60 hundreds = thousands

A butterfly starts at 20m and changes -16m

Fynjy0 [20]

You should use Google.

8 0

4 years ago

Read 2 more answers

I dont understand this.

lakkis [162]

To find the area of a rectangle the formula is:

Area = length * height

A = L * H

In this case:

L = 3x

H = 2x

^^^In-put these values into the equation given above

A = 3x * 2x

Now you must multiply them together.

When multiplying numbers with variable(s) you multiply the number portion normally ( 3 * 2 = 6).

Multiplying variables is slightly different. The matching variables (x and x) will become one "x" and have an exponent attached to the x.

What will the exponent be? If a variable has no visible exponent it can be assumed that it has an exponent of 1. When multiplying variables the exponents on each variable will be <em>sumed </em>together and attached to the final variable:

$x^{1} *x^{1} = x^{1+1}$ = x²

Now combine the product of the numbers with the product of the variables:

Area = 6x²

Hope this helped!

~Just a girl in love with Shawn Mendes

8 0

4 years ago

Find two numbers x and y such that a) 2x+y=100 and A=2x+2xy+y is maximized b) 2x+4y-15=0 and B= √x2+y2is minimized. Note that in

zaharov [31]

Answer:

a) x = 25, y = 50

b) x = 1.5, y = 3

Step-by-step explanation:

We have to use Lagrange Multipliers to solve this problem. The maximum of a differentiable function f with the constraint g(x,y) = b, then we have that there exists a constant $\lambda$ such that

$\nabla f(x,y) = \lambda \, \nabla g(x,y)$

Or, in other words,

$f_x(x,y) = \lambda \, g_x(x,y) \\ f_y(x,y) = \lambda \, g_y(x,y)$

a) Lets compute the partial derivates of f(x,y) = 2x+2xy+y. Recall that, for example, the partial derivate of f respect to the variable x is obtained from derivating f thinking the variable y as a constant.

$f_x(x,y) = 2 + 2y$

On the other hand,

$f_y(x,y) = 2x+1$

The restriction is g(x,y) = 100, with g(x,y) = 2x+y. The partial derivates of g are

$g_x(x,y) = 2; g_y(x,y) = 1$

This means that the Lagrange equations are

$2y + 2 = 2 \, \lambda$
$2x +1 = \lambda$
$2x + y = 100$ (this is the restriction, in other words, g(x,y) = 100)

Note that 2y + 2, which is $2 \, \lambda$ is the double of 2x+1, which is $\lambda$ . Therefore, we can forget $\lambda$ for now and focus on x and y with this relation:

2y+2 = 2 (2x+1) = 4x+2

2y = 4x

y = 2x

If y is equal to 2x, then

g(x,y) = 2x+y = 2x+2x = 4x

Since g(x,y) = 100, we have that

4x = 100

x = 100/4 = 25

And, therefore y = 25*2 = 50

Therefore, x = 25, Y = 50.

b) We will use the suggestion and find the minumum of f(x,y) = B² = x²+y², under the constraing g(x,y) = 0, with g(x,y) = 2x+4y-15. The suggestion is based on the fact that B is positive fon any x and y; and if 2 numbers a, b are positive, and a < b, then a² < b². In other words, if (x,y) is the minimum of B, then (x,y) is also the minimum of B² = f.

Lets apply Lagrange multipliers again. First, we need to compute the partial derivates of f:

$f_x(x,y) = 2x \\f_y(x,y) = 2y$

And now, the partial derivates of g:

$g_x(x,y) = 2 \\ g_y(x,y) = 4$

This gives us the following equations:

$2x = 2 \, \lambda \\ 2y = 4 \, \lambda \\ 2x+4y-15 = 0$

If we compare 2x with 2y, we will find that 2y is the double of 2x, because 2y is equal to $4 \, \lambda$ , while on the other hand, $2x = 2 \, \lambda$ . As a consequence, we have

2y = 2*2x

y = 2x

Now, we replace y with 2x in the equation of g:

0 = g(x,y) = 2x+4y-15 = 2x+4*2x -1x = 10x-15

10 x = 15

x = 15/10 = 1.5

y = 1x5*2 = 3

Then, B is minimized for x 0 1.5, y = 3.

4 0

3 years ago

True or false: When a figure on a coordinate grid is translated down and to the right, the vertex with the largest y-coordinate

Montano1993 [528]

Answer:

True

Step-by-step explanation:

Translation down and to the right doesn't change the dimensions of the original figure.

This will change coordinates of each vertex but the highest coordinates of the pre-image and image will correspond to each other.

7 0

4 years ago

A snowcone cup at the country fair is 15 cm tall and has a diameter of 8 cm if the cup is full just the top what is the volume o

slavikrds [6]

Answer:

2827 cubic centimetre

Step-by-step explanation:

The cup is cylindrical in shape and it is full to the top.

The height of the cup is 15 cm and its diameter is 8 cm (radius = 4 cm).

The volume of a cylinder is given as:

$V = \pi r^2h$

where r = radius

h = height

The volume of the liquid in the cup is:

$V = \pi * 15^2 * 4$

V = 2827.43 cubic centimetre ≅ 2827 cubic centimetre

3 0

3 years ago