The Kynix Blog - Amplifiers

Overview: The article discusses the vital role of feedback amplifiers in electronic circuits and examines their types. It also highlights the desirable effects of negative feedback on signal amplification, enhancing overall performance. To improve the reliability and performance of amplification circuits, feedback amplifiers play an essential role in electronics. A feedback loop allows these amplifiers to fine-tune and enhance their output, leading to more accurate and dependable operation. What is feedback?The term "feedback" describes the process of redirecting a portion of an amplifier's output signal into an input signal. Here, the input to the circuit is a portion of the output signal that has been added or reduced to the source signal. Consequently, the amount of feedback may rise or fall based on the operation of adding or subtracting the signal from the source signal. What is a feedback amplifier?An important part of the amplifier is the feedback circuit, which works by feeding back some of the signal's output to the input. These amplifiers have several uses since they provide better control over many parameters.Types of FeedbackPositive FeedbackPositive feedback occurs when feedback is used to increase the input signal. Positive feedback adds to the input signal, and the new input to the circuit is greater than the source signal. For this reason, it is also known as regenerative feedback. Positive feedback occurs when the feedback energy (voltage or current) is in phase with the input signal. Fig. 1 shows that both the amplifier and the feedback network create a 180° phase shift. As a result, the sum of the 360° phase shift around the loop occurs, and the feedback voltage (Vf) becomes in phase with the input signal (Vin). Fig. 1 Illustration of the positive feedback amplifier. Source: Rakesh Kumar, Ph.D.The positive feedback increases the amplifier's gain. However, it has the drawbacks of increased distortion and instability. Positive feedback is, therefore, rarely used in amplifiers. Positive feedback is utilized in oscillators, multivibrator circuits, and some active filters. Negative FeedbackNegative feedback is defined as feedback that decreases the input signal. Degenerative feedback, also known as negative feedback, occurs when the signal feedback is out of phase with the input signal by 180°. Negative feedback occurs when the input signal's voltage or current is out of phase with the feedback energy. The feedback network is supposed to introduce no phase shift, or 0° phase shift, however, the amplifier introduces a 180° phase change into the circuit, as seen in Fig. 2. As a result, the input signal (Vin) and the feedback voltage (Vf) are 180° out of phase. Fig. 2 Illustration of the negative feedback amplifier. Source: Rakesh Kumar, Ph.D. Advantages of Negative Feedback AmplifierA negative feedback amplifier provides several benefits, including lower distortion, more stable gain, wider bandwidth, and better input and output impedances. Negative feedback is used in amplifiers and other control circuits to improve stability. Gain StabilityGain is defined as the ability of a circuit to increase the power or amplitude of a signal. Gain is the ratio of output to input signal in an amplifier and can be expressed as A, as shown in the equation. It can be a voltage gain, a current gain, or a power gain. Gain is typically a unitless measurement.A = Vout / Vin Negative voltage feedback improves the stability of amplifier gain by making it independent of transistor characteristics and supply voltage fluctuations. Desensitizing the gain refers to making the overall gain of an amplifier less sensitive to variations in the amplifier's internal components or operating conditions. The gain only depends on the feedback circuit's parameters. Feedback circuits, which are typically resistive networks, are not impacted by temperature, transistor settings, or frequency changes. Consequently, the gain of the amplifier is extremely stable. This is one of the key benefits of using negative feedback in amplifiers. Non-Linear DistortionNegative feedback plays a crucial role in reducing non-linear distortion and makes the gain of the amplifier almost constant. It helps maintain a more proportional relationship between input and output signals, reducing non-linear distortions that occur when the amplifier operates outside its linear region. Improved BandwidthNegative feedback improves the frequency response and extends the bandwidth of the amplifier. This ensures that the amplifier can handle a wider range of frequencies more effectively, maintaining consistent gain across the spectrum. Input and Output ImpedanceNegative feedback in amplifiers significantly influences both input and output impedances, enhancing the overall performance and stability of the amplifier. NoiseDepending on whether a transistor or tube is employed, an amplifier might have a variety of noise sources. Negative feedback helps reduce the noise in the output signal. To conclude, negative feedback lowers the amplifier's gain. At the same time, negative feedback reduces distortion and noise. This trade-off is generally beneficial, as the improved linearity and reduced distortion often outweigh the loss in gain. A feedback amplifier to considerLM6172The LM6172 is a high-speed, low-power, low-distortion, dual-voltage feedback amplifier designed by Texas Instruments. It is particularly noted for its excellent DC and AC performance, making it suitable for a wide range of applications. The LM6172 boasts a very high slew rate of 3000 V/μs, which allows it to handle rapid changes in input signals without significant delay. It has a unity-gain bandwidth of 100 MHz, ensuring stable operation even at high frequencies.The amplifier is designed to operate efficiently, consuming minimal power, which is crucial for battery-operated and portable devices. The LM6172 features low total harmonic distortion and can operate over a wide supply voltage range from ±2.5V to ±18V, providing flexibility for various design requirements. It operates over a broad temperature range from -55°C to 125°C, making it suitable for industrial and military applications. The LM6172 is available in various packages, including 8-DIP and surface-mount options, providing flexibility for different design and manufacturing requirements. Summarizing the Key PointsFeedback amplifiers play a crucial role in enhancing the efficiency and stability of amplification circuits in electronics.Understanding the types of feedback, such as positive and negative, is essential for optimizing signal amplification.Negative feedback offers benefits like reduced distortion, improved stability, wider bandwidth, and enhanced input/output impedances.The LM6172 amplifier by Texas Instruments exemplifies a high-speed, low-power, low-distortion feedback amplifier suitable for various applications. ReferenceAyobamidele, Segun & Oyebola, Blessed. (2018). Feedback Amplifier, Its Operation, Effect Importance and Connecting Types: A Review. 16-32.ALL ABOUT ELECTRONICS, “Introduction to Feedback Amplifier | The concept of Negative Feedback and its advantages,” July 7, 2024, https://www.youtube.com/watch?v=__8f6AXenYo.

Introduction to Amplifier GainSummary (2026 Update): From 5G RF front-ends to precision IoT sensors—Gain remains the fundamental metric of signal amplification. It quantifies the ratio of output to input for voltage, current, or power, typically expressed in decibels (dB). This guide covers the essential physics, calculation methods, and frequency response analysis required for high-performance circuit design in 2026.In electrical circuits, Gain generally refers to the degree of increase in current, voltage, or power of components, circuits, equipment, or systems. It is specified in decibels (dB), meaning the unit of gain is generally dB, which represents a relative value rather than an absolute unit like Volts or Amps. In short, its general meaning is the magnification factor. In electronics, it is strictly the ratio of the signal output to the signal input of a system. For example, antenna gain is a parameter that represents the radiation concentration of a directional antenna. But what exactly is amplifier gain in the context of modern semiconductors? How do you calculate it using 2026 industry standards? Read the following technical notes for a deep dive.Ⅰ Amplifier Gain Fundamentals1.1 Definition and ContextAmplifier gain is the logarithm of the ratio of output power to input power, used to express the magnitude of power amplification. It also refers to the magnification of voltage or current. The decibel (dB) is the standard unit. The total magnification of an electronic system is often several thousand (e.g., Low Noise Amplifiers) to millions (e.g., Operational Amplifiers). For example, a modern digital radio receiver might need to amplify a signal 20,000 times or more from the antenna to the DSP or speaker. Using linear numbers makes calculations unwieldy. In decibels, we take a logarithm, making the numbers manageable. Crucially, when amplifiers are cascaded (connected in series), the total linear magnification is multiplied, but the total gain in dB is additive, simplifying system design.1.2 Gain Representation in Decibels (dB)Voltage gain Av(dB) = 20log(|Av|)The voltage gain in decibels is 20 times the base-10 logarithm of the voltage ratio (Output Voltage / Input Voltage).Current gain Ai(dB) = 20log(|Ai|)The current gain in decibels is 20 times the base-10 logarithm of the current ratio.Power gain Ap(dB) = 10log(Ap). Note the factor is 10, not 20. Power gain = Output Power / Input Power.Why use decibels? Beyond simple convenience, human perception (like hearing) is logarithmic. A gain of 100,000,000 times (linear) is awkward to document. Converted to dB, it becomes 160dB, which is standard engineering notation. This principle mirrors why computing uses binary or hexadecimal. Engineers can easily convert between linear magnification and decibels depending on the simulation or datasheet requirement.Ⅱ Types of Amplifier Gain2.1 Voltage Gain (Av)Av = Vo / Vi means that voltage gain equals the amplifier's output voltage divided by the input voltage. This is the primary metric for Voltage Amplifiers.🔺 Open Loop Voltage Gain (AVOL)In the absence of negative feedback, the amplification factor of an operational amplifier (Op-Amp) is called Open-Loop Gain. Ideally, this is infinite. In practice, modern precision Op-Amps (like the OPA series replacing legacy chips) feature gains between $10^5$ to $10^7$. Representations include dB (e.g., 106dB) or V/mV. While legacy chips like the μA741C or LM318 had typical values around 200V/mV, 2026-era rail-to-rail amplifiers offer significantly higher linearity. We use the "virtual ground" assumption in calculations because the immense AVOL forces the differential input voltage to near zero.The Ideal Op Amp Characteristics:1) Open loop gain is infinite.2) Input impedance is infinite (no loading effect), and output impedance is 0.3) Bandwidth is infinite (instantaneous response).Video: How To Calculate the Voltage Gain of a Transistor Amplifier🔺 Closed Loop Voltage GainThis refers to the gain of the entire circuit after a negative feedback loop is applied. Feedback stabilizes the gain and widens bandwidth. The formula is: voltage gain = 20log(Vo / Vi).