X32 maclaurin expansions

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Maclaurin Expansions

Transcript of X32 maclaurin expansions

Page 1: X32 maclaurin expansions

Maclaurin Expansions

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Given a "nice" function f(x) (e.g. y = sin(x)) and x = a, we want to find a numerical method in calculating f(x)for x around a.

Maclaurin Expansions

Page 3: X32 maclaurin expansions

Given a "nice" function f(x) (e.g. y = sin(x)) and x = a, we want to find a numerical method in calculating f(x)for x around a.

Maclaurin Expansions

It turns out that being "nice" in this case means that the derivative exists.

Page 4: X32 maclaurin expansions

Given a "nice" function f(x) (e.g. y = sin(x)) and x = a, we want to find a numerical method in calculating f(x)for x around a.

Maclaurin Expansions

It turns out that being "nice" in this case means that the derivative exists. The higher the derivative we can find, the nicer the function is, the better the approximation we may achieve.

Page 5: X32 maclaurin expansions

Given a "nice" function f(x) (e.g. y = sin(x)) and x = a, we want to find a numerical method in calculating f(x)for x around a.

Maclaurin Expansions

It turns out that being "nice" in this case means that the derivative exists. The higher the derivative we can find, the nicer the function is, the better the approximation we may achieve. We will assume our functions are of the best kind, i.e. they're infinitely differentiable and we will approximate the points around x = 0.

Page 6: X32 maclaurin expansions

Given a "nice" function f(x) (e.g. y = sin(x)) and x = a, we want to find a numerical method in calculating f(x)for x around a.

Maclaurin Expansions

It turns out that being "nice" in this case means that the derivative exists. The higher the derivative we can find, the nicer the function is, the better the approximation we may achieve. We will assume our functions are of the best kind, i.e. they're infinitely differentiable and we will approximate the points around x = 0.Given such a nice function, we'll try to find polynomials of higher and higher degree that give better and better approximation.

Page 7: X32 maclaurin expansions

Given a "nice" function f(x) (e.g. y = sin(x)) and x = a, we want to find a numerical method in calculating f(x)for x around a.

Maclaurin Expansions

It turns out that being "nice" in this case means that the derivative exists. The higher the derivative we can find, the nicer the function is, the better the approximation we may achieve. We will assume our functions are of the best kind, i.e. they're infinitely differentiable and we will approximate the points around x = 0.Given such a nice function, we'll try to find polynomials of higher and higher degree that give better and better approximation. We'll find the power series that is the same as the function in some cases.

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Given a function f(x) that is infinitely differentiable at x = 0, we define the polynomial

=pn(x)

Maclaurine Expansions

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Given a function f(x) that is infinitely differentiable at x = 0, we define the polynomial

= f(0)pn(x)

f(0)(0)0!

Maclaurine Expansions

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Given a function f(x) that is infinitely differentiable at x = 0, we define the polynomial

f '(0)x= f(0)+pn(x)

f(0)(0)0!

f(1)(0)1!

Maclaurine Expansions

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Given a function f(x) that is infinitely differentiable at x = 0, we define the polynomial

f '(0)x f(2)(0)+ 2!= f(0)+ x2pn(x)

f(0)(0)0!

f(1)(0)1!

Maclaurine Expansions

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Given a function f(x) that is infinitely differentiable at x = 0, we define the polynomial

f '(0)x f(2)(0)+ 2!= f(0)+ x2pn(x)

f(0)(0)0!

f(3)(0)+ 3! x3..

f(1)(0)1!

Maclaurine Expansions

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Given a function f(x) that is infinitely differentiable at x = 0, we define the polynomial

f '(0)x f(2)(0)+ 2!= f(0)+ x2pn(x)

f(0)(0)0!

f(3)(0)+ 3! x3.. f(n)(0)+ n! xn

f(1)(0)1!

Maclaurine Expansions

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Given a function f(x) that is infinitely differentiable at x = 0, we define the polynomial

f '(0)x f(2)(0)+ 2!= f(0)+ x2pn(x)

f(0)(0)0!

f(3)(0)+ 3! x3.. f(n)(0)+ n! xn

f(1)(0)1!

or

pn(x) = Σk=0

n

xkk!

f(k)(0)

Maclaurine Expansions

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Given a function f(x) that is infinitely differentiable at x = 0, we define the polynomial

f '(0)x f(2)(0)+ 2!= f(0)+ x2pn(x)

f(0)(0)0!

f(3)(0)+ 3! x3.. f(n)(0)+ n! xn

f(1)(0)1!

or

pn(x) = Σk=0

n

xkk!

f(k)(0)

This is called the n'th (degree) Maclaurin polynomial (Mac-poly) for f(x).

