NEAR-EYE DISPLAYING METHOD CAPABLE OF MULTIPLE DEPTHS OF FIELD IMAGING

Abstract

Disclosed are near-eye displaying methods and systems capable of multiple depths of field imaging. The method comprises two steps. At a first step, one or more pixels of a self-emissive display emit a light to a collimator such that the light passing through the collimator is collimated to form a collimated light. At a second step, the self-emissive display provides at least one collimated light direction altering unit on a path of the light from the collimator to change direction of the collimated light to enable the collimated light from at least two pixels to intersect and focus at a different location so as to vary a depth of field.

Claims

1. A near-eye displaying method capable of multiple depths of field imaging, characterized in that the method comprises the steps of: one or more pixels of a self-emissive display emitting a light to a collimator such that the light passing through the collimator is collimated to form a collimated light; and providing at least one collimated light direction altering unit on a path of the light from the collimator to change direction of the collimated light to enable the collimated light from at least two pixels to intersect and focus at a different location so as to vary a depth of field.

2. The near-eye displaying method capable of multiple depths of field imaging of claim 1, characterized in that the self-emissive display comprises an active light source including an organic light-emitting diode, a micro light emitting diode, a quantum dot light emitter or a laser.

3. The near-eye displaying method capable of multiple depths of field imaging of claim 1, characterized in that the self-emissive display is a transparent display or a non-transparent display.

4. The near-eye displaying method capable of multiple depths of field imaging of claim 1, characterized in that the collimator is a microlens, a flat metalens or a liquid crystal spatial light modulator.

5. The near-eye displaying method capable of multiple depths of field imaging of claim 4, characterized in that the flat metalens has a function of a diopter lens for collimating a direction of the light.

6. The near-eye displaying method capable of multiple depths of field imaging of claim 4, characterized in that the liquid crystal spatial light modulator comprises a plurality of liquid crystal cells, an alignment of a liquid crystal within the liquid crystal cells can be changed by altering a driving voltage applied to the liquid crystal cells so that a direction of an incident light from every pixel is collimated.

7. The near-eye displaying method capable of multiple depths of field imaging of claim 1, characterized in that the collimated light direction altering unit is a microlens, a flat metalens, or a liquid crystal spatial light modulator.

8. The near-eye displaying method capable of multiple depths of field imaging of claim 7, characterized in that the microlens enables at least two collimated lights to intersect and focus.

9. The near-eye displaying method capable of multiple depths of field imaging of claim 7, characterized in that the flat metalens comprises a plurality of areas having bumps for enabling at least two collimated lights to intersect and focus.

10. The near-eye displaying method capable of multiple depths of field imaging of claim 9, characterized in that two different areas having bumps are utilized to enable at least two collimated lights to intersect and focus at different locations to create an image having multiple depths of field.

11. The near-eye displaying method capable of multiple depths of field imaging of claim 9, characterized in that an area having bumps is utilized to enable at least two collimated lights to intersect and focus at different locations to create an image having multiple depths of field.

12. The near-eye displaying method capable of multiple depths of field imaging of claim 7, characterized in that the liquid crystal spatial light modulator comprises a plurality of liquid crystal cells, an alignment of a liquid crystal within the liquid crystal cells can be changed by altering a driving voltage applied to the liquid crystal cells so as to change a direction of the collimated light and enable at least two collimated lights to intersect and focus.

13. The near-eye displaying method capable of multiple depths of field imaging of claim 12, characterized in that the driving voltage of at least two liquid crystal cells can be changed to enable at least two collimated lights to intersect and focus at different locations to create an image having multiple depths of field.

14. The near-eye displaying method capable of multiple depths of field imaging of claim 12, characterized in that the driving voltage of at least one liquid crystal cell can be changed to enable at least two collimated lights to intersect and focus at different locations to create an image having multiple depths of field.

15. The near-eye displaying method capable of multiple depths of field imaging of claim 1, characterized in that the pixel is a single pixel or a collection of pixels comprising a plurality of pixels.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0028] FIG. 1 is a flow schematic diagram of the near-eye displaying method capable of multiple depths of field imaging according to the present invention.

[0029] FIG. 2A is an architectural schematic diagram of the near-eye displaying method capable of multiple depths of field imaging according to the first embodiment of the present invention.

[0030] FIG. 2B is a schematic diagram of the near-eye displaying method capable of multiple depths of field imaging according to the first embodiment of the present invention.

[0031] FIG. 3A is an architectural schematic diagram of the near-eye displaying method capable of multiple depths of field imaging according to the second embodiment of the present invention.

