Amplifiers are essential components in modern electronics, playing a pivotal role in audio systems, communication networks, instrumentation, and countless other applications.
Generally, different types of amplifiers are used to boost the strength of input electrical signals, enabling everything from clear music playback to robust wireless communication.
In this article, UniBetter will give you a comprehensive guide, focusing on key parameters of amplifiers and, most importantly, different types of amplifiers and their uses.
Photo from
https://unsplash.com/photos/a-close-up-of-a-circuit-board-with-many-electronic-components–oT4BM9PAQQ?utm_content=creditShareLink&utm_medium=referral&utm_source=unsplash
Key Parameters of Amplifiers
Before diving into the different types of amplifiers, it’s important to understand the parameters that define their performance. Some common parameters are:
- Gain: Measures how much an amplifier increases the strength of a signal, typically expressed in decibels (dB). High gain is crucial for boosting weak signals but must be balanced to avoid distortion.
- Bandwidth: The range of frequencies an amplifier can handle effectively. Wider bandwidth allows for accurate amplification of a broader spectrum of frequencies, which is crucial for applications like audio and video processing.
- Distortion:Real-world amplifiers introduce some level of distortion, which are unwanted alterations to the signal’s waveform. Low distortion is vital for high-fidelity audio and precision instrumentation.
- Input & Output Impedance: The input impedance is presented by the amplifier to the signal source, and the output impedance is presented by the amplifier’s output terminals. Typically, the input impedance should be high, while the output impedance should be low.
- Efficiency:This parameter describes the ratio of the power delivered to the load (e.g., a speaker) to the total power consumed by the amplifier. Higher efficiency reduces energy loss and heat, which is especially important for battery-powered and high-power applications.
Different Types of Amplifiers and Their Uses
With various parameters to consider, what are different types of amplifiers, and what are amplifiers used for? This section will explore these two key questions from some common classification perspectives.
-
Based on the Frequency Range:
- Audio amplifiers are designed for the audible frequency range and are found in everything from headphones to concert sound systems.
- RF amplifiers are crucial in wireless communications, boosting signals for transmission and reception.
- Video amplifiers handle the wide bandwidth needed for video signals.
- DC amplifiers are used in measurement and control systems where low-frequency or static signals must be amplified.
| Type | Frequency range | Typical uses |
| Audio amplifier | 10 Hz-20 kHz | Home audio, musical instruments, public address systems. |
| RF amplifier | 10 kHz-100 MHz (or higher) | Radio transmitters/receivers, wireless communication. |
| Video amplifier | 0 Hz-several MHZ (or higher) | Television, video processing, display systems. |
| DC amplifier | 0 Hz (DC) and above | Instrumentation, sensor signal conditioning. |
-
Based on the Mode of Operation (Classes):
There are different classes of amplifiers, and here we will discuss 5 common types:
- Class A amplifiers provide the highest fidelity but are less efficient.
- Class B amplifiers improve efficiency by utilizing two active devices (transistors). However, there is crossover distortion at the point where one device turns off and the other turns on.
- Class AB amplifiers combine aspects of Class A and Class B operation. They achieve a higher efficiency and reduce crossover distortion.
- Class C amplifiers are equipped with high efficiency but also high distortion. They are primarily used in RF applications.
- Class D amplifiers use digital switching for very high efficiency, ideal for battery-powered and high-power devices.
| Class | Operation mode | Efficiency | Distortion | Typical uses |
| Class A | Conducts 100% of cycle | Low | Minimal | High-fidelity audio, ideal for audiophiles and professionals seeking the best audio quality |
| Class B | Conducts 50% of cycle | Moderate | Moderate to high | May be used in motor drivers, power inverters, and more.* |
| Class AB | Between A and B | Moderate-High | Moderate | Widely used for audio amplification and car audio systems. |
| Class C | <50% of cycle | High | High | Mainly for RF applications like oscillators and radio transmission. |
| Class D | Switching (PWM) | Very high | Moderate to low | Ideal for battery-operated and portable audio devices. |
* Note that there are a few pure Class B designs due to the crossover distortion. Class B amplifiers use two transistors set up in a push-pull arrangement. However, because both transistors are biased at cutoff (zero bias voltage), neither conducts when the input signal is near zero volts (±0.7 V). This creates a ‘dead zone’ in the output waveform, resulting in crossover distortion. This may cause unwanted audio distortion.
-
Based on the Active Devices Used:
- Vacuum Tube Amplifier: Utilizing vacuum tubes as active devices, these amplifiers were dominant in early electronics and are still favored by some audiophiles for their warm and smooth sound characteristics.
- Transistor/ Solid-state Amplifier: Employing transistors (such as BJTs or FETs) as the active devices, these amplifiers are the workhorse of modern electronics due to their compact size, lower operating voltages, higher efficiency, and versatility.
| Type | Active device | Typical uses |
| Vacuum tube amplifier | Vacuum tube/ valve | High-power RF, vintage audio, musical instruments. |
| Transistor amplifier | BJT, MOSFET, etc. | Modern audio, RF, general electronics. |
-
Based on the Function or Application:
It is also common to categorize different types of amplifiers according to what they are used for. For instance:
- Power Amplifier:
Designed to deliver a significant amount of power to a load, such as a loudspeaker. They are characterized by their power output capability and efficiency. Two common examples are audio amplifiers and RF power amplifiers.
- Voltage Amplifier:
Primarily designed to increase the voltage amplitude of a signal, with less emphasis on delivering high current. They typically have a high input impedance and a low output impedance. Their applications include audio devices, signal processing, and communication systems.
- Current Amplifier:
Designed to increase the current amplitude of a signal, often used to drive low-impedance loads. They typically have a low input impedance and a high output impedance. Their applications include audio and telecommunication systems.
- Operational Amplifier (Op-Amp):
These are high-gain voltage amplifiers with a differential input (one inverting input and one non-inverting input) and a single-ended output.
They are versatile building blocks, as they can be used with other electronic components (such as resistors and capacitors) to perform a variety of different operations (such as generating output current).
Some key uses of operational amplifiers are audio equipment, control systems, power management and conversion, and more.
- Instrumentation Amplifier:
A specialized type of differential amplifier with high input impedance, low output impedance, high common-mode rejection ratio (CMRR), and precisely controlled gain.
They are specifically designed to amplify low-level signals, such as heartbeats and temperature. Additionally, the gain can be easily adjusted through a single control.
All these features make them suitable for applications in medical, radar, navigation, and beyond.
UniBetter: Your Partner for Diverse Amplifier Needs
UniBetter understands the critical role that amplifiers play in various electronic systems and distributes different types of amplifiers with our unique advantages.
Our clients can expect to have hard-to-find amplifiers through our extensive supply network, which is comprised of over 7,000 global suppliers. Moreover, our team of 30+ experienced procurement experts will provide you with the best cost-saving solutions.
Quality is also guaranteed at UniBetter. We partner with reliable electronic component suppliers and offer 100% quality-assured electronic parts that pass rigorous tests conducted by our CSD quality management system.
Currently, our expertise is trusted by over 3,000 clients across various sectors, including automotive, IoT intelligence, industrial automation, computing, and beyond.
Conclusion
Amplifiers are indispensable in modern electronics, with different types and classes engineered for specific frequency ranges, operating modes, and applications.
For reliable access to different types of amplifiers and expert support, UniBetter stands out as a trusted partner. Feel free to contact UniBetter and discover how we can help you source the right amplifier for your next innovation!