KR101204898B1 - Projector system and method thereof - Google Patents

Abstract

The present invention relates to a projector system and a method of controlling the same, which can prevent a decrease in brightness due to a change in the zoom level by correcting the output brightness according to the zoom level. The present invention provides a light emitting device comprising: a screen on which an image is projected by a light source lamp and a lens unit; A zoom adjusting unit for adjusting a zoom level of the lens unit; A zoom sensor detecting the zoom level; And a controller configured to recognize at least one of the aperture level and angle of view information of the lens unit according to the zoom level and to correct the screen brightness according to at least one of the aperture level and the angle of view information.

Description

Projector system and control method

The present invention relates to a projector system and a control method thereof, and more particularly, to a projector system and a method of controlling the same, which are connected to a computer or a multimedia device to enlarge and display an image on an external screen.

The projector system may be connected to a computer or a multimedia device to enlarge and display an image on an external screen. The projector system can include a projector. At this time, the projector may receive signals from various video devices such as a PC, a TV, a VCR, a DVD, and express an enlarged image on a screen separately installed on the front through a lens.

The projector has the advantage of excellent image quality and large screen display. Therefore, in recent years, the demand for multimedia video equipment for home or office is increasing. The biggest advantage of the projector is that it can realize a large screen.

LCD TVs and PDP TVs that implement large displays are currently on the market up to 80 inches, while projectors vary in performance, such as brightness or resolution, but can easily implement 60-100 inch screens, and 300 inches. The above big screen can also be implemented.

In addition, the general TV, LCD TV, PDP TV, etc., the larger the screen size is bulky, the weight is increased. However, the projector is not affected by volume and weight because the screen size can be adjusted according to the distance between the projector and the screen. As such, large screens can be realized and relatively inexpensive compared to other displays, and demand for projectors is increasing in companies, schools, churches, and homes.

An object of the present invention is to provide a projector system and a method of controlling the same, by correcting the output brightness according to the zoom level, thereby preventing the brightness from being lowered due to the change of the zoom level.

The present invention provides a light emitting device comprising: a screen on which an image is projected by a light source lamp and a lens unit; A zoom adjusting unit for adjusting a zoom level of the lens unit; A zoom sensor detecting the zoom level; And a controller configured to recognize at least one of the aperture level and angle of view information of the lens unit according to the zoom level and to correct the screen brightness according to at least one of the aperture level and the angle of view information.

The light source may further include a light source controller configured to control the brightness of the light source lamp by applying a current to the light source lamp.

By adjusting the zoom level, the aperture level may be linked to be adjusted.

The controller may be configured to recognize a change in the aperture level according to the change of the zoom level, calculate a change in screen brightness according to the change in the aperture level, and to correct the change in the screen brightness.

The controller may calculate a first current correction value for correcting the screen brightness according to the change of the aperture level, and transmit the calculated first current correction value to the light source controller.

The controller may be configured to recognize a change in the angle of view according to the change of the zoom level, calculate a change in screen brightness according to the change of the angle of view, and to correct the change in the screen brightness.

The controller may calculate a second current correction value for correcting the screen brightness according to the change of the angle of view, and transmit the calculated second current correction value to the light source controller.

The control unit corrects a first current correction value for correcting a change in screen brightness due to a change in aperture level according to a change in the zoom level, and a change in screen brightness due to a change in angle of view according to a change in the zoom level. The final current correction value may be calculated by adding the second current correction values, and the final current correction value may be transmitted to the light source controller.

The relationship between the change amount of the aperture level and the change of angle of view according to the change of the zoom level, the change of screen brightness due to each, and the first current correction value and the second current correction value are provided in a table. The final current correction value may be calculated with reference to the table.

The apparatus may further include a distance recognition sensor measuring a distance from the lens unit to the screen.

