how to build a lcd screen price

Once it’s recognized that a custom display will be a better design and lead to a lower overall system-level cost it’s time to dive into the actual tooling costs.

There are many factors that go into determining the upfront tooling. There’s also due diligence to be performed prior to making this commitment to ensure that this new custom display supplier will effectively support you over the long term.

Customization can either be semi-custom or fully custom. Semi-custom is where some attributes of a standard product are modified to fit the application. In contrast, fully custom is where the design is started from scratch and each component is designed from the ground up.

Semi-custom is typically the preferred option to start with. And in the case of color TFT, it’s typically the only option, as the TFT panel comes with a significant tooling and minimum order quantity (MOQ) such that the customization costs outweigh the drawbacks of using the closest standard TFT glass platform available.

b) Custom color TFT displays— the bulk of this cost comes from the TFT glass cell at $70K–$200K depending on the type of TFT cell used (standard TN or IPS). The balance of the module is an additional $5,000 – $15,000.

f) Touch panels— resistive touch panels cost approximately $2,500, while capacitive touch panels can range between $4,000 and $10,000. If a standard capacitive touch sensor can be used, and only a custom top surface is customized, the tooling can be reduced to only $1,500.

g) Backlights— monochrome display backlights are less complex and cheaper to tool at $2,000 – $4,000. The color counterpart, due to its high brightness requirement, will run between $4,000 and $10,000.

i) Overlays— this can vary significantly depending on the complexity of the screen printing, as well as any additional features, such as button or LED indicators. The overlay will typically range from $1,500 - $4,500.

Now that we’ve reviewed some of the costs associated with custom displays, here are some tips you can use to make sure that you move forward with the right partner that will then support this custom display for the long term.

Many LCD display manufacturers try to accommodate all order volumes they receive. While this allows them to serve a wider range of customers, it makes them less specialized for serving certain types of customers. As a result, your specific production volumes may be prohibitively expensive.

Seek out a display manufacturer who is optimized to handle your specific production needs for LCD displays. This is necessary to get the display for the right cost and the appropriate level of support.

Always start with a semi-custom approach. Use the available standard products to base the new design on, and then keep modifying as needed. This results in the lowest tooling costs and an easier design process. And in the case of color TFT, unless you are developing the next iPhone, design your display based on one of the standard glass platforms readily available. Then from there, redesign the backlight and the mechanical and electrical interface for your specific application.

Behind every great company are happy customers. Find out whether your supplier has them. Make sure that when this experience is handed off from your supplier’s sales and design team, the production team is just as good and accommodating. This can be accomplished through references and audits.

Initiating a successful relationship for a new custom display is all about having an open and transparent relationship with the right partner. And by designing the ideal custom or semi-custom display with this partner, you can ensure you’re getting the best possible solution for your company.

If you have ever wondered what it took to make your own custom graphic LCD from scratch, this video from [Applied Science] is worth a watch. It’s concise and to the point, while still telling you what you need to know should you be interested in rolling your own. There is also a related video which goes into much more detail about experimenting with LCD technology.

[Applied Science] used microscope slides and parts purchased online to make an LCD that displays a custom graphic when activated. The only step that home experimenters might have trouble following is coating the glass slides with a clear conductive layer, which in the video is done via a process called sputtering to deposit a thin film. You don’t need to do this yourself, though. Pre-coated glass is readily available online. (Search for Indium-Tin Oxide or ‘ITO’ coated glass.)

The LCD consists of a layer of liquid crystal suspended between two layers of conductive glass. An electrical field is used to change the orientation of crystals in the suspension, which modulate the light passing through them. Polarizing filters result in a sharp contrast and therefore a visible image. To show a particular shape, some of the conductive coating is removed from one of the layers in the shape of the desired image. The process [Applied Science] uses to do this is nearly identical to etching a custom PCB.

Parts of LCD technology can be quite hackable. Neither of these videos are brand-new, either. Have any of you taken on the challenge of DIY LCD displays? We’ve seen experiments with electrochromatic glass using old LCD displays, as well as experiments in playing with polarized light to hide secret messages on LCD screens.

