The present disclosure relates to a radio wave arrival direction estimation apparatus.
In a multipath environment, a known apparatus estimates a direction from which direct and reflected waves arrive (for example, Patent Document 1). The apparatus disclosed in Patent Document 1 estimates the arrival direction of radio wave by using the center of a rotation plate and two antennas disposed at positions different from the center. Additionally, as the method for estimating the arrival direction of direct wave and the arrival direction of reflected wave in a multipath environment, the multiple signal classification (MUSIC) method and the method of direction estimation (MODE) are known.
Patent Document 1: Japanese Unexamined Patent Application Publication No. 2009-14688
When the arrival direction of radio wave is estimated by employing the MUSIC or the MODE, antennas need to be greater in number than arriving waves. For example, in the case in which one direct wave and one main reflected wave arrive, three antennas need to be installed. When the apparatus disclosed in Patent Document 1 is used, the antennas do not need to be greater in number than arriving waves, but the rotation plate needs to be installed; thus, the components constituting the apparatus increases, resulting in increase in size.
The present disclosure provides a radio wave arrival direction estimation apparatus in which antennas do not need to be greater in number than arriving waves and no rotation plate is necessary.
An aspect of the present disclosure provides a radio wave arrival direction estimation apparatus including two antennas configured to receive three kinds of radio waves with different frequencies and a computation unit configured to determine the arrival direction of the three kinds of radio waves arriving at the two antennas after propagating along two mutually different paths from a single transmit point in accordance with receive signals of the three kinds of radio waves with different frequencies received individually by the two antennas.
By receiving three kinds of radio waves with different frequencies, the arrival direction of radio wave can be estimated with the use of two antennas without necessarily using any movable mechanical device, such as a rotation plate.
A radio wave arrival direction estimation apparatus according to a first embodiment will be described with reference to
In the first embodiment, as main propagation paths along which radio waves emitted by the transmission device 20 travel to the radio wave arrival direction estimation apparatus 10, two mutually different paths of a first path P1 and a second path P2 exist. The first path P1 corresponds to, for example, a path along which a direct wave directly arrives at the radio wave arrival direction estimation apparatus 10 from the transmission device 20. The second path P2 corresponds to, for example, a path along which a reflected wave arrives at the radio wave arrival direction estimation apparatus 10 while the reflected wave is reflected by, for example, a building outdoors, or a wall or a floor indoors.
The radio wave arrival direction estimation apparatus 10 includes two antennas 11. The two antennas 11 are disposed at spatially different positions. The two antennas 11 have a function of receiving three kinds of radio waves with different frequencies emitted by the transmission device 20. Receive signals received by the two antennas 11 are inputted respectively to corresponding receive units 13. The two receive units 13 operate in accordance with a local clock provided by a local oscillator 12 and down-convert receive signals received by the antennas 11; in other words, the two receive units 13 both operates in accordance with synchronized local clock signals. For example, the receive unit 13 converts a receive signal into a complex signal (IQ signal) as a complex representation of the receive signal by comparing the receive signal with the local clock signal and outputs the complex signal. The complex signal contains amplitude information and phase information of the receive signal. The complex signal is outputted for each of the three kinds of radio waves with different frequencies.
The complex signals outputted by the two receive units 13 are inputted to a computation unit 14 (e.g., embodied as a processor). The computation unit 14 computes, in accordance with receive signals of the three kinds of radio waves with different frequencies, the arrival directions of radio waves having traveled along the first path P1 and the second path P2 and arrived at the two antennas 11. For example, the computation unit 14 computes the arrival direction of radio waves by performing arithmetic operation for the complex signals obtained by down-converting the receive signals received by the two antennas 11.
The information about the arrival direction of radio wave computed by the computation unit 14 is inputted to an output unit 15. The output unit 15 outputs the information about the arrival direction of radio wave to an output device 16. As the output device 16, for example, a printer, a display, or a communication device is used.
Next, processing of the computation unit 14 will be described with reference to
Firstly, in step ST1 in
[Math. 1]
S
11
=a
1
e
−iωτ
(1)
[Math. 2]
S
12
=a
2
e
−iωτ
(2)
where a1 is the amplitude of a signal transmitted along the first path P1 and received by the first antenna 11A; a2 is the amplitude of a signal transmitted along the second path P2 and received by the first antenna 11A; ω is the angular frequency of radio wave; τ11 is a time corresponding to the phase of a receive signal transmitted along the first path P1 with respect to the local clock signal; and τ12 is a time corresponding to the phase of a receive signal transmitted along the second path P2 with respect to the local clock signal.
