HEAD MOUNTED DISPLAY AND CONTROL METHOD THEREOF

A head mounted display and control method thereof are provided. The head mounted display includes a light transmittance controller, a light detector, a display and a controller. The light transmittance controller controls a transmittance amount of ambient light according to a control signal. The light detector detects an ambient luminance. The display generates a display image according to a driving signal. The controller generates a selected transmittance and a luminance of maximum gray value according to a setting value, the ambient luminance and a luminance of minimum gray value. The controller generates the control signal according to the selected transmittance, and generates the driving signal according to display data and the luminance of maximum gray value.

FIELD OF THE INVENTION

The invention relates to a head mounted display and a control method thereof and more particularly, to a head mounted display capable of adjusting a transparency of a display image and a control method thereof.

DESCRIPTION OF RELATED ART

With the advancement of electronic technology, display devices have become important tools in people's daily lives. As requirements for visual quality have risen day by day recently, a head mounted display capable of presenting augmented reality (AR) images has become a mainstream display device.

In actual use, in an AR display, a transparency of a presented display image varies as an ambient luminance varies with the use in different scenarios. In a situation that the ambient luminance is high, the transparency of the display image presented by the AR display is increased, such that a user cannot view the display image clearly. Such phenomenon can be improved through increasing a luminance of the display image. However, in case the luminance of the display image is regardless increased, it may cause a background to be covered by the display image, which may affect the safety if the user while walking.

SUMMARY

The invention provides a head mounted display and a control method thereof capable of adjusting a transparency of a display image, so as to effectively enhance the safety and display performance of the head mounted display in different environments.

A head mounted display of the invention includes a light transmittance controller, a light detector, a display and a controller. The light transmittance controller controls a transmittance amount of ambient light according to a control signal. The light detector detects an ambient luminance of the ambient light. The display generates a display image according to a driving signal. The controller generates a selected transmittance and a maximum gray luminance value according to a setting value, the ambient luminance and the minimum gray luminance value. The controller generates the control signal according to the selected transmittance and generates the driving signal according to display data and the maximum gray luminance value.

A control method of a head mounted display of the invention includes: detecting an ambient luminance of ambient light; generating a selected transmittance and a maximum gray luminance value according to a setting value, the ambient luminance and the minimum gray luminance value, generating a control signal according to the selected transmittance and generating a driving signal according to display data and the maximum gray luminance value; generating a display image according to the driving signal; and controlling a transmittance amount of the ambient light according to the control signal.

To sum up, the head mounted display of the invention can adjust the transmittance of a generated augmented reality (AR) display image according to the ambient luminance. In this way, the luminance and the transmittance of the display image generated by the head mounted display can be adjusted according to the actual ambient luminance, thereby enhancing the display performance in a premise that both the display quality and the safety can be kept.

DESCRIPTION OF EMBODIMENTS

Referring toFIG. 1,FIG. 1is a schematic diagram illustrating a head mounted display according to an embodiment of the invention. A head mounted display100includes a light transmittance controller110, a display120, a controller130and a light detector140. The light transmittance controller110is coupled to the controller130. The light transmittance controller110controls a transmittance amount of ambient light according to a control signal CTR. The light transmittance controller110controls the transmittance amount of the ambient light which is transmitted to the internal of the head mounted display. In the present embodiment, the light transmittance controller110may be an electrochromic display (ECD).

The display120is coupled to the controller130and configured to generate a display image according to a driving signal DRY. The display image generated by the display120may be an augmented reality (AR) image, and the display120may adjust a luminance of the display image according to the driving signal DRY. The light detector140is coupled to the controller130. The light detector140is configured to detect an ambient luminance AMBL of the ambient light and send information related to the detected ambient luminance AMBL to the controller130. The controller130generates a selected transmittance and a maximum gray luminance value according to a setting value, the ambient luminance AMBL and a minimum gray luminance value. The controller130also generates a control signal CTR according to the selected transmittance and generates the driving signal DRV according to display data DSPDATA and the maximum gray luminance value.

In addition, the setting value is used to set a transmittance state of the display image generated by the display120and may be input from the external of the controller130. In the embodiments of the invention, the setting value may be input by a user. Additionally, in the embodiments of the invention, the setting value CR may be equal to

wherein W255 represents the maximum gray luminance value, B0 represents the minimum gray luminance value, ECDTr represents the selected transmittance, and the ALIT represents the ambient luminance.

