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로드 중.... (전체 텍스트 보기)

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(1)

° Ë

ї  ÞÞ Ã Å “ Ó Þ ° Ë ÑV Ȗ ¥8 ý ° Ë Ñ] K ¡X ì Ä ñ m ÇT  • ¤X N Ë X ê sV  4 ®  o

T

%  r ) · ™ »Š û BM Î 3

ô

 Dz D G ³ ðï  r õ † < ƃ  ½ ¨" é ¶ F g • ¸4 Ÿ ¤  • ¸ Õ ªÒ  ¨, @ /„   305-600

"

k+ ä Œ ‰ x

ô

 Dz D G í ß –\ O l Õ ü t @ /† < Ɠ §  ” ¸- F g/ B N † < Æõ , r < É ª 429-793 (2005¸   12 Z 4 9{ 9  ~ à Î6 £ §, þ j7 á x‘ : r 2006¸   3 Z 4 7{ 9  ~ à Î6 £ §)

F

g: Ÿ x’  6   x F g$ 3 Ä »_  F g † < Æ& h  U  ´s  8 £ ¤& ñ \  › ' a ô  Ç 8 £ ¤& ñ ™ è/ å L$ í `  ¦ S X ‰ w n  l  0 A # Œ ² D G ] j& h Ü ¼– Ð / B N“   ) a

~

½ ÓZ O “   time of flight ~ ½ ÓZ O `  ¦ s 6   x ô  Ç F g † < Æ& h  U  ´s  8 £ ¤& ñ  © œu \  ¦ > hµ 1 Ï % i  . > hµ 1 Ï  ) a  © œu   H ² D G  8 £ ¤& ñ

™

è/ å L$ í `  ¦ ° ú   H F g " é ¶, F g  Ž Ø  ¦ l , F g   ½ + Ël , † < Êà º µ 1 ÏÒ q tl , Å Ò à º > à ºl  1 p x Ü ¼– Ð ½ ¨$ í ÷ &% 3  . > hµ 1 Ï  ) a



© œu \  ¦ s 6   x # Œ NPL (% ò ² D G² D Gw n Ó ü t o ƒ  ½ ¨™ è)\ " f ] j/ B N ) a CRM _  F g † < Æ& h  U  ´s \  ¦ 8 £ ¤& ñ # Œ q “ § % i 



 H X <, ‘ : r ƒ  ½ ¨\ " f 8 £ ¤& ñ  ) a   õ ü < NPL\ " f 8 £ ¤& ñ  ) a   õ ü <  H 8 £ ¤& ñ Ô  ¦S X ‰ • ¸ # 3 0 A î ß –\ " f { 9 u  % i  .

PACS numbers: 06.20.F, 42.81.Q

Keywords: F g$ 3 Ä », F g † < Æ& h  U  ´s , F g † < Æ > 8 £ ¤, 8 £ ¤& ñ ³ ðï  r

I. " e  ] Ø

F

g: Ÿ x’  6   x F g$ 3 Ä »/™ è \ " f ×  æ כ ¹ >  “  d ” ÷ &“ ¦ e ”   H F

g: £ ¤$ í 8 £ ¤& ñ  p '   H ’ < Hz  ´ (loss), Ò  oì  r í ß – (chromatic dispersion), — ¸× ¼ € 9 × ¼ f ”  â (mode field diameter), q ‚   + þ

A : £ ¤$ í (nonlinearity), ì ø Í  ’ < Hz  ´ (return loss), F g † < Æ& h  U

 ´s  (optical length) 1 p x s  e ”   [1,2]. : £ ¤ y  F g$ 3 Ä »_  F g

†

< Æ& h  U  ´s   H F g$ 3 Ä » : £ ¤$ í ¨ î  ì  r  \ " f ×  æ כ ¹ô  Ç Ó ü t o | ¾ Ó Ü

¼– Ð F g: Ÿ x’  õ  F g G ' p" f ì  r  \ " f & ñ S X ‰ >  F g † < Æ& h  U  ´s 

\

 ¦ 8 £ ¤& ñ ½ + É € 9 כ ¹$ í s  e ” >  ÷ &% 3   [3,4].

