Synchronous backlight device and operation method thereof
A synchronous backlight device and an operation method thereof are provided. The synchronous backlight device includes a pulse width modulation (PWM) control circuit and a backlight driving circuit. The PWM control circuit receives the video sync information from a video processing circuit and generates a PWM control signal. Wherein, the video sync information defines a plurality of video frame periods, the PWM control circuit at least divides each of the video frame periods into a first period and a second period, the lengths of the first periods of the video frame periods are equal to one another. The frequency of the PWM control signal in the first periods is different from the frequency of the PWM control signal in the second periods. The backlight driving circuit drives the backlight source of a display panel in accordance with the PWM control signal.
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This application is a Reissue Application of U.S. Pat. No. 10,692,443 issued on Jun. 23, 2020. The entirety of the above-mentioned patent is hereby incorporated by reference herein and made a part of this specification.
BACKGROUND Field of the InventionThe invention relates to a display device and more particularly, to a synchronous backlight device and an operation method thereof.
Description of Related ArtThe invention provides a synchronous backlight device and an operation method thereof for improving the issue backlight flicker.
According to an embodiment of the invention, a synchronous backlight device including a pulse width modulation (PWM) control circuit and a backlight driving circuit is provided. The PWM control circuit is configured to receive video sync information from a video processing circuit and generate a PWM control signal. The video sync information defines a plurality of video frame periods, the PWM control circuit at least divides each of the video frame periods into a first period and a second period, and lengths of the first periods of the video frame periods are equal to one another. A frequency of the PWM control signal in the first periods is different from a frequency of the PWM control signal in the second periods. The backlight driving circuit is coupled to the PWM control circuit to receive the PWM control signal. The backlight driving circuit is configured to drive a backlight source of a display panel according to the PWM control signal.
According to an embodiment of the invention, an operation method of a synchronous backlight device is provided. The operation method includes: receiving video sync information from a video processing circuit, wherein the video sync information defines a plurality of video frame periods; at least dividing each of the video frame periods into a first period and a second period by a PWM control circuit, wherein lengths of the first periods of the video frame periods are equal to one another; generating a PWM control signal by the PWM control circuit, wherein a frequency of the PWM control signal in the first periods is different from a frequency of the PWM control signal in the second periods; and driving a backlight source of a display panel by a backlight driving circuit according to the PWM control signal.
Based on the above, in the synchronous backlight device and the operation method thereof according to the embodiments of the invention, each video frame period is at least divided into the first period and the second period. The lengths of the first periods of various video frame periods are equal to one another. If the length of each video frame period is changed, the lengths of the second periods are changed as well. The frequency of the PWM control signal in the first periods is different from the frequency of the PWM control signal in the second periods. With the backlight source providing compensation light in the second periods, the synchronous backlight device and the operation method thereof can achieve improving the issue of backlight flicker.
In order to make the aforementioned and other features and advantages of the invention more comprehensible, several embodiments accompanied with figures are described in detail below.
The accompanying drawings are included to provide a further understanding of the invention, and are incorporated in and constitute a part of this specification. The drawings illustrate embodiments of the invention and, together with the description, serve to explain the principles of the invention.
A term “couple” used in the full text of the disclosure (including the claims) refers to any direct and indirect connections. For instance, if a first device is described to be coupled to a second device, it is interpreted as that the first device is directly coupled to the second device, or the first device is indirectly coupled to the second device through other devices or connection means. Moreover, wherever possible, components/members/steps using the same referral numerals in the drawings and description refer to the same or like parts. Components/members/steps using the same referral numerals or using the same terms in different embodiments may cross-refer related descriptions.
In the embodiment illustrated in
In the embodiment illustrated in
In step S420, the PWM control circuit 341 at least divides each of the video frame periods into a first period and a second period. Based on a design requirement, a first periods includes part or all of a data period of each of the video frame periods, and a second periods includes part or all of a blanking period of each of the video frame periods.
