JP2005190896A - Cable line for wireless lan - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a cable line composed of leakage coaxial cable with a small diameter suitable for an indoor wireless LAN system. <P>SOLUTION: The cable line is structured to serially connect a plurality of leakage coaxial cables 11A, 11B, 11C with outer diameters of ≤20 mm, with almost same coupling losses though amplifiers 12A, 12B, respectively. As for the amplifiers 12A, 12B, bidirectional amplifiers are used or two kinds of amplifiers for signal transmission and signal reception are used. If two kinds of amplifiers are used, the plurality of leakage coaxial cables used on a signal transmission side are serially connected through the amplifier for signal transmission and the plurality of leakage coaxial cables used on a signal reception side are serially connected through the amplifier for signal reception. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a wireless LAN cable line suitable for constructing an indoor wireless LAN system.

  Attempts have been made to use a leaky coaxial cable in an indoor wireless LAN system when forming an indoor wireless LAN (local area network). That is, as shown in FIG. 5, the leaky coaxial cable 1 is wired in a U-shape in the area 2, for example, the floor or the ceiling. Connected to the access point 5 are a LAN cable 8B connected to a host computer and a server and a power cable 8A for driving the access point 5. The access point 5 and the leaky coaxial cable 1 are connected through a connector 4 using a normal coaxial cable 6. Since there is no device such as the access point 5 on the leaky coaxial cable 1 side, it is not necessary to supply power. A terminating resistor 3 is connected to the end of the leaky coaxial cable 1.

  In this way, radio waves are transmitted from the leaky coaxial cable 1 over its entire length. Compared to transmission and reception of radio waves at a single point, it is not affected by the layout of indoor metal shelves or partitions. Further, since it is only necessary to install the access point 5 in one place, wiring work and maintenance inspection are considerably simplified.

Conventionally well-known leaky coaxial cables are used for transmission of railway radio, radio broadcasting in tunnels, and the like. In this leaky coaxial cable, for example, a trapezoidal cord made of high-density polyethylene is spirally wound on an inner conductor made of a copper pipe or a copper single wire, and an insulating layer is formed thereon by extrusion-coating polyethylene. A cable core is constructed by corrugating vertically with aluminum laminated tape with slots. The cable core and the support wire (steel stranded wire) are arranged in parallel, and are covered with a black polyethylene common to an SSD (self-supporting) mold (see Patent Document 1 and Patent Document 2).
JP-A-5-121926 JP-A-10-145136

The conventional techniques as described above have the following problems to be solved.
In order to construct an indoor wireless LAN system, a leaky coaxial cable that is as thin as possible is required. In practical use, an insulator having an outer diameter of 20 mm or less is preferable. The main parameters of this leaky coaxial cable are coupling loss and transmission loss. If the leaky coaxial cable has a small diameter, an attempt to set the coupling loss small will increase the transmission loss. For this reason, since the amount of radio wave attenuation increases, the length of the leaky coaxial cable actually becomes a short service section of about 10 m.
The well-known leaky coaxial cable has an outer diameter of about 40 mm, and is greatly different from that of the indoor wireless LAN system in terms of transmission signal and transmission power. Therefore, if the conventional design technique is used as it is, various problems in manufacturing and characteristics occur.

  The present invention has been made paying attention to the above points, and an object thereof is to provide a small-diameter leaky coaxial cable suitable for an indoor wireless LAN system.

The present invention solves the above problems by the following configuration.
<Configuration 1>
A cable line for a wireless LAN, wherein a plurality of leaky coaxial cables having an outer diameter of 20 mm or less and substantially the same coupling loss are connected in series through an amplifier.

  A leaky coaxial cable constituting a cable line for a wireless LAN includes an inner conductor, an insulator provided on the outer periphery of the inner conductor, and a plurality of slots arranged on the outer periphery of the insulator at regular intervals in the longitudinal direction. A short leaky coaxial cable having an outer diameter of an insulator of 20 mm or less and a length of about 10 m. . With such a configuration, a plurality of leaky coaxial cables having substantially the same coupling loss are sequentially connected in series through an amplifier, whereby a substantially uniform electric field level can be obtained over the length direction.

<Configuration 2>
The wireless LAN cable line according to Configuration 1, wherein a bidirectional amplifier is used as the amplifier.

  By using the bidirectional amplifier, an almost uniform electric field level can be obtained in the length direction of both the upstream leaky coaxial cable and the downstream leaky coaxial cable.

<Configuration 3>
In the wireless LAN cable line described in Configuration 1, two types of amplifiers for signal transmission and signal reception are used as the amplifier, and a plurality of the leaky coaxial cables used on the signal transmission side are connected to the transmission amplifier. A wireless LAN cable line comprising a plurality of leaky coaxial cables connected in series via a receiving amplifier and connected in series via a receiving amplifier.

