Scope: This bibliography contains references to algorithms for optical flow estimation.

Support level: Medium - 1998. This bibliography is medium well supported till the year 1998, i.e. I have collected quite a few references but the collection is not complete.

Publication types: Journal articles only. To keep effort low and quality high, I have confined this bibliography to journal articles only. Red titles indicate survey articles.

Online papers: An 'A' or 'P' (or 'T' for text only) after a reference link indicates that it leads to an abstract or full paper, respectively. Upper case letters refer to online documents provided by a journal, which might be accessible only to subscribers (indicated by a '?'). Lower case letters refer to online documents provided by an author. Also the links at the end of the references are differentiated in this way by upper and lower case letters at the beginning of the words 'abstract.html' etc. and by a '?', if the corresponding document is only accessible to subscribers. The site location is indicated by a preceding .uk, .com, etc.

BibTeX: A bibtex file for the journal article references is also available (compressed and uncompressed).

Search engine: This bibliography is also included in The Karlsruhe Collection of Computer Science Bibliographies. You can use its search engine to search through this bibliography.

Feedback: Please feel free to send me any kind of feedback about this bibliography.

Related Resources

• Bibliography Motion Processing (a superset of this bibliography)
• Bibliography Depth from Stereo
• Bibliography Image Motion Analysis
• Bibliography Segmentation from Motion
• Bibliography Visual Tracking
• Bibliography Video Coding

References

1. AccaDNataGius98.

Accame, M., De Natale, F.G.B., and Giusto, D.D. (February 1998).
High Performance Hierarchical Block-based Motion Estimation for Real-Time Video Coding
Real-Time Imaging, 4(1):67-79.
(.com-Abstract, .com-Paper?)

2. Adel91.

Adelson, E.H. (1991).
Mechanisms for Motion Perception
Optics and Photonics News, 2(8):24-30.

3. AdelBerg85.

Adelson, E.H. and Bergen, J.R. (1985).
Spatiotemporal Energy Models for the Perception of Motion
J. of the Optical Society of America A, 2(2):284-299.

4. AggaDuda75.

Aggarwal, J.K. and Duda, R.O. (1975).
Computer Analysis of Moving Polygonal Images
IEEE Transactions on Computers, 24(10):966-976.

5. AggaNand88.

Aggarwal, J.K. and Nandhakumar, N. (1988).
On the computation of motion from sequences of images - A review
Proceedings of the IEEE, 76(8):917-935.

6. Aisb89.

Aisbett, J. (May 1989).
Optical flow with an intensity-weighted smoothing
IEEE Transactions on Pattern Analysis and Machine Intelligence, 11(5):512-522.

7. AltuTeka97a.

Altunbasak, Y. and Tekalp, A.M. (September 1997 a).
Closed-Form Connectivity-Preserving Solutions for Motion Compensation Using 2-D Meshes
IEEE Transactions on Image Processing, 6(9):1255.
(-paper, .edu-paper.ps)

8. Anan89

Anandan, P. (1989).
A Computational Framework and an Algorithm for the Measurement of Visual Motion
International Journal of Computer Vision, 2(3):283-310.

9. AncoPogg95.

Ancona, N. and Poggio, T. (1995).
Optical flow from 1-D correlation: application to a simple time-to-crash detector
International Journal of Computer Vision, 14(2):131-146.

10. BainLane96

Bainbridge-Smith, A. and Lane, R.G. (1996).
Measuring confidence in optical flow estimation
Electronics Letters, 32(10):882-884.

11. BainLane97.

Bainbridge-Smith, A. and Lane, R.G. (1. January 1997).
Determining optical flow using a differential method
Image and Vision Computing, 15(1):11-22.

12. BarnThom80.

Barnard, S.T. and Thompson, W.B. (1980).
Disparity Analysis of Images
IEEE Transactions on Pattern Analysis and Machine Intelligence, 2(4):333-340.

13. Barn92b.

Barniv, Y. (1992 b).
Error analysis of combined optical-flow and stereo passive ranging
IEEE Transactions on Aerospace and Electronic Systems, 28(4):978-989.

14. BarrFleeBeau94

Barron, J.L., Fleet, D.J., and Beauchemin, S.S. (1994).
Performance of Optical Flow Techniques
International Journal of Computer Vision, 12(1):43-77.