Maclaurine Expansions

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Given a function f(x) that is infinitely differentiable at x = 0, we define the polynomial

f '(0)x f(2)(0)+ 2!= f(0)+ x2pn(x)

f(0)(0)0!

f(3)(0)+ 3! x3.. f(n)(0)+ n! xn

f(1)(0)1!

or

pn(x) = Σk=0

n

xkk!

f(k)(0)

This is called the n'th (degree) Maclaurin polynomial (Mac-poly) for f(x). If we set n to be , we get the Maclaurin series (Mac-series):

P(x) = Σk=0 xk.k!

f(k)(0)∞

Maclaurine Expansions

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Given a function f(x) that is infinitely differentiable at x = 0, we define the polynomial

f '(0)x f(2)(0)+ 2!= f(0)+ x2pn(x)

f(0)(0)0!

f(3)(0)+ 3! x3.. f(n)(0)+ n! xn

f(1)(0)1!

or

pn(x) = Σk=0

n

xkk!

f(k)(0)

This is called the n'th (degree) Maclaurin polynomial (Mac-poly) for f(x). If we set n to be , we get the Maclaurin series (Mac-series):

P(x) = Σk=0 xk.k!

f(k)(0)∞

Maclaurine Expansions

We call them the Mac-expansions of f(x).

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pn(x) is a polynomial whose values of the first n'th derivatives at x=0 are the same as f(x).

Maclaurine Expansions

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pn(x) is a polynomial whose values of the first n'th derivatives at x=0 are the same as f(x).

= f(0)pn(0)In other words,

Maclaurine Expansions

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pn(x) is a polynomial whose values of the first n'th derivatives at x=0 are the same as f(x).

f (0)

= f(0)

+ #x + #x2 + ..#xn-1|x=0

pn(0)In other words,

=pn(0)(1) (1)

Maclaurine Expansions

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pn(x) is a polynomial whose values of the first n'th derivatives at x=0 are the same as f(x).

f (0)

= f(0)

+ #x + #x2 + ..#xn-1|x=0 = f (0)

pn(0)In other words,

=pn(0)(1) (1) (1)

Maclaurine Expansions

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pn(x) is a polynomial whose values of the first n'th derivatives at x=0 are the same as f(x).

f (0)

= f(0)

+ #x + #x2 + ..#xn-1|x=0 = f (0)

pn(0)In other words,

=pn(0)(1)

f (0)+ #x + #x2 + ..#xn-2|x=0 =pn(0)(2) (2)

(1) (1)

Maclaurine Expansions

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pn(x) is a polynomial whose values of the first n'th derivatives at x=0 are the same as f(x).

f (0)

= f(0)

+ #x + #x2 + ..#xn-1|x=0 = f (0)

pn(0)In other words,

=pn(0)(1)

f (0)+ #x + #x2 + ..#xn-2|x=0 = f (0)=pn(0)(2) (2) (2)

(1) (1)

Maclaurine Expansions

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pn(x) is a polynomial whose values of the first n'th derivatives at x=0 are the same as f(x).

f (0)

= f(0)

+ #x + #x2 + ..#xn-1|x=0 = f (0)

pn(0)In other words,

=pn(0)(1)

f (0)+ #x + #x2 + ..#xn-2|x=0 = f (0)=pn(0)(2) (2) (2)

(1) (1)

and so on, up to pn(0) = f (0). (n) (n)

Maclaurine Expansions

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pn(x) is a polynomial whose values of the first n'th derivatives at x=0 are the same as f(x).

f (0)

= f(0)

+ #x + #x2 + ..#xn-1|x=0 = f (0)

pn(0)In other words,

=pn(0)(1)

f (0)+ #x + #x2 + ..#xn-2|x=0 = f (0)=pn(0)(2) (2) (2)

(1) (1)

and so on, up to pn(0) = f (0). (n) (n)

In fact, pn(x) is the only degree n (or less) polynomial whose values of the first n'th derivatives agree with those of f(x) at x = 0.

Maclaurine Expansions

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pn(x) is a polynomial whose values of the first n'th derivatives at x=0 are the same as f(x).

f (0)

= f(0)

+ #x + #x2 + ..#xn-1|x=0 = f (0)

pn(0)In other words,

=pn(0)(1)

f (0)+ #x + #x2 + ..#xn-2|x=0 = f (0)=pn(0)(2) (2) (2)

(1) (1)

and so on, up to pn(0) = f (0). (n) (n)

In fact, pn(x) is the only degree n (or less) polynomial whose values of the first n'th derivatives agree with those of f(x) at x = 0. In similar arguments, the Mac-series is the only power series that has all derivatives agree with those of f(x) at x = 0.

Maclaurine Expansions

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The following are some examples of the Mac-polys and Mac-series of basic functions calculated via the definition.

