Multiple Integrals

CHAPTER THREE (Multiple Integrals) Page 1

�� : �� !, #$ �� %�&�� %�� ',

': � ≤ ! ≤ ), � ≤ # ≤ �. ��)&� ��%��& �� , +�� ∬ � !, #$- �. , �� ∬ � !, #$- �! �#.

�ℎ�� !, #$�� 0��1� �� 1�� %�� ' �� ℎ� !# − 0&��, +� 3�# ��0�� ℎ� ��)&� ��%��& �� 1�� ' �� ℎ� 1�&�3� �� ℎ� 3 − ��3��& ��&�� %�� 1�� ℎ� !# − 0&�� )�� )�&�+ )# ' �� )�1� )# �ℎ� �� 5 = � !, #$ , 7�%�� 15.2 , ;�%� 1069$ .

?�&�3� = ∬ � !, #$- �..

@� ��&��&�� ℎ� 1�&�3� �� ℎ� 0&�� 5 = 4 − ! − # , �1�� %�&�� ': 0 ≤ ! ≤ 2 , 0 ≤ # ≤ 1 , �� ℎ� !# − 0&��. ��ℎ �&�� 0��0��&�� ℎ� ! − �!�� 7�%�� 15.4$ ;�%� 1069. @ℎ� 1�&�3� �� B . !$CDECDF �!. +ℎ�� . !$�� ℎ� �� − ��& �� !. 7�� ℎ 1�&�� !, +� 3�# ��&��&�� . !$ �� ℎ� ��%��&

Chapter Three Multiple Integrals

Double Integral

Double Integrals as Volume

Fubini’s Theorem for Calculating Double Integrals

. !$ = B 4 − ! − #$GDHGDF �# , +ℎ��ℎ �� ℎ� �� ℎ� ��1� 5 = 4 − ! − # �� ℎ� 0&�� − �� !. I� ��&��&��% . !$, ! �� ℎ�&� ��!�� ℎ� ��%�� J�� 0&�� +��ℎ ��0�� #. K�3)��% �ℎ� �+� ��%��&�, +� �� ℎ�� ℎ� 1�&�3� �� ℎ� �� &��

?�&�3� = B . !$CDECDF �! = B L B 4 − ! − #$�#GDHGDF MCDECDF �!

= B [4# − !# − GOE ]GDFGDHCDECDF �! = B LQE − !MCDECDF �! = [QE ! − CO

E ]F E = 5

��ℎ �&�� 0��0��&�� ℎ� # − �!�� 7�%�� 15.5$ ;�%� 1070. @ℎ� 1�&�3� �� B . #$GDHGDF �#. +ℎ�� . #$�� ℎ� �� − ��& �� #. 7�� ℎ 1�&�� #, +� 3�# ��&��&�� . #$ �� ℎ� ��%��& . #$ = B 4 − ! − #$CDECDF �! , +ℎ��ℎ �� ℎ� �� ℎ� ��1� 5 = 4 − ! − # �� ℎ� 0&�� − �� #. I� ��&��&��% . #$, # �� ℎ�&� ��!�� ℎ� ��%�� J�� 0&�� +��ℎ ��0�� !. K�3)��% �ℎ� �+� ��%��&�, +� �� ℎ�� ℎ� 1�&�3� �� ℎ� �� &��

?�&�3� = B . #$GDHGDF �# = B L B 4 − ! − #$�!CDECDF MGDHGDF �#

= B [4! − COE − !#]CDFCDEGDHGDF �# = B 6 − 2#$GDHGDF �# = [6# − #E]F H = 5

THEOREM 1 Fubini’s Theorem (First Form)

I� � !, #$ �� ℎ��%ℎ�� ℎ� ��%�&�� %�� ': � ≤ ! ≤ ), � ≤ # ≤ �, �ℎ�� ∬ � !, #$- �. = B B � !, #$ST �! �#UV = B B � !, #$UV �# �!ST .

W! 1: K�&��&�� ∬ � !, #$- �. �� !, #$ = 1 − 6!E# �� ': 0 ≤ ! ≤ 2, −1 ≤ # ≤ 1. X�&Y : ∬ � !, #$- �. = B B 1 − 6!E#$EF �! �#HZH = B ! − 2![#$FEHZH �#

= \ 2 − 16#$HZH

�# = [2# − 8#E]ZHH = 4. '�1��% �ℎ� �� %�� %�1�� ℎ� ��3� ��+��.

\ \ 1 − 6!E#$HZH

�# �!EF

= \ # − 3!E#E$ZHHEF

�! = \ 1 − 3!E$ − −1 − 3!E$EF

= B 2EF �! = 2!]FE = 4

Theorem 2 Fubini’s Theorem(stronger Form ^�� !, #$)� �� %�� '. 1- I� ' �� )# � ≤ ! ≤ ), %H !$ ≤ # ≤ %E !$, +��ℎ %H �� %E �� [�, )], �ℎ�� ∬ � !, #$- �. = B B � !, #$_O C$_` C$ST �#�!. 2- I� ' �� )# � ≤ # ≤ �, ℎH #$ ≤ ! ≤ ℎE #$, +��ℎ ℎH �� ℎE �� [�, �], �ℎ�� ∬ � !, #$- �. = B B � !, #$aO G$a` G$UV �!�#.

W! 2: 7�� ℎ� 1�&�3� �� ℎ� 0��3 +ℎ�� )�� %&� �� ℎ� !# −0&�� )�� )# �ℎ� ! − �!�� ℎ� &�� # = ! �� ! = 1 �� +ℎ�� 0 &�� ℎ� 0&�� 5 = � !, #$ = 3 − ! − #. X�&Y: X�� 7�%�� 15.11 �� ;�%� 1075 . 7�� # ! )��+�� 0 �� 1

# 3�# 1��# ��3 # = 0 �� # = ! 7�%�� 15.11)$. b��,

Double Integral over Bounded Nonrectangular Regions

1 = B B 3 − ! − #$CF �#�!HF = B [3# − !# − GOE ]GDFGDCHF �! = B L3! − [CO

E MHF �!

