SlideShare a Scribd company logo

Tom tellez sprinting a biomechanical approach

Flavio Clesio
Flavio Clesio
TechnologyBusiness
1 of 8
Download to read offline
Sprinting: A Biomechanical Approach By Tom Tellez World class male sprinters stride approximately forty-three times for a 100 meter race. If a mechanical error costs one-one thousandth of a second per stride, the total cost is .043 seconds by the finish. How can one be an efficient sprinter? However daunting the question appears, an answer lies in scientific principles alone. Kinesiology, biomechanics, and the laws of physics govern every sprinter’s technique. Kinesiology, the study of movement, dictates how a sprinter should move. Contributing to the study of movement is the discipline biomechanics, which refers to the engineering of the body and laws of physics governing it. While referencing laws of physics, kinesiology and biomechanics view the body as a unified system of interdependent parts, an approach necessary for proper analysis. Overview At the start of a race, the body must begin movement from a rest state. Once moving, the body requires time to build into full speed, or accelerate to full speed. At the beginning of this process, stride length as well as the number of strides per unit of time is small. However, both increase as acceleration increases. While having the ability to accelerate over 100 meters would be ideal, the body is only capable of accelerating for approximately sixty meters. The last forty meters would simply be maintaining technique and speed. Analysis of sprint mechanic s explains the finer nuances of sprint technique, including impulse, stride length, stride frequency, running velocity, arm movement, and leg action. Impulse Impulse is not only a term for the foot-ground contact created by each step but also a numeric value defined as force X time. This is the starting point to understanding scientific sprint technique because the impulse is the body’s only interaction with the ground, the one and only interaction, which produces linear movement. Impulse ultimately defines how the body should perform rotary movement (movement of body levers relative to body). Vector calculus defines impulse: each impulse has a direction and magnitude. Direction is the mixture of horizontal and vertical components, while magnitude is the measure of force. The best sprint technique consists of an ideal ratio between downward push and horizontal push (Fig. 9). This ratio, however, changes throughout the sprint race. Concerning force, of course great force can yield great stride length. However, misapplication of force translates to poor technique and loss of momentum. While the horizontal and vertical components of force within impulse play a role in creating body position, body position is also rotary. The ideal body position is perpendicular to the ground, where neck and head fall naturally in line. Depending on the impulse, the body may lean from the ground, as in the drive phase of sprinting, or remain vertical.
One finer detail of impulse relates to how various athletes contact the ground. 100-200 meter sprinters contact the ground on the ball of the foot (Fig. 1), 400- 800 meter runners’ contact in the arch (Fig. 2) and 1500 meter runners and up use almost the entire foot as a contact point (Fig 3). While producing the numerical value of each step in a print race requires special technologies, coaches can judge the quality of impulse by measuring momentum. For example, when sprinters show a “low and long” look like that of an ice skater, one possible error is too much horizontal force. A dramatic example of too much downward force would be an athlete who simply jogs in place without moving. But what if two athletes within a race produce near-perfect directional ratios, which one wins? The one applying more force, within the least amount of time wins (Weyand et al.1998). Force applied for long time intervals requires more energy output than force application for shorter time intervals. It is force applied with the proper directional ratio, which increases stride speed and creates longer stride length. Stride Length Stride length is the distance the center of gravity travels between each foot contact. Stride length is the resultant of momentum plus net impulse, which is given to the mass. It can be examined as the following: takeoff distance, flight distance, and landing distance (Fig. 4) Takeoff Distance Takeoff distance is the distance the center of gravity travels between the landing point and the point where ground contact is broken. The velocity at which the center of gravity is projected forward is also critical to the flight phase of the stride and is determined by the velocity at touch down and the vertical and horizontal impulses. Thus the speed through the takeoff distance along with good body position and angle of projection determines the takeoff velocity. It will therefore be advantageous to have a big takeoff distance coupled with a great amount of angular speed as the time element of impulse diminishes. Here, it should be noted that the negative velocity of the foot sets up the body position for take off but contributes very little to the actual take off which is the result of pushing the ground away from the body (body away from the ground). Flight Distance The flight distance is the distance that the center of gravity travels in the non- support phase of the stride. These factors determine the flight distance: angle of impulse, velocity at takeoff, relative height of center of gravity at takeoff, air resistance, and acceleration due to gravity. Landing Distance The landing distance is the distance the center of gravity is away from the landing foot. This distance is relatively short so as to reduce the breaking forces,
which decelerate the body. The point of course is to put the food down in a place, which can mechanically develop the most power. The foot lands slightly in front of the center of gravity before moving directly under the center of gravity for push off. If the foot lands behind the center of gravity, stumbling results. Whereas if the foot is too far forward I a reaching step, contact time with the ground will be too long, requiring too much force, resulting in a loss of momentum by the time the body is in a position to push off of the ground effectively. Stride Frequency Stride Frequency is the number of strides taken per unit of time. Stride time is easily confused with stride frequency. Stride time is the time it takes to complete one stride (time of support and time of nonsupport). Stride speed and angular velocity through the full range of motion (front and back oscillation) determine stride time. Because stride speed depends on the body state (fitness), it is more of a physiological function (muscle type, muscle flexibility, strength, neuro- muscular coordination, etc.) than biomechanical function. But, the paths the legs take that create speed and mechanical advantage is biomechanical. Running Velocity Running velocity is a product of stride length times frequency. Each athlete has a unique combination of the two at different running speeds. Common analysis of stride length and frequency mistakenly show the two inversely related. Stride length frequency are interdependent, where the relationship is based on the amount of resistance that must be overcome. Power (force X velocity) generated by the muscles improves stride length and frequency. The velocity component of power allows more work to be done (stride length) and increases stride speed (stride frequency). ARMS Coordinated movement of arms and legs remains the key to efficient sprinting. It is through range and force that the two coordinate. While the movement coordinates, arms lead legs in tempo and range. The following method of movement produces the proper range and force necessitated by the legs. The hand is positioned approximately shoulder-high, but not exceeding the chin, and slightly in front of the chest (Fig. 8). From this point, the hand initiates the downward stroke by flipping downward while the upper arm rotates backwards from the shoulder, and the elbow joint opens or increases the angle between forearm and upper arm (Fig. 7). After the hand passes by the hip, the elbow joint begins to close again and drives backwards and upwards while the shoulder continues rotating through full range of motion (Fig. 6). The swing forward requires a reversal of this process, where the elbow opens again while passing by the hip but closes after passing the hip until he hand achieves the approximate-shoulder-high position. Forearms and chest remain as relaxed as possible.
Scientifically speaking, the shoulder is the axis of rotation for the arm, while the elbow acts to shorten the lever when necessary. Closing the angle reduces the moment of arm inertia, increasing angular velocity, in turn creating quicker turnover. Arm movement without utilizing the elbow joint produces a straight-arm, pendular-like swing moving much too slow for leg coordination. Arm swing can allow for greater takeoff distance, enhancing stride length. Leg Action Overview The vertical force comes at take-off when the mass is elevated by pushing downward (pushing off the heel back onto the ball of the foot). The recovery foot steps up and over the drive knee as the foot takes the shortest path to the front of the body as the center of mass rises above the surface (Fig. 7 & 8). The knee then raises and extends as the foot moves forward and the shin becomes plumb (Fig. 7). The thigh drops towards the ground while the knee extends, causing the foot to have a negative velocity at foot placement. As the athlete builds momentum (mass X velocity) the ratio between both forces (vertical and horizontal) increases as the net horizontal force decreases. The stride becomes progressively quicker and longer as stride frequency and length are optimized. Stretch Reflex The stretch reflex acts similarly to loading a “Y” sling shot, or forked sling shot. Before shooting the projectile, it remains poised in the stretched elastic, just as the hip flexors remain stretched before the recovery phase. When the sling shot elastic is released, it pops back into original form, sending away the projectile. Novacheck along with Vaughan claim that sprint efficiency is due in part to “the storage and later return of elastic potential energy by the stretch of elastic structures (especially tendons)” (Novacheck 81). Furthermore, stretched tendons efficiently return energy upon recoil (Novacheck 84). The stretch reflex refers mainly to the knee cycling during the recovery phase. Knee Action The sling shot release parallels the leg recovery phase: the knee cycles through because the hip flexor pops back into normal position from its stretched position. Therefore, the knee coming through occurs naturally and does not necessitate an athlete’s conscious effort. Furthermore consciously lifting the knee high while sprinting inhibits the legs natural timing during the recovery phase. Consciously creating a high knee lift or normal knee lift is like stretching back a sling shot with projectile and helping push the projectile with the hand while the elastic is releasing. The action would cause a reduction of elastic force, resulting in slower movement with the sling shot as well as with sprinting. Scientific Overview
