Product Overview: TL431BIDBZR,215 - NXP Semiconductors

The TL431BIDBZR,215 from NXP Semiconductors is a precision programmable reference that operates as a low voltage zener with a 0.5% tolerance. This versatile device is a three-terminal adjustable shunt regulator with specified thermal stability over applicable automotive, commercial, and military temperature ranges.

Key Features

• Voltage Range: The device offers a broad range of voltages, from 2.495V to 36V, which are adjustable via external resistors.
• Temperature Compensation: It is well compensated for temperature changes, ensuring a stable output over a wide temperature range.
• Low Output Noise: This reference features low output noise, making it suitable for precision electronics where noise can be a critical factor.
• High Stability: The TL431BIDBZR,215 provides high stability and reliability, which is essential for maintaining consistent performance in critical applications.
• Surface-Mount Package: It comes in a small outline transistor (SOT-23) package, making it ideal for space-constrained applications.

Applications

The TL431BIDBZR,215 can be used in a wide range of applications, including but not limited to:

• Power supplies
• Battery chargers
• Voltage monitoring
• Adjustable current sources
• Switching power supplies

Quality and Reliability

NXP Semiconductors is known for its commitment to quality and the TL431BIDBZR,215 is no exception. This product is designed to meet the stringent requirements of the automotive industry and is qualified to AEC-Q100 standards for automotive reliability.

Environmental Compliance

The device is RoHS compliant, ensuring that it meets the European Union's directives on the restriction of hazardous substances. This makes the TL431BIDBZR,215 an environmentally friendly choice for manufacturers concerned with ecological impact.

With its combination of flexibility, stability, and precision, the TL431BIDBZR,215 from NXP Semiconductors is an excellent choice for designers who require a reliable voltage reference in their electronic systems.