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Chapter 7: Logarithmic and exponential functions

Section 7.4: integration

Theorem 7.25: (i) integral of tanu du=-ln|cosu| + C (ii) integral of cotu du=ln|sinu| + C (iii) integral of secu du=ln|secu + tanu| + C (iv) integral of cscu du= ln|cscu - cotu| + C

Theorem 7.24: If u=g(x) and g is differentiable, then integral of e^u^ du=e^u^ + C

Theorem 7.23: If u=g(x)=/=0 and g is differentiable, then integral of 1/u du= ln|u| + C

Section 7.3: natural exponential funtion

If u=g(x) and g is differentiable, then Dx e^u^= e^u^ Dxu

Theroem 7.20: If p and q are real numbers and r is a rational number, then (i) e^p^e^q^=e^p+q^ (ii) e^p^/e^q^=e^p^-e^q^ (iii)(e^p^)^r^=e^pr^

Theorem 7.19: (i) lne^x^=x for every x (ii)e^lnx^=x for every x>0

Definition of e^x^: if x is a real number, then e^x^=y iff lny=x

Approximation to e: e~=2.71828

Section 7.2: natural logarithmic function

Guidelines for Logarithmic differentiation: 1) y=f(x) 2) lny=lnf(x) 3) Dx[lny]=Dx[lnf(x)] 4)1/y Dxy=Dx[lnf(x)] 5) Dxy=f(x) Dx [lnf(x)]

Laws of ln: if p>0 and q>0, then (i) lnpq=lnp+lnq (ii) lnp/q=lnp-lnq (iii) lnp^r^=rlnp for every rational # r

Theorem 7.11: if u=g(x) & g is differentiable, then (i) Dx lnu=1/u Dxu if g(x)>0 (ii) Dx ln|u|= 1/u Dxu if g(x)=/=0

Theorem 7.10: Dx lnx= 1/x

Definition 7.9: Natural logarithmic funtion, denoted by ln, is defined by lnx=intergral (from 1 to x) of 1/t dt for every x>0

Section 7.1: inverse functions

Corollary 7.8: If g is the inverse of a differentiable funtion f and if f'(g(x))=/=0 then g'(x)=1/f'(g(x))

Theorem 7.7: If a differntiable function f has an inverse function g=f^-1^ & if f '(g(c))=/=0, then g is differntiable at c and g'(c)=1/f'(g(c))

Theorem 7.6: If f is continuous & increasing on [a,b], then f has an inverse function f^-1^ that is continous on [f(a), f(b)]

Domains and ranges of f & f^-1^: D of f^-1^= R of f R of f^-1^= D of f

Theorem 7.3: Let f be a one-to-one function with domain D and range R. if g is a funciton with domain R and range D, then g is the inverse function of f iff both of the followin holds ture: (i) g(f(x))=x for all x in D (ii) f(g(y))=y for all y in R

Definition 7.2: let f be a one-to-one funcition with domain D & range R. A function g with domain R and range D is the inverse function of f provided; y=f(x) in R iff x=g(y) in D

Definiton 7.1: A function f with domaiain D & range R is a One-to-one fucntion if whenever a =/= b in D, then f(a) =/= f(b) in R.