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
  • #141
Power = Force TIMES Velocity
Forget whether it's "muscle power" or power from anything else. Also, forget words like"far, far" - these things are just proportional. And Power is an instantaneous value, varying as force or velocity varies.
If you can accept this, then we have started talking the same language.
 
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  • #142
This was from an EMG expert. It shows my EMG results are quite right, and D. does not know the difference between the two EMGs, as basically there is no diffrence. What is basically proves, is that the on the faster reps, the higher peak forces from the accelerations, cannot be made up balanced out with the constant medium forces of the slower reps, when the faster reps are producing less force on the decelerations. This seems quite obvious to me, as if I struck something very hard like a heavy barbell, it’s going to put a huge jolt/tension on my muscles, do this 6 times in the same time frame as someone moving the barbell slow, and the muscles will, as they do feel very high tension on them and fatigue far far far faster than when moving the barbell slow.
Hi Wayne,

Thanks for considering our products - while our EMG systems are research orientated and will give you the best quality data, realistically in this situation the quality of your results will be far more dependent on the way that the system is used and the way that the data is interpreted. My advice would be to record the data as raw data - obtain the best raw EMG data that you can and then process the data to determine the results. By recording raw data you have the opportunity to reprocess the data in different ways to discover the best processing methods.

The difference between integrated mean EMG data and RMS EMG data is simply mathematical - the end results are simply derived from slightly different processing methods. I'd suggest a couple of books that you might want to obtain and read that discuss the different methods:

Cram JR, Kasman GS, Holtz J: Introduction to Surface Electromyography. Aspen Publishers ISBN 0-8342-0751-6
Craik RL, Otis CA : Gait Analysis:Theory and application. Mosby ISBN 0-8016-6964-2

Wayne
 
  • #143
sophiecentaur said:
Power = Force TIMES Velocity
Forget whether it's "muscle power" or power from anything else. Also, forget words like"far, far" - these things are just proportional.

Right.

sophiecentaur said:
And Power is an instantaneous value,

So "if" we were using the exact same power over 10 seconds, and could mesure/read this power to be the exact same every .1 of a seconds, could we say I 100J in 10 seconds, and for 20 seconds would be 100J

This equation for power states that a powerful machine/muscle is both strong and fast ?

sophiecentaur said:
varying as force or velocity varies.
If you can accept this, then we have started talking the same language.

Do you mean if force and velociry goes up so does power ? Or when power goes up so must force and velocity.

Wayne
 
  • #144
Wayne wrote; douglis wroute; said:
When I say which uses the most overall/total force, I mean, if you lift 80 pounds for 10 seconds, and then lift 40 pounds for 10 seconds, you will have used more overall/total force lifting the 80 pounds for 10 seconds.

And you will in the above use more energy lifting the 80 pounds, right ? Thus EVERY time you use MORE energy, you have to use MORE force, right ? As you are using more acceleration and velocity = more force/energy.

You can not show me a faster lift, where you don't use more energy, when you are not using more acceleration/velocity and these = force,

Wayne

douglis;3769291]No...it's possible to use the same and even more energy by lifting explosively the 40 pounds even though the average force is the half.The huge fluctuations of force are very energy demanding.

Sorry you got that wrong, I said if I lift 80 pounds for 10 seconds and 40 pounds for ten seconds, what I meant as I did not state speed or distance, was both amounts lifted the same speed and thus distance. This then would mean I have used more total or overall force and energy lifting the heaver weight.

douglis said:
In fact,there was a study that compared the energy expenditue of light weighted jump squats vs heavy squats.The jump squats used more energy but obviously their "total/overall force" was less.

You are one about different weights used, I am not.

douglis said:
For the last time.Greater energy expenditure doesn't equate greater force.

I am on about the same weight, the above was just to explain to you how you will use more total or overall force, it had nothing to do with the actual debate.

I move 80 pounds up and down 20 times in 10 seconds, you lift 80 pounds up and down 1 time in 10 seconds, I use more energy.

Greater energy expenditure does equate greater force, if you move the same weight faster in the same time frame.

Wayne
 
  • #145
waynexk8 said:
I move 80 pounds up and down 20 times in 10 seconds, you lift 80 pounds up and down 1 time in 10 seconds, I use more energy.

More energy yes...more peak force yes...but the average force is 80 pounds in both cases hence the forces "make up".

Greater energy expenditure does equate greater force, if you move the same weight faster in the same time frame.

Wayne

Well...since you discovered a new law...all you have to do is to prove it somehow or else it will remain a figment of your imagination.
 
  • #146
Wayne
You still seem to be insisting that your muscles and the way your body controls them are much simpler than they are. No one has argued that doing things faster can knacker you more and can damage muscles. It's just that you seem to insist on having a simple Physics formula - but not real Physics - your brand of Physics, in which all the names are jumbled up and re defined. No wonder we can't help you.
 
  • #147
douglis said:
1)The average force is the weight.

What your trying to say, or think, is that if you hold 80 pounds half way up for 10 seconds, and I move the weight up and down 20 times in 10 seconds, that we have both put out the exact same total/overall force thus tension on the muscles, right ?

“If” that were so, then why does anyone that uses 80% of their 1RM {repetition maximum} fail in lifting the weight, or/and hit momentary muscular failure say 50% faster ? I will tell you why. Its because the higher force needed for the accelerations, and for the decelerations, as on the decelerations you are still pressing with as much force as you can, its only on the very last portion of the lift that you immediately lower force very fast for the transition from positive to negative, then immediately on the negative there is force from the muscles thus tension on the muscles.

So there we have it, you fail faster, and this is basically because the faster reps “are” putting more tension on the muscles, so they fatigue/tire 50% faster. But your saying they don’t they fatigue/tire faster or put more tension on the muscles, your saying that they fatigue/tire 50% faster, because they use up more energy, and they use up more energy not because they are moving with greater acceleration = more force, or traveling with more velocity = more force, your saying they just they fatigue/tire faster because of no reason than they use more energy for some unknown reason, is that right ?

You also think that your medium forces can make up or balance out my higher forces, but you cannot say why ? However I can say why I say it’s not, as I move the weight 6 times more distance, use more power, that’s more energy and more work done.

