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IntroductionIn the landscape of modern electronics in 2025, the Zener diode remains a fundamental component for voltage stabilization and reference. Unlike standard diodes, Zener diodes are engineered to operate in the reverse breakdown region. By utilizing the specific breakdown voltage of the PN junction, they maintain a constant voltage across their terminals even when the current varies significantly.Zener diodes serve critical roles as voltage regulators, surge suppressors, and reference elements in power supply circuits. Given their importance, proper maintenance and accurate fault detection are essential skills for technicians and engineers. This guide details how to detect, test, and distinguish Zener diodes using modern troubleshooting techniques.Ⅰ How to Test Zener Diodes with Three Methods?1.1 Resistance Measurement (Basic Health Check)The resistance measurement method describes the basic health of the component—specifically, checking for shorts or open circuits. While modern digital multimeters (DMMs) are standard in 2025, analog multimeters can still be useful for this specific test due to their load characteristics.The Principle: Using an analog multimeter set to the Rx10K block (which typically uses an internal 9V or 15V battery), you can bias the PN junction.Forward Bias: Connect the red probe (negative in analog meters) to the Anode and black to the Cathode. You should see low resistance.Reverse Bias: Connect in reverse. Ideally, the resistance should be high. However, if the battery voltage exceeds the Zener voltage (e.g., a 5V Zener tested with a 9V internal battery), you will measure a resistance drop, indicating the Zener is functioning (breaking down) correctly.Using a Digital Multimeter: Set the meter to Diode Mode. Touch the probes to the diode. In one direction (forward bias), you should see a voltage drop between 0.6V and 0.8V. In the reverse direction, it should show "OL" (Open Loop) unless the Zener voltage is lower than the meter's test voltage (rare in modern DMMs). If you read 0.000V in both directions, the diode is shorted.1.2 Voltage Measurement (The Most Accurate Method)To determine the exact Zener voltage (Vz), testing the component "live" or in a test circuit is required. This is the professional standard for verifying if a Zener diode is drifting or operating within tolerance.Procedure:Connect a DC Power Supply in series with a current-limiting resistor (e.g., 1kΩ to 10kΩ) and the Zener diode (Reverse Biased).Set the power supply voltage higher than the expected Zener voltage.Use a digital multimeter in DC Voltage mode to measure across the Zener diode.Result: If the reading matches the component's rated voltage (e.g., 5.1V, 12V), the diode is healthy. If the voltage fluctuates significantly or equals the input voltage, the diode is faulty.1.3 Measuring High-Voltage Zeners (Insulation Tester)For industrial Zener diodes with high regulation voltages (above 20V or 50V), a standard multimeter's test voltage is insufficient. In these cases, a Megger (Insulation Resistance Tester) or a high-voltage DC supply can be used.Method: Connect the Megger leads to the diode (reversed). Slowly generate voltage. When the resistance reading stabilizes at a specific voltage drop, that represents the Zener breakdown voltage. Warning: Ensure the current is limited to prevent destroying the device, as Meggers can output high voltages meant for insulation testing, not semiconductor characterizing.Figure 1. Standard Zener Diode SymbolⅡ How to Measure the Leakage of Zener Diode?Leakage current is a silent killer in precision circuits. A Zener diode might pass a basic voltage test but fail under load or temperature changes due to excessive leakage.Advanced Testing: A standard multimeter cannot effectively detect minor leakage. Instead, use a Curve Tracer or an Oscilloscope with a component tester function. By applying a reverse voltage gradually, you monitor the current. A healthy Zener should conduct negligible current until it hits the "Knee Voltage." If the current rises linearly before the breakdown voltage, the diode is "leaky" (soft breakdown) and should be replaced.Ⅲ How to Figure the Polarity of the Zener Diode?Correct installation is vital. Here is how to identify the Anode (+) and Cathode (-):Visual Inspection (Through-Hole): Look for the black or blue band on the glass/plastic body. This band indicates the Cathode (-) side.Visual Inspection (SMD): On Surface Mount Devices, the Cathode is usually marked with a white bar or a chamfered edge.Multimeter Test: Set to Diode Mode. Place probes on terminals. The orientation that gives a reading (approx 0.7V) indicates the Red probe is on the Anode and the Black probe is on the Cathode.Figure 2. Zener Diode Regulator ConfigurationⅣ How to Identify Color Code Zener Diode?While many modern diodes have the part number printed directly (e.g., "5V1" or "1N4733"), older glass-passivated diodes use color bands similar to resistors.The color bands typically represent the JEDEC type number (e.g., 1Nxxxx). Alternatively, in the European BZX series, bands may denote voltage: Example: A diode with Brown (1) and Red (2) bands might represent 12V (depending on the specific manufacturer coding system). Always cross-reference with a datasheet or use a modern SMD/Component Tester (LCR Meter) to verify the breakdown voltage automatically.Ⅴ How to Distinguish Zener Diodes and Ordinary Diodes?Physically, Zener diodes and standard signal diodes (like the 1N4148) often look identical (small, glass, orange/red body with a black band).The Distinction Test: The defining characteristic is the Reverse Breakdown Voltage.Standard Diode: Will block reverse voltage up to very high limits (e.g., 100V+). Under a 12V reverse test, it acts as an Open Circuit.Zener Diode: Will conduct current when the reverse voltage exceeds its rating (e.g., 5.1V).Practical Trick: Apply 12V DC via a 1kΩ resistor to the diode in reverse. Measure the voltage across the diode. If it reads ~12V, it is likely a standard diode. If it reads a lower, stable voltage (e.g., 5.1V, 9.1V), it is a Zener Diode.Figure 3. Zener Diode Voltage Regulator CircuitⅥ FAQ1. How do you identify a 12V Zener diode?The most reliable method is to place the diode in a reverse-biased circuit with a power supply set to roughly 15V-20V and a series resistor. If the voltage across the diode clamps and stabilizes at approximately 12V, it is a 12V Zener. If you use a standard multimeter diode test, it will only show the forward voltage drop (~0.7V), which does not reveal the Zener voltage.2. How do you know if a Zener diode is bad?Common Failure Signs:Short Circuit: Reading 0Ω or 0V in both directions (most common failure).Open Circuit: Reading "OL" in both directions.Drift: The diode regulates voltage, but at the wrong value (e.g., a 5V Zener regulating at 3V or 8V).3. What is the difference between a rectifier diode and a Zener diode?A standard rectifier diode is designed to conduct current in only one direction (Forward Bias) and block voltage in the reverse direction. A Zener diode is designed to conduct in the forward direction like a normal diode, but also safely conduct in the reverse direction once a specific voltage threshold (Zener Voltage) is reached.4. What happens when a Zener diode is shorted?When a Zener diode fails short, it acts like a straight piece of wire. It allows maximum current to flow in both directions with zero resistance. In a power supply circuit, this usually causes the fuse to blow or the series resistor to overheat and burn out immediately.5. Can I test a Zener diode in-circuit?In-circuit testing is often inaccurate due to parallel components (capacitors or other resistors) affecting the reading. However, you can check for a dead short. If you measure 0Ω across the Zener while it is on the board, it is likely dead. For accurate voltage testing, lift one leg of the component off the PCB.6. Why is a Zener diode used in reverse bias?Zener diodes are heavily doped. This doping creates a very thin depletion region that allows electrons to tunnel across the junction when a specific reverse voltage is applied (Zener Effect). This property is what provides the stable reference voltage required for regulation.7. What happens if you forward bias a Zener diode?If you connect a Zener diode in forward bias (Anode to Positive), it behaves exactly like a standard silicon diode. It will conduct current with a voltage drop of approximately 0.7V. It does not provide voltage regulation in this orientation.8. How do I identify an SMD Zener diode?SMD (Surface Mount Device) Zeners are often too small for full part numbers. They use Marking Codes (typically 2 or 3 alphanumeric characters). You must look up this code in an "SMD Codebook" or datasheet to identify the voltage rating. Visually, they often come in SOT-23 (3-leg) or SOD-123 (2-leg) packages with a band marking the cathode.

"Ⅰ What is a Fuse Amperage Rating?", "Ⅱ 1 Amp Fuse" -> "Ⅱ What is a 1 Amp Fuse Used For?", and similar updates for sections Ⅲ through Ⅸ to align with Answer Engine Optimization (AEO) question formats.- Missing or improvable schema types detected: Missing Article schema, FAQPage schema, and HowTo schema (for the "How to Calculate Fuse Rating" section).- Sections with vague/unsupported claims: "Rule of Thumb: The fuse should be re-rated roughly 10-15% higher..." (Clarified with standard IEEE/NEC derating context).- Estimated content freshness score: 4/10-->2026 Executive Summary: Selecting the correct fuse amperage is critical for preventing electrical fires and equipment damage in both automotive and residential circuits. This guide covers standard fuse ratings from 1 Amp to 40 Amps, explaining their specific applications, color codes, and wattage capacities. It also provides a step-by-step method for calculating the exact fuse size needed based on wire gauge and continuous load requirements according to modern National Electrical Code (NEC) standards.Ⅰ What is a Fuse Amperage Rating?To choose the appropriate fuse amperage, you must first determine the circuit's full-load steady-state current at a standard ambient temperature of 25° C (68° F). Once the current value has been determined, a fuse rating of 135% of the current value is often chosen (and taken to the next standard value) for standard circuit protection to prevent nuisance blowing. For example, if the normal steady-state current is 10 amps, a 15A fuse is a suitable choice (10 amps x 135% = 13.5 amps; the next higher standard size is 15A). Note: For continuous loads (running 3+ hours), the 2026 National Electrical Code (NEC) typically recommends sizing the protection at 125% of the continuous load.  It's worth noting that if the fuse is utilized in an environment with potentially very high or low ambient temperatures (such as an engine bay or outdoor equipment), the nominal fuse current rating will need to be adjusted.  Fuses are heat-sensitive devices. Heat (generated by overcurrent passing through resistance) is required to melt the fuse element within the casing. The more heat generated, the faster the fuse element melts. Conversely, if less heat is applied, it takes longer to melt the element. If a fuse is exposed to a temperature higher than 25°C, the fuse amperage must be de-rated (adjusted higher) to compensate for the added environmental heat, preventing "nuisance tripping." If the fuse is used at a very low temperature, the element is cooled by the environment, meaning the fuse amperage might need to be lowered to ensure it opens in time during a fault. Rule of Thumb: Based on standard manufacturer derating curves, the fuse should be re-rated roughly 10-15% higher or lower for every 20°C shift in temperature away from 25°C. An example of a fuse re-rating when higher ambient temperatures are present: Normal full-load current1 Amp Normal fuse sizing1.5 Amps (135% of full load current, rounded to next standard)Ambient Temperature65°C (Hot environment)Re-rating Calculation2 Amps (Adjusted to ~130% of the normal fuse rating to handle ambient heat) Ⅱ What is a 1 Amp Fuse Used For?2.1 Basic Information about 1 Amp FuseA 1 amp fuse is a low-current protection device primarily used to safeguard sensitive electronics, low-power LED lighting, and delicate sensor circuits from overcurrent damage. Ceramic or glass fuses with a 1 amp rating provide dependable performance and cost-effective circuit protection. In the UK, they are sometimes used in plugs (though less common than 3A) to protect very thin cables or sensitive devices like electric shavers or toothbrushes from melting or catching fire.  2.2 Frequently Asked Questions about 1 Amp Fuse1. What color is a 1 amp fuse?Fuse color codes depend on the standard (Automotive vs. IEC). For standard automotive blade fuses (ATO/ATC), the current rating is color-coded. ColorRating (ATO Standard)Black (or Dark Green)1 AmpGray2 AmpViolet3 AmpPink4 Amp2. How many watts can a 1 amp fuse handle?This depends on your voltage. The formula is Watts = Volts x Amps.At 230V (UK/EU): 230V x 1A = 230 Watts.At 120V (US): 120V x 1A = 120 Watts.At 12V (Car): 12V x 1A = 12 Watts.(Note: Previous versions of this article referenced 3000 Watts, which applies to a 13A fuse, not a 1A fuse.) 3. Can you replace a 1 amp fuse with a 5 amp fuse?No. If you replace it with a 5A fuse, you will lose the protection the 1A fuse was intended to provide. A 1A fuse protects delicate wires or components. Allowing 5 amps to flow through a circuit designed for 1 amp could cause the device to overheat and effectively become the "fuse" itself, leading to irreparable damage or fire. Ⅲ What is a 3 Amp Fuse Used For?3.1 Basic Information about 3 Amp FuseA 3-amp fuse (colored red in the UK BS 1363 standard) is designed to protect appliances rated up to approximately 700 watts. In the UK, fuse ratings are based on the appliance's power rating. If you need to replace a fuse in a plug, you must use the same rating after remedying the fault. Typical 3A Fuse Applications: Table lamps, standard lamps, televisions, computers, mixers, blenders, fridges, freezers, and soldering irons.  A 13-amp fuse (colored Brown) is used for appliances rated between 700 and 3000 watts. Typical 13A Fuse Applications: Washing machines, dishwashers, microwaves, kettles, toasters, and irons. 3.2 Frequently Asked Questions about 3 Amp Fuse1. How many volts is a 3 amp fuse?Standard household fuses are typically rated for up to 240/250 Volts. Automotive 3A fuses are typically rated for up to 32V. Always check the voltage rating printed on the fuse body. 2. Can I use a 3 amp fuse in a 13 amp plug?Yes, if the appliance requires it. For example, a gas fire might have a standard plug, but the electrical draw is only for the ignition spark (very low current). In this case, the flex cable is likely thin and requires protection by a 3A fuse, even if the plug shell can technically hold a 13A fuse. 3. Radio calls for a 2.5 amp fuse. Can I use 3 amp?Generally, yes. 2.5 Amp fuses can be hard to find in some formats. A 3 Amp fuse is the closest standard value and is usually well within the supply wire's safety tolerance. However, if a 2 Amp fuse is available, that is a safer "step down" if the device is very sensitive, though it may blow more easily. Ⅳ What is a 5 Amp Fuse Used For?4.1 Basic Information about 5 Amp FuseA 5 amp fuse is commonly used in older UK lighting circuits, specific household appliances, and automotive sensor or ECU signal circuits. While modern UK plug fuses are standardized to 3A or 13A, 5 Amp fuses are still widely used in older equipment, lighting circuits, and specific appliances like shredders. In automotive fuse boxes (ATO/Mini), 5 Amp (Tan/Beige) fuses are very common for sensor circuits and ECU signals.  4.2 Frequently Asked Questions about 5 Amp Fuse1. Can you put a 5 amp fuse in a 13amp plug?Yes, physically it will fit (in UK BS1363 plugs). If your appliance draws less than 5 Amps (approx 1100W), utilizing a 5A fuse offers better protection than a 13A fuse. However, standard practice now usually defaults to 3A or 13A. 2. What happens if I put a 5amp fuse in a 13 amp plug?If the appliance draws more than 5 amps (e.g., a kettle), the fuse will blow immediately or shortly after use. The cable will remain safe, but the appliance won't work. If the appliance draws less than 5 amps, it will work normally with added safety. 3. How many watts can a 5 amp fuse take?On a UK 230V circuit (like a lighting circuit): 5A x 230V = 1150 Watts.On a US 120V circuit: 5A x 120V = 600 Watts. 4. Can I replace a 5 amp fuse with a 25 amp fuse?ABSOLUTELY NOT. Replacing a fuse with a higher-amp fuse (like jumping from 5A to 25A) creates a severe fire hazard. The wiring designed for 5 amps will likely melt and catch fire before a 25-amp fuse blows. Ⅴ What is a 10 Amp Fuse Used For?5.1 Basic Information about 10 Amp FuseA 10 amp fuse (typically red in automotive ATO/ATC standards) protects circuits designed to carry a continuous load of 7 to 8 amps, such as car audio systems, cabin lighting, and accessory sockets. A 10 Amp fuse is a staple in both household and automotive circuits. In homes, it is often found in older heating units or specific lighting control boards.  