KR100300028B1 - Method for connecting twisted pair network cable - Google Patents

Abstract

PURPOSE: A method for connecting a twisted pair network cable is provided to reduce costs for installation by connecting the twisted pair network cable to a twisted pair network cable of a hub side and a cascade in case that a PC connected to the hub is connected to another PC, and by transmitting/receiving data. CONSTITUTION: In case that a PC connected to a hub is connected to another PC, an adjacent node of the PC connected to the hub connects the first and the fourth line among twisted pair network lines to a transmission differential + terminal(TX+). The adjacent node of the PC connects the second and the fifth line to a transmission differential - terminal(TX-). In addition, the adjacent node connects the third and the seventh line to the receipt differential + terminal(RX+) and sixth and the eighth line to a receipt differential - terminal(RX-). A cascade node of another PC connects the fourth and the seventh line among the twisted pair network lines to a receipt differential + terminal(RX+). The cascade node connects the fifth and the eighth lien to the receipt differential - terminal(RX-). In addition, the cascade node connects the third and the first line to the transmission differential + terminal(TX+) and the sixth and the second line to the transmission differential - terminal(TX-).

Description

Twist Pair Network Cable Connection Method {METHOD FOR CONNECTING TWISTED PAIR NETWORK CABLE}

The present invention relates to a twisted pair network cable connection method for facilitating the formation of a twisted pair network, and in particular, by connecting the twisted pair network cable in a cascade to reduce the number of ports of the hub (HUB) to reduce the installation cost The present invention relates to a twisted pair network cable connection method for increasing data transmission efficiency.

In the conventional twisted pair network configuration, as shown in FIG. 1, a hub 10, which is a device capable of distributing and distributing a signal in different lines, and N nodes 20A that require signals from the hub 10 to be exported. It consists of twisted pair network cable (CA1 ~ CAN) to transmit to ~ 20N).

And, as shown in Figure 3, the structure of the twisted pair network cable between the hub and each node, the receiving differential terminal (RX) of the hub is connected to the transmission differential terminal (TX) of each node through line 1,2, The transmit differential stage (TX) of the hub is connected to the receive differential stage (RX) of each node through lines 3 and 6, and the remaining lines 4, 5 and 7, 8 are left open. I never do that.

Looking at the prior art configured as described above is as follows.

In order also export by dispersing the signal from one of the hub 10 in a different line of his ports - When the output signal to the (#P # _A P _N), the port-equal to the number of (#P # _A P _N) It is transmitted to N nodes 20A to 20N through twisted pair network cables CA1 to CAN.

The signal transmitted to the hub 10 through the N nodes 20A to 20N is also transmitted to the hub 10 through twisted pair network cables CA1 to CAN.

As shown in FIG. 2, twisted pair network cables CA1 to CAN transmit and receive signals as shown in FIG. 2, and the paired lines (1, 2), (3, 6), (4, 5), (twisted 7, 8) consisting of four twisted pair network cable, the structure is as shown in FIG.

That is, the structure of the twisted pair network cable between the hub and each node is, as shown in Figure 3, the receiving differential stage RX of the hub 10 is the transmission differential of each node 20A-20N through the line 1, 2 In connection with the stage TX, the signal transmitted by the transmission differential terminal TX of the nodes 20A-20N is transmitted to the receiving differential terminal RX of the hub 10 through lines 1 and 2 so as to be received. In addition, the transmission differential terminal TX of the hub 10 is connected to the reception differential terminal RX of each node 20A-20N through lines 3 and 6, and the transmission differential terminal of the hub 10 ( TX) transmits the signals transmitted through lines 3 and 6 so that they can be received by the receiving differential terminal RX of the nodes 20A-20N.

And, lines 4, 5 and 7, 8 connected with the remaining pairs are not left open.

Through the cable connection as described above, the hub 10 and each of the nodes 20A to 20N may transmit or receive signals or data.

The twisted pair network is a circular hub configured to connect each node or a back-bone network in a star form around a hub, or to repeatedly receive data transmitted by each node to all nodes. In some cases, the switching hub may be configured to use a switching hub that switches data transmitted from each node to a reception destination.

However, in the prior art as described above, when the twisted pair network is connected to each node of the PC centered around the hub, the number of nodes is configured to connect with the ports of the hub, so that there is a problem in that the installation cost is increased due to the number of ports. 4 Twisted pair Two pairs of network cables are not used and consumed.

Therefore, an object of the present invention for solving the conventional problems as described above is to connect the twisted pair network cable to the hub and the twisted pair network cable connected to the PC and another PC connected to the hub side to transmit and receive data This provides a twisted pair network cabling method that reduces installation costs by reducing the number of ports on the hub side.

Another object of the present invention is to provide a twisted pair network cable connection method for improving the transmission efficiency of the network by using all the unused cables among the twisted pair network cables.

1 is a configuration diagram of a conventional twisted pair network.

2 is a structural diagram of a twisted pair network cable in FIG.

3 is a diagram illustrating a twisted pair network cable connection structure in a network configuration between a hub and a conventional hub.

4 is an embodiment of a method of connecting a twisted pair network cable of the present invention;

FIG. 5 is an explanatory diagram showing a connection method of twisted pair network cables of hub neighbor nodes in FIG. 4; FIG.

