KR101455331B1 - Digital photographing apparatus and method - Google Patents

Abstract

The present invention relates to a kind of digital photographing apparatus and a method thereof and, more particularly, to an apparatus and method for transmitting an original video at a remote place by IEEE 802.3 standard. The digital photographing apparatus according to the present invention includes a video head and a monitor. The video head includes a sensing device, a first conversion module, a first media access module, and a first hardware module. The monitor includes a second hardware module, a second media access module, a second conversion module, and a display device. The provided digital photographing method is configured to input several original video data from the first hardware module to the second hardware module through a transmission medium and a specific network standard.

Description

[0001] DIGITAL PHOTOGRAPHING APPARATUS AND METHOD [0002]

The present invention relates to an apparatus and method for digital photography, and more particularly, to an apparatus and method for transmitting raw video over long distances according to the IEEE 802.3 standard.

Currently, surveillance camera equipment is being used in various fields in various places. Especially, it is considered to be an essential equipment for the home with the elderly, children and patients. (CCTV), high-definition closed-circuit television (HDTV), high-definition closed-circuit television (HDTV) Camera (IP camera, Internet protocol camera, IP Cam).

Since conventional CCTV cameras use analog video signals, they can be used for real-time (Real Time), Plug and Play (PnP) It has a frame rate of 30 frames per second. Therefore, existing CCTV cameras have advantages such as short boot time, low cost without damaging or distorting video. However, the maximum transmission distance of conventional CCTV cameras is only 100 meters, and the resolution of transmitted video is rather bad. And CCTV camera lens line must be connected directly to VCR. If construction is complicated and the circuit is long, video is susceptible to external noise.

The HD CCTV camera uses a method of transmitting the compressed video data over the coaxial cable instead of the packet transmission method to the network. Second, the HD CCTV camera does not use the method of compressing or packetizing the video during the transmission, so there is no transmission delay of the video. In the case of HD CCTV cameras, it compensates some of the shortcomings of conventional CCTV cameras and maximizes its advantages.

For example: HD CCTV cameras have almost no latency in video transmission, have real-time, plug and play (PnP), and 30 frames per second (frame rate) Is a short, high-resolution video that does not damage or distort video at the same time, with a maximum transmission distance of up to 330 meters. However, HD CCTV has a fatal drawback. Since the signal is transmitted directly through the coaxial cable, the video is susceptible to external triggering. In addition, the cost is relatively high compared to other digital imaging equipment, making it difficult for users to easily receive.

An IP camera (Internet protocol camera) mainly compresses video data and then transmits video data over the Internet according to network communication protocols and standards.

Therefore, there are many hardware devices required when using an IP camera. IP cameras require large amounts of compression, configuration, conversion, and other processes to be performed. So, the IP camera hardware is usually very expensive for hardware such as microcontroller (CPU), SDRAM, Flash memory, network chip and so on. In addition, IP camera software requires a considerable amount of design and investment time because most of the software of the IP camera requires operating system and user interface software and has to consider various suitability of each network environment. Because a large amount of data has to be processed and operated, it is difficult to satisfy the functions of real time video transmission, Plug and Play (PnP), or 30 frames per second transmission rate. In addition, the IP camera has a drawback that it takes a long time to boot and the video is also distorted due to damage after compression, and the maximum transmission distance is only about 100 meters.

IP cameras can be monitored elsewhere over the network, but it is also not easy for a user to operate an IP camera. Because IP cameras often involve complex tasks such as hardware, operating systems, multipoint LANs, network protocols, etc., users often encounter various problems when using them.

Not only ordinary users but also ordinary IT professionals have to learn through the long learning time of using IP camera and camera maintenance method. To configure the camera, the user must first have a wired or wireless (Wi-Fi) Internet, a network router, a computer with network access privileges, and a browser.

The IP camera can be used after the setting is completed through the direct RAM cable (LAN cable). The user should be proficient at least port forwarding, DDSM setting, IP address, gateway, port, device conflict setting, router setting, DDNS setting, etc. But it can be said that it can work on its own.

Unfortunately, many IP cameras do not provide a user-friendly environment at present. The majority of users have difficulty using it because they do not have enough background knowledge.

SUMMARY OF THE INVENTION The present invention has been proposed to solve the above-mentioned problems, and it is an object of the present invention to provide a real time, Plug and Play (PnP), a frame rate of 30 frames per second, And a transmission distance of at least 500 meters (if the optical fiber is used, the transmission distance is more than 500 meters), and at the same time, a low cost digital imaging apparatus and method.