Question to all please
If I was to lift and try to throw the same weight with open hands, are you saying then I would use more force ?

douglis said:
2)The peak force requires more data.If you use an accelerometer you can find the peak acceleration and then the peak force.

Yes.

douglis said:
3)Total or overall force doesn't exist in physics.What you're looking for is the integrated EMG or maybe you can describe it with gravity's impulse which is the same in both cases of your example(weight X 6 seconds).

So what about tension, can physics find out how much tension was put on so and so ?

No, that’s where the EMG and force plate come into action, these work out the total or overall force, or and average force.

If you think total or overall force does not exist in physics, why are you saying both lifts have the same total or overall force ?

We could call this total of overall force, total force with respect to time, so if I put 100 force on 80 pounds for 4 seconds, and you put 80 force on 100 pounds for 4 seconds, who put out the total or overall force ? As I would have moved the weight further, that would categorically say I did, right ? If not why ? If I put 100 force on 80 pounds for 4 seconds, and you put 80 force on 100 pounds for 6 seconds, who put out the total or overall force ? As I would have moved the weight further, that would categorically say I did, right ? if not why ? If I put 100 force on 80 pounds for 4 seconds, 79 pounds of force for 2 seconds, and you put 80 force on 100 pounds for 6 seconds, who put out the total or overall force ? As I would have moved the weight further, that would categorically say I did, right ? If not why ? And ? Means I am please asking you a question.

You seem to think, that as I move the weight further, I don’t use more total or overall force to do this ?

Wayne
 
  • #148
I do not subscribe to the term "total force". There is no such quantity in Physics. So the rest of your post means nothing, I'm afraid.
 
  • #149
sophiecentaur said:
Wayne
You still seem to be insisting that your muscles and the way your body controls them are much simpler than they are.

That are far more complicated, and am trying to simplify things, as instead of muscles, we can just say this is a machine pushing the muscles with force, and if you put too much strain on that machine, it will fail faster than the machine you don’t put as much strain, and strain in this case is higher force output, and thus more tension on the machines moving parts. Put to more strain on the machine, as in making it move as fast as it can with very high accelerations, and there will be too much tension on the machine, and it will fail. Same are the car that have been driven further, its parts fail faster, and that’s because more acceleration force thus tensions on the moving parts.

sophiecentaur said:
No one has argued that doing things faster can knacker you more and can damage muscles.

Ok thanks for that.

But I see it as the higher acceleration forces, anytime you move faster, it could be 3/3 against 10/10 in the same time frame, but every time you try and move faster, there has to be more acceleration, thus higher forces on the muscles.

sophiecentaur said:
It's just that you seem to insist on having a simple Physics formula - but not real Physics - your brand of Physics, in which all the names are jumbled up and re defined. No wonder we can't help you.

Sorry I am trying, but if D. is right, then physics does not have an equation for total or overall force, in the same time frame “could not we be the first to try and find one ?” As physics is physics, we should be able to work this out somehow, or is it the power equation, power = force acceleration ? Thus we all know there is more power in the faster, if more power and more power = more force acceleration, then am I not right ?

Will read the other posts later and get back to them, thank you for your time and help again.

What if a bought a force plate ?

Wayne
 
  • #150
waynexk8 said:
your saying they just they fatigue/tire faster because of no reason than they use more energy for some unknown reason, is that right ?

No...the reason is very well known.Biology studies tell us that the fluctuations of force are more energy demanding.

You also think that your medium forces can make up or balance out my higher forces, but you cannot say why ?

Everyone has told you why.Because the average force is the weight in any case.This by definition means that "your" higher peaks are exactly balanced by "your" lower peaks and the result is "my" medium force(the weight).

“could not we be the first to try and find one ?”
Wayne
First learn to use the basic physics terms and leave your big plans for the much later future.
 
  • #151
But in full tomorrow night and I must apologise for not answering some posts yet, I will get back to them, and thank you all again.

The below is again for D. it’s from “another” EMG expert. And would be interested to see how/or why he was wrong, and thought my EMG was wrong, mind you it’s not the first time you have been wrong, you had metabolism wrong, energy wrong, your rocket theory, now EMG, however we all get things wrong and you’re a very clever person. I got my training wrong for 15 years, doing the slow, so I cannot pass judgment.

Hi Wayne,

I got the email you sent to Motion Labs - we have a cooperation with them. The company I work for - prophysics AG in Zurich, Switzerland - market and sell the myon EMG system as well as the proEMG data capture and analysis software.

You can check out details of our prophysics on www.myon-prophysics.ch [Broken]

I read through your email. EMG measures the electrical activity of muscles using electrodes attached to the skin surface above the muscle's belly. To answer your direct question, whether to use Integrated or RMS calculation, the answer is probably RMS. The reason for this is that the RMS calculation is the "standard" way of representing the average voltage amplitude of the signal, and this is correlated with the muscle power.

Wayne
 
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  • #152
Wayne
For someone who claims to know nothing of Physics, you have become very assertive and a bit too stroppy for my liking.
Nothing I have ever written about the Physics of this topic is wrong. It's just too basic and glaringly obvious. The same goes for Douglis's statements about Physics.

The stuff about EMG results is not the Physics of moving masses up and down. I's about what your Muscles are doing. The fact is that, even when lowering something, your muscles are using energy (unless you just drop it on the floor). Hence, there is no direct relationship between Energy Expended in your muscles and Work Done on the Weights you lift. That is the beginning and end of the whole topic and neither you nor your fellow EMG users can change it.

The readings on your EMG machine can give you a lot of useful information about your Body and that's all.

I can't actually understand what you are trying to achieve here and slagging people off for making statements that you clearly don't actually understand is not getting us anywhere.
 
  • #153
waynexk8 said:
it’s not the first time you have been wrong, you had metabolism wrong, energy wrong, your rocket theory, now EMG, however we all get things wrong and you’re a very clever person.

Show me where I was wrong.
From physics point of view...you can not possibly know if you spend more energy by lifting and lowering a weight than just holding it for the same duration.Only biology has the answer...so I was never wrong.It was supposed to be a physics discussion.
Hi Wayne,

I got the email you sent to Motion Labs - we have a cooperation with them. The company I work for - prophysics AG in Zurich, Switzerland - market and sell the myon EMG system as well as the proEMG data capture and analysis software.

