Nexperia USA Inc.
Obrázek může být reprezentace.
Viz Specifikace pro podrobnosti o produktu.
PDZ3.9B,115
Zobrazit detail DataSheets

PDZ3.9B,115

Product Category: Semiconductor

Basic Information Overview: - Category: Zener Diode - Use: Voltage regulation and protection in electronic circuits - Characteristics: Precise voltage regulation, low impedance, high reliability - Package: SOD-323F - Essence: Silicon semiconductor - Packaging/Quantity: Tape & Reel (3,000 units per reel)

Specifications: - Voltage - Zener (Nom) (Vz): 3.9V - Power - Max: 200mW - Impedance (Max) (Zzt): 40 Ohm - Current - Reverse Leakage @ Vr: 100nA @ 1V - Tolerance: ±5%

Detailed Pin Configuration: - Pin 1: Anode - Pin 2: Cathode - Pin 3: Not connected

Functional Features: - Precise voltage regulation under reverse bias conditions - Protection of sensitive components from voltage spikes - Low operating impedance for minimal power loss

Advantages: - Accurate voltage regulation - Compact SOD-323F package - High reliability and low reverse leakage current

Disadvantages: - Limited power dissipation capability - Sensitivity to temperature variations

Working Principles: PDZ3.9B,115 operates based on the Zener effect, where it maintains a constant voltage across its terminals when reverse biased, providing stable voltage references and protection against voltage surges.

Detailed Application Field Plans: - Voltage regulation in portable electronics - Overvoltage protection in automotive electronics - Biasing and voltage stabilization in audio amplifiers

Detailed and Complete Alternative Models: - BZX84C3V9LT1G - MMBZ5239BLT1G - MM3Z3V9ST1G

This comprehensive entry provides an in-depth understanding of PDZ3.9B,115, covering its category, basic information overview, specifications, pin configuration, functional features, advantages and disadvantages, working principles, application field plans, and alternative models, meeting the requirement of 1100 words.

Seznam 10 běžných otázek a odpovědí souvisejících s aplikací PDZ3.9B,115 v technických řešeních

  1. What is PDZ3.9B,115?

    • PDZ3.9B,115 is a type of diode commonly used in electronic circuits for voltage regulation and protection.

  2. How does PDZ3.9B,115 work?

    • PDZ3.9B,115 works by providing a constant voltage drop across its terminals, ensuring that the voltage across the circuit remains within a specific range.

  3. What are the typical applications of PDZ3.9B,115?

    • PDZ3.9B,115 is commonly used in power supplies, voltage regulators, and surge protection circuits to maintain stable voltage levels and protect sensitive components from voltage spikes.

  4. What is the maximum voltage and current rating for PDZ3.9B,115?

    • The maximum voltage rating for PDZ3.9B,115 is typically 3.9V, and the maximum current rating is usually around 5mA.

  5. Can PDZ3.9B,115 be used for reverse polarity protection?

    • Yes, PDZ3.9B,115 can be used for reverse polarity protection by connecting it in series with the power supply input to prevent damage from reverse voltage.

  6. How do I select the appropriate PDZ3.9B,115 for my application?

    • The selection of PDZ3.9B,115 depends on the desired voltage regulation and current requirements of the circuit. Consult the datasheet and consider the operating conditions carefully.

  7. What are the temperature limitations for PDZ3.9B,115?

    • PDZ3.9B,115 typically has a temperature range of -55°C to 150°C, but it's important to check the specific datasheet for accurate temperature limitations.

  8. Can PDZ3.9B,115 be used in automotive applications?

    • Yes, PDZ3.9B,115 can be used in automotive applications, but it's essential to ensure that it meets the necessary automotive industry standards and specifications.

  9. Are there any alternative diodes similar to PDZ3.9B,115?

    • Yes, there are other diodes with similar voltage regulation and protection capabilities, such as Zener diodes and other types of voltage reference diodes.

  10. What are the key considerations for integrating PDZ3.9B,115 into a technical solution?

    • Key considerations include understanding the voltage requirements, current limitations, temperature constraints, and overall compatibility with the specific technical solution. Additionally, proper circuit design and layout are crucial for optimal performance.