JPH04208722A - Aligning device for simple radio equipment - Google Patents

Abstract

PURPOSE:To automatically align both simple radio equipments without manual operation by turning and operation both simple radio equipments in the horizontal direction and the vertical direction by driving mechanisms to decide the directions where intensities of electric field of alignment signals transmitted from each other are maximum and automatically aligning axes of radio wave propagation of both simple radio equipments. CONSTITUTION:When one simple radio equipments 1 or 2 is turned and operated in the horizontal direction or the vertical direction by horizontal and vertical driving mechanisms 10 and 11 or 15 and 16, the intensity of reception field of the alignment signal transmitted from the other simple radio equipment is detected by a field intensity detecting circuit 12 or 17. This detection signal is taken into a control circuit 9 or 14 to decide the direction, where the intensity of field in the horizontal direction and the vertical direction is maximum, by a comparing operation part, and the axis of radio wave propagation of one simple radio equipment is automatically aligned to that of the other based on the result of decision. Thus, both simple radio equipments are automatically aligned without manual operation.

Description

Detailed Description of the Invention (Field of Industrial Application) The present invention automatically aligns the propagation axes of simple radios for bidirectional transmission and reception (for example, 50 GHz simple radios) that are installed facing each other at a predetermined distance. The present invention relates to an alignment device for a simple radio device.

(Conventional technology) For data communication in areas where communication lines are not installed,
Simple radio with good portability and maneuverability, e.g. 50GH
Z-band simple unarmed aircraft will be used.

Since the frequency used in this simple radio is in the millimeter wave band and has good linearity and directivity, it is necessary to correctly align the radio wave propagation axes of the radios installed facing each other.

Conventionally, the method of aligning the radio wave propagation axes of such simple radio devices is to roughly align the radio wave propagation axes of the simple radio devices, and then adjust the radio wave intensity to the strongest electromagnetic field region of the radio waves arriving from the other side. This was detected manually using a meter, etc., and the antenna or the entire simple radio was manually adjusted so that the antenna of the simple thermal l1Ita was directed to this area.

(Problems to be Solved by the Invention) However, in such a conventional adjustment method, there are problems in that the adjustment operation is complicated and takes a lot of time, and the accuracy of propagation axis alignment also varies from person to person.

The present invention has been made in view of these points, and an object of the present invention is to provide an axis alignment device for a simple radio device that can automatically align the radio wave propagation axes of both devices without the need for human intervention. purpose.

(Means for Solving the Problems) In order to achieve the above object, the present invention provides first antennas that are installed facing each other at a predetermined distance apart to enable bidirectional transmission and reception. a second simple radio; a horizontal/vertical drive mechanism provided in at least one of the first and second simple radios to rotate the simple radio in the horizontal and vertical directions; field strength detection means for rotating the radio in the horizontal and vertical directions by the horizontal and vertical drive mechanism and detecting the received field strength in the horizontal and vertical directions of the alignment signal transmitted from the simple radio of the other party; , based on the electric field strengths in the horizontal and vertical directions detected by the electric field strength detection means, calculate the directions in which the electric field strengths in the horizontal and vertical directions are greatest, and set the radio wave propagation axis of one simple radio device to the other simple radio device. and control means for controlling the alignment of the horizontal and vertical drive mechanisms.

(Function) When one simple radio device is rotated horizontally or vertically by the horizontal/vertical drive mechanism, the received electric field strength of the alignment signal sent from the other party's simple radio device is detected. This detection signal is taken into the control means to determine the direction in which the electric field strength in the horizontal and vertical directions is greatest, and based on this determination result, the radio wave propagation axis of the simple radio is set to the other party's simple radio. Automatically aligns to the machine.

This makes it possible to automatically align the axes on both sides without requiring any human intervention.

(Example) An embodiment of the present invention will be described below with reference to FIG.

Figure 1 shows the overall configuration. 1 and 2 are 50 GHz simple radios for bidirectional transmission and reception that are installed facing each other at a predetermined distance. These simple radios 1 and 2 are installed on the ground. Mounted on each tripod 3.4. Each simple wireless! 1.2 includes a horizontal drive mechanism 5.6 that horizontally adjusts the radiation direction of radio waves and a vertical drive mechanism 7.8 that adjusts the radio wave radiation direction vertically based on each tripod 3.4.

Further, each of these drive mechanisms includes gears and motors (not shown), and can be manually operated using a handle or the like.