= [[COE − Cc

E ]CDFCDH = 1. �ℎ�� ℎ� �� %�� 1�� 7�%�� 15.11�$, �ℎ� ��%��& ��

�ℎ� 1�&�3� �� 1 = B B 3 − ! − #$HG �!�#HF = B [3! − COE − !#]CDGCDHHF �# z

= B L3 − HE − # − 3# + GOE + #EM �#HF = B LeE − 4# + [E #EM �#HF (3,0,0)

= [eE # − 2#E + GcE ]FH = 1. (1,0 ,2) z=3-x-y

@ℎ� �+� ��%��&� �f��&, �� ℎ�# �ℎ��&� )�. (1,1,1)

Y x=1 y=x y x=1 y=x

y=x x=y x=1 (1,0,0) y=x y

Y=0 x x x (1,1,0)

W! 3: K�&��&�� ∬ ghi CC- �. , +ℎ�� ' �� ℎ� ��%&� �� ℎ� !# − 0&�� )�� )# �ℎ� ! − �!��, �ℎ� &�� # = !, �� ℎ� &�� ! = 1. X�&Y: )# ��%�� +��ℎ ��0�� # �� ℎ�� +��ℎ ��0�� !, B B ghi CCCFHF �#$ �! = B G ghi CCHF $FGDC�! = B sin !HF �! = − cos 1$ + 1 ≅ 0.46. I� +� ��1�� ℎ� �� %�� 30� �� &��&��

B B ghi CCHG �!HF �# , +� �� 00�� )# �ℎ� �� ℎ�� B ghi CC �! �� )�

�!0�� 3� �� &�3��# ��.

Procedure for finding limits of integration

A) To evaluate ∬ � !, #$- �. �1�� %�� ' , ��%��% �� +��ℎ ��0�� # �� ℎ�� +��ℎ ��0�� !, ��J� �ℎ� ��&&�+��% ��0�: 1 − XJ��ℎ �ℎ� ��%�� %�� &�)�& �ℎ� )��% ��1�� 2 − I3�%�� 1��& &�� ^ ��% �ℎ��%ℎ ' �� ℎ� �� % #. p��J �ℎ� # − 1�&�� +ℎ�� ^ �� &��1��. @ℎ�� ℎ� &�3�� %��. 3 − Kℎ�� ! − &�3�� ℎ�� &�� && 1��& &�� ℎ��%ℎ '. @ℎ� ��%��& �� ∬ � !, #$- �. = B B � !, #$GD√HZCOGDHZC �#�!.HF

r$ @� �1�&�� ℎ� ��3� ��)&� ��%��& �� %��& +��ℎ ��

�� %�� 1�� , �ℎ� 0�� ℎ��5��& &��

1��& &��. ∬ � !, #$�.- = B B � !, #$sHZGOHZG �! �#HF

y &��1�� # = √1 − !2

!E + #E = 1 1 �� # = 1 − !

! + # = 1 L enter at x=1-y

x x=0 x=1 0

&��1�� ! = s1 − #E

Finding the limits of Integration

W! 4: XJ��ℎ �ℎ� ��%�� 1�� +ℎ��ℎ �ℎ� ��%�� B B 4! + 2$ECCO �# �!EF , ��J�� 0&�� +�� f��1�&�� %��& +��ℎ �ℎ� �� %�� 1��. 4 # = 2! (2,4)

��&Y: @ℎ� ��%�� %�� %�1�� )# # = !E �ℎ� ��f��&�� !E ≤ # ≤ 2!, �� 0 ≤ ! ≤ 2. ! = GE ! = s#

I� �� ℎ�� ℎ� ��%�� )�� )# �ℎ� ��1�� # = !E, �� # = 2! , )��+�� ! = 0 �� ! = 2. @� �� ℎ� &�3�� %��% �� ℎ� ��1�� , +� �3�%�� ℎ��5��&

&�� 0��% ��3 &�� %ℎ� �ℎ��%ℎ �ℎ� ��%��. I� �� ! = #2 �� &��1�� ! = s#. �� # )��+�� # = 0 �� # = 4. B B 4! + 2$√GtO �! �#uF = B 4 CO

E + 2!uF ]G/E√G �# = B 2# + 2s#uF − GOE − #$�#

= GOE + u[ #cO − Gc

w ]Fu = HwE + [E[ − wuw = 8. W1�&�� ℎ� ��%��&� �� W!�� 1 − 8 �� J��ℎ �ℎ� ��%��

�� %��: 1 − B B 4 − #E$EF �# �! ,[F 2 − B B ! + # + 1$HZH �! �#FZH , 3 − B B !E# − 2!#$�# �! , FZE[F 4 − B B sin ! + cos #$�! �#,xFExx

5 − B B ! sin # �# �!,CFxF 6 − B B �CyGzi GFzi {H �! �# , 7 − B B # �# �!,ghi CFxF 8 − B B �! �# GOGEH . In Exercises 9-14, integrate the func�on f(x, y) over the given region.

9 − � !, #$ = CG �1�� ℎ� ��%�� ℎ� �� f�� )�� )# �ℎ� &��

# = !, # = 2! , ! = 1 , ! = 2. 10 − � !, #$ = !E + #E �1�� ℎ� ��%�&�� %�� +ℎ�� 1�� 0,0$, 1,0$

�� 0,1$. 11 − � !, #$ = # − √! �1�� ℎ� ��%�&�� %�� 3 �ℎ� �� f��

)# �ℎ� &�� ! + # = 1. 12 − � !, #$ = !E + 3!# �1�� ℎ� ��%&� ': 0 ≤ ! ≤ 1, 0 ≤ # ≤ 1. 13 − � !, #$ = HCG �1�� ℎ� ��%&� ': 1 ≤ ! ≤ 2 , 1 ≤ # ≤ 2. 14 − � !, #$ = # cos !# �1�� ℎ� ��%&� ': 0 ≤ ! ≤ | , 0 ≤ # ≤ 1. I� W!�� 15 − 20 , �J��ℎ �ℎ� ��%�� %�� +�� f��1�&�� %��& +��ℎ �ℎ� �� %�� 1��.

15 − \ \ �# �! ,uZECF

16 − \ \ �# �!uZECE

, 17 − \ \ �! �# ,√GG

18 − \ \ �!�#.E√G

19 − B B �# �! }~H ,EF 20 − B B �! �# .H√GHF

W1�&�� ℎ� ��%��&� �� W!�� 21 − 23 )# �1�&��% �� f��1�&�� %��& �)�� )# ��1��% �ℎ� �� %��.

21 − \ \ !E �CG �!�# HG

, 22 − \ \ 2 #E sin !#EC

�# �! , 23 − \ \ ! �EG4 − #uZCO

F �#�!

24 − 7�� ℎ� 1�&�3� �� ℎ� ��&�� +ℎ�� )�� ℎ� ��%�� ℎ� !# − 0&�� ℎ�� )�� )# �ℎ� 0��)�&� # = 4 − !E �� ℎ� &�� # = 3! , +ℎ�&� �ℎ� ��0 �� ℎ� ��&�� )�� )# �ℎ� 0&�� 5 = ! + 4.