For instance, according to the data enablement signal DE in the video sync information, the video frame period F5 is at least divided into a first period P51 and a second period P52, the video frame period F6 is at least divided into a first period P61 and a second period P62, the video frame period F7 is at least divided into a first period P71 and a second period P72, and the video frame period F8 is at least divided into a first period P81 and a second period P82. Lengths of the first periods P51, P61, P71 and P81 of the video frame periods F5 to F8 are equal to one another. The first period P51 includes a data period of the video frame period F5, and the second period P52 includes a blanking period of the video frame period F5. The first period P61 includes a data period of the video frame period F6, and the second period P62 includes a blanking period of the video frame period F6. The first period P71 includes a data period of the video frame period F7, and the second period P72 includes a blanking period of the video frame period F7. The first period P81 includes a data period of the video frame period F8, and the second period P82 includes a blanking period of the video frame period F8.
In step S430, the PWM control circuit 341 generates the PWM control signal BL3. A frequency of the PWM control signal BL3 in the first periods is different from a frequency of the PWM control signal BL3 in the second periods, but a duty ratio of the PWM control signal BL3 in the first periods is equal to a duty ratio of the PWM control signal BL3 in the second periods. For instance, the frequency of the PWM control signal BL3 in the first period P51 is different from the frequency of the PWM control signal BL3 in the second period P52, but the duty ratio of the PWM control signal BL3 in each duty cycle of the first period P51 is equal to the duty ratio of the PWM control signal BL3 in each duty cycle of the second period P52.
In the embodiment illustrated in
The backlight driving circuit 342 is coupled to the PWM control circuit 341 to receive the PWM control signal BL3. In step S440, the backlight driving circuit 342 drives the backlight source 350 of the display panel 330 according to the PWM control signal BL3, such that the backlight source 350 is driven to provide the backlight 351 to the display panel 330.
Based on the above, the synchronous backlight device 340 and the operation method thereof provided by the present embodiment, each video frame period is at least divided into the first period and the second period. The lengths of the first periods of various video frame periods are equal to one another. If the length of each video frame period is changed, the lengths of the second periods are changed along therewith, but the lengths of the first periods are not. The frequency of the PWM control signal BL3 in the first periods is different from the frequency of the PWM control signal BL3 in the second periods, but the duty ratio of the PWM control signal BL3 in each first period is equal to the duty ratio of the PWM control signal BL3 in each second period. Thus, with the backlight source 350 being driven/controlled to provide compensation light (i.e., the backlight 351) in the second periods, the average backlight brightness in various video frame periods F5 to F8 may tend to be approximately equal to one another. In other words, the synchronous backlight device 340 and the operation method thereof can achieve improving the issue of backlight flicker.
For instance,
Referring to
In the embodiment illustrated in
The second PWM signal generating circuit 630 is coupled to the period defining circuit 610 to receive the second enablement signal 612. The second PWM signal generating circuit 630 may generate the second PWM signal 631 according to the second enablement signal 612 in the second periods. The second PWM signal generating circuit 630 may determine a duty ratio of the second PWM signal 631 in the second periods according to the same duty ratio parameter DR. In the embodiment illustrated in
The superimposing circuit 640 is coupled to the first PWM signal generating circuit 620 to receive the first PWM signal 621. The superimposing circuit 640 is coupled to the second PWM signal generating circuit 630 to receive the second PWM signal 631. The superimposing circuit 640 may superimpose the first PWM signal 621 and the second PWM signal 631 to obtain the PWM control signal BL3, as illustrated in
In the embodiment illustrated in
It should be noted that in different application scenarios, related functions of the synchronous backlight device 340, the PWM control circuit 341 and/or the backlight driving circuit 342 may be implemented in a form of software, firmware or hardware by employing general programming languages (e.g., C or C++), hardware description languages (e.g., Verilog HDL or VHDL) or other suitable programming languages. The programming languages capable of executing the related functions may be deployed in any computer-accessible media, such as magnetic tapes, semiconductor memories, magnetic disks or compact disks (e.g., CD-ROM or DVD-ROM) or may be delivered through the Internet, wired communication, wireless communication or other communication media. The programming languages may be stored in the computer-accessible media for a processor of the computer to access/execute the programming codes of the software (or firmware). In the implementation in the hardware form, one or more controllers, the functions of the embodiments of the invention can be implemented or executed by one or more controllers, microcontrollers, microprocessors, application-specific integrated circuits (ASICs), digital signal processors (DSPs), field programmable gate array (FPGAs) and/or other various logical blocks, modules and circuits in other processing units. In addition, the device and the method of the invention can be implemented through a combination of hardware and software.
