Does sports science research influence practice?

October 20, 2006

If the clinic directors didn't see a practical application to the

Weyand/Bundle research, they wouldn't have invited them to speak. This was a

coaching

seminar and not a biomechanics symposium. coordinated the

program. There were several Olympic medal winners who attended.

If you're looking for specifics as to how we are applying the research, go

to Barry Ross's site. All is free, with the exception of the speed tables,

which we are not allowed to release because the algorithm is property of Rice

University. We are in the process of negotiating with Rice for rights to make

the tables available to the public.

Ken Jakalski

Lisle High School

Lisle, IL

November 9, 2006

Barry wrote:

<<Hi Dr. Yessis,

Here are my matching responses, as you requested,to your questions:

(1) Yes, limb speeds can be the same. You can see this in action by

going to www.bearpowered.com/resources, then clicking on The Saga of

2 Runners. What you will see is that both runners are landing at the

same time, stride after stride, yet in a 100m race the faster of the

two is faster by 1 meter per second faster. If you watch the grounded

foot of each runner, you will see that the faster one's foot leaves

the ground increasingly earlier than the other. This allows more air

time to reposition his leg for the next stride. Weyand's study

mentions precisely what you see in the video, " Faster runners applied

greater forces during briefer contact periods, whereas slower runners

applied lesser ground forces during longer contact periods. "

The faster runner needs no more time to reposition limbs then slower

runner uses.

Interestingly, stride frequency does increase ( " The large

sensitivity of top speeds to small differences in the mass-specific

support forces applied to the running surface resulted from the

positive effect of support forces on maximal stride frequencies. "

Weyand, et al.). What is the cause of the faster stride frequency?

" Stride time (measured in s) was defined in accordance with Heglund

et al. as the time between consecutive footfalls of the same foot "

and " Stride frequency was determined from the inverse of the total

stride time (1/total stride time). "

Stride frequency, as determined above, improved because of the

shorter contact time of the faster runner. All of this is driven by

mass specific support force.

In answer to your question regarding distance covered, yes the faster

runner is covering more ground as he easily pulls away, but he

doesn't have to move limbs faster to do so. It's not individual limb

speed that's critical, it the speed of the body that must be

considered.

(2) You are correct in saying that force equals mass times

acceleration.

Where the problem lies for most is in recognizing that gravity pulls

the runner back to the ground and would continue accelerate the

runners mass until it hits terminal velocity (which won't happen to a

sprinter, so it's not really in issue here). In other words, the

airborne runner is now no different than any falling, accelerating

mass.

The opposite side of the amount of force created by the accelerating

mass of the runner striking the ground is what ground reaction force

plates measure. Newton's 3rd Law states that this measured force must

be equal to the force the runner hits the ground with. That force is

equal to 3 times bodyweight or more. The runner did not create this

force through chemical muscle power, but instead by merely hitting

the ground as a falling, accelerating mass. That is pure,

unadulterated physics.

Ground support force is the amount of force the runner must apply to

the ground so as not to collapse from the impact (support) and to

take maximum advantage of the force that will be returned by the

ground (Newton's 3rd law). This force applied by the runner is

derived primarily isometrically, so there is minimal change in muscle

length as well as minimal limb movement in creating force.

How does this equate to greater strength and less mass?

Let's assume that our runner is 150 lbs and hits the ground with 450

lbs of force against the mass of the earth. The earth is going to

return 450 lbs of force against the runner's mass. The runner's force

is not going to move the earth's mass but the earth's force is

certainly going to move the runner's mass since it is 3 times greater

than the mass of the runner. Now, up the ante with an elite sprinter

creating force equal to 5 x bodyweight and that sprinter is going to

be moving a lot further down the track. How can we know this? Because

Weyand's study showed that, " Average support forces of runners

applied to the running surface at top speed were systematically

higher for faster runners. "

(3) After digesting the above, it should be clear that strength

doesn't create ground reaction force, but rather accelerating mass

does. Ground reaction is just that, reaction to the force hitting it.

Since support force is largely isometric, joint actions are not the

prime points of focus for improvement. In addition, it should be very

clear from watching the video of the 2 runners that knee flexion is

minimal and therefore could not create the massive forces measured by

GRF plates. This goes back to the " test " I proposed to the members of

this forum.