��

.�� = ∬ �.-

W! 1: 7�� ℎ� �� ℎ� ��%�� ' )�� )# # = ! �� # = !E �� ℎ� �� f��. y y=x (1,1)

. = B B �# �!CCOHF = B ! − !E$HF �! = COE − Cc

[ ]FH = Hw . y=x # = !E

W! 2: 7�� ℎ� �� ℎ� ��%�� ' ��&�� )# �ℎ� 0��)�&� # = !E �� ℎ� &�� # = ! + 2 . X�&Y: I� +� ��%�� +��ℎ ��0�� ! �ℎ�� # , +� +�&& ��1�� ℎ� ��%�� ' �� +� ��%�� 'H & 'E. y (2,4)

. = ∬ �.-` + ∬ �.-O = B B �! �#√GZ√GHF + B B �! �#√GGZEuH

�� ℎ� ��ℎ�� ℎ��, ��1��% �ℎ� �� y=x+2 R2 y=x2

�� %�� %�1��: R1 x

. = B B �# �! ,�yECOEZH �&��&# �ℎ�� &� �� 30&��

. = B #]COCyEEZH �! = B ! + 2 + !E$EZH �! = COE + 2! + Cc

[ ]ZHE = �E

First and second Moments and centers of Mass

p�� p�3�� 3�&�� ℎ�� 0&�� 1��% ��%�� !# − 0&��. ��#: � !, #$, p��: p = ∬ � !, #$ �.

7�� 3�3��: pC = ∬ #� !, #$ �., pG = ∬ !� !, #$ �.

�� 3��: !̅ = �t� , #� = �~�

Areas, Moments , and Centers of Mass

p�3�� 3�3��$: .)�� ℎ� ! − �!�� ∶ IC = ∬ #E� !, #$ �.

.)�� ℎ� # − �!�� ∶ IG = ∬ !E� !, #$ �.

.)�� ℎ� ��%��: I� = ∬ !E + #E$ � !, #$�. = IC + IG

'�� %#��: .)�� ℎ� ! − �!��: 'C = sIC p⁄

.)�� ℎ� # − �!��: 'G = sIG p⁄

.)�� ℎ� ��%�� ∶ '� = sI� p⁄

W! 3: . �ℎ�� 0&�� 1�� ℎ� ��%�&�� %�� )�� )# �ℎ� ! − �!�� ℎ� &�� ! = 1 �� # = 2! �� ℎ� �� f��. @ℎ� 0&�� # �� ℎ� 0�� !, #$�� !, #$ = 6! + 6# + 6. 7�� ℎ� 0&�� 3��, �� 3�3��, �� 3��

3�3�� , �� %#�� )�� ℎ� �� !��. X�&Y: p = \ \ � !, #$EC

F�# �! =H

F\ \ 6! + 6# + 6$EC

F�# �! = \ 6!# + 3#E + 6#$FECH

F �!

= \ 12!E + 12!E + 12!$HF

�! = 8![ + 6!E$FH = 14

7�� 3�3�� ∶ pC = \ \ #� !, #$ECF

�# �! = \ \ # 6! + 6# + 6$ECF

�# �!HF

= \ 3!#E + 2#[ + 3#E]FECHF

�! = \ 12![ + 16![ + 12!E$�!HF

= 3!u + 4!u + 4![]FH = 11.

pG = \ \ !� !, #$ECF

�# �! = \ \ ! 6! + 6# + 6$ECF

�# �!HF

= \ 6!E# + 3!#E + 6!#$FEC�!HF

= \ 12![ + 12![ + 12!E$�!HF

= 6!u + 4![$FH = 10

�� 3��: !̅ = �t� , #� = �~� , !̅ = HFHu = eQ , #� = HHHu

IC = ∬ #E� !, #$ �. = B B #E 6! + 6# + 6$ECF �# �!HF = B 2!#[ + [E #u + 2#[$FEC �!HF

= B 16!u + 24!u + 16![$�!HF = 8!e + 4!u$FH = 12

��3�&��&#, �ℎ� 3�3�� )�� ℎ� # − �!�� IG = ∬ #E� !, #$ �. = B B !E 6! + 6# + 6$ECF �# �!HF = 39/5

I� = IC + IG = 12 + [�e = ��e 'C = sIC p⁄ = s12 14⁄ = s6 7⁄ , 'G = sIG p⁄ = s39 70⁄ , '� = sI� p⁄ = s99 70⁄ W! 4: 7�� ℎ� �� ℎ� ��%�� ℎ� �� f�� ℎ�� )�� )�1�

)# �ℎ� &�� # = ! �� )�&�+ )# �ℎ� 0��)�&� # = !E. X�&Y: X�� = 1 , p = \ \ 1C

�# �! = \ #HF

]COC �! = \ ! − !E$HF

�! = !E2 − ![3 ]FH = 16

pC = B B #CCOHF �# �! = B GOEHF ]COC �! = B CO

E − C�E $HF �! = Cc

w − C�HF]FH = HHe

pG = B B !CCOHF �# �! = B !#HF ]COC �! = B !E − ![$HF �! = Cc[ − uu]FH = HHE

��3 �ℎ�� 1�&�� p, pC �� pG , +� �� ∶ !̅ = �t� = HE , #� = �~� = Ee

@ℎ� �� ℎ� 0�� LHE , Ee M.

I� W!�� 1 − 8, �J��ℎ �ℎ� ��%�� )�� )# �ℎ� %�1�� &�� 1��. @ℎ�� ℎ� ��%�� )# ��)&� ��%��&�:

1$ @ℎ� �� !�� ℎ� &�� ! + # = 2. 2$ @ℎ� ! − �!��, �ℎ� ��1� # = �C , �� ℎ� &�� ! = 0, ! = ln 2. 3$ @ℎ� # − �!�� , �ℎ� &�� # = 2!, �� ℎ� &�� # = 4. 4$ @ℎ� 0��)�&� ! = −#E �� ℎ� &�� # = ! + 2. 5$ @ℎ� 0��)�&� ! = #E �� ! = 2# − #E. 6$ @ℎ� 0��)�&� ! = # − #E �� ℎ� &�� ! + # = 0. 7$ @ℎ� ��3��&&�0�� # = 2√1 − !E �� ℎ� &�� ! = ±1, # = −1. 8$ .)�1� )# # = !E, )�&�+ )# # = −1 , �� ℎ� &�� )# ! = −2, �� ℎ� ��%ℎ� )# # = 2! − 1. XJ��ℎ �ℎ� ��%�� ℎ�� ℎ� �� ℎ� ��%��&� �� !�� 9 − 14

9$ B B �! �#EGtOcwF , 10$ B B �# �!C EZC$ZC[F , 11$ B B �# �!��g Cghi C

��F , 12$ B B �! �#GyEGOEZH , 13$ B B �# �!HZCZECFZH + B B �# �!HZCZ~O

EF . 14$ B B �# �!FCOZuEF + B B �# �!√CFuF . 15$ 7�� ℎ� �� 3�� ℎ�� 0&�� # � = 3, )�� )# �ℎ�

&�� ! = 0, # = !, �� ℎ� 0��)�&� # = 2 − !E �� ℎ� �� f��. 16$ 7�� ℎ� 3�3�� %#�� )�� ℎ� ��

�!�� ℎ�� %�&�� 0&�� # � )�� )# �ℎ�

&�� ! = 3 �� # = 3 �� ℎ� �� f��.

