JP6200928B2 - Cable type antenna, extension cable type antenna, composite cable type antenna and wireless communication device - Google Patents

Description

  The present invention relates to a cable type antenna, an extension cable type antenna, a composite cable type antenna, and a wireless communication apparatus.

  With the recent widespread use of wireless local area networks (LANs), improvements in the throughput of data transmitted and received over wireless LANs are required. As a means for improving data throughput, a MIMO (Multiple-Input Multiple-Output) communication technique is known. This is a technique in which different data is transmitted from each antenna using a plurality of antennas, and data is simultaneously received by the plurality of antennas. In MIMO communication, the amount of data transmitted and received can be increased in proportion to the number of antennas used. For example, when data is transmitted / received using two transmitting antennas and two receiving antennas, double data throughput can be realized with respect to a pair of transmitting / receiving antennas.

  In a radio apparatus for MIMO communication, it has been proposed to use a leaky coaxial cable (LCX) as an antenna (see, for example, Patent Document 1). The LCX is a cable type antenna in which a hole called a slot is provided in an outer conductor of a coaxial cable. In LCX, electromagnetic waves inside the cable can be radiated (transmitted) to the outside of the cable and electromagnetic waves outside the cable can be taken into (received) inside the cable through such a slot.

  In Patent Document 1, a single LCX is used to transmit / receive a first system signal from one end of the LCX and transmit / receive a second system signal from the other end to perform multiple systems of MIMO transmission. A MIMO wireless communication apparatus is disclosed.

  By the way, in the MIMO wireless communication apparatus described in Patent Document 1, it is necessary to connect a wireless apparatus as a signal source and both ends of the LCX with a power feeding cable. A coaxial cable is generally used as the power supply cable. At this time, the LCX and the feeding coaxial cable are arranged close to each other in parallel in order to design a compact installation area of the entire wireless communication device including the wireless device, the LCX, and the feeding coaxial cable. There is a case.

  However, when the LCX and the feeding coaxial cable are arranged close to each other in parallel as in Patent Document 1, there is a problem that the transmission loss of the LCX increases due to the influence of the outer conductor of the feeding coaxial cable. there were. In addition, when the LCX and the feeding coaxial cable are separately laid as in Patent Document 1, it is necessary to lay while keeping the positional relationship between the LCX and the feeding coaxial cable in parallel. There was a problem that the work was complicated.

JP 2013-90044 A

  One aspect of the present invention has been proposed in view of such conventional circumstances, and the leaky coaxial cable and the feeding coaxial cable are integrally connected and arranged to be compact, and the leakage in that case Cable-type antenna, extension cable-type antenna, composite cable-type antenna, and radio using such a cable-type antenna, which can keep transmission loss of coaxial cables low and have excellent workability when laying An object is to provide a communication device.

In order to achieve the above object, the present invention provides the following means.
[1] The leaky coaxial cable and the feeding coaxial cable are arranged integrally connected in a parallel state with a certain distance between the outer conductors,
One end side of the leaky coaxial cable and the feeding coaxial cable in the same direction is connected via a curved connecting coaxial cable.
[2] The cable antenna according to [1], wherein an outer diameter of the connecting coaxial cable is smaller than outer diameters of the leaky coaxial cable and the feeding coaxial cable.
[3] The leaky coaxial cable and the feeding coaxial cable are arranged integrally connected in a parallel state with a certain distance between the outer conductors,
One end side of the same direction of the leaky coaxial cable and the power supply coaxial cable is connected in a state where a part of the power supply coaxial cable is curved.
[4] The leaky coaxial cable and the feeding coaxial cable are connected by a connecting portion formed integrally with a sheath of each of the leaking coaxial cable and the feeding coaxial cable. The cable type antenna according to any one of [1] to [3].
[5] The cable according to any one of [1] to [3], wherein the leaky coaxial cable and the feeding coaxial cable are integrally connected using a connector. Type antenna.
[6] The interval is in the range of λ / 4 to λ, where λ is the free space wavelength of the electromagnetic wave radiated from the slot of the leaky coaxial cable. [5] The cable-type antenna according to any one of [5].
[7] A tip antenna cable configured by the cable type antenna according to any one of [1] to [6];
An extension antenna cable configured by a leaky coaxial cable and a feeding coaxial cable, which are connected to the tip antenna cable and integrally connected in a state of being parallel to each other with a certain distance therebetween ,
The antenna antenna cable for extension and the antenna cable for extension have a structure in which the leaky coaxial cable is connected to each other and the power supply coaxial cable is connected to each other.
[8] Arrangement or integration of a plurality of the cable-type antennas according to any one of [1] to [6] and the cable-type antenna of any one of the extension cable-type antennas according to [7] A composite cable type antenna characterized by having a structure as described above.
[9] Of the plurality of cable-type antennas, one end of the leaky coaxial cable or the feeding coaxial cable of adjacent cable-type antennas and the other end of the leaky coaxial cable or the feeding coaxial cable Have a structure connected via a coaxial cable for connection, the composite cable antenna according to [8] above.
[10] The cable type antenna according to any one of [1] to [6], the extension cable type antenna according to [7], and the composite cable according to [8] or [9] One of the cable antennas, and
A wireless communication apparatus comprising an access point or a radio connected to the cable antenna.

  As described above, according to one aspect of the present invention, the leaky coaxial cable and the feeding coaxial cable are integrally connected and arranged to be compact, and the transmission loss of the leaky coaxial cable in that case is kept low. It is possible to provide a cable-type antenna, an extension cable-type antenna, a composite cable-type antenna, and a wireless communication apparatus using such a cable-type antenna, which are excellent in workability when laying. is there.

It is a perspective view showing an example of 1 composition of a cable type antenna concerning a 1st embodiment of the present invention. It is a top view which shows the structure of the cable type antenna shown in FIG. It is a perspective view which shows the structure of LCX. It is a perspective view which shows one structural example of the cable type antenna which concerns on the 2nd Embodiment of this invention. It is a perspective view which shows one structural example of the cable type antenna which concerns on the 3rd Embodiment of this invention. It is a perspective view which shows another structural example of the cable type antenna which concerns on the 3rd Embodiment of this invention. It is a top view which shows one structural example of the extension cable type | mold antenna which concerns on the 4th Embodiment of this invention. It is a top view which shows one structural example of the extension cable type | mold antenna which concerns on the 5th Embodiment of this invention. It is a top view which shows one structural example of the extension cable type | mold antenna which concerns on the 6th Embodiment of this invention. It is a perspective view which shows one structural example of the composite cable type | mold antenna which concerns on the 7th Embodiment of this invention. It is a perspective view which shows one structural example of the composite cable type | mold antenna which concerns on the 8th Embodiment of this invention. It is a perspective view which shows one structural example of the composite cable type | mold antenna which concerns on the 9th Embodiment of this invention. It is a top view which shows one structural example of the composite cable type | mold antenna which concerns on the 10th Embodiment of this invention. It is a top view which shows one structural example of the composite cable type | mold antenna which concerns on the 11th Embodiment of this invention. It is a top view which shows one structural example of the composite cable type | mold antenna which concerns on the 12th Embodiment of this invention. It is a top view which shows the example of 1 structure of the radio | wireless communication apparatus which concerns on the 13th Embodiment of this invention. It is a top view which shows the example of 1 structure of the radio | wireless communication apparatus which concerns on the 14th Embodiment of this invention. It is a top view which shows the example of 1 structure of the radio | wireless communication apparatus which concerns on 15th Embodiment of this invention. It is a top view which shows the example of 1 structure of the radio | wireless communication apparatus which concerns on the 16th Embodiment of this invention. It is a graph which shows the result of having measured the relationship between the space | interval and transmission loss in a cable type antenna at 2.4 GHz. It is a graph which shows the result of having measured the relationship between the space | interval and transmission loss in a cable type antenna at the time of 3.5 GHz. It is a graph which shows the result of having measured the relationship between the space | interval and transmission loss in a cable type antenna in case of 5.0 GHz.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
In addition, in the drawings used in the following description, in order to make the features easy to understand, there are cases where the portions that become the features are enlarged for the sake of convenience, and the dimensional ratios of the respective components are not always the same as the actual ones. Absent. In addition, the materials, dimensions, and the like exemplified in the following description are merely examples, and the present invention is not necessarily limited thereto, and can be appropriately modified and implemented without departing from the scope of the invention. .

(Cable antenna)
[First Embodiment]
First, as a first embodiment of the present invention, for example, a cable type antenna 1A shown in FIGS. 1 and 2 will be described. FIG. 1 is a perspective view showing the configuration of the cable type antenna 1A. FIG. 2 is a plan view showing the configuration of the cable-type antenna 1A.

  As shown in FIGS. 1 and 2, the cable-type antenna 1A is configured such that a leaky coaxial cable (hereinafter referred to as LCX) 2 and a feeding coaxial cable 3 are integrally connected. That is, the LCX 2 and the feeding coaxial cable 3 have the same length and are arranged in parallel with each other, and the sheath 4a of the LCX 2 and the sheath 4b of the feeding coaxial cable 3 are connected by the connecting portion 4c. Has been.

  As shown in FIG. 3, the LCX 2 has a linear center conductor 5, an insulator 6 concentrically covering the center conductor 5, and an insulator 6 concentrically, and periodically arranged in the extending direction. It has an outer conductor 8 provided with a plurality of slots 7 opened, and a sheath 4a has a structure in which the outer conductor 8 is concentrically covered. The sheath 4a of the LCX 2 may be composed of two layers, an inner layer and an outer layer. Further, as will be described later, the inner layer of the sheath 4a may be made of a transparent resin so that the slot 7 can be visually confirmed when the outer layer of the sheath 4a and the connecting portion 4c are formed by batch extrusion. Good. FIG. 3 is a perspective view showing the configuration of LCX2.