Another aspect of the invention, the step of recognizing reference information including the current zoom level and the aperture level; Determining whether the zoom level has changed; Calculating a first correction value for correcting a screen brightness due to a change in aperture according to a change in the zoom level; Calculating a second correction value for correcting a screen brightness due to a change in angle of view according to the change of the zoom level; And correcting a current value for controlling a light source lamp in consideration of the first correction value and the second correction value.

Recognizing a change in the aperture level according to the change of the zoom level, calculating a change in screen brightness due to the change in the aperture level, and calculating a first current correction value for correcting the change in the screen brightness. It may include.

Recognizing a change in angle of view according to the zoom level change, calculating a change in screen brightness due to the change in angle of view, and calculating a second current correction value for correcting the change in screen brightness; Can be.

The method may further include calculating a final current correction value by adding the first current correction value and the second current correction value.

The relationship between the change amount of the aperture level and the change of angle of view according to the change of the zoom level, the change of screen brightness due to each, and the first current correction value and the second current correction value are provided in a table. The final current correction value may be calculated with reference to the table.

According to the projector system and the control method thereof according to the present invention, it is possible to prevent the brightness deterioration due to the change of the zoom level by correcting the output brightness according to the zoom level.

1 is a block diagram schematically showing a projector system according to a preferred embodiment of the present invention.
2 is a flowchart schematically illustrating a method of controlling a projector system according to an exemplary embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram schematically showing the configuration of a projector system 10 according to a preferred embodiment of the present invention.

Referring to the drawings, the projector system 10 includes a screen 100; Light source lamp 210; A light source controller 220; A lens unit 310; A zoom adjusting unit 320; A zoom sensor 330; And a controller 400.

An image may be projected onto the screen 100 by the light source lamp 210 and the lens unit 310. The zoom adjuster 320 may adjust the zoom level of the lens unit 310. The zoom detector 330 may detect a zoom level.

The controller 400 may recognize at least one of the aperture level and the angle of view information of the lens unit 310 according to the zoom level, and may control to correct the screen brightness according to at least one of the aperture level and the angle of view information.

Therefore, by compensating the output brightness according to the zoom level, it is possible to prevent the brightness deterioration due to the change of the zoom level.

Here, the screen brightness may be controlled by adjusting the output of the light source lamp 210. In this case, the output of the light source lamp 210 may be controlled by adjusting the current applied to the light source lamp 210. To this end, the light source controller 220 may apply a current to the light source lamp 210 to control the brightness of the light source lamp.

The controller 400 may recognize a change in the aperture level according to the change of the zoom level, calculate a change in screen brightness according to the change in the aperture level, and control to correct the change in the screen brightness.

In addition, the controller 400 may recognize a change in the angle of view according to the change of the zoom level, calculate a change in screen brightness according to the change of the angle of view, and control to correct the change in the screen brightness.

When the projector system 10 is used in a limited space in a room having a limitation of a projection distance, the user can size an image projected on the screen 100 through a zooming function of the lens unit 310 to a size desired by the user. Can be enlarged and displayed. In this case, when the image is enlarged, the visibility of the projected image may decrease and the visibility of the user may deteriorate.

Typically, the projector system 10 may be operated in a fixed aperture manner to maintain a fixed aperture value regardless of the adjustment of the zoom level, or in a variable aperture manner in which the aperture value is adjusted in conjunction with the zoom level.

The projector system 10 according to an embodiment of the present invention may be operated by a variable aperture method in which the aperture level is adjusted in conjunction with the adjustment of the zoom level. Thus, the system can be configured using a limited size lens. Thus, the manufacturing cost can be lowered and the system can be easily miniaturized.

In this case, in the case of using the variable aperture method, when the zooming is performed by adjusting the zoom level to enlarge the projected image, the aperture value may be changed together and the brightness of the image projected on the screen 100 may be lowered. Here, the aperture value may be defined as a normal F number.