Õ

ª Q  ² D G ? /\ " f  H F g$ 3 Ä » F g † < Æ& h  U  ´s \  @ /ô  Ç ² D G  8

£ ¤& ñ ™ è/ å L$ í (traceability)s  S X ‰ ˜ Ð÷ &# Q e ” t  · ú § " f F g † < Æ

&

h

 U  ´s  8 £ ¤& ñ ° ú כ`  ¦ ’  ø @ l  # Q 9î  r  © œ S ! s  .   " f ² D G ]

j& h Ü ¼– Ð / B N“   ) a 8 £ ¤& ñ ~ ½ ÓZ O `  ¦ s 6   x ô  Ç F g$ 3 Ä »_  U  ´s  8 £ ¤

&

ñ l Õ ü t`  ¦ S X ‰ w n  # Œ ² D G  8 £ ¤& ñ ™ è/ å L ^ ‰> \  ¦ S X ‰ w n   9 F g

$

3 Ä » F g † < Æ& h  U  ´s  l ï  r`  ¦ › ' aº   í ß –\ O ^ ‰\  ˜ Ð/ å L K   ô  Ç  [1,2].

F

g: Ÿ x’  6   x F g$ 3 Ä »_  F g † < Æ& h  U  ´s \  ¦ 8 £ ¤& ñ   H ~ ½ ÓZ O [ þ t

“

É r OTDR (optical time domain reflectometer), OCDR (optical coherent domain reflectometer), OFDR (optical frequency domain reflectometer) 1 p x s  e ”   [5-8]. s ü <

° ú

 “ É r ~ ½ ÓZ O [ þ t“ É r U  ´s \  ¦ ~ 1 >  8 £ ¤& ñ ½ + É Ã º e ” t ë ß – U  ´s _  8 £ ¤

&

ñ # 3 0 A a % v “ ¦ ì  r K 0 p x s  ± ú  . ì ø ̀  \  F g$ 3 Ä »_  F g † < Æ& h 

E-mail: [email protected]

U

 ´s \  ¦ 8 £ ¤& ñ   H l ï  r 8 £ ¤& ñ ~ ½ ÓZ O “   time of flight ~ ½ ÓZ O “ É r F

g$ 3 Ä »\  ¦ : Ÿ x õ ô  Ç Ê ê_  r ç ß – t ƒ  `  ¦ 8 £ ¤& ñ # Œ U  ´s \  ¦ ½ ¨

  H ~ ½ ÓZ O Ü ¼– Ð V , “ É r 8 £ ¤& ñ % ò % i õ  “ ¦ ì  r K 0 p x _   © œ& h s  e ” 



 [4,9].

‘

: r  7 Hë  H \ " f  H ² D G ] j& h Ü ¼– Ð / B N“   ) a l ï  r 8 £ ¤& ñ ~ ½ ÓZ O “   time of flight ~ ½ ÓZ O `  ¦ s 6   x # Œ F g$ 3 Ä »_  F g † < Æ& h  U  ´s  8 £ ¤

&

ñ  © œu \  ¦ > hµ 1 Ï % i Ü ¼ 9,  € ª œô  Ç U  ´s _  F g$ 3 Ä »\  @ /K 

"

f F g † < Æ& h  U  ´s \  ¦ 8 £ ¤& ñ % i  . ¢ ¸ô  Ç % ò ² D G² D Gw n Ó ü t o ƒ  ½ ¨

™

è (NPL)\ " f 8 £ ¤& ñ ô  Ç   õ ü < q “ § % i  .

