JP6138592B2 - Layer 2 switch controller, control method and control program for layer 2 switch - Google Patents

Description

  The present invention relates to a layer 2 switch controller used in a LAN (Local Area Network) or the like. Hereinafter, the “layer 2 switch” is abbreviated as “L2SW (Layer 2 switch)”.

  Among the communication lines used in LANs, category 3, 4, and 5 wires for 10BASE-T and 100BASE-TX are expected to be converted to 100BASE-VG in the future. It is standardized and an RJ45 connector is used as the connector. Actually, among these 8 cores, 4 cores, each of which is paired with pin 1, pin 2, pin 3, and pin 6, are standardized and used for communication, and the remaining four cores are unspecified. ing. The above is the standard specification for the LAN, and the LAN is actually constructed with this specification.

  A house 80 shown in FIG. 11 includes a living room 81 on the first floor, a bedroom 82 on the second floor, and a wall 83 on the first and second floors. As a recent trend, in the house 80, a LAN cable 84 is wired on the wall 83 in the house, and RJ45 connectors 85 and 86 are arranged on the walls of each room so that a home network can be constructed. The LAN cable 84 in the wall is finally terminated so as to be connected to the switching hub 87.

  Recent televisions 88 and 89 and the recorder 90 (or the personal computer 91) have a LAN terminal, and by connecting to the LAN, the video can be distributed by a DLNA (Digital Living Network Alliance) function or can be connected to an external hard disk. Has a function to record. In addition, since these devices have a function of obtaining information from the Internet, it is necessary to connect the home network to a public line via an optical line or an ADSL line when using these functions. there were.

  However, the RJ45 connectors 85 and 86 generally disposed on the wall have only one unit per room. Therefore, in order to connect both the television 88 and the recorder 90 and both the television 89 and the personal computer 91 to the home network, it is necessary to prepare switching hubs 92 and 93 as shown in FIG. As a result, the following problems have occurred.

  (1) The fact that the switching hubs 92 and 93 must be newly purchased causes an economic burden, an increase in power consumption, an increase in CO2 emissions, and the like.

  (2) Generally, the television 88 and the recorder 90 (or the television 89 and the personal computer 91) are arranged as a set. For this reason, since the video / audio / power supply cables are connected to the back side thereof, it tends to be complicated. Also, if many devices are arranged adjacent to each other, octopus leg wiring is likely to occur, resulting in a risk of fire.

  (3) In the living room 81 and the like, a general idea that the user wants to enjoy total coordination including electrical appliances and furniture. For this reason, there is a strong demand from users that they do not want to place the switching hubs 92 and 93 having a relatively large inorganic design (box shape) in a visible place. In addition, since the switching hubs 92 and 93 cause the LEDs to blink during communication, there are many users who feel that they are inconspicuous when they are always in a conspicuous place. This is the same in the bedroom 82, and many users feel the switching hubs 92 and 93 as an obstacle to sleep because the LEDs blink in the dark.

  With such a background, if the television 88 and the recorder 90 (or the television 89 and the personal computer 91) can be connected to the home network without adding the switching hubs 92 and 93, the above-described problems can be solved. Can do. A technique for solving these problems is disclosed in Patent Document 1.

  FIG. 13 is a wiring diagram showing an RJ45 branch connector disclosed in Patent Document 1. As shown in FIG. The RJ45 branch connector 100 includes a housing 101, one opening 101a formed on one side of the housing 101, and two openings 101b formed on the other side facing the one side. 101c, three RJ45 connectors 102a, 102b, 102c disposed in the openings 101a, 101b, 101c, respectively, and eight signal lines 103 connecting the RJ45 connectors 102a, 102b, 102c to each other. Eight signal lines 103 are connected to the RJ45 connector 102a, and the eight signal lines 103 are divided into four signal lines 103 and connected to the RJ45 connectors 102b and 102c.

  At that time, the RJ45 connector 102a, pins 1, 2, 3, 6 and RJ45 connector 102b, pins 1, 2, 3, 6 and RJ45 connector 102a, pins 4, 5, 7, 8 and RJ45 connector 102c, 1 and 2 The 3rd and 6th pins correspond to each other. That is, all pins are alive in the RJ45 connector 102a, and only pins 1, 2, 3, and 6 are alive in the RJ45 connectors 102b and 102c.

  FIG. 14 is a schematic diagram showing an example of a LAN using an RJ45 branch connector. RJ45 branch connectors 105 and 106 are connected to both ends of a long-distance LAN cable 104, which is an 8-core twisted pair cable, and the RJ45 branch connector 105 and the switching hub 108 are connected by short LAN cables 107b and 107c. The RJ45 branch connector 106 and the personal computers 110b and 110c are connected to each other by short LAN cables 109b and 109c.

