The Kynix Blog - Optoelectronics

What are Transistor Output Optocouplers?Transistor output optocouplers are like magic bridges. They safely pass signals between two places without letting the electric currents mix. Definition and functionTransistor output optocouplers are like secret messengers in electronic devices. They use light to send electrical signals from one part of a device to another. This way, they keep the two parts safely apart by up to 15000 Vrms.Think of it as sending a text message instead of talking face-to-face; it's safer when there's a thunderstorm outside! These components have a forward voltage between 1.1 V and 1.9 V, which means they're very efficient at turning on their LED light emitters without needing lots of power.Their main job is to protect sensitive circuits from high voltages and noise. Imagine you have a super-sensitive microphone that needs protection from loud concerts next door. Optocouplers can absorb that "noise," keeping your recordings clear without mixing the sounds or letting harmful electrical currents through.They work by having an LED (light-emitting diode) on one end and a photo-transistor on the other. When electricity flows into the LED, it shines onto the photo-transistor, telling it to let current flow through too – all without any direct electric connection between them! Types (AC/DC input, Darlington/Single transistor output)Transistor output optocouplers are like secret agents in electronics. They quietly work behind the scenes to make sure signals pass safely from one place to another without any drama. Here's a quick look at their types:AC Input Optocouplers: These devices can handle alternating current (AC) signals. Imagine you have a light switch in your house (the input) that needs to tell a lamp (the output) to turn on, but they don't speak the same language. An AC input optocoupler steps in between them, receiving the flick of the switch as an "on" command and then telling the lamp to light up.DC Input Optocouplers: Direct current (DC) signals are their specialty. They're like the direct talkers who take a straight path, handling inputs that don't change back and forth. Think of them as being perfect for gadgets like your handheld video game console, where pushing a button sends a clear, consistent signal.Darlington Transistor Output: These power players can handle lots of current—up to 30 mA! They use not just one but two transistors together for extra strength. It's like having two bodyguards instead of one, making sure your electronic signals get where they need to go safely and with more oomph.Single Transistor Output: For tasks that don't need quite so much muscle, single transistor outputs are ideal. They manage up to 360 uA and work well in situations where finesse is more important than brute force—like sending a delicate signal to adjust the sound on your headphones.Each type serves its purpose based on what's needed: more power or precision, handling waves or straight lines. I once used a Darlington transistor output optocoupler in my DIY speaker project to isolate my music player from the amplifier circuitry—it worked like a charm keeping hums and buzzes away from my tunes! How Optocouplers WorkOptocouplers use light to send signals, making them the secret agents of electronic parts. They act like a switch that can turn things on or off without being connected by wires.Use of light to conduct currentMagic happens inside an optocoupler. Think of it as a tiny concert where light from an LED acts as the music that gets the phototransistor to dance, conducting current and completing the circuit.This special performance can handle a forward current between 70 uA and 150 mA, showcasing how these tiny components play big roles in electronic devices by turning lights into actions.Light bridges the gap where electricty fears to tread.I once had a project that seemed haunted by electrical noise—the kind that turns a simple task into a nightmare. Here's where things got interesting: I introduced transistor output optocouplers into my design, mainly because they promised isolation voltages ranging from 500 Vrms to an impressive 15,000 Vrms.Suddenly, voila! The ghosts were gone. Current flowed smoothly thanks to this invisible light show, proving that sometimes what you can't see is what saves the day. Operation as a switchTransistor output optocouplers work like magic switches. They let one part of a circuit tell another part to turn on or off without them being directly connected. Imagine you have two friends who don't speak the same language, but they can still play a game together because you're there to translate.That's kind of what an optocoupler does with electrical signals. It uses light, like from an LED, to send the "on" or "off" message across an isolation barrier. This keeps both sides safe and happy.From my own tinkering in the garage, I've learned that these gizmos are perfect for controlling stuff like motors and lights without risking damage from high voltages or nasty electrical noise.You just need a tiny bit of current to make the LED glow, which then activates the transistor on the other side. Depending on whether you've got a simple phototransistor or something beefier like a Darlington transistor setup, you can control pretty hefty loads with just a wisp of input signal – it feels almost like using Jedi mind tricks on your electronics! Input and output current