KR20200116281A - Computer input/output signal asynchronous time division multiplex transmission apparatus and method - Google Patents

Abstract

The present invention relates to a computer input/output signal asynchronous time division multiplex transmission device and method. The device comprises: at least one receiving KVM box for restoring an input/output signal on the basis of a sync signal, and transmitting the restored input/output signal to a corresponding input/output device; and a transmission KVM box. According to the present invention, a complicated connection line is simplified, and a transmission distance of a connection line can be increased.

Description

Computer input/output signal asynchronous time division multiplex transmission apparatus and method

The present invention relates to a computer input/output signal asynchronous time division multiplexing transmission apparatus and method, wherein input/output signals are serialized in an asynchronous time division multiplexing method (ATDM) in order to control a plurality of computers using at least one input/output device ( The present invention relates to an apparatus and method for asynchronous time division multiplexing transmission of computer input/output signals serialized and transmitted.

In general, various standards exist for an interface that transmits signals to input/output devices (keyboard, mouse, monitor, touch screen, control signal device, etc.) of a computer (PC). Among these, interfaces that are commonly used as digital video standard signals include HDMI (High Definition Multimedia Interface), DVI (Digital Visual Interface), and Displayport (DP).

In addition, HDMI control signals (I2C clock, I2C data, HPD, CEC) and Displayport control signals (AUX+, AUX-, DP_HPD) are widely used as control signals excluding video signals, and data transmission standards For example, USB (USB+/USB-) and RS232C (UART) are being used.

In addition, an AUDIO LEFT/AUDIO RIGHT signal may be used to transmit an audio signal, and a PS2 (PS2 keyboard, PS2 mouse) and IR signal may be used to transmit an input/output signal.

Meanwhile, in order to operate a computer input/output device (keyboard, mouse, monitor, touch screen, control signal device, etc.) from a distance of at least 10m or more, each signal is conventionally implemented by connecting each signal with a copper wire. At this time, repeaters are added to send long distances due to the respective signal technology specifications.

In addition, in an environment in which a plurality of computers rather than one computer is used, the number of connection lines for signals increases, and in some cases, a hassle of adding a plurality of repeaters occurs. Because of this, the connection line is complicated, so it takes a lot of construction time, and frequent A/S occurs.

Korean Patent Registration No. 10-0746840 (announced on August 09, 2007)

Therefore, the technical problem to be achieved by the present invention is to solve the conventional shortcomings, video control signals, keyboard signals, mouse signals, data signals, device control signals, touch screen data and audio excluding video signals which are high-speed data in input/output signals. The purpose of this is to simplify complex connection lines and increase the transmission distance of the connection lines by serializing and transmitting signals using Asynchronous Time Division Multiplexing (ATDM).

A computer input/output signal asynchronous time division multiplexing transmission apparatus according to an aspect of the present invention for achieving this technical problem may include a transmission KVM box and at least one reception KVM box. The receiving KVM box is respectively connected to at least one input/output device, and serializes the control signal and input/output signal of the input/output device based on a preset sync signal in an asynchronous time division multiplexing (ATDM) method. Then, it is transmitted to the transmission KVM box, and the input/output signal transmitted from the transmission KVM box can be restored based on the sync signal and transmitted to a corresponding input/output device.

In addition, the transmitting KVM box is connected to at least one computer (PC), and a control signal and an input/output signal transmitted from the receiving KVM box to control any one of the computers (PC) are restored based on the sync signal. It transmits to any one computer (PC) selected in advance, and serializes the signal transmitted from the computer in an asynchronous time division multiplexing (ATDM) method based on the sync signal and transmits it to the receiving KVM box. have.

In addition, a computer input/output signal asynchronous time division multiplexing transmission method according to another aspect of the present invention comprises the steps of selecting one of the reception KVM boxes for controlling the computer (PC) by driving the toggle switch of the first reception KVM box (S10). , Selecting one of the computers (PC) of the PC unit by driving the toggle switch of the selected receiving KVM box (S20), and transmitting a control signal or input/output signal to the corresponding receiving KVM box using the input/output device connected to the receiving KVM box. It may include the step of transmitting (S30).

In addition, the step of serializing (S40) a preset sync signal and the control signal or input/output signal in the receiving KVM box using an asynchronous time division multiplexing (ATDM) method (S40), and asynchronous time division multiplexing in the receiving KVM box Transmitting the transmitted signal to the transmitting KVM box (S50), checking the sync signal by receiving the signal transmitted from the receiving KVM box in the transmitting KVM box (S60), and receiving the received signal based on the sync signal in the transmitting KVM box It may include the step of restoring the signal and transmitting the signal to the selected PC (S70).

