Embodiments of the disclosure generally relate to an adaptive backlight module for a display and a method and system for fabricating the same.
Backlight units for display devices are often one of the largest draws on power consumption, causing battery endurance to be limited in mobile electronics. Often a large portion of the light exiting a display screen is not needed for a single user, and is vulnerable to being viewed by non-users in the line of sight. Many current privacy filters and films for laptops, monitors, and some mobile devices absorb light, thereby reducing energy efficiency of the device. Additionally, these current privacy filters and films are expensive, and are cumbersome in that they interfere with touch screen functionality and must be physically removed to enable wide-angle viewing of the display.
Thus, a need exists for techniques to reduce power consumption from the emission of excess light, and to provide privacy for a user.
So that the manner in which the above recited features of the present disclosure can be understood in detail, a more particular description of the disclosure, briefly summarized above, may be had by reference to embodiments, some of which are illustrated in the appended drawings. It is to be noted, however, that the appended drawings illustrate only typical embodiments of this disclosure and are therefore not to be considered limiting of its scope, for the disclosure may admit to other equally effective embodiments.
To facilitate understanding, identical reference numerals have been used, where possible, to designate identical elements that are common to the figures. It is contemplated that elements and features of one embodiment may be beneficially incorporated in other embodiments without further recitation.
An adaptive backlight module and method and system for producing an adaptive backlight module are described herein. In one embodiment, an adaptive backlight module includes a light source, a polarizer, at least one enhancement film disposed between the light source and the polarizer, and a diffuser disposed between the light source and the enhancement film. The diffuser includes a first electrode coupled to a first substrate and a second electrode coupled to a second substrate. A liquid crystal layer is disposed between the first electrode and the second electrode of the diffuser.
In another embodiment, a method of producing an adaptive backlight module is provided that includes forming at least one enhancement film on a first substrate, forming a polarizer on the enhancement film, forming a diffuser by forming a liquid crystal layer between a first electrode on the first substrate and a second electrode on a second substrate, and connecting the diffuser to a light source.
In another embodiment, a system for producing an adaptive backlight module includes a first chamber, configured to form a first electrode on a first substrate and a second electrode on a second substrate, and a second chamber, configured to form a diffuser by forming a liquid crystal layer between the first electrode on the first substrate and the second electrode on the second substrate.
Embodiments of the disclosure generally include an adaptive backlight module for a display and a method and system for fabricating the same.
The CVD chamber 104 is suitable for performing PECVD processes for fabricating circuitry on a large area substrate 214. The large area substrate 214 may be made of glass, a polymer, or other suitable substrate. The CVD chamber 104 is configured to form structures and devices on the large area substrate 214 for use in the fabrication of liquid crystal displays (LCD's) or flat panel displays, photovoltaic devices for solar cell arrays, or other structures. The structures may include thin film transistors and p-n junctions utilized to form diodes for photovoltaic cells, among other structures.
The CVD chamber 104 includes a chamber sidewall 230, a bottom 232, and a substrate support 224. The substrate support 224, such as a susceptor, supports the substrate 214 during processing. A heater element 226, such as a resistive heater, disposed in the substrate support 224, is coupled to plasma source 202 and is utilized to controllably heat the substrate support 224 and large area substrate 214 positioned thereon to a predetermined temperature. The CVD chamber 104 also includes a lid structure 208, a backing plate 212, a cover plate 210, and a gas distribution showerhead 218. The gas distribution showerhead 218 is positioned opposite the substrate support 224 and the large area substrate 214.
The CVD chamber 104 has a gas inlet 204 that is coupled to a gas source 206 and a plasma source 202. The plasma source 202 may be a direct current power source, a radio frequency (RF) power source, or a remote plasma source. The gas inlet 204 delivers process and/or cleaning gases from the gas source 206 to a processing region 216 defined in an area below the gas distribution showerhead 218 and above the substrate support 224. Gases present in the processing region 216 may be energized by the plasma source 202 to form a plasma. The plasma is utilized to deposit a layer of material on the substrate 214. Although the plasma source 202 is shown coupled to the gas inlet 204 in this embodiment, the plasma source 202 may be coupled to the gas distribution showerhead 218 or other portions of the CVD chamber 104.
The PVD chamber 102a includes a chamber body 308 and a lid assembly 304, defining a process volume 336. The chamber body 308 is typically fabricated from a unitary block of aluminum or welded stainless steel plates. The chamber body 308 generally includes sidewalls 310 and a bottom 314. The sidewalls 310 and/or bottom 314 generally include a plurality of apertures, such as an access port 318 and a pumping port (not shown). The pumping port is coupled to a pumping device (also not shown) that evacuates and controls the pressure within the process volume 336. The pumping device is able to maintain the pressure of the PVD chamber 102a to a certain vacuum level.
The lid assembly 304 generally includes a target 334 and a ground shield assembly 322 coupled thereto. The target 334 provides a material source that can be deposited onto the surface of a substrate 340 during a PVD process. The target 334 or target plate may be fabricated of a material that will become the deposition species or it may contain a coating of the deposition species. To facilitate sputtering, a high voltage power supply, such as a power source 316 is connected to the target 334.