15. BarrLipt94.

Barron, J.L. and Liptay, A. (1994).
Optical flow to measure minute increments in plant growth
Bioimaging, 2(1):57-61.

16. BartCappColo+93.

Bartolini, F., Cappellini, V., Colombo, C., and Mecocci, A. (1993).
Multiwindow least-squares approach to the estimation of optical flow with discontinuities
Optical Engineering, 32(6):1250-1256.

17. BartCappMeco92.

Bartolini, F., Cappellini, V., and Mecocci, A. (1992).
An optical flow algorithm preserving motion boundaries and its parallel implementation
European Transactions on Telecommunications and Related Technologies, 3(6):583-591.

18. BartPiva97.

Bartolini, F. and Piva, A. (31. July 1997).
Median based relaxation of smoothness constraints in optic flow computation
Pattern Recognition Letters, 18(7):649-655.

19. BattAmalKoch91

Battiti, R., Amaldi, E., and Koch, C. (1991).
Computing optical flow across multiple scales: an adaptive coarse-to-fine strategy
International Journal of Computer Vision, 6(2):133-145.

20. BeauBarr95.

Beauchemin, S.S. and Barron, J.L. (September 1995).
The Computation of Optical Flow
ACM Computing Surveys, 27(3):433-467.
(.org-abstract, .org-paper)

21. BenDBimbNesi93.

Ben-Tzvi, D., Del Bimbo, A., and Nesi, P. (1993).
Optical flow from constraint lines parametrization
Pattern Recognition, 26(10):1549-1561.

22. BergAdel87.

Bergen, J.R. and Adelson, E.H. (1987).
Hierarchical, Computationally Efficient Motion Estimation Algorithm
J. of the Optical Society of America A, 4:35.

23. BergBurtHing+92

Bergen, J.R., Burt, P.J., Hingorani, R., and Peleg, S. (1992).
A three-frame algorithm for estimating two-component image motion
IEEE Transactions on Pattern Analysis and Machine Intelligence, 14(9):886-895.
(.il-paper.pdf)

24. BergCarl91.

Bergholm, F. and Carlsson, S. (March 1991).
A theory of optical flow
Computer Vision, Graphics and Image Processing: Image Understanding, 53(2):171-188.

25. BeucBarr95.

Beuchemin, S.S. and Barron, J.L. (September 1995).
The computation of optical flow
ACM Computing Surveys, 27(3):433-467.
(.org-abstract, .org-paper)

26. BierThom86.

Bierling, M. and Thoma, R. (1986).
Motion compensating field interpolation using a hierarchically structured displacement estimator
Signal Processing, 11(4):387-404.

27. BiguGranWikl91.

Bigün, J., Granlund, G.H., and Wiklund, J. (August 1991).
Multidimensional orientation estimation with applications to texture analysis and optical flow
IEEE Transactions on Pattern Analysis and Machine Intelligence, 13(8):775-790.

28. BlacAnan96

Black, M.J. and Anandan, P. (January 1996).
The robust estimation of multiple motions: Parametric and piecewise-smooth flow fields
Computer Vision and Image Understanding, 63(1):75-104.

29. BlacJeps96

Black, M.J. and Jepson, A.D. (October 1996).
Estimating optical flow in segmented images using variable-order parametric models with local deformations
IEEE Transactions on Pattern Analysis and Machine Intelligence, 18(10):972-986.

30. Bout89.

Bouthemy, P. (May 1989).
Maximum Likelihood Framework for Determining Moving Edges
IEEE Transactions on Pattern Analysis and Machine Intelligence, 11(5):499-511.

31. BozdTekaOnur94a.

Bozdagi, G., Tekalp, A.M., and Onural, L. (June 1994 a).
3-D Motion Estimation and Wireframe Model Adaptation Including Photometric Effects for Model-Based Coding of Facial Image Sequences
IEEE Transactions on Circuits and Systems for Video Technology, 4(3):246-257.

32. BozdTekaOnur94b.

Bozdagi, G., Tekalp, A.M., and Onural, L. (September 1994 b).
An Improvement to MBASIC Algorithm for 3-D Motion and Depth Estimation
IEEE Transactions on Image Processing, 3(5):711-717.

