Vertical Cavity Surface Emitting Laser in T-1 Package

Vertical Cavity Surface Emitting
Laser in T-1 Package
OPV332
•
•
•
•
•
850nm VCSEL technology
High thermal stability
Low drive current
High output power
Narrow Beam Angle
The OPV332 is a Vertical Cavity Surface Emitting Laser (VCSEL) packaged in a dome lens T-1 package.
VCSELs offer many advantages in sensing applications when compared to infrared LEDs. These devices require
substantially lower drive currents to obtain the same amount of output power as LEDs. This feature allows
VCSELs to be used in low power consumption applications such as battery operated equipment.
The dome lens packaging creates a narrow 4 degree beam angle from the device. Long distance applications
may benefit from this feature as secondary optics may be eliminated, reducing total system cost. The OPV332 is
optically and spectrally compatible with Optek’s standard detector products such as the OP500 series phototransistors, OP530 series photodarlingtons and the OP900 series photodiodes.
Applications
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Emission
Surface
Non-contact position sensing
Photoelectric sensors
Optical encoders
Light curtains
VCSEL
Additional laser safety information can
be found on the Optek website. See
application bulletin #221.
Classification is not marked on the
device due to space limitations. See
package outline for centerline of optical radiance. Operating devices beyond maximum rating may result in
hazardous radiation exposure.
1
2
Pb
LEAD FREE
Optek reserves the right to make changes at any time in order to improve design and to supply the best product possible.
OPTEK Technology Inc.— 1645 Wallace Drive, Carrollton, Texas 75006
Phone: (800) 341-4747 FAX: (972) 323– 2396 [email protected] www.optekinc.com
A subsidiary of
TT electronics plc
VCSEL in T-1 Package
OPV332
Absolute Maximum Ratings
TA = 25o C unless otherwise noted
Storage Temperature Range
-40° to +100° C
Operating Temperature Range
0° to +85° C
260° C(1)
Lead Soldering Temperature [1/16 inch (1.6mm) from case for 5 sec with soldering iron]
Maximum Forward Peak Current, Continuous
12 mA
Maximum Reverse Voltage
5V
Maximum Forward Current, pulse (1µs P.W., 10% D.C.)
48 mA
Electrical Characteristics (TA = 25°C unless otherwise noted)
SYMBOL
PARAMETER
POT
Total Power Out
ITH
Threshold Current
VF
Forward Voltage
MIN
IR
Reverse Current
Series Resistance
η
Slope Efficiency
0.28
λ
Wavelength
840
Optical Bandwidth
θ
Beam Divergence
MAX
UNITS
1.5
RS
Δλ
TYP
20
CONDITIONS
mW
IF = 7 mA
3.0
mA
Note 2
2.2
V
IF = 7 mA
100
nA
VR = 5 V
55
ohms
Note 3
mW/mA
Note 4
860
nm
0.85
nm
4
Degrees
FWHM
Δη/ΔT
Temp Coefficient of Slope Efficiency
-0.50
%/°C
(0° - 70°C), Note 4
Δλ/ΔT
Temp Coefficient of Wavelength
0.06
nm/°C
(0° - 70°C)
ΔlTH
Temp Variance of Threshold Current
±1.0
mA
ΔVF/ΔT
Temp Coefficient for Forward Voltage
-2.5
mV/°C
(0° - 70°C), Note 2
(0° - 70°C)
NOTES:
(1) RMA flux is recommended. Solder dwell time can be increased to 10 seconds when flow soldering.
(2) Threshold Current is based on the two line intersection method specified in Telcordia GR-468-Core. Line 1 from 4 mA to 6 mA. Line 2 from 0 mA to 0.5 mA.
(3) Series Resistance is the slope of the Voltage-Current line from 5 to 8 mA.
(4) Slope efficiency, is the slope of the best fit LI line from 5 mA to 8 mA with 0.25mA test intervals.
Normalized Output Power vs.
Forward Current
Typical Angular Output
100%
200%
Normalized Output Power
Relative Output
80%
60%
40%
20%
100%
0%
90
60
30
0
30
60
Normalized at 7mA, 25°C
90
Angular Displacement—Degrees
OPTEK Technology Inc.— 1645 Wallace Drive, Carrollton, Texas 75006
Phone: (800) 341-4747 FAX: (972) 323– 2396 [email protected] www.optekinc.com
0%
0
2
4
6
8
10
12
Forward Current—mA
Issue 1.2 09.09
Page 2 of 2