KR100890301B1 - Apparatus capable of adjusting the color characteristic for the display system using the diffractive optical modulator and method thereof - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a color characteristic adjusting apparatus and method for changing the color characteristics of an image displayed on a screen in response to a request for a change in color characteristics input from a user in a display system using a diffractive optical modulator.

Diffraction type optical modulator, color characteristic, lower electrode, reference voltage, characteristic change

Description

Apparatus capable of adjusting the color characteristic for the display system using the diffractive optical modulator and method

1 is a perspective view of an open hole-based diffractive optical modulator according to the prior art.

2 is a plan view of the open hole-based diffractive optical modulator of FIG.

3 is a block diagram of a portable terminal including an optical modulator projector having a color characteristic adjusting device according to an embodiment of the present invention.

4 is a block diagram of a color characteristic adjusting apparatus in a display system using a diffractive optical modulator according to an embodiment of the present invention.

FIG. 5A shows a structure of image data of one frame composed of 480 X 640 pixels, and FIG. 5B is a structure diagram in which the input image data is transposed from the horizontal arrangement to the longitudinal arrangement.

6 is a graph showing the light intensity of the diffracted light versus the applied voltage in the diffractive optical modulator.

7 is a voltage vs. light intensity graph applied for each element of a diffractive optical modulator.

8 is a graph showing applied voltage versus average light intensity applied to a diffractive optical modulator.

9 is a correction table stored in the correction data storage unit for each element.

10 is a graph for explaining a process of calculating correction data for each element.

11 is a graph for explaining changes in light intensity by adjusting a lower electrode reference voltage.

12 is a flowchart of a method for adjusting color characteristics in a display system using a diffractive optical modulator according to an embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

316: baseband processor 318: image sensor module processor

320: display unit 330: light modulation projector

340: projection control unit 350: light modulation optical system

351: light source system 351R, 351G, 351B: light source

351S: condenser 352: illumination optics

353 diffraction optical modulator 354 Schullen optics

355: projection optical unit 356: scanning unit

357: drive integrated circuit 360: screen

400: portable terminal control system 402: video input unit

404: gamma reference voltage storage unit 406: image correction unit

408: correction data storage unit for each element 410: image data / synchronization signal output unit

412: upper electrode voltage range adjusting unit 414: lower electrode voltage adjusting unit

416: light source control unit 418: scanning control unit

422: light modulator driving circuit 424: light source driving circuit

426: scanner driving circuit

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a color characteristic adjusting apparatus and method for changing the color characteristics of an image displayed on a screen in response to a request for a change in color characteristics input from a user in a display system using a diffractive optical modulator.

As a next-generation display device, various flat panel displays (FPDs) are being actively researched. Among them, generalized display devices include liquid crystal displays (LCDs) using electro-optical characteristics of liquid crystals, and gases. And a plasma display panel (PDP) using discharge.

Among them, a liquid crystal display device (hereinafter, abbreviated as "LCD") has a narrow viewing angle and a slow response time, and requires a thin film transistor (TFT) and an electrode using a semiconductor manufacturing process. There is a difficulty.

Plasma display panel (PDP) has the advantage that the manufacturing process is simple and advantageous to large area, but the power consumption is large, and the discharge and luminous efficiency is low and expensive.

The development of a new display device that can solve the problems of the flat panel display device is in progress, and recently, the pixel (Pixel) using a micro electromechanical system (hereinafter, abbreviated as "MEMS") is an ultra-fine processing technology. A display device capable of displaying an image by forming a fine spatial light modulator (SLM) has been proposed.

Here, the spatial light modulator (SLM) is a converter for modulating the incident light beams in a spatial pattern corresponding to the electrical or optical input. Incident light can be modulated in its phase, intensity, polarization or direction, and light modulation can be achieved by various materials with various electro-optic or magneto-optic effects, and by materials that modulate the light by surface modification. have.

1 is a perspective view of an open hole-based diffractive light modulator according to the prior art.

Referring to the drawings, the open hole-based diffractive light modulator according to the prior art includes a substrate 101.

In addition, the open hole-based diffractive light modulator includes an insulating layer 102 formed on the substrate 101.

In addition, the open-hole-based diffraction type optical modulator is formed in a portion of the insulating layer 102, and the space between the holes 106aa to 106nb of the upper reflectors 106a to 106n and the upper reflectors 106a to 106n. It includes a lower reflector 103 for reflecting the light incident through the.

In addition, the open hole-based diffractive optical modulator has a pair of side support members 104 and 104 'formed at positions spaced apart from each other on the surface of the substrate 101 with the lower reflector 103 positioned therebetween. It is included.

In addition, the open-hole-based diffractive optical modulator is supported on both sides by a pair of side support members 104 and 104 ', and is spaced apart from the substrate 101, and the center portion is movable up and down. Holes (not shown) corresponding to the holes 106aa to 106nb formed in the 106a to 106n are formed, and include a plurality of laminate supporting plates 105a to 105n forming an array.

In addition, the open-hole-based diffraction type optical modulator is formed at the center portion of the laminate supporting plates 105a to 105n and has holes 106aa to 106nb at the center to reflect some of the incident light and some to holes 106aa. Top reflectors 106a to 106n passing through ˜106nb) and forming an array.