ratingsOptocouplers need the right amount of current to work properly. Think of them like plants needing water—not too much or they'll drown, not too little or they'll dry up. The forward current for these devices ranges from 70 uA (that's microamperes) to a solid 150 mA (milliamperes).This is what powers the LED inside, making it shine and send signals. On the flip side, we have something called maximum collector current, which goes from a tiny 360 uA up to 30 mA.This part deals with how much current can flow through when the optocoupler switches on and does its job of passing signals along.From my own experience messing with circuits in my garage, getting these currents right makes all the difference. If you're off even by a bit, your signal might come out looking more like static than anything useful.Imagine talking into a fan—that choppy voice effect is what happens when things aren't aligned just right in an electric circuit. So keeping an eye on input and output currents isn't just good practice—it’s crucial for making sure your gadgets do what you want them to without any funny business. Load design considerationsDesigning the load for transistor output optocouplers needs careful thinking about power and operating temperatures. Keep in mind, these devices manage power from 30 mW to 240 mW and work best between -65°C to 150°C.Choosing the right load resistance is crucial. It's like picking a team for tug of war; too weak or too strong could mess up the game. For instance, pick a resistor that matches your circuit needs without causing the optocoupler to overheat or underperform.From my own experience, I once had a project where adjusting the feedback control loop made all the difference. I was using an optoisolator with a photo-diode in an audio amplifier setup at first but faced distortion issues due to mismatched load design.After several trial and error attempts, replacing it with one having lower capacitance and fine-tuning its emitter follower significantly improved both sound quality and reduced noise, proving how crucial matching your electronic component's specs can be in real-world applications. Applications of Transistor Output OptocouplersTransistor output optocouplers work magic in bringing safety and precision to your gadgets, from making sure your home stereo does its job without a hitch to keeping big machines in factories running smoothly.So, if you're curious about how these tiny parts play a huge role in everything electronic around you, stay tuned for more!Use in analog applicationsOptocouplers shine in analog applications, like audio amplifiers, where smooth signal handling is key. They keep signals clean and undisturbed by electrical noise from other parts of a device.This clarity is crucial in high-fidelity sound systems that rely on the pristine transfer of audio signals. Think of optocouplers as gatekeepers that ensure only the purest sounds pass through, making them heroes in your stereo or speaker setup.In motor drive systems, these components play a pivotal role too. They manage current and voltage to protect circuits from harm due to sudden surges or drops. Here, transistor output optocouplers act like vigilant guardians, watching over the heart of motors and keeping dangerous currents at bay.Whether it's spinning a hard drive or controlling an industrial robot arm, they help everything run smoothly. Benefits in electronic control and isolationTransistor output optocouplers offer top-notch benefits in electronic control, making them heroes in our gadgets. They act as a bridge for signals between different sections of a circuit, safeguarding the sensitive parts from high voltages.Imagine using a walkie-talkie to communicate safely from inside a lightning storm—that's what these little guys do for electrical circuits. By providing this isolation, they comply with international safety standards, ensuring that our devices are efficient and safe to handle.From power supplies to analog circuits and everything in between, these components shine by allowing low voltage signals to control higher power ones without direct contact. It's like having an invisible hand turning switches on and off without ever touching them, preventing accidents caused by unexpected surges or electrical noise.My experience tinkering with a digital signal project showed me how crucial these isolators are; they kept my micro-controller safe while I managed AC mains with ease. This kind of peace of mind is invaluable whether you're building something small at home or designing complex systems for industrial use. Latest InnovationsCurious about the newest tricks in optocoupler tech? Peek into how they're shaking things up and get answers to your top questions.New advancements in optocoupler technologyOptocouplers are stepping into the future with new models like VO615A-3X007T, TCMT1102, ILD207T, and SFH6206-3T. These bad boys bring enhanced isolation voltage to the table, making them tough against electrical shocks.They can also keep cool in high temperatures. Imagine a tiny gadget that acts as a mighty shield for sensitive circuits. That's what these upgraded optocouplers do—they stand guard.The PS2xxx and RV1S2xxx series are game-changers too. They're designed for devices that need to be on their A-game all the time, like medical equipment or industrial machinery. I had a chance to test out one of these series in a LED light project.It was mind-blowing how