JP3623211B2 - Measuring device using radio wave reflector - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a measuring apparatus using a radio wave reflector made up of a radio wave reflector produced using a Luneberg lens and a scanning side device.
[0002]
[Prior art]
Conventionally, as a method for detecting a moving object, a method is generally employed in which a moving object is equipped with a radar reflector, the moving object is detected from the reflected wave, and positioning is performed. In this case, the corner reflector is the most widely used as a radar reflector, but recently, as a reflector having a much larger effective reflection area than that of the corner reflector and having a wide angle reflection characteristic, the Luneberg lens is used. There is a reflector with a radio wave reflector attached to the surface.
[0003]
In the reflector using the Luneberg lens, the electromagnetic wave (incident wave) incident on the Luneberg lens is focused on the intersection with the surface opposite to the incident wave by the radio wave reflector attached to the surface of the Luneberg lens. And is reflected by a radio wave reflecting material such as metal attached to the surface. The reflected wave is simply reflected in the incident direction.
[0004]
On the other hand, in the conventional navigation technology, the amplitude, phase, etc., based on radio waves emitted from other stations, such as artificial satellites and ground stations, as radio sources that emit radio waves other than the mobile body that is the local station. There is a type of radio navigation that uses GPS to guide the moving object.
[0005]
Alternatively, as radio navigation using a reflected wave reflected by a radio wave reflector, a radio wave emitted from the mobile body itself is used as an aid to the radio navigation. As described above, in any of the types, the distance from a plurality of reference points by receiving radio waves generated by a radio wave source that emits radio waves other than a moving object such as an artificial satellite or a ground station in the conventional navigation technology. Information is calculated and position is measured.
[0006]
As another type of radio navigation, the reflected signal reflected by each individual radio wave reflector is individually determined, and the distance between the mobile body and each of the individual radio wave reflectors is determined. Some types are configured to measure the position of or to guide the moving body on the path.
[0007]
[Problems to be solved by the invention]
In this way, the Luneberg lens with a radio wave reflector attached is simply used as a radar reflector, but it is desired to use this as a radio wave reflection source to position a mobile object and guide it to the path. There was a request.
[0008]
Accordingly, the inventors manufactured a radio wave reflector using a Luneberg lens and provided additional information such as an identification code to the reflected wave from the radio wave reflector, or the direction of the reflected wave in an arbitrary direction. In addition to forming a radio wave reflector using a Luneberg lens to which a means such as directing is added, a measuring device is constituted by a scanning side device that receives a reflected wave from the radio wave reflector, and this measuring device is used. Invented a navigation method for moving objects.
[0009]
Furthermore, the mobile body itself transmits radio waves without using an external radio wave source, and guides the mobile body along the path using the reflected wave signal from the radio wave reflector using the Luneberg lens. Invented a navigation method for positioning.
[0010]
[Means for Solving the Problems]
According to the first aspect of the present invention, the Luneberg lens and a reflector that reflects the radio wave incident on the Luneberg lens are arranged apart from each other on the surface of the Luneberg lens. A radio wave reflector comprising a reflector having a constant size, a means for rotating a Luneberg lens in which the reflector is disposed, a means for receiving and scanning a reflected wave from the radio wave reflector, and a radio wave reflection Means for measuring the reflection cross-sectional area of the reflected wave from the body with respect to time as a reflection characteristic, and receiving a reflected wave from a radio wave reflector that is amplitude-modulated at a constant frequency in time, and this received reflection A measuring device using a radio wave reflector, characterized by comprising a scanning side device having means for measuring a reflected wave amplitude-modulated at a frequency constant from the wave That.
[0011]
The invention according to claim 2 is a Luneberg lens, a reflector that is disposed on the surface of the Luneberg lens and reflects radio waves incident on the Luneberg lens, and the spacing and the size of the reflectors are arranged roughly. And a means for rotating the Luneberg lens, a means for receiving and scanning the reflected wave from the wave reflector, and a change in the reflection cross section of the reflected wave from the wave reflector with respect to time. A means for measuring as a reflection characteristic and a reflected wave from a radio wave reflector that is amplitude-modulated with a time-varying frequency, and a reflected wave that is amplitude-modulated with a time-varying frequency from the received reflected wave A measuring device using a radio wave reflector.
[0012]
The invention according to claim 3 rotates the Luneberg lens, the reflector that is disposed on the surface of the Luneberg lens, reflects the radio wave incident on the Luneberg lens, and the Luneberg lens on which the reflector is arranged. A radio wave reflector composed of means, and the radio wave reflector is arranged so that the reflector is different with respect to the latitudinal direction of the rotation axis of the Luneberg lens, and receives and scans the reflected wave from the radio wave reflector. , Comprising means for measuring a change in reflection cross section of a reflected wave from a radio wave reflector with respect to time as a reflection characteristic, and a scanning side device having means for measuring information on a latitudinal direction and information from a reflected wave. Is a measuring device using a radio wave reflector.
[0013]
The invention according to a fourth aspect is the invention according to any one of the first to second aspects, wherein the radio wave reflector is arranged such that the reflector is different from the latitudinal direction of the rotation axis of the Luneberg lens, and the scanning side The apparatus is a measuring apparatus using a radio wave reflector, characterized by having means for measuring information from latitude and information from the reflected wave.
