KR101125148B1 - Antenna for receiving gps signals - Google Patents

Abstract

The GPS receiving antenna according to the present invention includes a dielectric having a ground plane formed on a lower surface thereof, a plurality of patch radiating elements arranged in a line on an upper surface of the dielectric, and a feed line electrically connected to the patch radiating element, thereby improving narrow directivity and improvement. It provides a reception sensitivity, and as a result can effectively exclude the multipath propagation causing the position error.

Description

GPS reception antenna {ANTENNA FOR RECEIVING GPS SIGNALS}

The present invention relates to a GPS receiving antenna, and more particularly, to a GPS receiving antenna that enables improved gain acquisition and accurate location by reducing the reception rate for multipath propagation of satellite signals.

Satellite navigation systems, such as the Global Positioning System (GPS) used to determine the location of a wireless terminal, include a constellation of satellites that transmits GPS signals that can be analyzed by the wireless terminal. The orbits of the satellites are arranged on multiple planes so that signals can be received from at least three satellites at any location on the earth.

1 is a schematic diagram showing a general GPS system.

In the GPS system 100, the satellites 101 transmit a plurality of GPS signals 102 received by the wireless terminal 103.

Positioning operations are typically performed by receiving GPS signals 102 from three or more satellites.

On the other hand, a patch antenna is generally used as a reception antenna in a portable terminal for using a multimedia information / broadcast service, a current location service, and an electronic map service. In order to minimize the effects of ionospheric interference and multipath signals (noise) reflected from the ground, satellites transmit right hand circular polarization. Circular polarization antennas are used to receive GPS satellite signals, among which patch antennas are relatively inexpensive and have good reception. The patch antenna is light weight and has a planar structure that takes up little space, and can be used as a communication relay antenna for various mobile communication devices and portable devices as an antenna capable of retaining the largest gain and directivity in a given space.

Patch antennas, such as those used in conventional navigation, are designed to track the position of the terminal through the configuration of receiving signals from as many satellites as possible. However, according to this configuration, it is difficult to accurately track the location of the terminal by receiving the multi-path radio waves reflected by obstacles such as buildings and overpasses. In other words, the location tracking and measurement results are unstable due to the reception of multipath propagation causing a time delay in a navigation or GPS receiver.

An object of the present invention is to provide a GPS receiving antenna having an array patch antenna structure which can obtain more improved gain and narrow directivity.

This aims to reduce the position measurement error by improving the reception sensitivity of receiving GPS signals from satellites and minimizing the reception rate of multipath radio waves.

The GPS receiving antenna of the present invention for achieving the above object is a dielectric having a ground plane formed on the lower surface, a plurality of patch radiating elements arranged in a line on the upper surface of the dielectric and a feed line electrically connected to the patch radiating element It may include.

In this case, the patch radiating element may have a different width in the arrangement direction. Here, the width of the patch radiating element may be smaller than the width of the other side.

In addition, one side of the patch radiating element is a rectangle, the other side of the patch radiating element may be an isosceles trapezoid trapping the bottom side to one side of the rectangle.

In addition, a slot may be formed in the center of the patch radiating element in an oblique direction of the arrangement direction axis.

The patch radiating element may include four first, second, third and fourth patch radiating elements arranged in sequence, and the distance between the second and third patch radiating elements is the first and second patch radiating elements. It may be shorter than the distance and the distance of the third and fourth patch radiating element.

In this case, the distance between the first and second patch radiating elements may be the same as the distance between the third and fourth patch radiating elements.

The feed line may include: a first feed line connecting the first and second patch radiating elements to a letter 'c'; A second feed line connecting the third and fourth patch radiating elements to a letter 'c'; And a third feed line connecting the first feed line and the second feed line to a letter 'C', wherein the third feed line is closer to the first patch radiating element than a center of the first feed line. The second connection point may have a point as a first connection point and a point closer to the fourth patch radiating element than the center of the second feed line.

