In Equation (2), where y is by itself, we say that y is expressed explicitly in terms We can add -2x to both members of 2x + y = 4 to get The three pairings can now be displayed as the three ordered pairs Replacements for y are second components and hence y is the dependent variable.įor example, we can obtain pairings for equationīy substituting a particular value of one variable into Equation (1) and solving forįind the missing component so that the ordered pair is a solution to Ments for x are first components and hence x is the independent variable and If the variables x and y are used in an equation, it is understood that replace. It is convenient to speak of the variable associated with theįirst component of an ordered pair as the independent variable and the variableĪssociated with the second component of an ordered pair as the dependent variable. Of the variables, the value for the other variable is determined and thereforeĭependent on the first. In any particular equation involving two variables, when we assign a value to one Such pairings are sometimes shown in one of the following tabular forms. Some ordered pairs for t equal to 0, 1, 2, 3, 4, and 5 are With this agreement, solutions of theĮquation d - 40t are ordered pairs (t, d) whose components satisfy the equation. Second numbers in the pairs as components. We call such pairs of numbers ordered pairs, and we refer to the first and Order in which the first number refers to time and the second number refers toĭistance, we can abbreviate the above solutions as (1, 40), (2, 80), (3, 120), and If we agree to refer to the paired numbers in a specified The pair of numbers 1 and 40, considered together, is called a solution of theĮquation d = 40r because when we substitute 1 for t and 40 for d in the equation, The equation d = 40f pairs a distance d for each time t. In this chapter, we will deal with tabular and graphical representations. We have already used word sentences and equations to describe such relationships 4.Ě graph showing the relationship between time and distance.The distance traveled in miles is equal to forty times the number of hours traveled. In a certain length of time by a car moving at a constant speed of 40 miles per hour. As an example, let us consider the distance traveled The sign of the abscissa and ordinate depends upon the quadrant in which the point lies in the cartesian plane.The language of mathematics is particularly effective in representing relationshipsīetween two or more variables. Note: For the problems like above the points should always be projected on the cartesian plane. Therefore, for point $P\left( \right)$, abscissa = 6 units and ordinate = -8 units. Since it lies in the fourth quadrant, the ordinate for point (Q) is -8 units. Hence abscissa for point (Q) is 6 units.Īnd the distance of point (Q) to the horizontal or x -axis, measured parallel to the vertical or y -axis is 8 units. Similarly, the distance of point (Q) to the vertical or y -axis, measured parallel to the horizontal or x -axis is 6 units. Hence the ordinate for point (P) is 8 units. The distance of point (P) to the horizontal or x -axis, measured parallel to the vertical or y -axis is 8 units. The distance of point (P) to the vertical or y -axis, measured parallel to the horizontal or x -axis is 8 units. ![]() From the cartesian plane, by projecting the point (A) and (B) on x and y axes, we get the following data.
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