  The center conductor 5 and the outer conductor 8 are generally made of copper having a low electric resistance, but aluminum, silver or the like may be used. The insulator 6 is made of polyethylene having a low dielectric loss (tan δ) for the purpose of reducing transmission loss in a high frequency band. Alternatively, in order to reduce tan δ, foamable polyethylene may be used. Further, as a fireproof LCX2, a structure (not shown) in which a glass fiber tape is wound around the insulator 6 so that the center conductor 5 and the outer conductor 8 are not immediately short-circuited even if burned. It may be adopted.

  The plurality of slots 7 are arranged in a straight line at a constant pitch P in the extending direction of the LCX 2 and each open to the same direction. The opening shape of the slot 7 is not particularly limited, and may be, for example, a round hole or a long hole. In the present embodiment, as the slots 7 arranged in a zigzag shape, long holes that are oblique with respect to the extending direction of the LCX 2 are arranged side by side while alternately changing the oblique directions. Further, the vertical slot 7 may have a configuration (not shown) in which long holes perpendicular to the extending direction of the LCX 2 are arranged.

  The feeding coaxial cable 3 has a configuration in which the slot 7 is omitted from the LCX 2 configuration. That is, although not shown in the drawing, the power supply coaxial cable 3 includes a linear center conductor 5, an insulator 6 that covers the center conductor 5 concentrically, and an outer conductor 8 that covers the insulator 6 concentrically. And the sheath 4b has a structure in which the outer conductor 8 is concentrically covered.

  As shown in FIGS. 1 and 2, the LCX 2 and the feeding coaxial cable 3 are connected by a connecting portion 4 c provided between the sheath 4 a on the LCX 2 side and the sheath 4 b on the feeding coaxial cable 3 side. Yes. The sheaths 4a and 4b and the connecting portion 4c can be formed by collectively extrusion-coating the outer conductor of the LCX 2 and the outer conductor of the feeding coaxial cable 3 using polyethylene. Since the sheaths 4a and 4b and the connecting portion 4c are formed by collective extrusion, they are integrated without any boundary. As a resin material constituting the sheaths 4a and 4b and the connecting portion 4c, it is also possible to employ vinyl chloride or flame retardant polyethylene.

  The LCX2 side sheath 4a may be composed of two layers, an inner layer and an outer layer. In this case, the connecting portion 4c connects the outer layer of the sheath 4a on the LCX2 side and the sheath 4b on the feeding coaxial cable 3 side. Further, the outer layer of the sheath 4a, the sheath 4b, and the connecting portion 4c can be integrated without any boundary by batch extrusion coating.

  The connecting portion 4c is configured such that the LCX2 side sheath 4a and the feeding coaxial cable 3 are in a state in which a constant distance D is provided between the outer conductor 8 of the LCX2 and the outer conductor 8 of the feeding coaxial cable 3 which are parallel to each other. The side sheath 4b is connected. The connecting portion 4c is formed in a substantially rectangular flat plate shape between the sheath 4a and the sheath 4b. Each slot 7 of the LCX 2 is opened in a direction perpendicular to the surface including the LCX 2 and the feeding coaxial cable 3, that is, the main surface of the connecting portion 4c.

  Here, the interval D is preferably λ / 4 or more, where λ is the free space wavelength of the electromagnetic wave radiated from each slot 7 of the LCX 2. When the distance D is smaller than λ / 4, the transmission loss of the LCX 2 increases due to interference between the adjacent LCX 2 and the feeding coaxial cable 3. On the other hand, by increasing the distance D, the transmission loss of the LCX 2 can be kept low. However, even if the distance D is larger than λ, the transmission loss of the LCX 2 hardly changes. Therefore, in order to prevent an increase in the size of the cable-type antenna 1A, the distance D is preferably set to λ or less.

  The cable type antenna 1A has a structure in which one end side in the same direction of the LCX 2 and the feeding coaxial cable 3 is connected via a connecting coaxial cable 9 in a curved state. The connecting coaxial cable 9 has the same structure as the above-described feeding coaxial cable 3 and has an outer diameter smaller than the outer diameters of the LCX 2 and the feeding coaxial cable 3. Therefore, the connecting coaxial cable 9 is excellent in flexibility, and can connect one end side of the LCX 2 and the feeding coaxial cable 3 in the same direction with a small bending radius.

  In general, an allowable bending radius of a cable is determined from the viewpoint of mechanical strength. The allowable bending radius varies depending on the type of cable. For example, in a braided coaxial cable, the allowable bending radius is at least four times the outer diameter. Therefore, in order to reduce the bending radius of the connecting coaxial cable 9, the connecting coaxial cable 9 having higher flexibility than the LCX 2 and the feeding coaxial cable 3 must be used.

  In the cable type antenna 1 </ b> A, the LCX 2 and the feeding coaxial cable 3 are kept in a substantially U-shaped curved state at one end in the same direction of the LCX 2 and the feeding coaxial cable 3. Are connected.

  Connectors 10a and 10b are attached to both ends of the LCX2. Connectors 11 a and 11 b are attached to both ends of the feeding coaxial cable 3. Connectors 12 a and 12 b are attached to both ends of the connection coaxial cable 9.

  In the cable type antenna 1A, the connector 10a on one end side of the LCX 2 and the connector 12a on one end side of the connecting coaxial cable 9 are detachably connected, and the connector 11a on one end side of the feeding coaxial cable 3 and the connecting coaxial cable are connected. 9 is detachably connected to a connector 12b on the other end side.

  As described above, in the cable type antenna 1A of the present embodiment, the LCX 2 and the feeding coaxial cable are maintained with the constant distance D between the outer conductor 8 of the LCX 2 and the outer conductor 8 of the feeding coaxial cable 3. 3 can be made compact by connecting them together and the transmission loss of the LCX 2 can be kept low.

  Further, in the cable type antenna 1A of the present embodiment, since the LCX 2 and the feeding coaxial cable 3 are integrally connected and arranged, it is not necessary to separately lay the LCX 2 and the feeding coaxial cable 3; It is possible to improve workability when laying the cable type antenna 1A.

[Second Embodiment]
Next, as a second embodiment of the present invention, for example, a cable type antenna 1B shown in FIG. 4 will be described. FIG. 4 is a perspective view showing the configuration of the cable type antenna 1B. In the following description of the embodiment, the description of the same part as the cable type antenna 1A is omitted and the same reference numerals are given in the drawings.

  As shown in FIG. 4, the cable-type antenna 1B is fed with the LCX 2 in a state where a part of the feeding coaxial cable 3 (hereinafter referred to as a bending portion 3a) is curved instead of using the connecting coaxial cable 9. It is the structure to which the one end side of the same direction with the coaxial cable 3 for a cable is connected. The rest of the configuration is basically the same as that of the cable type antenna 1A.

  Specifically, in the cable type antenna 1B, the bending portion 3a is configured by extending one end side of the feeding coaxial cable 3 from the one end side of the LCX 2 and bending it in a substantially U shape. In the cable type antenna 1B, the connector 10a on one end side of the LCX 2 and the connector 11a on one end side of the feeding coaxial cable 3 are detachably connected.

  As described above, in the cable type antenna 1B of the present embodiment, the LCX 2 and the feeding coaxial cable 3 can be integrally connected and arranged without using the connecting coaxial cable 9 described above. Also in this case, the LCX 2 and the feeding coaxial cable 3 are integrally connected and arranged with a constant distance D between the outer conductor 8 of the LCX 2 and the outer conductor 8 of the feeding coaxial cable 3. By doing so, it is possible to reduce the transmission loss of the LCX 2 while reducing the size.

  Further, in the cable type antenna 1B of the present embodiment, since the LCX 2 and the feeding coaxial cable 3 are integrally connected and arranged, it is not necessary to separately lay the LCX 2 and the feeding coaxial cable 3; It is possible to improve workability when laying the cable type antenna 1B.

[Third Embodiment]
Next, as a third embodiment of the present invention, for example, a cable type antenna 1C shown in FIG. 5 will be described. FIG. 5 is a perspective view showing the configuration of the cable type antenna 1C. In the following description of the embodiment, the description of the same part as the cable type antenna 1A is omitted and the same reference numerals are given in the drawings.

  As shown in FIG. 5, the cable type antenna 1 </ b> C has a configuration using a plurality of connectors 20 that connect the LCX 2 and the feeding coaxial cable 3 in parallel with each other, instead of the connecting portion 4 c. The rest of the configuration is basically the same as that of the cable type antenna 1A.

  Specifically, in the cable-type antenna 1C, instead of the connecting portion 4c, a plurality of (three in this example) connections in which the LCX 2 and the feeding coaxial cable 3 are arranged at intervals in the respective extending directions. They are connected together by the tool 20 and are arranged integrally.

  The plurality of couplers 20 are connected between the LCX 2 and the feeding coaxial cable 3 in a state where a constant distance D is provided between the outer conductor 8 of the LCX 2 and the outer conductor 8 of the feeding coaxial cable 3 that are parallel to each other. They are connected.

  Each connector 20 has one gripping portion 21a for gripping the LCX 2, the other gripping portion 21b for gripping the feeding coaxial cable 3, and a connection portion 22 for connecting the gripping portions 21a and 21b. ing.

