Tangible, Embedded and Embodied Interaction - Lecture 9 - Next Generation User Interfaces (4018166FNR)

Transcript

1. 2 December 2005 Next Generation User Interfaces Tangible, Embedded and

   Embodied Interaction Prof. Beat Signer Department of Computer Science Vrije Universiteit Brussel beatsigner.com

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   March 25, 2024 Marble Answering Machine ▪ Marble answering machine ▪ incoming messages repre- sented by physical marbles ▪ Differences ▪ familiar physical objects show the number of messages ▪ aesthetically pleasing and enjoyable to use ▪ one-step actions to perform a task ▪ simple but elegant design with less functionality ▪ anyone can listen to any of the messages ▪ Might not be robust enough to be used in public space ▪ important to take into account where a product is going to be used Marble answering machine, D. Bishop, 1992

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   March 25, 2024 Marble Answering Machine (Video)

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   March 25, 2024 Graspable User Interfaces (1995) ▪ Direct control of electronic or virtual objects through physical handles (bricks) ▪ A brick is a new user inter- face that is tightly coupled to a virtual object ▪ Bricks are used on top of a large horizontal display surface known as the ActiveDesk ▪ GraspDraw is one particular application GraspDraw on ActiveDesk George W. Fitzmaurice, Hiroshi Ishii and William Buxton, Bricks: Laying the Foundations for Graspable User Interfaces, Proceedings of CHI 1995, ACM Conference on Human Factors in Computing Systems, Denver, USA, May 1995

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   March 25, 2024 Graspable User Interfaces (1995) … A graspable object Floor planner: multiple objects with handles and spline with multiple handles Two bricks attached to a single digital object (one acting as an anchor) Moving and rotating both bricks at the same time

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   March 25, 2024 Graspable User Interfaces (1995) … ▪ Advantages of Graspable UI design ▪ encourages two-handed interactions ▪ shifts to more specialised context-sensitive input devices ▪ allows for more parallel input specification ▪ makes use of our skills for physical object manipulations - affordances of artefacts define how we use the interface ▪ externalises traditionally internal computer representations ▪ facilitates interactions by making interface elements more "direct and manipulable" by using physical artefacts ▪ takes advantage of our spatial reasoning skills ▪ affords multi-person collaborative use ▪ … ▪ Foundations of tangible interaction

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   March 25, 2024 Affordances ▪ Term affordance introduced in 1977 by psychologist James J.Gibson in the 'The Theory of Affordances' ▪ originally defined as all possible actions with an object in an environment independent of an individual's ability to recognise these actions ▪ Don Norman refined the term affordances in the context of human-machine interaction ▪ only those possible actions with an object that can be recognised by an individual ▪ an affordance of an object tells us something (gives us a clue) about how to use the object ▪ good interaction design will take affordances and the related discoverability into account

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   March 25, 2024 Video: The Norman Door

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   March 25, 2024 Definition of Tangible Interaction ▪ Tangible interaction is an umbrella term for ▪ graspable user interfaces ▪ tangible user interfaces ▪ embodied interaction ▪ Tangible Interaction encompasses user interfaces and interaction approaches that emphasise ▪ tangibility and materiality of the interface ▪ physical embodiment of data ▪ whole-body interaction ▪ embedding of the interface and user interaction in real spaces and contexts ▪ physical objects as representation and control for digital information

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    March 25, 2024 Tangible Bits (1997) ▪ Beyond GUIs ("painted bits") ▪ Tangible User Interfaces (TUIs) augment the physical space by coupling digital information to everyday objects and environments ▪ physical instantiation of GUI elements in TUI ▪ Key concepts ▪ interactive surfaces ▪ coupling of bits and atoms ▪ ambient media (inspired by Life Wire) Hiroshi Ishii and Brygg Ullmer, Tangible Bits: Towards Seamless Interfaces between People, Bits and Atoms, Proceedings of CHI 1997, ACM Conference on Human Factors in Computing Systems, Atlanta, USA, March 1997 Hiroshi Ishii Brygg Ullmer