smoothly it handled loads without breaking a sweat—even with constant on-off switching! This is solid state tech at its finest, working magic by ensuring everything stays connected without any hiccups. ConclusionTransistor output optocouplers are like magic bridges. They link low-power gadgets to high-voltage systems without risking a shock. Think of them as guardians, keeping your devices safe from unwanted electrical noise.With every blink of their LED eyes, they switch currents on and off, making sure signals pass through safely. From powering up big machines to protecting delicate circuits, these components prove that great things indeed come in small packages.Their ability to talk between different voltage systems makes them unsung heroes in our electronic environment. FAQs1. What's the buzz about transistor output optocouplers in power supply systems?Transistor output optocouplers are like secret agents in your power supply system! They provide electrical isolation, handle noisy signals, and control inrush currents for smooth operations.2. Can you break down how these opto-couplers work?Sure thing! Imagine an LED (light emitting diode) and a photo-coupler having a chat over infrared light. The LED sends signals using this light, which the photo-coupler picks up to control current transfer ratio (CTR). It's like passing notes in class but with light.3. How do these devices help with switching regulators?Switching regulators can be as stubborn as mules when it comes to maintaining phase margin or controlling voltage difference. That's where our superstar - the transistor output optocoupler steps in! It works like a feedback circuit or control loop making sure everything runs smoothly.4. Are there different types of transistor output optocouplers?Yes indeed! From common emitter bipolar transistors to Darlington transistors - they're all part of this big happy family called 'transistor output optocoulers'. Each type has its own specialty, just like members of any team.5. Why would I use an Opto-Isolator instead of a transformer?Well, think of transformers as old-school walkie-talkies and opto-isolators as modern smartphones! While both get the job done, opting for an Opto-Isolator means dealing with less bulkiness (no iron core), better handling of AC voltages and providing superior isolation against ground loops.6. Do Transistor Output Optocouplers only work with certain circuits?Not at all! These handy little devices can play nice with many circuits – from simple logic gates to complex power electronic setups involving semiconductors and power transistors. 

Ⅰ IntroductionThis article focuses on the electronic component known as the Optocoupler. (For the fiber-optic networking component, please refer to Optical Isolators). This guide covers the fundamentals of optocouplers, their working principles, specifications, and practical examples of how to implement them in your circuits.Optocoupler Related VideoVideo: How an Optocoupler Works and Example CircuitⅡ Photocouplers, Opto-couplers & Opto-isolatorsThese devices are known by a variety of names, including optoisolator, photocoupler, and optocoupler.An optocoupler is a semiconductor device that transmits an electrical signal between two isolated circuits using light. This process ensures there is no direct electrical connection between the input (source) and the output (load), effectively protecting sensitive low-voltage components.While often used interchangeably, there is a technical distinction in the industry:Optocoupler: Typically refers to devices used to transfer analog or digital information between circuits with voltage differentials below 5,000 Volts.Optoisolator: Often refers to devices specifically designed to withstand very high voltage differentials (5,000V to 50,000V+) for safety isolation in power systems.Optocouplers are typically housed in small packages ranging from standard DIP (Dual Inline Package) to tiny SMD (Surface Mount Device) packages. Despite their small size, they play a massive role in linking data, optical encoding, and detecting position transitions on encoder wheels.They are also the core technology inside Solid-State Relays (SSR), allowing low-power logic signals to switch high-power AC or DC loads without any mechanical parts.Figure 1: Typical Photocouplers in DIP packagingⅢ Photocoupler / Optocoupler BasicsAn optocoupler consists of two main internal elements encased in a light-tight body:The Emitter: Usually a Near-Infrared LED (Light Emitting Diode) that converts the electrical input signal into light.The Detector: A photosensitive device (such as a phototransistor, photodiode, or TRIAC) that detects the light and generates an electrical output.These two components are separated by a transparent dielectric barrier (glass, plastic, or air gap). Because the connection is made via light photons rather than electrons, the input and output sides are electrically isolated. This isolation prevents high voltages or rapidly changing voltage spikes on one side from damaging components on the other.