In light of the foregoing, the synchronous backlight device and the operation method thereof provided by the embodiments of the invention can control/drive the backlight source synchronously, and therefore, the issue of motion blur can be effectively improved. The synchronous backlight device and the operation method thereof can be applied in the backlight control scenarios where the vertical sync signal is variable, or the vertical sync signal is fixed. In the synchronous backlight device and the operation method thereof, each of the video frame periods can be at least divided into the first period and the second period. The lengths of the first periods of various video frame periods are equal to one another. If the lengths of the video frame periods are changed, the lengths of the second periods are also changed along therewith, but the lengths of the first periods are not. The frequency of the PWM control signal BL3 in the first periods is different from the frequency of the PWM control signal BL3 in the second periods, but the duty ratio of the PWM control signal BL3 in the first periods is equal to the duty ratio of the PWM control signal BL3 in the second periods. Thus, with the backlight source 350 being driven to provide the compensation light (i.e., the backlight 351) in the second periods, the average backlight brightness in various video frame periods can tend to be approximately equal to one another. In other words, the synchronous backlight device and the operation method thereof can achieve improving the issue of backlight flicker.
Although the invention has been described with reference to the above embodiments, it will be apparent to one of the ordinary skill in the art that modifications to the described embodiment may be made without departing from the spirit of the invention. Accordingly, the scope of the invention will be defined by the attached claims not by the above detailed descriptions.
Claims
1. A synchronous backlight device, comprising:
- a pulse width modulation (PWM) control circuit, configured to receive video sync information from a video processing circuit and generate a PWM control signal, wherein the video sync information defines a plurality of video frame periods, and the PWM control circuit at least divides each of the video frame periods into different sub-frame periods including a first period and a second period, wherein lengths of the first periods of at least two of the video frame periods are substantially equal, and lengths of the second periods of the at least two of the video frame periods are different, and the PWM control signal in each of the second periods of the video frame periods has substantially a same frequency; and
- a backlight driving circuit, coupled to the PWM control circuit to receive the PWM control signal, and configured to drive a backlight source of a display panel according to the PWM control signal,
- wherein a flicker effect of the backlight source is reduced by performing a PWM setting operation in each of the sub-frame periods,
- wherein the PWM setting operation represents that a first frequency of the PWM control signal in each of the first periods is different from a second frequency of the PWM control signal in each of the second periods, and a first duty ratio of the PWM control signal in each of the first periods is equal to a second duty ratio of the PWM control signal in each of the second periods.
2. The synchronous backlight device according to claim 1, wherein the video processing circuit comprises a scalar circuit, and the video sync information comprises a vertical sync signal.
3. The synchronous backlight device according to claim 1, wherein the PWM control circuit at least divides each of the video frame periods into the first period and the second period according to the video sync information, the first period comprises part or all of a data period of one of the video frame periods, and the second period comprises part or all of a blanking period of the one of the video frame periods.
4. The synchronous backlight device according to claim 1, wherein the first frequency of the PWM control signal in each of the first periods is less than the second frequency of the PWM control signal in each of the second periods.
5. The synchronous backlight device according to claim 1, wherein the PWM control circuit comprises:
- a period defining circuit, configured to receive the video sync information from the video processing circuit and generate a first enablement signal and a second enablement signal according to a timing of the video sync information, wherein the first enablement signal defines the first periods, and the second enablement signal defines the second periods;
- a first PWM signal generating circuit, coupled to the period defining circuit to receive the first enablement signal, and configured to generate a first PWM signal according to the first enablement signal in the first periods and determine a duty ratio of the first PWM signal in the first periods according to a duty ratio parameter;
- a second PWM signal generating circuit, coupled to the period defining circuit to receive the second enablement signal, and configured to generate a second PWM signal according to the second enablement signal in the second periods and determine a duty ratio of the second PWM signal in the second periods according to the duty ratio parameter, wherein a frequency of the second PWM signal is different from a frequency of the first PWM signal; and
- a superimposing circuit, coupled to the first PWM signal generating circuit to receive the first PWM signal, coupled to the second PWM signal generating circuit to receive the second PWM signal, and configured to superimpose the first PWM signal and the second PWM signal to obtain the PWM control signal.
6. The synchronous backlight device according to claim 5, wherein the first PWM signal generating circuit further determines a phase of the first PWM signal in the first periods according to a delay parameter.
