TW201905506A - Light splitting apparatus - Google Patents

Abstract

A light splitting apparatus includes a first glass substrate, a second glass substrate and a third glass substrate. The first glass substrate guides a first color light beam of incident light to a display device, and changes a polarization direction of a first intermediate light beam of the incident light to produce a second intermediate light beam. The first color light beam is polarized in a first polarization direction. The second intermediate light beam includes a second color light beam polarized in a second polarization direction and a third color light beam. The second glass substrate guides the second color light beam polarized in the second polarization direction to the display device, and changes a polarization direction of the third color beam to a third polarization direction. The third glass substrate guides the third color light beam polarized in the third polarization direction to the display device.

Description

Spectroscopic device

The present invention relates to light splitting, and more particularly to a spectroscopic device having a polarizing effect and a retardable phase of a glass substrate.

Conventional display devices employ a polarizer, a phase retarder, or an electrochromic substrate to control the transmission paths of the respective light beams in the display device. However, since the phase retarder is made of plastic, the phase retarder does not perform well in short-wavelength applications. In addition, wrinkles are apt to occur when the phase retardation plate is attached to the polarizing plate, and it is difficult to align. Moreover, the conventional display device uses a pressure-sensitive adhesive to bond the respective wafers having the polarizing plate and the phase retardation plate, but in order to avoid damage to the microstructure on the phase retardation plate, it is not tight. Bonding the wafers results in poor reliability after bonding of the wafers, and the thickness is too thick.

In view of the above, it is an object of the present invention to provide a spectroscopic device having a polarizing effect and a phase-delayable glass substrate to solve the above problems.

According to an embodiment of the invention, a spectroscopic device is disclosed. The spectroscopic device comprises a first glass substrate, a second glass substrate and a third glass substrate. The first glass substrate is configured to guide a first color beam of incident light to a display element, and change a polarization direction of the first relay beam of the incident light to generate a second relay beam. The first color beam has a first polarization direction, and the second relay beam includes a second color beam and a third color beam, the second color beam having a second polarization direction. The second glass substrate is disposed on a side of the first glass substrate for guiding the second color beam having the second polarization direction to the display element, and changing the third color beam The direction of polarization is such that the third color beam has a third polarization direction. The third glass substrate is disposed on a side of the second glass substrate for guiding the third color light beam having the third polarization direction to the display element, wherein the second glass substrate is And disposed between the first glass substrate and the third glass substrate.

The spectroscopic device provided by the present invention may comprise a glass substrate having a polarizing effect and a retardable phase (such as a glass substrate having birefringence characteristics) to separate beams of different colors without setting a phase retardation plate, thereby reducing production cost. Improve product reliability and reduce the thickness of the wafer stack in the spectroscopic device. In addition, since the spectroscopic device provided by the present invention can utilize optical glue to bond/join different glass substrates, it is only necessary to perform a black coating operation once to prevent edge leakage.

Please refer to FIG. 1 , which is a functional block diagram of an embodiment of a display device of the present invention. The display device 100 can be implemented by various display devices, such as a television, a projection display, a portable display, or a wearable display, and can include, but is not limited to, a light source 110, a light splitting apparatus 120, and a display element. 130. The light source 110 can generate an incident light LI to the spectroscopic device 120, and the spectroscopic device 120 can utilize a plurality of glass substrates/glass substrates (or cover lenses; not shown in FIG. 1). The incident light LI is split into a plurality of color light beams B1 to BN (N is a positive integer greater than 1), wherein at least one of the plurality of glass substrates may have a polarizing effect and may delay the phase of the light beam. Next, the display element 130 can display an image based on the plurality of color light beams B1 to BN. For example (but the invention is not limited thereto), the plurality of color beams B1 B BN may be three primary color beams such as a red light beam, a green light beam, and a blue light beam, and the display element 130 may be based on a red light beam, a green light beam, and a blue light beam. The beam is used to display the image.

