Integration related to physics doubt

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SUMMARY

The discussion revolves around the integration of velocity to find displacement, specifically addressing the confusion between constants of integration. The original differential equation, dx/dt = v(t), leads to the integral x = ∫v(t)dt + C, where C represents the initial position. Participants clarify that constants of integration can differ based on context, and emphasize the importance of distinguishing between arbitrary constants when solving integrals. The consensus is that understanding the role of these constants is crucial for accurately interpreting displacement in physics.

PREREQUISITES
  • Understanding of basic calculus concepts, specifically integration.
  • Familiarity with differential equations, particularly dx/dt = v(t).
  • Knowledge of constants of integration and their significance in calculus.
  • Ability to interpret velocity-time graphs and their relation to displacement.
NEXT STEPS
  • Study the concept of definite vs. indefinite integrals in calculus.
  • Learn about the physical interpretation of integrals in motion, specifically in kinematics.
  • Explore the use of arbitrary constants in integration and their implications in physics problems.
  • Review examples of velocity-time graphs and how to calculate displacement from them.
USEFUL FOR

High school students studying calculus, physics enthusiasts, and educators looking to clarify concepts related to integration and displacement in motion.

sarvesh0303
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Homework Statement


I am a high school student and I am very fond of calculus. I know we get the distance by calculating the area under the v-t graph. But this is my take on another way to get an equation
The original differential equation is
dx/dt=v(t)

multiplying both sides by dt,
dx=v(t)dt

Integrating on both sides,
∫dx=∫v(t)dt

Hence we get
x+c=F(t)+C
where F(t) consists of variables only.
but

x=∫v(t)dt =F(t)+C

so i am getting x+c=x but since c is a constant and not necessarily zero x+c might not be equal to x.

Help! Spending sleepless nights on this problem

Homework Equations


x=∫v(t)dt

dx/dt=v(t)

The Attempt at a Solution


Tried my best. Couldn't reach anywhere.
 
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sarvesh0303 said:
Hence we get
x+c=F(t)+C

That's correct.
sarvesh0303 said:
but
x=∫v(t)dt =F(t)+C

Here's where you went wrong. How did x+c become just x? ∫dx=x+c as you indicated in the first quote, so x=∫v(t)dt is not true.
Also, your "c" and "C" both represent the same initial distance in this case, so you can subtract C from both sides to get x=F(t).
 
First off be careful using F(t) as an arbitrary function as F(t) generally denotes Force as a function of time. Your issue here is that x is being used for two different purposes on the LHS and RHS. On the RHS x denotes the distance traveled due to time (x(t)) and c is the initial starting point. Sum them up and you get the total displacement. However, on the LHS x refers to the total displacement where F(t) is the integral of dx/dt without the constant and c is the constant. The easiest way to see that the equations actually are the same is just evaluate the interior of the integral on the RHS.
i.e dx= v(t) dt = dx
 
sarvesh0303 said:

Homework Statement


I am a high school student and I am very fond of calculus. I know we get the distance by calculating the area under the v-t graph. But this is my take on another way to get an equation
The original differential equation is
dx/dt=v(t)

multiplying both sides by dt,
dx=v(t)dt

Integrating on both sides,
∫dx=∫v(t)dt

Hence we get
x+c=F(t)+C
where F(t) consists of variables only.
but

x=∫v(t)dt =F(t)+C

so i am getting x+c=x but since c is a constant and not necessarily zero x+c might not be equal to x.

Help! Spending sleepless nights on this problem

Homework Equations


x=∫v(t)dt

dx/dt=v(t)

The Attempt at a Solution


Tried my best. Couldn't reach anywhere.

Constants of integration are essentially arbitrary (and may have arbitrary names). Would it still trouble you if I wrote x=∫v(t)dt = F(t)+K? Now we would just have K = C-c.

