ON Semiconductor 2SC4853-4-TL NPN Transistor
The ON Semiconductor 2SC4853-4-TL is a high-quality NPN bipolar junction transistor (BJT) designed for a variety of applications requiring efficient amplification and switching. This versatile component is a crucial part of electronic circuits, providing reliable performance in both commercial and industrial environments.
Key Features
- Type: NPN
- Package: TLP
- Collector-Emitter Voltage (Vceo): 50V
- Collector-Base Voltage (Vcbo): 60V
- Emitter-Base Voltage (Vebo): 7V
- Collector Current (Ic): 100mA
- Power Dissipation (Pd): 200mW
- DC Current Gain (hFE): 70 to 700
- Transition Frequency (fT): 250MHz
- Operating Temperature Range: -55°C to +150°C
The 2SC4853-4-TL transistor is encapsulated in a compact TLP package, making it suitable for space-constrained applications. It is designed to handle a collector-emitter voltage of up to 50V and a collector-base voltage of up to 60V, with a collector current capability of 100mA. This ensures the device can manage moderate voltage and current levels while maintaining its integrity and performance.
With a power dissipation rating of 200mW, the 2SC4853-4-TL can efficiently handle the thermal energy generated during operation without compromising its lifespan. The transistor also features a broad DC current gain range, allowing for a high degree of flexibility in amplification applications. Additionally, its high transition frequency of 250MHz makes it suitable for use in high-speed switching circuits and RF applications.
The device operates over a wide temperature range from -55°C to +150°C, making it reliable in extreme conditions and suitable for use in outdoor or variable temperature environments. This robust temperature range ensures that the 2SC4853-4-TL can maintain stable performance even under thermal stress.
In summary, the ON Semiconductor 2SC4853-4-TL is an efficient and durable NPN transistor that provides designers with a reliable solution for a wide array of electronic applications, from amplification to high-frequency switching.