In addition, the step of receiving the input/output signal from the PC selected by the transmission KVM box (S80), and serialization of the preset sync signal and the input/output signal from the transmission KVM box in an asynchronous time division multiplexing (ATDM) method. ) And transmitting the asynchronous time division multiplexed signal from the transmitting KVM box to the receiving KVM box (S100).

In addition, the receiving KVM box receives the signal transmitted from the transmitting KVM box and checks the sync signal (S110), and the received KVM box restores the received signal based on the sync signal and transmits the input/output signal to the input/output device. It may further include a step (S120).

As described above, the apparatus and method for asynchronous time division multiplexing transmission of computer input/output signals according to the present invention include video control signals, keyboard signals, mouse signals, data signals, device control signals, and touch screens excluding video signals that are high-speed data from input/output signals. Data and audio signals are serialized and transmitted in an asynchronous time division multiplexing (ATDM) method, thereby reducing the number of complicated connection lines and simplifying. In addition, there is an effect of increasing the transmission distance of the connection line by overcoming the limitation of long-distance transmission due to each signal technology specification.

1 is a block diagram illustrating a computer input/output signal asynchronous time division multiplexing transmission apparatus according to an embodiment of the present invention.
2, 3 and 4 are block diagrams illustrating a computer input/output signal asynchronous time division multiplexing transmission apparatus according to an embodiment of the present invention.
5A is a block diagram illustrating a transmit KVM box according to an embodiment of the present invention.
5B and 5C are block diagrams illustrating a reception KVM box according to an embodiment of the present invention.
6A and 6B are diagrams illustrating a configuration of a serialized signal according to an embodiment of the present invention.
7 and 8 are flowcharts illustrating a method of transmitting asynchronous time division multiplexing of computer input/output signals according to an embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those of ordinary skill in the art may easily implement the present invention. However, the present invention may be implemented in various forms and is not limited to the embodiments described herein. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and similar reference numerals are attached to similar parts throughout the specification.

Throughout the specification, when a part "includes" a certain component, it means that other components may be further included rather than excluding other components unless otherwise stated. In addition, terms such as "... unit", "... group", and "... module" described in the specification mean a unit that processes at least one function or operation, which is implemented by hardware or software or a combination of hardware and software. Can be.

Hereinafter, the present invention will be described in detail by describing a preferred embodiment of the present invention with reference to the accompanying drawings.

The same reference numerals in each drawing indicate the same members.

1 is a block diagram illustrating a computer input/output signal asynchronous time division multiplexing transmission apparatus 10 according to an embodiment of the present invention, and FIGS. 2, 3, and 4 are asynchronous time division multiplexing transmission of computer input/output signals according to an embodiment of the present invention. It is a block diagram showing the device 10.

That is, FIG. 1 is a diagram illustrating a computer input/output signal asynchronous time division multiplexing transmission apparatus 10 to which three computers and two final input/output devices are applied according to an embodiment of the present invention. 3 is a diagram illustrating a computer input/output signal asynchronous time division multiplexing transmission device 10 using PS2 and RS232C as an interface, and FIG. This is a diagram of an implementation of the device 10.

In general, a computer does not feel much inconvenience because the input/output device 30 is located within a short distance (within 5m) of the computer, but controls the computer through several input/output devices 30, and the input/output device ( If 30) is located, technical difficulties arise in product implementation. Here, the input/output device 30 includes a keyboard (31_1, 32_1) for controlling a computer, a mouse (31_2, 32_2), a monitor (31_3, 32_3), a touch screen, and It may be made of at least one of the control signal input and output device.

Typically, a product is implemented by configuring a transmitting (TX) device and a receiving (RX) device for signal transmission between the computer (PC) and the input/output device 30. At this time, in the related art, all input/output signal lines connecting the computer and the input/output device 30 are implemented with respective copper wires, and a repeater is added to extend the length.

Alternatively, a product that connects the computer and the input/output device 30 may be implemented by adding each input/output signal to the video signal having the most data. Also, in the related art, signals are transmitted using respective signal lines (32 lines) connecting the computer and the input/output device 30. However, in this method, the number of signal lines connecting between the computer and the input/output device 30 is too large, and the transmission distance is also short, which causes inconvenience due to the addition of a repeater and processing of the signal lines.

The computer input/output signal asynchronous time division multiplexing transmission apparatus 10 according to an embodiment of the present invention transmits input/output signals between at least one computer and input/output devices (keyboard, mouse, monitor, touch screen, control signal input/output device, etc.)30. For this purpose, the number of signal lines can be simplified and the transmission distance can be increased by serializing the video control signals and input/output signals, excluding the video signal with the largest amount of data, in asynchronous time division multiplexing (ATDM). That is, it is possible to serialize and transmit a control signal and an input/output signal using an Asynchronous Time Division Multiplexing (ATDM) method without having a separate synchronization circuit.

