Impulse/force in pounds for the time frame

In summary, the conversation discusses the question of what the maximum impulse force would be on the components/parts of a machine as it lowers and then immediately stops a weight of 100 pounds at 2m/s for 1000mm before lifting it back up at the same speed. The conversation also addresses the force needed to lift the weight from rest and how it would increase every 10th of a second during the lift. The conversation also touches on the issue of force units being measured in both US and SI units. It is suggested that the time interval during the accelerating phase must be about 1 second to stay within the limits of the machine, and it is noted that the conversation involves a man lifting the weight, which can complicate the
  • #246
sophiecentaur said:
Absolutely. But you still are not accepting that the energy that a machine needs to supply can be near ZERO, the average force will be ZERO and the net Impulse will also be ZERO.
You would be right in saying that the Maximum force for a fast repetition rate would be greater than the maximum force for a slow rep rate.
But how does this machine help you to analyse what you think your muscles are doing? Where's the essential connection in your mind between the two entirely separate things?

DaleSpam said:
OK, I am glad you understand that. I apologize that you think it was an odd question, but from several of your previous comments it was not clear that you understood that point. I am glad that you do and it was just a miscommunication.

K great, thank you.

sophiecentaur said:
So, let's take the scenario of a machine or a person lifting a 50 kg weight up and down 500 mm in 3 s as smoothly as possible. I generated the attached plot to represent a typical position over time graph for such a lift. Look at it and see if it seems like a reasonable approximation to you.

The plot is generated in Mathematica using the following code:
Code:
y[t_] := -.25 Cos[2 \[Pi] t/3] + .25;
Plot[y[t], {t, 0, 3}, Frame -> True, 
 FrameLabel -> {Style["Time (s)", Larger], 
   Style["Height (m)", Larger]}, 
 PlotLabel -> Style["Position of Weight During Lift", Larger]]

Yes that look quite ok, I think. We are lifting 80% are we not, or close too ?

Wayne
 
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  • #247
sophiecentaur said:
This demonstrates well how you have got this wrong from beginning to end. Your muscles are not a machine. I can design a machine that uses NO energy whilst doing 'reps' at any rate and for any length of time (except to overcome some friction - and we could reduce this to an arbitrarily small amount).


How do you work that out ? What machine can lift say 80% up, and then lower it down using very little energy, and what energy is this ?


sophiecentaur said:
The way the forces vary as the weights accelerate will depend on the rate


Right, the faster you try a move/accelerate the weight, the more action reaction forces go back on your muscles as tension, move/accelerate very fast very high forces, = very high tensions on the muscles, move very slow, very low force, = very low tensions on the muscles, move very slow, very low force.


sophiecentaur said:
but the mean velocity is zero for each cycle, and so is the energy transfer.


Not sure what this has to do with the debate, as we need to know about the velocities themselves, that are produced by the person/machine creating these forces, as I just said, the faster you try a move/accelerate the weight, the more action reaction forces go back on your muscles as tension.



sophiecentaur said:
btw, when you describe your machine as having a certain "lifting force" you do not specify for how long or over what distance this force is applied - nor what happens on the way down; the model is incomplete.


Ok sorry there.


The machine has a lifting force of 100 pounds, it can lift 100 pounds up 1m in .5 of a second, and any speed slower, and can lower it 1m in .5 of a second, and any speed slower, for an unlimited time, for debates sake, the weight the machine will use will be 80% that’s 80 pounds.


The machine first lift the 80% up 1m in 3 seconds and lowers it 1m in 3 seconds, 1 time, = 2m in 6 seconds.


Then the machine lifts the 80% up 1m in .5 of a second, and lowers it 1m in .5 of a second, 6 times = 12m in 6 seconds.

On the way down it lowers it in control 1m in .5 of a second, I say in control, as if let to drop, it would get to the ground far faster. Also, as of the acceleration components, when the weight is being lowered, the faster it’s lowered the more force it puts on the machine/muscles, like in the faster it hits the ground the more impact force.


sophiecentaur said:
All this machine needs to consists of is a wheel, with the weights hung on the periphery. You could modify it, if you like, so that the weights are on a crank and push rod so that they are constrained to go just up and down. Over one cycle of operation, ZERO work has been done on the weights and Zero energy is expended by the energy source. All that is necessary is to start the machine up and bring it to the desired speed. This (kinetic) energy could all be reclaimed at the end of the exercise.
Perhaps this will help you to see that there is absolutely no parallel between what your muscles are doing and a simple mechanical model. Anything you may 'think' that your muscles are doing is entirely subjective. However many times you repeat a story about reps and rates and what you reckon you can tell us about what your muscles feel like, there is no direct correspondence between your body and simple mechanics. I believe that is what you have been trying to show all along.
__________________


Wow that sounds interesting, but its far too late to comment on that now, will get back to it tomorrow.


Wayne
 
  • #248
To all the other that have posted here, I will get back to them tommorrow, and thanks for your time and help.

Wayne
 
  • #249
waynexk8 said:
How do you work that out ? What machine can lift say 80% up, and then lower it down using very little energy, and what energy is this ?


Wayne

Plus all the rest
That comment shows that yo don't get the mosgt basic part of all this thread and others.

The machine doesn't need to use use "very little energy" on the way down. IT GETS ALL THE ENERGY BACK! Unlike your muscles, which don't have Energy Recovery. So the two cannot be compared.
You insist that this problem can be solved your way and you have the nerve to hang onto the idea in the face of people who know much more basic Physics than you. The only hope you have is to do a Physics course at some level which may help you understand what you need to know in order to grasp how crazy your idea is.
If someone told you that swimming the Pacific is a no no, how long would you not believe them?
 
  • #250
sophiecentaur...I think that he first needs to grasp more simple things.For example...he doesn't seem to understand the meaning of average force.
Otherwise he wouldn't say nonsense like "...the forces don't make up..." or "...average means nothing in this debate...".
More important he would understand that same average force equates same impulse(what he calls "total/overall force") when is applied for the same duration.
 
  • #251
waynexk8 said:
Yes that look quite ok, I think. We are lifting 80% are we not, or close too ?
I don't know about percentages, but from this motion diagram we can easily use Newton's laws to calculate the force exerted on the 50 kg mass by the lifter. I have plotted the force over time in the attached image.

At each point in time, the height of this plot represents the force applied by the lifter at that time. That has units of N. On this plot, we can also see a shaded area. This shaded area represents the impulse. The shaded area has units of Ns = kg m/s which is the same units as momentum. The average force is the impulse divided by 3 s. It has units of N also.

Note, as we had discussed before, the force must change over the course of the lift, it is higher when the weight is accelerating upwards, and lower when accelerating downwards. Also, although the force gets lower when accelerating downwards, it is never 0 in this case.

Does all of this make sense, in particular the impulse and average force?

