Timing Generator IC for 4200 k-pixwl CCD # Technical Documentation: LR38620 Infrared Emitting Diode
## 1. Application Scenarios
### Typical Use Cases
The LR38620 is a high-power infrared (IR) emitting diode designed for applications requiring reliable, long-distance infrared signal transmission. Its primary use cases include:
- Infrared Remote Control Systems : Used in consumer electronics (TVs, audio systems, air conditioners) and industrial remote controls where consistent signal transmission up to 30 meters is required
- Infrared Data Transmission : Suitable for short-range data communication systems, particularly in environments where RF interference is problematic
- Object Detection and Proximity Sensing : Employed in automated systems, security devices, and industrial automation for non-contact object detection
- Night Vision Illumination : Provides invisible illumination for security cameras and night vision equipment
- Optical Switches and Encoders : Used in position sensing and rotational encoding applications
### Industry Applications
- Consumer Electronics : Universal remote controls, smart home devices, gaming peripherals
- Security and Surveillance : IR illuminators for CCTV cameras, motion detectors, intrusion alarms
- Industrial Automation : Machine vision systems, conveyor belt monitoring, robotic guidance
- Automotive : Garage door openers, tire pressure monitoring systems (TPMS), in-car entertainment controls
- Medical Devices : Non-contact thermometers, pulse oximeters (with appropriate filtering)
- Telecommunications : IR-based data links for secure short-range communication
### Practical Advantages and Limitations
Advantages:
- High radiant intensity (typically 40-60 mW/sr at 100 mA) enables longer transmission distances
- Narrow emission angle (±15°) provides focused beam for directional applications
- Fast response time (<100 ns) suitable for high-speed data transmission
- Compatible with standard IR receiver modules (38 kHz modulation)
- Robust construction with epoxy resin encapsulation for environmental protection
- Low forward voltage requirement (typically 1.35V) enables battery-powered operation
Limitations:
- Limited to line-of-sight applications due to IR spectrum characteristics
- Susceptible to interference from ambient light sources (sunlight, incandescent bulbs)
- Requires precise alignment with receiver in directional applications
- Output power degrades with temperature increase (approximately -0.5%/°C)
- Not suitable for applications requiring visible light indication
## 2. Design Considerations
### Common Design Pitfalls and Solutions
Pitfall 1: Inadequate Current Limiting
- Problem : Direct connection to voltage source without current limiting can destroy the diode
- Solution : Always implement a series current-limiting resistor. Calculate using: R = (V_supply - V_f) / I_f
Pitfall 2: Thermal Management Issues
- Problem : Continuous operation at maximum current without heat sinking reduces lifespan
- Solution : Implement pulse operation mode or add heat sinking for continuous operation
Pitfall 3: Ambient Light Interference
- Problem : Sunlight or artificial light sources can saturate IR receivers
- Solution : Use modulated signals (typically 38-40 kHz) with corresponding receiver filtering
Pitfall 4: Optical Misalignment
- Problem : Poor alignment reduces effective transmission distance
- Solution : Implement mechanical alignment features or use lenses to widen effective angle
### Compatibility Issues with Other Components
IR Receiver Compatibility:
- Ensure receiver is tuned to the LR38620's peak wavelength (typically 940 nm)
- Match modulation frequency between transmitter and receiver (commonly 38 kHz)
- Verify receiver's minimum irradiance sensitivity aligns with transmitter output
Microcontroller Interface:
- Most microcontrollers cannot source sufficient current directly
- Requires transistor driver circuit (NPN or MOSFET) for proper operation
- Consider using dedicated IR encoder ICs for complex protocols (RC5, NEC, Sony SIRC)
Power Supply