II. ° Ë ÑV Ȗ ¥ ñ m ÇT  • ¤X N Ë U ê s0 n É õ m Í • ¤X N Ë X ê sV 

F

g$ 3 Ä »  H F g: Ÿ x’   x 9 F g > 8 £ ¤ 1 p x \  V , o   6   x ÷ &“ ¦ e ” Ü ¼ 9, s \  ¦ í ß –\ O  ‰ & ³ © œ\ " f  6   x l  0 AK " f  H Õ ª U  ´s \  ¦ & ñ S X

‰ >  8 £ ¤& ñ ½ + É € 9 כ ¹ e ”  . Õ ª Q   © œ o  : Ÿ x’  \   6   x

÷ &  H F g$ 3 Ä »  H Õ ª U  ´s  à º km s  © œÜ ¼– Ð U  ´l  M :ë  H \  U

 ´s \  ¦ 8 £ ¤& ñ   H X < # Q 9¹ ¡ § s  e ”  . { 9 ì ø Í& h Ü ¼– Ð U  ´s  L s

“ ¦ Ï ã J] X Ò  ¦ s  n “   B | 9 `  ¦ : Ÿ x õ    H y n C“ É r (

n(λ)c

) × L _  r

ç ß – t ƒ  s  µ 1 ÏÒ q tô  Ç . # Œl \ " f Ï ã J] X Ò  ¦ n (λ) õ  F g5 Å q c



 H  © œÃ ºs Ù ¼– Ð U  ´s  L `  ¦ ½ ¨ l  0 AK " f  H r ç ß – t ƒ  `  ¦

&

ñ S X ‰ y  8 £ ¤& ñ €    ) a  .

Time of flight ~ ½ ÓZ O “ É r ¿ º y n C_  r ç ß – t ƒ  `  ¦ s 6   x # Œ U

 ´s \  ¦ > í ß –   H ~ ½ ÓZ O Ü ¼– Ð F g$ 3 Ä »_  U  ´s \  ¦ 8 £ ¤& ñ   H X

< ² D G ] j& h Ü ¼– Ð “  & ñ  ) a l ï  r8 £ ¤& ñ ~ ½ ÓZ O s  . ‘ : r  7 Hë  H \ " f

-396-

(2)

Fig. 1. Experimental setup for the length measurements of optical fibers.



 H time of flight ~ ½ ÓZ O `  ¦ l ‘ : r Ü ¼– Ð # Œ s ×  æ G V ,  + þ AI 

\

 ¦ ° ú   H F g$ 3 Ä »_  F g † < Æ& h  U  ´s  8 £ ¤& ñ  © œu \  ¦ > hµ 1 Ï % i  .

Fig. 1 “ É r > hµ 1 Ï  ) a F g$ 3 Ä »_  U  ´s  8 £ ¤& ñ  © œu \  ¦ ˜ Ð# ŒÅ ғ ¦ e ”

 .

s

  © œu   H ` O Û ¼\  ¦ µ 1 ÏÒ q tr v   H ` O Û ¼ µ 1 ÏÒ q tl , µ 1 ÏÒ q t ) a ` O  Û

¼_  Å Ò à º\  ¦ 8 £ ¤& ñ   H Å Ò à º > à ºl ,  © œ    Y Us 

$

  s š ¸× ¼, 1 × 2 F g & e  ¦  Q, l ï  r  ⠖ Ж Ð ”  ' Ÿ ô  Ç y n C`  ¦ 8

£ ¤& ñ   H A F g Ž Ø  ¦ l , r + « > F g$ 3 Ä »  ⠖ Ж Ð ”  ' Ÿ  # Œ l  ï

 r  ⠖ И Ð  r ç ß – t ƒ   ) a + þ AI – Ð  Ž Ø  ¦ ÷ &  H B F g Ž Ø  ¦ l , l

ï  r ’    ñü < 8 £ ¤& ñ ’    ñ_  ` O Û ¼\  ¦ ì  r$ 3    H š ¸z  ´– ÐÛ ¼ ï á

Ô 1 p x Ü ¼– Ð s À Ò# Q4 Re ”  .