5.2 Frequently Asked Questions about 10 Amp Fuse1. What does a 10 Amp Fuse protect?A 10 amp fuse typically protects a circuit designed to carry roughly 7 to 8 amps continuous load. If you were to use a 30 amp fuse on this same circuit, a fault current of 20 amps would melt the wires without ever blowing the fuse, leading to a fire. 2. Can I use a 5 amp fuse instead of a 10 amp?Yes, this is safe, but it may be annoying. Using a lower-rated fuse (5A) in a 10A slot will not damage the equipment, but the fuse will likely blow during normal operation if the device tries to draw its full power. Ⅵ What is a 15 Amp Fuse Used For?6.1 Basic Information about 15 Amp FuseIn North American residential wiring, a 15 amp fuse or breaker is the standard protection device for general lighting and standard 120V wall outlet circuits wired with 14-gauge copper wire. Ideally, the continuous load should not exceed 80% of the rating (12 Amps). On a 120V circuit, a 15A fuse supports up to 1800W (15A x 120V). For example, a 1100W microwave + 800W of lighting = 1900W. This will blow the 15A fuse. However, a 1100W microwave + one 100W bulb = 1200W, which is safe.  6.2 Frequently Asked Questions about 15 Amp Fuse1. Is it OK to replace a 15 amp fuse with a 20 amp fuse?No. You should never upgrade from a 15-amp fuse/breaker to a 20-amp one just because it keeps tripping. 15-amp circuits are often wired with 14-gauge wire, which is not rated for 20 amps. Allowing 20 amps to flow through 14-gauge wire creates a fire risk inside your walls. 2. Why does my 15 amp fuse keep blowing?Overloading is the most common cause (e.g., plugging a heater and a hair dryer into the same circuit). The second most common cause is a short circuit, where a hot wire touches a neutral or ground wire, causing a massive surge in current that instantly blows the fuse. 3. What happens if you put a 15 amp fuse in a 20 amp slot?This is safe. The fuse will simply blow sooner. If the load on that 20A circuit exceeds 15A, your new fuse will pop, but the wiring will be perfectly safe. 4. Can I replace a 12 amp fuse with a 15 amp fuse?Never replace a fuse with one rated for higher current. If you cannot find a 12A fuse, use a 10A fuse as a temporary fix. Fuses protect the wiring, not just the device. Ⅶ What is a 20 Amp Fuse Used For?7.1 Basic Information about 20 Amp FuseA 20 amp fuse is used to protect heavy-appliance circuits and kitchen outlets wired with 12-gauge wire, allowing for up to 2400 watts of power usage on a 120V system. Kitchen outlets and heavy-appliance circuits in the US are typically wired with 12-gauge wire (yellow sheath) and protected by 20-amp fuses or breakers.  7.2 Frequently Asked Questions about 20 Amp Fuse1. What can happen if I put a 30 amp fuse replacement for a 20 amp fuse?This is a major safety violation. The 12-gauge wire used for 20A circuits cannot safely handle 30A. The wire insulation may melt, leading to arcing and house fires. 2. Can I use a 20 amp fuse instead of 15 in my car?No. If the 15A fuse keeps blowing, there is a problem with the component (e.g., seized wiper motor) or a short. putting in a 20A fuse risks burning out the car's wiring harness, which is extremely expensive to fix. Ⅷ What is a 30 Amp Fuse Used For?8.1 Basic Information about 30 Amp FuseA 30 amp fuse is a high-capacity protection device used for high-demand equipment like electric clothes dryers, RV air conditioners, and high-power aftermarket automotive amplifiers. In homes, they protect electric clothes dryers and some air conditioners (often requiring 10-gauge wire).  8.2 Frequently Asked Questions about 30 Amp Fuse1. Can you put a 30 amp fuse in a 20 amp spot?No. As mentioned before, the wiring for a 20A circuit is not heavy enough to carry 30 amps. You risk fire by doing this. 2. Can I replace a 25 amp fuse with a 30 amp fuse?It depends on the wire size, but generally, no. If the manufacturer specified 25A, it is for a reason. Jumping to 30A reduces the safety margin. 3. Why does my 30 amp fuse keep blowing?In car audio contexts, if a main power fuse blows immediately, the amplifier likely has an internal short in its power supply section. It is not a fuse problem; it is an equipment failure requiring service. Ⅸ What is a 40 Amp Fuse Used For?9.1 Basic Information about 40Amp FuseA 40 amp fuse is a heavy-duty component typically located in a vehicle's main power distribution box to protect major systems like radiator cooling fans, ABS pumps, and ignition mains. 9.2 Frequently Asked Questions about 40 Amp Fuse1. Are all 40 amp fuses the same?No. While the amperage is the same, the physical size varies. Common types include Maxi fuses (large), Standard ATO (medium), and JCase (box-shaped). You must match the physical type to your vehicle. 2. Can I use a 40 amp fuse instead of 30?No. Doing so allows 33% more current to flow than the circuit was designed for, creating a high risk of melting wires. 3. What color is a 40 amp fuse?Color codes depend on the fuse style.Fuse TypeColor for 40 AmpStandard ATO / ATC BladeOrangeMaxi Fuse (Large Blade)OrangeJCase (Cartridge)GreenVintage Ceramic (Continental)Varies (Often not available in 40A, max usually 25A Blue)(Note: The previous version of this article contained a table for specific vintage ceramic/glass fuses. The table above reflects modern automotive standards.) 4. Can I use a 40 amp fuse instead of 25?NO. Replacing a fuse with a significantly higher rating (40A vs 25A) completely defeats the purpose of the fuse.5. Can you replace a 35 amp fuse with a 40 amp fuse?It is risky. 35A is a common size for specific amplifiers or fans. While 5 amps seems like a small difference, it can be the difference between a wire getting warm and a wire melting. Stick to the manufacturer's rating.Ⅹ How to Calculate Fuse RatingIn three easy steps, here's how to calculate fuse size correctly:Find out what wire gauge you are using. This is printed on the wire casing (e.g., 14 AWG, 10 AWG).Find the maximum current for that wire gauge. Note: The table below provides conservative "Chassis Wiring" limits. Residential AC wiring (NEC) limits are stricter (e.g., 14 AWG = 15A max, 12 AWG = 20A max). AWG GaugeMax Current (Chassis Wiring)4135 A6101 A873 A1055 A (Auto) / 30 A (Home)1241 A (Auto) / 20 A (Home)1432 A (Auto) / 15 A (Home)1622 A1816 A2011 A227 A Using the maximum current value, choose a fuse that is lower than the wire's maximum capacity but higher than your device's draw. DO NOT EXCEED THE VALUES OF YOUR WIRE!Ⅺ ConclusionTo conclude, every fuse is designed for a specific amperage rating to protect the weakest link in the circuit (usually the wire). The type of load and code requirements must be taken into account when choosing a fuse. A fuse's amp rating should typically not exceed the circuit's current carrying capacity. For example, if a conductor is rated to carry 20A, the largest fuse that should be used is a 20A fuse.However, exceptions exist, such as motor circuits where "inrush current" (startup power) is high. In these cases, Slow-Blow or time-delay fuses are used to allow a temporary spike (up to 175% or 300% of load) without blowing, while still protecting against long-term shorts. Always adhere to the specific electrical code (NEC or ISO) relevant to your application.Frequently Asked QuestionsHow do I know if a fuse is blown?A blown fuse usually has a visibly broken metal filament inside its transparent casing. You may also see black smudge marks or melting. For opaque fuses, use a digital multimeter set to continuity mode; if the multimeter beeps, the fuse is functioning correctly.What causes a fuse to blow repeatedly?Fuses blow repeatedly due to circuit overloads or short circuits. An overload happens when too many devices draw power simultaneously on a single circuit. A short circuit occurs when a hot wire touches a neutral or ground wire, causing a massive, dangerous current spike.Can a blown fuse cause a fire?A blown fuse itself prevents fires by cutting off power during an overcurrent event. However, replacing a blown fuse with a higher-amperage fuse or bypassing it with wire removes this critical protection, allowing wires to overheat and potentially ignite a severe electrical fire.{ "@context": "https://schema.org", "@graph":[ { "@type": "Article", "headline": "The Best Guide to Amp Fuses: Ratings, Colors, and Calculations", "datePublished": "2023-01-01", "dateModified": "2026-03-20", "author": { "@type": "Organization", "name": "Kynix" }, "publisher": { "@type": "Organization", "name": "Kynix" }, "description": "A comprehensive 2026 guide to understanding fuse amperage ratings, color codes, and how to calculate the correct fuse size for automotive and residential circuits." }, { "@type": "FAQPage", "mainEntity":[ { "@type": "Question", "name": "How do I know if a fuse is blown?", "acceptedAnswer": { "@type": "Answer", "text": "A blown fuse usually has a visibly broken metal filament inside its transparent casing. You may also see black smudge marks or melting. 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CategoryⅠ IntroductionⅡ Development Background  2.1 Limitations of Microwave Oscillators  2.2 Origin of OEOⅢ Working Principle of OEO  3.1 The basic structure of OEO  3.2 Principle-based improvement directionⅣ Operating Characteristics of OEO  4.1 Advantage Performance  4.2 Disadvantage PerformanceⅤ Application of Optoelectronic Oscillator  5.1 Light Pulse Output  5.2 Clock ExtractionⅥ SummaryⅦ FAQ Ⅰ IntroductionThe optoelectronic oscillator (OEO) represents the first practical microwave oscillator that uses optical energy storage elements to generate signals with high spectral purity in the frequency range of several hundred MHz to more than 100 GHz. Many light wave energy storage components, such as fiber Fabry-Perot resonators, fiber ring resonators, optical micro disc resonators, etc. can be used to form OEO. It is a long fiber loop. The use of optical resonators can greatly reduce the size of OEO. Especially the optical microdisk resonator, which is a key component of integrating OEO in a single chip.  Figure1. Opto-Isolator OscillatorⅡ Development Background2.1 Limitations of Microwave OscillatorsGenerally speaking, the quality of the microwave signal generated by the microwave oscillator depends on the energy storage performance of the oscillation cavity. To produce high-quality microwave signals, a high-Q and low-loss energy storage unit is required. Current microwave oscillators are mostly based on electronics (such as dielectric oscillators) and acoustic (such as crystal oscillators) energy storage elements. When these components operate at frequencies above GHz, the energy storage characteristics will drop sharply, and the phase noise and spectral purity of the high-frequency microwaves produced will be poor. 2.2 Origin of OEOIn 1996, XSYao and L. Maleki of the California Institute of Technology Jet Power Laboratory developed a microwave oscillator based on a photonic energy storage unit during the use of photonics technology to improve the performance of a microwave system. This oscillator was named optoelectronic oscillator (OEO). Compared with microwave oscillators based on electronics and acoustic energy storage units, optoelectronic oscillators can generate high-purity microwave or millimeter-wave signals from several MHz to hundreds of GHz, and the Q value of their energy storage elements is as high as 1010, which generates high-frequency signals. The phase noise is as low as -163dBc / Hz at a frequency offset of 10kHz, and has both optical and electrical outputs. It is a very ideal high-performance microwave oscillator and is expected to be widely used in the future. Ⅲ Working Principle of OEO3.1 The basic structure of OEOThe basic structure of the optoelectronic oscillator is shown in Figure 2. It is a positive feedback loop composed of laser, electro-optic modulator, high Q optical energy storage unit (such as a certain length of optical fiber), photodetector, bandpass filter, microwave amplifier, phase shifter and microwave coupler. The energy of the oscillation comes from the injected light in front of the electro-optic modulator. After the injected light is modulated by the electro-optic modulator, it becomes an optical signal carrying a specific frequency. This optical signal is converted into an electrical signal by a photodetector, amplified, and then band-pass filtered. The filter filters out a specific frequency, part of which is used for output, and part of which is fed back into the microwave input port of electro-optic modulation to complete a cycle. After continuous cycling, a stable oscillation is finally formed. Since the optical oscillator uses a high-Q optical energy storage unit such as a low-loss long fiber, the output signal has extremely low phase noise. Figure2. Basic Structure of OEO3.2 Principle-based improvement directionIn addition, the loss in the optical energy storage unit such as optical fiber does not change with the change of microwave frequency, so theoretically the performance of the output signal of the optoelectronic oscillator will not deteriorate with increasing frequency. After nearly two decades of continuous exploration, the research on opto-electronic oscillators has made rapid progress. In the United States, opto-electronic oscillators have been successfully applied in cutting-edge technologies such as drones as high-quality local oscillators.  Nevertheless, in order to obtain a wider range of applications, optoelectronic oscillators need to be continuously improved in terms of performance and stability. Current research on optoelectronic oscillators is mainly focused on reducing phase noise, improving side mode suppression ratio, improving frequency stability, expanding output frequency, improving frequency tuning performance, miniaturization and multi-frequency oscillation, etc.Details are as follows:  (1) Phase NoiseThe phase noise of the output signal of the optoelectronic oscillator mainly comes from the thermal noise, scattered noise, and relative intensity noise of active devices such as lasers, photodetectors, and amplifiers. Phase noise can be reduced by optimizing the structure of microwave photonic links and the way the devices work. In experiments by D. Eliyahu and some others that produced extremely low phase noise (-163 dBc / Hz @ 6kHz) signals, a high power Nd: YAG laser with low relative intensity noise and an array amplifier with low phase noise were used. P.S.Devgan et al. Used low-biased Mach-Zehnder modulators and optical amplifiers to achieve an all-optical gain optoelectronic oscillator.  Compared with optoelectronic oscillators using electric amplifiers, the phase noise of this solution has been improved by 10dB. In addition, the use of high-power photodetectors can effectively reduce white noise, while the use of photodetector arrays to receive signals can effectively reduce the effects of flicker noise.Figure3. Phase Noise Modulation(2) Side Mode SuppressionIn order to obtain microwave output with low phase noise, the resonator of the photo-electric oscillator must have a very high Q value (Q = 2πfτ, f is the center frequency, and τ is the energy decay time), that is, a very large energy decay time is required. A larger τ can be obtained by increasing the fiber length, but as the fiber length increases, the longitudinal mode spacing (Δf = 1 / τ) in the cavity of the photo-electric oscillator decreases（As low as several tens of kHz）, in order to effectively suppress the non-oscillation mode and select a single oscillation frequency, a relatively narrow microwave band-pass filter is required. ①Dual-loop optoelectric oscillatorOne way to suppress side modes is to use a dual-loop optoelectronic oscillator. Two optical fiber loops of different lengths are formed in the cavity of the photo-electric oscillator. Only modes that satisfy the conditions for selecting the two loops at the same time can start oscillation. By selecting appropriate loop lengths, single-mode vibration can be achieved. The dual-loop optoelectronic oscillator scheme can be divided into an optical-domain coupled dual-loop structure and an optical-domain coupled dual-loop structure.  