LED Emitters - Infrared, UV, Visible

Part Number	Description / PDF	Quantity
APA1606SF4C-P22 Kingbright	1.6X0.6MM RA. INFRARED SMD LED	1
WP7113F3BT Kingbright	5MM INFRARED EMITTER	464
APT2012SF4C-PRV Kingbright	EMITTER IR 880NM 50MA 0805	23878
WP710A10F3BT Kingbright	3MM INFRARED EMITTER	0
ATS2012UV385 Kingbright	LED	1995
ATS2012UV415 Kingbright	LED	884
APPA3010SF4C-P22 Kingbright	INFRARED EMITTERS RA INFARED 1MW	47
WP7113SF6C Kingbright	5MM INFRARED EMITTER	991
APA3010F3C-GX Kingbright	EMITTER IR 940NM 50MA SMD	29835
WP7113SF7C Kingbright	5MM INFRARED EMITTER	980
AA3528AF3C Kingbright	EMITTER IR 940NM 50MA PLCC	7246
ATS2012UV395 Kingbright	LED	1922
APHHS1005F3C-70MAV Kingbright	INFRARED EMITTING DIODE	2727
APA3010F3C Kingbright	EMITTER IR 940NM 50MA SMD	0
APTD1608SF4C Kingbright	INFRARED EMITTING DIODE	1982
AA3528F3S Kingbright	EMITTER IR 940NM 50MA PLCC	1500
ATDS3534UV395B Kingbright	LED	80
APTR3216F3C Kingbright	LED SMD	1195
WP3A10SF7C Kingbright	EMITTER IR 850NM 50MA RADIAL	0
AP2012SF4C Kingbright	EMITTER IR 880NM 50MA 2012	0

LED Emitters - Infrared, UV, Visible

1. Overview

Light Emitting Diodes (LEDs) are semiconductor devices that convert electrical energy into light. The categories of infrared (IR), ultraviolet (UV), and visible LEDs are differentiated by their emission wavelengths. These devices play critical roles in modern technology, enabling applications from communication systems to medical diagnostics, with advantages including energy efficiency, compact size, and long operational lifetimes.

2. Main Types and Functional Classification

Type	Functional Characteristics	Application Examples
Infrared LEDs	850-940 nm wavelength, low power consumption, invisible emission	Remote controls, night vision cameras, optical sensors
UV LEDs	280-400 nm wavelength, germicidal properties, high photon energy	Water purification, counterfeit detection, medical disinfection
Visible LEDs	400-700 nm wavelength, high brightness, color tunability	Lighting, displays, automotive indicators

3. Structure and Composition

LED emitters typically consist of: - Die: Semiconductor material (e.g., GaAs for IR, AlGaN for UV, InGaN for visible) - Substrate: Sapphire or silicon carbide for mechanical support - Encapsulation: Epoxy or silicone lens for light extraction and protection - Contact Layers: Metal electrodes for electrical connection - Thermal Pad: For heat dissipation in high-power devices

4. Key Technical Specifications

Parameter	Description	Importance
Wavelength ( )	Peak emission spectrum	Determines application suitability
Optical Power	Light output (mW or W)	Performance in sensing/illumination
Efficiency (W/W)	Electrical-to-optical conversion rate	Energy consumption and thermal management
Viewing Angle	Light emission spread ( )	Optical design flexibility
Operating Temperature	-40 C to +125 C range	Reliability in harsh environments

5. Application Fields

Major industries include: - Consumer Electronics: Smartphones (proximity sensors), TVs (backlighting) - Healthcare: Pulse oximeters (IR), sterilization equipment (UV) - Industrial: Machine vision systems (visible), chemical detection (UV) - Security: Surveillance cameras (IR), document authentication (UV) - Automotive: Brake lights (visible), LiDAR systems (IR)

6. Leading Manufacturers and Products

Manufacturer	Product Examples	Key Features
OSRAM Opto	SFH 4715A (IR)	940 nm, 1.5 W radiant power
Cree LED	UV5T-3535 (UV)	365 nm, 120 mW output
Nichia Corporation	NCSxW215BS (Visible)	White LED with 215 lm output

7. Selection Recommendations

Key factors include: - Spectral matching to target application (e.g., 280-320 nm for DNA analysis) - Thermal management requirements (e.g., heatsinks for >1 W devices) - Environmental conditions (e.g., IP67 rating for outdoor use) - Cost vs. performance tradeoffs (e.g., high-efficiency UV LEDs for sterilization) - Compatibility with drive electronics (current/voltage specifications)

8. Industry Trends

Emerging developments: - Miniaturization for wearable devices (e.g., sub-1 mm IR LEDs) - Increased UV-C efficiency (targeting 10% wall-plug efficiency) - Integration with IoT systems (smart lighting networks) - Advancements in phosphor conversion for visible LEDs - Wide bandgap semiconductor adoption (GaN-on-SiC substrates) - Environmental regulations driving mercury-free UV solutions