INFINEON ILD620

ILD620/620GB
QUAD CHANNEL ILQ620/620GB
DUAL CHANNEL
AC INPUT PHOTOTRANSISTOR
OPTOCOUPLER
FEATURES
• Identical Channel to Channel Footprint
ILD620 Crosses to TLP620-2
ILQ620 Crosses to TLP620-4
• Current Transfer Ratio (CTR) at IF= ± 5 mA
ILD/Q620: 50% Min.
ILD/Q620GB: 100% Min.
• Saturated Current Transfer Ratio (CTRSAT)
at IF= ± 1 mA
ILD/Q620: 60% Typ.
ILD/Q620GB: 30% Min.
• High Collector-Emitter Voltage, BVCEO=70 V
• Dual and Quad Packages Feature:
- Reduced Board Space
- Lower Pin and Parts Count
- Better Channel to Channel CTR Match
- Improved Common Mode Rejection
• Field-Effect Stable by TRIOS
(TRansparent IOn Shield)
• Isolation Test Voltage from Double Molded
Package
• Underwriters Lab File #E52744
• VDE 0884 Available with Option 1
Dimensions in inches (mm)
Pin One I.D.
4
3
2
.268 (6.81)
.255 (6.48)
5
6
7
.390 (9.91)
.379 (9.63)
1
8 Collector
A/K
2
7 Emitter
A/K
3
6 Collector
A/K
4
5 Emitter
.045 (1.14) .150 (3.81)
.030 (.76) .130 (3.30)
4° Typ.
.305 Typ.
(7.75) Typ.
.135 (3.43)
.115 (2.92)
10 ° Typ.
.040 (1.02)
.030 (.76 )
.022 (.56)
.018 (.46)
.100 (2.54) Typ.
3°–9°
.012 (.30)
.008 (.20)
K=Cathode
.268 (6.81)
.255 (6.48)
Emitter
Forward Current .........................................± 60 mA
Surge Current............................................... ± 1.5 A
Power Dissipation ...................................... 100 mW
Derate from 25°C .................................. 1.3 mW/°C
Package
Isolation Test Voltage(t=1 sec.)......... 5300 VACRMS
Package Dissipation, ILD620/GB ............. 400 mW
Derate from 25°C ............................... 5.33 mW/°C
Package Dissipation, ILQ620/GB ............. 500 mW
Derate from 25°C ............................... 6.67 mW/°C
Creepage ................................................7 mm min.
Clearance ...............................................7 mm min.
Isolation Resistance
VIO=500 V, TA=25°C ................................≥1012 Ω
VIO=500 V, TA=100°C ............................. ≥10 11 Ω
Storage Temperature .................. –55°C to +150°C
Operating Temperature............... –55°C to +100°C
Junction Temperature ................................... 100°C
Soldering Temperature
(2 mm from case bottom).......................... 260°C
A/K
8
Maximum Ratings (Each Channel)
Detector
Collector-Emitter Breakdown Voltage ............. 70 V
Collector Current.......................................... 50 mA
Collector Current (t <1 ms) ......................... 100 mA
Power Dissipation ...................................... 150 mW
Derate from 25°C ..................................... 2 mW/°C
K=Cathode
1
.790 (20.07)
.779 (19.77 )
.045 (1.14)
.030 (.76)
A/K
1
16 Collector
Pin One I.D. A/K
2
15 Emitter
A/K
3
14 Collector
A/K
4
13 Emitter
A/K
5
12 Collector
A/K
6
11 Emitter
A/K
7
10 Collector
A/K
8
.150 (3.81)
.130 (3.30)
4° Typ.
.022 (.56)
.018 (.46)
9 Emitter
.305 Typ.
(7.75) Typ.
10 ° Typ.
.040 (1.02)
.030 (.76 )
.100 (2.54) Typ.
