2N5401CYTA

Product Overview

Use

It is commonly used as a general-purpose PNP transistor in various electronic circuits.

Characteristics

Low power dissipation
High current gain
Low noise
High voltage capability

Package

The 2N5401CYTA is typically available in a TO-92 package.

Packaging/Quantity

It is usually supplied in reels or tubes, with quantities varying based on manufacturer specifications.

Specifications

Collector-Emitter Voltage: 150V
Collector-Base Voltage: 160V
Emitter-Base Voltage: 5V
Collector Current - Continuous: 600mA
Power Dissipation: 625mW
DC Current Gain (hFE): 200 - 700
Transition Frequency: 150MHz
Operating and Storage Temperature: -55°C to +150°C

Detailed Pin Configuration

The 2N5401CYTA has three pins: 1. Emitter (E) 2. Base (B) 3. Collector (C)

Functional Features

The 2N5401CYTA offers: - Amplification of weak signals - Switching applications - Signal amplification in audio circuits

Advantages and Disadvantages

Advantages

High current gain
Low noise
Suitable for low-power applications

Disadvantages

Limited frequency response compared to other transistors
Relatively lower power dissipation capability

Working Principles

The 2N5401CYTA operates based on the principles of amplification and control of electrical currents. When a small current flows into the base terminal, it controls a larger current flowing between the collector and emitter terminals.

Detailed Application Field Plans

The 2N5401CYTA is widely used in: - Audio amplifiers - Signal processing circuits - Switching circuits - Voltage regulators

Detailed and Complete Alternative Models

Some alternative models to the 2N5401CYTA include: - BC557 - 2N3906 - BC327 - 2N4403

In conclusion, the 2N5401CYTA is a versatile PNP transistor with applications in various electronic circuits, offering high current gain and low noise characteristics. Its compact TO-92 package makes it suitable for use in space-constrained designs.

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기술 솔루션에 2N5401CYTA 적용과 관련된 10가지 일반적인 질문과 답변을 나열하세요.

What is the 2N5401CYTA transistor used for?
- The 2N5401CYTA transistor is commonly used for amplification and switching applications in electronic circuits.
What are the key specifications of the 2N5401CYTA transistor?
- The 2N5401CYTA transistor typically has a maximum collector current of 600mA, a maximum collector-base voltage of 160V, and a maximum power dissipation of 625mW.
How can I identify the pinout of the 2N5401CYTA transistor?
- The pinout of the 2N5401CYTA transistor is typically Emitter (E), Base (B), and Collector (C).
What are some common circuit configurations using the 2N5401CYTA transistor?
- Common circuit configurations include common emitter amplifiers, switch circuits, and voltage regulators.
What are the typical operating conditions for the 2N5401CYTA transistor?
- The 2N5401CYTA transistor is often operated within a temperature range of -55°C to 150°C and at various biasing levels depending on the specific application.
Can the 2N5401CYTA transistor be used for audio amplifier applications?
- Yes, the 2N5401CYTA transistor can be used in low-power audio amplifier circuits due to its amplification capabilities.
What are some common alternatives to the 2N5401CYTA transistor?
- Alternatives to the 2N5401CYTA transistor include the 2N3904, BC547, and BC548 transistors, which have similar characteristics and can be used in similar applications.
How do I calculate the biasing resistors for the 2N5401CYTA transistor in an amplifier circuit?
- Biasing resistors can be calculated using the desired quiescent operating point, the transistor's base-emitter voltage, and the available supply voltage.
What are the typical gain characteristics of the 2N5401CYTA transistor?
- The 2N5401CYTA transistor typically has a current gain (hFE) ranging from 100 to 300, depending on the operating conditions and configuration.
Are there any specific considerations for using the 2N5401CYTA transistor in high-frequency applications?
- In high-frequency applications, parasitic capacitances and lead inductances should be considered to ensure proper performance and stability of the circuit.