• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
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    • 专利摘要:
    The invention relates to light-emitting or light-reflecting displays with improved visual and acoustic properties, more particularly the invention relates to, for example, a display based on light-emitting elements such as light-emitting diodes (LEDs). Thus, an LED screen with improved acoustics and / or improved visual performance is presented for particular use or application in a studio environment where the quality performance of both image and sound when captured by a camera or an audience is challenged. The invention also relates to the use and applications of such a display, including systems and methods employing such a display, and more particularly to the use and application of such displays in studio environments.
    公开号:BE1027341B1
    申请号:E20195759
    申请日:2019-11-04
    公开日:2021-01-11
    发明作者:Robbie Thielemans;Frederick Waldman;Vince Dundee
    申请人:Stereyo;
    IPC主号:
    专利说明:

    The invention relates to a display with improved visual and / or acoustic properties, more particularly the invention relates to the light source screen based on light-emitting elements such as, for example, light-emitting diodes (LEDs). Thus, an LED display or screen with improved acoustic properties is proposed. The invention also relates to the use and applications of such an LED display, including systems and methods utilizing such an LED display.
    Background of the Invention Existing displays, using both light emitting (e.g. LED or OLED) and reflective technologies (e.g. LCD) used for studio applications, meaning for example in a broadcast environment, generally show defects in the final screen seen by the public or user. Complex and cumbersome manipulation is often performed to make images acceptable to the viewer again. Only mere acceptance is provided by a lack of better availability. A robust and simple solution is not provided in the art.
    In addition, in a recording studio, in addition to using displays such as LED displays, audio from all kinds of sources from every possible location must be taken into account. Cameras are used for recording in the studio. In addition to the images from the displays, the structural and furnishing environment of the studio, the actors or people present in it, as well as the audio being produced, are captured by the cameras and / or microphones for recording, and in the case of a recording event open to the public, these are also captured by the public. Therefore, a high-quality representation of both visual and acoustic performance is quite a challenge in this regard. In other words, there is a need for a studio display with improved acoustics and high quality custom visual characteristics for the specific purpose of studio applications.
    Object of the Invention The object of the invention is to provide display devices, such as, for example, light-emitting display devices, which are optimized for studio / on-screen / camera applications, i.e., for example, a studio with an LED screen (for example, in the back, behind actors or presenters or stage) and use a camera to record scenes.
    The light-emitting display devices are e.g. based on, but not limited to, LED technology and thus also including other possible comparable light emitting sources as known in the art.
    Furthermore, this invention can also be used for displays based on reflective light technologies (e.g., LCD displays without backlight), bistable reflective displays or interferometric based reflective displays.
    Both image performance adjustments and acoustic performance enhancements are considered in order to achieve good quality on-camera recording of a studio event.
    Summary of the Invention The invention relates to methods (and associated circuitry and arrangements) for improving the visual and / or acoustic performance of a display with respect to a camera recording the image displayed by the display, wherein the display is more visible. In particular, a number of discrete light sources include one of the discrete sources is Light Emitting Diode (LED), and / or with regard to audio recording where the display needs special precautions to reduce ambient noise and unwanted reflections.
    Instead of a display based on different light sources, a different type of display based on reflective light areas (such as, for example, LCD) can also be used.
    It is noted that in this text reference will mainly be made to a light-emitting display, and in particular to an LED display, although it is understood that the invention is also applicable to displays with respect to visual and acoustic performance improvement of a display. based on reflective technologies.
    The invention relates in particular to display screens in which the light sources are driven by (bit size limited) (PWM) drivers with a set fixed current.
    One or more of the proposed methods in accordance with the invention, analyze the output of the display required to display a (reference) image sequence and derive adjustment therefrom (such as a set fixed current) and control the light source (s) accordingly.
    The invention also relates to optimized utilization of the (full or wider than standard) dynamic range of a light source display by properly setting the fixed current. The invention relates to improving the visual performance of a light source display by adjusting the light source input signal to the bit size limited PWM drivers to compensate for various effects such as non-linearities caused by adjusting the current as indicated above. and / or non-linearities caused by the (RLC) behavior of the board on which said light sources are mounted and / or due to temperature effects.
    One or more of the proposed methods relates to achieving the ideal human eye transfer function, preferably by using control features (such as the clock) of said PWM drivers. By using this control feature, the limit of the bit size drastically reduced.
    The invention relates to displays in a studio environment, i.e. arrangements of one or more displays, one or more cameras that at least partially record what is displayed on one or more of these displays, and more particularly include such arrangements. also typically a good infrastructure such as instruments for generating and / or recording sound (such as microphones). With regard to such studio environments and sound inclusive setups, it is worth emphasizing that the display can also (and typically) be an (unwanted) sound generating instrument, especially the display subsystems such as coolers and / or power supplies thereof Moreover, the display can also reflect sound it has picked up from the environment. Especially in a closed environment and when using a curved screen, audio signals can be strongly reflected in the studio, causing the actors, the audience and / or the sound being received by a microphone are disturbed.
    It is an aspect of the invention to provide measures to improve (in addition to the visual performance also) the sound performance in such a studio environment by providing related modifications to said screens, for example by removing or disabling components in the display. screen that makes a lot of noise or noise, but also, for example, by providing sound-absorbing material, or reducing the sound-reflecting properties of the display by adapting the display or LED screen to a more open structure.
    In a further embodiment thereof, the control of the display has also been adapted to minimize poor sound performance within the studio.
    As an exemplary embodiment thereof, as indicated elsewhere in the description, the visual performance is (strongly) affected by temperature effects on the light sources (LEDs) of the display. While in ordinary displays this is combated by providing adequate cooling facilities, the negative effect on realizing the sound performance, the invention instead includes temperature compensation in the control of the display, leaving room for a lower cooling demand (and thus less unwanted noise generation).