7. The synchronous backlight device according to claim 1, wherein the PWM control circuit comprises:
- a low pass filter, configured to receive the video sync information from the video processing circuit and output a smoothed signal;
- a period defining circuit, coupled to the low pass filter to receive the smoothed signal and generate a first enablement signal and a second enablement signal according to a timing of the smoothed signal, wherein the first enablement signal defines the first periods, and the second enablement signal defines the second periods;
- a first PWM signal generating circuit, coupled to the period defining circuit to receive the first enablement signal, and configured to generate a first PWM signal in the first periods according to the first enablement signal and determine a duty ratio of the first PWM signal in the first periods according to a duty ratio parameter;
- a second PWM signal generating circuit, coupled to the period defining circuit to receive the second enablement signal, and configured to generate a second PWM signal in the second periods according to the second enablement signal and determine a duty ratio of the second PWM signal in the second periods according to the duty ratio parameter, wherein the frequency of the second PWM signal is different from the frequency of the first PWM signal; and
- a superimposing circuit, coupled to the first PWM signal generating circuit to receive the first PWM signal, coupled to the second PWM signal generating circuit to receive the second PWM signal, configured to superimpose the first PWM signal and the second PWM signal to obtain the PWM control signal.
8. An operation method of a synchronous backlight device, comprising:
- receiving video sync information from a video processing circuit, wherein the video sync information defines a plurality of video frame periods;
- at least dividing each of the video frame periods into different sub-frame periods including a first period and a second period by a PWM pulse width modulation (PWM) control circuit, wherein lengths of the first periods of at least two of the video frame periods are substantially equal, and lengths of the second periods of the at least two of the video frame periods are different;
- generating a PWM control signal by the PWM control circuit, wherein the PWM control signal in each of the second periods has substantially a same frequency; and
- driving a backlight source of a display panel by a backlight driving circuit according to the PWM control signal,
- wherein a flicker effect of the backlight source is reduced by performing a PWM setting operation in each of the sub-frame periods,
- wherein the PWM setting operation represents that a first frequency of the PWM control signal in each of the first periods is different from a second frequency of the PWM control signal in each of the second periods, and a first duty ratio of the PWM control signal in each of the first periods is equal to a second duty ratio of the PWM control signal in each of the second periods.
9. The operation method according to claim 8, wherein the video processing circuit comprises a scalar circuit, and the video sync information comprises a vertical sync signal.
10. The operation method according to claim 8, wherein the PWM control circuit at least divides each of the video frame periods into the first period and the second period according to the video sync information, the first period comprises part or all of a data period of one of the video frame periods, and the second period comprises part or all of a blanking period of the one of the video frame periods.
11. The operation method according to claim 8, wherein the first frequency of the PWM control signal in each of the first periods is less than the second frequency of the PWM control signal in each of the second periods.
12. The operation method according to claim 8, wherein the step of generating the PWM control signal comprises:
- generating a first enablement signal and a second enablement signal according to a timing of the video sync information by a period defining circuit, wherein the first enablement signal defines the first periods, and the second enablement signal defines the second periods;
- generating a first PWM signal according to the first enablement signal in the first periods and determining a duty ratio of the first PWM signal in the first periods according to a duty ratio parameter by a first PWM signal generating circuit;
- generating a second PWM signal according to the second enablement signal in the second periods and determining a duty ratio of the second PWM signal in the second periods according to the duty ratio parameter by a second PWM signal generating circuit, wherein a frequency of the second PWM signal is different from a frequency of the first PWM signal; and
- superimposing the first PWM signal and the second PWM signal to obtain the PWM control signal by a superimposing circuit.
13. The operation method according to claim 12, wherein the first PWM signal generating circuit further defines a phase of the first PWM signal in the first periods according to a delay parameter.
