KR20120027594A - Power saving type video door phone having hd video transmission and method therefor - Google Patents

Abstract

PURPOSE: An energy saving video door phone with an HD(High Definition) image transmission function and a method thereof are provided to transmit an HD image on the video door phone by RS-485 mode and a differential image processing mode. CONSTITUTION: A door camera(100) outputs an HD image. The door camera transmits a captured digital image of a visitor in a long distance transmission method. A monitor unit(200) converts the digital image into a RGB(Red, Green, Blue) signal. The monitor unit displays the RGB signal in a display unit(201).

Description

Energy-saving video door phone with HD video transmission function and its method {POWER SAVING TYPE VIDEO DOOR PHONE HAVING HD VIDEO TRANSMISSION AND METHOD THEREFOR}

The present invention relates to a video door phone, and more particularly, to an energy-saving video door phone having a high-definition video transmission function and a method thereof.

Recently, due to the importance of security and the development of image technology, the video door phone (hereinafter referred to as video phone) installed in the home has been developed in various ways in connection with functions such as home automation and home network.

The most basic function of the video phone is a video call with a visitor. The video phone is slightly different depending on the installation position of the camera, but is usually installed and operated within 35M of the camera. Therefore, when the visitor calls, the image captured by the door camera is transmitted along with the call signal to the video phone installed on the inner wall of the house, so that the two-way call is made between the visitor and the person in the house.

Since the video phone is usually operated at about 35M away from the door camera, the video quality is determined depending on which video transmission method is used to transmit the video captured by the camera to the video phone.

The most suitable video processing method with current technology is CVBS (Composite Video Blanking Sync) method. The CVBS method is a method in which a luminance, chromaticity, and sync signal are mixed and transmitted in one video line, and an image processed by the CVBS method is called a CVBS signal or a composite video.

1 is a block diagram of a conventional CVBS video phone.

As shown in FIG. 1, the conventional video phone system is largely composed of a camera unit 10 and a monitor unit 20.

The camera unit 10 is a part of photographing the visitor's video to the video phone 20 by the CVBS method, the camera module 11, the call button 12, the power control unit 13 and the call circuit unit 14 It includes.

The monitor unit 20 is a part showing a CVBS image (or composite image) transmitted from the camera unit 10 to a person in the house. The display unit 21, the control unit 22, the power supply circuit unit 23, and the call circuit unit It includes (24). In addition, the monitor 20 is provided with a memory for storing the image of the visitor and a speaker for outputting the voice of the visitor.

In addition, the camera module 11 of the door camera 10 includes a CCD camera for capturing an image of a visitor and outputting a CVBS image signal. The power control unit 13 provides a power supply (VCC) provided from the monitor unit 20 to the camera module 11, the call button 12 and the call circuit unit 14, the call circuit unit 12 Plays a role of delivering the visitor's audio to the monitor 20 through a call line.

In addition, the display unit 21 of the monitor unit 20 is composed of an LCD driver 21-1 and LCD 21-2, the LCD driver 21-1 is transmitted from the camera unit 10 The analog CVBS image is transferred to the LCD 21-2 and the LCD 21-2 is driven. The LCD unit 21-2 processes and displays an analog CVBS image on the screen.

The control unit 22 performs the overall control operation of the monitor unit 20, the power circuit unit 23 is the display unit 21, the control unit 22 and the call in the camera unit 10 and the monitor unit 20 The power supply VCC is supplied to the circuit unit 24. The call circuit unit 24 outputs the voice of the visitor transmitted from the call circuit unit 14 of the camera unit 10 to the speaker through the call line.

Hereinafter, the operation of a conventional video phone will be described.

When the visitor presses the call button 12, the call signal is transmitted to the control unit 22 of the monitor unit 22 through the call circuit units 14 and 24. At this time, the camera module 11 of the door camera 10 captures the visitor's image through the CCD camera 11-1, and then outputs an analog CVBS (composite image) signal mixed with luminance, chromaticity, and sync signals. It transmits to the monitor unit 20 through one video line.

The CVBS (composite image) signal transmitted from the CCD camera 11-1 of the camera module 11 is input to the display 21 of the monitor 20. The CVBS signal input to the display unit 21 is converted into an NTSC signal by the video scaler 21-1 and then displayed on the LCD 21-2. At this time, the power control unit 23 always supplies power to each part of the monitor unit 20 of the door camera 10.

