Uploaded byMohamedRamadan454985
PPSX, PDF226 views

Exponential & Logarithmic Functions--.ppsx

1. The document discusses exponential and logarithmic functions, including: defining them, understanding their inverse relationship, and how they can model real-world situations like population growth. 2. It provides examples of exponential growth and decay functions, defines the important constant e, and covers the basic properties and graphs of exponential and logarithmic functions. 3. The document also discusses taking derivatives of exponential and logarithmic functions, using rules like the power rule, exponential rule, and logarithmic rule.

Embed presentation

Downloaded 10 times
Exponential & Logarithmic Functions
Learning Objectives • Upon completing this module, you should be able to: 1. Define Logarithmic and Exponential functions . 2. Understand the inverse relation between Logarithmic and Exponential functions. 3. Know that Logarithmic and Exponential functions can be used to model a variety of real world situations. 4. Use the properties of logarithms and exponents for rewriting expressions and solving equations, and graphing functions 5. Find the derivatives of Logarithmic and Exponential functions .
• Population growth is a classic example – Geometric growth … 1 2 4 8 16 32 64 t = 0 1 2 3 4 5 6
Population Size vs. time 0 10 20 30 40 50 60 70 0 1 2 3 4 5 6 7 Time (t) Population Size (N)
Exponentials f(x) = ax, a > 0 a > 1 exponential increase 0 < a < 1 exponential decrease As x becomes very negative, f(x) gets close to zero As x becomes very positive, f(x) gets close to zero
• f(x) = ax is one-to-one. For every x value there is a unique value of f(x). • This implies that f(x) = ax has an inverse. • f-1(x) = logax, logarithm base a of x.
-4 -2 0 2 4 6 8 -6 -4 -2 0 2 4 6 8 f(x) = ax f(x) = logax
• logax is the power to which a must be raised to get x. • y = logax is equivalent to ay = x • f(f-1(x)) = alogax = x, for x > 0 • f-1(f(x)) = logaax = x, for all x. • There are two common forms of the log fn. – a = 10, log10x, commonly written a simply log x – a = e = 2.71828…, logex = ln x, natural log. • logax does not exist for x ≤ 0.
PROPERTIES OF EXPONENTIAL FUNCTIONS Let f (x) = ax, a > 0 , a ≠ 1. 1. The domain of f (x) = ax is (–∞, ∞). 2. The range of f (x) = ax is (0, ∞); the entire graph lies above the x-axis. 3. For a > 1, Exponential Growth (i) f is an increasing function, so the graph rises to the right. (ii) as x → ∞, y → ∞. (iii) as x → –∞, y → 0.
4. For 0 < a < 1, - Exponential Decay (i) f is a decreasing function, so the graph falls to the right. (ii) as x → – ∞, y → ∞. (iii) as x → ∞, y → 0. 5. The graph of f (x) = ax has no x-intercepts, so it never crosses the x-axis. No value of x will cause f (x) = ax to equal 0.
THE VALUE OF e The value of e to 15 places is e = 2.718281828459045. gets closer and closer to a fixed number. This irrational number is denoted by e and is sometimes called the Euler number. As n gets larger and larger, 1 1 n n       
• Or   1 0 1 lim 1 lim 1 x x x x e x x               1 1 x x  x 2.59374246 2.70481384 2.71692393 2.71814593 2.71828047 2.71828169 e  0.1 0.01 0.001 0.0001 0.00001 0.000001 0 
Properties of Exponents  am  an  am n  am an  amn (am )n  amn  (a  b)m  am  bm a b       m  am bm  a0 1  an  1 an  1 an  an  a b       n  b a       n a m n  am n OR
x = loga b ax = b base
