KR102206670B1 - Antenna assembly and method of providing frequency adaptive isolation - Google Patents

Abstract

The present invention relates to an antenna assembly which provides frequency adaptive isolation. The antenna assembly comprises: a MIMO antenna array provided as a multi-band antenna operable with respect to each of a plurality of frequency bands, and including a first antenna and a second antenna simultaneously operating with respect to the same operating frequency band; an isolation element which reduces interference between the first antenna and the second antenna; a matching circuit connected to the isolation element through a feed point of the isolation element and configured to adjust a frequency band in which the isolation element reduces the interference to at least one of the plurality of frequency bands; and a controller which obtains information on the operating frequency band, and controls the matching circuit to match a frequency band in which the isolation element reduces the interference to the operating frequency band. According to the present invention, transmission/reception performance of an antenna can be improved.

Description

Antenna assembly and method of providing frequency adaptive isolation {ANTENNA ASSEMBLY AND METHOD OF PROVIDING FREQUENCY ADAPTIVE ISOLATION}

The present invention relates to an antenna assembly providing frequency adaptive isolation and a method of providing frequency adaptive isolation, and more particularly, an antenna assembly providing isolation between MIMO antennas operable in a plurality of frequency bands. And a method of providing an isolation degree between beautiful antennae.

Recently, with interest in smart antennas, research on multiple input multiple output (MIMO) antennas using multiple transmit/receive antennas has been actively conducted.

Meanwhile, in the case of a MIMO antenna, in order to secure transmission and reception performance, it is important to reduce electromagnetic mutual coupling between each antenna and secure sufficient isolation. Thus, conventionally, a method of separating a plurality of antennas from each other has been used.

However, due to the recent trend of miniaturization of antenna modules and a trend in which a number of antennas are integrated and installed in a narrow space, there is a problem that it is difficult to secure isolation with only the conventional method, and research to solve this problem is actively being conducted. .

An object of the present invention is to improve the transmission/reception performance of an antenna by improving the isolation between antennas using an isolation element.

Another object of the present invention is to improve the degree of isolation between MIMO antennas using a frequency adaptive isolation element operable in a plurality of frequency bands.

Another object of the present invention is to improve the bandwidth of the MIMO antenna through the isolation element.

The problem to be solved by the present invention is not limited to the above-described problems, and problems that are not mentioned will be clearly understood by those of ordinary skill in the art from the present specification and the accompanying drawings. .

According to an aspect of the present invention, as an antenna assembly providing frequency adaptive isolation, a first antenna and a second antenna, each provided as a multi-band antenna operable for a plurality of frequency bands, and simultaneously operating for the same operating frequency band Mimo (MIMO) antenna array including a; An isolation element for reducing interference between the first antenna and the second antenna; A matching circuit that is connected to the isolation element through a feed point of the isolation element and controls a frequency band in which the isolation element reduces interference in at least one of the plurality of frequency bands. ); And a controller that obtains information on the operating frequency band, and controls the matching circuit to match a frequency band in which the isolation element reduces interference to the operating frequency band.

According to another aspect of the present invention, in a method for providing frequency adaptive isolation, operation of a MIMO antenna array including a first antenna and a second antenna provided as multi-band antennas operable for a plurality of frequency bands, respectively. Obtaining information on a frequency band; Matching a frequency characteristic of an isolation element for reducing interference between the first antenna and the second antenna to the operating frequency band; And reducing, by the isolation element, interference between the first antenna and the second antenna with respect to the operating frequency band. A method for providing frequency adaptive isolation may be provided.

According to another aspect of the present invention, an antenna assembly providing a frequency adaptive isolation degree, comprising: a first antenna and a second antenna operable in at least one of a first frequency band and a second frequency band; A first isolation mode providing an isolation degree between the first antenna and the second antenna with respect to the first frequency band, and a second isolation providing an isolation degree between the first antenna and the second antenna with respect to the second frequency band An isolation element for performing at least one isolation mode among the modes; And an isolation mode performed by the isolation element to obtain information on an operating frequency frequency band of the first antenna and the second antenna, and to provide an isolation degree between the first antenna and the second antenna for the operating frequency band. An antenna assembly including a; control circuit for adjusting the control circuit may be provided.