  Each connector 20 is made of, for example, a plastic material such as polyethylene, nylon, polyvinyl chloride, polyamide, or ABS (Acrylonitrile Butadiene Styrene) resin, which is a thermoplastic resin, by injection molding, cutting, or the like, and gripping portions 21a, 21b and connection. The part 22 has a configuration formed integrally.

  The gripping portions 21a and 21b have a structure (fitting structure) into which the LCX 2 or the feeding coaxial cable 3 is fitted. In addition, as a structure of the holding parts 21a and 21b, it is good also as a structure (clamp structure) which clamps by clamping the outer periphery of LCX2 or the coaxial cable 3 for electric power feeding not only in such a fitting structure.

  As described above, in the cable type antenna 1 </ b> C of the present embodiment, the LCX 2 and the feeding coaxial cable 3 can be integrally connected and arranged using the plurality of connectors 20 described above. Also in this case, the LCX 2 and the feeding coaxial cable 3 are integrally connected and arranged with a constant distance D between the outer conductor 8 of the LCX 2 and the outer conductor 8 of the feeding coaxial cable 3. By doing so, it is possible to reduce the transmission loss of the LCX 2 while reducing the size.

  Further, in the cable type antenna 1C of the present embodiment, since the LCX 2 and the feeding coaxial cable 3 are integrally connected and arranged, it is not necessary to separately lay the LCX 2 and the feeding coaxial cable 3; It is possible to improve workability when laying the cable type antenna 1C.

  Furthermore, in the cable type antenna 1 </ b> C of this embodiment, the LCX 2 and the feeding coaxial cable 3 can be laid by the work of attaching the connector 20 at the laying position and then attaching to the connector 20. Thereby, it is possible to further facilitate the installation work of the cable type antenna 1C.

  In addition, in the cable type antenna 1C of the present embodiment, the case where the connector 20 is applied to the configuration of the cable type antenna 1A is exemplified, but other than that, for example, like the cable type antenna 1D shown in FIG. It is also possible to apply the connector 20 to the configuration of the cable type antenna 1B. Moreover, about the said some connector 20, it is also possible to set it as the structure which connected the some connector 20 mutually.

[Fourth Embodiment]
Next, as a fourth embodiment of the present invention, for example, an extension cable antenna 100A shown in FIG. 7 will be described. FIG. 7 is a plan view showing the configuration of the extension cable antenna 100A. In the following description of the embodiment, the description of the same part as the cable type antenna 1A is omitted and the same reference numerals are given in the drawings.

  As shown in FIG. 7, the extension cable antenna 100A includes a tip antenna cable 101 and an extension antenna cable 102, and has a structure in which the tip antenna cable 101 and the extension antenna cable 102 are connected. Yes.

  The tip antenna cable 101 has the same configuration as the cable type antenna 1A described in the first embodiment. That is, the tip antenna cable 101 includes the LCX 2, the feeding coaxial cable 3, and the connecting coaxial cable 9. The outer conductor 8 of the LCX 2 and the outer conductor 8 of the feeding coaxial cable 3 are parallel to each other. The LCX 2 and the feeding coaxial cable 3 are integrally connected with a fixed distance D between them, and one end of the LCX 2 and the feeding coaxial cable 3 is curved. 9 have a structure connected via 9.

  On the other hand, the extension antenna cable 102 has a configuration in which the connecting coaxial cable 9 is omitted from the cable antenna 1A. That is, the extension antenna cable 101 has the LCX 2 and the feeding coaxial cable 3, and a constant distance D between the outer conductor 8 of the LCX 2 and the outer conductor 8 of the feeding coaxial cable 3 that are parallel to each other. The LCX 2 and the power feeding coaxial cable 3 are integrally connected and disposed.

  The tip antenna cable 101 and the extension antenna cable 102 have a structure in which the LCXs 2 are connected to each other and the feeding coaxial cables 3 are connected to each other. That is, the connector 10b on the other end side of the LCX 2 constituting the tip antenna cable 101 and the connector 10a on the one end side of the LCX 2 constituting the extension antenna cable 102 are detachably connected. Further, the connector 11b on the other end side of the feeding coaxial cable 3 constituting the tip antenna cable 101 and the connector 11a on one end side of the feeding coaxial cable 3 constituting the extension antenna cable 102 are detachably connected. ing.

  As described above, in the extension cable type antenna 100A of the present embodiment, the total length of the extension cable type antenna 100A can be extended by connecting the tip antenna cable 101 and the extension antenna cable 102. . Further, the total length of the extension cable type antenna 100A can be adjusted by the combination of the tip antenna cable 101 and the extension antenna cable 102.

  It can be said that the tip antenna cable 101 is configured by combining the extension antenna cable 102 and the connection coaxial cable 9. Therefore, also in the tip antenna cable 101, the total length of the extension cable type antenna 100A can be adjusted by changing the length of the extension antenna cable 102 combined with the connection coaxial cable 9.

  In the extension cable type antenna 100A of the present embodiment, the LCX 2 and the feeding coaxial cable 3 are integrated with a constant distance D maintained between the outer conductor 8 of the LCX 2 and the outer conductor 8 of the feeding coaxial cable 3. It is possible to reduce the transmission loss of the LCX 2 while reducing the size by linking and arranging.

  Further, in the extension cable type antenna 100A of the present embodiment, since the LCX 2 and the feeding coaxial cable 3 are integrally connected and arranged, it is not necessary to separately lay the LCX 2 and the feeding coaxial cable 3; It is possible to improve workability when laying the extension cable antenna 100A.

[Fifth Embodiment]
Next, for example, an extension cable antenna 100B shown in FIG. 8 will be described as a fifth embodiment of the present invention. FIG. 8 is a plan view showing the configuration of the extension cable antenna 100B. In the following description of the embodiment, the description of the same parts as those of the extension cable antenna 100A will be omitted, and the same reference numerals will be given in the drawings.

  As shown in FIG. 8, the extension cable type antenna 100B includes a tip antenna cable 101 and a plurality (two in this example) of extension antenna cables 102A and 102B (102). The tip antenna cable 101, one extension antenna cable 102A, and the other extension antenna cable 102B are arranged in a straight line in this order.

  The extension cable type antenna 100B has a structure in which the tip antenna cable 101 and the extension antenna cables 102A and 102B are connected via the first connection coaxial cable 30A and the second connection coaxial cable 30B. Have.

  Specifically, the first and second connection coaxial cables 30 </ b> A and 30 </ b> B have the same structure as the power supply coaxial cable 3 and have substantially the same outer diameter as that of the LCX 2 and the power supply coaxial cable 3. ing. The first and second connection coaxial cables 30A and 30B may be the same as the connection coaxial cable 9, that is, have an outer diameter smaller than the outer diameters of the LCX 2 and the feeding coaxial cable 3. .

  The first connecting coaxial cable 30A and the second connecting coaxial cable 30B have the same length. Connectors 31a and 31b are attached to both ends of the first and second connection coaxial cables 30A and 30B, respectively.

  The tip antenna cable 101 and one extension antenna cable 102A are connected to each other through the first connection coaxial cable 30A, and the feeding coaxial cable 3 is connected to the second connection coaxial cable 30A. It has a structure connected via a cable 30B.

  That is, the connector 10b on the other end side of the LCX 2 constituting the tip antenna cable 101 and the connector 31a on one end side of the first connection coaxial cable 30A are detachably connected. Further, the connector 11b on the other end side of the feeding coaxial cable 3 constituting the tip antenna cable 101 and the connector 31a on one end side of the second connecting coaxial cable 30B are detachably connected.

  The connector 10a on one end side of the LCX 2 constituting one extension antenna cable 102A and the connector 31b on the other end side of the first connection coaxial cable 30A are detachably connected. Further, the connector 11a on one end side of the feeding coaxial cable 3 constituting one extension antenna cable 102A and the connector 31b on the other end side of the second connecting coaxial cable 30B are detachably connected.

  Thus, the first connecting coaxial cable 30A and the second connecting coaxial cable 30B are arranged in a straight line between the tip antenna cable 101 and one extension antenna cable 102 in parallel with each other. Has been.

  Similarly, one extension antenna cable 102A and the other extension antenna cable 102B are connected to each other through the first connecting coaxial cable 30A and the feeding coaxial cable 3 is connected to the first extension coaxial cable 3A. It has the structure connected via the coaxial cable 30B for 2 connections.

  That is, the connector 10b on the other end side of the LCX 2 constituting one extension antenna cable 102A and the connector 31a on the one end side of the first connection coaxial cable 30A are detachably connected. The connector 11b on the other end side of the feeding coaxial cable 3 constituting one extension antenna cable 102A and the connector 31a on the one end side of the second connecting coaxial cable 30B are detachably connected.

  The connector 10a on one end side of the LCX 2 constituting the other extension antenna cable 102B and the connector 31b on the other end side of the first connecting coaxial cable 30A are detachably connected. Further, the connector 11a on one end side of the feeding coaxial cable 3 constituting the other extension antenna cable 102B and the connector 31b on the other end side of the second connecting coaxial cable 30B are detachably connected.

  Thus, the first connection coaxial cable 30A and the second connection coaxial cable 30B are linearly connected in parallel with each other between the one extension antenna cable 102A and the other extension antenna cable 102B. Is arranged.