Therefore, by compensating for the change amount of the aperture value due to the change of the zoom level to drive the light source lamp 210, it is possible to compensate for the decrease in screen brightness due to the change of the aperture value. To this end, the controller 400 recognizes a change in the aperture level according to the change of the zoom level, calculates a change in screen brightness according to the change in the aperture level, and controls the light source controller 220 to correct the change in the screen brightness. can do.

In this case, the controller 400 may calculate and transmit a first current correction value for correcting the screen brightness according to the change of the aperture level to the light source controller 220. In this case, the light source controller 220 may control the light source lamp 210 to be driven by the current value reflecting the first current correction value.

Therefore, by adjusting the output brightness in consideration of the change of the aperture level according to the change of the zoom level, the screen brightness can be kept constant even when the aperture level is changed.

On the other hand, when zooming by adjusting the zoom level to enlarge the projected image, the focal length is reduced. Accordingly, the angle of view of the image emitted through the lens unit 310 is increased, and as the angle of view is increased, the screen brightness of the image projected on the screen 100 may be lowered.

Therefore, by compensating for the change of the angle of view due to the change of the zoom level to drive the light source lamp 210, it is possible to compensate for the degradation of the screen brightness due to the change of the angle of view. To this end, the controller 400 may recognize the change in the angle of view according to the change of the zoom level, calculate the change in the screen brightness according to the change in the angle of view, and control the light source controller 220 to correct the change in the screen brightness. have.

In this case, the controller 400 may calculate and transmit a second current correction value for correcting the screen brightness according to the change of the angle of view to the light source controller 220. In this case, the light source controller 220 may control the light source lamp 210 to be driven by the current value reflecting the second current correction value.

Accordingly, by correcting the output brightness in consideration of the change of the angle of view according to the change of the zoom level, the screen brightness can be kept constant even when the angle of view is changed.

In this case, the controller 400 may change the first current correction value for correcting the change in the screen brightness due to the change in the aperture level according to the change in the zoom level, and the change in the screen brightness due to the change in the angle of view according to the change in the zoom level. The final current correction value may be calculated by adding the second current correction values to be corrected, and the final current correction value may be transmitted to the light source controller 220. In this case, the light source controller 220 may control the light source lamp 210 to be driven by the current value reflecting the final current correction value.

Accordingly, by adjusting the output brightness in consideration of the change in the aperture value and the change in the angle of view according to the change of the zoom level, the screen brightness can be kept constant even when the zoom level is changed.

Meanwhile, the relationship between the change amount of the aperture level and the change of the angle of view according to the change of the zoom level, and the change of the screen brightness due to each, the first current correction value and the second current correction value may be provided and stored as a table. At this time, the controller 400 may calculate the final current correction value with reference to the table.

Therefore, the final current correction value can be calculated quickly. Here, the calculation of the change amount of the aperture level and the change of the angle of view, the resulting change in screen brightness, the first current correction value, and the second current correction value are determined by referring to the set table as well as the calculation by a predetermined formula. It includes.

Meanwhile, the projector system 10 may further include a distance recognition sensor 500 that measures a screen distance corresponding to the distance from the lens unit 310 to the screen 100. In this case, the screen distance may be used to calculate or predict the screen brightness of the image projected on the screen 100 with respect to the light source output from the light source lamp 210.

The projected image to be projected onto the screen 100 may be input through the input device 600. The input device 600 may be various devices in which a conventional PC or a notebook is connected through a mobile device such as a computer, a smart phone, or a wired and / or wireless network.

In general, in a projector system having a zoom function, the lens group of the lens unit 310 needs to be moved in order to operate the zoom function. To this end, a driving device such as a step motor included in the zoom adjusting unit 320 may be used, which can be controlled electronically.

If the user knows information about the amount of movement of the internal movement group in the wide and tele ends of the projection lens included in the lens 310, for example, the focal length, the device may be used. In this way, the user can determine a zoom position for a position where the user can obtain a desired image size on a screen fixed at a certain position, and can move to a position corresponding to the corresponding amount. That is, it is possible to know the change in the focal length or angle of view of the projection lens that is changed when the movement occurs through the control of the drive motor.

