KR20200040403A - Inverted Feeding Microstrip Ppatch Aantenna for vehicle radar - Google Patents

Abstract

The present disclosure relates to an inverted feeding microstrip patch antenna, which uses a feeding layer of an inverted feeding microstrip structure and a reflective layer shielding the feeding layer to enable surface wave suppression on a single layer. According to the present disclosure, through the feeding layer of a reverse feeding microstrip patch structure and the reflective layer shielding the feeding layer, signal distortion caused by surface waves is minimized and economic costs are low.

Description

Reverse Feeding Microstrip Patch Antenna {Inverted Feeding Microstrip Ppatch Aantenna for vehicle radar}

The present disclosure relates to a microstrip patch antenna for a vehicle radar that enables surface wave suppression on a single layer by using a feed layer of an inverted microstrip structure and a reflective layer of a structure that shields it. The present disclosure uses a feed layer of an inverted feeding microstrip structure formed on a lower portion of a dielectric layer to correspond to an antenna patch and a reflective layer that shields the reverse feed microstrip to enable surface wave suppression on a single layer. Patch antenna.

In general, a radar antenna for replacing a proximity sensor of a vehicle or for obtaining a high resolution image at a short distance uses a frequency of a millimeter wave band based on a single antenna or a small number of array antennas. Since the frequency of the millimeter wave band is superior to the frequency of the microwave band, it has excellent linearity and has wideband characteristics, and thus is widely applied to radar and communication services. In addition, since the millimeter wave band has a small wavelength, it is easy to miniaturize the size of an antenna, and thus has an advantage of significantly reducing the size of the system. However, in the case of such a microstrip patch antenna, there is a problem in that signal distortion occurs due to the influence of surface waves in free space, and excessive ripple occurs in directional characteristics in the electric field plane.

In order to minimize the influence of the surface wave, a technique for realizing a printed circuit board with at least two or more multi-layers has been proposed. For example, it may be a method of adding a dielectric cover layer or employing a multi-layer substrate in which a plurality of dielectric layers are stacked. However, in the case of an antenna having such a multi-layer structure, since the signal leakage increases as the thickness of the substrate increases and the dielectric constant of the substrate increases, the radiation efficiency of the patch antenna decreases and the antenna gain decreases. There are disadvantages. In addition, the multi-layered structure of the antenna increases the manufacturing cost and there is a disadvantage that the manufacturing completeness of the antenna decreases.

Against this background, the present disclosure applies a feeding layer of an inverted microstrip of an inverted feeding microstrip structure, so that a reverse feeding microstrip patch for an automotive radar capable of suppressing surface waves on a single layer It is intended to provide an antenna.

In addition, the present disclosure is to provide a reverse feeding microstrip patch antenna for an automotive radar that can minimize signal distortion by additionally forming a reflective layer having a structure to support the feeding layer line of the reverse feeding microstrip structure.

In order to achieve the above object, in one aspect, the present disclosure includes a dielectric layer made of a dielectric material, an antenna patch layer including an antenna patch of a conductive metal material in a predetermined region above the dielectric layer, and a reverse direction on the lower surface of the dielectric layer. A microstrip for automotive radar including a feeding layer made of a conductive metal material formed in the form of a microstrip patch and a reflective layer capable of shielding the feeding layer by forming a feeding layer insertion groove into which the feeding layer can be inserted. Patch Antenna A microstrip patch antenna for reverse feeding is provided.

In another aspect, the present disclosure includes a dielectric layer made of a dielectric material, an antenna patch made of a conductive metal material formed in a reverse microstrip patch shape in a region below the dielectric layer, and a lower surface of the dielectric layer so that the antenna patch contacts one side. A vehicle including a feeding layer formed in the form of a reverse microstrip patch, and an inserting groove into which the antenna patch and the feeding layer can be inserted, are formed on a surface to shield the antenna patch and the feeding layer. Microstrip patch antenna for radar Provides a reverse feed microstrip patch antenna.

As described above, according to the present disclosure, through the feed layer of the reverse feeding microstrip patch structure and the reflective layer shielding the same, the miniature microstrip patch antenna of a single layer structure with low economic cost while minimizing signal distortion due to surface waves is provided. Can provide.