Therefore, the person in the house can check the appearance of the visitor displayed on the LCD 21-2, and while listening to the voice of the visitor input through the microphone (not shown) through the call circuits 14 and 24. Two-way voice communication is performed.

In the CVBS method used in the camera unit 10 in the conventional video phone, since the luminance, chromaticity, and sync signals are all mixed in one video line, video loss is inevitably generated. In addition, since the conventional video phone uses an analog CVBS signal, the image quality is not good, and the current consumption is large by driving an analog CCD camera.

With the recent launch of 3D TV products, there is a high demand for HD-quality video, and the eyes of consumers are on the rise. In particular, high-definition video is realized in TVs and mobile phones, but home videophones installed in front of the entrance are still maintained at 525 lines at 270,000 pixels due to wiring limitations.

Therefore, the entrance video phone, which is conventionally implemented as a CVBS video (composite video), does not match the video level of consumers. However, the reality is that CVBS video is the only solution that can send video by wire from the entrance to the living room inside the house. As a result, the implementation of HD-quality video on video phones is more urgent than ever.

In addition, the conventional video phone uses a CCD camera with a large current consumption, and in particular, since the power supply circuit of the monitor unit always supplies power to all the elements, it is operated even in the absence of a visitor, thereby increasing standby power.

An object of the present invention is to provide a video door phone capable of high resolution (HD) image transmission.

Another object of the present invention is to provide a power-saving video door phone that can reduce power consumption by operating the camera and monitor only when the visitor presses the call button.

An energy-saving video door phone according to an embodiment of the present invention for realizing the above problem includes a camera capable of outputting a high resolution image, and transmits a digital image of a visitor photographed by the camera using a long distance transmission method. A door camera; And a monitor unit converting the digital image transmitted from the door camera into an RGB signal and displaying the same on a display unit.

The camera is a C-MOS camera.

The long distance transmission method includes an RS-485 transmission method and a differential image transmission method.

The door camera captures an image of a visitor and outputs a parallel digital video signal in ITU656 format and converts the parallel digital video signal output from the C-MOS camera into a serial digital video signal to convert the differential video signal. Contains DSP output.

The monitor unit includes a DSP for converting the differential image signal transmitted from the door camera to a parallel signal and outputting an RGB signal, and an LCD for displaying the RGB signal output from the DSP on a screen to implement an HD-class clear image. .

The monitor unit includes a power control unit for supplying power to each of the door camera and the monitor unit, wherein the power control unit supplies power to the door camera and the monitor unit only when the call button of the camera is pressed.

An operation method of an energy-saving video door phone according to an embodiment of the present invention for realizing the above object includes: detecting a visitor's call; Supplying power to each unit of the door camera and the monitor unit when the visitor's call is generated; Transmitting the captured digital image to the monitor using a long distance transmission method after playing the visitor's image; Converting the transmitted digital image into an RGB signal and displaying the same on a display unit.

The long distance transmission method includes an RS-485 transmission method and a differential image transmission method.

The energy-saving video door phone having a high-definition video transmission function according to the embodiment uses a low power consumption C-MOS camera that outputs a digital image, and transmits the digital image of the C-MOS camera over a long distance without loss. By using RS-485 method (serial data processing) and differential image processing method, it is possible to transmit HD-quality video from a video phone, thereby achieving low power consumption.

1 is a block diagram of a video door phone using a conventional analog output method.
Figure 2 is a block diagram of an energy-saving video door phone using a digital output method according to an embodiment of the present invention.
FIG. 3 is a detailed configuration diagram of the camera module of FIG. 2, illustrating a transmission of a digital image. FIG.
4 is a view showing an embodiment of supplying power to the control unit of the indoor monitor when the call button is pressed in the present invention.
5 is a flowchart illustrating a method of operating an energy saving video door phone according to an embodiment of the present invention.

Hereinafter, a mobile terminal according to the present invention will be described in more detail with reference to the accompanying drawings. The suffixes "module" and "unit" for components used in the following description are merely given in consideration of ease of preparation of the present specification, and do not impart any particular meaning or role by themselves. Therefore, it should be noted that the "module" and "unit" may be used interchangeably with each other.

According to the present invention, if the parallel digital image output from the CCD camera is not simply converted into the CVBS method, the parallel digital image can be transmitted as it is, and the consumer provides a clearer picture quality product. Pointed out that we will be able to take on new product trends.

