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Title: Kinesiology of Athletic Movement: Kicking


1
Kinesiology of Athletic Movement Kicking
  • Zahra Abdalla
  • Ayan Elmi
  • Elizabeth Jenket
  • Alejandro Morales
  • Sondos Serageldin
  • Jill Sutera
  • Kevin Weeks

2
Soccer Kick Video
3
Background of Kicking
  • Kicking A series of rotational movements.
  • The Aim to produce through the kinematic chain
    of body segments, high angular velocity to the
    foot in order to exert enough force for the ball
    to move.
  • Kicking is a complex motor task, which rapidly
    develops between the ages of four and six.


4
Goal of Kicking
  • The place kick action is performed in order to
    accomplish a certain velocity of the ball ( needs
    greater swing limb/foot speed), or to direct the
    ball to a desired location.
  • The direction of the ball is determined by the
    position of the planted foot and the hip position
    at impact.
  • The length of time of the kick depends on the
    approach distance.
  • The intensity of the kick is determined by the
    desired distance and speed.

5
Biomechanical Analysis of Kicking
Figure 3. The last step and kicking phase in a
maximal kick (Luhtanen 1984)
  • 1) You put the foot back in order to gain enough
    kinetic energy before you hit the ball so the
    ball will move due to the kinetic energy of the
    foot
  • 2) Work is done by the foot on the ball- you have
    to work against gravity (muscles have to exert a
    torque against the gravity torque)
  • 3) Release Phase torque due to gravity will
    change gravitational potential energy of the leg
    to kinetic energy thus transferring energy from
    the foot to the ball

6
Athletic Application of Kicking
  • The standing place-kick can be applied to
    soccer and point scoring in both rugby and
    football.
  • This kick action can be broken down into 6
    stages
  • - the approach
  • - plant-foot forces
  • - swing-limb loading
  • - hip flexion and knee extension
  • - foot contact
  • - follow-through

7
Kicking Application cont.
  • The Approach As a child develops their
    kicking pattern they learn to pace the run up and
    adjust their approach into a diagonal angle. A
    45-degree angle produces the greatest peak ball
    velocity.
  • Plant-foot Forces The ground reaction force on
    the plant foot directly affects the ball speed.
    There is also a direct relationship between the
    direction of the plant foot and the direction the
    ball travels. The most accurate direction of the
    ball can be accomplished when the foot plant
    position is perpendicular to a line through the
    center of the ball. The optimal
    anterior-posterior (A-P) position of the plant
    foot is adjacent to the ball. This A-P position
    determines the flight path of the kicked ball.

8
Kicking Application cont.
  • Swing-limb loading The swinging of the limb
    prepares for the descending motion towards the
    ball. During this phase the opposite arm is
    raised to counter balance the rotating body. Both
    arms help keep the center of gravity over the
    support foot and increases the moment of inertia
    of the trunk. The kicking leg is extended and the
    knee is flexed to store elastic energy and allow
    a greater transfer of force to the ball. At the
    end of this phase there is maximal eccentric
    activity in the knee extensors.
  • Hip flexion and knee extension In this phase the
    thigh is swung forward and downward with a
    forward rotation of the lower leg. The leg then
    begins to accelerate due to the combined effect
    of the transfer of momentum and release of stored
    elastic energy in the knee extensors. The knee
    extensors then powerfully contract to swing the
    leg and foot towards the ball. After the kicking
    leg makes contact with the ball the knee is
    extended and the foot is plantarflexed. At this
    time the hamstrings are maximally activte to slow
    the legs eccentric movement.

9
Kicking Application cont.
  • Foot contact with the ball When the foot makes
    contact with the ball 15 of the kinetic energy
    of the swinging limb is transferred to the ball
    and the rest of the energy is used by the
    eccentric activity of the hamstring muscle group
    to slow the limb down.
  • Follow Through This serves to keep the foot in
    contact with the ball to maximize the transfer of
    momentum and therefore increase speed. This also
    serves to guard against injury by gradually
    dissipating the kinetic and elastic forces.