[0014]
The invention according to claim 5 is the invention according to each of claims 1 to 4,
Measurement using a radio wave reflector characterized in that identification information for identifying the radio wave reflector is set on the reflector surface, and the scanning side device has means for identifying the identification information from the received reflected wave. Device.
[0015]
DETAILED DESCRIPTION OF THE INVENTION
[Example 1]
A first embodiment of the present invention will be described with reference to FIGS.
FIG. 1 is an explanatory diagram showing the reflection principle of a radio wave reflector 1 using a basic Luneberg lens 2. A reflector 3 that reflects radio waves is disposed at a focal point 4 of the Luneberg lens 2, and the radio wave reflector 1. It is explanatory drawing which shows the case where it comprises. FIG. 2 is an explanatory diagram showing a case where the radio wave reflector 1 using the Luneberg lens 2 is rotated by the rotation shaft 5.
[0016]
[Example 1]
First, the reflection principle of the radio wave reflector 1 using the Luneberg lens 2 and the application field of a measuring apparatus using this principle will be described with reference to FIGS.
As shown in FIG. 1, the radio wave (incident wave 6) incident on the Luneberg lens 2 has a trajectory bent in the Luneberg lens 2 and forms a focal point 4 on the surface of the Luneberg lens facing the incident direction. Therefore, when the reflector 3 that reflects radio waves is disposed at the focal point 4, the incident wave 6 is reflected by the reflector 3, and the reflected wave 7 passes through the Luneberg lens 2 while bending the orbit, and the incident wave 6 Reflects in the flying direction. Therefore, a radio wave reflector 1 having a structure in which the reflector 3 is arranged on the surface of the Luneberg lens 2 can be considered.
[0017]
Next, as shown in FIGS. 1 and 2, when the radio wave reflector 1 is rotated about the rotation axis 5, an incident wave that is incident when the position of the reflector 3 is separated from the focal point 4 of the Luneberg lens 2 is used. All of 6a passes through the Luneberg lens 2 and does not output the reflected wave 7 as shown in FIG. Accordingly, all the radio waves other than the incident wave 6 incident when the reflector 3 is located at the focal point 4 of the Luneberg lens 2 are transmitted waves 8 and are transmitted through the Luneberg lens 2. Therefore, by rotating the Luneberg lens 2 about the rotation axis 5 as indicated by the arrow 10, reflection and transmission of radio waves incident on the Luneberg lens 2 can be switched.
[0018]
Therefore, by using such a principle, if the reflector 3 is arranged apart from the surface of the Luneberg lens 2 and the Luneberg lens 2 is rotated by the rotation shaft 5, the reflection cross-sectional area of the reflected wave 7 is obtained. Change over time. If the arrangement state of the reflector 3 is made to correspond to the binarized information, when the incident wave 6 is a continuous radio wave, an amplitude-modulated reflected wave 7 can be generated. On the side where the wave 7 is received and scanned (scanning side device), it is possible to acquire such information. When the arrangement interval and size of the reflectors 3 arranged in the Luneberg lens 2 are made constant, the reflected wave received by the scanning side device becomes a signal whose amplitude is modulated at a frequency that is constant in time.
[0019]
Therefore, the radio wave reflector 1 is configured by disposing a reflector 3 having a slit or a strip-like reflector 3 as binarized information such as a barcode on the surface of the Luneberg lens 2. At the same time, the radio wave reflector 1 is rotated by the rotating shaft 5. On the other hand, if the scanning side device is provided with means for receiving and scanning the reflected wave 7 and means for measuring the change in the reflection cross section of the reflected wave 7 from the radio wave reflector 1 with respect to time as a reflection characteristic, reflection will occur. An identification code based on the slit or the identification code from the reflector 3 arranged in a strip shape can be obtained from the wave 7. Therefore, a measuring apparatus capable of acquiring information set in the reflected wave 7 by the radio wave reflector 1 using the Luneberg lens 2 and the scanning side apparatus is obtained.
[0020]
[Example 2]
In the second embodiment of the present invention, the radio wave reflector 1 is formed in a structure in which n reflectors 3 are arranged uniformly on the surface of the Luneberg lens 2, and the radio wave reflector 1 is rotated N It is an Example at the time of rotating.
[0021]
In the case of the radio wave reflector 1 having such a structure, the radio wave (incident wave 6) incident on the Luneberg lens 2 is repeatedly reflected and transmitted at a frequency of nN. Therefore, when the width and interval of the reflectors 3 are arranged densely based on information, the frequency nN can be changed and reflected and transmitted. Therefore, the reflected wave 7 received by the scanning side device becomes an amplitude-modulated signal at a frequency that changes with time, and if this signal (reflected wave) is scanned, the reflected wave 7 is arranged in a coarse and dense manner. It becomes a measuring device that can acquire information based on the reflector.
[0022]
[Example 3]
A third embodiment of the present invention will be described with reference to FIG.
FIG. 3 shows an angle θ formed by the rotation axis 5 of the Luneberg lens 2 and the direction of the incident wave 6.₁And θ₂It is explanatory drawing which shows the case where the reflector 3 is arrange | positioned at the Luneberg lens 2 so that it may differ.
[0023]
As shown in FIGS. 3A and 3B, an angle θ formed by the rotation axis 5 of the Luneberg lens 2 and the direction of the incident wave 6.₁Or the angle θ₂The radio wave reflector 1 is configured by arranging the reflector 3 at a position where The radio wave reflector 1 is rotated n times per second by the rotation shaft 5. Then, the focal point 4 of the Luneberg lens 2 moves as indicated by a locus 9.
