巴西专利BR102018016262A2 DATA SIGN ADJUSTMENT TO SCREENS

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专利摘要:
"data signal adjustment for screens". The present invention relates to a screen that may have an active area that includes screen pixels. The screen may include an inactive notch region that extends into the active area. Data lines can provide screen trigger circuitry image data to screen pixels. Image data may include data signals that correspond to portions of the screen that do not include pixels, such as the idle notch region. null data signals may cause non-uniformity in the displayed image. null data signals can be adjusted to minimize non-uniformities. null data signals corresponding to the idle notch region can be adjusted to have gray levels that gradually decrease with the margin distance between the idle notch and the active area. All data signals corresponding to the idle notch can be adjusted to a uniform gray level.
公开号:BR102018016262A2
申请号:R102018016262-4
申请日:2018-08-09
公开日:2019-04-16
发明作者:Koorosh Aflatooni；Warren S. Rieutort-Louis；Jaen-Pierre S. Guillou；Pierre-Yves Emelie；Myung-Je CHO；Marc ALBRECHT；Graeme M. Williams；Sean C. Chang；Zhao Wang
申请人:Apple Inc.；
IPC主号:

专利说明:

[001] This application claims priority over US patent application No. 15 / 989,066, filed on May 24, 2018 and provisional patent application No. 62 / 553,745, filed on September 1, 2017, each of which is incorporated herein by way of reference in its entirety.
BACKGROUND [002] This document relates, in general, to electronic devices and, more particularly, to electronic devices with screens.
[003] Electronic devices often include screens. For example, cell phones and portable computers often include screens to present information to a user.
[004] The screens contain arrays of pixels to present images to a user. The active area can be rectangular and can be limited by an inactive area that does not include pixels. The data lines provide data signals from a screen integrated driver circuit mounted outside the active area for the pixels in the matrix.
[005] Difficulties can arise in an attempt to display images on screens that do not have uniformly rectangular shapes (for example, screens with rounded corners and / or inactive areas that extend into the active area to form an inactive notch). For example, data lines can be provided with data signals corresponding to pixels that would exist on a uniformly rectangular screen, but which do not exist due to the presence of rounded corner portions or a notched notched area. These data signals can be adjusted so that the image can be displayed. If care is not taken, however, adjusting the display data signals can cause unwanted visual artifacts in the
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2/33 screen.
SUMMARY [006] A screen can have an active area that includes screen pixels. The screen may include an inactive notch region that extends into the active area of the screen to accommodate a speaker or other components. The data lines can provide data signals from the screen trigger circuitry to the screen pixels. Port lines can control the loading of data signals to the screen pixels.
[007] When displaying data for a rectangular image, the data lines can be provided with data signals corresponding to pixels that would exist on a uniformly rectangular screen, but which do not exist due to the presence of the inactive notch region. These data signals for nonexistent pixels (null data signals) can cause non-uniformities in a displayed image. Null data signals can be adjusted to minimize non-uniformities (for example, smoothing the edge between the active area and the inactive notch region), but these adjustments can create abrupt transitions in the stresses that are provided in the data lines. These abrupt transitions can lead to unwanted screen artifacts.
[008] Data signal compensation operations can be used for the gradual transition of voltages in the data lines. The null data signals corresponding to the inactive notch region can be closer to the margin between the active area and the inactive notch and decrease to zero further from the margin. All data signals corresponding to a portion of the screen where there are no real pixels can be adjusted to a uniform gray level.
BRIEF DESCRIPTION OF THE DRAWINGS [009] Figure 1 is a diagram of an illustrative electronic device that has a screen according to a modality.
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3/33 [0010] Figure 2 is a perspective view of an illustrative electronic device that has a screen with an active area and an inactive area according to a modality.
[0011] Figure 3 is a diagram of an illustrative organic LED screen according to an embodiment.
[0012] Figure 4 is a diagram of a portion of an illustrative organic LED screen that has an inactive notch that extends into the active area according to a modality.
[0013] Figure 5 is a diagram of an illustrative pipeline for showing images on a screen according to a modality.
[0014] Figure 6 is a flow chart of illustrative steps involved in adjusting display signals on a screen according to a modality.
DETAILED DESCRIPTION [0015] An illustrative electronic device of the type that can be equipped with a screen is shown in Figure 1. Electronic device 10 can be a computing device such as a laptop computer, a computer monitor containing an embedded computer, a computer tablet, cell phone, media player, or other handheld or portable electronic device, a smaller device, such as a wristwatch device, a hanging device, a headset device, a device embedded in glasses, or other equipment worn on a user’s head, or other device to be worn close to the body or in miniature, a screen, a computer screen that contains an embedded computer, a computer screen that does not contain an embedded computer, a gaming device, a navigation device, an embedded system, such as a system in which electronic equipment with a screen is mounted on a kiosk or car or other team
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4/33 electronic device.
[0016] As shown in Figure 1, the electronic device 10 can have the control circuitry 16. The control circuitry 16 can include the processing and storage circuitry to support the operation of the device 10. The assembly processing and storage circuits can include storage such as hard disk drive storage, non-volatile memory (for example, flash memory or other electrically programmable read-only memory configured to form a solid state drive), volatile memory (for example, static or dynamic random access memory) etc. The processing circuitry in the control circuitry 16 can be used to control the operation of device 10. The processing circuitry can be based on one or more microprocessors, microcontrollers, digital signal processors, baseband processors , power management units, audio chips, application-specific integrated circuits, etc.
[0017] The set of input and output circuits in device 10, such as input and output devices 12, can be used to enable data to be provided to device 10 and to enable data to be provided from device 10 to external devices . Input and output devices 12 may include buttons, joysticks, scroll wheels, numeric keypads, keyboards, microphones, speakers, tone generators, vibrators, cameras, sensors, light-emitting diodes and other status indicators, data, proximity sensors, ambient light sensors, etc. A user can control the operation of the device 10 by providing commands through the input and output devices 12 and can receive status information and other outputs from the device 10 using the output features of the input and output devices 12.
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5/33 [0018] Input and output devices 12 can include one or more screens, such as screen 14. Screen 14 can be a screen as a touch screen that includes a touch sensor to collect touch input from a user. A touch sensor for screen 14 can be based on an array of capacitive touch sensor electrodes, acoustic touch sensor structures, resistive touch components, force based touch sensor structures, a touch based sensor light, or other suitable touch sensor arrangements. A touch sensor for the screen 14 can be formed from electrodes formed on a common screen substrate with the pixels of the screen 14 or can be formed from a separate touch sensor panel that overlaps the pixels of the screen 14 If desired, screen 14 can be insensitive to touch (that is, the touch sensor can be omitted).
[0019] Control circuitry 16 can be used to run software on device 10, such as operating system code and applications. During the operation of the device 10, the software running on the control circuitry 16 can display images on screen 14. If desired, the control circuitry 16 can include a data signal attenuator 55 to attenuate data signals from image provided to screen 14. In an illustrative example, the control circuitry 16 may also include a data signal compensator 57 to adjust data signals that have been attenuated by the attenuator 55. In another illustrative example, the data signal compensator data 57 can be incorporated into screen 14, where it can receive and adjust data signals that have been attenuated by attenuator 55.
[0020] A perspective view of an illustrative electronic device 10 is shown in Figure 2. Device 10 can have a housing 11 in which components such as the input and output devices
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12, screen 14 and control circuitry 16 are assembled. Housing 11, which can sometimes be called a casing or case, can be formed of plastic, glass, ceramics, fiber composites, metal (for example, stainless steel, aluminum, titanium, gold etc.), other suitable materials or a combination of any two or more of these materials. The housing 11 can be formed using a monoblock configuration in which part or all of the housing 11 is machined or shaped as a single structure or can be formed using multiple structures (for example, an internal frame structure, one or more structures that form external carcass surfaces, etc.).