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    March 25, 2024 Life Wire (1995) ▪ Life Wire (dangling string) designed by Natalie Jeremijenko while she was an artist in residence at Xerox PARC ▪ plastic cord attached to electric motor mounted on the ceiling ▪ motor connected to the local Ethernet and each passing network packet triggers a switch of the motor ▪ bits flowing through the network become tangible through motion, sound and touch Natalie Jeremijenko Life Wire, 1995

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    March 25, 2024 metaDESK ▪ Back-projected graphical surface with various tools ▪ phicons ▪ activeLENS and passiveLENS ▪ instruments ▪ Tangible Geospace ▪ application prototype Tangible Geospace on metaDESK Physical instantiation of GUI elements in TUI

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    March 25, 2024 Video: metaDESK

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    March 25, 2024 ambientROOM ▪ Complements the cogni tively-foreground inter- actions of the metaDESK with ambient media ▪ ambient light or shadows ▪ sound ▪ airflow ▪ Communicate information at the periphery of human perception ▪ investigate how the parallel background processing can be used to convey information via ambient media ▪ enable seamless transition between primary foreground task and background processing ambientROOM

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    March 25, 2024 Urp ▪ System supporting urban planning ▪ Integration of physical model with an interactive simulation ▪ tangible models of buildings throw a digital shadow on the interactive surface ▪ simulated wind shown as projected arrows on the table ▪ Various physical tools available to ▪ measure distance between two points or wind speed ▪ change material of building (e.g. glass walls) or daytime Urp system

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    March 25, 2024 ReacTIVision ▪ Open source toolkit for tangible multi-touch surfaces ▪ Fiducial markers and multi-touch finger tracking Kaltenbrunner and Bencina, 2007 Reactable

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    March 25, 2024 Video: Reactable

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    March 25, 2024 The Sand Noise Music Device ▪ Interactive art installation offering an intuitive and tactile method for control- ling and interacting with a generative electronic music system ▪ virtual objects move in the sand and obey the laws of gravity (e.g. speed up when flowing downhill) ▪ users can move the physical objects as well as change the topography of the sand landscape The sand noise music device

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    March 25, 2024 Video: The Sand Noise Music Device

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    March 25, 2024 ArtVis ▪ Advanced visualisation techniques in combination with a TUI ▪ explore Web Gallery of Art ▪ faceted browsing ▪ phidgets-based TUI ▪ RFID-tagged physical objects ▪ Three main components to explore, analyse and browse the information ▪ new insights about large collections of data Bram Moerman

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    March 25, 2024 ArtVis ... Bram Moerman

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    March 25, 2024 ArtVis ... Bram Moerman

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    March 25, 2024 Sifteo Cubes (Siftables) ▪ Interactive gaming platform for ▪ spatial reasoning ▪ collaboration ▪ pattern recognition ▪ … ▪ Originated from Siftables ▪ Features ▪ 1.5" block with 128x128 colour TFT LCD ▪ 32 bit ARM CPU ▪ 3-axis accelerometer ▪ near-field object sensing technology (detect closeby Sifteo cubes) Sifteo Cubes

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    March 25, 2024 Video: Sifteo Cubes

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    March 25, 2024 ZeroN ▪ Anti-gravity interaction element that can be levitated and moved freely by a computer in 3D space ▪ explores how altering the fundamental rule of the physical world will transform interaction between humans and materials in the future ▪ Users can place or move the ZeroN in the mid-air 3D space in the same way they can place and interact with objects on surfaces ZeroN

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    March 25, 2024 Video: ZeroN

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    March 25, 2024 TRANSFORM TRANSFORM, MIT ▪ Dynamic shape display that can physically render 3D content ▪ tangible interaction with digital content - geospatial data - 3D modelling - … ▪ TRANSFORM display can also interact with the physical world around it ▪ remote users can be displayed physically ▪ Step towards MIT’s vision of Radical Atoms

