2N5551 vs BC547 BJTs Comparison

The 2N5551and BC547are both NPN bipolar junction transistors (BJTs) commonly used in various electronic circuits. While they share some similarities, there are also key differences between them, making them suitable for different applications. This article provides a comprehensive comparison of these two transistors, focusing on their specifications, features, and applications.


What is 2N5551?


The 2N5551 is a popular general-purpose NPN bipolar junction transistor (BJT). It is commonly used for amplification and switching applications in electronic circuits. The 2N5551 transistor has three terminals: the emitter (E), the base (B), and the collector (C).

 

Here are some key specifications of the 2N5551 transistor:

 

Maximum Collector-Base Voltage (Vcb): 160 volts

Maximum Collector-Emitter Voltage (Vce): 160 volts

Maximum Emitter-Base Voltage (Veb): 6 volts

Maximum Collector Current (Ic): 600 mA

Maximum Power Dissipation (Pd): 625 mW

DC Current Gain (hfe): Typically around 100 to 300

Transition Frequency (ft): 150 MHz

 

2N5551 pinout        2n5551 symbol  2n5551 footprint      2n5551 3D

            2N5551 Pinout                                                          2N5551 Symbol                                                2N5551 Footprint                                      2N5551 3D-Model

 



What is BC547?


The BC547 is a widely used general-purpose NPN bipolar junction transistor (BJT). Similar to the 2N5551, it is commonly employed in various electronic circuits for amplification and switching purposes.

 

Here are some key specifications of the BC547 transistor:

 

- Maximum Collector-Base Voltage (Vcb): 50 volts

- Maximum Collector-Emitter Voltage (Vce): 45 volts

- Maximum Emitter-Base Voltage (Veb): 6 volts

- Maximum Collector Current (Ic): 100 mA

- Maximum Power Dissipation (Pd): 500 mW

- DC Current Gain (hfe): Typically around 110 to 800

- Transition Frequency (ft): 150 MHz

 

The BC547 transistor has three terminals: the emitter (E), the base (B), and the collector (C), similar to other NPN transistors. It is commonly available in a small TO-92 package.

 

BC547 Pinout BC547 Symbol BC547 Footprint BC547 3D-Model


Please refer to the BC547 datasheet, 2N5551 datasheet or specifications provided by the manufacturer for precise information on a specific BC547 transistor and 2N5551 transistor.


How does BC547 work?

+Vcc

           |

           R1

           |

Input ---- B

           |

           |

          ---

          ---

           |

           E

           |

          GND

In this circuit, the BC547 transistor is used as a simple switch. Here's how it works:

 

The input signal is applied to the base (B) terminal of the transistor.

A resistor (R1) is connected between the base and the positive power supply (+Vcc) to bias the transistor.

The emitter (E) terminal is grounded.

The output is taken from the collector (C) terminal and is connected to the load.

When a sufficient input signal is applied to the base terminal, it causes a current to flow through the base-emitter junction, turning the transistor on. As a result, current can flow from the collector to the emitter, allowing the circuit to operate as a switch. If the input signal is below a certain threshold, the transistor remains off, and no current flows through the collector-emitter path.

 

This basic configuration allows the BC547 transistor to be used in various applications, such as controlling small motors, relays, or LEDs, as well as amplifying small signals.

How does 2N5551 work?

+Vcc

           |

           R1

           |

Input ---- B

           |

           |

          ---

          ---

           |

           E

           |

          GND

In this circuit, the 2N5551 transistor is used as a common-emitter amplifier. Here's how it works:

 

The input signal is applied to the base (B) terminal of the transistor via a coupling capacitor.

A resistor (R1) is connected between the base and the positive power supply (+Vcc) to bias the transistor.

The emitter (E) terminal is grounded.

The output is taken from the collector (C) terminal and is connected to a load resistor or another stage of amplification.

When a small input signal is applied to the base terminal, the transistor amplifies it and produces a larger output signal at the collector terminal. The biasing resistor (R1) sets the operating point of the transistor, allowing it to operate in its linear amplification region.




2N5551 vs BC547 Specifications:

Feature

2N5551

NPN BJT

Type

NPN BJT

NPN BJT

Package

TO-92

TO-92

Maximum Collector Current (Ic)

600 mA

100 mA

Maximum Collector-Emitter Voltage (Vce)

40 V

45 V

Maximum Collector-Base Voltage (Vcb)

 40 V

50 V

Maximum Power Dissipation (Pd)

625 mW

500 mW

DC Current Gain (hFE)

50 - 300

110 - 800

Transition Frequency (ft)

300 MHz

300 MHz

 

 Features:

High current handling capability: The 2N5551 can handle significantly higher collector currents compared to the BC547, making it suitable for applications requiring higher power.

 

Lower saturation voltage: The 2N5551 has a lower saturation voltage, which means it can achieve a higher current gain at lower base currents.

 

Higher gain-bandwidth product: Both transistors have a similar transition frequency, but the 2N5551 has a higher gain-bandwidth product, making it suitable for high-frequency applications.

Widely available and affordable: Both transistors are readily available and relatively inexpensive.