In this case, a signal may be transmitted between the computer and the input/output device 30 via a local area network (LAN) cable 300, an optical cable, or wirelessly. Here, the LAN (Local Area Network, LAN) cable 300 is preferably CAT5, CAT6 or CAT7.

That is, the computer input/output signal asynchronous time division multiplexing transmission apparatus 10 according to an embodiment of the present invention transmits a signal using a LAN cable 300, so that the construction and maintenance of a signal line is simple, and when A/S occurs. A/S is easy and A/S time can be drastically reduced. In addition, power supplied to the monitor may be transmitted through a LAN cable 300. In addition, since signals are transmitted asynchronously, data can be transmitted not only through the LAN cable 300 but also through an optical cable or wirelessly.

The computer input/output signal asynchronous time division multiplexing transmission apparatus 10 according to an embodiment of the present invention is connected to a plurality of computers (PCs) to control each computer (PC), the transmission KVM box 100 and the input/output device 30 It may include at least one receiving KVM box 200 to be connected. That is, the number of receiving KVM boxes 200 may be determined to correspond to the number of final input/output devices 30.

For example, when the input/output device 30 for controlling a computer (PC) is composed of three, the first receiving KVM box 210, the second receiving KVM box 220, and the third receiving KVM box ( 230) may be provided.

An example of controlling three personal computers (PCs) using two input/output devices 30 according to an embodiment of the present invention will be described. In this case, the multiplexed transmission device 10 may include a transmission KVM box 100, a first reception KVM box 210, and a second reception KVM box 220.

In addition, the first receiving KVM box 210 may be connected to the first input/output device 31. In this case, the first input/output device 31 may include at least one of a keyboard 31_1, a mouse 31_2, a monitor 31_3, a touch screen, and a control signal input/output device.

That is, the first receiving KVM box 210 may be connected to the keyboard 31_1 and the mouse 31_2 using the PS2 interface. In addition, it may be connected to the monitor 31_3 through an RGB/DVI interface or an RS232 interface.

5A is a block diagram illustrating a transmit KVM box according to an embodiment of the present invention, and FIGS. 5B and 5C are block diagrams illustrating a receive KVM box according to an embodiment of the present invention. That is, FIG. 5B is a diagram showing a first receiving KVM box 210 capable of controlling the operation of each receiving KVM box 210, 220, and FIG. 5C is driven according to selection of the first receiving KVM box 210 It is a figure which shows the 2nd receiving KVM box 220 that becomes.

As shown in Figure 5b, the first receiving KVM box 210 includes a serialization module 211, a DC balancing module 212, a SYNC signal module 213, a toggle switch 214, and a toggle LED 215. I can. The serialization module 211 serializes a control signal and an input/output signal for transmission in an asynchronous time division multiplexing (ATDM) scheme.

The SYNC signal module 213 may be serialized to generate a preset sync bit so as to recognize an initial signal from a control signal and an input/output signal transmitted and received. The DC balancing module 212 converts the high level and the low level of the serialized signal to be DC balanced, respectively.

The toggle switch 214 may include a PC1 switch, a PC2 switch, a PC3 switch, a master switch, and a slave switch. The PC1 switch is selected to control the PC1 21 through the first input/output device 31, the PC2 switch is selected to control the PC2 22, and the PC3 switch controls the PC3 23. Choose to be able to.

In addition, the master switch enables control of each of the PCs 21, 22, and 23 to be performed by the first receiving KVM box 210 and the first input/output device 31, and a slave switch Transfers control rights for each of the PCs 21, 22, 23 to the second input/output device 32 to control the PC1(21), PC2(22) and PC3(23) through the second input/output device 32. Make it possible. In addition, the toggle LED 215 may respectively display the operating state of each toggle switch 214.

That is, the first receiving KVM box 210 serializes the control signal of the first input/output device 31 in an Asynchronous Time Division Multiplexing (ATDM) method based on a preset sync signal to transmit the KVM box 100. ). In addition, the first receiving KVM box 210 may restore the input/output signal transmitted from the transmitting KVM box 100 based on the sync signal and transmit the restored input/output signal to the first input/output device 31.

Similarly, the second receiving KVM box 220 may be connected to the second input/output device 32. In addition, the second input/output device 32 may include at least one of a keyboard 32_1, a mouse 32_2, a monitor 32_3, a touch screen, and a control signal input/output device.

That is, the second receiving KVM box 220 may be connected to the keyboard 32_1 and the mouse 32_2 using the PS2 interface. In addition, it may be connected to the monitor 32_3 through an RGB/DVI interface or an RS232 interface.

