Product Overview: LM4040C30IDBZT
The LM4040C30IDBZT is a precision micro-power shunt voltage reference from Texas Instruments, designed to maintain high stability and accuracy. This device is an ideal choice for space-critical and low-power applications where a stable reference voltage is essential. The LM4040C30IDBZT offers a fixed reverse-breakdown voltage of 3.0V with an impressive accuracy of ±0.1% at 25°C.
Manufactured with an advanced process, the LM4040C30IDBZT exhibits a low dynamic impedance and a wide operating current range, which makes it versatile for various circuits. The device operates over a current range of 45µA to 10mA, providing a stable reference voltage over the entire range of current. This feature ensures that the device can be used in applications with varying current demands without compromising performance.
Key Features:
- Precision Voltage: The LM4040C30IDBZT provides a precise 3.0V output, which is crucial for applications requiring an accurate reference voltage.
- High Accuracy: With an initial accuracy of ±0.1% and temperature coefficient as low as 50 ppm/°C, the device ensures reliable performance across a range of temperatures.
- Low Power Consumption: Its micro-power capabilities make it suitable for battery-powered and portable devices, helping to extend the overall battery life.
- Wide Operating Current Range: The device's broad operating current range offers design flexibility for various applications.
- Small Package: Available in the tiny SOT-23 package, the LM4040C30IDBZT is perfect for applications where space is at a premium.
Applications:
The LM4040C30IDBZT is designed for use in a wide array of applications, including but not limited to:
- Portable, battery-powered equipment
- Data acquisition systems
- Instrumentation
- Medical devices
- Automotive electronics
- Power supplies
With its combination of accuracy, reliability, and small form factor, the LM4040C30IDBZT from Texas Instruments is a top-tier choice for engineers and designers who require a stable voltage reference in their electronic designs.