Here, assuming that the first, second, third, and fourth patch radiating elements are arranged at equal intervals, the first connection point is the middle of the first feed line, and the second connection point is the second connection point. It may be in the middle of the feed line.

In addition, the first feed line has a width from the first connection point to the first patch radiating element side bending point is greater than the width of the other portion, the second feed line is the fourth patch radiating element at the second connection point The width to the side bend may be greater than the width of the other portion. Here, the width from the connection point with each of the bending points to the first and second patch radiating elements in the first feed line is within a range smaller than the width from the first connection point to the bending point on the first patch radiating element side. It is larger than the width of the other part, and the width from the connection point with each of the bent points to the third and fourth patch radiating elements in the second feed line is the width from the second connection point to the bend point of the fourth patch radiating element. It can be larger than the width of other parts within a smaller range.

In addition, the width of the third feed line from the connection point to each bending point with the first and second feed line may be greater than the width of the other portion.

The apparatus may further include a feeding unit connected to a center of the third feed line and having a width equal to a width from a connection point to each bend point with the first and second feed lines in the third feed line.

The apparatus may further include a feeding unit connected to a center inside of the third feed line and having a feeding point.

In addition, the patch radiating element may be in the range of six.

As described above, the GPS reception antenna according to the present invention can improve the signal reception sensitivity to the satellite and reduce the reception of the multipath radio waves by improving the structure of the arrangement antenna to improve the directivity. This improves the accuracy of location tracking and location measurements.

1 is a schematic diagram illustrating a general GPS system.
2 is a schematic diagram illustrating a GPS receiver related to the present invention.
3 is a graph showing simulation results and measurement results of return loss.
4 is a graph illustrating a gain measurement result of a general GPS reception antenna and a GPS reception antenna according to the present embodiment.
5 is a graph showing an axial ratio of a GPS receiving antenna according to the present embodiment.
6 is a graph showing the difference in gain when the material of the dielectric is Teflon and FR4.
7 is a graph showing the difference in return loss when the material of the dielectric is Teflon and FR4.
8 is a plan view showing a GPS receiving antenna according to another embodiment related to the present invention.
9 is a graph showing the average of the C / NO value for each channel in the GPS receiving antenna according to another embodiment related to the present invention.
10 is a graph showing an average C / N 0 change of time of the GPS receiving antenna according to another embodiment related to the present invention.
11 is a graph showing the number of satellites used for navigation solution calculation.
12 is a schematic diagram showing the entire trajectory of the straight running section and the rotating section.
FIG. 13 is an enlarged view of a straight running section of an upper part of the entire trajectories of FIG. 12; FIG.
FIG. 14 is an enlarged view of a lower left rotation section of the entire trajectory of FIG. 12.
FIG. 15 is an enlarged view of a lower straight line section of the entire trajectory of FIG. 12. FIG.
16 is a side view showing a radiation pattern of the GPS receiving antenna shown in FIG.
17 is a plan view showing a radiation pattern of the GPS receiving antenna shown in FIG.
18 is a graph showing the gain and the directivity angle of the radiation pattern of the GPS receiving antenna shown in FIG.

Hereinafter, a GPS receiving antenna according to the present invention will be described in more detail with reference to the accompanying drawings.

2 is a schematic diagram illustrating a GPS receiver according to the present invention.

The GPS receiver illustrated in FIG. 2 includes a dielectric 210 having a ground plane formed on a lower surface thereof, a plurality of patch radiating elements 230 arranged in a line on an upper surface of the dielectric, and a feed line electrically connected to the patch radiating element ( 250).