According to another aspect of the present invention, there is provided a method for providing frequency adaptive isolation, comprising: operating a first antenna and a second antenna operable in a first frequency band and a second frequency band in the same operating frequency band; Obtaining information on the operating frequency band; When the operating frequency band is the first frequency band, matching frequency characteristics of an isolation element providing an isolation degree between the first antenna and the second antenna to a first frequency band; When the operating frequency band is the second frequency band, matching frequency characteristics of the isolation element to a second frequency band; And reducing, by the isolation element, interference between the first antenna and the second antenna in the operating frequency band. The method for providing frequency adaptive isolation may be provided.

According to another aspect of the present invention, an antenna assembly providing a frequency adaptive isolation degree, comprising: a first antenna provided as a multi-band antenna operable for a plurality of frequency bands; A second antenna operating on a first frequency band, which is one of the plurality of frequency bands; A third antenna operating on a second frequency band, which is one of the plurality of frequency bands; An isolation element for reducing interference between the first antenna and the second antenna or between the first antenna and the third antenna; A matching circuit connected to the isolation element through a feed point of the isolation element and adjusting a frequency characteristic of the isolation element to at least one of the first frequency band and the second frequency band; And obtaining information on the operating frequency band of the first antenna, and when the sensed operating frequency band is the first frequency band, the matching circuit is configured to reduce interference between the first antenna and the second antenna. The matching circuit to adjust the frequency characteristic of the isolation element to match the first frequency band, and to reduce interference between the first antenna and the third antenna when the detected operating frequency band is the second frequency band An antenna assembly including a controller configured to match the frequency characteristic of the isolation element to the second frequency band may be provided.

The solution means of the subject of the present invention is not limited to the above-described solution means, and solutions that are not mentioned will be clearly understood by those of ordinary skill in the art from the present specification and the accompanying drawings. I will be able to.

According to the present invention, by using the isolation element to improve the isolation between antennas, it is possible to improve the transmission and reception performance of the antenna.

Further, according to the present invention, the degree of isolation between MIMO antennas can be improved by using a frequency adaptive isolation element operable in a plurality of frequency bands.

Further, according to the present invention, the bandwidth of the MIMO antenna can be improved through the isolation element.

The effects of the present invention are not limited to the above-described effects, and effects that are not mentioned will be clearly understood by those of ordinary skill in the art from the present specification and the accompanying drawings.

1 is a diagram illustrating an example of an installation position of an antenna assembly for a vehicle according to an embodiment of the present specification.
2 is a configuration diagram of a module-integrated smart antenna module according to an embodiment of the present specification.
3 is a block diagram illustrating an antenna assembly according to an exemplary embodiment.
4 is a diagram illustrating an antenna assembly according to an exemplary embodiment.
5 is a diagram for describing an antenna assembly according to another exemplary embodiment.
6 is a diagram for describing an antenna assembly according to another embodiment.
7 is a flowchart illustrating a method of providing a frequency adaptive isolation diagram according to an embodiment.
8 is a flowchart illustrating a method of providing a frequency adaptive isolation diagram according to another embodiment.
9 is a diagram illustrating an external structure of an antenna assembly according to an embodiment.
10 is a view showing the inside of the antenna assembly according to FIG. 9.

Since the embodiments described in the present specification are intended to clearly explain the spirit of the present invention to those of ordinary skill in the technical field to which the present invention pertains, the present invention is not limited by the embodiments described herein, and the present invention The scope of should be construed as including modifications or variations that do not depart from the spirit of the present invention.

The terms used in the present specification have been selected as general terms that are currently widely used in consideration of functions in the present invention, but this varies depending on the intention, custom, or the emergence of new technologies of those of ordinary skill in the technical field to which the present invention belongs. I can. However, if a specific term is defined and used in an arbitrary meaning unlike this, the meaning of the term will be separately described. Therefore, terms used in the present specification should be interpreted based on the actual meaning of the term and the entire contents of the present specification, rather than a simple name of the term.