[0024]
Reflector for the entire circumference of the locus by utilizing the fact that each locus 9 is different with respect to the angle formed by the rotation axis 5 and the incident wave 6, that is, the latitudinal direction of the Luneberg lens 2 with respect to the rotation axis 5. The radio wave reflector 1 is configured so that the ratio of installing 3 differs. Then, the scanning side device that receives and scans the reflected wave 6 from the radio wave reflector 1 makes an angle θ formed between the rotating shaft 5 and the incident wave 6.₁Or θ₂If a means for measuring the reflection characteristic is provided, a measuring device capable of measuring angle information can be obtained.
[0025]
Similarly, the number of the reflectors 3 arranged on the surface of the Luneberg lens 2 is changed with respect to the angle formed by the rotation axis 5 and the incident wave 6, or the position, size, interval, etc. of the reflector 3. On the other hand, the scanning-side device that receives and scans the reflected wave 6 from the radio wave reflector 1 has information on the angle of the reflected wave 6 of the radio wave reflector 1. If a means for analyzing and measuring is provided, a measuring device capable of obtaining information on these angles can be obtained.
[0026]
[Example 4]
A fourth embodiment of the present invention will be described with reference to FIG.
FIG. 4 is an explanatory view showing a case where two points on the surface of the Luneberg lens 2 are connected by the waveguide 11.
[0027]
As shown in FIG. 4, when two points on the surface of the Luneberg lens 2 are connected by the waveguide 11, the focal point 4 is formed at a point where one end (incident end) 12 of the waveguide 11 is in contact with the Luneberg lens 2. The incident wave 6 propagates through the waveguide 11 from here and is output to a point where the other end (reflection end) 13 of the waveguide 11 is in contact with the Luneberg lens 2, and a reflected wave connecting the focal point 4 to this point. The radio wave reflector 1 capable of generating 7 is formed. Therefore, the radio wave emitted from the direction of the incident wave 6 can generate the reflected wave 7 in a direction different from the direction in which the incident wave travels through the radio wave reflector. That is, a receiving device (not shown) in the direction of the reflected wave 7 can receive radio waves from a transmitting device (not shown) in the incoming direction of the incident wave 6.
[0028]
Thus, a radio wave reflector made up of a Luneberg lens and a waveguide connected to the surface of the Luneberg lens with two points separated from each other as an incident end and a reflection end, and the radio wave reflector If the measuring device is constituted by a device having means for receiving radio waves from the incident end and means for receiving reflected waves output from the reflection end, it can be in any direction depending on the installation direction of the transducer connected by the waveguide. A reflected wave can be generated.
[0029]
Further, instead of the waveguide 11, a pair of transducers connected by a cable connecting two points separated from each other is disposed on the surface of the Luneberg lens 2, and one point of this cable is arranged. Even if the radio wave reflector 1 is configured with the incident end of the incident wave 6 and the other point as the reflection end from which the reflected wave 7 is output, as in the case described above, it can be arbitrarily determined depending on the installation direction of the converter connected by the cable. A reflected wave can be generated in the direction.
[0030]
[Example 5]
A fifth embodiment of the present invention will be described with reference to FIGS. In the fifth embodiment, the scanning side device that receives and scans the reflected wave 7 from the radio wave reflector 1 using the Luneberg lens 2 described in the first to fourth embodiments is used for navigation of the moving body 21. This is an embodiment when used.
[0031]
FIG. 5 is an explanatory diagram showing the basic principle when the radio wave reflector 1 using the Luneberg lens 2 is used for navigation of the mobile body 21, and FIG. 6 is a reference radio wave reflector R₁24, reference radio wave reflector R₂25 is a reference wave reflector R_bFIG. 7 and 8 are time chart diagrams of a group of received signals from the radio wave reflector 1 using the Luneberg lens 2, FIG. 7 is a time chart diagram showing a case where the moving body 21 is on the path 22, and FIG. FIG. 6 is a time chart showing a case where a moving body 21 is out of a course 22; FIG. 9 is an explanatory diagram for measuring the relative position of the moving body 21.
[0032]
As shown in FIGS. 1 to 2, the reflector 3 is disposed on the surface of the Luneberg lens 2, and the radio wave (incident wave 6) incident on the Luneberg lens 2 is reflected by the reflector 3. The radio wave reflector 1 configured as described above is formed and used as a reference radio wave reflector 23 and reference radio wave reflectors 24 and 25 described later. In addition, the mobile body 21 is a radio wave source that emits radio waves, receives and scans the reflected wave 7 from the reference radio wave reflector 23 and the reference radio wave reflectors 24 and 25, respectively, and various information that the reflected wave 7 has. A scanning side device having means for measuring and analyzing.
[0033]
As shown in FIG. 5, reference numeral 20 denotes a route plane including the route 22, and a vertical plane including the route 22 of the moving body 21 is assumed. The reference radio wave reflector 23 is installed on the course plane 20 including the course 22 of the moving body 21. Assuming a horizontal plane orthogonal to the path plane 20 including the path 22 of the moving body 21, two reference radio wave reflectors R are provided.₁24 and reference radio wave reflector R₂25 is a reference wave reflector R_bA fixed distance L from the position of the course plane 20 including the course 22 where the path 23 is installed._aA fixed distance L in the horizontal direction from each other at the point O on the route path 20 that is separated._bIt is installed at a separated position. Two reference radio wave reflectors R₁24 and reference radio wave reflector R₂25 constitutes a set.
