makamo66 said:Are we shifting the angular momentum to the arms? Are we increasing our moment of inertia? Is the change of the center of mass relevant?
This is intuitive rather than analytic.makamo66 said:What I understood from the links you gave me is that the long jump would represent a rotation and the moment of inertia (MOI) would become larger when the arms are extended while jumping. Since angular momentum is conserved, the angular velocity would decrease and the larger MOI would prevent too much rotation. This however doesn't make sense to me because I don't see how the jump can be considered to be rotational.
CAVEAT: I have not looked at the literature.makamo66 said:As a result of lowering the COM, the take off height is decreased. I thought the idea was to increase the take off height so that one jumps further and not decrease it. What am I misunderstanding?
I seem to remember reading that, for long jump, you need your CM to be as high as possible but, for high jump, you need your CM to be as low as possible. An over simplification, perhaps but.makamo66 said:As a result of lowering the COM, the take off height is decreased. I thought the idea was to increase the take off height so that one jumps further and not decrease it. What am I misunderstanding?
It depends on the proportions of the individual body. Power / Weight (we mean Mass, really) ratio is a factor and also the mechanical advantage of the leg (lever) bones etc. Any answer to the OP must really relate to one particular jumper.makamo66 said:The runner is moving in a parabola, so I guess the jump will be longer the less tall it is.
Your arms are given both vertical and horizontal momentum at the start. Afair you use the arms to 'pull yourself up' as you're in free fall. I'd say they start off moving upwards and forward and, on impact with the floor, they are moving down and backwards. I don't know if the exercise has an actual name but frog jump performance can be improved by carrying an appropriate size of kettle bells to increase the effective mass of the arms. With that method, one is seriously aware of the feeling of pulling yourself towards the kettle bells - they're like free ballistic energy which was stored before you took off..makamo66 said:Everyone swings their arms forward to gain momentum.
Yes, there is a connection between the physics of a frog jump and taekwondo. Taekwondo involves various movements and techniques that require a good understanding of physics, including the principles of force, momentum, and energy.
The physics of a frog jump can be applied to taekwondo in several ways. For example, the explosive power generated in a frog jump is similar to the power generated in a taekwondo kick. Additionally, the principles of balance and weight distribution in a frog jump can also be applied to taekwondo stances and movements.
Yes, understanding the physics of a frog jump can improve your taekwondo performance. By understanding the principles of force, momentum, and energy, you can improve the power and effectiveness of your kicks and movements. Additionally, understanding balance and weight distribution can help you maintain stability and control in your stances and techniques.
Yes, there are several techniques in taekwondo that are influenced by the physics of a frog jump. These include jumping kicks, which require a good understanding of force and momentum, as well as balance and weight distribution. The explosive power generated in a frog jump can also be applied to techniques such as the roundhouse kick and the flying side kick.
There are various resources available for learning more about the physics of a frog jump and its application in taekwondo. You can consult with a taekwondo instructor who has a good understanding of physics, or you can do some research on your own by reading books or articles on the subject. Additionally, there are also online courses and videos that specifically focus on the physics of taekwondo techniques.