论文信息 - Improving Pointing in Graphical User Interfaces for People with Motor Impairments Through Ability-Based Design

Improving Pointing in Graphical User Interfaces for People with Motor Impairments Through Ability-Based Design

Pointing to targets in graphical user interfaces remains a frequent and fundamental necessity in modern computing systems. Yet for millions of people with motor impairments, children, and older users, pointing—whether with a mouse cursor, a stylus, or a finger on a touch screen—remains a major access barrier because of the fine-motor skills required. In a series of projects inspired by and contributing to ability-based design, we have reconsidered the nature and assumptions behind pointing, resulting in changes to how mouse cursors work, the types of targets used, the way interfaces are designed and laid out, and even how input devices are used. The results from these explorations show that people with motor difficulties can acquire targets in graphical user interfaces when interfaces are designed to better match the abilities of their users. Ability-based design, as both a design philosophy and a design approach, provides a route to realizing a future in which people can utilize whatever abilities they have to express themselves not only to machines, but to the world.

Jacob O. Wobbrock | J. Wobbrock

[1] Benjamin B. Bederson,et al. ThumbSpace: Generalized One-Handed Input for Touchscreen-Based Mobile Devices , 2007, INTERACT.

[2] Peter Robinson,et al. Cursor measures for motion-impaired computer users , 2002, ASSETS.

[3] Joel S. Greenstein,et al. Optimizing the Touch Tablet: The Effects of Control-Display Gain and Method of Cursor Control , 1986 .

[4] Motoyuki Akamatsu,et al. Movement characteristics using a mouse with tactile and force feedback , 1996, Int. J. Hum. Comput. Stud..

[5] Anthony J. Hornof,et al. EyeDraw: enabling children with severe motor impairments to draw with their eyes , 2005, CHI.

[6] Andrew T. Duchowski,et al. Efficient eye pointing with a fisheye lens , 2005, Graphics Interface.

[7] Krzysztof Z. Gajos,et al. SUPPLE: automatically generating user interfaces , 2004, IUI '04.

[8] Constantine Stephanidis,et al. User Interfaces for All: Concepts, Methods, and Tools , 2009 .

[9] James A. Landay,et al. Voicedraw: a hands-free voice-driven drawing application for people with motor impairments , 2007, Assets '07.

[10] Carl Gutwin,et al. Perceptibility and utility of sticky targets , 2008, Graphics Interface.

[11] Peter Robinson,et al. Investigating the applicability of user models for motion-impaired users , 2000, Assets '00.

[12] Tommy Strandvall,et al. Eye Tracking in Human-Computer Interaction and Usability Research , 2009, INTERACT.

[13] Benjamin B. Bederson,et al. Target size study for one-handed thumb use on small touchscreen devices , 2006, Mobile HCI.

[14] Daniel Vogel,et al. Shift: a technique for operating pen-based interfaces using touch , 2007, CHI.

[15] Melissa Dawe,et al. Caregivers, cost, and complexity: understanding technology usage by individuals with cognitive disabilities , 2005, ASAC.

[16] I. Scott MacKenzie,et al. Accuracy measures for evaluating computer pointing devices , 2001, CHI.

[17] Päivi Majaranta,et al. Twenty years of eye typing: systems and design issues , 2002, ETRA.

[18] Christopher M. Schlick,et al. Design pattern TRABING: touchscreen-based input technique for people affected by intention tremor , 2010, EICS '10.

[19] Juan Pablo Hourcade,et al. Learning from preschool children's pointing sub-movements , 2006, IDC '06.

[20] Shari Trewin,et al. Keyboard and mouse errors due to motor disabilities , 1999, Int. J. Hum. Comput. Stud..

[21] Andreas Paepcke,et al. EyePoint: practical pointing and selection using gaze and keyboard , 2007, CHI.

[22] Peter Robinson,et al. Developing assistive interfaces for motion-impaired users using cursor movement analysis in conjunction with haptic feedback , 2002 .