1 is a view showing a perspective view of a general microstrip patch antenna.
FIG. 2 is a diagram showing a signal generated in free space as a computer simulation result in the case of a general microstrip patch antenna.
FIG. 3 is a diagram illustrating an directional characteristic (E-plane pattern) in an electric field (E) plane in the case of a general microstrip patch antenna.
4 is a diagram illustrating distortion of a main beam pattern due to a structure of a signal conversion port in a general microstrip patch antenna.
5 is an exploded perspective view of a microstrip patch antenna for a vehicle radar according to an embodiment of the present disclosure, and an inversely fed microstrip patch antenna.
FIG. 6 is a perspective view of a microstrip patch antenna for an automotive radar according to an embodiment of the present disclosure, in a case where the antenna patch layer is formed as a single band on the dielectric layer in the reverse feeding microstrip patch antenna.
FIG. 7 is a perspective view of a microstrip patch antenna for an automotive radar according to an embodiment of the present disclosure in a case where the antenna patch layer is formed of a dual band of an antenna patch and a patch groove, and an external conductive film in a reverse-feed microstrip patch antenna. to be.
8 is a plan view illustrating a case in which a via hole formed around a patch groove is formed in two rows in a reversed feeding microstrip patch antenna for a microstrip patch antenna for an automobile radar according to an embodiment of the present disclosure.
FIG. 9 is a plan view showing a case where a direct feeding is performed through a shorting hole between an antenna patch and a lower feeding layer in a microstrip patch antenna for an automotive radar microstrip patch antenna according to an embodiment of the present disclosure.
10 is a microstrip patch antenna for an automotive radar according to an embodiment of the present disclosure, in a reverse feeding microstrip patch antenna, in the case of a dual band, an antenna patch is formed in a circular shape, and an outer edge of the patch groove is formed in a square shape. It is the top view shown.
11 is an example of a case in which a slot is formed in a form surrounding a via hole along an edge of an external conductive layer in the case of a dual band in a microstrip patch antenna for a vehicle radar according to an embodiment of the present disclosure. It is one floor plan.
12 is a plan view showing a case where an antenna patch is formed on a lower portion of a dielectric in a dual-band microstrip patch antenna for a reverse power feeding microstrip patch antenna for an automotive radar according to an embodiment of the present disclosure.
13 is a cross-sectional view illustrating a case where an antenna patch is formed on a lower portion of a dielectric in the case of a dual-band microstrip patch antenna for an inverted feeding microstrip patch antenna for an automotive radar according to an embodiment of the present disclosure.
14 is a perspective view of a microstrip patch antenna for an automotive radar according to an embodiment of the present disclosure in a case where a feed layer is formed under a dielectric layer in a reverse-feed microstrip patch antenna.
15 is a cross-sectional view showing a case where coupling feeding is performed between an antenna patch layer and a feeding line in the case of a single band in a microstrip patch antenna for an inverse feeding microstrip patch antenna for an automotive radar according to an embodiment of the present disclosure.
16 is a cross-sectional view showing a case where coupling feeding is performed between an antenna patch and a feeding line in the case of a dual band in a microstrip patch antenna for an inverse feeding microstrip patch antenna for an automotive radar according to an embodiment of the present disclosure.
17 is a cross-sectional view showing a case where direct feeding is performed by a shorting hole between an antenna patch and a feeding line in the case of a dual band in a microstrip patch antenna for a vehicle radar according to an embodiment of the present disclosure. .
FIG. 18 is a perspective view of a microstrip patch antenna for an automotive radar according to an embodiment of the present disclosure in a case where a reflective layer capable of shielding the feed layer is formed under the dielectric layer in the reverse feeding microstrip patch antenna.
19 is a view showing a top view of a reflective layer made of a conductor in a microstrip patch antenna for a reverse power feeding microstrip patch antenna for an automotive radar according to an embodiment of the present disclosure.
20 is a view showing a plan view of a reflective layer made of a conductor component in only a part of the area around the feeding layer insertion groove in a reverse feeding microstrip patch antenna for a microstrip patch antenna for an automobile radar according to an embodiment of the present disclosure.
FIG. 21 is a diagram showing a signal generated in free space as a computer simulation result for a microstrip patch antenna for a vehicle radar of the present disclosure in a reverse-feed microstrip patch antenna.
22 is a diagram illustrating an directional characteristic (E-plane pattern) in an electric field (E) plane for a microstrip patch antenna for a reverse power feeding microstrip patch antenna for an automotive radar according to an embodiment of the present disclosure.

