KR20080008680A - Image receiving device and method for image quality improvement - Google Patents

Abstract

An image receiving device and a method for improving the image quality of the same are provided to display plural sub frames with preset resolution on a screen by using plural actuators, thereby reducing the size of a DMD(Digital Micro-mirror Device) panel and maintaining resolution before the sub frames. An image receiving device(100) comprises a control unit(110), a first actuator(150), and a second actuator(160). The control unit generates a sub frame with resolution preset on the basis of a received image signal and generates a driving signal for adjusting a position where the sub frame is displayed. The first actuator adjusts the reflection angle of the sub frame according to the received driving signal and reflects the sub frame. The second actuator adjusts the reflection angle of the sub frame according to the driving signal and reflects the reflected sub frame once more.

Description

Image receiving device and method for image quality improvement

1 is a block diagram of an image receiving apparatus according to an embodiment of the present invention;

2 is a view illustrating an example of states of a first actuator and a second actuator adjusted according to a driving signal of a controller according to the present invention;

3 is a flowchart provided to explain an operation method of an image format conversion apparatus according to an embodiment of the present invention;

4 is a diagram illustrating an example of a subframe displayed on a screen according to the states of the first and second actuators according to the present invention.

Explanation of symbols on the main parts of the drawings

110: control unit 120: color wheel

130: condensing lens 140: DMD

150: first actuator 160: second actuator

The present invention relates to an image receiving apparatus and a method for improving image quality thereof, and more particularly, to an image receiving apparatus for providing a high resolution image using a plurality of actuators and a method for improving image quality thereof.

In general, an image receiving apparatus refers to an apparatus for displaying an image on a screen by projecting an image signal consisting of color signals of R, G, and B onto a screen. Conventionally, image receiving apparatuses using CRTs have been common, but recently, projection image receiving apparatuses have been in the spotlight, and among them, DLP (Digital Light Processing) image receiving apparatuses, called third generation projection apparatuses, have attracted attention.

DLP image receiver is composed of signal processing chips for controlling each mirror of DMDs based on DMDs with millions of fine mirrors integrated with display resolution. .

DMD is a semiconductor optical switch incorporating a fine driving mirror. Each 16 µm-size aluminum alloy micromirror formed on each cell of a static random access memory (SRAM) has an inclination of +/- 12 DEG per on / off state. At this time, the micro-mirror installed in the support is operated by the electrostatic field of the memory, and by adjusting the time that the light projected by the micro-mirror is reflected or not reflected, the person sees the brightness corresponding to the accumulated time. Brightness / darkness can be expressed for each pixel on the screen.

However, an actuator located between the DMD and the projection lens has a limit in reducing the number of fine mirrors included in the DMD by dividing and transmitting the image signal by half a frame from the DMD. As the number of fine mirrors increases, the price of the DMD increases and the quality of the images decreases when the number of fine mirrors decreases. Therefore, an image receiving apparatus and a method of improving image quality that can improve image quality while reducing the number of fine mirrors of the DMD are needed.

Accordingly, an object of the present invention is to provide an image receiving apparatus and a method for improving image quality that provide a high resolution image while reducing the size of a DMD by using a plurality of actuators.

According to an aspect of the present invention, there is provided a video receiving apparatus comprising: a controller configured to generate a subframe having a predetermined resolution based on a received video signal and to generate a driving signal for adjusting a position at which the subframe is displayed; A first actuator for adjusting a reflection angle of the subframe according to the received driving signal and reflecting the subframe; And a second actuator for adjusting a reflection angle of the subframe according to the driving signal and reflecting the reflected subframe again.

Preferably, the method may further include a digital micro-mirror device (DMD) for reflecting R, G, and B light for a subframe. In this case, when the first actuator receives a drive signal for adjusting the first actuator from the controller, the first actuator adjusts the reflection angle of the subframe, reflects the subframe received from the DMD, and the second actuator receives the second actuator from the controller. When the driving signal for adjustment is received, the reflection angle of the subframe may be adjusted, and the subframe may be reflected at the adjusted angle so that the subframe is displayed at the changed position.

Also, preferably, the controller may generate a drive signal of 120 Hz and 240 Hz to adjust the reflection angle of the subframe for each of the first actuator and the second actuator. At this time, the first and second actuators, respectively, for the first actuator and the second actuator so that the position of the subframe displayed on the screen moves a predetermined distance from the position of the previous subframe displayed on the screen according to the driving signal received from the controller. The reflection angle of the subframe can be adjusted.

Also, preferably, the first and second actuators have a reflection angle of the subframe such that the subframe is displayed at a position shifted by half a pixel left / right and up / down than the position of the previous subframe displayed on the screen. Can be adjusted.

On the other hand, the image processing method of the present invention, generating a subframe of a predetermined resolution based on the received image signal, and generating a drive signal for adjusting the position of the subframe is displayed; Adjusting a reflection angle of the subframe according to the received driving signal and reflecting the subframe; And adjusting the reflection angle of the subframe according to the driving signal, and reflecting the reflected subframe again.