Start At the start, mass is at rest. The property of inertia inherent in the mass resists changes in velocity (a vector with magnitude and direction) and according to Newton’s first law will maintain this velocity unless acted on by an external force. The amount of inertia within the mass is proportional to the amount of mass; objects with more mass require more force to move initially. When the sprinter applies force to the blocks, inertia is overcome and linear movement begins. Stride length and frequency are low because of inertia. This is why the first stride is the slowest and shortest. Force is initially applied backward and downward where the shin angles somewhat close to the ground and behind the knee. This motion is piston-like as it pushes the mass forward from its rest state. Horizontal impulse is greatest at this point (Weyand et al. 1991) but diminishes as mass increases speed. It is the net force that causes the mass to accelerate: the difference in mass forward force and the pushing force. At the start of a run when resistance is at its highest, it is easier to increase stride length because force needs something to work against. Acceleration Shortly after starting, stride length and frequency increase. As momentum builds, stride length tends to stabilize as momentum builds, resistance diminishes and net force approaches zero. Concurrently, frequency increases because resistance constantly decreases. In short sprints, it is important to accelerate over the longest possible distance in the shortest amount of time and try to maintain and decelerate gracefully. After the athlete has been successful in setting the body in motion, and the center of mass begins to gain momentum, a toppling would occur if the feet continued to go backward and downward. The acceleration process then goes through a mechanical transition where the legs go through the form of cycling motion. The lever lengthens to give a mechanical advantage and shortens on the recovery phase to give a speed advantage. The position of the body dictates how reactive forces affect the center of mass. The center of mass accelerates at a decreasing rate until maximum velocity (top speed) is attained. At max speed, the net horizontal force applied is zero. The ground tends to recede faster when the body picks up speed, resulting in reduction of contact time as well as effective force because of reduction in resistance. At this point in the race, the athlete tries to keep the effective force at zero until the net horizontal force becomes negative. When body momentum becomes greater than that of the legs, the body starts toppling over, causing a braking action each time the foot hits the ground. At this point, the athlete tries to relax and lets momentum of the mass take the body down the track. Movement
The human body is engineered to utilize a series of lever systems (third class) where force acts between the axis and the resistance. For any movement to occur, the lever must rotate around its axis. Based on this premise, it is safe to say that the origin of movement is rotary. Rotary motion simply refers to bodily motion. It is the interaction of physical laws and body levers. For an object to rotate, it must have two different types of forces acting on it at right angles: a centripetal or centrifugal force and tangential force. Centripetal and centrifugal forces cause objects to move toward the point of rotation, known as the axis. The axial or tangential force causes object to move perpendicularly in relation to the radius. In the human machine, force is closer than resistance to the axis. To illustrate, a sprinter resists the ground while producing movement and force with the thigh. This relationship makes the lever very inefficient because more torque is required for movement. For the sprinter, it is essential that the lever move through the full range of movement fast, requiring a torque (turning force) both forward and backward. Torque (force X movement arm) contributes to the angular velocity of the lever. If the length of the lever is constant, the lever would oscillate like a pendulum. But because lever length changes so does angular velocity, for any given force. Thus the angular velocity ties the length of the lever produces the linear velocity at the point farthest away from the axis. Both the arm and leg movement efficiency benefit from the ability to lengthen or shorten levers. By lengthening and shortening the lever, the athlete can change the moment of inertia (resistance to movement). The farther the moment of inertia (mass X radius) is away from the point of rotation, the harder it is to change motion. With a given amount of force, a shorter lever with the same mass as a longer lever would rotate faster than the longer but would have a mechanical disadvantage. It will therefore take more torque (moment of inertia X angular acceleration) to turn the longer lever than it would to turn the shorter. If no additional turning force is applied to the lever, angular momentum (moment of inertia X angular velocity) is conserved. An increase or decline in the moment of inertia will cause decline or increase in angular velocity respectively. This inverse relationship between the moment of inertia and angular velocity in the conservation of angular velocity in the conservation of angular momentum is one of the keys to great sprinting. Common Errors Stressing stride length or stride frequency
Debate on the best way of improving sprint speed focuses on two issues: increasing stride length versus increasing frequency. We are limited physiologically to the amount of strides than can be performed in a second. It is true that most good sprint athletes have just about the same frequency. So, an athlete with adequate conditioning who takes the longest strides usually wins. Stressing stride frequency alone results in inefficient sprint technique. Common knowledge portrays stride frequency as a speed advantage. However, stride frequency differs from stride speed. Stride speed is angular velocity of a stride, while frequency is the number of strides, or impulses, per second. Even if a sprinter has the fastest turnover, without proper force application, stride length will be small. This is because frequency alone does cause linear motion; applying force to the ground does. Proper force application results in stride length and frequency increases. Stride speed is involuntarily increased by the conservation of angular momentum. Shortening the radius, thus reducing the moment of inertia, results in an increase of angular velocity. The shorting of the lever occurs after the foot breaks contact with the ground. This movement is the response of the forces being applied correctly to the ground and is non-volitional. Illusion of Speed There is an illusion of speed when then lever does not go through the full range of motion; each movement looks and feels faster. For example if stride frequency is stressed, an athlete may not allow the hip extend through full range of motion to reap whatever benefits he created from applying force to the ground. Lack of hip extension detracts from momentum and ultimately decreases speed because of inefficiency. But the objective is not to move the lever fast but rather transport the mass down the track in the least time possible. Avoiding full range of motion also sacrifices proper force application. Leg preactivation: pawing action Pawing action is actually an illusion resulting from rapid hip extension. Too much voluntary action at the knees and ankles causes a reduction in angular velocity of the hip, which is the prime generator of force. Force causes motion while speed is a measurement of motion. Cyclic force is applied from the hip (radial force) which results in tangential motion of the foot. At foot placement, the shin should be approximately 90 degrees to the ground (Fig. 5). As the center of mass passes over the point of support, the heel briefly touches the ground and the ankle angle closes. This motion puts the Achilles tendon and calf in a stretch position while the knee is bent, allowing a greater push off force from the ball of the foot. Hips extend in one continuous motion from the knee lift position through the end of the push off
with no pauses in hip extension at foot contact. High knee lift Please see “Knee action” Reach and Pull Running action such as reaching and pulling with the hamstrings has been scientifically proven not to produce the most efficient movement (Weyand et. al. 1998). This running style is inefficient because it does not utilize the stretch reflex, but instead requires more muscle forces and volumes per unit of force applied to the ground (Weyand et al. 1998). Summary Scientific research across the world has yet to penetrate the track and field world. Athletes can be better sprinters with scientifically proven sprint technique. Better sprinters require coaches who are willing to learn scientific principles as well as a method of communicating their knowledge to the athlete. Works Cited Novacheck, Tom F. The biomechanics of running. Motion Analysis Laboratory, Gillette Children’s Specialty Healthcare, University of Minnesota. 1998; 77-95. Vaughan C.I. Biomechanics of running gait. Crit Rev Eng 12: 1-48 Weyand, Peter G., Deborah B. Sternlight, Matthew J. Bellizzi, and Seth Wright. Faster top running speeds are achieved with greater ground forces not more rapid leg movements. Journal of Applied Physiology 89: 1999-2000.