[0034]
Here, a case where the moving body 21 is guided along the route 22 will be described.
First, as shown in FIG. 7, when the mobile body 21 transmits a standard radio wave, this transmission signal is transmitted to the reference radio wave reflector R._b23, reference radio wave reflector R₁24, reference radio wave reflector R₂25 respectively. At this time, as shown in FIG. 6, when the moving body 21 is on the path 22, the moving body 21 and the reference radio wave reflector R₁24 and reference radio wave reflector R₂As shown in FIG. 7, the reference radio wave reflector R received by the scanning device provided in the moving body 21 is equal to each other._bThe reflected wave (received signal) from 23 has a delay time T_bReceived by two reference radio wave reflectors R₁24 and reference radio wave reflector R₂The reflected wave from 25 has a delay time T_rAre simultaneously received, and there is one reference signal group. Therefore, on the mobile body 21 side, it can be confirmed that the mobile station 21 is positioned on the route 22 by recognizing that the arriving reference signal groups match.
[0035]
On the other hand, as shown in FIG. 6, when the moving body 21a is out of the course 22, the detached moving body 21a and the reference radio wave reflector R₁24 and reference radio wave reflector R₂Since the distance from each other is different, the two reference reflectors R₁24, reference radio wave reflector R₂As shown in FIG. 8, the reflected wave (received signal) received from 25 has a delay time T_r1And T_r2In addition, they are separately received in close proximity to each other to form a reference signal group. Therefore, on the side of the moving body 21a that is off, each delay time T in the reference signal group._r1, T_r2Can be detected, the deviation from the course 22 can be detected. Therefore, the moving body 21a can be guided on the path 22 by performing control so that the delay time difference between the received signals in the reference signal group is minimized on the moving body 21a side.
[0036]
Therefore, when radio waves (transmission signals) are transmitted from the mobile body 21, each radio wave reflector (reference radio wave reflector R) is transmitted._b23, reference radio wave reflector R₁24 and reference radio wave reflector R₂25), the reflected wave (the reference signal and the reference signal group) is received by the scanning device provided in the moving body 21. At this time, the delay time of the reference signal from the reference radio wave reflector 23 is set to the moving body 21 located on the path 22._bThe two reference radio wave reflectors R forming a pair₁24 and reference radio wave reflector R₂25 and reference wave reflector R_bOn a plane made up of a total of three radio wave reflectors 23, the mobile body 21 is a reference radio wave reflector R._b23 to cT_b/ 2 reference radio wave reflectors R which are apart and form a pair₁24 and reference radio wave reflector R₂CT from 25 each_rSince it is at the position of / 2, the two-dimensional relative position of the moving body 21 can be calculated by the calculation means of the scanning side device.
[0037]
In this way, the radio wave reflector formed by arranging the reflector that reflects radio waves on the surface of the Luneberg lens 2 is referred to as the reference radio wave reflector R._b23 and reference radio wave reflector R₁24, the reference radio wave reflector R on the path plane including the path of the moving body 21_b23, this reference radio wave reflector R_bTwo reference radio wave reflectors R that form a pair at a point on the path plane that is a fixed distance away from the path 23 and that are perpendicular to the path plane and that are separated by an equal distance from the path plane.₁24 and reference radio wave reflector R₂25, a standard radio wave is transmitted from the mobile body 21, and a reference radio wave reflector R of the transmitted radio wave is transmitted._b2 reference wave reflectors R that form a pair with a reflected wave (standard signal) from 23₁24, R₂By receiving the reflected waves (reference signals) reflected by 25 and measuring their delay times, it is possible to detect a deviation between the two-dimensional position of the moving body and the course.
[0038]
Further, as shown in FIG. 9, the reference signal received on the mobile body 21 side is a delay time T._b, Reference signal is delay time T_r, Reference radio wave reflector R_bThe distance from 23 is cT_b/ 2, Reference radio wave reflector R₁24 and reference radio wave reflector R₂The reference signal from 25 is cT_r/ 2, so three radio wave reflectors (reference radio wave reflector R_b23, two reference radio wave reflectors R₁24 and reference radio wave reflector R₂25) and the reference radio wave reflector R_bThe cosine cos θ of the angle formed by the line connecting 23 and the moving body 21 is
cosθ = ((cTb / 2)²+ L_a ²− (CT_r/ 2)²+ L_b ²) / CT_bL_a
Can be calculated as
[0039]
Therefore, the reference radio wave reflector R_b23, the relative position is (cT_b/ 2) Cosθ ± (cT_b/ 2) The relative position of sinθ is calculated. Here, in the case of a radio wave reflector installed on the ground surface, the above-mentioned-term usually means the underground, so a simple logical expression (cT_b/ 2) Since two solutions can be specified as one when sin θ> 0, the relative position of the moving body 21 can be measured. Three radio wave reflectors (reference radio wave reflector R_b23, two reference radio wave reflectors R₁24 and reference radio wave reflector R₂In the case where each of 25) includes means for rotating, a reflected wave subjected to amplitude modulation is obtained.
[0040]
Similarly, the reference radio wave reflector R_b23 are two reference radio wave reflectors R that form a pair with each other₁24 and reference radio wave reflector R₂When it is installed nearer than 25, T_b<T_rA similar principle can be applied.