In addition, the present invention can reduce the standby power normally consumed by the camera if the power is usually designed to turn off the door camera and operate the camera and other main parts (display and control unit) only when the visitor presses the call button. Notice that it is.

On the basis of the above-mentioned rocking points, the present invention provides a design concept of a new concept entrance video phone which is a combination of digital image processing technology and data signal processing technology. In particular, the present invention meets the energy saving [green system] that is emerging as a recent issue, and applied the demand for high-quality video to general home video door phones.

That is, the basic concept of the present invention is to use a digital image (CCIR656 format) of a C-MOS camera module that has recently been developed to mega pixels without using a CVBS image output from a conventional CCD camera. The CCIR656 is a digital component interface standard for implementing 525 lines of TV images, also called ITU-656.

In particular, the present invention uses a C-MOS camera capable of low current consumption instead of a conventional CCD camera with a large current consumption, and normally does not supply power to the control unit of the monitor unit, but only when the visitor presses the call button. This provides a video phone capable of low power consumption and high quality video transmission.

2 is a block diagram of a video phone according to an embodiment of the present invention.

As shown in FIG. 2, the video phone according to the embodiment of the present invention has a number except for the configuration and some configuration of the camera module 101 of the door camera 100 and the LCD unit 201 of the monitor 200. It is basically the same as that of FIG. The monitor 20 includes a memory for storing the visitor's image, and a microphone and a speaker for inputting and outputting the visitor's voice.

The camera module 101 of the door camera 100 outputs a digital video signal of an ITU656 format by capturing an image of a visitor and outputs the C-MOS camera 101-1 and the C-MOS camera 101-1. And a digital signal processor (101-2) for converting the digital image into a serial digital image (RS-485 transmission method) and outputting differential image signals (image + and image).

The display unit 201 of the monitor unit 200 converts the differential image signal transmitted from the door camera 100 into a parallel signal and outputs an RGB signal and the DSP 201-1. It is composed of an LCD (201-2-2) to display the RGB signal output from the screen to implement a clear HD image.

3 is a detailed block diagram of the camera module 101 shown in FIG. 2.

The C-MOS camera 101-1 photographs a visitor's image and outputs an 8-bit image signal, a horizontal sync signal Hsync, and a vertical sync signal Vsync in ITU656 format. Since the digital video signal output from the C-MOS camera 101-1 is relatively high speed, the signal can be transmitted only within a short distance of 30 cm or less. Therefore, the DSP 101-2 multiplexes the digital video signal outputted from the C-MOS camera 101-1, performs a dual signal processing for long-distance (about 35M) transmission, and then applies a differential signal (video + And video).

Accordingly, the digital video signal output from the C-MOS camera 101-1 is converted into serial data in the DSP 101-2 for long-distance transmission (RS-485) and then duplicated signal processing (differential image processing) Manner) is performed. In other words, RS-485 and differential image processing are used for long-distance transmission of high-quality video data without video loss.

4 is a schematic configuration diagram for implementing a power saving video phone.

In general, in the video phone, the standby mode means that the controller 220 is in a sleep state with the minimum function while consuming the minimum current (standby current). Therefore, the present invention proposes a method of reducing the minimum standby current applied to the controller 220 by controlling the power applied to the controller 22 using the relay 205 when the video phone is not in use.

That is, the present invention does not normally supply power to the camera module 101, the display unit 201, the control unit 220 and the call circuit unit 104, 204, but the visitor presses the call button 102 of the camera. It provides a video door phone capable of low power consumption and high quality video that can be more power-saving by applying power to each unit only when pressed.

2 and 4, the minimum power is normally supplied to operate only the call button 102 and the relay 205 so that the camera module 101, the display unit 201, the controller 220, and the call circuit unit ( 104 and 204 are turned off.

Then, when the visitor presses the call button, a low level signal (by ground) is transmitted to the power circuit unit 203 of the monitor unit 200 through the call line and the relay 205. In this case, the relay 205 attaches a contact when a low level call signal is input, and applies a low level signal transmitted through the call line to the power circuit unit 203 of the monitor 200.

Therefore, when a low level call signal is input through the call line, the power circuit unit 203 supplies power to the camera module 101, the display unit 201, the control unit 220, and the call circuit unit 104, 204. To ensure that visitor shoots and two-way calls can be made normally.

Hereinafter, the operation of the video phone of the present invention will be described with reference to the accompanying drawings.