  That is, the 1st and 2nd pin twisted pairs on both sides of the long distance LAN cable 104 are used for transmission (TX +, TX−) and the 3rd and 6th pin twisted pairs are used for reception (RX +, RX−). Connects the phase according to the current standard specification and the phase using all 8 cores of the long-distance LAN cable 104 including unused wiring sections that are not specified in the standard specification by branching / aggregating action of the RJ45 branch connectors 105 and 106 To do. As a result, a signal passing through the short LAN cables 107b and 109b passes through the standard wiring portion of the long distance LAN cable 104, and a signal passing through the short LAN cables 107c and 109c is an unused wiring portion of the standard specification of the long distance LAN cable 104. Will go through.

JP 2000-331758 A

  As described above, the RJ45 branch connector is proposed in Patent Document 1. Even in this RJ45 branch connector, it is possible to bundle two LAN device signals into one LAN cable. However, as shown in FIG. 14, the RJ45 branch connector is connected to both ends of the LAN device side and the switching hub side. Is required. For this reason, two LAN cables are required on the switching hub side, two on the LAN device side, and one between the branch connectors. As can be imagined from the spread of wireless LAN in recent years, there is a problem of reducing the number of cables as much as possible.

  In recent residences, condominiums, etc., it is possible to easily construct a home network by drawing a cable in the wall in advance at the time of construction, installing an RJ45 connector on the wall, and connecting a LAN device with the LAN cable there. There are many cases. At this time, the LAN cable routed in the wall is terminated by a switching hub or the like. This switching hub is often installed in a place that is usually invisible, such as next to a switchboard, in a corner of a close-in, or in an attic. In such a place, since the replacement of the cable is not taken into consideration originally, an area for connecting the RJ45 branch connector and the cable is not secured, and there is a problem that the operation is difficult. Even if it is possible to connect them, there is a problem that it looks bad, and the cable is unintentionally scratched and damaged.

  Therefore, an object of the present invention is to provide an L2SW controller or the like that can eliminate the need for an RJ45 branch connector used on the switching hub side.

The L2SW controller according to the present invention is
The eight pins are provided between one or more RJ45 connectors having eight pins and two or more physical layers, and according to the input control signal, the eight pins are divided into a first group and a second group by four pins. A switch unit for connecting a first group and a second group of pins to any of the two or more physical layers;
When a LAN device using the first group and the second group of pins is connected to one RJ45 connector, the first group and the second group of pins are connected to the one physical layer. When the LAN device that outputs the control signal to the switch unit and uses one pin of the first group and the second group is connected to one RJ45 connector, the pins of the first group and the second group A control unit that outputs the control signal to the switch unit so as to connect two different physical layers to each other,
Is provided.

The L2SW control method according to the present invention is as follows:
The eight pins are provided between one or more RJ45 connectors having eight pins and two or more physical layers, and according to the input control signal, the eight pins are divided into a first group and a second group by four pins. For the switch unit that connects the pins of the first group and the second group to one of the two or more physical layers,
When a LAN device using the first group and the second group of pins is connected to one RJ45 connector, the first group and the second group of pins are connected to the one physical layer. The control signal is output to the switch unit,
When a LAN device that uses one pin of the first group and the second group is connected to one RJ45 connector, the pins of the first group and the second group are connected to two different physical layers, respectively. The control signal is output to the switch unit.

The control program for L2SW according to the present invention is as follows:
The eight pins are provided between one or more RJ45 connectors having eight pins and two or more physical layers, and according to the input control signal, the eight pins are divided into a first group and a second group by four pins. For the switch unit that connects the pins of the first group and the second group to one of the two or more physical layers,
When a LAN device using the first group and the second group of pins is connected to one RJ45 connector, the first group and the second group of pins are connected to the one physical layer. A function of outputting the control signal to the switch unit;
When a LAN device that uses one pin of the first group and the second group is connected to one RJ45 connector, the pins of the first group and the second group are connected to two different physical layers, respectively. A function of outputting the control signal to the switch unit,
Is realized on a computer.

  According to the present invention, even when two LAN devices are connected to one RJ45 connector on the L2SW controller side via the RJ45 branch connector, the two LAN devices are switched by switching the pin connection between the RJ45 connector and the physical layer. Since the pins of one RJ45 connector can be connected to two physical layers in correspondence with the equipment, the RJ45 branch connector on the L2SW controller side can be dispensed with.