This research group proposed a dual-loop optoelectronic oscillator based on polarization modulation and polarization division multiplexing. The polarization beam splitter not only realizes the conversion of polarization modulation to intensity modulation, but also realizes that the incident light wave is divided into two orthogonal polarization states to form a double loop. The side-mode rejection ratio of the 10GHz signal generated by this solution reached 78dB. Compared with the electric-domain coupled dual-loop scheme, the optical-domain coupled scheme requires only one photodetector. Optical domain coupling dual loop schemes can also be implemented using wavelength division multiplexing technology.Figure4. A Dual-loop Optoelectronic Oscillator②Coupled optoelectronic oscillatorAnother method to suppress side modes is to use a coupled optoelectronic oscillator (COEO). The coupled optoelectronic oscillator includes two parts: an actively mode-locked laser loop and an optical feedback loop. The active mode-locked fiber laser loop can effectively increase the Q value of the oscillator. Therefore, a shorter fiber length can be used to obtain low phase noise. This research group used a non-pumped erbium-doped fiber to achieve a 10.7GHz stable coupled photo-electric oscillator with a phase noise below -120dBc / Hz @ 10kHz. (3) Frequency StabilityThe factors that affect the frequency stability of the optoelectronic oscillator are mainly two aspects:  ①The high-Q components in the system (including long optical fibers and narrow-band electrical filters) are susceptible to changes in the environment, and the output frequency is changed to cause the output frequency. Instability, especially the change of equivalent cavity length caused by environmental factors such as temperature. ②Because the filters used in optoelectronic oscillators usually have a relatively large passband range, they are within the gain bandwidth of the loop. There will be many side molds. One of these side modes may obtain sufficient gain during the change of cavity length to replace the original starting frequency, resulting in unstable starting frequency. In addition, the bias point drift problem of common electro-optic modulators will also affect the stability of the output frequency, but isolating the optoelectronic oscillator from the environment or using a temperature control device can reduce the impact of environmental changes on the system. For example, in experiments of XSYao, the optoelectronic oscillator was placed in a foam-filled box to isolate the influence brought by vibration. The active phase-locked loop circuit control is used to lock the oscillation signal of the optoelectronic oscillator to an external reference source, which can also effectively improve the frequency stability of the optoelectronic oscillator.Figure5. Frequency Stability(4) Working FrequencyTheoretically, the optoelectronic oscillator can generate signals from several MHz to hundreds of GHz, and the phase noise has nothing to do with frequency, but the high-frequency millimeter wave optoelectronic oscillator is difficult to realize. This is mainly due to the use of microwave devices such as photoelectric modulators, microwave couplers, microwave phase shifters, microwave amplifiers, and microwave transmission lines in optoelectronic oscillators, whose operating frequency is limited by electronic bottlenecks. Although there have been recent reports of high-frequency microwave or millimeter-wave devices, these devices are generally expensive, consume large power, and have poor performance. In response to the above problems, M. Shin et al. Used the LiNbO3 Mach-Zehnder modulator's half-wave voltage to the proportional relationship between the wavelength to achieve the simultaneous generation of 10GHz fundamental frequency and 20GHz octave signal. (5) TunabilityIn order to generate a broadband adjustable microwave signal, the optoelectronic oscillator needs to use a broadband adjustable high Q filter, which can be a tunable electrical filter, an optical filter, or a microwave photon filter. Limited by the electronic bottleneck, the tuning range of the output signal of the optoelectronic oscillator using a tunable electrical filter is limited. Optoelectronic oscillators based on microwave photonic filters usually have a large tuning range.Figure6. Schematic of The Tunable Opto-electronic Oscillator(6) Miniaturization ResearchOptoelectronic oscillators usually include laser sources, intensity modulators, long fiber delay lines, photodetectors, electrical amplifiers, electrical phase shifters, electrical bandpass filters, and other electrical or optical devices. These discrete electrical and optical components make the optoelectronic oscillator bulky and cause large power losses. By using high-Q optical resonators (such as whispering wall mode resonators) to replace fiber lengths of several kilometers, the size of the energy storage unit of a photo-electric oscillator can be significantly reduced. (7) Multi-frequency OscillationOptoelectronic oscillators usually only produce a pure single frequency signal. In applications such as wideband channelized receivers and multi-band radars, signals of multiple frequencies are required. In 2012, F. Kong et al. Used a birefringence characteristic of a phase-shifted Bragg grating to implement a dual-frequency optoelectronic oscillator. The disadvantage of this solution is that it can only generate signals of two frequencies, and the system is very sensitive to the environment. If a multi-frequency optoelectronic oscillator based on a single-phase modulator and a multi-wavelength light source are used, a single-passband tunable microwave photon filter can be formed on each optical carrier. By increasing the number of optical carriers, it will be easy to obtain more channels of different frequency signal output. Ⅳ Operating Characteristics of OEO4.1 Advantage PerformanceOptoelectronic oscillator is generally a positive feedback loop composed of light source, intensity modulator, filter and photodetector (PD). It takes advantage of the low loss characteristics of modulators and optical fibers to turn continuous light into stable, clean spectrum RF/microwave signals. The continuous light emitted by the laser is transmitted to the photodetector through the optical fiber after passing through the electro-optic modulator. The photodetector converts the light into an electrical signal and enters the frequency selection, amplification, and feedback modulation device.  During this process, the active device will generate noise disturbances of different frequencies. These disturbances are filtered by the filter at the output to the desired frequency and used to feedback and control the electro-optic modulator. The amplifier in the loop provides gain, and after several cycles of the signal, a stable oscillation can be established, and its oscillation frequency is mainly determined by the passband characteristics of the filter. 4.2 Disadvantage PerformanceAlthough the performance of the optoelectronic oscillator is outstanding, its system composition also determines some of its shortcomings. First of all, in order to obtain a high Q signal output, a long fiber is generally used in the cavity. At this time, the length of the cavity also determines the interval between the oscillation modes. The longer the cavity, the smaller the mode interval. In theory, a sufficiently narrow filter can be used to filter out unwanted modes, but it is quite difficult to obtain the device.  Secondly, in terms of the phase noise of the signal, the relative intensity noise of the light source, the photodetector and the electric amplifier will all affects the phase noise of the resulting microwave signal. Excessive bandwidth of filters and amplifiers will also reduce the signal-to-noise ratio in the passband range and affect the quality of the oscillation frequency.  Finally, because the loop is mainly composed of optical fibers, its cavity length is easily affected by environmental conditions and stress. The change causes the change of the fundamental frequency of the oscillation to cause the output frequency to drift or hop. In addition, the long optical fiber occupies a relatively large volume, which causes obstacles to the miniaturization and integration of the entire optoelectronic oscillator system. Solving the above problems is some of the key work for the final practical use of optoelectronic oscillators. Figure7. Cristal Oscillator Ⅴ Application of Optoelectronic OscillatorThe basic function of the optoelectronic oscillator is to generate high-quality optical and electrical microwave signals, but after being updated, it has also derived some new applications. In these applications, the electrical output of the photo-oscillator basically keeps the microwave signal output, but some changes occur in the light output part.5.1 Light Pulse OutputIn 1997 and 2000, X. Steve Yao and others successively analyzed and demonstrated the hybrid structure (COEO) of the optical resonator and optical oscillator loop provided by SOA to generate electric microwave signals and light pulses. This solution is similar to a regenerative mode-locked laser.  The main difference is that the photoelectric loop of COEO needs to be oscillated, and the final output mode is constrained by the selection of the two loops. In 2007, Ertan Salik demonstrated a COEO structure based on erbium-doped fiber amplifier (EDFA) to provide optical path gain, and obtained a 9.4 GHz microwave signal with ultra-low phase noise of -150 dBc / Hz (at a frequency offset of 10 to 100 kHz). Output and light pulse output with only 2 fs jitter. The optical pulse output mechanism of this structure is based on a fiber mode-locked laser. Therefore, in order to obtain high-performance output, there are high requirements on the design of the cavity length stabilization, dispersion control, and polarization maintenance of the optical cavity. Another feasible solution is to generate light pulses by changing the photoelectric modulation characteristics in the optoelectronic oscillator loop. In 2003, Jacob Lasri et al. Used electro-absorption modulator (EAM) to replace Mach-Zehnder intensity modulation (MZM) in the traditional scheme. By controlling the bias of EAM, a narrow modulation transmission window was obtained. Electric microwave signal and light pulse output. If a multi-wavelength light source is used in the light source part, this structure can also conveniently generate multi-wavelength light pulses. The structure of this scheme is relatively simple, but EAM generally has a large insertion loss, and the resulting pulse width is also wide.Figure8. Electro Absorption ModulatorIn addition, using a semiconductor laser operating under gain switching conditions or using a large-signal direct-modulation as the light source of the photo-electric oscillator, it is possible to obtain an electric microwave signal and an optical pulse output without requiring an additional modulator.5.2 Clock ExtractionBecause the structure of the optoelectronic oscillator has the function of frequency selection and amplification feedback, no matter whether the optical or electrical signal is injected into the optoelectronic oscillator, its clock signal (or frequency-divided clock) can be changed as long as it falls within the passband of the filter. The output can be recovered after locking and regeneration.  The maximum recoverable clock frequency is determined by the center frequency of the filter in the loop and the bandwidth of the modulator and the photodetector. X. Steve Yao et al.  Later, Caiyu Loun and others analyzed the extraction scheme of the frequency-divided clock based on the optoelectronic oscillator in 2002. By using the output electrical signal of the optoelectronic oscillator as a trigger signal to observe the injected optical signal on an oscilloscope, the electrical signal at this time can be determined. Whether the output is a divided clock of the injected signal, and experimentally verified the divided clock extraction under the condition of 10 Gb / s injected signal. In 2005, Hidemi Tsuchida and his partners demonstrated a frequency-divided clock extraction experiment with an injected signal rate of 40 Gb / s and 160 Gb / s. Figure9. Clock RecoveryIt should be noted that this method also provides a new idea for clock extraction of non-return-to-zero (NRZ) signals. In theory, there is no obvious clock component for NRZ signals to be extracted, but as long as the frequency selection of the optical oscillator filter is carefully adjusted. The clock signal of the injected NRZ code signal can be found and generated by the window. Li Huo et al. proposed the clock of the injected 10 Gb / s NRZ code signal, and obtained the converted zero (RZ) at the same time in the optical output part of the optoelectronic oscillator. The EAM-based optoelectronic oscillator can also complete the clock recovery of the RZ code signal. In the experiments demonstrated by Jaoob Lasri et al., In order to obtain the optical clock pulse signal at the same time, a DC light with a wavelength different from the wavelength of the injected signal light was added. Since the power change of the injected signal light will form a periodic switching window on the EAM and transfer the clock information to the simultaneously injected DC light, the wavelength of this DC light is selected by the optical filter to complete the Oscillation can generate an electrical clock signal and simultaneously obtain an optical clock pulse at that wavelength. It should be said that in addition to optical and electrical microwave sources, pulse sources and clock extraction systems, there are other applications, such as generating dual-frequency signals, inserting encoders to form multi-function signal generators, and so on. However, various applications are based on the feature that the photo-electric oscillator structure can automatically generate stable low-phase noise microwave signals. Therefore, as long as it focuses on various fields that require high-quality microwave signals, many new applications can be developed. Ⅵ SummaryIt can be seen that as a high-quality optical and electrical microwave signal generator, the optoelectronic oscillator has great advantages and wide application prospects. Various unique application methods also lay the foundation for the multifunctionalization of the optoelectronic oscillator.  However, it is undeniable that the current optoelectronic oscillator is still mainly in the laboratory research stage. There is still a period of time before it can be practically applied in the national economic construction and the development of national defense science and technology. Its main constraints focus on how to make the optoelectronic oscillator system into a compact, integrated, and compact frequency control system. The realization of these requirements depends on the development and manufacturing process of new photonic microwave devices and corresponding active devices.  Although there are no direct targets for optoelectronic oscillators, recent literature reports show some opportunities. For example, utc-pd (uni-traveling -Carrier Photodiode) in optoelectronic detection can receive high optical power and have high power electrical signal output, which can reduce or avoid the use of electric amplifiers in optoelectronic oscillators. The development of integrated semiconductor laser and modulator technology makes it possible to miniaturize the light source and feedback modulation of the photoelectric oscillator. The high Q value photonic filter with semiconductor structure is helpful to realize the system integration and tunability of optoelectronic oscillator. It is believed that with the gradual maturity of these technologies, the optotoelectric oscillator will be applied in practice and play its due contribution.  Ⅶ FAQ1. What do you mean by optoelectronic devices?Optoelectronic devices are electrical-to-optical or optical-to-electrical transducers or instruments that use such devices in their operation. ... Optoelectronics is based on the quantum mechanical effects of light on electronic materials, especially semiconductors, sometimes in the presence of electric fields. 2. What are optoelectronic devices give example?Examples of optoelectronic devices are: laser diodes, superluminescent diodes and light-emitting diodes (LEDs), converting electrical energy to light. photodetectors (e.g. photodiodes and phototransistors), converting optical signals into electrical currents. 3. What is the working principle of optoelectronic devices?Optoelectronic devices are primarily transducers i.e. they can convert one energy form to another. These devices produce light by expending electrical energy. They can also detect light and transform light signals into electrical signals for processing by a computer. 4. What are Optoelectronics used for?Optoelectronic devices refer to components used to detect or emit electromagnetic radiation, typically in the visible and near-infrared (NIR) regions of the electromagnetic spectrum. Each of these functions exploits the photoelectric effect of materials, also known as light-matter interaction. 5. Is LDR an optoelectronic device?There are two types of optoelectronic devices. These are Photoconductive devices and Photovoltaic devices. Photoconductive devices detect variations in light intensity to activate or inhibit electronic circuits. LDR, Photodiodes and Phototransistors fall in this category. 6. What are optoelectronic junction devices?Optoelectronic junction devices are p-n junction devices in which, carriers are generated by photons. Photodiodes, light-emitting diodes (LEDs) and solar cells are examples of optoelectronic devices. A photodiode is a device that is used to detect optical signals. 7. Which substance has optoelectronic property?Unlike the majority of electronic devices, which are silicon-based, optoelectronic devices are predominantly made using III–V semiconductor compounds such as GaAs, InP, GaN, and GaSb, and their alloys due to their direct bandgap. 8. Who discovered optoelectronics?Three Bell Laboratories scientists, William Shockley, John Bardeen, and Walter Brattain, demonstrated the first transistor-based on point-contact germanium (Ge) device. On the other hand, the semiconductor laser was discovered 15 years later in 1962. 9. Is solar cell an optoelectronic device?Solar Cell is another example of an Optoelectronic device based on the p-n junction, and the operating mechanism of a solar cell is essentially the same as that of Photodiode in that, a p-n junction is illuminated by light and the photogenerated carriers are separated by the built-in electric field across the p-n junction. 10. What are optoelectronic devices Name any two optoelectronic devices?Examples of optoelectronic devices include telecommunication laser, blue laser, optical fiber, LED traffic lights, photo diodes and solar cells. The majority of the optoelectronic devices (direct conversion between electrons and photons) are LEDs, laser diodes, photo diodes and solar cells. 