Looking to take your project to the next level in terms of functionality and appearance? A custom LCD display might be the thing that gets you there, at least compared to the dot-matrix or seven-segment displays that anyone and their uncle can buy from the usual sources for pennies. But how does one create such a thing, and what are the costs involved? As is so often the case these days, it’s simpler and cheaper than you think, and [Dave Jones] has a great primer on designing and specifying custom LCDs.

The video below is part of an ongoing series; a previous video covered the design process, turning the design into a spec, and choosing a manufacturer; another discussed the manufacturer’s design document approval and developing a test plan for the module. This one shows the testing plan in action on the insanely cheap modules – [Dave] was able to have a small run of five modules made up for only $138, which included $33 shipping. The display is for a custom power supply and has over 200 segments, including four numeric sections, a clock display, a bar graph, and custom icons for volts, amps, millijoules, and watt-hours. It’s a big piece of glass and the quality is remarkable for the price. It’s not perfect – [Dave] noted a group of segments on the same common lines that were a bit dimmer than the rest, but was able to work around it by tweaking the supply voltage a bit.

We’re amazed at how low the barrier to entry into custom electronics has become, and even if you don’t need a custom LCD, at these prices it’s tempting to order one just because you can. Of course, you can also build your own LCD display completely from scratch too.

Liquid Crystal Displays or more commonly known as LCDs are one of the most common electronic components which help us interact with an equipment or a device. Most personal portable equipment and even gigantic industrial equipment utilize a custom segment display to display data. For many portable consumer electronics, a segment LCD display is one of the biggest contributors to the overall cost of the device, hence designing a custom segment display can drive the cost down while also utilizing the display area in the most optimum manner. These displays have the lowest cost per piece, low power requirements, and a low tooling fee too.

At first thought, designing a custom segment LCD might look like a Herculean task, but trust me that it is easier than it seems. In this article, we have summarised and compared the display types and available technologies which are required to construct a custom segment LCD. We have also provided a flowchart that can act as a step-by-step guide while you design your own custom LCD. We have also provided the process we followed, a require gathering sheet we used for communicating our needs to the manufacturer, and a few other data and the quotation we received from the manufacturer.

Icons: A silhouette of any shape can be placed on the glass which enhances the ability to display data. For example, a symbol of a heart can be made to denote heart rate or an icon for a low battery to show that the battery needs to be charged. Icons are counted as a single pixel or segment and can give a lot more details than similar-sized text.

LCD Bias– It denotes the number of different voltage levels used in driving the segments, static drives (explained later in this article) only have 2 voltage levels or 2 bias voltage while multiplex drives have multiple voltage levels. For example, 1/3 will have 4 bias voltages.

LCDs utilizes the light modulating properties of liquid crystals which can be observed by using polarizing filters. Polarizing filters are special materials that have their molecules aligned in the same direction. If the light waves passing through polarisers have the same orientation as the filter, then the molecules of lights are absorbed by the filter, hence reducing the intensity of light passing through it, making it visible.

In Layman’s language, when an electric current is applied to the electrodes, i.e. to the segment line and common line, it twists the Liquid Crystals w.r.t to the polarizing filter, obstructing the light in that particular area as shown in the figure below. Hence, that area becomes darker and prominent.

A custom LCD is important for maximizing the efficiency of the display area by adding custom symbols and characters. It also helps in reducing the cost and improving energy efficiency of the product. A higher number of custom symbols and specified placement of numerical and alphanumerical characters make the display more informative and readable for the user. This makes it look better than the plain old boring displays we get in the market. Furthermore, we can specify the viewing angle, contrast, and other specifications which can increase durability or give a better value for money for our intended usage.  A typical Custom Segment display is shown below, we will also show you how to design and fabricate the same further in the article.

The LCD display doesn’t emit any light of its own, therefore it requires an external source of illumination or reflector to be readable in dark environments.