FIG. 2 is a block diagram illustrating an L2SW controller according to the first embodiment. FIG. 6 is a connection diagram (part 1) illustrating an operation of the L2SW controller according to the first embodiment. FIG. 6 is a connection diagram (part 2) illustrating the operation of the L2SW controller according to the first embodiment. FIG. 6 is a connection diagram (part 3) illustrating the operation of the L2SW controller according to the first embodiment. FIG. 6 is a connection diagram (part 4) illustrating the operation of the L2SW controller according to the first embodiment. FIG. 3 is a flowchart (part 1) illustrating an operation of the L2SW controller according to the first embodiment. FIG. 6 is a flowchart (part 2) illustrating an operation of the L2SW controller according to the first embodiment. It is the schematic which shows the effect of the L2SW controller of Embodiment 1. FIG. 10 is a connection diagram illustrating an operation of the L2SW controller according to the second embodiment. It is a block diagram which shows the L2SW controller of Embodiment 3. It is the schematic (the 1) which shows the background art of this invention. It is the schematic (the 2) which shows the background art of this invention. It is a wiring diagram which shows the RJ45 branch connector currently disclosed by patent document 1. FIG. It is the schematic which shows an example of LAN using the RJ45 branch connector of FIG.

  DESCRIPTION OF EMBODIMENTS Hereinafter, embodiments for carrying out the present invention (hereinafter referred to as “embodiments”) will be described with reference to the accompanying drawings. In the present specification and drawings, the same reference numerals are used for substantially the same components.

  In the first embodiment, “switcher” and “processor” are examples of “switch unit” and “control unit” recited in the claims. Hereinafter, the “physical layer” is abbreviated as “PHY (physical)”, and the “MAC (Media Access Control) layer” is abbreviated as “MAC”.

  As shown in FIG. 1, the L2SW controller 10 includes a switcher 11 and a processor 12. The switcher 11 is provided between the RJ45 connectors 21 and 22 having eight pins and the PHY1 and PHY2, and divides the eight pins into a first group and a second group by four pins according to the input control signal C1. These first group and second group pins are connected to either PHY1 or PHY2. As an initial state, the RJ45 connector 21 and PHY1 are provided in a one-to-one correspondence, and the RJ45 connector 22 and PHY2 are provided in a one-to-one correspondence. A group of pins consists of a 1st pin, a 2nd pin, a 3rd pin and a 6th pin, and a 2nd group of pins consists of a 4th pin, a 5th pin, a 7th pin and a 8th pin. The switcher 11 is composed of, for example, a CMOS analog switch. The processor 12 functions as a computer incorporating a memory and an input / output interface. The switcher 11 may be provided outside the L2SW controller 10 as an IC instead of being provided in the L2SW controller 10.

  The processor 12 sends a control signal to the switcher 11 to connect the pins of the first group and the second group to the PHY 1 when a LAN device using the pins of the first group and the second group is connected to the RJ45 connector 21. C1 is output (steps S01 to S03 in FIG. 6). When a LAN device using one pin of the first group and the second group is connected to the RJ45 connector 21, the first group and the second group of pins are The control signal C1 is output to the switcher 11 so as to be divided into PHY1 and PHY2, respectively (step S04 in FIG. 6 to step S13 in FIG. 7).

  Further, when a LAN device that uses one pin of the first group and the second group is connected to the RJ45 connector 21, the processor 12 connects the first group and the second group pins to PHY1 and PHY2, respectively. Thus, when the control signal C1 is output to the switcher 11, if the pin is already connected to PHY2, this control signal C1 is not output (steps S04 and S05 in FIG. 6).

  Specifically, when a LAN device that uses one pin of the first group and the second group is connected to the RJ45 connector 21, the pins of the first group and the second group are connected to PHY1 and PHY2, respectively. The control signal C1 output to the switcher 11 connects one pin of the first group and the second group to the PHY 1 corresponding to the RJ45 connector 21, and connects the other pin of the first group and the second group to the RJ45 connector 21. The control signal C1 is output to the switcher 11 so as to switch alternately between a state connected to PHY2 not corresponding to the state and a state not connected to PHY2 (steps S06 to S13 in FIG. 7).

  More specifically, one pin of the first group and the second group is connected to PHY1 corresponding to the RJ45 connector 21, and the other pin of the first group and the second group is connected to PHY2 not corresponding to the RJ45 connector 21. A control signal C1 output to the switcher 11 so as to switch alternately between a state of being connected and a state of not being connected connects one pin of the first group and the second group of the RJ45 connector 21 to PHY1 and When the other pins of the first group and the second group are alternately switched between a state where they are connected to PHY 2 and a state where they are not connected (steps S 06 to S 13 in FIG. 7), when a LAN device is further connected to the RJ 45 connector 21, the RJ 45 connector 21. The other pins of the first group and the second group are fixed to be connected to PHY2 (steps S11 to S13 in FIG. 7), and RJ45. When a LAN device is connected to the connector 22, the other pins of the first group and the second group of the RJ45 connector 21 are fixed to a state where they are not connected to PHY 2 (steps S 07 to S 09 in FIG. 7) and output to the switcher 11. This is the control signal C1.

