JP2007049623A - Leakage transmission channel - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To broaden wholly a wireless communication region by raising the level of electric wave signals emitted without increasing transmission loss of a leakage transmission channel. <P>SOLUTION: A plurality of the leakage transmission channels 11-1 to 11-n where a plurality of slots s1 and a plurality of slots s2 are arranged alternately is connected with a distributor 13 for distributing signals to each of the leakage transmission channels. The slots s1 and the slots s2 are formed at given tilt angles θ and (180°-θ) to the axial direction of the transmission channel, respectively. Then, each of the leakage transmission channels is arranged parallel so as to align tilt angles of the first slots at a distributor side with one another. For example, the first slot at the distributor side of each of the leakage transmission channels is aligned with the slot s1. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a leaky transmission line antenna in which a plurality of leaky transmission lines having a plurality of slots formed with a predetermined inclination angle with respect to an axial direction are arranged, and a signal to the leaky transmission line is distributed by a distributor.

Conventionally, in a wireless communication system using a leaky transmission line antenna, for example, one end of a first leaky coaxial cable is connected to a relay device via a coaxial cable, and a coaxial cable is connected to the other end of the first leaky coaxial cable. One end of the second leaky coaxial cable is connected to the other end of the second leaky coaxial cable, and a terminator is connected to the other end of the second leaky coaxial cable via the coaxial cable so that each leaky coaxial cable functions as an antenna. A data processing device arranged in the vicinity of the cable uses a wireless transmission / reception device to perform wireless communication with the relay device via the first leaky coaxial cable, and a data processing device arranged in the vicinity of the second leaky coaxial cable transmits / receives wirelessly. A device that performs wireless communication with a relay device via a second leaky coaxial cable using a device is known (for example, see Patent Document 1).
JP-A-5-83258 (paragraphs “0013” and “0014”, FIG. 3)

  The one described in Patent Document 1 always has one leaky coaxial cable used when the data processing apparatus performs wireless communication. Therefore, the level of the radio signal radiated from the leaky coaxial cable is low, and the data processing apparatus leaks. Communication was possible only near the coaxial cable. If the slot of the leaky coaxial cable is increased, the level of the radiated radio signal can be increased. However, if this is done, the transmission loss increases, so the leaky coaxial cable cannot be laid for a long time, and the wireless communication area There was a problem that became narrow.

  Therefore, the present invention provides a leaky transmission line antenna that can increase the level of a radio signal radiated without increasing the transmission loss of the leaky transmission line and can broaden the radio communication area as a whole.

  The present invention connects a plurality of leaky transmission lines having a plurality of slots to a distributor that distributes a signal to each of the leaky transmission lines, and each leaky transmission line is inclined by a first slot on the distributor side. The leaky transmission line antenna is arranged in parallel so that the angles are equal, and a plurality of slots having the same inclination angle as the inclination angle of the first slot with respect to the axial direction are formed.

  ADVANTAGE OF THE INVENTION According to this invention, the level of the radio wave signal radiated | emitted can be raised without enlarging the transmission loss of a leaky transmission line, and the leaky transmission line antenna which can expand a radio | wireless communication area as a whole can be provided.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

(First embodiment)
As shown in FIG. 1, a plurality of slots s1 are formed with a predetermined inclination angle θ with respect to the axial direction, and are formed with a predetermined inclination angle (180 ° −θ) with respect to the axial direction. .., 11-n are arranged in parallel with each other in a zigzag slot array type in which a plurality of slots s2 are alternately arranged.

  One end of the n leaky transmission lines 11-1, 11-2,..., 11-n is connected to the distributor 13 via connectors 12-1, 12-2,. . Terminators 14-1, 14-2,..., 14-n are connected to the other ends of the n leaky transmission lines 11-1, 11-2,. The distributor 13 is connected to the base station 15 and distributes the signal from the base station 15 to the leaky transmission lines 11-1, 11-2,..., 11-n.

