Press'Em: Simulating varying button tactility via FDVV models

Yi Chi Liao; Sunjun Kim; Byungjoo Lee; Antti Oulasvirta

doi:10.1145/3334480.3383161

Abstrakti

Push-buttons provide rich haptic feedback during a press via mechanical structures. While different buttons have varying haptic qualities, few works have attempted to dynamically render such tactility, which limits designers from freely exploring buttons' haptic design. We extend the typical force-displacement (FD) model with vibration (V) and velocity-dependence characteristics (V) to form a novel FDVV model. We then introduce Press'Em, a 3D-printed prototype capable of simulating button tactility based on FDVV models. To drive Press'Em, an end-to-end simulation pipeline is presented that covers (1) capturing any physical buttons, (2) controlling the actuation signals, and (3) simulating the tactility. Our system can go beyond replicating existing buttons to enable designers to emulate and test non-existent ones with desired haptic properties. Press'Em aims to be a tool for future research to better understand and iterate over button designs.

Alkuperäiskieli	Englanti
Sivumäärä	4
DOI - pysyväislinkit	https://doi.org/10.1145/3334480.3383161
Tila	Julkaistu - 25 huhtik. 2020
OKM-julkaisutyyppi	Ei sovellu
Tapahtuma	ACM SIGCHI Annual Conference on Human Factors in Computing Systems - Honolulu, Yhdysvallat Kesto: 26 huhtik. 2020 → 30 huhtik. 2020 https://chi2020.acm.org/

Conference

Conference	ACM SIGCHI Annual Conference on Human Factors in Computing Systems
Lyhennettä	ACM CHI
Maa/Alue	Yhdysvallat
Kaupunki	Honolulu
Ajanjakso	26/04/2020 → 30/04/2020
www-osoite	https://chi2020.acm.org/

Pääsy asiakirjaan

10.1145/3334480.3383161

Muut tiedostot ja linkit

Link to publication in Scopus

Siteeraa tätä

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title = "Press'Em: Simulating varying button tactility via FDVV models",

abstract = "Push-buttons provide rich haptic feedback during a press via mechanical structures. While different buttons have varying haptic qualities, few works have attempted to dynamically render such tactility, which limits designers from freely exploring buttons' haptic design. We extend the typical force-displacement (FD) model with vibration (V) and velocity-dependence characteristics (V) to form a novel FDVV model. We then introduce Press'Em, a 3D-printed prototype capable of simulating button tactility based on FDVV models. To drive Press'Em, an end-to-end simulation pipeline is presented that covers (1) capturing any physical buttons, (2) controlling the actuation signals, and (3) simulating the tactility. Our system can go beyond replicating existing buttons to enable designers to emulate and test non-existent ones with desired haptic properties. Press'Em aims to be a tool for future research to better understand and iterate over button designs.",

keywords = "Button, FD model, FDVV model, Force feedback, Haptic, Haptic rendering, Input device, Modeling, Simulation, Tactility, Vibration",

author = "Liao, {Yi Chi} and Sunjun Kim and Byungjoo Lee and Antti Oulasvirta",

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T1 - Press'Em: Simulating varying button tactility via FDVV models

AU - Liao, Yi Chi

AU - Kim, Sunjun

AU - Lee, Byungjoo

AU - Oulasvirta, Antti

PY - 2020/4/25

Y1 - 2020/4/25

N2 - Push-buttons provide rich haptic feedback during a press via mechanical structures. While different buttons have varying haptic qualities, few works have attempted to dynamically render such tactility, which limits designers from freely exploring buttons' haptic design. We extend the typical force-displacement (FD) model with vibration (V) and velocity-dependence characteristics (V) to form a novel FDVV model. We then introduce Press'Em, a 3D-printed prototype capable of simulating button tactility based on FDVV models. To drive Press'Em, an end-to-end simulation pipeline is presented that covers (1) capturing any physical buttons, (2) controlling the actuation signals, and (3) simulating the tactility. Our system can go beyond replicating existing buttons to enable designers to emulate and test non-existent ones with desired haptic properties. Press'Em aims to be a tool for future research to better understand and iterate over button designs.

AB - Push-buttons provide rich haptic feedback during a press via mechanical structures. While different buttons have varying haptic qualities, few works have attempted to dynamically render such tactility, which limits designers from freely exploring buttons' haptic design. We extend the typical force-displacement (FD) model with vibration (V) and velocity-dependence characteristics (V) to form a novel FDVV model. We then introduce Press'Em, a 3D-printed prototype capable of simulating button tactility based on FDVV models. To drive Press'Em, an end-to-end simulation pipeline is presented that covers (1) capturing any physical buttons, (2) controlling the actuation signals, and (3) simulating the tactility. Our system can go beyond replicating existing buttons to enable designers to emulate and test non-existent ones with desired haptic properties. Press'Em aims to be a tool for future research to better understand and iterate over button designs.

KW - Button

KW - FD model

KW - FDVV model

KW - Force feedback

KW - Haptic

KW - Haptic rendering

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KW - Modeling

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