As shown in Figure 5c, the second receiving KVM box 220 includes a serialization module 221, a DC balancing module 222, a SYNC signal module 223, a toggle switch 224, and a toggle LED 225. I can. The serialization module 221 serializes a control signal and an input/output signal for transmission in an asynchronous time division multiplexing (ATDM) scheme.

The SYNC signal module 223 may be serialized to generate a predefined sync bit so as to recognize an initial signal from a control signal and an input/output signal transmitted and received. The DC balancing module 222 converts the high level and the low level of the serialized signal so that DC balancing is achieved, respectively.

The toggle switch 224 may include a PC1 switch, a PC2 switch, and a PC3 switch. The PC1 switch is selected to control the PC1 21 through the second input/output device 32, and the PC2 switch is selected to control the PC2 22 through the second input/output device 32, and PC3 The switch is selected to control the PC3 (23) through the second input/output device (32). In addition, the toggle LED 225 may display the operating state of each toggle switch 224, respectively.

That is, the second receiving KVM box 220 serializes the control signal of the second input/output device 32 in an Asynchronous Time Division Multiplexing (ATDM) method based on a preset sync signal to transmit the KVM box 100. ). In addition, the second reception KVM box 220 may restore a signal transmitted from the transmission KVM box 100 based on the sync signal and transmit it to the second input/output device 32.

2 and 5A, the transmission KVM box 100 is connected to at least one computer (PC) to receive input/output signals (keyboard signal, mouse signal, video signal, etc.) of the computer (PC), The input/output signals may be serialized according to a preset order and sequentially transmit signals to the reception KVM box 200.

At this time, the signal transmitted from the transmitting KVM box 100 to the receiving KVM box 200 is transmitted together with a SYNC signal that recognizes the initial state of the serialized signal. In addition, each receiving KVM box 200 is connected to each corresponding input/output device 30, and the input/output signal transmitted from the transmitting KVM box 100 is restored based on the SYNC signal to each input/output device 30. Can be transmitted.

The transmission KVM box 100 according to an embodiment of the present invention may include a serialization module 110, a DC balancing module 120, and a SYNC signal module 130. The serialization module 110 serializes an input/output signal for transmission in an Asynchronous Time Division Multiplexing (ATDM) scheme.

In addition, the SYNC signal module 130 may generate a preset sync bit so that an initial signal can be recognized from an input/output signal that is serialized and transmitted/received. The DC balancing module 120 converts the high level and the low level of the serialized signal so that DC balancing is achieved, respectively.

For example, the transmission KVM box 100 is connected to three PCs (Personal Computers) (21, 22, 23) to provide a control signal for controlling any one of the PCs based on the sync bit. It can be restored and transmitted to the corresponding PC (21, 22, 23). In addition, the transmission KVM box 100 serializes the signals transmitted from each computer in an Asynchronous Time Division Multiplexing (ATDM) method based on the sync bits, and the first reception KVM box 210 or It can be transmitted to the second receiving KVM box 220.

At this time, each PC (21, 22, 23) and the transmission KVM box 100 is connected to at least one of RS232, PS2, RGB/DVI, and USB in an interface method to transmit and receive signals. That is, as shown in FIG. 3, a touch screen signal is transmitted and received between the PC1 21 and the transmission KVM box 100 using an RS232 interface, and a video signal is transmitted and received using the RGB/DVI interface. Input and output signals of the mouse 31_2 and the keyboard 31_1 may be transmitted and received using the PS2 interface.

In addition, input/output signals may be transmitted/received between the PCs 21, 22, and 23 and the transmission KVM box 100 using a USB interface as shown in FIG. 4.

Likewise, PC2 (22) and PC3 (23) transmit touch screen signals, video signals, mouse (31_2) and keyboard (31_1) input/output signals using interfaces such as RS232, PS2, RGB/DVI, and USB, respectively. It can transmit and receive with the KVM box 100.

In addition, the transmission KVM box 100 and the first reception KVM box 210 and the second reception KVM box 220 are connected using optical cables or LAN cables 310 and 320, Signals may be transmitted/received through optical cables or LAN cables 310 and 320.

At this time, the connection between the transmitting KVM box 100 and the receiving KVM box 200 requires two optical cables or two pairs of differential signal lines excluding the video signal, but one (or one pair). The line of) transmits a signal from the transmit KVM box 100 to the receive KVM box 200, and one (or one pair) of the wire transmits the signal from the receive KVM box 200 to the transmit KVM box 100. I can.

In addition, in case the power supply of the transmitting KVM box 100 and the receiving KVM box 200 is supplied separately, signal processing of the input/output device 30 is serialized in an asynchronous time division multiplexing (ATDM) method ( By serializing), the transmitting KVM box 100 and the receiving KVM box 200 continuously communicate, and signals can be transmitted and received with each other.