  The transmitting amplifier and the receiving amplifier are the same, and the configuration is simple and can be obtained at a lower cost than the bidirectional amplifier.

<Configuration 4>
In the wireless LAN cable line according to Configuration 3, the leaky coaxial cable used on the signal transmission side and the leaky coaxial cable used on the signal reception side are arranged in parallel and each slot is positioned on one side surface A wireless LAN cable line characterized by being integrally covered with a common covering.

  With such a configuration, it is possible to accurately position the slots of the upstream leaky coaxial cable and the downstream leaky coaxial cable, and to prevent inconvenient coupling between the two. Further, since both slots can be directed in an optimum direction, a good network can be formed. Also, since two leaky coaxial cables for up and down can be installed at once, such as the back of the ceiling, LAN installation work can be performed accurately in a short time.

<Configuration 5>
The wireless LAN cable line according to Configuration 4, wherein a cross section of the common coating is a glasses type.

<Configuration 6>
The wireless LAN cable line according to Configuration 4 or 5, wherein the leaky coaxial cable is marked on a side surface opposite to the side surface on which the slot is provided.

  If the leaky coaxial cable is installed, if the mark is just above, the slot will definitely face down.

  Hereinafter, embodiments of the present invention will be described using specific examples.

FIG. 1 is an explanatory diagram of a wireless LAN cable line according to the first embodiment.
As shown in FIG. 1, a leaky coaxial cable 11 </ b> A is connected to an access point 15 via a general coaxial cable 16 and a connector 14. Next to that, a leaky coaxial cable 11B is laid. A bidirectional amplifier 13A is provided between the leaky coaxial cable 11A and the leaky coaxial cable 11B.

  The bidirectional amplifier 13A is provided with directional couplers 18A and 18B and amplifiers 12A and 12B. The signal supplied from the leaky coaxial cable 11A is input to the amplifier 12A via the directional coupler 18A. This signal is amplified by the amplifier 12A and sent to the leaky coaxial cable 11B through the directional coupler 18B. On the other hand, a signal transmitted in the direction of the access point 15 from the leaky coaxial cable 11B is input to the amplifier 12B via the directional coupler 18B in the bidirectional amplifier 13A. The signal amplified by the amplifier 12B is sent out toward the leaky coaxial cable 11A via the directional coupler 18A.

  In this way, both the upstream and downstream signals are amplified and sent out by the bidirectional amplifier 13A. A bidirectional amplifier 13B is also provided between the leaky coaxial cable 11B and the leaky coaxial cable 11C. This configuration is exactly the same as the bidirectional amplifier 13A.

  The access point 15 is connected to a server or the like, and bidirectional data transmission / reception is performed through the access point 15. The operation of the LAN itself is not different from the conventional one. Such leaky coaxial cables 11A, 11B, and 11C are preferably laid on, for example, an office ceiling plate, under a floor, or in a wall. Of course, if there is no problem in aesthetics, it can be used by pasting it on the wall.

  As shown in FIG. 1B, the wireless LAN cable line as described above is wirelessly coupled to a terminal device arranged in a predetermined range around the wireless LAN cable line. The horizontal axis of FIG.1 (b) shows the position of the longitudinal direction of the wireless LAN cable track | line. The vertical axis shows the electric field strength near the cable. A point A in FIG. 1B corresponds to a portion of the connector 14 that connects the coaxial cable 16 and the leaky coaxial cable 11A in FIG. Further, the location B corresponds to a portion where the bidirectional amplifier 13A is disposed. The place C corresponds to the position where the bidirectional amplifier 13B is disposed.

  A signal transmitted from the access point 15 through the coaxial cable 16 in the downstream direction, that is, in a direction from the access point 15 toward each of the leaky coaxial cables 11A, 11B, and 11C has a maximum value at the location A. Attenuates as it is transmitted. The leaky coaxial cable 11A radiates electromagnetic waves in the vicinity thereof along the longitudinal direction. Also, electromagnetic waves are received from the vicinity. As shown by the solid line 17A in FIG. 1B, the signal intensity is attenuated by the radiation of electromagnetic waves.

At location B, the signal is amplified by the amplifier 13A and raised to a certain level. Thereafter, while the leaky coaxial cable 11B is transmitted again, it gradually attenuates as indicated by a solid line 17B. At location C, it is again amplified by the amplifier 13B and the signal level is raised. As shown in FIG. 1B, the electric field strength in the vicinity of the leaky coaxial cables 11A, 11B, and 11C shows the characteristics shown in FIG. 1B along the longitudinal direction, but at a certain level or more. If there is, the terminal device can connect to the server via the leaky coaxial cable and transmit / receive data.
The leaky coaxial cable and the amplifier may be connected via a connector, or may be directly incorporated without using a connector.