    In a further embodiment thereof it is realized that the behavior of the power supply and / or the behavior of the display driver and / or the display behavior itself in relation to heat production is also strongly dependent on the way in which the display is driven or controlled. As an exemplary embodiment thereof, as indicated elsewhere in the description, the control is based on analyzing a reference sequence to thereby find a tuned (just enough) control approach that adjusts the settings (such as the current setting) of the control circuit (and its associated power supply} and also the light throughput of the display itself, in relation to the heat production, which also reduces the cooling requirement, with the effects on noise as indicated above.
    In a first aspect of the invention, there is provided a method wherein one or more displays (e.g., LED displays) are part of a studio environment, further comprising one or more cameras that at least partially record what is displayed on one or more of these. displays. The studio environment may further include a sound infrastructure. In one embodiment, the displays are adapted to minimize their sound generating behavior, and / or are adapted to maintain good visual performance, regardless of improved sound generating behavior. According to one embodiment, the screens or displays are adapted to optimize the sound behavior of the studio, in particular displays are either provided with acoustically absorbent material and / or are adapted to allow some of the sounds to pass through to prevent acoustic reflections.
    In a second aspect of the invention, there is provided a method for improving the interaction of a light source display with a camera that records the image displayed by the light source display, the method comprising: (i} receiving the light source input signal; and (ii) applying the light source input signal to the light source, after a programmable delay (relative to a sync signal related to the camera). According to one embodiment, the type of light source used for the display is a Light Emitting Diode (LED) and / or the programmable delay is selected to improve the interaction of the light source screen with the camera, more specifically to reduce banding effects when recording on camera. The cause of the banding or striping effect is due to a different timing when the camera shutter opens compared to the discrete PWM generation for the light sources.
    In a third aspect of the invention there is provided a method for optimally utilizing the (wider than standard) dynamic range of a light source display comprising a number of discrete light sources with bit size limited drivers, the method comprising: for at least one light source of said light source. display, (i} determining the dynamic range required to display a (reference) image sequence; (ii) setting a reference or offset value (e.g. current) of the driver of the corresponding light source at the center of the required dynamic range; (iii) (equally) discretize the required dynamic range around the set reference or offset value based on the (available) bit size of the driver; and (iv) adjust the light source accordingly.
    The term "wider than standard" means that when using a driver with a limited bit size, the goal is to try to use more bits than standard state-of-the-art displays.
    technology is or would be.
    In one embodiment, the type of light source used for the display is a Light Emitting Diode (LED), and / or the light sources are driven by PWM drivers with a set fixed current, being the set reference or the offset value.
    According to one aspect of the invention, there is provided a method for improving the visual performance of a light source display, comprising a number of different light sources,
    mounted on a (PCB) board, the method comprising: for at least one light source, (i) receiving the light source input signal; (ii) adjusting the light source input signal, to compensate for non-linearities caused by the non-linear behavior between the change of said reference or offset value and the light output of said light source perceived by the human eye (preferably after camera which image displayed by the light source display); (iii) applying the adjusted light source input signal to the light source.
    In accordance with one aspect of the invention, there is provided a method for optimally utilizing the (wider than standard) dynamic range (to an optimized maximum) of a light source display comprising a number of discrete light sources with bit size limited drivers, the method comprising: for the plurality of light sources of the display connected to the same driver, (i) for each of them, determining the dynamic range required to display a (reference) image sequence; (ii) setting a reference or offset value of the driver of the corresponding light source in the center of the maximum of the required dynamic ranges; (iii) for each of them discretize the required dynamic range around said (common) set reference or offset value based on the (available) bit size of said driver; and (iv ) controlling the light sources accordingly.
    The term optimized maximum is further explained.
    The higher the light output in images with a high dynamic range (cfr.
    HDR images), the more bit depth is required to maintain sufficient detail in low light.
    For example, striving for an optimized maximum in dynamic range means aiming for as much bit depth as possible for the highest possible light output, and this is more than would be the case for standard state-of-the-art LED screens. The light source used can be, for example, a Light Emitting Diode (LED) and / or the light sources are possibly driven by PWM drivers with a set fixed current, being said reference or offset value.
    According to a further aspect of the invention there is provided a method for controlling a light source display comprising a number of separate light sources, the light sources being driven by PWM drivers with a set fixed current, whereby the transfer function of the human eye (light output of the light source relating to the light perceived by the human eye), preferably after camera recording or taking into account both after camera recording and with direct perception, is adapted, realized (at least in part) by modulating the clock of said PWM drivers , in particular using high frequency for low light and low frequency for high light output The method may further include compensation for (RLC) non-linearities of the (PCB) board, and / or non-linearities caused by change of reference or offset value of mentioned drivers.
    According to a further aspect of the invention, there is provided a method for optimally utilizing the (wider than standard) dynamic range of a light source display comprising a number of separate light sources with bit size limited drivers, the method comprising: for each light pixel, for each color therein and the associated light source of the display, (i) determining the dynamic range required to display a (reference) image sequence; (ii) setting a reference or offset value of the driver of the corresponding light source at the center of the required dynamic range; (iii) (equally) discretize the required dynamic range around the set reference or offset value based on the (available) bit size of the driver; and (iv) adjusting the light source accordingly.
    In one aspect of the invention there is provided a method for improving the visual performance of a light source display, comprising a plurality of discrete light sources, mounted on a (PCB) plate, the method comprising: for at least one light source, (i) receiving the light source input signal; (ii) adjusting the light source input signal to compensate for non-linearities caused by the (RLC) behavior of the plate; (iii) applying the adjusted light source input signal to the light source. The light source can be a Light Emitting Diode (LED). In one embodiment, the visual performance is the visual performance perceived by a human eye before or after the camera recording the image displayed by the light display.
    According to an embodiment, wherein said adaptation is part of or based on the transfer function of the human eye (which relates the light output of the light source to the light perceived by the human eye), preferably after camera recording or taking into account both cameras. recording and direct observation.
