WO2012129950A1 - Projector and stereo image system - Google Patents

Abstract

Disclosed in the present invention are a projector and a stereo image system applied in the projection technical field. The projector of the present invention utilizes a polarizing filter to generate polarization image signal light alternated by the predetermined time interval, such as the frequency of 120 frames per second, and each image frame is alternated in sequence, then a projection lens converts the polarization image signal light to new projection image signal light with parallel vibration direction and constant polarization frequency, and the vibration direction of the light is not changed when the new projection image signal light is reflected by the projection screen into polarization glasses; a viewer can see only the corresponding image through the left lens and right lens of the polarization glasses, namely, through the polarization glasses, the viewer receives a left eye frame, then a right eye frame, and a left eye frame again, then a right eye frame again; thus generating stereo perception in a visual nervous system to achieve the purpose of viewing the stereo image, and achieving the purpose of viewing the stereo image through one projector.

Description

 Projector, stereoscopic image system

[Technical Field]

The present invention relates to the field of projection technology, and in particular, to a projector and a stereoscopic image system.

 【Background technique】

A projector is a device for projecting image signal light onto a projection screen. The existing projector includes a digital light processing (DLP) projector, a liquid crystal on silicon (LCOS) projector, and a liquid crystal display (LCD). Projector.

Please refer to FIG. 1 , which is a schematic diagram of a conventional projector. The projector 100 includes:

An image signal processing device 101, configured to generate image signal light;

The projection lens 102 is disposed on a transmission path of the image signal light generated by the image signal processing device 101 for projecting the generated image signal light onto the projection screen for imaging.

2 is a schematic diagram of an embodiment of a conventional digital light processing projector, the digital light processing type projector 200 includes: a digital light processing type image signal processing device 201, a projection lens 202;

The digital light processing type image signal processing device 201 is configured to generate image signal light, including:

a light source 2011 for providing light;

The relay lens 2012 is disposed on the transmission path of the light provided by the light source 2011 for projecting the light provided by the light source 2011 onto the digital micromirror device (DMD) 2013;

The digital micromirror device 2013 is disposed on the transmission path of the light provided by the light source 2011, and includes a plurality of micromirrors (not shown), and each of the micromirrors exhibits a state including an ON state, an OFF state, and an OFF state. a micromirror for reflecting the light projected by the relay lens 2012, and causing the reflected light to deviate from the projection lens 202, and exhibiting an ON state of the micromirror for reflecting the light projected by the relay lens 2012 to the projection The lens 202, the light reflected to the projection lens 202 becomes an image, that is, an image signal light is generated;

The projection lens 202 is disposed on the transmission path of the light provided by the light source 2011 for projecting the generated image signal light onto the projection screen for imaging.

3 is a schematic diagram of an embodiment of a conventional liquid crystal liquid crystal projector, the liquid crystal liquid crystal projector 300 includes: a liquid crystal liquid crystal type image signal processing device 301, a projection lens 302;

The liquid crystal display type image signal processing device 301 is configured to generate image signal light, including:

a light source 3011 for providing light;

The light splitting system 3012 is disposed on the transmission path of the light provided by the light source 3011, and is configured to divide the light provided by the light source 3011 into three colors of red light, green light, and blue light, and project the red light to the refractor mirror 3013 to emit green light. Projected to the liquid crystal on silicon imaging system 3015, the blue light is projected to the refractor 2304;

a refractor mirror 3013, disposed on the red light transmission path for refracting the red light to the silicon-based liquid crystal imaging system 3015;

a refractor 2304 is disposed on the transmission path of the blue light for refracting the blue light to the silicon-based liquid crystal imaging system 3015;

The liquid crystal on silicon imaging system 3015 is disposed on the transmission path of the three colors of red, green, and blue light, and is used for color combining the three colors of red, green, and blue light to perform image modulation to form an image to generate image signal light. ;

The projection lens 302 is disposed on a transmission path of the image signal light generated by the liquid crystal on-type image signal processing device 301, and is used for projecting the generated image signal light onto the projection screen for imaging.

4 is a schematic diagram of an embodiment of a conventional liquid crystal projector 400. The liquid crystal projector 400 includes a liquid crystal image signal processing device 401 and a projection lens 402.

a liquid crystal type image signal processing device 401 for generating image signal light;

The projection lens 402 is disposed on a transmission path of the image signal light generated by the liquid crystal image signal processing device 401 for projecting the generated image signal light onto the projection screen for imaging.

The design represented by Figure 2 is not the only possible method for constructing a digital light processing projector. The design represented by Figure 3 is not the only possible method for forming a liquid crystal liquid crystal projector. The design represented by Figure 4 is also It is not the only possible method of constituting a liquid crystal projector, and these figures are drawn for the purpose of example only.

Stereoscopic projection is realized by the principle of polarization of light. The existing scheme of realizing stereoscopic projection is to use two projectors to simultaneously project the image, and the polarization directions of the polarizers in front of the two projectors are perpendicular to each other, so that the two generated The polarization directions of the beam polarized light are also perpendicular to each other, and the direction of the polarized light does not change when the polarized light is projected onto the dedicated projection screen and then reflected to the viewer position, and the viewer can only see the corresponding polarized light through the left and right eyes of the polarized glasses. The image, so as to create a stereoscopic feeling in the visual nervous system, to achieve the purpose of viewing stereoscopic images, the prior art can not achieve the purpose of viewing stereoscopic images through a projector.

 [Summary of the Invention]

The technical problem to be solved by the present invention is to provide a projector and a stereoscopic image system.