FIG. 2 is an explanatory diagram showing a specific configuration of the leaky coaxial cable as described above.
FIG. 2A is a side view of the leaky coaxial cable 11, and the outer conductor 43 integrated with the sheath 42 is provided with a number of slots 41. A predetermined amount of electromagnetic waves are emitted from the slot 41, and communication with a terminal device arranged in the vicinity of the cable becomes possible. As shown in FIG. 2B, the leaky coaxial cable 11 is obtained by covering the outer periphery of the center conductor 45 with an insulator 44, an external conductor 43, and a sheath 42.

  Electromagnetic waves are emitted in the direction of the slot 41 of the leaky coaxial cable 11. For example, when this leaky coaxial cable 11 is arranged behind the ceiling, the cable 11 is laid so that the slot 41 is arranged on the lower side. As a result, the signal is efficiently radiated to the terminal device side, and the signal can be efficiently received from the terminal device to transmit and receive data. FIG. 2C is a perspective view showing a terminal of the leaky coaxial cable 11. As shown in this figure, the outer conductor 43 wound around the outer peripheral surface of the insulator 44 is integrated with the sheath 42, and the slot 41 is always arranged so as to face a certain direction with respect to the cable. Yes. Therefore, for example, if a mark indicating the position of the slot is provided on the outside of the sheath 42, the cable can be laid in an appropriate direction.

FIG. 3A is an explanatory diagram illustrating a cable line for wireless LAN according to the second embodiment of the present invention.
As shown in FIG. 3A, in this embodiment, the three leaky coaxial cables 21A, 21B, and 21C constituting the upstream line and the three leaky coaxial cables 31A, 31B, and 31C constituting the downlink line are used. And. A coaxial cable 26 and a coaxial cable 36 are connected from the access point 25 via the interface 27.

  The coaxial cable 26 is for an uplink and is connected to the leaky coaxial cable 21A via the connector 24. The coaxial cable 36 is for the downlink and is connected to the leaky coaxial cable 31A via the connector 34. An amplifier 23A is inserted between the leaky coaxial cables 21A and 21B on the upstream line. An amplifier 23B is inserted between the leaky coaxial cable 21B and the leaky coaxial cable 21C. An amplifier 33B is connected between the leaky coaxial cables 31C and 31B for the downlink. An amplifier 33A is inserted between the leaky coaxial cables 31B and 31A.

  A signal transmitted in the downstream direction from the access point 25 with the above configuration is transferred through the coaxial cable 26 and the connector 24 through the leaky coaxial cable 21A. Then, it is amplified by the amplifier 23A and transmitted again through the leaky coaxial cable 21B. Thereafter, the signal is amplified by the amplifier 23B and transmitted through the leaky coaxial cable 21C. Data is transmitted to the terminal devices arranged in the vicinity of these leaky coaxial cables 21A, 21B, and 21C. The signal transmitted from the terminal device is received by any of the leaky coaxial cables 31A, 31B, and 31C, transmitted through these cables, and sent to the access point 25.

  The graph shown in FIG. 3B is the same as that shown in FIG. 1B, and the horizontal axis indicates the position near the cable, and the vertical axis indicates the electric field strength. FIG. 1B illustrates the characteristics of the downlink. Accordingly, in FIG. 3B, the characteristics of the uplink are described. The characteristics of the downlink are the same as those shown in FIG. In the uplink, for example, a signal received by the leaky coaxial cable 31C is amplified by the amplifier 33B and raised to a predetermined level. This signal is transmitted to position B and amplified again by the amplifier 33A.

  When the coupling loss is about 60 decibels, even if two leaky coaxial cables are used such that one of them is up and the other is down, the transmission signal is disturbed due to signal wraparound. There are no negative effects. Therefore, it is possible to lay the uplink and the downlink relatively close to each other. Of course, if there is enough space in the installation location, the most efficient wireless LAN can be formed by laying the uplink and downlink slightly apart and directing these slots toward the terminal device side. It becomes possible to do.

FIG. 4 illustrates the configuration of the wireless LAN cable line of the third embodiment. In the wireless LAN cable line as shown in FIG. 3, each leaky coaxial cable is subjected to terminal processing, an amplifier is connected via connectors at both ends, and a connection is made from the access point to the extended coaxial cable. It was.
However, when two leaky coaxial cables are used in the roles of the uplink and downlink, if the signal output from the leaky coaxial cable of the uplink is strongly input directly to the leaky coaxial cable of the downlink, Processing problems may occur.

Therefore, in the embodiment shown in FIG. 4, an integrated unit of two leaky coaxial cables is used. That is, as shown in FIG. 4, the downstream leaky coaxial cable has a configuration in which a center conductor 155, an insulator 154, an outer conductor 153, and a sheath 152 are sequentially covered.
In FIG. 4, it is difficult to see, but the slots are arranged so as to be directed downward. Therefore, as shown in FIG. 4, when the beam 160 is radiated downward and the terminal device is in the direction of the beam 160, good communication is possible.