In the article today, we will introduce you all about diodes, what is this component and what are its characteristics, where to use it, etc.   Understand what diodes are and what they do in this video Catalog   I. What is a Diode? II. Diode Characteristics III. Diode Application IV. Diode Types V. Diode Conductive Property VI. Diode Parameters VII. Diode Testing FAQ   I. What is a Diode?   In electronic components, a diode is a device with two terminals. The most common function of diodes is to allow primarily the current to pass in one direction (called forward bias) and reverse blocking (known as reverse bias), which called asymmetric conductance. This characteristic of the current directionality of most diodes is commonly referred to as the rectifying function. The most common diodes made today are semiconductor materials such as silicon or germanium. The package of transistors has glass, plastic, and metal commonly. In the early stage, the vacuum electron diode is an electronic device that can transmit current as unidirectional conduction. There is a PN junction and two lead terminals inside the semiconductor diode and it has unidirectional current conductivity according to the direction of the applied voltage. But the crystal diode is a p-n junction interface formed by the sintering of p-type semiconductor and n-type semiconductor, and a space charge layer is formed on both sides of the interface to form a built-in field. When the applied voltage is zero, the diffusion current caused by the concentration difference between the carriers on both sides of the p-n junction is equal to the drift current caused by the self-built electric field. This is a common characteristic of diodes in normal conditions.   II. Diode Characteristics   1. Forward direction When the forward voltage is applied, it is small in the starting part of the forward characteristic, which is not enough to overcome the blocking effect of the electric field in the PN junction, and the forward current is almost zero, which is referred to as the headband. This forward voltage, which cannot lead the diode, is referred to as a deadband voltage. When the forward voltage is greater than the deadband voltage, the electric field blocking in the PN junction is overcome, and the diode is in conduction, and the current rises rapidly with the increase of the voltage. In the normal current range, the terminal voltage of the diode is almost unchanged at the time of conduction, which is referred to as the forward voltage of the diode. When the forward voltage across the diode exceeds a certain value, the internal electric field is rapidly weakened, in the case of this situation, the current increases rapidly and the diode leads forward, which called threshold voltage, and silicon tube is about 0.5V, germanium tube is about 0.1V, in addition, the forward on-voltage drop of silicon diode and germanium diode is about 0.6~0.8V and 0.2~0.3V respectively.   2. Reverse direction When the applied reverse voltage does not exceed a certain range, the current passing through the diode is the reverse current formed by the minority current carrier drift motion. Because the reverse current is very small, the diode is in a cut-off state. This is also called reverse saturation current or leakage current, and it is greatly affected by temperature. In general, the reverse current of silicon tubes is much smaller than that of germanium tubes. The reverse saturation current of low power silicon tube and low-power silicon tube is in the order of nA and the low-power germanium tube is in the order of μA. When the temperature increases, the number of current carriers increases, and the reverse saturation current increases when the temperature is rising.   3. Breakdown When the applied reverse voltage exceeds a certain value, the reverse current increases suddenly, which is called electric breakdown. The critical voltage that causes the breakdown is called the reverse breakdown voltage of diodes. When the electric breakdown occurs, the diode loses its unidirectional conductivity. If the diode is not overheated by electric breakdown, the unidirectional conductivity will not necessarily be permanently destroyed. After removing the applied voltage, its performance can still be restored. If not, the diode is damaged. Therefore, the reverse voltage should be avoided too high when using diodes.   Reverse: the reverse breakdown of the PN junction is divided into Zener breakdown and avalanche breakdown:   a. Zener breakdown  The reverse breakdown is divided into Zener breakdown and avalanche breakdown according to the mechanism. In the case of high doping concentration, when the width of the barrier region is very small and the reverse voltage is large, the covalent bond structure in the barrier region is destroyed, the shared electron is separated from the covalent bond binding, and the covalent electron-hole is produced, which results in the sharp increase of the current. This phenomenon is called Zener breakdown. If the doping concentration is low, and the width of the barrier is wider, which will not result in Zener breakdown easily.   b. Avalanche breakdown  Another breakdown is avalanche breakdown. When the reverse voltage is increased to a larger value, the external electric field accelerates the electron drift speed in the transition region, thus the valence electron in the covalent bond is collided out of the covalent bond by electric field electrodes, which produces a mobile or free electron-hole pair. The newly generated electron-hole is accelerated by the electric field and then bumped out of other valence electrons again. The carrier increases like an electron avalanche, resulting in a sharp increase in the current, which is called avalanche breakdown. Avalanche breakdown is a phenomenon that can occur in both insulating and semiconducting materials.   Regardless of the breakdown, if the current is not limited, it may cause permanent damage to the PN junction.   4. Voltage drop Voltage drop is defined as the amount of voltage loss that occurs through all or part of a circuit due to impedance. Diode voltage drop: forward voltage drop silicon diode (no light-emitting type) is 0.7V, the forward voltage drop of germanium tube is 0.3V. In addition, the forward tube voltage drop of LED will vary with different light-emitting colors. But there are three main colors, the specific reference values are as follows:    red LED is 2.0~2.2V yellow LED is 1.8~2.0V green LED is 3.0~3.2V   The rated current of normal luminescence is about 20mA.   The relation of voltage and current of the diode is not linear, therefore, it is necessary to select resistors properly in parallel with different diodes.   5. Characteristic curve As above mentioned, the diode has a unidirectional conductivity. Applying a forward voltage to the diode, when the voltage value is small, the current is very small, and when the voltage exceeds 0. 6V, the current starts to increase exponentially, which is generally referred to as the opening voltage of the diode. When the voltage reaches about 0.7V, the diode is in a fully conductive state, and this voltage is generally referred to as the conduction voltage of the diode and is indicated by the symbol UD.   For germanium diodes, the turn-on voltage is 0.2V and the on-voltage UD is about 0.3V. A reverse voltage is added to the diode: when the voltage is small, the current is small, and this referred to as the reverse saturation current IS. When the reverse voltage exceeds a certain value, the current begins to increase sharply, called reverse breakdown, and meanwhile, the voltage of this phenomenon occurred is called the reverse breakdown voltage of the diode, which is represented by the symbol UBR. The UBR values of different types of diodes vary greatly, ranging from dozens of volts to kilowatts.     III. Diode Application   1. General Principle The main function of a diode is to allow an electric current to pass in one direction (forward direction) and blocks it in the opposite direction (the reverse direction). Based on this function, the diode can be viewed as an electronic check valve. This unidirectional action is called rectification, which is used to transform alternating current (AC) to direct current (DC).   What's more, diodes also have other complicated behaviors than this simple on-off action(their nonlinear current-voltage characteristics as above mentioned). Diodes can conduct electricity if a certain threshold voltage or cut-in voltage is added in the forward direction (forward-biased). And the voltage drop across a forward-biased diode varies slightly with the current, which is affected by temperature; this effect can be used as a temperature sensor or as a voltage reference. In addition, diodes' high resistance to current flowing in the reverse direction drops to a low resistance sharply when the reverse voltage across the diode reaches a value called the breakdown voltage.    The current-voltage characteristic of semiconductor diodes can be fixed by selecting the semiconductor materials and the doping impurities introduced into the materials during manufacture. And these technical indexes are used to create special-purpose diodes that perform many different functions. For example, diodes are used to regulate voltage, to protect circuits from high voltage surges, to electronically tune radio and TV receivers, to generate radio-frequency oscillations, and to produce light.     2. Operational Principle In this video, we will explore the inner workings and applications of the diode in great detail. Apart from the basic working of the diode, this video also explains V-I characteristics and applications of diode (rectification using Bridge rectifier) with help of animation.   The crystal diode is a PN junction formed by p-type semiconductors and n-type semiconductors, and a space charge layer is formed on both sides of the interface with a self-built electric field. When there is a positive voltage bias, the mutual suppression of the external electric field and the self-built electric field leads to the increase of the carrier diffusion current and then the positive current caused by this interaction between them. When there is a reverse voltage bias, the external electric field and the self-built electric field are further strengthened, forming in a certain reverse voltage range independent of the reverse bias voltage, and the reverse saturation current be generated. When the applied reverse voltage excesses a certain value, the electric field intensity in the space charge layer of PN junction reaches the critical value to cause the multiplying process of carriers, resulting in a large number of electron-hole pairs and a very large reverse breakdown current, which is called a breakdown phenomenon of diodes.     3. Specific Explanations There are many types of diodes, and according to electronic fabrication, the following diodes are often used: Zener diodes for voltage regulators, switching diodes for digital circuits, various for resonance, and so on. The most common diode is the light-emitting diode. Light-emitting diodes (LEDs) are widely used in various electronic products, light sources for optical fiber communication, indicators, and lighting for various instruments. LEDs have many characteristics which can not be compared with ordinary light-emitting devices. These characteristics include safety, high efficiency, environmental protection, long life, fast response speed, small size, and solid structure. And the following are some of their main applications:   1) Application summary   (1) In electronic equipment LEDs are generally used in electronic devices as backlight or display, lighting applications. Displays ranging from large LCD televisions, computer displays, and media players such as MP3, MP4, and mobile phones.   (2) In the automobile and large machinery The light-emitting diode is widely used in automobiles and large machinery. Light-emitting diodes are used in the direction lights, in-vehicle lighting, mechanical equipment instrument lighting, large-light, turn-light, brake light, tail lights, and so on. It is mainly because the response of the light-emitting diode is fast and the service life is long (the service life of the general light-emitting diode is longer than that of the service life of automobiles and large machinery).   (3) In coal mine Owing to the advantages of high efficiency, low energy consumption, long life, strong luminosity and so on, LEDs are used in miner lighting devices. Although not fully popularized, it will be widely used in the near future, and LEDs will replace common light-emitting devices in coal mine applications.   (4) In decoration lights of the city Neon is an important symbol of modern urban prosperity, but there are many shortcomings, such as a short life span. Therefore, there are many advantages in replacing neon with LED. Compared with neon, LEDs not only have a longer life, but also save energy, be easily driven and controlled, and do not need maintenance. It is the inevitable result of LED equipment to replace the neon lamps with LED.   2) Selection of several common diodes   (1) detector diode  Generally, the detector diode is usually a point-contact type germanium diode. The detector with high working frequency, low reverse current, and large forward current should be selected according to the specific requirements of the circuit.   (2) rectifier diode Rectifier diodes are generally planar silicon diodes, used in various power rectifier circuits. When selecting rectifier diode, the parameters such as maximum rectified current, maximum reverse working current, cutoff frequency, and reverse recovery time should be considered. The rectifier diode used in the common series regulated power supply circuit is not strict with the reverse recovery time of cutoff frequency, so long as the maximum rectified current and the maximum reverse working current are selected according to the requirements of the circuit which can meet the requirements.   (3) Zener diode The Zener diode is generally used as a reference voltage source in a regulated power supply or as a protection diode in an overvoltage protection circuit. The selected Zener diode shall meet the main parameters based on the applying requirement. The stable voltage value of the Zener diode shall be the same as the reference voltage value of the application circuit, and the maximum stable current of the Zener diode shall be higher than the maximum load current of the application circuit by about 50%.   (4) switching diode  Switching diodes are mainly used in video recorders, TV sets, DVDs, and other household appliances and electronic equipment, such as switching circuits, detection circuits, high-frequency pulse rectifier circuits, and so on.   Medium-speed switching circuit and detection circuit, it is suitable to choose the 2AK series of ordinary switching diodes. High-speed switch circuits can choose RLS series, 1SS series, 1N series, and 2CK series high-speed switch diode.   According to the main parameters of the application circuit (such as forward current, maximum reverse voltage, reverse recovery time, etc.) to select the specific type of switch diode.   (5) variode When selecting variodes, the parameters such as working frequency, maximum reverse working voltage, maximum forward current, and zero-bias junction capacitance should be considered. A variode with a small reverse leakage current and various junction capacitance should be selected.     IV. Diode Types   There are many kinds of diodes. According to its semiconductor materials, it can be divided into germanium diodes (Ge-diodes) and silicon diodes (Si-diodes). According to its different applications, it can be divided into detector diode, rectifier diode, Zener diode, switching diode, isolation diode, Schottky diode, LED, silicon power-switch diode, rotary diode, and so on.    Semiconductor diodes work mainly on PN junctions. The point-contact type and Schottky type, which are the most common type based on the PN junction, and they also included in the range of general diodes. According to the characteristics of the PN structure(core structure), it can be divided into the point-contact diode, surface-contact diode, and planar diode.   1) point-contact type The point-contact diode is pressed on the surface of a clean semiconductor wafer with a thin metal wire, passing through a pulse current, so that one end of the contact wire is firmly sintered with the wafer to form a PN junction. Due to its point-contact characteristic, only a small current can flow through, thus it is suitable for high frequency and small current circuits, such as radio detection. However, compared with the surface junction type, the point-contact diode has poor forward and reverse characteristics, so it can not be used in high current and rectifier. Because the structure is simple, the price is cheap.   2) surface-contact type The PN junction of surface contact is made by alloy method or diffusion method. As for the surface-contact diode, its area of PN junction is larger, allowing a larger current to across through, it is suitable for the conversion of AC to DC circuit, that is rectifying function of diodes, but it is not suitable for the high-frequency circuit.   3) bond types  A bond diode is formed by melting gold or silver filaments on a single crystal sheet of silicon or germanium. and the characteristics are between the point-contact type diode and the alloy type diode. Compared with the point-contact type, although the PN junction capacitance of the bond diode is slightly increased, and its forward characteristic is particularly excellent. It is used as a switch and sometimes applied to the detection and power supply rectification (not greater than 50mA). In a bond diode, a diode of a fused gold wire is sometimes referred to as a gold bond type, and a diode of a fused silver wire is sometimes referred to as a silver bond type.   4) alloy type PN junctions were fabricated on N-type germanium or silicon single crystal wafers by adding indium, aluminum, and other metals. Small forward voltage drop, suitable for the large current rectifier. The PN junction is not suitable for high-frequency detection and high-frequency rectifier because of its large electrostatic capacity.   