The Kynix Blog

ⅠIntroductionA direct current (DC) motor is a type of rotary electrical motor that converts direct current electrical energy into mechanical energy. The most common types are based on magnetic field forces. Almost all types of DC motors have an internal mechanism, either electromechanical or electronic, that changes the direction of current in a portion of the motor on a regular basis.  CatalogⅠIntroductionⅡ Dc Motor Related VideoⅢ What is a DC Motor?Ⅳ How DC Motors Work？Ⅴ Types of DC Motors5.1 Shunt Wound DC Motor5.2 Series Wound DC Motor5.3 Compound Wound DC MotorⅥ Applications of DC MotorsⅦ Popular DC Motor BrandsⅧ What is the Difference Between an AC and DC Motor?8.1 AC Motor and It’s Mechanism8.2 Difference Between AC and DC MotorⅨ FAQ Ⅱ Dc Motor Related VideoDC Motor, How it works? Dc Motor Video Description：The working of a DC motor is well explained in this video with the help of animation. Construction details of DC Motor, Shunt & Series motor, concept of back EMF are also explained in this video. Ⅲ What is a DC Motor?A DC motor is an electric motor that runs on direct current (DC) (unlike an induction motor that operates via an alternating current). A direct current motor converts direct current electrical energy into mechanical energy.A direct current (DC) motor is a type of rotary electrical motor that converts direct current electrical energy into mechanical energy. The most common types are based on magnetic field forces. Almost all types of DC motors have an internal mechanism, either electromechanical or electronic, that changes the direction of current in a portion of the motor regularly. Figure1：What is a DC Motor?Ⅳ How DC Motors Work？Any rotary electrical machine that shifts direct current electrical energy into mechanical energy is referred to as a 'DC motor.' Small motors in toys and appliances to large mechanisms that power vehicles, pull elevators and hoists, and drive steel rolling mills are examples of DC motors. But how do direct current motors work?A stator and an armature are the two main components of a direct current motor. The stator is the motor's stationary component, while the armature rotates. In a direct current motor, the stator generates a rotating magnetic field that causes the armature to rotate.A simple DC motor generates an electromagnetic field aligned with the center of the coil by using a stationary set of magnets in the stator and a coil of wire with a current running through it. To concentrate the magnetic field, one or more windings of insulated wire are wrapped around the core of the motor.Insulated wire windings are connected to a commutator (a rotary electrical switch), which applies an electrical current to the windings. The commutator enables each armature coil to be energized in turn, resulting in a consistent rotating force (known as torque).When the coils are on and off in sequence, a rotating magnetic field is created that interacts with the varying fields of the stator's stationary magnets to produce torque, which causes it to rotate. These key operating principles of direct current motors enable them to convert electrical energy from direct current into mechanical energy via rotating movement, which can then be used for object propulsion. Figure2：working principleⅤ Types of DC MotorsDirect motors are classified based on how the field winding is connected to the armature.There are 3 main types of DC Motors: 5.1 Shunt Wound DC MotorFigure3：Shunt Wound DC Motor A DC shunt motor (also known as a shunt wound DC motor) is a type of self-excited DC motor in which the field windings are shunted to or paralleled with the motor's armature winding. The armature and field windings are exposed to the same supply voltage because they are connected in parallel. Though, as shown in the figure below, there are separate branches for the flow of armature current and field current.Figure4：DC shunt motor    5.2 Series Wound DC MotorFigure5：Series Wound DC Motor A series wound DC motor like a shunt wound DC motor or a compound wound DC motor, is a type of self-excited DC motor that gets its name from the fact that the field winding is connected internally in series to the armature winding. As a result, unlike a shunt motor, the field winding is exposed to the entire armature current.  Figure6：wound DC motor circuit 5.3 Compound Wound DC Motor A compound wound DC motor (also known as a DC compound motor) is a type of self-excited motor that is composed of both series and shunt field coils connected to the armature winding, as shown in the figure below.  Figure7：DC compound motor Both field coils provide the required amount of magnetic flux, which connects with the armature coil and produces the torque required to allow rotation at the desired speed. As we can see, a compound wound DC motor is created by combining a shunt wound DC motor and a series wound DC motor to achieve the best of both types. A shunt-wound DC motor, like a shunt-wound AC motor, has an extremely efficient speed regulation characteristic, whereas a DC series motor has a high starting torque.As a result, the compound wound DC motor strikes a balance between these two characteristics, offering a good combination of proper speed regulation and high starting torque.Though its starting torque is lower than that of a DC motor, and its speed regulation is not as good as that of a shunt DC motor. The overall characteristics of a DC shunt motor fall somewhere between these two extremes. Studying our electrical MCQs will help you learn more about motors.Types of Compound Wound DC Motor：Long Shunt Compound Wound DC MotorShort Shunt Compound Wound DC MotorCumulative Compounding of DC Motor  Ⅵ Applications of DC MotorsBecause of the various types of DC motors available, DC motors have a wide range of applications. The preceding section discussed some of the various applications and circumstances in which DC motors are used, as well as the advantages of the various types of motors.While each type has advantages, a DC motor can be used in a variety of ways. Small DC motors are used in tools, toys, and various household appliances at home. Conveyors and turntables are examples of DC motor applications in retail, while large DC motor applications in the industry include braking and reversing.Here are a few more specific uses for DC motors:DC motors for fansDC motors for pumpsDC motors for toysDC motors for electric carsDC motors for robotsDC motors for bikes Ⅶ Popular DC Motor BrandsPlease search the below online to view DC motors produced by some of our most popular brands.                                                                                  RS PRO                                                                               Crouzet                                                                                   Maxon  Ⅷ What is the Difference Between an AC and DC Motor?Electric motors are broadly classified into two types. They are the alternating current (AC) motor and the direct current (DC) motor. The AC motor is powered by alternating current, whereas the DC motor is powered by direct current.Figure8：Difference Between an AC and DC Motor 8.1 AC Motor and It’s MechanismA hoop of electromagnets is organized across the outside of an AC motor (making up the stator). Which can be configured to generate a rotating magnetic field. An axle made of solid metal, a wire loop, a coil, a squirrel cage made of metal bars, and interconnections are all found inside the stator. Other freely rotating metal parts that can conduct electricity are also present.The rotor, which is suspended within the magnetic field, acts as an electrical conductor. The magnetic field is constantly changing as a result of its rotation. The magnetic field generates (or induces) an electric current inside the rotor, according to Faraday's law of electromagnetism. If the conductor is a ring or a wire, the current flows in a loop around it. Instead, eddy currents swirl around a solid piece of metal if the conductor is simply a solid piece of metal.In any case, the induced current generates its magnetic field and, according to another electromagnetism law (Lenz's law), attempts to stop whatever is causing the rotating magnetic field by rotating as well. AC motors provide a relatively efficient way of generating mechanical energy from a simple electrical input signal.  Figure9：AC motor and DC notor 8.2 Difference Between AC and DC MotorAC MotorDC MotorAC motors do not require current conversion.Current is converted from alternative (AC) to direct (DC) output in DC motors.AC motors are available in two-phase, single-phase, and three-phase configurations.DC motors are all single phase.Armatures in alternating current motors do not rotate in tandem with the continuous rotation of magnetic fields.The armature rotates while the magnetic field rotates in DC motors.Repairing is not expensive.Repairs are quite expensive.Have a longer life expectancy.Have a shorter life expectancy.To begin operation, AC motors require effective starting equipment such as a capacitor.DC motors do not require any external assistance to begin operation.There are three input terminals.You should have two input terminals.When the load changes, AC motors are slow to respond.DC motors respond quickly to changes in load.AC motors are suitable for applications requiring high speed and variable torque.DC motors are appropriate for applications requiring high torque and variable speed.The speed of an alternating current motor is simply controlled by varying the frequency of the current.The speed of a direct current motor is controlled by varying the current of the armature winding.Implemented for large-scale industrial use.Intended for small-scale domestic use.The distinction between AC and DC motors is significant not only from a technical standpoint. It is also required for practical demonstrations. Whether you're an engineer or a business enthusiast, you can't choose the right one for your needs unless you understand the fundamental technical differences. Ⅸ FAQ1. How can you tell if a motor is AC or DC?Look for the stator core construction and rotor. If there is no commutator, then it is a AC motor. If there is a commutator and brushes, it may be either a DC motor or an AC commutator motor (Universal motor).2. Which motor is powerful AC or DC?AC motors are generally considered to be more powerful than DC motors because they can generate higher torque by using a more powerful current. However, DC motors are typically more efficient and make better use of their input energy.3. Why starter is used in DC motor?Starters are used to protect DC motors from damage that can be caused by very high current and torque during startup. They do this by providing external resistance to the motor, which is connected in series to the motor's armature winding and restricts the current to an acceptable level.4. What is the voltage of a DC motor?Typical DC motors may operate on as few as 1.5 Volts or up to 100 Volts or more. Roboticists often use motors that operate on 6, 12, or 24 volts because most robots are battery powered, and batteries are typically available with these values. Operating Current.5. Is a brushless motor AC or DC?There are two types of commonly used DC motors: Brushed motors, and brushless motors (or BLDC motors). As their names imply, DC brushed motors have brushes, which are used to commutate the motor to cause it to spin. Brushless motors replace the mechanical commutation function with electronic control.6.Does Tesla use DC or AC motors?Tesla, for example, uses alternating current (AC) induction motors in the Model S but uses permanent-magnet direct current (DC) motors in its Model 3. There are upsides to both types of motor, but generally, induction motors are somewhat less efficient than permanent-magnet motors at full load.7. Are Tesla motors brushless?Today, all the hybrids are powered by DC brushless drives, with no exceptions. The only notable uses of induction drives have been the General Motors EV-1; the AC Propulsion vehicles, including the tzero; and the Tesla Roadster. Both DC brushless and induction drives use motors having similar stators.