Recommended

The Biomechanics of Sprinting
The Biomechanics of SprintingThe Biomechanics of Sprinting
The Biomechanics of SprintingAthletics Northern Ireland
 
Coaching Sprint Mechanics. What to look for. What to say.
Coaching Sprint Mechanics. What to look for. What to say. Coaching Sprint Mechanics. What to look for. What to say.
Coaching Sprint Mechanics. What to look for. What to say. Mike Young
 
Neuromechanics of Speed Development
Neuromechanics of Speed DevelopmentNeuromechanics of Speed Development
Neuromechanics of Speed DevelopmentMike Young
 
The 100m Sprint: a Basic Needs Analysis
The 100m Sprint: a Basic Needs AnalysisThe 100m Sprint: a Basic Needs Analysis
The 100m Sprint: a Basic Needs AnalysisJill Costley
 
Fundamental Motor Learning Concepts for Coaches
Fundamental Motor Learning Concepts for CoachesFundamental Motor Learning Concepts for Coaches
Fundamental Motor Learning Concepts for CoachesMike Young
 
Science & Practice of Elite Speed Development
Science & Practice of Elite Speed DevelopmentScience & Practice of Elite Speed Development
Science & Practice of Elite Speed DevelopmentMike Young
 
Biomechanics of Jumping
Biomechanics of Jumping Biomechanics of Jumping
Biomechanics of Jumping Dr Nishank Verma
 
Bompa's Periodization for Sports Training
Bompa's Periodization for Sports TrainingBompa's Periodization for Sports Training
Bompa's Periodization for Sports TrainingJoel Smith
 

Recommended

The Biomechanics of Sprinting
The Biomechanics of SprintingThe Biomechanics of Sprinting
The Biomechanics of SprintingAthletics Northern Ireland
 
Coaching Sprint Mechanics. What to look for. What to say.
Coaching Sprint Mechanics. What to look for. What to say. Coaching Sprint Mechanics. What to look for. What to say.
Coaching Sprint Mechanics. What to look for. What to say. Mike Young
 
Neuromechanics of Speed Development
Neuromechanics of Speed DevelopmentNeuromechanics of Speed Development
Neuromechanics of Speed DevelopmentMike Young
 
The 100m Sprint: a Basic Needs Analysis
The 100m Sprint: a Basic Needs AnalysisThe 100m Sprint: a Basic Needs Analysis
The 100m Sprint: a Basic Needs AnalysisJill Costley
 
Fundamental Motor Learning Concepts for Coaches
Fundamental Motor Learning Concepts for CoachesFundamental Motor Learning Concepts for Coaches
Fundamental Motor Learning Concepts for CoachesMike Young
 
Science & Practice of Elite Speed Development
Science & Practice of Elite Speed DevelopmentScience & Practice of Elite Speed Development
Science & Practice of Elite Speed DevelopmentMike Young
 
Biomechanics of Jumping
Biomechanics of Jumping Biomechanics of Jumping
Biomechanics of Jumping Dr Nishank Verma
 
Bompa's Periodization for Sports Training
Bompa's Periodization for Sports TrainingBompa's Periodization for Sports Training
Bompa's Periodization for Sports TrainingJoel Smith
 
Speed Training For Sports Performance
Speed Training For Sports PerformanceSpeed Training For Sports Performance
Speed Training For Sports PerformanceMidwest Conditioning Systems
 
Biomechanic of Swimming
Biomechanic of SwimmingBiomechanic of Swimming
Biomechanic of Swimmingshahrul
 
James Hillier - Training Essentials for the Development of an Advanced High H...
James Hillier - Training Essentials for the Development of an Advanced High H...James Hillier - Training Essentials for the Development of an Advanced High H...
James Hillier - Training Essentials for the Development of an Advanced High H...Athletics Northern Ireland
 
Strength and Conditioning: Training Intensity
Strength and Conditioning: Training IntensityStrength and Conditioning: Training Intensity
Strength and Conditioning: Training IntensityJoel Smith
 
Periodisation models
Periodisation models Periodisation models
Periodisation models Jamie Knight
 
HamStrong: Examining hamstring injuries & what we can do to prevent them
HamStrong: Examining hamstring injuries & what we can do to prevent themHamStrong: Examining hamstring injuries & what we can do to prevent them
HamStrong: Examining hamstring injuries & what we can do to prevent themMike Young
 
Athlete Specific Strength Training Lecture
Athlete Specific Strength Training LectureAthlete Specific Strength Training Lecture
Athlete Specific Strength Training LectureJoel Smith
 
Phase Potentiation within Speed Development
Phase Potentiation within Speed DevelopmentPhase Potentiation within Speed Development
Phase Potentiation within Speed Developmentdlive11
 
Strength Training for Track & Field
Strength Training for Track & FieldStrength Training for Track & Field
Strength Training for Track & FieldJohn Grace
 
Ruf - Strength Training for Sprinters
Ruf - Strength Training for SprintersRuf - Strength Training for Sprinters
Ruf - Strength Training for SprintersBaylor University
 
maximal Strength training
maximal Strength trainingmaximal Strength training
maximal Strength trainingMahdi Cheraghi
 
Carrera de vallas 1
Carrera de vallas 1Carrera de vallas 1
Carrera de vallas 1asunsinobas
 
Chapter Planning of Competitions & Periodization
Chapter Planning of Competitions & Periodization Chapter Planning of Competitions & Periodization
Chapter Planning of Competitions & Periodization Ashish Phulkar
 
Biomotor Development for the Speed-Power Athlete
Biomotor Development for the Speed-Power AthleteBiomotor Development for the Speed-Power Athlete
Biomotor Development for the Speed-Power AthleteMike Young
 
Implementing a Mechanical Model for Plyometric Progressions
Implementing a Mechanical Model for Plyometric Progressions Implementing a Mechanical Model for Plyometric Progressions
Implementing a Mechanical Model for Plyometric Progressions Mike Young
 
Principles and practices of agility training
Principles and practices of agility trainingPrinciples and practices of agility training
Principles and practices of agility trainingJohn Cissik
 
Entrenamiento de la velocidad
Entrenamiento de la velocidadEntrenamiento de la velocidad
Entrenamiento de la velocidadFelipe Vargas Rios
 
Strength Training for Track and Field
Strength Training for Track and FieldStrength Training for Track and Field
Strength Training for Track and FieldJohn Cissik
 
Entrenamiento de Niños Y Púberes
Entrenamiento de Niños Y PúberesEntrenamiento de Niños Y Púberes
Entrenamiento de Niños Y PúberesAndrés Acevedo
 
Entrenamiento de la fuerza
Entrenamiento de la fuerzaEntrenamiento de la fuerza
Entrenamiento de la fuerzaLuis Fernando Gonzalez Arango
 
Biomechanics of ADL-I
Biomechanics of ADL-IBiomechanics of ADL-I
Biomechanics of ADL-IRadhika Chintamani
 
Year 11 biomechanics with levers, force summation
Year 11 biomechanics with levers, force summationYear 11 biomechanics with levers, force summation
Year 11 biomechanics with levers, force summationryanm9
 

More Related Content

What's hot

Biomechanic of Swimming
Biomechanic of SwimmingBiomechanic of Swimming
Biomechanic of Swimmingshahrul
 
James Hillier - Training Essentials for the Development of an Advanced High H...
James Hillier - Training Essentials for the Development of an Advanced High H...James Hillier - Training Essentials for the Development of an Advanced High H...
James Hillier - Training Essentials for the Development of an Advanced High H...Athletics Northern Ireland
 
Strength and Conditioning: Training Intensity
Strength and Conditioning: Training IntensityStrength and Conditioning: Training Intensity
Strength and Conditioning: Training IntensityJoel Smith
 
Periodisation models
Periodisation models Periodisation models
Periodisation models Jamie Knight
 
HamStrong: Examining hamstring injuries & what we can do to prevent them
HamStrong: Examining hamstring injuries & what we can do to prevent themHamStrong: Examining hamstring injuries & what we can do to prevent them
HamStrong: Examining hamstring injuries & what we can do to prevent themMike Young
 
Athlete Specific Strength Training Lecture
Athlete Specific Strength Training LectureAthlete Specific Strength Training Lecture
Athlete Specific Strength Training LectureJoel Smith
 
Phase Potentiation within Speed Development
Phase Potentiation within Speed DevelopmentPhase Potentiation within Speed Development
Phase Potentiation within Speed Developmentdlive11
 
Strength Training for Track & Field
Strength Training for Track & FieldStrength Training for Track & Field
Strength Training for Track & FieldJohn Grace
 
Ruf - Strength Training for Sprinters
Ruf - Strength Training for SprintersRuf - Strength Training for Sprinters
Ruf - Strength Training for SprintersBaylor University
 
maximal Strength training
maximal Strength trainingmaximal Strength training
maximal Strength trainingMahdi Cheraghi
 
