The present disclosure relates to the field of display technology, and more particularly to a method for controlling a display device, a control apparatus for a display device, and a display device comprising the control apparatus.
In the prior art, a local backlight adjustment method is often used for the control of a display device such as a liquid crystal display, in order to reduce the power consumption of the display device, enhance the contrast of the displayed image, reduce the image retention, etc. This local backlight adjustment method actually divides the backlight of the display device into multiple backlight sub-regions, and then controls respective backlight sub-regions independently. On this basis, the peak driving technique can be further combined, that is, peak driving is performed for some backlight sub-regions such that these backlight sub-regions reach possible maximum luminance so as to make the details of the displayed image clearer and further enhance the contrast of the displayed image.
The inventors of the present application have found that, after peak driving is performed for some backlight sub-regions of the display device, it is likely to make the sub-display areas of the display panel of the display device to which these backlight sub-regions correspond look too bright, which causes a large visual brightness difference between these sub-display areas and adjacent sub-display areas to which the backlight sub-regions not subjected to peak driving correspond. Particularly during the low gray scale period, the human eyes' perception of a luminance variation is more sensitive, such visual brightness difference may be more significant. In other words, the luminance uniformity of the image displayed by the display device may be decreased, thereby affecting the visual effect of the displayed image.
In view of the above, an embodiment of the present disclosure proposes a method for controlling a display device. The method may comprise steps of: determining whether or not to perform peak driving for respective backlight sub-regions of the display device, the backlight sub-regions corresponding to sub-display areas of the display device; and performing, in response to a result of the above determining step, data signal compensation at least for sub-display areas whose average luminance values are lower than a preset first luminance threshold among the sub-display areas to which the backlight sub-regions that are determined to be subjected to peak driving correspond.
In some embodiments, whether peak driving is performed for backlight sub-regions to which respective sub-display areas of the display device correspond may be determined based on average luminance of the respective sub-display areas or a number of pixels included by the respective sub-display areas whose luminance exceed a preset second luminance threshold.
In some embodiments, the step of determining whether or not to perform peak driving for respective backlight sub-regions of the display device may comprise: counting a number of pixels included in each sub-display area whose luminance exceed the second luminance threshold; calculating an average luminance value of each sub-display area; determining backlight sub-regions to be subjected to peak driving based on a result of the above counting step or calculating step.
In some embodiments, the method may comprise: determining that peak driving is performed for backlight sub-regions to which a first sub-display area, a second sub-display area and a third sub-display area of the display device correspond, the first sub-display area has an average luminance value greater than the preset first luminance threshold and includes N1 pixels whose luminance exceed the second luminance threshold, N1 being greater than a preset number threshold N0; the second sub-display area has an average luminance value greater than the first luminance threshold and includes N2 pixels whose luminance exceed the second luminance threshold, N2 being smaller than the preset number threshold N0; the third sub-display area has an average luminance value smaller than the first luminance threshold and includes N3 pixels whose luminance exceed the second luminance threshold, N3 being greater than the preset number threshold N0.
In some embodiments, the method may comprise: compensating a data signal to the third sub-display area by a first data signal compensation circuit so as to adjust light transmittance of the third sub-display area.
In some embodiments, for a data signal D of the third sub-display area which is smaller than a preset data signal threshold Dt, the data signal D is adjusted to D/K1 by the first data signal compensation circuit; for a data signal D of the third sub-display area which is greater than the data signal threshold Dt, the data signal D is adjusted to
by the first data signal compensation circuit,
where A represents the highest gray scale of a displayed image of the display device; the value K1 is obtained by the following equation:
BL
1
=BL
0
·K
1
γ
where BL1 is a backlight luminance of a backlight sub-region corresponding to the third sub-display area after backlight adjustment, BL0 is a default backlight luminance of a backlight sub-region corresponding to any sub-display area of the display device without backlight adjustment, and γ is a physical parameter of the display device which characterizes a distortion of an output image with respect to an input signal.
In some embodiments, the method may further comprise: performing data signal compensation for sub-display areas of the display device to which backlight sub-regions not subjected to peak driving correspond.
In some embodiments, the sub-display areas to which backlight sub-regions not subjected to peak driving correspond may include a fourth sub-display area, the fourth sub-display area having an average luminance value smaller than the first luminance threshold and including N4 pixels whose luminance exceed the second luminance threshold, N4 being smaller than the preset number threshold N0. The method may further comprise: compensating a data signal to the fourth sub-display area by a second data signal compensation circuit so as to adjust light transmittance of the fourth sub-display area.