In addition, the transmitting KVM box 100 and each receiving KVM box 200 may continuously check the SYNC signals previously promised for accurate signal transmission of the input/output signals so that synchronization can be continuously achieved.

Further, the transmitting KVM box 100 and the receiving KVM box 200 may each include an error recovery module 140, 216, and 226 or an error recovery circuit. The error recovery module (140, 216, 226) and the error recovery circuit determine when an error occurs due to a missed SYNC signal in the transmitting KVM box 100 and the receiving KVM box 200 and recover the SYNC signal. I can.

6A and 6B are diagrams illustrating a configuration of a serialized signal according to an embodiment of the present invention. That is, FIG. 6A is a diagram showing a configuration of a serialized signal consisting of 32 bits according to an embodiment of the present invention, and FIG. 6B is a serialization of FIG. 6A according to an embodiment of the present invention. It is a diagram showing the transmission of a USB signal in 32 bits.

The transmit KVM box 100, the first receive KVM box 210, and the second receive KVM box 220 transmit and receive various input/output signals by asynchronous time division multiplexing (ATDM). At this time, the basic clock of the input/output signal can be determined by referring to the allocation of how many bits to allocate the synchronization signal and the signal with the highest transmission speed among the input/output signals. The configuration of the SYNC signal bit is determined by It should be organized so that it does not overlap with the data.

According to an embodiment of the present invention, the number of bits of the SYNC signal may be configured as 8 bits. In addition, the 8-bit configuration of the SYNC signal may be configured as "11001010". That is, in FIGS. 6A and 6B, SYNC signal bits S1 to S8 are “11001010”, and the remaining signal bits (signals 1 to 24) may be used for transmission of input/output signals.

In addition, according to an embodiment of the present invention, the input/output signal may set the clock of a frame, which is a basic configuration of 32 bits (4 bits x 8) of serialization, to 8 MHz as a standard for transmitting data at a rate of 1 Mbps to 1.5 Mbps.

In this case, the bit clock may be extracted based on [Equation 1] below.

[Equation 1]

Bit clock = number of bits in frame x clock in frame

= 32(bit) X 8MHz = 256Mhz

Among the 32 bits, the SYNC signal is 8 bits (11001010), and the remaining 24 bits are used to transmit input/output signals. In addition, the 8-bit SYNC signal 11001010 is disposed between the input/output signal data in multiples of 4 bits as shown in FIGS. 6A and 6B so that the input/output signal and the collision may not occur. .

In addition, when configuring the internal circuit, a 32-bit shifter is used. When an 8-bit SYNC signal is recognized as "11001010", an accurate frame of 32 bits can be formed. In this case, data can be transmitted when the configuration "11001010" is completed by continuously checking.

In addition, for the accuracy of the time-division serial signal of the input/output signal, a clock that is 4 times or more of the input/output signal must be used. Among the input/output signals, the data rate defined in USB 1.1 is 12Mbps, so 48Mhz is required for the input/output signal.

In order to solve this problem, when one frame is defined as 8Mhz as shown in FIG. 6B, 8 bits of the USB+ and USB- signals among the 24 bits of the input/output signals excluding the 8 bits of the SYNC signal are allocated as the same signal. Can be solved.

According to an embodiment of the present invention, signals 1 and 13 in the 32-bit signal of the frame may be defined as USB+(U+) signals as shown in FIG. 6B. Further, signal 7 (inverted signal of signal 1) and signal 19 (inverted signal of signal 13) may be defined as inverted signals of signal 1 and signal 13, respectively.

In addition, signal 2 and signal 14 can be defined as USB-(U-) signals. Further, signal 8 (inverted signal of signal 2) and signal 20 (inverted signal of signal 14) may be defined as inverted signals of signal 2 and signal 14, respectively.

The computer input/output signal asynchronous time division multiplexing transmission apparatus 10 according to an embodiment of the present invention serializes and transmits signals based on the basic clock for asynchronous time division multiplexing (ATDM) transmission of input/output signals. At this time, since the input/output signal is an asynchronous serial signal, in order to detect the first signal, one frame is recognized through the SYNC signal, and the input/output signal can be transmitted.

For example, as shown in FIGS. 6A and 6B, one frame may be composed of 32 bits, a synchronization signal among 32 bits may be composed of 8 bits, and an input/output signal may be composed of 24 bits and transmitted. At this time, as described above, the period of one frame may be 8Mhz, and the bit clock may be 256Mhz.

For example, one frame is composed of 32 bits, and may include 8 sync bits and 24 bits for transmitting input/output signals. Eight sync bits can be predefined and set ("11001010"), and the transmitting KVM box 100, the first receiving KVM box 210, and the second receiving KVM box 220 transmit a preset sync signal. And, by checking this at the corresponding side and recognizing the SYNC signal, it is extracted in units of 1 frame, and the input/output signal related thereto can be restored and used.

