What Is the 2N3904 Transistor?

Key Technical Parameters of the 2N3904 Transistor

Electrical Characteristics of the 2N3904

Frequency Response of the 2N3904 Transistor

Practical Applications of the 2N3904 Transistor

Replacement Models for the 2N3904

Differences Between 2N3904 and 2N3906

Frequently Asked Questions

Definition and Overview

The 2N3904 is a widely used NPN Bipolar Junction Transistor (BJT). It is a key device in electronic engineering. It uses a current-controlled mechanism to provide signal amplification and switching control.

Since its release, it has become one of the most common active devices in analog and digital circuits. This is because it is universal, stable, and low-cost.

The 2N3904 works well in simple LED driver circuits and in complex multi-stage amplifiers. Compared with some early or special-purpose transistors, it has a better cost-performance ratio. This is why it stays popular after many decades.

Package and Pin Configuration

The 2N3904 usually uses the standard TO-92 package. This package is small and easy to solder onto a Printed Circuit Board (PCB).

Its pin layout is standard and easy to identify.

Pin Identification Method: Hold the flat side facing you, with the three pins pointing downward.

Pin Definition (left to right):

• Pin 1: Emitter
• Pin 2: Base
• Pin 3: Collector

Correct pin identification is important. Wrong wiring may cause permanent device damage.

Main Specifications and Features

The table below shows the basic parameters of the 2N3904:

Product Advantage:

At 200 mA collector current, the 2N3904 still keeps good current gain. It needs less base current for the same load. This reduces the load on the previous stage and simplifies the design.

Absolute Maximum Ratings

Absolute maximum ratings show the safe working limits. You should not exceed these values. Otherwise, the device may fail.

• Collector-Base Voltage (Vcbo): 60 V
• Collector-Emitter Voltage (Vceo): 40 V
• Emitter-Base Voltage (Vebo): 6 V
• Collector Current (Ic): 200 mA (DC)
• Total Power (Ptot): 625 mW at 25°C
• Operating and Storage Junction Temperature (Tj, Tstg): –55°C to +150°C

DC Current Gain (hFE)

DC current gain (hFE or β) shows the transistor’s ability to amplify current.

It is the ratio: hFE = Ic / Ib.

The value changes with collector current (Ic) and collector-emitter voltage (Vce).

Test Conditions:

At Ic = 10 mA and Vce = 1 V, hFE is usually 100–300.

This means a small base current change can control a collector current 100–300 times larger.

Saturation Voltage

When used as a switch, we want a low voltage drop in the ON state.

• Collector-Emitter Saturation Voltage (Vce(sat)): about 0.2 V (Ic = 50 mA, Ib = 5 mA).

A lower value means better efficiency and less heat.

• Base-Emitter Saturation Voltage (Vbe(sat)): about 0.85 V (Ic = 50 mA, Ib = 5 mA).

Product Advantage:

Because Vce(sat) is low, the 2N3904 works well in low-voltage systems like 3.3 V and 5 V. It sends more voltage to the load than many other transistors.

Transition Frequency (fT)

Transition frequency (fT) shows high-frequency performance.

It is the frequency where current gain drops to 1.

The 2N3904 has an fT of about 300 MHz.

Meaning:

It works well for medium- and high-frequency signals, such as Radio Frequency (RF) front-end amplification and FM (Frequency Modulation) receivers.

Capacitance Characteristics

Internal junction capacitances limit high-frequency response.

• Input Capacitance (Cibo): 4 pF (typical)
• Output Capacitance (Cobo): 8 pF (typical)

Visualization Description:

In a Bode plot, gain is flat at low frequencies. As frequency rises, gain falls at –20 dB per decade. The point where the line meets the 0 dB level is fT (300 MHz).

The junction capacitances cause this drop.

Switching Circuits

Switching is one of the most basic uses.

Working Principle:

When enough base current flows in, the transistor enters saturation. The collector-emitter path has a low voltage, and current flows through the load.

When base current is zero or very small, the transistor cuts off and acts like an open circuit.

Typical Loads:

Relay coils, LED groups, small DC motors, buzzers.

Amplifier Circuits

The 2N3904 can amplify small signals when properly biased in the linear region.

Common Amplifier Types:

• Class-A Amplifier: Good linearity; used in audio pre-amps.
• Common-Emitter Amplifier: Amplifies both voltage and current; very common.

Other Applications

The 2N3904 is also used in many derived circuits:

• Darlington Pair: Two 2N3904 transistors form a Darlington pair to get very high current gain.
• Logic Level Shifting: Converts signals between 3.3 V and 5 V systems.
• Pulse and Waveform Shaping: Used in multivibrators and pulse generators.

Product Advantage:

Using two 2N3904 devices in a Darlington pair offers more flexibility and lower cost compared with fixed single-package Darlington transistors.

Direct Replacements

• PN2222: Very similar to the 2N3904; often interchangeable.
• BC547: Also common. But its maximum Ic is 100 mA, and Vceo is 45 V, so check load current.

Other Universal NPN Transistors

• S8050: Higher collector current (up to 1.5 A).
• 2N4401: Ic up to 600 mA; good for higher-current switching.

Main Difference: Polarity

• 2N3904: NPN type.
• 2N3906: PNP type.

Circuit Differences

Bias Voltage:

• For NPN (2N3904): Collector connects to higher potential (positive supply). The base must be positive relative to the emitter.
• For PNP (2N3906): Collector connects to lower potential (ground or negative supply). The base must be negative relative to the emitter.

Current Direction:

• In NPN, current flows from collector → emitter.
• In PNP, current flows from emitter → collector.

Complementary Pair Use

The two devices have matched parameters and often form a complementary pair.

Typical Application:

Class-B push-pull amplifier.

The 2N3904 amplifies the positive half-cycle.

The 2N3906 amplifies the negative half-cycle.

Together they improve efficiency and reduce power loss.

This structure is common in audio amplifiers.

How to test a transistor with a multimeter?

Begin by setting your multimeter to its diode test function. The probing method depends on the transistor type: for an NPN transistor, the red probe should contact the base, while the black probe is used to check the emitter and collector. For a PNP transistor, the black probe is placed on the base, and the red probe is used on the emitter and collector. The measured values should be compared against the benchmarks provided in the transistor's datasheet to confirm proper operation.

Why would you use a transistor?​

Transistors serve to amplify weak electrical signals. When functioning as an electronic switch, a transistor governs a high-power circuit through the application of a low-power control signal.

What is the equivalent of a 2N3904 Mosfet?

The 2N3904 belongs to the family of NPN bipolar junction transistors (BJTs) and is fundamentally different from a MOSFET, so a direct equivalent does not exist. For circuits requiring an N-channel MOSFET, components like the BS170 or ZVN3306A are suitable candidates for replacement in many instances.

Is the 2N3904 obsolete?

Despite its long history, the 2N3904 NPN bipolar transistor is far from obsolete. It continues to be extensively utilized in electronic design, valued for its cost-effectiveness, dependable operation, and adaptability in various low-power applications, particularly amplification and switching.