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What are the applications of transistors? 

Bipolar junction transistor
Capacitor
Switched capacitor
Electronic circuit
Integrated circuit
Best insight from top research papers

Transistors have various applications in electronic circuits. They are used for amplification and switching purposes . Transistors can be configured as common-emitter amplifiers to sense liquids at different levels over time . They are also used in radios, computers, and integrated circuits . In digital integrated circuit architectures, transistors serve as circuit switches to charge and discharge capacitors . Transistors are essential for improving the performance of ultra-large-scale integrated circuits (ULSIs) . Thin-film transistors with rectifying source contacts have attractive properties for sensor and driver circuits, offering high performance uniformity and geometrical tolerance . These transistors can be used in ultra-compact sensing and data processing circuits . They form the foundation for the design of versatile thin-film circuits for sensing, signal conditioning, and signal conversion .

Answers from top 4 papers

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Papers (4)Insight
Open accessJournal ArticleDOI
Modeling of hybrid mos for the implementation of switched capacitor filter using single electron transistor
Brijendra Mishra, Vivek Singh Kushwah, Rishi Sharma 
04 May 2020
The paper does not explicitly mention the applications of transistors.
Open accessJournal ArticleDOI
Study and performance testing of transistor with common emitter amplifier circuit
G.R. Kumrey, S.K. Mahobia 
31 Aug 2016-International Journal of Research
The paper does not explicitly mention the applications of transistors.
Journal ArticleDOI
Application of Transistors in Textiles: Monitoring Water Transportation Behaviour in Fibrous Assemblies
Arobindo Chatterjee, Pratibha Singh, Subrata Ghosh 
01 Jun 2017-Journal of The Institution of Engineers : Series E
1 Citations
The paper discusses the application of transistors as amplifiers and switches for sensing and displaying real-time data in fibrous assemblies.
Journal ArticleDOI
Transistor Amplifiers and Their Frequency Response
Hyung Seok Park
01 Jan 2023-Synthesis lectures on electrical engineering
The paper does not explicitly mention the applications of transistors. However, it focuses on the applications of Bipolar Junction Transistors (BJT) in amplification and switching purposes.

Related Questions

Explain the operation of transistor as an amplifier?5 answersA transistor is an electronic device that can amplify signals. When used as an amplifier, a transistor takes a weak input signal and increases its strength to produce a larger output signal. The operation of a transistor as an amplifier involves several key steps. First, a power source is turned on, and a control unit applies a pinch-off voltage to the gate of the transistor. Then, a drain bias voltage is applied to the drain of the transistor, followed by a gate bias voltage to the gate. This sequence of voltage application allows the transistor to amplify the input signal effectively. In some cases, multiple transistors may be used in parallel to maintain linearity of the output signal, with an inductor connected to the source terminal of the first transistor. The transistor itself consists of a source region, at least two drain regions, channels between the source and drain regions, and gate electrodes on each channel. The drain regions are electrically isolated from each other, and drain electrodes are provided on each region.
What are some applications of transistors as switches?3 answersStep 1: Transistors are used as switches in various applications such as High Power Amplifiers (HPA) and solid-state microwave switches. They are also utilized in electrical power systems for protection during load faults and in RF switches for controlling the flow of current. Different types of transistors, including Metal Oxide Semiconductor Field Effect Transistors (MOSFET), Insulated Gate Bipolar Transistors (IGBT), and MOS Controlled Thyristors (MCT), are evaluated for their suitability in AC switch applications. Additionally, transistors with different threshold voltages, breakdown voltages, and on-resistances are employed in RF switches to provide specific characteristics without relying on different channel lengths. Step 3: Transistors are used as switches in various applications such as High Power Amplifiers (HPA) and solid-state microwave switches. They are also utilized in electrical power systems for protection during load faultsand in RF switches for controlling the flow of current. Different types of transistors, including Metal Oxide Semiconductor Field Effect Transistors (MOSFET), Insulated Gate Bipolar Transistors (IGBT), and MOS Controlled Thyristors (MCT), are evaluated for their suitability in AC switch applications. Additionally, transistors with different threshold voltages, breakdown voltages, and on-resistances are employed in RF switches to provide specific characteristics without relying on different channel lengths.
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