This applicationThis is a reissue application of U.S. Pat. No. 10,381,734, filed Oct. 17, 2018, as application Ser. No. 16/094,306 and issued Aug. 13, 2019, which is a national stage (under 35 U.S.C. 371) of International Patent Application No. PCT/RU2017/000124, filed Mar. 10, 2017, both of which is hereinare incorporated by reference herein in itstheir entirety.
The present invention relates generally to antennas, and more particularly to patch antennas used in Global Navigation Satellite Systems (GNSS).
A wide range of consumer, commercial, and industrial applications utilize patch antennas in GNSS applications which can determine locations with high accuracy. Currently deployed systems include the United States Global Positioning System (GPS) and the Russian GLONASS, and others such as the European GALILEO system are under development.
In a GNSS, a navigation receiver receives and processes radio signals transmitted by satellites located within a line-of-sight of the navigation receiver. A critical component of a GNSS is the receiver antenna. Key properties of the receiver antenna include bandwidth, multipath rejection, size, and weight. High-accuracy navigation receivers typically process signals from two frequency bands. For example, two common frequency bands are a low-frequency (LF) band in the range of 1164-1300 MHz, and a high-frequency (HF) band in the range of 1525-1610 MHz.
One reason for reduced GNSS positioning accuracy of land objects is related to receiving not only line-of-sight satellite signals but also signals reflected from surrounding objects, and especially from the Earth's surface (i.e., the ground). The strength of such signals depends directly on the antenna's directional pattern (DP) in the rear hemisphere. A right-hand circularly polarized signal is used as a working signal in navigation systems. As will be appreciated, a low level of directional pattern in the lower hemisphere (particularly in the nadir direction) is a standard antenna requirement, and typically a reduction in the antenna's weight and overall dimensions is desirable.
It is well-known that patch antennas are widely used in GNSS applications due to certain technical and operational advantages such as low height which enables low-profile patch antennas to be constructed. As will be understood, a conventional patch antenna typically includes a radiating patch located over a ground plane such that the lateral dimension (i.e., length) of the ground plane is longer than that of the patch. To provide qualitative signal reception from navigation satellites across the celestial hemisphere up to angles close to the horizon, the patch antenna should also have a wide enough Directional Pattern (DP) in the forward (i.e., upper) hemisphere. The width of a patch antenna DP is determined by the length of the patch such that the shorter the patch is, the wider the DP will be. The length of the patch is normally 0.2 . . . 0.3λ, wherein λ is the wavelength in free space and the minimal length is determined by the operational bandwidth. To provide for a resonance mode on such lengths, a dielectric between the ground plane and patch or capacitive elements is used.
A considerable contribution to positioning errors in GNSS systems is attributable to signal(s) reflected from the ground. To reduce this multipath error, a low DP level should be provided in the backward hemisphere, and one conventional solution is to choose a ground plane length equal to at least 0.5λ. The size of the ground plane determinates the overall antenna dimension, and the aforementioned wavelength corresponding to the minimal frequency of the operation range. For GNSS, this frequency is 1164 MHz, which corresponds to 258 mm which translates to an antenna size of at least 130 mm. Any further reduction in the length of the ground plane results in a noticeable increase in DP level in the backward hemisphere. If the length of the ground plane is equal to that of the patch, the DP level in the backward hemisphere is the same as in the forward hemisphere which is unacceptable for the standard operation of high-precision GNSS receivers. Therefore, a minimal dimension of standard patch antennas is limited by the length of the ground plane which provides the desired low level of DP in the lower hemisphere, and particularly in the nadir direction (i.e., the desired level of multipath suppression).
One example of an antenna providing for low DP level in the nadir direction is described in U.S. Pat. No. 9,184,503 where the antenna's design includes a length of ground plane that is equal to or smaller than the length of the patch. To achieve this design, a loop radiator is located around the patch whereby the radiator is excited by dual-wire lines connected to a separate power supply. The power supply provides excitation of the loop radiator with such amplitude and phase that the field of the patch is subtracted from the field of the loop radiator. However, potential drawbacks of such a design are the overall design complexity and the requirement of a separate supply line to power the loop radiator.
Therefore, a need exists for an improved high-precision GNSS antenna design with lower complexity, smaller dimensions, and efficient multipath suppression.
In accordance with an embodiment, a single-band right-hand circularly-polarized patch antenna comprises a ground plane and a patch connected to each other with at least four (4) wires for which the wire shape and location of the end points are selected such that they do not cause an antenna mismatch, and the electrical current carried in the wires produces an extra electromagnetic field subtracted from the patch electromagnetic field in the nadir direction. In accordance with the embodiment, this facilitates an antenna with low DP level (i.e., Down/Up level) in the nadir direction and with a smaller (and shorter) ground plane such that the size of the ground plane becomes practically as long as the patch, and there is no additional power supply necessary to power the wires. In accordance with an embodiment the patch antenna is a single-band right-hand circularly-polarized patch antenna providing a reduced directional pattern in the backward hemisphere.
In accordance with an embodiment the patch antenna is a dual-band right-hand circularly-polarized stacked-patch antenna comprising a ground plane, a low-frequency (LF) patch, a high-frequency (HF) patch, and at least four wires. Each of the wires is connected to the ground plane and LF patch via reactive impedance elements, and the current flowing through these wires produces an additional electromagnetic field that is subtracted from the electromagnetic field of the LF patch in the nadir direction. Further, in accordance with this embodiment, due to the possibility that induced currents in the wires may result in an undesirable increase in DP level in the backward hemisphere within HF range, the mode of operation for reactive impedance elements is selected such that undesirable effects of the wires in the HF range are minimized or eliminated completely.
These and other advantages of the embodiments will be apparent to those of ordinary skill in the art by reference to the following detailed description and the accompanying drawings.
In accordance with an embodiment, a single-band right-hand circularly-polarized patch antenna comprises a ground plane and a patch connected to each other with at least four (4) wires for which the wire shape and location of the end points are selected such that they do not cause an antenna mismatch, and the electrical current carried in the wires produces an extra electromagnetic field subtracted from the patch electromagnetic field in the nadir direction. In accordance with the embodiment, this facilitates an antenna with low DP level (i.e., Down/Up level) in the nadir direction and with a smaller (and shorter) ground plane until the size (i.e., length) of the ground plane is as long as the patch, and there is no additional power supply necessary to power the wires.
As noted previously, it is well-known that patch antennas are widely used in GNSS systems due to their low height which enables the design of certain low-profile devices. As shown in
As also noted previously, one example of an antenna providing for low DP level in the nadir direction is described in U.S. Pat. No. 9,184,503, and shown in
In
The parameter DU(θe) (Down/Up ratio) is equal to the ratio of the antenna pattern level F(−θe) in the backward hemisphere to the antenna pattern level F(θe) in the forward hemisphere at the mirror angle, where F represents a voltage level. Expressed in dB, the ratio is:
DU(θe) (dB)=20 log DU(θe) (E2)
A commonly used characteristic parameter is the Down/Up ratio at θe=+90 deg
The geometry of antenna systems is described with respect to the illustrative Cartesian coordinate system shown in
The coordinates of P 411 can also be expressed in the spherical coordinate system and in the cylindrical coordinate system. In the spherical coordinate system, the coordinates of P are P(R,θ,φ), where R=|{right arrow over (R)}| is the radius, θ 423 is the polar angle measured from the x-y plane, and φ 425 is the azimuthal angle measured from the x-axis. In the cylindrical coordinate system, the coordinates of P are P(r,θ,h), where r=|{right arrow over (r)}| is the radius, φ is the azimuthal angle, and h=|{right arrow over (h)}| is the height measured parallel to the z-axis. In the cylindrical coordinate axis, the z-axis is referred to as the longitudinal axis. In geometrical configurations that are azimuthally symmetric about z-axis 407, the z-axis is referred to as the longitudinal axis of symmetry, or simply the axis of symmetry (if there is no other axis of symmetry under discussion).
The polar angle θ is more commonly measured down from the +z-axis 0≤θ≤π). Here, the polar angle θ 423 is measured from the x-y plane for the following reason. If the z-axis 407 refers to the z-axis of an antenna system, and the z-axis 407 is aligned with the geographic Z-axis 305 in
Wires 505-1, 505-2, 505-3 and 505-4 have the same (or substantially the same) design and are arranged in a rotational symmetrical manner about vertical z-axis 407 (as shown in
Coordinates of points P1, P2, P3 and P4 can be determined in a cylindrical coordinate system with the origin at point O 510 located onto patch 501, i.e., the vertical coordinate of patch 501 is zero. The cylindrical coordinate system has vertical axis 407 in the antenna center that is oriented from ground plane 502 to patch 501. The angular coordinate is counted from the x-axis, the direction of which can be arbitrarily selected. As shown in
Point P1 has coordinates r1,φ1,z1, P2 has coordinates r2,φ2,z2, point P3 has coordinates r3,φ3,z3, and point P4 has coordinates r4,φ4,z4. Segment 506-n is vertical, and hence r=r2, φ=φ2. Segment 507-n is horizontal, respectively z2=z3. Segment 508-n is vertical and r3=r4, φ3=φ4. Segment 506-n is connected to the ground plane at point P1, segment 508-n is connected to the patch at P4. Horizontal segment 507-n is located over the patch (e.g., patch 501), i.e., z2>0.