10
AGONISTS and ANTAGONISTS
  • Agonists
  • Hip flexors rectus femoris, iliopsoas, sartorius
  • Knee extensors 4
  • Dorsiflexors
  • Antagonists
  • Hamstrings
  • Gastrocnemius
  • Plantarflexors

11
SYNERGISTS and STABILIZERS
  • Synergists
  • Hip internal external rotators, adductors,
    abductors
  • Knee adductors, abductors
  • Ankle Peroneals (lateral) , post tibialis
    (medial)
  • Stabilizers
  • Trunk stabilizers Abdominals, psoas major,
    erector spinae and postural muscles
  • Muscles of the plant foot and leg

12
Neutralizers and Primary Muscle Group IMAs EMAs
  • Neutralizers
  • Hip abductors and adductors, internal and
    external rotators
  • Foot inverters and everters, pronators and
    supinators
  • Primary Muscle Group IMA EMAs
  • Hip flexors, knee extensors, dorsiflexors of
    tailor joint

13
Major Muscles Contractors
  • Adductor Magnus
  • Pelvic on femoral adduction
  • Support body weight
  • Pectineus, Adductor Breves Longus
  • Femoral on pelvic adduction torque
  • Accelerate the ball
  • Hamstrings Quadriceps
  • Flexion Extension
  • Creates force

14
Axis of Rotation of the Hip
Saggital, Frontal and Horizontal Plane
15
Axis of Rotation of the Knee
Flexion Extension in the Sagittal Plane
16
Axis of Rotation of the Knee
Horizontal Plane
17
Axis of Rotation of the Ankle
18
Major External Forces
  • Gravity, friction, and time (duration of contact)
  • The ball will exert a force equal in magnitude to
    contact but opposite in direction

19
Major Internal Forces
  • The movements in soccer are monitored by players
    internally. Sense organs within the muscles,
    joints and tendons provide information to the
    central processing system about their movements.
    This is commonly called muscle sense or
    kinesthetic sense. In the internal loop the nerve
    endings in skin tell the footballer about the
    touch of the ball, kinesthetic receptors in
    joints control the joint angle, muscle spindles
    relate to the length change in the muscle, and
    the Golgi apparatus the tension in tendon.
  • Internal force phases of kick include
    preparation, approach kick, and follow-through.

20
Muscle Action during kicking preparation
(right-footed kick)
21
Muscle action during approach kicking
(right-footed kick)
22
Muscle action during follow-through (right-footed
kick)
23
Radius of Gyration
  • The radius of gyration is the distance between
    the hip of the planted leg and the opposing hip
    is the axis of rotation of the kicking motion.

24
Linear and Angular Velocity
  • The length of the body segments or the radius of
    rotational movements influences the linear
    velocity of the rotating foot.
  • The linear velocity of rotating levers can be
    expressed as a product of the radius of
    rotational movement and angular velocity.
  • A skillful soccer player produces high ball
    velocity by maximizing angular velocities of the
    thigh and shank (Asami et al. 1976).

25
Torques and Center of Mass
  • Note When you try to kick the ball, kick it at
    the center of mass- force from the foot should
    hit it in the center of mass to achieve total
    translational energy so the ball can reach
    farther, yet if not achieved it will be more
    stable
  • Torque exerted by the muscles to rotate the
    lower leg around the knee joint in order to move
    the lower leg in position to kick the ball
  • Torque due to gravity knowing the line of action
    of the weight (perpendicular distance to the line
    of action of the weight of the leg)

http//www.bethpage.ws/admin/chiscock/Kicking_Ball
.jpg
Figure 8. Torque of hip, knee and ankle in a
maximal instep kick (Luhtanen 1988)
26
Newtons Laws and Angular Motion Newtons 1st Law
  • 1st Law A body continues in a state of rest or
    uniform  rotation about its axis unless acted 
    upon by an external torque.       1) Rotatory
    motion of a lever usually results when muscle
    pulls on bone, providing the external resistance
    is less than the amount of muscular force acting
    on the bone.     2) If the mass is concentrated
    farther away from the axis of rotation, the
    moment of inertia will  be greater, thus the
    system (i.e., lever) will be harder to start or
    stop.
  • 3) The mass distribution about an axis of
    rotation (i.e., joint) may be altered by changing
    the limb position.

27
Newtons Laws and Angular Motion Newtons 2nd Law
  • Reactive Forces
  • Foot hits the ball force applied on the ball
    (contact force) and ball exerts reactive force
    back which gives rise to the acceleration of the
    ball

  • 2nd Law The acceleration of a rotating body is
    directly proportional to the force causing it, in
    the same direction of the force and is inversely
    proportional to the moment of inertia/ mass of
    the body.
  • WorkForce x Distance the magnitude of force
    applied by the kicker against the ball and the
    distance the ball moves in direction of the force
    of the kick
  • Angular momentum of a limb is increased if the
    angular velocity is increased ex. kicking a ball
  • Acceleration of the Ball Force Contact/ Mass of
    Ball