In some embodiments, a data signal D of the fourth sub-display area is adjusted to D/K2 by the second data signal compensation circuit, K2 is obtained by the following equation:
BL
2
=BL
0
·K
2
γ
where BL2 is a backlight luminance of a backlight sub-region corresponding to the fourth sub-display area after backlight adjustment, BL0 is a default backlight luminance of a backlight sub-region corresponding to any sub-display area of the display device without backlight adjustment, and γ is a physical parameter of the display device which characterizes a distortion of an output image with respect to an input signal.
In some embodiments, the step of determining whether or not to perform peak driving for respective backlight sub-regions of the display device may further comprise: calculating a power P1 required for peak driving of a backlight sub-region that is determined to be subjected to peak driving; comparing the required power P1 with a power threshold P0; when the required power P1 is smaller than the power threshold P0, peak driving is performed for the backlight sub-region that is determined to be subjected to peak driving, and the power threshold P0 is a power difference between a rated power or a maximum power of the display device and a power required by the display device for displaying a one-frame image.
Another embodiment of the present disclosure provides control apparatus for a display device. The control apparatus may comprise: a peak driving circuit disposed in a backlight module for determining whether or not to perform peak driving for respective backlight sub-regions and performing peak driving for a backlight sub-region that is determined to be subjected to peak driving, the backlight sub-regions corresponding to sub-display areas of the display device; and a data signal compensation circuit disposed in a display panel for performing, based on a determination result of the peak driving circuit, data signal compensation at least for sub-display areas whose average luminance values are lower than a preset first luminance threshold among the sub-display areas to which the backlight sub-regions that are determined to be subjected to peak driving correspond.
In some embodiments, the peak driving circuit may determine whether or not to perform peak driving for backlight sub-regions to which respective sub-display areas of the display device correspond based on average luminance of the respective sub-display areas or a number of pixels included by the respective sub-display areas whose luminance exceed a preset second luminance threshold.
In some embodiments, the peak driving circuit may comprise: a statistics module for counting a number of pixels included in each sub-display area whose luminance exceed the second luminance threshold; an average luminance value calculation module for calculating an average luminance value of each sub-display area; a determination module for determining backlight sub-regions to be subjected to peak driving based on a result of the statistics module or the average luminance value calculation module.
In some embodiments, the determination module may determine that peak driving is performed for backlight sub-regions to which a first sub-display area, a second sub-display area and a third sub-display area of the display device correspond, the first sub-display area has an average luminance value greater than the preset first luminance threshold and includes N1 pixels whose luminance exceed the second luminance threshold, N1 being greater than a preset number threshold N0; the second sub-display area has an average luminance value greater than the first luminance threshold and includes N2 pixels whose luminance exceed the second luminance threshold, N2 being smaller than the preset number threshold N0; the third sub-display area has an average luminance value smaller than the first luminance threshold and includes N3 pixels whose luminance exceed the second luminance threshold, N3 being greater than the preset number threshold N0.
In some embodiments, the data signal compensation circuit may comprise: a first data signal compensation circuit for compensating a data signal to the third sub-display area so as to adjust light transmittance of the third sub-display area.
In some embodiments, for a data signal D of the third sub-display area which is smaller than a preset data signal threshold Dt, the first data signal compensation circuit adjusts the data signal D to D/K1; for a data signal D of the third sub-display area which is greater than the data signal threshold Dt, the first data signal compensation circuit adjusts the data signal D to
A represents the highest gray scale of a displayed image of the display device; the value K1 is obtained by the following equation:
BL
1
=BL
0
·K
1
γ
BL1 is a backlight luminance of a backlight sub-region corresponding to the third sub-display area after backlight adjustment, BL0 is a default backlight luminance of a backlight sub-region corresponding to any sub-display area of the display device without backlight adjustment, and γ is a physical parameter of the display device which characterizes a distortion of an output image with respect to an input signal.
In some embodiments, the data signal compensation circuit may further perform data signal compensation for sub-display areas of the display device to which backlight sub-regions not subjected to peak driving correspond.