It should be noted that the type and number of beams of the plurality of color beams B1 B BN generated by the spectroscopic device 120 can be determined according to actual design requirements. For example, the spectroscopic device 120 can split the incident light LI into three primary color beams including a cyan light beam, a magenta light beam, and a yellow light beam, and output the same as multiple color. Light beams B1 to BN. In another example, the spectroscopic device 120 can split the incident light LI into four primary color beams such as a red light beam, a green light beam, a blue light beam, and a yellow light beam, and output them as the plurality of color light beams B1 B BN. In yet another example, the spectroscopic device 120 can split the incident light LI into six primary color beams such as a red light beam, a green light beam, a blue light beam, a cyan light beam, a magenta light beam, and a yellow light beam, and output the same as The plurality of color beams B1 to BN. In addition, since the spectroscopic device 120 can split the incident light LI without using a phase retardation plate, the spectroscopic device 120 (or the display device 100) can have low production cost and high reliability.

In order to facilitate the understanding of the technical features of the present invention, the following is an example in which the spectroscopic device splits the incident light into three primary color light beams. However, the invention is not limited thereto. As long as the spectroscopic device using a glass substrate having a polarizing effect and a retardable phase is used to split the incident light into a plurality of color light beams, design-related changes are within the scope of the present invention. Please refer to Figure 2 together with Figure 1. Fig. 2 is a schematic view showing an example of the operation of one of the spectroscopic devices 120 shown in Fig. 1. In this implementation example, the spectroscopic device 220 can include, but is not limited to, a plurality of glass substrates 222-226 that can split the incident light LI into a plurality of color light beams B1 B B3, wherein the glass substrate 224 is disposed on The glass substrate 222 is interposed between the glass substrate 226. The glass substrate 222 can guide a light beam satisfying a first predetermined optical characteristic (such as a light beam having a polarization direction D11) to the display element 130, change the polarization direction of the remaining light beam, and thereby change the remaining polarization direction. The beam is delivered to a glass substrate 224. The glass substrate 224 can guide a light beam satisfying a second predetermined optical characteristic (such as a light beam having a polarization direction D21) to the display element 130, change the polarization direction of the remaining light beam, and thereby change the remaining polarization direction. The beam is delivered to a glass substrate 226. The glass substrate 226 can direct a light beam that satisfies a third predetermined optical characteristic, such as a light beam having a polarization direction D31, to the display element 130. Further explanation is as follows.

In this embodiment, the glass substrate 222 can guide the color beam B1 of the incident light LI to the display element 130, and change the polarization direction of the relay beam M1 of one of the incident lights LI to generate a relay beam M2, wherein The color beam B1 may have a polarization direction D11 (which satisfies the first predetermined optical characteristic), the relay beam M2 may include a color beam B2 and a color beam B3, and the color beam B2 has a polarization direction D21. In other words, since the glass substrate 222 can change the polarization direction of the relay beam M1, the polarization direction of the color beam B2 included in the relay beam M1 can be changed from a polarization direction D22 to a polarization direction D21. In this way, when the color light beam B2 having the polarization direction D21 is incident on the glass substrate 224, the glass substrate 224 can guide the color light beam B2 having the polarization direction D21 (which satisfies the second predetermined optical characteristic) to Display element 130. In addition, in this embodiment, the color beam B3 included in the relay beam M1 may have a polarization direction D33, and the glass substrate 222 may change the polarization direction of the color beam B3 from the polarization direction D33 to a polarization. Direction D32.

The glass substrate 224 is provided corresponding to one side of the glass substrate 222. In addition to directing the color beam B2 having the polarization direction D21 to the display element 130, the glass substrate 224 can additionally change the polarization direction of the color beam B3 such that the color beam B3 has a polarization direction D31. In other words, the glass substrate 224 can convert the polarization direction of the color beam B3 from the polarization direction D32 to the polarization direction D31. In this way, when the color light beam B3 having the polarization direction D31 is incident on the glass substrate 226 (which is disposed corresponding to one side of the glass substrate 224), the glass substrate 226 can have the color light beam B3 having the polarization direction D31. (the third predetermined optical characteristic is satisfied) is guided to the display element 130.

