Opto-Electronic Device# Technical Documentation: LN516GA Lithium Coin Cell Battery
## 1. Application Scenarios
### Typical Use Cases
The LN516GA is a 3V lithium manganese dioxide (Li-MnO₂) coin cell battery designed for long-term, low-power applications. Its primary use cases include:
- Memory Backup Power : Maintaining volatile memory (SRAM) in industrial controllers, medical devices, and automotive systems during main power interruptions
- Real-Time Clock (RTC) Circuits : Powering timekeeping circuits in servers, networking equipment, and embedded systems
- Portable Medical Devices : Providing backup power for glucose meters, digital thermometers, and portable monitors
- IoT Edge Devices : Serving as primary or backup power for wireless sensors, smart tags, and remote monitoring systems
- Consumer Electronics : Powering configuration memory in televisions, set-top boxes, and gaming consoles
### Industry Applications
- Automotive : Infotainment systems, telematics control units, and keyless entry systems
- Industrial Automation : PLCs, HMI panels, and measurement instruments requiring parameter retention
- Telecommunications : Base station controllers, network switches, and optical line terminals
- Medical : Patient monitors, diagnostic equipment, and portable therapeutic devices
- Smart Metering : Electricity, water, and gas meters requiring time-stamped data logging
### Practical Advantages
- Extended Shelf Life : 10-year storage capability with minimal capacity loss (≤1% annual self-discharge at 20°C)
- Wide Temperature Range : Operational from -40°C to +85°C, suitable for harsh environments
- High Energy Density : 225mAh capacity in compact CR11108-sized package (11.6mm diameter × 1.8mm height)
- Stable Voltage Profile : Flat discharge curve maintains ~3V throughout most of discharge cycle
- Mercury-Free Construction : RoHS compliant and environmentally conscious design
### Limitations
- Limited Current Capability : Maximum continuous discharge current of 1mA (3mW), unsuitable for high-power applications
- Non-Rechargeable : Primary cell design prohibits recharging attempts (risk of leakage or rupture)
- Voltage Sensitivity : Prolonged exposure to voltages above 3.2V during charging circuits can damage cell
- Mounting Constraints : Requires proper pressure distribution in battery holders to avoid casing deformation
## 2. Design Considerations
### Common Design Pitfalls and Solutions
Pitfall 1: Incorrect Polarity Connection
- Problem : Reverse polarity connection during assembly causes immediate cell damage
- Solution : Implement foolproof battery holders with polarized design and clear marking on PCB silkscreen
Pitfall 2: Excessive Load Current
- Problem : Attempting to draw >1mA continuous current causes voltage drop and reduced service life
- Solution :
- Implement current-limiting resistors in series with battery
- Use MOSFET switching to isolate battery during normal operation
- Add parallel capacitor (10-100µF) to handle brief current spikes
Pitfall 3: Charging Circuit Malfunction
- Problem : Faulty charging circuits applying voltage to battery during main power operation
- Solution :
- Implement Schottky diode isolation (BAT54S recommended)
- Add voltage monitoring circuit to disable charging above 3.1V
- Use dedicated battery protection ICs (e.g., Seiko S-82 series)
Pitfall 4: Thermal Management Issues
- Problem : Exposure to temperatures >85°C during reflow soldering of nearby components
- Solution :
- Install battery after all reflow processes complete
- Use temporary thermal shields during assembly
- Design battery location away from heat-generating components
### Compatibility Issues
With Active
