Integral Calculus: Formulas and Theorems, Cheat Sheet of Calculus

A concise overview of integral calculus, covering topics from definite integrals and the fundamental theorem of calculus to more advanced techniques like integration by parts and partial fraction decomposition. It also includes information on improper integrals, area between curves, volumes of solids of revolution, differential equations, and series convergence tests. Structured as a reference sheet, ideal for students seeking a quick review of key concepts and formulas in calculus. It also touches on taylor series and big-o notation, offering a comprehensive summary for exam preparation or quick reference. This material is suitable for university students studying calculus or related fields, providing a solid foundation in integral calculus and its applications. (437 characters)

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Calculus 2 Notes
1 Integration
Basic Definitions and Theorems
Let x=ba
n, let xi=a+ix, let Ii= [xi1, xi]
Regular partition of [a, b] into nsubintervals: I1, I2, I3,...In
Riemann Sum:
n
P
i=1
f(x
i)∆x
Definite Integral: Zb
a
f(x) dx= lim
n→∞
n
X
i=1
f(x
i)∆x
Theorem: If f(x) is continuous or has finitely many discontinuites on [a, b],
then f(x) is integrable on [a, b]
Ln=
n
P
i=1
f(xi1)∆x, Rn=
n
P
i=1
f(xi)∆x
Properties of Integrals
Zb
a
cf(x) dx=cZb
a
f(x) dx
Zb
a
(f(x) + g(x)) dx=Zb
a
f(x) dx+Zb
a
g(x) dx
If mf(x)Mx[a, b], then m(ba)Zb
a
f(x) dxM(ba)
If f(x)g(x)x[a, b], then Zb
a
f(x) dxZb
a
g(x) dx
Zb
a
f(x) dx
Zb
a
|f(x)|dx
Separating the Domain Theorem: Zb
a
f(x) dx=Zc
a
f(x) dx+Zb
c
f(x) dx
1
pf3
pf4
pf5
pf8
pf9
pfa

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Calculus 2 Notes

1 Integration

Basic Definitions and Theorems

  • Let ∆x = b−n a, let xi = a + i∆x, let Ii = [xi− 1 , xi]
  • Regular partition of [a, b] into n subintervals: I 1 , I 2 , I 3 ,... In
  • Riemann Sum:

Pn i=

f (x∗ i )∆x

  • Definite Integral:

Z (^) b

a

f (x) dx = lim n→∞

X^ n

i=

f (x∗ i )∆x

  • Theorem: If f (x) is continuous or has finitely many discontinuites on [a, b], then f (x) is integrable on [a, b]
  • Ln =

Pn i=

f (xi− 1 )∆x, Rn =

Pn i=

f (xi)∆x

Properties of Integrals

Z (^) b

a

cf (x) dx = c

Z (^) b

a

f (x) dx

Z (^) b

a

(f (x) + g(x)) dx =

Z (^) b

a

f (x) dx +

Z (^) b

a

g(x) dx

  • If m ≤ f (x) ≤ M ∀x ∈ [a, b], then m(b − a) ≤

Z (^) b

a

f (x) dx ≤ M (b − a)

  • If f (x) ≥ g(x) ∀x ∈ [a, b], then

Z (^) b

a

f (x) dx ≥

Z (^) b

a

g(x) dx

Z (^) b

a

f (x) dx ≤

Z (^) b

a

|f (x)| dx

  • Separating the Domain Theorem:

Z (^) b

a

f (x) dx =

Z (^) c

a

f (x) dx +

Z (^) b

c

f (x) dx

  • The definite integral represents the signed area under f (x)
  • If f (x) is an odd function, then

Z (^) a

−a

f (x) dx = 0

  • If f (x) is an even function, then

Z (^) a

−a

f (x) dx = 2

Z (^) a

0

f (x) dx

Average Value

  • Average Value of f (x) on [a, b]: (^) b−^1 a

Z (^) b

a

f (x) dx

  • Average Value Theorem: If f (x) is continuous on [a, b], then there exists

c ∈ [a, b] such that f (c) = (^) b−^1 a

Z (^) b

a

f (x) dx

Antiderivatives

  • Antiderivative: F (x) is an antiderivative of f (x) if F ′(x) = f (x)
  • Antiderivative Theorem: If F (x), G(x) are antiderivatives of f (x) on an interval I, then F (x) = G(x) + C for a constant C
  • Indefinite Integral:

Z

f (x) dx = F (x) + C

Fundamental Theorem of Calculus

  • FTC Part 1: (^) ddx

Z (^) x

a

f (x) dx = f (x)

  • Extended FTC Part 1: (^) ddx

Z (^) h(x)

g(x)

f (x) dx = f (h(x))h′(x) − f (g(x))g′(x)

  • FTC Part 2:

Z (^) b

a

f (x) dx = F (b) − F (a)

Evaluating Integrals

  • Power Rule: For n ̸= − 1 ,

Z

xn^ dx =

xn+ n + 1

+ C

  • Integral of x−^1 :

Z

x−^1 dx = ln |x| + C

  • Substitution Rule:

Z (^) b

a

f (g(x))g′(x) dx =

Z (^) g(b)

g(a)

f (u) du

  • On [b 1 , b 2 ]:

Z (^) b 2

b 1

f (x) dx =

Z (^) a

b 1

f (x) dx +

Z (^) b 2

a

f (x) dx

  • Type 2 p-integrals:

Z 1

0

xp^

dx converges for p < 1

Area Between Curves

  • If y 1 (x) ≤ y 2 (x) ∀x ∈ [a, b], then the area between y 1 (x) and y 2 (x) for

x ∈ [a, b] is

Z (^) b

a

(y 2 (x) − y 1 (x)) dx

  • If x 1 (y) ≤ x 2 (y) ∀y ∈ [c, d], then the area between x 1 (y) and x 2 (y) for

y ∈ [c, d] is

Z (^) d

c

(x 2 (y) − x 1 (y)) dy

Volumes of Solids of Revolution

  • Disk Method: V =

Z (^) b

a

πf (x)^2 dx

  • Washer Method: V =

Z (^) b

a

π(g(x)^2 − f (x)^2 ) dx

  • Shell Method: V =

Z (^) b

a

2 πxf (x) dx

2 Differential Equations

Basic Definitions

  • Differential Equation: Equation relating f (x) and its derivatives
  • Order of DE: Highest order derivative that appears in the DE
  • General Solution: Complete set of all solutions to a DE
  • Particular Solution: A solution to a DE where all arbitrary constants are assigned a value
  • Initial Value Problem: A DE with initial conditions that can be used to find the value of constants
  • Direction Fields: A plot showing the slope at every point for a DE in the form (^) ddyx = f (x, y)
  • Solution Curve: The graph of a particular solution to a DE. Can be visu- alized from the direction field.

Separable DE

  • Definition: A DE that can be written in the form d dyx = g(x)h(y)
  • Solving a Separable DE
    • Write the DE in the form d dyx = g(x)h(y)
    • Find any solutions with h(y) = 0
    • For h(y) ̸= 0, evaluate

Z

h(y) dy =

Z

g(x) dx and solve for y

  • A suitable substitution can be used to transform a non-separable DE into a separable DE

Linear DE

  • Defintion: A DE in the form An(x)y(n)^ + An− 1 (x)y(n−1)^ + · · · + A 1 (x)y′^ + A 0 (x)y = B(x)
  • Standard Form of First Order Linear DE: y′^ + P (x)y = Q(x)
  • Solving a First Order Linear DE
    • Find μ(x) = exp

Z

P (x) dx

choosing any value for C

  • Multiply by μ(x): μ(x)(y′^ + P (x)y) = μ(x)Q(x) which becomes (yμ(x))′^ = μ(x)Q(x)
  • Integrate both sides and solve for y

Applications

  • Mixing Problems: d dAt = rin(t) − rout(t)
  • Newton’s Law of Heating/Cooling: d dTt = −k(T − Ts) for k ∈ R+
    • Solution: T (t) = Ts + Ae−kt, A = T (0) − Ts
  • Exponential Growth/Decay: d dPt = kP for k ∈ R
    • Solution: P (t) = Aekt, A = P (0)
  • Logistic Growth/Decay: d dPt = kP

1 − MP

for k ∈ R

  • Solution: P (t) = (^) 1+AeM−kt , A = M P^ − (0)P^ (0)
  • p-series
    • Can be used for series in the form

P 1

np

  • Converges for p > 1
  • Diverges for p ≤ 1
  • Telescoping Series
  • Can be used for series in the form

P

(an − an+k) for any k ∈ Z

  • Use cancellations to find a closed-form expression for Sm
  • Converges if lim m→∞ Sm converges
  • Diverges if lim m→∞ Sm diverges
  • Use partial fraction decomposition if needed
  • Can be used for find the value of the infinite series if it converges
  • Integral Test
  • Can be used for series in the form

P

an if f (n) = an ∀n ∈ N and f (x) is positive, continuous, decreasing on [k, ∞) for some k ∈ R

  • Converges if

Z ∞

k

f (x) dx converges

  • Diverges if

Z ∞

k

f (x) dx diverges

  • Useful if f (x) is easily integrable
  • Direct Comparison Test
  • Can be used for two series

P

an,

P

bn if 0 ≤ an ≤ bn eventually

  • If

P

bn converges, then

P

an converges

  • If

P

an diverges, then

P

bn diverges

  • A geometric series or p-series works well as a comparison
  • Limit Comparison Test
  • Can be used for two series

P

an,

P

bn if an ≥ 0 , bn > 0 eventually

  • Let L = (^) nlim→∞

an bn

  • If L > 0 and finite, then both series converge or both series diverge
  • If L = 0 and

P

bn converges, then

P

an converges

  • If L = ∞ and

P

bn diverges, then

P

an diverges

  • A geometric series or p-series works well as a comparison
  • Ratio Test
    • Can be used for series in the form

P

an

  • Let L = lim n→∞

an+ an

  • Converges (absolutely) if L < 1
  • Diverges if L > 1
  • Inconclusive if L = 1
  • Useful if an has exponentials, factorials, nn
  • Root Test
  • Can be used for series in the form