[0021] As shown in Figure 2, screen 14 can have an active area AA and an inactive area IA that together occupy most or all of the front face of device 10. The active area AA can include pixels that emit light to display images to a user. The inactive margin area IA can surround the active area AA and be used to accommodate screen trigger circuitry, door trigger circuitry, power supply circuitry and conductive paths to provide display signals to pixels in the area active. The inactive area IA can be free of screen pixels. Active area AA and inactive area IA can meet at a 51 margin (sometimes referred to in the present invention as an active area margin, inactive area margin, boundary or dividing line between the active area and the inactive area) to accommodate the input-output components 12 such as a speaker, camera, ambient light sensor or proximity sensor on device 10, a portion of the inactive area IA can extend into the active area AA to form a notch 50 (sometimes called in the present invention of a notched region, inactive notch or notch-shaped recess). The shape of margin 51 between the active area and the inactive area can have flexed portions (sometimes
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7/33 called curved portions, deflected portions, sinuous portions or serpentine portions in the present invention) where the notch 50 extends into the active area. As shown in Figure 2, margin 51 may have rounded corners. Since the inactive area IA is free of screen pixels, the input and output components can be mounted in the notched area 50 without being obstructed by the active screen structures.
[0022] Screen 14 can be an organic LED screen. On an organic LED screen, each pixel contains a respective organic LED. An ELVDD positive power supply voltage can be supplied to an organic LED positive power supply terminal and an ELVSS earth power supply voltage can be supplied to the LED earth power supply terminal. organic light. The diode has an anode (terminal AN) and a cathode (terminal CD). The state of a drive transistor controls the amount of current flowing through the diode and, therefore, the amount of light emitted from the screen pixel. The cathode is coupled to the earth terminal, so that the cathode terminal of the diode can sometimes be called the earth terminal.
[0023] As shown in Figure 3, the canvas 14 can include layers like the substrate layer 24. The substrate24 and, if desired, other layers in the canvas 14 can be formed from layers of material like layers of glass, layers polymer (for example, flexible sheets of polyimide or other flexible polymers) etc. The substrate 24 can be flat and / or can have one or more curved portions. The substrate 24 may have a rectangular shape with vertical left and right edges that extend along the geometric axis Y and upper and lower horizontal edges that extend along the geometric axis X, or may have a non-rectangular shape.
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In configurations in which substrate 24 has a rectangular shape with four corners, the corners can, if desired, be rounded.
[0024] Screen 14 may have an array of image pixels 22 arranged in rows and columns. The pixels 22 form an active AA area of the screen 14 that displays images to a user. The inactive margin portions of the screen 14, such as the inactive areas IA along one or more of the edges of the substrate 24, do not contain pixels 22 and do not display images to the user (i.e., the inactive area IA is free of pixels 22 ).
[0025] Each pixel 22 (sometimes referred to in the present invention as light emitting pixels 22) may have a light emitting diode as an organic light emitting diode and associated thin film transistor circuitry. The matrix of pixels 22 can be formed from rows and columns of pixel structures (for example, pixels formed from structures in canvas layers like substrate 24). There can be any suitable number of rows and columns in the pixel array 22 (for example, ten or more, a hundred or more, or a thousand or more). Screen 14 may include pixels 22 of different colors. For example, screen 14 may include red pixels that emit red light, green pixels that emit green light and blue pixels that emit blue light. Settings for screen 14 that include pixels of other colors can be used, if desired. The use of a pixel layout with red, green and blue pixels is illustrative only.
[0026] The screen driver circuitry 20 for the screen 14 can be mounted on a printed circuit board that is coupled to substrate 24 or can be mounted on substrate 24. Signal paths, such as signal path 26, they can couple the screen driver circuitry 20 to the control circuitry 16. The circuitry 20 may include one or more screen driver integrated circuits and / or thin film transistor circuitry.
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9/33 [0027] During operation, the control circuitry of device 10 (for example, control circuitry 16 of Figure 1) can provide a circuitry as a screen trigger circuitry 20 information about images (for example, image data frames) to be displayed on screen 14. To display images on screen pixels 22, the screen trigger circuitry 20 can provide image data corresponding to data lines D while outputting clock signals and other control signals to support screen trigger circuitry, such as door trigger circuitry 18. Data lines D are associated with respective 22 pixel columns. The door trigger circuitry 18 can produce port line signals (sometimes called scan signals, broadcast activation signals, etc.) or other control signals for pixels 22. Port line signals p can be transmitted to pixels 22 using lines such as gate G lines. There may be one or more gate lines per row of pixels 22. Door trigger circuitry 18 may include integrated circuits and / or thin film transistor and may be located along the edges of the screen 14 (for example, along the left and / or right edges of the screen 14, as shown in Figure 3) or elsewhere on the screen 14 (for example, as part of the circuitry 20, along the bottom edge of the screen 14 etc.). The configuration in Figure 3 is merely illustrative.
[0028] Door trigger circuitry 18 can declare door line signals in door G lines on screen 14. For example, door trigger circuitry 18 can receive clock signals and other control signals from the set of screen trigger circuits 20 and can, in response to the received signals, declare a port signal on port G lines in sequence, starting with the signal
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10/33 of port line G in the first row of screen pixels 22. As each port line is activated, data from data lines D is loaded into the corresponding row of screen pixels. In this way, the control circuitry in device 10, like the screen driver circuitry 20, can provide pixels 22 with signals that direct pixels 22 to generate light to display a desired image on the screen 14.
[0029] The pixel circuitry 22 and, if desired, a screen trigger circuitry, such as circuitry 18 and / or 20, can be formed using thin film transistor circuitry . Thin film transistors on screen 14 can generally be formed using any suitable type of thin film transistor technology (for example, silicon transistors such as polysilicon thin film transistors, semiconductor oxide transistors as transistors zinc oxide, gallium and indium etc.).
[0030] Conductive trajectories (for example, one or more signal lines, conductive blanket films and other conductive structures provided with a pattern) can be provided on screen 14 to route D data signals, G gate signals and power signals as an ELVDD positive power supply signal for pixels 22. As shown in Figure 3, these signals can be supplied to pixels 22 in active area AA using signal routing paths that receive D signals, port lines G and ELVDD.
[0031] As shown in Figure 3, the notch 50 can project into the active area AA of the screen 14. Although the notch 50 is free of screen pixels 22, the portions of the active area AA adjacent to the notch (for example, active area portions AA 'on the left and right sides of the notch 50) may include screen pixels 22. To provide port signals from port driver circuitry 18 to
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11/33 pixels 22 on both sides of the notch 50, the door lines G can have flexed portions (sometimes referred to in the present invention as curved portions, serpentine-shaped portions, sinuous portions, or deflected portions) that are routed to the around notch 50. While there are no pixels 22 in notch 50 to which these gate lines G provide gate signals, notch 50 may include another set of circuits, such as dummy pixels or capacitor structures that are coupled to these gate lines . Fictitious pixel structures and / or capacitor structures can help prevent unwanted screen artifacts that may arise due to the fact that the G port lines that are routed through the notch 50 (for example, port lines that provide port signals to pixels in the active area AA 'region) are coupled to different numbers of screen pixels 22 in relation to the gate lines G formed in the rest of the active area AA.
