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5 Exponential and Logarithmic Functions Case Study 5.1 Rational Indices 5.2 Logarithmic Functions 5.3 Using Logarithms to Solve Equations 5.4 Graphs of Exponential and Logarithmic Functions 5.5 Applications of Logarithms Chapter Summary Case Study The growth rate of bacteria can be expressed by an exponential function. We can use it to find the number of bacteria. How can we find the number of bacteria after a certain period of time? Although it is not easy to see bacteria with our naked eyes, bacteria do exist almost everywhere. Most bacteria reproduce by cell division, that is, one bacterium can divide and become 2, 2 become 4, and so on. However, each species reproduces itself at different rates due to different humidities and temperatures. P. 2 5.1 Rational Indices A. Radicals We learnt that if x2 y, for y 0, then x is a square root of y. If x3 y, then x is a cube root of y. If x4 y, then x is a fourth root of y. In general, for a positive integer n, if xn y, then x is an nth root of y and we use the radical n y to denote an nth root of y. 2 y is usually written as Remarks: If n is an even number and y 0, then y has one positive nth root and one negative nth root. Positive nth root: n y ; Negative nth root: n y If n is an even number and y 0, then n y is not a real number. If n is an odd number, then n y 0 (for 0) and n y 0 (for y 0). Examples: 3 5 P. 3 64 4 243 3 y. 5.1 Rational Indices B. Rational Indices In junior forms, we learnt the laws of indices for integral indices. Recall that (am)n amn, where m and n are integers. Try to find the meaning of 1 ( y n )n 1 yn and m yn: 1 n n y y 1 Take nth root on both sides, we have y n n y . Since Then consider Hence we have m yn 1 m n y and m yn y m 1 n 1 ( y n )m 1 ( ym )n (n y) m n ym m yn (n y ) m n y m . P. 4 5.1 Rational Indices B. Rational Indices Therefore, for y 0, we define rational indices as follows: 1. 1 yn n y 2. m yn (n y ) m n y m where m, n are integers and n 0. Remarks: In the above definition, y is required to be positive. However, the definition is still valid for y 0 under the following situation: m The fraction is in its simplest form and n is odd. n For example: 2 (8) 3 (3 8) 2 (2) 2 4 P. 5 5.1 Rational Indices B. Rational Indices Example 5.1T Simplify (3 b 2 ) 6, where b 0 and express the answer with a positive index. Solution: (3 b 2 ) 6 (b 2 3 ) 6 2 ( 6 ) b 3 b4 First express the radical with a rational index. Then use (bm)n bmn to simplify the expression. P. 6 5.1 Rational Indices B. Rational Indices Example 5.2T 1 1 Evaluate 2 4 2 . Solution: 1 2 4 1 2 9 4 1 2 1 2 3 2 2 1 3 2 2 3 Change the mixed number into an improper fraction first. P. 7 5.1 Rational Indices B. Rational Indices Example 5.3T 9 x 3 3x 1 Simplify x2 . 6 27 Solution: 9 x 3 3 x 1 3 2 ( x 3) 3 x 1 x2 6 27 2 3 33( x 2) 1 32( x 3) ( x 1) 1 3( x 2) 2 Change the numbers to the same base before applying the laws of indices. 