 © œ    Y Us $   s š ¸× ¼ (NewFocus 6300, 6310)_ 

 © œ % ò % i “ É r y Œ •y Œ • 1520 nm ∼ 1570 nm ü < 1280 nm ∼ 1340 nm s  9 Ø  ¦§ 4 _  î ß –& ñ • ¸  H 0.1 % s ? / s  . s  F g

"

é

¶ \ " f  “ : r y n C“ É r F g ì  r C q Ö  ¦ s  40 : 60 “   1 × 2 F g &  e

 ¦  Q\  ¦  6   x # Œ ¿ º  Òì  r Ü ¼– Ð ì  r o   ) a  . y n Cs  F g$ 3 Ä »\  ¦ :

Ÿ

x õ  €   ’ < Hz  ´s  µ 1 ÏÒ q t l  M :ë  H \  ’ < Hz  ´`  ¦ ˜ Ð © œ l  0 A

# Œ 60 %– Ð ì  r C ÷ &  H F g & e  ¦  Q_  é ß – \  F g$ 3 Ä »\  ¦ ƒ  

 

 # Œ  Ž Ø  ¦ l  B – Ð { 9   “ ¦   É r  Òì  r“ É r f ” ] X   Ž Ø  ¦ l  A – Ð { 9  ô  Ç .

Fig. 2 \ " f · ú ˜ à º e ” 1 p w s  F g & e  ¦  Q\ " f ì  r o   ) a  6 £ §

\

 r + « >6   x F g$ 3 Ä »\  ¦ : Ÿ x õ ô  Ç y n C (B)“ É r l ï  r  ⠖ Ж Ð ”  ' Ÿ  ô

 Ç  6 £ § \  F g Ž Ø  ¦ l – Ð { 9  ÷ &  H y n C (A)\  q  # Œ r + « >

6  

x F g$ 3 Ä »_  U  ´s  (L)ë ß –  p u  o \  ¦  8 ”  ' Ÿ  >   ) a  .  



" f y Œ •y Œ •_   Ž Ø  ¦ l \ " f 8 £ ¤& ñ  ) a ’    ñ  H š ¸z  ´– ÐÛ ¼ ïá Ô\ 

"

f r ç ß – s  (τ )\  ¦ ° ú “ ¦    >   ) a  . t ƒ  r ç ß – \   

 É

r  o  (L)  H (

n(λ)

) s  . # Œl \ " f, c   H y n C_  5 Å q • ¸, n (λ)  H y n Cs  : Ÿ x õ    H F g$ 3 Ä »_  Ï ã J] X Ò  ¦, λ  H y n C_   © œs 



.   " f F g Ž Ø  ¦ l \ " f  Ž Ø  ¦ ) a y n CÜ ¼– РÒ'  t ƒ   r ç ß –

`

 ¦ > í ß – €   Ï ã J] X Ò  ¦ s  · ú ˜ 9”   F g$ 3 Ä »_  U  ´s \  ¦ & ñ S X ‰ 

>

 8 £ ¤& ñ ½ + É Ã º e ”  .

Fig. 2. Delay time between pass A (reference) and pass B (pass the optical fiber).

ô

 Ǽ #  r + « >6   x F g$ 3 Ä »  © œ‚ à Ì÷ &# Q e ” t  · ú §“ É r  © œI \ " f

 â

– Ð Aü <  ⠖ Ð B_   o  s  e ” `  ¦  â Ä º\   H Õ ª M :_ 



o  s  ë ß –  p u \  K { © œ   H ”  ' Ÿ  r ç ß –s  s  µ 1 ÏÒ q t÷ &

>

  ) a  . Õ ª QÙ ¼– Ð r + « >6   x F g$ 3 Ä »\  _ ô  Ç í  H à ºô  Ç t ƒ  r  ç

ß – (τ )“ É r s ü < ° ú  s  Æ Ò– Ð µ 1 ÏÒ q t ) a r ç ß – t ƒ  `  ¦ ˜ Ð& ñ 

#

Œ > í ß –K    ) a  .