5 is a flowchart illustrating a method of operating an energy saving video door phone according to an embodiment of the present invention.

As shown in FIG. 5, a minimum power is initially supplied such that only the call button 102 and the relay 205 are operated (S10). As a result, most elements of the door camera 100 and the monitor unit 200 are turned off.

When the visitor presses the call button 12, a low level call signal is applied to the power circuit unit 203 of the monitor unit 22 through the call circuit units 14 and 24. When the call signal is detected, the power circuit unit 203 supplies a normal power supply (VCC) to the display unit 201, the control unit 220, and the call circuit unit 204 of the monitor unit 200, and at the same time the door camera 100 Supply to the camera module 101 and the call circuit unit 104 (S20 ~ S40).

The C-MOS camera 101-1 of the camera module 101 outputs a digital video signal of ITU656 format by photographing a visitor's appearance, and the DSP 101-2 outputs the C-MOS camera 101-1. After multiplexing the digital video signal outputted by the multiplied signal processing for long distance (about 35M) transmission and outputs the differential signal (video + and video) through two lines (S50).

The differential signal (image + and image) transmitted from the door camera 100 is converted into an RGB signal by the DSP 201-1 of the display unit 201 and then output to the LCD 201-2 so as to display the visitor's image. Is displayed on the screen. Therefore, the person in the house performs a direction call by performing a call through a microphone and a speaker separately provided while viewing an image of the visitor displayed on the LCD 201-2 (S60).

As described above, the present invention uses a low-power C-MOS camera for outputting a digital image, and differentiates the RS-485 method (serial data processing) to transmit the digital image of the C-MOS camera over a long distance without loss. By using the image processing method, HD video pre-consumption and low power consumption are realized in the video phone. For example, the output of a conventional CCD camera is up to 270,000 pixels, but the C-MOS output is capable of realizing more than 200 million colors.

In addition, according to an embodiment of the present invention, the above-described method may be embodied as computer readable codes on a medium in which a program is recorded. The computer-readable medium includes all kinds of recording devices in which data that can be read by a computer system is stored. Examples of the computer-readable medium include ROM, RAM, CD-ROM, magnetic tape, floppy disk, optical data storage, and the like, and also implemented in the form of a carrier wave (for example, transmission over the Internet) . The computer may also include a control unit of the terminal.

The mobile terminal described above can be applied to not only the configuration and method of the embodiments described above but also all or some of the embodiments may be selectively combined so that various modifications may be made to the embodiments It is possible.

100: door camera 101: camera module
102 call button 103 power control unit
104, 204: call circuit 200: monitor
201: display unit 202: control unit
203: power supply circuit section 205: relay

Claims (8)

A door camera including a camera capable of outputting a high resolution image and transmitting a digital image of the visitor photographed in the camera by using a long distance transmission method;
An energy-saving video door phone, comprising: a monitor unit converting the digital image transmitted from the door camera into an RGB signal and displaying the same on a display unit. The method of claim 1, wherein the camera
Energy-saving video door phone, characterized in that the C-MOS camera. The method of claim 1, wherein the long distance transmission scheme
A video door phone comprising an RS-485 transmission method and a differential video transmission method. The method of claim 1, wherein the door camera
A C-MOS camera that outputs a parallel digital video signal in ITU656 format by taking a visitor's video, and a DSP that converts the parallel digital video signal output from the C-MOS camera into a serial digital video signal and outputs a differential video signal. Energy-saving video door phone comprising a. The method of claim 1, wherein the monitor unit
And a DSP for converting the differential video signal transmitted from the door camera into a parallel signal and outputting an RGB signal, and an LCD for displaying an RGB signal output from the DSP on a screen to implement a clear HD image. Energy-saving video doorphone. The method of claim 1, wherein the monitor unit
And a power control unit for supplying power to the door camera and the monitor unit, wherein the power control unit supplies power to the door camera and the monitor unit only when the call button of the camera is pressed. Door phone. Detecting a visitor's call;
Supplying power to each unit of the door camera and the monitor unit when the visitor's call is generated;
Transmitting the captured digital image to the monitor using a long distance transmission method after playing the visitor's image;
And converting the transmitted digital image into an RGB signal and displaying the converted digital image on a display unit. The method of claim 7, wherein the long distance transmission method
A method of operating a video door phone comprising an RS-485 transmission method and a differential image transmission method.

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