In some embodiments, the sub-display areas to which backlight sub-regions not subjected to peak driving correspond may include a fourth sub-display area, the fourth sub-display area has an average luminance value smaller than the first luminance threshold and includes N4 pixels whose luminance exceed the second luminance threshold, N4 being smaller than the preset number threshold N0, the data signal compensation circuit comprises a second data signal compensation circuit for compensating a data signal to the fourth sub-display area so as to adjust light transmittance of the fourth sub-display area.
In some embodiments, the second data signal compensation circuit may adjust the data signal D of the fourth sub-display area to D/K2, K2 is obtained by the following equation:
BL
2
=BL
0
·K
2
γ
BL2 is a backlight luminance of a backlight sub-region corresponding to the fourth sub-display area after backlight adjustment, BL0 is a default backlight luminance of a backlight sub-region corresponding to any sub-display area of the display device without backlight adjustment, and γ is a physical parameter of the display device which characterizes a distortion of an output image with respect to an input signal.
In some embodiments, the peak driving circuit may further comprise: a power calculation module for calculating a power P1 required for peak driving of a backlight sub-region that is determined to be subjected to peak driving; a comparison module for comparing the required power P1 with a power threshold P0. When the required power P1 is smaller than the power threshold P0, the peak driving circuit performs peak driving for the backlight sub-region that is determined to be subjected to peak driving, and the power threshold P0 is a power difference between a rated power or a maximum power of the display device and a power required by the display device for displaying a one-frame image.
A further embodiment of the present disclosure provides a display device that may comprise the control apparatus described in any one of the preceding embodiments regarding the control apparatus.
Embodiments of the present disclosure will be described in more detail below by way of non-limiting example with reference to the accompanying drawings so as to provide a thorough understanding of the principles and spirit of the present disclosure.
Hereinafter, specific embodiments of the present disclosure will be described in detail by way of examples. It is to be understood that the embodiments of the present invention are not limited to the examples set forth below, and modifications and variations can be made by those skilled in the art to the described embodiments under the principles or spirit revealed by the present disclosure, so as to obtain other different embodiments. Apparently, these embodiments all fall within the scope of the present invention.
In addition, it is to be noted that the drawings referred to herein are for the purpose of illustrating and explaining the embodiments of the present disclosure, each module or circuit embodied in the drawings is not necessarily an actual circuit configuration, and the connections between different modules or circuits are merely used for illustrating the embodiments of the present disclosure, which are not to be construed as limiting the scope of the present invention.
Examples of the display device mentioned herein include, but are not limited to, a liquid crystal display. Referring to
The inventors of the present application recognize that the visual brightness of a sub-display area SA depends mainly on the light transmittance of the sub-display area SA and the luminance of the backlight sub-region SB corresponding to the sub-display area SA. Meanwhile, the light transmittance of the sub-display area SA is in turn dependent on the deflection angle of the light valve such as a liquid crystal molecule influenced by an applied electric field, which is directly related to the data signal supplied to the sub-display area. Therefore, the visual brightness of the sub-display area can be changed by adjusting the data signal for the sub-display area. After peak driving is performed for the backlight sub-regions to which some sub-display areas of the display device correspond, it is likely to make the originally dark sub-display areas (e.g., sub-display areas having an average luminance value lower than the preset first luminance threshold) look too bright, which causes a large brightness difference between these sub-display areas and the sub-display areas to which the backlight sub-regions not subjected to peak driving correspond, and may reduce the luminance uniformity of the overall displayed image of the display device. However, with the method provided by the present embodiment, since data signal compensation can be performed at least for sub-display areas whose average luminance values are lower than the preset first luminance threshold among the sub-display areas to which the backlight sub-regions determined to be subjected to peak driving correspond, the data signals supplied to the corresponding sub-display areas can be adjusted so as to adjust the light transmittances of these sub-display areas, such that it becomes possible to reduce the luminance difference between different sub-display areas. Therefore, the method for controlling the display device provided by the embodiment of the present disclosure can not only achieve the advantages and effects of applying the local backlight adjustment and the peak driving technique, but also improve the uniformity of the overall luminance of the displayed image of the display device.