Introduction Radio Frequency Identification (RFID) is a type of automatic identification technology that uses radio frequency to carry out wireless non-contact two-way data communication, with recording media (electronic tags or radio frequency cards) to read and write. The purpose is identifying the target and making data exchange. This is an extremely complex system, so it involves many parameters. Next, we will introduce several important parameters in detail. What is RFID? How RFID works? Catalog Introduction Ⅰ RFID Parameters Explained 1.1 Rx Sensitivity 1.2 SNR (Signal-to-Noise Ratio) 1.3 Tx Power 1.4 ACLR/ACPR 1.5 Modulation Spectrum/Switching Spectrum 1.6 SEM (Spectrum Emission Mask) 1.7 EVM (Error Vector Magnitude) 1.8 Interference Indicators 1.9 Dynamic Range, Temperature Compensation and Power Control Ⅱ FAQ Ⅰ RFID Parameters Explained Radio frequency identification involves many settings, that is, parameter selections. What are they? Here gives you the detailed descriptions as following mentioned. 1.1 Rx Sensitivity Receiving sensitivity is one of the most basic concepts, characterizes the lowest signal strength that the receiver can recognize without exceeding a certain bit error rate (BER), which is a general term that follows the definition of the circuit switched (CS) era. In most cases, BER or  Packet Error Rate (PER) will be used to examine the sensitivity. In the Long Term Evolution (LTE) era,  use throughput to define simply. LTE does not have a circuit-switched voice channel, but this is also a real evolution. Because for the first time we no longer use "standardization" such as 12.2kbps RMC (voice coding at 12.2kbps) to measure sensitivity, but the throughput that users can really feel.   1.2 SNR (Signal-to-Noise Ratio) When talking about sensitivity, we often refer to SNR (signal-to-noise ratio), we generally talk about the demodulation SNR of the receiver. We define it as the ability of the demodulator to not exceed a certain bit error rate, that is, SNR threshold for demodulation.So where do S and N come from? S means Signal, or useful signal; N means Noise. The useful signal is generally emitted by the communication system transmitter, and the source of noise is very wide. The most typical one is the famous -174dBm/Hz (natural noise). It is a quantity that has nothing to do with the type of communication system. In a sense, it is actually a noise power density related to temperature. In addition, how much bandwidth do we receive determine the noise, that is, the final noise power is integrated on the bandwidth by the noise power density. 1.3 Tx Power The importance of the transmission power is that the signal from the transmitter needs to pass through the fading of space to reach the receiver. So the higher the transmission power means the longer the communication distance.So should we consider SNR for our transmitted signal? For example, if the SNR of our transmitted signal is very poor, do we receive the same bad?This involves the concept just mentioned, the natural noise we assume that spatial fading has the same effect on both signal and noise (in fact, it is not, the signal can resist fading through coding but noise not) and it acts like an attenuator. For example, we assume spatial fading is -200dB, the transmitted signal bandwidth is 1Hz, the power is 50dBm, and the SNR is 50dB, then what is the SNR received by the receiver?The power of the signal received by the receiver is 50-200=-150Bm (bandwidth 1Hz), and the noise of the transmitter 50-50=0dBm through spatial fading, and the power reaching the receiver is 0-200=-200dBm (bandwidth 1Hz)? At this time, this part of the noise has already been "submerged" under the natural noise -174dBm/Hz. At this time, we only need to consider the "basic component" of -174dBm/Hz to calculate the noise to the receiver. Actually, this is applicable in most cases of communication systems.   1.4 ACLR/ACPR These parameters are explained together because they actually represent part of the "transmitter noise", but these noises are not in the transmitting channel, but the part that the transmitter leaks into the adjacent channels, which can be collectively referred to as "Leakage in the adjacent channel".ACLR and ACPR (actually one thing, but one is called in the terminal test, the other is called in the base station test), both are named after "Adjacent Channel". They both describe the machine pair interference from other equipment. And their power calculation of the interference signal is also based on a channel bandwidth. This measurement method considers the signal leaked by the transmitter and the interference to the equipment receiver of the same or similar standard-the interference signal falls into the receiver band with the same frequency and the same bandwidth. That is, form the same frequency interference to the signal received by the receiver.In LTE, the ACLR test has two settings: EUTRA and UTRA. The former describes the interference among the LTE systems, and the latter considers the interference of the LTE system to the UMTS system. So we can see that the measurement bandwidth of EUTRAACLR is the occupied bandwidth of LTE RB, and the measurement bandwidth of UTRA ACLR is the occupied bandwidth of UMTS signals (FDD system 3.84MHz, TDD system 1.28MHz). In other words, ACLR/ACPR describes a kind of "peer-to-peer" interference: the leakage of the transmitted signal interferes with the same or similar communication system.This definition is significant. For example, in the actual network, there are often signal leakage from neighboring cells from other or in the same region. In other words, the adjacent channel leakage of the system itself is typical for neighboring cells. Therefore, the process of network planning and optimization is actually the process of capacity maximization and interference minimization. In addition, from the other side of the system, the mobile phones of users in crowded people may also become a source of mutual interference.Similarly, in the evolution of communication systems, the goal has always been to "smooth transition", that is, to upgrade and transform existing networks into next-generation networks. Therefore, the coexistence of two or even three generations of systems should consider the interference between different systems. So the introduction of UTRA in LTE is to consider the radio frequency interference to the previous generation system UMTS.   1.5 Modulation Spectrum/Switching Spectrum In the GSM system, Modulation Spectrum and Switching Spectrum also play a similar role to adjacent channel leakage. The difference is that their measurement bandwidth is not the occupied bandwidth of the GSM signal. From a definition point of view, it can be considered that the modulation spectrum is a measure of the interference between synchronous systems, and the switching spectrum is a measure of the interference between asynchronous systems. In fact, if the signal is not gating, the switching spectrum will definitely cover the modulation spectrum.This involves another concept: in the GSM system, the cells are not synchronized, although it uses TDMA. In contrast, TD-SCDMA and later TD-LTE, the cells are synchronized.Because the cells are not synchronized, the power leakage of the rising edge/falling edge of the A cell may fall to the payload part of the B cell, so we use the handover spectrum to measure the interference of the transmitter to the adjacent channel in this state. And in the entire 577us GSM timeslot, the proportion of rising edge/falling edge is very small after all. What’s more, most of the time, the payload of two adjacent cells will overlap in time. In this case, the interference of the transmitter to the adjacent channel can be evaluated by referring to the modulation spectrum. Figure 1. RFID Chip 1.6 SEM (Spectrum Emission Mask) SEM is an in-band indicator, which is distinguished from spurious emission. The latter includes SEM, but the focus is on the spectrum leakage outside the working frequency band of the transmitter. In addition, its introduction is more based on the perspective of EMC (Electromagnetic Compatibility).SEM provides a spectrum template. When measuring the spectrum leakage in the transmitter band, see if there are any points that exceed the template limit. It can be said that it is related to ACLR, but it is not the same. ACLR considers the average power leaked into the adjacent channel, so it uses the channel bandwidth as the measurement bandwidth, and it reflects the "critical noise point" of the transmitter in the adjacent channel. Where SEM reflects the capture of over-standard points in adjacent frequency bands with a smaller measurement bandwidth (usually 100kHz to 1MHz), which reflects the noise-based spurious emission.If you scan the SEM with a spectrum analyzer, you can see that the spurious points on the adjacent channel will generally be larger than the ACLR average. Therefore, if the ACLR indicator itself has no margin, the SEM will easily exceed it. On the other hand, if the SEM exceeds the ACLR, it does not necessarily mean bad. For example, a common phenomenon is that there is LO spurious or a certain clock and LO modulation component (often very narrow bandwidth, similar to dot frequency) in the transmitter link, although ACLR is good, the SEM may exceed the standard.   1.7 EVM (Error Vector Magnitude) EVM is a vector, which means it has amplitude and angle. It measures the error between the actual signal and the ideal signal. This measurement can effectively express the "quality" of the transmitted signal. That is, the farther the point distance of the actual signal to the ideal signal, the greater the error and the greater the modulus of the EVM.Why is the SNR of the transmitted signal not so important? There are two reasons: the first is that it is often much higher than the SNR required for demodulation of the receiver. The second is the condition, that is, the worst case. The transmitter noise has already been submerged under the natural noise after a large spatial fading, and the useful signal is also attenuated to near the demodulation threshold of the receiver.But the "intrinsic SNR" of the transmitter needs to be considered in some cases, such as short-range wireless communication. Even without considering the spatial fading, demodulation of such high-order quadrature modulated signals alone already requires a high SNR. The worse the EVM, the worse the SNR and the higher the difficulty of demodulation. Engineers working on 802.11 systems often use EVM to measure Tx linearity. While engineers working on 3GPP systems, they like to use ACLR/ACPR/Spectrum to measure it.From the origin, 3GPP is the evolutionary path of cellular communication, and from the very beginning it has to pay attention to adjacent channel and alternative channel interference. In other words, interference is the number one obstacle that affects cellular communication rates. Therefore, 3GPP always aims at "minimizing interference" during its evolution, such as frequency hopping in the GSM era, spread spectrum in the UMTS era, and the RB concept in LTE era.The 802.11 system is an evolution of fixed wireless access. It follows the spirit of the TCP/IP protocol and aims at "service first". In 802.11, there use often time division or frequency hopping methods to achieve multi-user coexistence. The network layout is more flexible, and the channel width is also flexible and variable. In general, it is not sensitive to interference (or rather high tolerance).In layman's terms, the origin of cellular communication is to make phone calls, and users who cannot get through the phone will go to the telecommunications; while the origin of 802.11 is the local area network, you just wait at first when the network is not good.So this determines that the 3GPP series must take ACLR/ACPR and other "spectrum regeneration" performance as indicators, while the 802.11 series can adapt to the network environment at the expense of speed.Specifically, "Adapt to the network environment at the expense of speed" means that in the 802.11 series, different modulation orders are used to cope with the propagation conditions. When the receiver finds a signal difference, it immediately informs the opposite transmitter to reduce the modulation order. As mentioned earlier, SNR and EVM in an 802.11 system are highly correlated. To a large extent, a reduction in EVM can improve SNR. In this way, we have two ways to improve the receiving performance: one is to reduce the modulation order, thereby reducing the demodulation threshold; the other is to reduce the transmitter EVM, so that the signal SNR is improved.Because EVM is closely related to the demodulation effect of the receiver, EVM is used to measure the performance of the transmitter in the 802.11 system (similarly, in 3GPP, ACPR/ACLR is the index that mainly affects the network performance). In addition, the deterioration of EVM is mainly caused by non-linearity (for example, AM-AM distortion of PA), so EVM is usually used as a sign to measure the linear performance of the transmitter. Figure 2. RFID 1.7.1 Relations of EVM to ACPR / ACLR It is difficult to define the