Tenand LTV-123S Property of lite-on only Datasheet

深圳市腾恩科技有限公司
SHENZHEN TENAND TECHNOLOGY CO.,LTD
http://www.tenand.com
! "# " $ % $ " &'(µ (( )Ω
* $# #$ " +, -#)(.)#+! $/"
0 1$ 1 " + " +, -#)(.)#+! $/"
2 + " +, -#)(.2)#+! $/"
" 1$" +, -#)(.2#)
' -#)(.22#)
' )
3
)& 1 + 1
((#1 4 ,4,
.5 + / 1 + , ! $$6 ,17 4 &! $ 18! 9 , ! $$6 ! $$ 6 ,1
' -#)(.22#)
' (
3
)& 1 + 1
((#1 4 ,4,
.5 + / 1 + , ! $$6 ,17 4 &! $ 18! 9 , ! $$6 ! $$ 6 ,1
' -#)(.22#)
' .
3
' -#)(.22#)
± ± ! ± "#
"± !#
"± !"
' 9
3
(°
&,-
0--
1
!
$%
&
'
()*+
*
!
$./*+
*
!
/.$*+
*
*
*
*
$$%
&
'
$
"
&*+
* 2
*
0+%
. 34
°$
5+%
.34 "
°$
1" 5+%
°$
"
)5 ) 9:;
$ % $ ! $$6 1 ! $$ 4 ! 1
)2! 64 1 1+ ! 1 !" / 1 164+ $$+ 1
! + 1 / 1
(! $ % $ 4 !< #+ + + ! $$6 1
.!4 % ""$ 1% $ ! $$6 4 %
(5 )2+ 1
' -#)(.22#)
' 3
(°
&,-
0--
*+
*
6
"
()$%
&
6
6
$
$
6
$$%
&
6
6
$./
;*+
;*
!
6
/.$
;*+
;*
$$%
(',5 /(
$9'('$/(&5&$5
) =
&7" '
µ'
*7*
*7 27 89:
'
*7" *2&7
6
*
&7
&7
'
6
6
*
&7
&7
µ'
"
"
6
"
'
1 $%(
$(
6
<
$./
5%*+
* 6
6
&(
( +$
×
$
*
&
×
&7'
*7*
"
*
&7" '
&7 '
6
Ω
$ *
3 <( 9
*7 27 =9:
$
6
$%.0 >%?
6
@
6
9:
((
6
"
@
µ
( 6
"
@
µ
*7*2&7"'
Ω2.;
(7
*7"*2&7"'
Ω
(7
× )
' -#)(.22#)
" " #" !
' ;
3
-#)(.
-
:)
=:);
>
).:(;
(:9
5
):(
- > 5
:9
(°
' -#)(.22#)
' ?
3
Fig.1 Forword Current
vs. Ambient Temperatute
Fig.2 Collector Power Dissiption
vs. Ambient Temperature
Collector Power dissipation Pc (mW)
60
Forward current IF(mA)
50
40
30
20
10
0
-30
0
25
50
75
100
125
200
150
100
50
0
-30
o
7mA
2
Ta= 75 C
50 C
o
200
o
25 C
0C
-25 C
o
100
o
50
20
10
5
2
1
0
2
4
6
8 10 12 14 16 18 20
0
0.5
Forward current IF (mA)
1.0
1.5
2.0
2.5
3.0
Forward voltage VF (V)
Fig.5 Current Transfer Ratio vs.
Forward Current
Fig.6 Collector Current vs.
Collector-emitter Voltage
200
50
VCE= 5V
Ta= 25 C
180
o
o
160
Collector current Ic (mA)
Current transfer ratio CTR (%)
125
1
0
140
120
100
80
60
40
40
25mA
30
20mA
2
5
10
20
Forward current IF(mA)
' -#)(.22#)
50
Pc(MAX.)
15mA
20
10mA
10
5mA
0
1
Ta= 25 C
IF = 30mA
20
0
100
o
Forward current IF (mA)
Collecotr-emitter saturation voltage
VCE (sat) (V)
5mA
3
75
500
O
Ta= 25 C
1mA
3mA
4
50
Fig.4 Forward Current vs. Forward
Voltage
6
Ic= 0.5mA
25
Ambient temperature Ta ( C)
Fig.3 Collector-emitter Saturation
Voltage vs. Forward Current
5
0
o
Ambient temperature Ta ( C)
0
1
2
3
4
5
6
7
8
9
Collector-emitter voltage VCE (V)
' =
3
Fig.8 Collector-emitter Saturation Voltage
vs. Ambient Temperature
Relative current transfer ratio (%)
150
Collector-emitter saturation voltage
VCE(sat) (V)
Fig.7 Relative Current Transfer Ratio
vs. Ambient Temperature
I F= 5mA
VCE= 5V
100
50
0
-30
0
25
50
75
0.16
I F= 20mA
I C= 1mA
0.14
0.12
0.10
0.08
0.06
0.04
0.02
0
-25
100
0
o
75
100
Fig.10 Response Time vs. Load
Resistance
-5
500
VCE= 20V
-6
10
Response time (µs)
Collector dark current ICEO (A)
50
Ambient temperature Ta ( C)
Fig.9 Collector Dark Current vs.
Ambient Temperature
10
25
o
Ambient temperature Ta ( C)
-7
10
-8
10
-9
10
-10
10
200
100
VCE= 2V
I C= 2mA
Ta= 25 C
o
50
tf
20
10
tr
td
5
ts
2
1
0.5
-11
10
-25
0
25
50
75
0.2
0.05
100
Fig.11 Frequency Response
VCE= 2V
I C= 2mA
Ta= 25 C
0
o
RL= 10kΩ
1
2
5
Input RD
RL
Input
Output
Output
10
10%
90%
ts
td
100Ω
10
0.5
Test Circuit for Response Time
Vcc
Voltage gain Av (dB)
0.1 0.2
Load resistance RL (kΩ)
o
Ambient temperature Ta ( C)
tr
1kΩ
tf
Test Circuit for Frequency Response
Vcc
20
0.5 1
RD
2
5 10 20
50 100
RL
Output
500
Frequency f (kHz)
' -#)(.22#)
' 3
3
Similar pages