In some embodiments, the current luminance levels of respective sub-display areas may be taken into account upon determining whether or not to perform peak driving for respective backlight sub-regions of the display device. For example, it is possible to determine whether or not to perform peak driving for backlight sub-regions to which respective sub-display areas of the display device correspond based on average luminance of the respective sub-display areas or the number of pixels included by the respective sub-display areas whose luminance exceed a preset second luminance threshold. In this case, a pixel whose luminance exceeds the preset second luminance threshold may be referred to as a pixel that meets the peak driving conditions. For example, the maximum luminance value of a certain pixel is 255. If the current luminance value thereof is greater than 200, the pixel can be considered as a pixel that meets the peak driving conditions. For example, if a certain sub-display area has a relatively high average luminance level or includes a large number of pixels that meet the peak driving conditions, it may be considered that such a sub-display area can be raised to a higher luminance level, or it is reasonable to select the backlight sub-region to which such a sub-display area corresponds for peak driving, because the current overall luminance level of such a sub-display area is closer to the desired maximum luminance than the other sub-display areas.
In some embodiments, as shown in
In some embodiments, the method for controlling the display device may comprise determining that peak driving is performed for backlight sub-regions to which a first sub-display area, a second sub-display area and a third sub-display area of the display device correspond, the first sub-display area has an average luminance value greater than the preset first luminance threshold and includes N1 pixels whose luminance exceed the second luminance threshold, N1 being greater than a preset number threshold N0; the second sub-display area has an average luminance value greater than the first luminance threshold and includes N2 pixels whose luminance exceed the second luminance threshold, N2 being smaller than the preset number threshold N0; the third sub-display area has an average luminance value smaller than the first luminance threshold and includes N3 pixels whose luminance exceed the second luminance threshold, N3 being greater than the preset number threshold N0. That is, in this embodiment, the sub-display area whose average luminance value is greater than the preset first luminance threshold or the sub-display area in which the number of pixels whose luminance exceed the second luminance threshold is larger than the number threshold N0 is determined as a sub-display area whose corresponding backlight sub-region is to be subjected to peak driving. As described above, it is reasonable to select the backlight sub-region to which such a sub-display area corresponds for peak driving because the current overall luminance level of such a sub-display area is closer to the desired maximum luminance.
In some embodiments, the method for controlling the display device may comprise compensating the data signal for the third sub-display area by a first data signal compensation circuit so as to adjust the light transmittance of the third sub-display area.
In some embodiments, for a data signal D for the third sub-display area which is smaller than a preset data signal threshold Dt, the data signal D is adjusted to D/K1 by the first data signal compensation circuit. For a data signal D for the third sub-display area which is greater than the data signal threshold Dt, the data signal D is adjusted to
by the first data signal compensation circuit, where A represents the highest gray scale of a displayed image of the display device, the value K1 is obtained by the following equation:
BL
1
=BL
0
·K
1
γ
where BL1 is a backlight luminance of a backlight sub-region corresponding to the third sub-display area after backlight adjustment, BL0 is a default backlight luminance of a backlight sub-region corresponding to any sub-display area of the display device without backlight adjustment, and γ is a physical parameter of the display device which characterizes a distortion of an output image with respect to an input signal. γ may vary depending on the types or models of different display devices, for example, γ may be equal to 2.2, 2.5, and so on. It is to be understood that the phrase “backlight adjustment” as mentioned herein refers to employing dimming methods to perform luminance adjustment for the backlight sub-regions to which relevant sub-display areas (e.g. the third sub-display area and the fourth sub-display area mentioned below) correspond. The dimming methods include local backlight adjustment and peak driving as mentioned herein.
The data signal Dnew for the third sub-display area of the display device which has been adjusted by the first data signal compensation circuit can be represented by the following formula:
The data signal threshold Dt may be a preset value much smaller than the maximum data signal value. In the case of performing peak driving for the backlight sub-region to which the third sub-display area corresponds, when the data signal D for the third sub-display area is smaller than the data signal threshold Dt, i.e. during the low gray scale period, the adjusted data signal Dnew (i.e. D/K1) can be reduced compared to the original data signal D. Therefore, at that time, the light transmittance of the third sub-display area can be reduced to some extent, so that the visual brightness of the third sub-display area during the low gray scale period may maintain or be close to the original luminance level thereof, thereby improving the luminance uniformity between the third sub-display area and the sub-display area to which the backlight sub-region not subjected to peak driving corresponds during the low gray scale period. In addition, when the data signal D is greater than the data signal threshold Dt, i.e. during the high gray scale period, since the sensitivity of the human eyes to a perceived luminance variation is not as good as that during the low gray scale period, the adjusted data signal Dnew at that time may be larger than the adjusted data signal (i.e. D/K1) during the low gray scale period, or even larger than the original data signal D, so that the third sub-display area exhibits a high luminance to achieve the advantages and effects by peak driving.
