SFH426-Z - OSRAM Opto Semiconductors

SFH 421

SFH 426

GaAlAs-IR-Lumineszenzdiode in SMT-Gehäuse

GaAlAs Infrared Emitter in SMT Package

Lead (Pb) Free Product - RoHS Compliant

SFH 421 SFH 426

2007-05-23 1

Wesentliche Merkmale

• GaAIAs-LED mit sehr hohem Wirkungsgrad

• Gute Linearität (Ie = f [IF]) bei hohen Strömen

• Gleichstrom- (mit Modulation) oder

Impulsbetrieb möglich

• Hohe Zuverlässigkeit

• Hohe Impulsbelastbarkeit

• Oberflächenmontage geeignet

• Gegurtet lieferbar

•SFH 421 Gehäusegleich mit SFH 320

SFH 426 Gehäusegleich mit SFH 325

Anwendungen

• Miniaturlichtschranken für Gleich- und

Wechsellichtbetrieb

• Industrieelektronik

• „Messen/Steuern/Regeln“

• Automobiltechnik

• Sensorik

• Alarm- und Sicherungssysteme

• IR-Freiraumübertragung

Typ

Type

Bestellnummer

Ordering Code

Gehäuse

Package

SFH 421 Q65110A1218

Kathodenkennzeichnung: abgesetzte Ecke

cathode marking: bevelled edge

TOPLED®

SFH 426 Q65110A2512 SIDELED®

Features

• Very highly efficient GaAIAs-LED

• Good Linearity (Ie = f [IF]) at high currents

• DC (with modulation) or pulsed operations are

possible

• High reliability

• High pulse handling capability

• Suitable for surface mounting (SMT)

• Available on tape and reel

•SFH 421 same package as SFH 320

SFH 426 same package as SFH 325

Applications

• Miniature photointerrupters

• Industrial electronics

• For drive and control circuits

• Automotive technology

• Sensor technology

• Alarm and safety equipment

• IR free air transmission

2007-05-23 2

SFH 421, SFH 426

Grenzwerte (TA = 25 °C)

Maximum Ratings

Bezeichnung

Parameter

Symbol

Wert

Value

Einheit

Unit

Betriebs- und Lagertemperatur

Operating and storage temperature range

Top; Tstg – 40 … + 100 °C

Sperrspannung

Reverse voltage

VR5 V

Durchlassstrom

Forward current

IF100 mA

Stoßstrom, τ = 10 µs, D = 0

Surge current

IFSM 2.5 A

Verlustleistung

Power dissipation

Ptot 180 mW

Wärmewiderstand Sperrschicht - Umgebung bei

Montage auf FR4 Platine, Padgröße je 16 mm2

Thermal resistance junction - ambient mounted

on PC-board (FR4), padsize 16 mm2 each

Wärmewiderstand Sperrschicht - Lötstelle bei

Montage auf Metall-Block

Thermal resistance junction - soldering point,

mounted on metal block

RthJA

RthJS

450

≈ 200

K/W

SFH 421, SFH 426

2007-05-23 3

Kennwerte (TA = 25 °C)

Characteristics

Bezeichnung

Parameter

Symbol

Wert

Value

Einheit

Unit

Wellenlänge der Strahlung

Wavelength at peak emission

IF = 100 mA, tp = 20 ms

λpeak 880 nm

Spektrale Bandbreite bei 50% von Imax

Spectral bandwidth at 50% of Imax

IF = 100 m A

∆λ 80 nm

Abstrahlwinkel

Half angle

ϕ± 60 Grad

deg.

Aktive Chipfläche

Active chip area

A0.09 mm2

Abmessungen der aktiven Chipfläche

Dimensions of the active chip area

L × B

L × W

0.3 × 0.3 mm²

Schaltzeiten, Ie von 10% auf 90% und von 90%

auf 10%, bei IF = 100 mA, RL = 50 Ω

Switching times, Ιe from 10% to 90% and from

90% to 10%, IF = 100 mA, RL = 50 Ω

tr, tf0.5 µs

Kapazität

Capacitance

VR = 0 V, f = 1 MHz

Co15 pF

Durchlassspannung

Forward voltage

IF = 100 mA, tp = 20 ms

IF = 1 A, tp = 100 µs

1.5 (≤ 1.8)

3.0 (≤ 3.8)

Sperrstrom

Reverse current

VR = 5 V

IR0.01 (≤ 1) µA

Gesamtstrahlungsfluss

Total radiant flux

IF = 100 mA, tp = 20 ms

Φe23 mW

Temperaturkoeffizient von Ie bzw. Φe,

IF = 100 mA

Temperature coefficient of Ie or Φe, IF = 100 mA

TCI– 0.5 %/K

Temperaturkoeffizient von VF, IF = 100 mA

Temperature coefficient of VF, IF = 100 mA

TCV– 2 mV/K

Temperaturkoeffizient von λ, IF = 100 mA

Temperature coefficient of λ, IF = 100 mA

TCλ+ 0.25 nm/K

2007-05-23 4

SFH 421, SFH 426

Strahlstärke Ie in Achsrichtung

gemessen bei einem Raumwinkel Ω = 0.01 sr

Radiant Intensity Ie in Axial Direction

at a solid angle of Ω = 0.01 sr

Bezeichnung

Parameter

Symbol Werte

Values

Einheit

Unit

Strahlstärke

Radiant intensity

IF = 100 mA, tp = 20 ms

Ie min

Ie typ

mW/sr

Strahlstärke

Radiant intensity

IF = 1 A, tp = 100 µs

Ie typ 48 mW/sr

SFH 421, SFH 426

2007-05-23 5

Relative Spectral Emission

Irel = f (λ)