While designing a custom segment LCD display, we have the leverage of choosing a lot of parameters that affect the final product. From the color of the display to the illumination technique and color of illumination as well as the type of input pins. Some important considerations we need to take while designing a custom 7 segment display are - the type of display, i.e. positive or negative, illumination method, driving technique, polarising type, and connection method. All these design criteria are explained below:

Positive and negative displays can be easily distinguished by the colour of the background and characters. Some common differences between the positive and negative displays are:

So, which one should you choose? When the displays are to be used in areas with higher ambient light, we should select positive segment LCD display as it has better visibility than negative segment LCD displays without using a backlight.

As we know that LED displays don’t emit any light, hence to illuminate it and make it visible in a dark environment, we can use different methods of illumination. The most common LCD Illumination methods are compared below:

For displays that need to be used for budget-friendly devices that should be small and rugged, LED lights are preferred for the displays due to the high durability and low cost of operations. For high brightness, CCFL and Incandescent lights can be used.

A polarizer film is the most important component of an LCD display, which makes it possible to display characters by controlling the light. There are 3 types of polarizers that can be used in the LCD display, the properties and difference are given below:

If your products need to be used with a switchable backlight, then trans-reflective reflectors are best to be used for front reflectors. If the device has to be used without backlight, then we can select a reflective polarizer for the back-panel as it gives the best contrast ratio.

Displays can be categorized into two types, passive displays, and active display, passive displays are simpler to construct as they have 2 connections at each segment, the conductors comprise of an Indium Tin Oxide to create an image, whereas the active displays use thin-film transistors (TFT) arranged in a grid. The name is due to its ability to control each pixel individually.

If your displays have fewer segments, then static LCD drive is preferred as it is easier to control and cheaper to construct, and has a better contrast ratio. But let’s say that if the number of segments in the display are more than 30-40 then a multiplex LCD drive should be preferred as it has multiple common pins, hence reducing the total number of pins required to drive the display.

Choosing a connector type!!! For the prototyping phase or if you need to connect your LCD display on a Microcontroller directly, a pin type connector is the best and most economical option you have. If you need to connect your LCD display in a final product with a high volume of production which also requires to be extremely durable, but at the same time should not take up a lot of space, a Flex type LCD Connector will work best for you

LCDs have limited viewing angles and when seen from an angle they lose contrast and are difficult to be observed.  The viewing angle is defined by the angles perpendicular to the center of the display towards its right, left, up, and down which are denoted by the notations 3:00, 9:00, 12:00, and 6:00 respectively. The viewing angle of LCD can be defined as the angle w.r.t. to the bias angle at which the contrast of segments is legible.

To improve the viewing angle in an LCD, a Bias is incorporated in the design which shifts the nominal viewing angle with an offset. Another technique is to increase the Voltage, it affects the bias angle, making the display crisper when viewed from a direction.

For example, the viewing angle of a TN type TFT LCD is 45-65 degrees. Extra-wide polarising film (EWP) can increase the viewing angle by 10 degrees, using an O film polariser can make the viewing angles 75 degrees but these come at a cost of reduced contrast.

Anti-glare filters are bonded with the top polarising filters using adhesive. It improves the viewability by re-directing light waves so they don’t reflect back towards the viewer thus reducing glare. Newer materials are capable of reducing the front glare by up to less than 0.3%.

LCD Control chip or LCD driver chips can be mounted on the flex cable, display, or externally on a PCB. The placement of LCD control chip can affect the cost and size of the display. The 2 most common methods of chip placement are-Chip of Board (COB)and Chip on Glass(COG) which are described below:

COG can be used as it is cheaper and makes the assembly process simpler, but if the dimensions are a constraint, then the COB is also a viable option.