  On the other hand, the leaky coaxial cable in the upward direction has a configuration in which a center conductor 255, an insulator 254, and an outer conductor 253 are sequentially covered. The sheath 252 and the sheath 152 of the downward leaking coaxial cable are connected via the bridge 100. The bridge 100 is integrated with a sheath 152 and a sheath 252 as shown in FIG. 4, and can be covered by a well-known coextrusion process so that the cross-section of the common covering becomes a glasses shape. The slot of the upward leaking coaxial cable is also arranged downward in FIG.

  Thereby, it is possible to satisfactorily receive a signal transmitted from a terminal device arranged below FIG. Such a cable is provided with marks 157 and 257 on sheaths 152 and 252, for example, as shown in FIG. 4. The cable is laid so that the marks 157 and 257 are just above. This will definitely make the slot face down.

  With the configuration as described above, it is possible to accurately position the slots of the upstream leaky coaxial cable and the downstream leaky coaxial cable, and to prevent inconvenient coupling (crosstalk in a broad sense) between the two. Furthermore, both slots can be directed in an optimum direction, and a good network can be formed. In addition, since the two cables can be laid on the ceiling, under the floor, or on the wall all at once, the LAN laying work can be performed accurately in a short time.

  Note that the method of integrating the two leaky coaxial cables is not limited to the above method. Although the case where the sheath is integrally extruded and coated has been described, two leaky coaxial cables may be connected by another bundling means. If two leaky coaxial cables are arranged in parallel and each slot of the outer conductor provided on the leaky coaxial cable is arranged so as to be oriented in almost the same direction, the downlink cable and the uplink cable are brought close to each other. Even if they are laid in parallel, crosstalk can be reliably prevented.

Although the above configuration is easiest in terms of manufacturing, if the direction of the slot of the downlink cable and the uplink cable can be controlled independently, the structure in which the other cable is not disposed within the communicable angle range of one cable You can do it.
Further, when the two leaky coaxial cables are connected in parallel by the bundling means, there is an effect that the slot can be automatically oriented in the optimum direction when laid on a flat surface.
Although the slots of the leaky coaxial cable are independent long holes regularly arranged, slits that are long in the longitudinal direction of the cable may be used. This can also be said to be a broad slot.

BRIEF DESCRIPTION OF THE DRAWINGS It is a figure which shows the structure of the cable line for wireless LAN of Example 1, (a) is explanatory drawing of the cable line for wireless LAN, (b) is the electric field vicinity of the cable in the longitudinal direction of the cable line for wireless LAN. It is explanatory drawing shown. It is a figure which shows the detail of the leaky coaxial cable of the Example, (a) is a side view, (b) is a cross-sectional view, (c) is a perspective view of a terminal. FIG. 5 is a diagram illustrating a configuration of a wireless LAN cable line according to a second embodiment, where (a) is an explanatory diagram of the wireless LAN cable line, and (b) is a field electric field strength in the longitudinal direction of the wireless LAN cable line. It is explanatory drawing shown. 10 is an explanatory diagram illustrating a configuration of a wireless LAN cable line according to Embodiment 3. FIG. It is explanatory drawing of indoor wireless LAN in the case of forming using the cable line for wireless LAN.

Explanation of symbols

11A, 11B, 11C Leaky coaxial cable 12A, 12B Amplifier 13A, 13B Bidirectional amplifier 14 Connector 15 Access point 16 Coaxial cable 18A, 18B Directional coupler

Claims (6)

  A cable line for a wireless LAN, wherein a plurality of leaky coaxial cables having an outer diameter of 20 mm or less and substantially the same coupling loss are connected in series through an amplifier. In the wireless LAN cable line according to claim 1,
A wireless LAN cable line, wherein a bidirectional amplifier is used as the amplifier. In the wireless LAN cable line according to claim 1,
Using two types of amplifiers for signal transmission and signal reception as the amplifier,
A plurality of the leaky coaxial cables used on the signal transmission side are connected in series via a transmission amplifier,
A wireless LAN cable line, wherein a plurality of the leaky coaxial cables used on the signal receiving side are connected in series via a receiving amplifier. In the wireless LAN cable line according to claim 3,
The leaky coaxial cable used on the signal transmission side and the leaky coaxial cable used on the signal reception side are integrally covered with a common covering in parallel with each slot positioned on one side surface. A wireless LAN cable line. In the wireless LAN cable line according to claim 4,
A cable line for a wireless LAN, characterized in that a cross-section of the common coating is a glasses type. In the cable line for wireless LAN according to claim 4 or 5,
A wireless LAN cable line, wherein a mark is provided on a side surface of the leaky coaxial cable opposite to a side surface provided with a slot.

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