[0044]
In this way, the moving body 21 moves along the reference path, and the moving body 21 is the reference radio wave reflector R.₁24 and reference radio wave reflector R₂The reflected wave from 25 is received, the delay time is measured, respectively, and the moving body 21 can be guided so that the measured delay time difference is minimized.
[0041]
Reference radio wave reflector R_bIn place of 23, a reference radio wave reflector composed of two reference radio wave reflectors forming a new set, that is, two sets of reference radio wave reflectors (one set is constituted by two reference radio wave reflectors) is installed. By installing a plurality of sets of reference radio wave reflectors, it is possible to detect a deviation between the three-dimensional position of the moving body and the path based on the same principle.
[0042]
[Example 6]
A sixth embodiment of the present invention will be described with reference to FIG.
FIG. 10 shows three reference reflectors R₁24, reference radio wave reflector R₂25 and reference radio wave reflector R₃It is explanatory drawing which shows the case where 26 is installed planarly.
[0043]
In FIG. 10, the reference radio wave reflector R_b23 is installed on the path 22 of the moving body 21, and this reference wave reflector R_b23, a certain distance from each other, orthogonal to the path 22, and each of the three reference radio wave reflectors R₁24, R₂25, R₃Assume a plane 30 constituted by 26. And on this plane 30, and each reference wave reflector R₁24, R₂25, R₃The three reference radio wave reflectors R are positioned at the same distance from the point O, that is, at the same distance from the point O at which the arrival delay times of the three reference signals received by the mobile body 21 are equal.₁24, R₂25, R₃26 is installed.
[0044]
Therefore, when a standard radio wave is transmitted from the mobile body 21, each of the radio waves has three reference radio wave reflectors R.₁24, R₂25, R₃26, and is received by the scanning device of the moving body 21. By measuring the delay times of the three received reflected waves (reference signals) and controlling the moving body 21 so that the delay time difference is minimized, the moving body 21 is guided along the path 22. It becomes possible.
[0045]
In this way, a radio wave reflector formed by arranging a reflector that reflects radio waves on the surface of the Luneberg lens 2 is used as a reference radio wave reflector and a reference radio wave reflector, and the reference radio wave reflection is reflected on the path 22 of the moving body 21. This standard radio wave reflector R_bThree reference radio wave reflectors R which are at least a pair spaced apart from each other by an equal distance from the intersection of the plane and the path on a plane perpendicular to the path 22 of the moving body 21 and spaced by a certain distance from the path 23.₁24, R₂25, R₃26, a standard radio wave is transmitted from the mobile body 21, and a reference radio wave reflector R of the transmitted signal is transmitted._b23 and reference radio wave reflector R₁24, R₂25, R₃The difference between the position of the moving body 21 and the course can be detected by receiving the reflected waves reflected from each of 26 and measuring their delay times.
[0046]
Furthermore, since the moving body is guided so that the delay times at which at least three reference signals arrive are equal, the position of the moving body 21 can be calculated from the delay times of the three reference signals. Furthermore, if another reference radio wave reflector is installed so as not to be located on the same plane 30, the three-dimensional position of the moving body 21 can be measured.
[0047]
In this way, instead of the standard radio wave reflector, two reference radio wave reflectors that form a new set are installed, or a plurality of reference radio wave reflectors that form a set are installed, so that the three-dimensional structure of the moving object Deviation between a specific position and a course can be detected. In addition, the moving body can be guided, and the three-dimensional position of the moving body can be measured.
[0048]
Reference radio wave reflector R_b23 and reference radio wave reflector R₁24, R₂25, R₃If means for rotating 26 is provided, the reflected wave is amplitude-modulated based on information set in the reflector 3 arranged in the Luneberg lens 2. Therefore, the scanning side device of the moving body 21 can receive this reflected wave and acquire information.
[0049]
[Example 7]
A seventh embodiment of the present invention will be described with reference to FIGS.
FIG. 11 shows three reference radio wave reflectors A (x_a, Y_a, Z_a), B (x_b, Y_b, Z_b), C (x_c, Y_c, Z_c), And FIG. 12 is a time chart for the case shown in FIG. 11, which are arranged sufficiently apart so that the reflected waves from the three reference radio wave reflectors A, B, C can be identified. Shows the case. FIG. 13 is a time chart for the case shown in FIG. 11 and shows a case where the reflection and transmission timings of the three reference radio wave reflectors A, B and C are set to be different.
[0050]
In the seventh embodiment, when three reference radio wave reflectors A to C are installed and the position of the moving body 21 is measured, as shown in FIG. 11, three reference radio waves that are not located on the same plane are used. Reflectors A, B, and C are installed. As shown in FIGS. 1 and 2, each of the reference radio wave reflectors A to C is a radio wave reflector 1 formed by arranging a reflector 3 on a Luneberg lens 2. In each of the reference radio wave reflectors A, B, and C, individual position information and identification information for identifying each of the reference radio wave reflectors A, B, and C are set.
[0051]
Therefore, when a standard radio wave (transmission signal) is transmitted from the mobile body 21, the transmission signal is reflected by the three reference radio wave reflectors A, B, and C, respectively. The reflected wave is modulated by information. The modulated reflected wave is received by the scanning side device provided in the moving body 21.