Magnification of the image projected onto the screen means an increase in the angle of view, which is a decrease in brightness as the area expands for the limited energy input from the light source and delivered to the final screen. This reduction is reduced by the ratio of the quadratic power of cos (Θ) due to the nature of the lighting conditions when summarized as the ratio of the amount of ambient light to the center. Here, the angle Θ may be defined as a value of the image size with respect to the projection distance.

The movement relationship between two elements of the projection optical system used for the projection of the image and the magnification and reduction of the projected image and the driving motor used to implement the image can be defined. In other words, the total trajectory data of the lens moving group and the total number of operation steps of the driving motor corresponding to the zoom range within the zooming range from the wide end to the tele end may be defined. In this case, the position of the zoom lens corresponding to each zoom level may be converted as a change in focal length and a change in angle of view. In addition, the current correction value according to the change in the aperture value and / or the change in the angle of view due to the change in the zoom level may be defined as the degree of brightness deterioration.

In the initial operation of the projector, the lens shift group inside for zooming is moved to the reference position, and the amount of movement with respect to the focal length and angle of view of the projection optical lens according to the operation of the drive motor based on the information at this position. Can be recognized.

When the user moves the lens group in order to enlarge the image at any limited position, the brightness of the peripheral part is recognized by the enlargement of the screen size according to the amount of movement at this time, and the value of the brightness correction of the predefined reference is adjusted. By controlling the current value to be transmitted to the controller 220 to change the current value, the degradation of the brightness can be corrected.

2 is a flowchart schematically showing a control method (S10) of a projector system according to an exemplary embodiment of the present invention. The control method (S10) of the projector system of FIG. 2 is a method of controlling the projector system 10 of FIG. 1. Therefore, the same matters as those in the projector system 10 are referred to, and detailed description thereof will be omitted.

Referring to the drawings, the control method of the projector system (S10) is a reference information recognition step (S110); A zoom level change determination step (S120); Generating first correction values (S210 to S230); Generating second correction values S310 to S330; And a correction step S150.

In the reference information recognizing step S110, reference information including a current zoom level and an aperture level may be recognized. In the zoom level change determination step (S120), it is determined whether the zoom level is changed.

In the first correction value generating steps S210 to S230, a first correction value for correcting the screen brightness due to the change of the aperture according to the change of the zoom level is calculated. In the second correction value generating steps S310 to S330, a second correction value for correcting the screen brightness due to the change of the angle of view according to the change of the zoom level is calculated.

In the correcting step (S150), the current value for controlling the light source lamp 210 of FIG. 1 is corrected in consideration of the first correction value and the second correction value. Therefore, by compensating the output brightness according to the zoom level, it is possible to prevent the brightness deterioration due to the change of the zoom level.

The reference information recognized in the reference information recognizing step S110 may include a screen distance corresponding to the distance between the projector, for example, the end of the lens, and the screen. In this case, the screen distance may be used to calculate or predict the screen brightness of the image projected on the screen 100 with respect to the light source output from the light source lamp 210.

Recognizing the change in the aperture level according to the zoom level change (S210), calculating the change in screen brightness due to the change in the aperture level (S220), and correcting the change in screen brightness in the first correction value generating step (S210 to S230). The first current correction value may be calculated (S230).

Therefore, by adjusting the output brightness in consideration of the change of the aperture level according to the change of the zoom level, the screen brightness can be kept constant even when the aperture level is changed.

In this case, when the aperture value is changed to become darker due to the change of the zoom level, the decrease in the screen brightness due to the change of the aperture value may be compensated by increasing the current value for driving the light source lamp 210 by that much.

In the second correction value generating step (S310 to S330), the change of the angle of view according to the change of the zoom level is recognized (S310), the screen brightness change due to the change of the angle of view is calculated (S320), and the screen brightness change is corrected. 2 it is possible to calculate the current correction value (S330).