  The L2SW control method of the first embodiment is based on the operation method of the L2SW controller 10 as an invention. The L2SW control program of the first embodiment is for causing the processor 12 to realize each function of the L2SW controller 10. The program may be recorded on a non-transitory storage medium, such as an optical disk or a semiconductor memory. In this case, the program is read from the recording medium by a computer and executed.

  According to the first embodiment, even when two LAN devices are connected to, for example, the RJ45 connector 21 on the L2SW controller 10 side via the RJ45 branch connector, the pin connection between the RJ45 connector 21 and PHY1, PHY2 is switched. Accordingly, the pins of the RJ45 connector 21 can be connected to the PHY1 and PHY2 in correspondence with the two LAN devices, so that the RJ45 branch connector on the L2SW controller 10 side can be dispensed with.

  Hereinafter, the first embodiment will be described in more detail.

  In the first embodiment, in order to simplify the description, a two-port L2SW controller 10 is taken as shown in FIG. The operation signals from the RJ45 connector 21 are a pair of 1st pin, 2nd pin, 3rd pin and 6th pin, 4th pin and 5th pin, 7th pin and 8th pin, respectively. The same applies to the RJ45 connector 22. The operation signals from the RJ45 connectors 21 and 22 correspond to PHY1 and PHY2, respectively, in the initial state. PHY 1 and MAC 1 are connected on a one-to-one basis, and PHY 2 and MAC 2 are connected on a one-to-one basis, and these are controlled by the processor 12. The switcher 11 is connected to the processor 12 by a control signal C1. The function of the switcher 11 is to connect Ports 1 and 2 and PHYs 1 and 2 in any combination in accordance with instructions from the processor 12. Port 1 is a port of the RJ45 connector 21, and Port 2 is a port of the RJ45 connector 22.

  FIG. 2 shows a connection state inside the switcher 11 at the normal time. The normal time is a state in which no cable is connected to the RJ45 connectors 21 and 22, that is, immediately after the system is started. At this normal time, the operation signal line 8 from Port 1 is connected to PHY 1 on a one-to-one basis. That is, the RJ45 connector 21 and PHY1 are connected with pins having the same number. Similarly, Port2 is connected to PHY2 on a one-to-one basis. The operation under each condition will be described based on this state.

<1> When 1 Gbps LAN Device is Connected to Port 1 As described above, auto-negotiation is initially performed between the processor 12 and the connected LAN device while maintaining the connection state of FIG. As a result, the processor 12 determined to have 1 Gbps maintains the connection shown in FIG. This is because all 8 wires of the RJ45 connector 21 are used in the case of 1 Gbps. At this time, the switcher 11 does not operate.

<2> When a 100 Mbps LAN device is connected to Port 1 Similarly, the connection shown in FIG. In this state, auto-negotiation is performed with the LAN device connected to the processor 12. As a result, the processor 12 that has determined 100 Mbps sends an instruction to the switcher 11 to change the connection shown in FIG. Since the 100 Mbps signal uses only the first and second pins and the four pins of the third and sixth pins, the switcher 11 only needs to be connected as shown in FIG. In other words, the 4th and 5th pins and the 7th and 8th pins of Port1 do not have to be connected to PHY1, so that the 1st and 2nd pins and 3rd pin of PHY2 as shown in FIG. And 6th pin can be connected. However, since the LAN device cannot be connected from the Port 2 RJ45 connector 22 in such a connection, the processor 12 controls the switcher 11 to switch the connection of FIG. 3 and FIG. 4 in a time division manner. LAN devices can be connected from either the Port 1 side or the Port 2 side.

<3> When Port 1 is connected as shown in FIG. 3 Since Port 2 and PHY 2 are connected one-to-one, this is not different from the normal operation. When a LAN device is connected to Port 2, since the link speed is determined by auto-negotiation, the LAN device can support both 1 Gbps and 100 Mbps.

<4> Case where Port 1 is Connected in FIG. 4 Here, let us consider a case where a 100 Mbps device is directly connected to the RJ45 connector 21 of Port 1. In this case, as described in <2>, Port1 and PHY1 are connected. Even when the connection shown in FIG. 4 is made, the 4th and 5th pins of Port1 and the 7th and 8th pins are connected to the 1st and 2nd pins of PHY2, and the 3rd and 6th pins. do not have to. Therefore, the switcher 11 switches between FIGS. 3 and 4 until a LAN device is connected to the Port 2.

