How can I simplify this derivative to make calculating arc length easier?

In summary, to find the arc length of the given function, we need to find the derivative and then use the formula L=\intds=\sqrt{1+(dy/dx)^{2}}. Simplifying the derivative may be helpful, and we can do so by using polynomial division and substituting a letter for (x+1).
  • #1
jen333
59
0
Hi! Here's my question on finding arc length. If I've taken the derivative correctly, is there anyway I can simplify it before putting it into the arc length formula?

Homework Statement


Find the arc length where 0[tex]\leq[/tex]x[tex]\leq[/tex]2
y=(x[tex]^{3}[/tex]/3)+x[tex]^{2}[/tex]+x+1/(4x+4)


Homework Equations


L=[tex]\int[/tex]ds=[tex]\sqrt{1+(dy/dx)^{2}}[/tex]



The Attempt at a Solution


I've only taken the derivative so far:
(dy/dx)=x[tex]^{2}[/tex]+2x+1-4(4x+4)[tex]^{-2}[/tex]
=(x+1)[tex]^{2}[/tex]-4(4x+4)[tex]^{-2}[/tex]


I tried expanding the equation, but that only makes it more complex.

I know to find the arc length I need to square the derivative and place it in the formula (and possibly using substitution), but I'm just wondering how I can simplify the above equation to make it easier to square and calculate!
 
Last edited:
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  • #2
Polynomial division! =]
 
  • #3
Yeah you should get this if you do the polynomial division correctly:

[tex]\int_0^2 (x+1)^2 + \frac{1}{4(x+1)^4} dx[/tex].

To make things easier, denote (x+1) by A or some other letter, then it'll look easier.

EDIT: Fixed error
 
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  • #4
I would look at it like this:
[tex]y'= x^2+ 2x+ 1- \frac{4}{(4x+ 4)^2}= x^2+ 2x+ 1- \frac{1}{4(x+1)^2}[/tex]
[tex]= (x+ 1)^2- \left(\frac{1}{2(x+1)}\right)^2[/tex]
so
[tex](y')^2= (x+1)^4- 1/2+ \left(\frac{1}{2(x+1)}\right)^4[/tex]
[tex](y')^2+ 1= (x+1)^4+ 1/2+ \left(\frac{1}{2(x+1)}\right)^4[/tex]
[tex]= \left((x+1)^2+ \left(\frac{1}{2(x+1)}\right)^2\right)^2[/tex]
so that
[tex]\sqrt{(y')^2+ 1}= (x+1)^2+ \frac{1}{2(x+2)}[/tex]
 
  • #5
HallsofIvy said:
[tex]= \left((x+1)^2+ \left(\frac{1}{2(x+1)}\right)^2\right)^2[/tex]
so that
[tex]\sqrt{(y')^2+ 1}= (x+1)^2+ \frac{1}{2(x+2)}[/tex]
There's a small error here, the last term should read 1/4(x+1)^2 instead.
 

FAQ: How can I simplify this derivative to make calculating arc length easier?

What is a "Crazy Function for Arc Length"?

A "Crazy Function for Arc Length" is a mathematical function that is used to calculate the length of an arc on a curve. This function can be used in various fields such as physics, engineering, and geometry.

How is the "Crazy Function for Arc Length" different from a regular arc length function?

The "Crazy Function for Arc Length" takes into account the changing curvature of a curve, whereas a regular arc length function assumes a constant curvature. This makes the "Crazy Function for Arc Length" more accurate in calculating the length of an arc on a curve.

What are the applications of the "Crazy Function for Arc Length"?

The "Crazy Function for Arc Length" has various applications in real-world scenarios. It is used in calculating the trajectory of projectiles, designing roller coaster tracks, and determining the length of a curved road or river.

Can the "Crazy Function for Arc Length" be applied to any type of curve?

Yes, the "Crazy Function for Arc Length" can be applied to any type of curve, including circles, ellipses, parabolas, and more complex curves. As long as the curve has a defined function, the "Crazy Function for Arc Length" can be used to calculate the length of an arc on it.

How is the "Crazy Function for Arc Length" derived?

The "Crazy Function for Arc Length" is derived using calculus and the concept of arc length as an integral. It involves breaking down the curve into infinitesimal segments and summing them up to find the total length of the arc. This function can be derived for any type of curve using the fundamental theorem of calculus.

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