  As described above, in the extension cable antenna 100B of this embodiment, the tip antenna cable 101 and the plurality of extension antenna cables 102A and 102B are connected using the first and second connection coaxial cables 30A and 30B. As a result, it is possible to extend the entire length of the extension cable type antenna 100B. Further, the total length of the extension cable type antenna 100B can be adjusted by combining the tip antenna cable 101, the plurality of extension antenna cables 102A and 102B, and the first and second connection coaxial cables 30A and 30B. is there.

  In the extension cable type antenna 100B of the present embodiment, the LCX 2 and the feeding coaxial cable 3 are integrated with a constant distance D maintained between the outer conductor 8 of the LCX 2 and the outer conductor 8 of the feeding coaxial cable 3. It is possible to reduce the transmission loss of the LCX 2 while reducing the size by linking and arranging.

  Further, in the extension cable type antenna 100B of the present embodiment, since the LCX 2 and the feeding coaxial cable 3 are integrally connected and disposed, it is not necessary to separately lay the LCX 2 and the feeding coaxial cable 3; It is possible to improve workability when laying the extension cable type antenna 100B.

[Sixth Embodiment]
Next, as a sixth embodiment of the present invention, for example, an extension cable antenna 100C shown in FIG. 9 will be described. FIG. 9 is a plan view showing the configuration of the extension cable antenna 100C. In the following description of the embodiment, the description of the same parts as those of the extension cable antenna 100A will be omitted, and the same reference numerals will be given in the drawings.

  As shown in FIG. 9, the extension cable type antenna 100C includes a tip antenna cable 101 and a plurality (two in this example) of extension antenna cables 102A and 102B (102). The tip antenna cable 101, one extension antenna cable 102A, and the other extension antenna cable 102B are arranged in this order. The tip antenna cable 101 and the one extension antenna cable 102A are arranged so as to be substantially perpendicular to each other. One extension antenna cable 102A and the other extension antenna cable 102A are arranged so as to be substantially perpendicular to each other. Furthermore, the tip antenna cable 101 and the other extension antenna cable 102A are arranged so as to be substantially parallel to each other. Thereby, the extension cable type antenna 100C is disposed so as to have a U-shape as a whole.

  In the extension cable type antenna 100C, the distal end antenna cable 101 and the extension antenna cables 102A and 102B are connected via the curved first connecting coaxial cable 30C and second connecting coaxial cable 30D. It has a structure.

  Specifically, the first and second connection coaxial cables 30 </ b> C and 30 </ b> D are flexible or curved coaxial cables similar to the connection coaxial cable 9, and are the same as the power supply coaxial cable 3 described above. It has a structure and has an outer diameter smaller than the outer diameters of the LCX 2 and the feeding coaxial cable 3. Connectors 31a and 31b are attached to both ends of the first and second connection coaxial cables 30C and 30D, respectively.

  The tip antenna cable 101 and the one extension antenna cable 102A are connected to each other through the first connecting coaxial cable 30C and the feeding coaxial cable 3 is connected to the second connecting coaxial cable 30C. It has a structure connected via a cable 30D.

  That is, the connector 10b on the other end side of the LCX 2 constituting the tip antenna cable 101 and the connector 31a on one end side of the first connection coaxial cable 30C are detachably connected. Further, the connector 11b on the other end side of the feeding coaxial cable 3 constituting the tip antenna cable 101 and the connector 31a on one end side of the second connecting coaxial cable 30D are detachably connected.

  The connector 10a on one end side of the LCX 2 constituting one extension antenna cable 102A and the connector 31b on the other end side of the first connecting coaxial cable 30C are detachably connected. Further, the connector 11a on one end side of the feeding coaxial cable 3 constituting one extension antenna cable 102A and the connector 31b on the other end side of the second connecting coaxial cable 30D are detachably connected.

  Further, the first connection coaxial cable 30C for connecting the LCX2 side in accordance with the arrangement of the tip antenna cable 101 and the one extension antenna cable 102A is the second connection for connecting the power supply coaxial cable 3 side. The cable is longer than the coaxial cable 30D and has a large bending radius. As a result, the first connecting coaxial cable 30C and the second connecting coaxial cable 30B are approximately parallel to each other in a state where they are parallel to each other between the tip antenna cable 101 and one extension antenna cable 102A. It is curved and arranged in an L shape.

  Similarly, one extension antenna cable 102A and the other extension antenna cable 102B are connected to each other through the first connection coaxial cable 30C, and to each other. It has the structure connected via the coaxial cable 30D for 2 connections.

  That is, the connector 10b on the other end side of the LCX 2 constituting one extension antenna cable 102A and the connector 31a on the one end side of the first connection coaxial cable 30C are detachably connected. Further, the connector 11b on the other end side of the feeding coaxial cable 3 constituting one extension antenna cable 102A and the connector 31a on one end side of the second connecting coaxial cable 30D are detachably connected.

  The connector 10a on one end side of the LCX 2 constituting the other extension antenna cable 102B and the connector 31b on the other end side of the first connection coaxial cable 30C are detachably connected. Further, the connector 11a on one end side of the feeding coaxial cable 3 constituting the other extension antenna cable 102B and the connector 31b on the other end side of the second connecting coaxial cable 30D are detachably connected.

  The first connection coaxial cable 30C for connecting the LCX2 side in accordance with the arrangement of the one extension antenna cable 102A and the other extension antenna cable 102B is a second connection for connecting the power supply coaxial cable 3 side. This is longer than the connecting coaxial cable 30D and has a large bending radius. Thus, the first connection coaxial cable 30C and the second connection coaxial cable 30B are in the same direction in a state where they are parallel to each other between the one extension antenna cable 102A and the other extension antenna cable 102B. Are curved in a substantially L shape.

  As described above, in the extension cable antenna 100C of this embodiment, the tip antenna cable 101 and the plurality of extension antenna cables 102A and 102B are connected using the first and second connection coaxial cables 30C and 30D. Thus, it is possible to extend the entire length of the extension cable type antenna 100C. Further, the total length of the extension cable type antenna 100C can be adjusted by a combination of the tip antenna cable 101, the extension antenna cables 102A and 102B, and the first and second connection coaxial cables 30C and 30D. Further, by using the first and second connection coaxial cables 30C and 30D in a curved state, the distal end antenna cable 101 and the extension antenna cables 102A and 102B can be matched to the arrangement of the distal end antenna cables 101 and 102B. It is possible to connect between a plurality of extension antenna cables 102A and 102B.

  In the extension cable type antenna 100C of the present embodiment, the LCX 2 and the feeding coaxial cable 3 are integrated with a constant distance D maintained between the outer conductor 8 of the LCX 2 and the outer conductor 8 of the feeding coaxial cable 3. It is possible to reduce the transmission loss of the LCX 2 while reducing the size by linking and arranging.

  Further, in the extension cable type antenna 100C of the present embodiment, since the LCX 2 and the feeding coaxial cable 3 are integrally connected and arranged, it is not necessary to separately lay the LCX 2 and the feeding coaxial cable 3; It is possible to improve workability when laying the extension cable antenna 100C.

  In the extension cable type antennas 100A to 100C shown in the fourth to sixth embodiments, the cable antenna 1A is used as the tip antenna cable 101. A similar configuration can be realized by using the type antenna 1B.

  In the extension cable antenna to which the present invention is applied, the number of extension antenna cables 102 connected to one tip antenna cable 101 is not particularly limited. Depending on the bending position or the like, the number and length of the extension antenna cables 102 connected to the tip antenna cable 101 are appropriately changed, or the first connection coaxial cables 30A and 30C and the first connection coaxial cables 30A and 30C are connected. Two connecting coaxial cables 30B and 30D can be added as appropriate.

  The extension cable antennas 100B and 100C are flexible or curved, and the first connection coaxial cables 30A and 30C and the second connection coaxial cables 30B and 30D are used. For example, when laying along the floor surface, wall surface, top surface, etc. of a building, the corner portion located at the boundary of each surface is used for the first connection. The extension cable antennas 100B and 100C can be three-dimensionally laid in a state where the coaxial cables 30A and 30C and the second connection coaxial cables 30B and 30D are bent in the same direction. For example, when the extension cable type antenna 100B is laid three-dimensionally between the wall surface and the top surface, the first connection coaxial cable 30A and the second connection coaxial cable are formed at the corner portion between the wall surface and the top surface. While the cable 30B is bent in the same direction, the extension antenna cable 102B can be laid on the wall surface, and the extension antenna cable 100A and the tip antenna cable 101 can be laid on the top surface.

(Composite cable type antenna)
[Seventh Embodiment]
Next, as a seventh embodiment of the present invention, for example, a composite cable antenna 200A shown in FIG. 10 will be described. FIG. 10 is a perspective view showing the configuration of the composite cable type antenna 200A. In the following description of the embodiment, the description of the same part as the cable type antenna 1A is omitted and the same reference numerals are given in the drawings.

  As shown in FIG. 10, the composite cable type antenna 200A has a configuration in which a plurality (two in this example) of cable type antennas 1A are arranged in the same plane. The two cable-type antennas 1A are arranged symmetrically across the butted boundary surface in a state where the feeding coaxial cables 3 are butted in parallel. Therefore, the boundary surface where the two cable-type antennas 1A are abutted is substantially orthogonal to the surface on which the two cable-type antennas 1A are arranged.

  As described above, the composite cable type antenna 200A of the present embodiment can be configured to combine the two cable type antennas 1A. In the composite cable type antenna 200A, even when the two cable type antennas 1A are combined, the constant distance D is maintained between the outer conductor 8 of the LCX 2 and the outer conductor 8 of the feeding coaxial cable 3. In addition, the LCX 2 and the feeding coaxial cable 3 can be connected together to be compact, and the transmission loss of the LCX 2 can be kept low.