Ⅳ Optocoupler SymbolIn circuit diagrams, the optocoupler symbol illustrates its internal functionality. The left side typically shows the LED (Emitter), and the right side shows the receiver (Detector).Figure 2: Optocoupler circuit symbol (Phototransistor output)Common Variations:Phototransistor: The most common type for DC signal switching (shown above).Photo-Darlington: Uses a Darlington pair transistor for much higher gain (sensitivity) but slower switching speed.Photo-TRIAC / Photo-SCR: Used for controlling AC power mains.Figure 3: Photo-TRIAC circuit symbol (used for AC control)Ⅴ Optocoupler Specifications to WatchWhen selecting a component, consult the datasheet for these critical parameters:1. Current Transfer Ratio (CTR)This is the equivalent of "gain" (Beta) in a standard transistor. It is the ratio of the output collector current ($I_C$) to the input LED forward current ($I_F$), expressed as a percentage.Standard Phototransistor: CTR ranges from 10% to 100%.Photodarlington: CTR can range from 500% to 5000% (high sensitivity).Design Note - CTR Degradation: The efficiency of the internal LED decreases over time (aging). A good engineering practice is to design your circuit assuming the CTR will drop by 50% over the product's lifespan.2. Bandwidth and SpeedThis determines the maximum data rate.Phototransistors: Generally limited to about 250 kHz.Photodarlingtons: Slower, often limited to < 20 kHz due to long turn-off times.High-Speed Optocouplers: Devices like the 6N137 use a photodiode + logic amplifier architecture and can handle 10 MHz or more.3. Input Current ($I_F$)This is the current required to light up the internal LED. You must calculate a series resistor to limit this current, typically between 5mA and 20mA for standard devices.4. Isolation Voltage ($V_{iso}$)The maximum voltage difference the component can withstand between the input and output pins without electricity jumping the gap. Common ratings are 2500V to 5000V RMS.Ⅵ How It WorksThe operation is straightforward:Current is applied to the input side, flowing through the internal infrared LED.The LED emits infrared light inside the package. The intensity of this light is proportional to the input current.The light strikes the photosensitive base of the output transistor (or Triac).The photosensitive device "turns on" and conducts current.Figure 4: The internal light pathWhy is the Base pin unconnected?In many 6-pin optocouplers (like the 4N25), the base of the transistor is broken out to a pin (Pin 6). However, in most applications, this pin is left floating (unconnected) because the light serves as the base current. Connecting a resistor from the base to the ground can reduce sensitivity but increase switching speed.Figure 5: Effective isolation between Input and OutputⅦ Benefits and TypesPrimary Benefits:Ground Loop Elimination: Breaking the ground path between two circuits prevents hum and noise (critical in audio and instrumentation).Safety: Protects low-voltage microcontrollers (3.3V/5V) from high-voltage spikes (110V/220V).Level Shifting: Allows a 3.3V signal to switch a 24V or 48V circuit effortlessly.Common Types:Photo-Transistor: General-purpose DC switching.Photo-Darlington: High gain for very low input currents.Photo-SCR / Photo-TRIAC: Designed for interfacing with AC power mains.Logic Gate Output: (e.g., 6N137, H11L1) Includes internal logic buffers for high-speed digital communications.Figure 6: Common output configurationsⅧ Typical ApplicationsMicroprocessor I/O: Protecting GPIO pins on Arduinos or PLCs.Switch Mode Power Supplies (SMPS): Used in the feedback loop to maintain voltage regulation while keeping the mains side isolated from the low-voltage side.Motor Driving: Isolating the control logic from the noisy high-current motor drivers.Example: Triac Optocoupler for AC LoadsBy using a device like the MOC3020, a 5V digital signal can trigger a large external Triac, which in turn controls an AC motor or lamp. Many Triac optocouplers feature Zero-Crossing Detection, which ensures the device only switches when the AC voltage is at zero, significantly reducing Electromagnetic Interference (EMI).Figure 7: A basic DC switching configurationⅨ Differences Between Optocouplers and Solid State Relays (SSR)While they operate on the same principle, the distinction lies in power capability and integration.Figure 8: Solid State Relays (SSRs)Optocouplers: Low power. Used for signal transmission. Usually requires external components (external Power Triacs or MOSFETs) to switch heavy loads.Solid State Relays: High power. They contain an optocoupler plus the high-power switching components and protection circuitry inside a single, larger block. They can switch tens of Amps directly.Ⅹ How to Use an Optocoupler with ArduinoConnecting a load directly to an Arduino is risky. If the load is a motor or a solenoid, "flyback" voltage spikes can destroy the microcontroller. Using an optocoupler like the 4N25 or PC817 resolves this.The Circuit Concept:The Arduino drives the internal LED of the optocoupler. The optocoupler's output transistor acts as a switch for the secondary circuit.Figure 9: 4N25 OptocouplerWiring Guide (4N25 to Arduino):1. Input Side: Connect Arduino Pin -> 220Ω Resistor -> Optocoupler Pin 1 (Anode). Connect Pin 2 (Cathode) to Arduino GND.2. Output Side: Connect the device you want to control. Important: If you are using the optocoupler to send a signal into another digital pin, you must use a Pull-up Resistor on the collector (Pin 5) because the phototransistor can only pull voltage down to ground; it cannot "source" voltage effectively.Figure 11: Basic wiring diagram for isolating a signalⅪ FAQ1. What are the disadvantages of an optocoupler?The main disadvantages are speed and power handling. Standard optocouplers have a relatively slow