quantitative relationship between EVM and ACPR/ACLR. From the non-linearity of the amplifier, EVM and ACPR/ACLR should be positively correlated. That is, the AM-AM and AM-PM distortion of the amplifier will amplify the EVM, and also the ACPR/ACLR.However, EVM and ACPR/ACLR are not always positively correlated. For example, Clipping is commonly used in digital IF. It is to reduce the peak-to-average ratio (PAR) of the transmitted signal. The reduction of peak power can help reduce the ACPR/ACLR after passing through the PA. However, clipping will also damage the EVM. Because whether it is clipping (windowing) or using a filter, they all cause damage to the signal waveform, affecting the EVM. 1.7.2 Source Flow of PAR PAR (Peak-to-Average Ratio) is usually represented by a statistical function such as CCDF, and its curve represents the power (amplitude) value of the signal and its corresponding probability of occurrence. For example, if the average power of a certain signal is 10dBm, the statistical probability that it has a power exceeding 15dBm is 0.01%, and we can consider its PAR is 5dB.PAR is an important factor affecting transmitter spectrum regeneration (such as ACLP/ACPR/Modulation Spectrum) in modern communication systems. The peak power will push the amplifier into the nonlinear region and produce distortion. And the higher the peak power, the stronger the nonlinearity.In the GSM era, because of the constant envelope characteristic of GMSK modulation, PAR is 0. When designing GSM power amplifiers, we often push it to P1dB to get the maximum efficiency. After the introduction of EDGE, 8PSK modulation is no longer a constant envelope, so we tend to push the average output power of the amplifier to about 3dB below P1dB, because the PAR of the 8PSK signal is 3.21dB.In the UMTS era, whether WCDMA or CDMA, the PAR is much larger than that of EDGE. The reason is the correlation of the signals in the code division multiple access system. In other words,  when the signals of multiple code channels are superimposed in the time domain, the same phase may occur, and the power will show a peak at this time.The PNR of LTE is derived from the burstiness of the RB. OFDM modulation is based on the principle of dividing multi-user/multi-service data into blocks in both the time domain and the frequency domain, so that high power may appear in a certain "time block". LTE uplink transmission uses SC-FDMA. First, DFT extends the time domain signal to the frequency domain, which is equivalent to "smoothing" the burstiness in the time domain, thereby reducing PAR. Figure 3. RFID Applications 1.8 Interference Indicators The "interference index" here refers to the sensitivity test under various applied interferences in addition to the static sensitivity of the receiver. In fact, it is very interesting to study the origin of these test items.Our common interference indicators include Blocking, Desense, Channel Selectivity, etc. 1.8.1 Blocking Blocking is actually a very old RF indicator, as early as the invention of radar. The principle is to pour a large signal into the receiver (usually the first LNA that suffers the most), making the amplifier enter the nonlinear region or even saturate. At this time, on the one hand, the amplifier gain suddenly becomes smaller, and on the other hand, extremely strong nonlinearity occurs, so the function of amplifying useful signals cannot work normally.Another possible Blocking is actually done through the receiver's AGC. Large signals enter the receiver link, and the receiver AGC will reduce the gain to ensure dynamic range, but the useful signal level entering the receiver is very low. At this time, the gain is insufficient, and the amplitude of the useful signal entering the demodulator is insufficient.Blocking indicators are divided into in-band and out-of-band, mainly because the RF front-end generally has a band filter, which has an inhibitory effect on out-of-band blocking. However, the blocking signal is generally point frequency without modulation. In fact, point-frequency signals without modulation at all are rare in practice. In engineering, it is approximately point-frequency to replace various narrow-band interference signals.For solving Blocking, the key is RF. In other words, it is to expand the dynamic range of receiver. For out-of-band blocking, the rejection of the filter is also very important. 1.8.2 AM Suppression AM Suppression is a unique indicator of the GSM system. From the description point of view, the interference signal is a TDMA signal similar to the GSM signal, synchronized with the useful signal and has delay.This scenario simulates the signal of the neighboring cell in the GSM system. From the point of view that the frequency offset of the interference signal is greater than 6MHz (GSM bandwidth is 200kHz), this is a very typical neighboring cell signal configuration. So we can think that AM suppression is a reflection of the receiver's interference tolerance to neighboring cells in the actual work of the GSM system.Adjacent (Alternative) Channel Suppression (Selectivity)Here we collectively refer to it as "adjacent channel suppression". In the cellular system, in addition to the same-frequency cells, we must also consider adjacent-frequency cells in our networking. The reason can be found in the transmitter index ACLR/ACPR/Modulation Spectrum that we discussed before. Because of the transmitter's spectrum regeneration, there will be strong signals falling into adjacent frequencies (generally, the farther the frequency offset, the lower the level, so the adjacent channel is generally the most affected), and this kind of spectrum regeneration is actually related to the transmitted signal. That is, receivers of the same standard are likely to mistake this part of the regenerated spectrum as a useful signal for demodulation.For example, if two neighboring cells A and B happen to be neighboring frequency cells (such networking methods are generally avoided, here is just a assumption), when a terminal registered in cell A swims to the campus junction of two, but the signal strength of the two cells has not reached the handover threshold, the terminal still maintains cell connection with A, and the ACPR of the B cell base station transmitter is higher. So the terminal’s receiving frequency band has a higher ACPR component of B cell, which overlaps with the useful signal of cell A in frequency. Because the terminal is far away from the base station of cell A at this time, the received signal is weak. At this time, when the ACPR component of cell B enters the terminal receiver, it causes co-channel interference to the original useful signal.If we pay attention to the definition of the frequency offset of the adjacent channel selectivity, we will find that there is a difference between Adjacent and Alternative, which corresponds to the first and second adjacent channels of ACLR/ACPR. It can be seen that the "transmitter spectrum leakage (regeneration)" in the communication protocol and the "receiver adjacent channel selectivity" are actually defined in pairs. 1.8.3 Co-Channel Suppression (Selectivity) Co-frequency interference generally refers to the interference pattern between two cells.According to the networking principles we described earlier, the distance between two cells with the same frequency should be as far as possible. In addition, even if they are farther away, there will be signals leaking to each other, but the difference is in intensity. For the terminal, the signals of the two campuses can be regarded as "correct and useful signals" (of course, there is a set of access specifications on the protocol layer to prevent such false access). Frequency strength of both depends on its co-frequency selectivity. 1.8.4 Summery Blocking is big signal interferes with small signal, but the AM Suppression is small signal interferes with large signal.Single-tone Desense is a unique indicator of the CDMA system. It has a feature: the single-tone is an in-band signal and is very close to the useful signal. In this way, it is possible to generate two kinds of signals falling into the receiving frequency domain: First is due to near-end phase noise of the LO, the baseband signal formed by the mixing of the LO and the useful signal, and the signal formed by the mixing of the LO phase noise and the interference signal. Both will fall within the range of the receiver baseband filter, the former is a useful signal and the latter is interference. Second is due to the nonlinearity in the receiver system. The useful signal (with a certain bandwidth, such as 1.2288MHz CDMA signal) may produce intermodulation with the interference signal on the nonlinear device, falling in the receiving frequency domain and becoming interference.The origin of single-tone desense is that the CDMA system uses the same frequency band as the original analog communication system AMPS, and the two networks coexisted for a long time. So the CDMA system must consider the AMPS system's interference to itself.The explanation of Blocking in theory: the large signal entering the receiver causes the amplifier to enter the nonlinear region, and the actual gain becomes smaller (for useful signals).But it is difficult to explain two scenarios:Scenario 1: The pre-stage LNA has a linear gain of 18dB. When a large signal is injected to make it reach P1dB, the gain is 17dB. If no other influence is introduced (the default LNA NF, etc. have not changed), then the noise figure of the entire system is actually very limited. It is nothing more than the fact that the denominator of the latter-stage NF becomes a little smaller when it is included in the total NF, which has little effect on the sensitivity of the entire system.Scenario 2: The IIP3 of the previous LNA is very high, so it is not affected. The second level gain block is affected (the interference signal makes it reach near P1dB). In this case, the impact of the entire system NF is even smaller.Here is a point of view: the influence of Blocking may be divided into two parts. One part is that the gain mentioned in the textbook is compressed, and the other part is actually that after the amplifier enters the nonlinear region, the useful signal is distorted in this region. This kind of distortion may include two parts, one part is the spectrum regeneration (harmonic component) of the useful signal caused by pure amplifier nonlinearity, and the other part is the Cross Modulation of the large signal modulating the small signal.From this we also put forward another idea: if we want to simplify the Blocking test (3GPP requires frequency sweeping, which is very time-consuming), we may be able to select certain frequency points, which have the greatest impact on useful signal distortion when the Blocking signal appears.From an intuitive point of view, these frequency points may have: f0/N and f0*N (f0 is the useful signal frequency, and N is a natural number). The former is because the N-th harmonic component generated by the large signal in the nonlinear region is just superimposed on the useful signal frequency f0 to form direct interference, and the latter is superimposed on the N-th harmonic of the useful signal f0 and affects the output signal f0.According to Pascal's law, the waveform of the time domain signal is actually the sum of the domain fundamental frequency signal and each harmonic. When the power of the Nth harmonic in the frequency domain changes, the corresponding in the domain is the envelope change of the time domain signal (have distortion). Figure 4. RFID Readers   1.9 Dynamic Range, Temperature Compensation and Power Control These three indicators will only be shown when certain extreme tests are performed, but they themselves represent the most significant part of RF design. 1.9.1 Dynamic Range of the Transmitter The dynamic range of the transmitter characterizes the maximum and minimum transmission power without damaging other transmission indicators. This concept is very broad. If you look at the main effects, you can understand that the linearity of the transmitter is not compromised at the maximum transmission power, and the SNR of output signal is maintained at the minimum transmission power.Under the maximum transmit power, the output is often close to the nonlinear region of active devices at all levels (especially the final amplifier), and the nonlinearity that often occurs is spectral leakage and regeneration (ACLR/ACPR/SEM), modulation error (PhaseError/EVM). The most susceptible at this time is basically the linearity of the transmitter.Under the minimum transmit power, the useful signal output by the transmitter is close to the natural noise of the transmitter, and may even be submerged in the transmitter noise. At this time, what needs to be guaranteed is the SNR of the output signal. In other words, the lower the transmitter noise at the minimum transmit power, the better. 