Carrera de vallas 1
Carrera de vallas 1Carrera de vallas 1
Carrera de vallas 1asunsinobas
 
Chapter Planning of Competitions & Periodization
Chapter Planning of Competitions & Periodization Chapter Planning of Competitions & Periodization
Chapter Planning of Competitions & Periodization Ashish Phulkar
 
Biomotor Development for the Speed-Power Athlete
Biomotor Development for the Speed-Power AthleteBiomotor Development for the Speed-Power Athlete
Biomotor Development for the Speed-Power AthleteMike Young
 
Implementing a Mechanical Model for Plyometric Progressions
Implementing a Mechanical Model for Plyometric Progressions Implementing a Mechanical Model for Plyometric Progressions
Implementing a Mechanical Model for Plyometric Progressions Mike Young
 
Principles and practices of agility training
Principles and practices of agility trainingPrinciples and practices of agility training
Principles and practices of agility trainingJohn Cissik
 
Strength Training for Track and Field
Strength Training for Track and FieldStrength Training for Track and Field
Strength Training for Track and FieldJohn Cissik
 
Entrenamiento de Niños Y Púberes
Entrenamiento de Niños Y PúberesEntrenamiento de Niños Y Púberes
Entrenamiento de Niños Y PúberesAndrés Acevedo
 

What's hot (20)

Speed Training For Sports Performance
Speed Training For Sports PerformanceSpeed Training For Sports Performance
Speed Training For Sports Performance
 
Biomechanic of Swimming
Biomechanic of SwimmingBiomechanic of Swimming
Biomechanic of Swimming
 
James Hillier - Training Essentials for the Development of an Advanced High H...
James Hillier - Training Essentials for the Development of an Advanced High H...James Hillier - Training Essentials for the Development of an Advanced High H...
James Hillier - Training Essentials for the Development of an Advanced High H...
 
Strength and Conditioning: Training Intensity
Strength and Conditioning: Training IntensityStrength and Conditioning: Training Intensity
Strength and Conditioning: Training Intensity
 
Periodisation models
Periodisation models Periodisation models
Periodisation models
 
HamStrong: Examining hamstring injuries & what we can do to prevent them
HamStrong: Examining hamstring injuries & what we can do to prevent themHamStrong: Examining hamstring injuries & what we can do to prevent them
HamStrong: Examining hamstring injuries & what we can do to prevent them
 
Athlete Specific Strength Training Lecture
Athlete Specific Strength Training LectureAthlete Specific Strength Training Lecture
Athlete Specific Strength Training Lecture
 
Phase Potentiation within Speed Development
Phase Potentiation within Speed DevelopmentPhase Potentiation within Speed Development
Phase Potentiation within Speed Development
 
Strength Training for Track & Field
Strength Training for Track & FieldStrength Training for Track & Field
Strength Training for Track & Field
 
Ruf - Strength Training for Sprinters
Ruf - Strength Training for SprintersRuf - Strength Training for Sprinters
Ruf - Strength Training for Sprinters
 
maximal Strength training
maximal Strength trainingmaximal Strength training
maximal Strength training
 
Carrera de vallas 1
Carrera de vallas 1Carrera de vallas 1
Carrera de vallas 1
 
Chapter Planning of Competitions & Periodization
Chapter Planning of Competitions & Periodization Chapter Planning of Competitions & Periodization
Chapter Planning of Competitions & Periodization
 
Biomotor Development for the Speed-Power Athlete
Biomotor Development for the Speed-Power AthleteBiomotor Development for the Speed-Power Athlete
Biomotor Development for the Speed-Power Athlete
 
Implementing a Mechanical Model for Plyometric Progressions
Implementing a Mechanical Model for Plyometric Progressions Implementing a Mechanical Model for Plyometric Progressions
Implementing a Mechanical Model for Plyometric Progressions
 
Principles and practices of agility training
Principles and practices of agility trainingPrinciples and practices of agility training
Principles and practices of agility training
 
Entrenamiento de la velocidad
Entrenamiento de la velocidadEntrenamiento de la velocidad
Entrenamiento de la velocidad
 
Strength Training for Track and Field
Strength Training for Track and FieldStrength Training for Track and Field
Strength Training for Track and Field
 
Entrenamiento de Niños Y Púberes
Entrenamiento de Niños Y PúberesEntrenamiento de Niños Y Púberes
Entrenamiento de Niños Y Púberes
 
Entrenamiento de la fuerza
Entrenamiento de la fuerzaEntrenamiento de la fuerza
Entrenamiento de la fuerza
 

Similar to Tom tellez sprinting a biomechanical approach

Year 11 biomechanics with levers, force summation
Year 11 biomechanics with levers, force summationYear 11 biomechanics with levers, force summation
Year 11 biomechanics with levers, force summationryanm9
 
Biomechanics and Sports
Biomechanics and Sports Biomechanics and Sports
Biomechanics and Sports Vibha Choudhary
 
HUMAN GAIT.pptx............................
HUMAN GAIT.pptx............................HUMAN GAIT.pptx............................
HUMAN GAIT.pptx............................IshaKanojiya1
 
Kinematics and kinetics of gait
Kinematics and kinetics of gaitKinematics and kinetics of gait
Kinematics and kinetics of gaitSukanya1411
 
Sports biomechaniscs
Sports biomechaniscsSports biomechaniscs
Sports biomechaniscsXerosAyer
 
Biomechanics 1 (intro, levers, planes and axis) 2015
Biomechanics 1 (intro, levers, planes and axis) 2015Biomechanics 1 (intro, levers, planes and axis) 2015
Biomechanics 1 (intro, levers, planes and axis) 2015Kerry Harrison
 
Basic Principles of Kinesiology
Basic Principles of KinesiologyBasic Principles of Kinesiology
Basic Principles of Kinesiologyjoldham5
 
UNIT - 9 - BIOMECHANICS AND SPORTS
UNIT - 9 - BIOMECHANICS AND SPORTSUNIT - 9 - BIOMECHANICS AND SPORTS
UNIT - 9 - BIOMECHANICS AND SPORTSMahendra Rajak
 
Healthy Running the Body in Balance
Healthy Running the Body in BalanceHealthy Running the Body in Balance
Healthy Running the Body in BalanceCharles Curtis
 
Sitting to Standing Mechanism and Osteoarthritis
Sitting to Standing Mechanism and OsteoarthritisSitting to Standing Mechanism and Osteoarthritis
Sitting to Standing Mechanism and OsteoarthritisStephan Van Breenen
 
SPORT ANATOMY GROUP 7.pptx
SPORT ANATOMY GROUP 7.pptxSPORT ANATOMY GROUP 7.pptx
SPORT ANATOMY GROUP 7.pptxIdowuSolomon1
 
Lecture 5 task specific strength2_(pt2) ppt
Lecture 5 task specific strength2_(pt2) pptLecture 5 task specific strength2_(pt2) ppt
Lecture 5 task specific strength2_(pt2) pptJoel Smith
 
Ch.8 biomechanics & sports
Ch.8 biomechanics & sportsCh.8 biomechanics & sports
Ch.8 biomechanics & sportsSandeep Tiwari
 

Similar to Tom tellez sprinting a biomechanical approach (20)

Biomechanics of ADL-I
Biomechanics of ADL-IBiomechanics of ADL-I
Biomechanics of ADL-I
 
Year 11 biomechanics with levers, force summation
Year 11 biomechanics with levers, force summationYear 11 biomechanics with levers, force summation
Year 11 biomechanics with levers, force summation
 
Biomechanics and Sports
Biomechanics and Sports Biomechanics and Sports
Biomechanics and Sports
 
Biomechanics in sports
Biomechanics in sportsBiomechanics in sports
Biomechanics in sports
 
HUMAN GAIT.pptx............................
HUMAN GAIT.pptx............................HUMAN GAIT.pptx............................
HUMAN GAIT.pptx............................
 
