The Kynix Blog

Introduction When the reverse bias voltage applied to the PN junction increases to a certain value, the phenomenon that the reverse current density suddenly begins to increase rapidly is called PN junction breakdown. From the mechanism, it can be divided into three categories: avalanche breakdown, tunnel breakdown and thermoelectric breakdown. Among them, there are two physical mechanisms for forming reverse breakdown in PN junction: zener breakdown and avalanche breakdown. Generally, both breakdowns coexist. So what is the difference between them? Avalanche Breakdown and Zener Breakdown Effect Explained Catalog Introduction Ⅰ Basic Characteristics 1.1 Avalanche Effect 1.2 Zener Effect Ⅱ Zener Effect vs Avalanche Effect Ⅲ Transistor Secondary Breakdown and Protection 3.1 A Brief Description 3.2 Cause of Breakdown 3.3 Precaution 3.4 Snubber Circuit Examples Ⅳ FAQ Ⅰ Basic Characteristics 1.1 Avalanche Effect As the reverse voltage increases, the electric field in the space charge region strengthens, and the energy obtained by the carriers in the barrier region also increases. When the reverse voltage is close to the breakdown voltage, these carriers with higher energy meet the neutral atoms in the space charge region and cause collision ionization, generating new electron-hole pairs. These newly generated electrons and holes will regain energy under the action of the electric field, collide with other neutral atoms to ionize them, and generate more electron-hole pairs. With reaction continues, causing the number of carriers in the space charge region to increase sharply, just like an avalanche, what’s more, the reverse current also increase sharply, resulting in breakdown. So this breakdown is called avalanche breakdown (or avalanche effect).This breakdown generally occurs in PN junctions with lower doping concentration and higher applied voltage. Because a PN junction in this state has a wider space charge region and more opportunities for impact ionization. Figure 1. Zener Breakdown vs Avalanche Breakdown 1.2 Zener Effect When the reverse voltage increases to a certain value, a strong electric field can be established in the barrier region, which can directly pull out the valence electrons bound in the covalent bond, so that a large number of electron-holes are generated in the barrier region. Then a large reverse current is formed, resulting in breakdown. At this time, atoms in the barrier region are directly excited under the action of a strong electric field is called Zener effect/breakdown. It is caused by the tunneling effect in quantum mechanics. Giving a simple metaphor, the simple understanding is that the two lines are too close, and they pass through directly. At this time, the potential barrier loses its function of blocking electrons, and a breakdown occurs.Zener breakdown generally occurs in PN junctions with higher doping concentrations. This is because the PN junction under this situation has a large charge density and a narrow width in the space charge region. As the temperature increases, the energy gap decreases, and a breakdown can be resulted in with a small reverse voltage. Figure 2. PN Junction Ⅱ Zener Effect vs Avalanche Effect 1) Zener effect mainly depends on the maximum electric field in the space charge region, and in the collision ionization mechanism is related to both the field strength and the collision accumulation process of carriers. Obviously, the wider the space charge region, the more times of multiplication, so the avalanche breakdown is not only related to the electric field, but also related to the width of the space charge region, which requires the thickness of the PN junction.2) Because avalanche breakdown is the result of impact ionization. If we increase the electrons and holes in the space charge region by means of illumination or fast particle bombardment, they will also have a multiplier effect. However, the above external effects will not have a significant impact on the Zener breakdown.3) The breakdown voltage is determined by the tunnel effect, and its temperature coefficient is negative, that is, the breakdown voltage decreases with the increase of temperature, which is the result of the decrease of the forbidden band width with the increase of temperature. The breakdown voltage determined by avalanche multiplication decreases with the increase of temperature due to the impact ionization rate (the ionization rate represents the number of electron-hole pairs generated by a carrier drifting a unit distance under the action of an electric field), and its temperature coefficient is positive. That is, the breakdown voltage increases with temperature. Zener with voltage lower than 5-6V is mainly due to Zener breakdown; Zener with voltage higher than 5-6V is mainly due to avalanche breakdown. Zener diodes with a voltage between 5-6V have similar breakdown degrees and the best temperature coefficient, which is why many circuits use 5-6V Zener tubes. The principle of the Zener tube determines that its response speed is not very fast, so a tube reference voltage is used in occasions with high speed requirements.4) For the PN junction with higher doping concentration and thinner barrier, it is mainly Zener breakdown. The PN junction with lower doping and therefore wider potential barrier is mainly avalanche breakdown, and the breakdown voltage is relatively high.The PN junction breakdown is an important electrical property, and the breakdown voltage limits the working voltage of the circuit, so semiconductor devices have certain requirements for the breakdown voltage. However, a variety of devices such as Zener diodes, avalanche diodes, and tunnel diodes can be fabricated by using the breakdown phenomenon.Under normal circumstances, the avalanche breakdown and Zener breakdown are within a certain range of conditions (breakdown voltage, time), with the normal working conditions are restored, are reversible. If it is only for protection, the TVS voltage regulator tube is mainly used for voltage regulation. The smaller the current passing through, the better. When the instantaneous voltage exceeds the normal working voltage of the circuit, the TVS diode will avalanche, providing an ultra-low resistance path for the instantaneous current, which is diverted through the diode, avoiding the protected device. In additional, the protected circuit keeps the cut-off voltage until the voltage returns to normal value. When the instantaneous pulse ends, the TVS diode automatically returns to the high resistance state, and the entire circuit entering the normal voltage, the failure mode of the TVS tube is mainly short circuit. But when the overcurrent passed is too large, it may also cause the TVS tube to be burst and open. Figure 3. TVS Diode Ⅲ Transistor Secondary Breakdown and Protection 3.1 A Brief Description In most switching power supplies, power switching transistors work under high-voltage, high-current high-frequency pulses, and switching on and off under such conditions will cause a great impact on the transistors. Secondary breakdown is one of the important causes of transistor damage. To design a high-performance, high-reliability switching power supply, it is necessary to have a clear understanding of the secondary breakdown of transistors and avoidance measures. 3.2 Cause of Breakdown The secondary breakdown is mainly caused by the high local temperature in the device body. The temperature rise is caused by thermal imbalance when forward biased and avalanche breakdown when reverse biased.Because the thermal resistance of the transistor is unevenly distributed throughout the tube, in some weak areas, the temperature rise will be higher than other parts, forming a so-called "hot spot", and so on until a critical temperature, causing the breakdown of the tube. The secondary breakdown caused by the avalanche breakdown is a phenomenon in which the electric field distribution of the junction is changed due to the excessive current density at some points after the primary avalanche breakdown occurs, resulting in a negative resistance effect and the local temperature is too high. 3.3 Precaution Turn-on and turn-off losses are important factors that affect the normal operation of switching devices. In particular, the transistor is prone to secondary breakdown in the dynamic process, and this phenomenon is directly related to the switching loss. Therefore, reducing the switching loss of the self-shutdown device is a necessary measure for the correct use of the device. There are two ways to reduce losses:(1) Turn off the transistor at the lowest possible collector-emitter voltage (Vce).(2) When the transistor is turned off during the rise of the emitter voltage, the emitter current should be minimized. For example, introducing a buffer circuit is one of the ways to achieve the above purpose. 3.4 Snubber Circuit Examples The following snubber circuits can be used in the design of switching power supplies to ensure that the transistors operate within a safe area.1) The commonly one is an energy-consuming shutdown snubber circuit. Although it consumes more energy, this circuit is simple. Figure 4. Commonly Used Shutdown Snubber Circuit It consists of an RCD network connected in parallel with transistor switches. When the transistor is turned off, the load current charges the capacitor C through the diode D, so that the collector current of the tube gradually decreases. Because the voltage across the capacitor C cannot be abruptly changed, its collector voltage is restrained. The situation where the collector voltage and current reach their maximum values at the same time is avoided, so there is no maximum instantaneous power consumption spike. When the tube is turned on, the capacitor releases energy and dissipates it in the resistor.2) Two commonly used energy-consuming turn-on snubber circuits.a. An inductor-diode network is connected in series with the transistor collector to form a turn-on snubber circuit. When the tube is turned on, the inductance Ls controls the current rise rate di/dt during the collector voltage drop. When the tube is turned off, the energy stored in the inductor Ls 1/2 freewheels through the diode Ds, and its energy is dissipated in the resistance of Ds and the reactor. Figure 5. Open Snubber Loop with Unsaturated Reactance b. Turn-on snubber circuit with saturable reactor: The purpose of using turn-on snubber circuit is to make the collector voltage drop to 0 when the collector current of the transistor is small, so as to minimize the turn-on loss. Especially for inductive loads, the effect is more significant. The designed saturable reactor should be: in one hand, after the collector voltage drops to zero, the buffer reactor is in a saturated state; in the other hand, before saturation, the collector voltage drops to zero, the reactor presents a high resistance, and the magnetizing current flowing through the tube is small to achieve the purpose of reducing turn-on loss. Figure 6. Open Snubber Circuit with Saturable Reactance 3) In the figure, Co is a transfer capacitor, and Dc is a feedback diode. These two components feed back energy to the load. When the tube is turned off, the buffer capacitor Cs is charged to the power supply voltage Vcc, and when the tube is turned on next time, the load current is transferred from the freewheeling diode Df to the transistor. At the same time, the voltage on Cs resonates to Co. When the tube is turned off again, the Cs is charged again, the capacitor Co is discharged to the load, and the energy is fed back. Figure 7. Passive Feedback Shutdown Buffer Circuit 4) This circuit stores the magnetic field energy and feeds back to the power supply through the transformer. The transformer is wound with two wires, and its primary side has a certain inductance; the polarity of the width side is opposite to that of the primary side, and a reverse diode is connected. When the tube is turned on, the primary side bears all the power supply voltage, and the secondary side has no energized circuit. When the tube is turned off, the polarity of the induced voltage on the secondary side is reversed, and when its voltage is higher than the power supply voltage Vcc, energy is fed to the power supply. Figure 8. Passive Feedback Opens the Buffer Circuit 5) The turn-on snubber circuit and the turn-off snubber circuit are combined to form a composite snubber circuit, and the composite snubber circuit has a protective effect when the transistor is turned on and off. This kind of circuit is also divided into two types: energy consumption and energy feeding.a. When the tube is turned on, the snubber capacitor is discharged through the Cs, Rs, and Ls loops, which reduces the current rising rate that the tube bears. In addition, when the tube is turned on, the inductance Ls can also limit the reverse recovery current of the freewheeling diode Df. Figure 9. Energy-consuming Composite Buffer Circuit b. When the transistor is turned off, the capacitor Co and the inductor Ls operate in parallel to feed the stored energy to the load. When the capacitor Co is discharged, the voltage on the inductor Ls gradually decreases to 0, and the load current is conducted through the freewheeling diode Df during this period. Figure 10. Energy-feeding Compound Snubber Circuit The various snubber circuits mentioned above can be divided into two types, namely energy-consuming and energy-feeding. The energy-consuming circuit is simple but relatively consumes more energy, and is suitable for the use of low-power circuits. The energy-feeding circuit is complex, but in a high-power supply, if the energy dissipated by the snubber circuit is dissipated in the form of heat, it is bound to cause a lot of trouble, so the energy-feeding buffer circuit should be used.   