(4) The deadlift is not better than its closest neighbor, the squat,

as far as maximizing strength, but it has some essential factors that

make it more efficient and effective for the training required. I'm

not

going to go into all those reasons. That being said, specific joint

action is not where strength is displayed for all of the reasons

stated above. Specificity of training for running is not centered

around joint movement but on increasing isometric strength, bone

density, muscle density, tendons etc. for increasing support force to

offset gravity. All of these are necessary as support and not the

creators of force. Ballistic lifts don't cut it here either.

(5) While the Pose method at least mentions gravity as relevant, it

barely touches on the importance of it. The system also relies on

training elements of running by means that simply don't work. I

passed on the Pose long ago.

It's quite simple to explain how vertical and horizontal influences

work together in sprinting (Interesting how that question is always

framed as how vertical can be responsible for horizontal. How about

we reverse the question: How does one get in the air by pure

horizontal forces?). The beginning of a run must be dominated by the

horizontal because it is necessary to use chemical muscle mechanical

work to overcome inertia by pushing the mass forward rather than

upward. As speed increases, the runner begins to elevate in order to

allow gravity to begin the work described above, that is, using the

force of gravity to create ground reaction force as well as creating

and storing elastic energy used for impulse in the vertical

direction. The vertical direction doesn't mean straight up, it means

that the runner will use a vector that allows them to trade the high

metabolic cost of chemical muscle mechanical work for the lower cost

of ground reaction force and effective impulse from elastic energy.

The horizontal force at take off is equal to the braking force at

touchdown, assuming no wind. This is true because of Newton's 3rd

law. The braking action is critical in maintaining the horizontal

portion of the vector. Here's why: The runner is traveling at a high

rate of speed while in air. At toe down, mass is just behind the

grounded foot. The foot stops moving forward at that point, but the

torso keeps moving horizontally, especially since the majority of the

mass is around hip height which creates a catapult-like effect. If

one drives a car at 25 miles per hour, but foolishly forgets to put

on a seat belt, what happens if the car hits a wall? The seatbeltless

person continues to move horizontally at the same speed the car was

moving until they hit something solid.

As mass crosses over the grounded foot, ground reaction force and

impulse from the elastic energy created from eccentric contraction

puts the runner back into their running vector. Ultimately, the

runner slows down as muscles tire from the isometric work and can no

longer create and release sufficient elastic energy.

(6) Your statement here was: " In relation to ground reaction forces,

you state that they are greatest halfway through the support stance

time and mostly gone after two-thirds of this time. "

In all due respect Dr. Yessis, this is what the measurements show and

there is no way to get around it. In fact, if you go back to

www.bearpowered.com/resources and click on Force Plate Fellow (circa

1970's or so and found on the internet), you will clearly see that a

ground reaction force plate only shows a measurement of force when

force is applied to it. It is also clear that merely crouching down

for the counter motion jump creates force because the body is

accelerating towards the plate (mass x acceleration=force). When the

man begins to move upward, force begins to disappear because he is no

longer accelerating downward. At the moment just before he lifts off

the ground, how much force is being applied to the ground? Virtually

no force is measured so there is virtually no force applied to the

ground when the jumper jumps. Isn't this where peak push off forces

should show if they exist?

In contrast, look at the 1 sec point where he begins toe down.

Within .2 seconds of toe down, force peaks, then starts to drop. This

is exactly what I described in (3) above. The answer to your

question, " How does this leave any force for the push-off? " is clear:

It doesn't leave any force for push off because there is no force

applied to the ground at push off. It also means that you're were

absolutely right when you say, " If this is true there is no need for

ankle extension. "

What you're seeing as ankle extension is caused by the reaction of

the previously grounded foot to the eccentric contraction of the calf

muscles and Achilles tendon as the man moves up from the counter

motion. The same reaction can be observed by pulling one forefinger

back as far as possible with the other forefinger, then releasing

it. It isn't chemical muscle power that snaps the just-released

finger forward, just as it isn't chemical muscle power that extends

the ankle at toe off. Pictures aren't proof of push off either

because they don't show force.

Proof that force is created at push off must be shown clearly on GRF

plates if that concept is to viable for training. Until that

proof is made available, exercises claiming to help create force at

push off should be set aside.

(7) I did not mean to imply that knee extension is the key factor in

supplying the speed in running. A small bend in the knee is necessary

to activate the spring part of the spring-mass model. A straight leg

would not allow for an effective spring action. It is the spring-like

action and GRF that supplies the speed in running.

