JP2556387B2 - Leaky coaxial line - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to a leaky coaxial line having a band-shaped leaky electric field region in which a fixed station and a plurality of mobile wireless devices (hereinafter referred to as mobile stations) are connected to the fixed station. The present invention relates to a leaky coaxial line in a communication method in which wireless communication is performed as a part of a relay medium.

(Prior art and its problems) For example, when a fixed station and a mobile station communicate with each other by radio frequency using a line using a leaky coaxial cable as a part of a relay medium, the line shown in FIG. The composition was general.

In FIG. 4, reference numeral 1 is a leaky coaxial cable or an open coaxial cable. Reference numeral 2 is a fixed station, which incorporates a transmitter (f ₁ ) and a receiver (f ₂ ) (not shown). Reference numeral 3 is a terminating device, and 4 is a portable mobile station, which has a transmitter (f ₂ ) and a receiver (f ₁ ) built therein (not shown). f ₁ and f ₂ are radio frequencies in the VHF or UHF band. The ANT of the mobile station 4 is a transmission / reception shared antenna.

Mutual communication between the fixed station 2 and the mobile station 4 is ensured by using the leaky coaxial cable 1 as a relay medium.

In FIG. 4, L is the length of the cable 1, d ₁ and d ₂ are the widths (distances) of the leakage electric field region from the cable 1, and both sides of the cable 1 are symmetrical.

P _l : Fixed station 2 transmission output, P ₂ : Fixed station 2 reception input, P _a : Portable mobile station 4 transmission output, P ₁ : Portable mobile station 4 reception input, L _c : Cable 1 The coupling loss of the mobile station ANT, α _f1 is the transmission loss / unit length of the cable at the radio frequency f ₁ , α _f2 is the transmission loss / unit length of the cable at the radio frequency f ₂ , and point A is that of the leaky coaxial cable 1. The position of the mobile station 4 in the vicinity is shown. When the length from the fixed station 2 to the point A is 1, the reception input P ₁ of the mobile station 4 from the fixed station 2 to the mobile station 4 by the downlink and the fixed input by the uplink from the mobile station 4 to the fixed station 2 are fixed. The reception input P ₂ of the station 2 is expressed by the following equations.

_{P 1 = P l -α f1 ×} l-L c P 2 = P a -L in _{c -α f2} × l such conventional circuit configuration, the portable mobile station 4
The order to reduce the size and weight, to reduce the transmission output P _a mobile station 4 is common. That is, if P _a <P _l , then α _f1 ≈
Since α _f2 , P ₁ > P ₂ .

For the reasons described above, the reception input P ₁ of the mobile mobile station 4 in the wireless downlink is larger than the reception input P ₂ of the fixed station 2 in the wireless uplink. As a result, the service area 6 of the wireless downlink is an L × d ₂ band area (cable 1
Since it is symmetric on both sides, it will be explained on one side. ), The wireless uplink service area 5 is an L × d ₁ strip-shaped area, and according to experiments, d ₁ > d ₂ , so the uplink / downlink comprehensive service area is the downlink service area 6 Significantly reduced uplink service area 5
However, there is a drawback that it is limited to the L × d ₁ region of

(Object of the Invention) As described above, the object of the present invention is to solve the drawback that the total communication service area that combines uplink and downlink is reduced because the service area of the uplink is narrow, and the service area of the uplink is reduced. It is intended to provide a leaky coaxial line capable of securing a wide comprehensive communication service area by expanding the service area to the same extent as the service area of the downlink.

(Structure and operation of the invention) The leaky coaxial line of the present invention is a leaky coaxial cable or an open coaxial cable extended from the fixed station so that the fixed station and the mobile station perform mutual communication using transmission waves having different frequencies. In a leaky coaxial line that uses a cable as a main relay medium and electromagnetically couples a mobile wireless device to the leak electric field, a receiving-only antenna that receives radio waves from the mobile station and a mobile station that has a built-in solar power source and is received by the antenna An amplifier for amplifying an upstream line signal from the antenna, and a cylindrical antenna mounted on the leaky coaxial cable with a nylon belt which is easily attached and removed by closely adhering the leaky coaxial cable from the outside in a state where the antenna and the amplifier are accommodated. The leaky coaxial cable for electromagnetically coupling with the case and the output end of the amplifier for electromagnetically coupling with the leaky coaxial cable. External mounting removed from consists an easy way attached to the coupler relay antenna device is characterized in that provided in the corresponding to the movement range of the mobile station position of the leaky coaxial cable.

That is, the wireless downlink from the fixed station to the mobile station is a leaky coaxial cable line (band-shaped service area) or open coaxial cable line in the VHF or UHF band, and the wireless uplink line from the mobile station to the fixed station is in the VHF or UHF band. For example, relay antennas provided with a receiving coaxial sleeve antenna are dispersedly arranged substantially parallel to the axial direction of the leaky coaxial cable or open coaxial cable, and an open coaxial cable or leaky coaxial cable is provided by an amplifier and a coupler added to the relay antenna. The electromagnetic wave from the mobile station is relayed and amplified by being electromagnetically coupled with and sent to an open coaxial cable or a leaky coaxial cable, and the service area of the wireless uplink is expanded to be almost equal to the service area of the wireless downlink. The greatest feature is the realization of a communication service area.