The present invention also provides a digital photographing apparatus and method capable of directly connecting to a computer and recovering raw video data through existing software when connected to a computer.

 According to an aspect of the present invention, there is provided a digital imaging apparatus including a video head and a monitor, wherein the video head includes a sensing element, a first conversion module, a first media access module, and a first hardware module.

One of them outputs the decoded original video as the first video data.

Then, after the first conversion module inputs the first video data, the first conversion module disassembles the first video data to generate a plurality of second video data again. Based on a particular network standard (e.g., the Institute of Electrical and Electronics Engineers 802.3 specification), this second video data is formatted to form multiple first data.

Then, after the first media access module inputs the first data, the first media access module formats the first data based on the specific network standard to form a plurality of second data. The first hardware module then enters this second data and formats the second data based on the particular network standard to form the third data.

The monitor includes a second hardware module, a second media access module, a second conversion module and a display device.

The second module inputs the third data and restores the third data through a specific network standard to form the corresponding second data.

The second media access module then enters this second data. Based on the particular network standard, the second media access module recovers this second data to form the first data described above.

The second transform module then restores the first data based on the specific network standard to form the corresponding second video data.

Then, the second video data is combined with the second conversion module to produce the corresponding first video data.

The display device then inputs the first video data and displays the corresponding video.

The first hardware module inputs the above-described third data to the second hardware module through a specific network standard and a transmission medium (e.g., RJ45 connector and CAT 5 cable).

To achieve the above objects and other objects, the present invention provides a digital photographing method as described below.

The video head execution video transmission program includes the following procedures.

(1) The video head decodes several first video data.

(2) The video head divides the first video data into several second video data.

(3) Based on a particular network standard, the video head processes this second video data to form several first data.

(4) The video head performs a media access control operation corresponding to a specific network standard to convert the first data into a plurality of second data.

(5) The video head executes the operation of the hardware corresponding to the specific network standard, and converts the first data into the third data.

The video display program of the monitor described above includes the following procedure.

(1) Through a specific network standard and transmission medium, the video head inputs such third data to the aforementioned monitor.

(2) The monitor executes the operation of the physical layer corresponding to a specific network standard to convert the third data into a plurality of second data.

(3) The monitor executes the media access control operation corresponding to the specific network standard to convert the second data into a plurality of first data.

(4) Based on the specific network standard, the monitor processes this first data to form the second video data.

(5) The monitor combines this second video data into the corresponding first video data, and then the monitor displays the video of the first video data.

According to the description of the preferred embodiment of the present invention, the video head described above includes a first control device. The first control device is connected to the aforementioned sensing device and the first media access module. The first controller is one overall internal Inter-Integrated Circuit controller (I2C).

According to the description of the preferred embodiment of the present invention, the above-mentioned video head includes a first timing generator and a first clock generator.

The first timing generator is connected to the above-mentioned first conversion module.

The first clock generator is connected to the first control device, the first media access module, and the timing generator mentioned above.

According to a preferred embodiment of the present invention, the first conversion module includes a first conversion device and a first buffer device.

Among them, the first conversion module is connected to the above-described sensing element.

The first buffer device is connected to the above-mentioned first conversion device.

The first buffer device includes a plurality of first-in first-out buffers.

According to the description of the preferred embodiment of the present invention, the first media access module described above includes N media access control devices. Where N is an integer greater than zero.

The media access control apparatus executes a media access control operation corresponding to the specific network standard described above.

The media access control apparatus includes a single encoder. The media access control apparatus encodes the corresponding first data to form corresponding second data.

According to the description of the preferred embodiment of the present invention, the first physical module includes M physical devices, which perform the operations of the physical layer corresponding to the specific network standard described above. M means an integer greater than zero.

According to the description of the preferred embodiment of the present invention, the above-mentioned monitor includes the second control device to which the above-described sensing element is connected and the above-mentioned first media access module.

The second control device described above is one I2C (Inter-Integrated Circuit controller).

According to the description of the preferred embodiment of the present invention, the above-mentioned monitor includes a second timing generator and a second clock generator.

The second timing generator is connected to the second conversion module described above.

The second clock generator is coupled to the second control device, the second media access module, and the timing generator described above.

According to the description of the preferred embodiment of the present invention, the above-mentioned second conversion module includes the second conversion device and the second buffer device.

The second conversion device is connected to the above-described display device.

The second buffer device is connected to the second conversion device described above, and the second conversion device includes a plurality of FIFO buffers.

According to the description of the preferred embodiment of the present invention, the above-mentioned second media access module includes N media access control devices. N means an integer greater than zero.

Such a media access control apparatus executes a media access control operation corresponding to the above-mentioned specific network standard.

The above-mentioned media access control apparatus includes one decoder. In order to form the corresponding first data, the media access control apparatus decodes the corresponding second data.

According to a preferred embodiment of the present invention, the above-mentioned second physical module includes M physical layer devices, and the second physical module executes a task of a physical layer corresponding to the above-mentioned specific network standard. M means an integer greater than zero.

According to the description of the preferred embodiment of the present invention, the specific network standard described above is the IEEE 802.3 standard (IEEE 802.3).

According to the description of the preferred embodiment of the present invention, the above-mentioned transmission medium is Category 5 cable (CAT 5), Category 6 cable (CAT 6) or optical fiber.

According to the description of the preferred embodiment of the present invention, the first data, the second data, and the third data described above include the raw data of the second video data described above, And has a corresponding packet format.

According to the present invention, the present invention transmits video data without damages and distortion without compression using the IEEE 802.3 standard and the category 5 cable of the Institute of Electrical and Electronics Engineers of the United States. In addition, since the present invention selectively uses only a part of the IEEE 802.3 standard, the present invention can omit a lot of complicated network operations. The present invention simplifies complicated network operations and the hardware system of the present invention is very simple, so no separate operating system (OS) is required.

According to the above-described configuration, the present invention has the following effects.

1. Plug-and-Play: Plug-and-Play: Plug-and-play, no need to set up the system.

2. Rapid boot: When the user plugs in the power, the present invention device is turned on instantly.

3. Real-time video: Because video data is not compressed, the transmission speed is greatly increased. Since the present invention can transmit video data immediately, the latency is less than 10 seconds.

4. Superior video quality: Because the video data is not compressed, the video is not damaged or distorted, and the transmission frame per second reaches 30 frames (FPS). In theory, the apparatus of the present invention does not need to drastically change the structure of the soft hardware. The higher the performance of the sensing device, the more the video quality can be maximized. Therefore, the device of the present invention can be considered to have a considerably extended function space.

5. Long distance transmission: According to the American Institute of Electrical and Electronics Engineers 802.3 specification and Category 5 cable specification, the present invention has a transmission distance of at least 500 meters. In addition, corrupted or undistorted video transmission is possible. The transmittable distance of the present invention is longer than that of the conventional photographing apparatus.

6. Low price: The hardware system of the present invention can be integrated into the SOC chip, and the apparatus of the present invention does not require any other operating system. Accordingly, the cost of the hardware system of the present invention is very low. Also, since the hardware and software system of the present invention is extremely simplified, the management and maintenance cost of the design and development processor can be greatly reduced.

7. High Reliability: Since the present invention is a highly integrated hardware and software system, the present invention has higher reliability than existing imaging devices.

As can be seen from the foregoing, the present invention overcomes the disadvantages of existing closed-circuit television systems (e.g., low quality video, easily affected external signals, very short transmissible distances, etc.) (Eg, real-time video, 30 frames per second FFS, fast boot, no configuration required, low cost). In addition, the present invention overcomes the disadvantages of IP cameras (e.g., slow boot, complex system configuration, no PnP, no real-time video transmission, less than 30 frames per second, high cost, short transmission distance). In addition, the present invention has kept the advantages of the IP camera (e.g., high-quality digital video) intact.

What is shown in Figure 1 is an architectural diagram of a digital device according to a preferred embodiment of the present invention;
Figure 2 shows a functional block diagram of a transmission circuit according to a preferred embodiment of the present invention;
Figure 3 is a functional block diagram of a receiving circuit according to a preferred embodiment of the present invention;
4 is a functional block diagram of a transmission circuit according to a preferred embodiment of the present invention;
Figure 5 is a functional block diagram of a receiving circuit according to a preferred embodiment of the present invention;
FIG. 6 is a functional block diagram of a media access control apparatus according to a preferred embodiment of the present invention;
Figure 7 is a functional block diagram of a first deque device according to a preferred embodiment of the present invention;
Figure 8 is a functional block diagram of a second incubation apparatus according to a preferred embodiment of the present invention;
Figure 9 is a schematic diagram of a method of video transmission ordering according to a preferred embodiment of the present invention;
Figure 10 is a schematic diagram of a method of video display ordering in accordance with a preferred embodiment of the present invention; And;
Figure 11 shows the comparison between the present invention and the prior art.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of a mobile phone case with a battery replacement door according to the present invention will be described with reference to the accompanying drawings.

The digital photographing apparatus includes a video head and a monitor, and the video head includes a sensing element, a first conversion module, a first media access module, and a first hardware module.

The monitor includes a second hardware module, a second media access module, a second conversion module and a display device.

The present invention allows a first hardware module to input a plurality of raw video data to a second hardware module through a specific network standard and a transmission medium.

1 is a structural explanatory diagram of a digital photographing apparatus according to a preferred embodiment of the present invention.

1, the digital photographing apparatus 100 includes a video head 102, a monitor 104, and a transmission medium 106. As shown in FIG.

Through which the video head 102 is electrically connected to the monitor 104 via the transmission medium 106.

In this embodiment, the transmission medium 106 is Category 5 cable, Category 5e cable, Category 6 cable or optical fiber. Among them, the video head 102 includes a sensing element 1022, a transmission circuit 1024 and an RJ-45 connector 1026.

The sensing element 1022 is connected to a transmission circuit 1024 and the transmission circuit 1024 is connected to an RJ-45 connector 1026 and the RJ-45 connector 1026 is connected to a transmission medium 106.

The monitor 104 also includes an RJ-45 connector 1042, a receiving circuit 1044 and a display device 1046.

Among them, the transmission medium 106 is connected to an RJ-45 connector 1042 and the RJ-45 connector 1042 is connected to a receiving circuit 1044. The receiving circuit 1044 is connected to the display device 1046.

When the user uses the digital imaging apparatus 100, the video head 102 transmits the corresponding video to the monitor 104 only when the power plug is plugged in, and the monitor 104 immediately displays the corresponding video.

Among them, the sensing element 1022 derives the corresponding video data, and inputs the video data to the transmission circuit 1024. [

The transmission circuit 1024 converts the video data into corresponding packet data based on the IEEE 802.3 standard, which is a specific network standard.

The transmission circuit 1024 transmits the corresponding packet data to the reception circuit 1044 through the transmission medium 106. [

Then, the receiving circuit 1044 converts the corresponding packet data into corresponding video data.

Then, the receiving circuit 1044 inputs the corresponding video data to the display device 1044, and displays the corresponding video.

2 is a block diagram of a transmission circuit according to a preferred embodiment of the present invention.

1 and 2, the transmission circuit 1024 includes a first conversion module 202, a first media access module 204, a first physical module 206, a first control device 208, Timing generator 210 and a first clock generator 212.

The first conversion module 202 is coupled to the sensing device 1022 and the first media access module 204 is coupled to the first conversion module 202 and the first physical module 206 is coupled to the first media access module 202. [ (Not shown).

The first controller 208 is coupled to the sensing element 1022 and the first media access module 204 and the first timing generator 210 is coupled to the first conversion module 202 and to the first clock generator 212 are connected to the first control device 208, the first media access module 204, and the timing generator 210.

Among them, the first conversion module 202 includes a first conversion device 2022 and a first buffer device 2024.

The first transducer 2022 is connected to the sensing element 1022 and the first buffer device 2024 is connected to the first transducer 2022 and the first media access module 204.

After the first conversion module 202 inputs the first video data, the first conversion module 202 decomposes the first video data into a plurality of second video data.

Based on the particular network standard, the first transformation module 202 processes this second video data to produce a plurality of first data. In other words, the first transcoding device 2022 formats the second video data into the first packet data corresponding to a specific network standard.

The first transducer 2022 then inputs this first data to the first buffer device 2024 and then the first buffer device 2024 inputs this first data to the first media access module 204 do.

Based on the particular network standard, the first media access module 204 processes the first data into a plurality of second data. That is, the first media access module 204 formats the first data into second packet data corresponding to a specific network standard. The first physical module 206 then enters the second data and processes this second data based on the particular network standard into a plurality of third data.

That is, the first physical module 206 formats the first data and makes the second data separately into third packet data corresponding to a specific network standard.

3 is a functional block diagram of a receiving circuit based on a preferred embodiment of the present invention.

1 to 3, the receiving circuit 1044 includes a second conversion module 302, a second media access module 304, a second physical module 306, a second control device 308, And includes a timing generator 310 and a second clock generator 312.

The second conversion module 302 is connected to the display device 1046. The second media access module 304 is connected to the second conversion module 302 and the second physical module 306 is connected to the second media access module 304. [ (Not shown).

The second control device 308 is connected to the display device 1046 and the second media access module 304.

The second conversion module 302 includes a second conversion device 3022 and a second buffer device 3024.

The second conversion device 3022 is connected to the display device 1046 and the second buffer device 3024 is connected to the second conversion device 3022 and the second media access module 304.

The first physical module 206 may input a plurality of third data to the second physical module 306 and then transmit the second physical module 306 ) Processes this third data into a plurality of second data. That is, the second physical module 306 formats the third data into second packet data corresponding to a specific network standard.

Then, the second physical module 306 inputs this second data to the second media access module 304. Based on the particular network standard, the second media access module 304 processes this second data into a plurality of first data.

That is, the second media access module 304 formats such second data to make the second data individually the first packet data corresponding to the specific network standard.

The second media access module 304 then enters this first data into the second buffer device 3024. [

Then, the second buffer device 3024 inputs the first data to the second conversion device 3022.

Based on the particular network standard, the second conversion module 3022 processes the first data to produce the corresponding second video data. That is, the second transform module 3022 reconstructs the first data to generate second video data corresponding to the first data.

Thereafter, the second conversion module 3022 combines the second video data to form the corresponding first video data.

Subsequently, the display device 1046 inputs the first video data and displays the corresponding video.

Here, the first data, the second data and the third data contain the raw data of the second video data and individually have a packet format corresponding to a specific network standard.

4 is a functional block diagram of a transmission circuit based on a preferred embodiment of the present invention.

2 and 4, the first buffer device 2024 includes a buffer 302, a buffer 304, and a buffer 306, although FIG. 4 has a configuration similar to that of FIG.

The buffer 302, the buffer 304 and the buffer 306 are individually connected to the first converter 2022. The first media access module 204 includes a main media access control device 308, a media access control device 310 and a media access control device 312.

The main media access control apparatus 308 is connected to the buffer 302. The media access control apparatus 310 is connected to the buffer 304 and the media access control apparatus 312 is connected to the buffer 306. [

The first physical module 206 includes a physical device 314, a physical device 316, and a physical device 318.

The physical device 314 is connected to the main media access control device 308 and the physical device 316 is connected to the media access control device 310. The physical device 318 is connected to the media access control device 312 do.

In this embodiment, the buffer 302, the buffer 304 and the buffer 306 are FIFO buffers (first in first out buffer), and the first control device is an inter-integrated circuit controller , I²C), and the specific network standard is IEEE802.3.

After the first conversion device 2022 inputs the first video data, the first conversion device 2022 decomposes the first video data into a plurality of second video data. Based on IEEE 802.3, the first transcoder 2022 packetizes this second video data into a plurality of first data.

That is, the first data is the first packet data corresponding to IEEE802.3.

Thereafter, the first conversion device 2022 inputs these first data to the buffer 302, the buffer 304, and the buffer 306 in order.

The buffer 302 then inputs the corresponding first data to the main media access control apparatus 308. The buffer 304 inputs the corresponding first data to the media access control apparatus 310 and the buffer 306 Inputs the corresponding first data to the media access control device 312. [

Next, the main media access control apparatus 308, the media access control apparatus 310 and the media access control apparatus 312 individually execute IEEE 802.3 media access control (MAC) Create the second data. That is, the second data is the corresponding second packet data of IEEE802.3.

Thereafter, the main media access control apparatus 308 inputs the corresponding second data to the physical apparatus 314, the media access control apparatus 310 inputs the corresponding second data to the physical apparatus 316, The media access control device 312 inputs the corresponding second data to the physical device 318. [

The physical device 314, the physical device 316 and the physical device 318 then individually perform the work of a physical layer (PHY) corresponding to IEEE80.3, thereby creating the corresponding third data . That is, the third data is the third packet data corresponding to IEEE802.3.

5 is a functional block diagram of a receiving circuit according to a preferred embodiment of the present invention.

The second buffer device 2024 includes a buffer 502, a buffer 504 and a buffer 506.

The buffer 502, the buffer 504 and the buffer 506 are individually connected to the second converter 2022.

The second media access module 304 includes a main media access control device 508, a media access control device 510 and a media access control device 512.

The main media access control device 508 is connected to the buffer 502. The media access control apparatus 510 is connected to the buffer 504 and the media access control apparatus 512 is connected to the buffer 506. [

The first physical module 306 includes a physical device 514, a physical device 516, and a physical device 518.

The physical device 514 is connected to the main media access control device 508 and the physical device 516 is connected to the media access control device 510. The physical device 518 is connected to the media access control device 512 do.

In the present embodiment, the buffer 502, the buffer 504 and the buffer 506 are FIFO buffers (first-in first-out buffers), and the first control device is an inter-integrated circuit controller (I2C) I²C). The specific network standard is IEEE802.3.

Through IEEE 802.3 and CAT 5, the physical device 314 enters the corresponding third data into the physical device 514 and the physical device 316 enters the corresponding third data into the physical device 516 , The physical device 318 inputs the corresponding third data to the physical device 518. [

Then, the physical device 514, the physical device 516, and the physical device 518 separately execute a job of a physical layer (PHY) corresponding to IEEE802.3 to create corresponding second data.

That is, the second data is the second packet data corresponding to IEEE802.3.

Thereafter, the physical device 514 inputs the corresponding second data to the main media access control device 508, the physical device 516 inputs the corresponding second data to the media access control device 510, The physical device 518 inputs the corresponding second data to the media access control device 512.

Thereafter, the main media access control apparatus 508, the media access control apparatus 510, and the media access control apparatus 512 individually execute the media access control (MAC) operation of IEEE802.3, It produces the first data.

That is, the first data is the first packet data corresponding to IEEE802.3. Next, the main media access control apparatus 508 inputs the corresponding first data into the buffer 502, the media access control apparatus 510 inputs the corresponding first data into the buffer 504, (512) inputs the corresponding first data to the buffer (506).

The buffer 502, the buffer 504 and the buffer 506 then input the first data to the second converter 3022 in order.

After the second converter 3022 inputs the first data, the second converter 3022 restores the first data to the corresponding second video data on the basis of IEEE802.3, and then the second converter 3022 3022 combine the second video data into the corresponding first data. Thereafter, the display device 1046 inputs the first data and displays the corresponding video.

6 is a block diagram illustrating functions of a media access control apparatus according to an exemplary embodiment of the present invention.

The media access control apparatus 600 includes a first enqueue device 602, a buffer module 604, a first deque device 606, a first auxiliary memory device 608, a failure detection device 610, a second enqueer device 612, a second auxiliary memory device 614, a buffer module 616 and a second deque device 618.

After the first data enters, the first incubation apparatus 602 is connected to the buffer module 604, and the buffer module 604 is connected to the first dequeue apparatus 606.

The buffer module 604 is connected to the first dequeue unit 606. The first dequeue unit 606 temporarily stores the data in the first auxiliary memory unit 608 and then sends the data to the second data unit.

When the third data enters the second incubation apparatus 612, it is temporarily stored in the second auxiliary storage apparatus 614. If a data abnormality is found, it is connected to the failure detection apparatus 610, 606 to send an error message to the second data.

If it is determined that the data is correct, it is connected to the buffer module 616, and the buffer module 616 is connected to the second dequeue device 618_, and the data is sent as the fourth data.

Referring to FIGS. 4 and 6, the main media access control device 308, the media access control device 310 and the media access control device 312 are very similar to the media access control device 600.

When the first data is input to the first enqueue device 602, the first enqueue device 602 writes the corresponding data to the buffer module 604 based on the corresponding flags, The buffer module 604 processes the corresponding data and allows the corresponding data to proceed to the 10 Gigabyte Media Interpentent Interface (XGMII) standard.

Then, the corresponding data is input to the first dequeue unit 606.

The first dequeue unit 606 performs a cyclical redundancy check (CRC). Thereafter, the first enqueue device 602 encodes the first data.

7 is a functional block diagram of a first deque device according to a preferred embodiment of the present invention.

The first dequeue device 606 includes a first data access device 702, a first cyclic redundancy check device 704, an encoder 706, a barrel shifter 708 and a first sensing device 710.

The first sensing device 710 is connected to the fault sensing device 610 and the encoder device 706. The first sensing device 710 and the failure sensing device 610 detect whether an error has occurred.

The encoder 706 encodes the corresponding first data to produce the corresponding second data.