Hereinafter, with reference to the drawings will be described the present invention in more detail.

1 is a block diagram of an image receiving apparatus according to an embodiment of the present invention. Referring to FIG. 1, the image receiving apparatus includes a controller 110, a color wheel 120, a condensing lens 130, a DMD 140, a first actuator 150, and a second actuator 160. do.

The controller 110 generates a plurality of subframes having a predetermined resolution based on the received video signal. In this case, the controller 110 preferably generates four subframes as one group, but is not necessarily limited thereto.

In addition, the controller 110 generates a driving signal for controlling the driving of the first actuator 150 and the second actuator 160 which will be described later. Here, the driving signal of the first actuator 150 generated by the controller 110 is preferably 120 Hz, and the driving signal of the second actuator 160 is 240 Hz, but is not necessarily limited thereto.

The color wheel 120 is composed of an RGB color filter having a predetermined area, and rotates the subframe received from the controller 110 in accordance with a signal of a corresponding color of the DMD 140 to be described later to separate the R, G, and B light. In this case, the color wheel 120 is rotated by a driving motor (not shown) operated by the control of the controller 110.

The condensing lens 130 focuses the R, G and B light incident from the color wheel 120, and adjusts the focused light to the size of the DMD 140 to be described later and irradiates the DMD 140.

The DMD 140 reflects R, G, and B light incident from the condensing lens 130 to the first actuator 150 and the second actuator 160 which will be described later located in the screen (not shown) direction.

Each of the first and second actuators 150 and 160 has a transmission mirror (not shown) in the center, and the transmission mirror refracts and transmits incident light. At this time, any one of the first actuator 150 and the second actuator 160 is used to adjust the position of the subframe displayed on the screen (not shown) up and down, and the other one to the left and right of the position of the subframe Used to adjust.

In this case, the first actuator 150 and the second actuator 160 change the angles of the first and second actuators 150 and 160 by the driving signals received from the controller 110, respectively, to the screen (not shown). Adjust the position of the displayed subframe up / down, left / right. That is, the first and second actuators 150 and 160 adjust the position of the subframe displayed on the screen (not shown) by adjusting the reflection angle of the subframe based on the received driving signal. Here, the first actuator 150 reflects the subframe received from the DMD 140 to the second actuator 160, and the second actuator 160 reflects the subframe reflected from the first actuator 150. It is displayed on the screen (not shown).

That is, according to the driving signal received from the control unit 110, the first actuator 150 and the second actuator 160, as shown in FIG. 2, of each subframe received from the DMD 140 in four states. Adjust the position to display on the screen (not shown). Here, as shown in FIG. 2, the first actuator 150 and the second actuator 160 change their angles so that the first to fourth states are changed by a predetermined time received from the controller 110. do.

Specifically, referring to FIG. 2, the first actuator 150 and the second actuator 160 display the first subframe received from the DMD 140 at the correct position of the screen in the first state, and the controller 110. In response to the second actuator driving signal received from the second actuator 160, the angle is changed so that the first and second actuators 150 and 160 are in the second state. The first and second actuators 150 and 160 in the second state move the second subframe received from the DMD 140 to the left by a predetermined distance from the first subframe and display them on a screen (not shown).

Subsequently, the first actuator 150 changes the angle according to the first actuator driving signal received from the controller 110, and the first and second actuators 150 and 160 enter the third state. The first and second actuators 150 and 160 in the third state move the third subframe received from the DMD 140 over a predetermined distance from the second subframe and display the same on a screen (not shown). According to the second actuator driving signal received from the controller 110, the second actuator 160 changes the angle so that the first and second actuators 150 and 160 are in a fourth state. The first and second actuators 150 and 160 in the fourth state move the fourth subframe received from the DMD 140 to the right by a predetermined distance from the third subframe and display them on the screen (not shown). Here, the first and second actuators display the subframes of the current state on the screen (not shown) at positions shifted half a pixel left / right and up / down from the previous subframe according to the first to fourth states.

3 is a flowchart provided to explain an operation method for an image receiving apparatus according to an embodiment of the present invention.

Referring to FIG. 3, first, the controller 110 generates a plurality of subframes having a predetermined resolution based on the received video signal (S310).

Specifically, for example, when receiving a video signal having a resolution of 1280 * 720, the control unit 110 based on the video signal having a resolution of 1280 * 720 a plurality of sub having a resolution of 427 * 240 Create a frame. Here, the controller 110 preferably generates four subframes as one group, but is not necessarily limited thereto.

Subsequently, the first and second actuators 150 and 160 adjust the angles of the first and second actuators 150 and 160 according to the driving signal received from the controller 110 (S320). Here, the driving signal of the first actuator 150 received from the controller 110 is 120Hz, the driving signal of the second actuator 160 is preferably 240Hz, but is not necessarily limited thereto.