Maclaurine Expansions

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The following are some examples of the Mac-polys and Mac-series of basic functions calculated via the definition. Later, we will use these expansions to calculate the expansions of other functions (in stead of using the definition).

Maclaurine Expansions

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The following are some examples of the Mac-polys and Mac-series of basic functions calculated via the definition. Later, we will use these expansions to calculate the expansions of other functions (in stead of using the definition).Example: A. Find the Mac-expansion of f(x) = 1 + x + x2 + x3 + x4 around x = 0.

Maclaurine Expansions

Page 30: X32 maclaurin expansions

The following are some examples of the Mac-polys and Mac-series of basic functions calculated via the definition. Later, we will use these expansions to calculate the expansions of other functions (in stead of using the definition).Example: A. Find the Mac-expansion of f(x) = 1 + x + x2 + x3 + x4 around x = 0.We need the derivatives of f(x):

Maclaurine Expansions

Page 31: X32 maclaurin expansions

The following are some examples of the Mac-polys and Mac-series of basic functions calculated via the definition. Later, we will use these expansions to calculate the expansions of other functions (in stead of using the definition).Example: A. Find the Mac-expansion of f(x) = 1 + x + x2 + x3 + x4 around x = 0.We need the derivatives of f(x):f (x) = 1 + 2x + 3x2 + 4x3 (1)

Maclaurine Expansions

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The following are some examples of the Mac-polys and Mac-series of basic functions calculated via the definition. Later, we will use these expansions to calculate the expansions of other functions (in stead of using the definition).Example: A. Find the Mac-expansion of f(x) = 1 + x + x2 + x3 + x4 around x = 0.We need the derivatives of f(x):f (x) = 1 + 2x + 3x2 + 4x3 f (0) = 1. (1) (1)

Maclaurine Expansions

Page 33: X32 maclaurin expansions

The following are some examples of the Mac-polys and Mac-series of basic functions calculated via the definition. Later, we will use these expansions to calculate the expansions of other functions (in stead of using the definition).Example: A. Find the Mac-expansion of f(x) = 1 + x + x2 + x3 + x4 around x = 0.We need the derivatives of f(x):f (x) = 1 + 2x + 3x2 + 4x3 f (0) = 1. (1) (1)

f (x) = 2 + 3*2x + 4*3x2 (2)

Maclaurine Expansions

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The following are some examples of the Mac-polys and Mac-series of basic functions calculated via the definition. Later, we will use these expansions to calculate the expansions of other functions (in stead of using the definition).Example: A. Find the Mac-expansion of f(x) = 1 + x + x2 + x3 + x4 around x = 0.We need the derivatives of f(x):f (x) = 1 + 2x + 3x2 + 4x3 f (0) = 1. (1) (1)

f (x) = 2 + 3*2x + 4*3x2 f (0) = 2! (2) (2)

Maclaurine Expansions

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The following are some examples of the Mac-polys and Mac-series of basic functions calculated via the definition. Later, we will use these expansions to calculate the expansions of other functions (in stead of using the definition).Example: A. Find the Mac-expansion of f(x) = 1 + x + x2 + x3 + x4 around x = 0.We need the derivatives of f(x):f (x) = 1 + 2x + 3x2 + 4x3 f (0) = 1. (1) (1)

f (x) = 2 + 3*2x + 4*3x2 f (0) = 2! (2) (2)

f (x) = 3*2 + 4*3*2x (3)

Maclaurine Expansions

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The following are some examples of the Mac-polys and Mac-series of basic functions calculated via the definition. Later, we will use these expansions to calculate the expansions of other functions (in stead of using the definition).Example: A. Find the Mac-expansion of f(x) = 1 + x + x2 + x3 + x4 around x = 0.We need the derivatives of f(x):f (x) = 1 + 2x + 3x2 + 4x3 f (0) = 1. (1) (1)

f (x) = 2 + 3*2x + 4*3x2 f (0) = 2! (2) (2)

f (x) = 3*2 + 4*3*2x f (0) = 3! (3) (3)

Maclaurine Expansions

Page 37: X32 maclaurin expansions

The following are some examples of the Mac-polys and Mac-series of basic functions calculated via the definition. Later, we will use these expansions to calculate the expansions of other functions (in stead of using the definition).Example: A. Find the Mac-expansion of f(x) = 1 + x + x2 + x3 + x4 around x = 0.We need the derivatives of f(x):f (x) = 1 + 2x + 3x2 + 4x3 f (0) = 1. (1) (1)

f (x) = 2 + 3*2x + 4*3x2 f (0) = 2! (2) (2)

f (x) = 3*2 + 4*3*2x f (0) = 3! (3) (3)

f (x) = 4*3*2 (4)

