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Answer: There is no constant term.

Solution:

I expanded it using the Binomial Theorem:

\(x^8 + 4x^5 + 6x^2 + \frac4x + \frac1{x^4}\)

There appears to be no constant term.

Very nice, WhyamIdoingthis....!!!!

We  have  the form   Ax + By  + C = 0      

The distance  between  the given point  (3,4)  = (x, y) and this line  =

l Ax + By + C  l

________________

sqrt  [A^2  + B^2]

l 4 (3)  + 8(4)  +  7  l                  l  51   l

_________________  =        _________  =     51  /  (4 sqrt 5)  ≈   5.7  units

sqrt  [ 4^2 + 8^2 ]                    sqrt 80

Answer: \(0\)

Solution:

\(x^2\) is always positive. So is the absolute value of x (which is then squared to get \(x^2\)). Since both sides of the expression are \(x^2\), there is only one possible answer for \(x^2-x^2\); \(0\).

Answer: \(3\)

Solution:

\(5^b\cdot5\) (essentially what you wrote except using multiplication) can be turned into \(5^{b+1}\). \(25^{b-1}\) can be turned into \(5^{2(b-1)}\), or \(5^{2b-2}\). Now you have to set these two equal to each other:

\(5^{b+1}\)= \(5^{2b-2}\)

You can get rid of the base, because they're the same.

\(b+1=2b-2\)

Subtracting \(b\) from both sides and adding 2 gives \(b=3\)

amongus

first write \(y=\frac{3x+20}{4}\) in standard form: 

\(y=\frac{3x+20}{4}\:\: \\4y=3x+20\:\:\:\:\:\:\:\:\:\: \\3x-4y+20=0\:\:\)

using distance from point to line formula: 

\(\frac{\left|3\cdot 0-4\cdot 0+20\right|}{\sqrt{3^2+\left(-4\right)^2}}=\frac{20}{5}=4\)

call this distance RS

rs is a perpendicular bisector of the chord

this creates a right triangle with sides AR, RS, and AS

so the radius squared  is: \(10^2+4^2=116\)

area of circle: \(\pi r^2=116\pi \)

JP

the only way the expression \(\frac{x^2\:+\:1}{x^2\:-\:4x\:+\:c}\) is not real is if the denominator equals zero

 \(x^2\:-\:4x\:+\:c=0 \)

discriminant is:

 \((-4)^2-4c \\=16-4c\)

to have no real solutions:

\(16-4c<0 \\4c>16 \\c>4\)

smallest integer value is c=5

JP

thank you!

You can use a calculator and get about 193.994845224, which when rounded to the nearest integer is is 194

equation of the red line in the form y=mx+b: 

slope is 2, y-intercept is -1, so the equation of the red line is y=2x-1

since it's a dashed line, the line isn't included in the shaded region

so the equation is y<2x-1

in the form ax+by+c>0, this equation sould be 2x-y-1>0

JP

Use binomial thoerem

4+1=5th row of pascal triangle

1,4,6,4,1

1 x^4

4x^3y

6x^2y^2

4xy^3

1 y^3

use this expansion of (x+y)^4 

Thank you, melody !

Hi Technoblade,

You have already had your hand slapped by MPS and Why, and they are right, you should not take the credit for other people's answers.

BUT

I am pleased that you are showing an interest here. 

If you find an answer like you did here, post a link to it.  I'd be more than happy to give you a point for that.  

Finding previous answers is a skill in itself.  If you learn from that answer then better still. 

Don't be discouraged,  just don't plagiarize and you will fit in here just fine.   

As to how \(m=a+b\) : 

Finding the slope between AB:
\(m=\frac{a^2-b^2}{a-b}=\frac{(a-b)(a+b)}{(a-b)}=a+b\)

\(x^2-mx-c=0\) -->subsituite m=a+b then let x=a or x=b and solve for c, yielding c=-ab

If you knew the solution, can you please share it?
 

Thanks very much guest, I am glad I could help   

Like so:

Tackle these sort of problems like this:

hint: (a+b)^4 = a^4 + 4*a^3*b + 6*a^2*b^2 + 4*a*b^3 + b^4. Can you take it from here?

Regular pentagon ABCDE is inscribed in a unit circle.  Compute AB*AC.

~~~~~~~~~~~~~~~~~~~~~~~~~~~

I find this very interesting:

If the length of a side of a regular pentagon is 1 unit, then the length of AC = 1.618033989 Golden ratio

Given positive integers x and y such that \(x \ne y\) and

\( \dfrac{1}{x} + \dfrac{1}{y} = \dfrac{1}{18}\),
what is the smallest possible value for \(x+y\)?

\(\begin{array}{|rcll|} \hline \dfrac{1}{x} + \dfrac{1}{y} &=& \dfrac{1}{18} \\\\ \dfrac{x+y}{xy} &=& \dfrac{1}{18} \\\\ \mathbf{xy} &=& \mathbf{18*(x+y)} \\ \hline \end{array}\)

\(\large{AM\ge GM}\)

\(\begin{array}{|rcll|} \hline \mathbf{\dfrac{x+y}{2}} &\ge& \mathbf{\sqrt{xy}} \\ x+y &\ge& 2\sqrt{xy} \quad &| \quad \text{square both sides} \\ (x+y)^2 &\ge& 4xy \quad | \quad xy = 18*(x+y) \\ (x+y)^2 &\ge& 4*18*(x+y) \\ x+y &\ge& 4*18 \\ \mathbf{x+y } &\ge& \mathbf{72} \\ \hline \end{array}\)

Cos 80 = h / 12

solve for h

Yup, seems like this guy is solving more advanced questions than he asks and he is plagiarizing other people's answers to build rep.