crystal clear transparent lcd display quotation

Transparent lcd displays are available in a variety of colors. On Alibaba.com, you can find the type of transparent lcd displays made in a variety of materials. such as polystyrene, inexpensive, and easy to maintain and use. Clear lcd displays in bulk are available at wholesale prices.

Transparent lcdds are flexible because they include more things than a single-, rystal-displays, and membrane-displaysers. Clear lcdds are flexible, which include them that require more maintenance and more than the latter type of display. Find lcdds in bulk available on Alibaba.com.

Transparent LCD displays have a variety of functions and interfaces for different products. On the other hand, LCD displays create a variety of events that will be relevant to the user and interfere with the content.

Find the ideal type of lcd display in bulk, suppliers on Alibaba.com offer a wide variety of lcd displays in bulk. For lcd displays in bulk, it"s free to explore the wide variety of lcd displays in bulk and at wholesale prices.

Transparent LCD’s provide an innovative display solution opening up new ways for brands to promote their products and services. Examples include retail stores looking to advertise a new fashion clothing or accessory, museums securely housing a precious artifact with information displayed on screen or brands looking to launch a new product at a live event or show. The opportunities are endless!

Our Transparent LCD Displays include a Grade A LCD panel with metal bezel protecting the edges / electronics and a media board supporting HDMI or VGA inputs from your PC, Laptop or Media Player.

Transparent screen technology offers intriguing ways to deliver visual information to your audience, being used to reveal or conceal products, objects or artefacts behind the screen.

The combination of HD LCD technology (4K on our 65″, 86″, 98″ version) with a transparent screen substrate opens up creative avenues that were previously closed with traditional LCD displays. Solid black pixels on a transparent background can be used in intriguing ways to hide (and gradually reveal) whatever is behind the screen.

Our Transparent LCD monitors are designed for integration into the customers own furniture housing or display case while our Transparent LCD showcases offer a complete solution including the display, housing and backlight with white or black options available on request. We can also offer custom freestanding options for POP / POS displays. Transparent LCD’s are predominantly fully housed however we’ve recently developed an innovative housing method using a high brightness LED panel which allows the display case sides to remain transparent for improved visibly into the display case.

Using their original design as a starting point, we worked closely with the team at Nike to adapt to the mechanical aspects of the design, the result was a sleek and minimalist set of nine Transparent LCD Display Screens, custom built to suit the applications requirements, bringing Nike’s original concept ideas to life.

Retail windows, interactive booths, display cases, interactive games, vending machines, drinks coolers… the uses for this amazing technology are limited only by your creativity.

Transparent LCD’s comprise of an LCD panel without the backlight with white pixels appearing as transparent. In order to display an image, the Transparent LCD needs to be integrated into a housing with a high bright LED backlight.

We can also offer more complete solutions like our Transparent LCD Showcase that comes fully contained and ready to use with a powerful backlighting system to guarantee the best picture quality.

Yes in order to display an image Transparent LCD’s need to have a strong backlight. Notoriously Transparent LCD’s have also needed some form of housing to achieve optimum image quality, however, Nike’s House of Innovation paired our Transparent LCD’s with powerful, oversized backlights that allowed the screens to be mounted with no surround but still producing a high-quality image.

Transparent LCD’s are arguably the most popular transparent screens but are hindered by their need for a backlight to operate. For applications looking for a similar effect without the backlighting, Transparent OLEDs require no housing or surround but are only currently available in a 55″ screen size with HD quality. For larger transparent screen applications, Transparent LED’s are recommended with external and internal solutions usually installed to glass facades for the impact of an led screen without compromising the view from inside the building.

We also offer transparent projection technologies including our Clearview Rear Projection Film featured in Guardians of the Galaxy as well as at the 83rd Oscars celebration and MTV EMA awards.

Transparent LCD’s are a great way to combine physical and digital displays in one central place making them a popular choice for museums and exhibitions. Our transparent screens can also be integrated into display furniture and appliances & vending machines like freezer doors for supermarkets. Other uses include POS displays, store window displays, trade shows and product launches.

We manufacture in Britain and ship worldwide – if you need further information, a pricing quote, or want to discuss ideas for using our Transparent LCD Display click the link below to contact us, email us via info@prodisplay.com or call us on +44 (0)1226 361 306.

LCD Transparent Displays, transparent screens, transparent monitors, see through screens, transparent touch screen technology, and kits from CDS as we have our own range of transparent screens / displays and transparent video screens manufactured for us, and as we control the manufacturing, we can not only offer more sizes than anyone else in the world, but also guarantee stable supply, long term availability LCDs with amazing quality.  We have replaced the Samsung Transparent Displays / see through Displays and LG Transparent OLEDs that are no longer available!

CDS has increased the use of these see through screens / see through displays / see through computer screens / clear monitors across the world including touchscreen computer screens combined with the transparent LCD touch screens and Transparent OLED displays.