[0052]
At this time, if there is a sufficient distance difference between each of the reference radio wave reflectors A, B, and C, as shown in FIG. 12, the received signals received by the scanning device of the mobile body 21 are delayed times Ta and Tb, respectively. , Tc can be individually identified and received. Therefore, the scanning device of the mobile body 21 can calculate the two-dimensional position of the mobile body itself from the delay times Ta, Tb, and Tc of the reflected waves from the three reference radio wave reflectors A, B, and C, respectively. I can do it.
[0053]
Thus, a radio wave reflector formed by arranging a reflector that reflects radio waves on the surface of the Luneberg lens is used as a reference radio wave reflector, and at least three reference radio wave reflectors are provided. Position information is set for each of the reflectors A, B, and C, a standard radio wave is transmitted from the mobile body 21, and a reflected wave (reference signal) modulated by the position information is received by the mobile body 21. The two-dimensional position of the moving body 21 can be measured from the wave delay times Ta, Tb, and Tc.
[0054]
Further, since identification information for identifying the reference radio wave reflector is set for each of the reference radio wave reflectors, the two-dimensional position information of the mobile body 21, the identification information of the reference radio wave reflector, and the like can be acquired. .
[0055]
Further, since the terrain information is added to the reflected wave from the reference radio wave reflector, and the three-dimensional position of the moving body 21 is measured from the reflected wave and the terrain information, the area where the moving body 21 is moving Can be grasped three-dimensionally.
[0056]
Here, when there is not a sufficient distance difference between each of the reference radio wave reflectors A, B, and C, the intervals of the delay times Ta, Tb, and Tc are reduced. As a result, the reflected waves from the reference wave reflectors A, B, and C cannot be individually identified and received.
[0057]
Therefore, in this case, a radio wave reflector in which the arrangement location of the reflector 3 arranged in the Luneberg lens 2 shown in FIG. 1 is changed to produce three reference radio wave reflectors A, as shown in FIG. Three reference radio wave reflectors A, B, and C are set so that reflection and transmission timings from B and C are different from each other.
[0058]
Next, when a standard radio wave is transmitted from the scanning side device of the moving body 21, this transmission signal is reflected by each of the individual reference radio wave reflectors A to C. Then, as shown in FIG. 13, each reflected wave (each reference signal) from each of the reference radio wave reflectors A to C can be individually identified and received as delay times Ta, Tb, and Tc. Therefore, in the scanning device of the moving body 21, the reflected waves from the three reference radio wave reflectors A to C can be individually identified and received at the delay times Ta, Tb, and Tc. Therefore, the position of the moving body 21 can be measured from the delay times Ta, Tb, and Tc.
[0059]
As described above, since the reflection and transmission timings of the at least three reference radio wave reflectors A to C are set to be different from each other, even if the distance between the three reference radio wave reflectors A to C is not sufficient. The delay times of the reflected waves from the three reference radio wave reflectors A to C can be individually identified and received. Therefore, the position information of the moving body 21 can be obtained.
[0060]
Furthermore, since the reference radio wave reflectors A to C have means for rotating, more information can be added to the reflected wave by rotating the radio wave reflector.
[0061]
[Example 8]
An eighth embodiment of the present invention will be described with reference to FIG.
FIG. 14 is an explanatory diagram showing a case where the route 22 is set on a route plane 40 that passes through the centers of the two radio wave reflectors 41 and 42 (becomes the route 22).
[0062]
The two radio wave reflectors 41 and 42 are radio wave reflectors using Luneberg lenses, as in the above embodiments. The two radio wave reflectors 41 and 42 are equidistant L in a direction perpendicular to the course plane 40 including the course 22._bThe radio wave reflectors 41 and 42 are installed at different positions and are set to reflect radio waves at different frequencies or timings. Reference numerals 43 and 44 denote reflection patterns of the radio wave reflector 41 and the radio wave reflector 42, respectively. Reference numerals 45 and 46 denote the maximum reflection cross-sectional areas of the reflection patterns 43 and 44, respectively.
[0063]
Therefore, the standard radio waves (transmission signals) transmitted from the scanning device of the moving body 21 are reflected by the radio wave reflectors 41 and 42, respectively. This reflected wave is received by the scanning side device of the moving body 21, and the signal intensity of the reflected wave having a different frequency or timing is individually measured.
[0064]
The point where the signal intensities of the two reflected waves coincide constitute the path 22. Therefore, if the moving body 21 is controlled so that the signal strengths of the two reflected waves coincide with each other, the moving body 21 is guided along the path 22 on the path plane 40 passing through the centers of the two radio wave reflectors 41 and 42. I can do it. Further, since a set of points at which the ratio of the signal strengths of the two reflected waves is constant becomes a hyperbola, it is possible to set a course by hyperbola navigation.
[0065]
In this way, a radio wave reflector is placed on the surface of the Luneberg lens so that reflection and transmission are repeated at a plurality of different frequencies or timings. Transmit and receive two reflected waves modulated at different frequencies or timings from a plurality of radio wave reflectors on the mobile body side, and control the mobile body so that the ratio of the signal strengths of the plurality of received signals is constant. Therefore, the path of the moving body can be set by the two reference radio wave reflectors. Further, it is possible to guide the moving body along the set route.
[0066]
Furthermore, since the reference radio wave reflector has means for rotating, more information can be added to the reflected wave by rotating the radio wave reflector.
