BZX384C3V6-HE3-08
Introduction
The BZX384C3V6-HE3-08 is a voltage regulator diode that belongs to the category of semiconductor devices. This entry provides an overview of its basic information, specifications, pin configuration, functional features, advantages and disadvantages, working principles, application field plans, and alternative models.
Basic Information Overview
- Category: Semiconductor Devices
- Use: Voltage Regulation
- Characteristics: Low forward voltage drop, high surge current capability
- Package: SOD-323
- Essence: Voltage regulation and transient voltage suppression
- Packaging/Quantity: Available in tape and reel packaging with varying quantities
Specifications
- Voltage: 3.6V
- Power Dissipation: 250mW
- Forward Voltage Drop: 0.9V
- Reverse Leakage Current: 5µA
- Operating Temperature Range: -65°C to +150°C
Detailed Pin Configuration
The BZX384C3V6-HE3-08 has a standard SOD-323 package with two pins. The pinout configuration is as follows: 1. Pin 1: Anode 2. Pin 2: Cathode
Functional Features
- Voltage Regulation: Provides stable 3.6V output voltage
- Transient Voltage Suppression: Protects against voltage spikes and transients
- Low Forward Voltage Drop: Ensures minimal power loss
Advantages and Disadvantages
Advantages
- Reliable voltage regulation
- High surge current capability
- Compact SOD-323 package
- Low forward voltage drop
Disadvantages
- Limited maximum power dissipation
- Narrow operating temperature range
Working Principles
The BZX384C3V6-HE3-08 operates based on the principle of Zener diode voltage regulation. When the input voltage exceeds 3.6V, the diode conducts and regulates the output voltage to maintain a constant 3.6V level. Additionally, it suppresses transient voltage spikes by diverting excess current.
Detailed Application Field Plans
The BZX384C3V6-HE3-08 finds applications in various electronic circuits requiring stable voltage regulation and transient voltage suppression. Some specific application fields include: - Power supply units - Voltage reference circuits - Overvoltage protection systems - Signal conditioning circuits
Detailed and Complete Alternative Models
Some alternative models to the BZX384C3V6-HE3-08 include: - BZX384C3V6-HE3-09 - BZX384C3V6-HE3-10 - BZX384C3V6-HE3-11
These alternative models offer similar voltage regulation and transient voltage suppression capabilities, with variations in characteristics such as power dissipation and reverse leakage current.
In conclusion, the BZX384C3V6-HE3-08 is a semiconductor voltage regulator diode with specific characteristics and applications. Its reliable performance in voltage regulation and transient voltage suppression makes it a valuable component in various electronic circuits.
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What is the BZX384C3V6-HE3-08?
- The BZX384C3V6-HE3-08 is a 3.6V Zener diode designed for voltage regulation and protection in electronic circuits.
What are the typical applications of BZX384C3V6-HE3-08?
- It is commonly used for voltage reference, voltage clamping, and surge suppression in various technical solutions.
What is the maximum power dissipation of BZX384C3V6-HE3-08?
- The maximum power dissipation is typically around 300mW.
What is the voltage tolerance of BZX384C3V6-HE3-08?
- The voltage tolerance is typically ±5%.
What is the operating temperature range for BZX384C3V6-HE3-08?
- The operating temperature range is usually -65°C to +150°C.
How does BZX384C3V6-HE3-08 protect against voltage spikes?
- It acts as a voltage clamp, limiting the voltage across the circuit it protects.
Can BZX384C3V6-HE3-08 be used for voltage regulation?
- Yes, it can be used as a stable reference voltage source in voltage regulation circuits.
What are the package options available for BZX384C3V6-HE3-08?
- It is commonly available in SOD-323 surface mount packages.
Is BZX384C3V6-HE3-08 suitable for low-power applications?
- Yes, it is suitable for low-power applications due to its low power dissipation.
Are there any specific layout considerations when using BZX384C3V6-HE3-08?
- It is recommended to keep short traces and minimize parasitic inductance for optimal performance.