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3 years ago

Given that (1,9) is on the graph of f(x), find the corresponding point for the function 2/3 f(x)

Mathematics

1 answer:

GrogVix [38]3 years ago

7 0

Answer:

(1,6)

Step-by-step explanation:

If "(1, 9) is on the graph of f(x),"

then (1, [2/3][9]) is on the graph of the function y = (2/3)f(x). This works out to (1, 6).

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Need help with these proofs asap i have a 58 in geometry cuz of proofs ;c

shutvik [7]

Sucks for you. nerdddddddddddddddddddddddddd

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3 years ago

Here is a story: Lin bought 4 bags of apples. Each bag had the same number of apples. After eating 1 apple from each bag, she ha

Setler [38]

Answer:

Let's define the variable x as the number of apples in each bag.

We know that she bought 4 bags, then the total number of apples that she has is:

Apples = 4*x

Now she eats one apple for each bag, then she eats 4 apples, so she now has:

Apples = 4*x - 4

And we know that this is equal to 28, then:

4*x - 4 = 28

now we can solve this for x.

4*x = 28 + 4 = 32

x = 32/4 = 8

x = 8

There are 8 apples in each bag.

For the diagram part, by a small online search y found the image that you can see below.

The diagram that correctly represents this situation is diagram C, where x represents the number of apples in each bag.

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3 years ago

The last question!!!!!!!!!!!!!!

Gwar [14]

Answer:

800

Step-by-step explanation:

if you look at the graph and go where t=2 you see that it will have 800 bacteria at two hours

6 0

3 years ago

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Jena lives 1 mile from the school. She rides her bike at a speed of 4 miles per hour. If she leaves school at 2:30 p.m., what ti

Finger [1]

Answer:

I believe it's A

Step-by-step explanation:

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2 years ago

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What is the measurement to the calculation to figure the numbers of pi

AlexFokin [52]

Answer:

There's a lot of them.

There are many different ways to calculate $\pi$ . The ones used by computers to generate tons of digits are usually infinite series.

The series that has been prominent in recent records for the most digits of pi is the Chudnovsky algorithm.

The algorithm is this:

$\frac{1}{\pi}=12\sum_{k=0}^{\infty}\frac{\left(6k\right)!\left(545140134k+13591409\right)}{\left(3k\right)!\left(k!\right)^3\left(640320\right)^{3k+\frac{3}{2}}}$

For faster performance, it can be simplified to this:

$\frac{426880\sqrt{10005}}{\pi}=12\sum_{k=0}^{\infty}\frac{\left(6k\right)!\left(545140134k+13591409\right)}{\left(3k\right)!\left(k!\right)^3\left(-262537412640768000\right)^k}$

Other algorithms have been used, but right now this is the one that is being used to set the recent records.

There are also some approximations that are used because they are very easy to calculate.

first, $\frac{22}{7}$ can be used to calculate a fairly accurate pi, but a better rational approximation is $\frac{355}{113}$ This fraction is actually accurate to 6 digits and it is the best approximation of $\pi$ in simplest form and with a denominator below 30,000.

There are several other approximations and if you want to learn more I would recommend looking at the Wikipedia page which has tons of algorithms for pi.

4 0

3 years ago