According to the description set forth above, after completing the setting of the setting value CR, the controller130may obtain the maximum gray luminance value (=W255) and the selected transmittance (=ECDTr) according to the given minimum gray luminance value (=B0) and the detected ambient luminance (=ALIT). The controller130may also generate the control signal CTR according to the selected transmittance, thereby adjusting the light transmittance controller110according to the selected transmittance and controlling the light transmittance controller110to adjust the transmittance amount of the ambient light.

Furthermore, the controller130may set the maximum gray luminance value according to the ambient luminance AMBL and the setting value CR and then calculate the selected transmittance (=ECDTr) according to the relational formula between the setting value CR and the maximum gray luminance value (=W255), the minimum gray luminance value (=B0), the selected transmittance (=ECDTr) and the ambient luminance AMBL.

On the other hand, a relationship among the setting value CR, the ambient luminance AMBL, the minimum gray luminance value (=B0), the selected transmittance (=ECDTr) and the maximum gray luminance value (=W255) may be established in a look-up table. For example, the look-up table may be as shown in Table 1:

The corresponding minimum gray luminance value in Table 1, for example, is equal to 0.3 nit. According to a degree of the ambient luminance AMBL, environments may be divided into three types, which are dark, indoor and outdoor. According to the setting value CR, different maximum gray luminance values (W255) may be set. In the present embodiment, the setting value CR is used to correspondingly set an image transparency of the display image, wherein the setting value CR is negatively correlated to the image transparency. According to the detected ambient luminance AMBL, the maximum gray luminance value (W255) may be calculated according to the selected transmittance (ECDTr) obtained according to the look-up table.

It should be noted that Table 1 does not record all possible setting values CR. When the setting value CR is not recorded in Table 1, the controller130may calculate by means of an interpolation or an extrapolation method and obtain the corresponding maximum gray luminance value (W255) and the selected transmittance (ECDTr).

It is to be additionally mentioned that the look-up table may be configured in any storage device in the controller130or may be stored in a storage device in any form outside the controller130, which is not particularly limited.

Hereinafter, referring toFIG. 2,FIG. 2is a schematic diagram illustrating the operation of a head mounted display device according to an embodiment of the invention. A head mounted display device200has a light transmittance controller210and a display220. The light transmittance controller210and the display220are sequentially disposed in front of a target area TG. The light transmittance controller210is configured to control a transmittance amount of ambient light ENV which is transmitted to the target area TG, and the display220projects a display image DIMG to the target area TG, wherein the target area TG may be a position of a user's eye.

In the present embodiment, through detecting an ambient luminance, the head mounted display device200may synchronously adjust the transmittance amount of the ambient light ENV which is transmitted to the target area TG and adjust a luminance of the display image DIMG generated by the display220. The display quality may be enhanced in a condition that the safety is kept.

Hereinafter, referring toFIG. 3,FIG. 3is a schematic diagram illustrating a head mounted display according to another embodiment of the invention. A head mounted display300includes light transmittance controllers310-1and310-2, displays320-1and320-2, a controller330, a light detector340, a look-up table350and a setting value receiving interface360. In the present embodiment, the light transmittance controller310-1and the display320-1may correspond to a first eye of a user, and the light transmittance controller310-2and the display320-2may correspond to a second eye of the user. The controller330is simultaneously coupled to the light transmittance controllers310-1and310-2and the displays320-1and320-2. The light detector340is configured to detect an ambient luminance of ambient light and provide information related to the ambient luminance to the controller330. The setting value receiving interface360is coupled to the controller330and configured to receive a setting value input by the user. The controller330may perform a look-up operation in the look-up table350according to the ambient luminance and the setting value, or alternatively, further calculate a selected transmittance and a maximum gray luminance value by means of an interpolation or an extrapolation operation.

The setting value receiving interface360may be a graphical interface. In the present embodiment, the setting value receiving interface360provides a movable cursor SB. The user may, for example, adjust a position of the cursor SB through a touch medium, thereby providing a corresponding setting value to the controller330. The cursor SB of the present embodiment may move at a transmittance ranging from 0 to 100, and when intending to increase the transmittance of the display image, the user may move the cursor SB from a position P01 to a position P02. By contrast, when intending to decrease the transmittance of the display image, the user may move the cursor SB from the position P02 to the position P01. The setting value receiving interface360may generate the setting value according to a position where the cursor SB is located and provide the setting value to the controller330.