Maclaurine Expansions

Page 38: X32 maclaurin expansions

The following are some examples of the Mac-polys and Mac-series of basic functions calculated via the definition. Later, we will use these expansions to calculate the expansions of other functions (in stead of using the definition).Example: A. Find the Mac-expansion of f(x) = 1 + x + x2 + x3 + x4 around x = 0.We need the derivatives of f(x):f (x) = 1 + 2x + 3x2 + 4x3 f (0) = 1. (1) (1)

f (x) = 2 + 3*2x + 4*3x2 f (0) = 2! (2) (2)

f (x) = 3*2 + 4*3*2x f (0) = 3! (3) (3)

f (x) = 4*3*2 f (0) = 4! (4) (4)

Maclaurine Expansions

Page 39: X32 maclaurin expansions

The following are some examples of the Mac-polys and Mac-series of basic functions calculated via the definition. Later, we will use these expansions to calculate the expansions of other functions (in stead of using the definition).Example: A. Find the Mac-expansion of f(x) = 1 + x + x2 + x3 + x4 around x = 0.We need the derivatives of f(x):f (x) = 1 + 2x + 3x2 + 4x3 f (0) = 1. (1) (1)

f (x) = 2 + 3*2x + 4*3x2 f (0) = 2! (2) (2)

f (x) = 3*2 + 4*3*2x f (0) = 3! (3) (3)

f (x) = 4*3*2 f (0) = 4! (4) (4)

f (x) = 0 for n > 5(n)

Maclaurine Expansions

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Hence p0(x) = f(0) = 1

Maclaurine Expansions

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Hence p0(x) = f(0) = 1

f '(0)x= f(0)+p1(x)

Maclaurine Expansions

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Hence p0(x) = f(0) = 1

f '(0)x = 1 + 1x= f(0)+p1(x)

Maclaurine Expansions

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Hence p0(x) = f(0) = 1

f '(0)x = 1 + 1x= f(0)+p1(x)

f(2)(0)+ 2! x2f '(0)x = f(0)+p2(x)

Maclaurine Expansions

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Hence p0(x) = f(0) = 1

f '(0)x = 1 + 1x= f(0)+p1(x)

f(2)(0)+ 2! x2f '(0)x = f(0)+p2(x) = 1 + 1x + 2!2!

x2

Maclaurine Expansions

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Hence p0(x) = f(0) = 1

f '(0)x = 1 + 1x= f(0)+p1(x)

f(2)(0)+ 2! x2f '(0)x = f(0)+p2(x) = 1 + 1x + 2!2!

x2

= 1 + x + x2

Maclaurine Expansions

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Hence p0(x) = f(0) = 1

f '(0)x = 1 + 1x= f(0)+p1(x)

f(2)(0)+ 2! x2f '(0)x = f(0)+p2(x) = 1 + 1x + 2!2!

x2

= 1 + x + x2

f(2)(0)+ 2! x2 f(3)(0)+ 3! x3f '(0)x = f(0)+p3(x)

Maclaurine Expansions

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Hence p0(x) = f(0) = 1

f '(0)x = 1 + 1x= f(0)+p1(x)

f(2)(0)+ 2! x2f '(0)x = f(0)+p2(x) = 1 + 1x + 2!2!

x2

= 1 + x + x2

f(2)(0)+ 2! x2 f(3)(0)+ 3! x3f '(0)x = f(0)+p3(x)

+ x2 + x31x = 1 + 2!2!

3!3!

Maclaurine Expansions

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Hence p0(x) = f(0) = 1

f '(0)x = 1 + 1x= f(0)+p1(x)

f(2)(0)+ 2! x2f '(0)x = f(0)+p2(x) = 1 + 1x + 2!2!

x2

= 1 + x + x2

f(2)(0)+ 2! x2 f(3)(0)+ 3! x3f '(0)x = f(0)+p3(x)

+ x2 + x31x = 1 + 2!2!

3!3! = 1 + x + x2 + x3

Maclaurine Expansions

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Hence p0(x) = f(0) = 1

f '(0)x = 1 + 1x= f(0)+p1(x)

=p4(x)

f(2)(0)+ 2! x2f '(0)x = f(0)+p2(x) = 1 + 1x + 2!2!

x2

= 1 + x + x2

f(2)(0)+ 2! x2 f(3)(0)+ 3! x3f '(0)x = f(0)+p3(x)

+ x2 + x31x = 1 + 2!2!

3!3! = 1 + x + x2 + x3

+ x2+ x31x 1+ 2!2!

3!3! + x44!

4!