  Next, the operation when the RJ45 branch connector 23 is connected to the Port 1 RJ45 connector 21 will be described with reference to FIG. Since the RJ45 branch connector 23 divides 8 wires into 4 wires and 4 wires, even if the LAN device 31 to be connected supports 1 Gbps, it can be connected only at 100 Mbps. A normal LAN controller has a function to automatically link down and connect at 100 Mbps when the number of cables is 4 even if the LAN device supports 1 Gbps. With this function, even when the LAN device 31 corresponding to 1 Gbps is connected to the RJ45 branch connector 23, the LAN device 31 is connected to the PHY 1 at 100 Mbps (4 lines). If the LAN device 31 is a device compatible with 100 Mbps, it is connected at 100 Mbps by normal auto-negotiation.

  Next, a case where a LAN device 32 is further connected to the RJ45 branch connector 23 will be considered. In this case as well, the same reasoning as when the LAN device 31 is connected is established, and the LAN device 32 is connected at 100 Mbps regardless of whether it corresponds to 1 Gbps or 100 Mbps. However, the LAN device 32 is connected to the 1st and 2nd pins of PHY2, the 3rd and 6th pins via the 4th and 5th pins and the 7th and 8th pins of Port1. Thus, it is different from the LAN device 31.

  In the above description, a case where a LAN device or an RJ45 branch connector is connected to the Port 1 side has been described, but the same applies to a case where a LAN device or an RJ45 branch connector is connected to the Port 2 side. Even when an L2SW controller with two or more ports is used, the same operation is possible by detecting a port where the processor is not linked up and issuing an instruction to connect the Port and PHY. . Therefore, the first embodiment is not limited by the connection order or the number of ports.

  Next, what flow the processor 12 is actually controlling in the above-described operation will be described with reference to the flowcharts of FIGS. Here, the control of Port 1 will be described, but Port 2 is also controlled in the same flow.

  First, the processor 12 performs “PHY1 connection detection” (step S01). When the connection is detected (Yes), next, “1 Gbps or 100 Mbps” is determined (step S02). If it is determined to be 1 Gbps, the connection is completed while maintaining the connection shown in FIG. 2 (step S03). If it is determined that the transmission rate is 100 Mbps, the “PHY2 link state” is checked to check whether PHY2 is already connected (step S04). If the link is already up (UP), the connection state of Port 2 is maintained and the connection is completed (step S05).

  If PHY2 is link-down (DOWN), the processor 12 sends an instruction to the switcher 11 so as to connect as shown in FIG. 3 (step S06). “PHY2 connection detection” is performed in the state shown in FIG. 3 (step S07). If connection is detected (Yes), the switching operation of the switcher 11 is stopped (step S08), and the connection of Port2 is completed (step S08). Step S09). At this time, the link speed is a speed determined by auto-negotiation with a device connected to Port2.

  When the connection of PHY2 is not detected (No), the processor 12 switches the switcher 11 to the connection shown in FIG. 4 (step S10), and performs “PHY2 connection detection” (step S11). If the connection can be detected, the switching operation of the switcher 11 is stopped (step S12), and the connection of Port 1 is completed (step S13).

  If the connection cannot be detected, the connection is switched to the connection shown in FIG. 3 (step S06), and the previous operation is repeated. At this time, the operation of switching the connection in FIGS. 3 and 4 is repeated in a time division manner until PHY 2 detects a connection (step S07).

  Next, the effect in the switching hub 40 using the L2SW controller 10 of the first embodiment will be described with reference to FIG.

  It is assumed that the switching hub 40 using the L2SW controller 10 terminates the LAN cable 84 on the wall 83. The television 88 and the recorder 90 arranged in the living room 81 are connected to the switching hub 40 via the RJ45 branch connector 41 and the RJ45 connector 85. Similarly, the television 89 and the personal computer 91 arranged in the bedroom 82 are connected to the switching hub 40 via the RJ45 branch connector 42 and the RJ45 connector 86.

  According to the switching hub 40, one LAN cable 84 wired on the wall 83 is sufficient for each of the RJ45 connectors 85 and 86, and it is not necessary to connect the RJ45 branch connector before the switching hub 40. The effect is to reduce the number. Further, the switching hubs 92 and 93 arranged in each room shown in FIG. 12 are not required, and if the RJ45 branch connectors 41 and 42 are used, two LAN devices can be connected to each other.

  More specifically, in the example of FIG. 14, one long-distance LAN cable 104, one RJ45 branch connector 105 on the switching hub 108 side, and two on one RJ45 branch connector 106 on the LAN device side. LAN cables 107b and 107c and two RJ45 connectors on the switching hub 108 side are required. On the other hand, in the example of FIG. 8, one LAN cable 84 and one RJ45 connector on the switching hub 108 side may be used for one RJ45 branch connector 41 on the LAN device side. That is, in the example of FIG. 8, one RJ45 branch connector 105 on the switching hub 108 side, two LAN cables 107b and 107c, and one RJ45 connector on the switching hub 108 side in the example of FIG.