17$ 7�� ℎ� �� ℎ� ��%�� ℎ� �� f�� )�� )# �ℎ�

! − �!��, �ℎ� 0��)�&� #E = 2! �� ℎ� &�� ! + # = 4. 18$ 7�� ℎ� �� %�&�� %�� 3 �ℎ� �� f��

)# �ℎ� &�� ! + # = 3.

Polar coordinates:- Represent by the pair �, �$ +ℎ�� $�� # ��3 �ℎ� ��%�� !�� 0�� 0$, �� ℎ� �� %&� )��+�� & ��# �� # �;. @ℎ� ��%&� �$�� 0��1� +ℎ�� 3�� P (r, �)

�� &�J+�� %��1� +ℎ�� 3�� r

�&��J+��. �

I� 0�&�� ℎ� �� +�&& )� � �, �$ o initial ray x

�� $�� 0�&�� %�� %�1�� )# 0 ≤ ℎH �$ ≤ � ≤ ℎE �$, � ≤ � ≤ � , +ℎ�� − − − � ≤ 2|

��, I = ∬ � �, �$- �. = B B � �, �$aO �$a` �$��

I� � �, �$ = 1, �ℎ�� ℎ� 1�&�� ℎ� ��%��& �� $�� ℎ� �� '$

I = ∬ �� - � � = � �$

X� .�� ' = B �OE�� = . �

. �� ℎ� �� &�� )# �ℎ� ��1� � = � �$ �

.�� )��+�� +� ��1�� . = B �̀OZ�OOE��

Double Integral in Polar Coordinates

�E �H

W! 1: 7�� ℎ� �� &�� )# �ℎ� &�3�� E = 2�E cos � . ��&Y: . = B �O

E�� = B E TO ��g E�E��

��+ �� 1�&�� J� cos 2� = 0

2� = cosZH 0 = ∓ xE → � = ∓ xu , �� = − xu �� = xu

. = B E TO ��g E�Ex/uZx/u �� = TO ghi E�E ]Zx/ux/u = TOE ¢sin xE − sin − xE£ = TO

E [1 + 1] = �E

�ℎ� ��& �� = 2 �E

W! 2: 7�� ℎ� �� )�� )# �ℎ� ��1� � = 2 + cos � , �� ℎ� &�� = 0, � = xE

X�&Y: . = B Ey��g �$OE�D�O�DF �� = HE B 4 + 4 cos � + cosE �$�OF ��,

= HE ¤4� + 4 sin � ⃒F�O + B HZ��g E�$E

�OF ��¦=HE ¤4� + 4 sin � + HE � − Hu sin 2� |F

�O¦ = | + 2 + x{ = �{ | + 2. W! 3: 7�� ℎ� �� ℎ� �� = � 1 + cos �$�� ℎ� ��&� � = �

X�&Y: ℎ�� +� ℎ�1� �H & �E �� +ℎ��ℎ �H = � 1 + cos �$ �� E = �

�� 3�� ℎ� &�3�� %�� &�, &�� H = �E � = xE

�� = � 1 + cos �$, cos � = 0 → � = cosZH 0 = ∓ |/2

. = B �̀OZ�OOE�Dx/E�DZx/E �� = 2 B [TO Hy��g �$OZTO]Ex/EF �� = � = − xE

= �E B 1 + 2 cos � + cosE � − 1$x/EF �� = �E B 2 cos � + HZ��g E�$Ex/EF ��

= �E[2 sin � + HE � − Hu sin 2�]F�O = �E ¢2 + xu£ = TO

u [8 + |].

Changing Cartesian Integrals into Polar Integrals

Sometimes adouble integrals eaiser to evaluate using polar coordinates. @ℎ�� 0��&&# �� ℎ� ��%�� %�� )� ��&# �� % � 0�&�� f��. @ℎ� ��&&�+��% ��3�&� �� 1�� )��+�� %�&� �� 0�&��

�� . ! = � cos � , # = � sin � , �E = !E + #E , tan � = GC

'��%�&� �� ;�&��

∬ � !, #$ �. ∬ � �, �$ � ��

�. = �! �# �. = � ��

Y ∆�

�E �E = �E�

∆# �H = �H� ∆� = �E − �H

∆! x �H

�� &��%�ℎ = � = ��

&�� H ≅ �E ≅ �

∆. = � ∆� ∆� , ∆� = ��

∆� = �� , �. = � ��

�� %��& ! = � cos � , # = � sin �

�� ! = % �, �$ , # = ℎ �, �$

∬ � !, #$- �! �# = ∬ � % �, �$, ℎ �, �$$µ |¶(�, �)| ��

@ℎ� �� ¶ �, �$�� ℎ� ¶��)�� ℎ� �� 3��. I� 3��

ℎ�+3��ℎ �ℎ� ��3�� !0��% �� % �ℎ� �� 0��

�� · �� · �� 3�� '. @ℎ� ¶��)�� 3�� ¶��)�� ℎ� �� 3�� ! = % �, �$ , # = ℎ �, �$

¶ �, �$ = ¸¹C¹� ¹C¹�¹G¹� ¹G¹�¸ = ¹C¹� ¹G¹� − ¹G¹� ¹C¹� , �� ¶ �, �$ = ¹ C,G$¹ �,�$

ℎ�� +� ℎ�1� ! = � cos � , # = � sin �

¶ �, �$ = ¸¹C¹� ¹C¹�¹G¹� ¹G¹�¸ = ºcos � −� sin �sin � � cos � º = � cosE � + sinE �$ = �

�� ∬ � !, #$- �!�# = ∬ � � cos �µ , � sin �$ |�|�� =∬ �(� cos �µ , � sin �) �� .

@� �1�&�� » �(�, �)-

�. �1�� %�� ' �� 0�&�� , ��%��%

�� +��ℎ ��0�� ℎ�� +��ℎ ��0�� , ��J� �ℎ� ��&&�+��% ��0�: 1) XJ��%ℎ �ℎ� ��%�� &�)�& �ℎ� )��% ��1��. y

!E + #E = �E 2 !E + #E = 4

4 = �E, � = 2 √2 ' (√2, √2)

# = � sin � , √2 = � sin � , � = √Eghi � = √2 csc � x

2) 7�� ℎ� � − &�3�� %��: I3�%�� # (^)��3 �ℎ� ��%�� % �ℎ��%ℎ (')�� ℎ� �� % (�). p��J (�)1�&�� +ℎ�� (&)�� &��1�� (').