9 points the radio wave propagation axis of the simple radio device 1 to the other party's simple radio device 2.
This is a control circuit consisting of a microprocessor for controlling the axis alignment of Drive circuit 10, vertical drive circuit 1
1, a horizontal drive mechanism 5 and a vertical drive mechanism 7 are connected to each other.

Further, a field strength detection circuit 12 for detecting the strength of the electric field coming from the other party's simple radio device 2 is connected to the simple radio device 1, and the output signal of this field strength detection circuit 12 is transmitted to the control circuit 9.
is input to the comparison calculation section 9a. The comparison calculation unit 9a separately compares and calculates the electric field strength detected last time and the electric field strength detected this time each time the simple wireless ML is stepped by a predetermined angle in the horizontal and vertical directions. The maximum electric field strength in the direction can be determined by the control circuit 9. A memory 13 connected to the control circuit 9 stores the comparison results for each step and the orientation (angle) data of the simple radio 1 in the horizontal and vertical directions at that time.

14 is a control circuit consisting of a microprocessor for controlling the alignment of the radio wave propagation axis of the simple radio device 2 with respect to the simple radio device 1 on the other side, as in the case of the simple radio device 1 described above. Signal S for axis alignment for radio device 2
2 is supplied, and the control circuit 14
A horizontal drive mechanism 6 and a vertical drive mechanism 8 are connected to each other via a horizontal drive circuit 15 and a vertical drive circuit 16, respectively.

Further, a field strength detection circuit 17 is connected to the simple wireless device 2 to detect the strength of the electric field coming from the other party's simple radio device 3, and the output signal of the field strength detection circuit 17 is transmitted to the control circuit 1.
4 is input to the comparison calculation unit 14a. Comparison calculation unit 14a
calculates the electric field strength detected last time and the electric field strength detected this time separately each time the simple radio device 2 is stepped by a predetermined angle in the horizontal and vertical directions, and calculates the maximum horizontal and vertical directions from the comparison result. Electric field strength control circuit 14
It is possible to judge by. A memory 18 connected to the control circuit 14 stores the comparison results for each step and the orientation (angle) data of the simple radio 2 in the horizontal and vertical directions at that time.

Next, the operation will be explained.

First, manually operate the horizontal drive mechanisms 5, 6 and vertical drive mechanisms 7, 8 of the simple radios 1, 2 installed at each location where two-way transmission and reception is possible without obstacles. 2
Roughly match the radio wave emission directions. After that, set the simple radio device 1 to the alignment operation mode, and set the simple radio device 2 of the other party.
is placed in a non-operating mode, and the control circuit 14 supplies an alignment signal S2 to the simple radio device 2, and wirelessly transmits the alignment signal S2 to the simple radio device 1 side.

Next, the control circuit 9 outputs a rotation step command in the clockwise rotation direction to the horizontal drive circuit 10, thereby causing the horizontal drive mechanism 5
is driven to horizontally rotate the simple radio 1 to the right by a predetermined angle. In this state, the field strength detection circuit 12 detects the electric field strength of the alignment signal S2 that the simple radio device 1 receives from the other party's simple radio device 2, and inputs the detection output signal to the comparison calculation section 9a of the control circuit 9. . The comparison calculation unit 9a compares the previous horizontal electric field strength stored in the memory 13 and the currently detected electric field strength, and if the larger electric field strength, for example the current electric field strength, is larger, the current electric field strength is determined. The electric field strength is replaced with the previous electric field strength and stored in the memory 13 together with the angle data at that time.

Thereafter, each time a comparison calculation process is performed in the same way, the control circuit 9 outputs a horizontal rotation step command in the clockwise rotation direction to the horizontal drive circuit 5 to horizontally rotate the simple radio 1 in the clockwise direction. The intensities are sequentially compared and the data stored in the memory 13 is rewritten to the larger electric field intensity.

Then, when it is determined that the horizontal electric field strength detected in the next rightward horizontal rotation step operation is smaller than the previous electric field strength, the maximum horizontal electric field strength of the simple radio 1 is the same as the previous one. It is determined that the horizontal drive mechanism 5 is rotated counterclockwise, and the horizontal direction of the simple wireless ML is returned to the previous horizontal angle position. This sets the horizontal direction of the simple radio device 1.