In some embodiments, an optical microstructure may be disposed in at least one of the plurality of glass substrates 222-226 to polarize a particular polarization direction (such as polarization direction D11/D21/D31). The light beam is directed to display element 130. Please refer to Figure 3 together with Figure 2. Fig. 3 is a schematic view showing an example of one of the glass substrates 222 shown in Fig. 2. In this implementation example, the glass substrate 222 can include, but is not limited to, a light input region R1, an optical microstructure R2, and a light output region R3. The light incident region R1 can receive incident light (such as incident light LI) of one of the glass substrates 222 and direct the incident light to the optical microstructure R2. Next, the optical microstructure R2 can guide a light beam having a polarization direction D11, such as the color light beam B1, to the light exit region R3, so that the light beam having the polarization direction D11 can be transmitted to a display element via the light exit region R3 (such as Display element 130) shown in Figure 1. The remaining light beam among the incident light (the light beam not guided to the light exiting region R3; such as the relay light beam M1) is transferred to the glass substrate 224 after its polarization direction is changed. It should be noted that the glass substrate 224 and/or the glass substrate 226 can also be implemented using the structure shown in FIG.

In addition, in some embodiments, at least one of the plurality of glass substrates 222-226 may have a birefringence characteristic to split an incident light and change a pole of the component light of the incident light. Direction. For example (but the invention is not limited thereto), at least one of the plurality of glass substrates 222-226 may be a sapphire substrate, a quartz substrate, a tourmaline substrate or Rutile substrate. Please note that in one embodiment, a glass substrate having a higher refractive index can reduce the amount of ultraviolet light incident. In another embodiment, in the case where the glass substrate 222/224/226 is implemented by a sapphire substrate, the sapphire substrate has a high refractive index (for example: greater than 1.7), high hardness, and high light transmittance ( For example, greater than 85%), the thickness of the glass substrate 222/224/226 can be reduced (eg, 0.4 mm to 0.5 mm) while still maintaining good optical performance.

Furthermore, in some embodiments, at least two of the polarization directions D11, the polarization directions D21 and the polarization directions D31 satisfying the first, second, and third predetermined optical characteristics, respectively, may be identical to each other, such that the guidance At least two of the plurality of color light beams B1 to B3 of the display element 130 shown in FIG. 1 may have the same polarization direction. Please refer to FIG. 2 and FIG. 4 together. FIG. 4 is a polarization direction of the plurality of color light beams B1 to B3 incident on one of the plurality of glass substrates 222 to 226 shown in FIG. A schematic of an embodiment. In the embodiment shown in FIG. 4, the polarization direction D11, the polarization direction D21, and the polarization direction D31 may both be linear polarization vertical polarization directions, and the plurality of color light beams B1 to B3 may be respectively blue light beams. The green light beam and the red light beam (that is, the RGB three primary colors) are implemented. In other words, the incident light LI emitted by the light source 110 shown in FIG. 1 may include a plurality of linearly polarized beams. However, this is merely for convenience of explanation and is not intended to be a limitation of the present invention.

In this embodiment, the blue light beam (color beam B1) may have a linearly polarized polarization direction (polarization direction D11) before the incident light LI is incident on the glass substrate 222. The green light beam (color beam B2) may have a horizontal polarization direction of polarization (polarization direction D22), and the polarization direction D33 of the red beam (color beam B3) may have a vertical polarization direction of linear polarization (pole Direction D33). When the incident light LI is incident on the glass substrate 222, the glass substrate 222 can guide the blue light beam having the vertical polarization direction to the display element 130, and convert the polarization direction of the green light beam into the vertical polarization direction (polarization). Direction D21), and transforming the polarization direction of the red beam into a horizontal polarization direction (polarization direction D32). Therefore, when a green light beam having a vertical polarization direction (polarization direction D21) is incident on the glass substrate 224, the glass substrate 224 can guide the green light beam to the display element 130 shown in FIG. Further, when a red light beam having a horizontal polarization direction (polarization direction D32) is incident on the glass substrate 224, the glass substrate 224 can change the polarization direction of the red light beam from the horizontal polarization direction to the vertical polarization direction (pole The direction D31) is such that the glass substrate 226 can direct the red light beam to the display element 130 shown in FIG.