In addition, the open-hole-based diffraction type optical modulators are formed on the laminate support plates 106a to 106n and are spaced apart from each other, and are positioned on the side support members 104 and 104 ', and the laminate support plates 106a to 106n are disposed. A plurality of pairs of piezoelectric bodies 110a to 110n and 110a 'to 110n' for moving up and down are provided.

Here, the pair of piezoelectric materials 110a to 110n and 110a 'to 110n' include lower electrode layers 110aa to 110na and 110aa 'to 110na', piezoelectric material layers 110ab to 110nb and 110ab to 110nb ', and upper electrode layers 110ac. When the voltage is applied to ˜110 nc 110 ac Accordingly, the upper reflection parts 106a to 106n also move up and down.

On the other hand, when light is incident on the upper reflecting portions 106a to 106n of the open hole diffraction type optical modulator, the upper reflecting portions 106a to 106n reflect some light and some of the light through the holes 106aa to 106nb. The lower reflector 103 reflects the light passed through the holes 106aa to 106nb of the upper reflector 106a to 106n.

As a result, the reflected light reflected by the upper reflector 106a to 106n and the reflected light reflected by the lower reflector 103 form diffracted light having various diffraction coefficients, and the light intensity of the diffracted light is determined by the upper reflector 106a. 106n) and the step difference between the lower reflector 103 become maximum when the wavelength of the incident light becomes λ, and becomes an odd multiple of λ / 4, and becomes a minimum when the even multiple becomes even.

Here, one upper reflector 106a and a lower reflector 103 corresponding thereto may form scanning diffraction point light for forming pixels of an image formed on the screen. To describe this in more detail, referring to FIG. 2, a diffractive optical modulator includes a, b, c, c, d, e, ..., nth pixels of an image formed on a screen. N upper reflection parts 106a to 106n corresponding to each of the pixels. Referring to the diffractive light modulator with reference to one upper reflector of reference numeral 106a, the reflected light reflected from the reflecting surfaces 106a1, 106a2, and 106a3 of the upper reflector 106a and the open hole 107a1 of the upper reflector 106a. , 107a2, 107a3-, where 107a3 is the distance between the upper reflector 106a and the adjacent upper reflector 106b) so that the reflected light reflected by the lower reflector 103 forms diffracted light. The diffracted light becomes scanning diffracted point light corresponding to the pixels of the image formed on the screen.

That is, each of the upper reflectors 106a to 106n forms a scanning diffraction point light corresponding to the pixel of the image formed on the screen together with the reflection surface of the lower reflector 103 corresponding thereto. Aligned in line to form a scan line (here, the scan line is assumed to be composed of n scanning diffraction point lights corresponding to n pixels).

On the other hand, the diffraction type optical modulator described above can be used in various applications, for example, it can be used in a display device.

In the display device using such a diffractive light modulator, the light intensity of the diffracted light projected on the screen is adjusted to be always constant with respect to the input image.

However, in a display device using a diffractive light modulator, the brightness of external light and the like may be changed from time to time according to the surrounding environment, and thus, the light intensity of the diffracted light projected on the screen and the brightness of external light and the like are inconsistent.

Accordingly, the present invention has been made to solve the above problems, and can respond to the user's request to change the color characteristics of the display system using a diffractive optical modulator to actively cope with changes in the brightness of the external light. It relates to a color characteristic adjusting apparatus and a method thereof.

The apparatus of the present invention for achieving the above object comprises a light source system, a first reflecting portion and a second reflecting portion spaced apart from the first reflecting portion and varying in proximity distance, and the first reflecting portion and the first reflecting portion. 2. An optical system including a diffraction type optical modulator in which the reflected light reflected from the reflector generates diffracted light and the light intensity of the diffracted light is determined according to a distance between the first reflector and the second reflector. An input unit; An input unit configured to receive a color characteristic change request from a user; Outputs the image data received from the image input unit, and adjusts the distance between the first reflecting unit and the second reflecting unit of the diffractive optical modulator required according to the image data when the input unit receives a color characteristic change request from the user. Image output unit for outputting; And an optical modulator driving circuit driving the proximity distance of the first reflecting unit and the second reflecting unit of the diffractive optical modulator according to the adjusted proximity distance output from the image output unit when the image data is input from the image output unit. Characterized in that made.

In addition, the present invention comprises a light source system, a first reflecting portion and a second reflecting portion spaced from the first reflecting portion and the proximity distance is variable, the reflected light reflected from the first reflecting portion and the second reflecting portion is An optical system including a diffraction type optical modulator for generating diffracted light and determining the light intensity of diffracted light according to the proximity distance between the first reflector and the second reflector, wherein (a) an image input unit receives image data and outputs an image. Outputting the image data received by the image input unit to an optical modulator driving circuit; (b) the optical modulator driving circuit displaying the image by driving the diffractive optical modulator according to the input image data; (c) an input unit receiving a color characteristic change request from a user; And (d) when the image output unit receives a color characteristic change request from the user through the input unit, adjusts the distance between the first reflecting unit and the second reflecting unit of the diffractive optical modulator according to the image data, thereby adjusting the diffraction. It characterized in that it comprises a step of outputting to the fluorescent modulator drive circuit.