We planned to design an air quality monitoring system for which we needed a custom segment LCD panel for an air quality monitoring device. Our product needs to display the following data: 2.5-micron and 10-micron particulate matter (PM) suspended in the air; the units should be in parts per million (PPM). CO2 in the air in PPM along with total volatile organic compounds present in the air in parts per billion (PPB). To make the product more usable, we included time in 24-hour format, Temperature in ºC, Battery status, loudspeaker status, Bluetooth status, and Wi-Fi status. And for some personal touch, we also added how good the air quality in the room is by using 3 different smileys.

We realized that it was impossible to provide all these data in a generic LCD available in the market, thus decided to build a custom LCD for our project.

A step-by-step flowchart is shown below to walk you through each and every step of selecting components and getting your custom segment LCD manufactured.

We started by listing down our requirements and drew a mock-up of the display on paper. After finalizing the placement of all the segments and icons on the prototype sketch of the display, we then decided which all icons and segments have to be kept on for the whole time and which needs to be driven. Realizing that there are too many segments, characters and icons, hence we selected a multiplex drive with 8 common pins which helped us bring down the total pins from an estimated 180 pins to less than 40 pins.

Since the device was meant to be used inside houses and offices, which are more often than not well lit and protected from environmental conditions, we opted for a positive mode display. For superior contrast ratio and better viewing angle, we chose a Film Super Twisted Nematic Display (FSTN) with a drive condition of 1/8 Duty and bias of 1/4.

Usually, the displays are mounted at a height of 4.5 feet from the ground, thus the viewing direction was selected to be 12"O clock with an operating frequency of 64Hz. We selected a Transmissive polarizer for the front glass and a reflective polarizer for the rear glass so that the natural light can pass through the front panel and the display can achieve the maximum contrast without the need for backlighting and we opted for the pin type connectors as they are easy for prototyping and are suitable for harsh environment with a lot of vibrations and shocks which best suited our purpose.

In the above image of a custom display design, we sent to the manufacturer, the red lines over multiple characters indicate that all these are considered as a single segment. For the sake of simplicity, we added test like T, S, U, B to denote Text, Symbols, Units, and Battery respectively. These characters were followed by numbers to simplify communication between us and the manufacturer. For example, if we needed any particular text or symbol to remain on, we can easily specify that to the manufacturer by using the corresponding text for that segment.

We mailed our requirements to multiple LCD manufacturers, (you will find a lot of LCD manufacturers on the Internet). Most LCD manufacturers have competitive pricing, and reply within a week. A sample requirement sheet is shown above which a customer needs to fill to specify all the details to the manufacturer.

This is a sample Custom Segment LCD quotation we got from one of the manufacturers. As you can see, the cost is based on the quantity. Higher the quantity, lower the cost. Apart from the cost per quantity, there is one more component called tooling fees. Tooling fee is a one-time fee charged by the manufacturer. It is for the technical design, support, and customization of the product. Customization of PCB or tooling of LCD can drive the tooling price higher or lower.

The tooling time and cost depend on how detailed and accurate designs you sent to the manufacturer. They then send the exact dimensions and technical details of the product they will be manufacturing. Once you confirm the design, they manufacture and ship the product which might take 4-8 weeks to arrive depending on the size of the order and mode of transportation selected.

A custom segment LCD can help you personalize your product while also saving the overall cost of your product. The whole process will take you around 2-3 months, which will include the designing phase, prototyping phase, and getting your custom segment LCDs delivered to your doorstep. Higher ordering quantity will reduce the cost per piece of each unit, thus driving down the cost of your final product.

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Video walls deliver the wow factor and imbue commercial office space with that modern look associated with cutting-edge companies. Video walls display content in a way that is unique and captures the attention of target audiences.

However, the high cost (or at least the perception of a high cost), typically associated with such display technology has prevented many businesses from building their dream video wall.

You can absolutely still create such displays on a budget without breaking the bank, though. This article will provide you with a general overview of what a video wall for a commercial enterprise might cost, from a very simple video wall to a much more elaborate setup. This will help you narrow down the size, style, and price range that fits your needs and budget.

The overall costs of a video wall depend largely on size, processor, type of display technology and quality of video mounts, as well as ancillary costs like installation, making video walls one of the most customizable pieces of technology you can install.

