![\"\"](\"/userfiles/image/steps_images/step1.JPG\")
The relation is
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x y = - 2x + 1 y (x, y) -1 Y = - 2(-1) + 1 = 3 3 (-1, 3) 0 Y = - 2(0) + 1 = 1 1 (0, 1) 1 Y = -2(1) + 1 = -1 -1 (1, -1) 2 Y = - 2(2) + 1 = -3 -3 (2, -3) \
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Express the relation as ordered pairs![\"\"](\"/test/fckeditor/editor/plugins/fckeditor_wiris/integration/showimage.php?formula=89e79a6b1141f402911a2a1781e1f8eb.png\")
.![\"\"](\"/userfiles/image/steps_images/step2.JPG\")
Create a coordinate system and plot the ordered pairs.
\Draw a line through the points.
\![\"graph](\"/userfiles/image/Library/Algebra%202/graph_linear_equation_y=-2x+1(3).gif\")
Since x can be any real number, there are an infinite number of ordered pairs that can be graphed. All of them lie on the line shown.![\"\"](\"/userfiles/image/steps_images/step3.JPG\")
Every real number is the x-coordinate of some point on the line.
\So, the domain (x-coordinates on the line) is set of all real numbers.
\Every real number is the y-coordinate of some point on the line.
\So, the range (y-coordinates on the line) is also set of all real numbers.
\The relation is Continuous.
\![\"\"](\"/userfiles/image/steps_images/step4.JPG\")
Draw the vertical lines through the points. Observe that there is no vertical line contains more than one of the points. This graph passes the vertical line test.
\For each x-value, there is exactly one y-value, so the equation y = -2x + 1 represents a function.
\![\"graph](\"/userfiles/image/Library/Algebra%202/graph_linear_equation_y=-2x+1_vertical_lines.gif\")
![\"\"](\"/userfiles/image/steps_images/solution.JPG\")
The domain (x-coordinates on the line) is set of all real numbers.
\The range (y-coordinates on the line) is also set of all real numbers.
\The relation is Continuous.The equation y = -2x + 1 represents a function.