Angular coordinate φ1 of segment 506-n connected to the ground plane (e.g., ground plane 502) is greater than angular coordinate φ3 of segment 508-n being connected to the patch. Thus, φ1>φ3. The positional relationship of segments 506-n and 508-n will now be discussed. Using a top view, the imaginary line connecting the coordinate origin and a point of segment 507-n will rotate counterclockwise when moving from point P3 belonging to segment 508-n to point P2 belonging segment 506-n. Thus, the imaginary line connecting any point of wire 505-n will rotate counterclockwise when moving from the end point of wire 505-n (i.e., P4) to the starting point of wire 505-n (i.e., P1). In this way, it will be understood that when moving along vertical segments (508-n, 506-n) the imaginary line does not rotate.
The orientation and the positional relationship of the wires, as described above, in the right-hand circularly polarized antenna results in an electric current in horizontal segments 507-n such that the associated field is subtracted from the field of patch 501 in the nadir direction. As a result, the total antenna field in the nadir direction is substantially reduced. The reduction is due, in part, to the specific orientation of the plurality of wires such that the reduction of the total antenna field in the nadir direction is, illustratively, a function of variations between the first electromagnetic field associated with the plurality of wires and the second electromagnetic field associated with the radiating patch. In accordance with the embodiment, this variation is represented and determined by subtracting the second and first electromagnetic fields. The length of each horizontal segment 507-n lies close to a quarter of the wavelength, and the segments along with ground plane 502 can be interpreted as segments of a transmission line which are shorted at their ends by segments 506-n. These transmission lines are connected to patch 501 by segments 508-n. It is well-known that a short-circuited transmission line that is a quarter wavelength long has open-circuit impedance, and this why these connections do not cause the mismatch of the antenna formed by patch 501 and ground plane 502.
The length of each horizontal segment 507-n is close to a quarter of a wavelength on the frequency of LF band (i.e., around 60 mm). The segments along with ground plane 602 can be considered as segments of a transmission line shorted at their ends by segments 506-n. The transmission lines are connected to LF patch 601 via segments 508-n. It is well-known, as noted above, that a short-circuited transmission line that is a quarter wavelength long has an open-circuit impedance such that these connections do not cause the mismatch of the antenna formed by patch 601 and ground plane 602.
Each of wires 505-n is connected to ground plane 602 and LF patch 601 through reactive impedance elements 611-n (e.g., 611-1, 611-2, 611-3, and 611-4) and 612-n (e.g., 612-1 and 612-2). Wire 505-1 has a starting point P1 and end point P4. At point P1 wire 505-1 is connected to reactive impedance element 611-1. Element 611-1 is in turn connected to ground plane 603. At point P4 wire 505-1 is connected to impedance element 612-1. Element 612-1 is in turn connected to LF patch 601. Elements 611-n and 612-n ensure a short circuit mode within LF band and an operation mode with practically open-circuit conditions within HF band. Such connecting eliminates undesirable effects of wires 505-n in HF band. Also, in accordance with an embodiment, elements 612-n can be eliminated such that wires 505-n can be directly connected to patch 601 at points P4.
Wires 505-n and reactive impedance elements 611-n and 612-n are arranged in a rotational symmetrical manner to vertical z-axis 407 passing through the antenna center. Each of reactive impedance elements 611-n and 612-n, as shown in
In a further antenna embodiment, wires 505-n can be arranged such that the wires do not protrude outside of LF patch 601 in the top view, and this is depicted in
Another embodiment, antenna 900 shown in
In accordance with the embodiment shown in
In
The foregoing Detailed Description is to be understood as being in every respect illustrative and exemplary, but not restrictive, and the scope of the invention disclosed herein is not to be determined from the Detailed Description, but rather from the claims as interpreted according to the full breadth permitted by the patent laws. It is to be understood that the embodiments shown and described herein are only illustrative of the principles of the present invention and that various modifications may be implemented by those skilled in the art without departing from the scope and spirit of the invention. Those skilled in the art could implement various other feature combinations without departing from the scope and spirit of the invention.
Filing Document | Filing Date | Country | Kind |
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PCT/RU2017/000124 | 3/10/2017 | WO |
Publishing Document | Publishing Date | Country | Kind |
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WO2018/164599 | 9/13/2018 | WO | A |
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2012154791 | Oct 2014 | RU |
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Entry |
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International Search Report and Written Opinion dated Dec. 14, 2017, in connection with International Patent Application No. PCT/RU2017/000124, 6 pgs. |
Number | Date | Country | |
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Parent | 16094306 | Mar 2017 | US |
Child | 17365977 | US |