An object of the present invention is to provide a projector including: an image signal processing device, a polarizing filter, and a projection lens;

The image signal processing device is configured to generate image signal light;

The polarizing filter is disposed on a transmission path of the image signal light generated by the image signal processing device, and includes: an electric field selector, an electric field provider, and a polarizer;

The electric field selector is configured to select a predetermined time, and when the electric field selector selects N/120 seconds, an electric field is provided to the polarizer, wherein the N includes an odd number and an even number;

The electric field provider is configured to provide an electric field to the polarizer when the electric field selector selects to supply an electric field to the polarizer;

The polarizer includes: a first conductive layer, a liquid crystal layer, a second conductive layer, and a quarter wave plate;

The first conductive layer is configured to transmit the image signal light generated by the image signal processing device to obtain a polarized image signal light ray;

And the liquid crystal layer is bonded to the first conductive layer, and when the first conductive layer and the second conductive layer are not added with an electric field, the polarized image signal light is rotated by a predetermined angle to obtain a polarization. And oscillating the polarized image signal light obtained by the rotation; and transmitting the electric field to the first conductive layer and the second conductive layer when the electric field provider supplies the polarization Image signal light

The second conductive layer is adhered to the liquid crystal layer for transmitting a polarized image signal light transmitted through the liquid crystal layer, and a polarized image signal light 2;

The quarter-wave plate is bonded to the second conductive layer for transmitting a polarized image signal light having a direction of vibration transmitted through the second conductive layer at a predetermined angle to the fast axis thereof. Converting the transmitted polarized image signal light into a polarized image signal light 3; transmitting the polarized light through the second conductive layer and transmitting the polarized image signal light at a predetermined angle to the fast axis The image signal light is converted into a polarized image signal light four;

The projection lens is disposed on the transmission path of the polarized image signal light 3 and the polarized image signal light 4 for projecting the polarized image signal light 3 and the polarized image signal light 4 to image on the projection screen.

An object of the present invention is to provide a projector, including: an image signal processing device, a polarizing filter, and a projection lens;

The image signal processing device is configured to generate image signal light;

The polarizing filter is disposed on a transmission path of the image signal light generated by the image signal processing device, and includes: an electric field selector, an electric field provider, and a polarizer;

The electric field selector is configured to select a predetermined time to provide an electric field to the polarizer;

The electric field provider is configured to provide an electric field to the polarizer when the electric field selector selects to supply an electric field to the polarizer;

The polarizer includes: a first conductive layer, a liquid crystal layer, a second conductive layer, and a quarter wave plate;

The first conductive layer is configured to transmit the image signal light generated by the image signal processing device to obtain a polarized image signal light ray;

And the liquid crystal layer is bonded to the first conductive layer, and when the first conductive layer and the second conductive layer are not added with an electric field, the polarized image signal light is rotated by a predetermined angle to obtain a polarization. And oscillating the polarized image signal light obtained by the rotation; and transmitting the electric field to the first conductive layer and the second conductive layer when the electric field provider supplies the polarization Image signal light

The second conductive layer is adhered to the liquid crystal layer for transmitting a polarized image signal light transmitted through the liquid crystal layer, and a polarized image signal light 2;

The quarter-wave plate is bonded to the second conductive layer for transmitting a polarized image signal light transmitted through the second conductive layer The polarized image signal light ray 2 is transmitted through the second conductive layer; the transmitted polarized image signal light ray 2 is converted into the polarized image signal light ray 4;

The projection lens is disposed on the transmission path of the polarized image signal light 3 and the polarized image signal light 4 for projecting the polarized image signal light 3 and the polarized image signal light 4 to image on the projection screen.

The object of the present invention is to provide a stereoscopic image system, including: a projector, a projection screen, and polarized glasses;

The projector includes: an image signal processing device, a polarizing filter, and a projection lens;

The image signal processing device is configured to generate image signal light;

The polarizing filter is disposed on a transmission path of the image signal light generated by the image signal processing device, and includes: an electric field selector, an electric field provider, and a polarizer;

The electric field selector is configured to select a predetermined time to provide an electric field to the polarizer;

The electric field provider is configured to provide an electric field to the polarizer when the electric field selector selects to supply an electric field to the polarizer;

The polarizer includes: a first conductive layer, a liquid crystal layer, a second conductive layer, and a quarter wave plate;

The first conductive layer is configured to transmit the image signal light generated by the image signal processing device to obtain a polarized image signal light ray;

And the liquid crystal layer is bonded to the first conductive layer, and when the first conductive layer and the second conductive layer are not added with an electric field, the polarized image signal light is rotated by a predetermined angle to obtain a polarization. And oscillating the polarized image signal light obtained by the rotation; and transmitting the electric field to the first conductive layer and the second conductive layer when the electric field provider supplies the polarization Image signal light

The second conductive layer is adhered to the liquid crystal layer for transmitting a polarized image signal light transmitted through the liquid crystal layer, and a polarized image signal light 2;

The quarter-wave plate is bonded to the second conductive layer for transmitting a polarized image signal light transmitted through the second conductive layer The polarized image signal light ray 2 is transmitted through the second conductive layer; the transmitted polarized image signal light ray 2 is converted into the polarized image signal light ray 4;

The projection lens is disposed on the transmission path of the polarized image signal light 3 and the polarized image signal light 4, and is configured to transmit the transmitted polarized image signal light into three through the polarized image signal light Polarizing the image signal ray five, and projecting the polarized image signal ray five to image on the projection screen; transmitting the transmitted polarized image signal ray four into a polarized image signal ray through the polarized image signal ray four And projecting the polarized image signal light 6 onto the projection screen; the direction of vibration of the polarized image signal light 5 is parallel to the vibration direction of the polarized image signal light 3, and the vibration of the polarized image signal light 6 The direction is parallel to the vibration direction of the polarized image signal light four;

The projection screen is disposed on a transmission path of the polarized image signal light ray 5 and the polarized image signal light ray projected by the projection lens in the projector, and is used for reflecting the polarized image signal light ray to obtain a polarization image. Signal light VII; for reflecting the polarized image signal light six, obtaining a polarized image signal light VIII; the obtained polarized image signal light ray seven vibration direction is parallel with the polarization image signal light ray five vibration direction, the obtained The direction of vibration of the polarized image signal light eight is parallel to the direction of vibration of the polarized image signal light six;

The polarized glasses are disposed on a transmission path of the polarized image signal light 7 and the polarized image signal light 8 obtained by being reflected by the projection screen, and include: a left lens, a right lens, and a glasses frame;

The left lens is disposed on the eyeglass frame, and includes: a left lens quarter wave plate and a left lens polarizing plate;

The left lens quarter wave plate is configured to convert the transmitted polarized image signal light seven into a polarized image signal light ray through the polarized image signal light VII obtained by being reflected by the projection screen;

The left lens polarizing plate is configured to transmit the polarized image signal light IX;

The right lens is disposed on the eyeglass frame, and includes: a right lens quarter wave plate and a right lens polarizing plate;

The right lens quarter wave plate is configured to transmit the polarized image signal light eight obtained by the reflection through the projection screen into a polarized image signal light ray;

The right lens polarizing plate is configured to transmit light of the polarized image signal;

The polarity direction of the left lens polarizer is not parallel to the polarity direction of the right lens polarizer.