Weyand truly understands running, as would his peers attest along

would the multiple citations of his work in the research papers of

others. Not one locomotion scientist has come forward to contend

against the research paper in the 6 years since publication of the

paper we've been discussing. Weyand's paper is ground breaking in its

analysis of running speed, mass-specific force, the effects of force

application, and much more.

And finally, there is always a danger in using pre-suppositional

thinking in order to review the merits of a " new " proposition. All of

us should be aware of that when we examine anything new, since we've

all been guilty of relying on something we thought to be true as the

bench mark for looking at the efficaciousness of a new approach. It

took 3 years for me to get through the fog of my pre-suppositions

regarding sprinting and sprint training before I could fully

understand the vast amount of research regarding the spring-mass

model and a strength training routine that fits within in the

trainable aspects of the model.>>>

***

Hello Barry

I've been out of town and apoloogize for the delay in responding.

Early in this discussion I mentioned the need to connect the dots

between the Weyand study and how it is applied. I'm sorry but I

must ask it again because your responses state many truths but not

how they fit into the discussion.

For example, in RE #1 there's nothing new here --- the information

is accurate but not the conclusion. More importantly it does not

address limb speed Speed of the body is dependant on limb speed and

the push-off. Simply compare a marathoner to a sprinter. Leg (limb)

speed is much different. This is pure physics, not opinion. The

formula for speed gives you the answer. Speed (more accurately

velocity) equals distance divided by time.

You go to great lengths talking about stride length and frequency

which are related to speed but not to the question asked. This only

clouds the issue.

RE #3 This is where a major problem exists. Yes a runner's body is

subject to gravity, but has little to do with it's speed. It plays

a minor role in comparison to the forces produced by the body.

For example, the vertical displacement of the CG in a sprinter is about 4

cm --about 1 inch. A free falling body dropping 1 inch cannot

generate the forces produced.

Your introduction of isometric force production is new and quite

intriguing as it may disprove what you have been saying. Do you mean

to say that when the foot hits the ground the limb muscles undergo

isometric " contraction " ? What happened to the eccentric and

concentric forces that are responsible for the spring model that you

previously espoused? Also note that the foot is in contact with the

ground for about one hundredth of a second, --certainly not enough

time to generate much isometric force.

Later on you state it is the support force that is isometric. This

is partially true but does it also provide the push-off force to

which you alluded earlier?

Your use of Newton's reaction law is also quite limited. By the way

you should know that I taught biomechanics for about 40 years and

am quite familiar with the laws and their application. Your

application of this law is flawed because you only consider the

vertical forces.

In # 6 you admit there are horizontal forces. Before it was only vertical, thus

my question on how it is converted to horizontal. These forces interact and

produce a reultant force, not two separate forces as you imply. And it can ONLY

be applied at push-off if Newton's law is to be in effect. But then you say it

is non-existent at pushoff since there are no vertical (I guess) forces at this

time. You still have not answered how the vertical is converted to horizontal

or if it is, how it is generated. This is the crux of this discussion and is

what must be addressed.

I need an explanation of the way you use braking force. How can it

be equal to horizontal force at take off? Sprinters minimize

braking forces as much as possible. Zero force is the best.

Also important at this time is to consider how the leg gets under

the body. Or since, in your view, what the legs do while airborne

is inconsequential why not have the runners land on the heel well in

front of the body, as many sprinters and even more marathoners do?

If we are to believe you, this would create even higher braking

forces which would then produce a stronger push-off.

Your last sentence in # 5 shows how you are erroneously concluding

the information that you have been presenting. We read that " ...the isometric

work (and) can no longer create and release elastic energy " . What happened to

the tendon-muscle complex and the spring model based on the eccentric-concentric

" contraction " ?

This is what I mean about sticking with the issues and not grabbing

bits of correct information and then trying to work them into a

seemingly scientific explanation.

RE # 6 I never challenged the force plate readings. I challenge the

way the data was interpreted and used by you or perhaps I should say

Weyand because you learned this from him. What has been lacking in

all the discussions is the horizontal component which most force

plate platforms do not record. But yet everything in your

discussion was explained by the vertical forces. This is what I

challenged and if someone truly understands running it should be

obvious that horizontal forces are much more important than the

vertical. And I don't refer to your use of horizontal when coming

out of the blocks. This has nothing to do with the issue at hand.