  The n leaky transmission lines 11-1, 11-2,..., 11-n are aligned so that the first slot on the distributor side becomes the slot s1. That is, the inclination angle of the first slot on the distributor side is made equal to θ. In addition, here, the slots s1 and the slots s2 of the leaky transmission lines 11-1, 11-2,..., 11-n are aligned so as to be substantially aligned at the positions in the axial direction of the transmission lines.

  By arranging the n leaky transmission lines 11-1, 11-2,..., 11-n in this way, the first slot on the distributor 12 side in each leaky transmission line is a slot s1, which is inclined with respect to each other. The angles are aligned at θ. A plurality of slots s1 are formed alternately with the slots s2 in the axial direction of the transmission path. With such an arrangement, it is possible to increase the level of the radio wave signal radiated without increasing the slot s1 and the slot s2.

  That is, the individual radiation signal levels of the leaky transmission lines 11-1, 11-2,..., 11-n are low, but the radiation signal level of the radio signal is obtained by aligning the inclination angle of the first slot on the distributor side. Is synthesized and expensive. As a result, the wireless communication terminal (not shown) can connect the leaky transmission lines 11-1, 11-2,..., 11-n even at positions away from the leaky transmission lines 11-1, 11-2,. Wireless communication with the base station 15 is possible. Further, it is not necessary for the leaky transmission lines 11-1, 11-2,..., 11-n to increase the slots s1 and s2 more than necessary, so that the transmission loss does not increase and the installation distance is increased. Can do. Thereby, the wireless communication area can be expanded as a whole.

Next, the experimental results of reception field strength measurement will be described.
Four leaky transmission lines C1, C2, C3, and C4 having the same slot shape are prepared, and an arbitrary combination of the four leaky transmission lines C1, C2, C3, and C4, for example, C1 + C2, C1 + C3 , C1 + C4, C2 + C3, C2 + C4, and C3 + C4 were laid in parallel to each other, and the received electric field strength was measured.

  A combination of C1 + C2, C1 + C3, C1 + C4, C2 + C3, C2 + C4, C3 + C4, laid in parallel with the first slot on the distributor side aligned, and received electric field at a point 10 m away from the leaky transmission path As a result of measuring the strength, the measured values indicated by the triangular points in FIG. 2 were obtained. That is, a value of about −70 dBm was obtained as the received electric field strength for any combination.

On the other hand, the combination of C1 + C2, C1 + C3, C1 + C4, C2 + C3, C2 + C4, C3 + C4 is laid in parallel with the inclination angle of the first slot on the distributor side being different, and at a point 10 m away from the leaky transmission line. As a result of measuring the received electric field strength, the measured values indicated by the square points in FIG. 2 were obtained. That is, every combination resulted in a decrease in received electric field strength to around -80 dBm.
In this way, the state in which the first slot on the distributor side is laid in parallel so that the inclination angles are aligned, and the state in which the first slot on the distributor side is laid in parallel so that the inclination angle is different It was found that a difference of about 10 dBm in received electric field strength occurs.

  In this embodiment, the first slots on the distributor side of the n leaky transmission lines 11-1, 11-2,..., 11-n are aligned so as to become the slot s1, and each leak Although the case where the slots s1 and s2 of the transmission path are aligned so as to be substantially aligned in the direction orthogonal to the axial direction of the transmission path has been described, the present invention is not limited to this. For example, as shown in FIGS. 3A and 3B, the first slot on the distributor side of n leakage transmission lines 11-1, 11-2,... Even if it arrange | positions so that it may become, it may arrange | position so that a position may mutually shift | deviate with respect to the direction orthogonal to the axial direction of a transmission line.