15 Definition: b a x b x a    log 8 2 3 8 log 3 2   because
Rules of Logarithms with Base a If M, N, and a are positive real numbers with a ≠ 1, and x is any real number, then 1. loga(a) = 1 2. loga(1) = 0 3. loga(ax) = x 4. 5. loga(MN) = loga(M) + loga(N) 6. loga(M/N) = loga(M) – loga(N) 7. loga(Mx) = x · loga(M) 8. loga(1/N) = – loga(N) N a N a  ) ( log Rules of Logarithms These relationships are used to solve exponential or logarithmic equations
Changing the base of a logarithm lo gac = x → c ≡ ax so logbc ≡ logbax ≡ x·logba
Therefore or a log c log x b b  a log c log c log b b a  log log 1 b a a b 
COMMON LOGARITHMS 1. log 10 = 1 2. log 1 = 0 3. log 10x = x 4. 10log x  x The logarithm with base 10 is called the common logarithm and is denoted by omitting the base: log x = log10 x. Thus, y = log x if and only if x = 10 y. Applying the basic properties of logarithms
NATURAL LOGARITHMS 1. ln e = 1 2. ln 1 = 0 3. log ex = x 4. eln x  x The logarithm with base e is called the natural logarithm and is denoted by ln x. That is, ln x = loge x. Thus, y = ln x if and only if x = e y. Applying the basic properties of logarithms
MODEL FOR EXPONENTIAL GROWTH OR DECAY   0 kt A t A e  A(t) = amount at time t A0 = A(0), the initial amount k = relative rate of growth (k > 0) or decay (k < 0) t = time
• Example: Radioactive decay A radioactive material decays according to the law N(t)=5e-0.4t 0 1 2 3 4 5 6 0 2 4 6 8 10 Time t (months) Number of grams N months 023 . 4 ) 4 . 0 /( 6909 . 1 t ) 4 . 0 )/( 2 . 0 ( ln t t 4 . 0 ) 2 . 0 ( ln ) (e ln ) 2 . 0 ( ln e 5 / 1 e 5 1 t 4 . 0 t 4 . 0 t 4 . 0               When does N = 1? For what value of t does N = 1?
DOMAIN OF LOGARITHMIC FUNCTION Domain of y = loga x is (0, ∞) Range of y = loga x is (–∞, ∞) Logarithms of 0 and negative numbers are not defined.
GRAPHS OF LOGARITHMIC FUNCTIONS
Derivatives Memorize dx du e e dx d u u   dx du a a a dx d u u   ln ) ( dx du u u dx d   1 ln dx du nu u dx d n n 1   dx du a u u dx d a   ln 1 log
27 Examples. f (x) = 5 ln x. f (x) = x5 ln x. Note: We need the product rule. (x 5 )(1/x) + (ln x)(5x 4 ) f ‘ (x) = (5)(1/x) = 5/x f ‘ (x) = = x 4 + (ln x)(5x 4) For you: Find dy/dx for y = x x
28 Examples. f (x) = ln (x 4 + 5) f (x) = 4 ln √x f ‘ (x) = ) 5 x ( dx d 5 x 1 4 4   f ‘ (x) = 4 3 1 x 5 4x   2 1 x 1 4 ) x ( ' f  x 2  = 4 ln x 1/2 5 x x 4 4 3   x ln 2  1 2 1 x 2 
29 Example.  ) x ( ' f   1 x 3 x 2 3 e ) x ( f      3 2 x 3x 1 2 (3x 6x f '( e ) x)       ) 1 x 3 x ( dx d e 2 3 1 x 3 x 2 3    
Differentiating Logarithmic Expressions EXAMPLE SOLUTION Differentiate.              1 4 2 1 ln 3 2 x x x x This is the given expression.              1 4 2 1 ln 3 2 x x x x         1 4 ln 2 1 ln 3 2     x x x x       1 4 ln 2 ln 1 ln ln 3 2       x x x x       1 4 ln 2 ln 3 1 ln 2 ln 2 1       x x x x Differentiate.                  1 4 ln 2 ln 3 1 ln 2 ln 2 1 x x x x dx d
Differentiating Logarithmic Expressions Distribute. CONTINUED             1 4 ln 2 ln 3 1 ln 2 ln 2 1             x dx d x dx d x dx d x dx d Finish differentiating. 4 1 4 1 2 1 3 1 1 2 1 2 1         x x x x Simplify. 1 4 4 2 3 1 2 2 1       x x x x
32 General Derivative Rules Power Rule General Power Rule General Exponential Derivative Rule 1 n n x n x dx d   ' u u n u dx d 1 n n   Exponential Rule x x e e dx d  ' u e e dx d u u  Log Rule x 1 x ln dx d  General Log Derivative Rule ' u u 1 u ln dx d 