Time of flight ~ ½ ÓZ O \ " f  H ¿ º ’    ñ_  0 A © œ \  ¦ 8 £ ¤& ñ

Ž  H t  ¢ ¸  H ` O Û ¼_  Å Ò à º\  ¦    or &  t ƒ   r ç ß –`  ¦ · ú ˜



? />   ) a  . ‘ : r  7 Hë  H \ " f  H ` O Û ¼_  Å Ò à º\  ¦    o r v 



 H ~ ½ ÓZ O  (frequency shift modulation method)\  ¦ s 6   x 

%

i  . Fig. 3“ É r Å Ò à º\  ¦    or & " f t ƒ   r ç ß –`  ¦ ½ ¨ 



 H õ & ñ `  ¦ ˜ Ð# ŒÅ ғ ¦ e ”  . s  ~ ½ ÓZ O “ É r F g$ 3 Ä »_  U  ´s \  K  {

© œ   H t ƒ   r ç ß – î ß –\  N > h_  ` O Û ¼ ” > r F  • ¸2 Ÿ ¤ F g " é ¶ _

   › ¸ Å Ò à º (f

1

)\  ¦ › ¸] X ô  Ç Ê ê\  (Fig. 3(a)), Å Ò à º

\

 ¦ f

1

 Ò'  é ß –> & h Ü ¼– Ð    or &  N-1 > h_  ` O Û ¼ ” > r F 

  H f

2

– Ð    or v   H ~ ½ ÓZ O s   (Fig. 3(b)).

s

M : t ƒ   r ç ß –“ É r ¿ º Å Ò à º_  s _  % i à º– Ð ½ ¨½ + É Ã º e ”

  H X < s  כ “ É r  6 £ § õ  ° ú  “ É r d ” (1), d ” (2)– Ð   è ­ q à º e ” 



.

τ = N f

1

= N − 1 f

2

(1)

τ = 1 f

1

− f

2

(2)

#

Œl \ " f τ   H U  ´s  L “   F g$ 3 Ä »_  t ƒ   r ç ß –, f

1

“ É r Fig. 3(a) \ " fü < ° ú  s  ¿ º ’    ñ_  t ƒ   r ç ß – î ß –\  N > h_ 

` O

Û ¼ ” > r F ½ + É M :_  Å Ò à º, f

2

  H Fig. 3(b) \ " fü < ° ú  s 

¿

º ’    ñ_  t ƒ   r ç ß – î ß –\  N − 1 > h_  ` O Û ¼ ” > r F ½ + É M : _

 Å Ò à ºs  . š ¸z  ´– ÐÛ ¼ ïá Ô\  ¦ s 6   x €   Å Ò à º\  ¦   



or v   H  כ \  _ K " f ¿ º ` O Û ¼ { 9 u    H  כ `  ¦ S X ‰ “  ½ + É

(3)

Fig. 3. Calculation of the delay time by (a) the mod- ulation frequency f

1

and (b) the modulation frequency f

2

.

Ã

º e ”   H X < s  כ “ É r t ƒ   r ç ß – î ß –\  Å Ò à º f “   ` O Û ¼

&

ñ à ºC ë ß –  p u ” > r F ô  Ç   H  כ `  ¦ _ p  Ù ¼– Ð f

1

õ  f

2

`  ¦ í  H

& h Ü ¼– Ð ½ ¨½ + É Ã º e ”  .

