1 / 12

MEGN 536 – Computational Biomechanics Euler Angles

MEGN 536 – Computational Biomechanics Euler Angles. Prof. Anthony J. Petrella. Rotational Transformations. Recall from our discussion last time… Global ref is denoted by uppercase letters, X, Y, Z Body-fixed rotations can be computed for x , y , z axes

osias
Download Presentation

MEGN 536 – Computational Biomechanics Euler Angles

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. MEGN 536 – Computational BiomechanicsEuler Angles Prof. Anthony J. Petrella

  2. Rotational Transformations • Recall from our discussion last time… • Global ref is denoted by uppercase letters, X, Y, Z • Body-fixed rotations can be computed for x, y, z axes • Any combination can be applied in any order • The combined (total) rotation is computed by a simple product of individual rotation matrices • Order of body-fixed rotations is read right-to-left • The combined (total) rotation transforms vectors from the global reference frame to the local frame • Rows of the total rotation matrix are the unit vectors of the local frame

  3. Rotational Transformations • What are common combinations / orders of rotations? Euler was one of the first to propose… • Type I angles are used for the joint coordinate system (JCS) • These are body-fixed rotations Greenwood, Principles of Dynamics, 2nd ed., Prentice Hall, 1988

  4. Euler Angles • We will define the orientation of a moving body segment relative to a global reference using three rotations around z, y, and x body-fixed axes • Let the local segment frame be initially coincident with the global ref (fixed in another part of body) • There will then be three rotated configurations of the local segment frame: • after the first rotation → x’’, y’’, z’’ • after the second rotation → x’, y’, z’ • after the third rotation, the final configuration → x, y, z

  5. Using Euler Angles • Moving reference frame • Lowercase axis labels: x, y, z • Lowercase unit vectors also: i, j, k • Fixed in a body segment (such as tibia) and used to define motion of segment based on rotation and translation of ref frame • Global reference frame • Uppercase axis labels: X, Y, Z • Uppercase unit vectors: I, J, K • Fixed in another portion of the anatomy (such as femur) and used as a foundation from which to measure motion of moving ref frame

  6. Using Euler Angles • If we use Type I Euler angles, • Rotation f around z-axis (z’’) • Rotation q around Line of Nodes(common perpendicular to Z and x, this is the intermediate y-axis, which is the same as y’’ and y’) • Rotation y around x-axis • Then the local segment frame moves as shown at right • From part c of the figure at theright, the Line of Nodes can be computed as:

  7. Finding Euler Angles • From the figure below we can easily compute the three Euler angles as… • Where positive values areshown in the figure andcorrespond to…

  8. Joint Coordinate System (JCS) for Knee • Purpose: express rotation angles and translations in clinically / anatomically meaningful ways • Joint angles referenced to JCS allow us to quantify… • Flexion/Extension (F/E) • Adduction/Abduction (Ad/Ab) also referred to sometimes as Varus/Valgus (V/V) …remember, valgus is knock-knee’d • Internal/External Rotation (I/E) • Joint translations allow us to quantify… • Superior/Inferior translation (S/I) • Anterior/Posterior translation (A/P) • Medial/Lateral translation (M/L)

  9. Joint Coordinate System (JCS) for Knee • Let the femur represent the global reference • Tibia moves relative to the femur • Let us define the reference frames as shown • Uppercase letters on femur • Lowercase letters on tibia • X-axis is the long axis, S/I • Y-axis is A/P • Z-axis is M/L • Same for lowercase letters X Z Y x z y

  10. Joint Coordinate System (JCS) for Knee • We adopt some conventions (Grood & Suntay, 1983) • F/E (f) is rotation of tibia around M/L axis of femur (Z-axis) • Ad/Ab (q) is rotation of tibia around common floating axis that is at right angles to F/E and I/E axes (L-axis) • I/E (y) is rotation of tibia around its own long axis (x-axis) • Floating axis always defined by cross product of femur M/L(Z-axis) with tibia longitudinal axis (x-axis) • Translations expressed as distances along JCS axes, this is done with simple dot products • Other quantities (forces or moments) may also be expressed in terms of components along JCS axes

  11. Joint Coordinate System (JCS) for Knee • Figure below shows the left knee, but the right knee is the same • The JCS is definedas shown • Note: you can seethat the commonfloating axis L is theperpendicular to bothZ and x • Note that Z and x arenot necessarily perpendicular to eachother…so this is not an orthogonal ref frame x Z X Z Y x z Adduction and abduction y

  12. Joint Coordinate System (JCS) for Knee • Clinical translations are expressed as distances along JCS axes • Find the total displacement vector that defines the tibial origin location relative to the femoral origin (D) • M/L translation is measured along the F/E axis fixed in the femur (Z-axis) • A/P translation is measured along the floating axis (L-axis) • S/I translation is also called compression/distraction and is measured along the long axis of the tibia (x-axis) • Use simple dot products to find the components of the displacement vector along the anatomical axes… DM/L = D Z ; DA/P = D L ;DS/I = D x

More Related