1.9.2 Dynamic Range of the Receiver The dynamic range of the receiver is actually related to the two indicators we talked about before, the first is the reference sensitivity, and the second is the receiver IIP3 (interference indicator).The reference sensitivity actually characterizes the minimum signal strength that the receiver can recognize. We mainly talk about the maximum receiving level of the receiver.It refers to the maximum signal that the receiver can receive without distortion. This distortion may occur at any stage of the receiver, from the previous LNA to the receiver ADC. For the front-level LNA, the only thing we can do is to increase IIP3 as much as possible so that it can withstand higher input power. For the subsequent step-by-step devices, the receiver uses AGC (automatic gain control) to ensure that the useful signal falls on the device within the input dynamic range. Simply put, there is a negative feedback loop: detect the received signal strength (too low/too high)-adjust the amplifier gain (up/down)-the amplifier output signal to ensure that it falls within the input dynamic range of the next stage device.Here we talk about an exception: the front-end LNA of most mobile phone receivers has AGC function. If you study their datasheet carefully, you will find that the front-end LNA provides several variable gain sections, and each gain section has its corresponding noise factor. Generally speaking, the higher the gain, the lower the noise factor. This is a simplified design. The design goal of the receiver RF link is to keep the useful signal input to the receiver ADC within the dynamic range and keep the SNR higher than the demodulation threshold (the SNR is not critical,  but "just enough"). Therefore, when the input signal is large, the front-stage LNA reduces gain, loss NF, and increases IIP3 at the same time. When the input signal is small, the front-stage LNA increases gain, reduces NF, and meanwhile reduces IIP3. Figure 5. RFID Discover 1.9.3 Temperature Compensation Generally speaking, we only have temperature compensation in the transmitter. Of course, the receiver performance is also affected by temperature. On the one hand, the receiver link gain decreases at high temperatures, and NF increases. On the other hand, at low temperatures, receiver link gain increases, and NF decreases. However, due to the small signal characteristics of the receiver, both gain and NF are within the range of system redundancy.It can also be subdivided into two parts: one part is the compensation for the power accuracy of the transmitted signal, and the other part is the compensation for the change in the transmitter gain with temperature.Transmitters of modern communication systems generally perform closed-loop power control (except for the slightly "old" GSM system and Bluetooth system). Therefore, the power accuracy of transmitters calibrated through production procedures actually depends on the accuracy of the power control loop. Generally speaking, the power control loop is a small signal loop, and the temperature stability is very high, so the demand for temperature compensation is not high, unless there are temperature-sensitive devices (such as amplifiers) on the power control loop.Temperature compensation for transmitter gain is more common, which has two common purposes:One is "visible", usually for systems without closed-loop power control (such as the aforementioned GSM and Bluetooth), this type of system usually does not require high output power accuracy, so the system can apply a temperature compensation curve (function) to keep the RF link gain within an interval. So that when the baseband IQ power is fixed and the temperature changes, the RF power output by the system can also be kept within a certain range.The other is "invisible", usually in a system with closed-loop power control. Although the RF output power of the antenna port is precisely controlled by the closed-loop power control, we need to keep the DAC output signal within a certain range (A common example is the need for digital predistortion (DPD) of the base station transmission system), then we need to control the gain of the entire RF link more accurately around a certain value.In the early stage of low accuracy and low cost accuracy requirements, temperature compensation attenuators are more common. Require higher accuracy requirements, the solution generally: temperature sensor + digital attenuator/amplifier + production calibration. 1.9.4 Power Control of the Receiver After talking about dynamic range and temperature compensation, let's talk about a related and very important index: power control.Transmitter power control is a necessary function in most communication systems. Commonly used in 3GPP, such as ILPC, OLPC, and CLPC. In addition, it must be tested in RF design.All transmitter power control purposes include two points: power consumption control and interference suppression.Let’s first talk about power consumption control: In mobile communications, in view of the changes in the distance between the two ends and the different levels of interference, for the transmitter, it is only necessary to maintain the signal strength enough for the receiver of the other party to demodulate accurately. If it is low, the communication quality is impaired, and if it is too high, the empty power consumption is meaningless. This is especially true for battery-powered terminals like mobile phones.Interference suppression is a more advanced requirement. In CDMA-type systems, because different users share the same carrier frequency (differentiated by orthogonal user codes), in the signal arriving at the receiver, user's signal is covered by the same frequency for other users. If the signal power of each user is high or low, the high-power user will drown out the low-power user’s signal. Therefore, the CDMA system adopts a power control method to control the power of different users reaching the receiver, and sends a power control command to each terminal to make the air interface power of each user the same. This kind of power control has two characteristics: the first is that the power control accuracy is very high (the interference tolerance is very low), and the second is that the power control cycle is very short (the channel may change quickly).In the LTE system, uplink power control also has the effect of interference suppression. Because LTE uplink is SC-FDMA, and multiple users also share carrier frequencies, which also interfere with each other, so the same air interface power.The GSM system also has power control. In GSM, we use power level to characterize the power control step length, each level is 1dB. It can be seen that GSM power control is relatively rough.Interference Limited SystemHere is a related concept: interference limited system. The CDMA system is a typical interference limited system. In theory, if each user code is completely orthogonal and can be completely distinguished by interleaving and de-interleaving, then the capacity of the CDMA system can be infinite. Because it can be used on limited frequency resources. The user code extended layer by layer distinguishes an infinite number of users. But in fact, since the user codes cannot be completely orthogonal, noise is inevitably introduced during multi-user signal demodulation. The more users there are, the higher the noise will be, until the noise exceeds the demodulation threshold. In other words, the capacity of the CDMA system is limited by interference (noise).The GSM system is not an interference limited system, but a time-domain and frequency-domain limited system. Its capacity is limited by frequency (a carrier frequency of 200kHz) and time domain resources (8 TDMAs can be shared on each carrier frequency user). Therefore, the power control requirements of the GSM system are not strict. 1.9.5 Transmitter Power Control and Transmitter RF Indicators Next, let's discuss the factors that may affect the transmitter power control in the RF design.For RF, if the power detection (feedback) loop design is correct, then we can do not much for the transmitter closed-loop power control (most of the work is done by the physical layer protocol algorithm), and the most important thing is the flatness in the transmitter band.Because the transmitter calibration can only be carried out on a limited number of frequency points, especially in the production test, the less frequency points the better. However, it is entirely possible for the transmitter to work on any carrier in the frequency band in practice. In a typical production calibration, we will calibrate the transmitter's frequency points to keep accuracy. So the closed-loop power control is correct at the calibrated frequency points. However, if the transmit power is not flat in the entire frequency band, some frequency points deviates greatly from the calibration frequency point. Therefore, the closed-loop power control with the calibration frequency point as a reference will have errors and even mistakes.   Ⅱ FAQ 1. What is RFID and how it works?RFID tags transmit data about an item through radio waves to the antenna/reader combination. ... The energy activates the chip, which modulates the energy with the desired information, and then transmits a signal back toward the antenna/reader. 2. What is RFID used for?RFID tags are a type of tracking system that uses radio frequency to search, identify, track, and communicate with items and people. Essentially, RFID tags are smart labels that can store a range of information from serial numbers, to a short description, and even pages of data. 3. Is RFID harmful to human?Electromagnetic fields generated by RFID devices—touted as a patient-safety technique to keep track of supplies, medical tests and samples, and people—could cause medical equipment to malfunction, according to a recent study of medical devices in Amsterdam published in the June 25 Journal of the American Medical. 4. What is RFID example?For example, an RFID tag attached to an automobile during production can be used to track its progress through the assembly line, RFID-tagged pharmaceuticals can be tracked through warehouses, and implanting RFID microchips in livestock and pets enables positive identification of animals. 5. What are the components of RFID?Every RFID system consists of three components: a scanning antenna, a transceiver and a transponder. When the scanning antenna and transceiver are combined, they are referred to as an RFID reader or interrogator. 6. Who discovered RFID?Charles WaltonRFID was, however, officially invented in 1983 by Charles Walton when he filed the first patent with the word 'RFID'. NFC started making the headlines in 2002 and has since then continued to develop. 7. How is RFID made?The antenna can be made of etched copper, aluminum or conductive ink, while the chip and antenna are typically put on a substrate that is PET or paper. ... Usually, this inlay is inserted into a printable label to create an RFID transponder that can be affixed to a product. 8. Where did RFID come from?The First RFID PatentsMario W. Cardullo claims to have received the first U.S. patent for an active RFID tag with rewritable memory on January 23, 1973. That same year, Charles Walton, a California entrepreneur, received a patent for a passive transponder used to unlock a door without a key. 9. What is a RFID system?Radio Frequency Identification (RFID) refers to a wireless system comprised of two components: tags and readers. ... Passive RFID tags are powered by the reader and do not have a battery. Active RFID tags are powered by batteries. RFID tags can store a range of information from one serial number to several pages of data. 10. What are the three parameters that define an RFID system?Every RFID system consists of three components: a scanning antenna, a transceiver and a transponder. When the scanning antenna and transceiver are combined, they are referred to as an RFID reader or interrogator. 11. What are the basic criteria in RFID?Many large organizations and government agencies have mandated that their suppliers provide goods with RFID tags. These published mandates may specify tag type, frequency, amount of memory, read range, read rate and speed, and protocol. In addition, the mandates may specify how the goods should be tagged. 12. What is the maximum read range of RFID module?Maximum read distance of 1.5 meters (4 foot 11 inches) - usually under 1 meter (3 feet) and you can use a single or multi port reader plus custom antennas to extend the read range to longer tag read distances or a wider RFID read zone. 13. What is RFID in supply chain management?+RFID (Radio Frequency Identification) is a form of extremely low-power data communication between a RFID scanner and an RFID tag. ... The tags are placed on any number of items, ranging from individual parts to shipping labels. 14. How many bits does an RFID tag have?It depends on the vendor, the application and type of tag, but typically a tag carries no more than 2 kilobytes (KB) of data—enough to store some basic information about the item it is on. Simple “license plate” tags contain only a 96-bit or 128-bit serial number. 15. Does RFID reader store data?An RFID tag can store large amounts of data additionally to a unique identifier • Unique item identification is easier to implement with RFID than with barcodes. • Its ability to identify items individually rather than generically.