[0067]
【The invention's effect】
According to the first aspect of the present invention, the Luneberg lens and a reflector that reflects the radio wave incident on the Luneberg lens are arranged apart from each other on the surface of the Luneberg lens. A radio wave reflector comprising a reflector having a constant size, a means for rotating a Luneberg lens on which the reflector is disposed, a means for receiving and scanning a reflected wave from the radio wave reflector, and a radio wave reflection Means for measuring the reflection cross-sectional area of the reflected wave from the body with respect to time as a reflection characteristic, and receiving a reflected wave from a radio wave reflector that is amplitude-modulated at a constant frequency in time, and this received reflection Since it is a measuring device using a radio wave reflector composed of a scanning side device having means for measuring a reflected wave amplitude-modulated with a frequency that is constant in time from a wave, radio wave reflection Side need not itself transmitting a radio wave as a radio wave source, it is possible to provide additional information on the scanning side. In addition, on the radio wave reflector side, radio waves can be transmitted and received in an arbitrary direction and a lot of other information can be added. Further, the arrangement interval and size of the reflectors are arranged constant, while the scanning device receives the reflected wave from the radio wave reflector that is amplitude-modulated at a frequency that is constant in time and receives the received wave. Since the means for measuring the reflected wave amplitude-modulated from the reflected wave at a frequency that is constant in time is provided, the information set in the reflected wave can be acquired by the radio wave reflector and the scanning side device. .
[0068]
The invention according to claim 2 is a Luneberg lens, a reflector that is disposed on the surface of the Luneberg lens and reflects radio waves incident on the Luneberg lens, and the spacing and the size of the reflectors are arranged roughly. And a means for rotating the Luneberg lens, a means for receiving and scanning the reflected wave from the wave reflector, and a change in reflection cross section of the reflected wave from the wave reflector with respect to time. A means for measuring as a reflection characteristic and a reflected wave from a radio wave reflector that is amplitude-modulated with a time-varying frequency, and a reflected wave that is amplitude-modulated with a time-varying frequency from the received reflected wave Therefore, the information set in the reflected wave by the radio wave reflector and the scanning device is used. It is possible to get. Further, the radio wave reflector side does not need to transmit radio waves as a radio wave source, and can provide additional information to the scanning side. On the radio wave reflector side, radio waves can be transmitted and received in an arbitrary direction, and a lot of other information can be added. Furthermore, since the intervals and sizes of the reflectors are arranged roughly, identification information based on the reflectors can be acquired.
[0069]
The invention according to claim 3 rotates the Luneberg lens, the reflector disposed on the surface of the Luneberg lens and reflecting the radio wave incident on the Luneberg lens, and the Luneberg lens on which the reflector is arranged. A radio wave reflector composed of means, and the radio wave reflector is arranged so that the reflector is different with respect to the latitudinal direction of the rotation axis of the Luneberg lens, and receives and scans the reflected wave from the radio wave reflector. A radio wave reflector comprising: means for measuring a change in reflection cross section of a reflected wave from a radio wave reflector with respect to time as a reflection characteristic; and a scanning side device having means for measuring information on a latitudinal direction and information from the reflected wave Therefore, it is not necessary for the radio wave reflector side to transmit radio waves as a radio wave source, and it is possible to provide additional information to the scanning side. In addition, on the radio wave reflector side, radio waves can be transmitted and received in an arbitrary direction and a lot of other information can be added. Further, the arrangement interval and size of the reflectors are arranged constant, while the scanning device receives the reflected wave from the radio wave reflector that is amplitude-modulated at a frequency that is constant in time and receives the received wave. Since the means for measuring the reflected wave amplitude-modulated from the reflected wave at a frequency that is constant in time is provided, the information set in the reflected wave can be acquired by the radio wave reflector and the scanning side device. .
[0070]
In addition, since the scanning side device has means for measuring information on the latitude direction and information from the reflected wave, angle information can be measured. Similarly, the number of reflectors arranged on the surface of the Luneberg lens is changed to a different angle with respect to the latitudinal direction of the rotation axis, or the radio wave reflector has a structure in which the position, size, interval, etc. of the reflectors are changed. The scanning side device that receives and scans the reflected wave from the radio wave reflector includes means for analyzing and measuring information about the angle of the reflected wave of the radio wave reflector. It is possible to obtain information on the angle of
[0071]
The invention according to a fourth aspect is the invention according to any one of the first to second aspects, wherein the radio wave reflector is arranged such that the reflector is different from the latitudinal direction of the rotation axis of the Luneberg lens, and the scanning side Since the apparatus is a measuring apparatus using a radio wave reflector comprising a scanning side device having means for measuring information from latitude information and reflected waves, the radio wave reflector and the scanning side device provide the above claims. There exists an effect similar to the invention of Claim 3.
[0072]
According to a fifth aspect of the present invention, in the first to fourth aspects of the present invention, identification information for identifying the radio wave reflector is set on the reflector surface, and the scanning side device receives the received reflection. Since it is a measuring device using a radio wave reflector comprising a scanning side device having means for identifying identification information from waves, the same effects as the inventions of the first to fourth aspects are obtained.
[Brief description of the drawings]
FIG. 1 shows the first and second embodiments of the present invention, and is an explanatory view showing the reflection principle of a radio wave reflector 1 using a basic Luneberg lens 2, and a reflector 3 that reflects radio waves; Is an explanatory view showing a case where the radio wave reflector 1 is configured by being arranged at the focal point 4 of the Luneberg lens 2.