[23] Edward Lank,et al. Endpoint prediction using motion kinematics , 2007, CHI.

[24] P. John Clarkson,et al. Countering design exclusion through inclusive design , 2002, CUU '03.

[25] Ravin Balakrishnan,et al. Acquisition of expanding targets , 2002, CHI.

[26] Motoyuki Akamatsu,et al. A multi-modal mouse with tactile and force feedback , 1994, Int. J. Hum. Comput. Stud..

[27] Jeff A. Johnson,et al. The Xerox Star: a retrospective , 1989, Computer.

[28] Gregg Vanderheiden,et al. Fundamental principles and priority setting for universal usability , 2000, CUU '00.

[29] Cathleen Wharton,et al. Toward an HCI research and practice agenda based on human needs and social responsibility , 1997, CHI.

[30] Worthy N. Martin,et al. Human-computer interaction using eye-gaze input , 1989, IEEE Trans. Syst. Man Cybern..

[31] Maria C. Yang,et al. Haptic Force-Feedback Devices for the Office Computer: Performance and Musculoskeletal Loading Issues , 2001, Hum. Factors.

[32] W. Buxton,et al. A study in two-handed input , 1986, CHI '86.

[33] Brad A. Myers,et al. EdgeWrite: a stylus-based text entry method designed for high accuracy and stability of motion , 2003, UIST '03.

[34] Brad A. Myers,et al. Writing with a Joystick: A Comparison of Date Stamp, Selection Keyboard, and Edge Write , 2004, Graphics Interface.

[35] William Buxton,et al. Issues and techniques in touch-sensitive tablet input , 1985, SIGGRAPH '85.

[36] John R. Anderson,et al. Intelligent gaze-added interfaces , 2000, CHI.

[37] Peter Gregor,et al. “User sensitive inclusive design”— in search of a new paradigm , 2000, CUU '00.

[38] W. C. Howell. of the Human Factors and Ergonomics Society , 2010 .

[39] Jon Froehlich,et al. Barrier pointing: using physical edges to assist target acquisition on mobile device touch screens , 2007, Assets '07.

[40] Simeon Keates,et al. Developing steady clicks:: a method of cursor assistance for people with motor impairments , 2006, Assets '06.

[41] Jacob O. Wobbrock,et al. Taming wild behavior: the input observer for obtaining text entry and mouse pointing measures from everyday computer use , 2012, CHI.

[42] A J Moss,et al. Assistive technology devices and home accessibility features: prevalence, payment, need, and trends. , 1992, Advance data.

[43] Steven K. Feiner,et al. Rubbing and tapping for precise and rapid selection on touch-screen displays , 2008, CHI.

[44] Rüdiger Dillmann,et al. Haptic output in multimodal user interfaces , 1997, IUI '97.

[45] Patrick Baudisch,et al. Snap-and-go: helping users align objects without the modality of traditional snapping , 2005, CHI.

[46] Juan Pablo Hourcade,et al. Pointassist for older adults: analyzing sub-movement characteristics to aid in pointing tasks , 2010, CHI.

[47] I. Scott MacKenzie,et al. Towards a standard for pointing device evaluation, perspectives on 27 years of Fitts' law research in HCI , 2004, Int. J. Hum. Comput. Stud..

[48] Paul Kabbash,et al. The “prince” technique: Fitts' law and selection using area cursors , 1995, CHI '95.

[49] Jennifer M. Hootman,et al. Prevalence of doctor-diagnosed arthritis and arthritis-attributable activity limitation --- United States, 2007-2009. , 2010, MMWR. Morbidity and mortality weekly report.

[50] George E Stelmach,et al. Age-related kinematic differences as influenced by task difficulty, target size, and movement amplitude. , 2002, The journals of gerontology. Series B, Psychological sciences and social sciences.

