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NSVBAV23CLT1G Product Overview
Introduction
The NSVBAV23CLT1G is a versatile electronic component that belongs to the category of voltage reference diodes. This entry provides a comprehensive overview of the NSVBAV23CLT1G, including its basic information, specifications, pin configuration, functional features, advantages and disadvantages, working principles, application field plans, and alternative models.
Basic Information Overview
- Category: Voltage Reference Diode
- Use: Provides stable voltage references in various electronic circuits
- Characteristics: High precision, low temperature coefficient, and low dynamic impedance
- Package: SOD-123 package
- Essence: Precision voltage reference
- Packaging/Quantity: Available in reels with a specified quantity per reel
Specifications
- Voltage Reference: 2.3V
- Temperature Coefficient (Typical): 10ppm/°C
- Dynamic Impedance (Typical): 0.5Ω
- Operating Temperature Range: -40°C to 125°C
- Power Dissipation: 250mW
Detailed Pin Configuration
The NSVBAV23CLT1G has a standard SOD-123 package with three pins: anode, cathode, and no-connect.
Functional Features
- Provides a stable and precise voltage reference of 2.3V
- Low temperature coefficient ensures minimal voltage variation with temperature changes
- Low dynamic impedance for improved stability in various circuit applications
Advantages and Disadvantages
Advantages
- High precision and stability
- Wide operating temperature range
- Compact SOD-123 package for easy integration
Disadvantages
- Limited voltage options available
- Sensitive to reverse voltage and current overloads
Working Principles
The NSVBAV23CLT1G operates based on the principle of Zener diode breakdown, providing a stable voltage reference regardless of load variations or temperature changes.
Detailed Application Field Plans
The NSVBAV23CLT1G finds extensive use in precision analog and digital circuits, including: - Voltage regulators - Power management systems - Sensor interfaces - Data acquisition systems - Test and measurement equipment
Detailed and Complete Alternative Models
- NSVBAV22CLT1G: 2.2V voltage reference diode
- NSVBAV24CLT1G: 2.4V voltage reference diode
- NSVBAV25CLT1G: 2.5V voltage reference diode
In conclusion, the NSVBAV23CLT1G is a reliable and precise voltage reference diode suitable for a wide range of electronic applications, offering stability, precision, and compact packaging.
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Énumérez 10 questions et réponses courantes liées à l'application de NSVBAV23CLT1G dans les solutions techniques
What is NSVBAV23CLT1G?
- NSVBAV23CLT1G is a dual series Schottky barrier diode with a forward voltage of 0.38V and a reverse voltage of 30V.
What are the typical applications of NSVBAV23CLT1G?
- It is commonly used in voltage clamping, protection circuits, and high-speed data lines in various technical solutions.
What is the maximum forward current rating for NSVBAV23CLT1G?
- The maximum forward current rating for NSVBAV23CLT1G is 200mA.
What is the operating temperature range for NSVBAV23CLT1G?
- The operating temperature range for NSVBAV23CLT1G is -65°C to +150°C.
Can NSVBAV23CLT1G be used in high-frequency applications?
- Yes, NSVBAV23CLT1G is suitable for high-frequency applications due to its fast switching characteristics.
Does NSVBAV23CLT1G have any special packaging requirements?
- NSVBAV23CLT1G is available in a small SOD-323 package, making it suitable for compact designs.
What is the reverse leakage current of NSVBAV23CLT1G at room temperature?
- The reverse leakage current of NSVBAV23CLT1G at room temperature is typically 2µA.
Is NSVBAV23CLT1G RoHS compliant?
- Yes, NSVBAV23CLT1G is compliant with the Restriction of Hazardous Substances (RoHS) directive.
Can NSVBAV23CLT1G be used in battery-powered devices?
- Yes, NSVBAV23CLT1G's low forward voltage and low power dissipation make it suitable for battery-powered devices.
Are there any recommended layout considerations for using NSVBAV23CLT1G in a circuit?
- It is recommended to minimize trace lengths and keep the diode close to the protected components to reduce parasitic inductance and optimize performance.