5) diffusion type In the high-temperature P-type impurity gas, the single crystal wafer heated with N-type germanium or silicon makes one part of the surface of the single crystal become P-type. Due to the small forward voltage drop of the PN junction, it is suitable for a high current rectifier. In addition, the use of high-current rectifiers has changed from silicon alloy to silicon diffusion.   6) mesa type Although its fabrication method of PN junction is the same as that of diffusion type, only the PN junction and its necessary parts are retained, and the unnecessary part is corroded by chemical. The rest of it takes on a mesa shape, hence its name. The initial production of this type is made of semiconductor materials by diffusion method. Therefore, this type is also called diffusion mesa. It usually used for small current switches.   7) planar type It is named after the surface of the semiconductor is made flat. In a semiconductor single crystal chip (mainly an N-type silicon single crystal chip), a P-type impurity is diffused, and a PN junction formed by selectively diffusing a part of the N-type silicon single crystal chip by a shielding effect of a silicon wafer surface oxide film. Therefore, it is not necessary to use chemicals. In addition, the surface of the PN junction is recognized as a type that having good stability and long service life due to the coating of the oxidized film. Initially, the semiconductor material used is formed by chemical extension, and the planar type is also referred to as an epitaxial planar type.    The planar diode is a kind of special silicon diode, it not only can pass through a large current, but also has stable and reliable performance, and it is widely used in switching, pulse, and high-frequency circuits.   8) alloy diffusion type It is a kind of alloy type. Alloy materials are easily diffused materials, which can be over diffused with the alloy by skillfully mixing impurities so that the proper concentration distribution of impurities can be obtained in the formed PN junctions. This method is suitable for the manufacture of high-sensitivity varactor diodes.   9) epitaxial type A diode formed by the manufacture of a PN junction by using an epitaxial surface length process. Manufacturing requires great skill. Because of its ability to control the distribution of impurities at random, it is suitable for the manufacture of high-sensitivity capacitive diodes.   10) Schottky   The basic principle is that: the formed substrate is used to block the reverse voltage on the contact-surfaces of metals (such as lead) and semiconductors (N-type silicon wafers). Schottky and PN junction have fundamental difference in the principle of rectifying function. Its voltage resistance is only about 40V. Its advantages are: switch speed is very fast: reverse recovery time is particularly short. Therefore, switching diodes and low-voltage high current rectifiers can be made based on this method.   According to application, diodes can be divided as :   1. detector diode  The main function of the detector is to detect the low-frequency signal in the high-frequency signal. It belongs to the point-contact type, so its junction capacitance is smaller and its working frequency is higher, and it is generally made of germanium. In principle, when the modulation signal is extracted from the input signal, usually, and the output current less than the 100mA( the rectifier current 100mA is used as the boundary) is called the demodulation. Its advantages include: the working frequency can reach 400MHz, the forward voltage drop is small, the junction capacitance is small, the detection efficiency is high, and the frequency characteristic is good. In addition to being used for detection, it can also be used for limiting, clipping, modulating, mixing, switching, and other circuits. Furthermore, there are also two diode assemblies dedicated to FM demodulation.   2. rectifier diode In principle, the output from the input AC DC is rectified. The rectified current size (100mA) is usually used as the boundary of the output current greater than the 100mA called a rectifier. Surface junction type, so junction capacitance is larger, generally below 3kHZ. Maximum reverse voltage from 25 volts to 3000 volts a total of 22 volts. Classified as follows: 1 silicon semiconductor rectifier diode 2CZ type, 2 silicon bridge rectifier QL type, 3 for television high voltage silicon stack working frequency near 100KHz 2CLG type.   3. clipper diode  The forward voltage drop of the diode is substantially unchanged after the diode is in conduction (the silicon tube is 0.7V, and the silicon tube is 0.3V). With this characteristic, the amplitude of the signal can be limited to a certain range with this limiting element in the circuit.   Most of the diodes can be used as a clipping component, but there is also a dedicated clipping diode like a protective instrument and a high-frequency Zanner diode. To have a particularly strong effect on limiting the sharp amplitude, a diode typically made of a silicon material. There is also a component set: a number of necessary rectifying diodes are connected in series to form a whole, depending on the need for limiting the voltage.   4. modulation diode It usually refers to the ring modulation dedicated diode. It is a combination of four diodes with good forward characteristics and consistency. Even though other varactor diodes have modulation applications, they are usually used directly as FM.   5. mixer diode  In the frequency range of 500~10000Hz, Schottky type and point-contact type diodes are usually used when diode mixing mode is used.   6. amplifier diode The amplification of a negative resistance device, such as a tunnel diode and a bulk diode, is generally performed with a diode, and also the parametric amplification of the variode. Thus, the amplification diodes generally refer to a tunnel diode, a bulk diode, and a variode.   7. switching diode The resistance of the diode is very small under the forward voltage, which is equivalent to that of an on-on switch; under the action of reverse voltage, the resistance is very large, and in the cut-off state, that is turn off state. All kinds of logic circuits can be formed by using the switching characteristics of diodes.   A logic operation with a small current and a magnetic core excitation switching diode for use in milliamperes. The small current switching diode is usually a point-contact type and a bond diode, and also has a silicon diffusion type, a mesa type, and a planar type diode which can work at high temperature. The advantage of the switching diode is that the switching speed is fast, and the switching time of the Schottky diode is very short, thus it is the ideal switching diode. The 2AK point-contact is used for medium-speed switch circuits; the 2CK-type plane is used for high-speed switching circuits, usually for switches, clipping, clamp bits, or detection circuits, and the Schottky-barrier diode has the advantages of small positive voltage drop, high speed, and high efficiency.   8. variode Low-power diode for automatic frequency control (AFC) and tuning. Other manufacturers also have many other terms. When applying reverse voltage, the electrostatic capacity of the PN junction will change. Therefore, it is used for automatic frequency control, scanning oscillation, frequency modulation, and tuning. Generally, although silicon diffusion diodes are used, special diodes such as alloy diffusion type, epitaxial bonding type, and dual diffusion type can be used, because the electrostatic capacity of these diodes has a very large change rate for voltage. Junction capacitance changes with reverse voltage and replaces variable capacitance, used in tuning circuit, oscillating circuit, phase-locked loop circuit. For example, it is often used in TV high-frequency channel conversion and tuning circuits and mostly made of silicon material.   9. frequency multiplication diode For the frequency multiplication of diodes, the frequency doubling depends on the frequency doubling of the variode and the frequency multiplication of the snap-off diode. The variode used for frequency multiplication is called a variable reactor. Although the variable reactor works the same principle as the variode used in automatic frequency control, the construction of the reactor can withstand high power. Snap-off diode, also called step recovery diode, has a short reverse recovery time when switch on to switch off. If sine waves are applied to snap-off diodes because the on-off time is short, so the output waveform is quickly cut off, it can produce a lot of high-frequency harmonics.   10. Zener diode   This type is based on the reverse breakdown characteristic to be made. The voltage at both ends of the circuit remains basically unchanged, which plays the role of stabilizing the voltage. It is made into a diffusion or alloy type of silicon. Its reverse breakdown characteristic curve changes sharply. Made as a control voltage and a standard voltage component. Diode terminal voltage (also known as Zener voltage) from about 3V to 150V, which can be divided into many grades. In terms of power, there is 200mW to 100W or more. Working in the reverse breakdown state, the dynamic resistance RZ is very small. The two complementary diodes are connected in reverse series to reduce the temperature coefficient, which is turned into a 2DW type.   The p-n junction of Zener diodes is highly doped. And normal diodes will also break down with a reverse voltage but the voltage and sharpness of it may not as well as defined. Also, normal diodes are not designed to operate in the breakdown region, but Zener diodes can reliably operate in this case.   Zener diodes are widely used in electronic devices(almost all kinds) and are one of the basic parts of electronic circuits. It is used to generate low-power stabilized supply rails from a higher voltage and to provide reference voltages for circuits, particularly stabilized power supplies. It is also used to protect circuits from overvoltage, especially electrostatic discharge.   11. PIN diode This is a crystal diode constructed by a layer of intrinsic semiconductors (or low concentration impurity semiconductors) between the P and N regions. When the operating frequency exceeds 100MHz, the diode becomes an impedance element due to the memory effect of minority carriers and the transit time effect in the "intrinsic" layer, it becomes an impedance element because of losing rectifying function, and its impedance value varies with the bias voltage. The impedance of the "intrinsic" region is very high when the bias is zero or the DC reverse bias, and the "intrinsic" region is low impedance due to the carrier injection into the "intrinsic" region when the DC is positive bias. Therefore The PIN diode can be used as a variable impedance element. It is often used in high-frequency switches (microwave switches), phase shift, modulation, amplitude limiting, and other circuits.   12. avalanche diode It is a transistor that can produce high-frequency oscillation under the behavior of applied voltage. The working principle of producing high-frequency oscillation is that the carrier is injected into the crystal by avalanche breakdown. Because the carrier transit chip takes a certain time, the current lags behind the voltage, and the delay time occurs. If the transit time is controlled properly, there will be a dynatron effect in the relationship between current and voltage, which will produce high-frequency oscillation. So it is often used in oscillating circuits in the microwave field.   13. tunnel diode It is a crystal diode based on tunneling effect current as of the main current component. The substrate materials are gallium arsenide and germanium, and the N-type region of the P region is highly doped.    A tunnel diode is a dual terminal active device, and it can be used in low-noise and high-frequency amplifiers and high-frequency oscillators (whose operating frequency can be up to millimeter-wave level) or in high-speed switching circuits.   (Note: Tunneling is the quantum mechanical phenomenon where a subatomic particle passes through a potential barrier that it cannot surmount under the provision of classical mechanics.   Tunneling plays an essential role in several physical phenomena, such as the nuclear fusion that occurs in main sequence stars like the Sun. It has important applications in the tunnel diode, quantum computing, and scanning tunneling microscope. The effect was predicted in the early 20th century, and its acceptance as a general physical phenomenon came mid-century.   Fundamental quantum mechanical concepts are central to this phenomenon, which makes quantum tunneling one of the novel implications of quantum mechanics. Quantum tunneling is projected to create physical limits to the size of the transistors used in microprocessors, due to electrons being able to tunnel past them if the transistors are too small.)   14. step recovery diode It is also a diode with a PN junction. Its structural characteristics are that there is a steep impurity distribution area at the boundary of the PN junction, thus forming a "self-help electric field". The reverse current of the PN junction can be reduced to the minimum value (reverse saturation current) after a "storage time" because of the charge storage effect in the vicinity of the PN junction due to the conduction of a few carriers at the forward bias voltage. The self-help electric field of the step recovery diode shortens the storage time, makes the reverse current cut off quickly, and produces abundant harmonic components. The comb spectrum generation circuit can be designed by using these harmonic components. Fast turn-off (step recovery) diodes are used in pulse and high-order harmonic circuits.   15. Schottky barrier diode It is a metal-semiconductor junction diode with Schottky characteristics. The forward starting voltage is lower. In addition to materials, gold, molybdenum, nickel, titanium and other materials can be used in the metal layer. Its semiconductor materials are silicon or gallium arsenide, mostly N-type semiconductors. This device is conductive by most carriers, so its reverse saturation current is much larger than that of PN junction with minority carrier conduction. Because the memory effect of minority carriers in Schottky diodes is very small, the frequency response of it is limited only by the RC time constant, so it is an ideal device for high frequency and fast switching. Its working frequency can reach 100GHz. And, MIS (metal-insulator-semiconductor) Schottky diodes can be used as solar cells or light-emitting diodes.   It also can be used as a continuation diode in the switching power supply inductance and plays a role in the continuation of the current in the relay and another inductive load.   16. damping diode  Damping diodes are widely used in high-frequency voltage circuits, with high reverse working voltage and peak current, but their forward voltage drop is small. It is a kind of high frequency and high voltage rectifier diodes, and often used in TV line scanning circuits for damping and boost rectifying. The commonly used damping diodes are 2CN1, 2CN2, BSBS44, and so on.   17. transient voltage suppressor(TVS) TVS is used to protect the circuits when having a fast overvoltage. They are divided into two types: bipolar and unipolar, classified by the values of peak power (500W-5000W) and voltage (8.2V~200V).   18. double-base diode (unijunction diode) A three-terminal negative resistive device with two base electrodes and emitter used in an oscillating circuit, has the advantages of easy frequency adjustment and good temperature stability.   19. LED It is made of gallium phosphide and gallium arsenide. Low working voltage, small operating current, uniform luminescence, long life, emitting red, yellow, green, blue monochromatic light. With the development of technology, white light and highlight diode to forming the new industry of LED lighting. It is also used in VCD, DVD, calculators, and other displays.   20. silicon power switching diode The silicon power switching diode has the capability of high-speed conduction and cut-off. It is mainly used for high-power switch or voltage-stabilizing circuit, DC converter, high-speed motor speed-regulating, and high-frequency rectification and free-wheeling, and has the advantages of soft recovery property and strong overload capacity. And it is widely applied to the computer, radar power supply, stepper motor speed-regulation, and so on.     According to characteristic, diodes can be divided as:   Point-contact diodes, classified by forward and reverse characteristic, are as follows:   1. Common point contact diode This kind of diode, is usually used in demodulation and rectifier circuits and is an intermediate product with forward and reverse characteristics, such as SD34, SD46, 1N34A, and so on.   2. High reverse voltage resistance point contact diode A kind of component with maximum peak reverse voltage and the maximum DC reverse voltage, which used in the detection and rectification of high voltage circuits, but this type of diode generally has poor or moderate forward characteristics. In point-contact type germanium diode, there are SD38, 1N38A, OA81, and so on.    3. High reverse resistance point-contact diode Forward voltage characteristics are the same as general diodes. Although its reverse voltage is also particularly high, the reverse current is small. Used in circuits with high input resistance and high resistance load. For example, SD54 and 1N54A belong to high reverse resistance diodes made of germanium material.   4. High conduction point-contact diode It is the opposite of the high reverse resistance type. Its reverse characteristics are poor, but the forward resistance is small. For high conduction point-contact diodes, there are SD56,1N56A and so on. For high conduction bond diodes, it has better properties when operating. When the load resistance is especially low, its rectifier efficiency is good.    V. Diode Conductive Property   The most important characteristic of diodes is unidirectional conductivity. In the circuit, the current can only flow from the positive, flow out from the negative.   