It is to be additionally mentioned that in the present embodiment, the display320-1includes a display panel321-1, a back-light panel322-1and a timing controller323-1. The display panel321-1and the back-light panel322-1are disposed by overlapping with each other, and the timing controller323-1is coupled to the display panel321-1and the back-light panel322-1. The timing controller323-1operates and controls the display panel321-1and the back-light panel322-1to perform the operation of displaying the display image. On the other hand, the display320-2includes a display panel321-2, a back-light panel322-2and a timing controller323-2. The display panel321-2and the back-light panel322-2are disposed by overlapping with each other, and the timing controller323-2is coupled to the display panel321-2and the back-light panel322-2. The timing controller323-2operates and controls the display panel321-2and the back-light panel322-2to perform the operation of displaying the display image. The displays320-1and320-2as described above may be displays well-known to persons with ordinary skills in the art, and related operation details thereof are also well-known to the persons with ordinary skills in the art and will not be repeatedly described.

Hereinafter, referring toFIG. 4AandFIG. 4B, whereinFIG. 4Ais a graph illustrating a relationship between the ambient luminance and the selected transmittance according to the embodiments of the invention, andFIG. 4Bis a graph illustrating a relationship between the ambient luminance and the maximum gray luminance value according to the embodiments of the invention. According to the illustration ofFIG. 4A, the ambient luminance and the selected transmittance used for controlling the light transmittance controller are negatively correlated to each other. When the ambient luminance is increased, the selected transmittance of the light transmittance controller is correspondingly decreased. According toFIG. 4B, the ambient luminance and the set maximum gray luminance value are positively correlated to each other. Namely, when the ambient luminance is increased, the maximum gray luminance value is correspondingly increased.

Hereinafter, referring toFIG. 5,FIG. 5is a flowchart illustrating a control method of a head mounted display according to an embodiment of the invention. In step S510, an ambient luminance of ambient light is detected. In step S520, a selected transmittance and a maximum gray luminance value are generated according to a setting value, the ambient luminance and a minimum gray luminance value, a control signal is generated according to the selected transmittance, and a driving signal is generated according to display data and the maximum gray luminance value. In step S530, a display image is generated according to the driving signal, and in step S540, a transmittance amount of the ambient light is controlled according to the control signal.

Regarding the implementation details of the steps set forth above, they have been described in detail in the embodiments above and will not be repeated.

Referring toFIG. 6,FIG. 6is a flowchart illustrating a control method of a head mounted display according to another embodiment of the invention. In step S610, a setting value is received. In step S620, an ambient luminance is detected. In step S630, a maximum gray luminance value and a selected transmittance are obtained according to a look-up table. Then, in steps S640and S650, an amount of the maximum gray luminance value is determined. In step S640, whether the maximum gray luminance value is greater than a maximum luminance capable of being presented by the display of the head mounted display. If the maximum gray luminance value is greater than the maximum luminance, the maximum gray luminance value is set to be equal to the maximum luminance capable of being presented by the display (step S680). On the contrary, if the maximum gray luminance value is not greater than the maximum luminance, step S650is performed.

In step S650, whether the maximum gray luminance value is less than a minimum luminance capable of being presented by the display of the head mounted display. If the maximum gray luminance value is less than the minimum luminance, the maximum gray luminance value is set to be equal to the minimum luminance capable of being presented by the display (step S670). On the contrary, if the maximum gray luminance value is not less than the minimum luminance, step S660is performed.

In step S660, the maximum gray luminance value is maintained, and in step S690, the operations of the display and the light transmittance controller are respectively adjusted according to the maximum gray luminance value and the selected transmittance.

It is to be additionally mentioned that the sequence of performing steps S640and S650described above is not particularly limited, wherein steps S640and S650may also be synchronously performed, or step S650may be performed before step S640.

In view of the foregoing, the head mounted display of the invention can adjust the luminance of the display image and the transmittance amount of the ambient light of the light transmittance controller according to the ambient luminance and the setting value for setting the transmittance of the display image. In this way, in different environmental scenarios, the head mounted display, in the condition that the safety can be kept, can optimize the quality of the generated display image to enhance overall performance of the head mounted display.