  In this embodiment, the slots s1 are formed with a predetermined inclination angle θ with respect to the axial direction, and are formed with a predetermined inclination angle (180 ° −θ) with respect to the axial direction. Although the case where n leaky transmission lines 11-1, 11-2,..., 11-n in which a plurality of slots s2 are alternately arranged has been described, the present invention is not limited to this. For example, as shown in FIG. 4, n one-way slanted slot array type leakage transmission lines 11-11, 11-12,..., In which one of the slots s1 and s2 is formed at a predetermined interval, are arranged. It may be a thing.

(Second Embodiment)
As shown in FIG. 5, a plurality of slots s2 formed with a predetermined inclination angle (180 ° −θ) with respect to the axial direction, and formed with a predetermined inclination angle θ with respect to the axial direction. A zigzag slot array type first and second leaky transmission lines 21-1 and 21-2 in which a plurality of slots s1 are alternately arranged are arranged in parallel to each other.

  A plurality of slots s1 formed with a predetermined inclination angle θ with respect to the axial direction and a plurality of slots s2 formed with a predetermined inclination angle (180 ° −θ) with respect to the axial direction. Alternatingly arranged zigzag slot array type third leaky transmission lines 21-3 are arranged in parallel to the first and second leaky transmission lines 21-1, 21-2.

  Then, one end of the first leaky transmission line 21-1 is directly connected to the distributor 23 via the connector 22-1, and one end of the second leaky transmission line 21-2 is connected to the connector 22-2. Via the first contact 24a and the common contact 24c of the route switch 24, and is connected to the distributor 23. One end of the third leakage transmission line 21-3 is connected to the route via the connector 22-3. The distributor 24 is connected to the distributor 23 via a second contact 24b and a common contact 24c.

  In the first leaky transmission line 21-1, the first slot on the distributor 23 side is a slot s1 having an inclination angle θ, and the second leaky transmission line 21-2 is also 1 on the distributor 23 side. The first slot is a slot s1 having an inclination angle θ. That is, the first and second leaky transmission lines 21-1 and 21-2 are arranged so that the inclination angles of the first slot are aligned.

  The third leaky transmission line 21-3 has an inclination angle of the first slot on the distributor 23 side with respect to the inclination angle θ of the first slot s1 of the first leaky transmission line 21-1. Are arranged so as to be substantially symmetrical with respect to a direction orthogonal to the axial direction. In other words, the first slot on the distributor 23 side is the slot s2 whose inclination angle is (180 ° −θ).

  The distributor 23 is connected to a base station 25 and distributes and outputs a signal from the base station 25. The base station 25 switches and controls the route switch 24 when communicating with a wireless communication terminal (not shown). Terminators 26-1, 26-2, and 26-3 are connected to the other ends of the leaky transmission lines 21-1, 21-2, and 21-3, respectively.

  In such a configuration, when the base station 25 communicates with a wireless communication terminal (not shown) located away from the leaky transmission lines 21-1, 21-2, 21-3, the route switch 24 is connected. The common contact 24c is controlled to connect to the first contact 24a. In this state, the base station 25 transmits a signal to the first leaky transmission line 21-1 via the distributor 23, and sends a signal to the second leaky transmission line 21-2 via the distributor 23 and the route switch 24. Send to.

  As a result, radio waves are radiated from the first and second leaky transmission lines 21-1 and 21-2 that are arranged such that the first distributor on the distributor side is the slot s 1 and the inclination angles are aligned with θ. Therefore, the radiation level of the radio signal is synthesized and increased. Thus, reliable communication can be performed with a wireless communication terminal (not shown) located at a remote location.

  When the base station 25 communicates with a wireless communication terminal (not shown) in the vicinity of the leaky transmission lines 21-1, 21-2, 21-3, the route switch 24 is controlled to set the common contact 24c. The second contact 24b is connected. In this state, the base station 25 transmits a signal to the first leaky transmission line 21-1 via the distributor 23 and sends the signal to the third leaky transmission line 21-3 via the distributor 23 and the route switch 24. Send to.