Code:
Plot[Evaluate[50 D[y[t], {t, 2}] + 50 9.8], {t, 0, 3},  
 Frame -> True, 
 FrameLabel -> {Style["Time (s)", Larger], Style["Force (N)", Larger]}, 
 PlotLabel -> Style["Force from Lifter", Larger], 
 PlotRange -> {0, 560}, 
 Filling -> 0]
 

Attachments

  • ForceFromLifter.png
    ForceFromLifter.png
    2.4 KB · Views: 388
  • #252
I don't think that Wayne actually knows what question he is actually asking any more. The only way he can ask about anything is in the form of a two page story instead of a concise question. That shows he has not actually formulated a question but just wants to chat about Reps and all that stuff. He just feels that there must be 'some simple Physics' involved.

(I'm right, aren't I, Wayne?)
 
  • #253
douglis said:
DaleSpam...it doesn't have to be for over the whole rep.
Even if you examine separately the lifting and the lowering phase the average force is always the weight.In both phases the weight starts and ends at rest so the average acceleretion is always zero.

Look D. You say you will not let me apologise for repeating, but I have too, as I said over two years ago on a thread I actually called; average force means nothing here. So I say it again, if the average force is the same for 1 rep at 1/1 and 100 reps at 1/1 and 1 rep at 5/5 and 100 reps at 5/5, it means nothing in this debate.

As we are debating which rep with the same weight, in the same time frame puts the most tension on the muscles, as you fail at roughly 50% faster with this % and rep speeds on the fast, that’s MORE then obvious it’s the fast rep, or do you think you fail faster on the fast because it puts less tension on the muscle ? If so please say why.

Also, you said there was only one way to sort this out, with EMG, I bought one, and it showed after three experts on EMG said RMS was about the best way to find this out, that there is more overall/total activity on the fast reps. But you still insist when a real World practical experiment has proved you wrong, but you can’t state why.

You keep going on about average, when as I said it means nothings, and you also can't not tell me how you or why you work out this average, what’s average got to do with this.

Wayne
 
  • #254
douglis said:
No Wayne...we will not forgive you for repeating yourself.You ask again the same nonsense ignoring all the answers.

For some strange reason you're unable to understand that it's impossible to use the 100% of your force for the whole set.Regardless

No D. I TOTALLY understand this, I know the force/velocity curve, and I know I can’t use 100% force on 80% that’s why I always say, I try to use 100% of my force. But the point is, for the set amount of time, let’s call it 20 seconds, I am try to use as much force as I can, that’s quite close to 100%, you on the other had for the set time of 20 seconds, are not trying to use 100% force, you “are” only using 80% of your force, 20% less than me for the set time of 20 seconds.

Fast = as much force as he can exert for 20 seconds, let’s just call that 100.

Slow, = 80% of his maximum force for 20 seconds.

How can 80% for the same time frame be as high as 100% ?

Same in a car going uphill and down, I hit the gas 100% say this speed = 100mph, in one hour I have traveled 100 miles, you hit the gas at 80%, = 80mph, in one hour you have traveled 80 miles. [b/]You “only” traveled 80 miles as you DID NOT hit the gas with ENOUGH force, as I hit the gas with MORE force for the same time frame,[/b]

douglis said:
if you lift fast or slow you use the same average force for the same duration.

Explained why/why this average means, and explain why/how you have worked it out ? As I don’t know why you bring it up, or what it means. Sorry there, but I just don’t understand.

douglis said:
The impulse(what you stupidly call "total/overall force") is always the same.

I/we have been told now that physics can’t seem to measure overall/total force, or there can’t be one ? But the EMG can measure this, and it states categorically you are wrong, as it take into account the higher high force on the fast as the higher peak forces of the accelerations, and what I have said all along, is that your medium force cannot make up balance this out, if so, why would the EMG state higher for my fast ?

douglis said:
I don't care if you don't want to accept the truth or you just don't have the intelligence to understand it.
It's a fact...accept it.

That’s quite odd ? What truth have you ?

1,
EMG states fast,

2,
You use more energy in the fast,

3,
You do more work in the fast.

4,
So that’s more power in the fast,

5,
You move the weight 6 times further in the fast,

6,
You fail with these variables, 50% faster in the fast = there MUST be more tension on the muscles per unit of time to make them fail faster, = more tension = there must be more total/overall force if there is more tension as on failing faster.

7,
More speed, velocity and acceleration on the fast.

Is that enough truth, not sure what you have ?

Wayne
 
  • #255
douglis said:
The same as always!You ignore everything that has been answered.

No I do not; you are the one doing that.

douglis said:
Let's redefine the question.You asked which lifting speed has greater effect of force over time(impulse) which in Wayne's world is defined as "total/overall force".

Everyone explained to you that the impulse is identical regardless the lifting speed but you deny that fact based on some "practical proofs".Let's see them once again.[/quyote]

Before I answer this, you NEED to state why lift you are referring to, as the two different lifts, MUST have a different impulse.

Lift 1,
You lift 80% of the ground, up 1m and then down 1m all in 1 second, .5/.5

Lift 2,
You start at the top, lower the weight down 1m, and then lift it back up 1m all in 1 second, .5/.5

On lift 2, on the transition from negative to positive, there will be huge force on the muscles and coming from the muscles.

Also, “IS” the impulse the same on 1 rep and a 100 ? As I don’t think you are measuring the impulse with respect to time, as if you think you are, you are then saying f=ma is wrong, as your saying you don’t need a higher force to move something further in the same time frame.

Slow,
Car has a weight of 400kg and an Acceleration of 30m/s force pushing the car 400 x 30 = 12000N of force for 1 second.

Fast,
Car has a weight of 400kg and an Acceleration of 100m/s force pushing the car 400 x 100 = 40000N of force for 1 second.

Fast = 2800N more for 1 second.

“NOT” sure why I am wrong there, is it the deceleration ?


douglis said:
The EMG reads the Root Mean Square of the values.
Does the higher RMS somehow change the fact that the impulse is the same?NO!

The EMG show the total/overall muscle activity = force = tension on the muscles, its show what we are debating about, which has the most total/overall muscle activity, = the fast says the EMG.


douglis said:
Does the higher rate of energy expenditure somehow change the fact that the impulse is the same?NO!

That is NOT an answer, you need to say and explain why there is more energy used in the fast, I have told you, and you need to counter.


douglis said:
Does the greater distance somehow change the fact that the impulse is the same?NO!

Again, that’s no answer. Yes it does, I move the weight further in the same time frame, of course that needs more force, more acceleration needs more force, I mean its simple physics, its common sense. Newton's Law that force is equal to mass times acceleration, but we know in non-relativistic limit mass is invariant so if we apply more force it causes greater acceleration. The net force acting upon the object will be equal to the rate at which its momentum/movement change. When the object's velocity increases, so does its energy and hence it’s mass equivalent. It thus requires more force to accelerate it the same amount than it did at a lower velocity. Newton's Second Law.




douglis said:
Does the higher rate to fatigue somehow change the fact that the impulse is the same?NO!

All these prove what you say wrong; actually it would be nice if you gave me readable equations that state the impulse is the same per time, using the same weight over different distances and with diffract velocities and accelerations ?

douglis said:
So Wayne...quit these nonsense and see what everybody's telling you.Your above pseudoarguments are just a sad attempt to ignore the facts and keep leaving in your own world.