    In one embodiment, for one or more (especially a few, typically low light where non-linearities cause the most deleterious visual performance effects, such as, for example, not displaying the desired color or not illuminating all light sources equally when desired is) light output points (in the transfer function of the human eye}, a correction factor is determined, and for all other points a non-continuous interpolation (for example, using a spline function) is performed. The method can be used by light source basis or as an alternative to a set of light sources located close together on the (PCB) plate in a region According to one aspect of the invention, there is provided a method for determining adaptation information (correction factors) suitable for use in one of the methods as above, the method comprising: (a) displaying an image or a sequence of images (vid eo) with said light source display; (b} determining the visual performance perceived by a human eye (and / or after the camera records the image displayed by the light source display); (c) comparing this visual performance with the ideal visual performance; (d ) calculating the adaptation information (correction factors) based on the equation. The method can be applied to displays with a high density resolution (pixel pitch of 0.625 mm and higher). The method can also be applied to displays in which the light sources are driven by fixed current PWM drivers In a further aspect of the invention, there is provided a method for improving the visual performance of a light source display comprising a number of different light sources,
    wherein the visual performance is the visual performance perceived by a human eye both before and after the camera has captured the image displayed by the light source screen, the method comprising: providing a light source screen with at least 3 different colors (having a partially overlapping spectrum}; and for at least one light source, (i) receiving the light source input signal; (ii) adjusting light source input signal to compensate for camera conversion effects; (iii) further adjusting the light source input signal to to compensate for the visual performance perceived by a human eye immediately after the compensation of the camera conversion effect and (iv) applying the adjusted light source input signal to the light source. In one embodiment, the light source is a Light Emitting Diode (LED) , and / or said colors consisting of RED, GREEN, BLUE and CYAN and / or ORANGE, and / or said colors consisting of RED, GREEN, BLUE and WHITE. In a further aspect of the invention, there is provided a method of improving the visual performance of a light source display, the method comprising: for each light pixel (a pixel having at least 2 colors), for each color therein (i) determining the maximum required light output required for displaying a (reference) image sequence; (ii) setting a reference or offset value of the driver of the corresponding light source accordingly (same maximum); and (iii) controlling the light source accordingly.
    According to one embodiment, said light source is a Light Emitting Diode (LED). The method can be applied to displays in which the light sources are controlled by PWM drivers with a set fixed current, being the reference or offset value. In one embodiment, determining the maximum required light output takes into account the camera recording of the image displayed by the display.
    In a further aspect of the invention there is provided a method for improving the visual performance of a light source display, comprising a plurality of discrete light sources, mounted on a (PCB) plate, the method comprising: for at least one light source, (i} receiving the light source input signal, (ii) adjusting the light source input signal to compensate for temperature effects, and (iii) applying the adjusted light source input signal to the light source. In one embodiment, said temperature effect is determined by monitoring the light source. time of said light source and estimating said temperature effect therefrom. The light source screen may further comprise temperature sensors, and said temperature sensor may be used to calibrate said estimate. In addition, said temperature sensor may also be used for said adjustment, eg using a behavioral temperature model of said light source. the light source display y. Means for on-time monitoring (e.g., digital counters} may also be provided and can improve the accuracy of temperature compensation by, for example, also using the on-time of adjacent light sources.
    According to one aspect of the invention, there is provided a method for determining the relationship between the on-time of a light source mounted on a (PCB) board and the temperature effect therefrom ... According to another aspect of the invention, there is provided a method for determining the relationship between the temperature as measured by a temperature sensor mounted on a plate and the temperature at a light source at a certain distance on said plate ... In one aspect of the invention, one of the above methods is provided for displays that are part of a studio environment, with one or more monitors, one or more cameras that at least partially record what is displayed on one or more of these monitors. In one embodiment, the studio environment further includes a sound infrastructure and / or the displays are adapted to minimize their sound generating behavior. In one embodiment, said displays are adapted to maintain good visual performance regardless of the improved sound generating behavior.
    Overview of the Drawings Figure 1 schematically illustrates the prior art solution in compensating for the frame delay of the video display system by displaying the background a few frames earlier compared to the front action.
    Figure 2 shows an embodiment for illustrating the aspect of vertical sync update in relation to the shutter speed of the camera, in accordance with the invention.
    Figure 3 shows an embodiment for illustrating the flow adjustment aspect for the individual colors (instead of PWM tuning) to achieve the required color spectrum, in accordance with the invention. Figure 4 illustrates RLC behavior and non-linear effects, and shows an embodiment to illustrate how to compensate for non-linear effects or so-called non-linearities using spline functions or more general non-discontinuous interpolation, in accordance with the invention. Figure 5 graphically illustrates gamma correction with a spline function, in accordance with the invention.
    Figure 6 shows examples of an open screen.
    Figure 7 shows an example of acoustically absorbent material disposed between light-emitting elements.
    Figure 8 shows examples of acoustic surfaces according to the invention.
    Figure 9 shows an example of acoustically absorbing structures disposed between LEDs of an LED board, in accordance with the invention.
    Figure 10 shows an example of a standard screen and its sound reflections compared to an acoustically enhanced screen, in accordance with the invention.
    Figure 11 shows an embodiment of a studio setting in which a camera examines or measures a sound-making display wall, in accordance with the invention.
    Figure 12 shows an embodiment of a studio setting in which a camera views an actor and examines a display wall whose noise is suppressed or reduced by means of, for example, fan control or adjustment of the light output, in accordance with the invention.
    Figure 13 shows an embodiment of a studio setting, in which a camera observes actors and examines a display wall whose noise is suppressed or reduced like Figure 12, and in which the display wall is provided with acoustically absorbing or diffuse material, or the display wall has an open structure such that reflections of audio waves from the surface of the display wall are suppressed or reduced, in accordance with the invention. Figure 14 schematically illustrates the radiated color spectrum for Red, Green, Blue from the screen and from the camera, respectively, including additional colors to be added (e.g. cyan, orange) to the screen to allow visual perception of all colors by the human eye. is correct.