33. Bran97.

Brandt, J.W. (1997).
Improved accuracy in gradient-based optical flow estimation
International Journal of Computer Vision, 25(1):5-22.

34. Broc90.

Brockett, R.W. (1990).
Gramians, generalized inverses, and the least-squares approximation of optical flow
Journal of Visual Communication and Image Representation, 1(1):3-11.

35. BroiChel89.

Broida, T.J. and Chellappa, R. (1989).
Uniqueness and Performance Measure Results for 3-D Motion Estimation from a Monocular Sequence of Noisy Images
J. of the Optical Society of America, 6:879-889.

36. BultLittPogg89.

Bülthoff, H.H., Little, J.J., and Poggio, T. (February 1989).
A parallel algorithm for real-time computation of optical flow
Nature, 337(6207):549-553.

37. BurnRogeRuck+94

Burns, T.J., Rogers, S.K., Ruck, D.W., and Oxley, M.E. (July 1994).
Discrete, spatiotemporal, wavelet multiresolution analysis method for computing optical flow
Optical Engineering, 33(7):2236-2247.

38. BuxtBuxt83b.

Buxton, B.F. and Buxton, H. (1983 b).
Low-level edge detection for the extraction of optical flow data and passive ranging
GEC Journal of Research, 1(3):184-187.

39. BuxtBuxt84:

Buxton, B.F. and Buxton, H. (1984).
Computation of Optic Flow from the Motion of Edge Features in Image Sequences
Image and Vision Computing, 2(2):59-76.

40. BuxtBuxtStep84.

Buxton, B.F., Buxton, H., and Stephenson, B.K. (1984).
Parallel computations of optic flow in early image processing
IEE Proceedings F, 131(6):593-602.

41. CaffRocc76.

Cafforo, C. and Rocca, F. (1976).
Methods for Measuring Small Displacements of Television Images
IEEE Transactions on Information Theory, 22(5):573-579.

42. CampVerr92

Campani, M. and Verri, A. (1992).
Motion analysis from first-order properties of optical flow
Computer Vision, Graphics and Image Processing: Image Understanding, 56(1):90-107.

43. Camu97.

Camus, T. (April 1997).
Real-time quantized optical flow
Real-Time Imaging, 3(2):71-86.

44. CastMurrScot+88:

Castelow, D.A., Murray, D.W., Scott, G.L., and Buxton, B.F. (1988).
Matching Canny edgels to compute the principal components of optic flow
Image and Vision Computing, 6(2):129-136.

45. ChanSiu98.

Chan, Y.L. and Siu, W.C. (June 1998).
On Block Motion Estimation Using a Novel Search Strategy for an Improved Adaptive Pixel Decimation
Journal of Visual Communication and Image Representation, 9(2):139-154.

46. ChanTekaSeza97

Chang, M.M., Tekalp, A.M., and Sezan, M.I. (1997).
Simultaneous motion estimation and segmentation
IEEE Transactions on Image Processing, 6(9):1326-1333.

47. ChauMehr94.

Chaudhury, K. and Mehrotra, R. (1994).
Optical flow estimation using smoothness of intensity trajectories
Computer Vision, Graphics and Image Processing: Image Understanding, 60(2):230-244.

48. ChauMehr95.

Chaudhury, K. and Mehrotra, R. (1995).
A trajectory-based computational model for optical flow estimation
IEEE Transactions on Robotics and Automation, 11(5):733-741.

49. Chha97.

Chhabra, A.K. (April 1997).
Real-time computation of optical flow along contours of significant intensity change
Real-Time Imaging, 3(2):87-99.

50. ChhaGrog94.

Chhabra, A.K. and Grogan, T.A. (November 1994).
On Poisson solvers and semi-direct methods for computing area based optical flow
IEEE Transactions on Pattern Analysis and Machine Intelligence, 16(11):1133-1138.

51. ChibOzaw92.

Chiba, M. and Ozawa, S. (1992).
Detection of optical flow from a noisy image
Systems and Computers in Japan, 23(8):97-105.

52. ChihCaim97.

Chih-Ho, Y. and Caimi, F.M. (1997).
Determination of horizontal motion through optical flow computations
Journal of Computer Science and Technology, 12(2):133-144.

53. ChinKarlWill94.

Chin, T.M., Karl, W.C., and Willsky, A.S. (1994).
Probabilistic and sequential computation of optical flow using temporal coherence
IEEE Transactions on Image Processing, 3(6):773-788.