Now, one more note before I start breaking down options and prices. When I talk about video walls, I’m not referring to buying four TVs from a big box store and hanging them together. TVs are problematic as video walls for a number of reasons. Their bezels are usually larger and have logos, they’re usually not bright enough to serve as commercial displays, and they can’t meet the demand of 24/7 usage. You’ll hear me discuss LCDs and LEDs, but when I do, I’ll be referring to monitors, not TVs. It’s an important distinction.

While blended front projections and rear projection cubes are viable options for video walls, LED and LCDs are the most common display technology used for video walls.

Generally, LEDs are more expensive than LCDs (for models that deliver the same image quality), making the latter the budget-friendly choice. The major tradeoff is the LCD’s bezel lines for the line-free LED array.

When viewed from a distance, LED displays deliver a large seamless image presentation that’s ideal for stage presentation screens, corporate branding, and digital signage use cases. Using the correct pixel pitch makes LED display deliver a picture-perfect image that’s free of bezels or lines; however, they are not great for close viewing, though that is improving.

For simple video walls, a basic 2×2 high-quality LCD unit can cost as little as $4800, while larger, more elaborate setups with more advanced features (touchscreen capabilities) can go as high as $30,000.

You also need to consider the cost of mounting hardware and installation. A 2×2 mounting kit costs around $650, freestanding mounting kits go for $2,500 while complex sliding rails for very large displays can cost as much as $100,000. There are cost-effective options for enterprises on a budget as well as elaborate setups for companies who want to pull out all the stops.

A 1.2mm pixel pitch LED video wall costs approximately $2K sq./ft. This figure translates into $200K for a video wall with 160” x 90” outside dimensions. This includes the mounts, panels and installation costs without taking into account the cost of infrastructure, installation and programming and other ancillary costs (like tax and shipping).

While LEDs are more expensive than LCDs, they lend themselves to more customization in terms of size and shape, with the added benefit of being bezel-less.

It’s best not to scrimp on mounts. You should choose a mount that is sufficiently rigid to prevent sagging and able to provide alignment adjustments in all axes when needed. Most importantly, use mounts that permit front serviceability of individual panels. This prevents the need to remove other panels to service just one failed panel, thus reducing the cost of maintenance and repairs.

There is also a new motorized video wall mount that allows monitors to be serviced without even touching them. I’ll discuss this more in a future post.

Video processors handle video rotation, layering, or windowing of content and other custom effects. Depending on the content to be displayed and how it will be displayed, video processors can easily become the most expensive component of the video wall. The cost depends largely on the number of simultaneous layers displayed on the wall at a given time and the number of physical inputs and outputs required. Processors can range from $15k to $80K, depending on complexity.

For very simple video walls, you can purchase processors that cost far less. However, you should always go for good quality processors since low-quality ones may produce slow videos that will ruin the effect of your displays.

Now, some video wall monitors actually have tiling built in, so basic functionality already exists within the displays themselves. So if what you are displaying is very simple and straightforward, you may not even need a processor.

Also, custom content needs to be created (or scaled to fit) for video walls that don’t come in standard resolutions like 1080P, 2K,4K, etc. You might want to avoid such non-standard walls since it can be quite expensive to create such custom content. Instead, try to use a video wall layout that maintains standard aspect ratios. For LED walls, this means a 16:10, 16:9, or other cinema aspect ratios while LCD arrays should come in 2×2, 3×3, 4×4, and other standard array sizes.

With the wide range in prices of video wall components, processors, mounts and other ancillary fees, companies can afford to build a video wall, no matter their budget constraints. While DIY installation costs can help reduce costs, it isn’t advisable. You should always look for reliable, high-quality vendors and installation experts to help you create the ideal video wall for your business.

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If you go to another service provider, they can set their own fees, so ask them for an estimate. For service covered by AppleCare+, your fee per incident will be the same regardless of which service provider you choose.

