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36 possible rolls  

6 1

5 2

4 3    are all 7's   and two ways of rolling each of the,      6/36 = 1/6

That is incorrect.

[R1] - [R2] - [R3] + [R4] = 150.

Using vectors, we can show that the ratio of the volume is 18.

D is 20     then   go through the list    C is 15    B is 16   A is 11

The probability will always be % \(50\) because each turn, there is a 50-50 chance that the coin will be heads or tails.

Graph it using this graphing calculator. then answer the questions yourself.

3 and 1/2 squares in total, so it is 9x9x3+9/2= 247.5

your right man

No problem!

WOW thx I understand now! :D 

Based on Melody's post in the question you linked, yes, you can find the median by averaging the two parallel sides. It seems like you're having trouble finding the parallel sides. 

Call one parallel side x and the other x+7

The area of the trapezoid is the sum of the parallel sides times the height divided by 2 which equals 60 in this case.
\(\frac{h(b_1+b_2)}{2}\)

Since we know the height and the area, we can solve for the sides.

\(\frac{5(x+x+7)}{2}=\frac{10x+35}{2}=60\) From this, we get x=8.5. So we know your work above is correct. Since 1 side is x and the other is x+7, the two parallel sides are 8.5 and 15.5. To find the median, take the average of these two numbers.

If you take the time to proofread your question then maybe someone will take the time to answer it.

You cannot expect people to answer questions which are not complete.

Concentrate on working out how to post a picture.

In parallelogram ABCD, M is the midpoint of CD.  
The area of triangle BNC is 42.  
Find the area of triangle MNC.

\(\text{Let the area of $\triangle ABN = A_1$} \\ \text{Let the area of $\triangle BNC = A_2=42$} \\ \text{Let the area of $\triangle MNC = A_3=\ ?$} \\ \text{Let $h=h_1+h_2$ or $h_2=h-h_1$} \)

\(\begin{array}{|rcll|} \hline A_3 &=& \dfrac{xh_1}{2} \\ \mathbf{2A_3} &=& \mathbf{xh_1} \qquad (1) \\ \hline \end{array} \begin{array}{|rcll|} \hline A_1+A_2 &=& \dfrac{2xh}{2} \\ \mathbf{A_1+A_2} &=& \mathbf{xh} \qquad (2) \\ \hline \end{array} \)

\(\begin{array}{|rcll|} \hline A_1 &=& \dfrac{2xh_2}{2} \\ A_1 &=& xh_2 \quad | \quad h_2=h-h_1 \\ A_1 &=& x(h-h_1) \\ A_1 &=& xh-xh_1 \quad | \quad xh=A_1+A_2,\ xh_1=2A_3 \\ A_1 &=& A_1+A_2-2A_3 \\ 2A_3+A_1 &=& A_1+A_2 \\ 2A_3 &=& A_2 \\ A_3 &=& \dfrac{A_2}{2} \quad | \quad A_2 = 42 \\ A_3 &=& \dfrac{42}{2} \\ \mathbf{A_3} &=& \mathbf{21} \\ \hline \end{array}\)

The area of  \(\triangle MNC=\mathbf{21}\)

\(y=mx+c\) slope-intercept form

"Parallel to the graph of \(x+3y=-5\)" means that \(Ax+By=3\) have the same slope as it.

Both are written in standard form.

 \(x+3y=-5\) Divide both sides by 3

\(\frac{x}{3}+y=-\frac{5}{3}\) Rearrange

\(y=-\frac{1}{3}x-\frac{5}{3}\) Thus slope is \(-\frac{1}{3}\)

\(Ax+By=3\)

Rearrange to solve for y

\(\frac{A}{B}x+y=\frac{3}{B}\)

\(y=-\frac{A}{B}x+\frac{3}{B}\)

Notice \(\frac{A}{B}=\frac{1}{3}\) (Since it is the same slope as the previous line)

Thus we have

\(y=-\frac{1}{3}x+\frac{3}{B}\) 

Now, as given, \(Ax+By=3\) passes through the point (-7,2)

Substitute this into \(y=-\frac{1}{3}x+\frac{3}{B}\)

\(2=-\frac{1}{3}*(-7)+\frac{3}{B}\) , Solve for B 

\(2-\frac{7}{3}=\frac{3}{B}\) , \(B=-9\)

So the equation now becomes \(y=-\frac{1}{3}x-\frac{1}{3}\)

However, we want to find the value of A in order to answer the question "What is B-A"

\(Ax+By=3\), use (-7,2) (Also knowing the value of B= -9 to solve for A)

\(-7A+(-9)*(2)=3\)

\(A=-3\)

\(B-A=-9-(-3)=-9+3=-6\)

What is the surface area of a square pyramid with a height of 12 mm and a base that measures 10 mm on each side?

The amount of paper needed is the surface area of the cone minus the base of it. The surface area of that is pi * radius * slant height. So our answer is pi * 1.5 * 4 = 6pi = 18.85 = 19 sq in.

That was a brilliant solution!!!!!

The following image should help:

a=⟨3, −1⟩ and b=⟨−1,−4⟩ .

 complete the head to tail method, draw a +b on a graph without drawing unnecessary vectors.

a=⟨3, −1⟩ and b=⟨−1,−4⟩ complete the head to tail method, draw a +b on a graph without drawing unnecessary vectors.

I have 5 different biology textbooks and 4 different economics textbooks. In how many ways can I place the 9 textbooks on a bookshelf, in a row, if there must be an economics textbook in the middle, and there must be a biology textbook at each end?

B1 B2 B3 B4 B5     E1 E2 E3 E4

B***E***B 

5 * 4 * 4 * 6! = 57600   

Can someone help me?

\(\vec{a}=<5,-1>\), and \(\vec{b}=<-3,-4>\).
Represent \(\vec{a+b}\) by using the head to tail method.

Do not include any unnecessary vectors.