The projector of the present invention applies a polarizing filter to generate polarized image signal rays alternated at a predetermined time, for example, 120 frames per second, and each image frame is alternated in order, and then the projection lens converts the polarized image signal light into a vibration direction parallel and polarized. The new polarized image signal light of constant frequency, and the new polarized image signal light is reflected by the projection screen to the polarized glasses, the vibration direction of the light does not change, and the viewer can only see the corresponding lens through the left lens and the right lens of the polarized glasses. The image, that is, the viewer receives a left eye frame through the polarized glasses, the next right eye frame, then another left eye frame, and then another right eye frame, thereby generating a stereoscopic feeling in the visual nervous system to achieve viewing. The purpose of the stereoscopic image is to achieve the purpose of achieving stereoscopic images through a projector.

The stereoscopic image system of the present invention applies a projector to generate alternating polarized image signal rays at a predetermined time, such as a frequency of 120 frames per second, each image frame is alternated in order, and the generated alternating polarized image signal light is reflected to the polarized glasses through the projection screen. When the direction of vibration of the light does not change, the viewer can only see the corresponding image through the left lens and the right lens of the polarized glasses, that is, the viewer receives a left eye frame through the polarized glasses, and then a right eye frame, and then another The left eye frame, and then another right eye frame, creates a stereoscopic feeling in the visual nervous system, and achieves the purpose of viewing the stereoscopic image, thereby achieving the purpose of achieving stereoscopic images through a projector.

 [Description of the Drawings]

Figure 1 is a schematic view of a conventional projector;

2 is a schematic view of an embodiment of a conventional digital light processing projector;

3 is a schematic view of an embodiment of a conventional liquid crystal liquid crystal projector;

4 is a schematic view of an embodiment of a conventional liquid crystal projector;

Figure 5 is a schematic view of the projector of the present invention;

Figure 6 is a schematic illustration of a stereoscopic image system of the present invention.

 【detailed description】

The invention provides a projector and a stereoscopic image system, which are applied to the field of projection technology. The projector of the present invention applies a polarizing filter to generate polarized image signal light alternated at a frequency of 120 frames per second for a predetermined time, and each image frame is alternated in order. Then, the projection lens converts the polarized image signal light into a new polarized image signal light whose vibration direction is parallel and the polarization frequency is constant, and the light of the new polarized image signal is reflected by the projection screen to the polarized glasses. Will change, the viewer can only see the corresponding image through the left and right lenses of the polarized glasses, that is, the viewer receives a left eye frame through the polarized glasses, the next right eye frame, and then another left eye frame, then Another right eye frame creates a stereoscopic feeling in the visual nervous system and achieves the purpose of viewing stereoscopic images, thereby achieving the purpose of achieving stereoscopic images through a projector.

The present invention will be further described in detail below with reference to the accompanying drawings and embodiments. It is understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

The invention provides a projector.

5 is a schematic diagram of a projector according to the present invention, the projector 500 includes: an image signal processing device 501, a polarizing filter 502, a projection lens 503;

An image signal processing device 501, configured to generate image signal light;

The polarizing filter 502 is disposed on the transmission path of the image signal light generated by the image signal processing device 501, and includes: an electric field selector 5021, an electric field provider 5022, and a polarizer 5023;

An electric field selector 5021 for selecting a predetermined time to provide an electric field to the polarizer 5023;

The electric field provider 5022 is configured to provide an electric field to the polarizer 5023 when the electric field selector 5021 selects to supply an electric field to the polarizer 5023;

The polarizer 5023 includes: a first conductive layer 50231, a liquid crystal layer 50232, a second conductive layer 50233, a quarter wave plate 50234;

The first conductive layer 50231 is configured to transmit the image signal light generated by the image signal processing device 501 to obtain a linearly polarized light, that is, to obtain a polarized image signal light;

The liquid crystal layer 50232 is bonded to the first conductive layer 50231 for rotating the polarized image signal light by a predetermined angle when the first conductive layer 50231 and the second conductive layer 50233 are not added with an electric field, thereby obtaining linearly polarized light Polarized image signal light ray 2 and transmitted through the rotated polarized image signal light ray 2; when the electric field provider 5022 supplies an electric field to the first conductive layer 50231 and the second conductive layer 50233, the polarized image signal ray is transmitted through ;

The second conductive layer 50233 is adhered to the liquid crystal layer 50232 for transmitting the polarized image signal light transmitted through the liquid crystal layer 50232, and the polarized image signal light 2;

The quarter wave plate 50234 is bonded to the second conductive layer 50233 for transmitting the polarized image signal light transmitted through the second conductive layer 50233 to convert the transmitted polarized image signal light into an elliptically polarized light. Light one, that is, converted into polarized image signal light three; through the polarized image signal light transmitted by the second conductive layer 50233, the transmitted polarized image signal light is converted into elliptically polarized light two, that is, converted into polarized image signal light four;

The projection lens 503 is disposed on the transmission path of the polarized image signal light 3 and the polarized image signal light 4 for projecting the polarized image signal light 3 and the polarized image signal light 4 to image on the projection screen, including: transmitting the polarized image Signal light three, the transmitted polarized image signal light three is converted into elliptically polarized light three, that is, converted into polarized image signal light five, and the polarized image signal light is projected to the projection screen for imaging; the transmitted polarization The image signal light is converted into elliptically polarized light four, that is, converted into a polarized image signal light six, and the polarized image signal light 6 is projected onto the projection screen for imaging; the polarized image signal ray five is vibrating direction and the polarized image signal is ray three The vibrating directions are parallel, and the vibrating direction of the polarized image signal light ray is parallel to the vibrating direction of the polarized image signal ray four.