Ⅳ FAQ 1. What is a zener breakdown voltage?A normal p-n junction diode allows electric current only in forward biased condition. ... This sudden rise in electric current causes a junction breakdown called zener or avalanche breakdown. The voltage at which zener breakdown occurs is called zener voltage and the sudden increase in current is called zener current. 2. Which breakdown occurs in Zener diode?avalanche breakdownIn Zener diodes, avalanche breakdown occurs. When the Vz is greater than 8 volts in a Zener diode, avalanche breakdown occurs because there is an isolation of electrons and holes. 3. What is difference between avalanche and zener breakdown?The main difference between Zener breakdown and avalanche breakdown is their mechanism of occurrence. Zener breakdown occurs because of the high electric field whereas, the avalanche breakdown occurs because of the collision of free electrons with atoms. Both these breakdowns can occur simultaneously. 4. How do you calculate Zener breakdown voltage?The reverse current that results after the breakdown, is called Zener current (Iz). At breakdown, increase of VI increases II by large amount, so that V0 = VI– RI II becomes constant. This constant value of V0 which is the reverse breakdown voltage, is called Zener voltage. 5. What is avalanche breakdown of diode?What is Avalanche Breakdown? The avalanche breakdown occurs when a high reverse voltage is applied across the diode. As we increase the applied reverse voltage, the electric field across the junction increases. This electric field exerts a force on the electrons at the junction and frees them from covalent bonds. 6. How does an avalanche breakdown take place?Avalanche breakdown usually occurs when a high reverse voltage is applied across the diode. So as we increase the applied reverse voltage, the electric field across the junction will keep increasing. This generated electric field exerts a force on the electrons at the junction and it frees them from covalent bonds. 7. What is avalanche effect of Zener diode?Avalanche breakdown involves minority carrier electrons in the transition region being accelerated, by the electric field, to energies sufficient for freeing electron-hole pairs via collisions with bound electrons. The Zener and the avalanche effect may occur simultaneously or independently of one another. 8. What do you mean by zener breakdown voltage?When reverse biased voltage applied to the zener diode reaches zener voltage, it starts allowing large amount of electric current. At this point, a small increase in reverse voltage will rapidly increases the electric current. Because of this sudden rise in electric current, breakdown occurs called zener breakdown. 9. Is Zener voltage the same as breakdown voltage?The breakdown voltage,commonly called the Zener voltage, is the reverse-biased voltage that causes the diode to conduct current. Breakdown voltages usually range from 2.4 V to hundreds of volts. 10. What is meant by Zener effect?The Zener effect is a type of electrical breakdown that occurs in a reverse-biased PN junction when the electric field enables tunnelling of electrons from the valence to the conduction band of a semiconductor, leading to a large number of free minority carriers which suddenly increase the reverse current. 11. Which factor is responsible for Zener effect?In effect, electrons from the p-side valence band are able to tunnel across the barrier into the empty states in the n-side conduction band when a small reverse bias is applied. The result is a strong current from n to p in the diode, causing zener breakdown. 12. What is valence breakdown?Avalanche breakdown (or “the avalanche effect”) is a phenomenon that can occur in both insulating and semiconducting materials. It is a form of electric current multiplication that can allow very large currents within materials which are otherwise good insulators. It is a type of electron avalanche.

What is the soldering?What is the PCB soldering?Video about the pcb solderingPCB Soldering MaterialTypes of SolderingTypes of PCB SolderingWhat is the Wave SolderingWave Soldering ProgressThe advantages and disadvantages of wave solderingWhat is the Reflow Soldering?Reflow Soldering ProgressThe advantages and disadvantages of Reflow SolderingWhat is the Selective Soldering?Selective Soldering ProgressThe advantages and disadvantages of Selective SolderingWave Soldering VS Reflow SolderingSelective Soldering VS Wave SolderingReflow Soldering VS Selective SolderingThe conclusion of Wave Soldering VS Reflow Soldering VS Selective SolderingPCB Soldering FAQ What is the soldering?Soldering is the process of putting metal parts together with melted solder, a metal having a lower melting point than other metals. It is a process that is essential to the electronics industry and the main way to connect electrical components. Soldering is utilized in the construction of printed circuit boards (PCBs), as well as in the manufacture of jewelry, pipes, and plumbing. When soldering, a soldering iron or gun is used with solder at a temperature of less than 840 degrees Fahrenheit. Solder typically appears as a thin wire or tube. A flux-like acidic mixture is present inside the tube to stop oxidation.Despite the fact that there are many various kinds of solder, it is often an alloy of lead or tin, brass, or silver that is made to have a low melting point. This metal is melted by the soldering iron and then used to adhere components together rather like glue. The solder metal will re-harden into a single, substantial form that joins the two pieces as it cools. There are currently various lead-free solder options available in an effort to reduce lead usage due to environmental and safety concerns. These substitutes frequently consist of brass, copper, tin, or silver. Lead-free solder can be less effective than conventional solder and has a greater melting point.SolderingWhat is the PCB soldering?Soldering electrical circuit boards is also referred to as PCB soldering. One of the most fundamental skills for everyone who wants to deal with electronics and electrical circuits is this kind of soldering. The most fundamental definition of the soldering process is that it is a technique of attaching two little components together on the surface of the PCB, which is an abbreviation for Printed Circuit Board. There are many various ways you can finish the soldering process. To join two or more separate electrical components on your circuit board, in other words, soldering is a technique.The soldering action itself is pretty straightforward at its heart. A soldering iron, some solder, and the materials you are joining together are all you need to execute the simplest soldering task. A soldering iron is a tool that melts solder and is used to connect two pieces together. It resembles a pen and gets quite hot.Despite the fact that there are many various kinds of solder, it is often an alloy of lead or tin, brass, or silver that is made to have a low melting point. This metal is melted by the soldering iron and then used to adhere components together rather like glue. As the solder metal cools, it will re-harden into one large shape that connects the two parts.Pcb Soldering Video about the pcb solderingVideo Description: How to solder a through hole connection on a printed circuit board (PCB). PCB Soldering MaterialChoosing the correct sort of solder can seem like a daunting chore for a rookie designer or assembler because there are so many different varieties on the market. By enabling the molten, soft alloy solder to produce a eutectic that fuses as it cools, solders are used to create electrical connections between metal contacts. A soldered PCB's mechanical strength after solidification, the needed melting temperature, and any fumes released during soldering will all depend on the combination of metals used to build it. By looking at the core material, metallic components, and soldering flux kinds, we can distinguish between various PCB soldering materials. Lead-based filler metals, such as lead patch, were originally used in patching, however because to regulations, lead-based filler metals are gradually being replaced with lead-free fastens. These may consist of the following metals:BrassCopperAntimonyTinIndiumSilver or bismuth Types of SolderingLead-free solderLead-based solderFlux-core soldersSilver alloy solder Types of PCB SolderingWave SolderingReflow SolderingSelective Soldering What is the Wave SolderingElectronic components are attached to a printed circuit board (PCB) using the large-scale soldering technique known as wave soldering. The name comes from the method of attaching metal components to the PCB by applying waves of hot solder. The components are inserted into or placed on the PCB, which is then passed over a pumped wave or cascade of solder. The technique employs a tank to contain an amount of molten solder. A reliable mechanical and electrical connection is made when the solder wets the exposed metallic portions of the board (those not covered by solder mask, a protective layer that stops the solder from bridging across connections). The process is much faster and can create a higher quality product than manual soldering of components.Surface mount and through-hole printed circuit assemblies both use wave soldering. In the latter instance, before being subjected to the molten solder wave, the components are first attached to the printed circuit board surface by the placement apparatus.Wave Soldering Wave Soldering ProgressIt is essential that an electronics printed circuit board be produced and designed correctly in order to process it properly using a wave soldering equipment. It contains two steps to wave soldering progress.Step One Solder resist layer: The first is now considered best practice for board design. The PCB design incorporates a solder resist or solder mask layer, which provides a layer of "varnish"-like material to the board and prevents solder from adhering to it. Only the necessary parts for soldering are left exposed. The color of this solder resist is most frequently green.Step Two Pad spacing: The second major precaution is to make sure there is enough space between the solder pads that need to be soldered. There is a chance that the solder may bridge the two pads if they are too close together, leading to a short circuit. The spacing requirements for wave soldering depend on the orientation of the board in relation to the solder flow because the solder wave is