More Related Content

PPTX
Trigonometric Ratios and Functions 2.pptx
byMarjorie Malveda
 
PPTX
CMSC 56 | Lecture 16: Equivalence of Relations & Partial Ordering
byallyn joy calcaben
 
PPTX
10 3 double and half-angle formulas
byhisema01
 
DOC
Mathematics 8 Linear Functions
byJuan Miguel Palero
 
PPTX
Function and their graphs ppt
byFarhana Shaheen
 
PPT
unit_circle_lesson_in trigonometric functions
byramfreecs13
 
PPT
Section 3.3 quadratic functions and their properties
byWong Hsiung
 
PPTX
Arcs and angles of circles
byMartinGeraldine
 
Trigonometric Ratios and Functions 2.pptx
byMarjorie Malveda
 
CMSC 56 | Lecture 16: Equivalence of Relations & Partial Ordering
byallyn joy calcaben
 
10 3 double and half-angle formulas
byhisema01
 
Mathematics 8 Linear Functions
byJuan Miguel Palero
 
Function and their graphs ppt
byFarhana Shaheen
 
unit_circle_lesson_in trigonometric functions
byramfreecs13
 
Section 3.3 quadratic functions and their properties
byWong Hsiung
 
Arcs and angles of circles
byMartinGeraldine
 

What's hot

PPT
Radian and degree measure.
byKiran S B
 
PPSX
Introduction to Function, Domain and Range - Mohd Noor
byMohd. Noor Abdul Hamid
 