Hereinafter, some embodiments of the present disclosure will be described in detail through exemplary drawings. In describing the components of the present disclosure, terms such as first, second, A, B, (a), and (b) may be used. These terms are only for distinguishing the component from other components, and the nature, order, or order of the component is not limited by the term. When a component is described as being "connected", "coupled" or "connected" to another component, that component may be directly connected to or connected to the other component, but another component between each component It should be understood that elements may be "connected", "coupled" or "connected".

1 is a view showing a perspective view of a general microstrip patch antenna. Referring to FIG. 1, a general microstrip patch antenna is composed of a dielectric layer 10, an antenna patch 11, a lower conductor 12, and a feeding line 13. The dielectric layer 10 may be made of a dielectric material of various materials such as FR-4, Teflon, and ceramic. A lower conductor 12 made of a conductor is formed under the dielectric layer 10, and an antenna patch 11 made of a conductor and a feeding line 13 are formed on the upper surface of the dielectric layer 10. The power supply line 13 supplies power to the antenna patch 11.

In particular, the antenna for a car radar is generally implemented as a patch antenna using a single-layer (1-layer) printed circuit board. In the case of using a single layer or a small number of array antenna structures, the surface wave effect of the feeder line introduced into the antenna patch Therefore, there is a problem in that the antenna radiation pattern in the vertical electric field direction is distorted, and thus the performance of the antenna is deteriorated. In particular, when the length of the feed line is longer than the wavelength (1λ or more), radiation is made in the free space as the power proceeds on the feed line, and the radiated components act as components that cause distortion of the signal radiated from the antenna. do. This phenomenon applies equally to the design and verification of the antenna.

FIG. 2 is a diagram showing a signal generated in free space as a computer simulation result in the case of a microstrip patch antenna, and FIG. 3 is a diagram showing an E-plane pattern in an electric field (E) plane. . 2 and 3, it can be seen that in the case of the microstrip patch antenna, excessive ripple occurs in the directional characteristic in the electric field plane due to signal distortion in free space.

In particular, the microstrip patch antenna for automobile radar using the millimeter wave band requires a signal transition port for converting signals for verification on one side of the feed line, and the structure of the feed line and signal conversion port is required. Therefore, as shown in FIG. 4, distortion of the main beam pattern occurs, and this causes a problem that it is difficult to grasp the antenna performance. Moreover, when the signal conversion port is present, the ripple characteristic of the signal pattern of the microstrip patch antenna is further deteriorated, so an antenna design is required to minimize the influence of the power supply line and the signal conversion port.

The present disclosure provides a reverse feeding microstrip patch antenna structure capable of minimizing signal distortion due to surface waves while maintaining a single layer by constructing a feeding layer with a reverse feeding microstrip patch structure and shielding it through a reflective layer. In addition, hereinafter, the reverse feeding microstrip patch antenna of the present disclosure will be described as an example in which the radar is used as a vehicle radar, but may be used in various electronic devices such as aircraft, ships, or communication devices as well as automobiles, and riders ( lidar) or camera applications.

For reference, the types of radars that can be used in vehicles include pulse radars, bistatic radars, and FMCW (Frequency-Modulated Continuation Waveform) radars. Can be used. A pulse radar is a radar that uses a pulse with a sufficiently wide gap compared to the pulse width, and a bistatic radar is a radar that maintains a distance between each other using a separate antenna between a transmitter and a receiver, and the FMCW radar modulates the frequency. It is a radar that detects the distance from an object. Among them, in the case of an FMCW radar, a continuous signal whose frequency is changed is transmitted from the transmitter. This is sometimes called a chirp radar system. The waveform reflected from the vehicle to be tracked can be mixed with the transmitted signal to generate a CW signal indicating the distance between the radar transmitter / receiver and the vehicle to be tracked. The CW (Continuous Wave) signal is determined by sweeping up the frequency and then down-regulating the frequency again.

The present disclosure provides a microstrip patch antenna structure capable of minimizing signal distortion due to surface waves while maintaining a single layer by configuring the feed layer as a reverse microstrip patch and shielding it through a reflective layer.

