LED420-series TECHNICAL DATA Visible LED InGaN LED420-series are InGaN LEDs mounted on a lead frame and encapsulated in various types of clear silicone lens, which offers different design settings. On forward bias, it emits a radiation of typical 15 mW at a peak wavelength at 420 nm. Specifications • • • • • Structure: InGaN Peak Wavelength: typ. 420 nm Optical Ouput Power: typ. 15 mW Resin Material: Clear silicone resin Solder: Lead free Absolute Maximum Ratings (Ta=25°C) Type Power Dissipation Forward Current Reverse Voltage Operating Temperature Storage Temperature Soldering Temperature (for 5 sec.) Symbol PD IF VR TOP TSTG TSOL Value 200 50 5 -30 … +85 -40 … +100 265 Unit mW mA V °C °C °C Electro-Optical Characteristics (Ta=25°C) Item Forward Voltage Reverse Current Radiated Power Peak Wavelength Half Width 21.11.2011 Symbol VF IR PO λP Δλ Condition IF = 20 mA VR = 5 V IF = 20 mA IF = 20 mA IF = 20 mA LED420-series Min. 415 - Typ. 3.4 15 420 15 Max. 4.0 10 425 - Unit V µA mW nm nm 1 of 8 Characteristics of Radiant Intensity (Ta=25°C) Type LED420-01 LED420-02 LED420-03 LED420-04 LED420-05 LED420-06 LED420-09 LED420-46 LED420-41 LED420-42 LED420-31 LED420-33 LED420-34 LED420-36 Viewing Half Angle ±8° ±5° ±10° ±20° ±50° ±4° ±25° (long) ±10° (short) Brightness / Radiation Intensity (IF = 20 mA) [Unit: mW/sr] Min. Typ. Max. 60 60 40 12 4 90 ±14° ±20° ±13° 18 ±25° 9 Outer Dimension Dimension Figure Ø5 Ø5 Ø5 Ø5 Ø5 Ø5 Ø5 Oval Ø5 Ø4 Ø4 Ø3 Ø3 Ø3 Ø3 1 2 3 4 5 6 7 8 9 10 11 12 13 14 * Radiant Power is measured by S3584-08 * Radiant Intensity is measured by Ando Optical Multi Meter AQ2140 & AQ2741 The above specifications are for reference purpose only and subjected to change without prior notice. Outer Dimensions 21.11.2011 Figure-1 Ø 5Mold (Type 01) Figure-2 Ø 5Mold (Type 02) Figure-3 Ø 5Mold (Type 03) Figure-4 Ø 5Mold (Type 04) LED420-series 2 of 8 21.11.2011 Figure-5 Ø 5Mold (Type 05) Figure-6 Ø 5Mold (Type 06) Figure-7 Ø 5Mold (Type 09) Figure-8 Ø 5Mold (Type 46) Figure-9 Ø 4Mold (Type 41) Figure-10 Ø 4Mold (Type 42) Figure-11 Ø 3Mold (Type 31) Figure-12 Ø 3Mold (Type 33) Figure-13 Ø 3Mold (Type 34) Figure-14 Ø 3Mold (Type 36) LED420-series 3 of 8 Viewing half angle 21.11.2011 Figure-1 Ø 5Mold (Type 01) Figure-2 Ø 5Mold (Type 02) Figure-3 Ø 5Mold (Type 03) Figure-4 Ø 5Mold (Type 04) Figure-5 Ø 5Mold (Type 05) Figure-6 Ø 5Mold (Type 06) Figure-7 Ø 5Mold (Type 09) Figure-8 Ø 5Mold (Type 46) Figure-9 Ø 4Mold (Type 41) Figure-10 Ø 4Mold (Type 42) LED420-series 4 of 8 Figure-11 Ø 3Mold (Type 31) Figure-12 Ø 3Mold (Type 33) Figure-13 Ø 3Mold (Type 34) Figure-14 Ø 3Mold (Type 36) Typical Performance Curves Forward Current – Forward Voltage 21.11.2011 Relative Radiant Intensity – Pulsed Forward Current LED420-series 5 of 8 Forward Current – Pulse Duration Forward Voltage – Ambient Temperature Relative Radiant Intensity – Ambient Temperature Allowable Forward Current – Ambient Temperature 21.11.2011 LED420-series 6 of 8 Peak Wavelength Peak Wavelength – Ambient Temperature Precaution for Use 1. Cautions • DO NOT look directly into the emitted light or look through the optical system. To prevent in adequate exposure of the radiation, wear protective glasses. 2. Lead Forming • When forming leads, the leads should be bent at a point at least 3 mm from the base of the lead. DO NOT use the base of the leadframe as a fulcrum during lead forming. • Lead forming should be done before soldering. • DO NOT apply any bending stress to the base of the lead. The stress to the base may damage the LED’s characteristics or it may break the LEDs. • When mounted the LEDs onto the printed circuit board, the holes on the circuit board should be exactly aligned with the leads of LEDs. If the LEDs are mounted with stress at the leads, it causes deterioration of the lead and it will degrade the LEDs. 21.11.2011 LED420-series 7 of 8 Recommended Land Layout (Unit: mm) 3. Soldering Conditions • Solder the LEDs no closer than 3 mm from the base of the lead. • DO NOT apply any stress to the lead particularly when heat. • The LEDs must not be reposition after soldering. • After soldering the LEDs, the lead should be protected from mechanical shock or vibration until the LEDs return to room temperature. • When it is necessary to clamp the LEDs to prevent soldering failure, it is important to minimize the mechanical stress on the LEDs. • Cut the LED leads at room temperature. Cutting the leads at high temperature may cause the failure of the LEDs. Soldering Conditions 4. Static Electricity • The LEDs are very sensitive to Static Electricity and surge voltage. So it is recommended that a wrist band or an anti-electrostatic glove be used when handling the LEDs. • All devices, equipment and machinery must be grounded properly. It is recommended that precautions should be taken against surge voltage to the equipment that mounts the LEDs. 21.11.2011 LED420-series 8 of 8