|
| |
|
![[¹ÌÀûºÐ]¼ö·Å, ¹ß»ê, ±ØÇÑ (1 ÆäÀÌÁö)](/View/10_Sequences_Infinite_Series_Improper_Integrals_hwp_01_.gif "[¹ÌÀûºÐ]¼ö·Å, ¹ß»ê, ±ØÇÑ (1 ÆäÀÌÁö)")
![[¹ÌÀûºÐ]¼ö·Å, ¹ß»ê, ±ØÇÑ (2 ÆäÀÌÁö)](/View/10_Sequences_Infinite_Series_Improper_Integrals_hwp_02_.gif "[¹ÌÀûºÐ]¼ö·Å, ¹ß»ê, ±ØÇÑ (2 ÆäÀÌÁö)")
![[¹ÌÀûºÐ]¼ö·Å, ¹ß»ê, ±ØÇÑ (3 ÆäÀÌÁö)](/View/10_Sequences_Infinite_Series_Improper_Integrals_hwp_03_.gif "[¹ÌÀûºÐ]¼ö·Å, ¹ß»ê, ±ØÇÑ (3 ÆäÀÌÁö)")
|
![[¹ÌÀûºÐ]¼ö·Å, ¹ß»ê, ±ØÇÑ (1 ÆäÀÌÁö)](/View/10_Sequences_Infinite_Series_Improper_Integrals_hwp_01.gif "[¹ÌÀûºÐ]¼ö·Å, ¹ß»ê, ±ØÇÑ (1 ÆäÀÌÁö)")
![[¹ÌÀûºÐ]¼ö·Å, ¹ß»ê, ±ØÇÑ (2 ÆäÀÌÁö)](/View/10_Sequences_Infinite_Series_Improper_Integrals_hwp_02.gif "[¹ÌÀûºÐ]¼ö·Å, ¹ß»ê, ±ØÇÑ (2 ÆäÀÌÁö)")
![[¹ÌÀûºÐ]¼ö·Å, ¹ß»ê, ±ØÇÑ (3 ÆäÀÌÁö)](/View/10_Sequences_Infinite_Series_Improper_Integrals_hwp_03.gif "[¹ÌÀûºÐ]¼ö·Å, ¹ß»ê, ±ØÇÑ (3 ÆäÀÌÁö)")
[¹ÌÀûºÐ]¼ö·Å, ¹ß»ê, ±ØÇÑ
ÀÎ ¼â
¹Ù·Î°¡±â
Áñ°Üã±â
Å°º¸µå¸¦ ´·¯ÁÖ¼¼¿ä( Ctrl + D )
¸µÅ©º¹»ç
¸µÅ©ÁÖ¼Ò°¡ º¹»ç µÇ¾ú½À´Ï´Ù.¿øÇÏ´Â °÷¿¡ ºÙÇô³Ö±â Çϼ¼¿ä
( Ctrl + V )
¿ÜºÎ°øÀ¯
ÆÄÀÏ 
10_Sequences_Infinite_Series_Improper_Integrals.hwp
[Size :
38 Kbyte
]
10_Sequences_Infinite_Series_Improper_Integrals.hwp
[Size :
38 Kbyte
]
ºÐ·® 3 Page
°¡°Ý 1,000 ¿ø
×
¸µÅ© ÁÖ¼Ò°¡ º¹»çµÇ¾ú½À´Ï´Ù.
¸µÅ© ÁÖ¼Ò°¡ º¹»çµÇ¾ú½À´Ï´Ù.