You can check out details of our prophysics on www.myon-prophysics.ch [Broken]

I read through your email. EMG measures the electrical activity of muscles using electrodes attached to the skin surface above the muscle's belly. To answer your direct question, whether to use Integrated or RMS calculation, the answer is probably RMS. The reason for this is that the RMS calculation is the "standard" way of representing the average voltage amplitude of the signal, and this is correlated with the muscle power.

Wayne

Fig9.gif


Check the graph.Anyone who has the intelligence to breathe can understand that the RMS amplitude is NOT the average.
 
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  • #154
sophiecentaur said:
Wayne
For someone who claims to know nothing of Physics, you have become very assertive and a bit too stroppy for my liking.

Sorry about that, what part did you mean please ? I am not that type honest, it’s just me a D. have been debating so long, we have often said the odd thing to each other, nothings meant by it honest.

I did not say I knew nothing of physics, it’s more the physics theory I do not know.

Ok, “please” sophiecentaur, one of the things that could have made me stroppy, is that I do not get why you or D. cannot answer this one, please “could” you ?

1,
I lift a weight up from a motionless start, up 500mm in .5 of a second.

2,
A weight is being lowered under control, moving 500mm in .5 of a second, the mm before it hits the ground, I then have to try and lift it up 500mm in .5 of a second.

3,
As of the acceleration components, when moving down with that acceleration, the weight will appear {not sure of the right physics saying for this sorry ?} to be heaver, or have more force than if it was motionless. So it is going to be heaver/harder to lift, thus I “will” need more force than the first lift, think we all agree there ?

4,
How much more force please.

5,
If you can’t work out how much more force, and please you can add in your own accelerations for this if you need to. But if you can’t work it out, do you agree that the force needed would be about, and this is a very rough guess ? 50% more force for .2 of a second, then the same force as the first lift ?

6,
When you two, or anyone else are compeering my fast lifts force, and your slow lifts force, which modal are you compeering your lift two, the lift started from a motionless start, or the lift that is being lowered first then lifted ? I would say it’s the motionless lift, am I right or wrong please ?

sophiecentaur said:
Nothing I have ever written about the Physics of this topic is wrong. It's just too basic and glaringly obvious. The same goes for Douglis's statements about Physics.

How is it obvious ? As when using 80% of your 1RM {Repetition Maximum} you fail to lift the weight again, or you hit momentary muscular failure 50% faster on the faster reps, this must surely mean you have used up your temporary force faster, it can’t mean you have used up your temporary force slower, or you would still have force left, but you don’t, you don’t have any force left, so that can mean one think only, that on the fast you are using more force per unit of time, if not please explain your way of thinking. I use more energy in the same time frame; I move the weight far far far further in the same time frame.

I never said you did wrote anything wrong, I might have said I think you could have left something out, like not adding in all the variables, or kinology, or like in my 1 to 6 above. But what I don’t understand, and no one have tried to explain, is that when my peak acceleration forces are say a 100% or 100 pounds of force, how do you think that your 80% or 80 pounds of force can make up the 100 pounds of force, when its only 80 pounds, how can 80 ever be as high as a 100 ? The only way the 80 pounds of force could make this extra force up, or the shall we say the 100 pounds of tension on the muscles to the 80 pounds of tension on the muscles, is if the 80 pounds of tension was on the muscle far far far longer, please do you agree there, if not, how does the 80 pounds of tension make up the higher 100 pounds of tension on the muscles, as a 80 pounds tension, can never be as high as the 100 tension, as how could 80 pounds feel like 80 pounds on the muscles ? Its impulse, force with respect to time. A small force applied for a long time can produce the same momentum change as a large force applied briefly, because it is the product of the force and the time for which it is applied that is important. But in our case the reps, lifts are done for the same time frame.

sophiecentaur said:
The stuff about EMG results is not the Physics of moving masses up and down. I's about what your Muscles are doing. The fact is that, even when lowering something, your muscles are using energy (unless you just drop it on the floor). Hence, there is no direct relationship between Energy Expended in your muscles and Work Done on the Weights you lift. That is the beginning and end of the whole topic and neither you nor your fellow EMG users can change it.

The EMG does not compute energy ? The EMG computes the electrical signals the muscles give out, the more electrical signal = more muscle activity = more muscle force, of can we say muscle strength used. So I think it is the physics of the forces, and its adding in, or saying that the faster you move, the more force is used, its adding in the peak forces of the faster accelerations of the faster reps, and in my opinion it shows that the slow forces cannot make up or balance out the higher force or tensions that the faster has put on the muscles, thus it reads out higher for the fast. That is why more energy is used; it has to use more energy as of the higher forces from the higher velocities and accelerations. Also that’s why the fast mores the weight 6 times further, as it takes more force to move a weight further in the same time frame, yes ?

sophiecentaur said:
The readings on your EMG machine can give you a lot of useful information about your Body and that's all.

I can't actually understand what you are trying to achieve here and slagging people off for making statements that you clearly don't actually understand is not getting us anywhere.

Sorry honestly did not try to slag you off, not sure where you think I did that, but if you think that, I will, and will do it now, I apologise for anything I have said, and it was not meant at all.

Ok, I imagine you know or have heard what a force plate/platform is ? If I buy or have tests done, and that state the average and total or overall forces are higher in the fast, like the EMG states, what would you say then ?

http://en.wikipedia.org/wiki/Force_plate

Will get back to the others tomorrow. Again, thank you for your time and help; I only want a friendly debate.

Wayne
 
  • #155
waynexk8 said:
I did not say I knew nothing of physics, it’s more the physics theory I do not know.


Wayne

This absolutely sums up what's wrong with your approach. Physics IS THEORY. If you don't use the theory then anything you have to say is just idle chit chat.

It explains why you seem incapable of stating a question in less than ten paragraphs and incapable of understanding an answer that takes up a single line.
Would you ever ever ever challenge a mathematician about something on the grounds that you know Maths but not the 'theory'?
You do not believe that Physics cannot answer your question because you just don't know the Physics. Until you are prepared to learn some of the 'theory' you will never get this. Stick to arm waving.
 
  • #156
sophiecentaur said:
This absolutely sums up what's wrong with your approach. Physics IS THEORY. If you don't use the theory then anything you have to say is just idle chit chat.