Odd think to say, why 1 to 7 prove you wrong. D. for once shows me proof, I showed you on 1 to 7 of the last post.

Do you admit you only use 80% force for the set time ? I try to use 100% force, 80 – 100 = 20 more force used, quite simple, I use more force, thus more tension on the muscle = you fail faster.

Wayne
 
  • #256
Please, for all to answer this one.

I was just wondering and thinking, ARE you adding “all” the force, I mean with the fast there are NOT just force being exerted by the muscles, there are HUGE forces on them, for say .1 of a second x the 6 reps = high forces on the muscle for maybe .6 of a second. Have you added these in ?

I mean the peak force from the transition from negative to positive, the force on the muscle, NOT given out by the muscles ? We call them the MMMTs {Momentary Maximum Muscle Tensions} these forces “ON” the muscles can be as high as 140%

Have you added these on ?

Lift 1,
You lift 80% of the ground, up 1m and then down 1m all in 1 second, .5/.5

Lift 2,
You start at the top, lower the weight down 1m, and then lift it back up 1m all in 1 second, .5/.5

On lift 2, on the transition from negative to positive, there will be huge force on the muscles and coming from the muscles.

Wayne
 
  • #257
Wayne, please focus. I am trying to help you learn some physics, that is what you came here for, right? Do you understand the force-time diagram. Do you see how the force is not constant, but that it varies over the lift? Do you graphically see what the impulse is?
 
  • #258
waynexk8 said:
1,
EMG states fast,
EMG measures electrical activity in the muscles, not force nor energy.

waynexk8 said:
2,
You use more energy in the fast,
Yes.

waynexk8 said:
3,
You do more work in the fast.
No, you do 0 work over a rep regardless of if you do it fast or slow.

waynexk8 said:
4,
So that’s more power in the fast,
Peak power, yes, average power is 0.

waynexk8 said:
5,
You move the weight 6 times further in the fast,
OK, this can be interpreted more than one way, but at least one of them is correct.

waynexk8 said:
6,
You fail with these variables, 50% faster in the fast = there MUST be more tension on the muscles per unit of time to make them fail faster, = more tension = there must be more total/overall force if there is more tension as on failing faster.
While I am sure that you do fail faster with fast reps I don't think that your conclusions follow. Something is exhausting the muscle's ability to function, but why MUST it be the tension/time. Why couldn't it be the energy expenditure/time, or the oxygen debt, or ATP depletion, or lactate buildup, or temperature rise? I can think of lots of things that it could be, so the MUST just isn't true. Just because they fail faster does not imply that there is more tension/time.

waynexk8 said:
7,
More speed, velocity and acceleration on the fast.
Definitely.

Please get back on track, if you want to get anything out of this you need to actually challenge yourself mentally and learn a bit. Do you understand the previous graph, in particular, do you see what is meant by impulse?
 
  • #259
waynexk8 said:
That’s quite odd ? What truth have you ?

1,
EMG states fast,

2,
You use more energy in the fast,

3,
You do more work in the fast.

4,
So that’s more power in the fast,

5,
You move the weight 6 times further in the fast,

6,
You fail with these variables, 50% faster in the fast = there MUST be more tension on the muscles per unit of time to make them fail faster, = more tension = there must be more total/overall force if there is more tension as on failing faster.

7,
More speed, velocity and acceleration on the fast.

Is that enough truth, not sure what you have ?

Wayne

O.K. Wayne...so you claim that all the above somehow prove that more force per unit of time is applied for the fast reps.
The least thing you should do is to try to prove with physics that those variables have the effect you claim.You obviously can't even try because you lack of even basic physics knowledge so you only have two options:

1)DaleSpam has the superhuman patience to help you learn step by step some basic physics.Shut up and read carefully what he writes.

2)A better and more time saving option...read DaleSpam's last post and just accept it as a fact with no question asked.Especially this part:
DaleSpam said:
so the MUST just isn't true. Just because they fail faster does not imply that there is more tension/time.
 
Last edited:
  • #260
DaleSpam said:
Wayne, please focus. I am trying to help you learn some physics, that is what you came here for, right?

Ok.

Yes, and thank you

DaleSpam said:
Do you understand the force-time diagram.

Yesish.

DaleSpam said:
Do you see how the force is not constant, but that it varies over the lift?

Yes I understand that all too well.

DaleSpam said:
Do you graphically see what the impulse is?

Not really sure what you are getting at here ? Are you saying/showing that my force will go up and up, as I am trying to accelerate the weight as much as I can, then as I have to decelerate it to stop for the transition in the repetitions, I have to use less force ? If so yes I see that. However I think the area for the acceleration deceleration is a bit out. We found in a study that when using 81% the bar actually decelerated for 52% of the ROM. {range of motion} However, there was a flaw in that lift, as the concentric part of that lift, took 1.5 seconds. So I would say one of my lifts would have more an acceleration of 80% so I am using close to 100% force for 80% of .5 of a second.

Wayne
 
  • #261
Wayne - you really can't bring yourself to believe that you are on a hiding to nothing and that what goes on in your arms is to do with your Muscles and their non-ideal behaviour. Muscles are not simple machines or springs and cannot be modeled as such. If they were, you would use no energy / force / strength / bananas if you just stood and held something stationary. You know that doesn't happen. Why keep ignoring this?
 
  • #262
waynexk8 said:
Yesish.
OK, that doesn't sound very confident. Can you explain what makes you hesitate or a little unsure?

waynexk8 said:
Not really sure what you are getting at here ?
I am not getting at anything yet, I am just teaching you the meaning of the various important quantities. Are you unsure about what it means to have an area under a curved line, or is there something else bothering you about the area under the force v time diagram?

waynexk8 said:
Are you saying/showing that my force will go up and up, as I am trying to accelerate the weight as much as I can, then as I have to decelerate it to stop for the transition in the repetitions, I have to use less force ? If so yes I see that.
That is correct. The part where you are accelerating it up is the "peak" on the force v. time diagram, and the part where you are decelerating it is the "valley".

waynexk8 said:
However I think the area for the acceleration deceleration is a bit out. We found in a study that when using 81% the bar actually decelerated for 52% of the ROM. {range of motion}
OK. So in the approximation I am using the bar is decelerating for 50% rather than 52%. We could certainly use more accurate representations of the motion, but if we did so the math would quickly get more complicated. I just used the simplest function that I thought was close. I am actually very glad to know that it is only ~2% off by that measure.
 
  • #263
Will get back to the older questions.

DaleSpam said:
EMG measures electrical activity in the muscles, not force nor energy.