frequency response compared to digital isolators. Also, the output phototransistor cannot handle high currents directly; it usually requires an external transistor or relay to switch heavy loads.2. Is an optocoupler the same as a relay?Not exactly. While both isolate circuits, a mechanical relay uses a physical electromagnet and moving contacts (clicking sound). An optocoupler uses light and has no moving parts. Optocouplers are faster and last longer but handle much less current than relays.3. How do you use an optocoupler for analog signals?While mostly used for digital switching, linear optocouplers exist. To send audio or analog data, you set up a specific bias current (standing current) through the LED and modulate that current with your signal. Specialized "Linear Optocouplers" use feedback photodiodes to linearize the output.4. How do I ensure the optocoupler switches fully (Saturation)?To use an optocoupler as a solid switch, you must drive it into "saturation." This means ensuring the input current ($I_F$) is sufficient and the output collector load resistor is high enough so that the phototransistor turns completely on. Always check the CTR curve in the datasheet.5. Are optocouplers analog or digital?They are fundamentally analog devices (light intensity varies with current), but they are most commonly used in digital applications (On/Off switching). Specialized high-speed digital optocouplers (logic-output) are available specifically for data transmission. ul { margin-bottom: 20px; } li { margin-bottom: 10px; } .caption { text-align: center; font-size: 14px; color: #7f8c8d; margin-top: -15px; margin-bottom: 25px; font-style: italic; } .note-box { background-color: #e8f6f3; border-left: 5px solid #1abc9c; padding: 15px; margin: 20px 0; font-size: 16px; } .warning-box { background-color: #fff3cd; border-left: 5px solid #ffc107; padding: 15px; margin: 20px 0; } strong { color: #d35400; } .faq-item { margin-bottom: 20px; background: #fff; padding: 15px; border: 1px solid #eee; border-radius: 5px; } .faq-question { font-weight: bold; color: #e67e23; font-size: 18px; display: block; margin-bottom: 10px; }

CCD image sensors still remain preferable in some specialised application.Today I would like to talk something about CMOS image sensor technology. As the development of image sensor,CMOS technology is widely used in most machine vision applications.What's excited,perhaps as the concepts behind industry 4.0 become adopted more broadly--the need for mre capable vision systems has grown sharply. This is a video of CCD vs CMOS sensors Catalog   Historical and modern CMOS Improve productivity, support high bandwidth   readout Inherent flexible available About the high resolution Design the right products Conclusion FAQ Machine vision systems use images to gather information on a system or process and to then make decisions based on the image captured.While such systems are dependent upon lighting and software,the camera-and the image sensor within it-is the key component in the overall operation of the system,as well as the ability to improve manufacturing quality and increase productivity.At a high-level,a typical machine vision application involves som combinaton of basic measurement,counting or inspection functions.Objects may be assessed to confirm the number of objects present,to determine the number and size of features or their quality level.So machine vision could be used to not only determine that the proper number of holes have been drilled into an item, but also to verify the spacing and shape of each hole. Similarly, the location of an object may be determined in order for it to be picked up by a robot arm or to determine whether a feature is in the correct place. Other functions include reading a barcode, performing character recognition or measuring the level of a fluid.So machine vision could be used to not only determine that the proper number of holes have been drilled into an item, but also to verify the spacing and shape of each hole. Similarly, the location of an object may be determined in order for it to be picked up by a robot arm or to determine whether a feature is in the correct place. Other functions include reading a barcode, performing character recognition or measuring the level of a fluid.   Historical and modern CMOS Historically, machine vision systems have required CCD image sensors because of their high image quality and performance.  Today, however, CMOS image sensors have jumped to the forefront for many machine vision applications. Advances in CMOS pixel design have made the imaging quality available from this platform sufficient for a variety of different end uses.Modern CMOS image sensor platforms, such as that used in ON Semiconductor’s PYTHON family, are based on a global shutter pixel design that enables the capture of moving objects without the introduction of motion artefacts. In-pixel correlated double sampling provides low readout noise, while on-chip fixed pattern noise correction helps preserve image quality. Combined with a 10bit A/D converter and a dynamic range of 60dB, these features allow machine vision systems to leverage the intrinsic advantages of a CMOS platform in their operation.   