1 2 3 2 1 1 2 9 1 18 P. 8 5.1 Rational Indices n C. Using a Calculator to Find y m The following is the key-in sequence of finding 5 322 : 5 32 2 Since 5 322 32 5 32 , we can also press the following keys in sequence: 2 5 Remarks: If n is an even number and ym 0, then ym has two nth real roots, i.e., n y m . However, the calculator will only display n ym . P. 9 5.1 Rational Indices D. Using the Law of Indices to Solve Equations p q For the equation x b, where b is a non-zero constant, p and q are integers with q 0, we can take the power of q on both sides and solve the equation: p p q 3 x b p q q p q p 2 x3 p q q p q p 2 3 (x3 )2 (x ) b x x2 4 b xb q p 4 3 (2 2 ) 2 x 8 P. 10 5.1 Rational Indices D. Using the Law of Indices to Solve Equations Example 5.4T If (2 x 1) 1 3 1 3 , find x. Solution: (2 x 1) 1 3 1 3 (2 x 1) 1 3 1 [(2 x 1) 3 ]3 Change the equation into the 2 p q form x b first. 23 2x 1 1 8 x 7 16 P. 11 5.1 Rational Indices D. Using the Law of Indices to Solve Equations Example 5.5T Solve 22x 1 22x 8. Solution: 22x 1 22x 8 2(22x) 22x 8 22x(2 1) 8 22x 8 22x 23 2x 3 3 x 2 Take out the common factor 22x first. P. 12 5.2 Logarithmic Functions A. Introduction to Common Logarithm If a number y can be expressed in the form ax, where a 0 and a 1, then x is called the logarithm of the number y to the base a. It is denoted by x loga y. If y ax, then loga y x, where a 0 and a 1. Notes: If y 0, then loga y is undefined. Thus the domain of the logarithmic function loga y is the set of all positive real numbers of y. When a 10 (base 10), we write log y for log10 y. This is called the common logarithm. If y 10n, then log y n. ∴ log 10n n for any real number n. In the calculator, the button log also stands for the common logarithm. P. 13 5.2 Logarithmic Functions A. Introduction to Common Logarithm By the definition of logarithm and the laws of indices, we can obtain the following results directly: 1 1 ∵ 102 ∴ log 2 100 100 1 1 ∵ 101 ∴ log 1 10 10 ∵ 1 100 ∴ log 1 0 ∵ 10 101 ∴ log 10 1 ∵ 100 102 ∴ log 100 2 ∵ 1000 103 ∴ log 1000 3 Values other than powers of 10 can be found by using a calculator. For example: log 34 1.5315 (cor. to 4 d. p.) Given log x 1.2. ∴ x 101.2 0.0631 (cor. to 3 sig. fig.) P. 14 5.2 Logarithmic Functions B. Basic Properties of Common Logarithm The function f (x) log x, for x 0 is called a logarithmic function. There are 3 important properties of logarithmic functions: For M, N 0, 1. log (MN) log M log N M 2. log log M log N N 3. log M n n log M In general, 1. log M log N log (MN); log M M log ; log N N 3. (log M)n log M n. 2. Let M 10a and N 10b. Then log M a and log N b. Consider MN 10a 10b 10a b Take common logarithm on both sides. ∴ log (MN) a b log M log N M 10a Consider b 10a b Consider M n (10a)n N 10 10na M ∴ log M n na n log M ∴ log a b log M log N N P. 15 5.2 Logarithmic Functions B. Basic Properties of Common Logarithm Example 5.6T Evaluate the following expressions. 2 log 25 3 (a) log 5 log 80 (b) log 8 2 Solution: (a) 3 3 1 log 5 log 80 log 5 log80 2 2 2 1 (3 log 5 log80) 2 Since 3 log 5 log 80 log 53 log 80 log (53 80) log 10 000 4 3 ∴ log 5 log 80 2 2 P. 16 5.2 Logarithmic Functions B. Basic Properties of Common Logarithm Example 5.6T Evaluate the following expressions. 2 log 25 3 (a) log 5 log 80 (b) log 8 2 Solution: 2 log 25 log 100 log 25 (b) log 8 log 8 100 log 25 log 8 log 4 log 8 log 22 3 log 2 2 2 log 2 3 log 2 2 4 3 P. 17 5.2 Logarithmic Functions B. Basic Properties of Common Logarithm Example 5.7T 4 log x5 Simplify , where x 0. 