The target 334 generally includes a peripheral portion 324 and a central portion 338. The peripheral portion 324 is disposed over the sidewalls 310 of the chamber. The central portion 338 of the target 334 may protrude, or extend in a direction towards a substrate support 328. The substrate support 328 is generally disposed on the bottom 314 of the chamber body 308 and supports the substrate 340 thereupon during substrate processing within the PVD chamber 102a. The substrate support 328 may include one or more electrodes and/or heating elements imbedded within the plate-like body support.
During a sputtering process to deposit a material on the substrate 340, the target 334 and the substrate support 328 are biased relative each other by the power source 316. A process gas, such as inert gas and other gases, e.g., argon, and nitrogen, is supplied to the process volume 336 from a gas source 320 through one or more apertures (not shown), typically formed in the sidewalls 310 of the PVD chamber 102a. The process gas is ignited into a plasma and ions within the plasma are accelerated toward the target 334 to cause target material being dislodged from the target 334 into particles. The dislodged material or particles are attracted towards the substrate 340 through the applied bias, depositing a film of material onto the substrate 340.
The roll-to-roll PVD chamber 102b is configured for depositing material 378 on a flexible substrate 344. The roll-to-roll PVD chamber 102b may include at least a first vacuum processing region 366 and a second vacuum processing region 368 which may be separated from each other by at least one gas separation unit 370, wherein a gas separation passage 376 configured as a passageway for the flexible substrate 344 is provided therebetween.
The roll-to-roll PVD chamber 102b includes a vacuum chamber 372. Various vacuum deposition techniques can be used to deposit material on the flexible substrate 344. The flexible substrate 344 is guided, as indicated by arrow X, into the vacuum chamber 372. For example, the flexible substrate 344 can be guided into the vacuum chamber 372 from an unwinding station. The flexible substrate 344 is directed by rollers 358 to a substrate support configured for supporting the flexible substrate 344 during processing and/or deposition. As shown in
The embodiment depicted in
The flexible substrate 344 has a self-adhesive first main surface 348 which can be covered with a protection layer 342 configured as a release liner. The flexible substrate 344 may be guided on the support surface 352 of the rotatable coating drum 354, wherein the first main surface 348 is directed toward the rotatable coating drum 354. However, as the first main surface 348 may be covered with the protection layer 342, the first main surface 348 does not directly come into contact with the support surface 352.
The deposited material 378 is vacuum deposited on the second main surface 350 of the flexible substrate 344 which is directed away from the rotatable coating drum 354 via the first deposition source 362 in the first vacuum processing region 366 and via the second deposition source 364 in the second vacuum processing region 368. After vacuum deposition, the protection layer 342 covering the first main surface 348 may be removed, and the multilayer substrate 346 may be ready for use.
The distribution field of deposition material can be understood as including substantially all particles 384 released from the target elements 388, 390. Arrows denote the direction of the released particles 384 of the target elements 388, 390. For instance, the distribution field of deposition material of target element 388 includes all particles 384 originating from the target element 388. According to some embodiments, the distribution field may have substantially the shape of a cosine function. The length of arrows indicates approximately the number of particles 384 released in the direction of the arrow. For instance, the arrow going straight upwards presents the direction of a defined number of released particles 384, whereas the arrow to the left or right of the straight arrow presents a smaller number of particles 384. The target-substrate-distance 392 reaches from the target elements 388 and 390 to a plane 394 of a substrate surface.
According to some embodiments, the target support 386 and the substrate support of a deposition chamber may be adapted to be movable with respect to each other. For instance, the target support 386 and/or the substrate support may be adapted to adjust the distance between the plane 394 of the substrate surface and the target elements 388, 390. Typically, the distance between the plane 394 of the substrate surface and the target elements 388, 390 of the rotatable target assembly 382 may be adjusted dependent on the gap 396 between the target elements 388, 390 of the rotatable target assembly 382 before using the rotatable target assembly 382 in a deposition process.
A switchable diffuser 406 is on the light source and light guide plate 408. At least one enhancement film 404 is on the switchable diffuser 406. For example, the enhancement film 404 may be a light recycling film, or any other brightness enhancing film tailored to a particular device's optical emission pattern. A polarizer 402 is on the enhancement film 404. For example, in one embodiment, the polarizer may be a wire grid polarizer.