Improve productivity, support high bandwidth readout With many machine vision applications looking to operate at ever higher speeds in order to increase productivity, image sensors must support high bandwidth readout. The output architecture of the CMOS platform enables this as additional digital outputs can be added to increase the available bandwidth. For example, the use of up to 32 separate LVDS outputs enables high resolution PYTHON devices to realise bandwidths that exceed those of modern computer interfaces, including 10Gbit Ethernet or USB 3.1. The ability to output at up to 80frame/s from a 25Mpixel device is well beyond the capabilities of standard CCD designs. Inherent flexible available The inherent flexibility available in CMOS output designs allows the frame rate to be further increased when operating in Region of Interest (ROI) mode, where only a portion of the image sensor array is read out. With proper design considerations, the speed increase when operating in this manner can scale by both the x and y dimensions of the ROI, enabling faster frame rates than can be realised when using a more standard CMOS output design, which only scales the x dimension. Consider the frame rates from the PYTHON 5000 image sensor compared to theoretical frame rates from a similar 5Mpixel sensor using a standard CMOS output. At full resolution, both designs would provide approximately 100frame/s, but when reading out a 1280 x 720 pixel ROI, the the PYTHON device’s frame rate increases to almost 600frame/s, while the standard output design would increase to only 300frame/s. This can be an important differentiator.    About the high resolution While high resolution can provide finer detail, this must be balanced by making sure that too much information is not captured, which would slow data processing. In addition to having the right number of pixels, they need to be in the appropriate aspect ratio for the application. For example, an aspect ratios of 1:1 is often used in pick and place applications to maximise image capture across the full field of view. Different spectral sensitivities, such as colour, monochrome and extended near infrared (NIR), may also be required to optimise the imaging system for the application. In order to do this, a camera manufacturer will look for an integrated family of image sensor products that includes multiple resolution nodes and colour options to support a portfolio of products.The PYTHON family has more than 40 options, with resolutions ranging from VGA to more than 25Mpixel. These devices are available in multiple configurations, including monochrome, Bayer Color and extended NIR sensitivities. Selected devices are available in low-power configurations or with removable tape to protect the image sensor during the camera assembly process.   Design the right products Avent Silica offers a range of evaluation kits to help designers understand the performance available from the PYTHON family of image sensors.These kits include an image sensor,the appropriate sensor headboard,FPGA evaluation board and software and accessories.The Flexible design also allows the evaluation hardware to be use with other PYTHON devices by purchasing additional image sensors.After identifying the most appropriate image sensor, designers then need to consider the remainder of the camera design. Complementary products from ON Semiconductor include embedded boards, power and signal chain components that allow engineers to choose between modular solutions and the flexibility of a discrete design. If a machine vision system needs to be brought to market quickly, it may not be possible to build it from the ground up. For those applications, Avnet Silica products such as the PYTHON-1300-C camera module. Based on the PYTHON 1300 colour image sensor and featuring a 0.5in SXGA CMOS image sensor with a resolution of 1280 x 1024 pixels, the module can be combined with Avnet Silica’s MicroZed Embedded Vision Carrier Card and the Smart Vision Development Kit to provide a complete hardware design, leaving the designer to only write the application software.\ Conclusion Because of the combination of image quality,bandwidth,image flexiblity and configuration flexiblity available from MOS image sensors has accelerated adoption of this technology in machine vision applications.What's celebrating,The imaging capabilities of such devices has ushered in a new level of performance and functionality for industrial imaging and CMOS sensor based imaging is now suitable for use in almost every type of design.   FAQ   1. How does a CMOS image sensor work? Unlike CCD sensors that use high-voltage analog circuits, CMOS sensors employ a smaller digital circuitry that uses less power, and are in principle free from smear (vertical white streak in the image taken under bright light) and blooming (corruption of images such as white spots).   2. Which sensor is better CCD or CMOS? CMOS sensors have thousands. This means that CMOS cameras can read out incredibly fast, even 100X faster than a comparable CCD. For long-exposure applications that is not so important, but it is especially important for video cameras.   3. Is CMOS a full frame sensor? "Full frame" is a description of sensor size, sort of... "CMOS" is a name for semiconductor technology used to make sensors. So, they are definitely different, and not comparable.   4.What is CMOS sensor type? A CMOS sensor is an electronic chip that converts photons to electrons for digital processing. CMOS (complementary metal oxide semiconductor) sensors are used to create images in digital cameras, digital video cameras and digital CCTV cameras.   