Hamstring
Hamstring Hamstring
Hamstring
 
Kinematics and kinetics of gait
Kinematics and kinetics of gaitKinematics and kinetics of gait
Kinematics and kinetics of gait
 
Sports biomechaniscs
Sports biomechaniscsSports biomechaniscs
Sports biomechaniscs
 
Human Gait
Human GaitHuman Gait
Human Gait
 
Biomechanics 1 (intro, levers, planes and axis) 2015
Biomechanics 1 (intro, levers, planes and axis) 2015Biomechanics 1 (intro, levers, planes and axis) 2015
Biomechanics 1 (intro, levers, planes and axis) 2015
 
Basic Principles of Kinesiology
Basic Principles of KinesiologyBasic Principles of Kinesiology
Basic Principles of Kinesiology
 
UNIT - 9 - BIOMECHANICS AND SPORTS
UNIT - 9 - BIOMECHANICS AND SPORTSUNIT - 9 - BIOMECHANICS AND SPORTS
UNIT - 9 - BIOMECHANICS AND SPORTS
 
An421+2021
An421+2021An421+2021
An421+2021
 
Healthy Running the Body in Balance
Healthy Running the Body in BalanceHealthy Running the Body in Balance
Healthy Running the Body in Balance
 
Sitting to Standing Mechanism and Osteoarthritis
Sitting to Standing Mechanism and OsteoarthritisSitting to Standing Mechanism and Osteoarthritis
Sitting to Standing Mechanism and Osteoarthritis
 
GAIT.pptx
GAIT.pptxGAIT.pptx
GAIT.pptx
 
SPORT ANATOMY GROUP 7.pptx
SPORT ANATOMY GROUP 7.pptxSPORT ANATOMY GROUP 7.pptx
SPORT ANATOMY GROUP 7.pptx
 
Lecture 5 task specific strength2_(pt2) ppt
Lecture 5 task specific strength2_(pt2) pptLecture 5 task specific strength2_(pt2) ppt
Lecture 5 task specific strength2_(pt2) ppt
 
Sport science
Sport scienceSport science
Sport science
 
Ch.8 biomechanics & sports
Ch.8 biomechanics & sportsCh.8 biomechanics & sports
Ch.8 biomechanics & sports
 

More from Flavio Clesio

Machine Learning Operations Active Failures, Latent Conditions
Machine Learning Operations Active Failures, Latent ConditionsMachine Learning Operations Active Failures, Latent Conditions
Machine Learning Operations Active Failures, Latent ConditionsFlavio Clesio
 
Security in Machine Learning
Security in Machine LearningSecurity in Machine Learning
Security in Machine LearningFlavio Clesio
 
Machine Learning Operations (MLOps) - Active Failures and Latent Conditions
Machine Learning Operations (MLOps) - Active Failures and Latent ConditionsMachine Learning Operations (MLOps) - Active Failures and Latent Conditions
Machine Learning Operations (MLOps) - Active Failures and Latent ConditionsFlavio Clesio
 
Apache Spark: Casos de uso e escalabilidade
Apache Spark: Casos de uso e escalabilidadeApache Spark: Casos de uso e escalabilidade
Apache Spark: Casos de uso e escalabilidadeFlavio Clesio
 
Spark Summit EU 2017 - Preventing revenue leakage and monitoring distributed ...
Spark Summit EU 2017 - Preventing revenue leakage and monitoring distributed ...Spark Summit EU 2017 - Preventing revenue leakage and monitoring distributed ...
Spark Summit EU 2017 - Preventing revenue leakage and monitoring distributed ...Flavio Clesio
 
SP Big Data Meetup - March/16
SP Big Data Meetup - March/16SP Big Data Meetup - March/16
SP Big Data Meetup - March/16Flavio Clesio
 
Loren seagrave neuro biomechanics of maximum velocity sprinting
Loren seagrave neuro biomechanics of maximum velocity sprintingLoren seagrave neuro biomechanics of maximum velocity sprinting
Loren seagrave neuro biomechanics of maximum velocity sprintingFlavio Clesio
 
Dan pfaff - guidelines for plyometric training
Dan pfaff - guidelines for plyometric trainingDan pfaff - guidelines for plyometric training
Dan pfaff - guidelines for plyometric trainingFlavio Clesio
 
Planilha De Treinos - 100 Metros
Planilha De Treinos - 100 MetrosPlanilha De Treinos - 100 Metros
Planilha De Treinos - 100 MetrosFlavio Clesio
 

More from Flavio Clesio (10)

Machine Learning Operations Active Failures, Latent Conditions
Machine Learning Operations Active Failures, Latent ConditionsMachine Learning Operations Active Failures, Latent Conditions
Machine Learning Operations Active Failures, Latent Conditions
 
Security in Machine Learning
Security in Machine LearningSecurity in Machine Learning
Security in Machine Learning
 
Machine Learning Operations (MLOps) - Active Failures and Latent Conditions
Machine Learning Operations (MLOps) - Active Failures and Latent ConditionsMachine Learning Operations (MLOps) - Active Failures and Latent Conditions
Machine Learning Operations (MLOps) - Active Failures and Latent Conditions
 
Apache Spark: Casos de uso e escalabilidade
Apache Spark: Casos de uso e escalabilidadeApache Spark: Casos de uso e escalabilidade
Apache Spark: Casos de uso e escalabilidade
 
Spark Summit EU 2017 - Preventing revenue leakage and monitoring distributed ...
Spark Summit EU 2017 - Preventing revenue leakage and monitoring distributed ...Spark Summit EU 2017 - Preventing revenue leakage and monitoring distributed ...
Spark Summit EU 2017 - Preventing revenue leakage and monitoring distributed ...
 
SP Big Data Meetup - March/16
SP Big Data Meetup - March/16SP Big Data Meetup - March/16
SP Big Data Meetup - March/16
 
Loren seagrave neuro biomechanics of maximum velocity sprinting
Loren seagrave neuro biomechanics of maximum velocity sprintingLoren seagrave neuro biomechanics of maximum velocity sprinting
Loren seagrave neuro biomechanics of maximum velocity sprinting
 
Dan pfaff - guidelines for plyometric training
Dan pfaff - guidelines for plyometric trainingDan pfaff - guidelines for plyometric training
Dan pfaff - guidelines for plyometric training
 
Mini Atletismo
Mini AtletismoMini Atletismo
Mini Atletismo
 
Planilha De Treinos - 100 Metros
Planilha De Treinos - 100 MetrosPlanilha De Treinos - 100 Metros
Planilha De Treinos - 100 Metros
 

Recently uploaded

From Event to Action: Accelerate Your Decision Making with Real-Time Automation
From Event to Action: Accelerate Your Decision Making with Real-Time AutomationFrom Event to Action: Accelerate Your Decision Making with Real-Time Automation
From Event to Action: Accelerate Your Decision Making with Real-Time AutomationSafe Software
 
A Domino Admins Adventures (Engage 2024)
A Domino Admins Adventures (Engage 2024)A Domino Admins Adventures (Engage 2024)
A Domino Admins Adventures (Engage 2024)Gabriella Davis
 
Breaking the Kubernetes Kill Chain: Host Path Mount
Breaking the Kubernetes Kill Chain: Host Path MountBreaking the Kubernetes Kill Chain: Host Path Mount
Breaking the Kubernetes Kill Chain: Host Path MountPuma Security, LLC
 
The 7 Things I Know About Cyber Security After 25 Years | April 2024
The 7 Things I Know About Cyber Security After 25 Years | April 2024The 7 Things I Know About Cyber Security After 25 Years | April 2024
The 7 Things I Know About Cyber Security After 25 Years | April 2024Rafal Los
 
Automating Google Workspace (GWS) & more with Apps Script
Automating Google Workspace (GWS) & more with Apps ScriptAutomating Google Workspace (GWS) & more with Apps Script
Automating Google Workspace (GWS) & more with Apps Scriptwesley chun
 
08448380779 Call Girls In Friends Colony Women Seeking Men
08448380779 Call Girls In Friends Colony Women Seeking Men08448380779 Call Girls In Friends Colony Women Seeking Men
08448380779 Call Girls In Friends Colony Women Seeking MenDelhi Call girls
 
Strategies for Unlocking Knowledge Management in Microsoft 365 in the Copilot...
Strategies for Unlocking Knowledge Management in Microsoft 365 in the Copilot...Strategies for Unlocking Knowledge Management in Microsoft 365 in the Copilot...
Strategies for Unlocking Knowledge Management in Microsoft 365 in the Copilot...Drew Madelung
 