Awesome little transparent OLED display. Its a 128x56 pixels and 1.51 inch diagonal. Super-bright, monochrome (light blue). We powered it up with a Seeeduino for this demonstration.

The latest innovation in liquid crystal displays (LCDs) introduces an incredible Transparent LCD Screen. Now, you’ll not only be looking at an LCD, you’ll be seeing through it and into the area surrounding whatever goodies appear to be ‘housed’ inside it! Touch technology can also be added by using an interactive Touch Foil or IR Touch Frame.

Coupled with a clever Transparent LCD Screen unit set-up, this revolutionary technology, the latest mobile phone, face cream or jewellery is encased inside the display while pictures, video or special effects (think snow and sparkles) simultaneously surround the product to inform and dazzle onlookers.

How does the Transparent LCD Screen it work?The LCD utilises ambient light, with no internal back lighting requirement. For this reason, it is more energy efficient, cost effective and reliable than other displays of similar size.

As part of a transparent showcase, these screens can also be granted touch capability by combining them with touch foils or touch frames, to add an interactive element to your installation. This creates a very powerful impact when the content on screen integrates with real life objects behind the screen, encouraging viewers to interact on a level that will exceed expectations.

The uses for this technology are limited only by your imagination. Retail windows, interactive booths, display cases, interactive games, vending machines, drinks coolers, this list goes on.

We can manufacture bespoke housing for our range of transparent LCD screens, which includes display cases, counters, POS displays, exhibition stands, furniture and cabinets. Other solutions include incorporating transparent displays into fridges, appliances and vending machines.

A large transparent liquid crystal display (LCD) prototype with ultrahigh transmittance and good see-through property is demonstrated in this paper. The transmittance reaches more than 20% by introducing the RGBW pixel arrangement, a thin color filter process, a large aperture ratio design, as well as antireflective polarizer film. The see-through image quality is also greatly improved by suppressing the blurring by using domain reduction pixel design. All these approaches are applicable for large LCD panel products, and we expect broad applications of large transparent LCDs in the near future.

A large transparent liquid crystal display (LCD) prototype with ultrahigh transmittance and good see-through property is demonstrated in this paper. The transmittance reaches more than 20% by introducing the RGBW pixel arrangement, a thin color filter process, a large aperture ratio design, as well as antireflective polarizer film. The see-through image quality is also greatly improved by suppressing the blurring by using domain reduction pixel design. All these approaches are applicable for large LCD panel products, and we expect broad applications of large transparent LCDs in the near future.

Clearview™ transparent heating elements are an optically clear variation of our wire-wound heater that provides superior light transfer with higher durability than comparable technologies.

The wire-wound design brings high heating efficiency and quick thermal response with minimal power consumption. This makes Clearview LCD screen heaters ideal for applications such as computers, battery powered hand scanners, and touch screens.

Optically clear heaters are typically used in applications that require a high degree of light transmission. Clearview"s ultra-fine wire construction gives high optical clarity and ensures optimal light transmission for scanning and imaging applications.

Clearview provides controlled, direct heat to displays, lenses and clear panels, allowing continuous high definition operation of device monitors in low temperature environments. With an LCD screen heater, displays and touch screens remain usable in cold, high humidity/low dew point environments and locations where ambient temperature can change quickly.

Engineering services and consultation are available on every custom heating element order. Contact a specialist today for details about Clearview optically clear transparent LCD screen heaters.

Many people also use these screens as digital signage screens or for a transparent video wall. A fine led display offers a better display, and people use it for advertising media and products.

Installing an LED display screen can help in numerous ways. It is suitable to save costs, reduce noise, increase convenience, and more. Here are some of the best reasons and benefits of choosing an led transparent display screen.

The LED display screen has dedicated modules installed separately on each section of the LED screen. These modules are easily replaceable, making them ideal for long-term use and easy maintenance. It also makes the LED display screens ideal because of convenient maintenance management.

The display device connects to the computer system, which helps control the light-emitting diodes and regulates high energy levels. Users can update the content on-screen anytime they want, making it best for outdoor advertising.

Brightness levels are an optimal way to attract attention. The transparent LED screens have high transparency levels. These screens also have a light-emitting diode, producing higher-quality light. In addition, these screens are a better option than an LCD screens because they also help reduce light pollution.

The high availability of brightness makes the on-screen content crystal clear at night and during the daytime. The LED transparent screens also have a brightness adjustment option, making them best for all weather and environments.

The LED screens have a transparent led module that assists in creating digital signage on screens. You will find this characteristic only in transparent displays.

Transparent LEDs are best known for light emission, good heat dissipation, and rear maintenance modes. In addition, the transparent led displays have a low power consumption rate, which enables the audience to use them commercially without a problem.

The pixel density in these screens is very high, providing high-quality and life-like results in the display. These screens do not require air conditioning because of low heat production and are best for viewing at a distance. You can choose a fixed installation and get all these benefits on a single screen.