Being a track coach I'm surprised that you would not strongly

question the obvious lack of explanation for horizontal speed.

Simply asking yourself why sprinters use spikes should raise your

doubts about using this study and the many erroneous conclusions

that have been drawn from it.

You state (in # 6) that there is no force applied to the ground at

push off. This shows you do not believe--or understand-- that there

must be horizontal (with a vertical component) forces at takeoff.

If what you say is true you probably have the sprinters run without

spikes. Also I did not say ankle extension is not needed. As you may some day

learn it is a key force producing action.

I am not surprised that no one has challenged the results of Weyands

study. It takes a strong understanding of what constitutes running

from a biomechanical and kinesiological perspective,-- something

that to date I have not seen. As I mentioned earlier, you should

read my book, Explosive Running, for a full understanding -- at

least based on the latest sound, and not partial, information that

has been discussed.

You keep stating how Weyand truly understands running and how his

peers would attest. If this is so why do we not read some simple,

accurate, factual explanations of what occurs in the running stride?

Regards,

~~~~~~~~~~~~~~~~~~~~~~

Yessis, Ph.D

President, Sports Training, Inc.

www.dryessis.com

PO Box 460429

Escondido, CA 92046

~~~~~~~~~~~~~~~~~~~

November 10, 2006

Have either of you (Dr Yessis/Barry) and used this information to

coach sprinters on the track and/or in the gym, and if so, how is

your information applied? I'm curious as to the application of the

technicalities brought forth in this debate.

[Mod: Do search the archives as both members have offered some wonderful

insights in the past. Additionally, it may be worth searching both respective

websites www.bearpowered.com and www.dryessis.com - much of the information is

available for free]

Cowell

Raleigh, NC

November 10, 2006

1. " Speed of the body is dependant on limb speed and

the push-off. …This is pure physics, not opinion. "

2. " You still have not answered how the vertical is

converted to horizontal or if it is, how it is

generated. This is the crux of this discussion and is

what must be addressed. "

3 " …if someone truly understands running it should be

obvious that horizontal forces are much more important

than the vertical. "

The preceding 3 statements by Dr. Yessis reflect his

continued rejection of the findings of the Weyand

study (statement 1) and the spring mass model used by

locomotion scientists worldwide (statements 2 and 3).

He is certainly free to express his opinion, but he

offers no independent scientific studies to support

it. He does cite his own book without reference to

any particular statement in the book. The book itself

contains no references to outside authorities or to

his own published studies. Instead, in his response

in this thread opinions are offered in the form of

statements like:

" Being a track coach I'm surprised that you would not

strongly question the obvious lack of explanation for

horizontal speed. "

There has been an explanation for horizontal speed,

Dr. Yessis just does not accept it. It is misleading

to continually assert that there is a lack of an

explanation when what is lacking is an acceptance of

the explanation. The spring mass model was beat to

death the last time around on this topic. Do we

really need to do this again?

Likewise, statements like, " If this is so why do we

not read some simple, accurate, factual explanations

of what occurs in the running stride? " are also

disingenuous. Factual explanations have been given.

Those who have disagreed have their own explanations,

but they have not produced independent studies backing

up their positions. They also generally ignore (or

reject) the models used by scientists to explain how

humans walk and run.

Finally, the statement " I am not surprised that no one

has challenged the results of Weyands study. It takes

a strong understanding of what constitutes running

from a biomechanical and kinesiological perspective,

-- something that to date I have not seen, " reflects

a rejection of contemporary locomotion studies and the

scientists who conducted them.

Now that we have established that Dr. Yessis disagrees

with Weyand and the other published locomotion

scientists and studies, can we move on? Further

discussion is not going to change anything.

Jon Haddan

Irvine, CA

November 10, 2006

> Hello Barry

>

> I've been out of town and apoloogize for the delay in responding.

>

> Early in this discussion I mentioned the need to connect the dots

> between the Weyand study and how it is applied. I'm sorry but I

> must ask it again because your responses state many truths but not

> how they fit into the discussion.

>

> Regards,

> ~~~~~~~~~~~~~~~~~~~~~~

> Yessis, Ph.D

> President, Sports Training, Inc.

> www.dryessis.com

>

> PO Box 460429

> Escondido, CA 92046

> ~~~~~~~~~~~~~~~~~~~

>

***

Thank you for your response, Dr. Yessis.