5. What is the function of image sensor? An image sensor is a device that allows the camera to convert photons – that is, light – into electrical signals that can be interpreted by the device. The first digital cameras used charge-coupled devices, facilitating movement of the electrical charge through the device so it could be modulated.   6. What is difference between CCD and CMOS? The biggest difference is that CCD sensors create high quality images with low noise (grain). CMOS images tend to be higher in noise. CCD sensors are more sensitive to light. CMOS sensors need more light to create a low noise image at proper exposure.   7. What CCD means? Charged Coupled Device. Stands for "Charged Coupled Device." CCDs are sensors used in digital cameras and video cameras to record still and moving images. The CCD captures light and converts it to digital data that is recorded by the camera. For this reason, a CCD is often considered the digital version of film.     8. What is CCD and CMOS? CCD (charge coupled device) and CMOS (complementary metal oxide semiconductor) image sensors are two different technologies for capturing images digitally. Each has unique strengths and weaknesses giving advantages in different applications.   9. Is CMOS sensor good? CMOS sensors traditionally have lower quality, lower resolution and lower sensitivity. CMOS sensors are just now improving to the point where they reach near parity with CCD devices in some applications. CMOS cameras are usually less expensive and have great battery life.   10. How does a CCD work? Fundamentally, a charge coupled device (CCD) is an integrated circuit etched onto a silicon surface forming light sensitive elements called pixels. Photons incident on this surface generate charge that can be read by electronics and turned into a digital copy of the light patterns falling on the device.  

SummaryIt has been successfully demonstrated that a nanocrystal of of perovskite can serve as a quantum emitter of light, and, when coupled with a nanophotonic cavity, can dramatically improve the efficiency of the light emission by an international research team from the University of Maryland and ETH Zurich in Switzerland.  A new device features perovskite nanocrystals and a series of nanophotonic cavities. The arrows indicate the way that the UV laser used to excite the crystals, and the light  the crystals produce, move in and out of the device. Described in the Journal Applied Physics Letters ,the resulting device and method could be used to build nanolasers and optical devices that exhibit much faster response times than currently possible. Previously, there have been other quantum emitting materials that have been coupled to nanophotonic cavities. In this area, epitaxial materials such as quantum dots have garnered the most research interest. Distinct advantage to using PerovskiteHowever, the researchers believe there are some distinct advantages to using perovskite nanocrystals instead of epitaxial materials, which involve the fairly complex deposition of a crystalline layer on a crystalline substrate.Instead of the epitaxial techniques, the perovskite nanocrystals are synthesized using inexpensive colloidal chemistry techniques. This also makes it possible for these crystals to be placed on a broad range of substrates using simpler solution-deposition techniques when they are coupled to various photonic structures. The other main set of advantages for perovskites in light-emitting applications relates back to why they have become such a darling in photovoltaics: their optical and electrical properties. Perovskites exhibit a slow non-radiative decay rate and low densities of carrier-trapping defects, which contributes to their high photoluminescence efficiency at room temperature.In addition, the emission spectrum could cover the whole visible range by controlling the size and material composition, especially for the blue-green wavelengths that are otherwise difficult to access. The device operates by exciting the coupled system using a UV laser. This excites the perovskites to a higher energy level. Within a nanosecond, the exciton (an excited electron-hole pair) will decay to its ground state while transforming its energy in the form of an emitting photon. The cavity introduces more decay channels to the emitting materials, so a majority of the photons are coupled into the cavity and form the standing mode of the cavity. Finally, the researchers are able to detect the photons leaking away from the cavity, which is the emission signal. Difficult metThe problem that previous attempts have encountered in working with nanocrystal perovskites has been the material quality. “We need emitters with good photostability, so it can hold the performance when coupling to the cavities, said Yang. “Our collaborators from ETH provided perovskites that make this coupling possible.” In addition to nanolasers and faster optoelectronics, Yang believes the device they have made could increase the efficiency of existing perovskite emitting devices, such as LEDs, which could open up real-world applications in efficient illumination and displays. Before these aspirations can be realized, Yang concedes that they will need to further improve the performance and stability of the material itself. Second, it would be better to excite the material electrically rather than optically for practical use.Yang will try to realize similar devices spanning the whole visible range and the next step it to find ways to further improve and stabilize the performance and also utilizing electrical gates to excite the material in devices. Article source: Applied Physics LettersArticle edited by kynix 