Figure 5. Vertical, horizontal and lateral
ground reaction forces during maximal kicking
(Luhtanen 1984)
28
Newtons 2nd Law Impulse-Momentum
  • If you want to give the ball higher momentum your
    impulse must be higher.
  • The greater the mass of the leg, and the greater
    the velocity of the foot at impact, the greater
    the resultant velocity of the ball at impact.
  • When the foot touches the ball an impulse is
    exerted by the contact force of the foot
  • I Force contact x ?Time (duration of contact)
  • ?P Impulse (?P change in momentum of the ball)
  • The momentum of the kicking foot and leg mass of
    the leg velocity of the foot at impact
    velocity of the body as the player approaches the
    ball.

http//home.flash.net/waynok/graphics/flyingthrou
ghtheair.jpg
29
Impulse-Momentum Continued
  • The velocity production of the ball can be
    evaluated according to the conservation of the
    linear momentum in collision.
  • The action of the ankle can increase the release
    velocity of the ball a little. Through elastic
    collision, linear momentum transfers partly to
    the ball. The bigger the leg mass the higher the
    ball velocity. The point of application must be
    inside the effective hitting area, which depends
    on the tension in the ankle.

30
Newtons Laws and Angular Motion Newtons 3rd Law
  • When a torque is applied by one body to another,
    the  second body will  exert an equal and
    opposite torque  on the other body.
  • Fma the kicker and the ball experience
    different acceleration effect, that is dependent
    on its mass
  • Acceleration of the Ball Force Contact/ Mass of
    Ball
  • So the ball will exert a force equal in magnitude
    to contact but opposite in direction

http//www.shetland.gov.uk/community/news/images/j
0400097.jpg
31
Acceleration and Velocity
  • The acceleration of the kicking leg, and the
    resultant velocity at impact, is determined by
    the muscle forces being applied by the kicker.
  • The release velocity of the ball with respect to
    timing had the strongest relationship to the
    maximal torque produced during the 1. hip flexion
    2. knee extension and 3. short ankle stabilizing
    in the kicking leg.
  • Thus the increase of the body mass means increase
    in the mass of the foot and this automatically
    increases the release velocity of the ball in the
    kick.
  • The regulation of the effective mass in the
    kicking foot might play an important role for
    getting the high release velocity to the ball
    (Luhtanen 1988).

32
The Role of the Arms
  • The role of the arms in kicking is primarily to
    maintain the balance of the body.
  • The arms are usually extended out to the sides of
    the body during the forward motion of the kicking
    leg, to help to keep the center of gravity over
    the support foot, and to increase the moment of
    inertia of the trunk and increase resistance to
    rotation around the spine, or the long axis of
    the body.
  • As the kicking foot contacts the ball, the
    opposite arm moves forward and upward across the
    body to help keep the trunk down and the body in
    balance.

http//students.umf.maine.edu/pullenam/soccer.jpg
33
Kicking Questions
  • What are the primary movers (agonists) involved
    in the swing phase of kicking?
  • a) Quadriceps, hamstrings, plantar flexors
  • b) Hamstrings only
  • c) Gluteus medius, soleus, tibialis anterior
  • d) Adductor magnus, soleus, fibularis
    longus,sartorius
  • The greater the mass of the leg, the______ the
    velocity of the foot at impact,
  • the ________ the resultant velocity of the ball
    at impact.
  • a) greater, lower
  • b) lower, greater
  • c) lower, lower
  • d) greater, greater
  • The momentum of a soccer kick is dependent on
  • a) The velocity of the kick
  • b) The mass of the ball itself
  • c) The duration of the impact between the foot
    and the ball
  • d) All of the above
  • What is the purpose of the arms during kicking?
  • a) To allow greater transfer of force to the ball
  • b) To increase the intensity of the kick

34
References
  • Barfield, B (1998), The biomechanics of kicking
    in soccer. Clinics in Sports Medicine. 17(4)
    711-728.
  • Ben-Sira, D (1980), A comparison of the instep
    kick between novices and elites. In Barfield, B
    (1998), The biomechanics of kicking in soccer.
    Clinics in Sports Medicine. 17(4) 711-728.
  • Brukner, P, and Khan, K (2001), Clinical Sports
    Medicine(2nd ed). Roseville McGraw-Hill.
  • Chysowych, W. (1979), The Official Soccer Book of
    the United States Soccer Federation. In Barfield,
    B (1998), The biomechanics of kicking in soccer.
    Clinics in Sports Medicine. 17(4) 711-728.
  • Gainor, B, Pitrowski, G, and Puhl, J (1978), The
    kick. Biomechanics and collision injury. Am J
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  • Hay, J (1996), Biomechanics of Sport Techniques.
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  • Isokawa, M, and Lees, A (1988), A biomechanical
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    Reilly, T, and Williams, M, (2003), Science and
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  • Luhtanen, Pekka. Kicking. Coaches Infosevice
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