Accordingly, by correcting the output brightness in consideration of the change of the angle of view according to the change of the zoom level, the screen brightness can be kept constant even when the aperture level is changed.

In this case, when the angle of view changes due to the change of the zoom level, the current value driving the light source lamp 210 is increased by that amount, thereby compensating for the decrease in screen brightness due to the change in the aperture value.

In addition, the final current correction value may be calculated by adding the first current correction value and the second current correction value (S140). In this case, the current value for controlling the light source lamp 210 may be corrected by adding the first current correction value and the second current correction value to the correction step S150. Therefore, by compensating the output brightness according to the zoom level, it is possible to prevent the brightness deterioration due to the change of the zoom level.

Meanwhile, the relationship between the change amount of the aperture level and the change of the angle of view according to the change of the zoom level, and the change of the screen brightness due to each, the first current correction value and the second current correction value may be provided and stored as a table. At this time, the final current correction value can be calculated with reference to the table.

According to the present invention, it is possible to prevent the brightness deterioration due to the change of the zoom level by correcting the output brightness according to the zoom level.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation, You will understand. Accordingly, the true scope of protection of the present invention should be determined only by the appended claims.

10: projector system, 100: screen,
210: light source lamp, 220: light source control unit,
310: lens unit, 320: zoom adjustment unit,
330: zoom detection unit, 400: control unit,
500: distance recognition sensor, 600: input device.

Claims (15)

A screen on which an image is projected by the light source lamp and the lens unit;
A zoom adjusting unit for adjusting a zoom level of the lens unit;
A zoom sensor detecting the zoom level;
A controller configured to recognize at least one of the aperture level and angle of view information of the lens unit according to the zoom level and to correct the screen brightness according to at least one of the aperture level and the angle of view information; And
A light source controller configured to control a brightness of the light source lamp by applying a current to the light source lamp;
The control unit corrects a first current correction value for correcting a change in screen brightness due to a change in aperture level according to a change in the zoom level, and a change in screen brightness due to a change in angle of view according to a change in the zoom level. And a second current correction value to calculate a final current correction value, and transmit the final current correction value to the light source controller. delete delete delete delete delete delete delete The method of claim 1,
The relationship between the change amount of the aperture level and the change of angle of view according to the change of the zoom level, the change of screen brightness due to each, and the first current correction value and the second current correction value are provided in a table. And a projector system for calculating the final current correction value with reference to the table. The method of claim 1,
And a distance recognition sensor measuring a distance from the lens unit to the screen. Recognizing reference information including a current zoom level and an aperture level;
Determining whether the zoom level has changed;
Calculating a first correction value for correcting a screen brightness due to a change in aperture according to a change in the zoom level;
Calculating a second correction value for correcting a screen brightness due to a change in angle of view according to the change of the zoom level; And
Correcting a current value for controlling a light source lamp in consideration of the first correction value and the second correction value. The method of claim 11,
Recognizing a change in the aperture level according to the zoom level change;
Calculating a change in screen brightness due to the change in the aperture level, and
And calculating a first current correction value for correcting the change in screen brightness. Claim 13 was abandoned upon payment of a registration fee. The method of claim 12,
Recognizing a change in angle of view according to the zoom level change;
Calculating a change in screen brightness due to the change of angle of view; and
And calculating a second current correction value for correcting the change of the screen brightness. Claim 14 has been abandoned due to the setting registration fee. The method of claim 13,
And calculating the final current correction value by adding the first current correction value and the second current correction value. Claim 15 is abandoned in the setting registration fee payment. 15. The method of claim 14,
The relationship between the change amount of the aperture level and the change of angle of view according to the change of the zoom level, and the change of screen brightness due to each of the changes, the first current correction value and the second current correction value are provided as a table. The control method of the projector system for calculating the final current correction value by reference.

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