Space and volume are significant elements when choosing an LED screen for display. Therefore, an LED display screen takes up as little space as possible. These screens have a compact design, which helps with energy-saving and makes them lightweight.

A transparent LED screen offers appealing, unique, and cost-effective use. These features come from its unique design that helps regulate power consumption better. Have a look at how the transparent LED screen works.

The transparent led display has units of the pixel that determine output quality. The light-emitting diode makes up the pixel results in these screens. The transparent led display screens are an enhanced version of standard LED screens.

These transparent LED displays have a thickness of about 1mm, making them very sleek and allowing them to blend into their environment easily. The glass plates also have a standard distance of 5 μm intervals on each section with liquid crystal material lined up on the screens.

Note that these liquid crystal materials do not emit light themselves but use lamp tubes as standard light sources to function. You will also find a reflective film on the back of the crystal material, which helps with light emission.

The source transmits energy to the lower polarizer in the beginning. This is done through the liquid crystal material. The arrangement of the liquid crystal changes because the upper and lower layer of the transparent LED screen forms FET electrodes.

The system’s changing arrangement also helps create various shades and color differences in the transparent led display. This change occurs through polarizers installed in the system.

Minor abrasions, scratches, and even slight damages will appear on the screen and mess up the transparent screen. Thus, users must ensure care when handling and installing these screens.

Transparent LED screens are similar to opaque screens, such as displaying information, data, and other details. However, the LED display screens do the same while blending perfectly with their surroundings.

The cost-effective screens require less manufacturing time and are flexible for different uses. You might find these transparent LED display screens used in a wide variety of places. Here is a breakdown of some uses for LED screens.

The transparent led display screens have Polyethylene Terephthalate (PET) or Polycarbonate (PC) structures and solid and flexible materials. You can use them in outdoor locations without worrying about environmental protection or damage from external factors.

Showrooms want people to see their top products and profitable entities and increase public attention towards their manufacture. The transparent led screen is the best way to do this because it allows users to add any content to the screens and use them.

This transparent led screen is prevalent in places like museums, galleries, and art exhibitions. Many science and architectural events, like the Dubai Fair, have also used these LED screens.

Navigating your way around a new airport can be challenging for people, but the transparent screen makes it easier for users to know where they need to go. Many airports use these screens to share directions to particular locations to assist visitors.

In addition, the transparent screen also helps share information and advertise particular products. Airports also use these screens to promote other businesses in waiting for travelers to see.

Clubs, bars, cinemas, etc., use transparent screens for all their benefits. Smaller businesses advertise their products/services through these transparent screen displays, nail salons, dog walkers, etc. It also increases customer engagement while spending little to no on advertisement costs.

Shopping malls are another popular place for installing transparent led displays in the entrance areas, and it acts as a guide for customers and provides information about the products. These screens have energy-saving technology, making them ideal for 24×7 use.

Are you looking for a way to make your business more visible and attractive to customers? If so, consider investing in transparent LED screens. These screens are great for grabbing attention and creating an interactive customer experience.

Transparent LED screens are perfect for businesses that want to significantly impact without too much space. If you’re interested in learning more about transparent LED screens or want to order one for your business, reach out to our team today.

G06F3/0481—Interaction techniques based on graphical user interfaces [GUI] based on specific properties of the displayed interaction object or a metaphor-based environment, e.g. interaction with desktop elements like windows or icons, or assisted by a cursor"s changing behaviour or appearance

G06F3/04815—Interaction with a metaphor-based environment or interaction object displayed as three-dimensional, e.g. changing the user viewpoint with respect to the environment or object

This document describes techniques and apparatuses for implementing a transparent display device. A transparent display device includes a transparent or translucent screen to render images on the screen, and to render virtual objects that appear to be in a three-dimensional (3D) space behind the screen. The transparent display device also includes a hand tracker to sense movement of a user"s hands to interact with one or more of the virtual objects, and to generate 3D-input based on the movement. The transparent or translucent screen enables the user to see the user"s hands behind the screen as the user"s hands interact with the one or more virtual objects. The transparent display device is controlled to modify the rendering of the images on the screen or the virtual objects behind the screen based on the 3D-input.

This document describes techniques and apparatuses for implementing a transparent display device. A transparent display device includes a transparent or translucent screen to render images on the screen, and to render virtual objects that appear to be in a three-dimensional (3D) space behind the screen. The transparent display device also includes a hand tracker to sense movement of a user"s hands to interact with one or more of the virtual objects, and to generate 3D-input based on the movement. The transparent or translucent screen enables the user to see the user"s hands behind the screen as the user"s hands interact with the one or more virtual objects. The transparent display device is controlled to modify the rendering of the images on the screen or the virtual objects behind the screen based on the 3D-input.