  Next, the L2SW controller of the second embodiment will be described with reference to FIG.

  In the second embodiment, two PHY1 and PHY2 are allocated to one Port1. That is, PHY2 is not used as Port1 and Port2. Normally, Port1 and PHY1 are connected one-on-one. When a 1 Gbps LAN device is connected to Port 1, the one-to-one connection is maintained as it is. On the other hand, when a LAN device of 100 Mbps is connected to Port 1, the operation of switching between PHY 1 and PHY 2 as described in the first embodiment is performed.

  Next, the L2SW controller of Embodiment 3 will be described using FIG.

  The L2SW controller 50 according to the third embodiment is provided in the RJ45 connectors 21 and 22, and the light emitting diodes 51 and 52 as display units that display that the RJ45 connectors 21 and 22 are in use according to the input display signals C2 and C3. Is further provided. For example, when the pin of the RJ45 connector 21 not corresponding to PHY2 is connected to PHY2 (FIG. 5), the processor 53 outputs the display signal C3 to the light emitting diode 52 provided in the RJ45 connector 22 corresponding to PHY2. In the state shown in FIG. 5, since the LAN device cannot be connected from Port 2, whether or not the RJ45 connector 22 can be connected is displayed by the light emitting diode 52.

  Next, the present invention will be summarized.

  The features of the present invention are the switcher function, the control flow of the switcher by the processor, the function of notifying the use of the RJ45 connector (light emitting diode, etc.), and the like. And this invention makes the RJ45 branch connector of the switching hub side unnecessary by taking in the function of the RJ45 branch connector required in the switching hub side in patent document 1 to the switching hub side.

  In the present invention, as in the RJ45 branch connector proposed in Patent Document 1, two LAN devices can be connected to 1 Port of a switching hub by branching 8 lines of RJ45 signals into 4 lines and 4 lines. It is characterized by having. In Patent Document 1, the branch connector is necessary on both sides of the LAN device side and the switching hub side. By providing this branch function in the L2SW controller of the present invention, the switching hub side has an RJ45 branch connector. Is eliminated, and the number of connected cables is reduced.

  Although the present invention has been described with reference to the above embodiments, the present invention is not limited to the above embodiments. Various changes that can be understood by those skilled in the art can be made to the configuration and details of the present invention. Further, the present invention includes a combination of some or all of the configurations of the above-described embodiments as appropriate.

  Although a part or all of the above embodiments can be described as the following supplementary notes, the present invention is not limited to the following configurations.

[Appendix 1] Provided between one or more RJ45 connectors having eight pins and two or more physical layers, and according to the input control signal, the eight pins are divided into four groups in the first group and the second group. A switch unit for connecting the first group and the second group of pins to one of the two or more physical layers;
When a LAN device using the first group and the second group of pins is connected to one RJ45 connector, the first group and the second group of pins are connected to the one physical layer. When the LAN device that outputs the control signal to the switch unit and uses one pin of the first group and the second group is connected to one RJ45 connector, the pins of the first group and the second group A control unit that outputs the control signal to the switch unit so as to connect two different physical layers to each other,
L2SW controller equipped with.

[Supplementary Note 2] When a LAN device that uses one pin of the first group and the second group is connected to one RJ45 connector, the control unit sets the pins of the first group and the second group. When outputting the control signal to the switch unit to connect to two different physical layers, the second physical layer does not include the physical layer to which the pin has already been connected,
The L2SW controller according to appendix 1.

[Supplementary Note 3] When a LAN device using one pin of the first group and the second group is connected to one RJ45 connector, the first group and the second group of pins are different from each other. The control signal output to the switch unit to connect to the physical layer is
When the RJ45 connector and the physical layer are provided in a one-to-one correspondence as an initial state,
One pin of the first group and the second group is connected to the physical layer corresponding to the RJ45 connector, and the other pin of the first group and the second group is connected to the physical layer not corresponding to the RJ45 connector. It is a control signal output to the switch unit so as to switch alternately between a connected state and a non-connected state.
Appendix L or 2 L2SW controller.

[Supplementary Note 4] One pin of the first group and the second group is connected to the physical layer corresponding to the RJ45 connector, and the other pin of the first group and the second group is not compatible with the RJ45 connector. The control signal output to the switch unit so as to switch alternately between the state connected to the physical layer and the state not connected,
The first RJ45 connector and the first physical layer are provided in a one-to-one correspondence in the initial state, and the second RJ45 connector and the second physical layer are in a one-to-one correspondence in the initial state. When it is provided
One pin of the first group and the second group of the first RJ45 connector is connected to the first physical layer, and the other pin of the first group and the second group of the first RJ45 connector Is a control signal output to the switch unit so as to alternately switch between a state of connecting to the second physical layer and a state of not connecting to the second physical layer,
The L2SW controller according to appendix 3.