Maclaurine Expansions

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Hence p0(x) = f(0) = 1

f '(0)x = 1 + 1x= f(0)+p1(x)

=p4(x)

f(2)(0)+ 2! x2f '(0)x = f(0)+p2(x) = 1 + 1x + 2!2!

x2

= 1 + x + x2

f(2)(0)+ 2! x2 f(3)(0)+ 3! x3f '(0)x = f(0)+p3(x)

+ x2 + x31x = 1 + 2!2!

3!3! = 1 + x + x2 + x3

+ x2+ x31x 1+ 2!2!

3!3! + x44!

4!= 1 + x + x2 + x3 + x4

Maclaurine Expansions

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Hence p0(x) = f(0) = 1

f '(0)x = 1 + 1x= f(0)+p1(x)

=p4(x)

f(2)(0)+ 2! x2f '(0)x = f(0)+p2(x) = 1 + 1x + 2!2!

x2

= 1 + x + x2

f(2)(0)+ 2! x2 f(3)(0)+ 3! x3f '(0)x = f(0)+p3(x)

+ x2 + x31x = 1 + 2!2!

3!3! = 1 + x + x2 + x3

+ x2+ x31x 1+ 2!2!

3!3! + x44!

4!= 1 + x + x2 + x3 + x4

For n > 5, pn(x)

= 1 + x + x2 + x3 + x4 = f(x)

Maclaurine Expansions

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In general, if f(x) = a0 + ax + a2x2 + .. +akxk is a polynomial, thenp0(x) = a0

Maclaurine Expansions

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In general, if f(x) = a0 + ax + a2x2 + .. +akxk is a polynomial, thenp0(x) = a0

p1(x) = a0 + a1x

Maclaurine Expansions

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In general, if f(x) = a0 + ax + a2x2 + .. +akxk is a polynomial, thenp0(x) = a0

p1(x) = a0 + a1xp2(x) = a0 + a1x + a2x2

Maclaurine Expansions

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In general, if f(x) = a0 + ax + a2x2 + .. +akxk is a polynomial, thenp0(x) = a0

p1(x) = a0 + a1xp2(x) = a0 + a1x + a2x2

..

Maclaurine Expansions

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In general, if f(x) = a0 + ax + a2x2 + .. +akxk is a polynomial, thenp0(x) = a0

p1(x) = a0 + a1xp2(x) = a0 + a1x + a2x2

..pk(x) = a0 + a1x + a2x2.. + akxk = f(x)

Maclaurine Expansions

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In general, if f(x) = a0 + ax + a2x2 + .. +akxk is a polynomial, thenp0(x) = a0

p1(x) = a0 + a1xp2(x) = a0 + a1x + a2x2

..pk(x) = a0 + a1x + a2x2.. + akxk = f(x)and for all n > k, pn(x) = a0 + a1x + a2x2.. + akxk = f(x).

Maclaurine Expansions

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In general, if f(x) = a0 + ax + a2x2 + .. +akxk is a polynomial, then

Example: B. Find the Mac-expansion of f(x) = ex around x = 0.

p0(x) = a0

p1(x) = a0 + a1xp2(x) = a0 + a1x + a2x2

..pk(x) = a0 + a1x + a2x2.. + akxk = f(x)and for all n > k, pn(x) = a0 + a1x + a2x2.. + akxk = f(x).

Maclaurine Expansions

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In general, if f(x) = a0 + ax + a2x2 + .. +akxk is a polynomial, then

Example: B. Find the Mac-expansion of f(x) = ex around x = 0.

We need the derivatives of f(x):

p0(x) = a0

p1(x) = a0 + a1xp2(x) = a0 + a1x + a2x2

..pk(x) = a0 + a1x + a2x2.. + akxk = f(x)and for all n > k, pn(x) = a0 + a1x + a2x2.. + akxk = f(x).

Maclaurine Expansions

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In general, if f(x) = a0 + ax + a2x2 + .. +akxk is a polynomial, then

Example: B. Find the Mac-expansion of f(x) = ex around x = 0.

We need the derivatives of f(x):f (x) = ex f (0) = 1 for all n. (n) (n)

p0(x) = a0

p1(x) = a0 + a1xp2(x) = a0 + a1x + a2x2

..pk(x) = a0 + a1x + a2x2.. + akxk = f(x)and for all n > k, pn(x) = a0 + a1x + a2x2.. + akxk = f(x).