[51] Brian R. Johnson,et al. Selection of Web Browser Controls with and without Impenetrable Borders: Does Width Make a Difference? , 2003 .

[52] Ravin Balakrishnan,et al. Fitts' law and expanding targets: Experimental studies and designs for user interfaces , 2005, TCHI.

[53] Susumu Harada,et al. The angle mouse: target-agnostic dynamic gain adjustment based on angular deviation , 2009, CHI.

[54] Ben Shneiderman,et al. High Precision Touchscreens: Design Strategies and Comparisons with a Mouse , 1991, Int. J. Man Mach. Stud..

[55] Gregory D. Abowd,et al. Interaction techniques for ambiguity resolution in recognition-based interfaces , 2007, SIGGRAPH '07.

[56] Keith S. Jones,et al. Using Impenetrable Borders in a Graphical Web Browser: Are All Angles Equal? , 2002 .

[57] Shumin Zhai,et al. Beyond Fitts' law: models for trajectory-based HCI tasks , 1997, CHI Extended Abstracts.

[58] Volker Roth,et al. Bezel swipe: conflict-free scrolling and multiple selection on mobile touch screen devices , 2009, CHI.

[59] Scott E. Hudson,et al. Dirty desktops: using a patina of magnetic mouse dust to make common interactor targets easier to select , 2007, UIST.

[60] W. Buxton. Human-Computer Interaction , 1988, Springer Berlin Heidelberg.

[61] Patrick Langdon,et al. Mouse movements of motion-impaired users: a submovement analysis , 2003, ASSETS.

[62] Ravin Balakrishnan,et al. Pointing lenses: facilitating stylus input through visual-and motor-space magnification , 2007, CHI.

[63] Joanna McGrenere,et al. Steadied-bubbles: combining techniques to address pen-based pointing errors for younger and older adults , 2010, CHI.

[64] G.V. Kondraske. Rehabilitation engineering: towards a systematic process , 1988, IEEE Engineering in Medicine and Biology Magazine.

[65] Kori Inkpen Quinn,et al. Walk 'n scroll: a comparison of software-based navigation techniques for different levels of mobility , 2005, Mobile HCI.

[66] Renaud Blanch,et al. Object Pointing: A Complement to Bitmap Pointing in GUIs , 2004, Graphics Interface.

[67] Krzysztof Z. Gajos,et al. Personalized dynamic accessibility , 2012, INTR.

[68] Ben Shneiderman,et al. Universal Usability , 2000, UBIQ.

[69] Maria Gemou,et al. From "Design for All" Towards "Design for One" - A Modular User Interface Approach , 2007, HCI.

[70] F. Bowe. Making computers accessible to disabled people , 1987 .

[71] Tim Paek,et al. Usability guided key-target resizing for soft keyboards , 2010, IUI '10.

[72] Abigail Sellen,et al. A comparison of input devices in element pointing and dragging tasks , 1991, CHI.

[73] Jeff A. Bilmes,et al. Longitudinal study of people learning to use continuous voice-based cursor control , 2009, CHI.

[74] Allison Druin,et al. Differences in pointing task performance between preschool children and adults using mice , 2004, TCHI.

[75] Scott E. Hudson,et al. Automatically detecting pointing performance , 2008, IUI '08.

[76] B Phillips,et al. Predictors of assistive technology abandonment. , 1993, Assistive technology : the official journal of RESNA.

[77] Katsuro Inoue,et al. Button selection for general GUIs using eye and hand together , 2000, AVI '00.

[78] Brenda L. Hazard. Separate But Equal? A Comparison of Content on Library Web Pages and Their Text Versions , 2008 .

[79] Laurent Étienne,et al. Feeling bumps and holes without a haptic interface: the perception of pseudo-haptic textures , 2004, CHI.

[80] James A. Landay,et al. Voice Games: Investigation Into the Use of Non-speech Voice Input for Making Computer Games More Accessible , 2011, IFIP TC13 International Conference on Human-Computer Interaction.

