JPH0580841B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION (Industrial Application Field) The present invention relates to a microwave lens for feeding power to a wide-angle scanning multi-beam array antenna.

(Prior Art) A conventional microwave lens of this type is shown in FIG. The microwave lens used here has a plurality of beam terminal groups connected to the transmitter and a plurality of antenna terminal groups connected to the element antennas constituting the array antenna, and is selected as the microwave signal input terminal from the transmitter. The direction of the beam emitted from the array antenna can be changed by taking advantage of the fact that the relative phase of the signals distributed and output to each antenna terminal differs depending on the position of the beam terminal. It is a pass length lens such as a Rottmann lens. In this figure, reference numeral 1 denotes a microwave lens, which is constructed using a well-known design method to include a parallel plate portion 2, an antenna terminal side boundary line 3, and antenna terminal side focusing points 4 regularly arranged on the antenna terminal side boundary line 3. -1 to 4-n, a beam terminal side boundary line 5, and beam terminal side focusing points 6-1 to 6- which are regularly arranged on this beam terminal side boundary line 5;
m, antenna terminals 7-1 to 7-n, antenna terminal side tapered lines 8-1 to 8 for converting the antenna terminals 7-1 to 7-n and the parallel plate portion 2;
-n, beam terminals 9-1 to 9-m, beam terminal side tapered lines 10-1 to 10 for converting the beam terminals 9-1 to 9-m and the parallel plate portion 2;
-m is placed. That is, the tips of the antenna terminal side tapered lines 8-1 to 8-n become the antenna terminals 7-1 to 7-n, and the tips of the beam terminal side tapered lines 10-1 to 10-m become the beam terminals 9-n.
1 to 9-m. d ₁ to dn are the maximum widths of the antenna terminal side tapered lines 8-1 to 8-n, and S ₂ to
Sn is the gap width between adjacent tapered lines on the antenna terminal side,
a ₁ to am are the maximum widths of the beam terminal side tapered lines 10-1 to 10-m, and generally d ₁ ≒ d ₂ ≒...
…≒dn, S ₂ ≒S ₃ ≒……≒Sn, a ₁ ≒a ₂ ≒……≒am
becomes. n is the number of antenna terminals, and m is the number of beam terminals.

Next, a system diagram of an antenna device constructed using the microwave lens 1 described above is shown in FIG. 4 (device 1) and FIG. 5 (device 2).

In the device 1 (FIG. 4), the antenna terminals 7-1 to 7-n of one lens 1 are each element antenna of one series of multi-beam array antenna 11 corresponding to one quadrant (90 degree scanning range). 12-1 to 12
-n, and the antenna terminals 7-1 to 7-n of the other lens 1 are connected to the antenna terminals 7-1 to 7-n of another series of multi-beam array antennas 13 corresponding to another quadrant. Feed line 15 having the same length as each element antenna 14-1 to 14-n
connected by. Further, each of the beam terminals 9-1 to 9-m of the two microwave lenses 1 is connected to the output terminals 18-1 to 8-2m of the switch circuit 17, and the input terminal 19 of the switch circuit 17 is connected to the microwave signal. It is connected to a transmitter 20 that sends out. Furthermore, a controller 21 is connected to the switch circuit 17 to control it.

In the device 2 (FIG. 5), the antenna terminals 7-1 to 7-n of the lens 1 are connected to each element antenna 12- of one series of array antenna 11 via a feed line 15 having the same length as the two-way divider 16. 1 to 12-n, and each element antenna 14-1 to 14-n of another series of array antennas 13. As in the case of the device 1, each beam terminal 9-1 to 9-m of the microwave lens 1 is connected to the output terminal 18-1 to 18-m of the switch circuit 17, and the input terminal 19 of this switch circuit 17 is It is connected to a transmitter 20 that sends out wave signals. Furthermore, a controller 21 is connected to the switch circuit 17 to control it.

(Explanation of action and operation of conventional technology) Next, the operation will be explained.

The microwave lens 1 should be designed with consideration given to minimizing variations in the frequency characteristics and scanning angle characteristics of the radiation power level from the multi-beam array antennas 11 and 13.

Therefore, m beam terminals 9-1 to 9-m,
For all combinations of n antenna terminals 7-1 to 7-n, beam terminals 9-1 to 9-
The optimal design is to minimize the variation in loss between antenna terminals 7-1 to 7-n over the entire specified frequency band.