Wherein, the electric field selector 5021 selects a predetermined time, and the process of providing an electric field to the polarizer 5023 includes:

The electric field selector 5021 selects an electric field to be applied to the polarizer 5023 at N/120 seconds, where N includes odd and even numbers.

The first conductive layer 50231 includes indium tin oxide (ITO) conductive glass for transmitting the image signal light generated by the image signal processing device 501 to obtain a polarized image signal light.

The second conductive layer 50233 includes indium tin oxide ITO conductive glass, and is bonded to the liquid crystal layer 50232 for transmitting the polarized image signal light transmitted through the liquid crystal layer 50232 and the polarized image signal light.

The liquid crystal layer 50232 includes a twisted nematic (TN) type liquid crystal layer, and is bonded to the first conductive layer 50231 for rotating the polarized image signal when the first conductive layer 50231 and the second conductive layer 50233 do not add an electric field. When the light is at 90 degrees, the polarized image signal light 2 is obtained and transmitted through the rotated polarized image signal light 2; when the electric field provider 5022 supplies an electric field to the first conductive layer 50231 and the second conductive layer 50233, The polarized image signal ray one.

The liquid crystal layer 50232 includes a super twisted nematic (STN) type liquid crystal layer and is adhered to the first conductive layer 50231 for rotating the polarized image when the first conductive layer 50231 and the second conductive layer 50233 do not add an electric field. The signal light 270 degrees, the polarized image signal light 2 is obtained, and the polarized image signal light 2 obtained by the rotation is obtained; when the electric field provider 5022 provides the electric field to the first conductive layer 50231 and the second conductive layer 50233, The light of the polarized image signal is one.

The electric field selector 5021 includes a power supply gate for selecting a predetermined time to provide an electric field to the polarizer 5023.

Wherein, the electric field provider 5022 includes a power source for providing an electric field to the polarizer 5023 when the electric field selector 5021 selects to supply an electric field to the polarizer 5023.

The process of converting the transmitted polarized image signal light into the polarized image signal light by the quarter wave plate 50234 through the polarized image signal light transmitted by the second conductive layer 50233 includes:

The quarter-wave plate 50234 converts the transmitted polarized image signal light into a polarized image signal light 3 by transmitting a polarized image signal light whose vibration direction is at a predetermined angle to the fast axis.

The process of converting the transmitted polarized image signal light into the polarized image signal light by the quarter wave plate 50234 through the polarized image signal light 2 transmitted by the second conductive layer 50233 includes:

The quarter-wave plate 50234 converts the transmitted polarized image signal light into a polarized image signal light by transmitting a polarized image signal light 2 whose vibration direction is at a predetermined angle two to the fast axis.

Wherein, the quarter-wave plate 50234 transmits the polarized image signal light of the transmitted polarized image signal light into a circularly polarized light by transmitting a polarized image signal light having a 45-degree angle with the fast axis, that is, converted into a polarized image signal light. .

Wherein, the quarter wave plate 50234 transmits the polarized image signal light 2 of the polarized image signal to the circularly polarized light 2 through the polarized image signal light having the angle of the vibration direction at a 45 degree angle to the fast axis, that is, the converted into the polarized image signal light. .

The image signal processing device 501 includes: a silicon-based liquid crystal type image signal processing device for generating image signal light; or a liquid crystal image signal processing device for generating image signal light; or a digital light processing type image signal processing device, For generating image signal light; or display device for generating image signal light, the display device includes a television, a computer, a projector, a navigator, a mobile phone, a camera.

The polarization frequency of the polarization filter 502 can be the same as the playback frequency of the program source.

The alternating polarized image signal light generated by the polarizing filter 502 at a predetermined time, for example, a frequency of 120 frames per second, may be synchronized with the image signal light generated by the image signal processing device 501, and the image corresponding to the polarized image signal light. The frames alternate in order.

The projector 500 of the present invention applies the polarizing filter 502 to generate polarized image signal rays alternated at a predetermined time, for example, 120 frames per second, and the image frames are alternated in order, and then the projection lens 503 converts the polarized image signal light into a vibration direction phase. A new polarized image signal light that is parallel and has a constant polarization frequency, and the direction of vibration of the light is not changed when the new polarized image signal light is reflected to the polarized glasses through the projection screen, and the viewer can only use the left lens and the right lens of the polarized glasses. Seeing the corresponding image, that is, the viewer receives a left eye frame through the polarized glasses, the next right eye frame, then another left eye frame, and then another right eye frame, thereby generating a stereoscopic feeling in the visual nervous system. To achieve the purpose of viewing stereoscopic images, so as to achieve the purpose of viewing stereoscopic images through a projector.

The invention also provides a stereoscopic image system.

6 is a schematic diagram of a stereoscopic image system of the present invention, the stereoscopic image system 600 includes: a projector 601, a projection screen 602, and polarized glasses 603;

The projector 601 includes: an image signal processing device 6011, a polarization filter 6012, and a projection lens 6013;

The image signal processing device 6011 is configured to generate image signal light;

The polarizing filter 6012 is disposed on the transmission path of the image signal light generated by the image signal processing device 6011, and includes: an electric field selector 60121, an electric field provider 60122, and a polarizer 60123;

An electric field selector 60121 for selecting a predetermined time to provide an electric field to the polarizer 60123;

The electric field provider 60122 is configured to provide an electric field to the polarizer 60123 when the electric field selector 60121 selects to supply an electric field to the polarizer 60123;

The polarizer 60123 includes: a first conductive layer 601231, a liquid crystal layer 601232, a second conductive layer 601233, a quarter wave plate 601234;

The first conductive layer 601231 is configured to transmit the image signal light generated by the image signal processing device 6011 to obtain a linearly polarized light, that is, obtain a polarized image signal light;

