Product Overview: LM336DRG4-2.5 Voltage Reference

The LM336DRG4-2.5 is a precision 2.5V shunt regulator diode designed to provide a stable reference voltage for accuracy-critical applications. Manufactured by Texas Instruments, a leader in semiconductor solutions, this voltage reference is a reliable component for various electronic circuits, including power supplies, digital voltmeters, and precision instrumentation.

Key Features

• Voltage Accuracy: The device maintains a high level of accuracy, with an initial tolerance of ±1%, ensuring precise voltage regulation for sensitive circuits.
• Temperature Coefficient: With a low temperature coefficient, the LM336DRG4-2.5 offers stable performance over a wide temperature range, making it suitable for temperature-critical applications.
• Adjustable Output: While the device comes pre-trimmed to 2.5V, it can be adjusted over a range from 1V to over 10V with the use of external resistors, providing versatility in its application.
• Low Dynamic Impedance: The dynamic impedance of the LM336DRG4-2.5 is low, ensuring good load regulation in response to changing load conditions.

Applications

• Power Supply Control
• Digital Voltmeters
• Operational Amplifier Circuitry
• Precision Current Regulators
• Battery-Powered Equipment

Package and Quality

The LM336DRG4-2.5 comes in an 8-pin SOIC package, which is well-suited for space-constrained applications. The device is part of Texas Instruments' Green initiative, and it is RoHS compliant, minimizing the environmental impact by excluding hazardous substances. Texas Instruments ensures high manufacturing standards, providing a reliable and consistent performance for the LM336DRG4-2.5 voltage reference.

Summary

In summary, the LM336DRG4-2.5 from Texas Instruments is a high-precision, adjustable shunt voltage reference, offering excellent stability and accuracy for a variety of electronic applications. Its low temperature coefficient and wide adjustment range make it a versatile choice for designers looking to maintain voltage integrity within their circuits.