    Figure 15 illustrates a schematic overview of a spectral analysis system for tuning the spectrum of a multi-spectral display (with multi-color LEDs) to the spectrum of any white light source, also taking into account the sensitivities of the camera, according to Figure 16 is the corresponding flow chart of Figure 15. Figure 17 shows the PQ gamma curve as defined in BT2100 Figure 18 shows an embodiment for illustrating the aspect of a grayscale clock in relation to PWM, in accordance with the invention Description of the Invention The object of this invention is to provide LED (but not limited to that technology) display devices optimized for studio / on-screen / camera applications (ie studio with a (LED) screen (e.g. .in the back, behind actors or presenters or stage) and the use of a camera for recording scenes) where the image performance must be changed or adjusted to also have acceptable performance on camera and acoustic performance so that when in cube (or cubic) and / or dome or circular screen (i.e. that other shapes than standard cubes are also mentioned) serving as a background for e.g. actors, these (e.g. cube or circular screen) also have acceptable acoustic performance, so that the sound does not bounce directly off the screen and also becomes an acceptable real-time recording of actor conversations reached. This is just an example of use, but - as one can easily deduce - also has advantages in e.g. home theaters or movie theaters where this display system is used. As mentioned, LED display devices are given by way of example and are usually referred to in this specification, although the invention is not limited thereto. Therefore, display devices or displays in general, based on either light-emitting or light-reflecting technology, are contemplated by the invention. In other words, a display such as an LED display is proposed, and is adapted to studio applications, so that better conditions, whether acoustically or with respect to audio,
    or otherwise visually perceived by the actors and / or players in the studio, as well as by the recording or production crew for a studio application. Therefore, an improved performance in making picture, movies, television shows or other types of broadcasts, including also real-time application, in video and in audio aspects is achieved.
    The technical implementation for the purpose or proposal described above is now described in detail. A list of technical parameters that need adjustment compared to traditional screens with regard to camera recording in a (background) screen environment is now provided.
    1. Frame rate latency In case of action in the 'background' and in relation to foreground action or triggers, it is necessary that the background action (on the screen of the display) is fully synchronized with the audio and actor performance for the screen. Traditionally, this has been compensated by having the background display a few frames earlier compared to the front action, to compensate for the frame delay of the video display system, as schematically illustrated in Figure 1. However, one solution that prevents this is the frame delay. in the source, direction as much as possible on the screen. Depending on the design of the display and the data distribution, this can be limited to 1.5 frames or even less. However, this means that the digital video pipeline and processing must be adjusted accordingly to allow for less frame delay, for example by using more parallel processing (meaning a stronger processor is required), less buffering, and avoiding timing congestion constraints so that images or video data don't appear on the screen in bits and pieces, but are displayed smoothly.
    It should be noted that, in the case of non-live or no real-time applications (but recorded and viewed later), the audio is sometimes delayed in part due to sync issues otherwise. Of course, this is only possible in the case of recordings that are later edited or viewed and not in real time.
    2. Vertical sync update
    Coupled with the aforementioned feature, what is considered very useful is that the display can show the video (refresh the video} with respect to vertical sync update, but the update time is programmable compared to the fixed position of the synchronization signal. This means that when synchronization occurs, the display waits a certain amount of programmed 'clock' before updating the screen. This feature is very useful for determining and finding optimal exposure times on the camera to ensure that the 'grab' 'and / or A / D conversion (transfer signal or content to digital value) takes place in the camera when the PWM powered screen is started, and therefore light emitting elements of the display (or e.g. LEDs of the LED display) will On the one hand, the camera has a certain so-called shutter speed (comparable to aperture on a lens). rden the images or video data scanned vertically on the screen or display, meaning the images appear in vertical order. The shutter speed of the camera can be defined so that only part or a strip (for example, between the dotted lines) of the entire screen is viewed on the camera. In the event that this portion or strip coincides with new images not yet received entering the screen from top to bottom, then nothing within this portion or strip will be seen. According to an embodiment of the invention as shown in Figure 2, new images or video data are always provided within the strip, representing the shutter speed of the camera. In other words, synchronization is provided by means of a programmable update time of new incoming images or the synchronization signal with which new images are scanned. The programmable aspect means that it can be programmed to wait a certain amount of time for images to be viewed or displayed. This goes one step further, this can not only be done per screen, but also e.g. per tile, or even segment by segment in case segments in tiles are needed.
    3. Reduce or eliminate banding effects caused by multiplexing Traditional displays are optimized for the cost of light-emitting sources or elements and electronics to drive them. For example, consider an LED
    display (like traditional display) that is optimized for the cost of LEDs and electronics to drive them. Therefore, there is a tendency (to lower the silicon cost) to increase the multiplex ratio. With this reference is also made to Belgian patent application BE2019 / 5196 filed with priority date March 7, 2019 relating to "Real-time deformable and transparent display" which describes multiplexing issues in detail, and in particular which describes how to reduce multiplexing, prevent or eliminate by using a local LED driver. Because the human eye does 'slow' integration, one has the impression that all multiplex LEDs are always on even though they are time multiplex on / off ... This principle in combination with the shutter speed of the camera creates the typical banding effects seen on camera. Therefore, in order to minimize this effect, one tries to reduce multiplexing as much as possible and even have no multiplexing at all ... This does not necessarily mean that the costs are higher, because when multiplexing is reduced, the efficiency becomes higher and even cheaper LEDs can be used because the average LED on time will be the same length. If we go even further on this route, we can e.g. make use of LEDs with integrated drivers, for which reference is again made to the Belgian patent application BE2019 / 5196 as mentioned above. The last aspect of integrated drivers completely avoids multiplexing and thus limits, avoids or eliminates banding effects.
    It is noted that we can also use the LEDs used for the deformable display as described in BE2019 / 5196, so as not to have all these problems on the camera, but for the sake of this description of the invention we can also link directly to this previously filed Belgian patent application.