3 3 log x log x Solution: 4(5) log x 4 log x5 log x3 log 3 x 3 log x 1 log x 3 20 log x 10 log x 3 6 P. 18 5.2 Logarithmic Functions B. Basic Properties of Common Logarithm Example 5.8T If log 3 a and log 5 b, express the following in terms of a and b. (a) log 225 (b) log 18 Solution: (a) log 225 log (32 52) (b) log 32 log 52 2 log 3 2 log 5 2a 2b log 18 log (2 32) log 2 log 32 10 log 2 log 3 5 log 10 log 5 2 log 3 1 b 2a P. 19 5.2 Logarithmic Functions C. Other Types of Logarithmic Functions We have learnt the logarithmic function with base 10 (i.e. common logarithm). For logarithmic functions with bases other than 10, such as the function f (x) loga x for x 0, a 0 and a 1, they still have the following properties: For M, N, a 0 and a 1, 1. loga a 1 2. loga 1 0 3. loga (MN) loga M loga N M 4. loga loga M loga N N 5. loga M n n loga M P. 20 5.2 Logarithmic Functions C. Other Types of Logarithmic Functions Example 5.9T 1 Evaluate log2 24 log2 6 . 2 Solution: log2 1 24 log2 6 log2 24 log2 6 2 24 log2 6 log2 4 log 2 2 1 P. 21 5.2 Logarithmic Functions D. Change of Base Formula A calculator can only be used to find the values of common logarithm. For logarithmic functions with bases other than 10, we need to use the change of base formula to transform the original logarithm into common logarithm: Change of Base Formula For any positive numbers a and M with a 1, we have log M loga M . log a Let y loga M, then we have a y M. log a y log M y log a log M log M y log a Take common logarithm on both sides. P. 22 5.2 Logarithmic Functions D. Change of Base Formula In fact, besides common logarithm, the change of base formula can also be applied for logarithms with bases other than 10. Change of Base Formula For any positive numbers a, b and M with a, b 1, we have logb M . loga M logb a P. 23 5.2 Logarithmic Functions D. Change of Base Formula Example 5.10T Solve the equation logx 1 8 25. (Give the answer correct to 3 significant figures.) Solution: logx 1 8 25 log 8 25 log ( x 1) log 8 log (x 1) 25 0.03612 x 1 1.08673 x 0.0867 (cor. to 3 sig. fig.) P. 24 5.2 Logarithmic Functions D. Change of Base Formula Example 5.11T Show that log8 x 2 log4 x, where x 0. 3 Solution: log8 x log4 x log4 8 log4 x log4 3 42 log4 x 3 log4 4 2 2 log4 x 3 P. 25 5.3 Using Logarithms to Solve Equations A. Logarithmic Equations Logarithmic equations are equations containing the logarithm of one or more variables. For example: log x 2 log5 (x 2) 1 We need to use the definition and the properties of logarithm to solve logarithmic equations. For example: If loga x 2, then x a2 . P. 26 5.3 Using Logarithms to Solve Equations A. Logarithmic Equations Example 5.12T Solve the equation log3 (x 7) log3 (x 1) 2. Solution: log3 (x 7) log3 (x 1) 2 x 7 log3 2 x 1 x7 32 x 1 x 7 9x 9 x 2 P. 27 5.3 Using Logarithms to Solve Equations A. Logarithmic Equations Example 5.13T Solve the equation log x2 log 4x log (x 1). Solution: log x2 log 4x log (x 1) log 4x(x 1) log (4x2 4x) x2 4x2 4x 3x2 4x 0 x(3x 4) 0 4 x or 0 (rejected) 3 When x 0, log x2 log 0, log 4x log 0 and log (x 1) log (1), which are undefined. So we have to reject the solution of x 0. P. 28 5.3 Using Logarithms to Solve Equations B. Exponential Equations Exponential equations are equations in the form ax b, where a and b are non-zero constants and a 1. To solve ax b: ax b log ax log b x log a log b Take common logarithm on both sides. The equation is reduced to linear form. log b ∴ x log a P. 29 5.3 Using Logarithms to Solve Equations B. Exponential Equations Example 5.14T Solve the equation 5x 3 8x 1. (Give the answer correct to 2 decimal places.) Solution: 