FIGS. 2A and 2B illustrate first and second embodiments of the present invention and are explanatory diagrams illustrating a case where a radio wave reflector 1 using a Luneberg lens 2 is rotated by a rotation shaft 5; FIG.
FIG. 3 shows a third embodiment of the present invention, in which the angle θ formed by the rotation axis 5 of the Luneberg lens 2 and the direction of the incident wave 6 is shown.₁And θ₂It is explanatory drawing at the time of arrange | positioning the reflector 3 so that it may differ.
FIG. 4 shows a fourth embodiment of the present invention and is an explanatory view showing a case where two points on the surface of a Luneberg lens 2 are connected and arranged by a waveguide 11;
FIG. 5 shows a fifth embodiment of the present invention, and is an explanatory diagram showing a basic principle when a radio wave reflector 1 using a Luneberg lens 2 is used for navigation of a moving body.
FIG. 6 shows a fifth embodiment of the present invention, and a reference radio wave reflector R₁24, reference radio wave reflector R₂25 is a reference wave reflector R_bIt is explanatory drawing which shows the case where it is installed in the place comparatively near 23. FIG.
FIG. 7 is a time chart showing a fifth embodiment of the present invention and showing a case where a moving body 21 is on a path 22;
FIG. 8 shows a fifth embodiment of the present invention, and is a time chart diagram showing a case where the moving body 21 is out of the course 22;
FIG. 9 shows a fifth embodiment of the present invention and is an explanatory diagram for measuring the relative position of a moving body.
FIG. 10 shows a sixth embodiment of the present invention and includes three reference reflectors R₁24, reference radio wave reflector R₂25 and reference radio wave reflector R₃It is explanatory drawing which shows the case where 26 is installed planarly.
FIG. 11 shows a seventh embodiment of the present invention and is a schematic view when three reference radio wave reflectors A, B, and C are installed.
FIG. 12 shows a seventh embodiment of the present invention, which is disposed sufficiently apart so that the reflected waves from the three reference radio wave reflectors A, B, and C shown in FIG. 11 can be identified. It is a time chart which shows a case.
13 shows a seventh embodiment of the present invention, and is a time chart showing a case where the reflection and transmission timings of the three radio wave reflectors A, B, and C shown in FIG. 11 are set to be different. .
FIG. 14 shows an eighth embodiment of the present invention, and is an explanatory diagram showing a case where a course 22 is set on a course plane 40 that passes through the centers of two radio wave reflectors 41 and 42 (becomes the course 22). It is.
[Explanation of symbols]
1 Radio wave reflector
2 Luneberg lens
3 Reflectors
4 Focus
5 Rotating shaft
7 Reflected wave
11 Waveguide
12 Incident end of waveguide 11
13 Reflection end of waveguide 11
20 Course plane including course
21 Mobile
22 Path of moving body 21
23 Reference radio wave reflector
24 Reference radio wave reflector R₁
25 Reference radio wave reflector R₂
26 Reference radio wave reflector R₃
30 Plane perpendicular to the course
A, B, C Reference radio wave reflector
40 Course plane including course (center)
41, 42 radio wave reflector

Claims (5)

The Luneberg lens and a reflector that reflects the radio wave incident on the Luneberg lens are arranged apart from each other on the surface of the Luneberg lens, and the arrangement interval and size of these reflectors are made constant. A radio wave reflector comprising a reflector and means for rotating the Luneberg lens in which the reflector is disposed;
Means for receiving and scanning the reflected wave from the radio wave reflector, means for measuring a change in reflection cross section of the wave reflected from the radio wave reflector with respect to time, and an amplitude at a frequency that is constant in time A scanning side device having means for receiving the modulated reflected wave from the radio wave reflector and measuring the reflected wave amplitude-modulated at a frequency that is constant in time from the received reflected wave. A measuring device using a radio wave reflector characterized by. A Luneberg lens, a reflector that is disposed on the surface of the Luneberg lens and reflects radio waves incident on the Luneberg lens, and the spacing and size of the reflector are arranged roughly, and the Luneberg lens A radio wave reflector comprising rotating means;
Means for receiving and scanning the reflected wave from the radio wave reflector, means for measuring a change in reflection cross section of the wave reflected from the radio wave reflector with respect to time, and amplitude modulation with a time-varying frequency And a means for measuring a reflected wave amplitude-modulated from the received reflected wave with the time-varying frequency from the received reflected wave. Measuring device using. A radio wave reflector comprising a Luneberg lens, a reflector that is disposed on the surface of the Luneberg lens and reflects a radio wave incident on the Luneberg lens, and means for rotating the Luneberg lens on which the reflector is arranged And the radio wave reflector is arranged such that the reflector is different with respect to the latitudinal direction of the rotation axis of the Luneberg lens,
Means for receiving and scanning a reflected wave from the radio wave reflector, means for measuring a change in reflection cross section of the reflected wave from the radio wave reflector with respect to time, information on the latitude direction, and the reflected wave A measuring device using a radio wave reflector, comprising: a scanning side device having means for measuring information from The radio wave reflector is arranged such that the reflector is different with respect to the latitudinal direction of the rotation axis of the Luneberg lens,
The measuring apparatus using the radio wave reflector according to claim 1, wherein the scanning side device has means for measuring the information from the information on the latitude and the reflected wave. On the reflector surface, set identification information for identifying the radio wave reflector,
The measurement apparatus using the radio wave reflector according to claim 1, wherein the scanning side device includes means for identifying the identification information from a received reflected wave.

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