    4. Set the power for individual colors instead of matching PWM to the required light output. Another item that is typically overlooked in the light emitting elements (e.g. LEDs) or the display industry is the power setting (Il ) for the individual light-emitting elements (e.g. LEDs). In traditional setups these currents are fixed and the light output is modulated with PWM. But because for studio applications the typical light output required is lower than average use (due to the background aspect of the screen in the studio, for example), it means that when the brightness is reduced, the PWM cycle is reduced, and when the PWM cycle is reduced, this means the actual on-time of the light-emitting element or e.g. LED is less and this means that the chance that the shutter speed of the camera will match the on-time of the light-emitting element or e.g. LED does not notice, is higher. Hence, the grayscale display on the camera is not considered ok. Therefore, it is recommended to set the currents appropriately (rather than tuning PWM) for each individual color, as shown in Figure 3. In other words, the current is adjusted for maximum PWM per color to achieve the required light output. As a result, there is no more loss of bits related to color depth, and therefore no loss of color depth is observed. In addition, it is intended to reduce the current of the light-emitting elements e.g. Have LEDs programmable (see also PQ curve profiling at the end of the document regarding dynamic range) up to the desired maximum light output at the desired color temperature (for color temperature see later in section 9. as camera profiling may also be involved … Reference according to the principle of metamerism).
    5. RLC behavior and non-linear effects The importance of the previous current setting is now further justified because of the RLC behavior of printed circuit board (electronics). Constant current drivers with PWM function are generally considered to be linear. This is generally the case. However, in the lowlights (i.e. the region where not much light is needed, very small gray scale details) this is not the case. The main reason for this is due to the routing layout on the PCB and therefore the traces and routing lines have a typical RLC behavior. For displays with a high resolution (<3 mm or higher resolution), coupled to multiplex lines on the PCB, the RC in particular has a negative (or devastating) effect on the linearity of the gray scale, in some other cases this can even be so-called crosstalk or cause crosstalk (cf. typical LED ghosting effects.) The avoidance of this problem has been described in many articles or documents and is beyond the scope of this invention description. But nonetheless, it is known in the art how to prevent it, the state of the art does not solve the non-linearities, Since the response of the human eye is also non-linear to the perception of light or brightness, typical gamma functions must be applied, but traditional systems do not take these non-linearities into account. Referring to Figure 4, to compensate for these non-linearities, for example, spline functions can be used to adjust the lowlight drive so that the desired light output is achieved for the human eye. In other words, spline functions or more generally non-discontinuous interpolation are used to compensate for nonlinear effects or so called nonlinearities. See also graphical representation of Figure 5 to illustrate gamma correction with e.g. spline function.
    It can go even further that the function or characteristic is even different for each light-emitting element (eg LED) and / or region on the display board (eg LED display board). Therefore, a gamma function can be implemented per pixel or region to adjust and correct for even better or more uniform video performance.
    6. Temperature compensation Usually, (O) LED / LCD boards should also have a uniform temperature. As it is known in the industry, (O) LEDs are temperature sensitive (especially and usually red dies or pixels). A combination of temperature sensors in the (O) LED tile, together with active measurement of the on-time of the (O) LED (e.g. digital counters}, can estimate the behavior of the red die or pixel brightness. measure and compensate is added so that red brightness of the individual (O) LEDs or areas of (O) LEDs is compensated and color or color temperature is maintained.Here the compensation is preferable to PWM and does not adjust the current while per individual (O) LED this compensation via PWM tuning is more convenient because of the cost-efficient (O) LED display architecture (although in theory compensation through current adjustment would also be feasible).
    7. Acoustics For typical studio applications, not only video or color performance is of the utmost importance, but also the acoustic behavior of the display.
    In terms of acoustics, we have 2 items to solve in such a (studio) application:
    a / Acoustic noise from the screen itself. This could be due to the use of fans or even psu (power supply) noise (typical battery vibrations). The latter has to be solved by better design to reduce this noise (frequency, potting, phasing of current draw). The former can be reduced by making the fan speed dependent on the required cooling and even turning it off when the threshold is considered safe. Also the thermal design of the display or e.g. LED tile can help a lot. It is noted that internal convection in closed cabinet and fan will normally result in less audible noise compared to an open design.
    b / Studio noise due to the geometry of state-of-the-art displays in studio applications. This is most important for studio applications: because the typical screens are flat or flat, when bent they form a very large surface that reflects sound or noise, which is not considered a good feature (for example, a screen behind a camera recording where actors having a conversation reflects the conversation in such a way that the echo and noise make the conversation inaudible to the actors themselves). Several solutions are proposed: e Open screen (characterized by a certain degree of (acoustic) transparency, and for which reference can be made to the open structure of the deformable display as described in patent application BE2019 / 5196), an example of which is shown in Figure 6 (a) e Open screen with (sound-absorbing) cloth behind it, an example of which is shown in Figure 6 (b) e Screen with optical amplifier at the top e Acoustically absorbing and / or diffuse material between light-emitting elements or e.g. LEDs e Acoustically absorbing and / or diffuse surface between light-emitting elements or e.g. LEDs e Acoustically absorbing and / or diffuse surface (e.g. blackened) between light-emitting elements or e.g. LEDs and transparent on top of the light-emitting elements or e.g. LEDs For the acoustically absorbing material and / or surfaces (between the light-emitting elements or, for example, LEDs), refer to the illustrations of Figures 7 to 9. The optical amplifier as mentioned above may also have the function e.g. to change the beam angle of the light sources (e.g. LEDs) or to add diffusion and e.g. perception of fill factor. In addition, the optical amplifier can be an acoustic amplifier at the same time, provided that the structure or architecture is in accordance with the acoustic wavelength. Figure 10 shows an example of a standard screen and its sound reflections compared to an acoustically enhanced screen, in accordance with the invention. A few embodiments, in accordance with the invention, of a studio setting with improved visual and / or acoustic performance are described with Figures 11-13. Figure 11 shows an embodiment of a studio setting in which a camera examines or inspects a display wall making noise, in accordance with the invention. The display wall or e.g. LED wall must perform well in order to be able to make a properly captured image with the camera. Adjustment of settings in the display wall are made in such a way that a correct representation of the image is achieved after it has been captured by the camera.