[0032] A screen as shown in Figure 3 can, for example, include approximately 2,500 rows of screen pixels 22 and 1,250 columns of screen pixels 22. In the illustrative arrangement of Figure 3, such screen 14 would have 2,500 input lines G and 1,250 data lines D. As shown in Figure 3, the data lines D that run along the left and right edges of the screen can provide data signals to a pixel in each of the rows of the screen, including pixels that are formed in the portions of active area AA 'on each side of notch 50. Due to the presence of notch 50, however, some lines of D data that run through the center of the screen can provide data signals for less than each row of the screen (ie, D data lines that are under notch 50 can go through notch 50 and end earlier than data lines that provide pixel data signals in the active area region AA '). In one example, the notch 50 may have a height in the Y direction of approximately 100 rows of pixels. In such an arrangement, data lines D that go into the
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12/33 notch 50 can be attached to approximately 100 fewer screen pixels 22 than data lines that extend across the entire height of the screen (for example, data lines that extend across the active area region AA ' and into the edge of the active area in the AA 'region).
[0033] As port lines G control the loading of data signals (data loading) from data lines D in pixels 22, the presence of notch 50 can result in an arrangement in which a first set of port lines that extend from edge to edge through the active area of the screen in the X direction (for example, door lines that do not go into slot 50 and are not in the active area portion AA ') to control data loading for both a first set of data lines and a second set of data lines. The first set of data lines can extend across the screen in the Y direction to the edge of the active area adjacent to the notch in the active area portion AA '(for example, data lines that do not go into notch 50). The second set of data lines can extend across the screen and end at the notch. A second set of door lines extending through the active area portion AA 'and going into the notch 50 can control data loading for the first set of data lines that is present adjacent to the notch in the area portion activates AA ', but not for the second set of data lines that extends across the screen and ends at the notch. The first and second sets of door lines can each include any suitable numbers of door lines (for example, three, five, ten, one hundred, five hundred or other suitable numbers of door lines). The first and second sets of data lines can each include any appropriate numbers of data lines (for example, three, five, ten, one hundred, five hundred or other Petition 870180069135, 08/09/2018, p. 22 / 94
13/33 other appropriate numbers of data lines).
[0034] Although there are no actual image pixels 22 in slot 50, data lines that provide data signals to columns of pixels ending in slot 50 can still generate data signals as if there were pixels in slot 50. For example , these data lines can also be switched between different data voltages for each row of pixels, since the door lines carry a data frame on the screen. Since there are no screen pixels in slot 50, however, these data signals are not actually received by any screen pixels 22 and are simply replaced by a new data signal in data line D when the next row of pixels is programmed. These data signals can be called data signals for virtual pixels 22 '(because the data signals correspond to pixels that do not really exist), inactive data (because the data corresponds to the inactive notch area of the screen) non-image data (because the data signals do not match any image content displayed in the active area), null data signals (because even if the data signals have a value greater than zero, they are not used to trigger pixels in the active area) , constant or constant value data (because the data that is triggered on the D data lines corresponding to the inactive notch may not change between frames), dummy data signals, filler data signals or notch data signals. Once the programming for the frame has reached a row that includes screen pixels coupled to data lines D that end early (that is, the data lines that follow into slot 50), the data signals on those lines D data will be supplied to a screen pixel 22.
[0035] Null data / non-image data may correspond to data signals that, if given to a pixel, will cause the pixel
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14/33 do not emit light (for example, the pixel would remain off and look black). In this way, the null data / non-image data can have the minimum level of data signal voltage (for example, 0 volts) and correspond to a gray level of 0, and can be called black data. Null data / non-image data can correspond to data signals that, if given to a pixel, will cause the pixel to emit some light while remaining below the maximum luminance of the pixel. In this way, the null data / non-image data can have a data signal voltage level greater than the minimum and correspond to a gray level of 1 or higher and can be called gray data.
[0036] In layouts in which the active area AA of the screen 14 has rounded corners as shown in Figure 3, the inactive area may include corner regions 59 (sometimes referred to in the present invention as inactive corners) that would include screen pixels if not either by the rounded corners of the active area AA (for example, if the active area AA had a completely rectangular shape). Corner regions 59 can cause premature termination of data lines D that go into corner regions 59. In this type of arrangement, at least some of the data signals in these data lines are actually for virtual pixels 22 'that correspond to locations in the corner regions 59.
[0037] On organic LED screens, the colored emitting material can be used to provide light emitting diodes with the ability to emit red, green and blue light (or light of other colors). For example, red organic light emitting diodes can contain red organic emitting material, green organic light emitting diodes can contain green organic emitting material, and blue organic light emitting diodes can contain blue organic emitting material. The emitting material can degrade
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15/33 since light-emitting diodes are used. Intense use, when the diodes are driven by large currents, can age the diodes more quickly than the use of light, where the diodes are driven with small currents. As the diodes age, the degraded emitter material will cause the diodes to emit a reduced amount of light for a given drive current. Pixel luminance on organic LED screens is therefore, in general, a function of the aging history of pixels on the screen. The luminance and pixel aging can be monitored based on the data signals that are supplied to the pixels. For example, a pixel that is endowed with data signals that cause the pixel to be triggered at a high luminance level using large currents will degrade more quickly than if the same pixel was endowed with data signals that cause the pixel to be triggered at a low luminance level using low currents. Since the data signals sent on data lines D generally correspond to a gray value between 0 and 255 (that is, the higher the data signal value / gray value, the brighter the pixel is triggered), the set of circuits in electronic device 10 may be able to track the aging of the screen pixels based on these data signals as they are provided on data lines D.
[0038] To compensate for these changes induced by unwanted aging in screen pixels 22 and therefore to ensure that screen 14 can display images accurately, device 10 can be equipped with pixel luminance degradation compensation capabilities (sometimes compensation in the present invention). In particular, the control circuitry of device 10 can be used to implement a pixel luminance degradation tracker and / or
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16/33 pixel luminance that maintains information about the aging history of each of the pixels (sometimes referred to in the present invention as burning statistics) on screen 14. Based on this aging information, the pixel luminance degradation compensator you can adjust the luminance values provided for each of the pixels on the screen 14. As the pixel luminance that has degraded due to aging decreases over time, the data signals (sometimes referred to in the present invention as pixel luminance values or gray values) provided to other pixels on the screen can be changed (for example, reduced) so that the overall luminance of the screen corresponds to the reduced luminance of the pixels that have aged the fastest.
[0039] As described above in connection with Figure 3, the screen trigger 20 can send inactive data signals to pixels that would be present (but not really present) if it were not for the presence of the notch 50. Like the aging of the screen is monitored based on the data signals sent on data lines D (regardless of whether or not they are actually received by any 22 pixels), however, those inactive data signals being provided for virtual pixels 22 '(for example, in the notch 50 or corner regions 59) may cause inaccuracies in tracking pixel luminance degradation. For example, if screen trigger 20 is sending inactive data signals that correspond to high luminance values, but no pixels are actually receiving these data signals or displaying shiny content because the data signals are for 22 'virtual pixels, pixel luminance degradation tracking can, however, take these inactive data signals into account when determining pixel aging. When the pixel luminance degradation compensator compensates (reduces) the brightness of the screen based on information from
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17/33 pixel aging for pixels that don't really exist, screen 14 may be dimmed inaccurately or prematurely.