To eliminate such sources of ambiguity (in cases where it matters at all), go with *definite* integration, so if the object starts from x(0) = a the position at time t is
x(t) = a + \int_0^t v(s) \, ds. Notice that I have avoided writing \int_0^t v(t) \, dt, which some people will do. This would be a good thing to avoid---it makes the same symbol 't' perform double duty in the same problem---once as a limit of integration, and once as a dummy integration variable. The point is that \int_0^t v(s) \, ds = \int_0^t v(w) \, dw = \int_0^t v(\text{anything})\, d\text{anything}.

RGV
 
Mr. Ray Vickson : You said that C-c=k but Mr. Nessdude14 said that c's are equal giving k as zero. Who is correct?

and I appreciate the definite integration idea but I also want to know how I could do it through indefinite integration

Mr. Nessdude14: If c=C then in this case F(t) consists only of variables dependent on t right? does that mean the x does not involve a constant?
in this case is x the change in distance or total distance?

Mr. dot.hack: thanks for the pointer about F(t) . also does x here mean total displacement or change in displacement?

Anyway, thanks for all the help you people have put in.
 
Mathematically, if two people are doing the same integral, one gets f(x)+ c and the other gets f(x)+ C, "c" and "C" might well be different, might well be the same.

However, in applications, there has to be some addition condition that determines the "constant of integration". Initially, you said "I know we get the distance by calculating the area under the v-t graph". Exactly what distance are you talking about?
If v(t) is the speed of a moving object, \int f(t)dt is NOT the distance a an obect moves. It is, rather, the x coordinate of the position of the object- and that depends on both the speed and the initial position. You would have to know the initial position in order to determine the constant. If you were to do the problem as a definite integral, \int_{t_0}^{t_1} v(t)dt, there is no constant of integration and you woud have calculated the distance traveled between t_0 and t_1.
 
Halls of Ivy: Is the c always the initial position and the rest of the integral always the change in x-coordinate of the position ?

Thanks for the help!
 
sarvesh0303 said:
Halls of Ivy: Is the c always the initial position and the rest of the integral always the change in x-coordinate of the position ?
Thanks for the help!

Yes; whenever you integrate velocity with respect to time, the "C" constant represents initial position. The only reason that I was able to say your "C" and "c" values were equal is because within the constraints of the problem, they represent the same initial position.
 
sarvesh0303 said:
Mr. Ray Vickson : You said that C-c=k but Mr. Nessdude14 said that c's are equal giving k as zero. Who is correct?

and I appreciate the definite integration idea but I also want to know how I could do it through indefinite integration

Mr. Nessdude14: If c=C then in this case F(t) consists only of variables dependent on t right? does that mean the x does not involve a constant?
in this case is x the change in distance or total distance?

Mr. dot.hack: thanks for the pointer about F(t) . also does x here mean total displacement or change in displacement?

Anyway, thanks for all the help you people have put in.

If you write x = F(t) (instead of F(t)+C), does that make a difference? NO, it does not! F(t) = ∫ v(t) dt is defined as any antiderivative of v; that is, F(t) is any function such that dF(t)/dt = v(t). That means that F(t) itself can contain an arbitrary constant. So, if v(t) = a*t (a = constant), F(t) could be (1/2)*a*t^2, or it could be 762 + (1/2)*a*t^2, or it could be -2012 + (1/2)*a*t^2. or be (1/2)*a*t^2 + C.

Usually in integration tables or in answers delivered by computer algebra systems, for example, a specific formula is written for F(t) and the constant of integration is omitted. The user is supposed to understand that a constant of integration is missing and must by determined by some other problem information, or be left unevaluated.

Anyway, if Person A writes x+c = F+C and Person B writes x = F+c, there is NO contradiction: just because both persons use the sam letter C does not mean they are the same constant. We really ought to write ca+ x = F + Ca and x = F + Cb, to distinguish between the expressions by A and B.

RGV
 
  • #10
I finally understood!

Thanks a lot for those all who have contributed to this thread and helped clear my doubt!
 

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