The liquid crystal layer 601232 is bonded to the first conductive layer 601231, and is used to rotate the polarized image signal light by a predetermined angle when the first conductive layer 601231 and the second conductive layer 601233 do not add an electric field, thereby obtaining linearly polarized light Polarizing the image signal light 2 and transmitting the polarized image signal light 2 obtained by the rotation; when the electric field provider 60122 supplies an electric field to the first conductive layer 601231 and the second conductive layer 601233, transmitting the polarized image signal light ;

The second conductive layer 601233 is adhered to the liquid crystal layer 601232 for transmitting the polarized image signal light transmitted through the liquid crystal layer 601232, and the polarized image signal light 2;

The quarter-wave plate 601234 is bonded to the second conductive layer 601233 for transmitting the polarized image signal light transmitted through the second conductive layer 601233 to convert the transmitted polarized image signal light into an elliptically polarized light. Light one, that is, converted into polarized image signal light three; through the polarized image signal light transmitted by the second conductive layer 601233, the transmitted polarized image signal light is converted into elliptically polarized light two, that is, converted into polarized image signal light four;

The projection lens 6013 is disposed on the transmission path of the polarized image signal light 3 and the polarized image signal light 4 for projecting the polarized image signal light 3 and the polarized image signal light 4 to image on the projection screen 602, including: transmitting the polarization The image signal light three converts the transmitted polarized image signal light into three elliptically polarized light three, that is, into a polarized image signal light five, and projects the polarized image signal light five onto the projection screen 602 for imaging; The image signal light is four, and the transmitted polarized image signal light is converted into elliptically polarized light four, that is, converted into a polarized image signal light six, and the polarized image signal light 6 is projected onto the projection screen 602 for imaging; the polarized image signal The vibration direction of the light five is parallel to the vibration direction of the polarized image signal light three, and the vibration direction of the polarized image signal light six is parallel to the vibration direction of the polarized image signal light four;

The projection screen 602 is disposed on the transmission path of the polarized image signal light 5 and the polarized image signal light 6 projected by the projection lens 6013 in the projector 601, and is used for reflecting the polarized image signal light 5 to obtain elliptically polarized light five, that is, Obtaining a polarized image signal light VII; for reflecting the polarized image signal light six, obtaining elliptically polarized light six, that is, obtaining a polarized image signal light VIII; the obtained polarized image signal ray seven vibration direction and the polarization image signal ray five vibration The directions are parallel, and the obtained polarization direction of the polarized image signal light is parallel to the vibration direction of the polarized image signal light six;

The polarizing glasses 603 are disposed on the transmission path of the polarized image signal light ray 7 and the polarized image signal light ray obtained by the projection screen 602, and include: a left lens 6031, a right lens 6032, and an eyeglass frame 6033;

The left lens 6031 is disposed on the eyeglass frame 6033, and includes: a left lens quarter wave plate 60311 and a left lens polarizing plate 60312;

The left lens quarter wave plate 60311 is configured to convert the transmitted polarized image signal light into seven linearly polarized light by translating the polarized image signal light 7 obtained through the projection screen 602, that is, into a polarized image signal. Light nine

a left lens polarizing plate 60312 for transmitting the polarized image signal light nine;

The right lens 6032 is disposed on the eyeglass frame 6033, and includes: a right lens quarter wave plate 60321, a right lens polarizing plate 60322;

The right lens quarter wave plate 60321 is configured to convert the polarized image signal light eight obtained by the reflection through the projection screen 602 into a linearly polarized light, that is, into a polarized image signal. Ten rays of light;

a right lens polarizing plate 60322 for transmitting light of the polarized image signal;

The polarity direction of the left lens polarizing plate 60312 is not parallel to the polarity direction of the right lens polarizing plate 60322.

Wherein, the electric field selector 60121 selects a predetermined time, and the process of providing an electric field to the polarizer 60123 includes:

The electric field selector 60121 selects an electric field to be applied to the polarizer 60123 at N/120 seconds, where N includes an odd number and an even number.

The first conductive layer 601231 includes indium tin oxide ITO conductive glass for transmitting the image signal light generated by the image signal processing device 6011 to obtain a polarized image signal light.

The second conductive layer 601233 includes indium tin oxide ITO conductive glass, and is bonded to the liquid crystal layer 601232 for transmitting the polarized image signal light transmitted through the liquid crystal layer 601232 and the polarized image signal light.

The liquid crystal layer 601232 includes a twisted nematic TN type liquid crystal layer, and is bonded to the first conductive layer 601231, and is used to rotate the polarized image signal light when the first conductive layer 601231 and the second conductive layer 601233 do not add an electric field. At 90 degrees, a polarized image signal ray 2 is obtained, and the polarized image signal ray 2 obtained by the rotation is obtained. When the electric field provider 60122 supplies an electric field to the first conductive layer 601231 and the second conductive layer 601233, the polarization is transmitted. Image signal light one.

The liquid crystal layer 601232 includes a super twisted nematic STN type liquid crystal layer and is adhered to the first conductive layer 601231 for rotating the polarized image signal light when the first conductive layer 601231 and the second conductive layer 601233 do not add an electric field. At 270 degrees, a polarized image signal light 2 is obtained, and the polarized image signal light 2 obtained by the rotation is obtained. When the electric field provider 60122 supplies an electric field to the first conductive layer 601231 and the second conductive layer 601233, Polarized image signal light.

The electric field selector 60121 includes a power supply gate for selecting a predetermined time to provide an electric field to the polarizer 60123.

Wherein, the electric field provider 60122 includes a power source for providing an electric field to the polarizer 60123 when the electric field selector 60121 selects to supply an electric field to the polarizer 60123.

The process of converting the transmitted polarized image signal light into the polarized image signal light by the quarter wave plate 601234 through the polarized image signal light transmitted by the second conductive layer 601233 includes:

The quarter-wave plate 601234 converts the transmitted polarized image signal light into a polarized image signal light 3 by transmitting a polarized image signal light whose vibration direction is at a predetermined angle to the fast axis.

The process of converting the transmitted polarized image signal light into the polarized image signal light by the quarter wave plate 601234 through the polarized image signal light 2 transmitted by the second conductive layer 601233 includes:

The quarter-wave plate 601234 converts the transmitted polarized image signal light into a polarized image signal light by transmitting a polarized image signal light of a predetermined angle two to the fast axis.

