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2N4403RLRM
Product Overview
Category
The 2N4403RLRM belongs to the category of small signal transistors.
Use
It is commonly used for amplification and switching applications in electronic circuits.
Characteristics
- Small size
- Low power consumption
- High gain
- Low noise
Package
The 2N4403RLRM is typically available in a TO-92 package.
Essence
This transistor is essential for low-power, high-frequency applications.
Packaging/Quantity
It is usually packaged in reels or tubes, with quantities varying based on manufacturer specifications.
Specifications
- Maximum Collector-Emitter Voltage: 40V
- Maximum Collector-Base Voltage: 60V
- Maximum Emitter-Base Voltage: 6V
- Collector Current - Continuous: 600mA
- Power Dissipation: 625mW
- DC Current Gain (hFE): 100 - 300
- Transition Frequency: 250MHz
Detailed Pin Configuration
The 2N4403RLRM has three pins: 1. Emitter (E) 2. Base (B) 3. Collector (C)
Functional Features
- High voltage capability
- Low leakage current
- Fast switching speed
Advantages
- Small size allows for use in compact circuit designs
- Low power consumption
- High gain makes it suitable for amplification purposes
Disadvantages
- Limited maximum collector current compared to other transistors
- Moderate transition frequency
Working Principles
The 2N4403RLRM operates as a semiconductor device, controlling current flow between its terminals based on the voltage applied at the base terminal.
Detailed Application Field Plans
This transistor is widely used in various electronic applications such as: - Audio amplifiers - Signal amplification circuits - Switching circuits - Oscillator circuits
Detailed and Complete Alternative Models
Some alternative models to the 2N4403RLRM include: - BC557 - 2N3904 - 2N2222
In conclusion, the 2N4403RLRM is a versatile small signal transistor with applications in amplification and switching circuits. Its compact size, low power consumption, and high gain make it a popular choice for various electronic designs.
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Liệt kê 10 câu hỏi và câu trả lời thường gặp liên quan đến ứng dụng 2N4403RLRM trong giải pháp kỹ thuật
What is the 2N4403RLRM transistor used for?
- The 2N4403RLRM is a general-purpose PNP bipolar junction transistor commonly used in amplification and switching applications.
What are the key specifications of the 2N4403RLRM transistor?
- The 2N4403RLRM has a maximum collector current of 600mA, a maximum collector-emitter voltage of 40V, and a maximum power dissipation of 625mW.
How can I identify the pinout of the 2N4403RLRM transistor?
- The pinout of the 2N4403RLRM transistor is typically identified as the emitter (E), base (B), and collector (C) when viewing the flat side with the leads pointing down.
What are some common circuit configurations using the 2N4403RLRM transistor?
- Common circuit configurations include common-emitter amplifiers, switch circuits, and voltage regulators.
What are the typical applications of the 2N4403RLRM transistor?
- Typical applications include audio amplifiers, signal processing circuits, motor control, and general purpose switching.
What are the recommended operating conditions for the 2N4403RLRM transistor?
- The recommended operating temperature range is -55°C to 150°C, and the maximum junction temperature is 150°C.
How do I calculate the base current and resistor values for driving the 2N4403RLRM transistor?
- The base current can be calculated using the desired collector current and the current gain (hFE) of the transistor. The base resistor value can then be determined using Ohm's law.
What are the typical hFE (current gain) values for the 2N4403RLRM transistor?
- The hFE values typically range from 100 to 300 under specified test conditions.
Can the 2N4403RLRM transistor be used in high-frequency applications?
- While the 2N4403RLRM can be used in moderate frequency applications, it may not be suitable for very high-frequency designs due to its transition frequency limitations.
Are there any common pitfalls or considerations when using the 2N4403RLRM transistor in technical solutions?
- It's important to consider thermal management, proper biasing, and voltage/current ratings to ensure reliable performance and avoid damaging the transistor.