Biomedical Engineering Reference
In-Depth Information
24. Cutting JE, Vishton PM (1995) Perceiving layout: the integration, relative dominance, and
contextual use of different information about depth. In: Epstein W, Rogers S (eds) Handbook
of perception and cognition: Vol. 5: perception of space and motion. Academic Press, New
Yo r k
25. Darken RP, Cockayne WR, Carmein D (1997) The omni-directional treadmill: a locomotion
device for virtual worlds. In: Proceedings of ACM symposium on user interface software and
technology, pp 213-221
26. Ernst MO, Banks MS (2002) Humans integrate visual and haptic information in a statistically
optimal fashion. Nature 415:429-433
27. Fortenbaugh FC, Hicks JC, Turano KA (2008) The effect of peripheral visual field loss on
representations of space: evidence for distortion and adaptation. Investig Ophthalmol Visual
Sci 49:2765-2772
28. Frenz H, Bremmer F, Lappe M (2003) Discrimination of travel distance from 'situated' optic
flow. Vis Res 43:2173-2183
29. Gallistel CR (1990) The organization of learning. MIT, Cambridge
30. Gibson JJ (1958) Visually controlled locomotion and visual orientation in animals. Br J
Psychol 49:182-194
31. Gibson JJ (1979) The ecological approach to visual perception. Houghton Mifflin, Boston
32. Glasauer S, AmorimMA, Vitte E, Berthoz A (1994) Goal directed linear locomotion in normal
and labyrinthine-defective subjects. Exp Brain Res 98:323-335
33. Goldin SE, Thorndyke PW (1982) Simulating navigation for spatial knowledge acquisition.
Hum Factors 24:457-471
34. Golledge R, Klatzky R, Loomis J (1996) Cognitive mapping and wayfinding by adults without
vision. In: Portugali J (ed) The construction of cognitive maps. Kluwer, The Netherlands, pp
215-246
35. Grant SC, Magee LE (1998) Contributions of proprioception to navigation in virtual environ-
ments. Hum Factors 40:489-497
36. Guidice NA, Bakdash JZ, Legge GE (2007) Wayfinding with words: spatial learning and
navigation using dynamically updated verbal descriptions. Psychol Res 71:347-358
37. Harm DL (2002) Motion sickness neurophysiology, physiological correlates, and treatment.
In: Stanney KM (ed) Handbook of virtual environments: design, implementation, and appli-
cations. Erlbaum, Mahwah, pp 637-661
38. Harris LR, Jenkin M, Zikovitz DC (2000) Visual and non-visual cues in the perception of
linear self-motion. Exp Brain Res 135:12-21
39. Hay JC, Pick HL Jr (1965) Visual capture produced by prism spectacles. Psychon Sci 2:215-
216
40. Heilig M (1992) El cine de futro: the cinema of the future. Presence Teleoperators Virtual
Environ 1:279-294 (Original work published 1955)
41. Heft H (1996) The ecological approach to navigation: AGibsonian perspective. In: Portugali J
(ed) The construction of cognitive maps. Kluwer Academic Publishers, Dordrect, pp 105-132
42. Heft H (1997) The relevance of Gibson's ecological approach for environment-behavior stud-
ies. In: Moore GT, Marans RW (eds) Advances in environment, behavior, and design, vol 4.
Plenum, New York, pp 71-108
43. Hettinger LJ (2002) Illusory self-motion in virtual environments. In: Stanney KM (ed) Hand-
book of Virtual Environments. Erlbaum, New Jersey, pp 471-492
44. Hilsendeger A, Brandauer S, Tolksdorf J, Fröhlich C (2009) Navigation in virtual reality with
the wii balanceboard
TM
. In: GI-Workshop Virtuelle und Erweiterte Realität, ACM
45. Hodgson E, Bachmann E, Waller D (2011) Redirected walking to explore virtual environ-
ments: assessing the potential for spatial interference. ACM Trans Appl Percept 8, Article
22
46. Hollerbach JM (2002) Locomotion interfaces. In: Stanney KM (ed) Handbook of virtual
environments: design, implementation, and applications. Erlbaum, New Jersey, pp 239-254
47. von Holst E, Mittlestaedt H (1950) Das reafferenz princip: (Wedlselwirkungen zwischen
Zentrainervensystem und Peripherie.) Die Naturwissenschften, 37, 464-476. Translated in:
