KR20240040208A - CCTV High Definition Image Data Long Distance Transmission System - Google Patents

Abstract

The present invention relates to a long-distance transmission system of high-definition (HD) video data for CCTV through high-definition video interpolation. The long-distance transmission system of multi-channel high-definition (HD) video data according to the present invention uses existing wired UTP cables while wirelessly High-definition video data transmitted using a combination of transmission is interpolated for mutual loss compensation and time delay is corrected, and low-loss high-definition video data is transmitted to the receiving end even during long-distance transmission, providing clear images to users.

Description

CCTV High Definition Image Data Long Distance Transmission System

The present invention relates to a long-distance transmission system for CCTV high-definition video data. A plurality of digital high-definition video signals captured by a high-definition camera are stored in a local video storage device of the transmission unit, and the modulated digital high-definition video signals are transmitted through a single line cable. This relates to a long-distance transmission system for high-definition video data for CCTV that can be transmitted over a distance of 1 km or more.

The demand for CCTV security systems for disasters, traffic, surveillance of the elderly and children, etc. is continuously increasing.

The core technologies of the CCTV transmission system are classified into cameras, video storage, video transmission and control, etc. Among these, video transmission involves sending data from cameras obtained from cameras over long distances at high speed without loss using the minimum number of lines. It's purpose.

In general, CCTV's video transmission system has multiple CCTV cameras installed and managed by a control or integrated control unit, and a signal system such as video transmission and camera adjustment is required to systematically manage and control them, so two-way communication is possible. A network is being formed and systemized.

However, when transmitting high-definition video, when CCTV is installed outdoors, the distance to the control system increases and exposure to noise elements increases, so the transmission method has become a problem.

In addition, in the video transmission, it is usually possible to connect with a BNC or UTP cable within about 1 km, but beyond that, optical communication technology must be used. The core of the optical communication technology used in the CCTV transmission system is technology to convert video signals into optical signals, optical signal protocol technology, and multiplexing technology to transmit and receive various signals on one line.

It has recently been reported that the above optical communication technology can be used in a nearly lossless manner over 12 km or more at a transmission speed of 100 Mbit/s per channel for more than 20 channels, but this is only in the research stage. In the case of actual HD-level CCTV, it is similar to existing SD-level CCTV. Due to the significantly higher data size, the reality is that there are limitations in network transmission or data processing on servers. In other words, HD video signals taken from HD CCTV could only transmit images of a fixed size, so if high resolution video was transmitted, network traffic would increase too much, and in order to resolve network traffic, the resolution would be too low. When transmitting video, there is a disadvantage in that traffic is reduced, but the receiving end has to view low-quality video.

In addition, optical communication transmission lines have the disadvantage of being very vulnerable when the installation direction is not only a straight line but also a curved path, such as in the case of path movement due to the embedding of optical cables in a straight line. In addition, above all, problems with buried optical communication transmission lines remain in that the components and installation costs are too expensive and all existing transmission facilities must be dismantled to construct new ones.

In order to solve the problems described above, the purpose is to provide a long-distance transmission system for video data that can transmit high-definition video data to users while reducing loss from the receiving end to the output unit.

The long-distance transmission system for multi-channel high-definition video data for CCTV is HD TX, which receives multiple digital high-definition video signals captured by multiple HD cameras (10), converts them into multiple analog video signals, and outputs them through a parallel UTP cable. (20) and an HD junction box (30) for serially transmitting the plurality of analog video signals according to time changes through a 1-line coaxial cable (UTP cable) connection of the video signals generated by modulating the plurality of analog video signals. , a video signal receiver 40 that demodulates the video signal to extract a plurality of analog video signals; An HD RX 50 that converts the extracted analog signal into a digital high-definition video signal, a first image processor 60 that performs image processing, and image interpolation and delay time after detecting and comparing different high-definition video signals It includes a control unit 70 that interpolates, a DVR 80 that stores the converted digital high-definition video signal, and an output unit 90 that reproduces the digital high-definition video signal, and an HD junction box 30. A second video transmitter 100 is provided, and the HDRX 50 is provided with a second video receiver. The second video transmitter is wirelessly connected to the second video receiver via a hub, and is also connected to the HD junction. The box 30 performs coding processing according to signal data preset for each HD camera, and the signal data is a time slot, time slot period, and coding method, and the different high-definition video transmissions include first video transmission and second video transmission. It is a video transmission, and the first video transmission is a video transmission through the HD junction box 30, a video signal receiver 40, and an HD RX 50, and the second video transmission is a second video transmission unit 100, a hub ( HUB), which is video transmission through the second video receiver 110.

The long-distance transmission system for multi-channel high-definition (HD-level video) video data has the advantage of effectively performing long-distance transmission by interpolating the signal attenuation of high-definition video data. High-definition video is transmitted based on the first video transmission. In addition, the high-definition video is simultaneously transmitted through the second video transmission, and the control unit of the receiving end detects the previously stored video for which the video processing of the first video transmission has been completed, compares it with the video transmitted as the second video transmission, and then determines the video. After correcting and synchronizing interpolation and delay times, lossless, high-quality video can be provided to users. In addition to the advantage of being able to use a conventional wired line, it is possible to obtain and reproduce high-definition video as is at the RX receiving end by comparing and determining whether there is video loss and using a control unit that has video interpolation and delay time interpolation functions. Accordingly, it is possible to efficiently provide users with clear, high-definition images that can achieve the purposes of quick parking guidance, fire detection, and surveillance of theft or intrusion.

Figure 1 shows a long-distance transmission system for multi-channel high-definition (HD-level video) video data for CCTV according to the present invention. Figure 2 shows a long-distance transmission system for multi-channel high-definition (HD-level video) video data for CCTV according to the present invention. This shows the control part of .

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

Figure 1 shows a long-distance transmission system for multi-channel high-definition video data for CCTV according to the present invention.

The long-distance transmission system for multi-channel high-definition video data for CCTV according to the present invention is largely transmitted in parallel with first video transmission and second video transmission.

First image transmission will be described with reference to the drawings. First, a plurality of HD cameras 10 that capture digital high-definition images are each connected to the HD TX 20 in parallel. The HD TX (20) receives digital high-definition video signals captured from a camera, converts them into a plurality of analog video signals, and outputs them through a parallel UTP cable. The HD junction box 30 performs coding according to signal data preset for each HD camera and multiplexes the coded video signals to generate one video signal. In addition, the HD junction box modulates the generated video signal into a carrier wave and transmits it through a 1-line coaxial cable.

Meanwhile, the signal data may include a timeslot, timeslot period, and coding method. The video signals are coded using different coding methods and sequentially assigned to time slots, and the coding method order of the video signals may be changed at a preset time slot period.

The video signal can be selectively coded among coding methods such as convolution code, LDPC code, and RS code. For example, the first HD camera may be set to code using a convolution code, the second HD camera may be set to code using an RS code, and the third HD camera may be set to code using an RS code. there is. Subsequently, the coded video signals are assigned to time slots according to a preset order.

Additionally, the coding order of the coding process may be changed on a time slot cycle basis. For example, if the 1st, 2nd, and 3rd HD cameras are coded in the order of convolution code, LDPC code, and RS code, respectively, in the Nth time period slot, the 1st, 2nd, and 3rd HD cameras are coded in the N+1th time period slot. Can be coded in the following order: RS code, convolution code, and LDPC code, respectively.

The generated video signal is then serially transmitted as an analog video signal according to time changes through a 1-line coaxial cable (UTP cable) connection. The one-line coaxial cable may have a long length of at least 1 km or more.

Next, the second video transmission will be described. Referring to FIG. 1, the HD junction box 30 is further provided with a second video transmission transmitter 100 for transmitting high-definition video by streaming. The second video transmission transmitter includes a first gain differential amplifier that amplifies the video gain of the converted video signal to reduce loss when transmitting the wired video signal over a long distance. The video signal output from the second video transmission transmitter is transmitted to the second video transmission receiver 110 through a relay unit (HUB). Additionally, the second video transmission transmitter transmits signal data generated from the HD junction box to the second video transmission receiver.

The second video transmission unit can transmit streaming of high-definition video data over a wireless network using either MPEG-4 or H.264, which compresses and transmits the data.

The second video transmission receiver includes a signal restorer that performs signal restoration to compensate for attenuation of the video signal, a CMOS amplifier that amplifies the restored signal and performs streaming modulation of the analog video signal, and performs time division demultiplexing to provide multiple signals. It includes a second image processing processor that parallel processes high-definition image data and distributes the video stream.

The video signal received from the second video transmission and reception unit is transmitted to the control unit, and the signal data received from the second video transmission and reception unit is transmitted to the HD RX.

Meanwhile, the video signal receiver 110 demodulates a video signal transmitted from a 1-line coaxial cable, and HD RX converts the demodulated analog video signal into a digital video signal.

The HD RX 50 decodes the demodulated video signal based on signal data. The HD RX decodes the demodulated video signal based on a coding method according to the timeslot and timeslot period and outputs it to the first video processor.

The first image processing unit includes a multiplexer, a first image processing processor, a scaler, and a first image detector. Additionally, the first image processing processor further includes a GPU for graphics processing and a display formatter for display format conversion. .

The multiplexer distributes a plurality of transmitted high-definition images in parallel for image processing.

The first image processing processor processes graphic image processing and display format conversion on the first image signal distributed in parallel.

The scaler realigns and arranges the first image signal. In addition, the scaler upscales the processed high-definition image data after image processing and displays the lost pixel information on the display so that it can be confirmed.

The first image detector detects the first image at a time designated by the user's selection.

Next, the control unit 70 detects two high-definition video signals transmitted through the first video transmission and the second video transmission, makes a comparison decision, and then processes video interpolation and delay time interpolation.

The DVR 80 records digital high-definition video signals, and the output unit 90 outputs high-definition video signals.

Hereinafter, with reference to FIG. 2, the control unit of the long-distance transmission system according to the present invention will be described.

Figure 2 shows the control unit of a long-distance transmission system for multi-channel high-definition (HD-level video) video data for CCTV according to the present invention.

The control unit 70 of the transmission system according to the present invention includes a second image detection unit 71, an image matching unit 72, an image interpolation unit 73, a delay time correction unit 74, and an HD output unit ( 75).

The second image detection unit 71 detects a second image that can be compared with a designated time following transmission of the first image.

In this way, the image selected in the first image detection unit of the first image signal processing unit is transmitted to the image matching unit together with the corresponding image selected in the second image detection unit.

The image matching unit 72 matches the first image of the first image detector with the second image of the second image detector. The image matching unit may additionally be configured with a loss compensation image synthesis unit by having a loss compensation value of the image data. Accordingly, it is possible to apply image interpolation by considering the exact loss value.

The image interpolation unit 73 interpolates the lost image based on the matched image. Specifically, the image interpolation unit restores the lost pixel image by comparing it with the image data of the second detection unit 71, which detects the video stream transmitted using the RGB format converted by the display formatter.

The delay time correction unit 74 determines the delay time of the first image and the second image and corrects the delay time. Preferably, after determining the delay time, the pre-stored high-definition image data can be configured to be collectively corrected through the user's selective input. The first image may be transmitted by wire, and the second image may be transmitted wirelessly.

In this way, the final corrected high-definition video signal is transmitted to the HD output unit 75 using an HDMI (High Definition Multimedia Interface) connection.

Using the long-distance transmission system of video data according to the present invention, places such as large buildings or shopping centers with a video transmission distance of 1 km or more can be captured by up to 256 HD cameras while classified into multiple transmission units (HD TX). By managing one video through one PC, it can be controlled through one central control room consisting of 256 HD cameras.

In addition, for the central control, an integrated management control unit is installed, and a large capacity server is installed to store the transmitted video data in real time, compare and match it, and process high-definition video in batches through delay time and video interpolation.

The biggest advantage of the present invention is that it uses conventional wired transmission facilities as is and adds only a second video transmission facility to compensate for the attenuation rate and interpolates the loss portion when transmitting each high-definition video data at the receiving end, providing the user with high-definition video data. can be provided.

Above, the present invention has been described in detail through specific embodiments, but the present invention is not limited to the above embodiments, and various modifications can be made by those skilled in the art within the scope of the technical idea of the present invention.

10: Multiple HD Cameras 20: Multiple HD TX
30: HD junction box 40: Video signal receiver
50: HD RX 60: first image processing unit
70: Control unit 80: DVR
90: output unit 100: second video transmitter
110: second video receiver

Claims (1)

In a long-distance transmission system of multi-channel high-definition video data for CCTV through time and video interpolation, a plurality of digital high-definition video signals taken from a plurality of HD cameras (10) are received and converted into a plurality of analog video signals using a parallel UTP cable. an HD TX (20) that outputs a plurality of analog video signals through a 1-line coaxial cable (UTP cable) connection, and an HD junction box (30) that serially transmits video signals generated by modulating a plurality of analog video signals. ) and a video signal receiver 40 that demodulates the video signal to extract a plurality of analog video signals; An HD RX 50 that converts the extracted analog signal into a digital high-definition video signal, a first image processor 60 that performs image processing, and image interpolation and delay time after detecting and comparing different high-definition video signals It includes a control unit 70 that interpolates, a DVR 80 that stores the converted digital high-definition video signal, and an output unit 90 that reproduces the digital high-definition video signal, and the HD junction box 30 ) is provided with a second video transmitter 100, and the HD RX 50 is provided with a second video receiver, and the second video transmitter is wirelessly connected to the second video receiver via a HUB, The HD junction box 30 performs coding processing according to signal data preset for each HD camera, and the signal data is a time slot, time slot period, and coding method, and video transmission transmitted through the one-line coaxial cable is performed in multiple ways. The video captured by the HD camera is coded with preset signal data and then transmitted to the HD RX (50) through the video signal receiver 40, and the signal data is transmitted to the HD RX through the second video receiver 110. is transmitted, and HD RX is configured to decode the video signal based on signal data. The different high-definition video transmissions are first video transmission and second video transmission, and the first video transmission is through the HD junction box (30). , video transmission through the video signal receiver 40 and HD RX 50, and the second video transmission is video transmission through the second video transmission unit 100, hub, and second video reception unit 110. A long-distance transmission system for multi-channel high-definition video data for CCTV.
Claim 2
The method according to claim 1, wherein the first image processing unit includes a multiplexer, a first image processing processor, a scaler, and a first image detection unit, and the multiplexer distributes a plurality of transmitted high-definition images in parallel for image processing. , the first image processing processor processes the parallel distributed first image signal for graphic image processing and display format conversion, the scaler rearranges and arranges the first image signal, and the first image detector operates according to the user's selection. A long-distance transmission system for multi-channel high-definition video data for CCTV, characterized by detecting the first video at a specified time.
Claim 3
The method according to claim 1, wherein the control unit 70 includes a second image detection unit 71, an image matching unit 72, an image interpolation unit 73, and a delay time correction unit 74, and the second image detection unit 70 The image detection unit 71 detects a second image that can be compared with a specified time according to the transmission of the first image, and the image matching unit 72 detects the first image of the first image detection unit and the second image of the second image detection unit. Matching the images, the image interpolation unit 73 interpolates the lost image based on the matched image, and the delay time correction unit 74 determines the delay time of the first image and the second image to determine the delay time. A long-distance transmission system for multi-channel high-definition video data for CCTV, characterized by correcting.