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Depending on the issue, you might also have coverage with AppleCare+. Terms and Conditions apply, including fees. Feature availability and options may vary by country or region.

We guarantee our service, including replacement parts, for 90 days or the remaining term of your Apple warranty or AppleCare plan, whichever is longer. This is in addition to your rights provided by consumer law.

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Advanced LED video wall with MicroLED models in 0.6, 0.7 and 0.9mm pixel pitches, and 1.2mm pixel pitch standard LED; with powerful processing, proprietary alignment technology and off-board electronics.

Planar® CarbonLight™ VX Series is comprised of carbon fiber-framed indoor LED video wall and floor displays with exceptional on-camera visual properties and deployment versatility, available in 1.9 and 2.6mm pixel pitch (wall) and 2.6mm (floor).

From cinema content to motion-based digital art, Planar® Luxe MicroLED Displays offer a way to enrich distinctive spaces. HDR support and superior dynamic range create vibrant, high-resolution canvases for creative expression and entertainment. Leading-edge MicroLED technology, design adaptability and the slimmest profiles ensure they seamlessly integrate with architectural elements and complement interior décor.

From cinema content to motion-based digital art, Planar® Luxe Displays offer a way to enrich distinctive spaces. These professional-grade displays provide vibrant, high-resolution canvases for creative expression and entertainment. Leading-edge technology, design adaptability and the slimmest profiles ensure they seamlessly integrate with architectural elements and complement interior decor.

Advanced LED video wall with MicroLED models in 0.6, 0.7 and 0.9mm pixel pitches, and 1.2mm pixel pitch standard LED; with powerful processing, proprietary alignment technology and off-board electronics.

From cinema content to motion-based digital art, Planar® Luxe MicroLED Displays offer a way to enrich distinctive spaces. HDR support and superior dynamic range create vibrant, high-resolution canvases for creative expression and entertainment. Leading-edge MicroLED technology, design adaptability and the slimmest profiles ensure they seamlessly integrate with architectural elements and complement interior décor.

Advanced LED video wall with MicroLED models in 0.6, 0.7 and 0.9mm pixel pitches, and 1.2mm pixel pitch standard LED; with powerful processing, proprietary alignment technology and off-board electronics.

LED video wall solution with advanced video wall processing, off-board electronics, front serviceable cabinets and outstanding image quality available in 0.9mm pixel pitch

Planar® CarbonLight™ VX Series is comprised of carbon fiber-framed indoor LED video wall and floor displays with exceptional on-camera visual properties and deployment versatility, available in 1.9 and 2.6mm pixel pitch (wall) and 2.6mm (floor).

Carbon fiber-framed indoor LED video wall and floor displays with exceptional on-camera visual properties and deployment versatility for various installations including virtual production and extended reality.

a line of extreme and ultra-narrow bezel LCD displays that provides a video wall solution for demanding requirements of 24x7 mission-critical applications and high ambient light environments

Since 1983, Planar display solutions have benefitted countless organizations in every application. Planar displays are usually front and center, dutifully delivering the visual experiences and critical information customers need, with proven technology that is built to withstand the rigors of constant use.

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LCD panel prices have risen for 4 months in a row because of your home gaming? Since this year, the whole LCD panel market has smoked. Whether after the outbreak of the epidemic, LCD panel market prices rose for four months, or the panel giants in Japan and South Korea successively sold production lines, or the Chinese mainland listed companies frequently integrated acquisition, investment, and plant construction, all make the industry full of interesting.

LCD panel prices are already a fact. Since May this year, LCD panel prices have risen for four months in a row, making the whole industry chain dynamic. Why are LCD panels going up in price in a volatile 2020? The key factor lies in the imbalance between supply and demand.

The 43 inches and 55 inches rose more than double digits in August, reaching 13.7% each, and rose another $7 and $13, respectively, to $91 and $149, respectively, in September.

For larger sizes, overseas stocks remained strong, with prices for 65 inches and 75 inches rising $10 on average to $200 and $305 respectively in September.

