Part No. L200CWPB3KB-15D Page 1 of 4
L200CWPB3KB-15D
23105 Kashiwa Court, Torrance, CA 90505
Phone: (800) 579-4875 or (310) 534-1505 Fax: (310) 534-1424
E-mail: webmaster@ledtronics.com
Website: http://www.ledtronics.com
DWG NO. DSDC0469
REVISION —
DWG BY:
09-18-06
09-18-06
LL / JAG
09-27-06
PL
__-__-__
__
__-__-__
__
CHK BY:
QA:
MFG:
468nm Pure Blue
5mm, Dome, 8.6mm Height
15° viewing angle
__._ lumens per Watt
(If = 20mA, Ta = 25°C)
Part No. Page 2 of 4
23105 Kashiwa Court, Torrance, CA 90505
Phone: (800) 579-4875 or (310) 534-1505 Fax: (310) 534-1424
E-mail: webmaster@ledtronics.com
Website: http://www.ledtronics.com
L200CWPB3KB-15D DWG NO. DSDC0469
Features:
High intensity •
•
•
•
5mm diameter package
Tinned leads
Pb-free
Package Dimensions:
Part No. Chip Material Lens Color Emission Color
L200CWPB3KB-15D InGaN Water Clear Super Bright Blue
Notes:
1. All dimensions are in millimeters (inches).
2. Tolerance is ±0.25mm (.010”) unless otherwise noted.
3. Protruded resin under flange is 1.0mm (.04”) max.
4. Lead spacing is measured where the leads emerge from the package.
5. Specifications are subject to change without notice.
6. Precautions for ESD: Static electricity and surge can damage the LED. It is recommended
to use a wristband or anti-electrostatic glove when handling the LED. All devices,
equipment and machinery must be properly grounded.
Part No. Page 3 of 4L200CWPB3KB-15D
23105 Kashiwa Court, Torrance, CA 90505
Phone: (800) 579-4875 or (310) 534-1505 Fax: (310) 534-1424
E-mail: webmaster@ledtronics.com
Website: http://www.ledtronics.com
DSDC0469DWG NO.
Absolute Maximum Ratings at Ta=25ºC
Parameter MAX. Unit
Power Dissipation 80 mW
Peak Forward Current (1/10 Duty Cycle, 0.1ms Pulse Width) 100 mA
Continuous Forward Current 20 mA
Derating Linear From 50ºC 0.4 mA/ºC
Reverse Voltage 5 V
Electrostatic Discharge (ESD) 150 V
Operating Temperature Range -30ºC to +80ºC
Storage Temperature Range -40ºC to +100ºC
Lead Soldering Temperature[4mm(.157”) From Body] 260ºC for 5 Seconds
Notes:
1. Luminous intensity is measured with a light sensor and filter combination that approximates the
CIE eye-response curve.
3. The dominant wavelength (λd) is derived from the CIE chromaticity diagram and represents the
single wavelength which defines the color of the device.
2. 1/2 is the off-axis angle at which the luminous intensity is half the axial luminous intensity.
4. Forward voltage measurement allowance is: ±0.1V
5. Luminous Intensity Measurement Allowance is ±10%
θ
Electrical Optical Characteristics at Ta=25ºC
SCP
Lumens
Radiant Intensity
---
---
cd
lm
---
---
---
---
--- 62 --- mW/sr
Parameter Symbol Min. Typ. Max. Unit Test Condition
Luminous Intensity IVmcd IF=20mA (Note 1)
Viewing Angle 21/2 15 Deg (Note 2)
Peak Emission Wavelength 460nm IF=20mA
Dominant Wavelength d 468
---
---
---
--- nm IF=20mA (Note 3)
Spectral Line Half-Width --- 28--- nm IF=20mA
IF=20mA
IF=20mA
IF=20mA
Forward Voltage VF--- 3.24.0 V IF=20mA
Reverse Current IR
Ie
--- --- 50 µA VR=5V
θ
λ
∆λ
λp
-
3300 4500 ---
--- ---
Chromaticity Coordinates x: ~0.14 y: ~0.05IF=20mA
Part No. L200CWPB3KB-15D Page 4 of 4
23105 Kashiwa Court, Torrance, CA 90505
Phone: (800) 579-4875 or (310) 534-1505 Fax: (310) 534-1424
E-mail: webmaster@ledtronics.com
Website: http://www.ledtronics.com
DWG NO. DSDC0469
Typical Electrical / Optical Characteristics Curves
(25ºC Ambient Temperature Unless Otherwise Noted)
0.2
-60
°
-90 1.0
°
0.8 0.6 0.4
-30
°
60
°
0.2 0.4 0.6 1.00.8 90
°
0
°
30
°
Beam Pattern
Relative Intensity (LOP@M AX=1)
Forward Current
Derating Curve
0
10
20
30
40
50
60
0 102030405060708090
Ta (ºC)
Forward Current
IF(mA)
Spec tral R adian ce ( Pea k @ 468 nm)
0. 0
0. 2
0. 4
0. 6
0. 8
1. 0
38 0 40 0 420 440 4 60 4 80 500 52 0 54 0 560 580 600 6 20 640 660 680
Wavelength (nm)
Normalized
Response
Forward Current
vs Forward Voltage
0
5
10
15
20
25
30
35
2.5 2.7 2.93 .13 .3 3.5 3.73 .94 .14 .3 4.5
Forward Voltage VF(V)
Forward Current
IF(mA)
Relative L um in ous In tensity
vs Forw ard Curre nt
0
0.5
1
1.5
2
2.5
3
0 5 10 15 20 25 30 35
Forw ard C urre nt IF(m A)
Relative Intensity
(LOP@20mA=1)