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    March 25, 2024 Video: TRANSFORM

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    March 25, 2024 Radical Atoms (2012) ▪ Vision taking a leap beyond Tangible Bits ▪ assuming a hypothetical generation of materials that can change their form and appearance dynamically ▪ Radical Atoms is about ▪ a computationally transformable and reconfigurable material that is bidirectionally coupled with an underlying digital model (bits) ▪ the future material that can transform its shape, conform to constraints and inform the users of its affordances ▪ a vision for the future of human-material interaction, in which all digital information has a physical manifestation so that we can interact directly with it ▪ a new Material User Interface (MUI) Hiroshi Ishii, Dávid Lakatos, Leonardo Bonanni and Jean-Baptiste Labrune, Radical Atoms: Beyond Tangible Bits, Toward Transformable Materials, interactions 19(1), January 2012

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    March 25, 2024 Radical Atoms Concept ▪ Transform ▪ interface can transform its shape to modify the model and reflect changes in the computational model ▪ Conform ▪ interface has to conform to some physical laws and user constraints (e.g. for safety) ▪ Inform ▪ user has to be informed about changing interface affordances

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    March 25, 2024 Interactions with Radical Atoms ▪ Direct touch and gestural interaction ▪ gestures coupled with direct touch create an interaction appropriate for Radical Atoms since users are able to rapidly reform dynamic materials at all scales ▪ Context-aware transformation ▪ context-aware transformations of the hand tool/interface - e.g. screwdriver adapting to the type of screw it is operating on ▪ Shape-memory clay: Perfect Red ▪ Perfect Red is a fictional material that can be sculpted like and responds according to rules inspired by CAD operations - e.g. if we split a piece in two even halves, then the operations performed on one part are mirrored on the other part

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    March 25, 2024 Vision-driven Design Research ▪ Quantum leaps in HCI rarely result from studies on user needs but from the passion and dreams of visionaries ▪ e.g.Douglas Engelbart ▪ Vision-driven research ▪ strong vision can last beyond our lifespan ▪ have to wait for enabling technologies but exploration of interaction design can already start!

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    March 25, 2024 Data Physicalisation ▪ Tangible user interfaces (TUIs) for interacting with digital data and services ▪ e.g. ArtVis ▪ Physical objects used for output ▪ often static encoding of digital information ▪ How can we achieve dynamic data physicalisation with dynamic affordances ▪ e.g. 3D visualisation with additional dimensions represented by physical variables such as temperature or texture ▪ exploration of big data sets ▪ tangible holograms as an experimental platform

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    March 25, 2024 Tangible Hologram (TangHo) Platform Timothy J. Curtin

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    March 25, 2024 Tangible Hologram (TangHo) Platform …

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    March 25, 2024 TangHo Prototype ▪ Lego Mindstorms-based 6DOF arm prototype ▪ motors can be locked or set to float mode - useful for bidirectional I/O ▪ replaceable sphere for different types of non-visual feedback ▪ Challenges ▪ inverse kinematics (final system will be body mounted) - use robotics toolbox (MATLAB) ▪ limited HoloLens hand tracking ▪ 3D printing of final arm Timothy J. Curtin

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    March 25, 2024 TangHo Interactions

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    March 25, 2024 Homework ▪ Read the following paper that is available on Canvas (papers/Ishii2012) ▪ H. Ishii, D. Lakatos, L. Bonanni and J.-B. Labrune, Radical Atoms: Beyond Tangible Bits, Toward Transformable Materials, inter- actions, 19(1), January 2012

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    March 25, 2024 References ▪ G.W. Fitzmaurice, H. Ishii and W. Buxton, Bricks: Laying the Foundations for Graspable User Inter- faces, Proceedings of CHI 1995, ACM Conference on Human Factors in Computing Systems, Denver, USA, May 1995 ▪ https://dx.doi.org/10.1145/223904.223964 ▪ J.J. Gibson, The Ecological Approach to Visual Perception, Chapter 8: The Theory of Affordances, 1979, ISBN-13: 978-1848725782 ▪ https://cs.brown.edu/courses/cs137/readings/Gibson-AFF.pdf