[0032] FIG. 3B is a schematic diagram of the near-eye displaying method capable of multiple depths of field imaging according to the second embodiment of the present invention.

[0033] FIG. 4A is an architectural schematic diagram of the near-eye displaying method capable of multiple depths of field imaging according to the third embodiment of the present invention.

[0034] FIG. 4B is a schematic diagram of the near-eye displaying method capable of multiple depths of field imaging according to the third embodiment of the present invention.

[0035] FIG. 5A is a schematic diagram illustrating the concept of multiple depths of field according to the near-eye displaying method capable of multiple depths of field imaging of the present invention.

[0036] FIG. 5B is another schematic diagram illustrating the concept of multiple depths of field according to the near-eye displaying method capable of multiple depths of field imaging of the present invention.

[0037] FIG. 6A is a schematic diagram illustrating the concept of multiple depths of field according to another embodiment of the near-eye displaying method capable of multiple depths of field imaging of the present invention.

[0038] FIG. 6B is another schematic diagram illustrating the concept of multiple depths of field according to another embodiment of the near-eye displaying method capable of multiple depths of field imaging of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0039] Embodiments of the present invention will now be described, by way of example only, with reference to the accompanying drawings.

[0040] FIG. 1 is a flow diagram of a near-eye displaying method capable of multiple depths of field imaging according to the present invention; the method comprises the steps of: [0041] Step 101: one or more pixels of a self-emissive display emitting a light to a collimator such that the light passing through the collimator is collimated; and [0042] Step 102: providing at least one collimated light direction altering unit on a path of the light from the collimator to change direction of the collimated lights to enable the collimated light from at least two pixels to intersect and focus at a different location so as to vary a depth of field.

[0043] According to the aforementioned method, a self-emissive display 1 utilized technology that enables self-emission; and the self-emissive display 1 may be a transparent display or a non-transparent display. The self-emissive display 1 may comprise active light sources such as organic light-emitting diodes (OLED), micro light emitting diodes (micro LED), quantum dot light emitters, or lasers . . . etc.

[0044] The collimator may be a microlens, a liquid crystal spatial light modulator (LCSLM) or a flat metalens. The following further explains the different types of collimators: [0045] (1) Microlens: As shown in FIG. 2A, a microlens 2 is on a light path of a light emitted by the self-emissive display 1. During operation, as shown in FIG. 2B, a direction of an incident light from at least one pixel 11 of the self-emissive display 1 is collimated. [0046] (2) Liquid Crystal Spatial Light Modulator (LCSLM): As shown in FIG. 3A, a liquid crystal spatial light modulator 3 comprises a plurality of liquid crystal cells 31; when at least one pixel 11 on the self-emissive display 1 emits an incident light, as shown in FIG. 3B, a driving voltage of one of the liquid crystal cells 31 receiving the incident light of the at least one pixel 11 can be changed so that the incident light from the at least one pixel 11 is collimated (the known technology of changing the driving voltage of the liquid crystal cell 31 to alter the phase of the liquid crystal is omitted herein). [0047] (3) Flat Metalens: As shown in FIG. 4A, a flat metalens 4 comprises a plurality of areas 41 having bumps; during operation, as shown in FIG. 4B, an incident light from one of the pixels 11 can be collimated by one of the areas 41 (the fact that the flat metalens 4 can affect light to travel at a different direction is well known in the art; and thus, further explanation is omitted herein). The flat metalens described herein is a metasurface containing nano-bumps which serves the function of refracting light and changing the direction of the collimated light.

[0048] The collimated light direction altering unit is a microlens, a liquid crystal spatial light modulator (LCSLM) or a flat metalens. The following further explains the different types of collimated light direction altering units:

[0049] (1) Microlens: [0050] A. The structure of the microlens 2 is shown in FIG. 2A; the microlens 2 is utilized to allow at least two collimated lights to intersect and focus to create a virtual image; [0051] B. Two different microlens 2 are utilized to enable two collimated lights to intersect; another microlens 2 is utilized to enable another collimated light to intersect and focus at a different location to produce an image having multiple depths of field.