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. 

ⅠIntroduction A diode is a semiconductor device that functions as a one-way current switch. It allows current to flow freely in one direction while severely limiting current flow in the opposite direction. Because they convert alternating current (ac) to pulsating direct current (dc), diodes are also known as rectifiers (dc). Diodes are classified based on their type, voltage, and current capacity. Diodes have polarity, which is determined by an anode (positive lead) and a cathode (negative lead) (negative lead). Catalog ⅠIntroduction Ⅱ Diode Related Video: Ⅲ How to Tell Which Way Round a Diode Should Be? 3.1 Examining the Markings 3.2 USing a Multimeter Ⅳ How to Check the Direction of a Diode? Ⅴ How to Check if a Diode Is Bad? Ⅵ How to Test a Diode Rectifier? Ⅶ How to Test Diodes with a Digital Multimeter？ 7.1 Diode Test Analysis Ⅷ FAQ     Ⅱ Diode Related Video: Diodes Explained - The basics how diodes work working principle pn junction Diode Video Description: Diodes Explained, in this tutorial we look at how diodes work, where diodes are used, why diodes are used, the different types. We look at diodes in half and full bridge rectifiers to convert AC to DC.   Ⅲ How to Tell Which Way Round a Diode Should Be? A diode is a two-terminal electronic device that conducts current in one direction while blocking current in the other. A diode, also known as a rectifier, is a device that converts alternating current (AC) to direct current (DC). Because diodes are essentially "one-way," it's critical to understand how to tell which end is which. You can usually tell by looking at the markings on the diode, but if they've worn off or don't exist, you can test the diode with a multimeter. 3.1 Examining the Markings     Figure1: P-type   Understand how a diode works. An N-type semiconductor is joined to a P-type semiconductor to form a diode. The N-type semiconductor serves as the negative end of the diode and is referred to as the "cathode." The P-type semiconductor, also known as the "anode," is the diode's positive end. The diode will conduct current if the positive side of a voltage source is connected to the positive end of the diode (the anode) and the negative side is connected to the negative end of the diode (the cathode). The current is blocked if the diode is reversed (up to a limit).   Figure2: schematic symbol   Discover the meaning of the diode schematic symbol. On schematics, diodes are represented by a symbol that explains how to install the diode. An arrow points to a vertical bar with a line extending from it. The arrow represents the diode's positive side, while the vertical bar represents its negative side. Consider the positive side flowing into the negative side, with the arrow indicating the flow direction.   Figure3: large band   Seek out the large band. If the schematic symbol is not printed on it, look for other items such as a ring, band, or line. A bulk of colored bands will be printed near the diode's negative side (cathode) on the majority of diodes. The band will wrap completely around the diode.   Figure4: Recognize the positive end of an LED Recognize the positive end of an LED. An LED is a light-emitting diode, and the legs usually indicate which side is positive. The positive, anode pin is on the longer leg. Examine the LED's outer casing if the pins have been trimmed. The negative, cathode pin is the one closest to the flat edge.     3.2 USing a Multimeter Figure5: Recognize the positive end of an LED Recognize the positive end of an LED. An LED is a light-emitting diode, and the legs usually indicate which side is positive. The positive, anode pin is on the longer leg. Examine the LED's outer casing if the pins have been trimmed. The negative, cathode pin is the one closest to the flat edge.   Figure6: Connect the diode   Connect the diode to the multimeter. Connect the positive lead to the diode's positive end and the negative lead to the diode's negative end. The meter's display should show a reading. If your meter has a Diode mode, the voltage will be displayed on the meter if it is connected positively to positive and negatively to negative. Nothing will be displayed if it is entered incorrectly. If your meter does not have a Diode mode, connecting it positive-to-positive and negative-to-negative will result in very low resistance. If you go the wrong way, you'll encounter a lot of resistance, which is sometimes expressed as "OL."   Figure7: Examine an LED Examine an LED. A light-emitting diode (LED) is a semiconductor that emits light. Set the multimeter to the diode function. Place one of the positive leads on one of the pins and the other on the other. If the LED illuminates, the positive lead is in contact with the positive pin (the anode) and the negative lead is in contact with the negative pin (the cathode). If it doesn't light up, it's because the leads are touching opposite pins.   Ⅳ How to Check the Direction of a Diode? Electronic circuits are designed to collaborate with other circuits to form a unit that performs a specific task. Many circuits, such as power regulation circuits, have to be safeguarded against power "spikes" and accidental polarity reversal. A diode is an electronic component that allows electricity to flow in only one direction while preventing potentially harmful reversals from reaching the sensitive circuit. The current flows into the diode's "cathode" (negative side) and then out the "anode" (positive side) toward the protected circuit. When installing a diode, you must be familiar with electronics standards. Understand the circuit's schematic diagram. Trace the electrical polarity as it passes through the circuit until it reaches the point where the cathode (negative side) of the diode is to be soldered to the board. In a schematic, a diode glyph has a vertical line on one side and a solid black arrow pointing to that line. The diode's cathode is represented by the vertical line. That end of the diode must face the direction of the negative current flow. Examine your diode thoroughly, using a magnifying glass if necessary. On the cathode (negative) end of every diode, there is either a colored dot or a band printed. On the cathode end of a black plastic diode, a white band will be painted, whereas glass diodes will have either a white or a black band. In the absence of polarity markings, use a digital multimeter to test the polarity of a diode. To measure "Ohms," simply turn the meter unit on and turn the dial. Connect the black (negative) test probe to one of the diode's metal legs and the red (positive) test probe to the other. Reverse the probes if there is no reading or only a "1" displayed on the meter. When you get an actual ohm reading on the display, make a note of which side the negative (black) probe is on. That is the diode's cathode (negative) side.   Tips: The small white band on the cathode side of a glass diode may be difficult to see. To make the white band move visible, place the glass diode on a dark piece of paper or fabric if necessary.On some types of diodes, the band colors can vary, but never the positioning. A diode's band is always on the cathode side. The color of the band is unimportant.Additional bands on some specialty diodes, such as Zener diodes, represent tolerance and voltage values. Even so, the polarity band is the first band at the end.   Ⅴ How to Check if a Diode Is Bad? Tools Digital multimeterSoldering ironDesoldering braidPliers     Ⅵ How to Test a Diode Rectifier? Testing a Rectifier With the Diode Function If your multimeter has a diode function, one of the dial settings will have a symbol that looks like a diode. When this option is selected, a voltage exists between the meter leads, and when you touch them to the diode terminals, the meter records the voltage drop. The voltage drop in the forward direction is usually in the range of 0.5 to 0.8 volts. Because no current flows in the opposite direction, the meter either reads 0 or OL, which stands for open loop. To begin the test, ensure that the circuit is unplugged and that all capacitors in the circuit have been discharged. You do not need to remove the diode from the circuit if you do this. Begin by connecting the negative meter lead (usually black) to the cathode of the diode and the positive lead (red) to the anode. Keep a close eye on the meter reading, which should be between 0.5 and 0.8 volts. If it's close to zero, the diode is faulty. Reverse the leads now. If you get a reading of 0 or OL, the diode is fine. If you get nearly the same voltage reading, the diode has shorted and is no longer operational.   Conducting a Diode Test With an Ohmmeter When performing a resistance test, the diode must be removed from the circuit. Before you begin, turn off the power and discharge any capacitors in the circuit. This is especially important when testing a microwave diode because the microwave's high voltage capacitor can cause a severe shock. Set the multimeter to measure resistance () and connect the black (negative) and red (positive) leads to the cathode and anode, respectively. The diode is forward-biased in this configuration, and you should get a resistance reading between 1 K and 10 M. Change the leads to the opposite terminals. Now that the diode has been reverse-biased, the reading should be infinity or OL. If the readings in both directions are the same, the diode is faulty.   Ⅶ How to Test Diodes with a Digital Multimeter？ Figure8: Diode Test mode The Diode Test mode on a multimeter generates a low voltage between the test leads. When the test leads are connected across a forward-biased diode, the multimeter displays the voltage drop. The Diode Test is carried out as follows: Ascertain that a) all power to the circuit is turned off and b) there is no voltage at the diode. Voltage may exist in the circuit as a result of charged capacitors. If this is the case, the capacitors must be discharged. Set the multimeter to measure alternating current or direct current voltage as needed.Set the dial (rotary switch) to Diode Test. It may share a dial position with another function.Connect the diode's test leads. Take note of the displayed measurement.The test leads should be reversed. Take note of the displayed measurement.   7.1 Diode Test Analysis For the most commonly used silicon diodes, a good forward-based diode has a voltage drop of 0.5 to 0.8 volts. The voltage drop in some germanium diodes ranges from 0.2 to 0.3 V. When a good diode is reverse-biased, the multimeter displays OL. The OL value indicates that the diode is operating as an open switch. A faulty (opened) diode prevents current from flowing in either direction. When the diode is opened, a multimeter will show OL in both directions. In both directions, a shorted diode has the same voltage drop reading (approximately 0.4 V). Figure9: Diode test analysis When the positive (red) test lead is on the anode and the negative (black) test lead is on the cathode, the diode is forward biased. A good diode's forward-biased resistance should be between 1000 and 10 M. When the diode is forward-biased, the resistance measurement is high because the current from the multimeter flows through the diode, resulting in the high-resistance measurement required for testing. When the positive (red) test lead is on the cathode and the negative (black) test lead is on the anode, the diode is reverse-biased. On a multimeter, the reverse-biased resistance of a good diode displays OL. If the readings in both directions are the same, the diode is faulty. Figure10: resistance   The resistance mode procedure is conducted as follows: Ascertain that a) all power to the circuit is turned off and b) there is no voltage at the diode. Voltage may exist in the circuit as a result of charged capacitors. If this is the case, the capacitors must be discharged. Set the multimeter to measure alternating current or direct current voltage as needed.Set the dial to Resistance (). It may share a dial position with another function.After the diode has been removed from the circuit, connect the test leads to it. Take note of the displayed measurement.The test leads should be reversed. Take note of the displayed measurement.When testing diodes in the Resistance mode, compare the readings to a known good diode for the best results.   Ⅷ FAQ 1. What are the 3 main uses of diodes? Application of Diode Rectifying a voltage: turning AC into DC voltages.Drawing signals from a supply.Controlling the size of a signal.Mixing (multiplexing) signals.As freewheeling of the inductive energy. 2. Are diodes AC or DC? It allows current to flow easily in one direction, but severely restricts current from flowing in the opposite direction. Diodes are also known as rectifiers because they change alternating current (ac) into pulsating direct current (dc). 3. What is diode made of? Today, most diodes are made of silicon, but other semiconducting materials such as gallium arsenide and germanium are also used. 4. What is diode resistant? Hence, diode resistance can be defined as the effective opposition offered by the diode to the flow of current through it. ... Ideally speaking, a diode is expected to offer zero resistance when forward biased and infinite resistance when reverse biased. 5. How diodes are formed? A diode is formed by joining two equivalently doped P-Type and N-Type semiconductor. ... At the point of contact of the P-Type and N-Type regions, the holes in the P-Type attract electrons in the N-Type material. Hence the electron diffuses and occupies the holes in the P-Type material.

