Product Overview: TLV431AH6TA from Diodes Incorporated

The TLV431AH6TA is a precision low-voltage shunt regulator offered by Diodes Incorporated, a leading global manufacturer and supplier of high-quality application-specific standard products within the broad discrete, logic, analog, and mixed-signal semiconductor markets. This particular device is designed to provide a reliable solution for adjustable voltage regulation while maintaining stability when used with capacitive loads.

Featuring a low output voltage range that is adjustable from 1.24V to 16V with a typical dynamic impedance of 0.22 ohms, the TLV431AH6TA is an ideal choice for precision voltage regulation in a variety of applications. Its low threshold voltage and wide operating voltage range make it suitable for use in numerous applications, including power supplies, battery chargers, and voltage monitors.

The TLV431AH6TA is characterized by its tight voltage tolerance, boasting a reference voltage tolerance of ±1% at 25°C. This accuracy is maintained over a wide temperature range from -40°C to +85°C, ensuring reliable performance in various operating conditions. The shunt regulator's low minimum cathode current for regulation, typically at 0.4mA, allows for efficient operation, making it an energy-conscious choice for power-sensitive designs.

Packaged in a small SOT-23 surface-mount package, the TLV431AH6TA is designed for space-conscious applications where board space is at a premium. The compact form factor does not compromise its robustness, with the device capable of handling continuous cathode currents up to 15mA. This makes it a versatile component for both portable and stationary electronic systems.

In summary, the TLV431AH6TA shunt regulator from Diodes Incorporated is a high-performance solution for applications requiring precise voltage control. Its low operational current, adjustable output voltage, and tight voltage tolerances, combined with a small package size, make it an excellent choice for designers looking to optimize power management in their electronic circuits.