[0052] (2) Liquid Crystal Spatial Light Modulator (LCSLM): [0053] A. The structure of the liquid crystal spatial light modulator 3 is shown in FIG. 3A. The structure of the liquid crystal spatial light modulator 3 comprises a plurality of liquid crystal cells 31; the operational principle of changing the direction of the collimated light is changing a driving voltage of one of the liquid crystal cells 31 receiving the incident light (the collimated light) of two pixels 11, so that the direction of at least two incident lights (the collimated lights) is changed, causing the at least two incident lights (the collimated lights) to intersect and create a focus of a virtual image; [0054] B. The driving voltage of at least two different liquid crystal cells 31 are changed so that two collimated lights intersect at different locations and create foci to produce an image having multiple depths of field; [0055] C. The driving voltage of a liquid crystal cell 31 remains constant, and the driving voltage of at least another different liquid crystal cell 31 is changed so that two collimated lights intersect at different locations and create foci to produce an image having multiple depths of field.

[0056] (3) Flat Metalens: [0057] A. The structure of the flat metalens 4 is shown in FIG. 4A. The flat metalens 4 enables at least two collimated lights to intersect and create focus to produce a virtual image; [0058] B. Two different areas 41 having bumps are utilized to enable two collimated lights to respectively intersect at different locations to create foci to produce an image having multiple depths of field; [0059] C. A different area 41 having bumps is utilized to enable at least two collimated lights to intersect and focus at different locations to create an image having multiple depths of field.

[0060] When generating image having multiple depths of field, different combinations of collimators and collimated light direction altering units can be used. The combinations are described as the following: [0061] (1) A microlens is used as a collimator; and a microlens, a liquid crystal spatial light modulator (LCSLM) or a flat metalenses is used as a collimated light direction altering unit. [0062] (2) A liquid crystal spatial light modulator is used as a collimator; and the same liquid crystal spatial light modulator is used as a collimated light direction altering unit. [0063] (3) A flat metalens is used as a collimator; and the same flat metalense is used as a collimated light direction altering unit. [0064] (4) A flat metalense is used as a collimator; and a microlens, a liquid crystal spatial light modulator, or a flat metalens is used as a collimated light direction altering unit.

[0065] As shown in FIG. 5A, the collimator is a microlens 2, and the collimated light direction altering unit is a liquid crystal spatial light modulator 3. After the microlenses 2 collimate light from two pixels 11 of the self-emissive display, one of the liquid crystal cells 31 of the liquid crystal spatial light modulator 3 adjusts the direction of light from one or more of the pixels 11, so that lights of two pixels 11 can extend and form a virtual image 51. As shown in FIG. 5B, the phase of one of the liquid crystal cells 31 can be changed to alter the direction of the collimated light such that lights of two pixels 11 can overlap at another location to form another virtual image 52 so as to extend the depth of field. With the aforementioned method, the phase of the liquid crystal cells 31 can be adjusted constantly so that human eyes 6 are able to view multiple continuous virtual images to achieve multiple depths of field imaging.

[0066] In another aspect of the present invention, a single element can be utilized to collimate and change the direction of the light. The description is as the following: [0067] (1) The microlens 2 can directly collimate light and change the direction of the collimated light. However, the directions at which different microlens can re-direct the collimated light are predetermined according to the manufacturing process of the microlens. Therefore, as shown in FIG. 6A, two separate microlenses 2 cause two collimated lights to intersect and create focus to produce the virtual image 53. However, if forming a focus for another virtual image is needed, then, as shown in FIG. 6B, light from another microlens 2 and the collimated light from the original microlens 2 intersect to create another focus to produce another virtual image 54. [0068] (2) The liquid crystal spatial light modulator 3 or the flat metalens 4 can be used simultaneously to collimate light and adjust the direction of the collimated light, and the driving voltage of the liquid crystal cells 31 of the liquid crystal spatial light modulator 3 can be directly changed to adjust the direction of the collimated light to form foci at different locations for producing a virtual image. However, the flat metalens 4 needs to utilize multiple different areas 41 having bumps to form foci at different locations to produce a virtual image.

[0069] The near-eye displaying method capable of multiple depths of field imaging according to the present invention has the following advantages over the prior art: [0070] 1. The present invention enables light emitted by two or more pixels to intersect at different locations to create foci so that the output image exhibits the effect of having multiple depths of field. The aforementioned pixel is a single pixel or a collection of pixels comprising a plurality of pixels. [0071] 2. The liquid crystal spatial light modulator according to the present invention can directly adjust the direction of the collimated light; thus, it does not require moving the position of the pixel to enable lights emitted by two pixels intersecting and creating foci at different locations. The cost arisen from using redundant optical elements can be eliminated.

[0072] Although particular embodiments of the present invention have been described in detail for purposes of illustration, various modifications and enhancements may be made without departing from the spirit and scope of the present invention. Accordingly, the present invention is not to be limited except as by the appended claims.