For example,
According to another embodiment of the present disclosure, data signal compensation can be further performed for the sub-display areas to which backlight sub-regions not subjected to peak driving correspond. That is, this embodiment of the present disclosure can further reduce the difference in luminance between the sub-display areas to which the backlight sub-regions not subjected to peak driving correspond and the sub-display areas to which the backlight sub-regions that have been subjected to peak driving correspond. Consequently, this embodiment can further improve the uniformity of the overall luminance of the displayed image of the display device and improve the visual effect of the displayed image.
In some embodiments, the sub-display areas to which the backlight sub-regions not subjected to peak driving correspond may include a fourth sub-display area. The fourth sub-display area has an average luminance value smaller than the first luminance threshold and includes N4 pixels whose luminance exceeds the second luminance threshold, N4 being smaller than the preset number threshold N0. The method further comprises compensating the data signal for the fourth sub-display area by a second data signal compensation circuit so as to adjust the light transmittance of the fourth sub-display area.
In some embodiments, the data signal D for the fourth sub-display area may be adjusted to D/K2 by the second data signal compensation circuit, where K2 is obtained by the following equation:
BL
2
=BL
0
·K
2
γ
BL2 is a backlight luminance of a backlight sub-region corresponding to the fourth sub-display area after backlight adjustment, BL0 is a default backlight luminance of a backlight sub-region corresponding to any sub-display area of the display device without backlight adjustment, and γ is a physical parameter of the display device which characterizes a distortion of an output image with respect to an input signal.
Referring to
Another embodiment of the present disclosure provides a control apparatus for a display device. Referring to
As shown in
In some embodiments, the peak driving circuit 10 may take into account the current luminance levels of respective sub-display areas upon determining whether or not to perform peak driving for respective backlight sub-regions of the display device. For example, the peak driving circuit 10 may determine whether or not to perform peak driving for the backlight sub-regions to which respective sub-display areas correspond based on the average luminance of the respective sub-display areas SAs or the number of pixels included by the respective sub-display areas SAs whose luminance exceed the preset second luminance threshold.
In some embodiments, the determination module may determine that peak driving is performed for backlight sub-regions to which a first sub-display area, a second sub-display area and a third sub-display area of the display device correspond. The first sub-display area has an average luminance value greater than the preset first luminance threshold and includes N1 pixels whose luminance exceed the second luminance threshold, N1 being greater than a preset number threshold N0. The second sub-display area has an average luminance value greater than the first luminance threshold and includes N2 pixels whose luminance exceed the second luminance threshold, N2 being smaller than the preset number threshold N0. The third sub-display area has an average luminance value smaller than the first luminance threshold and includes N3 pixels whose luminance exceeds the second luminance threshold, N3 being greater than the preset number threshold N0. It is to be understood that the second luminance threshold may be numerically equal to or may not be equal to the first luminance threshold. It is reasonable to select the backlight sub-region to which the sub-display area having a higher current average luminance or including a large number of pixels having high luminance corresponds for peak driving, because the current overall luminance level of such sub-display areas is closer to the desired maximum luminance.
In an embodiment of the present disclosure, as shown in
In an embodiment, for a data signal D to the third sub-display area which is smaller than a preset data signal threshold Dt, the first data signal compensation circuit 110 adjusts the data signal D to D/K1. For a data signal D to the third sub-display area which is greater than the data signal threshold Dt, the first data signal compensation circuit 110 adjusts the data signal D to
where A represents the highest gray scale of a displayed image of the display device, for example, A may be equal to 255, the value K1 is obtained by the following equation:
BL
1
=BL
0
·K
1
γ
where BL1 is a backlight luminance of a backlight sub-region corresponding to the third sub-display area after backlight adjustment, BL0 is a default backlight luminance of a backlight sub-region corresponding to any sub-display area of the display device without backlight adjustment, and γ is a physical parameter of the display device which characterizes a distortion of an output image with respect to an input signal. γ may vary depending on the types or models of different display devices, for example, γ may be equal to 2.2, 2.5, and so on.