.135 (3.43)
.115 (2.92)
3°–9°
.012 (.30)
.008 (.20)
DESCRIPTION
The ILD/Q620 and ILD/Q620GB are multi-channel input phototran-sistor
optocouplers that use inverse parallel GaAs IRLED emitters and high gain
NPN silicon phototransistors per channel. These devices are constructed
using over/under leadframe optical coupling and double molded insulation
resulting in a Withstand Test Voltage of 7500 VACPEAK.
The LED parameters and the linear CTR characteristics combined with the
TRIOS field-effect process make these devices well suited for AC voltage
detection. The ILD/Q620GB with its low IF guaranteed CTRCEsat minimizes
power dissipation of the AC voltage detection network that is placed in
series with the LEDs. Eliminating the phototransistor base connection provides added electrical noise immunity from the transients found in many
industrial control environments.
5–1
Characteristics
Symbol
Min.
Typ.
Max.
Unit
Condition
VF
1
1.15
1.3
V
IF=± 10 mA
20
Emitter
Forward Voltage
Forward Current
IF
2.5
µA
VR=± 0.7 V
Capacitance
CO
25
pF
VF=0 V, f=1 MHz
Thermal Resistance, Junction to Lead
RTHJL
750
°C/W
Capacitance
CCE
6.8
pF
VCE=5 V, f=1 MHz
Collector-Emitter Leakage Current
ICEO
10
100
nA
VCE=24 V
Collector-Emitter Leakage Current
ICEO
2
50
µA
TA=85°C, VCE=24 V
Thermal Resistance, Junction to Lead
RTHJL
500
Detector
°C/W
Package Transfer Characteristics
Channel/Channel CTR Match
CTRX/CTRY
1 to 1
CTR Symmetry
ICE(RATIO)
0.5
Off-State Collector Current
ICE(OFF)
1
Saturated Current Transfer Ratio
CTRCEsat
60
Current Transfer Ratio
CTRCE
Collector-Emitter Saturation Voltage
VCEsat
IF=± 5 mA, VCE=5 V
3 to 1
2
ICE(IF=–5 mA)/IF(=+5 mA)
µA
VF=± 0.7 V, VCE=24 V
%
IF=± 1 mA, VCE=0.4 V
600
%
IF=± 5 mA, VCE=5 V
0.4
V
IF=± 8 mA, ICE=2.4 mA
%
IF=± 1 mA, VCE=0.4 V
10
ILD/Q620
50
80
ILD/Q620GB
Saturated Current Transfer Ratio
CTRCEsat
30
Current Transfer Ratio (Collector-Emitter)
CTRCE
100
Collector-Emitter Saturation Voltage
VCEsat
200
600
%
IF=± 5 mA, VCE=5 V
0.4
V
IF=± 1 mA, ICE=0.2 mA
V/µs
VCM=50 VP-P, RL=1 kΩ, IF=0 mA
VCM=50 VP-P, RL=1 kΩ, IF=10 mA
Isolation and Insulation
Common Mode Rejection, Output High
CMH
5000
Common Mode Rejection, Output Low
CML
5000
V/µs
Common Mode Coupling Capacitance
CCM
0.01
pF
Package Capacitance
CI-O
pF
VI-O=0 V, f=1 MHz
Insulation Resistance
RS
1012
Ω
VI-O=500 V
Channel to Channel Insulation
0.8
500
VAC
Switching Times
Figure 1. Non-saturated switching timing
IF=10 mA
F=10 KHz,
DF=50%
Figure 3. Non-saturated switching timing
IF
VCC=5 V
VO
RL=75 Ω
tPHL
V0
tPLH
tS
Figure 2. Saturated switching timing
50%
F=10 KHz,
DF=50%
VCC=5 V
RL
tD
tR
tF
VO
IF=10 mA
ILD/Q620/GB
5–2
Figure 6. Collector-emitter
g leakage versus ptemperature
Iceo - Collector-Emitter - nA
Figure 4. Saturated switching timing
IF
tD
tR
VO
tPLH
Symbol
Typ.
Unit
Test
Condition
On Time
TON
3.0
µs
IF=± 10 mA
Rise Time
tR
20
µs
VCC=5 V
µs
RL=75 Ω
50% of VPP
Off Time
tOFF
2.3
Fall Time
tF
2.0
µs
Propagation H-L
tPHL
1.1
µs
Propagation L-H
tPLH
2.5
µs
Characteristic
Symbol
Typ.