It explains why you seem incapable of stating a question in less than ten paragraphs and incapable of understanding an answer that takes up a single line.
Would you ever ever ever challenge a mathematician about something on the grounds that you know Maths but not the 'theory'?

Sorry, yes my writings are long.

If I had four marbles on the table, and the mathematician took 2 away, and said I still have 4 there, then yes I would challenge his theory with my practical World experiments.

sophiecentaur said:
You do not believe that Physics cannot answer your question because you just don't know the Physics. Until you are prepared to learn some of the 'theory' you will never get this. Stick to arm waving.

I am trying to learn, however I think you could also try to see how theory does not always provide the truth, as in the fast rep fails at lifting first, that “must” mean, that the person doing the fast, used more muscle force per unit on time, if not why does the fast have no force to pick up the 80 pounds, but the slow does ? Also, how does the fast move the weight 6 times futher in the same time span, how does the fast use more energy in the same time span, if its not as you two say using more force up per unit of time.

Physics, or right/correct physics, is only right/correct physics, when the theory is proven with practical experiments, unless that, it stays an unproved theory.

I am not arm waving, I have come here asking and hoping for answer to questions, so I ask quite simple questions like the below, but I get no answer, please I do not understand why you can’t answer the below. Not being sarcastic here, but it’s the only thing I can think of, you do understand what I am saying/asking below ? If not please say, as its looks very straight forward to me, please tell me if the below is the wrong way to ask, or just say why you will not answer, as I do not get it. I can here to ask some friendly polite questions, and it seems more of a match to put me down, I just don’t understand this.

1,
I lift a weight up from a motionless start, up 500mm in .5 of a second.

2,
A weight is being lowered under control, moving 500mm in .5 of a second, the mm before it hits the ground, I then have to try and lift it up 500mm in .5 of a second.

3,
As of the acceleration components, when moving down with that acceleration, the weight will appear {not sure of the right physics saying for this sorry ?} to be heaver, or have more force than if it was motionless. So it is going to be heaver/harder to lift, thus I “will” need more force than the first lift, think we all agree there ?

4,
How much more force please.

5,
If you can’t work out how much more force, and please you can add in your own accelerations for this if you need to. But if you can’t work it out, do you agree that the force needed would be about, and this is a very rough guess ? 50% more force for .2 of a second, then the same force as the first lift ?

6,
When you two, or anyone else are compeering my fast lifts force, and your slow lifts force, which modal are you compeering your lift two, the lift started from a motionless start, or the lift that is being lowered first then lifted ? I would say it’s the motionless lift, am I right or wrong please ?

sophiecentaur said:
Nothing I have ever written about the Physics of this topic is wrong. It's just too basic and glaringly obvious. The same goes for Douglis's statements about Physics.

How is it obvious ? As when using 80% of your 1RM {Repetition Maximum} you fail to lift the weight again, or you hit momentary muscular failure 50% faster on the faster reps, this must surely mean you have used up your temporary force faster, it can’t mean you have used up your temporary force slower, or you would still have force left, but you don’t, you don’t have any force left, so that can mean one think only, that on the fast you are using more force per unit of time, if not please explain your way of thinking. I use more energy in the same time frame; I move the weight far far far further in the same time frame.

I don’t understand, and no one have tried to explain, is that when my peak acceleration forces are say a 100% or 100 pounds of force, how do you think that your 80% or 80 pounds of force can make up the 100 pounds of force, when its only 80 pounds, how can 80 ever be as high as a 100 ? The only way the 80 pounds of force could make this extra force up, or the shall we say the 100 pounds of tension on the muscles to the 80 pounds of tension on the muscles, is if the 80 pounds of tension was on the muscle far far far longer, please do you agree there, if not, how does the 80 pounds of tension make up the higher 100 pounds of tension on the muscles, as a 80 pounds tension, can never be as high as the 100 tension, as how could 80 pounds feel like 80 pounds on the muscles ? Its impulse, force with respect to time. A small force applied for a long time can produce the same momentum change as a large force applied briefly, because it is the product of the force and the time for which it is applied that is important. But in our case the reps, lifts are done for the same time frame.
sophiecentaur said:
Originally Posted by sophiecentaur
The stuff about EMG results is not the Physics of moving masses up and down. I's about what your Muscles are doing. The fact is that, even when lowering something, your muscles are using energy (unless you just drop it on the floor). Hence, there is no direct relationship between Energy Expended in your muscles and Work Done on the Weights you lift. That is the beginning and end of the whole topic and neither you nor your fellow EMG users can change it.

The EMG does not compute energy ? The EMG computes the electrical signals the muscles give out, the more electrical signal = more muscle activity = more muscle force, of can we say muscle strength used. So I think it is the physics of the forces, and its adding in, or saying that the faster you move, the more force is used, its adding in the peak forces of the faster accelerations of the faster reps, and in my opinion it shows that the slow forces cannot make up or balance out the higher force or tensions that the faster has put on the muscles, thus it reads out higher for the fast. That is why more energy is used; it has to use more energy as of the higher forces from the higher velocities and accelerations. Also that’s why the fast mores the weight 6 times further, as it takes more force to move a weight further in the same time frame, yes ?

Wayne
 
  • #157
douglis said:
Show me where I was wrong.
From physics point of view...you can not possibly know if you spend more energy by lifting and lowering a weight than just holding it for the same duration.Only biology has the answer...so I was never wrong.It was supposed to be a physics discussion.

D. you can surely work out the power used in both ? Surely you must know that if you move something further in the same time frame you need more energy, that’s goes for everything, then it’s in every calorie counting book and site and nutritionist have know this for 100s of years, I also showed you how they work it out in a sealed room. Then after years it was a physicist who worked it out for you with physics and told you.

LOOK, please let’s forget about that, as you did immediately say you was wrong when you was, I salute you for that, I will and do not want to rub it in every again, so sorry.

No its not just a physics debate, it’s a World wide debate, and whatever needs to be added in, to answer the question, will be.

Problem is, you do not answer questions.


douglis said:
Fig9.gif


Check the graph.Anyone who has the intelligence to breathe can understand that the RMS amplitude is NOT the average.