IntroductionIn the era of smart phones, there are two ways to extend battery life, one is to directly use a large-capacity battery, and another is to use quick charge technology. Using large-capacity batteries is a easy way but with bulky piece of phones. Here let’s talk about the quick charge. How can you make the phone charge faster?How Does Fast Charging Work?CatalogIntroductionⅠ Quick Charge FactorsⅡ Battery Charging Basics2.1 Charging Heat2.2 Charging PowerⅢ Quick Charge Development3.1 USB Battery Charge 1.23.2 Qualcomm Quick Charge3.3 OPPO VOOC Charge3.4 Pump Express (PE)3.5 OnePlus Dash Charge3.6 Huawei SuperCharge3.7 Low Voltage Solution3.8 Quick Charge AgreementⅣ FAQ Ⅰ Quick Charge FactorsTo realize the quick charging function on the mobile phone, three elements need to be met: Charger, Battery, Charge IC. Adding a point, the charger needs to meet sufficient output current and voltage, because the wiring of the charger has a large parasitic resistance. If requiring a larger charging current, the on-load output voltage of the charger needs to be higher.Quick charge tech of smartphones is mainly divided into three categories: VOOC flash charge, Qualcomm Quick Charge 2.0, and MediaTek Pump Express Plus.At present, the mainstream modes of quick charge on the market include three modes: High voltage and constant currentLow voltage and high currentHigh voltage and high currentFigure 1. Fast ChargingⅡ Battery Charging Basics2.1 Charging HeatHow does the battery charge and solve the heat?Figure 2. Heating Up While ChargingThe basic condition for battery charging is that the charger voltage must be higher than the battery voltage to generate a charging current and complete the charge transfer process. At present, most of the batteries of mobile phones are composed of single lithium or multiple lithium. Generally, the working voltage of mobile phone batteries is about 3.3V~4.2V. During discharge, the voltage will drop, so the average voltage is about 3.7V-3.8V.When charging, the electric energy enters the mobile phone and is processed by the step-down circuit in the mobile phone, and then outputs a voltage of about 3.3~4.5V to charge the battery. And this voltage drop process is responsible for the charge management IC module in the mobile phone. It is responsible for converting the current output by the power supply into a current through the battery. In this process, there will be a certain loss, which will be transferred out of heat.2.2 Charging PowerIn the case of a certain battery level, power indicates the charging speed, the higher the power, the faster the charging speed.Power (P) = voltage (V) x current (I)In theory, increasing the current and voltage can higher the charging power of the battery, but lithium batteries are prone to battery damage or deflagration due to undervoltage or overvoltage. Thus mobile phones must be equipped with a complete power circuit. Among them, the charging control IC and the power control IC are the most important. Ⅲ Quick Charge DevelopmentAccording to theory, quick charge adjust the input value of the voltage and current, thereby shorten the charging time of the mobile phone. Next, let us take a look at the development history of it.The charging standard of mobile phones can be traced back to the era of feature phones, which can be started from the charging standard USB BC 1.2 (BC is the abbreviation of Battery Charge).3.1 USB Battery Charge 1.2The USB specification was first introduced in 1995. It was developed by USB Implement Forum (USB IF), including Intel, NEC Corporation, Compaq, DEC (American Digital Equipment Corporation), IBM (International Business Machines Corporation), Microsoft, and Northern Telecom.The USB BC1.2 standard was published by the USB IF in 2010. It refers to the ability to directly charge the battery of a portable device, and has become a key standard for establishing the correct way to charge the battery through the USB port. So BC1.2 is a set of official standards that can use USB interface to charge portable devices like mobile phones (including power-off charging). Here you may ask, what is the relationship between the USB specification protocol and fast charging?The emergence of USB BC 1.2 makes simultaneous charging and data transmission a reality. Although the USB interface was originally used by manufacturers to transfer data and connect devices such as keyboard or mouse instead of charging. Just think, wouldn't it be much more convenient if you can use the USB interface to charge these devices? So USB BC 1.2 came into being. Although the maximum voltage of the USB interface was still 5V at that time, and the maximum current of USB charging is 1.5A. Although it did not increase the voltage (mainly to adapt to other portable devices), but the USB interface can reach 7.5W with 1.5A current. At that time, the USB BC 1.2 is enough to cope with the charging of mobile phones.The emergence of USB BC 1.2 not only ended the chaotic scenes of USB charging specifications at that time, but it also has good support for hubs/distributors/HUB. So the USB interface data line has become the hot product of various manufacturers for a while. But there is also a data cable with a MicroUSB 2.0 interface (also known as the Android cable). It has only four wires inside, and its current carrying capacity is very limited (2A is the max).Although the USB BC 1.2 standard was able to meet the charging needs of mobile phones at the time, the development of mobile phones has not stopped. With the time goes by, mobile phones have more and more functions. In order to cope with daily use, the battery capacity has also become larger and larger, and the battery capacity has also exceeded 2000mAh, but with the extension of the charging time. When the cell phone battery capacity reaches 3000mAh or even 4000mAh, does it have to be charged overnight? So the charging speed again meets forward higher requirements.3.2 Qualcomm Quick ChargeIn 2013, it was the chip supplier Qualcomm who discovered this problem. Qualcomm first put forward the concept of "Fast Charge", and Quick Charge 1.0 was born. Improve the charging efficiency by increasing the input current, support 5V/2A, that is, the maximum charging power of 10W, breaking through the 1.5A current upper limit of the USB Battery Charge 1.2. In the same year, Huawei also introduced the "fast charge" concept to the first generation of Mate phones, which also supports 5V/2A input, and can fully charge a 4050mAh battery within 3.5 hours.In 2014, the situation was a little different. Qualcomm overturned the QC1.0 strategy and adopted a high-voltage quick charging solution.As mentioned above, P (power) = V (voltage) * I (current), because the data line of MicroUSB 2.0 can only support up to 2A current. Since it couldn’t to increase the current at that time, only adjust the voltage. For example, a fast charge with 18W power, if you want to use a 5V voltage, the current has exceeded 3A. A normal MicroUSB can never withstand such a high current. Using a voltage of 12V, the current only needs 1.5A, so the problems had be solved.The big advantage of this high-voltage fast charging tech is that the cost is relatively low (no need to buy different data cables), and the disadvantages are also obvious. The voltage of the charger is suddenly increased to twice as much, and the step-down heat is also extremely large for the mobile phone. So a major shortcoming of high-voltage quick charge is that the mobile phone generates serious heat during charging.This fast charging solution is the high-voltage QC2.0. It is the most popular and influential standard in the history of QC. For example, Samsung’s 2018 flagship Galaxy S9 still uses the QC2.0.Figure 3. Qualcomm Quick ChargeQC2.0 has improved the charging voltage from the conventional 5V that has been maintained for many years to 9V/12V/20V. It achieves 18W high-power power transmission at the same 2A current as QC1.0, and does not require special wires.QC2.0 has far-reaching influence because of its powerful compatibility. At that time, Micro USB was the standard configuration of smart phones, but it was restricted by the physical interface. Once the current exceeds 2A, it is prone to damage. The smart part of QC2.0 bypasses the restrictions of the Micro USB interface and the data cable, and only increases the charging speed by directly adjusting the input voltage. What’s more, QC2.0 quick charge tech has given peers a idea for reference.3.3 OPPO VOOC ChargeFor example, OPPO introduced VOOC (Voltage Open Loop Multi-step Constant-Current Charging). What OPPO uses here is another solution. There is a fact that normal MicroUSB data cable can't carry such a large current. Because the usual MicroUSB data cable has only five measuring points and four wires, so just increase their number. Therefore, the original VOOC charging head is extremely big because of integrates IC circuit.In addition, because the circuit is rebuilt, you can only use the official special data cable, and the ordinary MicroUSB data cable cannot achieve the fast charging effect. The shortcoming is obvious that the cost is high. But the biggest problem is that high-current charging has more damages. For example, it has been shortening the battery service life of many mobile phones because of VOOC quick charge a year later.Following the principle of "equivalent exchange", since such a heavy price has been paid, there will certainly be generous returns. The advantage of the first-generation VOOC fast charge is that with the 5V/5A 25W ultra-high power, OPPO mobile phones equipped with VOOC fast charge are extremely fast in charging speed. And it puts the heat source into the charger externally, and the heat generated by the mobile phone during charging is significantly less than that of the high-voltage fast charging solution. As a result, the high-voltage fast charging solution led by Qualcomm QC and the low-voltage and high-current fast charging solution led by OPPO VOOC have parted ways.VersionLaunch TimeVoltage/CurrentDescriptionVOOC 2.020155V/4ASame as the first versionVOOC 3.020195V/5ACharge the phone up to 55% in 30 minutesVOOC 4.0202010V/5A(50W)Charge the phone up to 67% in 30 minutesSuperVOOC20185V/6A (30W)Charge a two-cell battery in seriesSuperVOOC 2.0202010V/6.5A (65W)Successor of Super VOOC with GaN technologyThe key to fast charging of mobile phones is the small micro USB interface. At this time, USB type-C appears. Simply list its advantages, such as: support positive and negative plug compatibility, compatible with USB 3.1 standards, support 10Gbit/s transmission in maximum, support the USB Power Delivery charging protocol, support 5A current, the maximum can provide 100W of power. Therefore, the Type-C interface is inherently friendly to large currents.Qualcomm is a giant in mobile phone chips and communications patents, and by virtue of its dominant position, it can quickly popularize its fast charging standards to gain the standard license fee. However, various manufacturers have also begun to develop their own fast charging standards to share this big cake.3.4 Pump Express (PE)Also in 