  In this case, the first leakage side transmission line 21-1 in which the first on the distributor side is the slot s1 and the slots s1 and s2 are alternately formed in the axial direction, and the first on the distributor side is the slot s2. Since radio waves are radiated from the third leaky transmission line 21-3 in which the slots s1 and slots s2 are alternately formed in the axial direction, the radiation level of the radio signals does not increase. However, since the wireless communication terminal (not shown) is arranged in the vicinity, the base station 25 can communicate with the wireless communication terminal reliably through the first and third leaky transmission paths 21-1 and 21-3. it can.

  As described above, since the radiation level of the radio signal can be switched according to the arrangement position of the wireless communication terminal (not shown), it is troublesome to replace the leaky transmission line when changing the radiation level of the radio signal as an antenna. Can be easily dealt with without complicated work, and versatility can be improved. Also in this embodiment, the level of the radio signal radiated can be increased without increasing the transmission loss of the leaky transmission path, and the radio communication area can be expanded as a whole.

(Third embodiment)
As shown in FIG. 6, a plurality of slots s1 formed with a predetermined inclination angle θ with respect to the axial direction and a plurality of slots s1 formed with a predetermined inclination angle (180 ° −θ) with respect to the axial direction. Zigzag slot array type first leaky transmission line 31-1 in which slots s2 are alternately arranged, and a plurality of slots s2 formed with a predetermined inclination angle (180 ° −θ) with respect to the axial direction, and A zigzag slot array type second leaky transmission line 32-1 in which a plurality of slots s1 formed with a predetermined inclination angle θ with respect to the axial direction are alternately arranged is arranged in parallel.

  Then, one end of the first leakage transmission line 31-1 is connected to the distributor 36 via the connector 33-1 via the first contact 35a and the common contact 35c of the route switch 35-1, and the first One end of each of the two leaky transmission lines 32-1 is connected to the distributor 36 via the connector 34-1 via the second contact 35b and the common contact 35c of the route switch 35-1. Terminators 37-1 and 38-1 are connected to the other ends of the leaky transmission lines 31-1 and 32-1, respectively.

  The first slot on the distributor 36 side of the first leaky transmission line 31-1 is a slot s1 having an inclination angle θ. The first slot on the distributor 36 side of the second leaky transmission line 32-1 is a slot s2 having an inclination angle of (180 ° −θ). Therefore, as a whole, the first leaky transmission line 31-1 and the second leaky transmission line 32-1 have different inclination angles of the slots with respect to the axial position.

The first leaky transmission line 31-1, the second leaky transmission line 32-1, the connectors 33-1 and 34-1, the route switch 35-1 and the terminators 37-1 and 38-1 are included in one set. Is configured.
Similarly, the second set includes a first leaky transmission line 31-2, a second leaky transmission line 32-2, connectors 33-2 and 34-2, a route switch 35-2, and terminators 37-2 and 38. -2 is connected in the same way as the first set, and n sets are provided. The n-th set includes the first leaky transmission line 31-n, the second leaky transmission line 32-n, the connectors 33-n and 34-n, the route switch 35-n, and the terminators 37-n and 38. -n is connected in the same way as the first set.

  The first leaky transmission lines 31-1 to 31-n of each set are aligned so that the first slot on the distributor 36 side is all the slot s1. That is, the first slots on the distributor side are arranged so that the inclination angles are aligned with θ. The second leaky transmission lines 32-1 to 32-n of each set are aligned so that the first slot on the distributor 36 side is all the slot s2. That is, the first slots on the distributor side are arranged so that the inclination angles are aligned at (180−θ).

  The distributor 36 is connected to the base station 39, and the signal from the base station 39 is distributed to each set and output. The base station 39 switches and controls the route switchers 35-1 to 35-n when wirelessly communicating with a wireless communication terminal (not shown).