Unit
Test
Condition
On Time
TON
4.3
µs
IF=± 10 mA
Rise Time
tR
2.8
µs
VCC=5 V
Off Time
tOFF
2.5
µs
RL=1 Ω
Fall Time
tF
11
µs
VTH=1.5 V
Propagation H-L
tPHL
2.6
µs
Propagation L-H
tPLH
7.2
µs
Vce = 10V
1
10
TYPICAL
0
10
10 -1
10 -2
-20
0
20
40
60
80
100
Ta - Ambient Temperature - °C
120
100
80
60
TJ (MAX)=100°C
40
20
0
--60
-40
-20
0
20
40
60
80
Ta - Ambient Temperature - °C
100
Figure 8. Maximum LED power dissipation
200
150
100
50
0
60
--60
40
-40
-20
0
20
40
60
80
Ta - Ambient Temperature - °C
100
85°C
20
Figure 9. Collector current versus diode forward
current
25°C
0
100
Normalized to
50
IF=10 mA
VCE=5 V
TA=25°C
10
5.0
–55°C
IC –Normalized Collector Current
IF - LED Forward Current - mA
2
10
Figure 7. Maximum LED current versus ambient
temperature
Figure 5. LED forward current versus forward voltage
-20
-40
-60
-1.5
3
10
IF - Maximum LED Current - mA
Characteristic
5
4
10
PLED - LED Power - mW
tS
tPHL
VTH=1.5 V
tF
10
-1.0
-0.5
0.0
0.5
1.0
1.5
VF - LED Forward Voltage - V
ILD/Q620GB
ILD/Q620
2.5
1.0
0.5
0.1
1
5
10
Forward Current–IF (mA)
20
ILD/Q620/GB
5–3
Figure 10. Normalization factor for non-saturated and
saturated CTR TA=50°C versus if
Figure 13. Peak LED current versus peak duration, Tau
10000
2.0
τ
1.5
Duty Factor
If(pk) - Peak LED Current - mA
CTRNF - Normalized CTR Factor
Normalized to:
Vce = 10V, IF = 5mA, Ta = 25°C
CTRce(sat) Vce = 0.4V
NCTRce
1.0
NCTRce(sat)
0.5
Ta = 50°C
1000
100
0.0
.1
1
10
IF - LED Current - mA
10 -6
10
100
P
- Detector Power - mW
DET
CTRNF - Normalized CTR Factor
CTRce(sat) Vce = 0.4V
NCTRce
1.0
NCTRce(sat)
Ta = 70°C
.1
1
10 -5
10-4
10-3
10-2
10 -1
10 0
10 1
200
Normalized to:
Vce = 10V, IF = 5mA, Ta = 25°C
0.0
τ
DF = /t
.05
.1
.2
.5
Figure 14. Maximum detector power dissipation
2.0
0.5
t
t - LED Pulse Duration - s
Figure 11. Normalization factor for non-saturated and
saturated CTR TA=70°C versus if
1.5
.005
.01
.02
10
150
100
50
0
-60
100
-40
-20
0
20
40
60
Ta - Ambient Temperature - °C
80
100
IF - LED Current - mA
Figure 15. Maximum collector current versus collector
voltage
Figure 12. Normalization factor for non-saturated and
saturated CTR TA=100°C versus if
1000
Normalized to:
Vce = 10V, IF = 5mA, Ta = 25°C
1.5
Ice - Collector Current - mA
CTRNF - Normalized CTR Factor
2.0
CTRce(sat) Vce = 0.4V
NCTRce
1.0
0.5
NCTRce(sat)
Ta = 100°C
1
10
IF - LED Current - mA
100
Rth = 500°C/W
10
25°C
50°C
75°C
1
.1
0.0
.1
100
.1
90°C
1
10
Vce - Collector-Emitter Voltage - V
100
ILD/Q620/GB
5–4