The present disclosure relates generally to displays, and more particularly to displays employing light emitting diode based backlights.
This section is intended to introduce the reader to various aspects of art that may be related to various aspects of the present disclosure, which are described and/or claimed below. This discussion is believed to be helpful in providing the reader with background information to facilitate a better understanding of the various aspects of the present disclosure. Accordingly, it should be understood that these statements are to be read in this light, and not as admissions of prior art.
Liquid crystal displays (LCDs) are commonly used as screens or displays for a wide variety of electronic devices, including portable and desktop computers, televisions, and handheld devices, such as cellular telephones, personal data assistants, and media players. Traditionally, LCDs have employed cold cathode fluorescent light (CCFL) light sources as backlights. However, advances in light emitting diode (LED) technology, such as improvements in brightness, energy efficiency, color range, life expectancy, durability, robustness, and continual reductions in cost, have made LED backlights a popular choice for replacing CCFL light sources. However, while a single CCFL can light an entire display; multiple LEDs are typically used to light comparable displays.
Numerous white LEDs may be employed within a backlight. Depending on manufacturing precision, the light produced by the individual white LEDs may have a broad color or chromaticity distribution, for example, ranging from a blue tint to a yellow tint or from a green tint to a purple tint. During manufacturing, the LEDs may be classified into bins with each bin representing a small range of chromaticity values emitted by the LEDs. Within each backlight, LEDs may be selected to produce the target white point. However, due to the range of chromaticity values emitted by LEDs, even by those within the same bin, the white points emitted by different displays may vary. Further, other display components, such as the diffuser plate and thin film transistor layers, can magnify variations in the chromaticity values emitted by the LEDs, and further, can shift the white points emitted by displays. Accordingly, users may perceive variations in the color of different displays. These variations may be particularly noticeable in the displays of handheld devices, such as portable media players and cellular phones, which are frequently exchanged between users or viewed in close proximity to one another.
A summary of certain embodiments disclosed herein is set forth below. It should be understood that these aspects are presented merely to provide the reader with a brief summary of these certain embodiments and that these aspects are not intended to limit the scope of this disclosure. Indeed, this disclosure may encompass a variety of aspects that may not be set forth below.
The present disclosure relates generally to techniques for calibrating displays to produce a target white point. Displays used in similar devices each may be calibrated to the target white point to promote uniformity in the appearance of device displays. In accordance with disclosed embodiments, a display may include an LED backlight that has multiple strings of LEDs, with each string including LEDs from a different bin. Each of the strings may be separately tested at a base current, such as 20 mA, to determine the emitted chromaticity of the string. The emitted chromaticity values for each string may be stored as calibration values within the display, and then subsequently used to determine driving strengths for the LED strings. For example, an LED controller for the backlight may compare the calibration values to the target white point and then determine the driving strength for each string that allows the display to produce the target white point when the light from the strings is mixed.
Further, in certain embodiments, one or more adjustments also may be made to the LCD panel included in the display. For example, in certain embodiments, the driving strength adjustments may not be sufficient to align the emitted white point with the target white point. In these embodiments, hardware and/or software adjustments may be employed in the LCD panel to compensate for the deviation between the emitted white point and the target white point. For example, the pixels may be adjusted, or a color mask may be shaped, to shift the overall chromaticity emitted by the display in the green, blue, and/or red direction. In another example, the voltages provided to certain pixels may be adjusted to shift the overall chromaticity emitted by the display in the green, blue, and/or red direction.
Various aspects of this disclosure may be better understood upon reading the following detailed description and upon reference to the drawings in which:
One or more specific embodiments will be described below. In an effort to provide a concise description of these embodiments, not all features of an actual implementation are described in the specification. It should be appreciated that in the development of any such actual implementation, as in any engineering or design project, numerous implementation-specific decisions must be made to achieve the developers' specific goals, such as compliance with system-related and business-related constraints, which may vary from one implementation to another. Moreover, it should be appreciated that such a development effort might be complex and time consuming, but would nevertheless be a routine undertaking of design, fabrication, and manufacture for those of ordinary skill having the benefit of this disclosure.
The present disclosure is directed to techniques for producing a consistent white point on displays used in different devices. In particular, the present techniques are designed to enable displays on similar devices (e.g., devices of the same model or type) to emit a consistent white point so that the displays appear to have an identical, or substantially identical color and brightness, as observed by a user. According to certain embodiments, the uniform white point may be determined and then set as the target white point for displays used in similar devices.