3, a color characteristic adjusting apparatus and a method thereof in a display system using a diffractive optical modulator according to an exemplary embodiment of the present invention will be described in detail with reference to FIG. 3.

Here, an example of a display apparatus using a diffraction type optical modulator (also referred to as an optical modulator projector) used in a portable terminal among the display apparatus using a diffraction type optical modulator will be described.

In addition, although a mobile projector is described in the present invention, the present invention is not limited thereto, and may be used in a portable device including a PDAG, an MP3 unit, a Monmon clock, a laptop computer, a camera, and the like. Thus, the term "portable terminal" hereinafter includes both the above-mentioned portable device and similar devices.

3 is a block diagram of a portable terminal including an optical modulator projector having a color characteristic adjusting apparatus according to an embodiment of the present invention, and FIG. 4 is a display system using a diffraction type optical modulator according to an embodiment of the present invention. 12 is a configuration diagram of a color characteristic adjusting apparatus, and FIG. 12 is a flowchart of a color characteristic adjusting method in a display system using a diffractive optical modulator according to an exemplary embodiment of the present invention.

As shown in FIG. 3, a portable terminal including an optical modulator projector equipped with a color characteristic adjusting device according to an embodiment of the present invention includes a wireless communication unit 310 for performing wireless communication, and requires information from a user. And an input unit 312 that receives a color characteristic change request from a user.

In addition, the portable terminal may be configured to display the image data stored in the memory 314, the memory 314, etc., which store the image data, on the display unit 320, or in the optical modulator projector 330, which is a display system using a diffractive optical modulator. The projection controller 340 controls the image data to be projected on the screen 360, and if the user wants to provide a color characteristic change menu, the color characteristic change menu is provided, and the user uses the input unit 312 to perform color characteristics. And a baseband processor 316 for controlling the projection control unit 340 of the optical modulator projector 330 to change the color characteristics of the screen in response to such a request.

In addition, the portable terminal processes the image input from the provided camera or the like and receives the image image data from the image sensor module processor 318 and the base band processor 316 to transmit the processed image image data to the base band processor 316. The display unit 320 displays a received image on the screen and receives a menu window screen of the color change menu from the baseband processor 316 to provide a color change menu window to the user.

In addition, the portable terminal generates an image according to the image data received from the baseband processor 316 by using the diffraction type optical modulator 310 under the control of the baseband processor 316 and then enlarges the generated image image. And an optical modulator projector 330 projecting onto the screen 360. Here, the baseband processor 316 may be referred to as a portable terminal control system 400.

Herein, the optical modulator projector 330 may use the optical modulation optical system 350 to generate an image according to the image image data input from the base band processor 316 according to a control signal input from the base band processor 316. And a projection control unit 340 for controlling the 350 and changing the color characteristics of the screen when the user wants to change the color characteristics of the screen and receives the color characteristic change control signal from the baseband processor 316 accordingly. The optical modulation system 350 generates an image image according to a control signal input from the projection controller 340, enlarges the generated image image, and projects the image image onto the screen 360.

As shown in FIG. 4, the projection control unit 340 includes an image input unit 402, an image correction unit 406, a gamma reference voltage storage unit 404, an image compensator 406, and an element-specific correction data storage unit. 408, image data / synchronization signal output unit 410, upper electrode voltage range adjusting unit 412, lower electrode voltage adjusting unit 414, light source control unit 416, scanning control unit 418, optical modulator driving circuit 422 ), A light source driving circuit 424, and a scanner driving circuit 426. Here, the gamma reference voltage storage unit 404, image correction unit 406, element-specific correction data storage unit 408, upper electrode voltage range adjustment unit 412, lower electrode voltage adjustment unit 414, image data / The synchronization signal output unit 410 may be referred to as an image output unit. In addition, the upper electrode voltage range adjusting unit 412 and the lower electrode voltage adjusting unit 414 may be viewed as reference voltage output units.

The image input unit 402 performs an interface function between the optical modulation optical system 350 and the portable terminal control system.

The image input unit 402 of the projection controller 340 receives image image data from the baseband processor 316, and simultaneously receives a vertical synchronization signal Vsync and a horizontal synchronization signal Hsync.

In addition, the image correction unit 406 of the projection control unit 340 performs data transpose (or image pivoting) for converting the image image data arranged in the horizontal direction in the longitudinal direction and inputted in the horizontal direction. The video image data is converted into vertical video image data and output. The reason why data transpose is necessary in the image correction unit 406 is that the scan line output from the diffractive optical modulator 353 corresponds to a plurality of pixels (for example, 480 pixels when the input image data is 480 * 640). This is because the scanning diffraction point lights are arranged vertically so as to scan and display in the horizontal direction.

That is, as shown in Fig. 5A, the standard image data is aligned in the lateral direction. However, the diffractive light modulator 353 has a plurality of upper reflectors arranged in the longitudinal direction as shown in Fig. 2, so that the plurality of image data are displayed while being scanned in the transverse direction.