Specifically, referring to FIG. 2, when the first and second actuators 150 and 160 receive the second actuator driving signal of 240 Hz from the controller 110 in the initially set first state, the second actuator 160 may be used. The first and second actuators 150 and 160 change from the first state to the second state by adjusting the angle. When the first actuator driving signal of 120 Hz is received from the controller 110, the first actuator 150 adjusts the angle so that the first and second actuators 150 and 160 change from the second state to the third state. do. At this time, when the second actuator driving signal of 240 Hz is received from the controller 110, the second actuator 160 adjusts the angle so that the first and second actuators 150 and 160 change from the third state to the fourth state. do.

In addition, the first and second actuators 150 and 160 display the subframes at positions adjusted according to the first to fourth states (S330).

4 is a diagram illustrating an example of a subframe displayed on a screen according to the states of the first and second actuators according to the present invention.

Specifically, referring to FIGS. 2 and 4, the first actuator 150 and the second actuator 160 reflect the first subframe received from the DMD 140 in the initially set first state to display a screen (not shown). ). When the driving signal 240Hz for controlling the second actuator 160 is received from the controller 110 according to the description of step S320, and the first and second actuators 1450 and 160 are in the second state, the DMD 140 The second subframe received from) is reflected and displayed at a position moved a predetermined distance to the left of the first subframe.

Subsequently, when the driving signal 120 Hz for adjusting the first actuator 150 is received from the controller 110 and the first and second actuators 1450 and 160 are in the third state, the received signal from the DMD 140 is received. The third subframe is reflected and displayed at a position moved by a predetermined distance above the second subframe. In addition, when the driving signal 240Hz for controlling the second actuator 160 is received from the controller 110 and the first and second actuators 1450 and 160 are in the fourth state, the fourth received from the DMD 140 is received. The subframe is reflected and displayed at a position moved a predetermined distance to the right than the third subframe.

In this case, the first and second actuators 150 and 160 adjust the angles of the first and second actuators 150 and 160 according to the driving signal received from the controller 110 in the manner described in operation S320. Display all subframes received from the screen on the screen (not shown). That is, the first and second actuators 150 and 160 repeat the first to fourth states by adjusting the angles of the first and second actuators until all subframes are displayed on a screen (not shown). Here, the first and second actuators display the subframes of the current state on the screen (not shown) at positions shifted half a pixel left / right and up / down from the previous subframe according to the first to fourth states.

In addition, the first and second actuators 150 and 160 may change the angle in accordance with a falling time of the driving signal received from the controller 110, but is not necessarily limited thereto.

As described above, according to the present invention, by displaying a plurality of subframes having a predetermined resolution on a screen by using a plurality of actuators, the size of the DMD panel can be reduced, and the resolution before the subframe can be maintained as it is.

In addition, although the preferred embodiment of the present invention has been shown and described above, the present invention is not limited to the specific embodiments described above, but the technical field to which the invention belongs without departing from the spirit of the invention claimed in the claims. Of course, various modifications can be made by those skilled in the art, and these modifications should not be individually understood from the technical spirit or the prospect of the present invention.

Claims (5)

A controller configured to generate a subframe having a predetermined resolution based on the received video signal and to generate a driving signal for adjusting a position at which the subframe is displayed; A first actuator for adjusting a reflection angle of the subframe according to the received driving signal and reflecting the subframe; And And a second actuator for adjusting a reflection angle of the subframe according to the driving signal and reflecting the reflected subframe again. The method of claim 1, Further comprising a digital micro-mirror device (DMD) for reflecting the R, G, B light for the subframe, The first actuator is, When the driving signal for adjusting the first actuator is received from the controller, the reflection angle of the subframe is adjusted, and the subframe received from the DMD is reflected at the adjusted angle. The second actuator, When the driving signal for adjusting the second actuator is received from the controller, the reflection angle of the subframe is adjusted, and the subframe is reflected at the adjusted angle so that the subframe is displayed at the changed position. Video receiver. The method of claim 2, The control unit, Generating a driving signal of 120 Hz and 240 Hz to adjust a reflection angle of the subframe with respect to each of the first actuator and the second actuator, The first and second actuators, The reflection angle of the subframe with respect to each of the first actuator and the second actuator so that the position of the subframe displayed on the screen is shifted by a predetermined distance from the position of the previous subframe displayed on the screen according to the driving signal received from the controller. Image receiving apparatus, characterized in that for adjusting. The method of claim 3, The first and second actuators, And a reflection angle of the subframe is adjusted so that the subframe is displayed at a position in which the position of the subframe is moved left / right and up / down half a pixel from the position of the previous subframe displayed on the screen. . Generating a subframe having a predetermined resolution based on the received video signal, and generating a driving signal for adjusting a position at which the subframe is displayed; Adjusting a reflection angle of the subframe according to the received driving signal and reflecting the subframe; And And adjusting the reflection angle of the subframe according to the driving signal and reflecting the reflected subframe again.

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