Embodiments of techniques and apparatuses for implementing a transparent display device are described with reference to the following drawings. The same numbers are used throughout the drawings to reference like features and components:

This document describes techniques and apparatuses for implementing a transparent display device. A transparent display device includes a transparent or translucent screen to render images on the screen, and to render virtual objects that appear to be in a three-dimensional (3D) space behind the screen. The transparent display device also includes a hand tracker to sense movement of a user"s hands to interact with one or more of the virtual objects, and to generate 3D-input based on the movement. The transparent or translucent screen enables the user to see the user"s hands behind the screen as the user"s hands interact with the one or more virtual objects. The transparent display device is controlled to modify the rendering of the images on the screen or the virtual objects behind the screen based on the 3D-input.

FIG. 1 is an illustration of an example environment 100 in which a transparent display device can be implemented. Environment 100 includes a transparent display device 102, which is illustrated, by way of example and not limitation, as one of a smart phone 104, a laptop computer 106, a television device 108, a desktop computer 110, or a tablet computer 112.

Transparent display device 102 includes processor(s) 114 and computer-readable media 116, which includes memory media 118 and storage media 120. Applications and/or an operating system (not shown) embodied as computer-readable instructions on computer-readable media 116 can be executed by processor(s) 114 to provide some or all of the functionalities described herein. Computer-readable media also includes a controller 122. How controller 122 is implemented and used varies, and is described in further detail below.

Transparent display device 102 also includes a transparent screen 124 that is configured to render images on the screen, and to render virtual objects that appear to be in a three-dimensional (3D) space behind the screen. While referred to as a transparent screen herein, transparent screen 124 can be implemented as either a transparent screen or as a semi-transparent or translucent screen. Transparent screen 124 can be implemented to render two-dimensional (2D) images and/or 3D images. For example, in some embodiments transparent screen 124 can render 2D images that are typically displayed on a 2D screen, such as a word-processing document, a PDF document, 2D pictures, or 2D video, to name just a few. Alternately or additionally, transparent screen 124 can render 3D images that can be viewed with or without eye glasses. For example, in some cases transparent screen 124 can be implemented to render 3D images using an optic such as a wedge that can be viewed by a user without the use of eye glasses. In other cases, transparent screen 124 can render 3D images that can be viewed by a user wearing eye glasses, such as shutter glasses, polarized glasses, or lenticular glassless displays, to name just a few.

As described in more detail below, transparent display device 102 can be controlled to transition between rendering the 2D images and/or 3D images on the transparent screen and rendering the virtual objects that appear to be in the 3D space behind the transparent screen. As discussed in more detail below, the images displayed on the transparent screen may be opaque, or partially opaque, to cover the virtual objects, but can be controlled to slide away to reveal the virtual objects displayed behind transparent screen 124.

In various embodiments, transparent screen 124 may be configured as a 2D or 3D flat-panel electronic display, such as a high-resolution liquid crystal display (LCD). Transparent screen 124 can be physically coupled to transparent display device 102 or implemented separate from transparent display device 102. For example, transparent screen 124 is physically coupled to laptop computer 106 but is implemented separate from desktop computer 110.

FIG. 2 illustrates a detailed example 200 of transparent display device 102 in accordance with one embodiment. In this example, transparent screen 124 uses a grid 202 to render virtual objects 204 that appear to a user as if the virtual objects are rendered in a 3D space 206 behind transparent screen 124. It is to be appreciated that grid 202 may not be viewable by the user, but is used by transparent display device 102 to render the virtual objects so that they appear to be positioned in the 3D space behind transparent screen 124. In this example, virtual objects 204 are depicted as windows 208 and 210. Windows 208 and 210 can each represent a page associated with an application, such a web browser page, a word-processing document, or a PDF file. It is to be noted, however, that transparent screen 124 can render any type of virtual object in 3D space 206.

By rendering virtual objects 204 that appear to be in 3D space 206, transparent screen 124 enables the user to manipulate virtual objects 204 using one or both of the user"s hands. It is to be noted that transparent screen 124 is transparent and thus enables the user to see the user"s actual hands (as opposed to a virtual rendering of the user"s hands) as the user manipulates virtual objects 204. Thus, transparent display device 102 leverages the user"s spatial understanding and kinesthetic memory to access and manipulate virtual objects 204 in 3D space 206.

Transparent display device 102 also includes a hand tracker 126, which is configured to sense movement of the user"s hands, such as gestures, to interact with one or more of virtual objects 204 in 3D space 206 behind transparent screen 124, and to generate 3D-input based on the movement. In an embodiment, hand tracker 126 is implemented as a depth camera that senses a 3D position, movement, and/or pose of each of the user"s hands. As discussed in more detail below, controller 122 is configured to receive the 3D-input from hand tracker 126, and to modify the rendering of the 2D or 3D images on transparent screen 124 (not illustrated in FIG. 2) or virtual objects 204 in 3D space 206, based on the 3D-input.