The dielectric 210 is a dielectric substrate having a constant thickness of ε, and a ground plane is formed on one surface and a radiation element serving as an antenna is placed on the other surface. The radiation element at this time is a patch radiating element. The antenna thus formed is called a microstrip patch antenna, which is a type of resonant antenna whose frequency band varies depending on the length of the patch radiating element. Microstrip patch antennas are interpreted as emitting signals by fringing effects. There are several dielectrics used in microstrip patch antenna designs, where the dielectric constant of the substrate usually ranges from 2.2 ≦ ε ≦ 12. Thick dielectrics and low dielectric constants are desirable for antenna performance. The thicker the dielectric and the lower the dielectric constant, the better the efficiency and bandwidth, the weaker the boundary field (radiary field) radiated into the space is desirable for antenna characteristics. However, since the miniaturization may be limited due to the thickness, the thickness of the dielectric is determined in consideration of the improvement of these parts and antenna characteristics. The material of the dielectric may be FR4 or teflon.

The patch radiating element 230 is a radiation element acting as an antenna and is placed on the top surface of the dielectric in the form of a flat patch. In the present embodiment, a plurality of patch radiating elements are arranged in a row on the upper surface opposite to the lower surface on which the ground plane is formed in the dielectric.

In this way, the beamwidth provides a narrow directivity, which reduces the number of satellite signals to be received while improving the gain of the satellite signals to be received. As a result of the experiment, it was confirmed that the reception rate of the multipath propagation causing the position error is reduced, and thus a very accurate position can be calculated.

A slot 231 may be formed in the center of the patch radiating element in an oblique direction of the arrangement axis. The position, length and width of the slot may be set in consideration of the improvement of the signal gain and the reduction and directivity of the C / N ratio. In Fig. 2, the length of the slot is 6.1 mm and the width is 1.59 mm.

There may be a plurality of patch radiating elements arranged in a row on the dielectric upper surface within six ranges. The number of patch radiating elements may be further increased but it is desirable to be limited to a maximum of six for miniaturization.

Let's consider a case where the number of patch radiating elements is four.

When the first patch radiating element, the second patch radiating element, the third patch radiating element, and the fourth patch radiating element are arranged in order from the left side of the dielectric top surface, the distance between the second and third patch radiating elements is the first and second patches. It may be shorter than the distance of the radiating element and the distance of the third, fourth patch radiating element. In this case, the distance between the first and second patch radiating elements is preferably the same as the distance between the third and fourth patch radiating elements.

In FIG. 2, the distance between the first and second patch radiating elements and the distance between the third and fourth patch radiating elements is set to 65.15 mm based on the center of the patch radiating element, and the second patch radiating element and the third patch radiating element Was set to 51.75 mm.

The feed line 250 is a first feed line 251 connecting the first and second patch radiating elements to the letter 'C', and a second feed line connecting the third and fourth patch radiating elements to the letter 'C'. 253 and a third feed line 255 connecting the first feed line and the second feed line to a letter 'c'.

The feed line connected to the patch radiating element is connected to the center of one side of the patch radiating element. If the patch radiating elements are paired as shown in FIG. 2, the connection between the patch radiating elements is not made at the side of the patch radiating element but at the bottom thereof, so that the shape is 'c'.

This form is also applied to a feed line (third feed line) connecting the other feed lines (first feed line, second feed line).

The third feed line 255 has a point closer to the first patch radiating element than the center of the first feed line as the first connection point, and the point closer to the fourth patch radiating element than the center of the second feed line is the second connection point. can do. The first connection point and the second connection point may be specifically as follows. That is, assuming that the first, second, third, and fourth patch radiating elements are arranged at equal intervals, the first connection point is the middle of the first feed line, and the second connection point is the second feed line. It may be in the middle of. In fact, since the first, second, third and fourth patch radiating elements are not arranged at equal intervals and the distance between the second and third patch radiating elements is smaller than the distance between the other patch radiating elements, the first connection point is connected to the first feed line. It becomes a point closer to the first patch radiating element than the center of, and the second connection point is also similar to the fourth patch radiating element. According to such a configuration, the length of the feed line for each patch radiating element is different, and the directivity can be improved by adjusting the length according to the power distribution principle.

