The DDZ9678Q-7 is a high-quality Zener diode from Diodes Incorporated, renowned for its precision and reliability in voltage regulation applications. This small surface-mount device is designed to provide a precise voltage reference in a variety of electronic circuits, making it an essential component for designers looking for stable and consistent performance.
Key Features
- Voltage Regulation: The DDZ9678Q-7 offers a nominal Zener voltage of 10V, making it suitable for a range of voltage stabilization tasks.
- Power Dissipation: With a power dissipation rating of 500mW, this Zener diode can handle moderate levels of power without compromising its operational integrity.
- Tolerance: It features a tight tolerance level, ensuring precise voltage regulation and minimal variance in performance.
- Package: Encased in an SOD-123 package, the DDZ9678Q-7 is compact and suitable for high-density mounting, allowing for efficient use of PCB space.
- Operating Temperature: The device is designed to operate within a wide temperature range, ensuring reliability and stability across different environmental conditions.
Applications
The DDZ9678Q-7 Zener diode is used in a variety of applications, including but not limited to:
- Power supply regulation
- Overvoltage protection circuits
- Voltage reference in precision circuits
- Switching power supplies
- Consumer electronics
Quality and Reliability
Diodes Incorporated is committed to delivering high-quality components that meet the rigorous demands of the electronics industry. The DDZ9678Q-7 Zener diode is manufactured with the highest standards of quality control, ensuring that each device performs to its specifications. With its robust design and dependable performance, the DDZ9678Q-7 is a go-to choice for engineers and designers who require a reliable voltage reference solution.
For detailed specifications, technical data, and application notes, customers are encouraged to refer to the official datasheet provided by Diodes Incorporated. This will ensure the successful integration of the DDZ9678Q-7 into their electronic designs.