created by solder flowing out of the reservoir tank as the board passes over it. Pads that are separated from one another perpendicular to the solder flow should have a wider separation than those that are separated perpendicular to it. This is due to the fact that solder bridges are considerably more likely to form in the direction that solder flows. The advantages and disadvantages of wave solderingThe advantages of wave solderingNo glue is needed to secure components during reflow soldering.Board areas where no soldering is required do not have to be masked off.Soldering machines that conduct selective soldering are generally cheaper to operate.Parameters for each are variable and can be more finely controlled.Allows wave soldering to be applied to boards with SMDs and vias.Suited for PTH assemblyIs more time-saving than hand solderingMore affordableLess prone to PCB warpageProvides strong solder joint quality The disadvantages of wave solderingHigh solder consumptionHigh flux consumptionHigh power consumptionHigh nitrogen consumptionAn increase in post-wave solder reworkMasking of sensitive areas on PCB assembliesCleaning of wave solder aperture pallets or masksCleaning of soldered assemblies What is the Reflow Soldering?Although reflow soldering differs slightly from wave soldering, it is still the most used method for joining surface mount components to a circuit board. For soldering through-hole components, wave soldering is more frequently utilized. Reflow soldering can be used for this purpose, however it is rarely done because wave soldering is more affordable.Reflow soldering is the process of attaching components to contact pads by creating a solder paste from powdered solder and flux. The solder is then melted and the junction is connected by heating the entire assembly in a reflow oven or under an infrared lamp. If necessary, you might use a hot air pencil to solder each individual link.Reflow Soldering Reflow Soldering ProgressThere are numerous separate steps that make up the reflow process itself. These are necessary to make sure that the board is heated to the appropriate degree for reflow soldering without causing any excessive amounts of thermal shock. The greatest quality solder junctions are produced when the temperature of the reflow tunnel or chamber is properly profiled. These are the four steps that are typically employed:Preheat: The boards must gradually warm up to the necessary temperature. The board or the components could be harmed by the thermal stress if the rate is too high. Thermal soak: The board then enters what is frequently referred to as a thermal soak area after being brought up to temperature. For two reasons, the card in this case is kept at a certain temperature. One is to make sure that any spaces that aren't heated enough due to shadowing effects are brought up to the necessary temperature. The other is to eliminate the solvents or volatiles from the solder paste and to activate the flux. Reflow: The soldering process's reflow area is where the maximum temperature is reached. The solder is made to melt and form the necessary solder joints here. The real reflow procedure involves the flux lowering the surface tension at the metal-to-metal contact to achieve metallurgical bonding, which enables the melting of the individual solder powder spheres. Cooling: After reflow, the boards need to be cooled, but it needs to be done without stressing the components. Excess intermetallic development and thermal shock to the components are prevented by proper cooling. The cooling zone typically has temperatures between 30 and 100°C (86 and 212°F). The temperature in this zone causes a relatively quick cooling rate, which is selected to give the solder a fine grain structure for the structurally soundest union possible. The advantages and disadvantages of Reflow SolderingThe advantages of Reflow SolderingTrusted by many manufacturersBest suited for SMT assemblyEffective for numerous SMT package types in a single processEasy to monitor and controlIt is a less wasteful method when dealing with specific parts of a PCB The disadvantages of Reflow SolderingFor those seeking to enhance certain aspects of the convection reflow soldering process, the use of nitrogen can be the key. But the use of nitrogen may be expensive.The temperature thresholds of the PCB assembly and the unique requirements of the solder paste must be taken into account while creating the reflow soldering profile. Accurate profiling must be obtained in order to be effective. What is the Selective Soldering?For THT and mixed technology soldering applications, selective soldering, commonly referred to as mini-wave soldering, provides economical, consistent outcomes. Individually programmable and monitored soldering spots are used to regulate flux quantities and soldering time. Additionally, it is the only technique that can be repeated to solder THT components onto a two-sided PCB assembly.Selective Soldering Selective Soldering ProgressStep 1: Fluxing or the application of liquid flux.Step 2: Preheating of the PCB assembly.Step 3: Soldering with a site-specific solder nozzle. The advantages and disadvantages of Selective SolderingThe advantages of Selective SolderingSecure and fast process optimizationReliable solder joint creation without overheating componentsGuaranteed process repeatabilityThe elimination of expensive wave solder palletsThe ability to solder around tall parts with tight spacingThe ability to solder dense concentrations of THT pins The disadvantages of Selective SolderingSince each circuit board must have a customized program, the technique is time-consuming and not well suited for mass production.As there are several parameters, processing problems may occur. Wave Soldering VS Reflow SolderingHow do you decide which soldering technique to employ when? Pad shapes, how much time you have, component orientations, the type of printed circuit board, and other variables could all play a role. Wave soldering is more difficult in several aspects. Careful observation is required for factors like board temperature and the length of time the board is in the solder wave. Board flaws are far more likely to occur when the proper wave soldering environment is not created.When you use reflow soldering to create your printed circuit boards, you won't have to worry nearly as much about protecting the environment. Even yet, wave soldering is frequently more expedient and less expensive than reflow soldering. It is frequently the only feasible method of soldering a board. Reflow soldering is frequently employed for smaller-scale manufacturing projects that don't call for a technique that can be used for quick, low-cost mass production.Remember that in some circumstances you might be able to employ both reflow soldering and wave soldering. It is possible to wave solder components after reflow soldering them on one side. Additionally, you can always manually solder or hand solder PCB components, but if you have access to one of the mechanical techniques of soldering, this will rarely be a suitable strategy. Reflow soldering is still significantly superior, and manual soldering is simply a substitute for it. Selective Soldering VS Wave SolderingWhen it comes to Printed Circuit Boards with through-hole and bigger surface mount components, wave soldering is the best technique. On the other hand, selective soldering is advantageous for a densely populated board since it enables the consideration of a lot of factors. However, because it necessitates the development of a special program for every circuit board, it is inappropriate for mass production. Reflow Soldering VS Selective SolderingWhen producing a circuit board, through-hole components require the use of a selective soldering machine. Reflow is only suitable for SMT components because it only solders the board's top surface. However, all sides of through-hole components need to be soldered.Fewer businesses are using selective soldering for component assembly due to the high production capacity and ease of reflow oven soldering. There are simply too many benefits to ignore. Reflow ovens have replaced hand soldering as the predominant method of PCB assembly in the industry, whereas selective soldering was formerly far more common. In a given amount of time, a reflow oven can produce many more units.The assembly process is also made simpler. A solder ball (often a mixture of solder and flux) is deposited at the location of the joint after the components have been positioned on the board. The solder starts to flow plastically and form the solder junction when the board is conveyed through the oven. The board exits the oven and can either be used in the product of which it is a part or it can be transported to the person who will use it before the end user. Component assembly takes longer using selective soldering machines. They usually cost more money. Furthermore, assembling a lot of PCB designs doesn't need for intricate soldering. Reflow is frequently used by component manufacturers rather as selective soldering for this very reason. The conclusion of Wave Soldering VS Reflow Soldering VS Selective SolderingWave soldering is more challenging in various respects and close inspection is required for elements like board temperature and the amount of time the board remains in the solder wave, while Environmental preservation won't be a major concern when you employ reflow soldering to make your printed circuit boards. What’s more, wave soldering is frequently more expedient and less expensive than reflow soldering. So if you want to take the cost and environment into account, the wave soldering must be the best choice.Wave soldering is the optimum method for Printed Circuit Boards with through-hole and larger surface mount components. However, because selective soldering allows for the evaluation of numerous variables, it is favorable for a board that is densely packed. But selective soldering is not suitable for mass production, though, as it calls for the creation of a unique software for each circuit board.Due to the great production capacity and simplicity of reflow oven soldering, fewer companies are adopting selective soldering for component assembly. When employing selective soldering machines, component assembly takes longer. They typically have higher prices. Furthermore, complex soldering is not necessary for the assembly of many PCB designs. For this exact reason, component manufacturers commonly use reflow instead of selective soldering. PCB Soldering FAQWhat is the PCB soldering?Your circuit board is the PCB. As you use your soldering equipment to connect various components and terminals to one another and to the board, all of the soldering you conduct will occur on the surface of this board. What are the 4 types of soldering?Lead-free solder, lead-based solder, and flux-core solder are the three primary varieties of solder. The silver alloy solder is a different variety. These kinds are created using alloy composition. Other solder kinds exist as well, depending on the form, core type, and application. What is the difference between reflow soldering and wave soldering?There are two soldering methods that are completely distinct from one another: wave soldering and reflow soldering. In wave soldering, the components are joined together with the aid of a melted solder wave crest. Components are soldered using reflow, which is created by hot air, in reflow soldering. What is the difference between selective soldering and wave soldering?In contrast to wave soldering, which strikes all solder joints simultaneously, selective soldering progressively solders individual components using a local wave on an x-y gantry. However, additional benefits have made selective soldering the method of choice in many circumstances. What are the advantages of wave soldering?Components are held in place during reflow soldering without the use of adhesive. No need to mask off board sections that don't need to be soldered. Selective soldering equipment are typically less expensive to run. Each has adjustable parameters that can be more precisely regulated.

