What are the x- and y- intercepts of the linear equation -5x + 3y = -15
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veronica has 423 baseball cards she put them in 10 piles each how many piles of 10 cards did she make
( -5 , 12) and ( 2 , 26)
Which choice describes a question that could be answered by moving the decimal point 3 places to the right?A.multiplying 31.04 by 100B.multiplying 31.04 by 1,000C.dividing 31.04 by 102D.dividing 31.04 by 103
Need help on this question!!! solve for x
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Answer:
93
Step-by-step explanation:
Use PEMDAS and plug in the values for x and y. So replace x with 8 in the parenthesis, resulting in (8+2x3) since you do multiplication before addition, it would be 8+6 equaling 14. 14 would be multiplied by 6, so it would be 84, but do not forget the y^2, which would be 3^2 and since 3x3 is 9, you would add 9 to 84
To find the answer, we can first put x=8 and y=3 into the equation:
y^2 + 6(x + 3×2)
=3^2 + 6(8+3×2)
We can them proceed to calculate by doing the multiplications in the first steps:
=9 + 6(8+6)
=9 + 6×14
=9 + 84
=93
Therefore, the answer is 93.
Hope it helps!
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the value of the second 5=500 which is equal to 5 hundred because it is in the hundreds place
Hope this helps!! :D
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To solve the equation by drawing disks on a place value chart, represent 2 copies of 4 tenths as disks in the tenths place. The equation is 0.4 + 0.4 = 0.8.
To represent and solve for "2 copies of 4 tenths" using a place value chart, you can follow these steps:
**Step 1:** Set up the place value chart. The place value chart includes columns for units, tenths, hundredths, and so on.
```
Units | Tenths | Hundredths | ...
```
**Step 2:** Represent the first "4 tenths." Draw four disks in the tenths place, which is the second column from the right.
```
Units | Tenths | Hundredths | ...
▢ ▢ ▢ ▢
```
**Step 3:** Represent the second "4 tenths." Draw four more disks in the tenths place.
```
Units | Tenths | Hundredths | ...
▢ ▢ ▢ ▢
+ ▢ ▢ ▢ ▢
```
**Step 4:** Add the two sets of "4 tenths" together. When you add them visually, you get eight disks in the tenths place.
```
Units | Tenths | Hundredths | ...
▢ ▢ ▢ ▢
+ ▢ ▢ ▢ ▢
------------
▢ ▢ ▢ ▢
```
**Step 5:** Express the sum in standard decimal form. In this case, it's 0.8.
So, 2 copies of 4 tenths is equal to 0.8 in standard decimal form.
Learn more about equations here:
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Events A and B are mutually exclusive, with P(A) = 0.36 and P(B) = 0.05.
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4x – y + z = 7
X – 3y + 2z =-5
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Answer:
(x, y, z) = (1, 12, 15)
Step-by-step explanation:
As with any set of linear equations, there are many possible routes to a solution. We might simplify the notation a bit by writing the coefficients in an augmented matrix. The columns, left to right, represent the coefficients of x, y, and z, in order, and the constant term.
The row operations we'll use are multiplying a row by a value and adding that result to another row, replacing the other row by the sum.
We can make things a little simpler by writing the second equation first. Then the augmented matrix we're starting with is ...
Adding the second row to the first, we get ...
Dividing the first row by 5 gives ...
Subtracting this from the second row, and again from the third row, we are left with ...
Multiplying the second row by 3 and adding that to the third row, we get ...
Subtracting the third row from the second gives ...
Finally, multiplying the last row by -1, we have the solution:
This matrix corresponds to the equations ...
- x = 1
- y = 12
- z = 15
_____
The purpose of our choice of row operations is to make the diagonal elements 1 and the off-diagonal elements 0. That is how we end up with the final equations shown.
As we said, there are many ways to go about this. In general, one can ...
- if necessary, swap rows until the diagonal term of interest is non-zero. If you are doing this using a computer program, generally you want the diagonal term to have the coefficient with the largest magnitude. When doing this by hand, you may want to arrange the rows to avoid fractions when you do the normalizing.
- divide the row by the coefficient of the diagonal element to "normalize" the diagonal element to a value of 1
- zero the other elements in that column by multiplying the row just normalized by the element in another row, then subtracting the product. (The 4th matrix shown above shows this for the first column.)
- proceed to the next diagonal element and repeat the process until all diagonal elements are 1. If you cannot make all diagonal elements 1, then the system of equations does not have a unique solution. If any row becomes all zeros, the system is "dependent" and has infinite solutions. If a row is zeros except for the rightmost column, the system is "inconsistent" and has no solutions.