PPT
Unit circle
bykristinmiller929
 
PPT
Special Right Triangles
byFidelfo Moral
 
PDF
Lesson 16: Inverse Trigonometric Functions (slides)
byMatthew Leingang
 
PPTX
Zeros of a polynomial function
byMartinGeraldine
 
PPTX
Integration by partial fraction
byAyesha Ch
 
PPTX
Quadratic equations
byLenie Zapata
 
ODP
Factorials
byteamxxlp
 
PPTX
Inverse Function.pptx
bySerGeo5
 
PPTX
Lesson 1 - Introduction to Limits.pptx
byLoryMaeAlcosaba
 
PPT
Section 6.3 properties of the trigonometric functions
byWong Hsiung
 
PPT
mathematical induction
byankush_kumar
 
PDF
3.4 Composition of Functions
bysmiller5
 
PPT
Properties of logarithms
byJessica Garcia
 
PDF
2.5.2 Isosceles and Equilateral Triangles
bysmiller5
 
PPTX
Composition and inverse of functions
byCharliez Jane Soriano
 
PPT
Graphs of trigonometry functions
bylgemgnani
 
PDF
Differential Equation
byV.M. Raut Shri Shivaji Science College, Amravati
 
PPT
Trigonometric identities
byVinisha Pathak
 
Radian and degree measure.
byKiran S B
 
Introduction to Function, Domain and Range - Mohd Noor
byMohd. Noor Abdul Hamid
 
Unit circle
bykristinmiller929
 
Special Right Triangles
byFidelfo Moral
 
Lesson 16: Inverse Trigonometric Functions (slides)
byMatthew Leingang
 
Zeros of a polynomial function
byMartinGeraldine
 
Integration by partial fraction
byAyesha Ch
 
Quadratic equations
byLenie Zapata
 
Factorials
byteamxxlp
 
Inverse Function.pptx
bySerGeo5
 
Lesson 1 - Introduction to Limits.pptx
byLoryMaeAlcosaba
 
Section 6.3 properties of the trigonometric functions
byWong Hsiung
 
mathematical induction
byankush_kumar
 
3.4 Composition of Functions
bysmiller5
 
Properties of logarithms
byJessica Garcia
 
2.5.2 Isosceles and Equilateral Triangles
bysmiller5
 
Composition and inverse of functions
byCharliez Jane Soriano
 
Graphs of trigonometry functions
bylgemgnani
 
Differential Equation
byV.M. Raut Shri Shivaji Science College, Amravati
 
Trigonometric identities
byVinisha Pathak
 

Similar to Exponential & Logarithmic Functions--.ppsx

PPTX
Exponential and Logarithmic Functions Functions
byakuntansiibn
 
PPTX
Ch 4 Exponential and Logarithmic Functions
byakuntansiibn
 
PPT
chapter3.ppt
byJudieLeeTandog1
 
PPTX
Math12 lesson11
bydylanxclusive
 
PPTX
Math12 lesson11
byKathManarang
 
PPTX
Exponential and logrithmic functions
byMalikahmad105
 
PPT
Chapter4 exponentialandlogarithmicfunctions-151003150209-lva1-app6891
byCleophas Rwemera
 
PPT
Introductory maths analysis chapter 04 official
byEvert Sandye Taasiringan
 
PPT
Chapter 4 - Exponential and Logarithmic Functions
byMuhammad Bilal Khairuddin
 
PPTX
Algebra 2 06 Exponential and Logarithmic Functions 2.pptx
byPallaviGupta66118
 
PPT
Exponents and Logs
byNeil MacIntosh
 
PPTX
exponentialandlogarithmicfunctions-140306230640-phpapp01.pptx
byarmandoranido24
 
PPTX
Exponential and logarithmic functions
byNjabulo Nkabinde
 
PPT
Math130 ch09
byPutrace
 
PDF
Module 4 exponential and logarithmic functions
bydionesioable
 
PDF
Chapter 3 exponential and logarithmic functions
bySarah Sue Calbio
 
PPT
Business Math Chapter 2
byNazrin Nazdri
 
PPTX
4.4 the logarithm functions t
bymath260
 
DOCX
WEEK-9.docx
byAmieDCandelaria
 
PPTX
PPT _1 Week 33 dated 04-11-2023 logarithm Function.pptx
byByronJimenez19
 
Exponential and Logarithmic Functions Functions
byakuntansiibn
 
Ch 4 Exponential and Logarithmic Functions
byakuntansiibn
 
chapter3.ppt
byJudieLeeTandog1
 
Math12 lesson11
bydylanxclusive
 
Math12 lesson11
byKathManarang
 
Exponential and logrithmic functions
byMalikahmad105
 
Chapter4 exponentialandlogarithmicfunctions-151003150209-lva1-app6891
byCleophas Rwemera
 
Introductory maths analysis chapter 04 official
byEvert Sandye Taasiringan
 
Chapter 4 - Exponential and Logarithmic Functions
byMuhammad Bilal Khairuddin
 
Algebra 2 06 Exponential and Logarithmic Functions 2.pptx
byPallaviGupta66118
 
Exponents and Logs
byNeil MacIntosh
 
exponentialandlogarithmicfunctions-140306230640-phpapp01.pptx
byarmandoranido24
 
Exponential and logarithmic functions
byNjabulo Nkabinde
 
Math130 ch09
byPutrace
 
Module 4 exponential and logarithmic functions
bydionesioable
 
Chapter 3 exponential and logarithmic functions
bySarah Sue Calbio
 
Business Math Chapter 2
byNazrin Nazdri
 
4.4 the logarithm functions t
bymath260
 
WEEK-9.docx
byAmieDCandelaria
 
PPT _1 Week 33 dated 04-11-2023 logarithm Function.pptx
byByronJimenez19
 

Recently uploaded

PDF
International Men's Day Event: Breaking the Silence: Embracing Vulnerability ...
byAssociation for Project Management
 
PDF
The voice of the rain poem class 11th.pdf
byReeta Baral
 
PDF
Types of eggs and Egg membranes (Developmental Zoology)
bySudhandraKarthi
 
PPTX
META-ANALYSIS INTERPRETATION, PUBLICATION BIAS AND GRADE ASSESSMENT.pptx
bySystematic Reviews Network (SRN)
 
PDF
Madhumathi Endowment Quiz Finals by Sreejesh P S and Shyam Krishnan P - Keral...
bySreejesh P S
 
