absolute_value_functions, Study notes of Mathematics

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3.6+ Absolute Value Functions 287 3.6 Absolute Value Functions Learning Objectives In this section, you will: > Graph an absolute value function. > Solve an absolute value equation. Figure 1 Distances in deep space can be measured in all directions. As such, it is useful to consider distance in terms of absolute values. (credit: "s58y"/Flickr) Until the 1920s, the so-called spiral nebulae were believed to be clouds of dust and gas in our own galaxy, some tens of thousands of light years away. Then, astronomer Edwin Hubble proved that these objects are galaxies in their own right, at distances of millions of light years. Today, astronomers can detect galaxies that are billions of light years away. Distances in the universe can be measured in all directions. As such, it is useful to consider distance as an absolute value function. In this section, we will continue our investigation of absolute value functions. Understanding Absolute Value Recall that in its basic form f(x) = |x| , the absolute value function is one of our toolkit functions. The absolute value function is commonly thought of as providing the distance the number is from zero on a number line. Algebraically, for whatever the input value is, the output is the value without regard to sign. Knowing this, we can use absolute value functions to solve some kinds of real-world problems. Absolute Value Function The absolute value function can be defined as a piecewise function x if x>0 soy = bal = { * if x <0 Using Absolute Value to Determine Resistance Electrical parts, such as resistors and capacitors, come with specified values of their operating parameters: resistance, capacitance, etc. However, due to imprecision in manufacturing, the actual values of these parameters vary somewhat from piece to piece, even when they are supposed to be the same. The best that manufacturers can do is to try to guarantee that the variations will stay within a specified range, often +1%, + 5%, or +10%. Suppose we have a resistor rated at 680 ohms, +5%. Use the absolute value function to express the range of possible values of the actual resistance. Q Solution We can find that 5% of 680 ohms is 34 ohms. The absolute value of the difference between the actual and nominal resistance should not exceed the stated variability, so, with the resistance R in ohms,