Similarly, complex signals S21 and S22 computed by converting signals transmitted along the first path P1 and the second path P2 and received by the second antenna 11B into complex representations are given by the following expressions:
[Math. 3]
S
21
=a
1
e
−iωτ
(3)
[Math. 4]
S
22
=a
2
e
−iωτ
(4)
where it is assumed that the amplitude of a signal transmitted along the first path P1 and received by the second antenna 11B and the amplitude of a signal transmitted along the second path P2 and received by the second antenna 11B are respectively identical to the amplitude of a signal transmitted along the first path P1 and received by the first antenna 11A and the amplitude of a signal transmitted along the second path P2 and received by the first antenna 11A; τ21 is a time corresponding to the phase lag of a receive signal transmitted along the first path P1 with respect to the local clock signal; and τ22 is a time corresponding to the phase lag of a receive signal transmitted along the second path P2 with respect to the local clock signal.
The complex signals p1 and p2 received by the first antenna 11A and the second antenna 11B are given by the following expressions.
[Math. 5]
p
1
=S
11
+S
12
=a
1
e
−iωτ
+a
2
e
−iωτ
(5)
[Math. 6]
p
2
=S
21
+S
22
=a
1
e
−iωτ
+a
2
e
−iωτ
(6)
To express signals received by the first antenna 11A and the second antenna 11B by using parameters of arrival time difference (corresponding to phase difference), Δτ1, Δτ2, and Δτ12 are defined as follows.
[Math. 7]
Δτ1≡τ21−τ11
Δτ2≡τ22−τ12
Δτ12≡τ12−τ11 (7)
Δτ1 is an arrival time difference between a radio wave transmitted to the first antenna 11A along the first path P1 and a radio wave transmitted to the second antenna 11B along the first path P1. Δτ2 is an arrival time difference between a radio wave transmitted to the first antenna 11A along the second path P2 and a radio wave transmitted to the second antenna 11B along the second path P2. Δτ12 is an arrival time difference between a radio wave transmitted to the first antenna 11A along the first path P1 and a radio wave transmitted to the first antenna 11A along the second path P2.
Expression (7) can be modified as follows.
[Math. 8]
τ22τ11=Δτ2+Δτ12
τ21τ12=Δτ1−Δτ12 (8)
Next, in step ST2 in
A1, A2, and A3 are given by the following expressions.
Next, in step ST3 in
The difference between the path length from the transmission device 20 (
Under this assumption, it can be considered that, when the angular frequency ω is changed, only the term A3 including Δτ12 is changed in Expression (9). The exponential function as the coefficient of A3 represents the amount of rotation of the locus of the product p1*·p2 on the complex plane with respect to the real axis (I axis). The locus of the product p1*·p2 is approximated by a straight line having an inclination corresponding to the amount of rotation. Since the exponential portion of the exponential function as the coefficient of A3 of Expression (9) includes Δτ1+Δτ2, Δτ1+Δτ2 can be calculated in accordance with the inclination of the approximation straight line of the locus of the product p1*·p2. The average angular frequency ω among the three kinds of radio waves can be used when Δτ1+Δτ2 is calculated.
However, Δτ1+Δτ2 usually results in multiple solutions, and a unique solution cannot be determined. A single solution needs to satisfy the following condition:
where f is the highest frequency of the three kinds of radio waves received by the radio wave arrival direction estimation apparatus 10. The following expression is derived from Expression (11):
where Δd1 and Δd2 are each the difference of path length illustrated in
According to Expression (12), by setting the distance D between the two antennas 11 to a distance shorter than λ/4, the solution of Δτ1+Δτ2, which is the sum of arrival time differences, can be uniquely determined.
Next, in step ST4 in
Subsequently, step ST5 in
Firstly, the quotient p2/p1 is multiplied by the following expression.
In accordance with this, a real part and an imaginary part are calculated. The real part is given by the following expression.
The imaginary part is given by the following expression.
According to Expressions (14) and (15),
it can be understood that Expressions (16) draws a locus of the circumference of a circle on the complex plane while the angular frequency ω is changed. The locus of Expression (16) when the angular frequency ω is changed is obtained by rotating the locus of the quotient p2/p1 by the same angle as the angle of the inclination of the approximation straight line expressed as Expression (9) in a direction opposite to the inclination of the approximation straight line.
According to Expression (14), the real number component of a center coordinate of the circumference of the circle after rotation is given by the following expression.
Thus, when the real number component of a center coordinate of the circumference of the circle after rotation is determined, Δτ1−Δτ2 can be determined in accordance with Expression (17). When coordinates of at least three points on the circumference of a circle are determined, a center coordinate of the circumference of the circle can be determined. Since in the first embodiment three kinds of radio waves with different frequencies are received, coordinates of three points on the circumference of a circle can be determined by using the computational result of the quotient p2/p1. When Δτ1−Δτ2 is calculated in accordance with Expression (17), the average angular frequency ω of the three kinds of radio waves can be used.