The positions of the beam terminal side focusing points 6-1 to 6-m,
Positions of antenna terminal side focusing points 4-1 to 4-n,
Maximum width a ₁ to am of beam terminal side tapered line 10-1 to 10-m, antenna terminal side tapered line 8
The maximum widths d ₁ to dn of -1 to 8-n and the gap widths S ₂ to Sn between adjacent tapered lines on the antenna terminal side are determined in consideration of the above conditions. Now, if a radio wave is input from any of the m beam terminals 9-1 to 9-m, this radio wave will have loss characteristics and phase characteristics that depend on the shape of the lens 1, and will be transmitted to the n antenna terminals. It propagates to 7-1 to 7-n.

In the case of the device 1 (FIG. 4), the input terminal 19 of the switch circuit 17 and any one of the output terminals 18-1 to 18-2m are connected internally by the action of the controller 21, and thereby the transmitter 20 The microwave signal sent from the microwave lens 1 is input to one of the beam terminals 9-1 to 9-m of one of the two microwave lenses 1. Due to the nature of the microwave lens 1, the distribution phase to each antenna terminal changes depending on the position of the selected beam terminal. Each of the element antennas 12-1 to 12-n or 14-1 to 14-n constituting the antenna is excited with the same relative phase as the distribution phase brought between the antenna terminals, and the desired position in space is excited. Beam scanning is performed in the direction.

(Problems to be Solved by the Invention) The conventional microwave lens shown in Fig. 3 was constructed as described above, so power was fed to two lines of multi-beam array antennas in order to scan two quadrants at a wide angle. When attempting to do so, device 1 (Figure 4)
In this case, two lenses 1 are required, and device 2 (fifth
In the case of (Fig.), n two-way dividers 16 are required,
In either case, the disadvantage was that the structure had to be large-scale and expensive.

Furthermore, in the above configuration, when designing the lens 1, the gap widths S ₂ to Sn between adjacent tapered lines on the antenna terminal side are the maximum widths d 1 to d ₁ of the tapered lines 8-1 to 8-n on the antenna terminal side. dn, and in this case, the gap acts as an open load for the parallel plate section 2 as a transmission line, so radio waves are reflected at this section, and the loss characteristics and phase of the microwave lens 1 are affected. It also had the disadvantage of deteriorating characteristics.

(Means for Solving the Problems) This invention was made to eliminate the drawbacks of the conventional lens as described above, and it adds a new antenna terminal and a tapered line on the antenna terminal side to the conventional lens. By doing so, without using a two-way divider,
The present invention aims to provide a microwave lens that can feed power to multiple series of multi-beam array antennas, thereby contributing to the realization of an inexpensive and high-performance antenna device. The present invention provides a microwave lens used as a feeding circuit for a multi-beam array antenna that scans multiple quadrants at a wide angle, respectively, by arranging a plurality of beam terminal-side tapered lines on the beam terminal-side boundary line of a parallel flat plate portion, so that each beam terminal The tip of the side tapered line is used as a beam terminal, and the number of antenna terminal side tapered lines is multiple times the number of horizontal antenna elements per quadrant on the antenna terminal side boundary line of the parallel plate part, so that there is no gap between adjacent tapered lines. The antenna terminals are arranged so that the tips of the tapered lines on each antenna terminal side serve as antenna terminals.

(Embodiment of the invention) An embodiment of the invention will be described below with reference to the drawings.

FIG. 1 shows a microwave lens showing one embodiment of the present invention, in which a set of antenna terminal side focusing points 4-1
Another set of antenna terminal side focusing points 4-1b to 4- is located between a to 4-na according to the desired design method.
nb has been established. Antenna terminals 7-1a to 7
-na, 7-1b to 7-nb and antenna terminal side tapered lines 8-1a to 8-na, 8-1b to 8-nb also connect to the antenna terminal side focusing points 4-1a to 4-na, 4-1b to 4-nb corresponding to 2
We have set up a group. The antenna terminal side tapered lines 8-1a to 8-na, 8-1b to 8-nb have their maximum widths d ₁ a to dna, d ₁ b- so that there are no gaps on the antenna terminal side boundary line 3. It is arranged as dnb.

FIG. 2 is a structural diagram of an antenna device using the microwave lens described above.

Two sets of antenna terminal groups 7-1a to 7-na, 7-1b to 7-nb of the lens 1 are connected to two series of multi-beam array antennas 11 for wide-angle scanning of two quadrants via a feed line 15. 13 element antennas 12-1 to 12-n, 14-1 to 1
4-n, respectively. That is, the number of antenna terminals 7-1a to 7-na is
The number of antenna terminals 7-1b to 7-nb corresponds to the number of horizontal antenna elements of the multi-beam array antenna 11 for scanning the quadrant of the second quadrant.
This corresponds to the number of horizontal antenna elements of the multi-beam array antenna 13 for scanning the quadrant of . Similar to the conventional apparatus, a switch circuit 17 and a transmitter 20 are connected to the beam terminal side of the microwave lens 1, and a controller 21 is connected to select the terminal of the switch circuit 17.