Electrical muscle activity in the muscles is the force/strength they are using for the set time. Why/how could you think other, and what did you think it was ?

http://www.actabio.pwr.wroc.pl/Vol4No2/2.pdf

For the evaluation of muscle activities associated with force exertion the surface
electromyography method is well established. The amplitude of the EMG signal
quantitatively expresses muscle activity [16], [18], [32], [40] and has been used in
studies of various vocations to estimate muscle loads in tasks involving upper limbs [9],
[17], [38].
As maximum force exerted by the hand depends on upper limb location, for
musculoskeletal load assessment it is important to determine how the value of
maximum force changes in relation to upper limb location. Although studies which
considered this problem (as cited above) have been performed, taking into account
variety of upper limb locations, further research is still needed for normalisation
purposes.
The force which the muscle exerts as well as muscle tension expressed by the
amplitude of the EMG signal depend on muscle length (upper limb location) [3]. Also
the study of DUQUE, MASSET and MALCHAIRE [7] confirmed that differences in EMG
signal amplitude in the flexor carpi radialis muscle should occur according to wrist
flexion and extension, and the study of Wright (as cited in [6]) showed that the activity
of the long head of the biceps brachii depends on the arm abduction and arm rotation.
Muscle activity during force exertion can be spread up between muscle activity for
upper limb stabilisation in a defined upper limb location and activity connected with
the external force exertion. It should be expected that not only the component of
muscle activity, which is responsible for upper limb stabilisation, depends on upper
limb location but muscle activity associated with force exertion is influenced by upper
limb location as well. Therefore, it is also an interesting problem to see whether the
component of muscle activity, which is associated with handgrip force exertion, varies
according to upper limb location.

This is why I bought the EMG, to show what I call the total/overall muscle force or/and strength used in a set time will be different.

Let me try and prove my total/overall muscle force theory. Lift a very light weight up and down for 10 seconds, lift a very heavy weight up and down for 10 seconds, and the very heavy weight will need more total/overall force.


You use more energy in the fast,

=DaleSpam;3819491]Yes.

You do more work in the fast.

DaleSpam said:
No, you do 0 work over a rep regardless of if you do it fast or slow.

As I move the weight 12m to the slow 2m, that’s more work done ? Or are you saying, that if I move up, and then back down to the starting position I have done no work ? Still don’t get that, as I thought work was force times the distance through which goes, thus 12m = more distance the force was used for than the 2m ?

So that’s more power in the fast.

DaleSpam said:
Peak power, yes, average power is 0.

Don’t get that sorry ? Let's calculate how much power I would be used on both rep speeds. Distance weight 91 kg moved 1.85 M.

Determine the force we will need to figure out what the weight of the barbell is (W = mg = 91 kg x 9.81 m/s = 892 kg.m/s or 892 N). Now, if work is equal to Force x distance then, U = 892 N x 1.85 m = 1650 Nm.

We can calculate that lifting a 200 lb barbell overhead a distance of 1.85 m required 1650 J of work. You will notice that the time it took to lift the barbell was not taken into account.

Let us only add up the positive part of the lift.

The concept of power however, takes time into consideration. If for example, it took .5 seconds to complete the lift, then the power generated is 1650 J divided .5 s = 3300 J/s.

If it took 2 seconds to complete the lift, then the power generated is 1650 J divided 2 s = 825 J/s.

Slow set,
825 x 6 = 4950Joules.

Fast set,
3300 x 25 = 82500Joules

You move the weight 6 times further in the fast,

DaleSpam said:
OK, this can be interpreted more than one way, but at least one of them is correct.

K.

You fail with these variables, 50% faster in the fast = there MUST be more tension on the muscles per unit of time to make them fail faster, = more tension = there must be more total/overall force if there is more tension as on failing faster.

DaleSpam said:
While I am sure that you do fail faster with fast reps I don't think that your conclusions follow. Something is exhausting the muscle's ability to function, but why MUST it be the tension/time. Why couldn't it be the energy expenditure/time, or the oxygen debt, or ATP depletion, or lactate buildup, or temperature rise? I can think of lots of things that it could be, so the MUST just isn't true. Just because they fail faster does not imply that there is more tension/time.

Basically you fail faster because your muscles are working harder, and why would your muscles need to work harder ? Because they were using more force/strength per unit of time. As the muscles don’t work harder because things are getting easier, but they work harder like machines or anything else, when the situation gets harder, and its far harder to accelerate a weight 6 times in 6 seconds, and to move a weight 12m to 2m in the same time frame.

It will be also energy expenditure/time, oxygen debt, ATP depletion, lactate build-up, and temperature rise, but the question is, “why” do you use more of these ? I would think there can only be one answer, as the muscles are using more total/overall force, and having more total/overall force exerted on them, thus more tension on the muscles.

Question,
1,
I lift and fail at 24 seconds, I lift the weight 24 times and 48m, you lift the weight for 24 seconds, you lift the weight 4 times and 8m, if wanted you could lift the weight for 48 seconds, but you stop at 24 seconds, which muscle has worked the hardest ? Which do I use more force.

2,
I lift and fail 50% faster, at 30 seconds, I then lift up a lighter weight and lift it for another 30 seconds. which muscle has worked the hardest ?

Which do I use more force, 1 or 2 ? Which lifters muscles work the hardest ?

More speed, velocity and acceleration on the fast.

DaleSpam said:
Definitely.

Please get back on track, if you want to get anything out of this you need to actually challenge yourself mentally and learn a bit. Do you understand the previous graph, in particular, do you see what is meant by impulse?[/QUOTE]

Right answered that one.

Wayne
 
  • #264
waynexk8 said:
Electrical muscle activity in the muscles is the force/strength they are using for the set time. Why/how could you think other, and what did you think it was ?
I have a PhD in biomedical engineering and did some coursework and research in functional electrical stimulation for neuro-prosthetic applications, so I know a thing or two about EMG, EEG, EKG, muscle recruitment, electrical stimulation, pacemakers, etc. Electrical muscle activity measures voltage changes due to the depolarization of the muscle cell membranes during the muscle's action potential, not the force exerted by the muscle.

waynexk8 said:
The amplitude of the EMG signal
quantitatively expresses muscle activity [16], [18], [32], [40] and has been used in
studies of various vocations to estimate muscle loads in tasks involving upper limbs [9],
[17], [38].
Note, the key word "estimate". If you know the EMG and you know the tension v recruitment curve and you know the position of the limb and you know the force v tension curve for that position then you can use the EMG to make a good estimate as to what the force is. An estimate and a measurement are not the same thing. Force is measured with a force transducer, an EMG is a voltage transducer. The units of the EMG are μV, not N.

waynexk8 said:
This is why I bought the EMG, to show what I call the total/overall muscle force or/and strength used in a set time will be different.

Let me try and prove my total/overall muscle force theory. Lift a very light weight up and down for 10 seconds, lift a very heavy weight up and down for 10 seconds, and the very heavy weight will need more total/overall force.
Before you can prove your total/overall muscle force theory you need to define it, otherwise there is no theory to prove or disprove. That is the purpose of teaching you about the standard physics concepts. I am hoping that as you learn what is meant by them you can express your concepts in the standard language, clearly define your theory, and then we can see the implications.

So, let's talk a little more about impulse and see if it has the properties that you expect for "total/overall muscle force".