Finding limits of Integration in Polar Coordinates

@ℎ�� 1�&�� − &�3�� 0�� ℎ� ��%&� �$ �ℎ�� ^$ y &��1� �� = 2 3�J�� +��ℎ �ℎ� 0��1� ! − �!��. 2 R 3$ 7�� ℎ� � − &�3�� %��: √2 �� = √2 csc � 7�� ℎ� �3�&&�� &��%�� x

� − 1�&�� ℎ�� )�� '. y L X� �ℎ� ��%��& �� √2 �E&��%�� xE

�H�3�&&�� x

» � �, �$-

�. = \ \ � �, �$�ODE

�̀ D√E �g� �� .

�DxE�Dxu

W! 1: 7�� ℎ� 3�3�� )�� ℎ� ��%�� ℎ�� 0&�� # � !, #$ = 1, )�� )# �ℎ� f�� &� !E + #E = 1 �� ℎ� �� f��. X�&Y: @ℎ� 3�3�� I� � = xE +ℎ�� I� = ∬ !E + #E$- �. !E + #E = 1 L

I� = B B !E + #E$√HZCOF �# �!HF r=1 � = 0 I��%�� +��ℎ ��0�� # %�1��: o r=0 x

B !E √1 − !EHF + HZCO$cO[ �!, �� %��& ��&� �� 1�&�� +��ℎ�� )&��. r�� +� �ℎ��%� �ℎ� ��%��& ��%��& �� 0�&�� , ��)��% , ! = � cos � , # = � sin � , !E + #E = �E �� 0&��% �!�# )# ��

I� = \ \ !E + #E$√HZCO

F�#�!H

F= \ \ �E$H

F� ��

I� = \ �u4 ]FH ��xE

F= \ 14

�� = |8

W! 2: W1�&�� ∬ �COyGO- �# �!, +ℎ�� ' �� ℎ� ��3��&�� %�� )�� )# �ℎ� ! − �!�� ℎ� ��1� # = √1 − !E. ∬ �COyGO- �# �! = B B ��OHFxF � �� = B HE ��O]FHxF �� = B HExF � − 1$�� = xE � − 1$

# = √1 − !E

� = 1

-1 � = | � = 0 1 x

W! 3: ��3�� ℎ� 1�&�3� �� ℎ� ��&�� )�&�+ �ℎ� �� !, #$ = 4 − !E − #E, �)�1� �ℎ� !# − 0&�� 1�� ℎ� ��%�� )��

)# !E + #E = 1 & !E + #E = 4. ∬ � !, #$ �. = ∬ � �, �$ � ��

� !, #$ = 4 − !E + #E$ = 4 − �E

!E + #E = �E

� = 1 & � = 2

\ \ 4 − �E$EH

� �� = \ \ 4� − �[$EH

�� ExF

= \ 4�E2ExF

− �u4 ]HE��

B 8 − 4$ExF − L2 − HuM �� = B �uExF �� = �u �]FEx = �E |. W! 4: ��3�� ℎ� 1�&�3� �� 5 = s9 − !E − #E�1�� ℎ� ��%�� !E + #E ≤ 4 �� ℎ� �� . � !, #$ = s9 − !E − #E , � �, �$ = √9 − �E

!E + #E ≤ 4 , �E ≤ 4, � ≤ 2

\ \ Ls9 − �EMEF

� �� xE

F= \ − 12

\ 9 − �E$HEE

F −2�$��

\ − 12 23 xE

F. 9 − �E$[/E]FE$ �� = \ 9 − 5√53

$�� = ¼27 − 5√56 ½ |

W! 5: W1�&�� B B s !E + #E$[O√�ZCOF[F �#�! . X�&Y: )# ��1��% �� 0�&��

� �, �$ = s �E$[O = �[, # ≥ 0 �� # ≤ s9 − !E

B B �[�D[�DFx/EF . � �� = B ��ex/EF ]F[ �� = Eu[HF | ! ≥ 0 �� ! ≤ 3

#E ≤ 9 − !E

#E + !E ≤ 9 , �E ≤ 9

� ≤ 3

I� � !, #, 5$�� &�� )�� %�� 0��, ��ℎ ��

�ℎ� ��%�� 0�� )# � ��&�� )�&& �� &�30 �� &�#, �ℎ�� ℎ� ��%��& �� 1��

� 3�# )� �� 0&� ��%��& �� 1�� . 5

∭ � !, #, 5$À �! �# �5

Triple Integrals in Rectangular Coordinates

I� � !, #, 5$�� f��& 1 �ℎ�� ℎ� ��0&� ��%��& +�&& )� �ℎ� 1�&�3� �� &�� , )�� %�� 0��

1 = ∭ �1À . @ℎ�� %��& ��)&�� &��&�� ℎ� 1�&�3�� &�� &�� )# ��1��

��. Á�� Â�� Ã��

�� 1�&�� 0&� ��%��& )# �00&#��% � �ℎ�� 3��& 1�� 7�)�� @ℎ��3 �� 1�&�� )# �ℎ�� 0�� %&� ��%��. .� +��ℎ

��)&� ��%��&�, �ℎ�� %��3�� 0�� % �ℎ� &�3�� %�� ℎ�� %&� ��%��&�

@� �1�&�� ∭ � !, #, 5$À �1 z

�1�� %�� , ��%�� +��ℎ ��0�� Ä , �ℎ�� +��ℎ ��0�� Å, ��&&# +��ℎ ��0�� !. 5 = �2 !, #$

1$ XJ��ℎ �ℎ� ��%�� &��% +��ℎ �� " shadow" ' 1��& 0��É��$�� ℎ� !# − 0&��. &�)&� �ℎ� D �00�� &�+�� )��% �� ℎ� �00�� &�+�� )��% ��1�� '. 5 = �1 !, #$ 2$ 7�� ℎ� 5−&�3�� %��: ��+ � &�� p 0��% �ℎ��%ℎ ��#0��& 0�� !, #$�� ' 0��&&�& �� ℎ� 5 − �!��. a y .� Ä ��, p �� 5 = �H !, #$ # = %H !$ �� &��1�� 5 = �E !, #$. @ℎ�� ℎ� x b ' # = %E !$ 5 − &�3�� %��. 3$ 7�� ℎ� Å − &�3�� %��: ��+ � &�� ^ �ℎ��%ℎ !, #$0��&&�& �� ℎ� # − �!��. .� # ��, ^ �� ' ��

# = %H !$�� &��1�� # = %E !$. leave at z2=f2(x,y) @ℎ�� ℎ� # − &�3�� %��. D M 4$ 7�� ℎ� ! − &�3�� %��: �ℎ�� ! − &�3�� ℎ�� &�� && &�� ℎ��%ℎ ' 0��&&�& �� ℎ� # − �!�� enter at z1=f1(x,y) ! = � �� ! = ) �� ℎ� 0��% ��%��$ y @ℎ�� ℎ� ! − &�3�� %��. x R y=g1(x) y=g2(x) L