The price of LCDS for large-size TVs of 70 inches or more hasn’t budged much. In addition, LTPS screens and AMOLED screens used in high-end phones have seen little or no increase in price.

As for October, LCD panel price increases are expected to moderate. The data shows that in October 32 inches or 2 dollars; Gains of 39.5 to 43 inches will shrink to $3;55 inches will fall back below $10; The 65-inch gain will narrow to $5.

During the epidemic, people stayed at home and had no way to go out for entertainment. They relied on TV sets, PCS, and game consoles for entertainment. After the resumption of economic work and production, the market of traditional home appliances picked up rapidly, and LCD production capacity was quickly digested.

However, due to the shutdown of most factories lasting 1-2 months during the epidemic period, LCD panel production capacity was limited, leading to insufficient production capacity in the face of the market outbreak, which eventually led to the market shortage and price increase for 4 consecutive months.

In fact, the last round of price rise of LCD panels was from 2016 to 2017, and its overall market price has continued to fall since 2018. Even in 2019, individual types have fallen below the material cost, and the whole industry has experienced a general operating loss. As a result, LCD makers have been looking for ways to improve margins since last year.

A return to a reasonable price range is the most talked about topic among panel makers in 2019, according to one practitioner. Some manufacturers for the serious loss of the product made the decision to reduce production or even stop production; Some manufacturers planned to raise the price, but due to the epidemic in 2020, the downstream demand was temporarily suppressed and the price increase was postponed. After the outbreak was contained in April, LCD prices began to rise in mid-to-late May.

This kind of price correction is in line with the law of industrial development. Only with reasonable profit space can the whole industry be stimulated to move forward.

In fact, the market price of LCD panels continued to decline in 2018-2019 because of the accelerated rise of China’s LCD industry and the influx of a large number of local manufacturers, which doubled the global LCD panel production capacity within a few years, but there was no suitable application market to absorb it. The result of excess capacity is oversupply, ultimately making LCD panel prices remain depressed.

Against this background, combined with the impact of the epidemic in 2020, the operating burden of LCD companies in Japan and South Korea has been further aggravated, and it is difficult to make profits in the production of LCD panels, so they have to announce the withdrawal of LCD business.

business in June 2022. In August, Sharp bought JDI Baishan, a plant in Ishikawa prefecture that makes liquid crystal display panels for smartphones. In early September, Samsung Display sold a majority stake in its SUZHOU LCD production plant to Starlight Electronics Technology, a unit of TCL Technology Group. LGD has not only pulled out of some of its production capacity but has announced that it will close its local production line in 2020. According to DSCC, a consultancy, the share of LCD production capacity in South Korea alone will fall from 19% to 7% between 2020 and 2021.

It is worth mentioning that in industry analysis, in view of the fact that Korean companies are good at using “dig through old bonus – selling high price – the development of new technology” the cycle of development mode, another 2020 out of the LCD production capacity, the main reason may be: taking the advantage of China’s expanding aggressively LCD manufacturers, Korean companies will own LCD panel production line hot sell, eliminating capacity liquid to extract its final value, and turning to the more profitable advantage of a new generation of display technologies, such as thinner, color display better OLED, etc. Samsung, for example, has captured more than 80% of the OLED market with its first-mover advantage.

From the perspective of production capacity, the launch of LCD tracks by major manufacturers in Japan and South Korea must reduce some production capacity in the short term, which to some extent induces market price fluctuations. In the long run, some of the Japanese and Korean LCD production capacity has been bought by Chinese manufacturers, coupled with frequent investment in recent years, the overall capacity is sure to recover as before, or even more than before. But now it will take time to expand the production layout, which more or less will cause supply imbalance, the industry needs to be cautious.

The LCD panel industry started in the United States and then gradually moved to Japan, South Korea, China, and Taiwan. At present, the proportion of production capacity in The Chinese mainland has reached 52% in 2020, and there are leading LCD panel products in China represented by BOE, Huxing Optoelectronics. Meanwhile, the production capacity layout of BOE, Huike, Huxing Optoelectronics, and other manufacturers has been basically completed, making industrial integration a necessity.