So now you are saying that two people that make work with and use EMG machines are wrong ? Please tell me what your graph is supposed to mean and why you made it that way, in other words please explain it in full, you never explain anything, then please send an E-mail to these people with my return headings, and tell them how/why you think they are wrong.

E-mail, sales.i@motion-labs.com

Subject, Re: [From Website] to Edmund Cramp.

E-mail, roren@prophysics.ch

Subject, Re: Your email regarding EMG systems

Then please try to answer the below, and if you say I run out of force because of I used up the energy fast, I know that, the question is sort of why did I use up more energy doing something faster ? Did I use up more because I was using more force per unit of time, the same, or less. But the main issue is the force, the energy is “only” the supply, and we are on about the force, the energy supply. as in the fast rep fails at lifting first, that “must” mean, that the person doing the fast, used more muscle force per unit on time, if not why does the fast have no force to pick up the 80 pounds, but the slow does ? Also, how does the fast move the weight 6 times further in the same time span, how does the fast use more energy in the same time span, if it’s not as you two say using more force up per unit of time.

Wayne
 
  • #158
Only an instrument that measures what is happening to the weights themselves can measure the work involved and the forces involved. The EMG doesn't do this so it is not contradicting the Physics.
You are clearly not "trying to learn". Not even one small step at a time. Because you disregard every basic part of theory, preferring the 'but surely' argument and 'it stands to reason'.
You dismissed my analogy concerning a mathematician by quoting an example where the Mathematician was not right and had no proper reasoning behind his result. But you argue against the RMS thing and that is totally Maths.
 
  • #159
waynexk8 said:
LOOK, please let’s forget about that, as you did immediately say you was wrong when you was, I salute you for that, I will and do not want to rub it in every again, so sorry.

As always you misunderstood what I admited I was wrong.
I was wrong from biology point of view.From physics point of view I was perfectly right and you're saying nonsense.You can't possibly know if you spend more energy if you lift a weight 10 times up and down or you just hold it for 10 seconds.

No its not just a physics debate, it’s a World wide debate, and whatever needs to be added in, to answer the question, will be.

OMG...you're totally delusional!What world wide debate you idiot?:rofl:
It's just a couple of us with superhuman patience trying to explain basic physics to you.

So now you are saying that two people that make work with and use EMG machines are wrong ? Please tell me what your graph is supposed to mean and why you made it that way,

The graph is not mine it's from the first site I found when I googled "rms amplitude".

The RMS is not the average.This is not offered for discussion...it's basic maths.You don't have to mail professors!:biggrin:

Check the below numbers:
-2, 5, -8, 9, -4

Their average is 0 but their RMS is 6.16.
The RMS is NOT the average.It's the quadratic mean.You probably don't have a clue what that means so you have to trust the link and me.
http://www.analytictech.com/mb313/rootmean.htm
Then please try to answer the below, and if you say I run out of force because of I used up the energy fast, I know that, the question is sort of why did I use up more energy doing something faster ?

I've tried so many times to explain that the force-energy relation is not linear and greater energy expenditure doesn't equate greater force.
I'm sure by now that that's way beyond your intelligence.
 
  • #160
I stop here any physics related discussion with Wayne because obviously is a waste of time.
What's the point anyway?The below study is exactly what he's looking for.

waynexk8 said:
as in the fast rep fails at lifting first, that “must” mean, that the person doing the fast, used more muscle force per unit on time

Wayne

I have shown you the absolute proof that this is nonsense with a real study but you choose to ignore it.

Take a look again:

The fast push ups failed at 81.2 sec while the slow push ups failed at 101.2 sec.It's obvious that the fast push ups had greater rate of energy expenditure(see table 1).

BUT the Total Muscle Activation(for the pectoralis major for example) for the fast push ups is 2114.23 while for the slow push ups is 3121.81(see table 3).

So the muscle activation per second for the fast push ups is 2114.23/81.2=26.04
and the muscle activation per second for the slow push ups is 3121.81/101.2=30.85

http://jmbe.bme.ncku.edu.tw/index.php/bme/article/viewFile/635/839 [Broken]
Conclusion:
greater rate of energy expenditure does NOT equate greater muscle tension per unit of time.In fact,in the case of push ups,the exact opposite is true.

End of discussion.
 
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  • #161
sophiecentaur said:
Only an instrument that measures what is happening to the weights themselves can measure the work involved and the forces involved. The EMG doesn't do this so it is not contradicting the Physics.

It’s the muscles themselves that are exerting the force. For every reaction, there is an opposite reaction, so if you measure the work or the force from the muscles or the force moving/on the weight, you will find the reading.

But it’s the muscles forces we are after, or the tensions on the muscles, that’s the forces from the muscles forces onto the weights, with the opposite reaction forces creating tensions on the muscles, and as the EMG takes the muscle activity = muscle force, more muscle activity = more muscle force, yes ?

When you say work, do you mean the mechanical work, the product of a force times the distance through which it acts, work of the force, we know the fast does more work, or more work of the force, so is not that more force if it’s done more work, work of the force ?

sophiecentaur said:
You are clearly not "trying to learn". Not even one small step at a time. Because you disregard every basic part of theory, preferring the 'but surely' argument and 'it stands to reason'.

Sorry, when I say surely, I am more thinking out loud; please don’t think anything of it.

sophiecentaur said:
You dismissed my analogy concerning a mathematician by quoting an example where the Mathematician was not right and had no proper reasoning behind his result. But you argue against the RMS thing and that is totally Maths.

See your point on the analogy concerning a mathematician; yes suppose I was wrong there, but just making a point.

Another thing, I have not been explained what RMS is ? But then again, I could say that you are now disagreeing with people who make and work with EMG machines, and two of these stated to measure the total or overall force output of the muscles, RMS is about the best.

"Please" could you ansner this ? If not please state why.

1,
I lift a weight up from a motionless start, up 500mm in .5 of a second.

2,
A weight is being lowered under control, moving 500mm in .5 of a second, the mm before it hits the ground, I then have to try and lift it up 500mm in .5 of a second.

3,
As of the acceleration components, when moving down with that acceleration, the weight will appear {not sure of the right physics saying for this sorry ?} to be heaver, or have more force than if it was motionless. So it is going to be heaver/harder to lift, thus I “will” need more force than the first lift, think we all agree there ?

4,
How much more force please.