Impulse has the property that if you exert twice the force for the same amount of time you have doubled your impulse. So, for example, if you exert 100 lbs for 10 s and I exert 50 lbs for 10 s you have exerted twice the impulse that I have. Does this agree with your concept of "total/overall muscle force"?

Impulse also has the property that if you exert the same force for twice as long you have doubled your impulse. So, for example if you exert 100 lbs for 10 s and I exert 100 lbs for 5 s you have exerted twice the impulse that I have. Does this also agree with your concept of "total/overall muscle force"?
 
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  • #265
DaleSpam said:
Note, the key word "estimate". If you know the EMG and you know the tension v recruitment curve and you know the position of the limb and you know the force v tension curve for that position then you can use the EMG to make a good estimate as to what the force is. An estimate and a measurement are not the same thing. Force is measured with a force transducer, an EMG is a voltage transducer. The units of the EMG are μV, not N.

Hi DaleSpam...if you have the time check the paragraph "2.1 Participants and experimental protocol" in http://jmbe.bme.ncku.edu.tw/index.php/bme/article/viewFile/635/839 [Broken].Do you think that the magnitude total muscle activation (TMA) can give a good estimation of the impulse?It's basically the integration of the EMG curve in respect of time.

It's interesting that the TMA per second is greater for the slow puh ups(in contast of what Wayne claims).For example if you check the tables 1 and 3 for the pectoralis major:
for the slow push ups the TMA is 3121.81 for 101.2 sec.(TMA/t=30.85)
while for the fast push ups the TMA is 2114.22 for 84.2 sec.(TMA/t=25.11)
 
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  • #266
douglis said:
O.K. Wayne...so you claim that all the above somehow prove that more force per unit of time is applied for the fast reps.
The least thing you should do is to try to prove with physics that those variables have the effect you claim.You obviously can't even try because you lack of even basic physics knowledge so you only have two options:

Hi D. and all.

Are you trying to be sarcastic or something ? I mean we are on a physics forum, I have all ready proved this, ITS UP TO YOU TO “TRY” AND DISPROVE IT, the cards are in my hands, the EMG states you wrong.

Don’t you understand, it’s up to you to try and prove me wrong and you right, WHAT PROOF AND EVIDENCE HAVE YOU ?


1,
EMG states fast,

I have the videos to prove it. All EMGs state this; it was MORE than obvious to me and most.

I mean walk up a 1 mile very steep hill with a pack on your back, then “try” and run up it as fast as you can. Which is the hardest on the muscles or/and which physiologically causes the greatest stimulus, as they are fast and slow actions causing far far far different stimulus even though they produce the same mechanical work, as computed by moving the same load through the same distance.
2,
You use more energy in the fast,

This has been known for a 100 years, I knew this 40 years ago. And this physics site showed and proved this to you.

3,
You do more work in the fast,

Work is the product of a force times the distance through which it acts, I move the weight 12m you move it 2m in the same time frame.

4,
So that’s more power in the fast,


Lets calculate how much power I would be used on both rep speeds. Distance weight 91 kg moved 1.85 M.

Determine the force we will need to figure out what the weight of the barbell is (W = mg = 91 kg x 9.81 m/s = 892 kg.m/s or 892 N). Now, if work is equal to Force x distance then, U = 892 N x 1.85 m = 1650 Nm.

We can calculate that lifting a 200 lb barbell overhead a distance of 1.85 m required 1650 J of work. You will notice that the time it took to lift the barbell was not taken into account.

Let us only add up the positive part of the lift.

The concept of power however, takes time into consideration. If for example, it took .5 seconds to complete the lift, then the power generated is 1650 J divided .5 s = 3300 J/s.

If it took 2 seconds to complete the lift, then the power generated is 1650 J divided 2 s = 825 J/s.

Slow set,
825 x 6 = 4950Joules.

Fast set,
3300 x 25 = 82500Joules


5,
You move the weight 6 times further in the fast,

I move the weight 12m you move the weight 2m

6,
You fail with these variables, 50% faster in the fast = there MUST be more tension on the muscles per unit of time to make them fail faster, = more tension = there must be more total/overall force if there is more tension as on failing faster.

There is a huge study proving this, have no time to find it right now, but you have seen it.

And there is my video.


http://www.youtube.com/watch?v=sbRVQ_nmhpw&list=UUTeoEssmCPZycmfODrHvM2w&index=71&feature=plcp7,
More speed, velocity and acceleration on the fast.

Well if you don’t understand that ?
douglis said:
1)DaleSpam has the superhuman patience to help you learn step by step some basic physics.Shut up and read carefully what he writes.

I am listening and answering, and all here are very intelligent and polite, and I thank them.

But no one is disproving what I say, like the 1 to 7 above, just try and say prove the EMG is wrong, but that’s not possible, as it’s a test that’s been done over and over by me, and 100,00 around the World, it’s one of the first tests people do when learning EMG, it’s a standard test.

Then there is you fail 50% faster, I mean that’s more obvious than 1 + 1 = 2, I mean you fail faster because the faster reps, like running to walking are far hider, they are harder because your putting more total/overall tension per unit of time on the muscles, that more tension = more total/overall force per unit of time on the muscles, or what do you think it means.

Why do you think your using more energy ? Look, what happens when you run faster and faster, you use more and more force, vertical and horizontal and a little different, but basically the same, you have to use more force to run faster, and more force to rep the weight faster.

douglis said:
2)A better and more time saving option...read DaleSpam's last post and just accept it as a fact with no question asked.Especially this part:

Will read his posts now.

Wayne
 
  • #267
Could someone please answer this.


What forces do you think you have that can make up of balance out the higher propulsive forces of the fast in the studies ?

Let’s take the mean propulsive forces, slow 6.2mean in 10.9 seconds. Fast 45.3mean 2.8 seconds, now let’s divided the mean slow of 10.9 seconds by the fast 2.8 = 3.8, so now let’s divide the slow mean by 3.8 = 1.6.

Fast mean for 2.8 seconds = 45.3.

Slow mean for 2.8 seconds = 1.6.

The fast has nearny 3000% more mean propulsive force as in N's in the same time frame.

Please what forces have I left out that the slow has to make up or balance out these ?

http://www.jssm.org/vol7/n2/16/v7n2-16pdf.pdf

Wayne
 
  • #268
sophiecentaur said:
Wayne - you really can't bring yourself to believe that you are on a hiding to nothing and that what goes on in your arms is to do with your Muscles and their non-ideal behaviour. Muscles are not simple machines or springs and cannot be modeled as such. If they were, you would use no energy / force / strength / bananas if you just stood and held something stationary. You know that doesn't happen. Why keep ignoring this?

Not sure what you mean here ? I know its to do with my muscles, but I thought we were not debating this out on a machine repping the weight ?

I need to get back to your other post from a few days ago, sorry there.

Wayne
 
  • #269
How do you work that out ? What machine can lift say 80% up, and then lower it down using very little energy, and what energy is this ?

Wayne

sophiecentaur said:
Plus all the rest
That comment shows that yo don't get the mosgt basic part of all this thread and others.