@ℎ� ��%��& �� \ \ \ � !, #, 5$ÊDËO C,G$ÊDË̀ C,G$

GD_O C$GD_` C$

CDSCDT

�5 �# �!. 7�&&�+ ��3�&�� 0�� #�� ℎ��%� �ℎ� �� %��. @ℎ� "shadow" �� %�� &�� ℎ� 0&�� ℎ� &�� +� 1��)&�� +��ℎ ��0��

�� +ℎ��ℎ �ℎ� �� %�� J�� 0&��. @ℎ� �)�1� 0�� 00&�� +ℎ��1�� &�� %�� )�� )�1� �� )�&�+ )# � ��, �� +ℎ�� ℎ� "shadow" ��%�� ' �� )�� )# � &�+�� 00�� 1�. W! 1: 7�� ℎ� 1�&�3� �� ℎ� ��%�� &�� )# �ℎ� �� 5 = !E + 3#E, �� 5 = 8 − !E − #E. X�&Y: @ℎ� 1�&�3� �� 1 = ∭ �5 �# �!À D (-2,0,4)

@� �� ℎ� &�3�� %�� (2,0,4) (-2,0,0)

�1�&��% �ℎ� ��%��&, +� �� J��ℎ

�ℎ� ��%��. @ℎ� �� %�� (2,0,0) L y

�� ℎ� �&&�0��& �#&�� !E + 3#E = 8 − !E − #E

�� !E + 2#E = 4, 5 > 0

(x,y) x2+2y

Z=x2+3y

Z=8-x2-y

@ℎ� )��# �� ℎ� ��%�� ', �ℎ� 0��É�� ℎ� !# − 0&��, �� &&�0�� +��ℎ �ℎ� ��3� �f�� !E + 2#E = 4. @ℎ� upper )��# �� ' �� ℎ� ��1� # = s 4 − !E$/2. @ℎ� &�+�� )��# ��

�ℎ� ��1� # = −s 4 − !E$/2. 5 − &�3�� %��, �ℎ� &�� p 0��% �ℎ��%ℎ � �#0��& 0�� !, #$�� '

0��&&�& �� ℎ� 5 − �!�� 5 = !E + 3#E �� &��1�� 5 = 8 − !E − #E. # − &�3�� %��.@ℎ� &�� ^ �ℎ��%ℎ !, #$ 0��&&�& �� ℎ� # − �!��

' �� # = −s 4 − !E$/2 �� &��1�� # = s 4 − !E$/2. 7��&&# +� �� ℎ� ! − &�3�� %��. .� ^ �+��0� �� ', �ℎ� 1�&�� ! 1�� 3 ! = −2

�� −2,0,0$ �� ! = 2 �� 2,0,0$. @ℎ� 1�&�3� �� 1 = Í �5 �# �!

À= \ \ \ �5 �# �!.{ZCOZGO

COy[GO

s uZCO$/E

Zs uZCO$/EE

1 = \ \ 8 − 2!E − 4#E$s uZCO$/E

Zs uZCO$/EE

ZE�# �!

1 = \[ 8 − 2!E$# − 43 #[]Zs uZCO$/Es uZCO$/EEZE

1 = \[2 8 − 2!E$ 4 − !E2 $H/EEZE

− 83 4 − !E2 $[/E]�!

1 = \[8 4 − !E$2 4 − !E2 $H/EEZE

− 83 4 − !E2 $[/E]�!

1 = \ Î8 − 83Ï ¼4 − !E2 ½[/EEZE

�! = 163 \ 4 − !E$[/EEZE

&�� ! = 2 sin � , �! = 2 cos � ��

! − &�3�� ∶ −2 �� 2 +�&& )� − xE �� xE

1 = 163 \ 4 − 4 sinE �$ [/Ex/E

–x/E2. cos � �� = 8 . 163 \ 1 − sinE �$[/E cos � ��x/E

–x/E

1 = 8 . 163 \ cosE �$[E cos � ��x/E–x/E

= 8 . 163 \ cosu � ��x/EZx/E

1 = 8 . 163 \ cosE �$Ex/E

–x/E �� = 8 . 163 \ Î1 + cos 2�2 ÏEx/E

–x/E ��

1 = 2 . 163 \ 1 + 2 cos 2� + cosE 2�$x/E–x/E

�� W! 2: 7��% �ℎ� &�3�� %�� ℎ� �� # �5 �!

�� 0 �ℎ� &�3�� %�� 1�&��% �ℎ� ��0&� ��%��& �� !, #, 5$�1�� ℎ� ��ℎ�� +��ℎ 1�� 0,0,0$, 1,1,0$, 0,1,0$ �� 0,1,1$ .

��&Y: +� �J��ℎ � �&��% +��ℎ �� ℎ��+ ' �� ℎ� !# − 0&�� 1 (0,1,1)

@ℎ� �00�� %ℎ� − ℎ��$)��% �� x+z=1 y=x+z D

&�� ℎ� 0&�� # = 1. �ℎ� &�+�� &�� − ℎ��$ (0,1,0)

)��% �� &�� ℎ� 0&�� # = ! + 5 1 (1,1,0)

@ℎ� �00�� )��# �� ' �� ℎ� &�� 5 = 1 − !.

@ℎ� &�+�� )��# �� ℎ� &�� 5 = 0. 7�� +� �� ℎ� # − &�3�� %��&

@ℎ� &�� ℎ��%ℎ � �#0��& 0�� !, 5$�� ' 0��&&�& �� ℎ� # − �!��

� �� # = ! + 5 , �� &��1�� # = 1

��!� +� �� 5 − &�3�� %��&, �ℎ� &�� ^ �ℎ��%ℎ !, 5$ 0��&&�& �� ℎ� 5 − �!�� ' �� 5 = 0 �� &��1�� 5 = 1 − !$. 7��&&# +� �� ℎ� ! − &�3�� %��&. .� ^ �+��0� �� ', �ℎ� 1�&��

! 1�� 3 ! = 0 �� ! = 1 , @ℎ� ��%��& ��

\ \ \ � !, #, 5$HCyÊ

�# �5 �!. W! 3: '�1��% W!�30&� 2 ��% �ℎ� �� 5 �# �!

��&Y: @� ��%�� !, #, 5$�1�� ℎ� ��ℎ�� ℎ� �� 5 �# �!, +� 0��3 �ℎ� ��0� �� ℎ� ��&&�+��% +�#. 7�� +� �� ℎ� 5 − &�3�� %�� . . &�� 0��&&�& �� ℎ� 5 − �!�� ℎ��%ℎ � �#0��& 0�� !, #$�� ℎ� !# − 0&�� ℎ��+ �� ℎ� ��ℎ��

�� 5 = 0 �� !�� ℎ��%ℎ �ℎ� �00�� 0&�� +ℎ�� 5 = # − !