5,
If you can’t work out how much more force, and please you can add in your own accelerations for this if you need to. But if you can’t work it out, do you agree that the force needed would be about, and this is a very rough guess ? 50% more force for .2 of a second, then the same force as the first lift ?

6,
When you two, or anyone else are compeering my fast lifts force, and your slow lifts force, which modal are you compeering your lift two, the lift started from a motionless start, or the lift that is being lowered first then lifted ? I would say it’s the motionless lift, am I right or wrong please ?


Wayne
 
  • #162
I am not disagreeing with what the EMG people are saying. The problem is that you do not seem to understand what they are saying and how it applies to your question.
Why should you need to have RMS explained any more. It isn't an explanation that you need. What you need to do is to use the definition to work out some numbers yourself. Douglis has given you a perfect worked example.

I cannot be bothered to answer that question because it is just a smoke screen to protect you from going to the trouble of working stuff out for yourself.
 
  • #163
douglis said:
As always you misunderstood what I admited I was wrong.
I was wrong from biology point of view.From physics point of view I was perfectly right and you're saying nonsense.You can't possibly know if you spend more energy if you lift a weight 10 times up and down or you just hold it for 10 seconds.

YES you can, I don’t understand why you don’t know this or could think other, you use more force on the acceleration and on the higher vilocity, will explain this in full tomorrow. Do a search on physics and energy used uin distance and or disstnce per unit of time.

Then do another sherach, on room calorimetry. the Energy Expenditure and Nutrient Oxidation will and have been established in a room calorimetry. Many Statistics will be measured eg; Heart rate, oxygen consumption, fat consumption, protein consumption and carbohydrate consumption, to determine the effects of exercise at different intensities. On every occasion when an activity has been practiced at a faster rate, the heart rate, oxygen consumption, fat consumption, protein consumption and carbohydrate consumption, has been higher, therefore energy expenditure, nutrient oxidation will be higher.
The increase in the rate of energy expenditure/cost will be due the increase in the intensity/force of muscle activity. When a muscle is subjected to a greater acceleration, speed or velocity, EMG reading will go up, when muscle uses more force, more force will equal more acceleration, speed, velocity, equals more energy.

jarednjames wrote;Let's say it takes 10N to lift the weight in 1 second (a = f/m), if you apply 20N it would only take 0.5 seconds and so on. But the force applied per unit time is the same.

The difference comes when you look at energy. The kinetic energy of moving the weight (100lbs) at an average velocity of 1m/s is 22 joules, but the KE of moving the weight at 2m/s is 90 joules. So the higher the average velocity of the weight, the more the energy use increases - which is why you get tired quicker.

The faster you move something, the more energy it takes. As you can see, simply doubling the velocity (which would halve the rep speed) requires over four times more energy. Each time you double speed of the reps, and as such halve the time for the reps, you are increasing the energy requirement in this manner.

That is why you're using more energy.
* All figures are for guidance only.

jarednjames wrote;
To reduce the time to move an object a distance of 1m, you have to increase the force. By increasing the force, the acceleration becomes larger:

a = f/m therefore if you double to force to 2f you get 2a = 2f/m.

Let's say we have an object that is 1kg. To move that 1m in 1s (1m/s) requires a KE of 0.5mv2 = 0.5*1*1 = 0.5 Joules of energy.
Now, to move it 100m in 1s (100m/s) requires a KE of 0.5*1*10000 = 5000 Joules. So in the first case I need a tiny amount of energy, in the second I need a huge amount in comparison.

For your case to move that 1m in 1s (1m/s) requires a KE as above (0.5 Joules).
Now, to move it 1m in 0.5s (2m/s) requires a KE of 0.5*1*4 = 2 Joules. So again you can see how simply halving the time of the repetition requires you to use more energy to complete it. The time applied is considered in the velocity figure.

For you to move the weight 1 rep in 1s requires 0.5 Joules - that is the energy you must provide to do it.
For you to move the weight 1 rep in 0.5s requires 2 Joules - again, that is the energy you must provide to do it.

If you do not provide that energy, you can't complete the rep in the required time.


douglis said:
OMG...you're totally delusional!What world wide debate you idiot?:rofl:

This has been going on for many years on different forums with different people.


douglis said:
It's just a couple of us with superhuman patience trying to explain basic physics to you.

If you as you do, claim you are right, then how do you account for the following.
1,
As when using 80% of your 1RM {Repetition Maximum} when you fail to lift the weight again, or you hit momentary muscular failure 50% faster on the faster reps, this must surely mean you have used up your temporary force faster, it can’t mean you have used up your temporary force slower, or you would still have force left, but you don’t, you don’t have any force left, so that can mean one think only, that on the fast you are using more force per unit of time. I use more energy in the same time frame; I move the weight far far far further in the same time frame.

And if you say I run out of force because of I used up the energy fast, I know that, the question is sort of why did I use up more energy doing something faster ? Did I use up more because I was using more force per unit of time, the same, or less. But the main issue is the force, the energy is “only” the supply, and we are on about the force, the energy supply. as in the fast rep fails at lifting first, that “must” mean, that the person doing the fast, used more muscle force per unit on time, if not why does the fast have no force to pick up the 80 pounds, but the slow does ? Also, how does the fast move the weight 6 times further in the same time span, how does the fast use more energy in the same time span, if it’s not as you two say using more force up per unit of time.

If not please explain your way of thinking, please for once answer.


2,
I don’t understand, and no one have tried to explain, is that when my peak acceleration forces are say a 100% or 100 pounds of force, how do you think that your 80% or 80 pounds of force can make up the 100 pounds of force, when its only 80 pounds, how can 80 ever be as high as a 100 ? The only way the 80 pounds of force could make this extra force up, or the shall we say the 100 pounds of tension on the muscles to the 80 pounds of tension on the muscles, is if the 80 pounds of tension was on the muscle far far far longer, please do you agree there, if not, how does the 80 pounds of tension make up the higher 100 pounds of tension on the muscles, as a 80 pounds tension, can never be as high as the 100 tension, as how could 80 pounds feel like 80 pounds on the muscles ? Its impulse, force with respect to time. A small force applied for a long time can produce the same momentum change as a large force applied briefly, because it is the product of the force and the time for which it is applied that is important. But in our case the reps, lifts are done for the same time frame.