5 is an exploded perspective view of a microstrip patch antenna for a vehicle radar according to an embodiment of the present disclosure, and an inversely fed microstrip patch antenna.

Referring to FIG. 5, the microstrip patch antenna for automobile radar of the present disclosure includes a reverse feeding microstrip patch antenna 100 as a dielectric layer 110, an antenna patch layer 120, a feeding layer 130, and a reflective layer 140. It can be done.

The dielectric layer 110 may be made of a dielectric material of various materials such as FR-4, Teflon, and ceramic. At this time, the dielectric layer 110 may be formed with a plurality of via holes 112 penetrating the dielectric layer 110 in a form surrounding the antenna patch layer 110 formed thereon. Accordingly, the dielectric layer 110 may be electrically connected to the lower reflective layer 140 by a plurality of via holes 112, and may serve to suppress signals leaking in the form of surface waves from the antenna patch layer 120. .

At this time, the plurality of via holes 112 surrounding the antenna patch layer 120 may be spaced apart at various distances, but at a distance of 1/2 (λ / 2) or less of the wavelength emitted from the antenna patch layer 120 By separating, it is possible to prevent the wavelength λ emitted from the antenna patch layer 120 from escaping between the plurality of via holes 112.

The antenna patch layer 120 may be made of a conductive metal, and silver (Ag) or copper (Cu) may be exemplified as a representative conductive metal. The antenna patch layer 120 may be formed on the dielectric layer 110 in a printing method such as printing.

The antenna patch layer 120 may be formed of a single band structure. In this case, the antenna patch of a single structure will form one antenna patch layer 120. Alternatively, the antenna patch of a single structure and a patch groove of a predetermined interval may be formed of a dual band structure in which an external conductive film formed by being spaced apart is formed together. In this case, the antenna patch, the patch groove, and the external conductive layer will form one antenna patch layer 120. The case where the antenna patch layer has a dual band structure will be described in more detail below. Meanwhile, the length of the antenna patch layer 120 may have a size of λ / 2 based on the operating frequency (λ) of the microstrip patch antenna.

The feeding layer 130 may be formed of a conductive metal formed on the lower surface of the dielectric layer 110. As the conductive metal constituting the power feeding layer 130, silver (Ag) or copper (Cu) may be mentioned as in the antenna patch layer 120. In addition, the feeding layer 130 may be formed under the dielectric layer 110 by a printing method such as printing, like the antenna patch layer 120.

The feeding layer 130 may supply power to the antenna patch layer 120 through a coupling feeding or direct feeding method. When the coupling feeding is performed, the upper antenna patch layer 120 and the feeding layer 130 are arranged to overlap by a predetermined interval in the vertical direction, and between the overlapping regions between the antenna patch layer 120 and the feeding layer 130 Feeding will be made by the capacitance formed in the. On the other hand, for direct feeding, this may be realized by forming a shorting hole electrically connecting the antenna patch layer 120 and the feeding layer 130.

The feeding layer 130 extends from the feeding line 132 and the feeding line 132 extending to the vertical lower portion of the antenna patch layer 120 for coupling feeding or direct feeding to the antenna patch layer 120 It may be formed of a signal conversion port 134 formed on the opposite side of the patch layer 120. The signal conversion port 134 is a part for converting a signal for verification of a microstrip patch antenna for an automotive radar using a millimeter wave band.

The reflective layer 140 serves to fix the structure consisting of the dielectric layer 110, the antenna patch layer 120, and the feeding layer 130, and at the same time, to insert the feeding layer 130 formed under the dielectric layer 110. A feeding layer insertion groove 142 that can be formed on the upper surface. The reflective layer 140 may be formed entirely of a conductor component, or only a part of the region surrounding the feed layer insertion groove 142 may be formed of a conductor component, and the other portion may be formed of a non-conductor component. The conductor component constituting the reflective layer 140 may use an area plated on a printed circuit board.

Since the microstrip antenna structure disclosed above is a signal conversion port 134 and a feed layer 130 composed of a feed line 132 is formed on the lower surface of the dielectric layer 110 and is shielded by the reflective layer 140 below, the antenna It can minimize the effect on the radiation characteristics of, and has the effect of being easy to manufacture and reducing the manufacturing cost because it maintains the structure of a single layer.