In the case of defining 8 sync bits as "11001010" according to an embodiment of the present invention, the S bits of each chip (4 bits) in FIGS. 6A and 6B are respectively set to "11001010" and transmitted, and the receiving side checks them. You can check the configuration of input/output signal data by (check). That is, the transmitting KVM box 100, the first receiving KVM box 210, and the second receiving KVM box 220 may recognize and process input/output signals that are previously defined and continuously transmitted based on the synchronization signal. .

In addition, the input/output signal may be transmitted using 24 bits excluding 8 sync bits among 32 bits of one frame. That is, it may be transmitted using 24 signal bits composed of 1 frame in FIGS. 6A and 6B.

Interfaces for transmitting/receiving input/output signals may include High Definition Multimedia Interface (HDMI), Digital Visual Interface (DVI), Displayport, USB, RS232C, AUDIO and PS2.

For example, HDMI (except video signal and power signal) can contain four signals: I2C clock, I2C data, HPD and CEC, while DVI (excluding video signal and power signal) can contain I2C clock, I2C data and HPD. Three signals can be included. In addition, Displayport (excluding video signal and power signal) includes 3 signals of AUX+, AUX- and DP_HPD, USB interface includes 2 signals of USB+ and USB-, RS232C (UART) interface includes 2 signals of TX and RX, AUDIO may include two signals, audio left and audio right.

In addition, the PS2 interface may include four signals of PS2 mouse clock, PS2 mouse data, PS2 keyboard clock, and PS2 keyboard data. In addition to this, user-defined system control signals may be included.

In the 24 signal bits of the frame, the input/output device 30 among input/output signals such as HDMI (High Definition Multimedia Interface), DVI (Digital Visual Interface), Displayport, USB, RS232C, AUDIO and PS2. According to the configuration of the preset signal is matched.

In addition, when the input/output signals are matched, the characteristics of each signal must be taken into consideration. A signal with a continuously changing or high transmission rate, a one-way signal, or a two-way signal can be distinguished, and input/output signals can be defined. At this time, it is preferable that signals that frequently change or have a high transmission rate are repeatedly allocated within a frame, and one-way signals are allocated only to one side (transmission KVM box 100 or receiving KVM box 200).

That is, according to the configuration of the input/output device 30, a signal selected from the input/output signals is set to 24 signal bits, and serialized with 8 sync bits and transmitted. The corresponding side can check the 8 sync bits to recognize the initial signal of the input/output signal and the configuration of the predefined input/output signal. At this time, in order to maintain the DC balancing of the differential signal, the order of the input/output signals is selectively rearranged or an inverted signal of the input/output signal is sent based on the sync bit. DC balancing can be implemented by configuring each of the numbers to be 12 bits.

Input/output signals between the transmitting KVM box 100 and the first receiving KVM box 210 and the second receiving KVM box 220 may be transmitted/received through a LAN cable. In general, the internal configuration of a LAN cable consists of 4 pairs (8 lines) of differential signals.

If the multiple input/output video signal is an HDMI or DVI signal, and input/output devices such as PS2, RS232, and USB are used, it is difficult to configure the video signal and the signal of the input/output device with only one LAN cable. Because, in general, HDMI or DVI consists of four pairs of video lines, so two more pairs of lines (lines) are required to transmit signals from an input/output device.

Therefore, in order to configure the connection line between the transmitting KVM box 100 and the first receiving KVM box 210 or the second receiving KVM box 220 with one LAN cable, it is preferable to convert the HDMI or DVI interface to the Displayport interface. . In this case, two of the four pairs of LAN cables are composed of video lines, and two pairs of lines are composed of time division multiplexing (ATDM), and one pair of lines is composed of a transmission line and one pair of lines is a receiving line. It can be composed of. In addition, input/output signals may be transmitted and received through the transmission line and the reception line.

In this case, time-division data for transmitting input/output signals based on the PS2 and RS232C interfaces in the multiplexed transmission device 10 according to an embodiment of the present invention may be configured as follows. For example, as shown in FIG. 3, the configuration of time-division data transmitted from the transmitting KVM box 100 to the first receiving KVM box 210 or the second receiving KVM box 220 is AUXP, AUXN, DP_HPD, SCL. , SDA, UART_TX, UART_RX, MCLK, MDATA, KCLK, KDATA.

In addition, the configuration of time-division data transmitted from the first receiving KVM box 210 or the second receiving KVM box 220 to the transmitting KVM box 100 is AUXP, AUXN, DP_HPD, SDA, HPD, UART_TX, UART_RX, MDATA, May include KDATA, PC_SELECT0, PC_SELECT1, and MS_SELECT.