5x 3 8x 1 log 5x 3 log 8x 1 (x 3) log 5 (x 1) log 8 x(log 5 log 8) 3 log 5 log 8 3 log 5 log 8 log 5 log 8 14.70 (cor. to 2 d. p.) x P. 30 5.4 Graphs of Exponential and Logarithmic Functions A. Graphs of Exponential Functions For a 0 and a 1, a function y ax is called an exponential function, where a is the base and x is the exponent. Consider the exponential function y 2x. x –1 y 0.5 0 1 1 2 2 4 3 8 1 y 2 x y2 x 4 5 16 32 The domain of the function is all real numbers. y 0 for all real values of x. x 1 Also plot the function y : 2 x y –5 –4 –3 –2 –1 32 16 8 4 2 0 1 1 0.5 The graphs are reflectionally symmetric about the y-axis. y-intercept 1 P. 31 5.4 Graphs of Exponential and Logarithmic Functions A. Graphs of Exponential Functions Properties of the graphs of exponential functions: 1. The domain of exponential function is the set of all real numbers. 2. The graph does not cut the x-axis, that is, y 0 for all real values of x. 3. The y-intercept is 1. x 1 4. The graphs of y ax and y are reflectionally a symmetric about the y-axis. 5. For the graph of y ax, (a) if a 1, then y increases as x increases. (b) if 0 a 1, then y decreases as x increases. Notes: Property 4 can be proved algebraically. The graphs of y f (x) and y g(x) are reflectionally symmetric about the y-axis if g(x) f (x). P. 32 5.4 Graphs of Exponential and Logarithmic Functions A. Graphs of Exponential Functions Consider the graphs of y 2x and y 3x. x y –1 0.5 0 1 1 2 2 4 3 8 4 16 x y –1 0.33 0 1 1 3 2 9 3 27 4 81 y3 x The graph y 3x increases more rapidly. x 1 Consider the graphs of y and 2 x 1 y . Which graph decreases more 3 rapidly? P. 33 y2 x 5.4 Graphs of Exponential and Logarithmic Functions A. Graphs of Exponential Functions Properties of the graphs of exponential functions: For the graphs of y ax and y bx, where a, b, x 0, (i) If a b 1, then the graph of y ax increases more rapidly as x increases; (ii) If 1 b a, then the graph of y ax decreases more rapidly as x increases. P. 34 5.4 Graphs of Exponential and Logarithmic Functions B. Graphs of Logarithmic Functions Consider the graphs of y log2 x and y log1 x. 2 x 0.5 y –1 1 0 2 1 4 2 8 3 16 4 x 0.5 y 1 1 0 2 4 8 16 –1 –2 –3 –4 x-intercept 1 The domain of the function is all positive real numbers. The graphs are reflectionally symmetric about the x-axis. P. 35 5.4 Graphs of Exponential and Logarithmic Functions B. Graphs of Logarithmic Functions Properties of the graphs of logarithmic functions: 1. The domain of logarithmic function is the set of all positive real numbers, i.e., undefined for x 0. 2. The graph does not cut the y-axis, (that is, x 0 for all real values of y). 3. The x-intercept is 1. 4. The graphs of y loga x and y log1 x, where a 0 are a reflectionally symmetric about the x-axis. 5. For the graph of y loga x, (a) if a 1, then y increases as x increases. (b) if 0 a 1, then y decreases as x increases. P. 36 5.4 Graphs of Exponential and Logarithmic Functions B. Graphs of Logarithmic Functions Consider the graph of y log2 x. If a positive value of x is given, then the corresponding value of y can be found by the graphical method. e.g., when x 7, y 2.8. by the algebraic method. e.g., when x 7, y log2 7 log 7 2.8 log 2 If a value of y is given: Graphical method e.g., when y 1.6, x 3.0. Algebraic method e.g., when y 1.6, 1.6 log2 x 21.6 x x 3.0 Given a value of y, then x 