[0040] To prevent the pixel luminance degradation compensator from reducing screen brightness based on pixel aging information for pixels that do not actually exist, electronic device 10 can implement data signal attenuation (sometimes called in this data signal reduction, data signal minimization, adaptive margin gain or edge filtering) that adjusts the values of the inactive data signals being provided for the virtual pixels 22 '(for example, in the notch 50 or corner regions 59) before these data signals are distributed on data lines D. For example, data signal attenuation can be implemented in control circuitry 16 so that the values of the inactive data signals for the virtual pixels 22 'are set to zero (that is, minimum luminance or black pixel data) before being fed to the screen driver circuitry 20 o u distributed in data lines D. Once these data signals are set to 0, their effect on pixel luminance degradation tracking can be reduced or eliminated, thereby preventing the pixel luminance degradation compensator from reducing the screen brightness based on pixel aging information for pixels that don't actually exist. The data signal attenuation may not adjust the data signals for the screen pixels 22 in the active area AA of the screen, so these data signals will be distributed normally on the D data lines.
[0041] If desired, adaptive margin gain operations (data signal attenuation) of the type described above can also be used to provide a smooth visual transition between the active area AA and the inactive area IA in the region around the notch 50. For
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18/33 example, when margin 51 has curved portions, as shown in Figure 3, adaptive margin gain operations can adjust the data signals provided to pixels 22 next to the curved portions of margin 51. Adjusting some of the signals of data provided to screen pixels 22 in the active area AA can help prevent abrupt brightness transitions that can create jagged edges visible along margin 51.
[0042] If desired, data signal attenuation operations can be performed using circuitry on control circuitry 16 and / or on screen trigger circuitry 20. In another example, the electronic device 10 may include hardware structures, such as a data signal attenuator (sometimes called in the present invention a data signal attenuation circuitry, a data signal minimizer, a data signal reducer, a filter mechanism or an adaptive margin gain mechanism) that performs data signal attenuation operations. If desired, data signal attenuator 55 can be formed in the control circuitry 16, the screen driver 20, or from another circuitry in the device 10.
[0043] As described above in connection with Figure 3, each pixel 22 can receive a positive ELVDD power supply voltage on a positive power supply voltage line (for example, a positive power supply voltage loop) and data signals on data lines D. Due to the arrangement of data lines D and positive power supply voltage lines on screen panel 14, there may be capacitive coupling between data lines D and the voltage line of positive power supply during normal operation of the screen 14. The D data lines that extend below the notch 50 can be triggered with a data signal (sometimes called gray level here) of 0 for the program.
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19/33 mation of approximately the first 100 rows of the screen (ie, the inactive notch) when data signal attenuation is implemented. Since programming begins with a row of the screen that includes screen pixels 22 to which these D data lines provide data signals, however, the data signal attenuation will no longer be applied and these D data lines will be provided with normal data signals. In some scenarios, this can lead to a major change in the data signal that is provided in a D data line. For example, a data line D below the 50 slot region can transition from providing a gray value. from 0 for the first 100 rows to a gray value of approximately 225 in row 101. This sudden change in voltage in data line D can change the capacitive coupling (sometimes called horizontal cross interference in the present invention) between the line D data and the positive power supply voltage line, causing a voltage drop in the positive power supply voltage line in the vicinity of the row in which the transition occurs (for example, in one or more of the rows 90 to 110 of screen 14). Since the amount of current flowing through the organic light-emitting diode at each pixel 22 is based on the positive power supply voltage, this voltage drop across the positive power supply voltage line can cause the current flowing through the diodes organic light emitters in the vicinity of row 100 also fall. This drop in current passing through the organic light-emitting diodes can cause a resulting drop in the brightness of these pixels, causing a dark horizontal line to appear on the screen in the vicinity of row 100. If care is not taken, that dark line can be visible to an electronic device user 10, creating an undesirable screen artifact.
[0044] To reduce or eliminate the dark line on the margin between the
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20/33 central active area AA and the portion of active area AA 'adjacent to the notch 50 without causing premature screen fading due to pixel luminance degradation compensation, the null data signals that are provided for the virtual pixels 22' ( for example, in the notch 50 or corner regions 59) can be set to a value that facilitates the transition of data signal value in the active area below the notch 50 or in the nearby corner regions 59. Operations that adjust data signals to facilitate this transition can be called in the present invention for data signal compensation, data signal correction, data signal adjustment or data signal masking. In one example, data signal compensation operations can be performed using a circuit set in the control circuit set 16 and / or the screen trigger circuit set 20. In another example, the electronic device 10 it may include hardware structures such as a data signal compensator 57 (sometimes referred to in the present invention as a data signal compensation circuitry or a data signal canceller) that performs data signal compensation operations. If desired, the data signal compensator 57 can be formed in the control circuitry 16, the screen trigger 20, or with the use of another circuitry in the device 10. Data signal compensation operations can be be performed using a mathematical mask that is applied to null data signals, using a lookup table that relates specific pixel addresses (for example, the specific row and column in which a pixel is located) with the respective compensated inactive data signals or inactive data signal compensation factors (for example, gain values), using a lookup table that relates specific pre-compensation data signals to compensated inactive data signal values , or
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21/33 using other operations.
[0045] An illustrative diagram of a portion of the screen 14 in the vicinity of the notch 50 is shown in Figure 4. Figure 4 shows a group of screen pixels 22 in the active area AA below the notch 50 which are provided with data signals ( gray levels) of an exemplary value A. The inactive notch 50 may include a transition region 61 (sometimes referred to in the present invention as a margin region) and an upper region 63 (sometimes referred to in the present invention as a central region). The transition region 61 and the upper region 63 correspond to the virtual pixels 22 'for which the data lines D still carry data signals, although there are actually no light emitting pixels in this area. In the transition area 61, the data signals (gray levels) that are provided in the data lines D for those imaginary pixels 22 'are shown to have an exemplary value of T1 for the lowest row of virtual pixels 22' in the notch 50 (i.e., the last row of virtual pixels 22 'before the active area of AA), and an exemplary TN value for a row of virtual pixels in the transition region 61 that is furthest from the margin between notch and active area ( for example, the last row of pixels in the transition area 61). The transition region 61 can correspond to (include) two, three, five, ten, twenty-five, fifty, one hundred or other numbers of virtual pixel rows 22 '(for example, the value of N in TN can be between 2 and 500, inclusive). The data signals (gray levels) that are provided in data lines D for imaginary pixels 22 'in the upper portion 63 are shown to have an exemplary value of Z. The upper region 63 may correspond to (include) two, three , five, ten, twenty-five, fifty, one hundred or other numbers of virtual pixel rows 22 '.
[0046] In an illustrative example, the values of inactive data signals that correspond to transition area 61 may gradually
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22/33 decreases you to rows of virtual pixels 22 'that are farthest from the margin between the inactive notch and the active area. For example, the gray level A value for screen pixels 22 in the active area AA may be 150. Instead of setting the gray level values for all virtual pixels 22 'to zero (which can cause them to appear unwanted screen artifacts), the gray level T1 for a first row of virtual pixels 22 'in the transition area 61 can be adjusted to 100. The gray level Tn for the last row of virtual pixels can be set to 1. The gray levels for virtual pixels 22 'between the first and the last row of virtual pixels in the transition zone 61 can have values between 1 and 100. In this way, the null data corresponding to the inactive notch (for example, the transition zone 61) can be called gray data or gray image data that includes a plurality of different levels of gray. The gray levels can decrease linearly or exponentially the farther in the transition zone 61 the virtual pixel is. In other words, the gray levels (data signals) corresponding to the inactive notch may decrease linearly or exponentially with increasing the margin distance between the active area and the inactive notch (for example, the farther from the margin between the inactive notch and the active area) the location in the transition zone 61 that the null data signal corresponds to, the lower the gray level can be). The gray level Z for virtual pixels 22 'in the upper zone 63 can be set to zero. In this way, the null data corresponding to the inactive notch (for example, the upper zone 63) can be called black data. By gradually reducing (tapering) the gray levels provided in data lines D ending at notch 50, the voltage drop in the positive power supply line can be limited and the presence of the dark line around margin 53 can be reduced or deleted. Since the inactive data signals provided on the