The displays may each include an LED backlight that illuminates the display using multiple strings of LEDs, with each string including LEDs from a different color bin. Accordingly, each string within an LED backlight may have a different chromaticity. The strings may be selected to have complementary chromaticities, so that when light from the strings is mixed together, a white point that is fairly close to the target white point is emitted. Each of the strings may be separately tested at a base current, such as 20 mA, to determine the emitted chromaticity of the string. Values indicative of the emitted chromaticities may then be stored within the display as calibration values. For example, in certain embodiments, the chromaticity coordinates for each string may be stored as calibration values. The calibration values can then be used during operation of the backlight to determine driving strengths for the LED strings. Each string may be controlled independently by separate driver, or driver channel, which in turn allows each string to be operated at a separate driving strength to fine-tune the white point of the display to the target white point. In particular, control logic within the display may be used to determine the driving strength for each string that aligns the emitted white point with the target white point.
In certain embodiments, the driving strength adjustments may not be sufficient to align the emitted white point with the target white point. In these embodiments, adjustments also may be made to the LCD panel to compensate for the deviation from the target white point so that the overall chromaticity emitted by the display matches a target chromaticity. For example, in certain embodiments, the voltage applied to pixels in the LCD panel may be adjusted to shift the overall chromaticity in the green, blue, and/or red direction. In another example, hardware modifications, such as shaping a color mask or adjusting the number or size of pixels, may be employed to shift the overall chromaticity.
As illustrated in
Further, user input structures 16, 18, 20, and 22 may be manipulated by a user to operate a graphical user interface (GUI) and/or applications running on electronic device 10. Moreover, in certain embodiments, electronic device 10 may include a touch screen, located in front of display 14, that allows the user to interact with electronic device 10. Electronic device 10 also may include input and output (I/O) ports 28 and 30 that allow connection of device 10 to external devices, such as headphones, external speakers, a power source, or other electronic device.
Information received through network device 36 and I/O port 30, as well as information contained in storage 34, may be displayed on display 14. Display 14 may generally include an LED backlight 38 that functions as a light source for an LCD panel 40 within display 14. As noted above, a user may select information to display by manipulating a GUI through user input structures 16, 18, 20, and 22, and a touch screen. In certain embodiments, a user may adjust properties of LED backlight 38, such as the color and/or brightness of the white point, by manipulating a GUI through user input structures 16, 18, 20, and 22 and the touch screen. An input/output (I/O) controller 42 may provide the infrastructure for exchanging data between input structures 16, 18, 20, and 22, I/O ports 28 and 30, display 14, and processor 32.
Backlight 38 includes a light guide 46, such as a light guiding plate, one or more optical films 48, such as one or more brightness enhancement films, and a light source 50 that includes LEDs 52. Light from LEDs 52 is directed through light guide 46 and optical films 48 and generally emitted toward LCD panel 40. As shown in
LEDs 52 may be any type of LEDs designed to emit a white light. In certain embodiments, LEDs 52 may include phosphor based white LEDs, such as single color LEDs coated with a phosphor material, or other wavelength conversion material, to convert monochromatic light to broad-spectrum white light. For example, a blue die may be coated with a yellow phosphor material. In another example, a blue die may be coated with both a red phosphor material and a green phosphor material. The monochromatic light, for example, from the blue die, may excite the phosphor material to produce a complementary colored light that yields a white light upon mixing with the monochromatic light. LEDs 52 also may include multicolored dies packaged together in a single LED device to generate white light. For example, a red die, a green die, and a blue die may be packaged together, and the light outputs may be mixed to produce a white light. Further, LEDs 52 may include ultraviolet (UV) dies with a mix of red, green, blue, or yellow phosphor material.
Additional details of illustrative display 14 may be better understood through reference to
LED backlight 38 includes an LED controller 58 that governs operation of light source 50. In particular, LED controller 58 includes one or more drivers 60 that power and drive strings 62 of LEDs 52 mounted within backlight 38. Each string 62 includes LEDs 52 that emit light of a similar color and/or brightness. Specifically, LEDs 52 may include groups of LEDs selected from different bins defining properties of the LEDs, such as color or chromaticity, flux, and/or forward voltage. LEDs 52 from the same bin may be joined together in one or more strings 62, with each string being independently driven by a separate driver 60 or driver channel. Each display 14 may have a target white point, represented by a set of chromaticity coordinates, tristimulus values, or the like. The same target white point may be used across similar devices, and each device may be calibrated to emit the target white point so that similar devices all emit a uniform white point.