If not please explain your way of thinking, please for once answer.


douglis said:
The graph is not mine it's from the first site I found when I googled "rms amplitude".

Yes but what do you think it means, and why did you show it ?

douglis said:
The RMS is not the average.This is not offered for discussion...it's basic maths.You don't have to mail professors!:biggrin:

I never said it was.

douglis said:
Check the below numbers:
-2, 5, -8, 9, -4

Their average is 0 but their RMS is 6.16.
The RMS is NOT the average.It's the quadratic mean.You probably don't have a clue what that means so you have to trust the link and me.
http://www.analytictech.com/mb313/rootmean.htm

GOD, I “think” I know what you two are doing wrong. No wonder its what or why the EMG experts use it, no time to explain now, as not 100% sure, but you should be able to see why, if you try to understand why am EMG expert would ”have” to use the RMS or quadratic mean. Problem is, why are you not using this ? As we are on about the total or overall muscle activity, force.

RMS or quadratic mean will used in the situations, where it is the square of the values that matters; an electrical current squared will be proportional to the power. A quadratic mean, RMS should be used for periodic data (i.e., over time, a graph describes a sine curve), or when both positive and negative data are included, and what you seek is an "average distance from zero" for the various data point. The quadratic mean, a statistical measure of the magnitude of a varying quantity. It is especially useful when varieties are positive and negative.


You times it by two; you're multiplying a number by itself. Five squared is 25, five times five is 25.


The problem is, why are you two not adding in the negative force ?


douglis said:
I've tried so many times to explain that the force-energy relation is not linear and greater energy expenditure doesn't equate greater force.
I'm sure by now that that's way beyond your intelligence.

I know it’s not liner, try and explain on this physics forum then.

Wayne
 
  • #164
sophiecentaur said:
I am not disagreeing with what the EMG people are saying. The problem is that you do not seem to understand what they are saying and how it applies to your question.
Why should you need to have RMS explained any more. It isn't an explanation that you need. What you need to do is to use the definition to work out some numbers yourself. Douglis has given you a perfect worked example.

I cannot be bothered to answer that question because it is just a smoke screen to protect you from going to the trouble of working stuff out for yourself.

I will tomorrow, thanks for your time and help, just going out.

This should interest you, see table 2.

Force-velocity, impulse-momentum relationships:

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


Wayne
 
  • #165
I have read the paper an I think I can see your problem. I find little to disagree with what is written.
They are not considering the whole cycle (lift/lower) when they refer to mean force. They are not only discussing free lifts but machines that present RESISISTIVE loads. Everything changes in that case because you are not just changing gravitational potential energy in that case but work is being done in overcoming friction.
If you had read what they say then you would not think they are disagreeing with established physics at all. You did not understand what you were arguing about because you insisted on giving details instead of condensing your questions into something meaningful.
 
  • #167
sophiecentaur said:
They are not considering the whole cycle (lift/lower) when they refer to mean force. They are not only discussing free lifts but machines that present RESISISTIVE loads.

sophiecentaur...if you read the ''methods'' paragraph the authors admit that they record ONLY the ''propulsive'' force and not the whole average force for the lift.By ''propulsive'' force they mean the additional than the weight force in order to accelerate.With the method they use they can measure only the positive value of the propulsive force.The negative values in order to decelerate are not recorded.
 
  • #168
So the whole thread is GIGO, as usual. And I wonder why they use a term like "propulsive force" which has no strict definition faik.

You need to read more carefully, Wayne.
 
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  • #169
Will be back later to get back to some of the old questions I have missed.

Here D, I double checked, what do you say now on this and the other mails regarding RMS and EMG ? I understand why they say to usde RMS, and the other methords, do you now understand why you use ROM ?

Hi Wayne,
There are a few research papers floating around that suggest that the RMS envelope of EMG activity approximates to the force exerted by a muscle. There are several different methods of integrating and averaging muscle activity - all produce estimates of muscle force, the RMS method appears to be slightly more favored but I don't believe that there's any solid proof that it's any more accurate than any other method - the different methods are discussed in the EMG section of the Craik and Otis book which goes into a reasonable amount of detail while remaining understandable.

Regards,
Edmund Cramp
--
<< Personal contact information removed by Moderators >>
Wayne
 
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  • #170
Wayne still doesn't understand that answer.
I notice he doesn't ever quote from a long correspondence with any of his other sources.
 
  • #171
sophiecentaur said:
That's interesting. The TMA is the sum of all activity over a period of time and that is going to depend on a lot of things, I reckon. It seems to me that we evolved with a certain minimum level of activity when doing heavy work so 'slow' work may just not be as efficient. In fact the whole system is not efficient; if it were, we'd need to have ratchets to lock our limbs in elevated positions once they were up there - rather than burning up energy and hurting ourselves as we do. (I believe horses lock their legs when they sleep standing up)
As you say, very little of this is Physics and Wayne seems to think that one can be 'bent' to fit the other.
It's been entertaining, though, at times.

Dont understand why you don't think lifting and lowering weight and the human movment is not physics ? Its physics, biomacanics and Kinology.

Check out page 49 and 50, and have a look at the physics equastions there.

http://books.google.co.uk/books?id=2JI04kdV9isC&pg=PA41&source=gbs_toc_r&cad=4#v=onepage&q&f=false

The muscles have several different muscle fibers, but basically there are the fast and slow. The fast muscle fibers are used for more explosive movements, like heavy lifting for 10 to 20 seconds, 100m sprint. Slow muscle fibers are for the more endurance, lifting very light weights for several minutes, marathon running.

However, the slow muscle fibers have very little capacity for growth, if any. But the fast muscle fibers have far great capacity for growth, these are the ones you need to train and focus on. And these muscles fibers are best trained in the manner they evolved for. There are many ways to do this, but on average the time spent training these will be with 80% training them for multiple tension with reps from 6 to 20 fast explosive reps. At times you can go as low as 3 or maybe up to 30. One other thing about using high force acceleration explosive reps, is you can use far higher weights, and I think that’s self explanatory.

Wayne
 
  • #172
sophiecentaur said:
Wayne.
You produce too much writing for anyone to be able to read.
You claim to have "proved" that Physics is wrong. Really??

