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It seems intuitive that $a\; \propto \frac{F}{m}$, as the greater the force that is applied on an object, the greater its acceleration will be. Inversely, the greater the mass of the object, the slower the acceleration will be.

However, when rewriting proportions as equations, you must introduce a constant of proportionality, and in this case of a direct proportion, if $a \propto \frac{F}{m}$ then when rewriting as an equation you will have $$a = k\cdot\frac{F}{m}$$

In order to get the standard formula $F = ma$ this constant must be $1$. However, how do we know that this is the case? How do we know that the constant isn't $2$ and the formula $F = \frac{1}{2}ma$, for instance?

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    $\begingroup$ Related post physics.stackexchange.com/q/70186 $\endgroup$
    – user26143
    Mar 18, 2014 at 17:39
  • $\begingroup$ possible duplicate of How did Newton discover his second law? $\endgroup$
    – jinawee
    Mar 18, 2014 at 18:11
  • $\begingroup$ Different, but related: physics.stackexchange.com/q/112959/44126 $\endgroup$
    – rob
    Jun 24, 2014 at 2:56
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    $\begingroup$ It should be understood that Newton's law is not "intuitive", it is highly non-trivial and involved and depends on a bunch of experimental facts that beautifully unite in the form of Newton's law. In particular, there is nothing intuitive about the fact that there exists a force, or that there exists a mass, or that $a\propto\frac{F}{m}$. All of these things depend on crucial experimental facts. See this masterpiece of an answer by tparker: physics.stackexchange.com/a/340890/20427 $\endgroup$
    – user87745
    Feb 26, 2019 at 14:38
  • $\begingroup$ F DOES equal kma. In the SI system of units, the unit of force, which is the Newton, has been defined in such a way that k=1. For the English system of units, which is pounds mass, pounds force, and ft/s^2, k is NOT equal to 1. $\endgroup$ Feb 26, 2019 at 18:02

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That's the way the unit of force is defined. One newton is the force that accelerates a mass of one kilogram by $1\ \mathrm{m/s^2}$. The newton is chosen to make the constant of proportionality equal to one.

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  • $\begingroup$ ok that fixes the value of k as 1, but was there any reason to take it as dimensionless? $\endgroup$
    – user22180
    Jun 28, 2014 at 13:34
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    $\begingroup$ @user22180 Multiplication by 1 is easy. And 1 is easy to remember. $\endgroup$ Apr 14, 2018 at 17:26
  • $\begingroup$ Can we say that force is a quantity that physicist defined to make problem solving in mechanics convenient? They found that having $k=1$ is convenient and hence they defined $1N$ in such a way that $k=1$. Is it? $\endgroup$ Dec 13, 2019 at 6:57
  • $\begingroup$ @Kaushik yes, that's it. $\endgroup$ Dec 13, 2019 at 9:02
  • $\begingroup$ Yes, Turely right! $\endgroup$
    – Kartikey
    Feb 16, 2020 at 8:06
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I think it is more intuitive to say that (net) force is proportional to acceleration: $F\propto a$. The proportional constant tells us now how easy it is to accelerate an object with a certain force. This proportional constant is called the (inert) mass of said object. Hence $F=m\cdot a$.

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  • $\begingroup$ The comment by @JohnRennie is a clearer answer. $\endgroup$
    – garyp
    Mar 18, 2014 at 23:36
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    $\begingroup$ This answer makes a misleading impression that $m$ of a body is to be determined as the ratio $F/a$, with values of $F$ and $a$ known beforehand. This would be hard to do. In contrast, $m$ is measured very easily by a scale or just counting the number of equal components forming the body.With value of $m$ obtained this way and force measured in independent units (weight or deformation coordinate), the second law reads $F=kma$ where $k$ is some constant. It is a simplifying step to change units of $F$ so that we do not have to maintain $k$ in the equations. Check out John Rennie's comment. $\endgroup$ Jun 24, 2014 at 8:05
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    $\begingroup$ Actually determining the ratio $F/a$ IS the way a scale usually works: The acceleration is known ($g=9.81m/s^2$) and the force is measured by measuring the pressure created by the object upon the scale or by comparing the object to another set of weights with known/defined mass (and therefore known force). Even so, it might be interesting to further read into the (non-)difference between inertial and gravitational mass: wikipedia $\endgroup$ Jun 26, 2014 at 9:59
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In Newtonian mechanics, we have the quantity momentum (I'll get to force a bit later):

$$\vec p = m\vec v $$

which is conserved and is thus a quantity of fundamental importance. We can think of the mass as the constant of proportionality between momentum and velocity.

