INFINEON SFH640-1

SFH 640
5.3
FEATURES
• CTR at IF=10 mA, VCE=10 V
SFH640-1, 40-80%
SFH640-2, 63-125%
SFH640-3*, 100-200%
• Good CTR Linearity with Forward Current
• Low CTR Degradation
• Very High Collector-Emitter Breakdown Voltage, BVCER=300 V
• Isolation Test Voltage: 5300 VACRMS
• Low Coupling Capacitance
• High Common Mode Transient Immunity
• Phototransistor Optocoupler
6 Pin DIP Package with Base Connection
• Field Effect Stable: TRIOS+
V
•
VDE 0884 Available with Option 1
• Underwriters Lab File #E52744
The SFH 640 is an optocoupler with very high
BVCER, a minimum of 300 volts. It is intended for
telecommunications applications or any DC application requiring a high blocking voltage. The
SFH640 is a “better than” replacement for H11D1.
*Supplies from this group can't always be guranteed due
to unforseeable yield spread.
+TRIOS–TRansparent IOn Shield
PHOTOTRANSISTOR
HIGH BVCER VOLTAGE
OPTOCOUPLER
Dimensions in inches (mm)
Pin One ID
3
2
1
Anode 1
.248 (6.30)
.256 (6.50)
6 Base
Cathode 2
4
5
5 Collector
NC 3
6
4 Emitter
.335 (8.50)
.343 (8.70)
.300 (7.62)
typ.
.039
(1.00)
Min.
4°
typ.
D E
DESCRIPTION
KV TRIOS
.018 (0.45)
.022 (0.55)
.130 (3.30)
.150 (3.81)
18° typ.
.020 (.051) min.
.031 (0.80)
.035 (0.90)
.100 (2.54) typ.
.010 (.25)
.014 (.35)
.110 (2.79)
.150 (3.81)
.300 (7.62)
.347 (8.82)
Maximum Ratings (TA=25°C)
Emitter
Reverse Voltage ...................................................................................6 V
DC Forward Current ....................................................................... 60 mA
Surge Forward Current (tp≤10 µs) .................................................. 2.5 A
Total Power Dissipation ............................................................... 100 mW
Detector
Collector-Emitter Voltage ................................................................ 300 V
Collector-Base Voltage .....................................................................300 V
Emitter-Base Voltage ..........................................................................7 V
Collector Current ........................................................................... 50 mA
Surge Collector Current (tp≤1 ms) ............................................... 100 mA
Total Power Dissipation ............................................................... 300 mW
Package
Isolation Test Voltage (between emitter and
detector, refer to climate DIN 40046 part 2
Nov. 74) ...................................................... 5300 VACRMS/7500 VACPK
Isolation Resistance
VIO=500 V, TA=25°C .........................................................................≥1012 Ω
VIO=500 V, TA=100°C .......................................................................≥1011 Ω
Insulation Thickness between Emitter and Detector .................. ≥0.4 mm
Creepage .................................................................................................≥7 mm
Clearance .................................................................................................≥7 mm
Comparative Tracking Index
per DIN IEC 112/VDE 0303, part1 ................................................... 175
Storage Temperature Range .......................................... -55°C to +150°C
Operating Temperature Range....................................... -55°C to +100°C
Junction Temperature......................................................................100°C
Soldering Temperature (max. 10 sec., dip soldering:
distance to seating plane≥1.5 mm) .............................................260°C
5–1
Characteristics (TA=25°C, unless otherwise specified)
Symbol
Min
Typ
Max
Unit
Condition
1.1
1.5
V
IF=10 mA
V
IR= 10 µA
µA
VR=6 V
VR=0 V, f=1 MHz
Emitter
Forward Voltage
VF
Reverse Voltage
VR
Reverse Current
IR
0.01
Capacitance
CO
25
pF
Thermal Resistance
RthJA
750
K/W
6
10
Detector
Voltage
Collector-Emitter
Emitter-Base
BVCER
BVBEO
300
7
V
V
ICE=1 mA, RBE=1 MΩ
IEB=10 µA
VCE=10 V, f=1 MHz
VCB=10 V, f=1 MHz
VEB=5 V, f=1 MHz
Capacitance
CCE
CCB
CEB
7
8
38
pF
pF
pF
Thermal Resistance
RthJA
250
K/W
Coupling Capacitance
CC
0.6
pF
Coupling Transfer Ratio
SFH 640-1
IC/IF
Package
SFH 640-2
IC/IF
SFH 640-3
IC/IF
40
13
63
22
100
34
80
%
125
%
200
%
IF=10 mA, VCE=10 V
IF=1 mA, VCE=10 V
IF=10 mA, VCE=10 V
IF=1 mA, VCE=10 V
IF=10 mA, VCE=10 V
IF=1 mA, VCE=10 V
30
45
70
Saturation Voltage, Collector-Emitter
SFH 640-1
SFH 640-2
SFH 640-3
VCEsat
VCEsat
VCEsat
0.25
0.25
0.25
0.4
0.4
0.4
V
V
V
IF= 10 mA, IC=2 mA
IF= 10 mA, IC=3.2 mA
IF=10 mA, IC=5 mA
Leakage Current, Collector-Emitter
ICER
1
100
nA
VCE=200 V, RBE=1 MΩ
Figure 1. Switching times measurement-test circuit and waveform
INPUT
0
RL
IF
VCC
IC
OUTPUT
0
10%
47Ω
ton
toff
tpdon
tpdof
td
tr
tr
ts
10%
50%
50%
90%
90%
Switching Times (Typical)
IC=2 mA (to adjust by IF), RL=100 Ω, TA=25°C, VCC=10 V
Description
Symbol
Values
Unit
Turn-On Time
tON
5
µs
Rise Time
tR
2.5
µs
Turn-Off Time
tOFF
6
µs
Fall Time
tF
5.5
µs
SFH640
5–2
Figure 2. Current transfer ratio (typ.)
VCE=10 V, TA=25°C, normalized to
IF=10 mA, NCTR=f(IF)
Figure 5. Output characteristics
(typ.) TA=25°C, ICE=f(VCE, IF)
Figure 8. Permissible loss diode
IF= f(TA)
Figure 3. Diode forward voltage (typ.)
VF=f(IF,TA)
Figure 6. Transistor capacitances
(typ.) TA=25°C, f=1 MHz, CCE=f(VCE)
CCB=f (VCB), CEB=f (VEB)
Figure 9. Permissible power dissipation PIOT=f(TA)
Figure 4. Output characteristics (typ.)
TA=25°C, ICE=f(VCE, IB)
Figure 7. Collector-emitter leakage
current (typ.) IF=0, RBE=1 MW,
ICER=f(VCE)
SFH640
5–3