Biomedical Engineering Reference
In-Depth Information
39. Yu, Z., & Bajaj, C. (2004). A fast and adaptive method for image contrast enhancement.
Proceedings of 2004 IEEE International Conference on Image Processing (ICIP'04).
Vo l .
,
2
,
1001-1004.
40. Bajaj, C., & Goswami, S. (2009). Modeling cardiovascular anatomy from patient-specific
imaging. In J. M. R. S. Tavares & R. M. N. Jorge (Eds.),
Advances in computational vision and
medical image processing
(pp. 1-28). Netherlands: Springer.
41. Johnson, C. R., & Sanderson, A. R. (2003). A next step: Visualizing errors and uncertainty.
IEEE Computer Graphics and Applications
,
23
(5), 6-10.
42. Westerhoff, H. (2012). White paper: VPH, Molecular Systems Biology (MSB), and their
43. O'Donoghue, S. I., et al. (2004). The SRS 3D module: Integrating structures, sequences and
features.
Bioinformatics
,
20
(15), 2476-2478.
44. Rhead, B., et al. (2010). The UCSC Genome Browser database: Update 2010.
Nucleic Acids
Research
,
38
(1), D613-D619.
45. Gehlenborg, N., et al. (2010). Visualization of omics data for systems biology.
Nature Methods
,
7
, S56-S68.
46. McFarlane, N., et al. (2012). Report on best practice, Multiscale Spatio-temporal Visualisation
Project.
47. Hansen, C. D., & Johnson, C. R. (2005).
Visualization handbook
. San Diego: Academic Press.
48. Luebke, D., et al. (2002).
Level of detail for 3D graphics
. San Francisco: Morgan Kaufmann.
49. Staadt, O. G., et al. (2007). Interactive processing and visualization of image data for biomedical
and life science applications.
BMC Cell Biology
,
8
(1), S10.
50. Biodigital Human (2012). Biodigital Human,
https://www.biodigitalhuman.com/
51. Zygote Body (2012). Zygote Body
http://www.zygotebody.com/
52. Hunter, P., et al. (2010). A vision and strategy for the virtual physiological human in 2010
and beyond.
Philosophical Transactions of The Royal Society: A Mathematical Physical and
Engineering Sciences
,
368
(1920), 2595-2614.
53. Testi, D., et al. (2011). Interactive visualization of multiscale biomedical data: An integrated
approach. Proceedings of the 1st IEEE Symposium on Biological Data Visualization (BioVis),
pp. 3-4.
54. Visualization Toolkit (2012). Visualization Toolkit,
http://www.vtk.org/
55. Caban, J. J., et al. (2007). Rapid development of medical imaging tools with open-source
libraries.
Journal of Digital Imaging
,
20
(Suppl 1), 83-93.
56. Leardini, A., et al. (2005). Advanced multimodal visualisation of clinical gait and fluoroscopy
analyses in the assessment of total knee replacement.
Computer Methods and Programs in
Biomedicine
,
79
(3), 227-240.
57. Karray, F., et al. (2008). Human-Computer Interaction: Overview on state of the art.
Interna-
tional Journal on Smart Sensing and Intelligent Systems
,
1
(1), 137-159.
58. McNamara, N., & Kirakowski, J. (2006). Functionality, usability, and user experience: Three
areas of concern.
Interactions.
,
13
(6), 26-28.
59. St Amant, R., & Riedl, M. O. (2001). A perception/action substrate for cognitive modeling in
HCI.
International Journal of Human-Computer Studies
,
55
(1), 15-39.
60. Cutrell, E., & Tan, D. (2008). BCI for passive input in HCI. Proceedings of CHI.
61. Picard, R. W. (1999). Affective computing for HCI. Proceedings of HCI International (8th
International Conference on Human-Computer Interaction): Ergonomics and User Interfaces,
pp. 829-833.
62. Myers, B. A. (1998). A brief history of human-computer interaction technology.
Interactions
,
5
(2), 44-54.
63. Sutherland, I. E. (1968). A head-mounted three dimensional display. Proceedings of Fall Joint
Computer Conf., pp. 757-764, Washington: Thompson Books.
64. Friedewald, M., & Raabe, O. (2011). Ubiquitous computing: An overview of technology
impacts.
Telematics Informatics
,
28
(2), 55-65.
65. Maybury, M. (1998). Intelligent user interfaces: an introduction. Proceedings of the 4th Inter-
national Conference on Intelligent User interfaces, pp. 3-4.