In some embodiments, transparent display device 102 also includes an input panel 128 that is positioned behind transparent screen 124 and is configured to receive 2D-input, such as touch-input and/or key-input, from the user. In this example, as opposed to the conventional design of a laptop where the laptop screen is attached to the trailing edge (far from the user) of the keyboard panel, transparent screen 124 is coupled to a near-edge (edge closer to the user) of input panel 128. Input panel 128 may include any combination of a keyboard configured to receive key-input or a mouse, track pad, touch pad, or other 2D sensing device configured to receive touch-input. By being positioned behind transparent screen 124, input panel 128 enables the user to reach behind the transparent screen to use the input panel.

It is to be noted that because transparent screen 124 is transparent or translucent, the user may be able to see input panel 128 as the key-input or touch-input is entered. For example, when input panel 128 includes a keyboard, the user may be able to see both the keys of the keyboard and the user"s fingers through the transparent screen as the user types on the keyboard. Further, the position of input panel 128 behind transparent screen 124 enables the user to easily transition between using input panel 128 (e.g., for typing) to manipulating virtual objects 204 in 3D space 206. For example, if the user is typing on the keyboard of input panel 128, the user can simply raise one or both of the user"s hands in order to manipulate or interact with virtual objects 204.

FIG. 3 illustrates a detailed example 300 of a side view of the transparent display device illustrated in FIG. 2. In this example, transparent screen 124 is coupled to input panel 128 via a foldable hinge 302. Foldable hinge 302 enables transparent screen 124 to fold on top of input panel 128 to close transparent display device 102. Foldable hinge 302, in this example, is attached to the middle of both transparent screen 124 and input panel 128, which enables the user to comfortably place the user"s hands behind the transparent screen to use input panel 128.

While examples 200 and 300 illustrate transparent screen 124 as being physically attached to input panel 128, alternately input panel 128 may be positioned behind transparent screen 124 without being physically connected to the transparent screen. For example, transparent screen 124 may be implemented as a desktop monitor, and input panel 128 may be implemented as a keyboard and/or mouse that can be placed behind the desktop monitor.

In some embodiments, transparent display device 102 also includes a head tracker 130 that is configured to track a position of the user"s head or eyes relative to transparent screen 124. Controller 122 is configured to render, or modify the rendering of, virtual objects 204 based on the position of the user"s head or eyes so that the virtual objects appear to be in 3D space 206. Head tracker 130 can be implemented as a 3D camera or as an array of cameras. In various embodiments, both hand tracker 126 and head tracker 130 may be implemented as short-range depth cameras. In example 200, hand tracker 126 and head tracker 130 can be mounted to transparent screen 124, making transparent display device 102 truly a mobile device. Thus, controller 122 controls transparent display device 102 to render virtual objects 204 on transparent screen 124 that are updated in real time based on the user"s eye or head position, such that the user perceives that the virtual objects are displayed behind the transparent screen at a programmed set position.

FIG. 4 aillustrates a detailed example 400 of transparent display device 102 in accordance with one embodiment. In this example, transparent display device 102 renders a 2D or 3D image 402 on the surface of transparent screen 124. Image 402 may be any type of 2D image that can be displayed on a conventional 2D screen, or 3D image that can be displayed on a 3D screen. In this example, image 402 is a picture of a pair of dice. Note, however, that transparent screen 124 may display image 402 as a web browser window, a word-processing document, a picture, or a PDF file, to name just a few examples. The user can interact with image 402 using input panel 128. For example, the user can type on the keyboard of input panel 128 to write an email message, or use a track pad or mouse of the input panel to modify the size of image 402. Transparent display device 102 receives the 2D-input from the user via input panel 128, and controller 122 controls the transparent display device to modify the rendering of image 402 on the transparent screen based on the 2D-input.

In various embodiments, transparent display device 102 employs a “sliding door” technique when the user raises one or both of the user"s hands off of input panel 128 to reach into the 3D space behind transparent screen 124. Consider for example that in FIG. 4 bthe user raises one of the user"s hands off of input panel 128 to reach into 3D space 206. Hand tracker 126 senses this movement, and generates 3D-input that is received by controller 122. Controller 122 then controls transparent screen 124 to slide the rendering of image 402 to reveal one or more virtual objects that appear to be in 3D space 206 behind transparent screen 124. In this example, the rendering of image 402 is controlled to slide down transparent screen 124. Alternately, however, the rendering of image 402 can be controlled to slide up transparent screen 124 or to slide across (e.g., slide left across or slide right across) transparent screen 124. In some embodiments, image 402 can also or instead be controlled to fade, dissolve, or transition in any other way to reveal the virtual objects in 3D space 206.

After the rendering of the image on the screen slides to reveal the virtual objects, the user can interact with the virtual objects using one or both of the user"s hands. In an embodiment, when the user lowers the user"s hand to go back to entering input using input panel 128, hand tracker 126 senses the movement of the user"s hand to reach towards the input panel and generates 3D-input that is received by controller 122. Controller 122 then controls transparent screen 124 to slide the rendering of image 402 to cover the one or more virtual objects (e.g., slide back up, back down, back left, or back right). It is to be appreciated, therefore, that the sliding door technique enables the user to easily transition between entering 2D-input via input panel 128 and entering 3D-input using the user"s hands in 3D space 206.