The machine doesn't need to use use "very little energy" on the way down. IT GETS ALL THE ENERGY BACK! Unlike your muscles, which don't have Energy Recovery. So the two cannot be compared.

Where and how does the machine get its energy back ? It will be powered by say diesel or electricity, let’s say diesel, so it uses, let’s just say a half a pint of diesel to lift the weight, you tell me where and how the machine gets that diesel back ? You know very well that when the half a pint of diesel is gone, has been used to lift the weight, you can “never” get it back.

And when it lowers the weight, it will have to use energy again, as in the diesel, a little less this time, but it has to use energy/diesel to move in any direction, as its using force, and this force is putting tension on the machine.

sophiecentaur said:
You insist that this problem can be solved your way and you have the nerve to hang onto the idea in the face of people who know much more basic Physics than you.

You and all here know physics far better than me, but I give you 7 real World practical points proving your theory does not fit, and as you know, a theory, is just a theory until you can prove it with a practical experiment, and I have proved it wrong and few times.

Just for now take the EMG, and the fact that you fail 50% faster.

Also, what have you proved ? I see no equations, what you did say that there is no such thing as total/overall force in physics, yet the EMG reads out a higher average reading on the faster, and the EMG work with the equations of physics, they are put in the EMG.

I thought is was the physics job to do the theory, and when the practical proves this wrong, the physics needs to be looked at.

sophiecentaur said:
The only hope you have is to do a Physics course at some level which may help you understand what you need to know in order to grasp how crazy your idea is.
If someone told you that swimming the Pacific is a no no, how long would you not believe them?

I do see what you mean, but what about my points, like the EMG, and the fact you fail faster, they can only mean one thing, the fast is putting more tension on the muscle, and the only way to put more tension on the muscle is by putting out more force, and taking more force on the muscles.

Wayne
 
  • #270
Could anyone please answer this ?

I was just wondering and thinking, ARE you adding “all” the force, I mean with the fast there are NOT just force being exerted by the muscles, there are HUGE forces on them, for say .1 of a second x the 6 reps = high forces on the muscle for maybe .6 of a second. Have you added these in ?

I mean the peak force from the transition from negative to positive, the force on the muscle, NOT given out by the muscles ? We call them the MMMTs {Momentary Maximum Muscle Tensions} these forces “ON” the muscles can be as high as 140%

Have you added these on ?

Lift 1,
You lift 80% of the ground, up 1m and then down 1m all in 1 second, .5/.5

Lift 2,
You start at the top, lower the weight down 1m, and then lift it back up 1m all in 1 second, .5/.5

On lift 2, on the transition from negative to positive, there will be huge force on the muscles and coming from the muscles.

Wayne
 
  • #271
waynexk8 said:
How do you work that out ? What machine can lift say 80% up, and then lower it down using very little energy, and what energy is this ?

Wayne



Where and how does the machine get its energy back ? It will be powered by say diesel or electricity, let’s say diesel, so it uses, let’s just say a half a pint of diesel to lift the weight, you tell me where and how the machine gets that diesel back ? You know very well that when the half a pint of diesel is gone, has been used to lift the weight, you can “never” get it back.

And when it lowers the weight, it will have to use energy again, as in the diesel, a little less this time, but it has to use energy/diesel to move in any direction, as its using force, and this force is putting tension on the machine.



You and all here know physics far better than me, but I give you 7 real World practical points proving your theory does not fit, and as you know, a theory, is just a theory until you can prove it with a practical experiment, and I have proved it wrong and few times.

Just for now take the EMG, and the fact that you fail 50% faster.

Also, what have you proved ? I see no equations, what you did say that there is no such thing as total/overall force in physics, yet the EMG reads out a higher average reading on the faster, and the EMG work with the equations of physics, they are put in the EMG.

I thought is was the physics job to do the theory, and when the practical proves this wrong, the physics needs to be looked at.



I do see what you mean, but what about my points, like the EMG, and the fact you fail faster, they can only mean one thing, the fast is putting more tension on the muscle, and the only way to put more tension on the muscle is by putting out more force, and taking more force on the muscles.

Wayne

Here you go again - leaping in with both feet in the absence of knowledge. Do you know the difference between a Machine and an Engine? Of course a diesel engine has no energy return but a Machine, consisting of no more than a SPRING can lift and lower a weight without losing any energy at all (allowing for a minuscule amount, due to friction.

You have got it wrong when you say it is up to us to Disprove what you say. I'm afraid that it is up to you to Prove what you say because it goes against all known Physics. Just read any simple textbook to find out the meanings and derivations the various terms that you are using with such abandon.

There is not a single statement from any of us which denies the fact that you feel more knackered and your muscles ache more when you are doing exercise faster. Our issue it that you are trying to 'explain' this in 'physics' terms that just don't apply. You have a gut feeling that it should be straightforward but you don't seem to realize just how muscles actually work. If you read what douglis tells you, instead of giving all those "but surely" - type responses then you might learn something.

Most people come on this forum in order to learn something. You have breezed in and you're trying to tell us all how we should be able to do something with the Physics that we understand but that you do not. Do you ever consider that you might just be plain wrong in this?
 
  • #272
waynexk8 said:
Hi D. and all.

Are you trying to be sarcastic or something ? I mean we are on a physics forum, I have all ready proved this, ITS UP TO YOU TO “TRY” AND DISPROVE IT, the cards are in my hands, the EMG states you wrong.

Wayne

OMG you're really delusional.You don't have a clue about basic physics terms and you think have proved something!ALL your nonsesnse from 1-7 show NOTHING in terms of force.
I won't repeat them...it's a waste of time.
For your own good...quit your nonsense and just focus on DaleSpam's posts...he's really trying to help you.
 
  • #273
waynexk8 said:
Could anyone please answer this ?

I was just wondering and thinking, ARE you adding “all” the force, I mean with the fast there are NOT just force being exerted by the muscles, there are HUGE forces on them, for say .1 of a second x the 6 reps = high forces on the muscle for maybe .6 of a second. Have you added these in ?

I mean the peak force from the transition from negative to positive, the force on the muscle, NOT given out by the muscles ? We call them the MMMTs {Momentary Maximum Muscle Tensions} these forces “ON” the muscles can be as high as 140%

Have you added these on ?
Yes. Newton's 3rd law guarantees that at all times the force of the mass on the person is equal and opposite to the force of the person on the mass. A MMMT would be seen in a sudden spike in the acceleration or deceleration of the mass.

Can you please respond to my questions of post 265?:

Before you can prove your total/overall muscle force theory you need to define it, otherwise there is no theory to prove or disprove. That is the purpose of teaching you about the standard physics concepts. I am hoping that as you learn what is meant by them you can express your concepts in the standard language, clearly define your theory, and then we can see the implications.

So, let's talk a little more about impulse and see if it has the properties that you expect for "total/overall muscle force".