F

g$ 3 Ä »_  U  ´s  8 £ ¤& ñ z  ´+ « >“ É r “ : r • ¸ x 9 _ þ v • ¸ 1 p x õ  ° ú  “ É r 8 £ ¤

&

ñ ¨ 8 Š â s  8 £ ¤& ñ   õ \  % ò † ¾ Ó`  ¦ p } 9  à º e ” l  M :ë  H \  “ : r • ¸ ü

< _ þ v • ¸\  ¦ { 9 & ñ >  Ä »t r &   ô  Ç . ‘ : r z  ´+ « >\ " f  H † ½ Ó

“

: r † ½ Ó_ þ v  © œu \  ¦ s 6   x # Œ F g$ 3 Ä » Šҁ  _  “ : r • ¸\  ¦ 23 • ¸, _ þ v

•

¸\  ¦ 50 %  ÷ &• ¸2 Ÿ ¤ 30ì  r s  © œ † ½ ӓ : r † ½ Ó_ þ v l \  ¦ 1 l x r †   Ê

ê\  F g$ 3 Ä »_  U  ´s \  ¦ 8 £ ¤& ñ % i  .

ô

 Ǽ #  % ò ² D G _  ³ ðï  r l  › ' a “   NPL\ " f  6   x   H l ” > r _  F g

$

3 Ä » U  ´s  8 £ ¤& ñ  © œu   H F g$ 3 Ä »\  ¦ : Ÿ x õ ô  Ç y n Cõ  : Ÿ x õ  t 

· ú

§  H l ï  rF g`  ¦  _   Ž Ø  ¦ l – Ð ’    ñ\  ¦ 8 £ ¤& ñ   H ç ß –[ O 

>

+ þ A r Û ¼% 7 ›s  . Õ ª QÙ ¼– Ð q ç ß –[ O $ í Y Us $  F g " é ¶`  ¦



6   x K  ë ß – ¸ ú š6 £ § \ O s  F g$ 3 Ä »_  U  ´s \  ¦ 8 £ ¤& ñ ½ + É Ã º e ”  .

Õ

ª Q  F g$ 3 Ä » F g † < Æ& h  U  ´s _   © œ : £ ¤$ í `  ¦ 8 £ ¤& ñ l  0 A K

" f  © œ    Y Us $  F g " é ¶ õ  ° ú  “ É r ç ß –[ O $ í Y Us $ \  ¦   6

 

x ½ + É  â Ä º\   H l ï  r  ⠖ Ð A ü < 8 £ ¤& ñ  ⠖ Ð B_  ç ß –[ O  ‰ & ³ © œ

\

 _ K  ¸ ú š6 £ § s  µ 1 ÏÒ q t÷ &  H é ß –& h s  e ”  .

Fig. 4. The length measurement of NPL

0

s CRM (3 km) at 1310 nm and 1550 nm.

Fig. 5. The length measurement of NPL

0

s CRM (13 km) at 1310 nm and 1550 nm.

‘

: r  7 Hë  H \ " f > hµ 1 Ïô  Ç  © œu   H s ×  æ G V , `  ¦ ° ú   H q ç ß –[ O 

>

+ þ A r Û ¼% 7 ›s l  M :ë  H \  ç ß –[ O $ í Y Us $ \  ¦  6   x K • ¸ ç ß – [ O

 ‰ & ³ © œs  µ 1 ÏÒ q t t  · ú §  Z  }“ É r & ñ S X ‰ • ¸– Ð F g$ 3 Ä »_  U  ´s 

\

 ¦ 8 £ ¤& ñ ½ + É Ã º e ”  . ¢ ¸ô  Ç s   © œu   H  © œ    Y Us $  F g

"

é

¶`  ¦  6   x Ù ¼– Ð F g$ 3 Ä »_  F g † < Æ& h  U  ´s \  @ /K " f  © œ _

” > r$ í `  ¦ 8 £ ¤& ñ ½ + É Ã º e ”   H  © œ& h `  ¦ ° ú   H  . ô  Ǽ #  ‘ : r  7 Hë  H

\

" f > hµ 1 Ïô  Ç  © œu   H l ï  r  ⠖ Ж Ð ”  ' Ÿ ô  Ç y n C`  ¦ 8 £ ¤& ñ   H A F g Ž Ø  ¦ l ü < r + « > F g$ 3 Ä »  ⠖ Ж Ð ”  ' Ÿ ô  Ç y n C`  ¦ 8 £ ¤& ñ 



 H B F g Ž Ø  ¦ l ü < ° ú  “ É r ¿ º > h_  : £ ¤$ í s  q 5 p w ô  Ç F g Ž Ø  ¦ l 

 € 9 כ ¹ô  Ç é ß –& h s  e ”  .