Next, in step ST6 in
Next, in step ST7 in
[Math. 18]
D sin θ1=cΔτ1
D sin θ2=cΔτ2 (18)
where D is the distance between the two antennas 11 (
When Expression (18) is calculated, the arrival directions θ1 and θ2 are still not specified with respect to plus and minus. Furthermore, Δτ1 and Δτ2 may be replaced with each other, it is impossible to determine which of the arrival directions θ1 and θ2 is the arrival direction of a direct wave. To uniquely determine the arrival direction θ1 of a direct wave, it is desired to previously check the movement range of the actual transmission device 20 (
Next, with reference to
In accordance with the inclination angle α of the approximation straight line L and the real part of the center coordinate of the circle circumference C2, Δτ1 and Δτ2 can be calculated. In accordance with Δτ1, Δτ2, and the distance D between the antennas 11, the arrival directions θ1 and θ2 of radio wave can be determined.
Although in the simulation described above the frequency was changed within the range of 2.40 to 2.48 GHz in increments of 2 MHz, the actual measurement only needs to use three kinds of radio waves with different frequencies.
Next, excellent effects of the first embodiment will be described. With the first embodiment, the arrival direction of radio wave can be estimated in a multipath environment by using the two fixed receive antennas 11 (
In the first embodiment, it is assumed that when three kinds of radio waves with different frequencies are represented by using the value of the product p1*·p2 and plotted as three points on a complex plane, the three points are positioned on a single approximation straight line (the approximation straight line L in
Conversely, if the fractional bandwidth is excessively small, three points corresponding to three kinds of radio waves on a complex plane are positioned close to each other, and as a result, errors are likely to occur when the inclination of the approximation straight line or the center coordinate of the circumference of a circle is determined. To achieve highly accurate calculation of the inclination of the approximation straight line and the center coordinate of the circumference of a circle, the fractional bandwidth can be 3% or greater.
Microwaves or millimeter waves can be used as the three kinds of radio waves with different frequencies used in the first embodiment. When microwaves or millimeter waves are used, the distance D between the two antennas 11 (
Next, various modifications to the first embodiment will be described. In the first embodiment, as described above, the distance D between the two antennas 11 can be λ/4 or shorter to uniquely determine Δτ1+Δτ2 in step ST3 (
In the first embodiment, the arrival direction of radio wave is determined in accordance with the product p1*·p2, which is the product of the complex conjugate p1* of the complex signal p1 and the complex signal p2, and the quotient p2/p1, which is calculated by dividing the complex signal p2 by the complex signal p1. As another method, the arrival direction of radio wave may be calculated in accordance with the product p1*·p2 and the quotient p1/p2 that is calculated by replacing the denominator and the numerator with each other.
Additionally, Δτ1 and Δτ2 may be determined by calculating simultaneous equations of Expression (5) and Expression (6). In accordance with Expression (5) and Expression (6), simultaneous equations with six variables and different angular frequencies ω can be obtained. The six unknowns are the amplitudes a1 and a2, and the times τ11, τ12, τ21, and τ22, each of which corresponds to a phase with reference to the local clock signal. By computing the simultaneous equations with the six variables, the arrival time differences Δτ1 and Δτ2 can be determined.
While in the first embodiment the receive units 13 are respectively provided for the two antennas 11, the two receive units 13 are not necessarily provided and a single receive unit 13 may be shared by the two antennas 11. For example, the single receive unit 13 can perform receive processing from the two antennas 11 in a time-division manner.
As described above, the arrival direction of radio wave can be estimated by using the radio wave arrival direction estimation apparatus 10 according to the first embodiment. By using a plurality of radio wave arrival direction estimation apparatuses 10, the transmission device 20 (
Next, the radio wave arrival direction estimation apparatus 10 according to a second embodiment will be described with reference to
In the second embodiment, a receiver of an existing wireless communication system can also be used as the radio wave arrival direction estimation apparatus. Furthermore, the single device can perform both estimation of the arrival direction of radio wave and data communication. For example, a signal of a BLE advertising channel can be used as a radio wave used to estimate the arrival direction of radio wave. In particular, it is desirable that a field with a predetermined signal pattern of transmit and receive signals be used to estimate the arrival direction of radio wave.
The embodiments described above are mere examples, and as might be expected, the configurations described in the different embodiments may be partially replaced or combined with each other. In particular, almost identical effects and advantages achieved by almost identical configurations in the plurality of embodiments are not mentioned in every embodiment. Moreover, the present disclosure is not limited to the embodiments described above. For example, various modifications, improvements, and combinations would be apparent to those skilled in the art.
Number | Date | Country | Kind |
---|---|---|---|
2018-146495 | Aug 2018 | JP | national |
This is a continuation of International Application No. PCT/JP2019/028867 filed on Jul. 23, 2019 which claims priority from Japanese Patent Application No. 2018-146495 filed on Aug. 3, 2018. The contents of these applications are incorporated herein by reference in their entireties.
Number | Date | Country | |
---|---|---|---|
Parent | PCT/JP2019/028867 | Jul 2019 | US |
Child | 17165083 | US |