P

an

  • Let L = lim n→∞

p n|a n|

  • Converges (absolutely) if L < 1
  • Diverges if L > 1
  • Inconclusive if L = 1
  • Useful if an = (bn)n
  • Alternating Series Test
  • Can be used for series in the form

P

(−1)nan if an > 0

  • Converges if lim n→∞ an = 0 and 0 < an+1 ≤ an
  • Diverges if lim n→∞ an ̸= 0
  • Inconclusive if ak+1 > ak for some k ∈ N
  • Absolute Convergence Test
  • Can be used for series in the form

P

an

  • Converges if

P

|an| converges

  • Cannot show divergence

Estimation Theorems

  • Integral Test Estimation Theorem: Suppose that an = f (n) for all n ∈ N andZ f (x) is positive, continuous, decreasing on [k, ∞) for some k ∈ Z, with ∞

k

f (x) dx being convergent. Then, for S =

P∞

n=

an,

Z ∞

m+

f (x) dx ≤

S − Sm ≤

Z ∞

m

f (x) dx for m ≥ k

  • Alternating Series Estimation Theorem: Suppose that lim n→∞ an = 0 and

0 < an+1 ≤ an. Then, for S =

P∞

n=

(−1)nan, |S − Sm| ≤ am+

  • Substitution: For a = 0, f (bxk) =

P∞

n=

cnbnxkn, where b ∈ R, b ̸= 0, k ∈ N

∗ If Rf is finite, then the new radius of convergence is

Rf |b|

 1 /k

∗ If Rf is infinite, then the new radius of convergence is also infinite ∗ The new interval of convergence is {x ∈ R | bxk^ ∈ If }

Differentiating and Integrating Power Series

d dx

X^ ∞

n=

cn(x − a)n^ =

X^ ∞

n=

ncn(x − a)n−^1

Z X∞

n=

cn(x − a)n^ dx =

X^ ∞

n=

cn n + 1

(x − a)n+1^ + C

  • The radius of convergence will never change, but the interval of conver- gence may change

Taylor Series

  • Taylor Series of f (x) at a:

P∞

n=

f (n)(a) n! (x^ −^ a)

n

  • Maclaurin Series of f (x):

P∞

n=

f (n)(0) n! x

n

  • Order m Taylor Polynomial of f (x) at a: Tm,a(x) =

Pm n=

f (n)(a) n! (x^ −^ a)

n

  • Uniqueness of Power Series Theorem: If f (x) =

P∞

n=

cn(x − a)n, then cn is

unique and cn = f^

(n)(a) n!

  • Lagrange’s Remainder Formula: If f (m+1)(x) is continuous on an interval I containing a, and x ∈ I, then ∃c between a and x where f (x)−Tm,a(x) = f (m+1)(c) (m+1)! (x^ −^ a)

m+

  • Taylor’s Inequality: If f (m+1)(x) is continuous on an interval I containing a, and |f (m+1)(x)| ≤ k for all x ∈ I with k ∈ R, then |f (x) − Tm,a(x)| ≤ k (m+1)! (x^ −^ a)

m+

  • Convergence Theorem for Taylor Series: If |f (n)(x)| ≤ k for all n ∈ N and x ∈ I, then f (x) =

P∞

n=

f (n)(a) n! (x^ −^ a)

n (^) for all x ∈ I

Common Power Series

  • ex^ =

X^ ∞

n=

xn n!

for x ∈ R

  • cos(x) =

X^ ∞

n=

(−1)nx^2 n (2n)!

for x ∈ R

  • sin(x) =

X^ ∞

n=

(−1)nx^2 n+ (2n + 1)!

for x ∈ R

1 − x

X^ ∞

n=

xn^ for |x| < 1

  • ln(1 + x) =

X^ ∞

n=

(−1)n−^1 xn n

for x ∈ (− 1 , 1]

  • arctan(x) =

X^ ∞

n=

(−1)nx^2 n+ 2 n + 1

for |x| ≤ 1

  • (1 + x)α^ =

X^ ∞

n=

α n

xn^ for |x| < 1 if α /∈ Z≥ 0 and x ∈ R if α ∈ Z≥ 0

  • Binomial Coefficient:

α n

nQ− 1 k=

(α − k)

n!

Big-O Notation

  • f (x) = O(g(x)) as x → a if ∃M > 0 such that |f (x)| ≤ M |g(x)| for all x in a neighbourhood of a
  • Theorems
    • If f (x) = O(g(x)) as x → a and g(x) = O(h(x)) as x → a, then f (x) = O(h(x)) as x → a
    • If f (x) = O(g(x)) as x → a and lim x→b h(x) = a with h(x) ̸= a for all x in a neighbourhood of b, then f (h(x)) = O(g(h(x))) as x → b
    • If f (x) = O(xm) as x → 0 and g(x) = O(xn) as x → 0, then ∗ f (x)g(x) = O(xm+n) as x → 0 ∗ f (x) ± g(x) = O(xmin{m,n}) as x → 0 ∗ xf (x) = O(xm+1) as x → 0 ∗ (^) x^1 f (x) = O(xm−^1 ) as x → 0 if m ≥ 1