Drivers 60 may include one or more integrated circuits that may be mounted on a printed circuit board and controlled by LED controller 58. In certain embodiments, drivers 60 may include multiple channels for independently driving multiple strings 52 of LEDs with one driver 60. Drivers 60 may include a current source, such as a transistor, that provides current to LEDs 62, for example, to the cathode end of each LED string. Further, the drivers 60 may include components, such as resistors, amplifiers, and field effect transistors, for regulating the current provided to LEDs 62. Drivers 60 also may include voltage regulators. In certain embodiments, the voltage regulators may be switching regulators, such as pulse width modulation (PWM) regulators.
LED controller 58 may set the driving strengths of drivers 60 to certain driving strengths that enable display 14 to emit the target white point. Specifically, LED controller 58 may send control signals to drivers 60 to vary the current and/or the duty cycle to LEDs 52. For example, LED controller 58 may provide forward current reference signals (e.g., in the form of control voltages) to drivers 60 to adjust the amount of current passing through strings 62. In another example, LED control 58 may vary the PWM duty cycle of drivers 60.
LED controller 58 may determine the driving strengths at which to set drivers 60 using information stored in memory 64. For example, LED controller 58 may use calibration values 66 stored in memory 64 in conjunction with calibration logic 68 to determine the driving strength for each driver 60, or driver channel. Calibration values 66 describe chromaticity and/or brightness properties of LED strings 62 that can be used to determine the driving strengths for producing the target white point. For example, according to certain embodiments, calibration values 66 may represent the chromaticities and/or brightness of each LED string 62 included within backlight 38. In another example, calibration values 66 may represent the chromaticity and/or brightness of mixed light emitted by the combination of LED strings 62. In yet another example, calibration values 66 may represent the deviation in each string from the target white point, or the deviation in the mixed light from the LED strings 62 from the target white point.
The calibration values 66 may be determined by independently testing the LED strings 62 prior to, or after, assembly of LED strings 62 within display 14, as discussed further below with respect to
LED controller 58 may then employ the calibration values 66 to determine the appropriate driving strengths for each LED string 62. For example, LED controller 58 may execute calibration logic 64 stored within memory 64 to determine the driving strengths, as discussed further below with respect to
According to certain embodiments, memory 64 may be an EEPROM, flash memory, or other suitable optical, magnetic, or solid-state computer readable media. As shown in
After determining the driving strengths, LED controller 58 may then adjust drivers 60 to operate at the determined driving strengths. According to certain embodiments, LED controller 58 may store the determined driving strengths in memory 64, as base driving strengths that can be employed throughout the operation life of backlight 38. For example, the chromaticity and brightness of the LEDs 52 may shift over time due to aging or changes in temperature. In certain embodiments, LED controller 58 may be designed to compensate for these shifts by adjusting the driving strength of drivers 60. In these embodiments, LED controller 58 may use the base driving strengths as a starting point for future driving strength adjustments.
As described above with respect to
Each bin represents different chromaticities, and LEDs may be selected from different bins so that when light from the LEDs mixes, a chromaticity close to the target white point is produced. The center bin W may encompass chromaticity values corresponding to the target white point, while the surrounding bins N1-17 may encompass chromaticity values which are further from the target white point. According to certain embodiments, LEDs may be selected from the neighboring bins N1-17 on opposite sides of center bin W so that when the light from each of the LEDs 52 is mixed, the emitted light may closely match the target white point. For example, as shown on chart 70, bin W may encompass the target white point. A backlight employing all bin W LEDs may substantially match the target white point. However, manufacturing costs may be reduced if a larger number of bins are used within a backlight. Accordingly, LEDs from neighboring bins N1-17, for example, may be employed within the backlight. The LEDs from the neighboring bins N1-17 may be selectively positioned within the backlight to produce an output close to the target white point. For example, the LEDs from neighboring bins may be staggered or arranged sequentially throughout backlight 38. The LEDs from the same bin may be joined on separate strings, so that the driving strength of LEDs from different bins may be independently adjusted to align the emitted light with the target white point.