Therefore, in order to form an image of one frame composed of 480 x 640 pixels by scanning the scanning line using the diffractive optical modulator 353, 480 longitudinally arranged data are required.

In other words, Fig. 5A shows the structure of the image data of one frame composed of 480 X 640 pixels. The image data shown in Fig. 5A is input from the outside in the transverse direction, that is, in the order of (0,0), (0,1), (0,2), (0,3).

However, since 480 longitudinally arranged data are required using the diffractive optical modulator 353, as shown in Fig. 5B, the input image data must be transposed from the transverse arrangement to the longitudinal arrangement. .

The image correction unit 406 sequentially outputs the data transposed image data from the first column to the last column during the scanning time.

At this time, the image correction unit 406 performs correction according to the element-specific correction data table stored in the element-specific correction data storage unit 408 with respect to the image data and corrects the image data corrected by the image data / synchronous signal output unit 410. Will output

On the other hand, the gamma reference voltage storage unit 404 stores the upper electrode (gamma) reference voltage and the lower electrode (gamma) reference voltage, wherein the upper electrode (gamma) reference voltage is the light of the diffractive optical modulator 353 The upper electrode reference voltage referred to when the modulator driving circuit 422 outputs an applied voltage according to the gray level of image data for each element. The lower electrode reference voltage is applied to the lower electrode of the diffractive optical modulator 353. Refers to the voltage.

The gamma reference voltage storage unit 404 stores the upper electrode reference voltage and the lower electrode reference voltage for reference when the optical modulator driving circuit 422 of the diffractive optical modulator 353 outputs an applied voltage according to the gray level. The reason for this is that the gamma characteristic of Fig. 6, in which the light intensity of the diffracted light emitted from the diffractive light modulator 353 does not change linearly but varies linearly with the voltage level of the applied voltage, is represented. Referring to the light intensity hysteresis curve of FIG. 6, the light intensity desired to be obtained varies linearly, ie, P1, P2... When PN makes the interval constant, the applied voltage to be applied is R1, R2... Since Rn does not have a constant interval and exhibits nonlinearity, the optical modulator driving circuit 422 of the diffractive optical modulator 353 stores the upper electrode reference voltage and the lower electrode reference voltage in the gamma reference voltage storage unit 404. It is necessary to refer to it when outputting the applied voltage according to the gray level.

In addition, the upper electrode reference voltage and the lower electrode reference voltage stored in the gamma reference voltage storage unit 404 are determined for each light source. For example, the R upper electrode reference voltages of R1 to Rn for the R light source, and G The G upper electrode reference voltages of G1 to Gn are determined for the light source, and the B upper electrode reference voltages of B1 to Bn are determined for the B light source. In this case, the upper electrode reference voltage stored in the gamma reference voltage storage unit 404 may store the minimum upper electrode reference voltage and the maximum upper electrode reference voltage for each light source. That is, the upper electrode reference voltage stored in the gamma reference voltage storage unit 404 may store only its minimum and maximum values.

In such a situation, the optical modulator driving circuit 422 receives the upper electrode voltage corresponding to the gray level of the image data from the image data / synchronous signal output unit 410 through the upper electrode voltage range adjusting unit 412. An upper electrode voltage corresponding to the corresponding gray level is obtained by referring to the provided upper electrode reference voltage. In this case, the upper electrode voltage range adjusting unit 412 reads the upper electrode reference voltage stored in the gamma reference voltage storage unit 404 and outputs the read upper electrode reference voltage to the optical modulator driving circuit 422. At the same time, the lower electrode voltage is provided to the diffractive optical modulator 353 from the lower electrode voltage adjusting unit 414. That is, the lower electrode voltage adjusting unit 414 reads the lower electrode reference voltage stored in the gamma reference voltage storage unit 404 and provides the lower electrode reference voltage to the lower electrode of the diffractive optical modulator 353.

Accordingly, the diffraction type optical modulator 353 is driven by the upper electrode voltage provided by the optical modulator driving circuit 422 and the lower electrode voltage provided by the lower electrode voltage adjusting unit 414 to modulate the incident light incident to the diffracted light. To form.

On the other hand, when the upper electrode reference voltage and the lower electrode reference voltage when the diffractive optical modulator 353 is manufactured, the light intensity detector (for example, a photo center, etc.) is repeatedly operated after the diffractive optical modulator 353 is repeatedly driven in a predetermined voltage range. By using the light intensity for each element, and as shown in Figure 6 it is obtained by configuring the light intensity hysteresis curve for each element accordingly. An example of the light intensity hysteresis curves for three different elements obtained at this time is shown in FIG. 7. In the case of element 1, the voltage having the smallest light intensity is Vp1min, and the voltage having the light intensity is Vp1max, and element 2 In the case of, the voltage with the smallest light intensity is Vp2min, for the voltage with the highest light intensity, Vp2max. For element 3, the voltage with the smallest light intensity is Vp3min and for the largest voltage, Vp3max.

In this case, the tester may set the upper electrode reference voltage range to include the lowest voltage capable of detecting the smallest light intensity of all elements and the highest voltage capable of detecting the greatest light intensity. For example, in FIG. , Vtmax is determined.