Impulse has the property that if you exert twice the force for the same amount of time you have doubled your impulse. So, for example, if you exert 100 lbs for 10 s and I exert 50 lbs for 10 s you have exerted twice the impulse that I have. Does this agree with your concept of "total/overall muscle force"?

Impulse also has the property that if you exert the same force for twice as long you have doubled your impulse. So, for example if you exert 100 lbs for 10 s and I exert 100 lbs for 5 s you have exerted twice the impulse that I have. Does this also agree with your concept of "total/overall muscle force"?
 
  • #274
Read the other posts later, just going to price some jobs up, and just thought of this, and again thank you for your help and time.

PLEASE let’s try this way. 1RM or maximum you can lift up one time = 100 pounds.

1,
I lift a 90 pounds and hold it half way up for 20 seconds, as I am first applying over 90% or/and 90 pounds of force, then hold it steady with 90% or/and 90 pounds of force and then lower.

2,
You as you are only applying 80% or/and 80 pounds of force, do not, cannot lift the weight, as your only apply 80% or/and 80 pounds of force.1a,
I have applied an average of 90% or/and 90 pounds of force for 20 seconds = 90F x 20S.

2b,
You have applied an average of 80% or/and 80 pounds of force for 20 seconds = 80F x 20S.

HOWEVER, the three of you here, are telling me that 80F = 90F and that we have both applied the same amount of force for the 20 seconds, EVEN thou we all agree that I use 90F and you use 80F, you turn around after agreeing that, and say different, and that we used the same force for the same time frame ?


Wayne
 
  • #275
waynexk8 said:
HOWEVER, the three of you here, are telling me that 80F = 90F and that we have both applied the same amount of force for the 20 seconds, EVEN thou we all agree that I use 90F and you use 80F, you turn around after agreeing that, and say different, and that we used the same force for the same time frame ?

Wayne

Who agrees with that?The three of us are telling you that we both apply 80 pounds on average for 20 sec but for some reason you're unable to understand it.Your above example does not represent what happens in dynamic lifting where ALWAYS force equal with the weight is applied for the duration of the set.Regardless the lifting speed.
Stop your nonsense and read carefully what we write.
 
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  • #276
douglis said:
Hi DaleSpam...if you have the time check the paragraph "2.1 Participants and experimental protocol" in http://jmbe.bme.ncku.edu.tw/index.php/bme/article/viewFile/635/839 [Broken].Do you think that the magnitude total muscle activation (TMA) can give a good estimation of the impulse?
Thanks for the paper, it was an interesting read. The TMA, by itself, is not an estimate of impulse, but scaled by the corresponding force data from the dynamometer, it would be. Of course, the estimate would be pretty inaccurate since the forces would vary with both joint position and speed for a given EMG reading.

However, it is probably good enough to make relative assessments. I.e. you couldn't use it to estimate that the impulse was X, but you could use it to estimate that the impulse was greater for the slow than for the fast (due to the longer time).

douglis said:
It's interesting that the TMA per second is greater for the slow puh ups(in contast of what Wayne claims).For example if you check the tables 1 and 3 for the pectoralis major:
for the slow push ups the TMA is 3121.81 for 101.2 sec.(TMA/t=30.85)
while for the fast push ups the TMA is 2114.22 for 84.2 sec.(TMA/t=25.11)
Yes, I found that interesting too. I am thinking of what properties Wayne should be looking for in selecting a measure. Here is what I came up with.

1) it should be physical, and not require biomechanical or physiological information
2) it should scale with weight
3) it should scale with time
4) for a fixed weight and measure decreasing the rep rate should increase the time
5) for a fixed weight and measure increasing the rep rate should increase the number of reps

I can't think of any more based on the data. Impulse is actually pretty close, it accomplishes all of those except 4).
 
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  • #277
DaleSpam said:
Yes, I found that interesting too. I am thinking of what properties Wayne should be looking for in selecting a measure. Here is what I came up with.

1) it should be physical, and not require biomechanical or physiological information
2) it should scale with weight
3) it should scale with time
4) for a fixed weight and measure decreasing the rep rate should increase the time
5) for a fixed weight and measure increasing the rep rate should increase the number of reps

I can't think of any more based on the data. Impulse is actually pretty close, it accomplishes all of those except 4).

The numbers 1,2 and 3 are achieved with the "normalization" of the EMG data like it's described at the paragraph "analysis and treatment EMG data" at this http://www.scribd.com/coldstreamer/d/2528195-Elliot-et-al-A-biomechanical-analysis-of-the-sticking-during-the-bench-press.

You can also see many force-time graphs where the impulse can be easily calculated.
 
  • #278
douglis said:
The numbers 1,2 and 3 are achieved with the "normalization" of the EMG data like it's described at the paragraph "analysis and treatment EMG data" at this http://www.scribd.com/coldstreamer/d/2528195-Elliot-et-al-A-biomechanical-analysis-of-the-sticking-during-the-bench-press.
Note figure 6b. In that figure the EMG is lower during the descent compared to the sticking region, but the force is higher.
 
  • #279
Wayne wrote;
Could anyone please answer this ?

I was just wondering and thinking, ARE you adding “all” the force, I mean with the fast there are NOT just force being exerted by the muscles, there are HUGE forces on them, for say .1 of a second x the 6 reps = high forces on the muscle for maybe .6 of a second. Have you added these in ?

I mean the peak force from the transition from negative to positive, the force on the muscle, NOT given out by the muscles ? We call them the MMMTs {Momentary Maximum Muscle Tensions} these forces “ON” the muscles can be as high as 140%

Have you added these on ?

DaleSpam;3824653Yes. Newton's 3rd law guarantees that at all times the force of the mass on the person is equal and opposite to the force of the person on the mass. A MMMT would be seen in a sudden spike in the acceleration or deceleration of the mass.

Yes a sudden spike would be the MMMT’s.

But please, there “HAS” to be different force/s generated in both lifts, which one are you saying that you think is equal to the slow lift.

Lift 1,
You lift 80% of the ground, up 1m and then down 1m all in 1 second, .5/.5


Lift 2,
You start at the top, lower the weight down 1m, and then lift it back up 1m all in 1 second, .5/.5


On lift 2, on the transition from negative to positive, there will be huge force on the muscles and coming from the muscles, so this lift “will” generate more tension on the muscles, agreed ? if there is more tension on the muscles as in lift 2, and there is, as this can be proven practically quite easy, there must be more force.


DaleSpam said:
Can you please respond to my questions of post 265?:

Ok will go back first thing tomorrow, sorry I missed, very glad you said.

DaleSpam said:
Before you can prove your total/overall muscle force theory you need to define it, otherwise there is no theory to prove or disprove.

Right, agreed.

DaleSpam said:
That is the purpose of teaching you about the standard physics concepts. I am hoping that as you learn what is meant by them you can express your concepts in the standard language, clearly define your theory, and then we can see the implications.

We could ask, which is harder, more fatiguing on the muscle, this is the fast, so why is the fast harder and more fatiguing. First we know that you use far far far more energy on the fast in the same time frame, we all should be asking why is this, to find that out, maybe we should go a step further, the fast moves the weight 6 times the distance in the same time frame, to me if you move something further in the same frame, and 6 times further, you have to use more force, that equals the more energy used.