What is Hard Drive?Hard disk, hard disk drive (HDD), hard disk, or fixed disk is the most important storage device of computer. It is composed of one or more aluminum or glass discs. These discs are covered with ferromagnetic material. Your documents, pictures, music, videos, programs, application preferences, and operating system represent digital content all can be stored on a hard drive. Most hard drives are permanently sealed and fixed in the hard drive. Early hard disk storage media was replaceable, but today's hard disk is a fixed storage medium, which is sealed in a case. With the development, removable hard disks have also appeared, and they are becoming more and more popular with different types. In addition, most of the hard disks installed on microcomputers are called Winchester hard drive.Hard DriveTopics Covered in this GuideWhat is Hard Drive?Hard Drive Tech ParametersHard Drive ClassificationsHard Disk StructureHow Does Hard Disk Work?Hard Drive MaintenanceUsing TipsHard Drive FaultsTypes of Hard Disk InterfacesCan a Computer Run without a Hard Drive?Should I Buy SSD or HDD?What the Defferences between HDD and SSD?What is the Lifespan of a Hard Drive?How Much Do Hard Drives Cost?What are the Best Hard Drives?Hard Drive Tech Parameters1) HD CapacityCapacity is the most important parameter of the hard disk. The capacity of the hard disk is measured in megabytes (MB) or gigabytes (GB). However, the hard disk manufacturer usually takes 1G=1000MB in the nominal hard disk capacity, so the capacity we see in the BIOS or when formatting the hard disk will be smaller than the manufacturer’s nominal value.The hard disk capacity index also includes the single-disk capacity. It refers to the capacity of a single disk of a hard disk. The larger the single disk capacity, the lower the unit cost and the shorter the average access time. For users, the capacity of the hard disk is like the computer memory, and it will never be too much.2) Rotational SpeedRotational speed, or spindle speed is the rotation speed of the motor spindle in the hard disk, which is the maximum number of revolutions that the hard disk platter can complete in one minute. It is one of the important parameters indicating the grade of the hard disk. It is one of the key factors that determine the internal transmission rate of the hard disk, and directly affects the speed of the hard disk to a large extent. The faster the rotation speed of the hard disk, the faster the hard disk can find files. The hard disk speed is expressed in revolutions per minute, and the unit is expressed as RPM(revolutions per minute). The larger the RPM value, the faster the internal transfer rate, the shorter the access time, and the better the overall performance of the hard drive.The spindle motor of the HDD makes the platters to rotate at a high speed, generating buoyancy to make the head float above the platters. Bring the sector of the data to be accessed below the head, the faster the speed, the shorter the waiting time. Therefore, the rotational speed largely determines the read speed of the hard disk.The rotation speed of ordinary hard disks for household use is generally 5400rpm and 7200rpm. High-speed hard disks are the first choice for desktop users. For notebook users, it is mainly 4200rpm and 5400rpm. Although some companies have released 7200rpm notebook hard disks, they are still rare in the market. Users have the highest requirements on server for hard disk performance. The speed of SCSI hard disks used in servers is basically 10000rpm, and even 15000rpm. The performance is much higher than that of household products.A higher speed can shorten the average seek time and actual read and write time of the hard disk. However, as the speed of the hard disk continues to increase, it also brings negative effects such as temperature rise, heavy motor spindle wear, and great operating noise. The speed of notebook hard disks is lower than that of desktop hard disks, which is affected to a certain extent by this factor. The internal space of the notebook is small, and the size of the notebook hard disk (2.5 inches) is also designed to be smaller than that of the desktop hard disk (3.5 inches). The temperature rise caused by the increase in speed puts higher requirements on the heat dissipation performance of the notebook itself. In addition, the noise becomes larger, it is necessary to take noise reduction measures, so more technique requirements on the notebook hard disk productions. At the same time, the increase in speed, while the others remain unchanged, means that the power consumption of the motor will increase, the more electricity is consumed per unit time, and the working time of the battery is shortened, so that the portability of the notebook will be affected. Therefore, notebook hard drives generally use a relatively low-speed 4200rpm hard drive.3) Access TimeThe average access time refers to the time required for the head to reach the target track position from the starting position and find the data sector to be read and written on the target track.The average access time reflects the read and write speed of the hard disk, which includes the seek time and waiting time of the hard disk, that is, average access time = average seek time + average waiting time.The average seek time of the hard disk refers to the time required for the head of the hard disk to move to the specified track on the disk surface. This time is of course as small as possible. The average seek time is usually between 8ms and 12ms, while a SCSI HDD should be less than or equal to 8ms.The waiting time of the hard disk, also known as the Latency, refers to the time that the magnetic head is already in the track to be accessed and waiting for the sector to be accessed to rotate below the head. The average waiting time is half of the time required for the disc to rotate one round, and should generally be less than 4ms.4) Data Transfer RateData transfer rate refers to the speed at which the hard disk reads and writes data, in megabytes per second (MB/s). It includes internal data transfer rate and external data transfer rate.The internal transfer rate is also known as the sustained transfer rate, which reflects the performance of the hard disk buffer when it is not in use. The internal transfer rate mainly depends on the rotation speed of the hard disk.The external transfer rate is also called the burst data transfer rate or the interface transfer rate. It is nominally the data transfer rate between the system bus and the hard disk buffer. The type of hard disk interface is related to the size of the hard disk cache.The maximum external transfer rate of the Fast ATA interface HD is 16.6MB/s, while the Ultra ATA interface hard disk reaches 33.3MB/s.The hard disk using SATA (Serial ATA) port is also called serial hard disk. Serial ATA adopts a serial connection method. The serial ATA bus uses an embedded clock signal and has a stronger error correction capability. Compared with the past, its biggest difference is that it can check the transmission instructions (not just data). Errors are found to be automatically corrected, which greatly improves the reliability of data transmission. The serial interface also has the advantages of simple structure and support for hot swapping.5) Cache MemoryCache memory is a memory chip on the hard disk controller with extremely fast access speed. It is a buffer between the internal storage of the hard disk and the external interface. Since the internal data transfer speed of the hard disk is different from the transfer speed of the external interface, the cache plays a role as a buffer among them. The size and speed of the cache is an important factor directly related to the transmission speed of the hard disk, which can greatly improve the overall performance of the hard disk. When the hard disk accesses fragmented data, data needs to be continuously exchanged between the hard disk and the memory. With a large cache, the fragmented data can be temporarily stored in the cache, reducing the load on the external system and improving the data transmission speed. Hard Drive Classifications1) Mechanical Hard Disk (HDD)HDDMechanical hard disk (HDD) is a traditional hard disk, one of the main storage media for computers. It is composed of one or more magnetic discs made of aluminum or glass, magnetic heads, rotating shafts, control motors, head controllers, data converters, interfaces and caches. When working, the head is suspended on a high-speed rotating disc to read and write data. Mechanical hard disk is a computer storage device that integrates precision machinery, microelectronic circuits, and electromagnetic conversion.2) Solid State Drive (SSD)SSDA solid state drive (SSD) is an array storage composed of multiple flash memory chips plus a main control and cache, and belongs to a hard drive made of an array of solid electronic storage chips. Compared with a mechanical hard disk, the read speed is faster and the seek time is shorter, which can speed up the operating system startup speed and the software startup speed.3) Solid State Hybrid Drive (SSHD)SSHDSolid state hybrid drive is a combination of mechanical hard disk and solid-state hard disk. It uses small-capacity flash memory particles to store commonly used files. Disk is the most important storage medium. Flash memory only serves as a buffer to reduce seek time and improve efficiency. Hard Disk StructureThe hard disk is one of the most important storage for computers. Most of the software needed for the computer to function properly is stored on the hard drive. Because the storage capacity of hard disk is large, it is different from computer memory and optical disk. Hard disks are storage devices based on hard rotating disks used on computers. It stores and retrieves digital data on a flat magnetic surface.Take a Look Inside a Hard Drive1) Magnetoresistive Heads (MR heads)The magnetoresistive head is the most expensive part of the hard disk, and it is also the most important and critical part of the HD technology. The traditional magnetic head is an electromagnetic induction magnetic head that combines reading and writing. However, the reading and writing of hard disks are two completely different operations to limit the hard disk design. The MR head uses a separate head structure: the write head still uses the traditional magnetic induction head (MR head cannot write), and the read head uses a new type of MR head. In this way, during the design, the different characteristics of the two can be optimized separately to obtain the best read/write performance. In addition, the MR head gets the signal amplitude through changes in resistance rather than changes in current, so it is very sensitive to signal changes, and the accuracy of reading data is correspondingly improved. Further more, because the read signal amplitude has nothing to do with the track width, the HD track can be made very narrow, thereby increasing the density of the disc. In addition, GMR heads (Giant Magnetoresistive heads) made of materials with a multi-layer structure and better magnetoresistive effect have gradually become popular.2) Magnetic TrackWhen the disk rotates, if the head is held in one position, each head will draw a circular track on the surface of the disk, called tracks. They are invisible to the naked eye at all, because they are only some magnetized areas on the disk surface that are magnetized in a special way, and the information on the disk is stored along such tracks. Adjacent tracks are not close to each other. This is because when the magnetization units are too close, the magnetism will affect each other, and at the same time it will also cause difficulties for the magnetic head to read and write. For example, a 1.44MB 3.5-inch floppy disk has 80 tracks on one side, and the track density on the hard disk is much greater than this value, usually there are thousands of tracks on one side.The surface of the disk is coated with a magnetic medium used for recording, which are magnetic particles under the microscope. The polarity of tiny magnetic particles can be quickly changed by the magnetic head, and can be maintained stably after the change. The system distinguishes 0 or 1 in the binary system through changes in magnetic flux and magnetoresistance. It is precisely because all operations are performed under microscopic conditions, so if the hard disk is operated at high speed while being shocked by external forces, it may cause irreversible data loss due to the head slaps on the surface of the disk. In addition, the uniaxial anisotropy and volume of the magnetic particles will obviously affect the thermal stability of the magnetic particles, and the thermal stability determines the stability of the magnetic particle, that is, the correctness and stability of the stored data. However, it cannot be increased blindly, because it is limited by the write field that the magnetic head can provide and the signal-to-noise ratio of the medium.3) FanEach track on the disk is equally divided into several arc segments, which are the sectors of the disk. Each sector can store 512 bytes of info. The hard disk drive reads and writes data to the disk  from the sectors. 