[Supplementary Note 5] One pin of the first group and the second group of the first RJ45 connector is connected to the first physical layer, and the first group and the second group of the first RJ45 connector The control signal output to the switch unit so as to alternately switch between the state of connecting the other pin of the second physical layer and the state of not connecting to the second physical layer,
One pin of the first group and the second group of the first RJ45 connector is connected to the first physical layer, and the other pin of the first group and the second group of the first RJ45 connector Are alternately switched to a state of being connected to the second physical layer and a state of being not connected, and when a LAN device is further connected to the first RJ45 connector, the first group and the second of the first RJ45 connector are connected. When the other pin of the group is fixed to be connected to the second physical layer, and a LAN device is connected to the second RJ45 connector, the first group and the second group of the first RJ45 connector It is a control signal output to the switch unit so as to fix the other pin in a state where it is not connected to the second physical layer.
The L2SW controller according to appendix 4.

[Appendix 6] The display device further includes a display unit provided on the RJ45 connector for displaying that the RJ45 connector is in use according to the input display signal.
When the RJ45 connector and the physical layer are provided in a one-to-one correspondence as an initial state,
The control unit outputs the display signal to the display unit provided in the RJ45 connector corresponding to the physical layer when a pin of the RJ45 connector not corresponding to the physical layer is connected to the physical layer. To
The L2SW controller according to any one of appendices 1 to 5.

[Appendix 7] The group of pins is composed of Pin 1, Pin 2, Pin 3, and Pin 6,
The two groups of pins consist of 4th pin, 5th pin, 7th pin and 8th pin.
The L2SW controller according to any one of appendices 1 to 6.

[Supplementary Note 8] Provided between one or more RJ45 connectors having eight pins and two or more physical layers, and according to the input control signal, the eight pins are divided into four groups of first and second groups. Dividing, for the switch unit connecting these first group and second group pins to any of the two or more physical layers,
When a LAN device using the first group and the second group of pins is connected to one RJ45 connector, the first group and the second group of pins are connected to the one physical layer. The control signal is output to the switch unit,
When a LAN device that uses one pin of the first group and the second group is connected to one RJ45 connector, the pins of the first group and the second group are connected to two different physical layers, respectively. To output the control signal to the switch unit,
L2SW control method.

[Supplementary Note 9] Provided between one or more RJ45 connectors having eight pins and two or more physical layers, and according to the input control signal, the eight pins are divided into four groups of first and second groups. Dividing, for the switch unit connecting these first group and second group pins to any of the two or more physical layers,
When a LAN device using the first group and the second group of pins is connected to one RJ45 connector, the first group and the second group of pins are connected to the one physical layer. A function of outputting the control signal to the switch unit;
When a LAN device that uses one pin of the first group and the second group is connected to one RJ45 connector, the pins of the first group and the second group are connected to two different physical layers, respectively. A function of outputting the control signal to the switch unit,
L2SW control program for realizing the above in a computer.

  The present invention is applicable to all products using an L2SW controller, such as a switching hub, a home gateway device, and a wireless LAN router.

10, 50 L2SW controller 11 Switcher (switch part)
12, 53 processor (control unit)
21, 22 RJ45 connector 23 RJ45 branch connector 31, 32 LAN device 40 Switching hub 41, 42 RJ45 branch connector 51, 52 Light emitting diode (display unit)
PHY1, PHY2 Physical layer MAC1, MAC2 MAC layer Port1, Port2 Port C1 Control signal C2, C3 Display signal

80 Housing 81 Living 82 Bedroom 83 Back of the wall 84 LAN cable 85, 86 RJ45 connector 87, 92, 93 Switching hub 88, 89 Television 90 Recorder 91 Personal computer

100, 105, 106 RJ45 branch connector 101 Housing 101a, 101b, 101c Opening 102a, 102b, 102c RJ45 connector 103 Signal line 104 Long distance LAN cable 107b, 107c, 109b, 109c LAN cable 108 Switching hub 110b, 110c Personal computer

Claims (9)