[81] Ravin Balakrishnan,et al. "Beating" Fitts' law: virtual enhancements for pointing facilitation , 2004, Int. J. Hum. Comput. Stud..

[82] Peter Robinson,et al. Investigating haptic assistive interfaces for motion-impaired users: Force-channels and competitive attractive-basins , 2002 .

[83] Keith S. Jones,et al. Acquisition Speed with Targets on the Edge of the Screen: An Application of Fitts' Law to Commonly Used Web Browser Controls , 2001 .

[84] S. Mackenzie,et al. A comparison of input device in elemental pointing and dragging task , 1991, CHI 1991.

[85] Deborah A. Newton,et al. Using Handheld Applications to Improve the Transitions of Students with Autism Spectrum Disorders , 2014 .

[86] Jacob O. Wobbrock,et al. A general-purpose target-aware pointing enhancement using pixel-level analysis of graphical interfaces , 2012, CHI.

[87] Abderrahmane Kheddar,et al. Can Isometric Input Devices Simulate Force Feedback , 2000 .

[88] Jacob O. Wobbrock,et al. Enhanced area cursors: reducing fine pointing demands for people with motor impairments , 2010, UIST.

[89] R. Stefanacci. It's all about access. , 2005, Managed care.

[90] Juan Pablo Hourcade,et al. PointAssist: assisting individuals with motor impairments , 2013, CHI.

[91] Sigurd Mikkelsen,et al. Validity of questionnaire self-reports on computer, mouse and keyboard usage during a four-week period , 2007, Occupational and Environmental Medicine.

[92] Pavel Slavík,et al. Whistling User Interface (U3I) , 2004, User Interfaces for All.

[93] Robert J. K. Jacob,et al. What you look at is what you get: eye movement-based interaction techniques , 1990, CHI '90.

[94] G C Vanderheiden. Universal design and assistive technology in communication and information technologies: alternatives or complements? , 1998, Assistive technology : the official journal of RESNA.

[95] Howell O. Istance,et al. Zooming interfaces!: enhancing the performance of eye controlled pointing devices , 2002, Assets '02.

[96] Krzysztof Z. Gajos,et al. Automatically generating custom user interfaces for users with physical disabilities , 2006, Assets '06.

[97] Olivier Chapuis,et al. Evaluation of pointing performance on screen edges , 2008, AVI '08.

[98] Scott E. Hudson. Adaptive semantic snaping—a technique for semantic feedback at the lexical level , 1990, CHI '90.

[99] Georgios Kouroupetroglou,et al. Indoor Navigation and Location-Based Services for Persons with Motor Limitations , 2014 .

[100] Alan F. Newell,et al. Extra-ordinary human-computer interaction , 1995 .

[101] Andrew Sears,et al. Physical disabilities and computing technologies: an analysis of impairments , 2002 .

[102] G. Vanderheiden,et al. Abstract user interface representations: how well do they support universal access? , 2002, CUU '03.

[103] J. Mitchell,et al. Dynamic versus static menus: an exploratory comparison , 1989, SGCH.

[104] A. D. Fisk,et al. Age-related differences in movement control: adjusting submovement structure to optimize performance. , 1997, The journals of gerontology. Series B, Psychological sciences and social sciences.

[105] Atsuo Murata,et al. Improvement of Pointing Time by Predicting Targets in Pointing With a PC Mouse , 1998, Int. J. Hum. Comput. Interact..

[106] Christian Stary,et al. DESIGN AND EVALUATION OF THE USER INTERFACE OF FOREIGN LANGUAGE MULTIMEDIA SOFTWARE : A COGNITIVE APPROACH , 1998 .

[107] Jacqueline Vischer,et al. Design Intervention: Toward a More Humane Architecture , 1991 .

[108] Simon Harper,et al. Is there design-for-all? , 2007, Universal Access in the Information Society.