Microstrip patch antenna for automotive radar of the present disclosure In the reverse feeding microstrip patch antenna 100, the antenna patch layer 120 and the feeding layer 130 may be modified in various forms, and the details will be described in more detail. Shall be

FIG. 6 is a perspective view of a microstrip patch antenna for an automotive radar according to an embodiment of the present disclosure in a case where the antenna patch layer 120 is formed as a single band on the dielectric layer 110 in a reverse-feed microstrip patch antenna. . For reference, here, for convenience of description, the antenna patch layer 120 is shown to be made of a constant thickness, but since the antenna patch layer 120 is made of a thin metal film, its thickness is compared to that of the dielectric layer 110. It will be very small.

Referring to FIG. 6, the shape in which the antenna patch layer 120 is formed may be formed in a polygonal shape of various shapes such as a triangle or a pentagon, as well as a square or a circle. The antenna patch layer 120 having a single band structure may be easily formed on the dielectric layer 110 by a printing method.

7 is a microstrip patch antenna for an automotive radar according to an embodiment of the present disclosure, in a reverse feeding microstrip patch antenna, the antenna patch layer 120 is an antenna patch 122, a patch groove 123, and a dual band of an external conductive film. It is a view showing a perspective view when formed.

Referring to FIG. 7, the antenna patch layer 120 has an antenna patch 122 and a patch groove 123 formed to be spaced a predetermined distance therefrom, and an external conductive film 124 having a structure surrounding the antenna patch 122. It can be made. Here, both the antenna patch 122 and the outer conductive layer 124 may be formed of a conductor component of the same material, and the patch groove 123 corresponding to the space between the antenna patch 122 and the outer conductive layer 124 is It may be formed by a method such as etching. In the case of forming the external conductive film 124 in the form surrounding the antenna patch 122, since a plurality of via holes 112 and 126 are simultaneously formed from the surface of the external conductive film 124 to the dielectric layer 110, The via hole 126 formed in the external conductive layer 124 and the via hole 112 formed in the dielectric layer 110 will have the same shape and position.

Even in this case, the via hole 126 around the outer conductive layer 124 and the via hole 112 of the dielectric layer 110 are preferably formed in a form surrounding the patch groove 123 and the feeding layer 130. These via holes 112 and 126 serve to minimize the influence of electromagnetic waves on areas other than the antenna patch layer 120 and the feed layer 130, and due to the structure of the via holes 112 and 126, reverse microstrip patch It is possible to minimize the effect of the current emitted from the feeding layer 130 of the antenna radiation.

At this time, the via hole 126 around the patch groove 123 formed on the surface of the external conductive film 124 and the via hole 112 of the dielectric layer 110 may be formed in a single row arrangement, but in a plurality of two or more rows. It may be formed. 8 is a plan view illustrating a case where via holes 126 formed around a patch groove 123 are formed in two rows in a microstrip patch antenna for a reverse power feeding microstrip patch antenna for an automotive radar according to an embodiment of the present disclosure.

Meanwhile, as described above, in the case of the dual band structure of the antenna patch 122 and the external conductive layer 124, the antenna patch 122 may be coupled to the lower feeding layer 130 or directly fed or coupled. When coupling feeding is performed, the antenna patch 122 and the feeding layer 130 on the upper side are arranged to overlap by a predetermined interval in the vertical direction, and are formed in an overlapping region between the antenna patch 122 and the feeding layer 130 Feeding will be performed by the capacitance, and in the case of direct feeding, feeding may be performed by forming a shorting hole 128 electrically connecting the antenna patch 122 and the feeding layer 130. 9 is a microstrip patch antenna for an automotive radar according to an embodiment of the present disclosure, in the reverse feeding microstrip patch antenna, the antenna patch 122 and the lower feeding layer 130 are directly fed through the shorting hole 128. It is a plan view showing a case.

Also, the antenna patch 122 and the patch groove 123 forming the antenna patch layer 120 may have the same shape or different shapes. For example, in the case of FIG. 9 shown above, it is a plan view showing a case where the antenna patch 122 and the patch groove 123 formed around it are formed in the same rectangular shape. On the other hand, in the case of FIG. 10, the antenna patch 122 is formed in a circular shape, and the outer edge of the patch groove 123 is a plan view illustrating a case in which a rectangular shape is formed. Of course, the antenna patch 122 may be formed in various polygonal shapes such as a triangle and a square as well as a circular shape, and the outer border of the patch groove 123 may be formed in various shapes such as a circular, triangular, or square shape.