  Further, in the composite cable type antenna 200A of the present embodiment, even when the two cable type antennas 1A are combined, there is no need to separately lay the LCX 2 and the feeding coaxial cable 3, so that the composite cable type antenna 200A is provided. It is possible to improve workability when laying.

  In addition, in the composite cable type antenna 200A of the present embodiment, the two cable type antennas 1A are arranged side by side. However, the two cable type antennas 1A may be integrated on the boundary surface where they are abutted. .

[Eighth Embodiment]
Next, as an eighth embodiment of the present invention, for example, a composite cable type antenna 200B shown in FIG. 11 will be described. FIG. 11 is a perspective view showing the configuration of the composite cable type antenna 200B. In the following description of the embodiment, the description of the same parts as those of the composite cable antenna 200A will be omitted and the same reference numerals will be given in the drawings.

  In the composite cable type antenna 200B, as shown in FIG. 11, the boundary surface where the two cable type antennas 1A are abutted is substantially parallel to the surface on which the two cable type antennas 1A are arranged. Other than that, it has the same configuration as the composite cable type antenna 200A.

  As described above, the composite cable type antenna 200B of the present embodiment can have a configuration in which two cable type antennas 1A are combined. In the composite cable type antenna 200B, even when the two cable type antennas 1A are combined, the constant distance D is maintained between the outer conductor 8 of the LCX 2 and the outer conductor 8 of the feeding coaxial cable 3. In addition, the LCX 2 and the feeding coaxial cable 3 can be connected together to be compact, and the transmission loss of the LCX 2 can be kept low.

  Further, in the composite cable type antenna 200B of the present embodiment, even when the two cable type antennas 1A are combined, it is not necessary to separately lay the LCX 2 and the feeding coaxial cable 3, so that the composite cable type antenna 200B is provided. It is possible to improve workability when laying.

  In addition, in the composite cable type antenna 200B of the present embodiment, the two cable type antennas 1A are arranged side by side. However, the two cable type antennas 1A may be integrated at the boundary where they are abutted.

[Ninth Embodiment]
Next, as a ninth embodiment of the present invention, for example, a composite cable type antenna 200C shown in FIG. 12 will be described. FIG. 12 is a perspective view showing the configuration of the composite cable type antenna 200C. In the following description of the embodiment, the description of the same part as the cable type antenna 1A is omitted and the same reference numerals are given in the drawings.

  The composite cable type antenna 200C has a configuration in which two cable type antennas 1A are arranged in the same plane as shown in FIG. 12, but the LCX2 side sheath 4a constituting one cable type antenna 1A and the other The sheath 4a on the LCX2 side that constitutes the cable type antenna 1A is connected via a connecting portion 4d. Further, the sheath 4a on the LCX2 side constituting the other cable type antenna 1A and the sheath 4b on the feeding coaxial cable 3 side constituting the other cable type antenna 1A are connected via a connecting portion 4c. Furthermore, the feeding coaxial cable 3 constituting one cable type antenna 1A and the feeding coaxial cable 3 constituting the other cable type antenna 1A are abutted in parallel.

  Further, the connection coaxial cable 9 that connects one end side in the same direction of the LCX 2 and the feeding coaxial cable 3 constituting one cable type antenna 1A is composed of the LCX 2 and the feeding coaxial cable 3 constituting the other cable type antenna 1A. These are longer than the connecting coaxial cable 9 that connects one end side in the same direction, and have a larger bending radius.

  As described above, the composite cable type antenna 200C of the present embodiment can be configured by combining the two cable type antennas 1A. In this composite cable type antenna 200C, even when two cable type antennas 1A are combined, the external conductor 8 of the LCX 2 constituting one cable type antenna 1A and the outside of the LCX 2 constituting the other cable type antenna 1A It is possible to reduce the transmission loss of the LCX 2 while reducing the size of the LCX 2 while keeping the constant distance D between the conductor 8 and the LCX 2 and the coaxial cable 3 for feeding together. is there. Further, the LCX 2 and the feeding coaxial cable 3 are integrated with a constant distance D between the outer conductor 8 of the LCX 2 and the outer conductor 8 of the feeding coaxial cable 3 constituting the other cable type antenna 1A. It is possible to reduce the transmission loss of the LCX 2 while reducing the size by linking and arranging.

  Further, in the composite cable type antenna 200C of the present embodiment, even when the two cable type antennas 1A are combined, it is not necessary to separately lay the LCX 2 and the feeding coaxial cable 3, so that the composite cable type antenna 200B is provided. It is possible to improve workability when laying.

  The composite cable antennas 200A to 200C shown in the seventh to ninth embodiments are configured using the cable antenna 1A, but the composite cable antennas 200A to 200C using the cable antenna 1B. It is also possible to realize a configuration similar to the above.

[Tenth embodiment]
Next, as a tenth embodiment of the present invention, for example, a composite cable type antenna 400A shown in FIG. 13 will be described. FIG. 13 is a plan view showing the configuration of the composite cable type antenna 400A. In the following description of the embodiment, the description of the same part as the cable type antenna 1A is omitted and the same reference numerals are given in the drawings.

  As shown in FIG. 13, the composite cable type antenna 400A has a configuration in which two cable type antennas 1A are combined. The two cable-type antennas 1A are arranged in a straight line in the same plane.

  A curved first connecting coaxial cable 50A is connected to the end of the feeding coaxial cable 3 constituting one of the cable antennas 1A (right side in FIG. 13). That is, the connector 11b on the other end side of the feeding coaxial cable 3 constituting one cable type antenna 1A and the connector 51a on the one end side of the first connecting coaxial cable 50A are detachably connected.

  Similarly, a second connecting coaxial cable 50B in a curved state is connected to the end of the feeding coaxial cable 3 constituting the other (left side in FIG. 13) cable-type antenna. That is, the connector 11b on the other end side of the feeding coaxial cable 3 constituting the other cable type antenna 1A and the connector 51a on the one end side of the second connecting coaxial cable 50B are detachably connected.

  The end portion of the LCX 2 constituting the cable type antenna 1A on one side (right side in FIG. 13) and the end portion of the LCX 2 constituting the cable type antenna 1A on the other side (left side in FIG. 13) are linear thirds. Are connected via a connecting coaxial cable 50C. That is, the connector 10b on the other end side of the LCX 2 constituting one cable type antenna 1A and the connector 51b on the other end side of the third connection coaxial cable 50C are detachably connected, and the other cable type antenna 1A is connected. The connector 10b on the other end side of the LCX 2 and the connector 51a on the one end side of the third connection coaxial cable 50C are detachably connected.

  The third connection coaxial cable 50C is a flexible cable having an outer diameter smaller than the outer diameters of the LCX 2 and the feeding coaxial cable 3 as in the first and second connection coaxial cables 50A and 50B. Alternatively, a curved coaxial cable can be used. Further, similarly to the first and second connection coaxial cables 30A and 30B, it is also possible to use a linear coaxial cable having substantially the same outer diameter as that of the LCX 2 and the feeding coaxial cable 3.

  The first connection coaxial cable 50A and the second connection coaxial cable 50B are opposite to each other in the vicinity of the center of the third connection coaxial cable 50C, and the third connection coaxial cable from that position. It is curved in a substantially L shape in a direction away from the cable 50C. Thereby, the connector 51b on the other end side of the first connection coaxial cable 50A and the connector 51b on the other end side of the second connection coaxial cable 50B face each other in the same direction.

  In the composite cable type antenna 400A having the above-described configuration, the two cable type antennas 1A are combined in two directions (left and right directions in FIG. 13) by combining the two cable type antennas 1A. Is possible.

  As described above, in the composite cable type antenna 400A of the present embodiment, even when the two cable type antennas 1A are combined, a constant distance is provided between the outer conductor 8 of the LCX 2 and the outer conductor 8 of the feeding coaxial cable 3. In a state where D is held, the LCX 2 and the feeding coaxial cable 3 are integrally connected and arranged, so that the size can be reduced and the transmission loss of the LCX 2 can be kept low.

  Further, in the composite cable type antenna 400A of the present embodiment, even when the two cable type antennas 1A are combined, it is not necessary to separately lay the LCX 2 and the feeding coaxial cable 3, so that the composite cable type antenna 400A is provided. It is possible to improve workability when laying.

  Note that the composite cable type antenna 400A of the present embodiment has a configuration in which two cable type antennas 1A arranged in a straight line in the same plane are combined. By changing the bending angle of the three connecting coaxial cables 50A to 50C, the opening angle of these two cable type antennas 1A can be arbitrarily changed.

[Eleventh embodiment]
Next, as an eleventh embodiment of the present invention, for example, a composite cable type antenna 400B shown in FIG. 14 will be described. FIG. 14 is a plan view showing the configuration of the composite cable type antenna 400B. In the following description of the embodiment, the description of the same parts as those of the composite cable type antenna 400A will be omitted and the same reference numerals will be given in the drawings.

  As shown in FIG. 14, the composite cable type antenna 400B has a configuration in which three cable type antennas 1A are combined, that is, the third connection to the two cable type antennas 1A included in the composite cable type antenna 400A. Instead of the coaxial cable for use 50C, a third cable type antenna 1A is further combined. The rest of the configuration is basically the same as that of the composite cable type antenna 400A.