    Figure 12 shows an embodiment of a studio setting in which a camera views an actor and examines a display wall whose noise is suppressed or reduced by means of, for example, fan control or adjustment of the light output, in accordance with the invention. The sound or noise emitted from the display wall is typical fan noise, from the fan that is present there for cooling purposes. By excluding or removing the fan, or otherwise controlling or modulating it with the generated heat, the noise can be reduced or suppressed. For example, the fan is forced to slow down or run and therefore makes less noise when the temperature has dropped. Alternatively, in reducing the light output from the display wall, less power is involved and thus less heat will be generated by the display wall. As a result, the existing fans can be automatically slowed down or even turned off in some cases.
    Figure 13 shows an embodiment of a studio setting, in which a camera observes actors and examines a display wall whose noise is suppressed or reduced as in Figure 12, and in which the display wall is provided with acoustically absorbing or diffusing material, or the display wall has an open structure such that reflections of audio waves from the surface of the display wall are suppressed or reduced, in accordance with the invention. The display wall, more in particular for example the wall surface facing the studio environment and / or the actors, can also reflect sound or audio waves. In particular when the display wall is curved, the effect on e.g. the actors further strengthened. As a solution for eliminating such audio reflections from the display wall, an open structure or architecture for the display can be chosen. Another possible solution is to provide, for example, an acoustically absorbing and / or diffusing material in (for example, between the LEDs) or on (for example as a surface layer of) the display wall.
    8. Also add markers or markers. Reference can be made here to markers as described in Belgian patent application BE2019 / 5196. Screen markers can be embedded in the acoustically absorbing and / or diffusing material or can be generated by the light emitting elements or e.g. LEDs. These markers can be used for e.g. geometric reference settings of the image recorded by the camera. Alternatively, the markers can also be used as a reference for mapping and geometrically adjusting the display content to match the desired positioning on the screen. Furthermore, such markers can also be used for interactive scenes where they can be used with cameras embedded in head-up displays to create immersive environments.
    9. Color conversion on the display (eg LED display) and therefore color conversion in the camera is no longer necessary. As illustrated in Figure 14, the light emitted color spectrum for red, green and blue from the screen is not necessarily the same as the color sensitivity curves of the camera, although some of the spectra may overlap. Therefore, the camera will perceive the colors differently from the colors output from the screen. A traditional solution to this erroneous color capture by the camera is for operators to adjust the RGB (or other) color gains in the camera setup itself. But this has a detrimental effect, because the perceived colors although the camera looks acceptable when recording the screen, but the color rendition (as seen by the camera) of the background, person (s), actor (s), performer ( s} or presenter will also change, so using this traditional adaptation always requires a 'good' enough approach,
    which means that this (manual) adjustment always results in "OK enough" or is perceived as sufficient on the camera for both the screen and the environment. In other words, it will never be perfect for both.
    Therefore, a more suitable solution is proposed by adjusting the screen side or the LED display or LED wall itself. Here on the display side, for example, individual color intensities can be changed so that they are recorded as needed for the camera. Because only the display (primary) color intensities are changed, this has no effect on the 'environment' or scene. Hence, the camera shot looks perfect for scene and display. Since the color sensitivity of professional and semi-professional cameras is well documented and known, one can add, for example, a display setting that indicates which type of camera is being used, eliminating the need for manual intervention. The method for deriving the correct setting is based on knowledge of the primary colors of the screens and entering the camera sensitivity. This method can be used even for cell phone cameras.
    Yet, as a result, visual perception to the human eye can now be greatly distorted (because the human eye's color perception is different from that of a camera). Therefore, additional colors (eg cyan, orange) can be added to the display or eg LED wall, so that the disturbance is eliminated and the visual perception of the human eye is corrected and thus satisfactory. Adding extra colors to the screen basically means adding multiple color spectral elements. The multiple spectral elements will allow the display to utilize the color theory called "metamerism" making it perfectly possible to display the same perceived color with completely different spectral settings.
    In fact, this "challenge" is part of a broader aspect of display and light sources for photography and video applications. This display in a studio environment also acts as a light source, regardless of whether this is desired or not. As previously stated, the light spectrum of typical LED lighting devices, such as typical red-green-blue (RGB) LED devices, is fixed and does not match the light spectrum of, for example, natural sunlight or industry standard white light sources, such as halogen lamps, tungsten lamps and fluorescent lamps. Therefore, the resulting reflected light when using LED lighting devices may not match that of natural sunlight or industry standard light sources. As a result, the reflected image resulting from the LED lighting devices may not be correctly displayed as perceived by the human eye or as captured by a still or video camera (e.g. standard film or digital image recording), compared to the reflected image that results from natural sunlight or standard light sources. While it is possible to filter manually in conjunction with the LED lighting, manual filtering is not sufficient to provide a match for all colors.