Maclaurine Expansions

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f(1)(0)x f(2)(0)+ 2!= f(0)+ x2pn(x) f(3)(0)+ 3! x3.. f(n)(0)+ n! xn

Therefore the n'th Mac-polynomial of ex isMaclaurine Expansions

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f(1)(0)x f(2)(0)+ 2!= f(0)+ x2pn(x) f(3)(0)+ 3! x3.. f(n)(0)+ n! xn

Therefore the n'th Mac-polynomial of ex is

x + 2!= 1 + x2

+ .. ++ 3!x3

n!xn

Maclaurine Expansions

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f(1)(0)x f(2)(0)+ 2!= f(0)+ x2pn(x) f(3)(0)+ 3! x3.. f(n)(0)+ n! xn

P(x) = Σk=0 k! .

xk

Therefore the n'th Mac-polynomial of ex is

x + 2!= 1 + x2

+ .. ++ 3!x3

n!xn

The Mac-series of ex is∞

x + 2!1 + x2

+ .. ++ 3!x3

n! ..xn

=

Maclaurine Expansions

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y = ex

y=x+1

The graphs of Mac-polys for y = ex

Maclaurine Expansions

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y = ex

y=x+1

y=x2/2+x+1

Maclaurine Expansions

The graphs of Mac-polys for y = ex

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y = ex

y=x+1

y=x2/2+x+1

y=x3/6+x2/2+x+1

Maclaurine Expansions

The graphs of Mac-polys for y = ex

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f(1)(0)x f(2)(0)+ 2!= f(0)+ x2pn(x) f(3)(0)+ 3! x3.. f(n)(0)+ n! xn

P(x) = Σk=0 k! .

xk

Therefore the n'th Mac-polynomial of ex is

x + 2!= 1 + x2

+ .. ++ 3!x3

n!xn

The Mac-series of ex is∞

Example: C. Find the Mac-expansion of f(x) = sin(x), around x = 0.

x + 2!1 + x2

+ .. ++ 3!x3

n! ..xn

=

Maclaurine Expansions

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f(1)(0)x f(2)(0)+ 2!= f(0)+ x2pn(x) f(3)(0)+ 3! x3.. f(n)(0)+ n! xn

P(x) = Σk=0 k! .

xk

Therefore the n'th Mac-polynomial of ex is

x + 2!= 1 + x2

+ .. ++ 3!x3

n!xn

The Mac-series of ex is∞

Example: C. Find the Mac-expansion of f(x) = sin(x), around x = 0.

We need the derivatives of sin(x).

x + 2!1 + x2

+ .. ++ 3!x3

n! ..xn

=

Maclaurine Expansions

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f(1)(0)x f(2)(0)+ 2!= f(0)+ x2pn(x) f(3)(0)+ 3! x3.. f(n)(0)+ n! xn

P(x) = Σk=0 k! .

xk

Therefore the n'th Mac-polynomial of ex is

x + 2!= 1 + x2

+ .. ++ 3!x3

n!xn

The Mac-series of ex is∞

Example: C. Find the Mac-expansion of f(x) = sin(x), around x = 0.

We need the derivatives of sin(x). We can arrange them in a circle.

x + 2!1 + x2

+ .. ++ 3!x3

n! ..xn

=

Maclaurine Expansions

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sin(x)

cos(x)

-sin(x)

-cos(x)

Maclaurine Expansions

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sin(x)

cos(x)

-sin(x)

-cos(x)

derivative: 0th, 4th, 8th, ..

Maclaurine Expansions

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sin(x)

cos(x)

-sin(x)

-cos(x)

derivative: 0th, 4th, 8th, ..

derivative: 1st, 5th, 9th, ..

Maclaurine Expansions

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sin(x)

cos(x)

-sin(x)

-cos(x)

derivative: 0th, 4th, 8th, ..

derivative: 1st, 5th, 9th, ..

derivative: 2nd, 6th, 10th, ..

Maclaurine Expansions

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sin(x)

cos(x)

-sin(x)

-cos(x)

derivative: 0th, 4th, 8th, ..

derivative: 1st, 5th, 9th, ..

derivative: 2nd, 6th, 10th, ..

derivative: 3rd, 7th, 11th, ..

Maclaurine Expansions

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sin(x)

cos(x)

-sin(x)

-cos(x)

derivative: 0th, 4th, 8th, ..

derivative: 1st, 5th, 9th, ..

derivative: 2nd, 6th, 10th, ..

derivative: 3rd, 7th, 11th, ..

At x = 0:

Maclaurine Expansions

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sin(x)

cos(x)

-sin(x)

-cos(x)

derivative: 0th, 4th, 8th, ..

derivative: 1st, 5th, 9th, ..

derivative: 2nd, 6th, 10th, ..

derivative: 3rd, 7th, 11th, ..

At x = 0: 0

1

0

-1

derivative: 0th, 4th, 8th, ..

derivative: 1st, 5th, 9th, ..

derivative: 2nd, 6th, 10th, ..

derivative: 3rd, 7th, 11th, ..