🔺 IF (Intermediate Frequency) Voltage GainThe IF voltage gain (Avm) refers to the maximum voltage gain within the passband—specifically the frequency range where the voltage amplitude remains above 0.707 of the maximum (the -3dB points).2.2 Current Gain (Ai)Ai = Io / Ii defines current gain as the output current divided by the input current. These circuits are known as Current Amplifiers (or Current Mirrors in IC design).2.3 Transimpedance Gain (Rm)Ar = Vo / Ii. Here, the gain represents Output Voltage / Input Current. This topology is called a Transimpedance Amplifier (TIA), critical in 2026 for photodiode sensors and fiber optic receivers.2.4 Transconductance Gain (gm)A = Io / Vi. Transconductance gain is the ratio of Output Current to Input Voltage. These are Transconductance Amplifiers (OTAs), often used as the input stage in modern Op-Amps. Ⅲ Fully Differential Amplifier GainA fully differential amplifier (FDA) is standard in modern high-speed ADC drivers. It features four distinct gain metrics based on Common Mode (CM) and Differential Mode (DM) signals.Adm (Differential Gain): The gain from differential input to differential output. This is the desired signal amplification.Acm (Common Mode Gain): The gain from common-mode input to common-mode output. Ideally, this should be zero to reject noise.Adcm (Mode Conversion - Diff to CM): Gain from differential input to common-mode output.Acdm (Mode Conversion - CM to Diff): Gain from common-mode input to differential output.Design Goal: Maximize Adm while minimizing Acm, Adcm, and Acdm. A high Adm ensures strong signal integrity. A low Acm is crucial; if Acm is non-zero in cascaded stages, common-mode noise (like 60Hz hum or EMI) amplifies, causing "rail saturation." Adcm and Acdm must be minimized to prevent signal distortion and feedback loops that can destabilize the amplifier. In 2026 designs, Common-Mode Rejection Ratio (CMRR) is the key spec that aggregates these parameters. Ⅳ Frequency Response and Gain CalculationCapacitors in an amplifier circuit dictate the frequency response. We analyze gain across three bands: Low Frequency (LF), Intermediate Frequency (IF), and High Frequency (HF).Figure: The Relationship between Gain and Frequency (Bode Plot)1) Intermediate Frequency (IF):Coupling/Bypass Capacitors → Short Circuit.Transistor Parasitic Capacitance → Open Circuit.The gain expression is frequency-independent (flat). This is the nominal gain of the amplifier.2) Low Frequency (LF):Coupling and bypass capacitors are significant here. Their impedance rises as frequency drops, reducing gain. The circuit acts as a High-Pass Filter.3) High Frequency (HF):Internal transistor capacitances (Cpi, Cmu) and stray load capacitances dominate. As frequency rises, these act as short circuits, shunting the signal to ground. The circuit acts as a Low-Pass Filter.Gain Function and Corner Frequencies (S-Domain Analysis)In the complex frequency domain (s-domain), Capacitance = 1/sC and Inductance = sL. The system function A(s) is a ratio of polynomials:Factoring the numerator and denominator reveals the zeros and poles:Key Characteristics:1) For physical stability, the number of zeros (m) must be ≤ poles (n).2) In low-frequency amps, poles are real numbers corresponding to RC time constants.The gain function is split into three bands:Determining the Lower Corner Frequency (fL):At low frequencies, s → ∞ relative to the low poles. The response is governed by coupling capacitors. If one pole is significantly larger (closer to the passband) than the others, it is the Dominant Pole (p1).Approximation using the Dominant Pole concept:......(a)Determining the Upper Corner Frequency (fH):At high frequencies, transistor internal capacitances dominate. Here, we look for the smallest pole (closest to the passband) which acts as the dominant high-frequency pole.The simplified derivation for bandwidth (fBW) typically relies on identifying these dominant poles in the transfer function. Ⅴ FAQ: Common Questions on Amplifier Gain1. How is gain strictly defined in electronics?Gain is the dimensionless ratio of Output / Input. While it has no physical units (Volts/Volts cancel out), it is almost always expressed in Decibels (dB) to handle large magnitudes comfortably. The symbol is "A" (e.g., Av for Voltage Gain).2. What is the difference between Voltage, Current, and Power Gain?Voltage Gain (Av) is Vout/Vin. Current Gain (Ai) is Iout/Iin. Power Gain (Ap) is Pout/Pin. Note that Power Gain is the product of Voltage and Current Gain. In dB: Power Gain uses 10log, while Voltage/Current uses 20log.3. What is the typical current gain (Alpha) of a Common-Base amplifier?In a Common-Base (CB) configuration, the current gain is called Alpha (α). Since the emitter current is the sum of base and collector current (IE = IB + IC), and the output is taken from the collector, the output is always slightly less than the input. Thus, α is always < 1 (typically 0.95 to 0.99).4. How do you calculate the gain of a Differential Amplifier?For a standard differential amp with balanced resistors (R1=R2=R3=R4), it is a Unity Gain device where Vout = V2 - V1. If resistors differ, the gain is determined by the ratio of the feedback resistor to the input resistor.5. What defines an "Ideal" Op-Amp in 2026 theory?An ideal op-amp is a theoretical construct with: Infinite Open Loop Gain, Infinite Input Impedance (draws no current), Zero Output Impedance (drives any load), and Infinite Bandwidth. Real-world components strive to approach these limits using advanced CMOS or BiCMOS processes.6. Why is Op-Amp gain so high?Op-Amps are designed as multi-stage differential amplifiers. They utilize active loads (current mirrors) rather than passive resistors internally, allowing them to achieve massive Open Loop Gains (often >100,000x) to ensure precise performance when closed-loop feedback is applied.7. How do I find the gain of an Inverting Op-Amp?The formula is straightforward: Gain (Av) = - (Rf / Rin). Rf is the feedback resistor, and Rin is the input resistor. The negative sign indicates a 180-degree phase shift.{ "@context": "https://schema.org", "@type": "TechArticle", "headline": "Comprehensive Guide to Amplifier Gain: Formulas, Types, and Calculation (2026 Edition)", "description": "A deep dive into Amplifier Gain in electronics. Learn about Voltage, Current, and Power gain, decibel conversion, frequency response analysis, and modern fully differential amplifier theories.", "datePublished": "2019-01-01", "dateModified": "2026-01-05", "author": { "@type": "Organization", "name": "Kynix Semiconductor" }, "mainEntity": { "@type": "FAQPage", "mainEntity": [ { "@type": "Question", "name": "How is gain strictly defined in electronics?", "acceptedAnswer": { "@type": "Answer", "text": "Gain is the dimensionless ratio of Output divided by Input. While it has no physical units, it is almost always expressed in Decibels (dB). The symbol is usually A." } }, { "@type": "Question", "name": "What is the formula for Voltage Gain in dB?", "acceptedAnswer": { "@type": "Answer", "text": "Voltage Gain in dB is calculated as 20 * log10(Vout / Vin)." } }, { "@type": "Question", "name": "What is the difference between Voltage, Current, and Power Gain?", "acceptedAnswer": { "@type": "Answer", "text": "Voltage Gain (Av) is Vout/Vin. Current Gain (Ai) is Iout/Iin. Power Gain (Ap) is Pout/Pin. In dB conversion, Voltage and Current use 20log, while Power uses 10log." } }, { "@type": "Question", "name": "What is the current gain (Alpha) of a Common-Base amplifier?", "acceptedAnswer": { "@type": "Answer", "text": "In a Common-Base configuration, the current gain (Alpha) is always less than 1 (unity), typically between 0.95 and 0.99." } }, { "@type": "Question", "name": "How do you calculate the gain of an Inverting Op-Amp?", "acceptedAnswer": { "@type": "Answer", "text": "The gain is calculated using the formula: Gain = - (Rf / Rin), where Rf is the feedback resistor and Rin is the input resistor." } } ] }}

Introduction RF power amplifier is an important part of various wireless transmitters. In the front-end circuit of the transmitter, the power of the RF signal generated by the modulation oscillator circuit is very small, and it needs to go through a series of amplification-buffer stage, intermediate amplification stage, and final power amplification stage to obtain enough RF power before feeding. In order to obtain a sufficiently large RF output power, a RF power amplifier must be used. RF Power Amplifier Design: The Basics Catalog Introduction Ⅰ Requirements of RF Power Amplifier Ⅱ Types of Power Amplifier in Use Ⅲ Parameters of RF Power Amplifier Design Ⅳ Key Feature: Non-Linearity 4.1 Nonlinear Characteristics 4.2 Influence of Nonlinear Characteristics Ⅴ FAQ Ⅰ Requirements of RF Power Amplifier With the vigorous development of modern digital mobile communication technology, users have more requirements on the performance of wireless communication equipment. To achieve stable and high-speed data transmission in various environments is one of the main goals of future mobile communication system researchers. The RF power amplifier is the last stage of the transmitter. It amplifies the modulated frequency band signal to the required power, ensuring that the receiver in the coverage area can receive a satisfactory signal level, but it cannot interfere too much with the communication of adjacent channels, and meanwhile try to keep the amplified high-power signal without distortion. The requirements of these different aspects make the users of power amplifiers have to consider many factors in all aspects. So you should get a full knowledge of RF power amplifiers. Figure 1. Classic RF Power Amplifier Circuit Ⅱ Types of Power Amplifier in Use What are the main types of RF amplifiers for such an important device?1) According to the operating frequency bandsAccording to the working frequency band, it can be divided into narrowband RF power amplifier and broadband RF power amplifier. The former generally uses frequency selective networks as load circuits, such as LC resonant circuits. The latter does not use the frequency selection network as the load loop, but employs the transmission line with a wide frequency response as the load.2) According to the network propertiesAccording to the nature of the matching network, power amplifiers can be divided into non-resonant power amplifiers and resonant power amplifiers. The matching network of the non-resonant power amplifier is a non-resonant system, such as high-frequency transformers, transmission line transformers and other non-resonant systems, and its load properties are purely resistive, where this is also called reactance properties.3) According to current conduction angleBased on it, RF power amplifiers can be divided into