It should be noted that in this embodiment, the first predetermined optical characteristic involved in the glass substrate 222 may include a predetermined polarization direction and a predetermined wavelength range. That is, when a light beam having the predetermined polarization direction (polarization direction D11) and having a wavelength within the predetermined wavelength range is incident on the glass substrate 222, the light beam can be guided to the display element 130. Therefore, although the red light beam has a vertical polarization direction, the glass substrate 222 may not guide the red light beam to the display element 130 because the wavelength of the red light beam exceeds the predetermined wavelength range.

In addition, the thickness of the glass substrate 222 may be determined according to an angular difference between the polarization direction D22 and the polarization direction D21 and the wavelength of the color beam B2, and/or the thickness of the glass substrate 224 may be polarized. The angle difference between the direction D32 and the polarization direction D31 and the wavelength of the color beam B3 are determined. In other words, in this embodiment, the thickness of the glass substrate 222 can be determined according to the amount of change in the polarization direction and the wavelength of the green light beam, and/or the thickness of the glass substrate 224 can be changed according to the polarization direction and red. The wavelength of the light beam is determined. For example, in the case where the glass substrate 222 converts the linearly polarized color light beam B2 (green light beam) from the horizontal polarization direction to the vertical polarization direction, the angular difference of the polarization direction is 90 degrees, which means The phase difference of the two-phase vertical electric field component of the color beam B2 is changed by 180 degrees. The thickness of the glass substrate 222 can be determined according to the following formula:

THK ₁ =(1/2+2k ₁ )×(λ ₂ /n _eff1 ),

Wherein THK ₁ is the thickness of the glass substrate 222, k ₁ is an integer greater than or equal to 0, λ ₂ is the wavelength of the color beam B2, and n _eff1 is the equivalent refractive index of the glass substrate 222. For example, in the case where the glass substrate 222 is implemented by a birefringent material, n _eff1 may be equal to both the extraordinary refraction index and the ordinary refraction index of the glass substrate 222. The difference between.

Similarly, in the case where the glass substrate 224 converts the linearly polarized color light beam B3 (red light beam) from the horizontal polarization direction to the vertical polarization direction, the angular difference of the polarization direction is 90 degrees (color beam B3) The phase difference of the two-phase vertical electric field component is changed by 180 degrees), and the thickness of the glass substrate 224 can be determined by the following formula:

THK ₂ = (1/2 + 2k ₂ ) × (λ ₃ / n _eff2 ).

Wherein THK ₂ is the thickness of the glass substrate 224, k ₂ is an integer greater than or equal to 0, λ ₃ is the wavelength of the color beam B3, and n _eff2 is the equivalent refractive index of the glass substrate 224. For example, where glass substrate 224 is implemented from a birefringent material, n _eff2 may be equal to the difference between the extraordinary refractive index and the ordinary refractive index of glass substrate 224.

Please note that the above is for illustrative purposes only and is not intended to be a limitation of the invention. In a design change, the polarization directions D11, the polarization directions D21, and the polarization directions D31 that satisfy the first, second, and third predetermined optical characteristics, respectively, may be different from each other. In another design variation, the polarization direction D22 of the color beam B2 incident on the glass substrate 222 does not have to be perpendicular to the polarization direction D11 of the color beam B1 and the polarization direction of the color beam B3 incident on the glass substrate 222. D33 is not necessarily the same as the polarization direction D11 of the color beam B1, and/or the polarization directions D22 and polarization directions D33 of the color beam B2 and the color beam B3 of the relay beam M1 are not necessarily perpendicular to each other. In yet another design variation, the polarization direction D32 of the color beam B3 incident on the glass substrate 224 does not have to be perpendicular to the polarization direction D21 of the color beam B2 incident on the glass substrate 224.

