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3 years ago

Find the volume of the cylinder!

Mathematics

1 answer:

Amiraneli [1.4K]3 years ago

8 0

Answer: this is the answer i got before rounding it 2123.72 but your answer is 2123.7 hope it helps

Step-by-step explanation:

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Drag each equation to the model and situation it matches.<br> (Picture) *I will give a brainliest

arlik [135]

Answer:

First model gets the equation: y = 2 . 2^z

Second model gets the equation: y = 4^z

Third model gets the equation: y: = 4 . 2^z

7 0

3 years ago

Darnel has $9 in a savings account. The interest rate is 10%, compounded annually.

aksik [14]

9514 1404 393

Answer:

$2.98

Step-by-step explanation:

The amount of interest earned is ...

I = P((1 +r)^t -1)

I = $9(1.1^3 -1) ≈ $2.98

Daniel will earn about $2.98 in interest in 3 years.

6 0

3 years ago

1) Which expression has a value equal to 28 = 4?

Mkey [24]

Answer:

option . B

Step-by-step explanation:

The reason for this is because 28 over 4 is the same thing to 28 = 4 .

love you have a good day <3

8 0

3 years ago

15 points. Attached the question<br>

Vanyuwa [196]

Answer:

Step-by-step explanation:

(2x +1)/8 - (x-1)/3 = 5/24

multiple the 2x+1/8 by 3 and multiple (x-1)/3 by 8 then add them up

6x+3/24 - 8x-8/24 ➡ 6x-8x+11/24 = 5/24

➡ -2x+11 = 5

➡ -2x = 5-11

➡ x = 3

4 0

4 years ago

How many different linear arrangements are there of the letters a, b,c, d, e for which: (a a is last in line? (b a is before d?

inna [77]

A) Since a is last in line, we can disregard a, and concentrate on the remaining letters.
Let's start by drawing out a representation:

_ _ _ _ a

Since the other letters don't matter, then the number of ways simply becomes 4! = 24 ways

b) Since a is before d, we need to account for all of the possible cases.

Case 1: a d _ _ _
Case 2: a _ d _ _
Case 3: a _ _ d _
Case 4: a _ _ _ d

Let's start with case 1.
Since there are four different arrangements they can make, we also need to account for the remaining 4 letters.
$\text{Case 1: } 4 \cdot 4!$

Now, for case 2:
Let's group the three terms together. They can appear in: 3 spaces.
$\text{Case 2: } 3 \cdot 4!$

Case 3:
Exactly, the same process. Account for how many times this can happen, and multiply by 4!, since there are no specifics for the remaining letters.
$\text{Case 3: } 2 \cdot 4!$

$\text{Case 4: } 1 \cdot 4!$

$\text{Total arrangements}: 4 \cdot 4! + 3 \cdot 4! + 2 \cdot 4! + 1 \cdot 4! = 240$

c) Let's start by dealing with the restrictions.
By visually representing it, then we can see some obvious patterns.

a b c _ _

We know that this isn't the only arrangement that they can make.
From the previous question, we know that they can also sit in these positions:

_ a b c _
_ _ a b c

So, we have three possible arrangements. Now, we can say:
a c b _ _ or c a b _ _
and they are together.

In fact, they can swap in 3! ways. Thus, we need to account for these extra 3! and 2! (since the d and e can swap as well).

$\text{Total arrangements: } 3 \cdot 3! \cdot 2! = 36$

7 0

3 years ago