  In such a configuration, when the base station 39 communicates with a wireless communication terminal (not shown) located away from the leaky transmission path, the route switchers 35-1 to 35-n are switched and controlled. The common contact 35c of the route switcher is connected to the first contact 35a or the second contact 35b so that the inclination angles of the first slots on the distributor 36 side are aligned with each other in each set of leakage transmission paths. For example, when the common contacts 35c of all the route switchers 35-1 to 35-n are connected to the first contact 35a, the first leakage transmission paths 31-1 to 31-n are selected in each group. As a result, the inclination angles of the first slots on the distributor 36 side of the leaky transmission line are aligned with each other in each set.

  In this state, the base station 39 transmits signals to the first leaky transmission lines 31-1 to 31-n of each set via the distributor 36 and the route switchers 35-1 to 35-n. As a result, radio waves are radiated from the first leaky transmission lines 31-1 to 31-n of the respective sets in which the first distributor side is arranged in the slot s1 so that the inclination angles thereof are aligned with θ. Therefore, the radiation level of the radio signal is synthesized and increased. Thus, reliable communication can be performed with a wireless communication terminal (not shown) located at a remote location.

  In addition, when the base station 39 communicates with, for example, a wireless communication terminal (not shown) in the vicinity of the leaky transmission path, half of the route switchers 35-1 to 35-n are connected. The common contact 35c is connected to the first contact 35a or the second contact 35b so that the inclination angles of the first slots on the distributor 36 side of the n / 2 leaky transmission lines are aligned. Thus, although the level of the radio signal radiated from the n leaky transmission paths is low, the radio communication terminal is in the vicinity, so that the radio communication terminal can perform radio communication with the base station 39 via the leaky transmission path.

  Further, when the base station 39 communicates with a wireless communication terminal (not shown) located not far from the leaky transmission path, several route switches among the route switchers 35-1 to 35-n are performed. The common contact 35c is connected to the first contact 35a or the second contact 35b so that the inclination angles of the first slots on the distributor 36 side of several leaky transmission lines are aligned. For example, when the common contact 35c of three route switchers is connected to the first contact 35a, three first leakage transmission paths are selected.

In this state, the base station 39 transmits a signal to the three first leaky transmission lines and the n-3 second leaky transmission lines via the distributor 36 and the route switcher. Thereby, the radiation level of the radio wave signal radiated from the leaky transmission line is increased to a certain degree by being synthesized.
Thus, reliable communication can be performed with a wireless communication terminal (not shown) that is not in the vicinity but is not far away.

  As described above, since the radiation level of the radio signal can be switched in a plurality of stages according to the arrangement position of the wireless communication terminal (not shown), the leakage transmission path is replaced when the radiation level of the radio signal is changed as an antenna. Such a troublesome work can be dealt with, and versatility can be improved. Also in this embodiment, the level of the radio signal radiated can be increased without increasing the transmission loss of the leaky transmission path, and the radio communication area can be expanded as a whole.

Next, the experimental results of reception field strength measurement will be described.
For example, a leaky transmission line antenna using four sets of the first leaky transmission line 31, the second leaky transmission line 32, the connectors 33 and 34, the route switch 35 and the terminators 37 and 38 is formed. The received electric field strength at a point 10 m away from the antenna part was measured. As a result, the results shown in Experiment A, Experiment B, and Experiment C in FIG. 7 were obtained.

  In the experimental example A, the inclination angle of the first slot on the distributor side in all four sets of leaky transmission lines is aligned, and all of the leaky transmission lines selected in the four sets are the first leaky transmission lines 31, Alternatively, the second leaky transmission path 32 is used. In this case, a high received electric field strength of about −68 dBm was obtained.

  In Experimental Example B, the inclination angle of the first slot on the distributor side in three sets of leaky transmission lines out of the four sets is made uniform. In this case, a received electric field strength of about −74 dBm was obtained.

  In Experimental Example C, the inclination angle of the first slot on the distributor side in the two sets of four sets, that is, half of the leaky transmission lines, is made uniform. In this case, a received electric field strength of about −82 dBm was obtained.