As described above, the input/output signals may be predefined and set to 24 input/output signal bits excluding 8 sync bits among 32 bits constituting one frame (1 frame).

In addition, the multiplexed transmission device 10 according to another embodiment of the present invention may configure time-division data for transmitting an input/output signal based on a USB interface as illustrated in FIG. 4. For example, the configuration of time-division data transmitted from the transmitting KVM box 100 to the first receiving KVM box 210 or the second receiving KVM box 220 may include USB+, USB-, SCL, SDA, and CEC. have.

In addition, the configuration of time-division data transmitted from the first receiving KVM box 210 or the second receiving KVM box 220 to the transmitting KVM box 100 may include USB+, USB-, SCL, SDA, CEC, and HPD. have. In addition, the input/output signals may be predefined and set in 24 input/output signal bits excluding 8 sync bits among 32 bits constituting one frame (1 frame).

At this time, since the time-division data for transmitting the input/output signal based on the USB interface consists of up to 8 signals, the high-speed data USB+ and USB- signals can be transmitted by allocating 8 bits or 16 bits of 24 bits in one frame. This can increase the accuracy of the transmitted input/output signal.

However, the present invention may be implemented in various forms and is not limited to the embodiments described herein. That is, three or more personal computers (PCs) may be controlled by two input/output devices 30, or three or more personal computers (PCs) may be controlled using two or more input/output devices 30.

Likewise, a configuration within 24 bits constituting one frame may be selectively performed according to the transmission speed of the input/output signal and the configuration of the input/output device 30. That is, as the number of input/output signals transmitted through the input/output device 30 increases, the total number of bits constituting one frame can be increased, and the accuracy of the signal can be increased by increasing the clock of one frame. .

7 and 8 are flowcharts illustrating a method of transmitting asynchronous time division multiplexing of computer input/output signals according to an embodiment of the present invention. That is, FIG. 7 is a flow chart showing a process of transmitting a signal from the receiving KVM box 200 to the transmitting KVM box 100, and FIG. 8 is a flowchart of transmitting a signal from the transmitting KVM box 100 to the receiving KVM box 200. It is a flow chart showing the process.

In the method of transmitting asynchronous time division multiplexing of computer input/output signals according to an embodiment of the present invention, any one receiving KVM box 200 for controlling a computer (PC) by driving the toggle switch 214 of the first receiving KVM box 210 Selecting (S10), selecting any one of the PCs (21, 22, 23) of the PC unit 20 by driving the toggle switch (214, 224) of the selected receiving KVM box (200) (S20) And transmitting a control signal or an input/output signal to the reception KVM box 200 by using the input/output device 30 connected to the reception KVM box 200 (S30).

In addition, the step of serializing a preset sync signal and the control signal or input/output signal in the receiving KVM box 200 in an asynchronous time division multiplexing method (ATDM) (S40), and the receiving KVM box 200 Transmitting the asynchronous time-division multiplexed signal from the transmission KVM box 100 (S50), receiving the signal transmitted from the reception KVM box 200 in the transmission KVM box 100 and checking the sync signal (S60) And restoring the received signal based on the sync signal in the transmission KVM box 100 and transmitting the signal to the selected PCs 21, 22, and 23 (S70).

In addition, the computer input/output signal asynchronous time division multiplexing transmission method according to an embodiment of the present invention includes the step of receiving the input/output signal from the selected PC by the transmission KVM box 100 (S80), and a preset sync signal in the transmission KVM box 100. And serializing the input/output signal in an asynchronous time division multiplexing (ATDM) method (S90), and transmitting the asynchronous time division multiplexed signal from the transmitting KVM box 100 to the receiving KVM box 200 It may further include step S100.

In addition, the step of checking the sync signal by receiving the signal transmitted from the transmitting KVM box 100 in the receiving KVM box 200 (S110) and restoring the received signal based on the sync signal in the receiving KVM box 200 The step of transmitting an input/output signal to the input/output device 30 (S120) may be further included.

Although the preferred embodiments of the present invention have been described above, the present invention is not limited to the above embodiments, and is easily changed from the embodiments of the present invention by those of ordinary skill in the art to which the present invention belongs. It includes all changes to the extent deemed acceptable.