[109] Shari Trewin,et al. A study of input device manipulation difficulties , 1996, Assets '96.

[110] Tovi Grossman,et al. The bubble cursor: enhancing target acquisition by dynamic resizing of the cursor's activation area , 2005, CHI.

[111] M. Robertson,et al. Daily computer usage correlated with undergraduate students' musculoskeletal symptoms. , 2007, American journal of industrial medicine.

[112] Carl Gutwin,et al. Improving focus targeting in interactive fisheye views , 2002, CHI.

[113] Sophie Rovner. IT'S ALL ABOUT ACCESS , 2008 .

[114] Melissa Dawe,et al. Desperately seeking simplicity: how young adults with cognitive disabilities and their families adopt assistive technologies , 2006, CHI.

[115] Olivier Chapuis,et al. DynaSpot: speed-dependent area cursor , 2009, CHI.

[116] Jacob O. Wobbrock,et al. WalkType: using accelerometer data to accomodate situational impairments in mobile touch screen text entry , 2012, CHI.

[117] Sri Kurniawan,et al. Non-speech Operated Emulation of Keyboard , 2006 .

[118] Ivan E. Sutherland,et al. Sketchpad a Man-Machine Graphical Communication System , 1899, Outstanding Dissertations in the Computer Sciences.

[119] David M. Lane,et al. A Process for Anticipating and Executing Icon Selection in Graphical User Interfaces , 2005, Int. J. Hum. Comput. Interact..

[120] Markus Löchtefeld,et al. A user-specific machine learning approach for improving touch accuracy on mobile devices , 2012, UIST '12.

[121] Jacob O. Wobbrock. The benefits of physical edges in gesture-making: empirical support for an edge-based unistroke alphabet , 2003, CHI Extended Abstracts.

[122] Andrew Sears,et al. How do people tap when walking? An empirical investigation of nomadic data entry , 2007, Int. J. Hum. Comput. Stud..

[123] I. Scott MacKenzie,et al. Fitts' throughput and the speed-accuracy tradeoff , 2008, CHI.

[124] Katharina Reinecke,et al. Accurate measurements of pointing performance from in situ observations , 2012, CHI.

[125] C. Fichten,et al. What government, agencies, and organizations can do to improve access to computers for postsecondary students with disabilities: recommendations based on Canadian empirical data , 2000, International journal of rehabilitation research. Internationale Zeitschrift fur Rehabilitationsforschung. Revue internationale de recherches de readaptation.

[126] Neff Walker,et al. A comparison of selection time from walking and pull-down menus , 1990, CHI '90.

[127] Jacob O. Wobbrock,et al. From the lab to the world: lessons from extending a pointing technique for real-world use , 2011, CHI Extended Abstracts.

[128] Krzysztof Z. Gajos,et al. Automatically generating personalized user interfaces with Supple , 2010, Artif. Intell..

[129] Shumin Zhai,et al. High precision touch screen interaction , 2003, CHI '03.

[130] William Buxton,et al. Tracking menus , 2003, UIST '03.

[131] Jacob O. Wobbrock,et al. Exploring the design of accessible goal crossing desktop widgets , 2009, CHI Extended Abstracts.

[132] Krzysztof Z. Gajos,et al. Goal Crossing with Mice and Trackballs for People with Motor Impairments: Performance, Submovements, and Design Directions , 2008, TACC.

[133] R A Abrams,et al. Optimality in human motor performance: ideal control of rapid aimed movements. , 1988, Psychological review.

[134] Peter Robinson,et al. Investigating the use of force feedback for motion-impaired users , 2000 .

[135] I. Scott MacKenzie,et al. Eye gaze interaction with expanding targets , 2004, CHI EA '04.

[136] Nava R. Silton. Innovative Technologies to Benefit Children on the Autism Spectrum , 2014 .

[137] Juan Pablo Hourcade,et al. Evaluating one handed thumb tapping on mobile touchscreen devices , 2008, Graphics Interface.