1) forward characteristic    In electronic circuits, if the positive electrode of the diode is connected to the high potential terminal and the negative electrode to the low potential terminal, the diode will be switched on. This connection is called forward bias. It must be noted that when the forward voltage applied to both ends of the diode is very small, the diode cannot be switched on, and the forward current flowing through the diode is very weak.    2) reverse characteristic    In the electronic circuit, the positive electrode of the diode is connected to the low potential terminal, and the negative electrode is connected to the high potential terminal. In this case, there is almost no current flowing through the diode, and the diode is in the cut-off state. This connection mode is called reverse bias. When the diode is in reverse bias, there will still be a weak reverse current flowing through the diode, called leakage current. When the reverse voltage at both ends of the diode increases to a certain value, the reverse current will increase sharply, and the diode will lose the unidirectional conductivity, this state is called the breakdown of the diode as forward mentioned.   VI. Diode Parameters   The parameters of the diode are used for indicating the performance of the diode and the technical index of the applications. Different types of diodes have different characteristic parameters, and for beginners, the following main parameters must be understood:   (1) rated forward working current It refers to the maximum positive current allowed by the diode during long-term continuous operation.   (2) maximum surge current  It is an excess forward current that is allowed to flow. It is a transient current, and it is usually about 20 times the rated forward current.   (3) maximum reverse operating voltage When the reverse working voltage at both ends of the diode reaches a certain value, the tube will break down and lose its unidirectional conductivity. In order to keep safe, a maximum reverse working power value is specified. For example, the reverse voltage of an lN4001 diode with a reverse voltage of 50V, and is 1000V for IN4007.   (4) reverse current Reverse current is a kind of current that the diode flows through the diode at a specified temperature and maximum reverse voltage. The smaller the reverse current, the better the unidirectional conductivity of the tube. The reverse current is closely related to the temperature, the reverse current increases twice when the temperature rises 10℃ at one time. In addition, silicon diode has better stability than germanium diode at high temperature.   (5) reverse recovery time When the forward voltage converts into the reverse voltage, the current can not stop at a short time, because it has a delay time, which is called reverse recovery time. It directly affects the switching speed of the diode.   (6) maximum power The maximum power is the voltage applied at both ends of the diode multiplied by the current.    (7) dynamic resistance The ratio of the voltage variation near the static operating point to the variation of the corresponding current in the diode characteristic curve.   (8) frequency characteristic Due to the existence of junction capacitance, when the frequency is up to a certain degree, the capacitance reactance is small enough to make the PN junction short-circuit, resulting in the diode loses unidirectional conductivity and cannot work. The larger the PN junction area is, the larger the junction capacitance is, so it can’t work at high frequency.   VII. Diode Testing   General diodes (including detection diodes, rectifier diodes, damped diodes, switching diodes, continuous diodes) have unidirectional conductivity. It is suitable to use a multimeter to detect the positive and reverse resistance, the electrode of the diode can be identified and the damage of the diode can be estimated.   1. The multimeter is placed in the R×100 barrier or R×1k barrier for polarity discrimination. The two-meter pens are connected with two electrodes of the diode respectively. After one result is measured, the two-meter pens are adjusted to obtain another result. In the two measurements, the large resistance value measured is reverse resistance, and the smaller resistance value measured is forward resistance. In addition, the black meter pen is connected with the positive pole of the diode, and the red meter pen is connected with the negative pole of the diode during a small resistance measurement.   2. In general, the positive resistance of GE diode is about 1kΩ and the reverse resistance is about 300. The resistance of the silicon diode is about 5kΩ and the reverse resistance is infinity. The smaller the forward resistance, the better the reverse resistance. The greater the difference between the positive and reverse resistance values, the better the unidirectional conductivity of the diode. If the positive and reverse resistance values of the diodes are all close to zero or the resistance values are small, the internal breakdown short circuit or leakage damage of the diode is indicated. If the positive and reverse resistance values of the diode are infinite, then the dipole is proved. The pipe is open and damaged.   3. Detection of reverse breakdown voltage(withstand voltage) of the diode can be measured by a transistor DC parameter meter. The method is: when measuring the diode, the "NPN/PNP" selection key of the testing meter should be set to the NPN state, and the negative pole should be inserted into the "e" jack of the testing meter and the positive pole of the diode should insert to the "c" jack, then press the V (BR) key, finally the reverse breakdown voltage of the diode can be detected. Another way is that a megohmmeter and a multimeter are used to measure the reverse breakdown voltage of the diode. When measured, the negative electrode of the diode is connected to the positive pole of the megohmmeter, and the positive electrode of the diode is connected to the negative pole of the megohmmeter, and meanwhile, the voltage across the diode is monitored by a multimeter (placed in the appropriate DC voltage level).    Several Detection methods of Common Diode   1. Detection of a low power crystal diode A. Distinguishing positive and negative electrode   (a) Observe the symbol mark on the shell. Usually, the symbol of the diode is marked on the shell with the one end with the triangular arrow being the positive and the other end is the negative pole.   (b) Observe the color dots on the shell. On the shell of a point-contact diode, it is usually marked with a polar color dot (white or red). One end with a general colored point is a positive pole. There are also diodes marked with color bands, and one end with the color bands is a negative pole. For example, a diode shell with a silver band is the negative pole.   (c) the one end of the black meter pen is the positive pole, and one end of the red meter pen is the negative pole, whichever takes the smaller value.   B. Detecting the maximum reverse breakdown voltage.    For alternating current, the maximum reverse operating voltage is the AC peak voltage the diode receives because it is constantly changing.   2. Detection bidirectional trigger diode Put the multimeter in the corresponding DC voltage block. When testing, shake the mega-meter to measure the VBR value. Finally, comparing VBO with VBR, the smaller the difference between the absolute values, the better the symmetry of the measured bidirectional trigger diode.   3. Detection of transient voltage suppression diode (TVS) The multimeter is used to measure the quality of the tube. According to the method of measuring the common diode, the positive and reverse resistance can be measured for the single-pole TVS. The general forward resistance is about 4kΩ, and the reverse resistance is infinity.   For the bidirectional polar TVS, the resistance between the two pins measured by two-meter pens should be infinite, otherwise, the diode performance is poor or damaged.   4. Detection of high-frequency variable-resistance diodes The difference between the positive and negative of high-frequency resistive diodes and ordinary diodes in appearance is that the color code is different. Ordinary diodes are generally black, while high-frequency resistive diodes are always a light color. Its polarity of the band is similar to that of the ordinary diode, that is, one end with a green band represents a negative pole, and the other end without a green band is a positive pole.   5. Detection of variode Inter-modulation by adjusting the red meter pen and the black meter pen of the multimeter, the resistance value between the two pins of the variode should be infinite. During the measurement, it is found that the multimeter pointer has a slight swing to the right or resistance of zero, indicating that the measured variode has a leakage fault or has broken down.   6. Detection of monochromatic light-emitting diodes A 1.5V dry battery is attached to the outside of the multimeter, and the multimeter is placed in R×10 or R×100 block. This method is equivalent to giving the multimeter a voltage of 1.5V, which increases the detection voltage to 3V (the starting voltage of the LED is 2V). When detecting, rotate the two pins of the LED with the two-meter pens of the multimeter. If the diode performance is good, there must be a normal luminous, at this time, the black pen is connected to the positive pole and the red pen is connected to the negative pole.   7. Detection of Infrared light-emitting diode A. Identify the positive and negative electrodes of infrared LEDs. An infrared LED has two pins, usually, the long pin is positive and the short pin is negative. Because the infrared LED is transparent, the electrode inside the tube and shell are clearly visible. The larger electrode is the negative electrode, and the narrower and smaller one is the positive electrode.   B.Measure the positive and reverse resistance of infrared LED firstly, usually, the forward resistance should be about 30k, reverse resistance should be more than 500k so that the device can be used normally.   8. Detection of IR receiver A. identify pin polarity   (a) Detection in appearance. The common IR receiver appearance color is black. When recognizing pins, facing the light window, from left to right, it is positive and negative respectively. In addition, there is a small oblique plane at the top of the IR receiver, usually a negative pin at one end with the oblique plane and a positive electrode at the other end.   (b) First uses multimeter to judge the positive and negative electrodes of common diodes, that is, to exchange red and black meter pen to measure the resistance between the two pins of the diode twice. Under normal conditions, the obtained resistance values should be various. Taking the smaller resistance, the connected end by the red-meter pen is negative and the black-meter pin is positive.   B. detection performance   The forward and reverse resistance of the IR receiver is measured by a multimeter electric barrier. According to the value of forward and reverse resistance, the quality of the IR receiver can be primarily judged.   9. Laser diode detection The pin arrangement order of the laser diode can be determined according to the method of detecting the forward and reverse resistance of ordinary diodes. However, it is important to note that since the forward voltage drop of the laser diode is larger than that of the ordinary diode, the multimeter pointer only slightly swings to the right when detecting the forward resistance.   FAQ   1. What is diode and its symbol? Diode, an electrical component that allows the flow of current in only one direction. In circuit diagrams, a diode is represented by a triangle with a line across one vertex.   2. What is special about a diode? Some semiconductor junctions, composed of special chemical combinations, emit radiant energy within the spectrum of visible light as the electrons change energy levels. Simply put, these junctions glow when forward biased. A diode intentionally designed to glow like a lamp is called a light-emitting diode, or LED.   3. Are diodes AC or DC? It allows current to flow easily in one direction, but severely restricts current from flowing in the opposite direction. Diodes are also known as rectifiers because they change alternating current (ac) into pulsating direct current (dc). Diodes are rated according to their type, voltage, and current capacity.   4. Why do we use zener diode? Zener diodes are used for voltage regulation, as reference elements, surge suppressors, and in switching applications and clipper circuits. The load voltage equals breakdown voltage VZ of the diode. The series resistor limits the current through the diode and drops the excess voltage when the diode is conducting.   5. What is unit of diode? A diode is not a measurable quantity. Hence,it does not have a unit. Generally,for a diode,we measure characteristics like forward voltage drop,reverse voltage drop and reverse breakdown voltage which are usually measured in Volts.   6. Do diodes have resistance? Just like a resistor or any other load in a circuit, a diode offers resistance in a circuit. Unlike resistors, though, diodes are not linear devices. This means that the resistance of diodes does not vary directly and proportional to the amount of voltage and current applied to them.   7. Does diode reduce current? Ideally, diodes will block any and all current flowing the reverse direction, or just act like a short-circuit if current flow is forward. Unfortunately, actual diode behavior isn't quite ideal. Diodes do consume some amount of power when conducting forward current, and they won't block out all reverse current.   8. How are diodes classified? Diodes are classified according to their characteristics and are offered in a number of different types, including rectifiers, switching diodes, Schottky barrier diodes, Zener (constant voltage) diodes, and diodes designed for high-frequency applications.   9. What is the most common diode? The most commonly used signal diode is the 1N4148. This diode has a close brother called 1N914 that can be used in its place if you can't find a 1N4148. This diode has a forward-voltage drop of 0.7 and a peak inverse voltage of 100 V, and can carry a maximum of 200 mA of current.   10. What is the difference between a Zener diode and a Schottky diode? As their switching speed is very high, Schottky diodes recover very fast when the current reverses, resulting in only a very small reverse current overshoot. ... A special type of diode, called the Zener diode, blocks the current through it up to a certain voltage when reverse biased.   11. What is difference between Schottky diode and normal diode? In the normal rectifier grade PN junction diode, the junction is formed between P type semiconductor to N type semiconductor. Whereas in Schottky diode the junction is in between N type semiconductor to Metal plate. The schottky barrier diode has electrons as majority carriers on both sides of the junction.   12. Why it is called diode? A diode is called a diode because it has two distinct electrodes (i.e. terminals), called the anode and the cathode. A diode is electrically asymmetric because current can flow freely from the anode to the cathode, but not in the other direction. In this way, it functions as a one-way valve for current.   13. Is a diode the same as a resistor? Key Difference: A diode is a type of electrical device that allows the current to move through it in only one direction. ... A resistor is an electric component that is used to provide resistance to current in the circuit. They are mostly used to produce heat or light.   14. How much voltage can a diode take? Silicon diodes have a forward voltage of approximately 0.7 volts. Germanium diodes have a forward voltage of approximately 0.3 volts. The maximum reverse-bias voltage that a diode can withstand without “breaking down” is called the Peak Inverse Voltage, or PIV rating.   15. Can a resistor replace a diode? Diodes only conduct in one direction whereas resistors conduct in both directions. Without analyzing the actual circuit the results would be unpredictable but, generally speaking, being that diodes & resistors are designed to do different things, substituting one for the other is something you wouldn't want to do.   You May Also Like Characteristics and Functions of Diodes Rectifiers and Filters Notes Simplify Current Monitoring by Using Diode | Power Supply Negative End