But you might ask "why isn't $\vec p = k \cdot m \vec v$ instead?"

The answer is that, by the appropriate choice of units, $k$ can always be made equal to one.

In other words, we want the following: one unit of momentum equal to the product of one unit of mass and one unit of speed.

For example, in SI units, the unit of momentum is

$$kg \cdot \frac{m}{s}$$

with is the product of one unit of mass and one unit of speed.

Now, suppose that the unit of mass were grams rather than kilograms? Would we write

$$\vec p = 1000 \cdot m \vec v$$

or would the unit of momentum become

$$g \cdot \frac{m}{s}$$

instead?

Now, a similar argument could be made for $\vec F = m \vec a$ but we don't really need to because we have

$$\vec F = \frac{d \vec p}{dt} = m \frac{d \vec v}{dt} = m \vec a $$

for $m$ constant.

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In the Newton's Second Law, Newton basically defined what Force is. He could have taken that constant as any number that he wanted, he chose 1 for simplicity.

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    $\begingroup$ Not that your answer implies it but it should be made clear that the second law of motion is not just the definition of force. It is a full-fledged law of physics, i.e., it is non-trivial. $\endgroup$
    – user87745
    Feb 26, 2019 at 14:33
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A lot of the other answers kind of point to this, but the best way of looking at Newton's second law is to think of it as a definition of force -- while it encodes the notion of a push or pull, technically, we have to encode this quantitatively. Newton's second law encodes the fact that pulls create acceleration, and it sets the unit of a pull in such a way that you don't need your constant of proportionality.

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The equation $F = km.a$ is actually more correct, since this equation might be used to define units, but if the units are pre-defined, then the value of $k$ is to be found. This is the theory that Stroud and Wallot taught to engineers at the turn of last century.

For example, 'pdl' = pound * ft/s/s, pound = 'slug' * ft/s/s, and pound = pound * 'g' are all coherent equations, but pdl = 32.175 * pound * ft/s^2 is likewise valid.

The theory of Wallot and Stroud is quantity analysis, where like on the london underground, distances are measured in km, speeds in mph, and time in minutes. The units are all set, and the object is to find 'k' in D = k.VT.

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There is no proportionality constant for the same reason there isn't one in

$$\text{distance} = \text{speed}\times\text{time}$$.

It's from using consistent units. For instance, if distance and time are kilometers and hours, and we express speed in kilometers per hour, then there is no conversion factor.

The $F = ma$ formula defines a force as being mass, times acceleration. The units in which force is measured is derived from the product of the units of acceleration and mass.

In metric units, acceleration is $\displaystyle\frac{\text{m}}{s^2}$, and the product of acceleration and mass in $\text{kg}$ is therefore $\displaystyle\frac{\text{kg}\cdot\text{m}}{s^2}$.

The unit of force, the Newton, is then simply defined as: $$1N = 1\frac{\text{kg}\cdot\text{m}}{s^2}$$ with no additional conversion factor.

If an extra constant were present, it would only be changing the measurement unit of force, creating an annoying inconvenience. For instance if you have mass and acceleration composed of a combination of metric units (meters and seconds), but force is being expressed in pounds, then there will be a constant: the conversion factor between Newtons and pounds.

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  • $\begingroup$ I like the basic idea of your answer, except for "The $F=ma$ formula defines a force as being mass, times acceleration." because it makes an impression that force as a concept is defined as $ma$. If this was so, the equation would be exact, not an approximate relation inferred from experience. It is better to say "The $F=ma$ formula is a simplified writing of the second law $F=kma$ allowed by changing the unit of $F$.". $\endgroup$ Jun 24, 2014 at 8:41
  • $\begingroup$ @JánLalinský Would you say that the distance-speed-time formula $d = vt$ is really just a simplified way of writing $d = kvt$ allowe by changing the units of $d$? $\endgroup$
    – Kaz
    Feb 26, 2019 at 16:52
  • $\begingroup$ I wouldn't, because I don't know any preexisting notion of speed that does not depend on the definition of distance per time. However, notice that even $d=vt$ does not define the concept of distance or velocity. It is merely statement that there is some rectilinear motion happening. The situation is completely different for the concept of force, because this was existing before the current concepts of mass and acceleration were established and was measured in units different from mass $\times$ distance $/$ time $/$ time. $\endgroup$ Feb 27, 2019 at 0:39
  • $\begingroup$ @JánLalinský This is true in that the force concept is involved in phenomena such as pressure and stress. A cable not undergoing acceleration can have a tension in it measured in Newtons, and divided by the cross-section area, a stress measurable in Pascals. $\endgroup$
    – Kaz
    Feb 27, 2019 at 0:58
  • $\begingroup$ That is a good example. Force can have various manifestations, not merely acceleration. And so it can be measured in units of that manifestation, such deformation of the body under force or quantity of weights needed to counterbalance that force, etc. $\endgroup$ Feb 27, 2019 at 1:01
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A lot of these comments/posts are suggesting that Newton's law is defining force, but I don't think this is a good way of looking at it, otherwise it is trivial and the statement is vacuous. I look at Newton's law as essentially defining mass, ie. $m=\frac{F}{a}$ and the reason Newton's law is then nontrivial is because it says that $m$ is constant.