On the other hand, the thickness of each feed line may vary depending on the part. For example, the width of the first feed line from the first connection point to the bending point on the side of the first patch radiating element may be greater than the width of the other portion. Similarly, the width of the second feed line from the second connection point to the bend point of the fourth patch radiating element may be greater than the width of other portions. When the width of the first and second feed lines is 2.2 mm, the width from the first connection point to the first patch radiating element side bending point and the width from the second connection point to the fourth patch radiating element side bending point may be 5.5 mm. have.

In addition, the width (2.94 mm) from the connection point with the first and second patch radiating elements to each bending point in the first feed line is greater than the width (5.5 mm) from the first connection point to the bending point at the first patch radiating element side. It can be larger than the width of other parts (2.2mm) within a small range. Similarly, the width (2.94 mm) from the connection point with each of the third and fourth patch radiating elements in the second feed line to each bending point is greater than the width (5.5 mm) from the second connection point to the bend point in the fourth patch radiating element. It can be larger than the width of other parts (2.2mm) within a small range.

In addition, the width from the connection point (first and second connection points) to each bending point with the first and second power supply lines in the third power supply line may be larger than the width of other portions.

The apparatus may further include a feeding part connected to the center of the third feed line and having a width equal to a width from the connection point to the bend points to the first and second feed lines. The feeding part may have a shape extending from the third feeding line, and a feeding point 257 connected to the center inside of the third feeding line and penetrating the dielectric may be further formed. By forming the feeding point in this way, it is possible to form the feeding part inside the third feed line, which increases durability and robustness as compared to the configuration in which the feeding part is formed outward of the third feeding line (FIG. 8).

The performance of the GPS antenna configured as described above is as follows.

For reference, the dielectric has an area of 233 mm x 79 mm and a thickness of 1.6 mm and is made of Teflon material. The distance from the first and fourth patch radiating elements to the ends of each bend point is 11.13 mm, and the distance from the second and third patch radiating elements to the ends of each bend point is smaller than that. The distance difference is due to the difference in width from the first and second connection points to the respective bending points. The distance from the center of the feeding part to the first and second connection points (center) in the third feed line is 66.75 mm. The width of the feeding part is 5.88 mm, and each patch radiating element has a horizontal length of 44.5 mm and a vertical length of 44.8 mm.

FIG. 3 is a graph showing a simulation result and a measurement result of return loss, indicating a -10 dB match between 1.56 GHz and 1.62 GHz, which is a GPS / Glonass band.

4 is a graph illustrating a result of measuring gains of a general GPS reception antenna and a GPS reception antenna according to the present embodiment, and it can be seen that the passive gain has a passive gain of about 5 dBi in the GPS / Glonass band.

FIG. 5 is a graph showing the axial ratio of the GPS receiving antenna according to the present embodiment, and it can be seen that it has a 3 dB CP characteristic at 1.59 GHz. That is, the optimum performance is shown in the GPS band.

For reference, FIG. 6 and FIG. 7 show the difference when the material of the dielectric material is Teflon and FR4. FIG. 6 is a graph showing the difference of gain, and FIG. 7 is a graph showing the difference of return loss.

Referring to FIG. 6, it can be seen that Teflon has an average gain of about 2dBi in the GPS / Glonass band, and FIG. 7 shows that the matching characteristic of FR4 is relatively excellent. The matching characteristics in the Teflon material can be further improved by changing the shape / distance of the patch radiating element and the width thickness / distance of the feed line.

The patch radiating element is shown in the form of a square including a slot in the center thereof, but the shape may be as follows.

8 is a plan view illustrating a GPS receiving antenna according to another embodiment related to the present invention.

The GPS receiving antenna shown in FIG. 8 includes a dielectric 310 having a ground plane formed on a lower surface thereof, a plurality of patch radiating elements 330 arranged in a line on an upper surface of the dielectric material having different widths (vertical lengths) in an arrangement direction, and A feed line 350 is electrically connected to the patch radiating element.