2014, MediaTek launched its own Pump Express (PE) quick charge tech, and Meizu's mCharge fast charging is based on this, and the later Pump Express Plus (PEP) fast charging. Huawei launched the Fast Charge Protocol (FSP) in the early days. As for Xiaomi and Nubia, many manufacturers that still use Qualcomm QC for their flagship mobile phones. They belong to high-voltage fast charging scheme.3.5 OnePlus Dash ChargeNext, let’s talk about OnePlus. Although OnePlus uses Qualcomm’s SoC, but chose a low-voltage and high-current charging solution, that is, Dash charge. It first debuted with the launch of OnePlus 3, where OnePlus promised 60% of full charge in just 30 minutes of charging.Seeing this, do you think that Qualcomm's high-voltage fast charging solution has won the victory, while the low-voltage solution can survive hardly?Of course not, the turning point is that more and more mobile phones are equipped with USB Type-C interface. By 2016, it has become popular. For example, Android flagship phones basically use this interface.3.6 Huawei SuperChargeIn the same year, Huawei improved its FastCharge (FCP) to SuperCharge (SCP). SCP can be said to be one of the fastest/good compatible fast charging representatives in the world, and is compatible with PD and Qualcomm QC protocols.3.7 Low Voltage SolutionMediaTek has also switched to a low-voltage solution. Pump Express technology has developed to 3.0. Pump Express 3.0 is the world's first fast charging solution that uses Type-C interface for direct charging. This solution can effectively prevent the phone from getting hot during charging. In a word, it is very safe.In 2017, Meizu released Super mCharge quick charge tech. It has a charging power of up to 55W at 11V/5A. Unfortunately, due to the inability to get mass production, this 55w super fast charge is still not applied to mobile phones, and replaced by MCharge4.0 fast charging technology. The earlier mCharge3.0 is a high-voltage fast charging solution (24W), and its charger output voltage can reach up to 12V; while mCharge4.0 (25W) belongs to low-voltage and high-current solution, with 5V output voltage and 5A current.Qualcomm began to discover the advantages of the low-voltage solution, so it uses the low voltage and high current solution in the QC4.0 fast charging protocol. Of course, it also supports high voltage fast charging at the same time.Although low-voltage and high-current solutions have basically ruled fast charging, the fast charging protocols of various companies are not compatible with each other. That is to say, although they all use Type-C, they must use the fast charging function of mobile phones corresponding to their own agreement. In other words, although they are all Type-C interfaces, the fast charge protocol is different.3.8 Quick Charge StandardFortunately, the USB IF has unified the fast charging standard. Mobile phones should employ fast charge according to the USB PD protocol. Adjust voltage and current. This standard is also supported by Google. However, various manufacturers make their own mobile phones, and use their own fast charging protocols. So the USB PD protocol has been put aside.The main reasons why mobile phone manufacturers have become more obsessed with constant voltage and high current over the years are: greater power and less charging heat. The USB PD3.0 has successfully incorporated Qualcomm's QC4 protocol. So far, USB PD3.0 has been the regular rule. In short, manufacturers who want to continue to develop their own charging technology, they only need to be based on the USB PD protocol. Moreover, the latest 100W fast charge has been successfully tested. Although large-scale commercial use is unlikely right now, the technical bottleneck will always be overcome.Every Fast Charging Standard Explained Ⅳ FAQ1. What is considered quick charge?For fast charging, you're looking at something that bumps the voltage up 5V, 9V, 12V, and beyond, or increases amperage to 3A and above. Keep in mind, your device will only take in as much power as its charging circuit is designed for.2. Does Quick Charge work with any cable?Do I need any specific equipment for fast charge? Fast charge requires 3 components – a compatible phone/tablet/laptop or other device, a charger that supports USB Fast charge, and a compatible cable. The cable will have USB-C at least on the charger end, and either USB-C or Apple Lightning on the device end.3. Is fast charging bad?The bottom line is, fast charging won't impact your battery life substantially. But the physics behind the technology means you shouldn't expect the battery to last longer than using a conventional “slow” charging brick.4. What phones use quick charge?Apple, Samsung, Google, OnePlus, LG, Sony, Motorola, Huawei, Xiaomi, OPPO, ViVo and Realme.5. What is the meaning of VOOC?The OPPO VOOC (Voltage Open Loop Multi-step Constant-Current Charging) Flash Charging system is a proprietary rapid-charge technology created by OPPO Electronics, which, at present, is able to charge certain OPPO devices from 0 to 75% in just 30 minutes.6. Which phones support VOOC?Realme Narzo 20 Pro (65W Dart Charging)Realme 7 (30W Dart Charging)Realme 7i (18W)Realme 6 (30W VOOC fast charging)Realme X2 (30W VOOC fast charging)7. What is difference between Dash and Warp Charge?The key difference in the two standards is the increase in wattage on the Warp Charge standard. ... In comparison, Dash Charge uses a 5V / 4A (20W) configuration, and both require dedicated Warp Charge / Dash Charge compatible cables to carry the energy.8. Can you use Dash charge with other phones?Dash charge won't harm the phone.. Yes it can. I don't think OnePlus' type C cables or charger are up to USB Type C specifications. I would advise to not do it and get the proper cables and charger for your other device.9. How fast is Huawei SuperCharge?46 mAh per minuteAn infographic put together by Hometop shows that Huawei Super Charge is the fastest at over 46 mAh per minute.10. What is MediaTek Pump Express?Pump Express 4.0 is the latest advance in MediaTek's family of charging innovations. This next-generation charging technology will change your (battery) life, cutting smartphone battery recharge times by over half, compared to a standard USB charger.11. What is MediaTek Pump Express 2.0?They use the MediaTek Pump Express 2.0 fast charging technology and reach a 35% (1,785mAh) in just 30 minutes giving several hours use. It can fully charge the huge battery via its USB-C connector from 0-100% to give 2 full days use in just 2.5 hrs.12. What is super flash charge?The company introduced its 65W SuperVOOC charging that can charge 4000mAh battery on the Reno Ace / Ace2 fully in about 30 minutes. ... The company's 125W fast charging is rumoured to charge the phone's battery from 0 to 100% in about 10 minutes.13. What is DART charge Realme?The Realme 30W Dart Charge Power Bank is an easy recommendation from our side for anyone who owns a compatible device. It comes with two-way fast charging and support for multiple quick charge protocol support. The power bank is also compatible with multiple smartphones apart from Realme.

Ⅰ IntroductionBNC connectors have a bayonet-style coupling mechanism that allows for quick connection and disconnects while also providing positive locking. Mating takes only a quarter-turn of the coupling nut. BNC RF connectors have a classic, dependable design that allows them to accommodate a wide range of RG and industry-standard coaxial cables in a variety of termination styles.catalogⅠ IntroductionⅡ What is a BNC Connector?Ⅲ BNC Connector Related Video:Ⅳ BNC Connector Features and BenefitsⅤ BNC Connector ApplicationsⅥ Related ProductsⅦ 75 ohm vs 50 ohm7.1 Applications7.2 50 Ohm and 75 Ohm Cables: Differences / Distinctions7.3 Why 50 Ohm and 75 Ohm?7.4 SpecificationsⅧ Other Types of BNC ConnectorⅪ SDI vs BNC9.1 Definition: SDI vs. BNC Cables9.2 BNC Connectors on SDIⅩ FAQ Ⅱ What is a BNC Connector?Paul Neill of Bell Labs and Carl Concelman of Amphenol created The Bayonet Neill Concelman (BNC) connector. The original purpose of the BNC connector was for military applications, but it is now primarily used in the broadcast market. This connector has evolved to keep up with the changing industry landscape, and it now provides the 12G SDI performance required in 4K and Ultra-HD applications. BNC connector types for coaxial cable have been widely adopted and continue to be a popular choice for current and next-generation video technology. Ⅲ BNC Connector Related Video: BNC Connector Video Descirption: This short video demonstrates how to connect a crimp style BNC connector to RG-58 50-ohm coax. Other crimp-style coaxial connectors will be installed in a similar manner. It should be noted that the connectors are specific to the type of coax being used, and having the proper crimping tool is necessary. Optionally (carefully) solder the center pin, and finish with heat shrink tubing for a clean professional look. Ⅳ BNC Connector Features and BenefitsCustomers can match impedance to system requirements using the bayonet coupling mechanism, which provides positive, quick mating and un-mating. 50 and 75 ohm impedance designs are available.Military, industrial, and commercial connectors are available.Many common BNC coaxial cable designs are available.Female and male BNC configurations Ⅴ BNC Connector ApplicationsAntennasBroadcast (75 Ω)TelecommunicationsAutomotiveComputers/LANsMedical EquipmentSatcomBase StationsCable ModemsInstrumentationMilitary/Aerospace Ⅵ Related Products                                                                       BNC Adapters                                                         BNC Accessories                                 BNC Cable Assemblies Ⅶ 75 ohm vs 50 ohmBNC connectors are typically available in 50 ohms and 75-ohm versions, which are matched for use with cables of the same characteristic impedance. The 75-ohm connector is slightly different in dimensions from the 50-ohm variant, but the two can be made to mate.BNC cables and connectors are available in 50 Ohm and 75 Ohm specifications.ohm cables/connectors are designed for high-quality digital video (CCTV) and can scale their output based on the input.75-ohm cables can also be used effectively on older analog video formats, making them more versatile and flexible in any situation.When low signal loss is critical, 75 Ohm BNC cables/connectors are used.50-ohm cables and connectors are compatible with older analog video formats. If you are looking for high-quality video output, 50 Ohm will not provide it.Connecting the two types of connectors is possible, but it is not recommended: mixing will not result in the best output.With 50 Ohm cables, 50 Ohm BNC connectors are used. With 75 Ohm cables, 75 Ohm connectors are used. 7.1 Applications75 Ohm BNC applications include satellite, high-definition televisions, and cable TV receiver boxes.Receivers for AM/FM radio.Police scanners. RG-179 coaxial cable has a 75 Ohm BNC connector and is used in high-temperature environments.Applications of 75 Ohm BNC Cables using RG-179A 75 Ohm BNC connector is used on the RG-179 coaxial cable.Is designed specifically for high-temperature environments: Finished with a TFE taped outer jacket. It can withstand temperatures of up to 200 degrees Celsius.RG-179 is commonly used in high-temperature applications such as:Hospital and clinic medical equipmentVideo surveillance cameras are applied for safety purposes.Audio surveillance systems.  