Referring to FIGS. 5 and 6, the main media access control apparatus 508, the media access control apparatus 501 and the media access control apparatus 512 are very similar to the media access control apparatus 600.

When the second data is transmitted from the third data and input to the second enqueue device 612, the second enqueue device 612 transmits data to the 10 Gigabit Media Independent Interface (XGMII) It detects whether an error occurs in the process.

Then, the corresponding data is transmitted to the second auxiliary storage device 614, and a cyclical redundancy check (CRC) is performed on the corresponding data.

After the corresponding data is emerge, the corresponding data is written to the buffer module 616 based on the corresponding flags.

Then, the buffer module 616 again inputs the corresponding data to the second deque device 618.

Figure 8 is a second invasive device functional block diagram in accordance with a preferred embodiment of the present invention.

The second enqueue device 612 includes a second sensing device 612, a barrel shifter 804, a decoder 806, a second cyclic redundancy check device 808 and a second data access device 810.

The second data access device 810 transmits the corresponding fourth data to form the corresponding first data.

9 is a flowchart of a method of a transfer program according to a preferred embodiment of the present invention.

In the digital photographing method of the present invention, one video transmission program and one video display program are executed.

Among them, the video transmission program includes the following procedure.

The video head decodes the first video data (S102).

Thereafter, the video head decomposes the first data into a plurality of second video data (S104).

Subsequently, based on the specific network standard, the video head converts the second video data into a plurality of first data (S106).

Subsequently, the video head executes a media access control operation corresponding to a specific network standard (S108).

Then, the video head converts the first data into a plurality of second data (S110).

Subsequently, the video head executes the work of the physical layer corresponding to the specific network standard (S112).

Then, the video head converts the second data into a plurality of third data (S114).

Then, the video head inputs the third data to the monitor through the specific network standard and the transmission medium (S116).

10 is a flow chart of a method of a video display program according to a preferred embodiment of the present invention.

9 and 10, the method is a method of executing one video display program, and includes the following procedure.

Through the specific network standard and the transmission medium, the monitor decodes the third data (S202).

Thereafter, the monitor executes a job of a physical layer corresponding to a specific network standard (S204).

The monitor then converts the third data into a plurality of second data (S206).

Then, the monitor executes a media access control operation corresponding to a specific network standard (S208).

Thereafter, the monitor converts the second data into a plurality of first data (S210).

Then, based on the specific network standard, the monitor processes this first data to form second video data (S212).

Then, the monitor combines these second video data to produce the corresponding first video data (S214).

Then, the first video data is input to the monitor and the corresponding video is displayed (S216).

In this embodiment, the above-mentioned transmission medium includes a category 5 cable (CAT 5), a category 5e cable (CAT 5e), a category 6 cable (CAT 6), or an optical fiber.

In addition, the first data, the second data and the third data described above include the source data of the second video data.

In addition, each has a packet format corresponding to a specific network standard.

Here, it should be particularly noted that the first media access module and the second media access module each include N media access control devices.

The first physical module and the second physical module also include M physical devices individually. Where N and M are integers greater than zero.

Although FIGS. 4 and 5 illustrate an embodiment with N = M = 3, if the user is familiar with this technique and knows, then the apparatus and method of the present invention still work when N = M = 1.

Figure 11 shows a comparison of the present invention and prior art.

As shown in FIG. 11, the present invention not only overcomes the disadvantages of the prior art, but also retains the advantages of the prior art.

It should be noted that the above description is intended only to illustrate the present invention and not to limit the possibility of the practice of the present invention, in particular it should be borne in mind that the purpose described in detail is to assist in the understanding of the invention . However, users who understand and understand this technique should know that this is not the only solution. The above-described embodiments may be presented in other special forms without departing from the spirit or essential characteristics of the present invention. And the appended claims are therefore used to define the present invention.