In addition, the glass substrate 222/224 is not limited to converting a color beam from a horizontal polarization direction of linear polarization to a vertical polarization direction of linear polarization to a linear polarization direction and linear polarization. The other of the vertical polarization directions. In short, as long as a glass substrate having a polarizing effect and a retardable phase is used to split an incident light into a plurality of color light beams without additionally providing a phase retardation plate, design-related changes are within the scope of the present invention.

Since the phase retardation plate is not required to be provided between the glass substrates in the spectroscopic device provided by the present invention, an optical adhesive can be used to bond/bond different glass substrates, thereby encapsulating the glass substrates. Please refer to FIG. 5, which is a schematic diagram of another embodiment of the spectroscopic device 120 shown in FIG. 1. The light splitting device 520 can include, but is not limited to, a plurality of glass substrates 522-526, an optical adhesive 532, and an optical adhesive 534, wherein the plurality of glass substrates 522-526 can be respectively formed by the plurality of glasses shown in FIG. The substrates 222 to 226 are implemented. In this embodiment, the optical splitting device 520 can use the optical adhesive 532 and the optical adhesive 534 to stack a plurality of glass substrates 522 to 526, wherein the optical adhesive 532 can bond the glass substrate 522 and the glass substrate 524, and the optical adhesive 534 can bond glass substrate 524 to glass substrate 526. At least one of the optical adhesive 532 and the optical adhesive 534 may be a heat curing adhesive/resin or a light curing adhesive such as an ultraviolet curing adhesive.

The configuration of the spectroscopic device 520 shown in Fig. 5 is for illustrative purposes only and is not intended to be a limitation of the present invention. For example, the spectroscopic device 520 can include an anti-reflection coating (ARC) or an optical microstructure (not shown in FIG. 5) formed on at least one glass substrate to enhance light. Light transmission/transparency. In another example, after forming the stacked structure shown in FIG. 5, a black coating process may be performed on the spectroscopic device 520 to form a coating layer on the plurality of glass substrates 522-526. Edge (not shown in Figure 5) to prevent edge leakage.

It is worth noting that for a conventional spectroscopic device, once a wafer (including a polarizing plate and a phase retarding plate) is prepared, a black coating operation is required at the edge of the wafer to prevent edge leakage. All wafers require a black coating operation before packaging. That is, if the conventional spectroscopic device includes three wafers, three black coating operations are required to prevent edge leakage. In contrast, since the spectroscopic device provided by the present invention can eliminate the need for a phase retardation plate, and optical glue can be used to follow different glass substrates, after all the glass substrates (or wafers) are stacked, only A black coating operation on the spectroscopic device prevents edge leakage. In other words, the spectroscopic device provided by the present invention can not only have a thin overall thickness, but also reduce the production cost involved in black coating.

In summary, the spectroscopic device provided by the present invention may comprise a glass substrate having a polarizing effect and a retardable phase (such as a glass substrate having birefringence characteristics) to separate beams of different colors without providing a phase retardation plate. Therefore, the production cost can be reduced, the reliability of the product can be improved, and the total thickness of the wafer stack in the spectroscopic device can be reduced. In addition, since the spectroscopic device provided by the present invention can utilize optical glue to bond/join different glass substrates, only one black coating operation is required to prevent edge leakage. The above is only a preferred embodiment of the present invention. Equivalent changes and modifications made to the scope of the patent application of the present invention are intended to be within the scope of the present invention.