04-2024-HHUG-Sales-and-Marketing-Alignment.pptx
04-2024-HHUG-Sales-and-Marketing-Alignment.pptx04-2024-HHUG-Sales-and-Marketing-Alignment.pptx
04-2024-HHUG-Sales-and-Marketing-Alignment.pptxHampshireHUG
 
Bajaj Allianz Life Insurance Company - Insurer Innovation Award 2024
Bajaj Allianz Life Insurance Company - Insurer Innovation Award 2024Bajaj Allianz Life Insurance Company - Insurer Innovation Award 2024
Bajaj Allianz Life Insurance Company - Insurer Innovation Award 2024The Digital Insurer
 
2024: Domino Containers - The Next Step. News from the Domino Container commu...
2024: Domino Containers - The Next Step. News from the Domino Container commu...2024: Domino Containers - The Next Step. News from the Domino Container commu...
2024: Domino Containers - The Next Step. News from the Domino Container commu...Martijn de Jong
 
EIS-Webinar-Prompt-Knowledge-Eng-2024-04-08.pptx
EIS-Webinar-Prompt-Knowledge-Eng-2024-04-08.pptxEIS-Webinar-Prompt-Knowledge-Eng-2024-04-08.pptx
EIS-Webinar-Prompt-Knowledge-Eng-2024-04-08.pptxEarley Information Science
 
A Year of the Servo Reboot: Where Are We Now?
A Year of the Servo Reboot: Where Are We Now?A Year of the Servo Reboot: Where Are We Now?
A Year of the Servo Reboot: Where Are We Now?Igalia
 
Driving Behavioral Change for Information Management through Data-Driven Gree...
Driving Behavioral Change for Information Management through Data-Driven Gree...Driving Behavioral Change for Information Management through Data-Driven Gree...
Driving Behavioral Change for Information Management through Data-Driven Gree...Enterprise Knowledge
 
Slack Application Development 101 Slides
Slack Application Development 101 SlidesSlack Application Development 101 Slides
Slack Application Development 101 Slidespraypatel2
 
Workshop - Best of Both Worlds_ Combine KG and Vector search for enhanced R...
Workshop - Best of Both Worlds_ Combine KG and Vector search for enhanced R...Workshop - Best of Both Worlds_ Combine KG and Vector search for enhanced R...
Workshop - Best of Both Worlds_ Combine KG and Vector search for enhanced R...Neo4j
 
Advantages of Hiring UIUX Design Service Providers for Your Business
Advantages of Hiring UIUX Design Service Providers for Your BusinessAdvantages of Hiring UIUX Design Service Providers for Your Business
Advantages of Hiring UIUX Design Service Providers for Your BusinessPixlogix Infotech
 
Powerful Google developer tools for immediate impact! (2023-24 C)
Powerful Google developer tools for immediate impact! (2023-24 C)Powerful Google developer tools for immediate impact! (2023-24 C)
Powerful Google developer tools for immediate impact! (2023-24 C)wesley chun
 
Presentation on how to chat with PDF using ChatGPT code interpreter
Presentation on how to chat with PDF using ChatGPT code interpreterPresentation on how to chat with PDF using ChatGPT code interpreter
Presentation on how to chat with PDF using ChatGPT code interpreternaman860154
 
Artificial Intelligence: Facts and Myths
Artificial Intelligence: Facts and MythsArtificial Intelligence: Facts and Myths
Artificial Intelligence: Facts and MythsJoaquim Jorge
 
Scaling API-first – The story of a global engineering organization
Scaling API-first – The story of a global engineering organizationScaling API-first – The story of a global engineering organization
Scaling API-first – The story of a global engineering organizationRadu Cotescu
 

Recently uploaded (20)

From Event to Action: Accelerate Your Decision Making with Real-Time Automation
From Event to Action: Accelerate Your Decision Making with Real-Time AutomationFrom Event to Action: Accelerate Your Decision Making with Real-Time Automation
From Event to Action: Accelerate Your Decision Making with Real-Time Automation
 
A Domino Admins Adventures (Engage 2024)
A Domino Admins Adventures (Engage 2024)A Domino Admins Adventures (Engage 2024)
A Domino Admins Adventures (Engage 2024)
 
Breaking the Kubernetes Kill Chain: Host Path Mount
Breaking the Kubernetes Kill Chain: Host Path MountBreaking the Kubernetes Kill Chain: Host Path Mount
Breaking the Kubernetes Kill Chain: Host Path Mount
 
The 7 Things I Know About Cyber Security After 25 Years | April 2024
The 7 Things I Know About Cyber Security After 25 Years | April 2024The 7 Things I Know About Cyber Security After 25 Years | April 2024
The 7 Things I Know About Cyber Security After 25 Years | April 2024
 
Automating Google Workspace (GWS) & more with Apps Script
Automating Google Workspace (GWS) & more with Apps ScriptAutomating Google Workspace (GWS) & more with Apps Script
Automating Google Workspace (GWS) & more with Apps Script
 
08448380779 Call Girls In Friends Colony Women Seeking Men
08448380779 Call Girls In Friends Colony Women Seeking Men08448380779 Call Girls In Friends Colony Women Seeking Men
08448380779 Call Girls In Friends Colony Women Seeking Men
 
Strategies for Unlocking Knowledge Management in Microsoft 365 in the Copilot...
Strategies for Unlocking Knowledge Management in Microsoft 365 in the Copilot...Strategies for Unlocking Knowledge Management in Microsoft 365 in the Copilot...
Strategies for Unlocking Knowledge Management in Microsoft 365 in the Copilot...
 
04-2024-HHUG-Sales-and-Marketing-Alignment.pptx
04-2024-HHUG-Sales-and-Marketing-Alignment.pptx04-2024-HHUG-Sales-and-Marketing-Alignment.pptx
04-2024-HHUG-Sales-and-Marketing-Alignment.pptx
 
Bajaj Allianz Life Insurance Company - Insurer Innovation Award 2024
Bajaj Allianz Life Insurance Company - Insurer Innovation Award 2024Bajaj Allianz Life Insurance Company - Insurer Innovation Award 2024
Bajaj Allianz Life Insurance Company - Insurer Innovation Award 2024
 
2024: Domino Containers - The Next Step. News from the Domino Container commu...
2024: Domino Containers - The Next Step. News from the Domino Container commu...2024: Domino Containers - The Next Step. News from the Domino Container commu...
2024: Domino Containers - The Next Step. News from the Domino Container commu...
 
EIS-Webinar-Prompt-Knowledge-Eng-2024-04-08.pptx
EIS-Webinar-Prompt-Knowledge-Eng-2024-04-08.pptxEIS-Webinar-Prompt-Knowledge-Eng-2024-04-08.pptx
EIS-Webinar-Prompt-Knowledge-Eng-2024-04-08.pptx
 
A Year of the Servo Reboot: Where Are We Now?
A Year of the Servo Reboot: Where Are We Now?A Year of the Servo Reboot: Where Are We Now?
A Year of the Servo Reboot: Where Are We Now?
 
Driving Behavioral Change for Information Management through Data-Driven Gree...
Driving Behavioral Change for Information Management through Data-Driven Gree...Driving Behavioral Change for Information Management through Data-Driven Gree...
Driving Behavioral Change for Information Management through Data-Driven Gree...
 
Slack Application Development 101 Slides
Slack Application Development 101 SlidesSlack Application Development 101 Slides
Slack Application Development 101 Slides
 
Workshop - Best of Both Worlds_ Combine KG and Vector search for enhanced R...
Workshop - Best of Both Worlds_ Combine KG and Vector search for enhanced R...Workshop - Best of Both Worlds_ Combine KG and Vector search for enhanced R...
Workshop - Best of Both Worlds_ Combine KG and Vector search for enhanced R...
 