On the one hand, South Korean enterprises out of the LCD track, the domestic factory horse enclosure, plant expansion action. While LCDs may not sell as well as “upstart” flexible screens, respondents believe they are still strong enough in the traditional home appliance market to warrant continued investment. Zhao Bin, general manager of TCL Huaxing Development Center, has said publicly that the next-generation display technology will be mature in four to five years, but the commercialization of products may not take place until a decade later. “LCD will still be the mainstream in this decade,” he said.

On the other hand, there is no risk of neck jam in China’s LCD panel industry, which is generally controllable. In mainland China, there will be 21 production lines capable of producing 32-inch or larger LCD panels by 2021, accounting for about two-thirds of the global total. In terms of the proportion of production capacity, the Chinese mainland accounted for 42% of the global LCD panel in 2019, 51% this year, and will continue to climb to 63% next year.

Of course, building factories and expanding production cannot be accomplished overnight. In the process of production capacity recovery, it is predicted that there will be several price fluctuations, and the cost may be passed on to the downstream LCD panel manufacturers or consumers when the price rises greatly, which requires continuous attention.

From the company that created the world’s first folding phone comes an open-source kit to help anyone build their own products with flexible displays!

Royole has shown an incredible ability to find the right niche and pivot at the right time with their technological offerings. The company arguably built the first-ever flexible smartphone – the FlexPai – outpacing even Samsung, and their RoKit now aims at helping democratize the fully flexible display (FFD), so creatives and designers can tinker with it, building their own products too.

The kit comes packaged in a pretty impressive aluminum briefcase, containing everything you need to bring your unique tech idea to life. The upper part of the briefcase houses Royole’s 3rd Generation Cicada Wing 7.8-inch fully flexible touch-sensitive display, while the lower half of the briefcase contains a development motherboard running Android 10, an HDMI adapter (in case you want to connect your flexible display to an existing computer like a Raspberry Pi, smartphone, laptop, or any other gadget), and a bunch of power cables for good measure.

The idea behind the RoKit, says Royole Founder and CEO Dr. Bill Liu, is to “invite every industry to imagine and design with flexibility in mind, unfolding new possibilities for creators and accelerating the development of flexible solutions in all walks of life.” Envisioned as the world’s first open platform flexible electronics development kit, the RoKit allows other creators to do exactly what Royole did with the FlexPai in 2018 – create electronic products that the world has never seen before.

To show how limitless their flexible displays can be, Royole’s even created a few conceptual products that highlight exactly how folding screens can make products sleeker, smaller, and better. The examples include (as shown below) handheld gimbals/cameras with slide-out displays, a slick monolithic computer that transitions magically from keyboard to screen (I wonder where they got that idea from), and even a helmet with a rear display that contours perfectly to the shape of the head, allowing you to communicate efficiently with drivers behind you.

For now, the RoKit is available for purchase on the Royole website in the United States, United Kingdom, Germany, Japan, and China. Priced at $959, it definitely isn’t cheap, although one could make the case that it’s just about affordable for being able to test out and prototype a product before you actually develop it with mass-produced flexible displays.

- In this video, we will build a simple display screen. Since I was listening to myself carefully in the prior videos, I will start by using the strategy of making a curve, looking for command line options that will help out, and then leveraging existing work whenever possible. Before we build the display screen let"s take a look at a bad example, which is always fun. So I"m going to turn on this layer down here at the bottom. Now here we"ve got a LCD display screen. You might notice it looks a little bit odd. Typically they"re not flush in consoles like this. Also we"ve got some very sharp edges so no fielding whatsoever. So again, just keep this in mind as an example of what not to do. Turn that back off. We"re going to go over here. So let"s build our first curve. I think it might be easier to do this in another viewport here because this is going to appear on the front face. So I"m going to switch from perspective to front view, double-clicking on the label to zoom in. I"d like to…

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