Wherein, the quarter-wave plate 601234 converts the transmitted polarized image signal light into a circularly polarized light by transmitting a polarized image signal light having a 45-degree angle to the fast axis, thereby converting into a polarized image signal light. .

Wherein, the quarter-wave plate 601234 transmits the polarized image signal light 2 at a 45-degree angle to the fast axis of the vibration direction, and converts the transmitted polarized image signal light into a circularly polarized light 2, that is, into a polarized image signal light. .

The projection screen 602 includes a metal projection screen, which is disposed on the transmission path of the polarized image signal light 5 and the polarized image signal light 6 projected by the projection lens 6013 in the projector 601, and is used for reflecting the polarized image signal light 5 to obtain The elliptically polarized light is five, that is, the polarized image signal light ray is obtained; the light ray for reflecting the polarized image is six, and the elliptically polarized light is obtained, that is, the polarized image signal light VIII is obtained; and the obtained polarized image signal ray seven vibration direction and polarization The vibration directions of the image signal ray five are parallel, and the obtained polarization direction of the polarization image signal ray eight is parallel to the vibration direction of the polarization image signal ray 6.

The process of converting the transmitted polarized image signal light into the polarized image signal light by the left lens quarter wave plate 60311 through the polarized image signal light 7 obtained by being reflected by the projection screen 602 includes:

The left lens quarter wave plate 60311 transmits a polarized image signal light ray 7 of a predetermined angle three to the fast axis of the vibration direction, and converts the transmitted polarized image signal light ray into a polarized image signal light ray nine.

The process of converting the transmitted polarized image signal light into the polarized image signal light by transmitting the polarized image signal light eight obtained by the right lens quarter wave plate 60321 through the projection screen 602 includes:

The right lens quarter-wave plate 60321 transmits a polarized image signal light ray eight at a predetermined angle to the fast axis by the vibration direction, and converts the transmitted polarized image signal light VIII into a polarized image signal ray ten.

The process of transmitting the light of the polarized image signal by the left lens polarizing plate 60312 includes:

The polar direction is at a predetermined angle three with the fast axis of the left lens quarter wave plate 60311 for transmitting the polarized image signal light nine; or the polarity direction is parallel to the vibration direction of the polarized image signal light nine, The light is transmitted through the polarized image signal nine.

The process of transmitting the light of the polarized image signal by the right lens polarizing plate 60322 includes:

The polar direction is at a predetermined angle four with the fast axis of the right lens quarter wave plate 60321 for transmitting the polarized image signal light ten; or the polarity direction is parallel to the vibration direction of the polarized image signal light ten, Ten rays are transmitted through the polarized image signal.

Wherein, the left lens quarter-wave plate 60311 transmits the polarized image signal light ray 7 at a 45-degree angle to the fast axis of the vibration direction, and converts the transmitted polarized image signal light ray into a polarized image signal ray nine.

Wherein, the right lens quarter wave plate 60321 transmits the polarized image signal light eight at a 45 degree angle to the fast axis of the vibration direction, and converts the transmitted polarized image signal light into eight into the polarized image signal light.

Wherein, the polar direction of the left lens polarizing plate 60312 is at a 45 degree angle with the fast axis of the left lens quarter wave plate 60311, for transmitting the polarized image signal light nine; or the polar direction and the polarized image signal light nine The vibration directions are parallel and are used to transmit the polarized image signal light nine.

Wherein, the polar direction of the right lens polarizing plate 60322 is at a 45 degree angle with the fast axis of the right lens quarter wave plate 60321, for transmitting the polarized image signal light ray; or the polar direction and the polarized image signal light ray ten The vibration directions are parallel and are used to transmit light through the polarized image signal.

The image signal processing device 6011 includes: a silicon-based liquid crystal type image signal processing device for generating image signal light; or a liquid crystal image signal processing device for generating image signal light; or a digital light processing type image signal processing device, For generating image signal light; or display device for generating image signal light, the display device includes a television, a computer, a projector, a navigator, a mobile phone, a camera.

The polarization frequency of the polarization filter 6012 may be the same as the playback frequency of the program source.

The alternating polarized image signal light generated by the polarizing filter 6012 at a frequency of 120 frames per second for a predetermined time may be synchronized with the image signal light generated by the image signal processing device 6011, and each image corresponding to the polarized image signal light The frames alternate in order.

The stereoscopic image system 600 of the present invention applies the projector 601 to generate alternating polarized image signal rays at a predetermined time, such as a frequency of 120 frames per second, each image frame is alternated in order, and the generated alternating polarized image signal light is reflected by the projection screen 602. When the polarized glasses 603 are not changed, the direction of vibration of the light does not change. The viewer can only see the corresponding image through the polarized glasses 603, the left lens 6031 and the right lens 6032, that is, the viewer receives a left eye frame through the polarized glasses 603, and then A right eye frame, then another left eye frame, and then another right eye frame, thereby generating a stereoscopic feeling in the visual nervous system, thereby achieving the purpose of viewing the stereoscopic image, thereby achieving the realization of viewing stereoscopic images through a projector. purpose.

For the projector and stereoscopic image system of the present invention, the form of implementation is varied. Any modifications, equivalent substitutions, improvements, etc. made within the spirit and scope of the present invention are intended to be included within the scope of the present invention.