Forward Current

IF = f (VF) single pulse, tp = 20 µs

Radiation Characteristics Irel = f (ϕ)

750

Ιrel

OHR00877

800 850 900 950 nm 1000

100

OHR00881

-3

-2

-1

0123456V8

0.2

0.4

1.0

0.8

0.6

1.0 0.8 0.6 0.4

0˚10˚20˚40˚ 30˚

OHL01660

50˚

60˚

70˚

80˚

90˚

100˚

0˚ 20˚ 40˚ 60˚ 80˚ 100˚ 120˚

Radiant Intensity

Single pulse, tp = 20 µs

Permissible Pulse Handling

Capability IF = f (tp), TA = 25 °C

duty cycle D = parameter

Ιe

Ιe 100 mA = f (IF)

OHR00878

Ιe

-3

-2

-1

10 10 110 210 4

(100mA)

OHR00886

-5

10 s

0.005=

0.5

0.2

0.1

0.01

0.02

0.05

-4

-3

-2

-1

Max. Permissible Forward Current

IF = f (TA)

OHR00883

100

120

20 40 60 80 100 120

˚C

thjA

= 450 K/W

2007-05-23 6

SFH 421, SFH 426

Maßzeichnung

Package Outlines

Maße in mm (inch) / Dimensions in mm (inch).

SFH 421

GPLY6724

0.7 (0.028)

0.9 (0.035)

1.7 (0.067)

2.1 (0.083)

0.12 (0.005)

0.18 (0.007)

0.5 (0.020)

1.1 (0.043)

3.3 (0.130)

3.7 (0.146)

0.4 (0.016)

0.6 (0.024)

2.6 (0.102)

3.0 (0.118)

2.1 (0.083)

2.3 (0.091)

Cathode marking

3.0 (0.118)

3.4 (0.134)

(2.4) (0.095)

0.1 (0.004) (typ.)

4˚±1

SFH 426

GPLY6880

(R1)

Cathode marking

Cathode Anode

(2.4 (0.094))

2.8 (0.110)

2.4 (0.094)

4.2 (0.165)

3.8 (0.150)

0.9 (0.035)

1.1 (0.043)

spacing

2.54 (0.100)

0.7 (0.028)

(2.85 (0.112))

(1.4 (0.055))

(0.3 (0.012))

3.4 (0.134)

3.8 (0.150)

4.2 (0.165)

(2.9 (0.114))

SFH 421, SFH 426

2007-05-23 7

Empfohlenes Lötpaddesign Reflow Löten

Recommended Solder Pad Reflow Soldering

Maße in mm / Dimensions in mm.

SFH 421

4.5 (0.177)

2.6 (0.102)

1.5 (0.059)

Cu-area > 16 mm

Cu-Fläche > 16 mm

Solder resist

Lötstopplack

4.5 (0.177)

1.5 (0.059)

2.6 (0.102)

Padgeometrie für

improved heat dissipation

verbesserte Wärmeableitung

Paddesign for

SFH 426

3.7 (0.146)

1.2 (0.047)

3.0 (0.118)

Cu-area > 16 mm

Cu-Fläche > 16 mm

Paddesign

for improved

heat dissipation

Wärmeableitung

für verbesserte

Padgeometrie

Lötstopplack

Solder resist

OHLPY965

2007-05-23 8

SFH 421, SFH 426

Lötbedingungen Vorbehandlung nach JEDEC Level 2

Soldering Conditions Preconditioning acc. to JEDEC Level 2

Reflow Lötprofil für bleifreies Löten (nach J-STD-020C)

Reflow Soldering Profile for lead free soldering (acc. to J-STD-020C)

Wellenlöten (TTW) (nach CECC 00802)

TTW Soldering (acc. to CECC 00802)

OHLA0687

˚C

120 s max

100

150

200

250

300

Ramp Up

100 s max

50 100 150 200 250 300

Ramp Down

6 K/s (max)

3 K/s (max)

25 ˚C

30 s max

260 ˚C +0 ˚C

-5 ˚C

245 ˚C ±5 ˚C

240 ˚C

255 ˚C

217 ˚C

Maximum Solder Profile

Recommended Solder Profile

235 ˚C -0 ˚C

+5 ˚C

Minimum Solder Profile

10 s min

OHLY0598

50 100 150 200 250

100

150

200

250

300

235 C

10 s

C... 260

1. Welle

1. wave

2. Welle

2. wave

5 K/s 2 K/s

ca 200 K/s

CC... 130100

2 K/s Zwangskühlung

forced cooling

Normalkurve

standard curve

Grenzkurven

limit curves

SFH 421, SFH 426

2007-05-23 9

Published by

OSRAM Opto Semiconductors GmbH

Wernerwerkstrasse 2, D-93049 Regensburg

www.osram-os.com

The information describes the type of component and shall not be considered as assured characteristics.

Terms of delivery and rights to change design reserved. Due to technical requirements components may contain

dangerous substances. For information on the types in question please contact our Sales Organization.

Packing

Please use the recycling operators known to you. We can also help you – get in touch with your nearest sales office.

By agreement we will take packing material back, if it is sorted. You must bear the costs of transport. For packing

material that is returned to us unsorted or which we are not obliged to accept, we shall have to invoice you for any costs

incurred.

Components used in life-support devices or systems must be expressly authorized for such purpose! Critical

components 1 , may only be used in life-support devices or systems 2 with the express written approval of OSRAM OS.

1 A critical component is a component usedin a life-support device or system whose failure can reasonably be expected

to cause the failure of that life-support device or system, or to affect its safety or effectiveness of that device or system.

2 Life support devices or systems are intended (a) to be implanted in the human body, or (b) to support and/or maintain

and sustain human life. If they fail, it is reasonable to assume that the health of the user may be endangered.