Hex Buffers with High Voltage Open-Collector Outputs# DM7417M Hex Buffer/Driver with High-Voltage Open-Collector Outputs
Manufacturer : FAIRCHILD
## 1. Application Scenarios
### Typical Use Cases
The DM7417M serves as a robust interface between low-level logic circuits and high-voltage/high-current peripheral devices. Its primary function is to buffer digital signals while providing voltage level translation and current driving capability.
Key implementations include:
- LED Display Driving : Capable of sinking up to 30mA per output, making it ideal for driving LED indicators and seven-segment displays directly from TTL logic outputs
- Relay and Solenoid Control : Open-collector outputs allow switching of inductive loads up to 15V, enabling direct control of relays, solenoids, and small motors
- Logic Level Translation : Bridges 5V TTL logic systems with higher voltage systems (up to 15V) through its open-collector output configuration
- Wired-OR Applications : Multiple outputs can be connected together to create wired-OR logic functions without external components
- Bus Driving : Suitable for driving bus lines in multi-drop configurations where multiple devices share communication lines
### Industry Applications
Industrial Automation :
- PLC output modules for actuator control
- Sensor interface circuits requiring voltage translation
- Panel indicator driving in control systems
Automotive Electronics :
- Dashboard indicator drivers
- Relay control modules
- Body control module interfaces
Consumer Electronics :
- Appliance control panels
- Audio equipment display drivers
- Power supply status indicators
Telecommunications :
- Line card status indicators
- Equipment rack status displays
- Test equipment interfaces
### Practical Advantages and Limitations
Advantages:
- High Current Sinking : 30mA per channel capability eliminates need for external drivers in many applications
- Voltage Flexibility : Open-collector outputs support operation with supply voltages up to 15V
- TTL Compatibility : Direct interface with standard TTL logic families
- Robust Design : Standard 14-pin DIP package with proven reliability
- Simple Implementation : Minimal external components required for most applications
Limitations:
- Pull-up Requirement : External pull-up resistors needed for proper high-level output
- Power Dissipation : Maximum power dissipation of 500mW limits simultaneous use of all outputs at maximum current
- Speed Constraints : Propagation delay of 27ns typical limits high-frequency applications
- Output Saturation Voltage : V_CE(sat) of 0.4V typical at 16mA affects low-level voltage margins
## 2. Design Considerations
### Common Design Pitfalls and Solutions
Pitfall 1: Inadequate Pull-up Resistor Selection
- Problem : Incorrect pull-up values cause slow rise times or excessive power consumption
- Solution : Calculate optimal value based on load capacitance and required switching speed
- Fast switching: Use lower values (1kΩ-2.2kΩ)
- Low power: Use higher values (4.7kΩ-10kΩ)
Pitfall 2: Thermal Management Issues
- Problem : Simultaneous maximum current operation causes overheating
- Solution : Implement current limiting or derate outputs when multiple channels are active
- Derate to 20mA per output when 4+ outputs active
- Add heatsink for continuous high-current operation
Pitfall 3: Inductive Load Transients
- Problem : Back-EMF from relays/solenoids damages outputs
- Solution : Include flyback diodes across inductive loads
- Use fast recovery diodes (1N4148) for small inductors
- Use Schottky diodes for better protection
### Compatibility Issues with Other Components
TTL Logic Families :
- Direct compatibility with 74
