KODENSHI KPI-L06

Photointerrupter(Transmissive)
KPI-L06
DESCRIPTION
DIMENSIONS
The photointerrupter high-performance standard type
KPI-L06 combines a high-output GaAs IRED with
a high sensitivity phototransistor.
FEATURES
• PWB direct mount type
• GAP : 5.0mm
• Easy to mount
APPLICATIONS
• Printers
• Copiers
•A T M
• Ticket Vending Machines
ABSOLUTE MAXIMUM RATINGS
Parameter
Rating
Unit
IF
60
mA
IFP
1
A
Forward Current
Input
Output
Pulse Forward Current
(Ta=25℃)
Symbol
*1
Reverse Voltage
VR
5
V
Power Dissipation
PD
100
mW
Collector Emitter Voltage
VCEO
30
V
Emitter Collector Voltage
VECO
5
V
Collector Current
IC
40
mA
Collector Power Dissipation
PC
100
mW
TOPR
-20 ~ +85
℃
TSTG
-30 ~ +85
℃
TSOL
260
℃
Operating Temperature
Storage Temperature
*2
*2
Soldering Temperature
*3
*1. Pulse width : tw≤100µsec.period : T=10msec
*2. No icebound or dew
*3. For MAX. 5 seconds at the position of 1mm from the package
ELECTRO-OPTICAL CHARACTERISTICS
Parameter
VF
Forward Voltage
Input
Output
Coupled
(Ta=25℃)
MIN.
TYP.
MAX.
Unit
IF=20mA
-
1.2
1.7
V
Symbol
Conditions
Reverse Current
IR
VR=5V
-
-
10
µA
Capacitance
CT
f=1KHz
-
25
-
PF
Peak Wavelength
?P
IF=20mA
-
940
-
nm
VCE=5V, 0 Lux
-
-
100
nA
0.5
-
15
mA
Dark Current
ICEO
Light Current
IL
Collector Emitter Saturation Voltage
Response Time
VCE(SAT)
Rise Time
tr
Fall Time
tf
VCE=5V, IF= 20mA (Non-shading)
IF=20mA, IC=0.1mA
-
-
0.4
V
VCC=5V, IC=2mA,
RL=100Ω
-
5
-
µs
-
5
-
µs
1/2
Photointerrupter(Transmissive)
KPI-L06
Collector power dissipation Vs.
Ambient temparature
Forward current Vs.
Forward voltage
(㎃)
(㎃)
0
20
40
60
80
20
40
60
80 (℃)
(℃)
Ambient
Ambient
temperature(Ta)
Ambienttemperature(Ta)
temperature(Ta)
Light Current( I L )
50
0
0.5 1.0 1.5 2.0
Forward
voltage(V
Forward
voltage( VFF))
Light current Vs.
Collentor-Emitter voltage
IF =50mA
3
IF =40mA
IF =30mA
2
IF =20mA
1
0
IF =10mA
0
L)
Relative
current(I
Relative light
light current(
I L)
Light Current(
I L ) L)
Light
Current(I
4
V CE=5V
IF =20mA
100
50
0
2 4
6 8 10 12 (V)
Collector-Emitter Voltage(
VCE ) CE)
Collector-Emitter
Voltage(V
0
-20
0
20 40
60 (℃)
Ambienttemperature(Ta)
temperature( Ta )
Ambient
Relative light current Vs.
Moving distance
(㎲)
10
2
tr
tf
10 1
10 2
10 3
10 4 (Ω)
Load
Resistance(
R
)
Road Resistance(R
L L)
L)
Relative
light
current(I
Relative light
current(
IL)
10
(%) X
V CC =5V
Ta=25˚C
IF =10mA
0
0
10
20
30
40
Forward
Current( IFF ))
Forward
Current(I
Y
VCC =5V
C
Ta=25˚
IF =10mA
100
(mA)
Dark current Vs.
Ambient temperature
(nA)
Switching time Vs.
Load resistance
3
2
1
(V)
(%)
C
Ta=25˚
3
Relative light current Vs.
Ambient temperature
(㎃)
5
4
V CE =10V
10 2
10 1
10 0
10 -1
0
20 40 60 80 100 (℃)
Ambient
temperature( Ta )
Ambient
temperature(Ta)
Responsetime
time measurement circuit
Response
circuit
VCC
Input
VCC =5V
C
Ta=25˚
IF =10mA
IC
RL
VOUT
Input
90%
10%
Output
td
tr
50
tf
Method
ofofmeasuring
position
Method
measuring position
detection characteristic
detection characteristic
Optical
Axis(X)
Optical Axis(X)
0
-2
0
+2
-2
0
Movingdistance(L)
distance( L )
Moving
2/2
+2 (mm)
-
0
+
Optical
Axis(Y)
Optical Axis(Y)
00
Light Current(I L )
50
100
Collector dark
I CEO CEO
) )
Collector
darkcurrent(
current(I
1 00
100
00
Responsetime
time
Response
tr, tf tr, tf
V CE =5V
Ta=25˚C
Ta=25˚
C
Forward
current(
Fo rwar
d c urrent(I
F)I F )
Power
Powerdissipation(P
dissipartion( PC ) C)
(㎽)
(㎽)
Light current Vs.
Forward current