On the other hand, when the antenna patch layer 120 is configured as a dual band, the surface of the external conductive layer 124 includes a plurality of via holes 126 electrically connected to the lower dielectric layer 110, but the via holes 126 Additional slots 129 may be formed on some surfaces of the remaining unformed regions. The slot 129 may be formed for the purpose of reducing signal distortion due to the influence of the surface wave or improving antenna performance, and may be formed in various forms such as a straight line, a curved straight line, and a curved line. 11 is a plan view illustrating an example in which the slot 129 is formed in a form surrounding the via hole 126 along the edge of the outer conductive layer 124.

In addition, the microstrip patch antenna for the automotive radar of the present disclosure may be formed on the upper surface of the dielectric 110, although the antenna patch 122 constituting the antenna patch layer 120 may be formed on the reverse feeding microstrip patch antenna. ) May be formed in the reverse direction on the lower surface. 12 is a microstrip patch antenna for a car radar according to an embodiment of the present disclosure, in a reverse-feed microstrip patch antenna, a diagram showing a top view of an antenna patch 122 formed under the dielectric 110 in the case of a dual band , FIG. 13 is a view showing a sectional view in this case.

First, referring to FIG. 12, since the antenna patch 122 is formed on the lower surface of the dielectric layer 110, the patch groove 123, the outer conductive layer 124, and the outer conductive layer ( A plurality of via holes 126 formed on the surface of 124 will be formed.

At this time, the antenna patch 122 and the feeding layer 130 under the dielectric layer 110 must be electrically connected, since in this case, the antenna patch 122 and the feeding layer 130 are located on the same plane, in this case a couple Power can be supplied by direct feeding rather than ring feeding. That is, as illustrated in FIG. 13, the antenna patch 122 and the feeding layer 130 are disposed in contact with one side, so that feeding by contact is made without being caused by a shorting hole. As described above, when the antenna patch 122 and the feed layer 130 are located on the same plane, the feed layer insertion groove 142 formed in the reflective layer 140 is formed so that the antenna patch 122 can also be inserted together. desirable.

FIG. 14 is a perspective view of a microstrip patch antenna for an automotive radar according to an embodiment of the present disclosure in a case where a feed layer 130 is formed under the dielectric layer 110 in a reverse feeding microstrip patch antenna.

Referring to FIG. 14, a reverse microstrip patch is formed on the lower surface of the dielectric layer 110 of the feed layer 130. The feeding layer 130 is formed to extend from the feeding line 132 and the feeding line 132 for supplying power to the antenna patch layer 120 in the case of a single band and the antenna patch 122 in the case of the dual band. Signal conversion port 134. The signal conversion port 134 is formed at one end of the feed line 122 and may be formed in a rectangular structure having a width greater than the width of the feed line 132. In addition, the via hole 112 formed in the dielectric layer 110 may be arranged in a form surrounding the antenna patch layer 120 and the feeding layer 130.

The power supply line 132 may partially overlap the antenna patch layer 120 in a vertical direction so as to supply power to the antenna patch layer 120. Accordingly, coupling feeding may be performed by capacitance, or direct feeding may be performed by a shorting hole connecting the antenna patch layer 120 and the feeding line 132.

FIG. 15 is a microstrip patch antenna for a vehicle radar according to an embodiment of the present disclosure. In the reverse feeding microstrip patch antenna, coupling feeding between the antenna patch layer 120 and the feeding line 132 is performed in the case of a single band. It is a sectional view showing. As illustrated in FIG. 15, the antenna patch layer 120 above the dielectric layer 110 is disposed such that the power supply line 132 and the partial region d under the dielectric layer 110 overlap. Due to this, a coupling capacitance is formed between the antenna patch layer 120 and the feeding line 132, and power can be supplied to the antenna patch layer 120 through this.