Looking at it, it can be seen that the width (vertical length in FIG. 8) of the patch radiating element 330 varies depending on the alignment direction line. In particular, when the width of one side is smaller than the width of the other side, the directivity is improved. In FIG. 8, one side of the patch radiating element is formed in a rectangle, and the other side of the patch radiating element is formed in an isosceles trapezoid where the bottom side is joined to one side of the rectangle.

In addition, four patch radiating elements are arranged at equal intervals along the arrangement direction line, and the power feeding line 350 is also formed at equal intervals without changing the width.

In addition, unlike the embodiment of FIG. 2, the feeding unit 370 is formed outside the third power supply line to partially pass over the dielectric.

Each characteristic of the GPS receiving antenna thus formed is as follows.

9 is a graph showing the average of the C / NO value for each channel of the GPS receiving antenna according to another embodiment related to the present invention.

When the GPS receiving antenna according to the present embodiment is referred to as an array patch antenna and the conventional GPS receiving antenna is referred to as a commercial antenna, an array patch antenna (average 34.39 [average 40.51 [dB-Hz]) is compared with a commercial antenna of the same channel. dB-Hz]) shows a lower C / N0 value of 6.11 [dB-Hz]. Furthermore, it can be seen that an array patch antenna receives three channels of satellite signals that are not received by a commercial antenna.

FIG. 10 is a graph showing an average C / N0 change in time of a GPS receiving antenna according to another embodiment related to the present invention.

As a result, it can be seen that the array patch antenna as a whole has a low C / N0 average value of about 4.23 [dB-Hz].

11 is a graph showing the number of satellites used for navigation solution calculation.

As a result, it can be seen that the array patch antenna (average of 7.04 satellite signals) uses 2.36 fewer satellite signals for navigation than the commercial antenna (average of 9.4 satellite signals). A small signal of the satellite signal used for navigation calculation may mean a decrease in accuracy at first glance, but in the present embodiment, the opposite is true. According to the present embodiment, since the satellite signals corresponding to the multipath propagation (2.36) are not used for navigation and calculation, the accuracy is increased.

In fact, the results of the navigation solution calculation using the commercial antenna and the array patch antenna will be described with reference to FIGS. 12 to 15.

12 is a diagram illustrating the entire trajectory tested and shows the trajectories of the straight running section and the rotating section. The green trajectory is for array patch antennas and the red trajectory is for commercial antennas.

13 is an enlarged view of the linear driving section of the upper part of the entire trajectory of FIG. 12, it can be seen that the red trajectory is far from the actual linear driving path. As a result of applying the satellite signal corresponding to the multipath propagation to the calculation, it can be seen that the error is greatly reduced when the array patch antenna is applied in which the reception ratio of the multipath propagation is reduced.

FIG. 14 is an enlarged view of a lower left rotation section of the entire trajectory of FIG. 12. Due to the interference of each building, there is a constant bias in both the commercial antenna and the array patch antenna. However, when the off-road is examined, the commercial antenna is much larger.

FIG. 15 is an enlarged view of a lower straight line section of the entire trajectory of FIG. 12. It can be seen that the disturbance of each building or the commercial antenna draws a lot of off-road trajectory, while the array patch antenna draws a fairly small trajectory.

In summary, the GPS receiving antenna of the present invention can sharply narrow the beam width by improving the arrangement, shape, distance, and length of the feed line of the patch radiating element. In other words, the directivity is improved, which can be used to eliminate the multipath propagation caused by the reflection and diffraction of the signal in the urban environment. Due to the improved directivity, fewer satellite signals are received than conventional GPS receiver antennas, but the reception rate of each satellite signal is improved and the multi-path propagation is blocked, so accurate location and tracking are possible.