4) CylinderA hard disk is usually composed of a set of overlapping disks. Each disk surface is divided into an equal number of tracks, and numbered from the "0" on the outer edge. The tracks with the same number form a cylinder. The number of cylinders on a disk is equal to the number of tracks on a disk. Since each disk surface has its own head, the number of disk surfaces is equal to the total number of heads. The so-called CHS of the hard disk, namely Cylinder, Head, Sector. So when the number of CHS of the hard disk is known, the capacity of the hard disk can be determined. The capacity of the hard disk is the number of cylinders and the number of sectors. How Does Hard Disk Work?How Do Hard Drives Work?When the hard disk is working, never turn off the power forcibly, which will cause physical damage to the hard disk and data loss. In addition, with high-speed components in the hard disk, if the high-speed disk is shut down forcibly and suddenly, which is more likely to cause damage to the hard disk. So don't turn on the computer immediately after shutting down. This requires time buffering.When the hard disk is working, try to avoid its vibration, because the distance between the magnetic head and the magnetic disk is very close. If it is subjected to severe vibration, the magnetic head will hit the magnetic disk to damage it, which will make the entire hard drive unusable.In the process of using the hard disk, many users compress files to reduce the use of disk space. This will cause the compressed volume file to continue to grow. The data access speed also slowed down, and the number of reads and writes increased, which would affect the heat generation and stability of the hard disk, even reduce service life.  Hard Drive MaintenanceFirst of all, the impact of dust on the hard disk is not small. If dust is attracted to the circuit board, it will cause unstable operation of the hard disk or damage to internal parts. The functional working status of the hard disk has a great relationship with the temperature. Too high or too low temperature will cause the clock frequency of the crystal oscillator to change, which will cause the circuit components to malfunction. In addition, if the temperature is too low, it will cause the air moisture condenses on the component, causing a short circuit.Second, we need to clear your hard drive regularly. This will increase the speed of your hard drive. If there are too many junk files on the hard disk, the speed will slow down and the tracks may be damaged. However, clean up frequently will also reduce the service life of the hard drive.Finally, it is anti-virus. Viruses are the biggest threat to the files stored on the hard drive. Therefore, once we found that the virus should be cleared up in time and try not to format the hard disk. Using Tips1) Don't shut down suddenly while working.When the hard disk starts to work, it is generally in high-speed rotation, if we suddenly turn off the power in the middle, it may cause violent friction between the head and the platter to damage the hard disk. Therefore, it is necessary to avoid this. When shutting down, you must pay attention to whether the hard disk indicator on the panel is still flashing, only the indicator stops flashing and then hard disk read and write ends, you can turn off the computer.2) Prevent dust from entering.Dust can cause great damage to the hard disk. This is because in a severely dusty environment, the hard disk can easily attract dust particles in the air, causing them to accumulate on the internal circuit components of the hard disk for a long time, which will affect the heat of the electronic components, causing the temperature of the circuit components to rise, and resulting in leakage or burnout of the components.In addition, dust may also absorb moisture, corrode the electronic circuits inside the hard disk, and cause some invisible problems. Therefore, although the volume of dust is small, the harm to the hard disk cannot be underestimated. Therefore, it is necessary to maintain environmental sanitation and reduce the humidity and dust content in the air. In addition, users cannot remove the hard disk cover by themselves, otherwise the dust in the air will enter the hard disk and scratch the platters or heads during read and write operations.3) Temperature ControlAs we all known, temperature affects the service life of the hard disk. A certain amount of heat is generated when the hard disk is working, so there is a heat dissipation problem during use. 20～25℃ is better. Temperature can also cause failure of hard disk circuit components, and magnetic media can also cause recording errors due to thermal expansion.On one hand, when the humidity is too high, the surface of the electronic components may absorb a layer of water, oxidizing and corroding the electronic circuits, resulting in poor contact or even short circuits, and it will also cause the magnetic force of the magnetic medium to change, causing data reading and writing errors. On the other hand, it is easy to accumulate a large amount of static charge generated by the rotation of the machine in low temperature, which will burn out the CMOS circuit, attract dust and damage the head and scratch the disk. In addition, try not to make the hard disk close to strong magnetic fields, such as loud speakers, motors, radios, mobile phones, etc., so as to prevent the data recorded on the hard disk from being damaged due to magnetization.Hard Disk Drive StructureHard Drive Faults1) HD Cooling FanConsidering the heat dissipation effect, many people install hard drive cooling fans for their computer hard drives. However, some low-end fans have obvious vibrations and can transmit vibration to the hard drive. In the long term, it will definitely affect the life of the hard drive.2) Optical DriveThe reading speed of mainstream optical drives has reached more than 50 times speed. When the optical disc rotates at a high speed, the vibration of the optical drive itself will drive the resonance of the chassis, which affects the work of the hard disk. And this kind of high-speed rotation generates a lot of heat, because the optical drive is so close to the hard drive, the heat released from the optical drive will surely increase the temperature of the hard drive.3) Static ElectricityIn the process of repairing the computer, many people hold the hard disk with their hands, but in dry weather, tens of thousands of volts of static electricity may accumulate on the hands of people, which may break down the chips on the circuit board, causing the hard disk to malfunction.4) FormattingIf the computer hard disk has bad sectors, many users will take formatting measures. In fact, low format damages the hard disk greatly. It may cause the proliferation of bad sectors on the disk, and even cause the loss of hard disk parameters, making the hard disk unable to use.5) Power SupplyA low-quality computer will cause the hard drive to be disturbed by voltage fluctuations, especially when the hard drive is reading and writing. If there is a problem with the power supply, a hard drive can be scrapped in an instant.6) Magnetic FieldBecause the hard disk is a device that relies on magnetic media to record data, if it is interfered by the magnetic field of the external environment, it is likely to cause the loss of disk data, so you should try to stay away from the magnetic field environment. Types of Hard Disk InterfacesThere are five categories of hard disk interfaces: IDE, SATA, SCSI, SAS, FC1) IDE (Integrated Drive Electronics)IDE refers to the hard disk drive that integrates the controller and the disk body, and is a hard disk transmission interface. There is another name called ATA (advanced technology attachment).2) SATA (Serial ATA)SATA hard disk is called serial hard disk based on its serial data transmission method. In the process of data transmission, the data line and the signal line are used independently, and the transmission clock frequency remains independent. Therefore, compared with the previous PATA, the transmission rate of SATA can reach 30 times that of parallel. It can be said that SATA technology is not an improvement of PATA technology in a simple sense, but a new bus architecture.3) SCSI (Small Computer System Interface)SCSI invention is mainly because the hard disk speed of the original IDE interface is too slow. In fact, SCSI is not designed specifically for hard drives, in fact it is a bus-type interface, working independently of the system bus.4) SAS (Serial Attached SCSI)SAS is serial attached SCSI, which is a new generation of SCSI technology. Like the popular SATA hard disks, it uses serial technology to achieve higher transmission speeds, and improves internal space by shortening the cable. It is a brand new interface developed after the parallel SCSI interface, which is designed to improve the performance, availability, and expandability of the storage system, and provide compatibility with SATA hard drives.SAS interface tech can be backward compatible with SATA. Specifically, the compatibility of the two is mainly reflected in the compatibility of the physical layer and the protocol layer.5) FC (Fibre Channel)Just like the SCIS interface, FC is not an interface technology designed and developed for hard disks at first. It is specially designed for network systems. However, as storage systems require high speed, they are gradually applied to hard disk systems. FC hard disk was developed to improve the speed and flexibility of multi-disk storage system. Its appearance greatly improves the communication speed of multi-disk system, and it uses optical cable connections between systems in a point-to-point (or switching) configuration. There are something to note: the hard disk itself does not have an FC interface, where the cabinet has, which is interconnected with an optical fiber switch. Note: Get more info from Types of Hard Disk Drive Interface.Can a Computer Run without a Hard Drive?A computer can still function without a hard drive. This can be done through a network, USB, CD, or DVD. Computers can be booted over a network, through a USB drive, or even off of a CD or DVD. When you attempt to run a computer without a hard drive, you will often be asked for a boot device. Should I Buy SSD or HDD?1) According to data read and write speedA computer with the same configuration can reach a read and write speed of about 500M/S with a solid state drive, but about 150MB/S with a mechanical hard drive. The difference is nearly three times the speed, which makes the difference in computer response speed even greater.2) According to data security and shock resistanceSince the mechanical hard disk reads and writes data through the magnetic head to read the disk, it is easy to cause data damage due to the collision of the disk and the magnetic head during high-speed rotation, especially it is in the handling process that the disc may be damaged, so everyone needs to be extremely careful when touching it.3) According to weight and volumeCompared with mechanical hard disks, solid state drives are smaller and lighter in appearance, and has stronger performance and faster transfer speed than mechanical hard drives.4) According to noise and heat dissipationSince the solid state drive is made of flash memory particles, it is not equipped with mechanical parts and flash memory chips, and there is no disk and head mechanical motors, fans, etc., so that it can ensure absolute silence. The heat is also very small, and the heat dissipation is also very fast.5) According to power consumptionSSDs commonly use less power and result in longer battery life because data access is much faster and the device is idle more often. With their spinning disks, HDDs require more power when they start up than SSDs. For example, the general full-speed power consumption of a 3.5-inch mechanical hard disk is about 12W, and a 2.5-inch hard disk is only about 5W. The full-speed power consumption of the solid-state drive is about 10W, its working power is generally 2-3W, less than 1W in standby mode.Although solid state drives are definitely faster than mechanical hard drives from above mentioned, but it doesn’t mean that solid state drives are necessarily better than mechanical hard drives, because in terms of price and capacity, mechanical hard drives are "T" is the unit, and most of the solid-state drives are still in G. Although there are also "T", the price is beyond everyone's expectations. One more thing to note is that it is more difficult to restore data if the solid state drive is damaged, while the mechanical hard drive can restore data through repair. Therefore, in terms of data security, mechanical hard drives have more advantages in storing important data. In short, consider comprehensively according to the actual situations. What the Defferences between HDD and SSD?A hard disk drive (HDD) is a traditional storage device that uses mechanical platters and a moving read/write head to access data. A solid state drive (SSD) is a newer, faster type of device that stores data on instantly-accessible memory chips.Generally, SSDs are more durable than HDDs in extreme and harsh environments because they don't have moving parts such as actuator arms. SSDs can withstand accidental drops and other shocks, vibration, extreme temperatures, and magnetic fields better than HDDs.SSDs commonly use less power and result in longer battery life because data access is much faster and the device is idle more often. With their spinning disks, HDDs require more power when they start up than SSDs. However, when not in use, magnetic drives are more reliable for long-term storage than flash memory ones. Thus, HDDs are more capable of long time storage than SSDs when powered off.While normal HDDs can last about 10 years max in reality, and an SSD lifespan has a built-in time of death. To keep it simple: an electric effect results in the fact that data can only be written on a storage cell inside the chips between approximately 3,000 and 100,000 times during its lifetime.As for price, SSDs are more expensive than hard drives in terms of dollar per gigabyte. A 1TB internal 2.5-inch hard drive costs between $40 and $60, but as of this writing, the very cheapest SSDs of the same capacity and form factor start at around $100.With their ruggedness and low energy consumption, SSDs are becoming more popular with portable PCs. With all the advantages that SSD has over HDD, price, availability and capacity are probably the primary factors constraining the acceptance of this new technology. Note: Get more info from SSD vs HDD: Is an SSD Really Necessary?What is the Lifespan of a Hard Drive?Though the average might be three to five years, hard drives can theoretically last much longer (or shorter, for that matter). If a hard drive works 24 hours continuously, it will be damaged in less than 3 years. After normal use, there should be no problem for 5 or 10 years. During use, the garbage must be cleaned regularly and kept HD cool, so as not to get stuck.As with most things, if you take care of your hard drive, it will better last to its potential. How Much Do Hard Drives Cost?A 1TB internal 2.5-inch hard drive costs between $40 and $60, but as of this writing, the very cheapest SSDs of the same capacity and form factor start at around $100. That translates into 4 to 6 cents per gigabyte for the hard drive versus 10 cents per gigabyte for the SSD.According to market trend, the number of hard drives sold each year has declined recently due to the migration of consumer PCs to SSDs, and also demand for higher-capacity HDDs by exascale datacenters. When demand for HDDs spikes, retailers sell out quickly, and prices increase as dealers come into play. What are the Best Hard Drives?Best Hard Drives at a Glance1️⃣Seagate BarraCuda2️⃣Toshiba X3003️⃣WD VelociRaptor4️⃣WD Blue Desktop5️⃣Seagate Firecuda Desktop6️⃣Seagate IronWolf NAS7️⃣Seagate FireCuda Mobile8️⃣WD My Book9️⃣G-Technology G-Drive