If not, you here seem to be saying you can move a weight 6 times further in the same time frame, using the exact same force that you only moved the weight 2m, as to 12m with the fast, please could you show and tell me how you can move the weight 6 times further using the exact same force as you used to move the weight just 2m with the slow rep ?

I as I said before, I try to use a 100 pounds of force for 6 seconds equals 100 pounds of force for 6 seconds, call it 100f x 6s, that’s why I move the weight further, as I use more force for the same time frame.

You use 80 pounds of force for 6 seconds call it 80f x 6s.

How can 80 force used for 6 seconds be as high as 100 force used for 6 seconds ?


You also seem to be saying the Second law is wrong, the acceleration a of a body is directly proportional to the net force F and inversely proportional to the mass, F = ma.

Please could someone answer this one.


What forces do you think you have that can make up of balance out the higher propulsive forces of the fast in the studies ?

Let’s take the mean propulsive forces, slow 6.2mean in 10.9 seconds. Fast 45.3mean 2.8 seconds, now let’s divided the mean slow of 10.9 seconds by the fast 2.8 = 3.8, so now let’s divide the slow mean by 3.8 = 1.6.

Fast mean for 2.8 seconds = 45.3.

Slow mean for 2.8 seconds = 1.6.

The fast has nearly 3000% more mean propulsive force as in N's in the same time frame.

Please what forces have I left out that the slow has to make up or balance out these ?

http://www.jssm.org/vol7/n2/16/v7n2-16pdf.pdf


DaleSpam said:
So, let's talk a little more about impulse and see if it has the properties that you expect for "total/overall muscle force".

Ok, great.

DaleSpam said:
Impulse has the property that if you exert twice the force for the same amount of time you have doubled your impulse. So, for example, if you exert 100 lbs for 10 s and I exert 50 lbs for 10 s you have exerted twice the impulse that I have. Does this agree with your concept of "total/overall muscle force"?

Impulse also has the property that if you exert the same force for twice as long you have doubled your impulse. So, for example if you exert 100 lbs for 10 s and I exert 100 lbs for 5 s you have exerted twice the impulse that I have. Does this also agree with your concept of "total/overall muscle force"?

Yes, that’s perfect and exactly what I have been saying, at last I think we all agree on something statisticaly.

So as I said above, if I try to exert 100 lbs for 10 s and you exert 80 lbs for 10 s, have not I have exerted 20% more the impulse than you have ? As that’s why I use more energy and more the weight further, and also fail faster, as of my temporary force has been used up faster.

Wayne
 
  • #280
waynexk8 said:
You also seem to be saying the Second law is wrong, the acceleration a of a body is directly proportional to the net force F and inversely proportional to the mass, F = ma.
I am not saying that at all. The second law is correct; you just have some misunderstandings. We will get to those in a bit. Right now we need to focus on the progress that we have made and flesh out the concept of impulse.

waynexk8 said:
Yes, that’s perfect and exactly what I have been saying, at last I think we all agree on something statisticaly.

So as I said above, if I try to exert 100 lbs for 10 s and you exert 80 lbs for 10 s, have not I have exerted 20% more the impulse than you have ?
OK, so now that we have confirmed that your concept of "total force" is the same as the standard physics concept of "impulse" I expect you to not write the words "total force" any more and to use the correct term "impulse". You may think that this is nitpicky, but there is a very important reason for doing this. Impulse has units of momentum, and not units of force, so the term "total force" is not only non-standard but incorrect. Something that does not have units of force cannot be any kind of force, let alone a "total force". Do you agree to this?

So, if you exert a constant 100 lb for 10 s then you have exerted an impulse of 1000 lb*s. And if you exert a constant 80 lb for 10 s then you have exerted an impulse of 800 lb*s. If you drew a force v time curve as I did above then each of these would be a simple straight flat line. And in both cases we would get the impulse by calculating the area under the curve (area of a rectangle is base times height which in this case is the time times the force).

OK, so now let's work a couple of problems to solidify the concept of impulse. Please show your work:

1) What is the impulse if you exert a 100 lb force for 5 s and then 80 lb for an additional 5 s?

2) What constant force would give the same impulse as in 1) if exerted over 10 s?

3) What is the impulse for the attached force vs time graph? (Hint: remember that the impulse is the area under the graph which is shaded in this graph and also remember that the area of a triangle is 1/2 base times height.)

4) What constant force would give the same impulse as in 3) if exerted over the same amount of time?

The graph is plotted in Mathematica using the following code:
Code:
y[t_] := 100 - 10 t;
Plot[y[t], {t, 0, 10}, Frame -> True, 
 FrameLabel -> {Style["Time (s)", Larger], 
   Style["Force (lb)", Larger]}, 
 PlotLabel -> Style["Force vs Time", Larger], Filling -> 0]
 

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<h2>1. What is impulse?</h2><p>Impulse is a measure of the change in momentum of an object. It is equal to the force applied to an object multiplied by the time for which the force is applied.</p><h2>2. How is impulse calculated?</h2><p>Impulse is calculated by multiplying the force applied to an object by the time for which the force is applied. The unit of impulse is Newton-seconds (N·s) in the metric system, or pound-seconds (lb·s) in the imperial system.</p><h2>3. What is the relationship between impulse and force?</h2><p>Impulse and force are directly proportional to each other. This means that the greater the force applied to an object, the greater the impulse will be. Similarly, the longer the force is applied, the greater the impulse will be.</p><h2>4. How is impulse related to change in momentum?</h2><p>Impulse is equal to the change in momentum of an object. This means that the impulse applied to an object will result in a change in its momentum. The direction of the change in momentum will depend on the direction of the force applied.</p><h2>5. How is impulse measured in pounds for a specific time frame?</h2><p>In the imperial system, impulse is measured in pound-seconds (lb·s). This means that the force applied must be measured in pounds (lb) and the time for which the force is applied must be measured in seconds (s).</p>

1. What is impulse?

Impulse is a measure of the change in momentum of an object. It is equal to the force applied to an object multiplied by the time for which the force is applied.

2. How is impulse calculated?

Impulse is calculated by multiplying the force applied to an object by the time for which the force is applied. The unit of impulse is Newton-seconds (N·s) in the metric system, or pound-seconds (lb·s) in the imperial system.

3. What is the relationship between impulse and force?

Impulse and force are directly proportional to each other. This means that the greater the force applied to an object, the greater the impulse will be. Similarly, the longer the force is applied, the greater the impulse will be.

4. How is impulse related to change in momentum?

Impulse is equal to the change in momentum of an object. This means that the impulse applied to an object will result in a change in its momentum. The direction of the change in momentum will depend on the direction of the force applied.

5. How is impulse measured in pounds for a specific time frame?

In the imperial system, impulse is measured in pound-seconds (lb·s). This means that the force applied must be measured in pounds (lb) and the time for which the force is applied must be measured in seconds (s).

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