��!� +� �� ℎ� # − &�3�� %��, �� ℎ� !# − 0&��, +ℎ�� 5 = 0, �ℎ�

�&�0�� ℎ� ��ℎ�� ℎ� 0&�� &��% �ℎ� &�� # = !. . &�� ℎ��%ℎ !, #$0��&&�& �� ℎ� # − �!�� ℎ� �ℎ��+ �� ℎ� !# − 0&�� # = ! �� !�� # = 1. 7��&&# +� �� ℎ� ! − &�3�� %��. .� �ℎ� &�� 0��&&�& �� ℎ� # − �!�� ℎ� 0��1�� 0 �+��0� �� ℎ� �ℎ��+

�ℎ� 1�&�� ! 1�� 3 ! = 0 �� ! = 1 �� ℎ� 0�� 1,1,0$.

@ℎ� ��%��& �� \ \ \ � !, #, 5$GZCF

�5 �# �!

I� � !, #, 5$ = 1 �ℎ�� 1 = \ \ \ �5 �# �!GZCF

= \ \ # − !$HC

�# �!

1 = \[12 #E − !#]GDCGDHHF

�! = \ Î12 − ! + 12 !EÏ �!HF

= [12 ! − 12 !E + 16 ![]FH = 16

+� %�� ℎ� ��3� ��&� )# ��%��% +��ℎ �ℎ� �� # �5 �!

1 = \ \ \ �# �5 �!HCyÊ

W! 4: Ñ��% �� %�� z

W��ℎ �� ℎ� ��&&�+��% ��%��&� %�1�� ℎ� 1�&�3� �� ℎ� ��&�� ℎ�+� �� ℎ� ��%�� y+z=1

�$ B B B �! �# �5EFHZÊFHF

)$ B B B �! �5 �#EFHZGFHF 2 y

�$ B B B �# �! �5HZÊFEFHF x

�$ B B B �# �5 �!HZÊFHFEF

�$ B B B �5 �! �#HZGFEFHF

�$ B B B �5 �# �!HZGFHFEF

+� +��J �� +��ℎ �ℎ� ��%��&� �� 0�� )&�

1 = \ \ \ �! �5 �#EF

= \ \ 2HZGF

�5 �# = \ 2 1 − #$ HF

�# = 1

.&�� 1 = \ \ \ �# �! �5HZÊF

= \ \ 1 − 5$EF

�! �5 = \[! − 5!]FEH

1 = \ 2 − 25$�5HF

@ℎ� ��%��&� �� 0�� , �, �, �� &�� %�1� 1 = 1

��

@ℎ� �1��%� 1�&�� 1�� %�� ' �� 0�� )# �ℎ� ��3�&�

.1��%� 1�&�� 1�� ' = HÒ�ÓÔÕ} �Ë - ∭ 7 �1-

I� 7 !, #, 5$ = s!E + #E + 5E , �ℎ�� ℎ� �1��%� 1�&�� 7 �1�� ' �� ℎ� �1��%� �� 0�� ' ��3 �ℎ� ��%��. I� 7 !, #, 5$�� ℎ� ��# �� ℎ� ��&��

�ℎ�� 0�� %�� ' �� 0��, �ℎ�� ℎ� �1��%� 1�&�� 7 �1�� ' �� ℎ� �1��%� ��# �� ℎ� ��&�� 3�� 0�� 1�&�3�. W! 3: 7�� ℎ� �1��%� 1�&�� !, #, 5$ = !#5 �1�� ℎ� ��)� )�� )# �ℎ�

�� 0&�� ℎ� 0&�� ! = 2 , # = 2 , �� 5 = 2 �� ℎ� �� . ��&Y: �� J��ℎ �ℎ� ��)� +��ℎ ��%ℎ ��& �� ℎ�+ �ℎ� &�3�� %��

The volume of the cube is 2$ 2$ 2$ = 8

@ℎ� 1�&�� ℎ� ��%��& �� 1�� ℎ� ��)� �� B B B !#5EFEFEF �! �# �5 =

B B COEEFEF # 5 ]FE �# �5 = B B 2 # 5 �# �5EFEF = B 2 GO

EEF ]FE �5 = B 4 5 �5EF = 4 ÊOE ]FE = 8.

∴ .1��%� 1�&�� !#5 �1�� ℎ� ��)� = HÒ�ÓÔÕ} ∭ !#5 �1 = H{ 8$ = 1

Masses and Moments in Three Dimensions

p��: p = ∭ �- �1 � = ��#$

�� 3�3�� )�� ℎ� �� 0&��: pGÊ ∭ !- � �1, pCÊ = ∭ # - � �1, pCG = ∭ 5- � �1

�� 3��: !̅ = ∭ CÙ UÒ� , #� = ∭ GÙ UÒ� , 5̅ = ∭ Ê Ù UÒ�

p�3�� 3�3��$

IC = ∭ #E + 5E$ � �1, IG = ∭ !E + 5E$ � �1, IÊ = ∭ !E + #E$ � �1

p�3�� )�� &�� ^: IÓ = ∭ �E � �1 , � !, #, 5$: �� 3 0�� !, #, 5$ �� &�� ^. '�� %#�� )�� &�� ^: 'Ú = sIÚ p⁄

W! 1: 7�� IC, IG , IÊ �� ℎ� ��%�&�� &�� # � �ℎ�+� �� ℎ� ��%��

IC = B B B #E + 5E$ÛOZÛOÜOZÜO

ÝOZÝO � �! �# �5 c

= 8 B B B #E + 5E$T/EFS/EFV/EF � �! �# �5 y

4 � � B B #E + 5E$�# �5ÜOFÝOF x a

= 4� � B Gc[V/EF + 5E# ]GDFGDS/E = 4� � B Sc

EuV/EF + ÊOSE $ �5

4� � LScVu{ + VcSu{ M = TSV Ù HE )E + �E$ = �HE )E + �E$. ��3�&��#, IG = �HE �E + �E$ �� IÊ = �HE �E + )E$. W! 2: 7�� ℎ� �� 3�� &�� # � )�� )�&�+ )# �ℎ� ��J ': !E + #E ≤ 4 �� ℎ� 0&�� 5 = 0 �� )�1� )# �ℎ� 0��)�&�� 5 = 4 − !E − #E

��&Y: )# ��33��# , !̅ = #� = 0 z

. @� �� 5̅ +� �� &��&��

pCG = ∬ B 5 ÊDuZCOZGOÊDF- � �5 �# �! z=4-x2-y

= ∬ ÊOE- ]FuZCOZGO � �# �!