6 is an explanatory diagram showing a method of connecting a twisted pair network cable of a cascade node in FIG. 4;

FIG. 7 is an explanatory diagram illustrating a twisted pair network cable connection method of a hub port in FIG. 4; FIG.

*** Explanation of symbols for main parts of drawing ***

10: hub 20: node

RX: Receive Differential Stage TX: Transmit Differential Stage

The present invention for achieving the above object is configured by cascading a twisted pair network cable connecting a PC connected to the hub and another PC, the hub adjacent node of the PC connected to the hub and another PC cascade node. It is characterized by.

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

4 is an embodiment of a twisted pair network cable connection method of the present invention, when connecting a PC connected to a hub and another PC, as shown here, the hub adjacent node of the PC connected to the hub and another PC cascade node It is configured by cascading twisted pair network cables to connect the.

As shown in FIG. 5, the hub neighbor node connects lines 1 and 4 of the twisted pair network line to the transmission differential + terminal (TX +), and connects lines 2 and 5 to the transmission differential terminal (TX-). Connect lines 3 and 7 to the receive differential + stage (RX +), and connect lines 6 and 8 to the receive differential stage (RX-).

Also, as shown in FIG. 6, the cascade node connects lines 4 and 7 of the twisted pair network line to the receiving differential + terminal (RX +), and connects lines 5 and 8 to the receiving differential terminal (RX-). Connect lines 3 and 1 to the TX differential terminal (TX +), and connect lines 6 and 2 to the TX differential terminal (TX-).

Referring to the operation and effect of the present invention configured as described in detail as follows.

When a signal or data is to be transmitted / received from a hub side to an adjacent node of a PC, a port and a twisted pair network cable of the hub side, as shown in FIG. 7, lines 1 and 2 are receiving differential ends (RX +, RX) of the hub. -), Lines 3 and 6 are connected to transmit differential stages (TX +, TX-), and the remaining lines 4, 5, 7, and 8 are not open.

At this time, the hub neighbor node of the PC adjacent to the hub is connected to the transmit differential terminals TX + and TX1 as in the conventional case, and the lines 3 and 6 are connected to the receive differential terminals RX + and RX-. Do not connect and use the remaining lines 4, 5, 7, and 8.

Therefore, the hub and the neighboring PCs transmit and receive data through two paired lines.

At this time, if the hub neighbor PC and another PC do not pass data through the hub and want to transfer data from the hub neighbor PC to another PC, or to transfer data from another PC to the hub side, use twisted pair network cable. Use cascaded as in 4.

That is, as shown in FIG. 5, the hub neighbor node connects lines 1 and 4 to the transmission differential + terminal (TX +), connects lines 2 and 5 to the transmission differential terminal (TX-), and 3,7. Connect line 1 to the receive differential + stage (RX +), connect line 6, 8 to the receive differential stage (RX-), and the cascade node receives line 4, 7 as the receive differential + Connect to RX +, connect lines 5 and 8 to the receive differential stage (RX-), connect lines 3 and 1 to the transmit differential stage (TX +), and transmit lines 6 and 2. Connect to differential stage (TX-).

Then, the transmission data on the hub side is transmitted to the receiving end of the hub neighbor node through lines 3 and 6, and the transmitted data is cascaded through lines 7,8 connected to lines 3 and 6 of the hub neighbor node, respectively. It is delivered to the receiving end RX of the node.

Eventually, the transmission data on the hub side is directly connected to the receiving end of another PC.

The transmission data of the hub neighbor node is received at the receiving end of the cascade node through lines 4 and 5 of the cascade node through lines 1 and 2.

As described above, transmission data can be transmitted to PCs far from the hub, and data can be transmitted and received from one PC to another PC without going through the hub.

Here, by using all four cables of the hub neighbor node and the cascade node, data output through one port of the hub is connected to two transmitters on the cascade node side, thereby reducing the number of ports of the hub.

And, in case of transmitting data from remote PC to hub, transmission data of cascade node is transmitted to line 7,8 of hub neighbor node through line 1,2.

Then, data is received at the receiving end of the hub neighbor node through line 7,8 of the hub neighbor node.

The hub neighbor node receiving the data transmits data through lines 1 and 2 of the hub side.

Accordingly, the hub side receives data through the line 1 and 2 to the receiving end.

As above, when transferring data from PC to distant hub, data from distant PC to hub, or data from one PC to another PC, cascade the twisted pair network cable. By using this, the transmission efficiency of data is improved.

Therefore, the present invention reduces the number of ports of the hub by using a twisted pair network cable cascaded when connecting the PC and another PC connected to the hub to reduce the cost, the performance of the network by using all the unused cables There is an effect to improve.

Claims (1)

When connecting a PC connected to a hub and another PC, the hub adjacent node of the PC connected to the hub connects lines 1 and 4 of the twisted pair network line to the transmission differential + stage (TX +), and connects lines 2 and 5 Connected to the transmit differential stage (TX-), connected to lines 3 and 7 to the receive differential + stage (RX +), and lines 6 and 8 to the receive differential stage (RX-), and The other PC's cascade node connects lines 4 and 7 of the twisted pair network line to the receive differential + stage (RX +), and lines 5 and 8 to the receive differential stage (RX-). A method of connecting a twisted pair network cable, comprising: connecting a line to a transmission differential + terminal (TX +) and connecting a line 6 and 2 to a transmission differential terminal (TX-).

Images