  Specifically, the third (upper side in FIG. 14) cable-type antenna 1A is in the same plane as the two linear (right and left in FIG. 14) cable-type antennas 1A. It is arranged at a right angle.

  One end (right side in FIG. 14) of the LCX2 constituting the cable type antenna 1A and the end of the third (upper side in FIG. 14) LCX2 constituting the cable type antenna 1A are curved. The second connection coaxial cable 50B is connected. That is, the connector 10b on the other end side of the LCX 2 constituting one cable type antenna 1A and the connector 51a on the one end side of the second connection coaxial cable 50B are detachably connected, and the third cable type antenna is connected. The connector 10b on the other end side of the LCX 2 constituting 1A and the connector 51b on the other end side of the second connection coaxial cable 50B are detachably connected.

  Similarly, the end of LCX 2 constituting the other (left side in FIG. 14) cable-type antenna 1A and the end of feeding coaxial cable 3 constituting the third (upper side in FIG. 14) cable-type antenna 1A. Are connected via a first connecting coaxial cable 50A in a curved state. That is, the connector 10b on the other end side of the LCX 2 constituting the other cable type antenna 1A and the connector 51a on the one end side of the first connection coaxial cable 50A are detachably connected, and the third cable type antenna. A connector 11b on the other end side of the feeding coaxial cable 3 constituting 1A and a connector 51b on the other end side of the first connecting coaxial cable 50A are detachably connected.

  In the composite cable type antenna 400B having the above-described configuration, the three cable type antennas 1A can be arranged in three directions by combining the three cable type antennas 1A.

  As described above, in the composite cable type antenna 400B of the present embodiment, even when the three cable type antennas 1A are combined, a constant distance is provided between the outer conductor 8 of the LCX 2 and the outer conductor 8 of the feeding coaxial cable 3. In a state where D is held, the LCX 2 and the feeding coaxial cable 3 are integrally connected and arranged, so that the size can be reduced and the transmission loss of the LCX 2 can be kept low.

  Further, in the composite cable type antenna 400B of the present embodiment, even when the three cable type antennas 1A are combined, there is no need to separately lay the LCX 2 and the feeding coaxial cable 3, so that the composite cable type antenna 400B is provided. It is possible to improve workability when laying.

  Note that the composite cable type antenna 400B of the present embodiment changes these three cable type antennas by changing the bending angles of the first and second connection coaxial cables 50A and 50B connecting the three cable type antennas 1A. It is possible to arbitrarily change the opening angle between 1A.

[Twelfth embodiment]
Next, as a sixteenth embodiment of the present invention, for example, a composite cable type antenna 400C shown in FIG. 15 will be described. FIG. 15 is a plan view showing the configuration of the composite cable type antenna 400C. In the following description of the embodiment, the description of the same parts as those of the composite cable type antenna 400B will be omitted, and the same reference numerals will be given in the drawings.

  As shown in FIG. 15, the composite cable type antenna 400C has a configuration in which the composite cable type antenna 400C is arranged in four directions by adding an extension antenna cable 102 to the configuration of the composite cable type antenna 400B. is there. The rest of the configuration is basically the same as that of the composite cable type antenna 400B.

  Specifically, the extension antenna cable 102 has a third (upper side in FIG. 15) cable-type antenna 1A across two (right and left) cable-type antennas 1A arranged in a straight line. It is located on the opposite side (lower side in FIG. 15), and is arranged in a straight line in the same plane as the third cable type antenna 1A.

  The end of the feeding coaxial cable 3 constituting one cable-type antenna 1A (on the right side in FIG. 15) and the one end of the LCX 2 constituting the extending antenna cable 102 are curved in the second connecting coaxial. It is connected via a cable 50B. That is, the connector 11b on the other end side of the feeding coaxial cable 3 constituting one cable-type antenna 1A and the connector 51a on the one end side of the second connecting coaxial cable 50B are detachably connected, and the extension antenna is connected. The connector 10a on one end side of the LCX 2 constituting the cable 102 and the connector 51b on the other end side of the second connection coaxial cable 50B are detachably connected.

  Similarly, the end of the feeding coaxial cable 3 constituting the other (left side in FIG. 15) cable-type antenna 1A and the one end of the feeding coaxial cable 3 constituting the extension antenna cable 102 are curved. The first connection coaxial cable 50A is connected. That is, the connector 11b on the other end side of the feeding coaxial cable 3 constituting the other cable type antenna 1A and the connector 51a on the one end side of the first connecting coaxial cable 50A are detachably connected to each other, and the extension antenna is connected. A connector 10a on one end side of the feeding coaxial cable 3 constituting the cable 102 and a connector 51b on the other end side of the first connecting coaxial cable 50A are detachably connected.

  Further, a straight first connecting coaxial cable 50A is connected to the other end of the LCX 2 constituting the extension antenna cable 102. That is, the connector 11b on the other end side of the LCX 2 constituting the extension antenna cable 102 and the connector 51a on one end side of the first connection coaxial cable 50A are detachably connected.

  Similarly, a linear second connection coaxial cable 50 </ b> B is connected to an end of the power supply coaxial cable 3 constituting the extension antenna cable 102. That is, the connector 11b on the other end side of the feeding coaxial cable 3 constituting the extension antenna cable 102 and the connector 51a on the one end side of the second connecting coaxial cable 50B are detachably connected.

  The composite cable type antenna 400C having the above-described configuration has a configuration in which the composite cable type antenna 400C is arranged in four directions by adding the extension antenna cable 102 to the configuration of the composite cable type antenna 400B. It is possible.

  As described above, in the composite cable type antenna 400C of the present embodiment, even when the three cable type antennas 1A and the extension antenna cable 102 are combined, the outer conductor 8 of the LCX 2 and the outer conductor 8 of the feeding coaxial cable 3 In addition, the LCX 2 and the feeding coaxial cable 3 can be connected and integrated together while maintaining a constant distance D between them, and the transmission loss of the LCX 2 can be kept low.

  Further, in the composite cable type antenna 400C of the present embodiment, even when the three cable type antennas 1A and the extension antenna cable 102 are combined, it is not necessary to separately lay the LCX 2 and the feeding coaxial cable 3, so this It is possible to improve workability when laying the composite cable type antenna 400C.

  Note that the composite cable type antenna 400C of the present embodiment changes the bending angle of the first and second connection coaxial cables 50A and 50B that connect the three cable type antennas 1A and the extension antenna cable 102. The opening angle between each of the three cable type antennas 1A and the extension antenna cable 102 can be arbitrarily changed.

  The composite cable antennas 400A to 400C shown in the tenth to twelfth embodiments have a configuration in which a plurality of cable antennas 1A are combined. It is also possible to realize the configuration.

  Moreover, the composite cable type antenna to which the present invention is applied is not limited to the configuration in which the plurality of cable type antennas 1A and 1B described above are combined, but may be configured in a combination of a plurality of extension cable type antennas. That is, the composite cable type antennas 400A to 400C can be extended by connecting the extension antenna cable 102 to the cable type antenna 1A (1B) constituting the tip antenna cable 101.

  In this case, the number of extension antenna cables 102 connected to one tip antenna cable 101 is not particularly limited, and it depends on the route, distance, bending angle, etc. to be laid. The number and length of the extension antenna cables 102 connected to the cable 101 are changed as appropriate, or the first connection coaxial cables 30A and 30C and the second connection coaxial cables 30B and 30D are added as appropriate. It is possible to do.

  Further, the composite cable type antennas 400A to 400C are flexible or curved, and the first to third connection coaxial cables 50A to 50C are used. Not only when laying, but when laying along the floor surface, wall surface, top surface, etc. of a building, for example, the first to third coaxial cables for connection 50A to 50C at the corners located at the boundaries of each surface. It is also possible to lay the composite cable type antennas 400A to 400C three-dimensionally in a state where the antennas are bent in the same direction. For example, in the case where the composite cable type antenna 400A is three-dimensionally laid between the wall surface and the top surface, the first or second connection coaxial cable 50A (50B) It is also possible to lay one cable-type antenna 1A on the wall surface and lay the other cable-type antenna 1A on the top surface while bending the third connecting coaxial cable 50C in the same direction.

(Wireless communication device)
[Thirteenth embodiment]
Next, for example, a wireless communication apparatus 300A illustrated in FIG. 16 will be described as a thirteenth embodiment of the present invention. FIG. 16 is a plan view showing the configuration of the wireless communication device 300A.

  As shown in FIG. 16, the wireless communication device 300A includes the cable-type antenna 1A of the first embodiment and an access point (AP) 301 connected to the cable-type antenna 1A. The AP 301 is electrically connected to an upper line (not shown) of the wireless LAN.

  The cable antenna 1A and the AP 301 are connected via a first connection coaxial cable 50A and a second connection coaxial cable 50B. That is, in this wireless communication device 300A, the connector 10b on the other end side of the LCX 2 constituting the cable type antenna 1A and the connector 51a on the one end side of the first connection coaxial cable 50A are detachably connected to each other. The connector 51b on the other end side of the connecting coaxial cable 50A is detachably connected to the AP 301. Further, the connector 11b on the other end side of the feeding coaxial cable 3 constituting the cable-type antenna 1A and the connector 51a on the one end side of the second connection coaxial cable 50B are detachably connected to each other for the second connection. A connector 51b on the other end side of the coaxial cable 50B is detachably connected to the AP 301.

  The first connection coaxial cable 50A and the second connection coaxial cable 50B are flexible or curved coaxial cables similar to the first and second connection coaxial cables 30C and 30D. Can be used.