14. A synchronous backlight device for a display panel, comprising:
- a pulse width modulation (PWM) control circuit, configured to receive a video sync information and generate a PWM control signal, wherein the PWM control signal is adapted to control a backlight source of the display panel, wherein
- the video sync information defines a plurality of video frame periods comprising a first video frame period and a second video frame period of different period lengths,
- the PWM control circuit divides each of the first video frame period and the second video frame period into different sub-frame periods including a first period and a second period corresponding to the first period, wherein length of the first period of the first video frame period is substantially equal to length of the first period of the second video frame period, and length of the second period of the first video frame period is different from length of the second period of the second video frame period,
- in each of the first periods, the PWM control signal comprises a first active pulse, and
- in each of the second periods, the PWM control signal comprises a plurality of second active pulses having substantially identical pulse width,
- wherein a flicker effect of the backlight source is reduced by setting a pulse width of the first active pulse of the PWM control signal wider than the pulse width of each of the second active pulses of the PWM control signal, and a first duty ratio of the PWM control signal in each of the first periods is equal to a second duty ratio of the PWM control signal in each of the second periods.
15. The synchronous backlight device according to claim 14, wherein a duty ratio of the PWM control signal in each of the first periods is substantially equal to a duty ratio of the PWM control signal in the corresponding second period.
16. The synchronous backlight device according to claim 14, further comprising:
- a backlight driving circuit, coupled to the PWM control circuit to receive the PWM control signal, and configured to drive the backlight source according to the PWM control signal.
17. The synchronous backlight device according to claim 14, wherein the PWM control circuit divides the first video frame period and the second video frame period according to the video sync information.
18. The synchronous backlight device according to claim 14, wherein the video sync information comprises one of a vertical sync signal and a data enablement signal.
19. The synchronous backlight device according to claim 14, wherein a number of the first active pulse of the PWM control signal arranged in each of the first periods is fewer than a number of the second active pulses of the PWM control signal arranged in the corresponding second period.
20. The synchronous backlight device according to claim 14, wherein the PWM control signal has a substantially identical waveform in each of the first periods, and the PWM control signal has a substantially identical frequency in each of the second periods.
21. A synchronous backlight device for a display panel, comprising:
- a pulse width modulation (PWM) control circuit, configured to receive a video sync information and generate a PWM control signal, wherein the PWM control signal is adapted to control a backlight source of the display panel, wherein
- the video sync information defines a plurality of video frame periods comprising a first video frame period and a second video frame period of different period lengths,
- the PWM control circuit divides each of the first video frame period and the second video frame period into at least a first period and a second period corresponding to the first period, wherein length of the first period of the first video frame period is substantially equal to length of the first period of the second video frame period, and length of the second period of the first video frame period is different from length of the second period of the second video frame period, and
- wherein a flicker effect of the backlight source is reduced by setting the PWM control signal to comprise a first active pulse in each of the first periods and a plurality of second active pulses in each of the second periods, wherein a pulse width of the first active pulse is wider than respective pulse width of each of the second active pulses, and a number of the first active pulse arranged in each of the first periods is fewer than a number of the second active pulses arranged in the corresponding second period, and a first duty ratio of the PWM control signal in each of the first periods is equal to a second duty ratio of the PWM control signal in each of the second periods.
22. The synchronous backlight device according to claim 21, wherein pulse widths of the second active pulses are substantially identical to each other.
23. The synchronous backlight device according to claim 21, wherein a single active pulse is arranged in each of the first periods.
24. The synchronous backlight device according to claim 21, wherein the PWM control signal has a substantially identical waveform in each of the first periods, and the PWM control signal has a substantially identical frequency in each of the second periods.
25. The synchronous backlight device according to claim 21, wherein a duty ratio of the PWM control signal in each of the first periods is substantially equal to a duty ratio of the PWM control signal in the corresponding second period.
26. The synchronous backlight device according to claim 21, further comprising:
- a backlight driving circuit, coupled to the PWM control circuit to receive the PWM control signal, and configured to drive the backlight source according to the PWM control signal.
27. The synchronous backlight device according to claim 21, wherein the PWM control circuit divides the first video frame period and the second video frame period according to the video sync information.
28. The synchronous backlight device according to claim 21, wherein the video sync information is one of a vertical sync signal and a data enablement signal.
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Type: Grant
Filed: Jun 7, 2022
Date of Patent: Nov 19, 2024
Assignee: Novatek Microelectronics Corp. (Hsinchu)
Inventors: Chung-Wen Wu (Yilan County), Wen-Chi Lin (Yilan County), Sih-Ting Wang (Kaohsiung)
Primary Examiner: Mark Sager
Application Number: 17/833,906
International Classification: H03K 7/08 (20060101); G02F 1/13357 (20060101); G09G 3/34 (20060101);