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Ofwgkta dgaf loiter squad 666
The answer depends on what relationship - if any - exists between the points in the table. There need not be any relationship.
The coordinates of every point on the graph, and no other points, are solutions of the equation.
A diagram that exhibits a relationship, often functional, between two sets of numbers as a set of points having coordinates determined by the relationship.
It is the locus of all points whose coordinates satisfy the equation of the line.
Ofwgkta dgaf loiter squad 666
Ofwgkta dgaf loiter squad 666
It is a straight line equation in the form of y = mx+c whereas m is the slope and c is the y intercept
The answer depends on what relationship - if any - exists between the points in the table. There need not be any relationship.
The solution set for a given equation is the set of all points such that their coordinates satisfy the equation.
They could be the coordinates of a straight line equation
The coordinates of every point on the graph, and no other points, are solutions of the equation.
Yes. You need only two points. If A (ax, ay) and B (bx, by) are two points on the line then the gradient (slope) of the line is m = (by - ay)/(bx - ax) provided bx ≠ ax. From this you can calculate m. Then the general slope-intercept form of the equation is y = mx + c Substitute the coordinates of A or B into this equation to find c. If bx = ax then the line is parallel to the y axis and its equation is x = ax. [There are other methods but they are similar to the above]
A diagram that exhibits a relationship, often functional, between two sets of numbers as a set of points having coordinates determined by the relationship.
Assuming you want the equation of the straight line between the two points (x0, y0) and (x1, y1), the equation is: y - y0 = m(x - x0) where m is the gradient between the two points: m = (y1 - y0) ÷ (x1 - x0) Note: if the two x coordinates are equal, that is x0 = x1, then the equation of the line is x = x0.
The coordinates of the points on the curve represent solutions of the equation.
It is the locus of all points whose coordinates satisfy the equation of the line.