 

2N5551 vs BC547 Applications:

2N5551:

    * Power amplifiers

    * Switching circuits

    * Motor drivers

    * High-current applications

BC547:

    * Low-power amplifiers

    * Preamplifiers

    * Logic circuits

    * General-purpose applications

 

 Conclusion:

The choice between the 2N5551 and BC547 depends on the specific application requirements. If high current handling capability is needed, the 2N5551 is the better choice. However, if lower power consumption or higher gain is desired, the BC547 is a more suitable option. Ultimately, understanding the specifications and features of each transistor is crucial for selecting the appropriate one for your project. You may send some RFQs to Vess Electronics to get your interested components parts.

 



Related Articles

MPC8270CVVUPEA Microprocessor Datasheet, Pinout, Equivalents

Release time:2023-12-07       Page View:295
1.27mm PowerPC G2_LE 1.53.3V 32-bit Microprocessor MPC82xx Series MPC8270 1.5V 480-LBGA Exposed PadMPC8270CVVUPEAOverviewThe MPC8270CVVUPEA is a specific model ofmicroprocessor in the PowerQUICC II Pro family, manufactured by NXP Semiconductors. It is a highly integrated processor that combines a Pow...

IRF640NPBF Specification, Model, Datasheet

Release time:2023-12-06       Page View:201
This post provide detailed information about IRF640NPBF Specification, Model, Datasheet

S1M Diode: Datasheet, Pinout, Alternatives

Release time:2023-12-05       Page View:2155
Diode 1000 V 1A Surface Mount DO-214AC (SMA)S1MDiodeS1MOverviewDescriptionIn the world of commodity rectifiers, onsemi S1 family of 1 A, P−I−N, SMA rectifiers stand out for their optimized low leakage, low capacitance, and fast response time. This was achieved while maintaining the industry standard VF max of 1.1 V at 1 A a...

XCF04SVOG20C Datasheet, Pinout, Application

Release time:2023-12-04       Page View:305
XCF04SVOG20C DescriptionThe Platform Flash series of in-systemprogrammable configuration PROMs. Available in1 to 32 Mb densities, these PROMs provide an easy-to-use,cost-effective, and reprogrammable method for storing largeXilinx FPGA configuration bitstreams. The Platform FlashPROM series includes both the 3.3V XCFxxS...

TPS5430DDAR PWM Converter Datasheet, Applications, Pinout

Release time:2023-12-01       Page View:270
Switching Voltage Regulators 5.5 to 36V Input 3A Step Dwn ConverterTPS5430DDAROverview The TPS543x has a standard input start-up voltage of 5.3V. The ENA pin can be used to turn off the TPS543x, lowering the supply current to 18 A. When the ENA pin is floating, an internal pullup current source allows operation. The TPS5...

AG10 vs A23 Batteries: Understanding the Difference

Release time:2023-11-28       Page View:758
Batteries are an essential part of our daily lives, powering a wide range of devices from remote controls to keyless entry systems. When it comes to small, button-cell batteries, the AG10 and A23 are two common types that are often used interchangeably. However, there are important differences between these two battery types that are worth understandin...

SIP-KITNXH001 vs. SIP-KITNXH002 DK: A Comparative Analysis

Release time:2023-11-27       Page View:852
Introduction:In the fast-paced world of technology, companies are constantly striving to innovate and develop newer, more advanced products. This holds particularly true for the field of telecommunications, where a multitude of components come together to enable seamless and reliable communication. In this article, we will compare two prominent products ...

BF998 Datasheet, Replacement, Applications

Release time:2023-11-24       Page View:1755
Trans RF MOSFET N-CH 12V 0.03A 4-Pin(3+Tab) SOT-143B

LR44 Battery vs 357 vs SR44: Equivalent, Specifications

Release time:2023-11-23       Page View:2440
LR44, 357, and SR44 are popular choices. These batteries are compact, widely available, and serve as power sources for a range of electronics. In this article, we will compare LR44, 357, and SR44 batteries in terms of their equivalency and specifications.

74HC244D vs 74HC244D,653 vs MM74HC244WM vs SN74LV244A Line Driver

Release time:2023-11-20       Page View:226
In this article, we will compare four popular ICs: 74HC244D, 74HC244D,653, MM74HC244WM, and SN74LV244A. We will delve into their descriptions, CAD models, features, applications, alternatives, dimensions, datasheet PDFs, specifications, and conduct a comprehensive product comparison.s

SN74HC74N Dual D-type Flip-Flop: Datasheet, Pinout, Applications

Release time:2023-11-17       Page View:962
2V~6V 60MHz D-Type Flip Flop DUAL 74HC74 14 Pins 74HC Series 14-DIP (0.300, 7.62mm)The Texas Instruments SN74HC74N is a dual D-type positive-edge-triggered flip-flop with clear and preset. This article will introduce its pinout, applications and datasheet.

AXG210144 Connector: Datasheet,CAD-Model,Dimension

Release time:2023-11-17       Page View:536
CatalogAXG210144DescriptionAXG210144CAD ModelAXG210144FeaturesAXG210144ApplicationsAXG210144AlternativesAXG210144DimensionAXG210144Datasheet PDFSpecificationsProduct comparisonFeatureFEATURES1.Width 1.7 mm slim and low profile two-piece type connectorMated height 0.6 mm/0.8mmSmaller compared to A35US• Wid...
RFQ