class A, AB, B, C, D, E and so on. The differences between these categories can be seen in the following table: Classification Conduction Angle Efficiency Linearity Application Class A Θ=360° ≤30% Very good Small Signal Low Power Amplification Class B Θ=180° ≤60% Lower than class A For High Power Class C Θ<180° About 60% Nonlinear amplifier For High Power Class AB 180°<Θ<360° 30%~60% Better than class B Small signal works in class A, large signal works in class B Class D Work in switch mode 80% Very good, only good for low frequencies Switch mode amplifier Class E Work in switch mode 90% Completely nonlinear amp Switch mode amplifier In the classification of amplifiers, we often talk about amplifiers of class A to E according to the conduction angle. Class A power amplifier is a linear amplifier, its response to the sine-wave  input is a sine-wave output, generally without distortion amplification, and the output frequency is the same as the input frequency. Since class A amplifiers do not require additional filtering circuitry, their packages can be small and cost less. The output of a class B amplifier is a half sine wave of the input, resulting in half-wave distortion, which produces many harmonics. The output power and efficiency of the class C working state are the highest among these working states, and most of the amplifiers used for radio frequency work in the class C. Figure 2. Class A Amplifier Load Curve   Ⅲ Parameters of RF Power Amplifier Design RF power amplifiers are electronic circuits that comprehensively consider issues such as output power, excitation level, power consumption, distortion, efficiency, size and weight. In the transmitting system, the output power of the RF power amplifier can be as small as mW and as large as several kW, but this refers to the output power of the final power amplifier. In order to achieve high power output, the last stage must have a sufficiently high excitation power level. At the same time, it has other important indicators, as follows:1) Operating FrequencyGenerally speaking, it refers to the linear operating frequency range of the amplifier. If the frequency starts at DC, the amplifier is considered to be a DC amplifier.2) GainThe working gain is the main indicator to measure the amplification ability of the amplifier. Here it is defined as the ratio of the power delivered to the load by the amplifier output port to the power actually delivered by the signal source to the amplifier input port.Gain flatness refers to the variation range of amplifier gain in the entire operating frequency band under a certain temperature, and is also a main indicator of the amplifier. Figure 3. Output Power and 1dB Compression Point (P1dB) Referring to the Figure 3, when the input power exceeds a certain amount, the gain of the transistor begins to decrease, and the end result is that the output power saturates. When the gain of the amplifier deviates from a constant or is 1dB lower than other small signal gains, this point is the famous 1dB compression point (P1dB). Generally speaking, the power capacity of an amplifier is expressed by the 1dB compression point.3) EfficientSince the power amplifier is a power component, it needs to consume the supply current. Therefore, the efficiency of the power amplifier is extremely important to the efficiency of the whole system. Power efficiency is the ratio of the RF output power of the amplifier to the DC power supplied to the transistors.ηp=RF Output Power/DC Input Power4) Intermodulation Distortion (IMD)Intermodulation distortion refers to the mixed components of two or more input signals with different frequencies passing through a power amplifier. This is due to the nonlinear nature of the amplifier. Among them, because the third-order intermodulation product is very close to the fundamental signal, it has the greatest influence, so the third-order intermodulation is the most important consideration for the related products. The lower the third-order intermodulation product, the better.5) Third-order Intermodulation Cut-off Point (IP3)The intersection point of the extension line of the fundamental wave signal output power and the extension line of the third-order intermodulation in Fig is called the third-order intermodulation cut-off point, which is represented by the symbol IP3. It is also an important indicator of nonlinearity. When the output power is constant, the greater the output power of the third-order intermodulation cut-off point, the better the linearity of the power amplifier.6) Dynamic RangeThe dynamic range of a power amplifier generally refers to the difference between the minimum detectable signal and the maximum input power in the linear operating region. Naturally, this value must be as large as possible.7) Harmonic DistortionWhen the input signal increases to a certain level, the power amplifier will generate a series of harmonics due to its work in the nonlinear region. For high-power amplifier systems, filters are generally required to reduce harmonics below 60dBc.8) Input/Output VSWR (Voltage Standing Wave Ratio)This is also a very important indicator of how well the amplifier matches the overall system. The deterioration of the input-output ratio will lead to the deterioration of the gain fluctuation and group delay of the system. However, it is difficult to design a power amplifier with a high VSWR. In general systems, the input VSWR of the power amplifier is required to be lower than 2:1.The main technical indicators of RF power amplifiers are output power and efficiency. Therefore how to improve them is the core of the design goals of RF power amplifiers. Usually in the RF power amplifier, the fundamental frequency or a certain harmonic can be selected by the LC resonant circuit to achieve distortion-free amplification. In addition to this, the harmonic components in the output should be as small as possible to avoid interference with other channels. Figure 4. Increase the Power of the RF Input Signal Ⅳ Key Feature: Non-Linearity In an ideal amplifier, the output signal should faithfully reflect the input signal, that is, the waveform should be the same. But in fact, for many reasons, the input signal cannot be exactly the same waveform as the input signal, which is called amplifier distortion.Amplifier distortion mainly includes frequency distortion (linear distortion) and waveform distortion (non-linear distortion). The former mainly refers to the difference in gain and delay of the amplifier for different frequency components; the latter refers to the same frequency, the output signal and the input signal are not linear. Frequency distortion is represented by spectral changes in the frequency domain, while nonlinear distortion is represented by changes in the time-domain waveform. Non-linear distortion is different from frequency distortion mainly because a large number of new frequency components are generated. The nonlinear distortion of the power amplifier is mainly discussed here. 4.1 Nonlinear Characteristics From the small-signal model and input characteristic curve of an ideal transistor, it can be seen that the transistor amplifier itself is not an ideal linear device, and at the same time, due to the influence of parasitic parameters, the linearity is further reduced. But within a certain power range, the transistor can be regarded as linear amplification. For power amplifier designers, how to obtain higher output power and improve linearity is the key.For a transistor amplifier, its volt-ampere characteristics can be described as follows: A power series expansion can be used to describe the volt-ampere characteristics of the device: In the formula, an(n=0,1,2,3,…) is a coefficient related to the circuit characteristics. Usually, the larger the n, the smaller the value of the coefficient an. When the nonlinear device in the circuit is represented by a power series, the number of series terms taken depends entirely on the magnitude of the signal amplitude and the required precision. 4.2 Influence of Nonlinear Characteristics The influence of the nonlinear characteristics of the device on the amplifier can be discussed in two cases. One is when there is only one signal at the input end, and the other is when the input end has one to two other signals in addition to the useful signal.🔺Only one signal at the inputLet the signal at the input end be , and substitute it into formula 2, at this time there is When the amplitude of the input signal is large and the effect of the cubic term must be considered, the fundamental frequency signal obtained from formula 2 is: Figure 5. 1dB Compression Point (PA) A3 in formula 3 is usually a negative value, that is, y1(t) decreases as the input signal amplitude increases, a phenomenon called gain compression.The "1dB compression point" is often used in engineering to measure the linear performance of the device. The 1dB compression point is defined as the input signal power P1dB that reduces the gain by 1dB from the linear gain. As shown in Figure 5. According to the definition of 1dB compression point and formula 3, we can get 🔺Two signals at the input.The signal amplified at the input end of the amplifier is generally not a single tone signal, but a spectral signal composed of a certain bandwidth. Due to the nonlinearity of the device, a large number of combined interference frequency components other than the useful signal will be generated at the output end. In addition, the combined frequency components of two or more interfering signals may also cause interference to the useful signal. Have an assumption: Substitute into formula 1, where It can be seen from the above formula that the fundamental frequency components of ω1 and ω2 are generated by the first and third power terms: A total of multiple frequency components are generated: ω1 , ω2 , ω1 ± ω2, 2ω1 - ω2, 2ω2 - ω1 , 3ω1 - 2ω2, 3ω2 - 2ω1.The difference frequency 2ω1 - ω2, 2ω2 - ω1 in the combined frequency is generated by the cubic term. The combination of these two signal frequencies is just within the sideband range of the signal frequency, which may cause interference to adjacent channels, and is one of the main indicators of transmission signal. Figure 6. Intermodulation Signal Interference This interference is caused by the mutual modulation of the two signals, so it is called intermodulation interference. At the same time, it is generated by a cubic term, so it is also called third-order intermodulation interference in engineering.When the third-order intermodulation interference is an important indicator of the communication machine, it is often measured by the intermodulation distortion ratio IMR and the third-order intermodulation blocking point IP3 in engineering. IMR is defined as the ratio of the amplitude of the third-order intermodulation product to the amplitude of the fundamental signal at a certain input amplitude. Definition of IP3: When the third-order intermodulation component increases to be equal to the fundamental frequency component, the receiver cannot receive normally, so there is a . Figure 7. Third-order Intermodulation Blocking Point 🔺Sideband Signals Figure 8. Sideband Signals and the Spectrum In fact, most of the sideband signals are generated outside the bandwidth after the useful signals of different frequencies within the bandwidth are modulated with each other. That is, the sideband signal rises faster than the in-band signal, and the spectral mask in the above figure becomes more and more flat. The increase of sideband signals will cause interference to adjacent channels, so the IEEE 802.11 protocol has strict requirements on the spectrum template, as shown in the Figure 9. Figure 9. DSSS Signal Modulation Spectral Mask Figure 10. OFDM 20MHz Bandwidth Signal Spectral Mask For the power amplifier, its nonlinear characteristics will increase the sideband of the modulated signal, and the sideband amplitude is not easily suppressed by other networks such as filters, and it is easy to cause design difficulties. Therefore, when choosing a PA, not only should pay attention to the maximum linear output that it can achieve, but also whether it can meet the sideband spectrum requirements at this output power.