Once the maximum electric field strength position in the horizontal direction of the simple radio device 1 is set, the control circuit 9 outputs an upward rotation step command to the vertical drive circuit 11, thereby driving the vertical drive mechanism 7 to The radio device 1 is vertically rotated upward by a predetermined angle. In this state, the field strength detection circuit 12 detects the electric field strength of the alignment signal S2 that the simple radio device 1 receives from the other party's simple radio device 2, and inputs the detection signal to the comparison calculation section 9a of the control circuit 9. The comparison calculation unit 9a compares the previous vertical electric field strength stored in the memory 13 and the current detected electric field strength, and determines the larger electric field strength,
For example, if the current electric field strength is larger, the current electric field strength is stored in the memory 13 together with the angle data at that time instead of the previous electric field strength.

Thereafter, each time a comparison calculation process is performed, the control circuit 9
A vertical rotation step command in the upward direction is output to the vertical drive circuit 7 to rotate the simple radio 1 in the upward direction.At the same time, the electric field strengths are sequentially compared, and the data stored in the memory 13 is set to the larger field strength. rewrite. Then, when it is determined that the vertical electric field strength detected in the next upward vertical rotation step operation is smaller than the previous electric field strength, the maximum vertical electric field strength of the portable radio 1 is the same as the previous one. When it is determined that there is an angle, the vertical drive mechanism 7 is driven downward, and the vertical angle of the simple radio 1 is returned to the previous vertical angle. This sets the vertical orientation of the simple radio device 1.

In this way, the propagation axis of the radio waves of the simple radio device 1 is automatically aligned with the simple radio device 2 of the other party.

When the alignment of simple radio device 1 is completed, simple radio device 2
is set to the alignment mode, and the control circuit 9 supplies the alignment signal S1 to the simple radio device 1, and wirelessly transmits the alignment signal S] to the simple radio device 2 side.

In such a state, the operations of the control circuit 14, field strength detection circuit 17, comparison calculation unit 14a, horizontal drive mechanism 6, and vertical drive mechanism 8 on the simple radio device 2 side are the same as in the case of the simple radio device 1 described above. , the explanation of its operation will be omitted.

By detecting the maximum electric field strength in the horizontal and vertical directions for the simple radio device 2, the propagation axis of radio waves of the simple radio device 2 is automatically aligned with the simple radio device 1 on the other side.

In this embodiment, the radio wave propagation axes of both the simple radios 1 and 2 can be automatically and correctly aligned without the need for human intervention. This can be done accurately and without error, and the simple radio equipment can be easily installed.

Note that the terminal devices to which the 50 GHz simple radio device is applied are telephones, personal computers, and workstations.

Furthermore, the present invention is not limited to the configuration shown in the above embodiments.
Various changes may be made within the scope of the claims.

(Effects of the Invention) As explained above, according to the present invention, both simple radios installed facing each other at a predetermined distance from each other can be rotated horizontally and vertically to transmit data from the other party. The direction in which the electric field strength of the alignment signal is greatest is determined, and the radio wave propagation axes of both sides are automatically aligned based on this. This has the effect of facilitating the installation of radio equipment.

[Brief explanation of the drawing]

FIG. 1 is an overall configuration diagram showing one embodiment of the present invention. In the figure, 1 and 2 are simple radios, 3 and 4 are tripods, 5,
6 is a horizontal drive mechanism, 7 and 8 are vertical drive mechanisms, 9 and 14 are control circuits, 9a and 14a are comparison calculation units, 13.18 is a memory, and 12.17 is an electric field strength detection circuit.

Claims (3)

[Claims] (1) first and second simple radios installed opposite each other at a predetermined distance to enable bidirectional transmission and reception, and provided on at least one of the first and second simple radios, the simple radio horizontal and vertical rotation operation
a vertical drive mechanism, and a received electric field in the horizontal and vertical directions of an alignment signal transmitted from the other party's simple radio by rotating the one of the simple radios in the horizontal and vertical directions by the horizontal and vertical drive mechanism; an electric field strength detection means for detecting the electric field strength; and a direction in which the electric field strength in the horizontal and vertical directions is greatest is calculated based on the electric field strengths in the horizontal and vertical directions detected by the electric field strength detection means, and An axis alignment device for a simple radio device, comprising: control means for controlling the alignment of a radio wave propagation axis with the other party's simple radio device, and controlling the horizontal/vertical drive mechanism. (2) The alignment device for a simple radio according to claim 1, wherein the first and second simple radios each include the horizontal/vertical drive mechanism, field strength detection means, and control means. (3) The simple radio device alignment device according to claim 1, wherein the first and second simple radio devices are 50 GHz radio devices.