Transparent display device 102 enables the user to interact with virtual objects that appear to be in the 3D space behind transparent screen 124 in a variety of different ways. In an embodiment, transparent display device 102 employs a “virtual cabinet” technique to cause transparent screen 124 to render multiple windows stacked in one or more 3D volumes that appear to be in 3D space 206. For example, FIG. 5 aillustrates another detailed example 500 of transparent display device 102 in accordance with one embodiment. In this example, transparent screen 124 renders multiple windows stacked in 3D volumes 502 and 504 that appear to be in 3D space 206. Each of the windows stacked in 3D volumes 502 and 504 can represent a page associated with an application, such a web browser page, a word-processing document, or a PDF file.

Transparent display device 102 enables the user to interact with 3D volumes 502 and 504 in 3D space 206 by positioning one or both of the user"s hands near the 3D volumes in 3D space 206. Hand tracker 126 is configured to sense movement of the user"s hand behind the transparent screen to select one of 3D volumes 502 or 504, and to generate 3D-input based on the movement. Responsive to receiving the 3D-input from hand tracker 126, controller 122 controls transparent display device 102 to render the selected 3D volume as open on transparent screen 124 to enable the user to interact with the multiple windows stacked in the selected 3D volume.

It is to be noted that rendering the 3D volume as open enables the user to more easily view the multiple windows in the selected 3D volume. For example, in FIG. 5 a, 3D volumes 502 and 504 are rendered as closed making it difficult for the user to see, or select, each individual window in 3D volumes 502 and 504. In FIG. 5 b, if the user moves the user"s hand to select 3D volume 504, the movement of the user"s hand is sensed by hand tracker 126 which generates 3D-input that is received by controller 122. Controller 122 then controls transparent screen 124 to modify the rendering of 3D volume 504 to render 3D volume 504 as open. For example, as illustrated in FIG. 5 b, the windows in 3D volume 504 are open, or spread out, as compared to the windows in 3D volume 502. Opening the 3D volume enables the user to more easily see, and thus more easily interact with, each of the windows in 3D volume 504.

Transparent display device 102 enables the user to interact with the multiple windows in open 3D volume 504 by positioning one or both of the user"s hands near the multiple windows in 3D space 206. For example, in FIG. 5 cif the user moves the user"s hand to one of the multiple windows 506 in 3D volume 504, the movement of the user"s hand is sensed by hand tracker 126 which generates 3D-input. Controller 122 receives the 3D-input and controls transparent screen 124 to render selected window 506 as selected. For example, in FIG. 5 ccontroller 122 controls transparent display device 102 to render window 506 as selected by causing window 506 to “pop up” out of 3D volume 504. Popping window 506 out of 3D volume 504 enables the user to see more information regarding window 506. The user can then select window 506, such as by pinching the window, to display the window as a 2D image on transparent screen 124.

In various embodiments, transparent display device 102 is configured to provide feedback on transparent screen 124 based on the location of the user"s hands in 3D space 206. In one embodiment, for example, controller 122 alters the color of the transparent screen based on the location of the user"s hand. In FIG. 5 c, for example, controller 122 can cause an area around window 506 to glow as the user reaches the user"s hand towards window 506. This feedback helps the user interact with the windows in 3D space 206. In another embodiment, a 3D cursor can be displayed which is mapped to a position of the user"s hand or finger. In another embodiment, controller 122 can cause a part of the screen to not be rendered based on the location of the user"s hand to render an illusion of the user"s hand being in front of a virtual object.

FIG. 6 is a flow diagram depicting an example method 600 implemented by a transparent display device. Block 602 renders an image on a transparent screen of a computing device. For example, transparent display device 102 (FIG. 1) renders a 2D or a 3D image on transparent screen 124 of the transparent display device.

Block 604 receives 2D-input from a user via an input panel positioned behind the transparent screen. For example, transparent display device 102 receives 2D-input from a user via input panel 128 that is positioned behind transparent screen 124. Input panel 128 may include any combination of a keyboard configured to receive key-input, or a mouse, track pad, or touch pad configured to receive touch-input.

Block 606 modifies the rendering of the image based on the 2D-input from the user. For example, controller 122 controls transparent display device 102 to modify the rendering of the 2D or 3D image on transparent screen 124 based on the 2D-input received from the user via input panel 128.

Block 608 senses movement of one of the user"s hands to reach into a 3D space behind the transparent screen, and block 610 generates 3D-input based on the movement of the user"s hand. For example, hand tracker 126 senses movement of one or both of the user"s hand to reach into 3D space 206 (FIG. 2) behind transparent screen 124, and generates 3D-input based on the movement.

Block 612 slides the rendering of the image on the screen to reveal one or more virtual objects that appear to be in the 3D-space behind the transparent screen responsive to receiving the 3D-input. For example, controller 122 controls transparent display device 102 to slide the rendering of the 2D or 3D image displayed on transparent screen 124 to reveal one or more virtual objects that appear to be in 3D space 206 behind the transparent screen responsive to receiving the 3D-input from hand tracker 126.