In FIGS. 1 and 2, parts corresponding to those in FIGS. 3, 4, and 5 are given the same reference numerals.

In the conventional microwave lens, the antenna terminal side tapered lines 8-1 to 8-n in FIG.
If the maximum width d ₁ to dn and the gap width S ₂ to Sn between adjacent tapered lines on the antenna terminal side are almost equal, the microwave lens of the present invention based on the intended design method can be used. Also, the antenna terminal side tapered lines 8-1a to 8-na, 8 in FIG.
-1b to 8-nb maximum width d ₁ a to dna, d ₁ b to
dnb is the maximum width d ₁ of the tapered lines 8-1 to 8-n on the antenna terminal side in the conventional lens (Fig. 3).
It can be taken to be approximately equal to dn, and it will not deviate much from the optimal design.

Moreover, since the part of the width _S2 to Sn that was the reflective surface in the conventional lens (Fig. 3) is filled in as new antenna terminal side tapered lines 8-1b to 8-nb, reflection is reduced. By suppressing this, the loss characteristics and phase characteristics of the lens 1 are improved. The degree of characteristic improvement due to this effect is determined by the maximum width of the tapered lines 8-1 to 8-n on the antenna terminal side.
Since the degree of characteristic deterioration due to the deviation of d ₁ to dn from the optimum value is greater than that, the overall performance of the lens 1 is improved. Furthermore, as shown in FIG. 2, the lens 1 can be directly connected to the two series of array antennas 11 and 13 by the feeder line 15 of equal length, so that an additional lens 1 or The two-way divider 16 is not required, and the structure of the antenna device can be realized easily and at low cost.

(Other Embodiments of the Invention and Examples of Application to Other Applications) In the above embodiment, the array antenna connected to the lens 1 was explained as having two lines, 11 and 13. This does not apply if the lens 1 can be designed so that it can be connected to an antenna.

(Effects of the Invention) As described above, according to the present invention, one lens is provided with multiple antenna terminals as compared to the conventional device, and is configured to be directly connected to multiple series of multi-beam array antennas. The antenna device can be made inexpensively without the need for a large lens or two-way splitter, and since the part that was a radio wave reflection surface in conventional lenses is connected to the antenna terminal via a tapered line, the lens itself loss characteristics,
This has the advantage of improved phase characteristics and higher performance.

[Brief explanation of the drawing]

Fig. 1 is a block diagram showing a microwave lens according to an embodiment of the present invention, Fig. 2 is a system diagram of an antenna device constructed using the microwave lens shown in Fig. 1, and Fig. 3 is a diagram showing a conventional microwave lens. 4 and 5 are system diagrams of an antenna device configured using the conventional microwave lens shown in FIG. 3. 1... Microwave lens, 2... Parallel flat plate part,
3... Antenna terminal side boundary line, 4-1d to 4-
na, 4-1b to 4-nb...Focusing point on the antenna terminal side, 5...Boundary line on the beam terminal side, 6-1 to 6
-m... Beam terminal side focusing point, 7-1a to 7-
na, 7-1b to 7-nb...Antenna terminal, 8
-1a to 8-na, 8-1b to 8-nb...Antenna terminal side tapered line, 9-1 to 9-m...
Beam terminal, 10-1 to 10-m... Beam terminal side tapered line, n... Number of antenna terminals, m...
Number of beam terminals, d ₁ a to dna, d ₁ b to dnb...Maximum width of tapered line on antenna terminal side, a ₁ to am...
Maximum width of tapered line on beam terminal side, 11...Array antenna, 12-1 to 12-n...Element antenna, 13...Array antenna, 14-1 to 14
-n...Element antenna, 15...Feed line, 16...
...2 distributor, 17... switch circuit, 18-1 to 18-m... output terminal, 19... input terminal, 2
0...Transmitter, 21...Controller.

Claims (1)

[Claims] 1 Among microwave lenses used as feeding circuits for multi-beam antennas that scan multiple quadrants at wide angles, a microwave lens that uses a system in which a group of beam terminals connected to a transmitter via a switch circuit is shared among multiple multi-beam antennas. In a wave lens, the number of antenna terminals that is multiple times the number of antenna elements constituting the multi-beam antenna for each quadrant is placed on the boundary line on the antenna terminal side for the antenna elements in the same order counting from the end of each quadrant. A microwave lens characterized by being arranged adjacent to each other by the number of multi-beam antennas.