As such, when the tester inputs the selected upper electrode reference voltage to the gamma reference voltage storage unit 404, the input upper electrode reference voltage is stored in the gamma reference voltage storage unit 404.

The element-specific correction data stored in the element-specific correction data calculator 408 is referred to by the image corrector 406 to correct the image data input from the image input unit 402 to generate corrected output image data. It may be written in a table as shown in FIG.

Referring to the correction data table of FIG. 9, it can be seen that there is an external input image gray level (input image image data), and the corrected image gray level (corrected output image image data) for each element is determined for each element.

For example, in the case of Element 1, if the input image gradation is 0, the corrected image gradation is 5, 1 is 6, and 254 is 249, and 255 is 250. It is necessary to understand the calculation process in order to know the reason why such element-specific correction data is required. In order to understand the calculation process, it is necessary to understand the operation of the optical modulator driving circuit 422 in the display application of the diffractive optical modulator 353. .

When the gray scale is input, the optical modulator driving circuit 422 refers to the upper electrode reference voltage output from the upper electrode voltage range adjusting unit 412 and outputs an upper electrode corresponding to the gray level. That is, for example, if the upper electrode reference voltage is R1 to Rn with respect to the R light source, the optical modulator driving circuit 422 outputs the driving voltage R1 when the gray level 0 is input, and outputs the driving voltage Rn when the gray level 255 is input. When a value between 0 and 255 is input, a predetermined driving voltage is output. However, as shown in FIG. 7, since the upper electrode reference voltage is set to include both the minimum voltage and the maximum voltage instead of the minimum voltage and the maximum voltage for each element, the correction data for each element must be calculated. Referring to FIG. 10, which shows the light intensity hysteresis curve only for element 1, when the gray level input from the outside is 0, for example, the output voltage is applied to the optical modulator driving circuit 422 without correcting 0. Becomes R1, and the light intensity output by Element 1 is 15. Therefore, in order to resolve such discrepancies, the corresponding gray level 10 corresponding to Vp1min in which the actual element 1 emits zero light intensity may be output to the optical modulator driving circuit 422.

In conclusion, the element-specific correction data storage unit 408 generates and stores a correction image gray scale that can correct the input image gray scale input from the outside according to the method described above in a table as shown in FIG. 9. .

The image data / synchronization signal output unit 410 provides the image data output from the image correction unit 406 to the optical modulator driving circuit 422.

Also, the image data / synchronization signal output unit 410 receives and outputs a vertical synchronizing signal and a horizontal synchronizing signal input from the image correcting unit 406.

In addition, the upper electrode voltage range adjusting unit 412 reads the upper electrode reference voltage stored in the gamma reference voltage storage unit 404 and outputs the output voltage to the optical modulator driving circuit 422 and changes color characteristics from the portable terminal control system 400. When the control signal is input, the upper electrode reference voltage is adjusted and output accordingly.

That is, the upper electrode voltage range adjusting unit 412 reads and outputs the upper electrode reference voltage stored in the gamma reference voltage storage unit 404. When the color characteristic change control signal is input from the portable terminal control system 400, The corrected upper electrode reference voltage is output by correcting the upper electrode reference voltage. The correction value of the upper electrode reference voltage is changed according to the correction request value of the color characteristic change control signal.

The lower electrode voltage adjusting unit 414 reads the lower electrode reference voltage stored in the gamma reference voltage storage unit 404 and outputs the same to the diffraction type optical modulator 353, and changes the color characteristics from the portable terminal control system 400. When the control signal is input, the lower electrode reference voltage is adjusted and output accordingly.

That is, the lower electrode voltage adjusting unit 414 reads and outputs the lower electrode reference voltage stored in the gamma reference voltage storage unit 404, and when the color characteristic change control signal is input from the portable terminal control system 400, The lower electrode reference voltage corrected by outputting the electrode reference voltage is corrected. In this case, the correction value of the lower electrode reference voltage is changed according to the correction request value of the color characteristic change control signal.

As such, the upper electrode reference voltage output from the upper electrode voltage range adjusting unit 412 is corrected by the color characteristic change control signal output from the portable terminal control system 400 or the lower electrode reference output from the lower electrode voltage adjusting unit 414. When the voltage is corrected by the color characteristic change control signal output from the mobile terminal control system 400, even if the same image data is input to the optical modulator driving circuit 422 from the image data / synchronization signal output unit 410, the diffracted light The light intensity of the diffracted light output by the modulator 353 is changed to change the color characteristics of the image displayed on the screen 360.

That is, when the upper electrode reference voltage output from the upper electrode voltage range adjusting unit 412 is adjusted, the optical modulator driving circuit when the same image data is output from the image correcting unit 406 to the image data / synchronization signal output unit 410. The upper electrode driving voltage of the diffractive light modulator 353 generated by 422 is changed, thereby changing the light intensity of the diffracted light generated by the diffractive light modulator 353, resulting in the display of the screen 360. The color characteristics of the image are changed.