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23/33 D data is still taken to zero for some of the virtual pixels 22 ', and as inactive data signals that are higher than zero are still reduced in relation to the data signals being provided for the screen pixels 22 in active area AA, the impact of these inactive data signals on tracking pixel luminance degradation can be limited so that premature screen fading is minimized.
[0047] As the transition region 61 and the upper region 63 of the notch 50 correspond to the rows of pixels to which the notch 50 extends, the null data corresponding to the values of Z, T1, TN and / or the other values of gray for transition region 61 can be provided when port lines for these rows are being used to control data loading. For example, while using a first (or more) port line (s) corresponding to a row (s) of pixels to which the notch 50 extends, the screen trigger circuitry 20 may provide a line D data (s) that truncate at the notch 50 with null data signals that correspond to gray values of T1, Tn and / or the other gray values (for example, gray data) for the transition region 61. You can there may be one, two, three, four, five, ten or more port lines for which the screen driver circuitry 20 operates in this manner to provide gray data. The gray levels associated with the gray data can decrease linearly or exponentially with increasing distance (from the door line) from the margin between the inactive notch 50 and the active area AA. While using one (or more) second port line (s) corresponding to one (or more) second row (s) of pixels to which the notch 50 extends, the screen trigger circuitry 20 can supply the D data line (s) that truncate the notch 50 with null data signals that correspond to gray values of Z (e.g., black data). Can ha
Petition 870180069135, of 08/09/2018, p. 33/94
24/33 see one, two, three, four, five, ten or more port lines for which the screen driver circuitry 20 operates in this manner to provide black data.
[0048] The example described above is merely illustrative. If desired, the gray levels for virtual pixels 22 'can be determined in other ways. For example, the gray levels for virtual pixels 22 'can decrease with the distance from margin 51 according to functions in addition to linear or exponential functions, can be adjusted using fixed or dynamically determined displacement values, can be adjusted accordingly. a value of 0 (or other value) as previously determined by data signal attenuation operations, can be adjusted from an original gray level that was not determined by data signal attenuation operations, or can be determined in other ways . If desired, the values of Z, T1, Tn and / or the other gray values for transition region 61 can all be the same. For example, all virtual pixels 22 'can be provided with the same gray level (for example, a gray level between 0 and 255). In another illustrative arrangement, the values of Z, T1, Tn and / or the other gray values for transition region 61 can be random gray levels, some or all of which are between 0 and 255. The values of gray for screen pixels 22 and virtual pixels 22 'provided above are also illustrative only. The gray levels provided for screen pixels in the active area AA may vary based on the image data frame shown above on screen 14. The adjusted gray levels provided in data lines D for virtual pixels 22 'may vary based on pixel gray levels 22 near the notch 50 and based on the function or other method used to determine the adjusted gray levels. Gray levels for virtual pixels 22 'can be static (for example, they can be predetermined and kept
Petition 870180069135, of 08/09/2018, p. 34/94
25/33 constant between multiple frames of display data) or can be dynamic (for example, switching between frames of display data and determined based on the data provided to pixels 22 in the active area AA, if desired).
[0049] In dispositions in which the gray values for virtual pixels 22 'are predetermined or random gray values (as opposed to being gradually reduced to zero as a function of distance from the margin 51), the gray values can be selected from in order to minimize the impact of these inactive data signals in tracking pixel luminance degradation and limit premature screen fading. For example, the pixel luminance degradation compensator may not take into account (that is, it may be insensitive to) gray levels that are below a threshold value when tracking pixel luminance degradation. In an illustrative example, this threshold value may be a gray level of 50. Adjusting the gray levels for virtual pixels 22 'below this threshold may not affect the tracking of pixel luminance degradation (for example, the tracking of pixel degradation). pixel luminance can be effectively ignored by inactive data signals provided on data lines D that are not actually supplied to pixels 22) while still facilitating the gray level transition at margin 51.
[0050] Although data signal compensation operations are described above in connection with slot 50 in Figure 4, equal or similar data compensation operations can be performed for inactive data signals that are provided for virtual pixels 22 'in corner regions 59.
[0051] A diagram of an illustrative pipeline for displaying an image on screen 14 using gray level compensation of the type described above in connection with Figure 4 is shown in Fi
Petition 870180069135, of 08/09/2018, p. 35/94
26/33 Figure 5. As shown in block 28, the display pipeline can start with an image data frame. In an illustrative example, the image data frame is provided by the control circuitry 16 of device 10. In block 30, sub-pixel rendering can process (for example, using a sub-pixel rendering mechanism) the image data frame to produce data signals corresponding to the specific arrangement of red, green and blue subpixels used on the screen 14. In block 32, a data signal attenuation can be performed. In block 36, tracking and pixel luminance degradation compensation can be performed. In block 38, dithering operations can be performed (for example, using a dithering mechanism) on the data signals. Dithering operations can adjust gray levels so that the average gray level for a group of pixels is equal to the desired gray level for all pixels in the group, even though none of the individual pixels in the group can be programmed with the level. of gray desired. Dithering operations can be used to smooth the visual appearance of the margin between the notch 50 and the active area AA. In block 40, data signals can be provided for screen trigger circuitry 20. In block 42, screen trigger circuitry 20 can trigger data signals on data lines D on screen 14 to display the picture data frame.
[0052] In block 34, data signal compensation operations of the type described above in connection with Figure 4 can be performed. In an illustrative example, data signal compensation operations can be performed before tracking and pixel luminance degradation compensation are performed on block 36 (for example, between blocks 32 and 34). In an arrangement like this, the data signals are adjusted to be
Petition 870180069135, of 08/09/2018, p. 36/94
27/33 low enough not to affect the tracking of pixel luminance degradation or cause premature screen fading, while still facilitating the gray level transition between the active area and the inactive notch.
[0053] In another illustrative arrangement, data signal compensation operations in block 34 may not be performed until after tracking and pixel luminance degradation compensation are performed in block 36. In this type of arrangement, the levels of gray for virtual pixels 22 'are further adjusted to a low value (for example, a gray level between 0 and 10 inclusive) using data signal attenuation operations prior to tracking and luminance degradation compensation pixels are performed on block 36 so that the effects of these inactive data signals on the tracking of pixel luminance degradation are minimized. To make the gray level transition between the active area and the inactive area more gradual, however, inactive data signals can be adjusted again before being triggered on D data lines. In one arrangement, signal compensation operations data in block 40 may include applying an offset to the gray values (for example, adding to the gray value), as reduced by the attenuation of the data signal, and applying a gain to the gray levels, as reduced by the attenuation of data signal (and / or as adjusted by offset). The combination of offset and gain can adjust all inactive data signals for virtual pixels 22 'to an arbitrary gain level (for example, 255) that reduces or eliminates the presence of unwanted screen artifacts, such as dark lines near the notch 50.
[0054] In another illustrative provision, data signal compensation operations in block 34 may include the application of a gain to the gray levels that have been reduced by
Petition 870180069135, of 08/09/2018, p. 37/94