Advantages of Hiring UIUX Design Service Providers for Your Business
Advantages of Hiring UIUX Design Service Providers for Your BusinessAdvantages of Hiring UIUX Design Service Providers for Your Business
Advantages of Hiring UIUX Design Service Providers for Your Business
 
Powerful Google developer tools for immediate impact! (2023-24 C)
Powerful Google developer tools for immediate impact! (2023-24 C)Powerful Google developer tools for immediate impact! (2023-24 C)
Powerful Google developer tools for immediate impact! (2023-24 C)
 
Presentation on how to chat with PDF using ChatGPT code interpreter
Presentation on how to chat with PDF using ChatGPT code interpreterPresentation on how to chat with PDF using ChatGPT code interpreter
Presentation on how to chat with PDF using ChatGPT code interpreter
 
Artificial Intelligence: Facts and Myths
Artificial Intelligence: Facts and MythsArtificial Intelligence: Facts and Myths
Artificial Intelligence: Facts and Myths
 
Scaling API-first – The story of a global engineering organization
Scaling API-first – The story of a global engineering organizationScaling API-first – The story of a global engineering organization
Scaling API-first – The story of a global engineering organization
 

Tom tellez sprinting a biomechanical approach

  • 1. Sprinting: A Biomechanical Approach By Tom Tellez World class male sprinters stride approximately forty-three times for a 100 meter race. If a mechanical error costs one-one thousandth of a second per stride, the total cost is .043 seconds by the finish. How can one be an efficient sprinter? However daunting the question appears, an answer lies in scientific principles alone. Kinesiology, biomechanics, and the laws of physics govern every sprinter’s technique. Kinesiology, the study of movement, dictates how a sprinter should move. Contributing to the study of movement is the discipline biomechanics, which refers to the engineering of the body and laws of physics governing it. While referencing laws of physics, kinesiology and biomechanics view the body as a unified system of interdependent parts, an approach necessary for proper analysis. Overview At the start of a race, the body must begin movement from a rest state. Once moving, the body requires time to build into full speed, or accelerate to full speed. At the beginning of this process, stride length as well as the number of strides per unit of time is small. However, both increase as acceleration increases. While having the ability to accelerate over 100 meters would be ideal, the body is only capable of accelerating for approximately sixty meters. The last forty meters would simply be maintaining technique and speed. Analysis of sprint mechanic s explains the finer nuances of sprint technique, including impulse, stride length, stride frequency, running velocity, arm movement, and leg action. Impulse Impulse is not only a term for the foot-ground contact created by each step but also a numeric value defined as force X time. This is the starting point to understanding scientific sprint technique because the impulse is the body’s only interaction with the ground, the one and only interaction, which produces linear movement. Impulse ultimately defines how the body should perform rotary movement (movement of body levers relative to body). Vector calculus defines impulse: each impulse has a direction and magnitude. Direction is the mixture of horizontal and vertical components, while magnitude is the measure of force. The best sprint technique consists of an ideal ratio between downward push and horizontal push (Fig. 9). This ratio, however, changes throughout the sprint race. Concerning force, of course great force can yield great stride length. However, misapplication of force translates to poor technique and loss of momentum. While the horizontal and vertical components of force within impulse play a role in creating body position, body position is also rotary. The ideal body position is perpendicular to the ground, where neck and head fall naturally in line. Depending on the impulse, the body may lean from the ground, as in the drive phase of sprinting, or remain vertical.
  • 2. One finer detail of impulse relates to how various athletes contact the ground. 100-200 meter sprinters contact the ground on the ball of the foot (Fig. 1), 400- 800 meter runners’ contact in the arch (Fig. 2) and 1500 meter runners and up use almost the entire foot as a contact point (Fig 3). While producing the numerical value of each step in a print race requires special technologies, coaches can judge the quality of impulse by measuring momentum. For example, when sprinters show a “low and long” look like that of an ice skater, one possible error is too much horizontal force. A dramatic example of too much downward force would be an athlete who simply jogs in place without moving. But what if two athletes within a race produce near-perfect directional ratios, which one wins? The one applying more force, within the least amount of time wins (Weyand et al.1998). Force applied for long time intervals requires more energy output than force application for shorter time intervals. It is force applied with the proper directional ratio, which increases stride speed and creates longer stride length. Stride Length Stride length is the distance the center of gravity travels between each foot contact. Stride length is the resultant of momentum plus net impulse, which is given to the mass. It can be examined as the following: takeoff distance, flight distance, and landing distance (Fig. 4) Takeoff Distance Takeoff distance is the distance the center of gravity travels between the landing point and the point where ground contact is broken. The velocity at which the center of gravity is projected forward is also critical to the flight phase of the stride and is determined by the velocity at touch down and the vertical and horizontal impulses. Thus the speed through the takeoff distance along with good body position and angle of projection determines the takeoff velocity. It will therefore be advantageous to have a big takeoff distance coupled with a great amount of angular speed as the time element of impulse diminishes. Here, it should be noted that the negative velocity of the foot sets up the body position for take off but contributes very little to the actual take off which is the result of pushing the ground away from the body (body away from the ground). Flight Distance The flight distance is the distance that the center of gravity travels in the non- support phase of the stride. These factors determine the flight distance: angle of impulse, velocity at takeoff, relative height of center of gravity at takeoff, air resistance, and acceleration due to gravity. Landing Distance The landing distance is the distance the center of gravity is away from the landing foot. This distance is relatively short so as to reduce the breaking forces,
  • 3. which decelerate the body. The point of course is to put the food down in a place, which can mechanically develop the most power. The foot lands slightly in front of the center of gravity before moving directly under the center of gravity for push off. If the foot lands behind the center of gravity, stumbling results. Whereas if the foot is too far forward I a reaching step, contact time with the ground will be too long, requiring too much force, resulting in a loss of momentum by the time the body is in a position to push off of the ground effectively. Stride Frequency Stride Frequency is the number of strides taken per unit of time. Stride time is easily confused with stride frequency. Stride time is the time it takes to complete one stride (time of support and time of nonsupport). Stride speed and angular velocity through the full range of motion (front and back oscillation) determine stride time. Because stride speed depends on the body state (fitness), it is more of a physiological function (muscle type, muscle flexibility, strength, neuro- muscular coordination, etc.) than biomechanical function. But, the paths the legs take that create speed and mechanical advantage is biomechanical. Running Velocity Running velocity is a product of stride length times frequency. Each athlete has a unique combination of the two at different running speeds. Common analysis of stride length and frequency mistakenly show the two inversely related. Stride length frequency are interdependent, where the relationship is based on the amount of resistance that must be overcome. Power (force X velocity) generated by the muscles improves stride length and frequency. The velocity component of power allows more work to be done (stride length) and increases stride speed (stride frequency). ARMS Coordinated movement of arms and legs remains the key to efficient sprinting. It is through range and force that the two coordinate. While the movement coordinates, arms lead legs in tempo and range. The following method of movement produces the proper range and force necessitated by the legs. The hand is positioned approximately shoulder-high, but not exceeding the chin, and slightly in front of the chest (Fig. 8). From this point, the hand initiates the downward stroke by flipping downward while the upper arm rotates backwards from the shoulder, and the elbow joint opens or increases the angle between forearm and upper arm (Fig. 7). After the hand passes by the hip, the elbow joint begins to close again and drives backwards and upwards while the shoulder continues rotating through full range of motion (Fig. 6). The swing forward requires a reversal of this process, where the elbow opens again while passing by the hip but closes after passing the hip until he hand achieves the approximate-shoulder-high position. Forearms and chest remain as relaxed as possible.