Also, when the lower electrode reference voltage output from the lower electrode voltage adjusting unit 414 is adjusted, when the same image data is output from the image correcting unit 406 to the image data / synchronization signal output unit 410, the optical modulator driving circuit ( Although the upper electrode driving voltage of the diffractive optical modulator 353 generated by 422 is not changed, the lower electrode reference voltage applied to the diffractive optical modulator 353 is changed so that the diffractive optical modulator 353 is changed. The light intensity of the generated diffracted light is changed, and as a result, the color characteristic of the image displayed on the screen 360 is changed.

For example, referring to FIG. 11, the lower electrode voltage is adjusted by the lower electrode voltage adjusting unit 414. FIG. 11 is a graph showing the applied voltage versus the output light intensity. The minimum upper electrode potential Vtmin, the maximum upper electrode potential Vtmax, and the lower electrode potential stored in 404 are shown. As shown by the solid line in FIG. 11, the optical modulator driving circuit 422 receives the upper electrode voltage corresponding to the gray level input from the image data / synchronous signal output unit 410 from the upper electrode voltage range adjusting unit 412. Outputting with reference to the electrode reference voltage can obtain the output light intensity as shown in the graph of the applied voltage versus the output light intensity.

Meanwhile, when the correction value set in the lower electrode voltage adjusting unit 414 is ΔV1, the lower electrode voltage adjusting unit 414 is corrected to the lower electrode reference voltage stored in the gamma reference voltage storage unit 404 by the diffractive optical modulator 353. The value is added and output, and since the upper electrode potential does not change, this results in moving the A graph to the B graph in the applied voltage vs. light intensity graph.

In addition, if the correction value set in the lower electrode voltage adjusting unit 414 is -ΔV2, the lower electrode voltage adjusting unit 414 may be connected to the gamma reference voltage storage unit 404 when the lower electrode is output from the diffractive optical modulator 353. The correction value is added to the stored lower electrode reference voltage (as a result, the result is subtracted) and the output is performed. As a result, the A graph is moved from the applied voltage vs. the light intensity graph to the C graph because the upper electrode potential does not change.

As such, the correction value of the lower electrode voltage adjusting unit 414 is changed to move the applied voltage vs. light intensity graph from A to B and from A to C, and the same image data is stored in the image correcting unit 406. When output to the synchronization signal output unit 410, the upper electrode driving voltage of the diffractive optical modulator 353 generated by the optical modulator driving circuit 422 is not changed, but the lower electrode is applied to the diffractive optical modulator 353. The reference voltage is changed and thus the driving voltage of the diffractive light modulator 353 is changed to change the light intensity of the diffracted light, thereby changing the color characteristics of the image displayed on the screen 360.

That is, for example, the optical modulator driving circuit 422 receives a specific gray scale value from the image data / synchronous signal output unit 410 and accordingly refers to the upper electrode reference voltage input from the upper electrode voltage range adjusting unit 412. When the Rex voltage value is output to the diffractive optical modulator 353, when the lower electrode reference voltage is first output to the lower electrode voltage adjusting unit 414, the diffraction emitted from the corresponding element of the diffractive optical modulator 353 is output. The light intensity of the light will be P1.

However, when the correction value set in the lower electrode voltage adjusting unit 414 is adjusted to become ΔV1, when the same image data is output from the image correcting unit 406 to the image data / synchronization signal output unit 410, the optical modulator driving circuit ( While the driving voltage of the diffractive optical modulator 353 generated by 422 is not changed in the upper electrode, the reference value of the lower electrode provided by the lower electrode voltage adjusting unit 414 to the diffractive optical modulator 353 is changed by -ΔV1. (I.e., the light intensity output curve is changed from A to B in the applied voltage in FIG. 11), and thus the light intensity generated by the corresponding element of the diffractive optical modulator 353 becomes P2, resulting in a weak light intensity. The color characteristic on 360 is changed.

Further, when the correction value set in the lower electrode voltage adjusting unit 414 is adjusted to -ΔV2, the optical modulator driving circuit is performed when the same image data is output from the image correcting unit 406 to the image data / synchronization signal output unit 410. While the driving voltage of the upper electrode of the diffractive diffraction type optical modulator 353 generated by the furnace 422 is unchanged, the reference value of the lower electrode provided by the lower electrode voltage adjusting unit 414 to the diffraction type optical modulator 353 is not changed. (By changing the light intensity output curve from A to C in the applied voltage in FIG. 11), the light intensity generated by the corresponding element of the diffractive optical modulator 353 becomes P3, thereby increasing the light intensity. As a result, the color characteristics on the screen 360 change.

Meanwhile, when the vertical synchronization signal and the horizontal synchronization signal are input from the image data / synchronization signal output unit 410, the light source controller 416 controls the driving circuit 424 accordingly so that the light source driving circuit 424 switches the light source. do.

Next, when the vertical synchronizing signal and the horizontal synchronizing signal are input from the image data / synchronization signal output unit 410, the scanning control unit 418 controls the scanner driving circuit 426 accordingly to project and The scanner (not shown) of the scanning optical unit 355 is driven.

When the image data (gray level) is input from the image data / synchronization signal output unit 410, the optical modulator driving circuit 422 refers to the upper electrode reference voltage provided from the upper electrode voltage range adjusting unit 412. The driving voltage of the upper electrode is generated and output to the diffractive optical modulator 353.