28/33 data signal attenuation without applying an offset. In such an arrangement, the inactive data signals may have been adjusted by the data signal attenuation operations to a value greater than 0 (for example, between 1 and 10). The gain can adjust all inactive data signals for virtual pixels 22 'to an arbitrary gain level (for example, 255) that reduces or eliminates the presence of undesirable screen artifacts, such as dark lines near the notch 50.
[0055] When performed after tracking and pixel luminance degradation compensation operations of block 36, data signal compensation operations can be performed on screen trigger circuitry 20. If desired, signal compensation data can be performed at the same time as other pixel compensation operations that occur on the screen trigger circuitry 20. In another example, data signal compensation operations can be performed between the time when the data signals they are transmitted from the screen driver circuitry 20 in block 36 and when they are displayed on screen 14 in block 38.
[0056] In another example, the screen trigger circuitry 20 can be configured to not provide data signals to data lines D ending under slot 50 when the screen rows being programmed do not include pixels receiving signals of data from these data lines D (ie, rows of the screen to which the notch 50 extends). In other words, the screen driver circuitry 20 may temporarily suspend data line switching when data signals would not actually be delivered to screen pixels 22 (and instead correspond to virtual pixels 22 '). In that arrangement, there would be no data signals being provided for virtual pixels 22 'to affect pixel luminance degradation tracking compensation or to create a
Petition 870180069135, of 08/09/2018, p. 38/94
29/33 sudden gray level transition, helping to minimize both premature fading of the screen and unwanted screen artifacts at margin 51 of active area and inactive area. Due to the fact that the screen driver circuitry 20 suspends the data signal recording operations for a period of time, the operation of the screen 14 in this way can also help to conserve energy.
[0057] A flow chart illustrating the steps that can be taken in a method for adjusting screen signals corresponding to the notch 50 is shown in Figure 6.
[0058] In step 100, the control circuitry 16 can provide a display data frame to be displayed on screen 14.
[0059] In step 102, the data signal attenuator 55 can attenuate (convert to black data) the inactive data signals (for example, data signals corresponding to the virtual pixels 22 ') in the frame to minimize the effect of the signals data in tracking pixel luminance degradation.
[0060] In optional step 104, the data signal compensator 57 can adjust (convert to gray data) the attenuated data signals to facilitate the transition between the data signals that are supplied to the pixels in the active area AA of the screen 14 and inactive data signals for virtual pixels. If optional step 104 is performed, optional step 108 can be omitted and step 106 can proceed directly to step 110.
[0061] In step 106, the data signals can be tracked with the use of pixel degradation and luminance compensation to monitor the aging of pixels on the screen 14.
[0062] In optional step 108, the data signal compensator 57 can adjust the attenuated data signals to facilitate the transition between the data signals that are supplied to the pixels in the active area AA of the screen 14 and the inactive data signals for virtual pixels. If the
Petition 870180069135, of 08/09/2018, p. 39/94
30/33 optional step 108 is performed, optional step 104 can be omitted and step 102 can proceed directly to step 106.
[0063] In step 110, compensated data signals can be transmitted on data lines D without actually being supplied to pixels 22 in the active area of the screen.
[0064] According to one modality, a screen includes pixels that form an active area, an inactive notch in the active area that does not include pixels and a screen trigger circuitry that provides image data to pixels in the active area and that provides data nulls corresponding to the inactive notch. Null data includes black data and gray data.
[0065] According to another modality, the inactive notch includes a transition portion adjacent to the active area, and the gray data provided by the screen trigger circuitry corresponds to the transition portion.
[0066] According to another modality, the inactive notch includes an upper portion, the transition portion is between the active area and the upper portion, and the black data provided by the screen trigger circuitry corresponds to the upper portion.
[0067] According to another modality, the screen trigger circuitry provides the gray data for the transition portion using a plurality of different gray levels.
[0068] According to another modality, the plurality of different levels of gray includes first, second and third levels of gray that decrease linearly.
[0069] According to another modality, the plurality of different levels of gray includes first, second and third levels of gray that decrease exponentially.
[0070] According to another modality, the inactive notch accommodates a speaker, a camera and an ambient light sensor.
Petition 870180069135, of 08/09/2018, p. 40/94
31/33 [0071] According to another modality, pixels comprise organic light-emitting diodes.
[0072] According to one modality, a screen includes rows and columns of pixels that form an active area that is configured to display images. The active area has a notch-shaped recess. The screen additionally includes first lines of data that extend across the rows of pixels and that end at an edge of the active area adjacent to the notch-shaped recess, second lines of data that extend through the active area and end at the shaped recess notch, first port lines that control data loading of the first data lines and second data lines in a first set of pixel rows in the active area, second port lines that control data loading in a second set of the rows of pixels in the active area from the first data lines and not from the second data lines and screen trigger circuitry. The screen trigger circuitry is configured to provide the second data lines with image data while using the first port lines to control data loading, providing the second data lines with the first non-image data while using a first set of second door lines to control data loading, and providing the second data lines with second non-image data that are different from the first non-image data while using a second set of second door lines to control loading of data.
[0073] According to another modality, the first non-image data is black image data and the second non-image data includes gray image data.
[0074] According to another modality, the gray image data includes a plurality of different levels of gray.
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32/33 [0075] According to another modality, the second set of second door lines is interposed between the first set of second door lines and the first door lines.
[0076] According to another embodiment, the second set of second door lines includes a first door line between the first door lines and the first set of second door lines, and the screen trigger circuitry is configured to provide a first gray level for the second data lines while using the first port line to control data loading. The second set of second door lines additionally includes a second door line between the first door line and the first set of second door lines, and the screen trigger circuitry is configured to provide a second level of gray for the second data lines while using the second port line to control data loading. The second set of second door lines additionally includes a third door line between the second door line and the first set of second door lines, and the screen trigger circuitry is configured to provide a third level of gray for the second lines of data while using the third port line to control data loading.
[0077] According to another modality, the gray levels decrease exponentially from the first gray level to the third gray level.
[0078] According to another modality, the gray levels decrease linearly from the first gray level to the third gray level.
[0079] According to another modality, the first non-image data and the second non-image data are not supplied to any of the pixels.
Petition 870180069135, of 08/09/2018, p. 42/94
33/33 [0080] According to one embodiment, a method of operating a screen that has a set of screen driver circuits that provides image data to data lines, a data signal attenuator, a data signal compensator data and pixels that form an active area configured to display image data includes adjusting the image data to black data with the data signal attenuator, adjusting the black data to gray data with the data signal compensator and supply the gray data to the data lines with the screen trigger circuitry. The gray data does not trigger any of the pixels.
[0081] According to another modality, the image data adjusted by the data signal attenuator corresponds to a notch-shaped region in the active area, and the method additionally includes providing at least some of the image data to the pixels that form the active area with the screen trigger circuitry.
[0082] According to another modality, the method additionally includes providing at least some of the black data to the data lines with the screen trigger circuitry. The black data does not trigger any of the pixels.
[0083] According to another modality, the method additionally includes adjusting all black data from the data signal attenuator to gray data with the data signal compensator.
[0084] The above is merely illustrative and modifications can be made to the described modalities. The previously mentioned modalities can be implemented individually or in any combination.