= ÙE ∬ 4 − !E − #E$E- �# �! y

= ÙE B B 4 − �E$EEFExF � �� 0�&�� $ x

= ÙE B [− Hw 4 − �E$[]FEExF �� = HwÙ[ B ��ExF = 32 xÙ[ . p = » \ � �5 �# �!uZCOZGO

F-= 8|� →→ 5̅ = pCGp = 43 , �� !̅, #�, 5̅$ = Î0,0, 43Ï.

Triple Integrals

1$ �� ! �� 0&� ��%��&� �� ℎ� 1�&�3� �� ℎ� ��%�&�� &�� ℎ� �� )�� )# �ℎ� �� 0&�� ℎ� 0&�� ! = 1, # = 2 , �� 5 = 3. W1�&�� ℎ� ��%��&�.

2$ �� ! �� 0&� ��%��&� �� ℎ� 1�&�3� �� ℎ�� 3 �ℎ� �� )# �ℎ� 0&�� 6! + 3# + 25 = 6. W1�&�� ℎ� ��%��&�. 3$ �� ! �� 0&� ��%��&� �� ℎ� 1�&�3� �� ℎ� ��%�� &�� )# �ℎ� �#&�� !E + 5E = 4, �� ℎ� 0&�� # = 3. W1�&�� ℎ� ��%��&�. 4$ W1�&�� ℎ� ��%��&�:-

IH = \ \ \ !E + #E + 5E$HF

�5 �# �!, IE = \ \ \ �5 �! �# {ZCOZGO

COy[GO

I[ = \ \ \ 1!#5 �! �# �5 }H

, Iu = \ \ \ �5 �# �! [Z[CZGF

Ie = B B B # sin 5xFxFHF �! �# �5, Iw = B B B ! �5 �# �!uZCOZGFHZCOFHF 5$ @ℎ� ��%�� %�� ℎ� ��%��& z Top: y+z=1 B B B �5 �# �!HZGFHCOHZH , �ℎ�+� �� ℎ� ��%�� , side:y=x2 (-1,1,0) '�+�� ℎ� ��%��& �� f��1�&�� x 1 (1,1,0) �� ℎ� �� $ �# �5 �!, )$ �# �! �5, �$ �! �# �5, �$ �! �5 �#, �$ �5 �! �#. (0,-1,1) z=y

2 z 6$ 7�%�� )�&�+ �ℎ�+� �ℎ� ��%�� (1,-1,1) ��%�� ℎ� ��%��& (1,-1,0) y B B B �5 �# �! .GOFFZHHF x '�+�� ℎ� ��%��& �� f��1�&�� ℎ� �� $ �# �5 �!, )$ �# �! �5, �$ �! �# �5, �$ �! �5 �#, �$ �5 �! �#. 7$ 7�� ℎ� 1�&�3� �� ℎ� ��%�� )��+�� ℎ� �#&�� 5 = #E �� ℎ� !# − 0&�� ℎ�� )�� )# �ℎ� �� 1��& 0&�� ! = 0, ! = 1 , # = −1 , # = 1. z

8$ 7�� ℎ� 1�&�3� �� ℎ� ��%�� ℎ� �� )�� )# �ℎ� �� 0&��, �ℎ� 0&�� # + 5 = 2, �� ℎ� �#&�� ! = 4 − #E. Z

Multiple Integrals · CHAPTER THREE (Multiple Integrals) Page 1 ... Multiple Integrals Double...

Documents

Transcript of Multiple Integrals · CHAPTER THREE (Multiple Integrals) Page 1 ... Multiple Integrals Double...

MULTIPLE INTEGRALS 16. 2 16.3 Double Integrals over General Regions MULTIPLE INTEGRALS In this section, we will learn: How to use double integrals to.

Multiple Integrals 12. Double Integrals over General Regions 12.3.

Chapter 15 – Multiple Integrals 15.4 Double Integrals in Polar Coordinates 1 Objectives: Determine how to express double integrals in polar coordinates.

exams.skule.ca · Web viewAER210. Multiple Integrals. Integrals as a function of a Parameter. Double integrals . Rectangular and nonrectangular regions. Fubini’s Theorem: can switch

MULTIPLE INTEGRALS 16. 2 MULTIPLE INTEGRALS In this chapter, we extend the idea of a definite integral to double and triple integrals of functions of.

MULTIPLE INTEGRALS - KSUfac.ksu.edu.sa/sites/default/files/chap15_sec4.pdf · 2014. 2. 19. · MULTIPLE INTEGRALS 15.4 Double Integrals in Polar Coordinates In this section, we will

Multiple Integration Double Integrals, Volume, and ...profb.yolasite.com/resources/Multiple Integration.pdfMultiple Integration Double Integrals, Volume, and Iterated Integrals In

ESSENTIAL CALCULUS CH12 Multiple integrals. In this Chapter: 12.1 Double Integrals over Rectangles 12.2 Double Integrals over General Regions 12.3 Double.

Chapter 14 Multiple Integrals 1. Double Integrals, Iterated Integrals, Cross-sectionsfstitl/2015-matb210/2015-lecture-008.pdf · 2016-10-18 · Chapter 14 Multiple Integrals.. 1.

Multiple Integration: Using Double Integrals- Example 2

CHAPTER 14 Multiple Integrals 14.1 Double Integrals ... · PDF fileDouble Integrals Changing to Better Coordinates ... Vector Calculus Vector Fields Line Integrals ... 16 Mathematics

Chapter 15. Multiple Integrals 15.4. Double Integrals in Polar …faculty.etsu.edu/gardnerr/2110/notes-12E/Beamer-Slides/Proofs-15-4… · Chapter 15. Multiple Integrals 15.4. Double

Chapter 15 Multiple Integrals - abbymath.com · Multiple Integrals 15-2 & 15-3 Iterated Integrals 15-1, 15-2, & 15-3 Double Integrals and Volume 15-4 Double Integrals in Polar Coordinates

Multiple Integration: Using Double Integrals- Example 1

Double Integrals over General Regions. Double Integrals over General Regions Type I Double integrals over general regions are evaluated as iterated integrals.

Chapter 3 Multiple Integral 3.1 Double Integrals 3.2 Iterated Integrals 3.3 Double Integral… · Chapter 3 Multiple Integral 3.1 Double Integrals 3.2 Iterated Integrals 3.3 Double

Multiple Integrals 12. Triple Integrals 12.7 3 Triple Integrals We have defined single integrals for functions of one variable and double integrals for.

MULTIPLE INTEGRALS 15. MULTIPLE INTEGRALS 15.5 Applications of Double Integrals In this section, we will learn about: The physical applications of double.

Multiple Integration Triple Integralsferrantetutoring.com/wp-content/...tripleIntegrals.pdf · Triple integrals are completely analogous to double integrals we introduced in the previous