54. ChouHang97.

Chou, Y.M. and Hang, H.M. (March 1997).
A New Motion Estimation Method Using Frequency Components
Journal of Visual Communication and Image Representation, 8(1):83-96.

55. ColoDBimbSant94.

Colombo, C., Del Bimbo, A., and Santini, S. (1. April 1994).
Optical flow through relaxation in the velocity space
Pattern Recognition Letters, 15(4):373-382.

56. ColoDBimbSant95.

Colombo, C., Del Bimbo, A., and Santini, S. (1995).
Optical flow by nonlinear relaxation
Pattern Recognition, 28(7):977-988.

57. ConvStelBran+97.

Convertino, G., Stella, E., Branca, A., and Distante, A. (1997).
Optic flow estimation by a Hopfield neural network using geometrical constraints
Machine Vision and Applications, 10(3):114-122.
(.com-Abstract, .com-Paper.pdf?)

58. CornDrou93.

Cornilleau-Peres, V. and Droulez, J. (September 1993).
Velocity-Based Correspondence in Stereokinetic Images
Computer Vision, Graphics and Image Processing: Image Understanding, 58(2):137-146.

59. DMichTorrUras93.

De Micheli, E., Torre, V., and Uras, S. (1993).
The accuracy of the computation of optical flow and of the recovery of motion parameters
IEEE Transactions on Pattern Analysis and Machine Intelligence, 15:434-447.

60. DBimbNesiSanz95.

Del Bimbo, A., Nesi, P., and Sanz, J.L.C. (1995).
Analysis of optical flow constraints
IEEE Transactions on Image Processing, 4(4):460-469.

61. DBimbNesiSanz96

Del Bimbo, A., Nesi, P., and Sanz, J.L.C. (1996).
Optical flow computation using extended constraints
IEEE Transactions on Image Processing, 5(5):720-739.

62. DennPrin94.

Denney, T.S.J. and Prince, J.L. (March 1994).
Optimal brightness functions for optical flow estimation of deformable motion
IEEE Transactions on Image Processing, 3(2):178-191.

63. DennPrin95.

Denney, T.S.J. and Prince, J.L. (1995).
A frequency domain performance analysis of Horn and Schunck's optical flow algorithm for deformable motion
IEEE Transactions on Image Processing, 4(9):1324-1327.

64. DiasAraúPare+97.

Dias, J., Araújo, H., Paredes, C., and Batista, J. (June 1997).
Optical normal flow estimation on log-polar images. A solution for real-time binocular vision
Real-Time Imaging, 3(3):213-228.

65. Dieh91.

Diehl, N. (1991).
Object-oriented motion estimation and segmentation in image sequences
Signal Processing: Image Communication, 3(1):23-56.

66. DresNage82.

Dreschler, L. and Nagel, H.H. (1982).
Volumetric Model and 3D Trajectory of a Moving Car Derived from Monocular TV Frame Sequences of a Street Scene
Computer Vision, Graphics and Image Processing, 20:199-228.

67. DrieBoroBiem91.

Driessen, J.N., Boroczky, L., and Biemond, J. (1991).
Pel-recursive motion field estimation from image sequences
Journal of Visual Communication and Image Representation, 2(3):259-280.

68. DuncChou92

Duncan, J.H. and Chou, T.C. (1992).
On the Detection of Motion and the Computation of Optical Flow
IEEE Transactions on Pattern Analysis and Machine Intelligence, 14(3):346-352.

69. EmerBergAdel92.

Emerson, R.C., Bergen, J.R., and Adelson, E.H. (1992).
Directionally Selective Complex Cells and the Computation of Motion Energy in Cat Visual Cortex
Vision Research, 32:203-218.

70. EndlWolfHall+71.

Endlich, R.M., Wolf, D.E., Hall, D.J., and Brain, A.E. (1971).
Use of a pattern recognition technique for determining cloud motions from a sequence of satellite photographs
J. Appl. Met., 10:105-117.

71. Enke88.

Enkelmann, W. (1988).
Investigations of multigrid algorithms for the estimation of optical flow fields in image sequences
Computer Vision, Graphics and Image Processing, 43(2):150-177.