First, it's clear from your response that your analysis is based

primarily on kinematic study which, by its definition, does not

include any application of force (kinematics is defined as (1) the

branch of classical mechanics concerned with describing the motions

of objects without considering the factors that cause or affect the

motion or (2) a branch of physics that deals with the motion of a

body or system without reference to force and mass)

Among other things in your response to RE #1, you mention limb speed,

push-off, the formula for speed, and opinion. As I've mentioned

before, many of your responses are based upon pre-suppositional

analysis, which is quite common when it comes to speed training.

If we start with opinion, we must first note the title of Weyand's

study:

" Faster top running speeds are achieved with greater ground forces

not more rapid leg movements "

Obviously, the study was designed to address the very issue you've

presupposed; limb speed drives sprint speed. Weyand's study showed

that limb speed was not the main factor driving speed (although

presupposed by the majority) but instead, speed increase was derived

from increasing stride length at lower speeds and stride frequency at

higher speeds. Stride frequencies at higher speeds came from shorter

ground contact time and shorter swing time (time a given foot was not

on the ground). In fact measurements showed that swing times for

runners of varying speeds are similar. In the Weyand study the

difference in swing time between an 11m/s runner and a 6m/s runner

was 0.03 seconds.

It is your merely your opinion that Dr. Weyand's study has flaw,

creates misconceptions, or is not ground breaking.

Weyand's study is ground breaking as the first to test the validity

of limb speed as the cause of faster running. One can choose to

ignore the results and analysis, but this is not the case with

locomotion experts. Presuppositional belief, absent research data, is

an insufficient argument against the study.

You also presuppose the existence of push-off, based solely on

kinematic analysis, and the importance of the vertical. You state in

RE #3 that the sprinter only elevates 4 cm, but if the athlete

elevates at all, then one must assume the concept of push-off must

include a vertical element, and by extension, should show measurable

force at the point the push-off occurs. Since no force is measured

where push-off is alleged to occur, then one must assume one of the

following: (1) There is no vertical elevation by the runner; (2) The

amount of force is too small to be measured; (3) there is no push-off

and the vertical is caused by something else. You've admitted that

the athlete elevates, so #1 is eliminated. #2 would require enough

force against the ground to move the athlete's mass vertically. In my

previous post, I suggested that you look at Force Plate Fellow on my

website. It is clear from that video that force plates are able to

measure force when a person merely goes from an upright position to a

squat because their mass is accelerating downward. Certainly, if a

push against the plate was powerful enough to move the runners mass

upward (as you've stated that is does), it should register that force

application. Yet there is no force measured at the point of " push-

off. " Therefore, the only remaining option is #3 – there is no " push-

off " as you understand it.

Your response to RE #3 is inaccurate. To create the amount

of peak force measured is likely beyond human capability. As a

strength trainer since 1968, I know when the limits of human strength

approach, and clearly, that strength limit is far below peak forces

obtained by force plate measurements. Your response is inadequate as

well, because it is based on several fallacious assumptions:

First, measurements peak at 3 times bodyweight, or more, for

sprinters. The time frame from beginning to end of measured forces is

less than .04 seconds, beginning after the first 3rd of ground

contact time and ending prior to the first half of contact time.

Unless you have data provided by research to prove an alternative

time or duration, the question is how the measured amount of force

can be generated by human volition in such a short time frame. In my

38 years on the strength training side, I've never seen anyone

capable of moving that much weight that quickly in the weight room,

let alone over and over again while running. Of course my experience

is certainly anecdotal, but I've asked the question many times on many

forums, discussions, workshops, etc, without a single individual

stepping forward to say that it is possible to do move that amount of

weight one time let alone the number of times it would take to run

50m.

On another post on this site, Boardman stated, " …The

forces " generated " by pliometric impacts and running footfalls at top

speeds arise out of the energy conservation principles we have been

invoking in our simplified calculations. Impact forces compress or

extend (flex) the elastic tissues in question, the tissues compress

or elongate storing the energy in their electromagnetic force fields

and then they " reflex " ; returning the energy through a resistive

(restorative) force as they return to original position (dimension).

This is NOT a volitionally contractile procedure. (Emphasis by

Boardman) "

Despite Mr. Boardman's comments to the contrary, kinematic based

coaches continue to claim that the runner uses chemical muscle

mechanical force (volitional) to create the amount of force measured.