FIG. 7 is a flow diagram depicting an additional example method 700 implemented by a transparent display device. Block 702 renders multiple windows stacked in one or more 3D volumes that appear to be in a 3D space behind a transparent screen. For example, transparent display device 102 (FIG. 1) renders multiple windows stacked in one or more 3D volumes, such as 3D volumes 502 and 504 (FIG. 5 a), that appear to be in 3D space 206 behind transparent screen 124.

Block 704 senses movement of a user"s hand behind the transparent screen to select one of the 3D volumes, and block 706 generates 3D-input based on the movement. For example, hand tracker 126 senses movement of the user"s hand behind transparent screen 124 to select 3D volume 504, and generates 3D-input based on the movement.

Block 708 renders the selected 3D volume as open to enable the user to interact with the multiple windows stacked in the selected 3D volume. For example, controller 122 controls transparent display device 102 to render selected 3D volume 504 (FIG. 5 b) as open on transparent screen 124 to enable the user to interact with the multiple windows stacked in selected 3D volume 504.

Block 710 senses additional movement of the user"s hand behind the transparent screen to select one of the multiple windows stacked in the open 3D volume, and block 712 generates additional 3D-input based on the additional movement. For example, hand tracker 126 senses additional movement of the user"s hand behind transparent screen 124 to select window 506 (FIG. 5 c) stacked in open 3D volume 504, and generates additional 3D-input based on the additional movement.

Block 714 renders the selected window as selected on the transparent screen. For example, controller 122 controls transparent display device 102 to render selected window 506 as selected on transparent screen 124, such as by causing window 506 to pop out of 3D volume 504.

FIG. 8 illustrates various components of example device 800 that can be implemented as any type of client, server, and/or display device as described with reference to the previous FIGS. 1-7 to implement techniques enabling a transparent display device. In embodiments, device 800 can be implemented as one or a combination of a wired and/or wireless device, as a form of flat panel display, television, television client device (e.g., television set-top box, digital video recorder (DVR), etc.), consumer device, computer device, server device, portable computer device, user device, communication device, video processing and/or rendering device, appliance device, gaming device, electronic device, and/or as another type of device. Device 800 may also be associated with a viewer (e.g., a person or user) and/or an entity that operates the device such that a device describes logical devices that include users, software, firmware, and/or a combination of devices.

Device 800 includes one or more processors 810 (e.g., any of microprocessors, controllers, and the like), which process various computer-executable instructions to control the operation of device 800 and to enable techniques for implementing a transparent display device. Alternatively or in addition, device 800 can be implemented with any one or combination of hardware, firmware, a system-on-chip (SoC), or fixed logic circuitry that is implemented in connection with processing and control circuits which are generally identified at 812. Although not shown, device 800 can include a system bus or data transfer system that couples the various components within the device. A system bus can include any one or combination of different bus structures, such as a memory bus or memory controller, a peripheral bus, a universal serial bus, and/or a processor or local bus that utilizes any of a variety of bus architectures.

The device applications 818 also include any system components or modules to implement techniques using or enabling a transparent display device. In this example, the device applications 818 can include controller 122 for controlling a transparent display device. CONCLUSION

This document describes various apparatuses and techniques for implementing a transparent display device. Although the invention has been described in language specific to structural features and/or methodological acts, it is to be understood that the invention defined in the appended claims is not necessarily limited to the specific features or acts described. Rather, the specific features and acts are disclosed as example forms of implementing the claimed invention.

a transparent screen configured to render images on the transparent screen, and to render virtual objects that appear to be in a three-dimensional (3D) space behind the transparent screen;

a hand tracker configured to sense movement of a user"s hands to interact with one or more of the virtual objects in the 3D space behind the transparent screen, and to generate 3D-input based on the movement; and

a controller configured to modify the rendering of the images on the transparent screen or the virtual objects behind the transparent screen based on the 3D-input.

2. The transparent display device of claim 1, wherein the transparent screen enables the user to see the user"s hands behind the transparent screen as the user"s hands interact with the one or more virtual objects.

3. The transparent display device of claim 1, wherein the transparent screen uses a grid to cause the virtual objects to appear to be in the 3D space.

4. The transparent display device of claim 1, further comprising an input panel positioned behind the transparent screen, the input panel configured to receive two-dimensional (2D) input from the user, and wherein the controller is further configured to modify the rendering of the images on the transparent screen based on the 2D-input from the user.

6. The transparent display device of claim 5, wherein the input panel includes at least one of a keyboard, a mouse, a track pad, or a touch pad, and wherein the transparent screen is coupled to the near edge of the input panel using a foldable hinge that enables the user to input the 2D-input behind the transparent screen.

7. The transparent display device of claim 1, further comprising a head tracker that is configured to track a position of the user"s head or eyes relative to the transparent screen, and wherein the controller is configured to modify the rendering of the one or more virtual objects that appear to be in the 3D space behind the transparent screen based on the position of the user"s head or eyes.