  Op-amp is short for operational amplifier. In practical circuits, they are usually combined with a feedback network to form some kind of functional module. It was named "operational amplifier" because it was used in the early days of analog computers to realize mathematical operations, and the name has been continued to this day. An operational amplifier is a circuit unit named from the point of view of function, and can be implemented by discrete devices or in semiconductor chips. With the development of semiconductor technology, the majority of op amps exist today in the form of a single chip. Nowadays, there is a wide variety of op amps, which are widely used in almost all industries. What is an operational amplifier? Catalog   Working principle of operational amplifier  Why is operational amplifier called op amp? Types of op amp Features of op amp FAQ Working principle of operational amplifier  When an operational amplifier is used, its output is connected to its inverTIng input node to form a negative feedback configuration—negaTIve. The reason is that the voltage gain of the operational amplifier is very large, ranging from hundreds to tens of thousands of times, the use of negative feedback to ensure the stable operation of the circuit. But that doesn't mean the operational amplifiers can't be connected to the positive feedback. On the contrary, in many systems that need to generate oscillatory signals, OP Amp with positive feedback configuration is a common component. Operational amolifier schematic diagram    Why is operational amplifier called op amp? In an actual circuit, the feedback network is usually combined to form a certain functional module. Since it was used in analogue computer to realize mathematical operation, it is named "operational amplifier", which continues to this day. Operational amplifier is a circuit unit based on its function, which can be implemented by discrete devices or semiconductor chips. With the development of semiconductor technology, the vast majority of operational amplifiers are in the form of single chip. Nowadays, there are many kinds of operational amplifiers, which are widely used in almost all industries. History of operational amplifier    Summing amplifier In 1941, the first operational amplifier composed of vacuum tubes was invented by Karl D. Swartzel Jr. Of Bell Labs and got the American patent 2,401,779, named “Summing Amplifier”. Model K2-W In 1952, model K2-W, the first operational amplifier with vacuum tube was sold by George A. Philbrick Researches (GAP/R) in the market. μA702 In 1963, the first operational amplifier in the form of a single IC chip was the μA702 designed by Fairchild Senmiconductors's Bob Widlar, and it was introduced after modification in 1965 named μA709.  μA741 In 1968, Fairchild Semiconductor Inc. Introduced the μA741 still in production, it is one of the most successful operational amplifiers of all the time and one of the very few oldest IC models.   - In 1941, the first operational amplifier composed of vacuum tubes was invented by Karl D. Swartzel Jr. Of Bell Labs and got the American patent 2,401,779, named “Summing Amplifier”. - In 1952, model K2-W, the first operational amplifier with vacuum tube was sold by George A. Philbrick Researches (GAP/R) in the market. - In 1963, the first operational amplifier in the form of a single IC chip was the μA702 designed by Fairchild Senmiconductors's Bob Widlar, and it was introduced after modification in 1965 named μA709.  - In 1968, Fairchild Semiconductor Inc. Introduced the μA741 still in production, it is one of the most successful operational amplifiers of all the time and one of the very few oldest IC models.   Types of op amp - General type: Its performance parameters are suitable for general use (low frequency and slow signal change), such as 741A, LM358 (double OP Amp), LM324 and LF356  with FET as input stage. - High-Z type:The characteristic of this kind of amplifier is that the input impedance of differential mode is very high and the input bias current is very small. The main measure to achieve these targets is to make use of the high input impedance of FET, but the input offset voltage of this kind of operational amplifier is larger. Such operational amplifier have LF356, LF355, LF347, CA3130, CA3140, etc. - Low-temperature drift type:In precision instruments, weak signal detection and other automatic control instruments, the bias voltage of operational amplifier is small and does not change with the temperature. The low temperature drift operation amplifier is designed for this purpose. At present, the commonly used operational amplifier has OP07, OP27, OP37, AD508 and ICL7650 composed of MOSFET device and so on. - High slew-rate type:In fast A/D converter, D/A inverter and video amplifiers, the conversion rate of the operational amplifier must be high, and the BWG of the unit gain bandwidth must be large enough. Common operational amplifier has LM318, 175A and so on. - Low -consumption type: Due to the wide application of portable instruments, low power supply and low power consumption must be used. Commonly used low-power operational amplifier has TL-022C,TL-160C and so on. - High voltage and power type:The output voltage of operational amplifier is mainly limited by power supply. In ordinary operational amplifier, the maximum output voltage is only dozens of volts and the output current is only dozens of Ma. In order to increase the output voltage and current, the auxiliary circuit must be added to the external circuit of the operational amplifier. High-voltage and high-power operational amplifier can output high voltage and high current without any additional circuit.   Features of op amp The input resistance is very high, the output resistance is very small, the voltage magnification is very large, and the zero drift is very small. Characteristics of ideal operational Amplifier in Linear region - Virtual Ground: When the operational amplifier is in a linear state, the potential of the inverse input is zero. - Virtual Short Circuit: When the operational amplifier is in a linear state, the two input terminals can be regarded as equipotential, which is called virtual short circuit. But both sides are not real short circuit. - Virtual Open Circuit: When the operational amplifier is in a linear state, two input terminals can be regarded as equivalent open circuit, which is called virtual open circuit. Obviously, it doesn’t break the two inputs actually.   FAQ   1. What is an op amp used for? What is an Operational Amplifier (Op-amp)? An operational amplifier is an integrated circuit that can amplify weak electric signals. An operational amplifier has two input pins and one output pin. Its basic role is to amplify and output the voltage difference between the two input pins.   2. What is op amp in electronics? An operational amplifier (op amp) is an analog circuit block that takes a differential voltage input and produces a single-ended voltage output. ... The inverting input is denoted with a minus (-) sign, and the non-inverting input uses a positive (+) sign.   3. How do op amps work? An operational amplifier only responds to the difference between the voltages on its two input terminals, known commonly as the “Differential Input Voltage” and not to their common potential. Then if the same voltage potential is applied to both terminals the resultant output will be zero.   4. What is a 741 op amp used for? The most common Op-Amp is the 741 and it is used in many circuits. The OP AMP is a 'Linear Amplifier' with an amazing variety of uses. Its main purpose is to amplify (increase) a weak signal - a little like a Darlington Pair. The OP-AMP has two inputs, INVERTING ( - ) and NON-INVERTING (+), and one output at pin 6.   5. What are the characteristics of op amp? -Infinite open-loop gain G = vout / v. in -Infinite input impedance Rin, and so zero input current. -Zero input offset voltage. -Infinite output voltage range. -Infinite bandwidth with zero phase shift and infinite slew rate. -Zero output impedance R. out -Zero noise. -Infinite common-mode rejection ratio (CMRR)   6. Where are op amps used? Op-amps are linear devices that are ideal for DC amplification and are used often in signal conditioning, filtering or other mathematical operations (add, subtract, integration and d3.   7. What is operational amplifier and its types? An operational amplifier (op amp) is an analog circuit block that takes a differential voltage input and produces a single-ended voltage output. Op amps usually have three terminals: two high-impedance inputs and a low-impedance output port.   8. Why is it called operational amplifier? Op-amp stands for operational amplifier. ... Originally, op-amps were so named because they were used to model the basic mathematical operations of addition, subtraction, integration, differentiation, etc. in electronic analog computers. In this sense a true operational amplifier is an ideal circuit element.   9. What is the difference between amplifier and operational amplifier? Amplifiers can be either electronic or mechanical in common definition whereas operational amplifiers are electronic amplifiers. Amplifiers, in general, have a limited capability of amplifying DC signals but all op-amps are capable of amplifying DC signals.   10. What is the main function of operational amplifier? An operational amplifier is an integrated circuit that can amplify weak electric signals. An operational amplifier has two input pins and one output pin. Its basic role is to amplify and output the voltage difference between the two input pins.   11. What are the advantages of operational amplifier? Advantages:  1. increased circuit stability 2. increased input impedance  3. decreased output impedance  4. increased frequency bandwidth at constant gain.   12. What are op amps used for in real life? Op amps are widely used in amplifiers oscillators, filters, comparators, integrators and differentiation,voltage regulator, current regulator. Non linear applications include precision rectified log amplifier . It is also used in analog to digital and digital to analog converter.   13. Where are operational amplifiers used? Operational amplifiers are linear devices that have all the properties required for nearly ideal DC amplification and are therefore used extensively in signal conditioning, filtering or to perform mathematical operations such as add, subtract, integration and differentiation.   14. What is an ideal operational amplifier? Operational amplifier: The ideal op amp is an amplifier with infinite input impedance, infinite open-loop gain, zero output impedance, infinite bandwidth, and zero noise. It has positive and negative inputs which allow circuits that use feedback to achieve a wide range of functions.   15. Why does an operational amplifier need a power supply? Operational amplifiers have two power supply rails because they usually need to swing bipolar - output voltages that go either positive or negative in response to the normal range of input signals. ... Without the dual supplies the output signal would clip at the ground potential.   16. How op-amp can be used as a differentiator? An op-amp differentiator is an inverting amplifier, which uses a capacitor in series with the input voltage. ... Differentiators have frequency limitations while operating on sine wave inputs; the circuit attenuates all low frequency signal components and allows only high frequency components at the output.   17. Is an op amp a transistor? Well for starters, an op amp is simply a combination of transistors, so by varying the transistor you can get different properties. One thing to also remember is that op amps are class A amplifiers which basically means that they are always on and therefore drawing power which can be undesirable.   18. Why is op amp a versatile device? Op Amps or operational amplifiers, are fundamental building blocks in electronic design, mainly because these analog integrated circuits (ICs) are very versatile. ... The term “differential amplifier,” for instance, simply means that the op amp will try to amplify any difference between the signals.   19. Does op amp need ground? An Op Amp inverting input (-) is at zero potential (A virtual ground), even though it does not have a galvanic connection to ground.   20. What is the difference between real ground and virtual ground? Real ground is when a terminal is connected physically to the ground or earth. where as virtual ground is a concept used in Op-Amps in which a node is assumed to have the potential that of the ground terminal.  