🔺Other Effects of NonlinearityIn addition to the previously mentioned gain drop, which generates a large number of harmonic components, as well as third-order intermodulation and sidebands, nonlinearity can also cause signal and EVM to deteriorate, etc.   Ⅴ FAQ 1. What is RF power amplifier?A radio frequency power amplifier (RF power amplifier) is a type of electronic amplifier that converts a low-power radio-frequency signal into a higher power signal. 2. How does RF power amplifier work?An RF amplifier is actually a tuned amplifier that enables the input signal of broadcast or transmitted information to control an output signal. The RF amplifier uses frequency-determining networks to convert the input signal into an output signal that will provide the required response at a given frequency. 3. What is the most efficient class of RF power amplifier?Class C AmplifierThe Class C Amplifier design has the greatest efficiency but the poorest linearity of the classes of amplifiers mentioned here. The previous classes, A, B and AB are considered linear amplifiers, as the output signals amplitude and phase are linearly related to the input signals amplitude and phase. 4. How do I choose an RF power amplifier?Considerations When Choosing An RF Power Amplifier:Gain.Operating Frequency.Output Power Level.Efficiency.Linearity.Mismatch Tolerance.Noise Level. 5. What are the advantages of RF amplifier?Following are the RF Amplifier advantages:The RF amplifier offers greater gain i.e. better sensitivity. It offers better selectivity and hence it has ability to select wanted signals from multiple input signals at the RF receiver. 6. What are the different types of RF amplifiers?Amplifier TypesBroadband AmplifiersGain Block AmplifiersLog AmplifiersVariable Gain AmplifiersLow Noise AmplifiersCoaxial and Waveguide Power AmplifiersLinear AmplifiersBi-Directional Amplifiers 7. What is RF amplifier circuit?A radio frequency power amplifier (RF power amplifier) is a type of electronic circuit that converts a low-power radio-frequency signal into a higher power signal. 8. Is Class D amplifier better than a class AB?The most common audio power amplifier operates in the Class-AB mode. It provides the greatest amount of output power with the least amount of distortion. ... Class-D amplifiers are switches that are more efficient and produce less heat than their Class-AB equivalents. 9. What are RF amplifiers used for?Whenever people need to magnify a radio frequency signal into a higher power signal, the RF amplifier plays a pivotal role. They are used in commercial and defense avionics, space and deep space, electronic warfare, naval applications, mobile internet, satellite communication, and wireless communications. 10. Which amplifier is used in RF amplifier?RF power amplifiers using LDMOS (laterally diffused MOSFET) are the most widely used power semiconductor devices in wireless telecommunication networks, particularly mobile networks. LDMOS-based RF power amplifiers are widely used in digital mobile networks such as 2G, 3G, and 4G.

ⅠIntroduction This project mainly introduces how to DIY a Simple Audio Player with  Amplifier LM386 . But before this project, it is very essential to know some basics of LM386. Therefore, the first of this article is about LM386 audio amplifiers and the second part we will have a look at the practical appliance of Simple Audio Player with Amplifier LM386. Catalog ⅠIntroduction Ⅱ Amplifier LM386 Related Video: Ⅲ LM386 Basics 3.1 LM386 Datasheet 3.2 LM386 Pinout 3.3 LM386 Features Ⅳ  Project Introduction 4.1 Hardware Required 4.2 Getting Ready with Your WAV Audio Files: 4.3 Circuit 4.4 Code 4.5 Working of this Arduino Music Player: Ⅴ FAQ How to make an LM386 audio amplifier circuit Amplifier LM386 Video Description: In this Video, We will explore how to use the popular LM386 class AB audio amplifier IC to build a simple mono 1 watt audio amplifier.  Ⅲ LM386 Basics Despite the fact that LM386 audio amplifiers are quite old. They do, however, have a lot of useful information. Assume your audio player has poor sound quality. You want to boost the volume. They are a good option. Because of the low voltage supply and the fact that it works well with a battery.   3.1 LM386 Datasheet You completed an audio circuit  . However, the sound is too faint. Many people use the LM386 to boost the sound to a speaker. The LM386 is a low-power audio amplifier. Also, you should be able to work with a battery,  It has a similar shape to  IC-741  and DIP-8. So, small and simple. Even if it's small, it makes a big sound. But...better. it's If you have previously read the LM386 Datasheet.   3.2 LM386 Pinout Figure1:pinout In DIP-8, we frequently use the LM386. There are only a few pin connections. Other packets are also the same. For example, SOP-8, TSSOP-8, and so on.   3.3 LM386 Features   Ⅳ  Project Introduction Including sounds or music in our project will always make it look and sound much more appealing. If you're working with an  Arduino  and have a lot of free spins, you can easily add sound effects to your project by purchasing an extra SD card module and a standard speaker. In this article, I'll show you how to play music and add sound effects with your  Arduino board, as well as introduce the IC LM386 Amplifier  , which we'll use in this process. We will play the.wav music files stored on an SD card in this project. The Arduino will be programmed to read these.wav files and play the audio on a speak through an LM386 Audio amplifier.   Figure2: Project     4.1 Hardware Required Arduino Due Board8-ohm speaker or headphonesArduino shield with an SD card with cs CS 4 (like the Ethernet shield)Components to build an external audio amplifierLM386 (low power audio amplifier)10 kohm potentiometer10 ohm resistor2 x 10 µF capacitor0.05 µF (or 0.1 µF) capacitor250 µF capacitor   4.2 Getting Ready with Your WAV Audio Files: The audio file to be stored on the SD card must be in.wav format and have 44100 Hz, 16-bit stereo quality. We need audio files in.wav format to play sounds from an SD card using Arduino because the Arduino Board can only play audio files in a specific format, which is wav format. There are many mp3 shields available for use with Arduino to create an Arduino mp3 player. Alternatively, to play mp3 files in Arduino, there are websites that will convert any audio file on your computer into that specific WAV file.   4.3 Circuit The shield is placed on top of the Due, and a micro-SD card is inserted into the slot. The card's root directory contains a.wav file called "test.wav." For a quick test, connect a pair of headphones to the ground and DAC0 while keeping the polarity in mind. To add a speaker to the board, connect an amplification circuit between the DAC0 pin and the speaker. The amplification circuit will boost the speaker's volume,  There are numerous audio amplifiers available, with the LM386 being one of the most common. The following scheme demonstrates how to construct the circuit using the LM386 and a variety of components. You can power the LM386 by connecting the Vs pin to various voltage sources, such as the +5 V on the Arduino Due's 5V pin or an external 9V  battery,  The capacitor is connected to pins 1 and 8 of the LM386 provides the amplifier's gain. The gain is set to 200 with the 10 F capacitor, and 50 without the capacitor. The volume of the amplifier can be adjusted using the potentiometer. Caution: Do not connect the speaker directly to the Arduino Due's pins.   Figure3 : Circuit   Figure4: LM386 mounting on breadboard   4.4 Code   4.5 Working of this Arduino Music Player: Simply press the button connected to pin 2 after programming your Arduino, and your Arduino will play the first song (saved as 1.wav) for you. You can now press the button again to change your track to the next song, 2.wav. Similarly, you can listen to all four songs. You can also play/pause the song by pressing the pin 3 button. Press it once to pause the song and once more to resume it from where it left off. Watch the video below to see the entire process in action (or maybe to relax with some songs). I hope you had a good time with the project. It is now up to your imagination to incorporate them into your projects. You can create a speaking clock, voice assistant, talking robot, voice alert security system, and many other things.   Ⅴ FAQ 1. How many watts is LM386? 700mW, mono, 5- to 18-V, analog input Class-AB audio amplifier. 2. How do you calculate LM386 gain? Voltage Gain Analysis: Without any external components, it has a gain of Gv = 2x15K/(150+1350) = 20 (26 dB). With a capacitor (or shortcutting) between pins 1 and 8 , it has a gain of Gv = 2x15K/150 =200 (46dB). 3. Is LM386 any good? The LM386 is a well-designed, basic workhorse that does a decent job when its hooves are kept clean and it's well-fed. Aside from having a slow op-amp stage by today's standards, it has decent performance. It can also sound horrible if you neglect it. 4. What is an audio amplifier circuit? The circuit of the audio amplifier consists of a transistor a device to apply the input signals and a speaker at the output. The transistors are connected based on the necessity. The important factors that need to be considered while designing a audio amplifier is gain,noise, frequency response and distortion. 5. Which amplifier can be used for audio amplifier? An audio power amplifier (or power amp) is an electronic amplifier that amplifies low-power electronic audio signals such as the signal from radio receiver or electric guitar pickup to a level that is high enough for driving loudspeakers or headphones. 6. What is the need of power amplifier? The function of a power amplifier is to raise the power level of input signal. It is required to deliver a large amount of power and has to handle large current. The characteristics of a power amplifier are as follows − The base of transistor is made thicken to handle large currents.