  • 4. Scientifically speaking, the shoulder is the axis of rotation for the arm, while the elbow acts to shorten the lever when necessary. Closing the angle reduces the moment of arm inertia, increasing angular velocity, in turn creating quicker turnover. Arm movement without utilizing the elbow joint produces a straight-arm, pendular-like swing moving much too slow for leg coordination. Arm swing can allow for greater takeoff distance, enhancing stride length. Leg Action Overview The vertical force comes at take-off when the mass is elevated by pushing downward (pushing off the heel back onto the ball of the foot). The recovery foot steps up and over the drive knee as the foot takes the shortest path to the front of the body as the center of mass rises above the surface (Fig. 7 & 8). The knee then raises and extends as the foot moves forward and the shin becomes plumb (Fig. 7). The thigh drops towards the ground while the knee extends, causing the foot to have a negative velocity at foot placement. As the athlete builds momentum (mass X velocity) the ratio between both forces (vertical and horizontal) increases as the net horizontal force decreases. The stride becomes progressively quicker and longer as stride frequency and length are optimized. Stretch Reflex The stretch reflex acts similarly to loading a “Y” sling shot, or forked sling shot. Before shooting the projectile, it remains poised in the stretched elastic, just as the hip flexors remain stretched before the recovery phase. When the sling shot elastic is released, it pops back into original form, sending away the projectile. Novacheck along with Vaughan claim that sprint efficiency is due in part to “the storage and later return of elastic potential energy by the stretch of elastic structures (especially tendons)” (Novacheck 81). Furthermore, stretched tendons efficiently return energy upon recoil (Novacheck 84). The stretch reflex refers mainly to the knee cycling during the recovery phase. Knee Action The sling shot release parallels the leg recovery phase: the knee cycles through because the hip flexor pops back into normal position from its stretched position. Therefore, the knee coming through occurs naturally and does not necessitate an athlete’s conscious effort. Furthermore consciously lifting the knee high while sprinting inhibits the legs natural timing during the recovery phase. Consciously creating a high knee lift or normal knee lift is like stretching back a sling shot with projectile and helping push the projectile with the hand while the elastic is releasing. The action would cause a reduction of elastic force, resulting in slower movement with the sling shot as well as with sprinting. Scientific Overview
  • 5. Start At the start, mass is at rest. The property of inertia inherent in the mass resists changes in velocity (a vector with magnitude and direction) and according to Newton’s first law will maintain this velocity unless acted on by an external force. The amount of inertia within the mass is proportional to the amount of mass; objects with more mass require more force to move initially. When the sprinter applies force to the blocks, inertia is overcome and linear movement begins. Stride length and frequency are low because of inertia. This is why the first stride is the slowest and shortest. Force is initially applied backward and downward where the shin angles somewhat close to the ground and behind the knee. This motion is piston-like as it pushes the mass forward from its rest state. Horizontal impulse is greatest at this point (Weyand et al. 1991) but diminishes as mass increases speed. It is the net force that causes the mass to accelerate: the difference in mass forward force and the pushing force. At the start of a run when resistance is at its highest, it is easier to increase stride length because force needs something to work against. Acceleration Shortly after starting, stride length and frequency increase. As momentum builds, stride length tends to stabilize as momentum builds, resistance diminishes and net force approaches zero. Concurrently, frequency increases because resistance constantly decreases. In short sprints, it is important to accelerate over the longest possible distance in the shortest amount of time and try to maintain and decelerate gracefully. After the athlete has been successful in setting the body in motion, and the center of mass begins to gain momentum, a toppling would occur if the feet continued to go backward and downward. The acceleration process then goes through a mechanical transition where the legs go through the form of cycling motion. The lever lengthens to give a mechanical advantage and shortens on the recovery phase to give a speed advantage. The position of the body dictates how reactive forces affect the center of mass. The center of mass accelerates at a decreasing rate until maximum velocity (top speed) is attained. At max speed, the net horizontal force applied is zero. The ground tends to recede faster when the body picks up speed, resulting in reduction of contact time as well as effective force because of reduction in resistance. At this point in the race, the athlete tries to keep the effective force at zero until the net horizontal force becomes negative. When body momentum becomes greater than that of the legs, the body starts toppling over, causing a braking action each time the foot hits the ground. At this point, the athlete tries to relax and lets momentum of the mass take the body down the track. Movement
  • 6. The human body is engineered to utilize a series of lever systems (third class) where force acts between the axis and the resistance. For any movement to occur, the lever must rotate around its axis. Based on this premise, it is safe to say that the origin of movement is rotary. Rotary motion simply refers to bodily motion. It is the interaction of physical laws and body levers. For an object to rotate, it must have two different types of forces acting on it at right angles: a centripetal or centrifugal force and tangential force. Centripetal and centrifugal forces cause objects to move toward the point of rotation, known as the axis. The axial or tangential force causes object to move perpendicularly in relation to the radius. In the human machine, force is closer than resistance to the axis. To illustrate, a sprinter resists the ground while producing movement and force with the thigh. This relationship makes the lever very inefficient because more torque is required for movement. For the sprinter, it is essential that the lever move through the full range of movement fast, requiring a torque (turning force) both forward and backward. Torque (force X movement arm) contributes to the angular velocity of the lever. If the length of the lever is constant, the lever would oscillate like a pendulum. But because lever length changes so does angular velocity, for any given force. Thus the angular velocity ties the length of the lever produces the linear velocity at the point farthest away from the axis. Both the arm and leg movement efficiency benefit from the ability to lengthen or shorten levers. By lengthening and shortening the lever, the athlete can change the moment of inertia (resistance to movement). The farther the moment of inertia (mass X radius) is away from the point of rotation, the harder it is to change motion. With a given amount of force, a shorter lever with the same mass as a longer lever would rotate faster than the longer but would have a mechanical disadvantage. It will therefore take more torque (moment of inertia X angular acceleration) to turn the longer lever than it would to turn the shorter. If no additional turning force is applied to the lever, angular momentum (moment of inertia X angular velocity) is conserved. An increase or decline in the moment of inertia will cause decline or increase in angular velocity respectively. This inverse relationship between the moment of inertia and angular velocity in the conservation of angular velocity in the conservation of angular momentum is one of the keys to great sprinting. Common Errors Stressing stride length or stride frequency
  • 7. Debate on the best way of improving sprint speed focuses on two issues: increasing stride length versus increasing frequency. We are limited physiologically to the amount of strides than can be performed in a second. It is true that most good sprint athletes have just about the same frequency. So, an athlete with adequate conditioning who takes the longest strides usually wins. Stressing stride frequency alone results in inefficient sprint technique. Common knowledge portrays stride frequency as a speed advantage. However, stride frequency differs from stride speed. Stride speed is angular velocity of a stride, while frequency is the number of strides, or impulses, per second. Even if a sprinter has the fastest turnover, without proper force application, stride length will be small. This is because frequency alone does cause linear motion; applying force to the ground does. Proper force application results in stride length and frequency increases. Stride speed is involuntarily increased by the conservation of angular momentum. Shortening the radius, thus reducing the moment of inertia, results in an increase of angular velocity. The shorting of the lever occurs after the foot breaks contact with the ground. This movement is the response of the forces being applied correctly to the ground and is non-volitional. Illusion of Speed There is an illusion of speed when then lever does not go through the full range of motion; each movement looks and feels faster. For example if stride frequency is stressed, an athlete may not allow the hip extend through full range of motion to reap whatever benefits he created from applying force to the ground. Lack of hip extension detracts from momentum and ultimately decreases speed because of inefficiency. But the objective is not to move the lever fast but rather transport the mass down the track in the least time possible. Avoiding full range of motion also sacrifices proper force application. Leg preactivation: pawing action Pawing action is actually an illusion resulting from rapid hip extension. Too much voluntary action at the knees and ankles causes a reduction in angular velocity of the hip, which is the prime generator of force. Force causes motion while speed is a measurement of motion. Cyclic force is applied from the hip (radial force) which results in tangential motion of the foot. At foot placement, the shin should be approximately 90 degrees to the ground (Fig. 5). As the center of mass passes over the point of support, the heel briefly touches the ground and the ankle angle closes. This motion puts the Achilles tendon and calf in a stretch position while the knee is bent, allowing a greater push off force from the ball of the foot. Hips extend in one continuous motion from the knee lift position through the end of the push off
  • 8. with no pauses in hip extension at foot contact. High knee lift Please see “Knee action” Reach and Pull Running action such as reaching and pulling with the hamstrings has been scientifically proven not to produce the most efficient movement (Weyand et. al. 1998). This running style is inefficient because it does not utilize the stretch reflex, but instead requires more muscle forces and volumes per unit of force applied to the ground (Weyand et al. 1998). Summary Scientific research across the world has yet to penetrate the track and field world. Athletes can be better sprinters with scientifically proven sprint technique. Better sprinters require coaches who are willing to learn scientific principles as well as a method of communicating their knowledge to the athlete. Works Cited Novacheck, Tom F. The biomechanics of running. Motion Analysis Laboratory, Gillette Children’s Specialty Healthcare, University of Minnesota. 1998; 77-95. Vaughan C.I. Biomechanics of running gait. Crit Rev Eng 12: 1-48 Weyand, Peter G., Deborah B. Sternlight, Matthew J. Bellizzi, and Seth Wright. Faster top running speeds are achieved with greater ground forces not more rapid leg movements. Journal of Applied Physiology 89: 1999-2000.