2y. dependent variable independent variable inverse function ∴ f (x) 2x f (x) log2 x P. 37 5.4 Graphs of Exponential and Logarithmic Functions C. Relationship between the Graphs of Exponential and Logarithmic Functions Consider the graphs of y 2x and y log2 x. yx Each of the functions f (x) 2x and y log2 x is the inverse function of each other. The graphs of y 2x and y log2 x are reflectional images of each other about the line y x. P. 38 5.4 Graphs of Exponential and Logarithmic Functions D. Transformations on the Graphs of Exponential and Logarithmic Functions In Chapter 4, we learnt about the transformations of the graphs of functions. We can also transform logarithmic functions and exponential functions. For example: Let f (x) log2 x and g(x) log2 x 2. y log x 2 ∴ y f (x) is translated 2 units upwards to become y g(x). 2 However, we have to pay attention to the properties of logarithmic functions such as loga (MN) loga M loga N. For example: If h(x) log2 4x, then it is the same as g(x): log2 4x log2 4 log2 x 2 log2 x P. 39 5.4 Graphs of Exponential and Logarithmic Functions D. Transformations on the Graphs of Exponential and Logarithmic Functions Example 5.15T The following figure shows the graph of y log2 x. Use the graph to sketch the graphs of the following functions: 1 2 (a) y log2 x (b) y log2 4 x Solution: 1 (a) Since y log2 x 4 1 log2 x log2 4 log2 x – 2 ∴ y log2 1 x 4 1 the graph of y log2 x is obtained by translating the 4 graph of y log2 x two units downwards. P. 40 5.4 Graphs of Exponential and Logarithmic Functions D. Transformations on the Graphs of Exponential and Logarithmic Functions Example 5.15T The following figure shows the graph of y log2 x. Use the graph to sketch the graphs of the following functions: 1 2 (a) y log2 x (b) y log2 4 x Solution: 2 x log2 2 – log2 x 1 – log2 x i.e., y –log2 x 1. (b) Since y log2 ∴ y log2 2 x 2 is obtained by reflecting the graph of x y log2 x about the x-axis, then translating one unit upwards. The graph of y log2 P. 41 5.4 Graphs of Exponential and Logarithmic Functions D. Transformations on the Graphs of Exponential and Logarithmic Functions Example 5.16T The following figure shows the graph of y 2x. Use the graph to sketch the graphs of the following functions: (a) y 2x 2 (b) y 2x Solution: (a) Let f (x) 2x, g(x) 2x 2. y 2x + 2 ∵ g(x) f (x 2) ∴ the graph of y 2x 2 is obtained by translating the graph of y 2x two units to the left. P. 42 5.4 Graphs of Exponential and Logarithmic Functions D. Transformations on the Graphs of Exponential and Logarithmic Functions Example 5.16T The following figure shows the graph of y 2x. Use the graph to sketch the graphs of the following functions: (a) y 2x 2 (b) y 2x Solution: y 2x (b) Let f (x) 2x, h(x) 2x. ∵ h(x) f (–x) ∴ the graph of y 2x is obtained by reflecting the graph of y 2x about the y-axis. P. 43 5.5 Applications of Logarithms (a) Loudness of Sound Decibel (dB): unit for measuring the loudness L of sound: L 10 log I I0 where I is the intensity of sound and I0 ( 1012 W/m2) is the threshold of hearing (minimum audible sound intensity) for a normal person. For example: Given that I 103 W/m2. 