In operation 604, at least one enhancement film may be formed on the first substrate on which the electrode is formed in operation 602. The enhancement film may be formed on the upper surface of the first substrate, opposite from the lower surface of the first substrate on which the electrode is formed in operation 602. The enhancement film may be formed on the substrate using an embossing, printing, or any other patterning process. Alternatively, the enhancement film may be formed using a CVD process as described above with respect to
In operation 606, after the enhancement film has been formed on the first substrate in operation 604, a polarizer may be formed on the enhancement film. The polarizer may be formed on the enhancement film using an embossing, printing, or any other patterning process. Alternatively, the polarizer may be formed on the enhancement film using a wire grid process, in which wires are placed into the enhancement film. Alternatively, the polarizer may be formed on the enhancement film using a CVD process as described above with respect to
If a roll-to-roll or sheet-to-sheet PVD process is used to form the electrodes on the substrates in operation 602, the substrates may be rolls or sheets of substrates that are ultimately cut to form multiple individual substrates. The electrodes formed in operation 602, the enhancement film formed in operation 604, and/or the polarizer formed in operation 606 may all be formed on one substrate roll or sheet. The roll or sheet may then be cut to the sizes of individual displays before operation 608. In an alternative embodiment the polarizer formed in operation 606 may be formed on a substrate independent from the substrates on which the electrodes are formed in operation 602. In another alternative embodiment, the enhancement film formed in operation 604 may also be formed on a substrate independent from the substrates on which the electrodes are formed in operation 602.
In operation 608, a liquid crystal layer is formed between the two substrates on which the electrodes are formed in operation 602 to form a diffuser. In operation 608, the lower surface of the first substrate (having the electrode thereon) faces the upper surface of the second substrate (having the electrode thereon) when the liquid crystal layer is formed. The liquid crystal layer is formed between the electrode on the first substrate and the electrode on the second substrate. To form the liquid crystal layer, a plurality of spacer elements, such as spacer beads, is placed between the electrodes. The spacer elements are used so that liquid crystals may be uniformly deposited between the electrodes. Liquid crystals are deposited between the electrodes to surround the spacer elements and to bond the two substrates to each other, thus forming one diffuser element. The liquid crystals may be deposited using an inkjet printing process, a slot die coating process, a screen printing process, a stamp transfer process, a vacuum filling process, or any other suitable liquid or solid injection or deposition process. The liquid crystal layer may be formed in a chamber independent from the CVD chamber 104, the PVD chamber 102, and the embossing/printing chamber 108, as is shown by the liquid crystal deposition chamber 106 in the embodiment of the system shown in
After the diffuser is formed in operation 608, a light source is connected to the diffuser to form an adaptive backlight module in operation 610. For example, the adaptive backlight module may be the adaptive backlight module 400A shown in
The adaptive backlight module described herein and the method and system for producing the same may allow for increased power efficiency when used in a display device, such as a liquid crystal display device. Electrodes on the diffuser of the adaptive backlight module may be electrically connected to a power source in a display device. For example, the electrodes 504, 508 in the switchable diffuser stack 500 shown in
Additionally, as shown in
In the embodiments of the switchable diffuser 406 shown in
According to embodiments, which can be combined with other embodiments described, herein an adaptive backlight module is provided. The adaptive backlight module includes a light source; a polarizer; at least one enhancement film disposed between the light source and the polarizer; and a diffuser disposed between the light source and the enhancement film. The diffuser includes a first electrode coupled to a first substrate, a second electrode coupled to a second substrate, and a liquid crystal layer disposed between the first electrode and the second electrode.
According to embodiments, which can be combined with other embodiments described herein, the light source includes one of: one or more cold cathode fluorescent lamps (CCFL), one or more light-emitting diodes (LED), and one or more organic light-emitting diodes (OLED).
According to embodiments, which can be combined with other embodiments described herein, the adaptive backlight module further includes a light guide plate and a reflector.
According to embodiments, which can be combined with other embodiments described herein, the liquid crystal layer includes smectic phase liquid crystals and a plurality of spacer elements.
According to embodiments, which can be combined with other embodiments described herein, the first electrode is disposed on a lower surface of the first substrate and includes a first indium tin oxide (ITO) film. The second electrode is disposed on an upper surface of the second substrate and comprises a first indium tin oxide (ITO) film. The lower surface of the first substrate faces the upper surface of the second substrate.
According to further embodiments, which can be combined with other embodiments described herein, a system for producing an adaptive backlight module is provided. The system includes a first chamber, configured to form a first electrode on a first substrate and a second electrode on a second substrate. Additionally, the system includes a second chamber, configured to form a diffuser by forming a liquid crystal layer between the first electrode on the first substrate and the second electrode on the second substrate.
According to embodiments, which can be combined with other embodiments described herein, the liquid crystal layer is formed in the second chamber using one of: an inkjet printing process, a slot die coating process, a screen printing process, a stamp transfer process, and a vacuum filling process.
According to embodiments, which can be combined with other embodiments described herein, the first chamber comprises a chemical vapor deposition (CVD) chamber.
According to embodiments, which can be combined with other embodiments described herein, the system further includes a third chamber configured to form an enhancement film on the diffuser.
According to embodiments, which can be combined with other embodiments described herein, the first chamber includes a physical vapor deposition (PVD) chamber.
While the foregoing is directed to embodiments of the present disclosure, other and further embodiments of the disclosure may be devised without departing from the basic scope thereof, and the scope thereof is determined by the claims that follow.
This application is a divisional of co-pending U.S. patent application Ser. No. 15/173,231, filed Jun. 3, 2016, which is hereby incorporated herein by reference.
Number | Date | Country | |
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Parent | 15173231 | Jun 2016 | US |
Child | 16271635 | US |