That is, the data signal Dnew for the third sub-display area of the display device which has been adjusted by the first data signal compensation circuit can be represented by the following formula:
As discussed above, in the case of performing peak driving for he backlight sub-region to which the third sub-display area corresponds, by adjusting the data signal to the third sub-display area in this way, the luminance uniformity between the third sub-display area and the sub-display area to which the backlight sub-region not subjected to peak driving corresponds can be improved during the low gray scale period. In addition, during the high gray scale period, the third sub-display area can exhibit a high luminance to achieve the advantages of peak driving.
In some embodiments, the data signal compensation circuit 11 may also perform data signal compensation for the sub-display areas to which the backlight sub-regions not subjected to peak driving correspond. As a result, the uniformity of the overall luminance of the displayed image of the display device can be further improved from another aspect, improving the visual effect of the displayed image. For example, according to an embodiment of the present disclosure, the sub-display areas to which backlight sub-regions not subjected to peak driving correspond include a fourth sub-display area. The fourth sub-display area has an average luminance value smaller than the first luminance threshold and includes N4 pixels whose luminance exceed the second luminance threshold, N4 being smaller than the preset number threshold N0. In this embodiment, the data signal compensation circuit 11 may compensate the data signal to the fourth sub-display area based on the determination result of the peak driving circuit 10. While for the first sub-display area and the second sub-display area having an average luminance value greater than the first luminance threshold, the two types of sub-display areas can be considered as relatively bright sub-display areas, so peak driving may be performed without data signal compensation. In this way, the overall luminance thereof can be further enhanced while the definition of the details of these sub-display areas can be further improved. Of course, in other embodiments, it is also possible to perform data signal compensation for the first sub-display area and the second sub-display area, which is more advantageous to the uniformity of the overall luminance of the displayed image of the display device. Therefore, in some embodiments of the present disclosure, as shown in
Although the circuit that performs data signal compensation for the third sub-display area and the circuit that performs data signal compensation for the fourth sub-display area are implemented independently as the first data signal compensation circuit 110 and second data signal compensation circuit 111 in the embodiment shown in
In some embodiments, the second data signal compensation circuit 111 may adjust the data signal D for the fourth sub-display area to D/K2, where K2 is obtained by the following equation:
BL
2
=BL
0
·K
2
γ
where BL2 is a backlight luminance of a backlight sub-region corresponding to the fourth sub-display area after backlight adjustment, BL0 is a default backlight luminance of a backlight sub-region corresponding to any sub-display area of the display device without backlight adjustment, and γ is a physical parameter of the display device which characterizes a distortion of an output image with respect to an input signal.
A further embodiment of the present disclosure further provides a display device that may comprise the control apparatus as described in any one of the preceding embodiments regarding the control apparatus. It is to be understood that such a display device may be any device that can be subjected to backlight adjustment and has display function, including, but not limited to, a liquid crystal display, a television, a mobile phone, a tablet computer, a player, a navigator, and the like.
The control apparatus for the display device as described in the embodiments of the present disclosure may be implemented in various hardware forms. For example, the function of the control apparatus can be realized by programming a field programmable gate array (FPGA) chip. Alternatively, it can also be realized using a programmable microprocessor or integrated circuit chip in combination with a peripheral circuit. Specific steps of the method for controlling the display device as described in the preceding embodiments of the present disclosure can be carried out by programming using various computer languages. In addition, the control apparatus for the display device and the method for controlling the display device as described in the preceding embodiments can also be realized by software programming in combination with hardware circuits.
While the embodiments of the present disclosure have been described in detail with reference to the accompanying drawings, it is to be noted that the above-described embodiments are intended to illustrate and not limit the present invention, and those skilled in the art will be able to design many alternative embodiments without departing from the scope of the appended claims. In the claims, the word “comprising” does not exclude other elements or steps than those enumerated in the claims, and the indefinite article “a” or “an” does not exclude a plurality. The mere fact that certain measures are recited in mutually different dependent claims does not indicate that a combination of these measures cannot be used to advantage.
Number | Date | Country | Kind |
---|---|---|---|
201610359385.X | May 2016 | CN | national |
The present application is the U.S. national phase entry of PCT/CN2017/070260, with an international filling date of Jan. 5, 2017, which claims the benefit of Chinese Patent Application NO. 201610359385.X, filed on May 30, 2016, the entire disclosure of which is incorporated herein by reference.
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/CN2017/070260 | 1/5/2017 | WO | 00 |