Allicdata Part #: | DSC2501S0LTR-ND |
Manufacturer Part#: |
DSC2501S0L |
Price: | $ 0.08 |
Product Category: | Discrete Semiconductor Products |
Manufacturer: | Panasonic Electronic Components |
Short Description: | TRANS NPN 20V 0.5A MINI3 |
More Detail: | Bipolar (BJT) Transistor NPN 20V 500mA 150MHz 200m... |
DataSheet: | DSC2501S0L Datasheet/PDF |
Quantity: | 1000 |
3000 +: | $ 0.07695 |
Series: | -- |
Packaging: | Tape & Reel (TR) |
Part Status: | Active |
Transistor Type: | NPN |
Current - Collector (Ic) (Max): | 500mA |
Voltage - Collector Emitter Breakdown (Max): | 20V |
Vce Saturation (Max) @ Ib, Ic: | 400mV @ 20mA, 500mA |
Current - Collector Cutoff (Max): | 100nA (ICBO) |
DC Current Gain (hFE) (Min) @ Ic, Vce: | 300 @ 500mA, 2V |
Power - Max: | 200mW |
Frequency - Transition: | 150MHz |
Operating Temperature: | 150°C (TJ) |
Mounting Type: | Surface Mount |
Package / Case: | TO-236-3, SC-59, SOT-23-3 |
Supplier Device Package: | Mini3-G3-B-B |
Base Part Number: | DSC2501 |
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DSC2501S0L is a type of single bipolar junction transistor (BJT), also known as a single transistor. As a single transistor, it typically consists of only three pins, or terminals, and operates through the use of current flowing between Ohmic and other non-Ohmic contacts. Its function is essentially analogous to that of a switch, making it largely a component of digital signal processing (DSP) applications. There are a variety of applications and use cases in which dual-transistors, as well as multiple transistors, are applicable. However, the single transistor of the DSC2501S0L is specifically designed to take on electrical precision tasks, and is also well-suited to act as an component in a variety of analog circuits.
Theory of Operation
The DSC2501S0L single transistor operates employed the concept of electron flow. An electron flow is defined as a flow of mobile electrons across an electrical circuit, and is functionally responsible for nearly all of the electricity powering our everyday lives. The transistor consists of three pins, or terminals, called the emitter, base, and collector. The two internal junctions between the two are known as the base-emitter junction and the base-collector junction.
When a forward bias voltage is applied to the base-emitter junction, electrons flow from emitter to base, and in effect, function as a bridge between the base and collector side of the circuit. The electrons become the collector current, and the current increases as the base-emitter voltage increases. The gain, or hfe, of the transistor is the ratio of the collector current to the base current, and is typically quoted in datasheets. As the gain of this single transistor increases, so does the number of transistors or dual-transistors required to reach desired levels of performance.
Theory Applied
The DSC2501S0L single transistor, when combined with other electronic components, can be employed for a variety of electrical and electronic applications. Amongst these are the areas of digital signal processing (DSP), telecommunications, and analog circuit design. In all applications, the single transistor functions to control current across two points, providing a great deal of versatility for convenient and efficient electrical engineering needs.
Digital signal processing is perhaps one of the most prevalent areas in which the DSC2501S0L single transistor is employed. As previously mentioned, the concept of electron flow is responsible for the majority of changes and transformations we see in many digital signal processing applications. The single transistor facilitates the movement of electrons between two points, by regulating the number of electrons flowing between the base, emitter, and collector. This regulation allows for dynamic and digital control of active electrical components, such as resistors and capacitors.
In the telecommunications industry, single transistors are used as switches to transmit and receive digital pulses, which are also known as digital pulses. Such transistors are employed on a larger scale in various telecommunications systems, such as digital data audio signaling devices. By controlling the flow of electricity between a pair of contacts, the single transistor implicitly helps to modulate and control the input voltage, allowing for the tailored reception of digital information.
In analog circuit design, single transistors are used as amplifiers for sensor readings. As noted before, transistor gain (the ratio of collector current to base current) increases as emitter voltage increases, allowing for a reliable and accurate adaptation to changes in the environment. By controlling the electron flow, the individual stages of an analog circuit can utilize the increased gain of the transistor to feedback desired levels of output voltage.
Conclusion
The DSC2501S0L single bipolar junction transistor is an essential component for many digital and analog circuit designs. Whether employed as a switch, an amplifier, or for a variety of other electronic applications, the single transistor is capable of providing a level of precision regulation that is unmatched by other components. The unique structure of the DSC2501S0L, coupled with its ability to regulate electron flow and control voltage, makes it a valuable asset for digital-signal-processing, telecommunications, and analog circuit designs.
The specific data is subject to PDF, and the above content is for reference
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