Second, you state, " …a runner's body is subject to gravity, but has

little to do with it's speed. For example, the vertical displacement

of the CG in a sprinter is about 4 cm --about 1 inch. A free falling

body dropping 1 inch cannot generate the forces produced. " There are

several possible deductions that could be made from your statement

including the following: (1) push-off exceeds the measured amount of

force occurring prior to mid-stance; (2) push-off occurs prior to mid-

stance; (3) force plate measurements are inaccurate; (4) the body is

not accelerating fast enough to produce the amount of force measured

(Force = M x A) from a 4 cm drop.

For the reason I stated earlier, it is not likely that, by human

volition, one would be able to move the amount of weight measured by

force plates within the time allotted. Therefore #1, in assuming an

even greater amount of force then what appears on force plates, is

not a viable deduction. # 2 is irrational according to the definition

of when push-off occurs. #3 is ludicrous. #4 has a few problems;

primary among them is that it's an inaccurate measurement. In

addition, it errantly presupposes that there is not enough time (in a

drop of 4 cm) to accelerate fast enough to create the amount of force

measured. This of course, ignores the top speed of a runner (which

could exceed 25 mph) contributing to the acceleration side of the

equation.

As a side note, our measurements, using software analysis, show that

a runner elevates more than 10cm (greater than 4 inches) rather than

your estimate of vertical displacement (4 cm or 1.5 inches (not the 1

in. you stated). This may not seem significant at first, but when

viewed in conjunction with rate of acceleration at high speed, it's

very significant

Regarding isometric contraction, there is no conflict with the spring-

mass model and eccentric contraction, since the eccentric contraction

is " forced " by the effect of the body landing at a high level of

force and that the stretch is increased as mass moves over the

grounded foot. There is only a conflict if one believes that the

force is chemically produced.

Dr. Yessis: clearly, your own statement in this section, " Also note

that the foot is in contact with the ground for about one hundredth

of a second, --certainly not enough time to generate much isometric

force, " disproves your own contention that measured force, or indeed

any force, is derived by chemical muscle mechanical force.

If isometric contractions, which create force significantly faster

than concentric contractions, are too short to generate much force in

the time you suggest, 0.01 seconds, how could the amount of measured

force be generated by concentric contractions within the time frame

you suggest?

In any case, the actual measured ground contact times are longer than

your conjecture, approximate 0.10s instead of 0.01s, still far short

of the time necessary to create force chemically.

I believe you misunderstood me, based upon this question, " Later on

you state it is the support force that is isometric. This is

partially true but does it also provide the push-off force to which

you alluded earlier? " since I did not allude to push-off as supplying

any force.

Finally, as pertains to RE #3 you believe that the application of

Newton's law in the research is flawed and that your knowledge of

biomechanics makes you familiar with its application. Just to set the

record straight, and without making a specific judgment towards you,

we both know that biomechanics is a core part of kinesiology, which

is the scientific study of human movement. This does not necessarily

provide expertise in all facets and applications of Newtonian

physics.

In RE # 5, you state that, " We read that " ...the isometric work (and)

can no longer create and release elastic energy " . What happened to

the tendon-muscle complex and the spring model based on the eccentric-

concentric " contraction " ? " The answer should be self evident since we

know that muscle don't run out of fuel when sprinting, as stated in

an article out of Rice University: " These findings complement what

scientists studying muscle fibers and cells have noted for some time:

Furiously contracting fibers do not run out of chemical energy.

Rather, muscles develop progressively less force with successive

contractions when they rely on anaerobic metabolism for chemical

energy. " In other words the muscles are no longer able to provide

the contractile power to run at high speed.

In RE # 6, I answered fully and clearly what creates the horizontal

direction. I'll repost it, in part, here:

-- It's quite simple to explain how vertical and horizontal

influences work together in sprinting (Interesting how that question

is always framed as how vertical can be responsible for horizontal.

How about we reverse the question: How does one get in the air by

pure horizontal forces?). The beginning of a run must be dominated by

the horizontal because it is necessary to use chemical muscle

mechanical work to overcome inertia by pushing the mass forward

rather than upward. As speed increases, the runner begins to elevate

in order to allow gravity to begin the work described above, that is,

using the force of gravity to create ground reaction force as well as

creating and storing elastic energy used for impulse in the vertical