In addition, the lower electrode voltage adjusting unit 414 reads and outputs the lower electrode reference voltage stored in the gamma reference voltage storage unit 404. When the color characteristic change control signal is input from the portable terminal control system 400, the lower electrode voltage is adjusted accordingly. The electrode reference voltage is adjusted and output to the diffractive optical modulator 353.

On the other hand, the light modulation optical system 350 is a light source system 351 for generating and outputting an RGB light source, the illumination optical unit 352 for injecting the light emitted from the light source system 352 to the diffractive light modulator 353, illumination The light incident from the optical unit 352 is diffracted (that is, the illumination optical unit 352 diffracts the incident light to form diffracted light having a plurality of diffraction orders, where diffracted light having a plurality of diffraction orders is obtained. The diffraction light of any one order or multiple orders will produce the desired image image.) The desired order of the plural orders of diffraction light generated by the diffraction light modulator 353 and the diffraction light modulator 353 for generating the image image And a projection and scanning optics 355 for projecting an image image of the diffraction light passing through the diffraction light to the screen 360.

Referring to FIGS. 3, 4 and 12, the operation of the portable terminal including the optical modulation projector including the color characteristic adjusting apparatus according to the embodiment of the present invention will be described as follows.

First, the baseband processor 316 determines whether the user selects a projection mode using the input unit 312 to enlarge the image image and projects it on the screen (step S110), and when the user selects the projection mode, the projection mode accordingly A window is provided and an image list is provided so that a user can select an image image to project on the screen 360 (step S102).

When the user selects an image to be projected on the screen 360 from the image list (step S114), the baseband processor 316 transmits the image image data of the image selected by the user to the projection controller 340.

The baseband processor 316 transmits a projection mode control signal to the projection controller 340, and transmits a driving signal according to the image image data input by the projection controller 340 to the light source system 351 and the diffractive optical modulator ( 353).

That is, the image input unit 402 of the projection controller 340 receives image image data from the baseband processor 316 and simultaneously receives a vertical synchronization signal Vsync and a horizontal synchronization signal Hsync.

In addition, the image correction unit 406 of the projection control unit 340 performs a data transpose for converting the image image data arranged in the horizontal direction in the longitudinal direction to convert the image image data input in the horizontal direction into the vertical image image. Convert it to data and output it.

The image correction unit 406 sequentially reads and outputs the data transposed image data from the first column to the last column during the scanning time.

In this case, the image corrector 406 corrects the image data inputted from the image input unit 402 according to the element-specific correction data table stored in the element-specific correction data storage unit 408 and displays the corrected image data / image data / Output to the synchronization signal output unit 410.

Then, when the image data (gray level) is input from the image data / synchronization signal output unit 410, the optical modulator driving circuit 422 receives the upper electrode reference voltage through the upper electrode voltage range adjusting unit 412 and receives the input signal. The driving voltage of the upper electrode is output to the diffractive optical modulator 353 by referring to the electrode reference voltage.

Accordingly, the diffraction type optical modulator 353 is driven by the driving voltage of the upper electrode and outputs a scanning line composed of a plurality of scanning diffraction point lights having an image image, and the projection and scanning optics 355 output the scanning line to the screen 360. Scanning is generated to generate an image (step S116).

Meanwhile, the baseband processor 316 determines whether the user selects the color characteristic change menu (step S118), and provides a color characteristic change menu window when the user selects the color characteristic change menu (step S120). At this time, the menu window provided to the user by the baseband processor 316 is provided with a button for increasing the amount of color characteristics, the button for reducing the amount of color characteristics, the user presses the corresponding button to increase or decrease the amount and then press the OK button (step) S122).

Then, the baseband processor 316 may adjust the lower electrode reference voltage increase / decrease control signal of the lower electrode voltage adjuster 414 (of course, the upper electrode voltage of the projection controller 340 when the color characteristic amount is increased / decreased). At this time, the adjustment of the upper electrode voltage range is requested to the upper electrode voltage range adjusting unit 412).

Accordingly, the correction value of the lower electrode voltage adjusting unit 414 is increased / decreased, and accordingly, the lower electrode reference voltage provided to the diffractive optical modulator 353 is increased / decreased to change color characteristics (step S124).

Here, the method of varying the reference voltage of the lower electrode has been described, but it is natural that the reference voltage of the upper electrode can be varied.

As described above, according to the present invention, the display system using the diffractive optical modulator has an effect of actively coping with changes in the brightness of external light.

In addition, according to the present invention, there is an effect to be able to respond to the user's request to change the color characteristics.