  In wireless communication apparatus 300A having the above-described configuration, cable-type antenna 1A functions as a 2 × 2 MIMO communication antenna that simultaneously transmits and receives different signals S1 and S2. That is, in this wireless communication apparatus 300A, one signal S1 from the AP 301 is sent to the second connecting coaxial cable 50B, the feeding coaxial cable 3, and the connecting coaxial cable from one end of the LCX 2 constituting the cable antenna 1A. Power is supplied through 9. At the same time, the other signal S2 is fed from the AP 301 via the first connection coaxial cable 50A to the other end of the LCX 2 constituting the cable antenna 1A.

  Thereby, different signals S1, S2 can be transmitted simultaneously from the cable-type antenna 1A. Conversely, different signals S1 and S2 can be simultaneously received by the cable type antenna 1A. The directivity of the signals S1 and S2 by the cable type antenna 1A varies depending on the directions of the signals S1 and S2 input / output to / from the LCX2.

  As described above, in the wireless communication device 300A of the present embodiment, it is possible to construct a 2 × 2 MIMO wireless communication device using the cable type antenna 1A. Note that, in the wireless communication device 300A of the present embodiment, a 2 × 2 MIMO wireless communication device can be constructed in the same manner when the cable antennas 1B to 1D are used instead of the cable antenna 1A. .

[Fourteenth embodiment]
Next, as a fourteenth embodiment of the present invention, for example, a wireless communication device 300B illustrated in FIG. 17 will be described. FIG. 17 is a plan view showing the configuration of the wireless communication device 300B. Further, in the following description of the embodiment, portions equivalent to those of the wireless communication device 300A are not described and are denoted by the same reference numerals in the drawings.

  As shown in FIG. 17, the wireless communication device 300B includes the extension cable antenna 100B of the fifth embodiment and an AP 301 connected to the extension cable antenna 100B. The extension cable antenna 100B and the AP 301 are connected to each other via the first connection coaxial cable 50A and the second connection coaxial cable 50B.

  That is, in the wireless communication device 300B, the connector 10b on the other end side of the LCX 2 constituting the other extension antenna cable 102B and the connector 51a on the one end side of the first connection coaxial cable 50A are detachably connected. The connector 51b on the other end side of the first connection coaxial cable 50A is detachably connected to the AP 301. Further, the connector 11b on the other end side of the feeding coaxial cable 3 constituting the other extension antenna cable 102B and the connector 51a on the one end side of the second connecting coaxial cable 50B are detachably connected, and the second The connector 51b on the other end side of the connection coaxial cable 50B is detachably connected to the AP 301.

  In wireless communication apparatus 300B having the above-described configuration, extension cable antenna 100B functions as a 2 × 2 MIMO communication antenna that simultaneously transmits and receives different signals S1 and S2. That is, in the wireless communication device 300B, one signal S1 from the AP 301 is sent to the second connection coaxial cable 50B, each feeding coaxial cable 3, each of the LCXs 2 constituting the extension cable antenna 100B. Power is supplied through the second connecting coaxial cable 30 </ b> B and the connecting coaxial cable 9. At the same time, the other signal S2 is fed from the AP 301 to the other end side of each LCX 2 constituting the extension cable type antenna 100B via the first connection coaxial cable 50A and each first connection coaxial cable 30A. .

  Thereby, different signals S1 and S2 can be simultaneously transmitted from the extension cable type antenna 100B. Conversely, different signals S1 and S2 can be simultaneously received by the extension cable antenna 100B. The directivity of the signals S1 and S2 by the extension cable antenna 100B varies depending on the directions of the signals S1 and S2 input / output to / from each LCX2.

  As described above, in the wireless communication device 300B of the present embodiment, it is possible to construct a 2 × 2 MIMO wireless communication device using the extension cable antenna 100B. In the wireless communication apparatus 300B of the present embodiment, a 2 × 2 MIMO wireless communication apparatus can be constructed in the same manner when the extended cable antenna 100A is used instead of the extended cable antenna 100B. .

[Fifteenth embodiment]
Next, for example, a wireless communication apparatus 300C illustrated in FIG. 18 will be described as a fifteenth embodiment of the present invention. FIG. 18 is a plan view showing the configuration of the wireless communication device 300C. Further, in the following description of the embodiment, portions equivalent to those of the wireless communication device 300A are not described and are denoted by the same reference numerals in the drawings.

  As shown in FIG. 18, the wireless communication device 300C includes the extension cable antenna 100C of the sixth embodiment and an AP 301 connected to the extension cable antenna 100C. The extension cable antenna 100C and the AP 301 are connected via the first connection coaxial cable 50A and the second connection coaxial cable 50B.

  That is, in the wireless communication device 300C, the connector 10b on the other end side of the LCX 2 constituting the other extension antenna cable 102B and the connector 51a on the one end side of the first connection coaxial cable 50A are detachably connected. The connector 51b on the other end side of the first connection coaxial cable 50A is detachably connected to the AP 301. Further, the connector 11b on the other end side of the feeding coaxial cable 3 constituting the other extension antenna cable 102B and the connector 51a on the one end side of the second connecting coaxial cable 50B are detachably connected, and the second The connector 51b on the other end side of the connection coaxial cable 50B is detachably connected to the AP 301.

  In wireless communication apparatus 300C having the above-described configuration, extension cable antenna 100C functions as a 2 × 2 MIMO communication antenna that simultaneously transmits and receives different signals S1 and S2. That is, in this wireless communication device 300C, one signal S1 from the AP 301 is sent to the second connection coaxial cable 50B, each feeding coaxial cable 3, each one of the LCXs 2 constituting the extension cable antenna 100C. Power is supplied through the second connecting coaxial cable 30 </ b> B and the connecting coaxial cable 9. At the same time, the other signal S2 is fed from the AP 301 via the first connection coaxial cable 50A and the first connection coaxial cable 30A to the other end side of each LCX2 constituting the extension cable antenna 100C. .

  Thereby, different signals S1 and S2 can be transmitted simultaneously from the extension cable type antenna 100C. Conversely, different signals S1 and S2 can be simultaneously received by the extension cable antenna 100C. The directivity of the signals S1 and S2 by the extension cable antenna 100C varies depending on the directions of the signals S1 and S2 input / output to / from each LCX2.

  In addition, when the wireless communication device 300C according to the present embodiment is disposed in a passage W such as a corridor having two corners as shown in FIG. It is possible to efficiently arrange the wireless communication area inside.

  As described above, in the wireless communication device 300C of the present embodiment, it is possible to construct a 2 × 2 MIMO wireless communication device using the extension cable antenna 100C.

[Sixteenth Embodiment]
Next, for example, a wireless communication device 300D illustrated in FIG. 19 will be described as a sixteenth embodiment of the present invention. FIG. 19 is a plan view showing the configuration of the wireless communication device 300D. Further, in the following description of the embodiment, portions equivalent to those of the wireless communication device 300A are not described and are denoted by the same reference numerals in the drawings.

  As illustrated in FIG. 19, the wireless communication device 300D includes the composite cable antenna 200A of the seventh embodiment and an AP 301 connected to the composite cable antenna 200A. The composite cable antenna 200A and the AP 301 are connected via a first connection coaxial cable 50A and a second connection coaxial cable 50B.

  That is, in this wireless communication device 300D, the connector 10b on the other end side of the LCX 2 constituting one cable type antenna 1A and the connector 51a on one end side of the first connection coaxial cable 50A are detachably connected, The connector 51b on the other end side of the first connecting coaxial cable 50A is detachably connected to the AP 301. Further, the connector 11b on the other end side of the feeding coaxial cable 3 constituting one cable type antenna 1A and the connector 51a on the one end side of the second connecting coaxial cable 50B are detachably connected to each other. A connector 51b on the other end side of the connection coaxial cable 50B is detachably connected to the AP 301.

  Similarly, the connector 10b on the other end side of the LCX 2 constituting the other cable type antenna 1A and the connector 51a on the one end side of the first connection coaxial cable 50A are detachably connected, and the first connection coaxial A connector 51b on the other end side of the cable 50A is detachably connected to the AP 301. Further, the connector 11b on the other end side of the feeding coaxial cable 3 constituting the other cable type antenna 1A and the connector 51a on the one end side of the second connecting coaxial cable 50B are detachably connected to each other. A connector 51b on the other end side of the connection coaxial cable 50B is detachably connected to the AP 301.

  In wireless communication apparatus 300D having the above-described configuration, composite cable antenna 200A functions as a 4 × 4 MIMO communication antenna that simultaneously transmits and receives different signals S1, S2, S3, and S4.

  That is, in this wireless communication device 300D, one signal S1, S3 from the AP 301 is sent to the second connection coaxial cable 50B and each feed coaxial cable 3 to one end side of each LCX 2 constituting the composite cable antenna 200A. Then, power is supplied through each second connecting coaxial cable 30B and connecting coaxial cable 9. At the same time, the other signals S2 and S4 from the AP 301 are passed through the first connection coaxial cable 50A and the first connection coaxial cables 30A to the other end side of each LCX 2 constituting the composite cable antenna 200A. Supply power.

  Thereby, different signals S1 to S4 can be simultaneously transmitted from the composite cable antenna 200A. Conversely, different signals S1 to S4 can be simultaneously received by the composite cable antenna 200A. The directivity of the signals S1 to S4 by the composite cable antenna 200A differs depending on the directions of the signals S1 to S4 input / output to / from each LCX2.

