navigation on large displays

This chapter reviews the role of theory and dynamic systems theory for understanding common interaction techniques including: targetting, trajectory generation, panning, scrolling and zooming. It explains how can be seen to be at the foundations of Human–Computer Interaction and might be essential for making progress in novel forms of interface. It reinterprets Fitts’ classical work with theoretic tools. It also highlights the limitations of theory for design of human–computer loops.

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Introduction

10.1093/oso/9780198799603.003.0001 ◽

2018 ◽

Author(s):

Xiaojun Bi ◽

Andrew Howes ◽

Per Ola Kristensson ◽

Antti Oulasvirta ◽

John Williamson

Keyword(s):

Information Visualization ◽

User Interfaces ◽

Graphic Design ◽

Interaction Design ◽

Human Interaction ◽

Learning Design ◽

Human Factors Engineering ◽

Interaction Techniques ◽

Iterative Design ◽

And Control

This chapter introduces the field of computational interaction, and explains its long tradition of research on human interaction with technology that applies to human factors engineering, cognitive modelling, artificial intelligence and machine learning, design optimization, formal methods, and control theory. It discusses how the book as a whole is part of an argument that, embedded in an iterative design process, computational interaction design has the potential to complement human strengths and provide a means to generate inspiring and elegant designs without refuting the part played by the complicated, and uncertain behaviour of humans. The chapters in this book manifest intellectual progress in the study of computational principles of interaction, demonstrated in diverse and challenging applications areas such as input methods, interaction techniques, graphical user interfaces, information retrieval, information visualization, and graphic design.

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Controlling Teleportation-Based Locomotion in Virtual Reality with Hand Gestures: A Comparative Evaluation of Two-Handed and One-Handed Techniques

Electronics ◽

10.3390/electronics10060715 ◽

2021 ◽

Vol 10 (6) ◽

pp. 715

Author(s):

Alexander Schäfer ◽

Gerd Reis ◽

Didier Stricker

Keyword(s):

Virtual Reality ◽

Virtual Worlds ◽

User Preferences ◽

Interaction Techniques ◽

Hand Gestures ◽

Wide Range ◽

Effectiveness And Efficiency ◽

High Degree ◽

Additional Hardware ◽

Comprehensive Study

Virtual Reality (VR) technology offers users the possibility to immerse and freely navigate through virtual worlds. An important component for achieving a high degree of immersion in VR is locomotion. Often discussed in the literature, a natural and effective way of controlling locomotion is still a general problem which needs to be solved. Recently, VR headset manufacturers have been integrating more sensors, allowing hand or eye tracking without any additional required equipment. This enables a wide range of application scenarios with natural freehand interaction techniques where no additional hardware is required. This paper focuses on techniques to control teleportation-based locomotion with hand gestures, where users are able to move around in VR using their hands only. With the help of a comprehensive study involving 21 participants, four different techniques are evaluated. The effectiveness and efficiency as well as user preferences of the presented techniques are determined. Two two-handed and two one-handed techniques are evaluated, revealing that it is possible to move comfortable and effectively through virtual worlds with a single hand only.

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