100‧‧‧ display device

110‧‧‧Light source

120, 220, 520‧‧ ‧ splitter

130‧‧‧Display components

222, 224, 226, 522, 524, 526‧ ‧ glass substrates

532, 534‧‧ ‧ optical adhesive

LI‧‧‧ incident light

B1, B2, B3, BN‧‧‧ color beams

M1, M2‧‧‧ relay beam

D11, D21, D22, D31, D32, D33‧‧‧ polarization direction

THK ₁ , THK ₂ ‧‧‧ thickness

R1‧‧‧ light zone

R2‧‧‧ optical microstructure

R3‧‧‧Lighting area

1 is a functional block diagram of an embodiment of a display device of the present invention. Fig. 2 is a schematic view showing an example of the operation of one of the spectroscopic devices shown in Fig. 1. Fig. 3 is a schematic view showing an example of a glass substrate shown in Fig. 2. Fig. 4 is a view showing an embodiment of the polarization directions of the plurality of color light beams incident on one of the plurality of glass substrates shown in Fig. 3. Fig. 5 is a schematic view showing another embodiment of the spectroscopic device shown in Fig. 1.

Claims (12)

A light splitting device comprising: a first glass substrate for guiding a first color beam of incident light to a display element, and changing a polarization direction of the first relay beam of the incident light to Generating a second relay beam, wherein the first color beam has a first polarization direction, the second relay beam includes a second color beam and a third color beam, and the second color beam has a second a direction of polarization; a second glass substrate disposed adjacent to a side of the first glass substrate for guiding the second color beam having the second polarization direction to the display element, and changing the a polarization direction of the third color beam such that the third color beam has a third polarization direction; and a third glass substrate disposed corresponding to one side of the second glass substrate for having the first The third color light beam of the triple polarization direction is guided to the display element, wherein the second glass substrate is disposed between the first glass substrate and the third glass substrate. The spectroscopic device of claim 1, wherein the first relay beam comprises the second color beam having a fourth polarization direction, and the first glass substrate is the second color beam The polarization direction is changed from the fourth polarization direction to the second polarization direction; the thickness of the first glass substrate is based on an angular difference between the fourth polarization direction and the second polarization direction and the first The wavelength of the two color beams is determined. The spectroscopic device of claim 1, wherein the first relay beam comprises the second color beam having a fourth polarization direction and the third color beam having the first polarization direction, a fourth polarization direction is perpendicular to the first polarization direction; the first glass substrate is configured to convert a polarization direction of the second color beam from the fourth polarization direction to the second polarization direction, and The polarization direction of the third color beam is converted from the first polarization direction to a fifth polarization direction perpendicular to the second polarization direction. The spectroscopic device of claim 1, wherein the second glass substrate converts a polarization direction of the third color beam from a fourth polarization direction to the third polarization direction; The thickness of the glass substrate is determined according to the angular difference between the fourth polarization direction and the third polarization direction and the wavelength of the third color beam. The spectroscopic device of claim 1, wherein the second glass substrate converts a polarization direction of the third color beam from a fourth polarization direction to the third polarization direction, the fourth The direction of polarization is perpendicular to the second polarization direction. The spectroscopic device of claim 1, wherein at least two of the first polarization direction, the second polarization direction, and the third polarization direction are identical to each other. The spectroscopic device of claim 1, wherein the first color beam is a blue light beam, the second color light beam is a green light beam, and the third color light beam is a red light beam. The spectroscopic device of claim 1, wherein at least one of the first glass substrate, the second glass substrate, and the third glass substrate has birefringence characteristics. The spectroscopic device of claim 8, wherein at least one of the first glass substrate, the second glass substrate and the third glass substrate is a sapphire substrate, a quartz substrate, a tourmaline substrate Or rutile substrate. The spectroscopic device of claim 1, wherein the second glass substrate is stacked between the first glass substrate and the third glass substrate; the spectroscopic device further comprises: a first optical adhesive And bonding the first glass substrate to the second glass substrate; and a second optical glue for bonding the second glass substrate to the third glass substrate. The spectroscopic device of claim 10, wherein at least one of the first optical glue and the second optical glue is an ultraviolet curing adhesive. The spectroscopic device of claim 10, wherein at least one of the first optical glue and the second optical glue is a thermosetting glue.