Introduction Operational amplifiers will oscillate in many practical applications. For example, there are many kinds of loads that will cause them to oscillate. A feedback network that is not properly designed can cause them to become unstable. Insufficient power supply bypass capacitors may also make them unstable. Even the input and output may oscillate into a single-port system. This article will tell some common causes that cause the op amp to oscillate and the corresponding countermeasures. Catalog Introduction Ⅰ Basic Op Amp Circuits Ⅱ Example: LTC6268 Amplifier Ⅲ Decompensated Amplifiers Ⅳ Feedback Network Ⅴ Load Problem Ⅵ Strange Impedance Ⅶ Power Ⅷ Conclusion Ⅸ FAQ Ⅰ Basic Op Amp Circuits Figure 1. shows a block diagram of a non-rail-to-rail amplifier. The input controls the gm box, which drives the gain node and is buffered at the output. The compensation capacitor Cc is the main frequency response component. The return pin of Cc should be grounded, if there is such a pin and the op amp is not grounded, the capacitor current will return to one or two power supplies. Figure 1. Block Diagram of a Non-Rail-to-Rail Amplifier Figure 2. is a block diagram of a rail-to-rail output amplifier. The output current of the input box gm is sent through a current coupler, which divides the current into two parts and supplies them to the output transistor. The frequency response is determined by two Cc/2s, which are actually connected in parallel. Figure 2. Block Diagram of a Rail-to-Rail Output Amplifier Figure 3. shows the frequency response of the ideal amplifier. Although the electrical principles of the two circuits are different, the behavior is similar. The single pole compensation formed by gm and Cc provides a unity gain bandwidth product frequency of GBF = gm/(2πCc). In the vicinity of GBF/Avol, the phase lag of these amplifiers changes from -180° to -270°, where Avol is the open-loop DC gain of the amplifier. When the frequency is much higher than this low frequency, the phase stays at –270°. This is the well-known "dominant pole compensation", where the Cc dominates the frequency response, hiding the various frequency limitations of the active circuit. Figure 3. Frequency Response of the Ideal Amplifier   Ⅱ Example: LTC6268 Amplifier Figure 4. shows the open-loop gain and phase response of the LTC6268 amplifier with frequency. The LTC6268 is a small and low-noise 500MHz amplifier with rail-to-rail output and only 3fA bias current. It can be used as a good example to illustrate the performance of real amplifiers. The -90° phase lag of the dominant pole compensation starts from about 0.1MHz, reaches -270° around 8MHz, and moves down by more than -270° when it exceeds 30MHz. In fact, all amplifiers have high frequency phase lag, except for the basic dominant compensation lag caused by the additional gain stage and output stage. Generally, the starting point of the additional phase lag is around GBF/10. Figure 4. Open-Loop Gain and Phase Response of the LTC6268 Amplifier with Frequency The stability of the feedback is a matter of loop gain and phase, or Avol multiplied by the feedback coefficient, which is the loop gain. If we connect the LTC6268 in a unity gain configuration, 100% of the output voltage is fed back. At very low frequencies, the output is the negative value of the "–" input, or the phase lags by -180°. Compensation adds a -90° hysteresis through the amplifier, introducing a –270° hysteresis from the "–" input to the output. When the loop phase lag increases to ±360° or its multiples, oscillation will occur, and the loop gain is at least 1V/V or 0dB. The phase margin is a measure of how much the phase lag differs from 360° when the gain is 1V/V or 0dB. Figure 4. shows that the phase margin is about 70° (10pF red curve) at 130MHz, and the phase margin as low as about 35° is feasible.A topic that is not often mentioned is gain margin, although it is an equally important parameter. When it is reduced to zero at some higher frequencies, the amplifier will oscillate if the gain is at least 1V/V or 0dB. As shown in Figure 4, when the phase drops to 0° (or a multiple of 360°, or –180° as shown in the figure), the gain is about –24dB around 1GHz. This is a very low gain and no oscillations will occur at this frequency. In fact, people want the gain margin to be at least 4dB.   Ⅲ Decompensated Amplifiers Although the LTC6268 is fairly stable at unity gain, there are still unstable op amps. By designing the amplifier compensation to be stable only at higher closed-loop gains, the design trade-off can provide a higher conversion rate, wider GBF, and lower input noise than the unity gain compensation scheme. Figure 5. shows the open loop gain and phase of the LTC6230-10. The amplifier is intended to be used with a feedback gain of 10 or greater, so the feedback network will attenuate the output by at least 10 times. Through this feedback network, you can find the frequency when the open-loop gain is 10V/V or 20dB, and find that the phase margin is 58° at 50MHz (±5V power supply). At unity gain, the phase margin is only about 0°, so the amplifier oscillates. Figure 5. LT6230-10 Gain and Phase Change with Frequency It is observed that when the closed-loop gain is higher than the minimum stable gain, all amplifiers will be more stable. Even a gain of 1.5 will make a unity gain stable amplifier much more stable.   Ⅳ Feedback Network The feedback network itself may also cause oscillations. In Figure 6, put a parasitic capacitor in parallel with the feedback divider resistor. It is inevitable that each terminal of each component on the circuit board has a capacitance of about 0.5pF to the ground, and there is also a wiring capacitance. Figure 6. Parasitic Capacitance In fact, the minimum capacitance of the node is 2pF, and there is about 2pF of wiring capacitance per inch of trace. The accumulated parasitic capacitance can easily reach 5pF. Using LTC6268, in order to reduce the power, we set the values of Rf and Rg to a very high 10kΩ. When Cpar = 4pF, the feedback network has a pole at 1/(2π*Rf||Rg*Cpar) or 8MHz. The phase lag of the feedback network is -atan(f/8MHz), we can estimate that the loop will have a phase lag of 360° around 35MHz. At this time, the phase lag of the amplifier is -261°, and the feedback network lags about -79°. At this phase and frequency, the amplifier still has a gain of 22dB, and the gain of the voltage divider is .At the 0° phase, the amplifier's 22dB multiplied by the feedback divider's –19dB produces a +3dB loop gain, and the circuit oscillates. In order to operate normally in the presence of parasitic capacitance, we must reduce the value of the feedback resistor so that the feedback pole can far exceed the unity gain frequency of the loop. That is, the ratio of the pole to the GBF should be at least 6 times.The input end of the op amp itself may also have a considerable capacitance, the same as Cpar. In particular, low noise and low Vos amplifiers have large input transistors and may have larger input capacitance than other types of amplifiers, and the input capacitance is loaded on the amplifier's feedback network. We need to consult the data sheet to understand how much capacitance will be connected in parallel with Cpar. Fortunately, the LT6268 has only 0.45pF capacitance, which is already very low for such a low noise amplifier. The macro model running on LTspice® provided free of charge by ADI can be used to simulate a circuit with parasitic capacitance. Figure 7. shows how to improve the capacitor tolerance of the voltage divider. Figure 7(a) shows a non-negative output amplifier configuration with Rin. Assuming that Vin is a low impedance source (<Rin), Rin will effectively attenuate the feedback signal without changing the closed-loop gain. And it will also reduce the impedance of the voltage divider and increase the feedback pole frequency, which is expected to far exceed GBF. In addition, Rin reduces the bandwidth around the loop and amplifies the input offset and noise.Figure 7(b) shows a negative output configuration. Rg still performs loop attenuation without changing the closed loop gain. In this case, the input impedance is not affected by Rg, but the noise, offset and bandwidth parameters will deteriorate.Figure 7(c) shows the preferred method of compensating Cpar in a non-inverting amplifier. If we set Cf* Rf = Cpar * Rg, then we have a "compensation attenuator", so that the feedback divider now has the same attenuation at all frequencies and solves the Cpar problem. The mismatch in the product will cause "bumps" in the passband of the amplifier and "shelf" in the response curve (At this time, the low-frequency response is flat, but becomes straight near f = 1/2 * Cpar * Rg.).Figure 7(d) shows the equivalent Cpar compensation for the negative output amplifier. The frequency response must be analyzed to find a correct Cf, and the bandwidth of the amplifier is part of the analysis.Here are some comments on current feedback amplifiers (CFA) in turn. If the amplifier in Figure 7(a) is a CFA, then "Rin" has little effect on changing the frequency response, because the negative input is very low impedance and actively copies the positive input. The noise index will degrade slightly, and the additional negative input bias current will actually appear in the form of Vos/Rin. Similarly, in terms of frequency response, the circuit in Figure (b) is not changed by "Rg". The inverting input is not just a virtual ground, it is a real ground with low impedance, and Cpar has been tolerated (only in negative output mode). The DC error is similar to the situation shown in (a), (c) and (d) may be the preferred solution for voltage input op amps, but CFA can't tolerate a direct feedback capacitor without oscillation at all.   