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    March 25, 2024 References … ▪ H. Ishii and B. Ullmer, Tangible Bits: Towards Seamless Interfaces between People, Bits and Atoms, Proceedings of CHI 1997, ACM Conference on Human Factors in Computing Systems, Atlanta, USA, March 1997 ▪ https://dx.doi.org/10.1145/258549.258715 ▪ J. Underkoffler and H. Ishii, Urp: A Luminous-Tangible Workbench for Urban Planning and Design, Proceedings of CHI 1999, ACM Conference on Human Factors in Computing Systems, Pittsburgh, USA, May 1999 ▪ https://dx.doi.org/10.1145/302979.303114

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    March 25, 2024 References … ▪ S. Jordà, G. Geiger, M. Alonso and M. Kaltenbrunner, The reacTable: Exploring the Synergy Between Live Music Performance and Tabletop Tangible Interfaces, Proceedings of TEI 2007, Baton Rouge, USA, February 2007 ▪ https://dx.doi.org/10.1145/1226969.1226998 ▪ S. Follmer, D. Leithinger, A. Olwal, A. Hogge and H. Ishii, inFORM: Dynamic Physical Affordances and Constraints Through Shape and Object Actuation, Proceedings of UIST 2013, St Andrews, UK, October 2013 ▪ https://dx.doi.org/10.1145/2501988.2502032

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    March 25, 2024 References … ▪ H. Ishii, D. Lakatos, L. Bonanni and J.-B. Labrune, Radical Atoms: Beyond Tangible Bits, Toward Transformable Materials, interactions, 19(1), January 2012 ▪ https://dx.doi.org/10.1145/2065327.2065337 ▪ B. Dumas, B. Moerman, S. Trullemans and B. Signer, ArtVis: Combining Advanced Visualisation and Tangible Interaction for the Exploration, Analysis and Browsing of Digital Artwork Collections, Proceedings of AVI 2014, International Working Conference on Advanced Visual Interfaces, Como, Italy, May 2014 ▪ https://beatsigner.com/publications/dumas_AVI2014.pdf

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    March 25, 2024 References … ▪ B. Signer and T.J. Curtin, Tangible Holograms: Towards Mobile Physical Augmentation of Virtual Objects, Technical Report WISE Lab, WISE-2017-01, March 2017 ▪ https://beatsigner.com/publications/signer_arXiv2017.pdf ▪ Proceedings of TEI, International Conference on ▪ https://dl.acm.org/conference/tei

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    March 25, 2024 References … ▪ Eva Hornecker, Tangible Interaction ▪ https://www.interaction-design.org/literature/book/the-glossary-of-human- computer-interaction/tangible-interaction ▪ Durrell Bishop’s Marble Answering Machine ▪ https://www.youtube.com/watch?v=RgVbXV1krgU ▪ The Norman Door ▪ https://www.youtube.com/watch?v=yY96hTb8WgI ▪ metaDESK ▪ https://www.youtube.com/watch?v=FsHHYK_UXkw ▪ ambientROOM ▪ https://www.youtube.com/watch?v=WO939s7FARQ

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    March 25, 2024 References … ▪ Reactable ▪ https://www.youtube.com/watch?v=Mgy1S8qymx0&gl=BE ▪ The Sand Noise Music Device ▪ https://www.youtube.com/watch?v=VJgD-lEUPpo ▪ Siftables ▪ https://www.ted.com/talks/david_merrill_demos_siftables_the_smart_blocks ▪ ZeroN ▪ https://www.youtube.com/watch?v=-i2kJMJz7Wg ▪ TRANSFORM ▪ https://www.youtube.com/watch?v=lCARHatJQJA

46. 2 December 2005 Next Lecture Virtual and Augmented Reality