III. ° Ë ÑV Ȗ ¥ ñ m ÇT  • ¤X N Ë õ m Í ÷ m Ç] M ö + s ÇÊ Ý

>

hµ 1 Ï  ) a F g$ 3 Ä » U  ´s  8 £ ¤& ñ  © œu \  ¦ s 6   x # Œ NPL (% ò ² D G

²

D Gw n Ó ü t o ƒ  ½ ¨™ è)\ " f ] j/ B N ) a F g$ 3 Ä » U  ´s  CRM_  F g † < Æ

&

h

 U  ´s \  ¦ 8 £ ¤& ñ % i Ü ¼ 9 NPL 8 £ ¤& ñ   õ ü < q “ § % i  .

Fig. 4  H 3 km % ò % i `  ¦ ° ú   H U  ´s  CRM_  ¨ î ç  H 8 £ ¤& ñ ° ú כ

(4)

–

Ð NPL_  8 £ ¤& ñ   õ ü < { 9 u † < Ê`  ¦ · ú ˜ à º e ”  . ¢ ¸ô  Ç Fig.

5  H 13 km % ò % i `  ¦ ° ú   H CRM _  8 £ ¤& ñ   õ “  X <  © œ 1310 nm \ " f 13078.98 m s  9  © œ 1550 nm \ " f 13084.87 m Ü ¼– Ð NPL\ " f 8 £ ¤& ñ ô  Ç ° ú כõ  Ô  ¦S X ‰ • ¸ s ? /\ " f { 9 u  



 H € ª œ  ñô  Ç   õ \  ¦ ˜ Ð# Œ Šғ ¦ e ”  .

‘

: r ƒ  ½ ¨\ " f > hµ 1 Ïô  Ç F g$ 3 Ä »_  F g † < Æ& h  U  ´s  8 £ ¤& ñ  © œu 



 H 8 £ ¤& ñ ¨ 8 Š â x 9 F g " é ¶ _   © œ\    É r F g$ 3 Ä »_  U  ´s    



o\  _ ô  Ç % ò † ¾ Ó`  ¦ þ j™ è o½ + É Ã º e ” Ü ¼Ù ¼– Ð l ” > r _  8 £ ¤& ñ ~ ½ Ó Z O

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(1979).

(5)

The Development of an Optical Length Measurement System for Optical Fibers

Duck Hee Lee and Seung Kwan Kim

Photometry & Radiometry Group, Korea Research Institute of Standards and Science, Daejeon 305-600

Jung-Chul Seo

Department of Nano-Optics, Korea Polytechnic University, Siheung 429-793 (Received 9 December 2005, in final form 7 March 2006)

To establish national traceability for length measurement of optical fibers, we have developed the length measurement system using the time-of-flight method. Our length measurement system is composed of calibrated optical sources, detectors, a function generator, and a frequency counter.

The National Physical Laboartory’s length Certified Reference Materials were measured and com- pared at wavelengths of 1310 nm and 1550 nm. Our results were in a good agreement with those reported by the National Physical Laboartory.

PACS numbers: 06.20.F, 42.81.Q

Keywords: Optical fibers, Optical length, Optical measurement, Measurement standards

E-mail: [email protected]

수치

Fig. 1. Experimental setup for the length measurements of optical fibers.
Fig. 5. The length measurement of NPL 0 s CRM (13 km) at 1310 nm and 1550 nm. ‘: r 7 HëH \ &#34; f &gt; hµ1 Ïô Ç © œu H s ×æ G V, `¦ °ú H q çß –[O &gt; +þ A r Û ¼%7 ›s l  M :ëH \  ç ß –[O $í Y Us $ \¦  6 x K • ¸ çߖ [ O  ‰

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