    For these reasons, alternative approaches are needed to allow the widespread use of LED lighting in, for example, photography and video applications. Therefore, there is a need for a system and method for matching the spectrum of a multi-color LED lighting device to the spectrum of any possible white light source. Figure 15 illustrates a schematic overview of a spectral analysis system for matching the spectrum of a multi-spectral display (with multi-color LEDs) to the spectrum of any white light source, while also taking into account the sensitivities of the camera. is the associated flow chart Figure 16 illustrates a functional block diagram of a spectra analysis system 100 for adapting the spectrum of a multicolor LED lighting device to the spectrum of any possible white light source, in accordance with the invention. Spectra analysis system 100 includes a reference light source 110 which may be any commercially available white light source, such as, but not limited to, one or more commercially available halogen lamps, tungsten lamps, fluorescent lamps, hydrargyrum medium-arc iodide (HMI) lamps, and combinations thereof. a Kino Flo 3200 fluorescent lamp from Kin o Flo Inc. (Burbank, CA) or a Lowell 3200 tungsten lamp from Lowel-Light Manufacturing, Inc. (Brooklyn, NY); where 3200 refers to a lamp color temperature (CT) of 3200 Kelvin (K). In addition, reference light source 110 may be representative of natural sunlight. In addition, spectra analysis system 100 includes a multi-color LED light source 114 which is, for example, an LED white light source formed of at least the combination of RGB plus one additional color, i.e., a 4-color LED light source. Preferably, multi-color LED light source 114 is an LED white light source formed from the combination of RGB plus three additional colors, i.e.
    a 6-color LED light source. In one example, the multicolor LED light source 114 is a 6-color modular LED lighting device. More specifically, the colors constituting the 6-color modular LED lighting device may include, but are not limited to, red, green, white, cyan, orange, and blue.
    Spectra analysis system 100 further includes a reference color palette 118, which is the reference color palette of colors to be illuminated by reference light source 110 and multi-color LED light source 114. Reference color palette 118 can be any number of colors determined by the user that defines the light spectrum of reference light source 110 and multi-color LED light source 114 can be analyzed. In one example, reference color palette 118 may be a Munsell or Macbeth color chart that may contain, for example, from about 8 to about 24 colors. Spectra analysis system 100 further includes a reflection spectrometer 122. Reflection spectrophotometers measure the amount of light reflected from a surface as a function of wavelength to produce a reflection spectrum. For a target sample illuminated by white, the operation of a spectrophotometer is to calculate the amount of light reflected at each wavelength interval. Referring to Figure 16, reflection spectrometer 122 is used to calculate the light reflected from reference color palette 118 when illuminated by reference light source 110 or multi-color LED light source 114. Reflection spectrometer 122 can be any commercially available spectrometer. Spectra analysis system 100 further includes a set of one or more image pickup devices
    126. Imaging devices 126 may include, for example, but are not limited to, a video camera 130, a movie camera 132, a digital camera 134, and a still camera 136. Video camera 130 may be any commercially available video camera for electronically recording moving images , such as this one used in the television industry. Film camera 132 can be any commercially available film camera for recording moving images on film, such as those used in the film industry. Digital camera 134 can be any commercially available digital camera for digitally recording still images, such as those available from Sony Corp. (Tokyo, Japan}, Canon Inc. (Tokyo, Japan}, and Eastman Kodak Company (Rochester, NY) Photo camera 136 can be any commercially available still camera for recording still images on film, such as 35mm cameras from Olympus Imaging America Inc. (Melville, NY), Canon Inc. (Tokyo, Japan), and Eastman Kodak Company (Rochester, NY) Spectra analysis system 100 further includes a computer 150 which can use any commercially available handheld, laptop, desktop, or network computer On computer 150 is a system controller 154 which can be any commercially available controller, microcontroller or digital signal processor (DSP) that can execute program instructions, such as those of an LED light source controller 158 and a spectra analysis algorithm 162 Furthermore, system controller 154 manages the overall operations of spectra analysis system 100, including management of communications and data transfer between hardware and software components thereof.
    LED light source controller 158 may be a software or hardware controller associated with multi-color LED light source 114. LED light source controller 158 provides the interface between spectra analysis algorithm 162 and multi-color LED light source 114. In particular, LED light source controller 158 reads a set associated multi-color LED settings 166, which are operating parameters that are then passed to multi-color LED light source 114, setting its light output. Operating parameters for multi-color LED light source 114 may include, but are not limited to, color temperature, overall device power level, individual intensity level of each of the multiple colors.
    Spectra analysis algorithm 162 may be a software algorithm that executes program instructions necessary to match the spectrum of a multi-color LED lighting device, such as multi-color LED light source 114, to the spectrum of any white light source, such as reference light source 110. A source of input data for spectra analysis algorithm 162 may include, but is not limited to, device specification data 170, image data 172, and reflection data 174. In one example, device specification data 170 may include certain specification information, such as the optical filter specifications and response curve. information, from any important or relevant image recording device 126 (e.g., video camera 130, movie camera 132, digital camera 134 and still camera 136) and from the human eye. This information may be provided by the manufacturer of each imaging device 126. In another example, device specification data 170 may include certain specification information for reference light source 110, such as the spectra information that may be provided by the manufacturer of a particular light source device. If not provided by the manufacturer, the spectra information from reference light source 110 can be measured through reflection spectrometer 122 and stored in device specification data
    170. In the case of image pickup devices 126 which are digital, image data 172 may be digital image data returned therefrom. Reflection data 174 may be the data returned by reflection spectrometer 122 which includes the amount of light reflected from reference color palette 118 at each wavelength interval. The operations performed by control of spectra analysis algorithm 162 may include, but are not limited to, the following: e activation / deactivation of the reference light source, either automatically via system controller 154 or, alternatively, by a user via a user interface (not displayed) to request manual activation / deactivation of the reference light source; activating / deactivating the multicolor LED light source, either automatically via system controller 154 and LED light source controller 158 or, alternatively, by prompting a user to manually activate / deactivate the multi-color LED light source; activating / deactivating the reflection spectrometer, either automatically via system controller 154 or, alternatively, by asking a user to manually activate / deactivate the reflection spectrometer; e storing the data returned by the reflection spectrometer; e calculating and storing the difference between the reflection of the reference light source and the reflection of the multi-color LED light source; e determining and storing the optimal output settings of the multi-color LED light source to match the spectrum of the reference light source; e applying any optical filter characteristics to the optimal output settings of the multi-color LED light source; using the optimum output settings of the multi-color LED light source, initiating an image recording event through one or more image capture devices, either automatically via system controller 154 or, alternatively, by asking a user to manually perform the image capture operation; and reading the image data from one or more image capturing devices and verifying that the spectrum of the multi-color LED lighting device substantially matches the spectrum of the reference light source.