[138] Georgios Kouroupetroglou,et al. Indoor Navigation and Location-Based Services for Persons with Motor Limitations , 2014 .

[139] Brian W. Epps. Comparison of Six Cursor Control Devices Based on Fitts' Law Models , 1986 .

[140] Constantine Stephanidis,et al. # 2001 Kluwer Academic Publishers. Printed in the Netherlands. Adaptive Techniques for Universal Access , 1999 .

[141] Krzysztof Z. Gajos,et al. A comparison of area pointing and goal crossing for people with and without motor impairments , 2007, Assets '07.

[142] Albert M. Cook,et al. Assistive Technologies: Principles and Practice , 1995 .

[143] Joaquim A. Jorge,et al. Towards accessible touch interfaces , 2010, ASSETS '10.

[144] J. J. Odell,et al. Architecture, User Interface, and Enabling Technology in Windows Vista's Speech Systems , 2007, IEEE Transactions on Computers.

[145] Peter Robinson,et al. Using haptic feedback to enhance computer interaction for motion-impaired users , 2000 .

[146] Anind K. Dey,et al. Probabilistic pointing target prediction via inverse optimal control , 2012, IUI '12.

[147] Shari Trewin,et al. Dynamic Modelling of Keyboard Skills: Supporting Users With Motor Disabilities , 1997 .

[148] F. L. Engel,et al. Improved efficiency through I- and E-feedback: a trackball with contextual force feedback , 1994, Int. J. Hum. Comput. Stud..

[149] Patrick Baudisch,et al. Precise selection techniques for multi-touch screens , 2006, CHI.

[150] Shumin Zhai,et al. More than dotting the i's --- foundations for crossing-based interfaces , 2002, CHI.

[151] Jacob O. Wobbrock,et al. Input observer: measuring text entry and pointing performance from naturalistic everyday computer use , 2011, CHI EA '11.

[152] K. Hinckley. Input technologies and techniques , 2002 .

[153] Krzysztof Z. Gajos,et al. Improving the performance of motor-impaired users with automatically-generated, ability-based interfaces , 2008, CHI.

[154] George V. Kondraske,et al. A PC-Based performance measurement laboratory system , 1990 .

[155] Xiao Li,et al. The vocal joystick:: evaluation of voice-based cursor control techniques , 2006, Assets '06.

[156] Robert J. K. Jacob,et al. Eye tracking in human-computer interaction and usability research : Ready to deliver the promises , 2002 .

[157] Andy Cockburn,et al. Improving the Acquisition of Small Targets , 2004 .

[158] Richard Wright,et al. The Vocal Joystick: A Voice-Based Human-Computer Interface for Individuals with Motor Impairments , 2005, HLT.

[159] M F Story,et al. Maximizing usability: the principles of universal design. , 1998, Assistive technology : the official journal of RESNA.

[160] Kyle Montague,et al. Designing for individuals: usable touch-screen interaction through shared user models , 2012, ASSETS '12.

[161] Jack Li,et al. Dynamically adapting GUIs to diverse input devices , 2006, Assets '06.

[162] Brad A. Myers,et al. Trackball text entry for people with motor impairments , 2006, CHI.

[163] David E. Meyer,et al. Speed—Accuracy Tradeoffs in Aimed Movements: Toward a Theory of Rapid Voluntary Action , 2018, Attention and Performance XIII.

[164] Jacob O. Wobbrock,et al. The effects of task dimensionality, endpoint deviation, throughput calculation, and experiment design on pointing measures and models , 2011, CHI.

[165] Joanna McGrenere,et al. A comparison of static, adaptive, and adaptable menus , 2004, CHI.

[166] E. R. Crossman,et al. Feedback Control of Hand-Movement and Fitts' Law , 1983, The Quarterly journal of experimental psychology. A, Human experimental psychology.