Maclaurine Expansions

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Set 0, 1, 0, -1, 0, 1, 0, -1, .. for f(n)(0) in the expansion:Maclaurine Expansions

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1x 0+ 2!= 0 + x2P(x) -1+ 3!x3

Set 0, 1, 0, -1, 0, 1, 0, -1, .. for f(n)(0) in the expansion:0+ 4!

x4 1+ 5!x5+ 6!

x60 + 7!x7..-1

Maclaurine Expansions

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1x 0+ 2!= 0 + x2P(x) -1+ 3!x3

Set 0, 1, 0, -1, 0, 1, 0, -1, .. for f(n)(0) in the expansion:0+ 4!

x4 1+ 5!x5+ 6!

x60 + 7!x7..-1

1x=P(x) – 3!x3

+ 5!x5

+..7!x7

Maclaurine Expansions

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1x 0+ 2!= 0 + x2P(x) -1+ 3!x3

Set 0, 1, 0, -1, 0, 1, 0, -1, .. for f(n)(0) in the expansion:0+ 4!

x4 1+ 5!x5+ 6!

x60 + 7!x7..-1

1x=P(x) – 3!x3

+ 5!x5

+..7!x7

The alternating odd numbers {1, -3, 5, -7, ..} may be written as {(-1)k(2k + 1)} for k = 0, 1, 2, 3, ..

Maclaurine Expansions

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1x 0+ 2!= 0 + x2P(x) -1+ 3!x3

Σk=0

Set 0, 1, 0, -1, 0, 1, 0, -1, .. for f(n)(0) in the expansion:0+ 4!

x4 1+ 5!x5+ 6!

x60 + 7!x7..-1

1x=P(x) – 3!x3

+ 5!x5

+..7!x7

The alternating odd numbers {1, -3, 5, -7, ..} may be written as {(-1)k(2k + 1)} for k = 0, 1, 2, 3, ..

1x=P(x) – 3!x3

+ 5!x5

+ .. =7!x7

Maclaurine Expansions

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1x 0+ 2!= 0 + x2P(x) -1+ 3!x3

Σk=0 (2k+1)!

(-1)kx2k+1

is the Mac-series of sin(x).

Set 0, 1, 0, -1, 0, 1, 0, -1, .. for f(n)(0) in the expansion:0+ 4!

x4 1+ 5!x5+ 6!

x60 + 7!x7..-1

1x=P(x) – 3!x3

+ 5!x5

+..7!x7

The alternating odd numbers {1, -3, 5, -7, ..} may be written as {(-1)k(2k + 1)} for k = 0, 1, 2, 3, ..

1x=P(x) – 3!x3

+ 5!x5

+ .. =7!x7

Maclaurine Expansions

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1x 0+ 2!= 0 + x2P(x) -1+ 3!x3

Σk=0 (2k+1)!

(-1)kx2k+1

is the Mac-series of sin(x).

Set 0, 1, 0, -1, 0, 1, 0, -1, .. for f(n)(0) in the expansion:0+ 4!

x4 1+ 5!x5+ 6!

x60 + 7!x7..-1

1x=P(x) – 3!x3

+ 5!x5

+..7!x7

The alternating odd numbers {1, -3, 5, -7, ..} may be written as {(-1)k(2k + 1)} for k = 0, 1, 2, 3, ..

1x=P(x) – 3!x3

+ 5!x5

+ .. =7!x7

Verify that the Mac-series of f(x) = cos(x) is

Σk=0 (2k)!

(-1)kx2k∞=P(x) +

4!x4

6!x6

8!x8

+ 1 – – – .. =2!x2

Maclaurine Expansions

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Example: D. Find the Mac-expansion of f(x) = (1 – x)-1 around x = 0.

Maclaurine Expansions

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Example: D. Find the Mac-expansion of f(x) = (1 – x)-1 around x = 0.

Again, we compute and obtain a pattern of the derivatives first.

Maclaurine Expansions

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Example: D. Find the Mac-expansion of f(x) = (1 – x)-1 around x = 0.

Again, we compute and obtain a pattern of the derivatives first. f(x) = (1 – x)-1 so at x = 0, f(0) = 1

Maclaurine Expansions

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Example: D. Find the Mac-expansion of f(x) = (1 – x)-1 around x = 0.

Again, we compute and obtain a pattern of the derivatives first. f(x) = (1 – x)-1 so at x = 0, f(0) = 1f (x) = (1 – x)-2 (1)

Maclaurine Expansions

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Example: D. Find the Mac-expansion of f(x) = (1 – x)-1 around x = 0.

Again, we compute and obtain a pattern of the derivatives first. f(x) = (1 – x)-1 so at x = 0, f(0) = 1f (x) = (1 – x)-2 so at x = 0, f (x) = 1 (1) (1)

Maclaurine Expansions

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Example: D. Find the Mac-expansion of f(x) = (1 – x)-1 around x = 0.