103 ∴ Loudness of sound 10 log 12 dB 10 10 log 109 dB 10(9) dB 90 dB W/m2 is the unit of the sound intensity used in Physics, which represents ‘watt per square metre’. P. 44 5.5 Applications of Logarithms Sound intensity of 1 W/m2 is large enough to cause damage to our audition (hearing): 1 Loudness of sound 10 log 12 dB 10 10 log 1012 dB 10(12) dB 120 dB which is about the loudness of airplane’s engine. Loudness 20 dB 30 dB 40 dB 50 dB 60 dB 80 dB 100 dB 120 dB Example Camera shutter A silent park A silent class An office with typical sound A conversation between two people one metre apart MTR platform Motor car’s horn Plane’s engine P. 45 5.5 Applications of Logarithms Example 5.17T If one person makes noise of 80 dB and another makes noise of 100 dB, then what is the ratio of the sound intensities made by the two people? Solution: Let I80 and I100 be the sound intensities made by the two people respectively. I 80 I 80 I 80 8 80 10 log log 8 10 I I0 I0 0 I I I 100 10 log 100 log 100 10 100 1010 I 0 I0 I0 I 80 108 I 0 10 I100 10 I 0 We can express each of the sound intensities I80 and I100 ∴ I80 : I100 108I0 : 1010I0 in terms of I0. 1 : 100 P. 46 5.5 Applications of Logarithms (b) Richter Scale The Richter scale R is a scale used to measure the magnitude of an earthquake: log E 4.8 1.5R where E is the energy released from an earthquake, measured in joules (J). Remarks: Examples of serious earthquakes on Earth: date: May 12, 2008 magnitude: 8.0 location: Sichuan province of China date: Dec 26, 2004 magnitude: 9.0 location: Indian Ocean date: May 22, 1960 magnitude: 9.5 location: Chile The Richter scale was developed by an American scientist, Charles Richter. P. 47 5.5 Applications of Logarithms Example 5.18T The most serious earthquake occurred in China was the Tangshan earthquake, which occurred on July 28, 1976. It was recorded as having the magnitude of 8.7 on the Richter scale. Compare the energy released by that earthquake with Taiwan’s 9-21 earthquake with a magnitude of 7.3 on the Richter scale in 1999. Solution: Since log E 4.8 1.5R, E 104.8 1.5R. You may notice that for earthquakes with a difference 104.8 1.5(8.7 ) 1.5(8.7 – 7.3) in magnitude of 1.4 on the 4.8 1.5( 7.3) 10 Richter scale, their energy 10 2.1 released is almost 125 times 10 greater. 126 ∴ The energy released by the Tangshan earthquake was 126 times that of Taiwan’s earthquake. P. 48 Chapter Summary 5.1 Rational Indices Laws of Indices For a, b 0, 1. am an am n 2. am an am n 3. (am)n amn 4. (ab)m ambm 5. am a m b b m 6. 1 an n a 7. m an n am P. 49 Chapter Summary 5.2 Logarithmic Functions If y ax, then loga y x, where a 0 and a 1. For base 10, we may write log y instead of log10 y. Properties of Logarithm For any positive numbers a, b, M and N with a, b 1, 1. loga a 1 2. loga 1 0 3. loga (MN) loga M loga N M 4. loga loga M loga N N 5. loga M n n loga M 6. loga M logb M logb a P. 50 Chapter Summary 5.3 Using Logarithms to Solve Equations By using the properties of logarithm, we can solve the logarithmic equations and exponential equations. P. 51 Chapter Summary 5.4 Graphs of Exponential and Logarithmic Functions x 1. 2. 1 The graphs of y a and y are reflectionally symmetric a about the y-axis. x The graphs of y loga x and y log1 x are reflectionally symmetric a about the x-axis. 3. The graphs of y ax and y loga x are symmetric about the line y x. P. 52 Chapter Summary 5.5 Applications of Logarithms Daily-life applications of logarithms: 1. Measurement of loudness of sound in decibels (dB) 2. Measurement of magnitude of an earthquake on the Richter scale P. 53