PPTX
cis.jackson.alaysia.ResearchPresentation 1.Microsoft Teams vs Zoom vs Webex v...
byMerritt College
 
PPTX
How to Access Revenue Report in Odoo 18 Events
byCeline George
 
PPTX
PARENTAL ROUTES OF DRUGS ADMINISTRATION .pptx
byAneetaSharma15
 
PPTX
Multiple Linear Regression - Least Square Method X₁ on X₂ and X₃
bySundar B N
 
PPTX
Introduction-to-Anatomy-and-Physiology.pptx
byAshish Umale
 
PPTX
GROWTH & DEVELOPMENT MILESTONES (INFANTS).pptx
byAneetaSharma15
 
PPTX
Planning Assessment for Outcome-based Education
byAdri Jovin
 
PPTX
Partial Correlation of Coefficient - Values of r₁₂.₃, r₂₃.₁ & r₁₃.₂
bySundar B N
 
PDF
SIHMA Scalabrini Institute for Human Mobility in Africa(SIHMA) - Annual Repor...
byScalabrini Institute for Human Mobility in Africa
 
PPTX
How to Track a Link Using Odoo 18 SMS Marketing
byCeline George
 
PDF
Advanced Process Flow and Micromachining Techniques for MEMS Fabrication: A D...
byGS Virdi
 
PPTX
ATTENTION -PART 2.pptx Shilpa Hotakar for I semester BSc students
bySHILPA HOTAKAR
 
PPTX
ORAL & SUBLINGUAL ROUTE OF DRUGS ADMINISTRATION.pptx
byAneetaSharma15
 
PPTX
Multiple Correlation - Introduction, Meaning, Examples, Options, Formulas and...
bySundar B N
 
PPTX
Expected Revenue Report In Odoo 18 CRM
byCeline George
 
International Men's Day Event: Breaking the Silence: Embracing Vulnerability ...
byAssociation for Project Management
 
The voice of the rain poem class 11th.pdf
byReeta Baral
 
Types of eggs and Egg membranes (Developmental Zoology)
bySudhandraKarthi
 
META-ANALYSIS INTERPRETATION, PUBLICATION BIAS AND GRADE ASSESSMENT.pptx
bySystematic Reviews Network (SRN)
 
Madhumathi Endowment Quiz Finals by Sreejesh P S and Shyam Krishnan P - Keral...
bySreejesh P S
 
cis.jackson.alaysia.ResearchPresentation 1.Microsoft Teams vs Zoom vs Webex v...
byMerritt College
 
How to Access Revenue Report in Odoo 18 Events
byCeline George
 
PARENTAL ROUTES OF DRUGS ADMINISTRATION .pptx
byAneetaSharma15
 
Multiple Linear Regression - Least Square Method X₁ on X₂ and X₃
bySundar B N
 
Introduction-to-Anatomy-and-Physiology.pptx
byAshish Umale
 
GROWTH & DEVELOPMENT MILESTONES (INFANTS).pptx
byAneetaSharma15
 
Planning Assessment for Outcome-based Education
byAdri Jovin
 
Partial Correlation of Coefficient - Values of r₁₂.₃, r₂₃.₁ & r₁₃.₂
bySundar B N
 
SIHMA Scalabrini Institute for Human Mobility in Africa(SIHMA) - Annual Repor...
byScalabrini Institute for Human Mobility in Africa
 
How to Track a Link Using Odoo 18 SMS Marketing
byCeline George
 
Advanced Process Flow and Micromachining Techniques for MEMS Fabrication: A D...
byGS Virdi
 
ATTENTION -PART 2.pptx Shilpa Hotakar for I semester BSc students
bySHILPA HOTAKAR
 
ORAL & SUBLINGUAL ROUTE OF DRUGS ADMINISTRATION.pptx
byAneetaSharma15
 
Multiple Correlation - Introduction, Meaning, Examples, Options, Formulas and...
bySundar B N
 