72. FaugMayb90.

Faugeras, O.D. and Maybank, S.J. (1990).
Motion from point matches: Multiplicity of solution
International Journal of Computer Vision, 4(3):225-246.

73. FennThom79

Fennema, C.L. and Thompson, W.B. (1979).
Velocity determination in scenes containing several moving objects
Computer Graphics and Image Processing, 9:301-315.

74. FleeJeps90

Fleet, D.J. and Jepson, A.D. (1990).
Computation of Component Image Velocity from Local Phase Information
International Journal of Computer Vision, 5(1):77-104.

75. FleeLang95.

Fleet, D.J. and Langley, K. (January 1995).
Recursive filters for optical flow
IEEE Transactions on Pattern Analysis and Machine Intelligence, 17(1):61-67.

76. FreeAdelHeeg91.

Freeman, W.T., Adelson, E.H., and Heeger, D.J. (1991).
Motion Without Movement
ACM Computer Graphics, 25(4):27-30.

77. GhosMehr97

Ghosal, S. and Mehrotra, R. (1997).
Robust optical flow estimation using semi-invariant local features
Pattern Recognition, 30(2):229-237.

78. GhosVane96.

Ghosal, S. and Vanek, P. (February 1996).
A fast scalable algorithm for discontinuous optical flow estimation
IEEE Transactions on Pattern Analysis and Machine Intelligence, 18(2):181-194.

79. GiusVern89.

Giusto, D.D. and Vernazza, G. (1989).
Optical Flow Calculation From Feature Space Analysis Through an Automatic Segmentation Process
Signal Processing, 16:41-51.

80. HaddKuo93.

Haddadi, N. and Kuo, C.C.J. (1993).
Computation of dense optical flow with a parametric smoothness model
Journal of Visual Communication and Image Representation, 4(4):309-323.

81. HaynJain83

Haynes, S.M. and Jain, R.C. (1983).
Detection of Moving Edges
Computer Vision, Graphics and Image Processing, 21(3):345-367.

82. Heeg87

Heeger, D.J. (1987).
Model for the Extraction of Image Flow
J. of the Optical Society of America, 4(8):1455-1471.
(very similar to Heeg88)

83. Heeg88

Heeger, D.J. (1988).
Optical Flow Using Spatio-Temporal Filters
International Journal of Computer Vision, 1(4):279-302.
(very similar to Heeg87)

84. HeitBout93

Heitz, F. and Bouthemy, P. (December 1993).
Multimodal Motion Estimation of Discontinuous Optical Flow Using Markov Random Fields
IEEE Transactions on Pattern Analysis and Machine Intelligence, 15(12):1217-1232.

85. Hild84a.

Hildreth, E.C. (1. August 1984 a).
Computations Underlying the Measurement of Visual Motion
Artificial Intelligence, 23(3):309-354.

86. Hild84b.

Hildreth, E.C. (1984 b).
The Computation of the Velocity Field
Proceedings of the Royal Society of London, Series B, 221:189-220.

87. HornSchu81

Horn, B.K.P. and Schunck, B.G. (1. August 1981).
Determining optical flow
Artificial Intelligence, 17(1-3):185-203.
(see HornSchu93 for a retrospective)
(.edu-paper.ps)

88. HornSchu93

Horn, B.K.P. and Schunck, B.G. (1. January 1993).
'Determining optical flow': a retrospective
Artificial Intelligence, 59(1-2):81-87.
(a retrospective of HornSchu81)

89. Hött90.

Hötter, M. (1990).
Object-Oriented Analysis Synthesis Coding Based on Moving Two-Dimensional Objects
Signal Processing: Image Communication, 2:409-428.

90. HsuNageReke84.

Hsu, Y.Z., Nagel, H.H., and Rekers, G. (1984).
New Likelihood Test Methods for Change Detection in Image Sequences
Computer Vision, Graphics and Image Processing, 26:73-106.

91. HuanLee89.

Huang, T.S. and Lee, C.B. (1989).
Motion and Structure from Orthographic Projections
IEEE Transactions on Pattern Analysis and Machine Intelligence, 11:536-540.

92. HuanNetr94.

Huang, T.S. and Netravali, A.N. (1994).
Motion and Structure from Feature Correspondences: A Review
Proceedings of the IEEE, 82(2):252-268.