Again, we compute and obtain a pattern of the derivatives first. f(x) = (1 – x)-1 so at x = 0, f(0) = 1f (x) = (1 – x)-2 so at x = 0, f (x) = 1 (1) (1)

f (x) = 2(1 – x)-3 (2)

Maclaurine Expansions

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Example: D. Find the Mac-expansion of f(x) = (1 – x)-1 around x = 0.

Again, we compute and obtain a pattern of the derivatives first. f(x) = (1 – x)-1 so at x = 0, f(0) = 1f (x) = (1 – x)-2 so at x = 0, f (x) = 1 (1) (1)

f (x) = 2(1 – x)-3 so at x = 0, f (x) = 2! (2) (2)

Maclaurine Expansions

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Example: D. Find the Mac-expansion of f(x) = (1 – x)-1 around x = 0.

Again, we compute and obtain a pattern of the derivatives first. f(x) = (1 – x)-1 so at x = 0, f(0) = 1f (x) = (1 – x)-2 so at x = 0, f (x) = 1 (1) (1)

f (x) = 2(1 – x)-3 so at x = 0, f (x) = 2! (2) (2)

f (x) = 3*2(1 – x)-4 (3)

Maclaurine Expansions

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Example: D. Find the Mac-expansion of f(x) = (1 – x)-1 around x = 0.

Again, we compute and obtain a pattern of the derivatives first. f(x) = (1 – x)-1 so at x = 0, f(0) = 1f (x) = (1 – x)-2 so at x = 0, f (x) = 1 (1) (1)

f (x) = 2(1 – x)-3 so at x = 0, f (x) = 2! (2) (2)

f (x) = 3*2(1 – x)-4 so at x = 0, f (x) = 3! (3) (3)

Maclaurine Expansions

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Example: D. Find the Mac-expansion of f(x) = (1 – x)-1 around x = 0.

Again, we compute and obtain a pattern of the derivatives first. f(x) = (1 – x)-1 so at x = 0, f(0) = 1f (x) = (1 – x)-2 so at x = 0, f (x) = 1 (1) (1)

f (x) = 2(1 – x)-3 so at x = 0, f (x) = 2! (2) (2)

f (x) = 3*2(1 – x)-4 so at x = 0, f (x) = 3! (3) (3)

In general, f (x) = n! (n)

Maclaurine Expansions

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Example: D. Find the Mac-expansion of f(x) = (1 – x)-1 around x = 0.

Again, we compute and obtain a pattern of the derivatives first. f(x) = (1 – x)-1 so at x = 0, f(0) = 1f (x) = (1 – x)-2 so at x = 0, f (x) = 1 (1) (1)

f (x) = 2(1 – x)-3 so at x = 0, f (x) = 2! (2) (2)

f (x) = 3*2(1 – x)-4 so at x = 0, f (x) = 3! (3) (3)

In general, f (x) = n! (n)

Therefore, P(x) = 1x + 2!1+ x2+ 3!x3+ 4!

x4 + … 2! 3! 4!

Maclaurine Expansions

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Example: D. Find the Mac-expansion of f(x) = (1 – x)-1 around x = 0.

Again, we compute and obtain a pattern of the derivatives first. f(x) = (1 – x)-1 so at x = 0, f(0) = 1f (x) = (1 – x)-2 so at x = 0, f (x) = 1 (1) (1)

f (x) = 2(1 – x)-3 so at x = 0, f (x) = 2! (2) (2)

f (x) = 3*2(1 – x)-4 so at x = 0, f (x) = 3! (3) (3)

In general, f (x) = n! (n)

Therefore, P(x) = 1x + 2!1+ x2+ 3!x3+ 4!

x4 + … or2! 3! 4!

P(x) = 1 + x + x2 + x3 + x4 .. is the Mac-series for (1- x) .

1

Maclaurine Expansions

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Summary of the Mac-seriesI. For polynomials P, Mac-poly of degree k consists the first k-terms of the polynomial P. Mac-series of polynomials are themselves.

II. For ex, its Σk=0 k! .

xk∞x + 2!1 + x2

+ .. ++ 3!x3

n! ..xn

=

Σk=0 (2k+1)!

(-1)kx2k+1∞x –

3!x3

+ 5!x5

+ .. =7!x7

– III. For sin(x), its

IV. For cos(x), its Σk=0 (2k)!

(-1)kx2k∞

+ 4!x4

6!x6

8!x8

+ 1 – – – .. =2!x2

V. For , its(1 – x )

11 + x + x2 + x3 + x4 .. = Σ

k=0

∞xk

Computation Techniques for Maclaurin Expansions

VI. For Ln(1 + x), its + 3x3

4x4

5x5

+ x – – 2x2

.. Σk=1 k .

(-1)k+1xk∞

=