Claims (11)

And a light source system, a first reflector and a second reflector spaced from the first reflector and varying in proximity, and the reflected light reflected from the first reflector and the second reflector generates diffracted light. In an optical system including a diffractive light modulator in which the light intensity of the diffracted light is determined in accordance with the proximity distance between the first reflector and the second reflector, An image input unit which receives image data; An input unit configured to receive a color characteristic change request from a user; Outputs the image data received from the image input unit, and adjusts the distance between the first reflecting unit and the second reflecting unit of the diffractive optical modulator required according to the image data when the input unit receives a color characteristic change request from the user. Image output unit for outputting; And When the user requests a change in color characteristics, when the image data is input from the image output unit, the distance between the first reflecting unit and the second reflecting unit of the diffractive optical modulator is adjusted according to the adjusted proximity distance output from the image output unit. Color characteristics adjusting device comprising an optical modulator driving circuit for controlling. The method of claim 1, The diffractive optical modulator includes a piezoelectric body including a lower electrode layer, a piezoelectric material layer, and an upper electrode layer to change a close distance between the first reflecting unit and the second reflecting unit. The image output unit is configured to vary the proximity distance between the first reflector and the second reflector of the diffractive optical modulator according to image data when the input unit receives a color characteristic change request from a user. And adjusting an applied driving voltage value to be applied to the color characteristic adjusting device. The method of claim 2, The image output unit, And stores an upper electrode reference voltage and a lower electrode reference voltage applied to the diffractive optical modulator, outputs an upper electrode reference voltage to the optical modulator driving circuit, and outputs a lower electrode reference voltage to the diffractive optical modulator. An applied voltage output unit configured to adjust and output the upper electrode reference voltage when an additional user receives a color characteristic change request; And And an image corrector configured to output the image data received by the image input unit to the optical modulator driving circuit. The method of claim 3, wherein The applied voltage output unit, A gamma reference voltage storage unit configured to store an upper electrode reference voltage to be applied to the upper electrode layer of the piezoelectric body and a lower electrode reference voltage to be applied to the lower electrode layer in the diffractive optical modulator; And  And a reference voltage output unit configured to read and output an upper electrode reference voltage and a lower electrode reference voltage stored in the gamma reference voltage storage unit, and adjust and output the upper electrode reference voltage when the input unit receives a color characteristic change request from a user. Consisting of color characteristic adjusting device. The method of claim 2, The image output unit, Storing an upper electrode reference voltage and a lower electrode reference voltage applied to the diffractive optical modulator, outputting an upper electrode reference voltage to the optical modulator driving circuit, and outputting a lower electrode reference voltage to the diffractive optical modulator, An applied voltage output unit configured to adjust and output a lower electrode reference voltage when the input unit receives a color characteristic change request from a user; And And an image corrector configured to output the image data received by the image input unit to the optical modulator driving circuit. The method of claim 5, wherein The applied voltage output unit, A gamma reference voltage storage unit configured to store an upper electrode reference voltage to be applied to the upper electrode layer of the piezoelectric body and a lower electrode reference voltage to be applied to the lower electrode layer in the diffractive optical modulator; And  And a reference voltage output unit configured to read and output an upper electrode reference voltage and a lower electrode reference voltage stored in the gamma reference voltage storage unit, and adjust and output a lower electrode reference voltage when the input unit receives a color characteristic change request from a user. Consisting of color characteristic adjusting device. The method according to claim 4 or 6, The reference voltage output unit, An upper electrode voltage range adjusting unit configured to adjust and output an upper electrode reference voltage when a color characteristic change control signal is input from the input unit after reading the upper electrode reference voltage stored in the gamma reference voltage storage unit; And, A color characteristic adjusting device including a lower electrode voltage adjusting unit configured to adjust and output a lower electrode reference voltage when a color characteristic change control signal is input from the input unit after reading the lower electrode reference voltage stored in the gamma reference voltage storage unit; . And a light source system, a first reflector and a second reflector spaced from the first reflector and varying in proximity, and the reflected light reflected from the first reflector and the second reflector generates diffracted light. In an optical system including a diffractive light modulator in which the light intensity of the diffracted light is determined in accordance with the proximity distance between the first reflector and the second reflector, (a) an image input unit receiving image data, and an image output unit outputting the image data received by the image input unit to an optical modulator driving circuit; (b) the optical modulator driving circuit displaying the image by driving the diffractive optical modulator according to the input image data; (c) an input unit receiving a color characteristic change request from a user; And (d) When the image output unit receives a color characteristic change request from the user through the input unit, the diffraction type is adjusted by adjusting the distance between the first reflecting unit and the second reflecting unit of the diffractive optical modulator required according to the image data. A color characteristic adjustment method comprising the step of outputting to the optical modulator drive circuit. The method of claim 8, The diffraction type optical modulator includes a piezoelectric body including a lower electrode layer, a piezoelectric material layer, and an upper electrode layer to change a proximal distance between the first reflecting unit and the second reflecting unit. In the step (d), when the input unit receives a color characteristic change request from the user, the image output unit changes the proximity distance between the first reflecting unit and the second reflecting unit of the diffractive optical modulator required according to the image data. And adjusting and outputting an applied driving voltage value to be applied to the upper electrode layer and the lower electrode layer. The method of claim 9, In step (d), (e) adjusting the upper electrode reference voltage stored in the gamma reference voltage storage unit when the reference voltage output unit of the image output unit receives a color characteristic change request from the user; And and (f) outputting the adjusted upper electrode reference voltage and the lower electrode reference voltage to the reference voltage output unit. The method of claim 9, In step (d), adjusting a lower electrode reference voltage stored in a gamma reference voltage storage unit when the input unit receives a color characteristic change request from a user; And and (h) outputting an upper electrode reference voltage and an adjusted lower electrode reference voltage to the reference voltage output unit.

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