Expected Revenue Report In Odoo 18 CRM
byCeline George
 

Exponential & Logarithmic Functions--.ppsx

  • 1.
  • 2.
    Learning Objectives • Uponcompleting this module, you should be able to: 1. Define Logarithmic and Exponential functions . 2. Understand the inverse relation between Logarithmic and Exponential functions. 3. Know that Logarithmic and Exponential functions can be used to model a variety of real world situations. 4. Use the properties of logarithms and exponents for rewriting expressions and solving equations, and graphing functions 5. Find the derivatives of Logarithmic and Exponential functions .
  • 3.
    • Population growthis a classic example – Geometric growth … 1 2 4 8 16 32 64 t = 0 1 2 3 4 5 6
  • 4.
    Population Size vs.time 0 10 20 30 40 50 60 70 0 1 2 3 4 5 6 7 Time (t) Population Size (N)
  • 5.
    Exponentials f(x) = ax,a > 0 a > 1 exponential increase 0 < a < 1 exponential decrease As x becomes very negative, f(x) gets close to zero As x becomes very positive, f(x) gets close to zero
  • 6.
    • f(x) =ax is one-to-one. For every x value there is a unique value of f(x). • This implies that f(x) = ax has an inverse. • f-1(x) = logax, logarithm base a of x.
  • 7.
    -4 -2 0 2 4 6 8 -6 -4 -20 2 4 6 8 f(x) = ax f(x) = logax
  • 8.
    • logax isthe power to which a must be raised to get x. • y = logax is equivalent to ay = x • f(f-1(x)) = alogax = x, for x > 0 • f-1(f(x)) = logaax = x, for all x. • There are two common forms of the log fn. – a = 10, log10x, commonly written a simply log x – a = e = 2.71828…, logex = ln x, natural log. • logax does not exist for x ≤ 0.
  • 9.
    PROPERTIES OF EXPONENTIALFUNCTIONS Let f (x) = ax, a > 0 , a ≠ 1. 1. The domain of f (x) = ax is (–∞, ∞). 2. The range of f (x) = ax is (0, ∞); the entire graph lies above the x-axis. 3. For a > 1, Exponential Growth (i) f is an increasing function, so the graph rises to the right. (ii) as x → ∞, y → ∞. (iii) as x → –∞, y → 0.
  • 10.
    4. For 0< a < 1, - Exponential Decay (i) f is a decreasing function, so the graph falls to the right. (ii) as x → – ∞, y → ∞. (iii) as x → ∞, y → 0. 5. The graph of f (x) = ax has no x-intercepts, so it never crosses the x-axis. No value of x will cause f (x) = ax to equal 0.
  • 11.
    THE VALUE OFe The value of e to 15 places is e = 2.718281828459045. gets closer and closer to a fixed number. This irrational number is denoted by e and is sometimes called the Euler number. As n gets larger and larger, 1 1 n n       
  • 12.
    • Or  1 0 1 lim 1 lim 1 x x x x e x x               1 1 x x  x 2.59374246 2.70481384 2.71692393 2.71814593 2.71828047 2.71828169 e  0.1 0.01 0.001 0.0001 0.00001 0.000001 0 
  • 13.
    Properties of Exponents  am an  am n  am an  amn (am )n  amn  (a  b)m  am  bm a b       m  am bm  a0 1  an  1 an  1 an  an  a b       n  b a       n a m n  am n OR
  • 14.
    x = logab ax = b base
  • 15.
  • 16.
    Rules of Logarithmswith Base a If M, N, and a are positive real numbers with a ≠ 1, and x is any real number, then 1. loga(a) = 1 2. loga(1) = 0 3. loga(ax) = x 4. 5. loga(MN) = loga(M) + loga(N) 6. loga(M/N) = loga(M) – loga(N) 7. loga(Mx) = x · loga(M) 8. loga(1/N) = – loga(N) N a N a  ) ( log Rules of Logarithms These relationships are used to solve exponential or logarithmic equations