No not physics is wrong; it’s just that all the variables have not been added in, like the EMG says the average/mean forces are higher in the fast.

sophiecentaur said:
YOUR Physics may be wrong but you do not explain what yor Physics actually is.

My (the Physics that everyone else recognises) says that the "average" (=mean?) force is equal to the weight.

Why is your average/mean force equal to the weight being moved ? The average/mean force would be equal to the force moving the weight ? So if the weight is 80 pounds and the force 100 pounds, why do you say the force is only 80 pounds and not a 100 pounds ? Are you taking about a certain time frame, as if I exerted 100 pounds of force on 80 pounds for .2 of a second and immediately stopped your saying that my average/mean force was only 80 pounds, when I am saying I exerted 100 pounds, so the average/mean force should be 100 pounds ?

sophiecentaur said:
My physics does not have a "temporary" force,

What I meant is that if I pushed with a force of 100 pounds for .1 of a second, that would be a temporary force. And if I tried to push the same weight for 10 seconds with a 100 pounds of force, then the force I tried to use, would have many Milly seconds of temporary force at different forces, as I could not keep up of push with 100 pounds for the ten seconds, so all forces are temporary.

sophiecentaur said:
it has a strict definition for RMS

Right, if I push with a positive force of over 80 pounds on the 80 pounds that’s a positive force, but if I push with a positive force of under 80 pounds, that’s still a positive force, and this force that’s under 80 pounds HAS to be taken account and added in for the total force, what it seems you and D. are doing, is leaving out this force for some unknown reason, I don’t get this could you explain, as all forces big or small, must be added in, as they are forces used by the muscles, thus tension are from big and small forces, you can’t leave them out.

sophiecentaur said:
and only uses the term "total force" to describe the sum of forces applied at one instant of time.

Right, so one instant could be .1 of a second, thus you would have to add all the forces up over the say 6 second time frame.

sophiecentaur said:
The above applies to PF as a whole. If you want a PF discussion then I suggest you use PF terms and not use your own terms, which have no meaning.
You claim you are not being arrogant but what other word is there for it?

It’s hard for me, it’s like you coming to my Wrought Iron Workshop, you or anyone would need a 5 year course, same as me learning this, I am honestly trying.

Wayne
 
  • #173
I get the impression that the above is an attempt to justify yourself more than anything else.
You make the point that Physics is involved in all of this. Well, that is obvious; I am aware of the Physics involved in pretty much the whole of my life. The point is that your contributions have involved virtually no real physics and the questions have been posed in 'not-real-physics[ terms. You prove my point in what you write about muscle fibres and their behaviour - interesting stuff but you quote no Physics in there because it is not relevant to the information.

You seem to have failed to pick up on the point that the forces dealt with in the information you have quoted to us with do NOT relate to weight-only situations. Any reciprocating movement which involves friction will involve extra work on top of weight times height lifted. This is why you seem to think that what I, for one, have been saying, is wrong. That extra consideration of friction changes everything. Do you understand that? If you were constantly to measure and record the force between your hands and the handles / bars you are moving and you also measured the changing position then you could calculate accurately, the actual Work Done on the load. But it would still not tell you how hard your muscles have been 'working'. (I have made this point several times already and the EMG information says as much, too).

What the EMG is trying to do is to tell you about is muscular behaviour. It also mentioned that RMS values give a good indication of that. Fair enough but, as you don't seem to cotton on to what RMS actually involves, then you may not understand what they have written.

There really is no hope for you, I fear. You are still using this expression "total force" but you haven't been consistent in what you mean by it. The fact is that the force you exert (that is a total force) is sometimes more and sometimes less than the weight on a free lift. If you examine what a whole lift actually feels like, you will see that's true - particularly with an 'easy' weight, which will feel lighter as you near the top and it slows down. I(f you moved up fast enough, you could actually throw the weight up and there would be no force on your hands.) The mean force, including all parts of the lift, will be just the weight. If you put a brake on the process (in some sort of machine) then this will no longer be true as you'd need a force even without the weight being there.
btw do you write Milly seconds just to wind people up? Or don't you know what ms are?

If I came into your wrought iron workshop then I would not have the nerve to tell you how to do your job and I would make every attempt to talk 'your language' about your work. You could, at least, be polite enough to do that where Science is concerned. Your use of 'mangled terms is very disrespectful of the Subject as you can see the language used correctly on every response you get. Despite your protestations, you have demonstrated that you have not in fact, been prepared to learn as you still maintain the use of your nonsense terms.

I think we have been very patient with you aamof. I cannot imagine you would be similarly indulged by the other correspondents sustaining such a long thread of conversation. They would soon get too exasperated to respond.
 
  • #174
sophiecentaur said:
I do not subscribe to the term "total force". There is no such quantity in Physics. So the rest of your post means nothing, I'm afraid.

Hmm, ok what could or can we call this ? Is there a word for this in the other branch of physics, kinology or biomechanics ? And if there is no meaning of this in physics, neither of us are right then ? As we can’t be if it has no meaning. Funny, but you say that the average force is equal to weight, so if there is an average, there must be a total, or please, what is your meaning by average ? And what’s it the total of ? D. has been debating this against me, thought he would know these, then why is he saying be total or overall forces are the same ?

So could not we say, that if I could hold 80 pounds half way up for 500 seconds, that my overall or total as in overall force was 80f/500s ? And if you could only hold the weight for 400 seconds, yours was 80f/400s ? Yes I know this is new, but that’s how physics evolved, equations of force, power, and work and so on were added thought out time.

So if I moved 80 pounds up 1m and down 1m 20 times in 20 seconds at .5/.5, I could say 80f/20s/.5.5 ? And the person moving the weight 1m and down 1m 2 times in 20 seconds at 5/5, could say 80f/20s/55.

Ok, maybe I am going in the land of fantasy here, but it’s nice to try and think of new things.

BUT there has to be an equation for this, as of the EMG, and a force plate can calculate this ?

Wayne
 
  • #175
waynexk8 said:
Funny, but you say that the average force is equal to weight, so if there is an average, there must be a total, or please, what is your meaning by average ?

Wayne

OK. You go from London to Bristol at an average speed of 62miles per hour. You could work that out easily enough. But how would you, Wayne, work out what your 'total speed' was? That's how daft your idea of total force is.
 
<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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