The service area mentioned here refers to a mobile effective range of the mobile station that can be received under the conditions of the transmission output and the reception sensitivity set for the fixed station and the mobile station, respectively, according to the usual definition.

 The present invention will be described in detail below with reference to the drawings.

FIG. 2 (a) is a basic configuration diagram of a communication system using the first embodiment of the present invention. In the figure, 1 is a leaky coaxial cable or an open coaxial cable. A fixed station 2 includes a transmitter (f ₁ ) 12, a receiver (f ₂ ) 13 and a coupling unit 14. 3 is a terminating device, and 4 is a portable mobile station, which incorporates a transmitter (f ₂ ) and a receiver (f ₁ ) (not shown). f ₁ and f ₂
Is a radio frequency in the VHF or UHF band. ANT is a transmission / reception shared antenna of the mobile station 4. Reference numeral 6 denotes a downlink service area (a strip electric field area on the ground surface) of the leaky coaxial cable 1. Reference numeral 5 denotes an upstream service area (band-shaped electric field area) of the leaky coaxial cable 1. Reference numeral 8 denotes a high frequency amplifier (dedicated to f ₂ ), which has a gain for compensating the coupling loss and has a solar power source (not shown) built therein. Reference numeral 10 denotes an electromagnetic coupling coupler, which is mainly electromagnetically coupled to the leaky coaxial cable 1. Reference numeral 7 denotes a wireless uplink service area (a substantially circular shape on the ground surface) when the coaxial sleeve relay antenna 9 for distributed reception (f ₂ ) is installed horizontally.

When the equivalent antenna gain of the leaky coaxial cable 1 is set to G _l , the antenna gain of the relay antenna 9 is G _a , and the antenna gains G _l and G _a at the radio frequencies f ₁ and f ₂ are measured, G _a > G _l . The gain difference is about 10 dB, and the service area 7 is expanded as shown in the figure to exceed the service area 6 indicated by the width d ₂ . That is, as compared with the conventional circuit shown in FIG. 4, the mutual communication service area in which the upstream and downstream are integrated is greatly expanded.

FIG. 2B is a cross-sectional view showing a situation in which the leaky coaxial cable 1 shown in FIG. 2A is stretched at a ground clearance h ₁ . Reference numerals 6 and 7 denote cross sections of the spatial service area centering on the leaky coaxial cable 1 and the relay antenna 9, respectively.

FIG. 3 is a block diagram of a communication system using the second embodiment of the present invention, in which the coaxial sleeve antenna 9 of the reception-only relay antenna in the first embodiment of FIG. ₂ ) is replaced with the whip antenna 19 for
The leaky coaxial cable 1 is electromagnetically coupled via the code 20, the high frequency amplifier (for exclusive use of f ₂ ) 8 and the coupler 10. The other parts shown in the figure have exactly the same functions as the parts shown in FIG.
Reference numeral 18 in FIG. 3 denotes a wireless uplink service area (when the whip antenna 19 is installed vertically) (substantially circular on the ground).

FIG. 1 (a) is a partial structural view of the present invention showing a state in which the relay antenna 9 shown in FIG. 2 (a) is attached to the leaky coaxial cable 1. 11 is a high frequency connector. 17
Shows a distributed relay antenna case (cylindrical) in which an amplifier 8 (incorporating a solar power source section), a coaxial sleeve antenna 9 and a high frequency connector 11 are incorporated. The distributed relay antenna case 17 is installed in close contact with the leaky coaxial cable 1 as shown in the figure.

1 (b) is the distributed antenna case 17 of FIG. 1 (a).
It is a perspective view which shows the attachment details of. Reference numeral 15 is a messenger wire of the leaky coaxial cable 1, and a distributed antenna 17 is attached to the leaky coaxial cable 1 and the messenger wire 15 from outside by a nylon belt 16 as shown in the figure. still,
As shown in the figure, the coupler 10 can be closely attached to the leaky coaxial cable 1 from the outside.

Above relay antenna 9 or 19, amplifier 8 and coupler 1
The relay antenna device configured by 0 is one of the constituent elements of the present invention.

(Operation) Referring to FIG. 2, a wireless downlink will be described.