93. HuntJaya87.

Huntsberger, T.L. and Jayaramamurthy, S.N. (1987).
Determination of the optic flow field using the spatiotemporal deformation of region properties
Pattern Recognition Letters, 6(3):169-177.

94. HuntJaya88.

Huntsberger, T.L. and Jayaramamurthy, S.N. (1988).
Determination of the optic flow field in the presence of occlusion
Pattern Recognition Letters, 8(5):325-333.

95. HwanLee93a

Hwang, S.H. and Lee, S.U. (April 1993 a).
A hierarchical optical flow estimation algorithm based on the inter-level motion smoothness constraint
Pattern Recognition, 26(6):939-952.

96. HwanLee93b.

Hwang, S.H. and Lee, S.U. (1993 b).
An optical flow estimation algorithm using the spatio-temporal hierarchical structure
IEICE Transactions on Information and Systems (D), E76-D(4):507-514.

97. IsaoChen94.

Isao, T.R. and Chen, V. (10. June 1994).
A neural scheme for optical flow computation based on Gabor filters and generalized gradient method
Neurocomputing, 6(3):305-325.

98. JacoWech87.

Jacobson, L. and Wechsler, H. (April 1987).
Derivation of optical flow using a spatiotemporal-frequency approach
Computer Vision, Graphics and Image Processing, 38(1):29-65.

99. JacoChieSela80.

Jacobus, C.J., Chien, R.T., and Selander, J.M. (1980).
Motion detection and analysis by matching graphs of intermediate-level primitives
IEEE Transactions on Pattern Analysis and Machine Intelligence, 2(6):495-510.

100. Jain81a.

Jain, R.C. (1981 a).
Extraction of Motion Information from Peripheral Processes
IEEE Transactions on Pattern Analysis and Machine Intelligence, 3(5):489-503.

101. Jasi91.

Jasinschi, R.S. (1991).
The properties of space-time sampling and the extraction of the optical flow: the effects of motion uncertainty
Journal of Visual Communication and Image Representation, 2(3):222-229.

102. JenkTsot86.

Jenkin, M. and Tsotsos, J.K. (1986).
Applying temporal constraints to the dynamic stereo problem
Computer Vision, Graphics and Image Processing, 24:16-32.

103. Joha73.

Johansson, G. (1973).
Visual Perception of Biological Motion and a Model for its Analysis
Perception and Psychophysics, 14:201-211.

104. KagoMiik90.

Kago, K. and Miike, H. (1990).
Optical flow analysis based on spatio-temporal correlation of dynamic image
Systems and Computers in Japan, 21(4):96-108.

105. KambGold94.

Kambhamettu, C. and Goldgof, D.B. (1994).
Curvature-Based Approach to Point Correspondence Recovery in Conformal Nonrigid Motion
Computer Vision, Graphics and Image Processing: Image Understanding, 60(1):26-43.

106. Kana84.

Kanatani, K. (1. July 1984).
Detection of Surface Orientation and Motion from Texture by a Stereo-Logical Technique
Artificial Intelligence, 23(2):213-237.

107. Kana85a.

Kanatani, K. (1985 a).
Tracing Planar Surface Motion frome a Projection Without Knowing the Correspondence
Computer Vision, Graphics and Image Processing, 29(1):1-12.

108. Kana85b.

Kanatani, K. (1985 b).
Detecting the Motion of a Planar Surface by Line and Surface Integrals
Computer Vision, Graphics and Image Processing, 29(1):13-22.

109. Kana88.

Kanatani, K. (March 1988).
Transformation of optical flow by camera rotation
IEEE Transactions on Pattern Analysis and Machine Intelligence, 10(2):131-143.

110. KappTPasKoen+96a.

Kappers, A.M.L., te Pas, S.F., Koenderink, J.J., and van Doorn, A.J (1996 a).
Simulating the detection of first-order optical flow components
Vision Research, 36(21):3539-3547.

111. KearThomBole87

Kearney, J.K., Thompson, W.B., and Boley, D.L. (March 1987).
Optical Flow Estimation: An Error Analysis of Gradient-Based Methods with Local Optimization
IEEE Transactions on Pattern Analysis and Machine Intelligence, 9(2):229-244.

