Rigorous Geometric Self-Calibrating Bundle Adjustment for a Dual Fluoroscopic Imaging System

High-speed dual fluoroscopy is a noninvasive imaging technology for three-dimensional skeletal kinematics analysis that finds numerous biomechanical applications. Accurate reconstruction of bone translations and rotations from dual-fluoroscopic data requires accurate calibration of the imaging geometry and the many imaging distortions that corrupt the data. Direct linear transformation methods are commonly applied for performing calibration using a two-step process that suffers from a number of potential shortcomings including that each X-ray source and corresponding camera must be calibrated separately. Consequently, the true imaging set-up and the constraints it presents are not incorporated during calibration. A method to overcome such drawbacks is the single-step self-calibrating bundle adjustment method. This procedure, based on the collinearity principle augmented with imaging distortion models and geometric constraints, has been developed and is reported herein. Its efficacy is shown with a carefully controlled experiment comprising 300 image pairs with 48 507 image points. Application of all geometric constraints and a 31 parameter distortion model resulted in up to 91% improvement in terms of precision (model fit) and up to 71% improvement in terms of 3-D point reconstruction accuracy (0.3-0.4 mm). The accuracy of distance reconstruction was improved from 0.3±2.0 mm to 0.2 ±1.1 mm and angle reconstruction accuracy was improved from -0.03±0.55° to 0.01±0.06°. Such positioning accuracy will allow for the accurate quantification of in vivo arthrokinematics crucial for skeletal biomechanics investigations.

[1]  J Wang,et al.  The AAPM/RSNA physics tutorial for residents: X-ray image intensifiers for fluoroscopy. , 2000, Radiographics : a review publication of the Radiological Society of North America, Inc.

[2]  Mauricio Galo,et al.  Generating Virtual Images from Oblique Frames , 2013, Remote. Sens..

[3]  Clive S. Fraser,et al.  Digital camera self-calibration , 1997 .

[4]  Scott Tashman,et al.  Validation of three-dimensional model-based tibio-femoral tracking during running. , 2009, Medical engineering & physics.

[5]  S. Woo,et al.  Relationship of anterior knee laxity to knee translations during drop landings: a bi-plane fluoroscopy study , 2011, Knee Surgery, Sports Traumatology, Arthroscopy.

[6]  A Hosseini,et al.  In-vivo time-dependent articular cartilage contact behavior of the tibiofemoral joint. , 2010, Osteoarthritis and cartilage.

[7]  Joseph J Crisco,et al.  Static and dynamic error of a biplanar videoradiography system using marker-based and markerless tracking techniques. , 2011, Journal of biomechanical engineering.

[8]  Angelo Cappello,et al.  A global method based on thin-plate splines for correction of geometric distortion: an application to fluoroscopic images. , 2003, Medical physics.

[9]  S.A. Banks,et al.  Accurate measurement of three-dimensional knee replacement kinematics using single-plane fluoroscopy , 1996, IEEE Transactions on Biomedical Engineering.

[10]  Scott Tashman,et al.  In vivo measurement of 3-D skeletal kinematics from sequences of biplane radiographs: Application to knee kinematics , 2001, IEEE Transactions on Medical Imaging.

[11]  Clive S. Fraser,et al.  Design and implementation of a computational processing system for off-line digital close-range photogrammetry , 2000 .

[12]  Soumya K. Ghosh,et al.  SCANNING ELECTRON MICROGRAPHY AND PHOTOGRAMMETRY , 1976 .

[13]  D. B. Baier,et al.  Three-Dimensional, High-Resolution Skeletal Kinematics of the Avian Wing and Shoulder during Ascending Flapping Flight and Uphill Flap-Running , 2013, PloS one.

[14]  C. Fraser,et al.  Digital camera calibration methods: Considerations and comparisons , 2006 .

[15]  K. Shelburne,et al.  A comparison of calibration methods for stereo fluoroscopic imaging systems. , 2011, Journal of biomechanics.

[16]  Edward M. Mikhail,et al.  Observations And Least Squares , 1983 .

[17]  Freddie H. Fu,et al.  The Kinematic Basis of Anterior Cruciate Ligament Reconstruction , 2008 .

[18]  Clive S. Fraser,et al.  Calibration of long focal length cameras in close range photogrammetry , 2011 .

[19]  Jessica M. Deneweth,et al.  Tibiofemoral Joint Kinematics of the Anterior Cruciate Ligament-Reconstructed Knee During a Single-Legged Hop Landing , 2010, The American journal of sports medicine.

[20]  Hans-Gerd Maas,et al.  Development of a geometric model for an all-reflective camera system , 2013 .

[21]  Rita Stagni,et al.  Effect of calibration error on bone tracking accuracy with fluoroscopy. , 2014, Journal of biomechanical engineering.

[22]  Stuart Robson,et al.  Close Range Photogrammetry , 2007 .

[23]  Elizabeth L Brainerd,et al.  Kinematics of the quadrate bone during feeding in mallard ducks , 2011, Journal of Experimental Biology.

[24]  K Bouazza-Marouf,et al.  Robotic-assisted internal fixation of hip fractures: A fluoroscopy-based intraoperative registration technique , 2000, Proceedings of the Institution of Mechanical Engineers. Part H, Journal of engineering in medicine.

[26]  Steffen Renisch,et al.  Image-Guided Therapy (IGT): New CT and Hybrid Imaging Technologies , 2006 .

[27]  D. B. Baier,et al.  X-ray reconstruction of moving morphology (XROMM): precision, accuracy and applications in comparative biomechanics research. , 2010, Journal of experimental zoology. Part A, Ecological genetics and physiology.

[28]  J Erik Giphart,et al.  Knee kinematic profiles during drop landings: a biplane fluoroscopy study. , 2011, Medicine and science in sports and exercise.

[29]  Scott Tashman,et al.  The association between velocity of the center of closest proximity on subchondral bones and osteoarthritis progression , 2009, Journal of orthopaedic research : official publication of the Orthopaedic Research Society.

[30]  M. A. Chapman,et al.  Constrained FEM Self-Cali bration , 1997 .

[31]  Freddie H. Fu,et al.  The Kinematic Basis of ACL Reconstruction. , 2008, Operative techniques in sports medicine.

[32]  E. Gronenschild,et al.  The accuracy and reproducibility of a global method to correct for geometric image distortion in the x-ray imaging chain. , 1997, Medical physics.

[33]  H. Wollschlager,et al.  Optical distortion due to geomagnetism in quantitative angiography , 1988, Proceedings. Computers in Cardiology 1988.

[34]  Guoan Li,et al.  An optimized image matching method for determining in-vivo TKA kinematics with a dual-orthogonal fluoroscopic imaging system. , 2006, Journal of biomechanical engineering.

[35]  S. Tashman,et al.  Are the kinematics of the knee joint altered during the loading response phase of gait in individuals with concurrent knee osteoarthritis and complaints of joint instability? A dynamic stereo X-ray study. , 2012, Clinical biomechanics.

[36]  E. Gronenschild,et al.  Correction for geometric image distortion in the x-ray imaging chain: local technique versus global technique. , 1999, Medical physics.

[37]  N. A. Borghese,et al.  Distortion correction for x-ray image intensifiers: local unwarping polynomials and RBF neural networks. , 2002, Medical physics.

[38]  Luis F. Gutiérrez,et al.  A practical global distortion correction method for an image intensifier based x-ray fluoroscopy system. , 2008, Medical physics.