In certain embodiments, LEDs from two or more neighboring bins N1-17 may be selected and mixed within an LED backlight. For example, a backlight may employ LEDs from complementary bins N2 and N6; complementary bins N1 and N5; or complementary bins N5, N3, and N8. Moreover, LEDs from the target white point bin W and from the neighboring bins N1-12 may be mixed to yield the desired white point. For example, a backlight may employ LEDs from bins W, N6, and N2. In another example, a backlight may employ multiple strings of LEDs selected from bin W. As may be appreciated, any suitable combination of bins may be employed within a backlight. Further, a wider range of bins than is shown may be employed.
Each string 62A and 62B may be tested separately to determine its chromaticity. For example, string 62A may be driven at a base current, such as 20 mA, while no current is directed to string 62B. Similarly, string 62B may be driven at the base current, while not current is direct to string 62A. Optical sensors, such as phototransistors, photodiodes, or photoresistors, among others, can then be employed to detect the chromaticity of each string 62A and 62B. Further, in certain embodiments, optical sensors may be employed to detect the chromaticity of the mixed light produced by operating both strings 62A and 62B. However, in other embodiments, the chromaticity of the mixed light from strings 62A and 62B, referred to as the “mixed chromaticity,” may be calculated from the individual chromaticities of strings 62A and 62B.
As shown by chart 82, the mixed chromaticity 86 deviates from the target white point 88 by an amount 90. However, as discussed further below with respect to
The measured chromaticity values may then be used to determine (block 98) the calibration values. According to certain embodiments, the calibration values may correspond to the measured chromaticity values. For example, as shown in
The calibration values may then be stored (block 100) within the display. For example, as described above with respect to
LED controller 58 may then determine (block 108) the driving strengths for the LED strings included within the backlight. In particular, LED controller 58 may use the calibration logic 68 to calculate the driving strengths based on the calibration values 66. For example, in embodiments where the calibration values 66 represent the chromaticities of each string of LEDs, LED controller 58 may employ the calibration logic 68 to determine the ratios that should exist between the driving strengths to produce the target white point. According to certain embodiments, LED controller 58 may determine the deviation in the chromaticity for each string of LEDs from the target white point and calculate the driving strength ratios based on the deviations. After determining the ratios, LED controller 58 may scale the driving strengths for each string of LEDs to produce the desired ratios.
In another example, in embodiments where the calibration values 66 represent the mixed chromaticity, LED controller 58 may employ the calibration logic 68 to compare the mixed chromaticity to the target white point and determine the amount of driving strength adjustment that should produce the target white point. In a further example, in embodiments where the calibration values 66 represent the magnitude and direction of deviation in the mixed chromaticity from the target white point, LED controller 58 also may employ the calibration logic to determine the driving strength adjustments that should produce the target white point. LED controller 58 may then apply the driving strength adjustments to the default driving strength settings for each driver 60 to determine the specific driving strengths.
After determining the driving strengths, the LED controller 58 may then set (block 110) the drivers 60 to the determined driving strengths. For example, the LED controller 58 may transmit control signals to the drivers 60 to adjust the amount of forward current applied to the LED strings. In another embodiment, LED controller 58 may transmit control signals to drivers 60 to vary the PWM duty cycle.
Although methods 92 and 102, shown in
Each string 62C, 62D, and 62 is driven by a separate driver 60C, 60D, and 60E, each of which is communicatively coupled to LED controller 58. The backlight may be assembled using method 92 described above with respect to
LED controller 58 may then determine (block 126) the driving strengths for the respective LED strings that will more closely align the mixed chromaticity 114 with the target white point 88. The driving strengths may generally be determined as described above with respect to block 108 of
LED controller 58 may then determine (130) the LCD adjustment required to align the mixed chromaticity with the target white point. For example, LED controller 58 may determine a gamma correction that should be applied to pixels 56 (
LED controller 58 may then set (block 132) the LCD adjustment. For example, LED controller 58 may transmit a control signal to LCD controller 54 (
The specific embodiments described above have been shown by way of example, and it should be understood that these embodiments may be susceptible to various modifications and alternative forms. It should be further understood that the claims are not intended to be limited to the particular forms disclosed, but rather to cover all modifications, equivalents, and alternatives falling within the spirit and scope of this disclosure.
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