112. KimKimKim89.

Kim, J.D., Kim, S.D., and Kim, J.K. (1989).
Fast convergent method for optical flow estimation in noisy image sequences
Electronics Letters, 25(1):74-75.

113. KimLee98.

Kim, J.W. and Lee, S.U. (September 1998).
Video Coding with R-D Constrained Hierarchical Variable Block Size (VBS) Motion Estimation
Journal of Visual Communication and Image Representation, 9(3):243-254.

114. KimKim92

Kim, Y.H. and Kim, S.D. (1992).
Image flow segmentation and estimation using desplaced spatial gradient
Electronics Letters, 28(24):2213-2215.

115. KircNiem92.

Kirchner, H. and Niemann, H. (1992).
Finite element method for determination of optical flow
Pattern Recognition Letters, 13(2):131-141.

116. Koen86.

Koenderink, J.J. (1986).
Optic Flow
Vision Research, 26(1):161-168.

117. KogaMiik88.

Koga, K. and Miike, H. (1988).
Determining optical flow from sequential images
Systems and Computers in Japan, 19(8):77-86.

118. KogaMiikMomo87.

Koga, K., Miike, H., and Momota, M. (1987).
Exact determination of optical flow by pixel-based temporal mutual-correlation analysis
IEICE Transactions on Information and Systems (D), E70-D(8):719-722.

119. KompTzovStri98a.

Kompatsiaris, I., Tzovaras, D., and Strintzis, M.G. (6. November 1998 a).
Flexible 3D Motion Estimation and Tracking for Multiview Image Sequence Coding
Signal Processing: Image Communication, 14(1/2):95-110.

120. KonrDubo92

Konrad, J. and Dubois, E. (1992).
Bayesian Estimation of Vector Motion Fields
IEEE Transactions on Pattern Analysis and Machine Intelligence, 14(9):910-927.

121. KumaTannBala96.

Kumar, A., Tannenbaum, A.R., and Balas, G.J. (1996).
Optical flow: a curve evolution approach
IEEE Transactions on Image Processing, 5(4):598-610.

122. LappGrig99.

Lappe, M. and Grigo, A. (1999).
How stereo vision interacts with optic flow perception: Neural mechanisms
Neural Networks, 12(9).

123. LappRaus93.

Lappe, M. and Rauschecker, J.P. (1993).
A Neural Network for the Processing of Optic Flow from Ego-Motion in Man and Higher Mammals
Neural Computation, 5(3):374-391.

124. Lawt83

Lawton, D.T. (1983).
Processing Translational Motion Sequences
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Subject Index

Year of publication:           '79'81'87    '88'89'90'91'92'93   '94        '95'96          '97

Links to references:            73 87 82 111 83  8 74 19 68 88 95 14 37 138 235 28 29 61 228 77

Subjects:                               
  Filter methods               
    Gradient                    73 87 -- 111 -- -- -- 19 -- 88 95 14 -- 138  -- 28 29 61  -- --
    Wavelet-Energy              -- -- 82  -- 83 -- -- -- -- -- -- 14 37  -- 235 -- -- --  -- --
    Wavelet-Phase               -- -- --  -- -- -- 74 -- -- -- -- 14 --  --  -- -- -- -- 228 --
    Others                      -- -- --  -- -- -- -- -- 68 -- -- -- --  --  -- -- -- --  -- 77
  Matching methods             
    Blocks                      -- -- --  -- --  8 -- -- -- -- -- 14 --  --  -- -- -- --  -- --
  Constraints                  
    Smoothness                  -- 87 --  -- --  8 -- 19 -- -- 95 -- --  --  -- -- -- --  -- --
    Others                      -- -- --  -- -- -- -- -- -- -- -- -- --  --  -- 28 29 --  -- --
                               
  Multi scale                   -- -- --  -- --  8 74 19 -- -- 95 -- 37 138 235 -- -- --  -- --
                               
  Survey                        -- -- -- 111 -- -- -- -- -- 88 -- 14 --  --  -- -- -- --  -- --

Author Index

346 authors, 34 (9%) with homepage. First author references are printed boldface.

Year Index

Journal Index

The numbers in the columns `R', `A', and `P' indicate the year from which on you can expect to find online references, abstracts, and papers, respectively. A '?' indicates documents, that may be accessible only to subscribers.

66 journals, 40 (60%) with homepage.