1. Specialist Certification Course The Combined Events and Multievents
Photo Credits:

2. The Basics of Biomechanics and Technical Model Design for the Combined Events and Multievents

3. Fundamental Biomechanical Terms
Force 
Linear and Angular Motion 
The Center of Mass 
Displacement 
Velocity and Acceleration

4. Newton’s Laws Newton’s First Law Newton’s Second Law
Newton’s Third Law

5. Momentum and Impulse
Momentum 
Impulse

6. An Expansion of Newton’s Third Law (Part 1)
Ground Reaction Forces
Swinging Segment Usage 
Principle of Rotational Opposition 
Law of the Ends and Middle

7. An Expansion of Newton’s Third Law (Part 2)
Newton’s Third Law in Flight
Newton’s Third Law in Single Support 
Newton’s Third Law in Double Support 
Commensurate Momentum Values
Commensurate Flexion and Extension
Symmetry 

8. Hinged Moments
The Hinged Moment 
Accelerations and Decelerations 

9. Bodies in Flight Gravity The Flight Path as a Parabola
Predetermined Flight Path and Rotations

10. Rotating Systems Transfers of Angular Momentum
Tangential and Axial Forces 
Conservation of Angular Momentum 

11. Stability Stability Height of the Center of Mass
Center of Mass/Base of Support Relationships 
Single and Double Support
Double Support
Single Support 
Dynamic Stability

12. Developing Technical Models (Part 1)
Commonalities
Commonality Based Teaching 
Technique and Style 
Sports Science Contributions to the Technical Model

13. Developing Technical Models (Part 2)
Evaluation of Technical Model Changes
Performance Level
Consistency
Injury Prevention 

14. Developing Technical Models (Part 3)
Cost/Benefit Analysis 
Benefit 
Difficulty
Further Issues
Scientific Rationale
Special Considerations for the Combined Events
The Principle of Biomechanical Efficiency