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  • $\begingroup$ That would be even worse than using $F=ma$ to define force. Mass is much more easily measured by scales, counting the number of equal components or by volume. Constancy of mass is also very basic experimental fact. $\endgroup$ Jun 24, 2014 at 8:23
  • $\begingroup$ @JánLalinský Well you haven't proposed an alternate definition of mass...would you prefer it if I said inertial mass? $\endgroup$
    – JLA
    Jun 24, 2014 at 17:16
  • $\begingroup$ It was not my intention to define mass. I do not think the notion is problematic - mass is quantity of matter and can be easily measured by scales or other means. If you want to define technical term "inertial mass" as $F/a$ while $F$ and $a$ are measured in units independent of unit of mass, you may do so, but I do not believe that is what the 2nd law is about. $\endgroup$ Jun 24, 2014 at 19:43
  • $\begingroup$ @JánLalinský I think the notion may be problematic if you don't define it...how do you measure it without knowing what to measure? In any case, I was in fact talking about inertial mass, and I think it does get at what the second law is about. Inertia is a bodies resistance to movement...this makes that statement precise. $\endgroup$
    – JLA
    Jun 25, 2014 at 1:10
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Actually $F=k\cdot ma$ expression is better, because it helps to make a transition to special relativity. In special relativity you need to take into account of relativistic mass for Newton second law to be fixed. In that case k becomes :

$$k = \frac{1}{\sqrt{1 - \dfrac{v^2}{c^2}}}$$

Now, it's very easy to understand why object can't move faster than light. Solving for limit of $k$ when v approaches c gives us an answer -> $ \infty $, infinity. This means that any physical object hypothetically moving at speed of light has a infinite relativistic mass.So to be able to give even a slightest acceleration to such object - we need to apply infinite force too. Which is non-sense, thus - no object can't be accelerated faster than light.

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Ever wondered why the value of $G$ in Newton's law of gravitation is not 1 just like in this case you stated. Keep reading. I will come to the answer a bit later.

This is Newton's law of Gravitation:

$F =\frac{Gm_1m_2}{R²}$

In this equation, there are four "defined" physical quantities $m_1$,$m_2$, $R$ and $F$ . 1kg of mass is defined as the mass of platinum-iridium aloy kept in at the International Bureau of Weights and Measures at Serves near Paris, similarly length (R) is defined as the length of a platinum-iridium rod and F is defined by Newton's first law of motion: $F=ma$(have patience).

So knowing the rest of the four quantity in the equation the value of unknown $G$(the fifth quantity) can be determined easily(using a torsion balance).

But what to do if there are two unknowns as in equation of Newton's first law: $F=kma$ Here $k$ and $F$ both are unknowns. When Newton discovered the law, the unit of force was not defined. No one thought of measuring forces. So $F$ is also an unknown value in the equation. But it does contains $F$, so it can be used to define $F$ instead! So Newton got an equation which he could use to define the first ever unit of force. But what to do of that constant $k$? Why was it chosen as $1$?

In fact, the value of k can be any real number but IUPAC took it as $1$. Why? Because it was the easiest way. Taking $k=1$,the equation becomes $F=ma$. It is easy to say that $1N$ of force is the force that can produce an acceleration of 1 m/s² to a body of mass $1kg$. But we take $k$ as 4.72675(any arbitrary number) we will have to include it in the definition. Also it will become measurements and calculations more difficult. So taking $k$ as $1$ is easier for us.

Now you can understand that had Newton discovered his law of gravitation first, he would have used it instead to define the unit of force. In that case he would had taken $G$ as $1$. And then the value of $k$ in his first law would been something else ( may be it would had been a complex value just as $G$). Now you can see that it's one because it makes it easy.

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  • $\begingroup$ 1 kg is no longer the mass of platinum-iridium alloy kept near Paris $\endgroup$
    – Dale
    Feb 11, 2020 at 18:53
  • $\begingroup$ I used it as an example. It's purpose was to make the reader know that kg was actually predefined. $\endgroup$
    – Kartikey
    Feb 12, 2020 at 4:09

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