Ⅴ Load Problem Just as the feedback capacitor can damage the phase margin, the load capacitor can do the same. Figure 8 shows the change in LTC6268 output impedance with frequency in the case of several gain settings. Note that the unity gain output impedance is lower than the output impedance at higher gains. Full feedback enables the open-loop gain to reduce the inherent output impedance of the amplifier. Therefore, in Figure 8, the output impedance at a gain of 10 is generally 10 times the output impedance at unity gain. Since the feedback attenuator reduces the loop gain, the gain around the loop is 1/10, otherwise it will reduce the closed-loop output impedance. The open-loop output impedance is about 30, which is obvious in the high-frequency flat region of the curve with a gain of 100. In this area, from around gain bandwidth frequency (about 100) to gain bandwidth frequency, there is not enough loop gain to reduce the open loop output impedance. Figure 8. Impedance and Frequency of LTC6268 Under Three Gain Conditions The capacitor load will cause the phase lag and amplitude attenuation of the open-loop output impedance. For example, a 50pF load and our LTC6268 output impedance form another pole at 106MHz, where the output has a –45° phase lag and –3dB attenuation. At this frequency, the amplifier has a phase of -295° and a gain of 10dB. Assuming unity gain feedback is used, we have not fully realized the oscillation because the phase is not brought to ±360° (at 106MHz). However, at 150MHz, the amplifier has 305° phase lag and 5dB gain. The phase of the output pole is –atan(150MHz/106MHz) = -55°, and the gain is .Multiplying the gain cyclically, we get a 360° phase and +0.2dB gain, which is another oscillator. 50pF seems to be the minimum load capacitance that will force the LTC6268 to oscillate.The most common way to prevent oscillations caused by the load capacitor is to simply connect a small resistor in series to the capacitor after the feedback connection. The resistance value of 10Ω to 50Ω will limit the phase lag that may be caused by the capacitive load and isolate the amplifier and low capacitive impedance when the speed is very high. Disadvantages include DC and low frequency errors that vary with load resistance characteristics, capacitive load frequency response is limited, and signal distortion caused if the load capacitance is not constant when the voltage changes.Increasing the closed-loop gain of the amplifier can often prevent the oscillation caused by the load capacitance. Operating the amplifier with a higher closed-loop gain means that at frequencies where the loop phase is ±360°, the feedback attenuator also attenuates the loop gain. For example, if we use the LTC6268, its closed-loop gain is +10, then we will see that the amplifier has a gain of 10V/V or 20dB at 40MHz and a phase lag of 285°. To ignite the oscillation, an output pole is required, causing an additional 75° hysteresis. By -75° =-atan(40MHz/Fpole) →Fpole =10.6MHz, we can find the output pole. This pole frequency comes from a load capacitance of 500pF and an output impedance of 30Ω. The output pole gain is .When the unloaded open-loop gain is 10, the loop gain at the oscillation frequency point is 0.26, so there is no oscillation this time, at least no oscillation caused by the simple output pole. In this way, we increased the tolerable load capacitance from 50pF to 500pF by increasing the closed-loop gain.In addition, unterminated transmission lines are also very bad loads because they will cause "runaway" impedance and phase changes that repeat with frequency (See the impedance of an unterminated 9-foot cable in Figure 9).If your amplifier can safely drive the cable under certain low-frequency resonance conditions, it is likely to oscillate at a higher frequency because its own phase margin is reduced. If the cable must be unterminated, a "back-match" resistor in series with the output can isolate the cable's extreme impedance changes. In addition, even if the transient reflection from the this end of the cable just recoils back to the amplifier, if the resistance of the backward matching resistor matches the characteristic impedance of the cable, the resistor can properly absorb this energy. If the backward resistor does not match the cable impedance, some energy will be reflected from the amplifier and terminals, and back to the unterminated end. When the energy reaches this end, it is quickly reflected back to the amplifier. As a result, there is a series of pulses bouncing back and forth, but attenuate each time. Figure 9. Impedance and Phase of the Unterminated Coaxial Cable Figure 9 shows a more complete output impedance model. The ROUT is the same as what we discussed in the LTC6268, and it is also 30Ω, in addition, add the Lout item. This is a combination of physical inductance and electronic equivalent inductance. The physical package, bonding wire, and external inductance add up to 5nH to 15nH. The smaller the package, the smaller the total value. Figure 10. Inductive Component of Amplifier Output Impedance In addition, any amplifier has an electrical inductance of 20nH to 70nH, especially bipolar devices. The finite Ft of the device turns the parasitic base resistance of the output transistor into an inductance. The harm is that Lout and CL may interact to form a series resonant circuit, then the same problem comes again. If there is no greater phase lag in the loop, the impedance of the series resonant circuit may drop to a level that Rout cannot drive. This may cause oscillations. For example, set Lout = 60nH and CL = 50pF. Resonant frequency is .Just within the passband of the LTC6268. In fact, this series resonant circuit is loaded to the output terminal during resonance, which changes the phase of the loop greatly near the resonant frequency. Unfortunately, Lout is not mentioned in the amplifier's data sheet, but its effect can sometimes be seen on the open-loop output impedance circuit. In short, for amplifiers with a bandwidth of less than 50MHz, this effect is not important.One solution is shown in Figure 10. Rsnub and Csnub form a so-called "shock absorber" whose purpose is to reduce the Q value of the resonant circuit so that the resonant circuit does not have a very low resonant impedance to the output of the amplifier. The value of Rsnub is usually estimated as the reactance of CL to reduce the Q value of the output resonance circuit to about 1. Adjust the size of Csnub to fully insert Rsnub into the output resonance frequency, that is, the reactance of Csnub <Cl. Csnub = 10 * CL is practical. Csnub unloads the amplifier at intermediate and low frequencies, especially at DC. If it is very large, Rsnub will put a heavy load on the amplifier at intermediate frequency, which will affect the low frequency, gain accuracy, closed-loop bandwidth and distortion. However, after a little fine-tuning, shock absorbers are often useful for controlling reactive loads, but shock absorbers must be adjusted through experiments. Figure 11: Using an Output Shock Absorber The negative input of the current feedback amplifier is actually a buffer output and will also have the series characteristics shown in Figure 8. Therefore, it may oscillate under the action of Cpar, just like the output terminal. You should try to reduce Cpar and any related inductance. Unfortunately, the damper on the negative input terminal modifies the relationship between closed-loop gain and frequency, so it is not very useful.   Ⅵ Strange Impedance Many amplifiers have an abnormal input impedance at high frequencies. This is most true for amplifiers with two input transistors in series, such as the Darlington configuration. Many amplifiers have PNP/NPN transistor pairs at the input, and their behavior changes with frequency similar to the Darlington configuration. The real part of the input impedance will become negative at some frequencies (generally much higher than GBF). Inductive source impedance will resonate with the input and circuit board capacitance, and negative real components may provoke oscillations. When driving with unterminated cables, this can also cause oscillations at many repetition frequencies. If it is inevitable to use a long inductive wire at the input, you can disconnect the wire with several series-connected resistors that can absorb energy, or install a medium-impedance shock absorber (about 300Ω) on the input lead of the amplifier.   