7.2 50 Ohm and 75 Ohm Cables: Differences / DistinctionsThe impedance of 50 Ohm and 75 Ohm coaxial cables is measured in Ohms, the unit that measures electrical resistance. The radio frequency signals sent down these cables are alternating current (AC) rather than direct current (DC) (DC). The magnitude and phase of the transmitted signal are countered and contained by the cable as it flows down its length with AC signals. As a result, the impedance rating for coaxial cable is as follows:Resistance: the amount of resistance to current flow.The amount of voltage generated by the magnetic field of an electrical current is referred to as inductance.Capacitance is the amount of charge contained or retained within a cable while current flows.Coaxial cable is designed specifically for signal transmission and is structured to balance resistance, capacitance, and inductance for consistent performance in radio frequency circuits. The impedance of a specific coaxial cable is determined by its composition, which includes the dielectric constant of the insulating layer and the radii of the outer and inner conductors. 7.3 Why 50 Ohm and 75 Ohm?For most radio frequency applications, the use of 50 and 75 Ohms as standard characteristic impedances for coaxial cable is essentially a compromise between optimal power handling and the lowest possible signal loss. These critical impedances were discovered through extensive testing in the early twentieth century. These experiments discovered that, while 30 Ohm cable provided excellent voltage and power handling, 77 Ohm coax provided the lowest attenuation.As a result, 50 Ohm coaxial cable would have a good power handling profile as well as low attenuation. Over the following decades, 50 Ohm coax emerged as the primary solution for cable with good power handling, particularly for 100 watts or more. It is frequently used for antenna cables in amateur and broadcast radio, cellular and wireless networking applications involving transmitters and transceivers.For applications requiring low signal loss, capacitance, and signal distortion, 75 Ohm cable was preferred. It is the coaxial cable of choice for applications requiring efficient signal transfer with low loss. These cables are frequently used in applications that require a connection to a receiver, primarily video applications that are low power and do not require the power handling of a 50 Ohm cable. Cable television, HDTV, and CCTV are examples of important applications. 75 Ohm coax can also be used for coaxial digital audio, allowing it to transfer audio, for example, in a home theater system. 7.4 SpecificationsElectrical50 Ohm75 OhmImpedance50 Ohm75 OhmFrequency RangeDC - 4 GHz (DC -12 GHz on Extended Range Designs)DC- 4 GHz (DC - 12 GHz on Extended Range Designs)Voltage Rating500 Volts RMS Max Continuous500 Volts RMS Max ContinuousDielectric Withstanding Voltage1500 VRMS Max1500 VRMS MaxVSWR (Return Loss)       DC - 4 GHz1.3 (-18 dB) Max1.5 (-14 dB) Max     12G Products: DC - 6 GHz 1.22 (-20 dB) Max     12G Products: 6 - 12 GHz 1.43 (-15 dB) MaxInsulation Resistance 5000 MΩ Min5000 MΩ MinCenter Contact Resistance1.5 mΩ Min1.5 mΩ MinOuter Contact Resistance0.2 mΩ Min0.2 mΩ MinRF Leakage55 dB Max @ 3 GHz55 dB Max @ 3 GHzInsertion Loss0.2 dB Max @ 3 GHz0.2 dB Max @ 3 GHzPower Handling316 W Max @ 1 GHz @ 25 ºC316 W Max @ 1 GHz @ 25ºCEvironmental  Temperature Range−65°C to +165°C−65°C to +165°CThermal ShockMIL-STD-202, Method 107 (Test Condition G), except high temp test @ +200⁰CMIL-STD-202, Method 107 (Test Condition G), except high temp test @ +200⁰CCorrosionMIL-STD-202, Method 101 (Test Condition B) - 5% Salt SolutionMIL-STD-202, Method 101 (Test Condition B) - 5% Salt SolutionVibrationMIL-STD-202, Method 204 (Test Condition D)MIL-STD-202, Method 204 (Test Condition D)Mechanical ShockMIL-STD-202, Method 213 (Test Condition G) - No Discontinuity PermittedMIL-STD-202, Method 213 (Test Condition G) - No Discontinuity PermittedMoisture ResistanceMIL-STD-202, Method 106MIL-STD-202, Method 106AltitudeMIL-STD-202 Method 105 (Test Condition C)MIL-STD-202 Method 105 (Test Condition C)Mechanical  Mating Cycles500 Min500 MinCoupling MechanismBayonetBayonetInterface SpecificationMIL-STD-348MIL-STD-348    Ⅷ Other Types of BNC ConnectorThere is also a threaded version of the BNC connector known as the TNC connector (Threaded Neil-councilman). The connector has a 50 impedance and works best in the frequency range of 0–11 GHz. When it comes to microwave frequencies, it outperforms the BNC connector. 50-OHM Twin BNC or twinaxTwin BNC (also known as Twinax) connectors have the same bayonet latching shell as regular BNC connectors but have two independent contact points (one male and one female), allowing the connection of a 78 ohm or 95 ohms shielded differential pair such as RG-108A.They have a maximum frequency of 100 MHz and a voltage of 100 volts. They are incompatible with standard BNC connectors. Twinax connectors are ideal for computer network applications because they feature keyway polarization, which ensures system integrity and prevents signals from being mixed.Twin BNC TriaxialTriaxial (or Triax) connectors are a type of BNC connector that carries a signal, a guard, and a ground conductor. Triax connectors are used in applications that require maximum RF shielding and minimal noise radiation. These are used in sensitive electronic measurement systems such as Keithley Instruments. Early triaxial connectors had only an extra inner conductor, but later triaxial connectors have a three-lug arrangement to prevent accidental forced mating with a BNC connector. Adaptors are available to allow some interconnection between triaxial and BNC connectors.Triaxial  Miniature connectorsMini BNC and High-Density BNC are smaller versions of the BNC connector (HD BNC). While retaining the original electrical specifications, they have smaller footprints, allowing for greater packing density on circuit boards and equipment backplanes. Because of their true 75 ohm impedance, these connectors are suitable for HD video applications. These BNC connectors are widely used in electronics, but in some applications, they are being replaced by LEMO-00 miniature connectors, which allow for much higher densities. For higher density products in the video broadcast industry, the DIN 1.0/2.3 and HD-BNC connectors are used. Miniature connectorsⅪ SDI vs BNC9.1 Definition: SDI vs. BNC CablesBayonet or BNC? Neil Concelman connectors are commonly found on coaxial cables. Male-type connectors are attached to the ends of basic BNC cables. It has a pin that connects to the cable conductor in the center.The rotating ring on the outside of the BNC cable tube is capable of locking to female connectors. This type of connector is commonly found on monitors. It aims to improve the accuracy of signals, particularly those sent by the video adapter.Two HD SDI-video cablesSDI, or Serial Digital Interface, on the other hand, is commonly used to transmit uncompressed and unencrypted video signals. This interface type is also used for broadcasting standard and high definition signals. These can be accompanied by audio and video signals.This interface type is primarily used by broadcasting facilities. It also includes closed captions, test signals, and content identification. 9.2 BNC Connectors on SDISDI is a signal transport format, whereas BNC is a connector format. SDI employs coaxial cables, which are typically terminated with a BNC plug.SDI transports 16 channels of pulse-code modulation (PCM) audio and uncompressed digital video. It transmits over a 75 Ohm coaxial cable with a BNC connector.SDI cables can no longer handle signals with bandwidths in the gigahertz range. To handle this digital signal, it must use a proper BNC connector. BNC connectors, on the other hand, can come in a variety of sizes. As a result, we recommend that you locate a BNC connector that is compatible with SDI.Despite its utility, the main disadvantage of using SDI is that it is not supported by a large number of consumer and prosumer devices. Despite this, some manufacturers use converter boxes to convert SDI signals. SDI has a limited number of resolutions that it can support.In general, a supporting BNC connector on your SDI cable is required to allow for greater signal bandwidth. Furthermore, the majority of users connect these two connectors by soldering or securing the locks.In summary, various types of equipment, such as radios and televisions, use BNC coaxial cable connectors. The connector has a single pin in the center. Furthermore, SDI makes use of this cable to accommodate signals that require a large amount of bandwidth. This interface is used by a variety of devices to transmit uncompressed or unencrypted digital signals.SDI alone is not recommended because signals with high bandwidth require a BC connector. As a result, because there are different dimensions for this type, it is critical to find a proper fit of the BNC connector to SDI.Ⅹ FAQ1. What does BNC stand for in connectors?Bayonet Neill–ConcelmanThe BNC (Bayonet Neill–Concelman) connector is a miniature quick connect / disconnect radio frequency connector used for coaxial cable. It features two bayonet lugs on the female connector; mating is fully achieved with a quarter turn of the coupling nut.2. What is the difference between BNC and F connector?BNC connectors are bayonet type connectors, commonly used in CCTV systems. They are the most suitable connector for use with RG59/U cable. ... F-Type connectors are used for CATV, SATV and Digital TV in conjunction with either RG6 or RG11 cables.3. What is BNC?(Bayonet Nut Coupling) A commonly used plug and socket for audio, video and networking applications that provides a tight connection. Using a mount somewhat similar to the way a bayonet (knife) is mounted onto the end of a rifle, BNCs are used to connect a variety of different coaxial cable types.4. Is BNC a media connector?BNC connectors are associated with coaxial media and 10Base2 networks. BNC connectors are not as common as they once were, but still are used on some networks, older network cards, and older hubs. Common BNC connectors include a barrel connector, T-connector, and terminators.5. Are BNC connectors still used?You might remember the BNC connector that was used for component connections in the 2000s and before. It has been used for SD video and HD video, but it's rarely seen in consumer electronics today. ... While N-connectors are still around, the C connector is no longer used.BNC connectors—or Bayonet Neill-Concelman—are a common type of RF connector that utilizes BNC cables. ... A BNC connector connects the analog video components from the camera to a TV monitor or DVR. It snaps firmly into place, providing for a quality and secure connection.