    10. Since traditional (surface mounted) LEDs have a certain RGB die or pixel arrangement within a package, the colors that are emitted in all directions will differ slightly. Therefore, one can rotate these LEDs alternately 90 ° / 180 ° degrees to overcome these viewing angle problems, but the acoustic shader can also take care of this. A diffuser lens can be mounted on top of the LEDs or light-emitting elements generally of the screen used, not only for uniformity aspects, but at the same time providing a structure for acoustic damping (or sound absorption and / or diffusion). With such an optical diffuser lens, a fairly closed design is proposed, although a more open design would also be an improvement, e.g. especially acoustically, where the open grid added material comprises only sound absorbing and / or diffusing properties and is provided as a matrix between the LEDs of the display. In one embodiment, the optical diffuser (e.g. lens) for improving / modifying the optical characteristic of the screen can work as well as an acoustic diffuser.
    11. Dynamic range Since LED screens have the potential to have a very high dynamic range (i.e. brightness of 5000nits and more), there is a need to show the full dynamic range defined by e.g. PQ gamma curve as defined in BT2100.
    https://www.eizoglobal.com/library/management/ins-and-outs-of-hdr/index2.html also available in Figure 17 of the drawings set.
    The range is from 0 to 10,000 nit because this gamma definition is based on absolute brightness.
    The range to clearly display all incoming values requires at least 24bits when using PWM. However, the most common LED constant current PWM drivers are limited to 14bit (and in some exceptional cases to 16bit).
    So this is not possible to show this full dynamic range without gray scale loss.
    However, what is suggested are several solutions to this problem to achieve wider than standard dynamic range:
    i. depending on the desired clustered content, the power of the PWM driver is also adjusted. Increasing the current will also increase the light output of the LEDs. This is not linear in most cases, but since we can characterize this behavior, it can be compensated for using a formula depending on the clarity required. Ideally, there is a current setting for each individual LED, but not all PWM LED drivers in the field have this feature. In general, a particular PWM driver current setting is common to a group of LEDs, and thus all LEDs (eg 8 or 16) connected to the PWM driver will be particularly affected. In case each LED has a current setting, the cluster is of course one LED. An algorithm can e.g. are: determine the maximum nit level for LEDs in certain cluster depending on the content and set the current for these specific LED or LEDs to maximum LED current. Depending on this current, determine other values of LEDs and use PWM to set the desired brightness using spline curve adjustment.
    ii. in conjunction with or independently of the above, there is also an alternate way to generate a gamma-like behavior. In all existing systems today, people work with a fixed frequency clock to generate a PWM cycle. E.g. in the case of 12bit, to achieve 50% brightness, one set PWM high for 2048 counts out of 4096. This is shown schematically in Figure 18 (a). Alternatively, as illustrated in Figure 18 (b), one can modulate the clock, i.e. higher frequency at the beginning of the PWM cycle to a lower frequency at the end of the PWM cycle. This basically means that the 'lowest' bit on time is shorter (and this is exactly what is needed in a gamma curve). So standalone or a combination of a gamma lookup table and modulation of the grayscale clock in frequency during PWM cycle can give you mathematically more than 24bit "gray" scales if you see it in a linear frequency time domain. And this is exactly what we want and considered very important, while it is not known at all in the art.
    iii.
    Although, in some circumstances, displaying the full dynamic range is not really desirable (for example, when the screen is used to see or evaluate how an image or movie looks on a traditional screen (for example, monitor or projector) that does not show the full dynamic range can reach 10,000nit). One can e.g. apply the spline curve adjustment to set the maximum brightness to the monitor brightness (and / or also change the global current to the LEDs for the desired color and brightness} and then display the content in the
    REAL - fixed brightness (and even the same color points => see calibration as described for example in patent application BE2019 / 5196 with regard to a deformable display)
    as if it were displayed on that monitor and / or projector.
    权利要求:
    Claims (4)
    [1]
    A method of using light-emitting or light-reflecting light source displays that are part of a studio environment, with one or more of said displays, wherein one or more cameras at least partially survey what is being displayed on one or more of said displays. said displays, wherein at least one of said displays includes an arrangement for visual enhancement of said at least one display, and wherein said studio environment includes at least one arrangement for acoustically matching, by modifying said displays to enhance the acoustic behavior of said displays to optimize the studio, in particular said displays are either provided with acoustically absorbing and / or diffuse material and / or adapted to transmit part of the sound that said displays generate themselves and / or have received from the environment.
    [2]
    The method of claim 1, wherein the displays are adapted to minimize their sound generating behavior, and / or the displays are adapted to maintain good visual performance, regardless of improved sound generating behavior.
    [3]
    3. A method of improving a light source display's visual performance for a light source display comprising a number of different light sources, the visual performance being the visual performance observed after the camera records the image displayed by the light source display, the method comprises: providing a light source display with at least 3 different colors (which may be a partially overlapping spectrum); and for at least one light source, (i) receiving the light source input signal; (ii) adjusting the light source input signal to compensate for camera conversion effects.
    [4]
    The method of claim 3, wherein (iii) the light source input signal is further adjusted to compensate for the visual performance perceived by a human eye immediately after compensation for the camera conversion effect and (iv) the adjusted light source input signal is adjusted to said light source.
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    同族专利:
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    引用文献:
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    法律状态:
    2021-03-19| FG| Patent granted|Effective date: 20210111 |
    优先权:
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    US201962858534P| true| 2019-06-07|2019-06-07|BE20205410A| BE1027295B1|2019-06-07|2020-06-08|ACOUSTIC STUDIO SCREEN|
    US16/895,872| US20200388210A1|2019-06-07|2020-06-08|Acoustic studio led screen|
    BE20205411A| BE1027296B1|2019-06-07|2020-06-08|ACOUSTIC STUDIO SCREEN|
    EP20178832.0A| EP3748945A1|2019-06-07|2020-06-08|Method for optimizing the dynamic range of a led screen|
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