8. The transparent display device of claim 1, wherein the controller is configured to modify the rendering of the images on the transparent screen by causing the rendering of the images to slide to reveal the virtual objects that appear to be in the 3D space behind the transparent screen responsive to the hand tracker sensing movement of the user"s hand to reach into the 3D space.

9. The transparent display device of claim 1, wherein the virtual objects comprise windows, and wherein the transparent screen is configured to render the windows as stacked in one or more 3D volumes in the 3D space.

sliding the rendering of the image on the transparent screen to reveal one or more virtual objects that appear to be in the 3D space behind the transparent screen responsive to receiving the 3D-input.

sliding the rendering of the image on the transparent screen to cover the one or more virtual objects responsive to receiving the additional 3D-input.

16. The method of claim 13, further comprising, responsive to sensing movement of the user"s hand behind the transparent screen, rendering feedback on the transparent screen based on the location of the user"s hand in the 3D space.

17. The method of claim 16, wherein rendering the feedback further comprises causing the transparent screen to glow based on the location of the user"s hand in the 3D space.

18. The method of claim 16, wherein rendering the feedback further comprises causing display of a cursor on the transparent screen based on the location of the user"s hand in the 3D space.

20. The method of claim 13, further comprising sensing a position of the user"s head or eyes relative to the transparent screen, and wherein the rendering the multiple windows comprises rendering the multiple windows as stacked in the one or more 3D volumes that appear to be in the 3D space behind the transparent screen based on the position of the user"s head or eyes relative to the transparent screen.

There’s no doubt that digital signage is the way forward when it comes to marketing your business and reaching even more customers than ever. What’s even more exciting is that with technology constantly improving, there are plenty of different options for you to choose from, including the emergent transparent displays. This fairly new technology comes in a number of different forms, offering so many uses for businesses and beyond. Here’s everything you need to know about see-through displays and how they work.

A transparent display is also known as a see-through display, and it allows the user to see what is being shown on the screen, while also still being able to see through it.

Emissive: these work by selectively adding to the intensity of the light that passes through the display. These are usually OLED displays, which are newer and becoming more widely available.

As it currently stands, the see through display screen is still a very emerging market that has a number of potential uses. Here are the four main types of tech and what they are being used for:

A head-up display, or HUD, is one that requires users to look away from their usual viewpoints. The name itself originated in the pilot cockpit, allowing them to get the information they needed by looking up. These displays are also now being experimented with in goggles and scuba masks.

They are also seen in Augmented Reality, or AR, which has expanded in the past few years. Headsets are now being seen with see-through displays over one eye to enhance the AR experience for users.

A transparent LED display is virtually invisible from up to 5 metres away, making them the perfect choice for glass window and façade applications. It means you can project images to people walking by your glass window on the street, while enabling them to still see behind into your store or office space.

LED displays are nice and lightweight, which makes them easy to both install and maintain. The transparent LED is one of the most popular choices for commercial use, offering an innovative solution by turning windows or buildings into a digital signage screen.

LCD screens are another popular choice on the market since they are lighter and much easier to scale. However, they require constant backlight and are restricted by their brightness, which has made it hard to use them as see-through displays.

Samsung introduced the first LCD Display in 2012, with their Samsung Transparent Smart Window. It’s a transparent touch screen LCD that can be fitted to any window. This technology has already been used to display products in stores. Clear glass display monitors also have a place in general retail. They can be placed in shop windows to show off the product behind, while also displaying advertising on the screen. It ensures that no view is blocked into the store, so customers can still window shop, while also being targeted with effective advertising.

A see-through LCD display can be used to create some amazing visual effects on an event stage, such as a concert. The see-through nature means they can create some holographic effects that will really stand out in a big crowd.

This display consists of a glass panel with a luminescent phosphorous layer and a circuit board. The circuit board lights up the panel, offering the most transparent and durable display on the market. Unlike OLED displays, it isn’t affected by the environment, so it can withstand much more.

These types of displays are mostly seen in vehicles such as cars, buses, trains, trams, boats and more, as the laminated glass can turn windows and window screens into information and functional displays.

When it comes to advertising your business and drawing customers into your store, it’s clear that the LCD & LED transparent displays are the best option – ensuring you have a constant backlight for best functionality.

Manufacturer of optical coatings, flat panel/LCD glass, instrument glass, & CRT filter glass. Products include anti-reflective/anti-glare coatings, transparent conductive coatings, fiber optic coatings, beam splitters, cover glass, etched glass, heater glass, glass sandwiches, lighting wedges, & circular polarizers. Applications include EMI/RFI protection, contrast adjustment, & optical instruments. Capabilities include precision glass cutting to tolerances of plus/minus .005 in. & precision glass edging to tolerances of plus/minus .002 in. Additional capabilities include custom manufacturing of laminated products. Services & products meet Military Spec.