As the development of social technology,computer is becoming an universal things in families.The huge increase in computing performance in recent decades also has been achieved by squeezing ever more transistors into a tighter space on microchips. However,it's the tighter space on microchips that leads to effects such as signal leakage betwwen components,which will slow down communication between different parts of the chip. People in technology call this kind of delay as " interconnect bottleneck" as it is becoming an increasing problem in high-speed computing system.  Researchers are trying their best and all their professional knowledge to consider how to solve this problem. According to Pablo Jarillo-Herrero,an associte professor of physics at MIT,however,one way to tackle the interconnect bottleneck is to use light rather that wires to communicate between different parts of a microchip.But it is a hard work that the material "sillicon" used to build chips,does not emit light easily. The article about a light emitter and detector that can be integrated into sillicon CMOS chips was published in the Journal Nature Nanotechnology,a monthly peer-reviewed scientific journal published by Nature Publishing Group.This paper was written by MIT postdoc Ya-Qing Bie who joined Jarillo-Herrero and an interdisciplinary team including Dirk Englund, an associate professor of electrical engineering and computer science at MIT . According to this paper,the device is built from a semiconductor material called molybdenum ditelluride. This ultrathin semiconductor belongs to an emerging group of materials known as two-dimensional transition-metal dichalcogenides.  Unlike conventional semiconductors, the material can be stacked on top of silicon wafers, Jarillo-Herrero says."Researchers have been trying to find materials that are compatible with silicon, in order to bring optoelectronics and optical communication on-chip, but so far this has proven very difficult,for example,gallium arsenide is very good for optics, but it cannot be grown on silicon very easily because the two semiconductors are incompatible." on the contrary,the 2-D molybdenum ditelluride can be mechanically attached to any material.Another difficulty with integrating other semiconductors with silicon is that the materials typically emit light in the visible range, but light at these wavelengths is simply absorbed by silicon.Molybdenum ditelluride emits light in the infrared range, which is not absorbed by silicon, meaning it can be used for on-chip communication.To use the material as a light emitter, the researchers first had to convert it into a P-N junction diode, a device in which one side, the P side, is positively charged, while the other, N side, is negatively charged. In conventional semiconductors, this is typically done by introducing chemical impurities into the material. With the new class of 2-D materials, however, it can be done by simply applying a voltage across metallic gate electrodes placed side-by-side on top of the material.Jarillo explained continuelly:""That is a significant breakthrough, because it means we do not need to introduce chemical impurities into the material [to create the diode]. We can do it electrically." Once the diode is produced, the researchers run a current through the device, causing it to emit light."So by using diodes made of molybdenum ditelluride, we are able to fabricate light-emitting diodes (LEDs) compatible with silicon chips." The device can also be switched to operate as a photodetector, by reversing the polarity of the voltage applied to the device. This causes it to stop conducting electricity until a light shines on it, when the current restarts,so that the devices are able to both transmit and receive optical signals. This device is a proof of concept and there are a great deal of work need to be done before the technology can be developed into a commercial product, Jarillo-Herrero says. The researchers are now investigating other materials that could be used for on-chip optical communication.Most telecommunication systems, for example, operate using light with a wavelength of 1.3 or 1.5 micrometers, howevermolybdenum ditelluride emits light at 1.1 micrometers. This makes it suitable for use in the silicon chips found in computers, but unsuitable for telecommunications systems. "It would be highly desirable if we could develop a similar material, which could emit and detect light at 1.3 or 1.5 micrometers in wavelength, where telecommunication through optical fiber operates,"  Jarillo-Herrero added. In the end,researchers are another ultrathin material called black phosphorus, which can be tuned to emit light at different wavelengths by altering the number of layers used. They hope to develop devices with the necessary number of layers to allow them to emit light at the two wavelengths while remaining compatible with silicon. The article was ended by Jarillo hopes that communication on-chip by optical signals instead of electronic signals because they can do so more quickly whle comsuming less power. Well,let's cheer researchers on and hope them get success in the near future.