  As described above, in the wireless communication device 300C of this embodiment, it is possible to construct a 4 × 4 MIMO wireless communication device using the composite cable antenna 200A. In the wireless communication device 300B of the present embodiment, a 4 × 4 MIMO wireless communication device can be constructed in the same manner when the composite cable antennas 200B and 200C are used instead of the composite cable antenna 200A. It is.

[Other Embodiments]
The wireless communication devices using the composite cable type antennas 400A to 400C shown in the tenth to twelfth embodiments are the same as the wireless communication devices 300A to 300D shown in the thirteenth to sixteenth embodiments, although not shown. In addition, it is possible to construct a 2 × 2 MIMO wireless communication apparatus using the composite cable type antennas 400A to 400C.

  Specifically, the composite cable antenna 400A shown in the tenth embodiment is connected to the AP 301 (not shown) via the first connection coaxial cable 50A and the second connection coaxial cable 50B. It is possible. In the wireless communication apparatus including the composite cable type antenna 400A, the composite cable type antenna 400A functions as a 2 × 2 MIMO communication antenna that transmits and receives different signals S1 and S2 simultaneously. That is, in this wireless communication apparatus, different signals S1, S2 can be transmitted simultaneously from the composite cable type antenna 400A. Conversely, different signals S1 and S2 can be simultaneously received by the composite cable antenna 400A.

  On the other hand, the composite cable type antenna 400B shown in the eleventh embodiment includes a first connection coaxial cable 50A connected to the feeding coaxial cable 3 constituting one cable type antenna 1A, and the other cable type antenna. It is possible to connect to the AP 301 (not shown) through a second connecting coaxial cable 50B connected to the feeding coaxial cable 3 constituting 1A. In the wireless communication apparatus including the composite cable type antenna 400B, the composite cable type antenna 400B functions as a 2 × 2 MIMO communication antenna that transmits and receives different signals S1 and S2 simultaneously. That is, in this wireless communication apparatus, different signals S1, S2 can be transmitted simultaneously from the composite cable type antenna 400B. Conversely, different signals S1 and S2 can be simultaneously received by the composite cable type antenna 400B.

  On the other hand, the composite cable type antenna 400C shown in the twelfth embodiment includes a first connection coaxial cable 50A connected to the LCX 2 constituting the extension antenna cable 102 and a power supply constituting the extension antenna cable 102. It is possible to connect to the AP 301 (not shown) via the second connection coaxial cable 50B connected to the coaxial cable 3. In the wireless communication apparatus including the composite cable type antenna 400C, the composite cable type antenna 400C functions as a 2 × 2 MIMO communication antenna that transmits and receives different signals S1 and S2 simultaneously. That is, in this wireless communication apparatus, different signals S1, S2 can be transmitted simultaneously from the composite cable type antenna 400C. Conversely, different signals S1 and S2 can be simultaneously received by the composite cable type antenna 400C.

In addition, this invention is not necessarily limited to the thing of the said embodiment, A various change can be added in the range which does not deviate from the meaning of this invention.
Specifically, the cable type antennas 1A to 1D, the extension cable type antennas 100A to 100C, and the composite cable type antennas 200A to 200C and 400A to 400C to which the present invention is applied are the antennas for the wireless LAN access point (AP) described above. For example, the present invention can be applied to a radio communication antenna on the base station side such as a mobile phone.

  In this case, the cable type antennas 1A to 1D, the extension cable type antennas 100A to 100C, and the composite cable type antennas 200A to 200C and 400A to 400C to which the present invention is applied are not connected to the AP 301 described above, By connecting, it is possible to construct the 2 × 2 MIMO or 4 × 4 MIMO wireless communication apparatus described above.

  Hereinafter, the effects of the present invention will be made clearer by examples. In addition, this invention is not limited to a following example, In the range which does not change the summary, it can change suitably and can implement.

  In this embodiment, when a transmission loss measuring device is connected to the cable antenna 1A and the frequencies are 2.4 GHz, 3.5 GHz, and 5.0 GHz, the distance D between the cable antennas 1A is changed. The transmission loss of was measured. In addition, the same measurement was performed for the case where the thickness t of the dielectric (cable connecting portion 4c) was changed to 0, 2, 4, and 8 mm. In addition, when thickness t is 0 mm, the case where space is provided between LCX2 and the coaxial cable 3 for electric power feeding is shown.

  In this measurement, LCX2 and feeding coaxial cable 3 having an outer diameter of outer conductor 8 of 5.5 mm and a thickness of sheath 4 (sheath 4a and sheath 4b) of 1.25 mm were used. Hereinafter, the measurement results when the frequencies are 2.4 GHz, 3.5 GHz, and 5.0 GHz are shown in FIGS. 20, 21, and 22.

  FIG. 20 is a graph showing the results of measuring the relationship between the distance D of the cable type antenna 1A and the transmission loss at 2.4 GHz. FIG. 21 is a graph showing the results of measuring the relationship between the distance D of the cable-type antenna 1A and the transmission loss at 3.5 GHz. FIG. 22 is a graph showing the results of measuring the relationship between the distance D of the cable-type antenna 1A and the transmission loss at 5.0 GHz.

  Table 1 below shows the correspondence between the free space wavelength λ of the electromagnetic wave emitted from the slot 7 of the LCX 2 and the interval D for each frequency.

  20, 21, and 22, it can be seen that the transmission loss of LCX 2 increases as the distance D between the outer conductor 8 of LCX 2 and the outer conductor 8 of the feeding coaxial cable 3 decreases. Further, the degree of increase in transmission loss is more conspicuous as the frequency is lower, and is more prominent as the thickness t of the dielectric increases.

  In any of the cases shown in FIGS. 20, 21, and 22, the transmission loss of LCX 2 can be increased by setting the distance D between the outer conductor 8 of the LCX 2 and the outer conductor 8 of the feeding coaxial cable 3 to λ / 4 or more. Was found to be low. Even if the interval D is made larger than λ, the transmission loss of the LCX 2 hardly decreases. Therefore, in order to realize the downsizing of the composite cable 1A, the interval D is preferably set to λ or less.

  DESCRIPTION OF SYMBOLS 1A-1D ... Cable type | mold antenna 2 ... Leaky coaxial cable (LCX) 3 ... Coaxial cable for electric power feeding 3a ... Curve part 3b ... 1st curve part 3c ... 2nd curve part 4 ... Sheath 4a ... Sheath 4b ... Sheath 4c, 4d ... connecting portion 5 ... center conductor 6 ... insulator 7 ... slot 8 ... outer conductor 9 ... coaxial cable for connection 9 ... first coaxial cable for connection 9B ... second coaxial cable for connection 10a, 10b ... connector 11a, 11b ... Connector 12a, 12b ... Connector 20 ... Connector 30A, 30C ... First connection coaxial cable 30B, 30D ... Second connection coaxial cable 31a, 31b ... Connector 50A ... First connection coaxial cable 50B ... 2nd coaxial cable for connection 50C ... 3rd coaxial cable for connection 51a, 51b ... connector 100A-1 DESCRIPTION OF SYMBOLS 0C ... Extension cable type antenna 101 ... Antenna cable for tip 102, 102A, 102B ... Extension antenna cable 200A-200C ... Composite cable type antenna 300A-300D ... Wireless communication apparatus 301 ... Access point (AP) 400A-400C ... Composite cable Type antenna

Claims (8)

The leaky coaxial cable and the feeding coaxial cable are arranged integrally connected in parallel with a certain distance between the outer conductors,
Wherein one end of the feeding coaxial cable is extended than one end of the leakage coaxial cable, in a state where one end of the feeding coaxial cable is curved, the same direction of the leaky coaxial cable and the feeding coaxial cable A cable-type antenna characterized in that one end side of the cable is connected. Wherein A leaky coaxial cable and the feeding coaxial cable to claim 1, characterized in that it is connected by a connecting portion formed on the sheath and integrally with each of the leakage coaxial cable and the feeding coaxial cable The cable antenna described. The cable-type antenna according to claim 1 , wherein the leaky coaxial cable and the feeding coaxial cable are integrally connected by using a connector. The gap, the leakage free space wavelength of the electromagnetic wave radiated from the coaxial cable of the slot when the lambda, any one of claims 1 to 3, characterized in that in the range of λ / 4~λ Cable type antenna as described in 1. An antenna cable for a tip constituted by the cable type antenna according to any one of claims 1 to 4 ,
An extension antenna cable configured by a leaky coaxial cable and a feeding coaxial cable, which are connected to the tip antenna cable and integrally connected in a state of being parallel to each other with a certain distance therebetween ,
The antenna antenna cable for extension and the antenna cable for extension have a structure in which the leaky coaxial cable is connected to each other and the power supply coaxial cable is connected to each other. A cable type antenna according to any one of claims 1 to 4 and an extension cable type antenna according to claim 5 are arranged side by side or arranged or integrated. Composite cable type antenna. Among the plurality of cable-type antennas, one end of the leaky coaxial cable or the feeding coaxial cable of adjacent cable-type antennas, and the other end of the leaky coaxial cable or the feeding coaxial cable, 7. The composite cable type antenna according to claim 6 , wherein the composite cable type antenna has a structure connected through a coaxial cable for connection. A cable type of any one of the cable type antenna according to any one of claims 1 to 4 , the extension cable type antenna according to claim 5 , and the composite cable type antenna according to claim 6 or 7. An antenna,
A wireless communication apparatus comprising an access point or a radio connected to the cable antenna.

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