The coupling feeding method may be applied to the antenna patch layer 120 in the case of a dual band composed of an antenna patch 122 and an external conductive layer 124. FIG. 16 shows a case where coupling feeding is performed between the antenna patch 122 and the feeding line 132 in the case of a dual band in a microstrip patch antenna for a vehicle radar according to an embodiment of the present disclosure. It is a sectional view shown.

Alternatively, a direct feeding may be performed by forming a shorting hole that electrically connects the antenna patch 122 and the feeding line 132, and FIG. 17 is a microstrip patch antenna for automobile radar according to an embodiment of the present disclosure. In the strip patch antenna, in the case of a dual band, a cross-sectional view showing a case where direct feeding is performed by the shorting hole 128 between the antenna patch 122 and the feeding line 132. The shorting hole 128 may electrically connect the antenna patch 122 and the feeding line 132 by forming a cylindrical inner surface with a conductive material.

18 is a microstrip patch antenna for an automobile radar according to an embodiment of the present disclosure, in a reverse feeding microstrip patch antenna, when a reflective layer 140 capable of shielding the feeding layer 130 is formed under the dielectric layer 110 It is a view showing a perspective view of.

Referring to FIG. 18, the reflective layer 140 serves to fix the dielectric layer 110, the antenna patch layer 120, and the feeding layer 130. Particularly, since the reflective layer 140 includes a feeding layer insertion groove 142 into which the feeding layer 130 can be inserted, it may serve to shield the feeding layer 130.

The reflective layer 140 may be formed of a conductor component, or only a portion of the surrounding area of the feed layer insertion groove 142 may be formed of a conductor component.

19 is a view showing a top view of a reflective layer made of a conductor in a microstrip patch antenna for a reverse power feeding microstrip patch antenna for an automotive radar according to an embodiment of the present disclosure.

Referring to FIG. 19, various types of conductors constituting the reflective layer 140 may be used, such as aluminum or copper, and a low-loss printed circuit board may be used in an antenna in an automobile field for the purpose of preventing deterioration of antenna performance. For example, a low-loss printed circuit board may be used by edge-plating a portion of the high-loss epoxy substrate.

Alternatively, as shown in FIG. 20, in a microstrip patch antenna for an automotive radar according to an embodiment of the present disclosure, in a reverse feeding microstrip patch antenna, a reflective layer made of a conductor component in only a part of the area around the feed layer insertion groove may be used. .

In this case, the reflective layer 140 may be composed of only a conductor region 144 having a rectangular structure surrounding the feed layer insertion groove 142 as a conductor, and the rest of the regions may be composed of a non-conductor. At this time, the non-conductor used in the reflective layer 140 may be made of a material such as rubber, plastic, glass, etc., and the conductor region 144 may be formed by attaching a thin plated film or copper foil tape on the non-conductor. It might be.

As described above, the microstrip patch antenna for the automotive radar of the present disclosure The reverse feeding microstrip patch antenna comprises a reverse microstrip patch of the feed layer and shields it through the reflective layer, thereby maintaining a single layer and distorting the signal due to surface waves Can be minimized.

21 is a microstrip patch antenna for a vehicle radar of the present disclosure, a diagram showing a signal generated in free space for a reverse feeding microstrip patch antenna as a computer simulation result, and FIG. 22 is a microstrip patch for a vehicle radar of the present disclosure. This is a diagram showing the directional characteristic (E-plane pattern) in the electric field (E) plane for the antenna-powered microstrip patch antenna. As shown in FIGS. 21 and 22, in the case of a microstrip patch antenna for an automotive radar of the present disclosure, in the case of a reversely fed microstrip patch antenna, signal distortion in free space caused by a conventional antenna is reduced, and in the electric field plane It can be seen that the ripple phenomenon is reduced in the directivity characteristics.

The reverse feeding microstrip patch antenna of the present disclosure may be applied to a high-resolution image radar using a plurality of sensors, along with a function of detecting a car, a person, a sign, a curb, etc. through object recognition in a short range.

The above description and the accompanying drawings are merely illustrative of the technical spirit of the present disclosure, and those of ordinary skill in the art to which the present disclosure pertains combine combinations of configurations without departing from the essential characteristics of the present disclosure. , Various modifications and variations such as separation, substitution and change will be possible. Therefore, the embodiments disclosed in the present disclosure are not intended to limit the technical spirit of the present disclosure, but to explain the scope, and the scope of the technical spirit of the present disclosure is not limited by the embodiments. That is, within the scope of the present disclosure, all of the constituent elements may be selectively combined and operated. The scope of protection of the present disclosure should be interpreted by the claims below, and all technical spirits within the scope equivalent thereto should be interpreted as being included in the scope of the present disclosure.