CatalogⅠThe Definition of Fuse Box1.1 What is the fuse box1.2  History and problem of Fuse Boxes1.3 The working principle of fuse boxⅡ The fuse box in a carⅢ How to Replace Fuse Box?Ⅳ The difference of fuse box in UK and North America4.1 United Kingdom4.2 North AmericanⅤFuse Box vs Circuit Breaker5.1 What is the Circuit Breaker5.2 The Difference and ApplicationⅥ Frequently Questions About Fuse Box ⅠThe Definition of Fuse Box1.1 What is the fuse boxFuse boxes are metal boxes that hold fuses, which are safety devices that shut off power when the fuse's design is exceeded. Fuses function by passing an electric current through a metal strip. If the electrical current exceeds the metal strip's limitations, the strip melts and the power is out of work.Figure1: What does the fuse box look like?  1.2  History and the problem of Fuse Boxes Before the 1960s, fuse boxes were commonly installed in homes. The majority of them have now been replaced with electrical panels.Fuse boxes are likely unmaintained and have numerous electrical wiring issues, such as cloth wiring or knob & tube, due to their age.Furthermore, because fuses had to be replaced every time one blows, many electricians upgraded/recommended that homeowners install electrical panels. Finally, fuses quickly earned a bad reputation among insurance companies due to homeowners replacing fuses with sticks of copper or larger-than-necessary fuses in order to stop blowing fuses. If the overloaded current continues to flow rather than being shut off, replacing fuses with oversized fuses or pieces of copper can quickly become hot and start a fire. 1.3 The working principle of fuse boxFuse boxes can protect electrical circuits from damage and short circuits caused by exposure to the elements. Fuses are applied to control and protect electrical currents flowing through wires to electrical components.The fuse is connected to a central fuse box, which houses the wiring for the entire home's electricity. Under normal conditions, the fuse allows electricity to freely pass between circuits across the filament. Ⅱ The fuse box in a car Fuse boxes in automobiles consist of engineering plastics such as PVC and PBT. Each material has varying degrees of resistance to high temperatures. Automotive fuse boxes required high-temperature materials because some automotive fuse boxes have to be installed in the engine compartment due to the high temperature during operation. In order to choose the correct fuse box, we should consider the current size of the car fuse used, the size requirements of the fuse, and the raw materials. The majority of vehicles have two fuse boxes. One is in the engine compartment to safeguard engine components such as the cooling system, anti-lock brake pump, and engine control unit. The other is usually located inside or beneath the dashboard on the driver's side of the cab to protect the internal electrical equipment. Avoiding the influence of external factors, the fuse box is equipped with various fuses and relays in a convenient location. Unless the vehicle has significant physical damage or electrical problems, it is usually unnecessary to replace the fuse box.  This vedio shows that how to replace fuse box in a vehicle Ⅲ How to Replace Fuse Box?Materials Needed• Owner's manual• Socket set and wrench• Screwdriver set• Pen and tape for labeling wires (optional but recommended)  Step 1: Unplug the battery cable. Disconnect the negative terminal from the battery. As a result, no electricity will flow through the system during the installation process.Set the negative cable aside in a location where it will not come into contact with any metallic objects. Figure2: battery cable  Step 2: Find and open the fuse box. Locate the fuse panel by opening the hood. It will have a cover over the fuses that you must remove to gain access to the panel.Nota bene: On most makes and models, the fuse function diagram is located on the inside of the panel's lid. It may come in handy at some point. Figure3:Locate the fuse box  Step 3: Turn off the fuse box's power supply. Locate and disconnect the power supply to the fuses once the lid has been removed and set aside.It's possible that the power supply is routed through the bottom. In that case, skip stepping 4 to remove the fuse box housing to gain access to the wires, then return to step 3 before continuing.It is most likely a single or set of red wires connected to a terminal via a bolt, similar to the battery. Remove the connections and set them aside.Note: You may want to tape and label them for ease of reinstallation.  Figure4:power supply  Step 4: Unplug the panel's housing. Remove any bolts that are holding the fuse box in place.They will be located around the perimeter and perhaps different lengths, so pay attention to where each bolt is located as you remove it.Keep bolts in a secure location while working. What is more, keep the bolts together with a magnetic tray, plastic bag, or container until you need them again.  Figure5: the panel's housing   Step 5: Unplug the wiring harnesses and label them. After removing the housing, you'll notice that there are more wires connected to the fuse box and routed to the various systems and sensors they protect. Begin removing them one by one.As you disassemble the panel, it is highly recommended that you label them properly using the fuse diagram. It reduces confusion and protects you from replacing parts that will be damaged by crossed wires.  Figure6: fuse diagram   Step 6: Confirm replacement and fuse transfer. The replacement of fuse box should be rated and designed specifically for your vehicle.  Figure7: the panel's housing  Examine both parts to ensure that your replacement is a perfect match. After you've confirmed this, installing with labeled wires should be a breeze.Use the fuses from the old box if you don't have new fuses and relays for the panel. Make sure that you place them in the exact location for which they are rated. Look to the cover of your panel for guidance on this.   Figure8: check the faulty  Note: Before you decide to reuse your fuses, make sure they are in good working order. Look for a broken filament inside the fuse's viewing window. If it is discolored or broken, the fuse is faulty, and you will need to replace it. Step 7: Reconnect all of the system's wires. After you've installed the fuses, you can begin reconnecting the various wires to all of the systems that the fuses protect.Begin with any in the most difficult-to-reach positions and finish with the easiest ones.If you labeled the wires as you disconnected them, compare the label to the diagram and reconnect the wires. Crossing these wires can result in permanent damage to the systems to which they are connected.Different systems and fuses are rated for varying amperages. After reconnecting the wires, double-check that they are securely connected.  Ⅳ The difference of fuse box in UK and North America4.1 United KingdomOlder electrical consumer units (also known as fuse boxes) in the United Kingdom are installed with either semi-enclosed (rewirable) fuses (BS 3036) or cartridge fuses (BS 1361). (Consumers usually received short lengths of 5 A-, 15 A-, and 30 A-rated wire wound on a piece of cardboard.) Modern consumer units typically use miniature circuit breakers (MCBs) rather than fuses, though cartridge fuses still worked in some applications where MCBs are prone to nuisance tripping. 4.2 North AmericanFuse boxes were used in buildings wired before 1960 in North America. These Edison base fuses, like Edison-base incandescent lamps, would screw into a fuse socket. 5 amperes, 10 amperes, 15 amperes, 20 amperes, 25 amperes, and 30 amperes were Later fuse boxes included rejection features in the fuse-holder socket, commonly known as Rejection Base (Type S fuses), which have smaller diameters that vary depending on the rating of the fuse, to prevent the installation of fuses with an excessive current rating. This means that only the preset (Type S) fuse rating can be used to replace fuses.This is a tri-national North American standard (UL 4248-11, CAN/CSA-C22.2 NO. 4248.11-07 (R2012), and NMX-J-009/4248/11-ANCE). By screwing in a tamper-proof adapter, existing Edison fuse boards can be easily converted to only accept Rejection Base (Type S) fuses. This adapter screws into the existing Edison fuse holder and has a smaller diameter threaded hole to accept the Type S rated fuse. ⅤFuse Box vs Circuit Breaker5.1 What is the Circuit BreakerA circuit breaker is another genre of safety device that has an internal switch mechanism that tripped automatically in the case of an electrical surge. An electromagnet or a bimetallic strip connected to a simple switch is applied to the basic residential circuit breaker.When the switch is ON, an electrical current can flow from a bottom terminal to an upper terminal. Unsafe levels of electrical current in an electromagnet generate a magnetic force strong enough to turn a metal lever in the switch to OFF, breaking the current. Bimetallic strips consist of two strips of two different metals; excessive current causes the thinner of the two strips to bend, causing the switch to be thrown to the off position and the connection to be broken.Circuit breakers, unlike fuses, can be reused. To re-establish the flow of electricity to the home, simply turn the circuit breakers back to the ON position. This simple switch action makes it simple to manually turn off electricity to individual circuits when working on the wiring in a specific part of the home. 5.2 The Difference and ApplicationFuses are generally more inexpensive and  Many hardware stores can purchase them. However, circuit breakers have other applications as well, protecting against more than just overheating, such as against electric shock as well.Check out the main differences and applications in the table below, based on practical factors like operation time and functionality.CharacteristicsFuse Box  Circuit BreakerFunctionDetection&interruptionInterruption OnlyOperation PrincipleBased on a conducting material’s healing propertyBased on an electromechanical principle – a switching mechanismOperation Mode•  Completely automatic• Needs manual replacement after the operation     • Needs comprehensive equipment (relays) for automatic operation• Resets quickly after the operationResponse Time~ 0.002 seconds0.1-0.2 secondsBreaking CapacitySmallLargeRepresentationProtection Protects against overload Protects against overload & short-circuits  ApplicationLow current electronic equipmentLarge current power equipment  Ⅵ Frequently Questions About Fuse Box 1. Is a fuse box necessary?Fuses leave more room for DIY errors.Putting a larger size fuse in the box than what it is equipped for can lead to electrical fires. Since circuit breakers do not need to be replaced, they do not have the same danger. 2. What is the fuse box called?consumer unitA fuse box, also sometimes known as a consumer unit, should be easy to find and is where the electricity in your home is controlled and distributed. 3. How long does a fuse box last?It is a potential lifesaver as it can detect small leakage currents in the range of 5–30 mA and can disconnect in less than 300ms which may prevent electrocution and injury. If your fuse box is greater than 25 years old it may not have an RCD. 4. Which is better fuse box or circuit breaker?In terms of circuit breaker vs fuse box, a circuit breaker is more advanced and can be used over and over again. While they don't respond as quickly as fuses, circuit breakers do not have to be replaced. The exception, of course, is replacing older or outdated circuit breakers. 5. Are fuse boxes still legal?Fuses have not been installed in homes for many decades. Electrical codes change every three years to continually improve the safety of electrical systems that are installed. As a result, no fuse panel currently in use in any home in the United States would comply with minimum code standards in effect today. 