16 to 18 are graphs showing the radiation pattern of the GPS receiving antenna shown in FIG. 2 in order, the plan view, and the gain. As shown in FIG. By narrowing the angle of view, instead of receiving fewer signals than before, the SLL (Side Love Level) improves to 10dB and has a high gain within the direction of angle. Through this, it is possible to exclude the multipath propagation mainly received outside the direction angle, and the reception rate of the received satellite signal is improved to enable accurate location tracking.

It will be understood by those skilled in the art that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. Therefore, the above-described embodiments are to be understood as illustrative in all respects and not as restrictive. The scope of the present invention is shown by the following claims rather than the detailed description, and all changes or modifications derived from the meaning and scope of the claims and their equivalents should be construed as being included in the scope of the present invention. do.

It can be applied to GPS receiving antenna.

In particular, it is advantageous to apply to a small GPS receiving antenna applied to a vehicle GPS or a portable GPS terminal.

210, 310 ... Dielectric 230, 330 ... patch radiating element
250, 350 ... Feed Line 251 ... First Feed Line
253 ... 2nd Feed Line 255 ... 3rd Feed Line
257 ... feeding point 370 ... feeding part

Claims (15)

A dielectric having a ground plane formed on its bottom surface;
A plurality of patch radiating elements arranged in a row on an upper surface of the dielectric; And
A feed line electrically connected to the patch radiating element;
Including;
The patch radiating element is a GPS receiving antenna, characterized in that the width of one side is smaller than the width of the other side according to the arrangement direction, one side is a rectangle and the other side is an isosceles trapezoid trapped on one side of the rectangle.
delete delete delete The method of claim 1,
GPS receiving antenna, characterized in that the slot is formed in the center of the patch radiation element in the diagonal direction of the array direction axis.
6. The method according to any one of claims 1 to 5,
The patch radiating element is composed of four first, second, third, fourth patch radiating elements arranged in sequence,
And the distance between the second and third patch radiating elements is shorter than the distance between the first and second patch radiating elements and the distance between the third and fourth patch radiating elements.
The method according to claim 6,
And the distance between the first and second patch radiating elements is the same as the distance between the third and fourth patch radiating elements.
The method of claim 7, wherein
The feed line,
A first feeding line connecting the first and second patch radiating elements to a letter 'c';
A second feed line connecting the third and fourth patch radiating elements to a letter 'c'; And
And a third feed line connecting the first feed line and the second feed line to a letter 'c'.
The third feed line has a point closer to the first patch radiating element than the center of the first feed line as a first connection point, and a second point closer to the fourth patch radiating element than the center of the second feed line. GPS receiving antenna characterized in that it has a connection point.
The method of claim 8,
Assuming that the first, second, third, and fourth patch radiating elements are arranged at equal intervals, the first connection point is the middle of the first feed line, and the second connection point is the second feed line. GPS reception antenna, characterized in that the middle of.
The method of claim 8,
The first feed line has a width from the first connection point to the first bending point of the radiating element side is greater than the width of the other portion,
And said second feed line has a width from said second connection point to said fourth patch radiating element side bending point greater than that of another portion.
The method of claim 10,
The first feed line has another portion within a range in which the width from the connection point with the first and second patch radiating elements to each bending point is smaller than the width from the first connection point to the bending point at the first patch radiating element side. Greater than the width of,
The second feed line has another portion within a range in which a width from a connection point with the third and fourth patch radiating elements to each bend point is smaller than a width from the second connection point to the bend point at the fourth patch radiating element side. GPS receiving antenna, characterized in that greater than the width.
The method of claim 8,
The third feed line is a GPS receiving antenna, characterized in that the width from the connection point to each bending point with the first, second feed line is larger than the width of the other portion.
The method of claim 8,
And a feeding unit connected to a center of the third feed line and having a width equal to a width from a connection point to each bend point to the first and second feed lines.
The method of claim 8,
And a feeding unit connected to a center inside of the third feed line and having a feeding point formed therein.
6. The method according to any one of claims 1 to 5,
And said patch radiating element is within six ranges.

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