Claims (15)

1. A projector, comprising: an image signal processing device, a polarizing filter, and a projection lens;

   The image signal processing device is configured to generate image signal light;

   The polarizing filter is disposed on a transmission path of the image signal light generated by the image signal processing device, and includes: an electric field selector, an electric field provider, and a polarizer;

   The electric field selector is configured to select a predetermined time, and when the electric field selector selects N/120 seconds, an electric field is provided to the polarizer, wherein the N includes an odd number and an even number;

   The electric field provider is configured to provide an electric field to the polarizer when the electric field selector selects to supply an electric field to the polarizer;

   The polarizer includes: a first conductive layer, a liquid crystal layer, a second conductive layer, and a quarter wave plate;

   The first conductive layer is configured to transmit the image signal light generated by the image signal processing device to obtain a polarized image signal light ray;

   And the liquid crystal layer is bonded to the first conductive layer, and when the first conductive layer and the second conductive layer are not added with an electric field, the polarized image signal light is rotated by a predetermined angle to obtain a polarization. Image signal light II Passing through the rotated polarized image signal light 2; and transmitting the polarized image signal light when the electric field provider supplies an electric field to the first conductive layer and the second conductive layer ;

   The second conductive layer is adhered to the liquid crystal layer for transmitting a polarized image signal light transmitted through the liquid crystal layer, and a polarized image signal light 2;

   The quarter-wave plate is bonded to the second conductive layer for transmitting a polarized image signal light having a direction of vibration transmitted through the second conductive layer at a predetermined angle to the fast axis thereof. Converting the transmitted polarized image signal light into a polarized image signal light 3; transmitting the polarized light through the second conductive layer and transmitting the polarized image signal light at a predetermined angle to the fast axis The image signal light is converted into a polarized image signal light four;

   The projection lens is disposed on the transmission path of the polarized image signal light 3 and the polarized image signal light 4 for projecting the polarized image signal light 3 and the polarized image signal light 4 to image on the projection screen.
2. The projector according to claim 1, wherein said quarter-wave plate transmits a polarized image signal light having a 45-degree angle to a direction of a vibration thereof, and converts the transmitted polarized image signal light into a light. For circularly polarized light, it is converted into polarized image signal light three;

   The quarter-wave plate transmits a polarized image signal light 2 whose angle of vibration is at a 45-degree angle to the fast axis, and converts the transmitted polarized image signal light into two into a circularly polarized light, and is converted into a polarized image signal light.
3. The projector according to claim 1, wherein said image signal processing device comprises: a liquid crystal on silicon type image signal processing device for generating image signal light; or a liquid crystal type image signal processing device for generating Image signal light; or a digital light processing type image signal processing device for generating image signal light; or a display device for generating image signal light, the display device including a television, a computer, a projector, a navigator, a mobile phone, a camera .
4. A projector, comprising: an image signal processing device, a polarizing filter, and a projection lens;

   The image signal processing device is configured to generate image signal light;

   The polarizing filter is disposed on a transmission path of the image signal light generated by the image signal processing device, and includes: an electric field selector, an electric field provider, and a polarizer;

   The electric field selector is configured to select a predetermined time to provide an electric field to the polarizer;

   The electric field provider is configured to provide an electric field to the polarizer when the electric field selector selects to supply an electric field to the polarizer;

   The polarizer includes: a first conductive layer, a liquid crystal layer, a second conductive layer, and a quarter wave plate;

   The first conductive layer is configured to transmit the image signal light generated by the image signal processing device to obtain a polarized image signal light ray;

   And the liquid crystal layer is bonded to the first conductive layer, and when the first conductive layer and the second conductive layer are not added with an electric field, the polarized image signal light is rotated by a predetermined angle to obtain a polarization. Image signal light II Passing through the rotated polarized image signal light 2; and transmitting the polarized image signal light when the electric field provider supplies an electric field to the first conductive layer and the second conductive layer ;

   The second conductive layer is adhered to the liquid crystal layer for transmitting a polarized image signal light transmitted through the liquid crystal layer, and a polarized image signal light 2;

   The quarter-wave plate is bonded to the second conductive layer for transmitting a polarized image signal light transmitted through the second conductive layer The polarized image signal light ray 2 is transmitted through the second conductive layer; the transmitted polarized image signal light ray 2 is converted into the polarized image signal light ray 4;

   The projection lens is disposed on the transmission path of the polarized image signal light 3 and the polarized image signal light 4 for projecting the polarized image signal light 3 and the polarized image signal light 4 to image on the projection screen.
5. The projector according to claim 4, wherein said quarter-wave plate transmits a polarized image signal light of a predetermined angle to a direction of a vibration axis thereof, and converts the transmitted polarized image signal light into a light. Polarization map Like signal light three;

   The quarter-wave plate transmits a polarized image signal light 2 whose vibration direction is at a predetermined angle to the fast axis, and converts the transmitted polarized image signal light into a polarized image signal light four.
6. The projector according to claim 4, wherein said quarter-wave plate transmits a polarized image signal light having a 45-degree angle to a direction of a vibration thereof, and converts the transmitted polarized image signal light into a light. For circularly polarized light, it is converted into polarized image signal light three;

   The quarter-wave plate transmits a polarized image signal light 2 whose angle of vibration is at a 45-degree angle to the fast axis, and converts the transmitted polarized image signal light into two into a circularly polarized light, and is converted into a polarized image signal light.
7. The projector of claim 4 wherein said electric field selector selects to provide an electric field to said polarizer at N/120 seconds, said N comprising an odd number, an even number.
8. The projector according to claim 4, wherein said image signal processing device comprises: a liquid crystal on silicon type image signal processing device for generating image signal light; or a liquid crystal type image signal processing device for generating Image signal light; or a digital light processing type image signal processing device for generating image signal light; or a display device for generating image signal light, the display device including a television, a computer, a projector, a navigator, a mobile phone, a camera .
9. A stereoscopic image system, comprising: a projector, a projection screen, and polarized glasses;

   The projector includes: an image signal processing device, a polarizing filter, and a projection lens;

   The image signal processing device is configured to generate image signal light;

   The polarizing filter is disposed on a transmission path of the image signal light generated by the image signal processing device, and includes: an electric field selector, an electric field provider, and a polarizer;

   The electric field selector is configured to select a predetermined time to provide an electric field to the polarizer;

   The electric field provider is configured to provide an electric field to the polarizer when the electric field selector selects to supply an electric field to the polarizer;

   The polarizer includes: a first conductive layer, a liquid crystal layer, a second conductive layer, and a quarter wave plate;

   The first conductive layer is configured to transmit the image signal light generated by the image signal processing device to obtain a polarized image signal light ray;

   And the liquid crystal layer is bonded to the first conductive layer, and when the first conductive layer and the second conductive layer are not added with an electric field, the polarized image signal light is rotated by a predetermined angle to obtain a polarization. Image signal light II Passing through the rotated polarized image signal light 2; and transmitting the polarized image signal light when the electric field provider supplies an electric field to the first conductive layer and the second conductive layer ;