Digital imaging devices: 100 Video heads: 102
Monitor: 104 Transmission Media: 106
Detection device: 1022 Transmission circuit: 1024
RJ-45 connector: 1026,1042 Receiving circuit: 1044
Display device: 1046 First conversion module: 202
First media access module: 204 First physical module: 206
First control device: 208 First timing generator: 210
First clock generator: 212 First converter: 2022
First buffer device: 2024 Second conversion module: 302
Second Media Access Module: 304 Second Physical Module: 306
Second control device: 308 Second timing generator: 310
Second clock generator: 312 Second converter: 3022
Second buffer device: 3024 buffer: 302, 304, 306, 502, 504, 506
Main media access control device: 308,508
Media access control device: 310,312,510,512,600
First Enqueue Device: 602 Buffer module: 604,616
First deque device: 606 First auxiliary memory device: 608
Fault detection device: 610 2nd enqueue device: 612
Second auxiliary storage device: 614 First data access device: 702
First cyclic redundancy checker: 704 Encoder: 706
Barrel shifter: 708,804
First sensing device: 710 Second sensing device: 802
Decoder: 806 Second cyclic redundancy check device: 808
Second data access device: 810

Claims (17)

A sensing element for outputting first video data; A first conversion module coupled to the sensing device for receiving first video data and decomposing the first video data into a plurality of second video data and processing second video data based on a specific network standard to form a plurality of first data; A first media access module connected to the first conversion module for inputting first data and forming a plurality of second data based on a specific network standard; A first physical module coupled to the first media access module for inputting second data and processing second data based on a specific network standard to form third data; And
A second physical module for inputting third data, for processing the third data based on the specific network standard to restore the second data; A second media access module connected to the second physical module for inputting second data and for processing second data based on a specific network standard to restore first data; A second media access module connected to the second media access module, for inputting first packet data, processing first data based on a specific network standard to form second video data, and combining the second video data to create first video data A second conversion module; And a display device, connected to the second conversion module, for inputting the first video data to display the corresponding video,
The first physical module inputs third data to the second physical module via a specific network standard and a transmission medium. The method according to claim 1,
Wherein the video head includes a first control device and the first control device is coupled to the sensing device and a first media access module. The method according to claim 1,
The video head comprises:
A first timing generator coupled to the first conversion module,
A first control device, and a first clock generator coupled to the first media access module and the first timing generator. The method according to claim 1,
Wherein the first conversion module comprises:
A first conversion device connected to the sensing element,
And a first buffer device coupled to the first transducer and the first media access module. 5. The method of claim 4,
Wherein the first buffer device comprises a plurality of FIFO buffers (first in first out buffer). The method according to claim 1,
Wherein each of the first and second media access modules includes N (an integer greater than zero) media access control devices and executes a media access control operation corresponding to a specific network standard. 6. The method of claim 5,
Wherein the media access control apparatus includes an encoder to encode the corresponding first data and form corresponding second data. The method according to claim 1,
Wherein each of the first and second physical modules comprises M (an integer greater than zero) physical devices and executes physical tasks corresponding to a particular network standard. The method according to claim 1,
Wherein the monitor comprises a second control device and the second control device is connected to the sensing element and the first media access module. The method according to claim 1,
The monitor includes:
A second timing generator coupled to the second conversion module,
A second controller, a second clock generator coupled to the second media access module and the second timing generator. The method according to claim 1,
Wherein the second conversion module comprises:
A second conversion device connected to the display device,
And a second buffer device coupled to the second transducer and the second media access module. 12. The method of claim 11,
Wherein the second buffer device comprises a plurality of FIFO buffers (first in first out buffer). The method according to claim 1,
Wherein the specific network standard is the Institute of Electrical and Electronics Engineers (IEEE) 802.3 standard. The method according to claim 1,
Wherein the transmission medium comprises at least one or a combination of at least one of a category 5 cable (CAT. 5), a category 5E cable (CAT. 5E), a category 6 cable (CAT, 6) or an optical fiber cable. The method according to claim 1,
Wherein the first data, the second data and the third data comprise raw data of the second video data and individually have a packet format corresponding to a particular network standard. Decoding the first video data, decomposing the first video data into a plurality of second video data, processing the second video data to form a plurality of first data based on a specific network standard, Converting the first data into a plurality of second data by executing a media access control operation corresponding to a network standard, and performing a physical layer operation corresponding to a specific network standard to convert the second data into a third plurality of data A video transmission program procedure including; And
The method comprising the steps of: inputting third data through a specific network standard and a transmission medium; converting a third data to a second plurality of data by executing a physical layer operation corresponding to a specific network standard; Converting the second data into a first plurality of data by executing a control operation, processing the first data to form second video data based on a specific network standard, Combining; And displaying a video corresponding to the digital video signal. 17. The method of claim 16,
Wherein the first data, the second data, and the third data both contain raw data of the second video data and each have a packet format corresponding to a particular network standard.

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