权利要求:
Claims (20)
[1]
1. Screen, characterized by comprising:
pixels that form an active area;
an inactive notch in the active area that does not include pixels; and a screen trigger circuitry that provides image data to the pixels in the active area and that provides null data corresponding to the inactive notch, the null data including black data and gray data.
[2]
Screen according to claim 1, characterized in that the inactive notch includes a transition portion adjacent to the active area, and the gray data provided by the screen trigger circuitry corresponds to the transition portion.
[3]
Screen according to claim 2, characterized in that the inactive notch includes an upper portion, the transition portion is between the active area and the upper portion, and the black data provided by the screen driver circuitry corresponds to the upper portion .
[4]
4. Screen according to claim 3, characterized by the screen trigger circuitry providing the gray data for the transition portion using a plurality of different gray levels.
[5]
5. Screen according to claim 4, characterized by the plurality of different gray levels including first, second and third levels of gray that decrease linearly.
[6]
6. Screen according to claim 4, characterized by the plurality of different gray levels including first, second and third gray levels that decrease exponentially.
[7]
7. Screen according to claim 1, characterized by the inactive notch accommodating a speaker, a camera and an ambient light sensor.
Petition 870180069135, of 08/09/2018, p. 44/94
2/5
[8]
Screen according to claim 7, characterized in that the pixels comprise organic light-emitting diodes.
[9]
9. Screen, characterized by comprising:
rows and columns of pixels that form an active area that is configured to display images, with the active area having a notch in the form of a notch;
first lines of data extending through the rows of pixels and ending at an edge of the active area adjacent to the notch-shaped recess;
second lines of data that extend through the active area and end in the notch-shaped recess;
first port lines that control the data loading of the first data lines and the second data lines in a first set of rows of pixels in the active area;
second port lines that control the loading of data in a second set of rows of pixels in the active area from the first data lines and not from the second data lines; and screen trigger circuitry configured for:
while using the first port lines to control data loading, provide the second data lines with image data;
while using a first set of second port lines to control data loading, supply the second data lines with the first non-image data; and while using a second set of second port lines to control data loading, provide the second data lines with second non-image data that are different from the first non-image data.
[10]
10. Screen according to claim 9, characterized
Petition 870180069135, of 08/09/2018, p. 45/94
3/5 for the first non-image data to be black image data, and for the second non-image data to include gray image data.
[11]
11. Screen according to claim 10, characterized in that the gray image data includes a plurality of different levels of gray.
[12]
Screen according to claim 11, characterized in that the second set of second door lines is interposed between the first set of second door lines and the first door lines.
[13]
13. Screen according to claim 12, characterized by the second set of second door lines including:
a first port line between the first port lines and the first set of second port lines, in that the screen trigger circuitry is configured to provide a first gray level for the second data lines while using the first port line to control data loading;
a second port line between the first port line and the first set of second port lines, the screen trigger circuitry being configured to provide a second gray level for the second data lines while using the second line port to control data loading; and a third port line between the second port line and the first set of second port lines, the screen trigger circuitry being configured to provide a third level of gray for the second data lines while using the third port line to control data loading.
[14]
14. Screen according to claim 13, characterized by the gray levels decreasing exponentially from the first gray level to the third gray level.
Petition 870180069135, of 08/09/2018, p. 46/94
4/5
[15]
15. Screen according to claim 13, characterized by the gray levels decreasing linearly from the first gray level to the third gray level.
[16]
16. Screen according to claim 9, characterized by the first non-image data and the second non-image data not being supplied to any of the pixels.
[17]
17. Method for operating a screen that has a screen trigger circuitry that provides image data to data lines, a data signal attenuator, a data signal compensator and pixels that form an active area configured to display the image data, the method being characterized by understanding:
with the data signal attenuator, adjust the image data to black data;
with the data signal compensator, adjust the black data to gray data; and with the screen trigger circuitry, provide the gray data to the data lines, and the gray data does not trigger any of the pixels.
[18]
18. Method according to claim 17, characterized in that the image data adjusted by the data signal attenuator corresponds to a notch-shaped region in the active area, the method further comprising:
with the screen trigger circuitry, provide at least some of the image data to the pixels that form the active area.
[19]
19. The method of claim 18, further comprising:
with the screen trigger circuitry, provide at least some of the black data to the data lines,
Petition 870180069135, of 08/09/2018, p. 47/94
5/5 black data does not trigger any of the pixels.
[20]
20. Method according to claim 18, characterized in that it further comprises:
with the data signal compensator, adjust all black data from the data signal attenuator to gray data.