The output of the f ₁ wave transmitted from the transmission section 12 of the fixed station 2 is transmitted to the leaky coaxial cable 1 via the coupling section 14 and forms a strip-shaped service area 6 around the leaky coaxial cable 1. Mobile station 4 exists in the illustrated position, f ₁ with an antenna (ANT)
The wave is received by a built-in receiving unit (not shown).
Next, the wireless uplink will be described. The output of the f ₂ wave transmitted via the ANT from the transmitter (not shown) built in the mobile station 4 is the reception-only distributed coaxial sleeve antenna 9 in the vicinity.
Received in the up-link, reception amplifier 8 → coupler 10 →
The signal is received by the receiving unit 13 via the coupling unit 14 of the cable 1 to the fixed station 2. Note that, for example, when weak radio waves are used, the radius d ₃ of the service area 7 ≈ 45 m and the width d of the service area 6
₂ ≈ 30m.

As described above, since the service areas of the wireless up-link and the wireless down-link are almost equal to each other, the up / down integrated service area is expanded.

In FIG. 2A, the relay antenna device including the receiving coaxial sleeve antenna 9, the receiving amplifier 8 and the coupler 10 has a structure that can be easily attached to and removed from the leaky coaxial cable 1 from the outside ( As shown in FIG. 1 (b)), the installation place or interval can be changed arbitrarily, and there is the convenience that the work of on-site adjustment work for constructing the service area 7 can be made extremely easy.

In FIG. 3, the wireless downlink is exactly the same as in the case of FIG. 2 (a), and therefore detailed description thereof is omitted. The width of the service area is d ₂ ≈30 m when weak radio waves are used, for example.

Next, for the wireless uplink, a whip antenna is used instead of the receiving coaxial sleeve antenna 9 of FIG. 2 (a).
19 is used and is connected to the receiving amplifier 8 via the high frequency cord 20. Since the other parts are exactly the same as in the case of FIG. 2 (a), detailed description thereof will be omitted.

The length of the high frequency cord 20 ≈ 5 m and the whip antenna 19
To be installed in the field. For example, when weak radio waves are used, the radius of the wireless uplink service area 18 is shown in FIG. 2 (a).
Since a of d ₃ is the same about 45 m, up / down overall service area it will have been extended.

(Effects of the Invention) As described in detail above, indoors and underground sections of buildings, etc. where radio wave propagation is poor (for example, underground malls and subway lines).
Needless to say, a wide service area can be ensured by utilizing the present invention for a mutual mobile wireless line in wireless control of a trolley, a crane, or the like that travels on a fixed traveling path. According to the experiment, for example, in the case of weak radio waves,
While the width of the upper / lower comprehensive service area of the prior art shown in the figure is d ₁ ≈4 m using the open coaxial cable,
The width of the upper / lower integrated service area of FIGS. 2 (a) and 3 according to the present invention is d ₂ ≈30 m using an open coaxial cable. That is, the improvement effect of the width of the service area is d ₂ / d ₁ ≈
It is 7 to 8 times, which is a great effect in expanding the service area.

Further, as already described, the relay antenna device including the receiving coaxial sleeve antennas 9 and 17 and the coupler 10 shown in FIGS. 1 (a), (b), 2 (a) and 3 Is
Since it can be easily attached to and detached from the open coaxial cable 1 to the outside, the effect of convenience in the site adjustment work is great. When the present invention is applied to a VHF or UHF band wireless line, it is of course effective, but as described above, the effect is remarkable especially in weak radio waves.

[Brief description of drawings]

1 (a) and 1 (b) are schematic structural diagrams of a relay antenna device which is a part of the present invention, FIG. 2 is a line configuration diagram showing a first embodiment of the present invention, and FIG. FIG. 4 is a line configuration diagram showing a second embodiment of the invention, and FIG. 4 is a conventional line configuration diagram. 1 ... Leaky coaxial cable, 2 ... Fixed station, 3 ... Terminator, 4 ... Portable mobile radio, 5,6 ... Band service area, 7,18 ... Circular service area, 8 ... Reception Amplifier, 9 ... Receiving coaxial sleeve antenna, 19 ... Whip antenna, 10 ... Coupler, 11 ... Connector, 12 ... Transmitting section, 13 ... Receiving section, 14 ... Coupling section, 15 ... Messenger Wire, 16 …… Nylon belt, 17 …… Antenna case, 20 …… High frequency cord.

Claims (1)

(57) [Claims] 1. A leaky coaxial line using a leaky coaxial cable extended from a fixed station as a main relay medium for mutual communication between a fixed station and a mobile station using transmission waves having different frequencies, An exclusive antenna for receiving radio waves from mobile stations,
An amplifier that has a built-in solar power supply and amplifies the uplink signal from the mobile station received by the antenna, and a nylon belt that is in close contact with the outside of the leaky coaxial cable in parallel with the antenna and the amplifier accommodated and is easy to attach and detach. And a cylindrical antenna case attached to the leaky coaxial cable, and a coupler connected to the output end of the amplifier for electromagnetically coupling with the leaky coaxial cable so that the leaky coaxial cable can be easily attached and detached from the outside. A leaky coaxial line characterized in that a relay antenna device consisting of is provided at a position corresponding to a moving range of the mobile station of the leaky coaxial cable.