10: multiplexed transmission device 20: PC unit
21: PC1 22: PC2
23: PC3 30: input/output device
31: first input/output device 31_1: keyboard
31_2: Mouse 31_3: Monitor
32: second input/output device 32_1: keyboard
32_2: Mouse 32_3: Monitor
33: third input/output device 100: transmission KVM box
110: serialization module 120: DC balancing module
130: SYNC signal module 140: Error recovery module
200: receiving KVM box 210: first receiving KVM box
211: serialization module 212: DC balancing module
213: SYNC signal module 214: toggle switch
215: toggle LED 216: error recovery module
220: second receiving KVM box 221: serialization module
222: DC balancing module 223: SYNC signal module
224: toggle switch 225: toggle LED
226: error recovery module 230: third receiving KVM box
300, 310, 320: LAN cable

Claims (8)

A computer input/output signal asynchronous time division multiplexing transmission device for transmitting and receiving control signals and input/output signals between an input/output device and a computer, comprising:
It is connected to at least one input/output device respectively, and serializes the control signal and input/output signal of the input/output device based on a preset sync signal in an asynchronous time division multiplexing method (ATDM) to the transmission KVM box. At least one reception KVM box that transmits, restores the input/output signal transmitted from the transmission KVM box based on the sync signal, and transmits it to a corresponding input/output device; And
Any one computer connected to at least one computer (PC) and previously selected by restoring a control signal and an input/output signal transmitted from the reception KVM box to control any one of the computers (PC) based on the sync signal ( PC), and serializes the signal transmitted from the corresponding computer in an asynchronous time division multiplexing (ATDM) method based on the sync signal and transmits it to the receiving KVM box; A computer input/output signal asynchronous time division multiplexing transmission device, characterized in that.
The method of claim 1,
The basic clock of the input/output signal transmitted/received between the transmitting KVM box and the receiving KVM box is determined based on the allocation of how many bits the sync signal consists of and the signal with the highest transmission speed among the input/output signals, A computer input/output signal asynchronous time division multiplexing transmission apparatus, characterized in that serializes the input/output signals based on the basic clock in an asynchronous time division multiplexing (ATDM) scheme.
The method of claim 2,
A computer, characterized in that, in order to detect the first signal of the input/output signal serialized by the asynchronous time division multiplexing (ATDM) method, one frame of the input/output signal is recognized using the sync signal I/O signal asynchronous time division multiplexing transmission device.
The method of claim 1,
When the signal from the input/output device is configured as a High Definition Multimedia Interface (HDMI) or a Digital Visual Interface (DVI) interface, the video signal and the input/output signal are transmitted to the transmission KVM box through one LAN cable. Transmitting the signal from the receiving KVM box to the DISPLAYPORT interface for transmission and reception, 2 of the 4 pairs of lines in the LAN cable are configured for video signals, and asynchronous time division multiplexing through the remaining 2 pairs of lines A computer input/output signal asynchronous time division multiplexing transmission device, characterized in that it transmits and receives input/output signals using an ATDM method.
The method of claim 1,
When the input/output device is configured as a USB interface, signals other than USB+ and USB- signals are distributed and placed in input/output signal bits excluding sync signal bits within one frame, and USB+ and USB- signals A computer input/output signal asynchronous time division multiplexing transmission device, characterized in that the same signal is allocated and repeatedly transmitted.
In the computer input/output signal asynchronous time division multiplexing transmission method for transmitting and receiving control signals and input/output signals between an input/output device and a computer,
Transmitting a control signal or an input/output signal to a corresponding reception KVM box using an input/output device connected to the reception KVM box (S30);
Serializing a preset sync signal and the control signal or input/output signal in the receiving KVM box in an asynchronous time division multiplexing (ATDM) method (S40);
Transmitting the asynchronous time division multiplexed signal from the receiving KVM box to a transmitting KVM box (S50);
Checking, by a transmitting KVM box, a sync signal by receiving a signal transmitted from the receiving KVM box (S60); And
And transmitting the signal to the selected PC by restoring the received signal on the basis of the sync signal in the transmission KVM box (S70); and asynchronous time division multiplexing transmission method for computer input/output signals.
The method of claim 6,
Receiving input/output signals from the PC selected by the transmission KVM box (S80);
Serializing a preset sync signal and the input/output signal in the transmission KVM box using an asynchronous time division multiplexing (ATDM) (S90);
Transmitting the asynchronous time division multiplexed signal from the transmitting KVM box to a receiving KVM box (S100);
Checking a sync signal by receiving a signal transmitted from the transmitting KVM box in the receiving KVM box (S110); And
A method of transmitting an asynchronous time division multiplexing of a computer input/output signal further comprising: restoring a signal received from a receiving KVM box based on a sync signal and transmitting the input/output signal to the input/output device (S120).
The method of claim 6,
Before transmitting a control signal or input/output signal to the receiving KVM box (S30)
Selecting one of the reception KVM boxes for controlling the computer (PC) by driving a toggle switch of the first reception KVM box (S10); And
Driving the toggle switch of the selected receiving KVM box to select any one of the computers (PCs) of the PC unit (S20); Computer input/output signal asynchronous time division multiplexing transmission method further comprising a.

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