There are an infinite number of them.
Here are a few:
X . . . . Y
-3 . . . -1
-2 . . . -0.6
-1 . . . -0.2
0 . . . . +0.2
1 . . . . 0.6
2 . . . . 1
3 . . . . 1.4
5 . . . . 2.2
10 . . . 4.2
7
An ordered pair or coordinates of a point in 2-dimensional space.
It is a linear equation in two variables, x and y. Any point on the line defined by the equation will satisfy the equation and conversely, any ordered pair that satisfies the equation will represent a point, in the Cartesian plane, will be on the line.
(0, 6)
13
7
An ordered pair or coordinates of a point in 2-dimensional space.
Substitute the values for the two variables in the second equation. If the resulting equation is true then the point satisfies the second equation and if not, it does not.
It is a linear equation in two variables, x and y. Any point on the line defined by the equation will satisfy the equation and conversely, any ordered pair that satisfies the equation will represent a point, in the Cartesian plane, will be on the line.
(0, 6)
13
Any ordered pair that satisfies y = 22 - X is a solution.
3x + 4y = -4 defines a line in 2-dimensional space and the coordinates of every point on the line is an ordered pair that satisfies the equation. I have neither the time nor the inclination to list an infinite number of ordered pairs.
15
There are infinitely many ordered pairs: each point on the straight line defined by the equation is an ordered pair that is a solution. One example is (0.5, 2.5)
There are an infinite number of ordered pairs that satisfy the equation.
x = 5 and y = 4