The eight pins are provided between one or more RJ45 connectors having eight pins and two or more physical layers, and according to the input control signal, the eight pins are divided into a first group and a second group by four pins. A switch unit for connecting a first group and a second group of pins to any of the two or more physical layers;
When a LAN device using the first group and the second group of pins is connected to one RJ45 connector, the first group and the second group of pins are connected to the one physical layer. When the LAN device that outputs the control signal to the switch unit and uses one pin of the first group and the second group is connected to one RJ45 connector, the pins of the first group and the second group A control unit that outputs the control signal to the switch unit so as to connect two different physical layers to each other,
A layer 2 switch controller. When the LAN device that uses one pin of the first group and the second group is connected to one RJ45 connector, the control unit may change the pins of the first group and the second group different from each other. When outputting the control signal to the switch unit to connect to the physical layer, the second physical layer does not include the physical layer to which the pin has already been connected,
The layer 2 switch controller according to claim 1. When a LAN device that uses one pin of the first group and the second group is connected to one RJ45 connector, the pins of the first group and the second group are connected to two different physical layers, respectively. The control signal output to the switch unit is
When the RJ45 connector and the physical layer are provided in a one-to-one correspondence as an initial state,
One pin of the first group and the second group is connected to the physical layer corresponding to the RJ45 connector, and the other pin of the first group and the second group is connected to the physical layer not corresponding to the RJ45 connector. It is a control signal output to the switch unit so as to switch alternately between a connected state and a non-connected state.
The layer 2 switch controller according to claim 1 or 2. One pin of the first group and the second group is connected to the physical layer corresponding to the RJ45 connector, and the other pin of the first group and the second group is connected to the physical layer not corresponding to the RJ45 connector. The control signal output to the switch unit so as to switch alternately between a connected state and a non-connected state,
The first RJ45 connector and the first physical layer are provided in a one-to-one correspondence in the initial state, and the second RJ45 connector and the second physical layer are in a one-to-one correspondence in the initial state. When it is provided
One pin of the first group and the second group of the first RJ45 connector is connected to the first physical layer, and the other pin of the first group and the second group of the first RJ45 connector Is a control signal output to the switch unit so as to alternately switch between a state of connecting to the second physical layer and a state of not connecting to the second physical layer,
The layer 2 switch controller according to claim 3. One pin of the first group and the second group of the first RJ45 connector is connected to the first physical layer, and the other pin of the first group and the second group of the first RJ45 connector A control signal output to the switch unit so as to alternately switch between a state of connecting to the second physical layer and a state of not connecting to the second physical layer,
One pin of the first group and the second group of the first RJ45 connector is connected to the first physical layer, and the other pin of the first group and the second group of the first RJ45 connector Are alternately switched to a state of being connected to the second physical layer and a state of being not connected, and when a LAN device is further connected to the first RJ45 connector, the first group and the second of the first RJ45 connector are connected. When the other pin of the group is fixed to be connected to the second physical layer, and a LAN device is connected to the second RJ45 connector, the first group and the second group of the first RJ45 connector It is a control signal output to the switch unit so as to fix the other pin in a state where it is not connected to the second physical layer.
The layer 2 switch controller according to claim 4. A display unit that is provided on the RJ45 connector and displays that the RJ45 connector is in use according to the input display signal;
When the RJ45 connector and the physical layer are provided in a one-to-one correspondence as an initial state,
The control unit outputs the display signal to the display unit provided in the RJ45 connector corresponding to the physical layer when a pin of the RJ45 connector not corresponding to the physical layer is connected to the physical layer. To
The layer 2 switch controller according to any one of claims 1 to 5. The group of pins consists of pin 1, pin 2, pin 3, and pin 6,
The two groups of pins consist of 4th pin, 5th pin, 7th pin and 8th pin.
The layer 2 switch controller according to any one of claims 1 to 6. The eight pins are provided between one or more RJ45 connectors having eight pins and two or more physical layers, and according to the input control signal, the eight pins are divided into a first group and a second group by four pins. For the switch unit that connects the pins of the first group and the second group to one of the two or more physical layers,
When a LAN device using the first group and the second group of pins is connected to one RJ45 connector, the first group and the second group of pins are connected to the one physical layer. The control signal is output to the switch unit,
When a LAN device that uses one pin of the first group and the second group is connected to one RJ45 connector, the pins of the first group and the second group are connected to two different physical layers, respectively. To output the control signal to the switch unit,
Layer 2 switch control method. The eight pins are provided between one or more RJ45 connectors having eight pins and two or more physical layers, and according to the input control signal, the eight pins are divided into a first group and a second group by four pins. For the switch unit that connects the pins of the first group and the second group to one of the two or more physical layers,
When a LAN device using the first group and the second group of pins is connected to one RJ45 connector, the first group and the second group of pins are connected to the one physical layer. A function of outputting the control signal to the switch unit;
When a LAN device that uses one pin of the first group and the second group is connected to one RJ45 connector, the pins of the first group and the second group are connected to two different physical layers, respectively. A function of outputting the control signal to the switch unit,
Layer 2 switch control program for realizing the above in a computer.

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