100: microstrip patch antenna
110: dielectric layer 112: dielectric layer via hole
120: antenna patch layer 122: antenna patch
123: patch groove 124: outer conductive film
126: external conductive film via hole 128: shorting hole
129: slot 130: feed layer
132: feed line 134: signal conversion port
140: shielding layer 142: feed layer insertion groove
144: conductor area

Claims (16)

A dielectric layer made of a dielectric material;
An antenna patch layer including an antenna patch made of a conductive metal material in a predetermined area above the dielectric layer;
A feed layer made of a conductive metal material formed in a reverse microstrip patch shape on a lower surface of the dielectric layer; And
A microstrip patch antenna for an automotive radar including a reflective layer capable of shielding the feed layer by forming a feed layer insertion groove into which the feed layer can be inserted. Reverse feed microstrip patch antenna. According to claim 1,
The dielectric layer is arranged in a form surrounding the antenna patch at the top, and a plurality of dielectric layer via holes electrically connected to the reflective layer at the bottom are formed. According to claim 2,
The plurality of dielectric layer via-holes are arranged at a distance of 1/2 or less of a wavelength emitted from the antenna patch layer. According to claim 3,
The antenna patch layer
A patch groove formed at a predetermined distance around the antenna patch; And
A microstrip patch antenna for an automotive radar further comprising an external conductive film formed around the patch groove. According to claim 4,
The antenna patch is a microstrip patch antenna for automobile radars made of a circular or polygonal structure. According to claim 4,
The patch groove is a microstrip patch antenna for automobile radars made of a circular or polygonal structure. According to claim 4,
The outer conductive film is positioned on a vertical line with a plurality of dielectric layer via holes formed in the dielectric layer, and is arranged in a form surrounding the patch groove at the top, and for a vehicle radar in which a plurality of outer conductive film via holes are formed to be electrically connected to the dielectric layer. Microstrip patch antenna Reverse feed microstrip patch antenna. The method of claim 7,
The plurality of dielectric layer via holes and the plurality of external conductive film via holes are formed by a plurality of two or more rows of microstrip patch antennas for automotive radar. According to claim 4,
The outer conductive film further includes a slot formed in a predetermined area in a form surrounding the plurality of outer conductive film via holes along an edge. A microstrip patch antenna for a reverse power feeding microstrip patch antenna. According to claim 1,
The length of the antenna patch is a microstrip patch antenna for an automotive radar, which is 1/2 of the operating frequency of the microstrip patch antenna. According to claim 1,
The feeding layer extends to a vertical lower portion of the antenna patch, and a feeding line arranged to overlap the antenna patch by a predetermined interval in a vertical direction; And
A microstrip patch antenna for an automotive radar including a signal conversion port extending from the feed line and formed on the opposite side of the antenna patch. The method of claim 11,
A microstrip patch antenna for a vehicle radar including a shorting hole through which the antenna patch and the feed line penetrate vertically to provide electrical connection. The method of claim 11,
The signal conversion port is a microstrip patch antenna for an automotive radar formed in a rectangular structure having a width greater than the width of the feed line. According to claim 1,
The reflective layer is a microstrip patch antenna for an automotive radar in which a part of the periphery or the entire area of the feed layer insertion groove is made of a conductor component. A dielectric layer made of a dielectric material;
An antenna patch made of a conductive metal material formed in a reverse microstrip patch type in a certain area under the dielectric layer;
A feeding layer formed in the form of a reverse microstrip patch on the lower surface of the dielectric layer so that one side contacts the antenna patch; And
A microstrip patch antenna for automobile radar including a reflective layer capable of shielding the antenna patch and the feed layer by forming an insertion groove into which the antenna patch and the feed layer can be inserted. Reverse feed microstrip patch antenna. The method of claim 15,
A patch groove formed in a larger area than the antenna patch on the dielectric layer; And
A microstrip patch antenna for an automotive radar further comprising an external conductive film formed around the patch groove.

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