Ⅰ IntroductionIn recent years, with the rapid development of the internet of things (IoT) and electronic technologies, embedded devices such as mobile phones, smartwatches, and sports bracelets have become important elements of cloud computing, IoT, and big data analytics. Embedded terminal devices become more usual in daily life. However, to meet the high storage requirements of these increasingly diverse applications, scientific research personnel face more challenges. Non-volatile memory is more and more popular in the market due to its advantages such as low energy consumption, non-volatile, high density, and low latency. The following is a basic introduction to new non-volatile memory with good future development prospects.The Future of Non-volatile MemoryCatalogⅠ IntroductionⅡ TerminologyⅢ Concept and ClassificationⅣ One Question Related to Non-volatile Memory and Going Further4.1 Question4.2 AnswerⅡ TerminologyMemory is an important part of computer systems. According to different positions in the storage system, memory can be simply divided into three types: on-chip memory, main memory, and hard disk. Correspondingly, static memory (SRAM), dynamic memory (DRAM), and magnetic disks have become the traditional technologies to realize these storage system. Over the past 40 years, these three technologies have achieved tremendous technical and commercial success. With the exception of magnetic disks, the manufacture of both static and dynamic memory relies on semiconductor integration technology. Although these two technologies are different, they also have a common characteristic: they both use the accumulation and release of charge on semiconductor devices to achieve data storage. For example, in a dynamic memory, the charge is used to represent a logic 1, and the discharge represents logic 0. In static memory, this process is achieved by charging and discharging the parasitic capacitance of the transistor. For example, solid-state storage, which widely used in flash memory, also stores data by capturing and releasing the charge on the floating gate of the transistor.With the improvement of manufacturing technologies, the size of semiconductor nano devices has continued to shrink, and the charges that can be stored on all of the above traditional memory devices has also decreased, which has brought serious reliability issues: First, more leakage current; second, a small perturbation of charges will have a relatively greater impact. In addition, the inherent limitations of the charge storage mechanism itself also can't be avoided, the processing of traditional mainstream memories at the nanoscale and the process disturbances are also very challenging.From the aspect of functions, static memory and dynamic memory both belong to the volatile memory category. Its characteristic is that when the power supply is off, the data stored in the memory will disappear and cannot be recovered. Especially in the design of dynamic memory, the charge on the capacitor will gradually leak out as the time increases. Therefore, the stored info need to be refreshed periodically. The static memory doesn't have this issue, but the area of the memory cell is usually large (about 20 times that of the dynamic memory cell), causing serious leakage current. Flash memory belongs to the non-volatile memory, and the data stored on it will be retained for a long time after the power off. In terms of performance, the first two types of memory read & write speed are on the level of nanoseconds, while the flash memory are on the level of hundreds of microseconds or even milliseconds. For the reading mode, the static memory and the dynamic memory can achieve random storage, for example, any one or several memory cells can be read and written at will. It different for Flash, although its storage density is high, the read operation must be performed in units of pages. Moreover, the content update of the flash memory cannot be achieved by directly overwriting the original content, but must be written to a new erased page. In addition, the maximum times of read and write supported by flash memory is extremely limited, typically between thousands of and millions of times. Ⅲ Concept and ClassificationConcept: Non-volatile memory refers to the computer memory of the person whose stored data will not disappear when the power is turned off. It is characterized by non-volatile, byte-by-byte access, high storage density, low energy consumption, and fast read and write speed, but the read speed  far faster than write, in other words, they are asymmetric in a limited life.Classification: According to whether the data in the memory can be rewritten at any time, the traditional non-volatile memory can be divided into two categories: read-only memory (ROM) and Flash memory. New type non-volatile memory compared with traditional non-volatile memory, its device has greatly improved energy consumption, read and write speed, integration density, etc. At present, the newly developed new non-volatile memory mainly includes four types: dielectric memory (FRAM), magnetic medium memory (MRAM), Ovonic phase change memory (OUM), and polymer memory (PFRAM).The following highlights four new non-volatile memories.The technical limitations of traditional memories and the huge challenges brought by the light weight have prompted researchers to look for a new generation of memory devices. People want to find a memory with the following characteristics:1) Nano level read and write speed of static memory2) Integrated density with dynamic memory and even flash memory level3) Flash-like non-volatile memory featuresAlthough such a storage technology has not been fully realized at present, some very promising new storage devices have been developed, and some have even entered the production stage. The four newly developed non-volatile memories are very promising for data processing, because of the limitations of traditional non-volatile memories, it is very likely to replace flash memory in the future.Table 1. New Non-volatile Memories Basic SituationsItemPerformanceManufactureLimitationApplicationFerroelectric RAM(FRAM)1) low energy consumption 2) high read & write speed3) long storage time4) low power operation5) anti-radiationsmaller size1) limit read & write times2) low storage density3) low reliability1) RF IC card2) fast-start memory3) embedded cache4) aerospaceMagnetic RAM(MRAM)1) high read & write speed 2) unlimited read & write times3) low power operationsimple circuithigh cost1) storage2) industrial automation, 3) games 4) energy management 5) communication 6) transportation7) aerospace electronics8) sensor terminalsPhase Change Memory (OUM) 1) long service life2) safety 3) low energy consumption1) small capacity2) low cost1) lower read &write speed2) poor temperature characteristic1) wired and wireless communications2) consumer electronics 3) PC and embedded devicesPolymeric RAM1) good stability 2) low power operation1) 3D stack2) easy processing3) low cost1) limit read & write times, 2) destructiveness1) PC 2) digital camera 3) mobile phoneFRAMa. IntoductionFRAM is the non-volatile memory technology in the new generation. In terms of performance, it consumes low energy and can store data for a long time although there is power failure. It combines the characteristics of high read-write speed of RAM and long-term data storage of ROM. Embedded FRAM in the non-volatile memory situation of radiation-resistant and low-power has great significance. It can be embedded in the chip in a more direct way and has better performance than any other alternative chips. In terms of manufacturing and technology, FRAM is easier to reduce size than flash memory due to the advanced nodes (65 nm or smaller), and does not require the use of very thin oxides or high voltages. b. LimitationWhen FRAM reaches a certain times of read and write, FRAM cells will lose their durability, and the FRAM yield problem caused by array size restrictions and further improvements in storage density and reliability still need to be resolved.c. ApplicationFRAM is a non-volatile memory that combines the advantages of low power consumption, high speed, long service life, and anti-radiation. It is promising in RF 1C card, fast startup memory, and system chip of cache and aerospace.d. Commercial progressFrom the point of international respect, well-known American company Ramtorn, which developed the first 4K bit commercial ferroelectric memory in 1993; after 1998, Ramtorn focused on product research and development, and handed over all production to semiconductor manufacturers. With the time goes by, Ramtorn represents the highest level of PZT-based commercial ferroelectric memory. Many other countries started late in the field of ferroelectric research and mainly based on scientific research. For example, the main work of some countries is still the preparation of ferroelectric thin films. MRAMa. MRAM BasicsMRAM is a non-volatile memory. For the performance, the write speed of MRAM is extremely fast, almost 1000 times that of flash memory, and 20 times that of FRAM. And it has unlimited read and write times, also it can switch on and off instantly and extend the battery life of portable computers. In terms of manufacturing and technology, the circuit of MRAM is simpler than ordinary memories, and only one readout circuit is needed for chip access. In addition, MRAM is easier to integrate (only 5 photomask layers are needed in the entire process), and there is no need to redesign at the transistor level of flash memory. All other core technologies used in the design can remain the same and work consistently.From 1986 to 1988, Albert Fert and Peter Grünberg discovered that nano-multilayer films composed of alternating ferromagnetic and non-magnetic metal layers made of molecular beam epitaxy have a much larger size than AMR, which is named as giant magnetoresistance (GMR). GMR is a quantum mechanical magnetoresistance effect observed in multilayers composed of alternating ferromagnetic and non-magnetic conductive layers, but it was difficult to put into practice. Soon, further research by Parkin team found that the (ferromagnetic / non-magnetic metal / ferromagnetic) three-layer film made by sputtering technology has a much larger giant magnetic resistance at room temperature than a single-layer ferromagnetic metal. For the spin valve, opened the way for practical use of GMR.The discovery and research of GMR had led to the realization of high-sensitivity read heads in high-density disks, and promoted the development of the entire modern hard disk industry. The earliest application of spin valve sensors in hard disk read heads was in the IBM Deskstar 16GP Titan, which was released in 1997 and has a storage capacity of 16.8GB. In 2007, Hitachi introduced the Deskstar 7K1000, the first 1TB hard drive.b. MRAM LimitationMRAM is much higher than flash memory in the production costs.c. MRAM ApplicationWith the advantages of low power consumption, high-speed reading, high integration, radiation resistance and unlimited rewrites, MRAM is used in storage, industrial automation, gaming, energy management, communications, consumption electronic,transportation and avionics fields. In addition, the IOT and big data analytics are gradually emerging,ubiquitous sensor terminals need to collect massive amounts of data, in order to save storage power consumption, MRAM and STT-MRAM have become the better choices for their relatively good performance.d. MRAM Commercial ProgressIn 2006, Freescale launched the world’s first commercial MRAM product with a capacity of 4Mb. Judging from the current product specifications and development status, the use of MRAM is still limited to some specific markets. From the perspective of cost and capacity, it cannot compete with NAND flash memory with a maximum capacity of 8Gb and DRAM with 512Mb capacity. However, with Samsung, Intel, TSMC and Global Foundry and other integrated circuit leaders strengthening investment in R & D and related production lines, STT-MRAM is gradually begin mass production, partially replacing SRAM and DRAM products and becoming one of the mainstream memories. OUMa. OUM BasicPhase change memory is a kind of memory that realizes information storage through material phase change. It is the non-volatile and large-capacity storage technology advocated by Intel, the world's number one semiconductor chip manufacturer. In terms of performance, it has a long read and write operation life and is easier to integrate than flash memory. OUM memory cells are extremely dense, and read operations is more safer than other memories. Low energy consumption, requiring very low power to operate. In addition, OUM unit can write about 1 billion times, which makes it an ideal alternative to large-capacity memory in portable devices. From the aspect of manufacturing process, compared with the integration of existing logic circuits, its storage unit is only 1/3 of MRAM and FRAM, and its production cost is lower than other new memories.Crystalline Phase and Amorphous Phase ChangeAlthough phase change memory is often categorized as “new memory”, the concept of “phase change” has introduced over 50 years. In 1962, the phase transition of As-Te glass was discovered. In 1968, Stanford Robert Ovshinsky described in an article that certain semiconductor materials can rapidly switch between two different states of resistance and conductivity under the action of an electric field (on the order of 10μs), he utilized chain structures, cross links, polymeric concepts, and divalent structural bonding with a huge number of unbonded lone pairs to achieve what is now referred to as the “Ovshinsky Effect”, an effect that turns special types of glassy, thin films into semiconductors upon application of low voltage. This discovery directly led to a large number of subsequent studies on the phase transition of thin films based on tellurium-arsenide-germanium-silicon alloy materials or sulfur-based glasses. In 1970, Nevill and Gordon Moore demonstrated the world’s first 256-bit phase change memory, and Moore was later known for putting forward the famous “Moore's Law” about the number of transistors in a dense integrated circuit doubles about every two years and served as the co-founder of Fairchild Semiconductor and CEO of Intel. After that, research on semiconductor memories based on phase change materials has gradually slowed down due to issues such as materials and power consumption, but phase change materials have been used very successfully in rewritable optical discs such as CD-RW / DVD-RW.   b. OUM LimitationThe read and write speed and frequency of OUM are not as good as FRAM and MRAM, and how to maintain its driving temperature stably is also a big technical problem.c. OUM ApplicationPhase change memory is suitable for wired and wireless communication equipment, consumer electronics, PC and other embedded applications due to its fast read and write speed, strong upgrade capabilities, and low power consumption. For example, it is used in the aerospace embedded system and used in smart meters to further integrate its storage architecture.d. OUM Commercial ProgressPhase change memory, as one of the most promising new memories, can be embedded at all levels of the memory architecture. Because of the similarity between phase change memory and dynamic memory, especially its lower power consumption and scalability, it has been considered as the best substitute for dynamic memory. But phase change memory also has disadvantages. The first is its limited times of erases and writes (usually only 107 to 108). If the number of erasing and writing exceeds this limit, the life of the memory cell will end, and the device can no longer be used. The second disadvantage is the limited write speed. The write speed of phase change memory is 6-10 times slower than dynamic memory. Write Operation of Phase Change Memory UnitNevertheless, phase change memory still has good applications in some fields. Several related studies have proposed various methods to overcome these shortcomings. For example, an architecture adjustment is used to compensate for the loss caused by the performance of writing, which can greatly reduce power consumption, thereby accelerating the commercialization of phase change memory as the main memory of a computer.In addition, the multi-level cell technology has been successfully implemented on phase change memory. In the design of a multi-level cell phase change memory, 2N resistive states are used to represent N digits, respectively, in other words, in a 2-bit multi-level cell phase change memory, 00, 01, 10, and 11 can be represented by four different resistance values, respectively. In the specific design, the resistance of the phase change material can be changed by adjusting the amplitude and time of the writing current / voltage. PFRAMa. PFRAM BasicsPFRAM is a plastic, polymer-based, and non-volatile memory. In terms of performance, PFRAM has advantages such as good stability and low power consumption. From manufacturing process, high density can be obtained through three-dimensional stacking technology, which is easy to make and has extremely low manufacturing costs, only about 10% of NOR-type flash memory.b. PFRAM LimitationPFRAM has a limited read and write operation life and its reads are destructive.c. PFRAM ApplicationThe final product of (PFRAM will be an all-organic storage system, which will be suitable for personal computers, handheld computers, digital cameras, mobile phones, handheld radios and communication devices, GPS systems, audio, video, game background program and other important fields.d. PFRAM Commercial ProgressPFRAM develops slowly in commercial use, and Intel is in a leading position. In 2014, Intel recruited JonKrueger (architecture and software engineer) to work for its polymer memory group and greatly promote the development of multi-layer plastic memory, finally their work is close to the software development stage, which indicates that this memory technology will accelerate to the market.Memory technology will continue to improve to meet different applications. On the one hand, The new type memories will create a new market and enter various application markets, on the other hand, it involves new materials and research concepts, it will be difficult to become the mainstream of the market in a long time. However, in the aerospace, industrial automation,  embedded cache of system chip and other sub-application areas, the new non-volatile memory will gradually transfer its technological breakthroughs to market penetration and achieve rapid development.With the advent of the 5G era, the development of application markets such as the IOT, artificial intelligence, and smart cities, and the urgent need for diverse memory requirements, coupled with traditional memory market change, new type memories will play an increasingly important role in the market. Ⅳ Questions Related to Non-volatile Memory and Going Further 1. Which memory is called non-volatile memory?Examples of non-volatile memory include read-only memory (see ROM), flash memory, most types of magnetic computer storage devices (e.g. hard disks, floppy discs and magnetic tape), optical discs, and early computer storage methods such as paper tape and punched cards. 2. Which is non-volatile memory RAM or ROM?RAM, which stands for random access memory, and ROM, which stands for read-only memory, are both present in your computer. RAM is volatile memory that temporarily stores the files you are working on. ROM is non-volatile memory that permanently stores instructions for your computer. 3. What is another name for non-volatile memory?Non-volatile memory (NVM) or non-volatile storage is a type of computer memory that can retain stored information even after power is removed. 4. Which is the most non-volatile memory?NAND flash, the most common type used in data storage, includes several variants, such as single-level cells or one bit per multi-level cell or two bits per cell; three-level cells or three bits per cell and quad-level cells or four bits per cell, respectively. 5. What is non-volatile memory explain with example?NV or non-volatile memory is a term used to describe memory or storage that is saved regardless if the computer has power. ... An example of non-volatile memory and storage is a computer hard drive, flash memory, and ROM.