Catalog IntroductionⅠ What is the Wireless HDMI Transmitter?  1.1 What is the Wireless HDMI Transmitter?  1.2 How do the Wireless HDMI Transmitter and receiver work?  1.3 How to Setup a Wireless Video HDMI Kits?Ⅱ The Best Wireless HDMI Video TransmitterⅢ Wired vs Wireless Video HDMIⅣ Why Use Wireless Video HDMI Ⅴ 9 Advantages to Choose the Wireless HDMIⅥ A Note about 4K Wireless HDMI SystemsⅦ Things to Consider when Buying a Wireless HDMI Video Transmitter Ⅷ Pros and Cons of Replacing HDMI Cables  with Wireless Video HDMIⅨ FAQIntroductionHDMI cables connect televisions to source devices like cable boxes, Blu-ray/DVD players, gaming consoles, and other media players. They allow you to send audio or video data from the source device to your television. HDMI is a universally recognized connector for digital home entertainment. This article will go over Wireless HDMI Transmitter and Receiver in greater detail.Ⅰ What is the Wireless HDMI Transmitter?1.1 What is the Wireless HDMI Transmitter?A Wireless HDMI Transmitter eradicates the need for an HDMI cable by sending the HDMI signal over low band frequencies. Wireless HDMI Transmitters  perform admirably due to a technology known as "Dynamic Frequency Selection," or DFS. This technology actively monitors the radio frequency spectrum in order to identify and select an available channel. This method selects the best frequency with the least amount of traffic interference for transmitting/receiving the HDMI signal. DFS contributes to the production of a dependable, high-quality HD or 4K signal with only 1 ms of latency; essentially, a blink of the eye. Watch the video below for a two-minute breakdown of how a Wireless HDMI Transmitter works. Wireless HDMI Transmitters  transmit audio, but what audio formats are supported? If you want to connect to a Dolby/DTS 5.1 or 7.1 surround sound system, make sure the extender supports the audio formats you're looking for. It's critical to get the right extender for your situation. We have yet to discover a Wireless HDMI Transmitter that supports Dolby Atmos, but we are confident that one is on the way.1.2 How do the Wireless HDMI Transmitter and Receiver Work?The HDMI video transmitter and receiver are two separate devices that work together to perform different functions.Transmitter and ReceiverA wireless data signal stream is transmitted by a transmitter.The data is received by a receiver and then streamed to your television.That's all there is to it.The wireless video HDMI transmitter communicates with the video or audio source device. This is typically a set-top box, Blu-ray player, gaming PlayStation, or other portable media. Following that, the transmitter sends a wireless signal from your source device to the receiver.The receiver is the device that connects to your television. The audio/video data stream is then wirelessly received from the transmitter up to 150 feet away and displayed on the TV. As a consequence, you can have your TV in an extremely separate mode.1.3 How to Setup a Wireless Video HDMI KitsIt's easy to set up a wireless video HDMI kit, such as ScreenBeam's wireless TV. A transmitter is connected to a media source device, and a receiver is connected to your TV or other display. The video stream is then wirelessly transmitted to the receiver by your transmitter.Wireless HDMI Transmitter and Receiver KitsConfiguring the Transmitter:Choose the Source Device (cable box, Blu-ray player, or other media player) from which you want to send a signal to your television.Connect your Source Device to the transmitter with a short HDMI cable.Connect the transmitter's power supply to a power outlet.Installing the Receiver:Connect your HDTV to the receiver with a short HDMI cable.Connect the receiver's power supply to a power outlet.You're ready to stream once all of your devices are turned on and the TV input is set to the appropriate HDMI connection.Ⅱ The Best Wireless HDMI Video TransmitterVideo: the Best Wireless HDMI TransmitterRunning a video cable between the source and the TV (or projector) isn't always feasible or convenient, especially if they're in different rooms. Since many wireless HDMI options can send an AV signal across a single room, we prefer the Iogear GW3DHDKIT Wireless HDMI Digital Kit since it reliably transmits the signal around the house, up to 100 feet, and has much more characteristics than other comparably priced systems.Wireless TransmitterThe Iogear GW3DHDKIT Wireless HDMI Smart Kit is a low-cost, easy-to-use solution for wirelessly transmitting 1080p and 5.1 HDMI video or audio signals across the room or around the house without sacrificing quality. The base unit has two HDMI inputs or one HDMI output, allowing you to connect multiple sources at the same time, and it can be powered via a USB 3.0 port.Ⅲ Wired vs Wireless Video HDMIThe primary distinctions between wired and wireless video HDMI are aesthetics and the ability to position your TV wherever you want in your home or business.Both are capable of transmitting high-quality video and audio (including 4K).Wired HDMI is a wired connection between the media source device and the TV display that uses an HDMI cable. Moreover, messy cables dangling from the TV to the media player can be unsightly in homes or businesses with wall-mounted TVs. Of course, one option is to drill holes in the walls and invest in somewhat costly installations to conceal cables.Wireless Video HDMI uses transmitters and receivers to transmit HD video and audio from a set-top source to a television. The setup is simple, and this method gives you a lot more flexibility in terms of where you can put your TV.Ⅳ Why Use Wireless Video HDMI The main reasons you might need to switch to wireless video HDMI are convenience and the elimination of wire clutter! Typically, the area around your television is littered with dozens of cables running this way and that. This solution aids in the removal of clutter.Locate, locate, locate! Another significant advantage of wireless video HDMI is the ability to send a signal to your TV from a different room than the source, whether it is your Roku box or some other device.Wireless Video HDMI is not really useful at home; it's also useful at the office. In seconds, users could even stream a presentation from the laptop to the conference room projector or TV. Wireless video HDMI has a plethora of applications.Learn about ScreenBeam's MyWirelessTV2, which allows you to place the TV virtually anywhere in the home or business without having to worry about cable clutter.Ⅴ 9 Advantages to Choose the Wireless HDMI1Stream images and videos in 4K HD 3D quality.2It is wireless and does not require Bluetooth.3No need for any APP, just plug and play.4Dual antenna support for 5G high speed. Long signal range of up to 98ft / 30M.5Transmits through walls, floors, and ceilings.6The receiver has HDMI, VGA, and audio ports. can work with external audio.7If you use your phone, you only need to connect with the receiver directly.8Portable and easy to transport while on business.9Can be used extensively in our daily lives for business, home theater, education, games, conferences, and so on. Business Applications: This transmitter and receiver kit can be used as a conference tool to increase meeting efficiency. A 4K transmitter is an excellent option for extending the NFL /MLB/NBA/MLB/Olympic Games...Home Use: Users can stream high-quality pictures/movies/videos to their family/lovers/friends using these wireless HDMI kits.Ⅵ A Note about 4K Wireless HDMI SystemsDVDO and IO Gear, for example, have introduced or announced 4K-capable wireless HDMI systems such as the DVDO Air 4K and the Iogear GW4K30GH60 and GW4K30KIT. At the moment, no 4K-friendly system that we are aware of can wirelessly transmit HDR, and only a select few can support a full 4K/60 signal. We are hesitant to make a selection in this category because these wireless systems cannot provide the full UHD/HDR experience. We still recommend using an 18 Gbps HDMI cable for in-room setups to get the most stable signal; for long-distance UHD/HDR setups, users might consider an HDMI-over-fiber-optic system like this reasonably priced Monoprice option.Ⅶ Things to Consider when Buying a Wireless HDMI Video Transmitter  A wireless HDMI video transmitter  can be used for a variety of purposes, including newsgathering and covert wireless video links. Here's how to get a good one:PowerMake sure that the production is high and the consumption is low when it comes to power. In fact, look for a transmitter that uses less than 10W of DC power to produce the desired output.Weight, size, and other considerationsLook for a lightweight transmitter that you can use no matter where you are. Furthermore, it must be compact so that it can be carried with you if necessary. Also, make certain that you can use the transmitter in areas with high heat. As a result, it must run cool for obvious reasons.User controlIf necessary, you should be able to change the preset channel locations. In fact, changing other parameters should be possible for you as well. You'll need to find a wireless HD video transmitter  with several preset channels as well as a PC GUI for this.ChoosingThere are times when you must choose between standard and infrared cameras. However, you can only do this if the transmitter accepts two video inputs rather than one.Enhanced usabilityIf you want to improve the usability of such applications that require both command and control, you can include an optional transceiver.TransmissionCheck that the wireless HD video transmitter  can send video to multiple receivers at the same time.QPSK modulation Search for a transmitter with strong QPSK  modulation, especially for digital broadcast radio wireless links in noisy conditions. Ⅷ Pros and Cons of Replacing HDMI Cables  with Wireless Video HDMIHDMI cables are used to connect media devices (DVRs, cable boxes, Blu-ray players, gaming consoles, and so on) to television to achieve multimedia content.So you're considering ditching traditional HDMI cables in favor of a wireless video HDMI solution. Before purchasing a wireless video HDMI kit, it is critical to understand what to expect from such a setup, including the benefits and drawbacks. First, the happy news...ProsGet Rid of Cable Clutter. Traditional HDMI cables look cluttered and unappealing. When you use wireless video HDMI, you can create a more organized and simplified environment around your TV. This is essential not only at home but also in the workplace.Quality of the connection. Your wireless video HDMI setup will provide high-quality video. Some kits can produce 1080p60 HD video, while others can produce 4k video. In other words, you can go wireless without having to worry about image or sound quality.Setup and use are simple. Wireless Video HDMI is simple to set up. Connect a transmitter to your media player and a receiver to your television.Wireless Video HDMI allows you to place your media device and TV wherever you want. Set up your Blu-ray player in one room and place your TV anywhere within a 150-foot range. Without such limitations of HDMI cables, this could be on a media stand or a wall mount.There is no need for a home Wi-Fi network. Wireless video HDMI, like an HDMI cable, does not demand a home Wi-Fi network, so if your internet goes down, you will still be able to access all of your devices.ConsConnection Quality. How can this be both a pro and a con? Depending on your circumstances, some variables can lower the quality of your connection. Often these wireless video HDMI kits get a range of 100 to 150 feet. Going beyond that range, or through more than two or three walls or floors, can reduce the connection's quality. Floors and walls made of brick, cement, metal, or stone can also degrade quality.Wireless connectivity is a low-cost investment. Wireless Video HDMI transmitter  and receiver kits can cost up to $150. It is crucial to decide whether the pros listed above provide the value you seek.Wireless Video HDMI kits, such as MyWirelessTV2, are available from a variety of online retailers, including eBay and Amazon.Ⅸ FAQ1. Are wireless HDMI transmitters any good?Most common wireless HDMI transmitters can send Full HD 1080p video quality. However, as wireless technology develops, like new Wi-Fi protocols and 5G, you can expect higher quality video to be available. As a matter of fact, some makers now offer 4K video quality transmission with their wireless HDMI extender.2. What's the difference between transmitter and receiver?Simply put, the main difference between a transmitter and a receiver is that a transmitter gathers and decodes information and the receiver displays the information in an audible and/or visual form that consumers can view or listen to. The most well-known and oldest of inventions to use this system is the radio.3. How do I connect my wireless receiver to my TV?In order to connect your TV to your receiver, simply connect an audio output port from your TV to an auxiliary input port on your home stereo receiver. When you turn on your TV, also turn on your stereo receiver and select that auxiliary input and you can enjoy improved sound.4. How do I connect my HDMI receiver to my TV?Make sure that the TV and receiver are connected using an HDMI cable. Connect the cable to the HDMI port that is labeled ARC or the port identified in your manual that supports ARC. Turn on the Control for HDMI setting on both the TV and the receiver or home theater system.5. What is electronic receiver?Receiver, in electronics, any of various devices that accept signals, such as radio waves, and convert them (frequently with amplification) into a useful form.6. How can I get signal on my TV?Reset the boxTurn everything off at the wall.Check that all cables are securely and firmly in place.Wait for 60 seconds.Plug your TV box (not the television set) in and turn it on.Wait another 60 seconds, or until the lights on the TV box have stopped flashing.Plug everything else back in and turn it all back on.7. Why is my TV not picking up any channels?First check that your TV is set to the correct Source or Input, try changing the Source or Input to AV, TV, Digital TV or DTV if you haven't already. If your “No Signal” message is not due to incorrect Source or Input being selected, then it's most likely caused by a set up or antenna fault.8. How do you fix a TV that says weak or no signal?Reset the TV boxPower off the TV box.Detach the power cable from the back of the unit, and from the wall outlet or power bar.Wait 30 seconds and then reconnect the power cable to the unit and the power source.Wait up to 2 minutes for the TV box to reboot.Power on your TV box and test it again.9. What causes a weak cable signal?A weak or inconsistent cable TV signal usually indicates that something is wrong with the wiring or the signal itself. Depending on where the problem is, you might be able to fix the problem, or you might have to contact the cable provider to improve the cable TV signal strength.10. How do I split HDMI to multiple TVs?