¿øÇÏ´Â °÷¿¡ ºÙÇô³Ö±â Çϼ¼¿ä
Ä«Æ®
|
´Ù¿î¹Þ±â
|
 ³×À̹ö ID·Î ´Ù¿î ¹Þ±â  Ä«Ä«¿À ID·Î ´Ù¿î ¹Þ±â  ±¸±Û ID·Î ´Ù¿î ¹Þ±â  ÆäÀ̽ººÏ ID·Î ´Ù¿î ¹Þ±â |
µÚ·Î
|
ÀÚ·á¼³¸í
¹ÌÀûºÐ - ¼ö·Å, ¹ß»ê, ±ØÇÑ¿¡ ´ëÇÑ ¿µ¹®ÀÚ·á
sequences infinite series improper integrals
sequences infinite series improper integrals
¸ñÂ÷/Â÷·Ê
Definition. A function f whose domain is the set of all positive integers 1,2,3.... is called an infinite sequence. The function value f(n) is called the nth term of the sequence.
Definition. A sequence {f(n)} is said to have a limit L if, for every positive number ¥å, there is another positive number N (which may depend on ¥å) such that |f(n)-L| [¥å for all n ¡Ã N. In this case, we say the sequence {f(n)} converges to L and we write , or f(n) ¡æ L as n¡æ¡Ä. A sequence which does not converge is called divergent.
Theorem 10.1. A monotonic sequence converges if and only if it is bounded.
Point. Sn = ¡Ã log (n+1)
Point. = 2 - .
Definition. A sequence {f(n)} is said to have a limit L if, for every positive number ¥å, there is another positive number N (which may depend on ¥å) such that |f(n)-L| [¥å for all n ¡Ã N. In this case, we say the sequence {f(n)} converges to L and we write , or f(n) ¡æ L as n¡æ¡Ä. A sequence which does not converge is called divergent.
Theorem 10.1. A monotonic sequence converges if and only if it is bounded.
Point. Sn = ¡Ã log (n+1)
Point. = 2 - .
º»¹®/³»¿ë
10. Sequences, Infinite Series, Improper Integrals.
Definition. A function f whose domain is the set of all positive integers 1,2,3.... is called an infinite sequence. The function value f(n) is called the nth term of the sequence.
Definition. A sequence {f(n)} is said to have a limit L if, for every positive number ¥å, there is another positive number N (which may depend on ¥å) such that |f(n)-L| [¥å for all n ¡Ã N. In this case, we say the sequence {f(n)} converges to L and we write , or f(n) ¡æ L as n¡æ¡Ä. A sequence which does not converge is called divergent.
Theorem 10.1. A monotonic sequence converges if and only if it is bounded.
Point. Sn = ¡Ã log (n+1)
Point. = 2 - .
Theorem 10.2. Let ¢²an and ¢²bn be convergent infinite series of complex terms and let ¥á and ¥â be complex constants. Then the series ¥Ò(¥á an + ¥â bn) also converges, and its sum is given by the equation = ¥á + ¥â.
Theorem 10.3. If ¢²an converges and if ¢²bn diverges, then ¥Ò(an ¡¦(»ý·«)
Definition. A function f whose domain is the set of all positive integers 1,2,3.... is called an infinite sequence. The function value f(n) is called the nth term of the sequence.
Definition. A sequence {f(n)} is said to have a limit L if, for every positive number ¥å, there is another positive number N (which may depend on ¥å) such that |f(n)-L| [¥å for all n ¡Ã N. In this case, we say the sequence {f(n)} converges to L and we write , or f(n) ¡æ L as n¡æ¡Ä. A sequence which does not converge is called divergent.
Theorem 10.1. A monotonic sequence converges if and only if it is bounded.
Point. Sn = ¡Ã log (n+1)
Point. = 2 - .
Theorem 10.2. Let ¢²an and ¢²bn be convergent infinite series of complex terms and let ¥á and ¥â be complex constants. Then the series ¥Ò(¥á an + ¥â bn) also converges, and its sum is given by the equation = ¥á + ¥â.
Theorem 10.3. If ¢²an converges and if ¢²bn diverges, then ¥Ò(an ¡¦(»ý·«)
Âü°í¹®Çå
¹ÌÀûºÐÇÐ
| 📝 Regist Info |
|
I D : schw**** Date : 2010-07-20 FileNo : 10980686 |
Cart  | |
| |