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引用文献:

公开号 | 申请日 | 公开日 | 申请人 | 专利标题

US7623140B1|1999-03-05|2009-11-24|Zoran Corporation|Method and apparatus for processing video and graphics data to create a composite output image having independent and separate layers of video and graphics|

US6914602B2|2001-01-19|2005-07-05|Adobe Systems Incorporated|Approximating gradients with offset midpoints|

KR101137885B1|2005-06-15|2012-04-25|엘지디스플레이 주식회사|Liquid Crystal Display Device and Testing Method thereof|

WO2007105700A1|2006-03-15|2007-09-20|Sharp Kabushiki Kaisha|Active matrix substrate and display device using the same|

KR101533666B1|2008-12-01|2015-07-06|삼성디스플레이 주식회사|Liquid crystal display and driving method of the same|

KR101406129B1|2012-03-28|2014-06-13|엘지디스플레이 주식회사|Display apparatus|

US9894781B2|2012-06-06|2018-02-13|Apple Inc.|Notched display layers|

US8933916B1|2012-06-26|2015-01-13|Jeffrey B. Doar|Ambient light sensing for display|

KR102050383B1|2012-12-28|2019-11-29|엘지디스플레이 주식회사|Organic Light Emitting Display Device|

JP6230074B2|2013-03-15|2017-11-15|シャープ株式会社|Active matrix substrate and method of manufacturing active matrix substrate|

KR102305456B1|2014-12-02|2021-09-28|삼성디스플레이 주식회사|Display apparatus and method of driving the same|

KR20160081793A|2014-12-30|2016-07-08|엘지디스플레이 주식회사|Display Device and Driving Method thereof|

CN104835467B|2015-05-21|2017-04-05|京东方科技集团股份有限公司|A kind of driving method and its device, display device|

CA2892714A1|2015-05-27|2016-11-27|Ignis Innovation Inc|Memory bandwidth reduction in compensation system|

CN104934007A|2015-07-06|2015-09-23|合肥京东方光电科技有限公司|Data line driving method and unit, source electrode driver, panel driving apparatus and display apparatus|

JP6929274B2|2015-09-28|2021-09-01|アップルインコーポレイテッドＡｐｐｌｅＩｎｃ．|Electronic device display with extended active area|

US10331260B2|2015-10-30|2019-06-25|Essential Products, Inc.|Variable transparency layers for electronic devices|

CN105487313A|2016-01-04|2016-04-13|京东方科技集团股份有限公司|Array substrate, display panel and display device and driving method thereof|

US10395599B2|2016-02-29|2019-08-27|Samsung Display Co., Ltd.|Display device|

KR20180029181A|2016-09-09|2018-03-20|삼성디스플레이 주식회사|Display device, driving device, and method for driving the display device|

US10185064B2|2016-10-26|2019-01-22|Microsoft Technology Licensing, Llc|Curved edge display with controlled luminance|

CN106843389A|2017-01-09|2017-06-13|广东欧珀移动通信有限公司|Electronic installation|

US10607549B2|2017-09-01|2020-03-31|Apple Inc.|Data signal adjustment for displays|US10607549B2|2017-09-01|2020-03-31|Apple Inc.|Data signal adjustment for displays|

KR20190049979A|2017-10-31|2019-05-10|삼성디스플레이 주식회사|A display device and a method for operating the same|

US10769991B2|2017-11-02|2020-09-08|Samsung Display Co., Ltd.|Display device|

KR20190059345A|2017-11-22|2019-05-31|삼성디스플레이 주식회사|Display device and method of driving the same|

US11120730B2|2017-12-14|2021-09-14|Sitronix Technology Corp.|Compensation circuit for display images and method for determining compensation region of display images|

US10964235B1|2018-06-25|2021-03-30|Apple Inc.|Electronic devices with narrow border displays|

JP2020003694A|2018-06-29|2020-01-09|シナプティクスインコーポレイテッド|Device, method, program, and recording medium for configuring display driver, and display driver|

CN110211537B|2018-08-22|2021-01-22|京东方科技集团股份有限公司|Driving method and driving circuit of display substrate and display device|

CN109119013A|2018-09-07|2019-01-01|武汉天马微电子有限公司|Driving method, display panel and the display device of display panel|

KR20200052036A|2018-11-06|2020-05-14|엘지전자 주식회사|Mobile|

KR20200089385A|2019-01-16|2020-07-27|삼성디스플레이 주식회사|Display apparatus and display system|

CN111477186B|2020-05-07|2021-03-16|Tcl华星光电技术有限公司|Time schedule controller, display panel and driving method thereof|

US11250770B1|2020-09-18|2022-02-15|Himax Technologies Limited|De-jaggy processing system and method for OLED display with curved space|

法律状态:
2019-04-16| B03A| Publication of a patent application or of a certificate of addition of invention [chapter 3.1 patent gazette]|

优先权:

申请号 | 申请日 | 专利标题

US201762553745P| true| 2017-09-01|2017-09-01|

US62/553,745|2017-09-01|

US15/989,066|2018-05-24|

US15/989,066|US10607549B2|2017-09-01|2018-05-24|Data signal adjustment for displays|

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