   The second conductive layer is adhered to the liquid crystal layer for transmitting a polarized image signal light transmitted through the liquid crystal layer, and a polarized image signal light 2;

   The quarter-wave plate is bonded to the second conductive layer for transmitting a polarized image signal light transmitted through the second conductive layer The polarized image signal light ray 2 is transmitted through the second conductive layer; the transmitted polarized image signal light ray 2 is converted into the polarized image signal light ray 4;

   The projection lens is disposed on the transmission path of the polarized image signal light 3 and the polarized image signal light 4, and is configured to transmit the transmitted polarized image signal light into three through the polarized image signal light Polarizing the image signal ray five, and projecting the polarized image signal ray five to image on the projection screen; transmitting the transmitted polarized image signal ray four into a polarized image signal ray through the polarized image signal ray four And projecting the polarized image signal light 6 onto the projection screen; the direction of vibration of the polarized image signal light 5 is parallel to the vibration direction of the polarized image signal light 3, and the vibration of the polarized image signal light 6 The direction is parallel to the vibration direction of the polarized image signal light four;

   The projection screen is disposed on a transmission path of the polarized image signal light ray 5 and the polarized image signal light ray projected by the projection lens in the projector, and is used for reflecting the polarized image signal light ray to obtain a polarization image. Signal light VII; for reflecting the polarized image signal light six, obtaining a polarized image signal light VIII; the obtained polarized image signal light ray seven vibration direction is parallel with the polarization image signal light ray five vibration direction, the obtained The direction of vibration of the polarized image signal light eight is parallel to the direction of vibration of the polarized image signal light six;

   The polarized glasses are disposed on a transmission path of the polarized image signal light 7 and the polarized image signal light 8 obtained by being reflected by the projection screen, and include: a left lens, a right lens, and a glasses frame;

   The left lens is disposed on the eyeglass frame, and includes: a left lens quarter wave plate and a left lens polarizing plate;

   The left lens quarter wave plate is configured to convert the transmitted polarized image signal light seven into a polarized image signal light ray through the polarized image signal light VII obtained by being reflected by the projection screen;

   The left lens polarizing plate is configured to transmit the polarized image signal light IX;

   The right lens is disposed on the eyeglass frame, and includes: a right lens quarter wave plate and a right lens polarizing plate;

   The right lens quarter wave plate is configured to transmit the polarized image signal light eight obtained by the reflection through the projection screen into a polarized image signal light ray;

   The right lens polarizing plate is configured to transmit light of the polarized image signal;

   The polarity direction of the left lens polarizer is not parallel to the polarity direction of the right lens polarizer.
10. The stereoscopic image system according to claim 9, wherein the quarter-wave plate transmits a polarized image signal light having a predetermined angle of one to a direction of the vibration axis, and the transmitted polarized image signal light is Into Polarized image signal light three;

    The quarter-wave plate transmits a polarized image signal light 2 whose vibration direction is at a predetermined angle to the fast axis, and converts the transmitted polarized image signal light into a polarized image signal light four.
11. The stereoscopic image system according to claim 9, wherein the quarter-wave plate transmits a polarized image signal light having a direction of a 45-degree angle to a fast axis thereof, and transmits a polarized image signal light. Converted to circularly polarized light one, converted into polarized image signal light three;

    The quarter-wave plate transmits a polarized image signal light 2 whose angle of vibration is at a 45-degree angle to the fast axis, and converts the transmitted polarized image signal light into two into a circularly polarized light, and is converted into a polarized image signal light.
12. The stereoscopic image system according to claim 9, wherein the left-eye quarter-wave plate transmits a polarized image signal light VII that is at a predetermined angle of three with respect to the fast axis, and the transmitted polarized image signal Light seven Converted to polarized image signal light nine;

    The quarter-wave plate of the right lens transmits a polarized image signal light ray of a predetermined angle of four with a direction of vibration of the right lens, and converts the transmitted polarized image signal light into eight ray of the polarized image signal;

    The left lens polarizing plate has a polarity direction at a predetermined angle three with respect to a fast axis of the left lens quarter wave plate for transmitting the polarized image signal light nine; or a polarity direction and the polarization image The vibration direction of the signal light nine is parallel, for transmitting the polarized image signal light nine;

    The right lens polarizing plate has a polarity direction at a predetermined angle four with a fast axis of the right lens quarter wave plate for transmitting light of the polarized image signal; or a polarity direction and the polarization image The vibration directions of the signal light ten are parallel, and are used to transmit the light of the polarized image signal.
13. The stereoscopic image system according to claim 12, wherein said left-eye quarter-wave plate transmits a polarized image signal light seven at a 45-degree angle to a fast axis of the vibration direction, and the transmitted polarized image signal Seven turns of light Become polarized image signal light nine;

    The quarter-wave plate of the right lens transmits a polarized image signal light eight at a 45-degree angle to the fast axis of the right lens, and converts the transmitted polarized image signal light into eight into a polarized image signal light;

    The left lens polarizing plate has a polarity direction at a 45 degree angle with a fast axis of the left lens quarter wave plate for transmitting the polarized image signal light nine; or a polarity direction and the polarization image The vibration direction of the signal light nine is parallel, for transmitting the polarized image signal light nine;

    The right lens polarizing plate has a polarity direction at a 45 degree angle with a fast axis of the right lens quarter wave plate for transmitting light of the polarized image signal; or a polarity direction and the polarization image The vibration directions of the signal light ten are parallel, and are used to transmit the light of the polarized image signal.
14. The stereoscopic image system of claim 9 wherein said electric field selector selects to provide an electric field to said polarizer at N/120 seconds, said N comprising an odd number, an even number.
15. The stereoscopic image system according to claim 9, wherein the image signal processing device comprises: a silicon-based liquid crystal type image signal processing device for generating image signal light; or a liquid crystal type image signal processing device for Generating image signal light; or digital light processing type image signal processing device for generating image signal light; or display device for generating image signal light, the display device including a television, a computer, a projector, a navigator, a mobile phone, camera.

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