[167] Peter Robinson,et al. Towards a practical inclusive design approach , 2000, CUU '00.

[168] Christopher M. Schlick,et al. Evaluating swabbing: a touchscreen input method for elderly users with tremor , 2011, CHI.

[169] Steven K. Feiner,et al. An integrated system for creating and presenting complex computer-based documents , 1981, SIGGRAPH '81.

[170] Douglas C. Engelbart,et al. A conceptual framework for the augmentation of man's intellect , 1988 .

[171] Juan Pablo Hourcade,et al. PointAssist: helping four year olds point with ease , 2008, IDC.

[172] I. Scott MacKenzie,et al. Effects of output display and control - display gain on human performance in interactive systems , 1994, Behav. Inf. Technol..

[173] D V Keyson,et al. Dynamic cursor gain and tactual feedback in the capture of cursor movements. , 1997, Ergonomics.

[174] Yosry Morsi,et al. Optimizing Assistive Technologies for Aging Populations , 2015 .

[175] Jacob O. Wobbrock,et al. Getting off the treadmill: evaluating walking user interfaces for mobile devices in public spaces , 2008, Mobile HCI.

[176] G. Frank,et al. The able self: adaptive patterns and choices in independent living for a person with cerebral palsy. , 1991, The American journal of occupational therapy : official publication of the American Occupational Therapy Association.

[177] Heidi Horstmann Koester,et al. Toward automatic adjustment of keyboard settings for people with physical impairments , 2007, Disability and rehabilitation. Assistive technology.

[178] Shumin Zhai,et al. Manual and gaze input cascaded (MAGIC) pointing , 1999, CHI '99.

[179] Patrick Baudisch,et al. Hover widgets: using the tracking state to extend the capabilities of pen-operated devices , 2006, CHI.

[180] Brad A. Myers,et al. Text entry from power wheelchairs: edgewrite for joysticks and touchpads , 2004, Assets '04.

[181] Paul Gnanayutham,et al. Assistive technologies for brain-injured gamers , 2013, ITCS 2013.

[182] Simeon Keates,et al. Towards a generic approach for designing for all users , 1999 .

[183] Renaud Blanch,et al. Semantic pointing: improving target acquisition with control-display ratio adaptation , 2004, CHI.

[184] R. Rosenfeld. Nature , 2009, Otolaryngology--head and neck surgery : official journal of American Academy of Otolaryngology-Head and Neck Surgery.

[185] C. Riviere,et al. Effects of age and disability on tracking tasks with a computer mouse: accuracy and linearity. , 1996, Journal of rehabilitation research and development.

[186] Chris Lankford. Effective eye-gaze input into Windows , 2000, ETRA.

[187] Krzysztof Z. Gajos,et al. Ability-Based Design: Concept, Principles and Examples , 2011, TACC.

[188] Shumin Zhai,et al. Characterizing computer input with Fitts' law parameters-the information and non-information aspects of pointing , 2004, Int. J. Hum. Comput. Stud..

[189] Joaquim A. Jorge,et al. Assessing mobile touch interfaces for tetraplegics , 2010, Mobile HCI.

[190] Peter Robinson,et al. User Models and User Physical Capability , 2002, User Modeling and User-Adapted Interaction.

[191] Constantine Stephanidis,et al. Universal access in the information society , 1999, HCI.

[192] Alan F. Newell,et al. Focussing on Extra-Ordinary Users , 2007, HCI.

[193] I. Scott MacKenzie,et al. Performance differences in the fingers, wrist, and forearm in computer input control , 1997, CHI.

[194] Patrick Langdon,et al. Multiple haptic targets for motion-impaired computer users , 2003, CHI '03.

[195] Takeo Igarashi,et al. Voice as sound: using non-verbal voice input for interactive control , 2001, UIST '01.

[196] I.,et al. Fitts' Law as a Research and Design Tool in Human-Computer Interaction , 1992, Hum. Comput. Interact..