  • 17.
    Changing the baseof a logarithm lo gac = x → c ≡ ax so logbc ≡ logbax ≡ x·logba
  • 18.
  • 19.
    COMMON LOGARITHMS 1. log10 = 1 2. log 1 = 0 3. log 10x = x 4. 10log x  x The logarithm with base 10 is called the common logarithm and is denoted by omitting the base: log x = log10 x. Thus, y = log x if and only if x = 10 y. Applying the basic properties of logarithms
  • 20.
    NATURAL LOGARITHMS 1. lne = 1 2. ln 1 = 0 3. log ex = x 4. eln x  x The logarithm with base e is called the natural logarithm and is denoted by ln x. That is, ln x = loge x. Thus, y = ln x if and only if x = e y. Applying the basic properties of logarithms
  • 21.
    MODEL FOR EXPONENTIAL GROWTHOR DECAY   0 kt A t A e  A(t) = amount at time t A0 = A(0), the initial amount k = relative rate of growth (k > 0) or decay (k < 0) t = time
  • 22.
    • Example: Radioactivedecay A radioactive material decays according to the law N(t)=5e-0.4t 0 1 2 3 4 5 6 0 2 4 6 8 10 Time t (months) Number of grams N months 023 . 4 ) 4 . 0 /( 6909 . 1 t ) 4 . 0 )/( 2 . 0 ( ln t t 4 . 0 ) 2 . 0 ( ln ) (e ln ) 2 . 0 ( ln e 5 / 1 e 5 1 t 4 . 0 t 4 . 0 t 4 . 0               When does N = 1? For what value of t does N = 1?
  • 23.
    DOMAIN OF LOGARITHMICFUNCTION Domain of y = loga x is (0, ∞) Range of y = loga x is (–∞, ∞) Logarithms of 0 and negative numbers are not defined.
  • 24.
  • 26.
    Derivatives Memorize dx du e e dx d u u   dx du a a a dx d u u  ln ) ( dx du u u dx d   1 ln dx du nu u dx d n n 1   dx du a u u dx d a   ln 1 log
  • 27.
    27 Examples. f (x) =5 ln x. f (x) = x5 ln x. Note: We need the product rule. (x 5 )(1/x) + (ln x)(5x 4 ) f ‘ (x) = (5)(1/x) = 5/x f ‘ (x) = = x 4 + (ln x)(5x 4) For you: Find dy/dx for y = x x
  • 28.
    28 Examples. f (x) =ln (x 4 + 5) f (x) = 4 ln √x f ‘ (x) = ) 5 x ( dx d 5 x 1 4 4   f ‘ (x) = 4 3 1 x 5 4x   2 1 x 1 4 ) x ( ' f  x 2  = 4 ln x 1/2 5 x x 4 4 3   x ln 2  1 2 1 x 2 
  • 29.
    29 Example.  ) x ( ' f   1 x 3 x 2 3 e ) x ( f     3 2 x 3x 1 2 (3x 6x f '( e ) x)       ) 1 x 3 x ( dx d e 2 3 1 x 3 x 2 3    
  • 30.
    Differentiating Logarithmic Expressions EXAMPLE SOLUTION Differentiate.             1 4 2 1 ln 3 2 x x x x This is the given expression.              1 4 2 1 ln 3 2 x x x x         1 4 ln 2 1 ln 3 2     x x x x       1 4 ln 2 ln 1 ln ln 3 2       x x x x       1 4 ln 2 ln 3 1 ln 2 ln 2 1       x x x x Differentiate.                  1 4 ln 2 ln 3 1 ln 2 ln 2 1 x x x x dx d
  • 31.
    Differentiating Logarithmic Expressions Distribute. CONTINUED            1 4 ln 2 ln 3 1 ln 2 ln 2 1             x dx d x dx d x dx d x dx d Finish differentiating. 4 1 4 1 2 1 3 1 1 2 1 2 1         x x x x Simplify. 1 4 4 2 3 1 2 2 1       x x x x
  • 32.
    32 General Derivative Rules PowerRule General Power Rule General Exponential Derivative Rule 1 n n x n x dx d   ' u u n u dx d 1 n n   Exponential Rule x x e e dx d  ' u e e dx d u u  Log Rule x 1 x ln dx d  General Log Derivative Rule ' u u 1 u ln dx d 