  In this way, when selecting each set of leaky transmission paths, the radiation level of the radio signal is stepwise by changing the number of leaky transmission paths with the same inclination angle of the first slot on the distributor side. The base station 39 can perform wireless communication at an appropriate radiation level according to the distance between the leaky transmission path antenna and a wireless communication terminal (not shown).

  In each of the embodiments described above, in each leaky transmission line, the inclination angle of the slot s1 is set to θ and the inclination angle of the slot s2 is set to (180 ° −θ). Even if (180 ° −θ) is slightly different from each other, there is no problem as long as the radiation level of the radio signal is within an allowable range that can be increased by synthesis.

The figure which shows the structure of the leaky transmission line antenna which concerns on the 1st Embodiment of this invention. The graph which shows the experimental result of the reception electric field strength measurement in the embodiment. The figure which shows the other example of arrangement | positioning of the leaky transmission line in the embodiment. The figure which shows the other slot arrangement | sequence example of the leaky transmission line used in the embodiment. The figure which shows the structure of the leaky transmission line antenna which concerns on the 2nd Embodiment of this invention. The figure which shows the structure of the leaky transmission line antenna which concerns on the 3rd Embodiment of this invention. The graph which shows the experimental result of the reception electric field strength measurement in the embodiment.

Explanation of symbols

  11-1 to 11-n: leaky transmission line, s1, s2 ... slot, 13: distributor, 14-1 to 14-n: terminator.

Claims (4)

Connect a plurality of leaky transmission lines having a plurality of slots to a distributor that distributes signals to each of the leaky transmission lines,
The leaky transmission lines are arranged in parallel so that the inclination angles of the first slot on the distributor side are aligned, and have the same inclination angle as the inclination angle of the first slot with respect to the axial direction. A leaky transmission line antenna comprising a plurality of slots.   2. The leaky transmission line antenna according to claim 1, wherein the plurality of slots of each leaky transmission line are formed in a zigzag slot arrangement type with respect to the axial direction. First, second and third leaky transmission lines having a plurality of slots;
A route switch that connects to the second and third leaky transmission lines and switches the leaky transmission lines;
The direct connection to the first leaky transmission line and the second and third leaky transmission lines are connected via the route switch to distribute signals to the first leaky transmission line and to the second leaky transmission line. A distributor for selectively distributing to the third leaky transmission line via the route switch,
The first leaky transmission line is formed with a plurality of slots having the same inclination angle as that of the first slot on the distributor side in the axial direction, and the second leaky transmission line is provided with the first leaky transmission line. Arranged in parallel so that the inclination angle of the first slot on the distributor side is aligned with the inclination angle of the first slot of the transmission line, the third leaky transmission line is the first slot Are arranged in parallel so that the inclination angle of the first slot on the distributor side is substantially symmetric with respect to the direction orthogonal to the axial direction with respect to the inclination angle of the first slot of the leaky transmission line The leaky transmission line antenna is characterized in that each leaky transmission line has a plurality of slots having the same inclination angle as the inclination angle of the first slot with respect to the axial direction. The first and second leaky transmission lines having a plurality of slots, and a route switcher for selectively switching a signal route to each of the leaky transmission lines, the first leaky transmission line is on the distributor side A plurality of slots having the same inclination angle as the inclination angle of the first slot of the first slot are formed in the axial direction, and the second leaky transmission line is formed with respect to the inclination angle of the first slot of the first leaky transmission line. The inclination angle of the first slot on the distributor side is substantially symmetric with respect to the direction orthogonal to the axial direction, and the same inclination as the inclination angle of the first slot with respect to the axial direction. A plurality of angular slots are formed, the first and second leaky transmission lines having this slot configuration are arranged in parallel and connected to the route switch to form a set, and a plurality of sets are provided.
A distributor is connected to each leaky transmission line of each set via a respective route switch, and a signal from the distributor is sent to each of the first and second leaky transmission lines via the route switch for each set. A leaky transmission line antenna characterized by being distributed alternatively.

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