Ⅶ Power The last source of oscillation to consider is power supply bypass. Figure 10 shows part of the output circuit. LVS+ and LVS– are the unavoidable packaging, IC bond wires, the physical length of the bypass capacitor (inductive like any conductor), and the series inductance of the circuit board traces. It also includes the external inductance that connects the local bypass component to the rest of the power bus (if not the power plane). Although 3nH to 10nH may seem small, at 200MHz, it is 3.8 to 12Ω. If the output transistor conducts a large high-frequency output current, there will be a voltage drop across the power inductor. Figure 12. Power Supply Bypass Capacitor Details The rest of the amplifier needs a noise-free power supply, because these parts cannot suppress power supply noise as the frequency changes. In Figure 13 we can see the power supply rejection ratio (PSRR) of the LTC6268 with frequency. In all operational amplifiers, because there is no ground pin, the compensation capacitor is connected to the power supply, which will couple power supply noise into the amplifier, and gm must cancel this noise. Due to the compensation, PSRR decreases with 1/f, in addition, the power supply rejection actually increases after 130MHz. Figure 13. LTC6268 Power Supply Rejection with Frequency Variation At 200MHz, due to the increase of PSRR, the output current may interfere with the power supply voltage inside the LVs inductor. Through the amplification of PSRR, the interference becomes a strong amplifier signal, driving the output current, generating internal power signals, etc., causing the amplifier to oscillate. This is why the power supplies of all amplifiers must be carefully bypassed with traces and components with very small inductance. In addition, the power supply bypass capacitor must be much larger than any load capacitor.If consider the frequency around 500MHz, then the range 3nH to 10nH becomes 9.4Ω to 31.4Ω. This is enough for the output transistor to generate self-oscillation by its inductance and IC component capacitance, especially when the output current is large (transistor gm and bandwidth increase). Because the bandwidth of transistors is very large, special attention needs to be paid, especially at high output currents.   Ⅷ Conclusion In short, the designer needs to consider the parasitic capacitance and inductance associated with each op amp terminal and the natural characteristics of the load. Usually the designed amplifier is very stable in the nominal environment, but each application needs to analyze it by itself.   Ⅸ FAQ 1. Does your op amp oscillate?Well, it shouldn't. We analog designers take great pains to make our amplifiers stable when we design them, but there are many situations that cause them to oscillate in the real world. ... Improperly designed feedback networks can cause instability. Insufficient supply bypassing can offend. 2. What is oscillator in op amp?An oscillator is an electronic circuit that produces a periodic signal. ... The feedback network takes a part of the output of amplifier as an input to it and produces a voltage signal. This voltage signal is applied as an input to the amplifier. 3. What causes an amplifier to oscillate?Causes of parasitic oscillationParasitic oscillation in an amplifier stage occurs when part of the output energy is coupled into the input, with the correct phase and amplitude to provide positive feedback at some frequency. ... Similarly, impedance in the power supply can couple input to output and cause oscillation. 4. How do you compensate an op amp?Another effective compensation technique is the miller compensation technique and it is an in-loop compensation technique where a simple capacitor is used with or without load isolation resistor (Nulling resistor). That means a capacitor is connected in the feedback loop to compensate the op-amp frequency response. 5. How can an op amp improve stability?To ensure stability, the value of RX should be such that the added zero (fZ) is at least a decade below the closed loop bandwidth of the op amp circuit. With the addition of RX,circuit performance will not suffer the increased output noise of the first method, but the output impedance as seen by the load will increase. 6. What are the requirements of oscillations in an amplifier?Oscillations around the 3dB bandwidth of the amplifier are usually due to input/output feedback. Higher frequency oscillations may only be visible on a spectrum analyzer. They may cause waveform distortion and be affected by touching the amplifier on power and signal cables. 7. How do you stop an oscillating op amp?If the op-amp still oscillates, try these things, in this order:1) Add a small resistor to the op-amp's output, either inside or outside the feedback loop. ...2) Do the same as in the previous step, except use a ferrite bead or chip ferrite instead of the resistor. ...3) Raise the amp's gain a bit. 8. How do you increase the gain margin of an op amp?You can increase the phase margin by making a dominant pole nearer to the zero frequency origin. This is accomplished by compensating the op amp through adding a shunting capacitor in the highest impedance node of the amplifier. This is a very well known technique which is used commonly to increase the phase margin. 9. Why the gain of op amp deteriorate with frequency?All opamps have a limit on upper frequency. In a LPF, at low frequencies, the output amplitude is equal to input. But as the frequency increases, the capacitive reactance decreases and the output amplitude starts to decrease. 10. What is used to avoid or minimize instability in amplifiers?It is often desirable to use capacitance to ground from an amplifier's active input terminals to reduce high-frequency interference, RFI and EMI. This filter capacitor has a similar effect on op amp dynamics as increased stray capacitance. 11. Why op amps oscillate an intuitive look at two frequent causes?With delay in the loop, the amplifier does not immediately detect its progress toward the final value. ... It overreacts by racing too quickly toward the proper output voltage. Note the faster initial ramp rate with delayed feedback. 12. How does an op-amp oscillator work?The Op-amp Multivibrator is an astable oscillator circuit that generates a rectangular output waveform using an RC timing network connected to the inverting input of the operational amplifier and a voltage divider network connected to the other non-inverting input.

Ⅰ IntroductionYou can image this case: If you drive an older vehicle, chances are you don't have Bluetooth. If you don't want to remove your factory stereo to install an aftermarket Bluetooth stereo, a Bluetooth amp is ideal. Not only will you be able to add Bluetooth to your vehicle, but you will also be able to amplify your speakers and improve overall system performance.CatalogⅠ IntroductionⅡ Bluetooth Amplifier Related  Video:Ⅲ What Is A Bluetooth Amplifier?Ⅳ What Is Bluetooth?Ⅴ Why You Need a Bluetooth AmplifierⅥ Common ApplicationsⅦ How Bluetooth Amplifiers Works？Ⅷ Three Things You Need to ConsiderⅨ Recomendation  Bluetooth Amplifiers9.1 Sony STRDH190 2-CH Stereo Bluetooth Audio Amplifier9.2 Pyle Karaoke Wireless Bluetooth Amplifier9.3 Fosi Audio Store BT20A Stereo Audio AmplifierⅩ FAQ   Ⅱ Bluetooth Amplifier Related  Video:Bluetooth AmplifierBluetooth Amplifier Video Description:Amplifier Bluetooth simple cocok buat kamu yang nggak mau ribet, cuma pakai speaker woofer 4-6inch dan 3-4inch buat vocal kamu bisa menikmati musik dengan banyak fitur.  Ⅲ What Is A Bluetooth Amplifier?Understanding technology is a difficult and time-consuming task. Because there is never a shortage of products brought to market. It is a tough task of staying on top. For instance, the Bluetooth headphone amp is such a product that it hasn't been around for very long, it's a good idea to start by defining it.A Bluetooth amplifier is a device that is intended to convert your favorite pair of wired headphones into wireless Bluetooth headphones by utilizing Bluetooth technology's radio frequency communication.Bluetooth AmplifierⅣ What Is Bluetooth?Bluetooth emerged as a technology in Sweden in the late 1990s. Its original goal was to limit the need for unnecessary cable connections between devices from various manufacturers.For example, if you have an Apple smartphone and a JBL or Bose speaker, it may be difficult to transfer an audio signal from one to the other as the two devices use rather proprietary connections.Bluetooth, on the other hand, allows devices to communicate with one another via short-range radio frequencies that alternate hundreds of times per second. This also contributes to security, making Bluetooth connections a very secure way to transfer data.Bluetooth Wireless Technology (BWT) has nearly limitless potential, particularly in the Internet of Things (or IoT), and is now used in smart speakers, smart home implementations, and a variety of other devices.Bluetooth Ⅴ Why You Need a Bluetooth AmplifierStream Music Through Your System Directly from Your AmplifierEliminate the Need of an Expensive Head UnitBoost Your System Ⅵ Common ApplicationsOne of the benefits of using a Bluetooth amplifier is that the device can offer you flexibility. What is more, ，While a Bluetooth amplifier is an excellent addition to your car's sound system, they are also ideal for marine and power sports applications, as well as just about any other application that requires an amplifier.amplifierIn the CarA Bluetooth amplifier is an additional, and possibly the most efficient, way to add Bluetooth to your vehicle. Many older stereos lack built-in Bluetooth simply because it was not a common feature at the time. Until Bluetooth amplifiers were released, the only way to add Bluetooth to your vehicle was to purchase a new, potentially expensive, Bluetooth head unit or a Bluetooth adapter that was compatible with your stereo. With a Bluetooth amplifier, you can kill two birds with one stone. You'll add the convenience of wireless Bluetooth streaming to your vehicle while also enhancing your current system. Some Bluetooth amplifiers also include a wired microphone, allowing you to make hands-free phone calls.On the BoatBluetooth amplifiers aren't just for use in your car; they're also great for listening to music while boating. Many boats don't even have a sound system, so if you want to add one, you'll probably have to build it from the ground up. A marine-rated Bluetooth amplifier eliminates the need for a head unit, saving you money while improving the overall performance of the system. And, just like in a car, if your boat has a sound system but the head unit isn't Bluetooth enabled, a Bluetooth amplifier can save you from having to replace the stereo.On the ATVAnyone interested in outdoor power sports is aware that free space is extremely limited. Because of this, installing a sound system in an ATV, UTV, SSV, or motorcycle can be a difficult task, and any space-saving measures you can take are invaluable. A Bluetooth amp can combine your source unit and amplifier into a single piece of equipment while still allowing you to play music through your system. Ⅶ How Bluetooth Amplifiers Works？ How Bluetooth Amplifiers WorksA Bluetooth amplifier is a very simple piece of equipment. It functions and installs similarly to any other amplifier (they can be connected to a source unit, but it is not required), but it includes an integrated Bluetooth module that allows you to connect virtually any Bluetooth-enabled device (smartphones, tablets, etc.) to it wirelessly. Bluetooth amps eliminate the need for a traditional head unit by allowing the amp to function as both the transmitter and the receiver.  Ⅷ Three Things You Need to ConsiderWatts of amplifier: This number indicates the maximum power output of your amplifier. As the power output of the speakers you're going to connect to your amplifier increases, so should the power output of your amplifier. Otherwise, you won't be able to get good sound quality. The total power output of your amplifier must be greater than or equal to the total power required by all of the speakers you intend to connect to it.Bluetooth version: Bluetooth 5.0 is the most recent Bluetooth version. Obsolete Bluetooth versions are not recommended for purchase because they are difficult to pair and have a limited operating range. Furthermore, you will not experience faster data transfer speeds when compared to the most recent version.Impedance: The impedance of your amplifier determines the quality of music you will hear. It should always be the same as the impedance of your speakers. As a result, always ensure that the impedance of your amplifier is equal to the total impedance of all the speakers you intend to connect to it. Ⅸ Recomendation Bluetooth AmplifiersThere are all kind of Bluetooth Amplifiers and the following three are the most popular at the present. This part will introduce their specifications, pros and cons.9.1 Sony STRDH190 2-CH Stereo Bluetooth Audio AmplifierSony STRDH190 2-CHSONY is without a doubt the best brand in the world when it comes to electronic items. If you are willing to pay a premium, there is no other brand that can compete with the quality of SONY products. Another example is their STRDH190 2-CH HOME STEREO RECEIVER.You can connect two pairs of speakers to it if A/B switching is enabled. With A+B mode, you can also switch between A and B to play speakers separately in two different rooms, or you can play all four speakers at once in the same room. It also has a full-size 14" headphone jack for listening to music through a headset.The STRDH190-2 AMPLIFIER features HI-RES AUDIO, which allows you to hear music as if the artist were performing in front of you. It has a high-capacity transformer that produces clear, distortion-free sound. Its redesigned design reduces transmitted vibrations from speaker sound pressure, providing you with more focused and powerful sound.This amplifier also has an FM RADIO feature. It comes with 30 pre-programmed radio channels. Its remote-control feature allows you to change audio settings from a distance, making you feel less tired and more at ease. The STRDH 190 2-CH Bluetooth amplifier has a low 5 14" height and will easily fit into your A/V cabinets. SpecificationsType: Amplifier with two channelsInput: Bluetooth input/4 RCA inputs/3.5mm aux inputImpedance: 6-16 ohm impedanceMaximum o/p power: 100 watts x 2 Work AC voltage range: 120-230 voltsRemote control and an FM antenna are included as extras.Dimensions: 11x17x5.2inches17 pound weightWarranty period: 12 monthsProsHigh output powerRemote control capabilityConnects to paired Bluetooth devices automatically.The FM tuner automatically searches for channels in your area.ConsLarge size and weightExpensive in terms of price. 9.2 Pyle Karaoke Wireless Bluetooth AmplifierPyle Karaoke WirelessPyle is a leading producer of high-quality home audio, car audio, and Pro Audio DJ speaker systems. To meet the diverse needs of consumers, the American brand creates a wide range of audio systems with advanced features.Pyle's Bluetooth amplifier has a power rating of 500w and is designed for amplifying multiple speakers with impedances ranging from 4 to 8 ohms. Furthermore, the amplifier has four channels, making it ideal for your PA and home theater system. It has Bluetooth version 4.0 and a decent range for pairing with all of the latest smart devices such as smartphones, laptops, and PCs.The Bluetooth amplifier has 7 input ports for a variety of connectivity options. There is a USB port, a micro SD slot, an FM radio, an AUX port, an MP3 slot, an audio port, and a REC. In addition, there is subwoofer output (L/R) connectors and two 14-inch microphone inputs.The amplifier includes a talk-over function for voice-over, announcements, and paging. When you activate the talk-over mode, the audio will be paused so that you can speak. The crisp buttons and rotary knob make the amplifier simple to use. You can adjust the equalization and volume using the rotary knob. The package also includes a remote control for controlling the amplifier from a distance.Despite the fact that the warranty period is not explicitly stated on the product page, all Pyle products come with a one-year warranty from the date of purchase. SpecificationsAmplifier with four channelsBluetooth/FM radio/AUX/two 14-inch microphone inputs/headphone jack/MP3/USB/SD card inputMaximum o/p power: 500 watts20Hz to 20kHz frequency response4 to 8 ohms in impedanceUp to 30 radio station presets are available.>81 dB signal-to-noise ratioRemote control/FM antenna is a unique feature.Dimensions: 13 x 9.84 x 3.54 inches10.3 pounds1-year warrantyProsProvides four channelsRemote control is used to control the unit from a distance.The FM tuner has an LCD.Wireless range of more than 40 feetConsUses an older Bluetooth version 4.0A bit heavy  9.3 Fosi Audio Store BT20A Stereo Audio AmplifierFosi Audio Store BT20AA FOSI product is next on the list of best Bluetooth amplifiers. This time, it's the BT20A amplifier, which has a maximum output of 200 watts. This allows you to use the same amplifier to power two passive speakers of 100 watts each.It has a built-in CSR64215 chip that provides a strong and stable Bluetooth connection with a range of 50 feet. You will enjoy exceptional music clarity thanks to the TPA3116D2 chip, which provides harmonic distortions of less than 0.04 percent even at high volumes.Again, using the bass and treble control knobs, you can adjust the music output to your liking. It also has a built-in power circuit that prevents sparking when you plug in your amplifier, making it safe to use.The sleek curved edges design of the FOSI BT20A is another feature that draws customers in. This allows you to handle it comfortably without experiencing any sharp pain in your palms. SpecificationsClass D, two-channel amplifierBluetooth and RCA inputs are available.2-8 ohm impedanceMaximum o/p power: 2 x 100 watts (200watts max)AC 110-240 volts is the working voltage.24v DC/4.5A power adapterA unique feature is that it includes a Bluetooth antenna.Dimensions: 5.2 x 3.54 x 1.42 in.2.09-pound weightPros18-month warrantyPowerful output.The bluetooth range is greater than that of the bt10a amplifier.Curved round edges are gentle on your hands.ConsThere is no remote control feature. Ⅹ FAQ1. What is a Bluetooth amplifier used for?A Bluetooth amplifier is designed to convert your favorite pair of wired headphones into wireless Bluetooth headphones by harnessing the radio frequency communication of Bluetooth technology.2. Can you connect an amplifier to a Bluetooth speaker?You can connect your receivers to a wireless speaker by using a Bluetooth transmitter. Plug the Bluetooth transmitter into the headphone port of the receiver. Turn on the receiver after plugging it into a power source.3. Is a Bluetooth amplifier worth it?If you can get yourself a decent set of Bluetooth headphones, then the answer to whether or not headphone amps are worth it is a resounding no. ... A headphone amp increases low voltage audio signal from a source device, allowing the signal to be converted into a sound wave by your headphones4. Do I need a Bluetooth amp?Bluetooth headphones will never need an amplifier, as the headphones themselves deliver the power to the drivers internally. Editor's note: this article was updated on June 14, 2021, to expand upon technical information.5. What is a Bluetooth audio amplifier?The product is simple, bluetooth audio transmitter equipment that can be connected to speakers and other devices, play music through bluetooth wireless transmission. ... At the same time, the product is a multifunctional amplifier for bluetooth speakers.