CatalogIntroductionⅠ Fuse Box Diagram in Your CarⅡ Fuse Box Diagram-Harley Davidson Softail2.1 Accessing the Fuse Box2.2 Fuse Box Cover2.3 Scheduled Maintenance of your Fuse Box2.4 Common Issues Ⅲ Fuse Box Diagram-Harley Davidson Touring (2000-2016)3.1 Fuse Box Location3.2 Fuse Box Diagram3.3 Inspecting FusesⅣ Fuse Box Diagram Harley Davidson Dyna Glide (2000-2015).4.1 Component Breakdown of the Fuse4.2 Common Issues Ⅴ Acura TL(2004-2014): Fuse Box Diagram5.1 Fuse Box5.2 Finding the Correct Fuse5.3 Inspecting and Replacing FusesⅥ Porsche 997(2005-2012): Fuse Box Diagram6.1 Fuse Box DiagramⅦ Honda Civic(1992-2000): Fuse Box Diagrams7.1 Honda Civic (1992-1995) Component Breakdown7.2 Honda Civic (1996-2000) Component BreakdownⅧ 2001 Ford F150 Fuse Box Diagram8.1 F150 Fuse Types8.2 2001 Ford F150 Fuse Box Location8.3 2001 F150 Passenger Compartment Fuse Box8.4 2001 F150 Engine Fuse Box DiagramIntroductionMany common electrical problems can be traced back to a blown fuse. But where can you find them? How can you know if they're working or not? Do you have a good understanding of the fuse box diagram? How do you address the situation? This article will shed some light on fuse boxes, how to locate your desired fuse, and how to examine and replace blown fuses, among other things. Let's have a discussion about it.Ⅰ Fuse Box Diagram in Your CarIf the car's electrical equipment were not working properly, a fuse could have blown. The presence of split wires inside the fuse characterizes complicated fuses. Before rebuilding any electrical parts, inspect the machine. Replace a fuse with one that is sized appropriately for the state it is replacing. If you use a larger amperage fuse, you risk damaging the wires and starting a fire.Fuse and relays are typically found inside a vehicle's passenger compartment and engine compartment. Fuses are built to withstand a given quantity of electricity at or above a certain power level. It helps to keep parts and wires from being burned out by high currents. An overload in a circuit might result in a short circuit. Relay - an electrical mechanism (switch) designed to close and open electrical circuits under certain conditions.Our fuse box diagrams can assist customers in determining which type of fuse to use on a particular electrical system. To see how the fuse and relay boxes are laid out on your car, utilize our internet scan to locate them. Similarly, you can select a car from the menu on the right or from the list that follows.A fuse box is a very obvious device, and replacing burned-out fuses is a simple task. Moving a fuse is far better than hunting for extra equipment or maintenance expenses you won't need (even if it means paying a car mechanic to do it), so take a few minutes to identify your fuse boxes. Your owner's manual will assist you in locating your seats.You must turn off the car's ignition before working on a fuse box. Never replace a fuse unless the new one is the same as the old one. The replacement fuse must be the same color and size as the previous fuse, or the circuit will not function.The fuse box contains a map that shows which fuse is for what purpose and how many amps it is. If the amperage of the fuse you're changing differs from the one on the map, it suggests the fuse was incorrectly changed, which could have caused an electrical failure.Cars and other vehicles are also equipped with blade-type fuses with prongs that plug into the car's fuse panel in the same way as appliances plug into walls. They come in a variety of sizes and can be used in a variety of amps. You may check the fuse's integrity by looking at the transparent filaments in its little slot. They are no longer functional if they have been fused or burned out.Ⅱ Fuse Box Diagram-Harley Davidson Softail2.1 Accessing the Fuse BoxAssume your fuse box is located beneath the seat. To remove the seat, you must first unscrew the screws that keep it in place and then remove the strap.Fuse box located under the seatLifting the seat reveals the fuse boxIf you need more assistance locating the fuse box on your Softail, here's a handy fuse box diagram:This fuse box diagram will help you figure out where to look for the fuse box on your Harley.2.2 Fuse Box CoverThe fuse box cover is particularly useful because it includes a diagram of the fuses in your fuse box. Make sure the diagram does not get rubbed off.Fuse box coverSee the fuse box diagram below to see which fuse handles which function and system:Detailed fuse box diagram2.3 Scheduled Maintenance of your Fuse BoxWhen one of your electrical systems, such as a headlight, horn, running lights, or turn signals, fails, you will need to open your fuse box. You can examine a fuse or use a tester to determine its condition.Visible fuse examinationTest your fuse2.4 Common IssuesMake certain that the fuse you're using to replace the broken fuse has the same amperage as the fuse you're replacing.Make sure your new fuse matches the old one.Ⅲ Fuse Box Diagram-Harley Davidson Touring (2000-2016)Fuse failures are frequently caused by old age and vibration, rather than by an electrical short. If you find yourself replacing the same fuse over and over again, it's a clue that you have a greater problem than a blown fuse, most likely a short circuit. When confronted with an electrical problem, it's a good idea to always check your fuses first.3.1 Fuse Box LocationThe fuse box on a Harley Davidson Touring is usually positioned beneath the seat, however, it can also be found under the left side cover. You can get to it by unscrewing the bolt on the back of the seat and sliding it off. The fuse box will be waiting for you right there. The fuse box cover is a plastic lid that contains a diagram of all the fuses and relays. So, if your turn signals aren't working, you can find the fuse that's causing the problem, inspect it, and replace it if necessary.Typical fuse box location3.2 Fuse Box DiagramThe fuse box, as previously stated, has a cover with a diagram printed on it. All you have to do is look at Figure 3 below, or at the cover of your fuse box, find the component that is causing you problems, and then match the number with the fuse. Remove the fuse, inspect it, and replace it if needed.Fuse Box Diagram-Harley Davidson3.3 Inspecting FusesIf you have an electrical problem with one of your bike's components, use the diagram to locate the right fuse to check. Remove the fuse and inspect the metal line within. A blown fuse may appear scorched, but it may also be blown more softly if the metal line is severed. Replacing a blown fuse can usually solve your electrical problem. You can check for continuity in the fuse without removing it if you have a multimeter or a test light. Good fuse vs. blown fuseⅣ Fuse Box Diagram Harley Davidson Dyna Glide (2000-2015)It is fairly typical to notice a blown fuse before any severe electrical failure if you have an electrical problem. Although a fuse may occasionally blow due to vibration or simply age, it usually indicates that there is another problem in the system that has to be addressed.A fuse box diagram is divided into three sections: fuse labels, amperage rating, and maxi-fuse. Once you've mastered all of these concepts, you'll be able to simply locate fuses and troubleshoot malfunctioning electrical components.Typical fuse box location on a Harley Davidson Dyna4.1 Component Breakdown of the Fuse Fuse LabelsThis fuse box schematic includes numerous numbered boxes with labels printed beneath them. Each of these numbers corresponds to a slot on the actual unit, and the label indicates the electrical component/system it belongs to. A replica of this diagram is usually seen on the cover over the fuse box on the bike.The fuse diagram direct from the factory manualFuse AmperageIf you look attentively at a fuse, you'll notice that it has a number printed on it. This number, which is normally white, indicates the maximum amount of current that the fuse can safely handle. Fuses must be changed with corresponding amp fuses or the associated electrical component may be destroyed.You can clearly see the amperage of each fuseThe Maxi FuseThe maxi fuse, also known as the main fuse, is a specific component on the bike that supplies power to all of the electrical components. To avoid any inadvertent shock, it is frequently disconnected when electrical components are being replaced. The maxi fuse is the largest of them all and is identified as the "Main Fuse" on the diagram. Disconnecting it is simpler than disconnecting the battery terminals and accomplishes the same result.The location of the maxi fuse on a typical Dyna4.2 Common Issues Blown FuseCheck the condition of the appropriate fuse if there is an electrical problem. Fuses are designed to act as a first line of defense if too much power is flowing through the system at once. Sometimes it is not the actual component that has failed, but rather the fuse itself.Open or Short CircuitThese issues are more related to the wire harness itself. An open circuit indicates that there is a break somewhere that is causing the current to cease flowing, but a short indicates that the wire is connected straight to the ground or to another component that it should not be. Both are a problem, however only an open circuit indicates that something isn't working, whereas a short can inflict more damage.Ⅴ Acura TL(2004-2014): Fuse Box DiagramThe Acura TL has two fuse boxes, and knowing your fuses can help you solve a lot of problems. When it comes to electrical problems, the fuses in your Acura TL are the best place to start. Each fuse in your fuse boxes is in charge of one or more electrical components. When a fuse receives too much electricity, the metal piece inside it breaks to prevent electrical overheating.5.1 Fuse BoxThe Acura TL is outfitted with two distinct fuse boxes. One fuse box is positioned beneath the hood, and the other is within the vehicle, in the driver's side footwell. The inside fuse box is in charge of several interior components, such as the dome light and audio, while the outside is in charge of some mechanical components, such as the ignition. Each vehicle's wiring is routed differently, and each brand and model may have various fuses in different fuse boxes.Interior fuse box Exterior fuse box5.2 Finding the Correct Fuse and Fuse Box Diagram  As previously stated, the fuses for each brand and model are located in distinct locations. There are two simple methods for locating the fuse you require. The first step is to look in your owner's manual under the fuses section for the appropriate fuse. The owner's handbook will provide you with a schematic that clearly shows where each fuse is positioned and what each fuse is responsible for. The second method is to open the fuse box and then turn the cover over. Each fuse box cover has a representation, or map, of all the fuses inside. So open the cover and look for the fuse you require.Locate the diagram on the inside of the fuse box cover5.3 Inspecting and Replacing FusesWhen in doubt, examine the fuses. Check the fuse if you have a problem with your car. If your fuel pump is acting up, check the fuse; if your dome light bulb is burnt, check your fuses; and the same applies to all components that are powered by electrical current. Each fuse contains a tiny metal bar within it; this bar is where the current flows, and when the current becomes too much, the bar breaks, saving you from electrical overheating.Keeping this in mind, to inspect a fuse, simply remove it and examine the bar inside. If it's broken, you'll need to replace it, but if it appears to be in one piece, you can continue with the diagnostic process because your fuse is functioning properly. Replace fuses with comparable fuses wherever possible. Inside the fuse box of most autos is a spare fuse or two.Ⅵ Porsche 997(2005-2012): Fuse Box DiagramOne of the fuses in your Porsche 911 will eventually blow. A blown fuse, in most cases, does not cause a severe problem and will not prevent you from driving your automobile. A blown fuse simply signifies that one of the components is not functioning properly. A blown fuse, for example, could cause your radio, interior lighting, brake lights, turn signals, and even a portion of your air conditioning to cease working. A blown fuse is frequently the source of an electrical problem, such as when your interior or exterior lighting ceases working. Before you take your automobile to a repair, check your fuse box and replace any possible blown fuses. You'll solve the problem in less than two minutes nine times out of ten.Also, before purchasing a new set of fuses, check inside your fuse box to see if you have any spare fuses; some automobiles come with extra fuses for you to utilize.Most contemporary vehicles include fuses with plastic housings and fusible connections. Fuse boxes in older vehicles are made of glass and are shaped like cylinders. The extremities of these fuses are stainless steel, and the middle is glass. The fuse box in contemporary cars is normally located under the hood, but the fuse box in older cars is located under the dashboard on the driver's side.6.1 Fuse Box DiagramHere's a diagram of your car's fuse box, along with notes on what each fuse regulates. Having this information on hand will save you from having to examine many fuses to determine which one to repair.Fuse box diagram - porsche-997(2005-2012)Fuse box assignmentⅦ Honda Civic(1992-2000): Fuse Box DiagramsIt's critical to understand where the fuses are located and what each fuse does so that if you ever have a problem, you know where to check first. Always begin the diagnosis of an electrical problem with the fuse because they are simple to test and relatively inexpensive to replace.7.1 Honda Civic (1992-1995) Component BreakdownInterior Fuse BoxOn the driver's side, the inside fuse box is positioned beneath the dashboard. The lid is secured with a clip. Swing the lid down and pull it out to remove it.Figure 1a. Interior fuse panel diagramFigure 1b. Driver's side fuse box.Figure 1c. Interior fuse number and circuit chart.Under the dash is the inside fuse panel (Figure 1a) (Figure 1b). The fuse, it's rating, and what it does are all listed in the table in Figure 1c. If your radio stopped working, for example, you'd need to test fuse number 23 and replace it with a new 15 amp fuse if it was determined to be broken. Because interior fuses frequently fail, it's a good idea to have a pack of varied amperage fuses in the glove compartment.Under the Hood Fuse BoxThe fuse box under the hood is located next to the battery in the engine compartment.Figure 2a. Diagram of the fuse box under the hoodFigure 2b. Fuse box locationFigure 2c. Fuse box explanationThe internal fuse panel (Figure 1a) is positioned beneath the dash (Figure 1b). Figure 1c shows the fuse, it is rating, and what it does. For example, if your radio stopped working, you'd need to test fuse number 23 and replace it with a new 15 amp fuse if it was discovered to be defective. Because interior fuses frequently fail, it is advisable to have a pack of various amperage fuses in the glove compartment.7.2 Honda Civic (1996-2000) Component BreakdownInterior Fuse BoxFigure 3a depicts the arrangement of the interior fuse panel (placed beneath the dash), whereas Figure 3b depicts a table comprising the fuse number, rating, and function of each fuse. If, for example, the radio stopped working, the next step would be to examine fuse number 23 and replace it with a new 15 amp fuse if it is broken. Interior fuses fail more commonly than under-the-hood fuses, so carry an assortment pack of different amperage fuses in the glove compartment.Figure 3a. Interior fuse panel diagramFigure 3b. Interior fuse number and circuit chart.Under the Hood Fuse BoxFigure 4a shows the layout of the fuse panel, which is positioned under the hood, and Figure 4b shows the amperage and what that fuse controls in that area. These fuses are less likely to blow and are larger than those found within the car, so you're less likely to have a replacement if one does blow. Furthermore, if one of these fuses does blow, it is usually a warning that something else is wrong, which led it to fail in the first place.Figure 4a. Fuse box located under the hood diagram.Figure 4b. Under the hood fuse box explanation.Ⅷ 2001 Ford F150 Fuse Box DiagramFuses provide electricity to almost every electrical system in your F150. A fuse is used for power supply in almost all systems that require electricity to operate. The battery in your Ford supplies power to the fuses and relays, which subsequently deliver power to the system to which the fuse is set. Fuses protect your electrical systems by preventing the batteries from overheating and causing the electrical wire to burn out.Fuses are designed to carry certain amounts of power, measured in amps. When a fuse is overloaded, or receives more amps of electricity than it can transmit, it breaks. A "blown fuse" is a word that is commonly used. When you have an electrical problem with your F150, check the fuse to see if it is blown before taking it to a mechanic. Finding and replacing fuses is fairly simple, which is why we always recommend checking them before paying a repair to diagnose the problem. Fuse not only power but also protect electrical systems. If your stereo were overloaded and there was no fuse, your stereo system would be destroyed. However, because a fuse connects the power source and the stereo, the fuse blows, preventing all electrical currents from passing to the stereo and causing it to break.8.1 F150 Fuse TypesFuses are available in a variety of power ratings, sizes, and colors. In general, the colors signify the number of amps that the fuse is designed to handle, however, this figure is frequently printed on the fuse's top as well. It is critical to use the right-sized fuses since using too tiny a fuse will cause the fuse to repeatedly break and using too large a fuse will cause the system it is powering to break.The majority of fuses will fit in the same fuse position. For example, a 5, 10, 15, and 20 amp fuse are all typically the same size. Because they all fit in the same slots, it is critical to consult your fuse box diagram to ensure you are using the correct sized fuse.Blade fuses are typically used in the 2001 F150. There are several types of blade fuses, as listed below, although the majority of those used by Ford are ATO or normal-sized fuses. Ford does, however, use certain larger cartridge-style fuses.Furthermore, relays are used in all automobiles. Electrical circuits are opened and closed by relays, whereas fuses are constantly open circuits. Because practically all electrical systems in your car turn on and off, such as your headlights, relays are required to open and close the circuit to turn them on and off. 8.2 2001 Ford F150 Fuse Box LocationThere are two fuse boxes in the 2001 F150. One can be found inside the cab, to the left of the steering wheel. The second is at the top right corner of the engine bay (drivers side).The interior fuse box is primarily responsible for controlling inside electrics such as the stereo, lights, and power windows, whereas the engine bay fuse box is in charge of towing components, exterior lights, windshield wipers, and numerous engine-related systems such as the fuel pump.Each fuse box is located in a distinct location and has a diagram. It's worth noting that the inside fuse box is referred to in the owner's handbook as the "passenger compartment fuse panel," although the fuse box is located to the bottom left of the steering wheel, not on the passenger side of the car.8.3 2001 F150 Passenger Compartment Fuse Box2001 F150 Passenger Compartment Fuse Box8.4 2001 F150 Engine Fuse Box Diagram2001 F150 Engine Fuse Box Diagram