1-4 Cell Li+ Battery SMBus Charge Controller for Supporting Turbo Boost Mode 20-VQFN -40 to 85# BQ24735RGRR Technical Documentation
*Manufacturer: Texas Instruments (TI)*
## 1. Application Scenarios
### Typical Use Cases
The BQ24735RGRR is a synchronous battery charge controller with integrated MOSFETs and power path management, primarily designed for:
Portable Computing Devices
- Laptop Computers : Manages battery charging while simultaneously powering the system
- Ultrabooks & Tablets : Supports slim form factors with minimal external components
- 2-in-1 Convertibles : Handles dynamic power transitions between battery and adapter modes
Industrial Portable Equipment
- Medical Diagnostic Devices : Provides reliable power management for portable medical instruments
- Field Testing Equipment : Ensures continuous operation during battery-adapter switching
- Handheld Scanners & Terminals : Optimizes battery life in logistics and inventory applications
### Industry Applications
- Consumer Electronics : High-end laptops, gaming notebooks, premium tablets
- Enterprise IT : Business laptops, mobile workstations, docking stations
- Medical Technology : Portable patient monitors, diagnostic equipment
- Industrial Automation : Handheld controllers, portable measurement devices
### Practical Advantages
Key Benefits:
- Integrated Power Path Management : Seamless transition between battery and adapter power
- High Efficiency (>95%) : Synchronous switching architecture minimizes power loss
- Compact Solution : 4mm × 4mm VQFN package with minimal external components
- Flexible Charging Profiles : Supports multiple battery chemistries (Li-ion, Li-polymer)
- Advanced Safety Features : Over-voltage, over-current, and thermal protection
Limitations:
- Maximum Input Voltage : 24V DC limits high-voltage applications
- Charging Current : Up to 8A may be insufficient for high-capacity battery packs
- Temperature Monitoring : Requires external NTC thermistor for optimal performance
- Battery Detection : Dependent on SMBus communication with host system
## 2. Design Considerations
### Common Design Pitfalls and Solutions
Pitfall 1: Inadequate Thermal Management
- Issue : Overheating during high-current charging
- Solution : Implement proper thermal vias, copper pours, and consider additional heatsinking
Pitfall 2: Power Supply Sequencing Problems
- Issue : Incorrect startup sequence causing system instability
- Solution : Follow recommended power-up sequence: VCC → ACOK → SMBus communication
Pitfall 3: SMBus Communication Failures
- Issue : Communication errors with host processor
- Solution : Ensure proper pull-up resistors (2.2kΩ typical) and clean signal routing
### Compatibility Issues
Power Source Compatibility
- AC Adapters : Requires 19V-20V typical laptop adapters
- USB-C Power Delivery : Not natively supported; requires additional PD controller
- Battery Packs : Compatible with 2-4 series Li-ion cells (7.4V-16.8V)
System Integration
- Host Processors : Requires SMBus-compatible microcontroller
- Battery Packs : Must include compatible gas gauge IC (e.g., TI bq series)
- Power Management : May conflict with other power ICs without proper isolation
### PCB Layout Recommendations
Power Stage Layout
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Critical Priorities:
1. Keep input capacitors (CIN) close to VIN and GND pins
2. Minimize loop area in high-current paths (BAT, SRN, SRP)
3. Use thick copper traces for battery and adapter connections
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Signal Routing Guidelines
- SMBus Lines : Route as differential pair with proper impedance control
- Analog Sensing : Keep SRN/SRP traces away from noisy digital signals
- Thermal Management : Use