The drawings attached to the present specification are for easy explanation of the present invention, and the shapes shown in the drawings may be exaggerated and displayed as needed to aid understanding of the present invention, so the present invention is not limited by the drawings.

In the present specification, when it is determined that a detailed description of a known configuration or function related to the present invention may obscure the subject matter of the present invention, a detailed description thereof will be omitted as necessary.

According to an aspect of the present application, as an antenna assembly providing frequency adaptive isolation, a first antenna and a second antenna, each provided as a multi-band antenna operable for a plurality of frequency bands, and simultaneously operating for the same operating frequency band Mimo (MIMO) antenna array including a; An isolation element for reducing interference between the first antenna and the second antenna; A matching circuit that is connected to the isolation element through a feed point of the isolation element and controls a frequency band in which the isolation element reduces interference in at least one of the plurality of frequency bands. ); And a controller that obtains information on the operating frequency band, and controls the matching circuit to match a frequency band in which the isolation element reduces interference to the operating frequency band.

The isolation element may be disposed between the first antenna and the second antenna.

The plurality of frequency bands may include at least one of an LTE frequency, a fifth generation (5G) frequency, and a GPS frequency.

The antenna assembly further includes a plate-shaped substrate, wherein the isolation element and the antenna array are disposed on a first surface of the substrate, and the matching circuit is on a second surface opposite to the first surface of the substrate. Can be placed.

One end of the isolation element may be connected to the substrate in a direction perpendicular to the substrate.

The first antenna and the second antenna may be disposed in a direction orthogonal to each other.

The antenna assembly may be installed in a vehicle roof.

The isolation element may have at least one of a monopole shape and a planar shape.

According to another aspect of the present application, an antenna assembly providing a frequency adaptive isolation degree, comprising: a first antenna and a second antenna operable in at least one of a first frequency band and a second frequency band; A first isolation mode providing an isolation degree between the first antenna and the second antenna with respect to the first frequency band, and a second isolation providing an isolation degree between the first antenna and the second antenna with respect to the second frequency band An isolation element for performing at least one isolation mode among the modes; And an isolation mode performed by the isolation element to obtain information on an operating frequency frequency band of the first antenna and the second antenna, and to provide an isolation degree between the first antenna and the second antenna for the operating frequency band. An antenna assembly including a; control circuit for adjusting the control circuit may be provided.

According to another aspect of the present application, as a method of providing frequency adaptive isolation,

Acquiring information on an operating frequency band of a MIMO antenna array including a first antenna and a second antenna provided as a multi-band antenna operable for each of a plurality of frequency bands; Matching a frequency characteristic of an isolation element for reducing interference between the first antenna and the second antenna to the operating frequency band; And reducing, by the isolation element, interference between the first antenna and the second antenna with respect to the operating frequency band. The method for providing frequency adaptive isolation may be provided.

According to another aspect of the present application, as a method of providing frequency adaptive isolation,

Operating a first antenna and a second antenna operable in the first frequency band and the second frequency band in the same operating frequency band; Obtaining information on the operating frequency band; When the operating frequency band is the first frequency band, matching frequency characteristics of an isolation element providing an isolation degree between the first antenna and the second antenna to a first frequency band; When the operating frequency band is the second frequency band, matching frequency characteristics of the isolation element to a second frequency band; And reducing, by the isolation element, interference between the first antenna and the second antenna in the operating frequency band. The method for providing frequency adaptive isolation may be provided.

According to another aspect of the present application, an antenna assembly providing a frequency adaptive isolation degree, comprising: a first antenna provided as a multi-band antenna operable for a plurality of frequency bands; A second antenna operating on a first frequency band, which is one of the plurality of frequency bands; A third antenna operating on a second frequency band, which is one of the plurality of frequency bands; An isolation element for reducing interference between the first antenna and the second antenna or between the first antenna and the third antenna; A matching circuit connected to the isolation element through a feed point of the isolation element and adjusting a frequency characteristic of the isolation element to at least one of the first frequency band and the second frequency band; And obtaining information on the operating frequency band of the first antenna, and when the sensed operating frequency band is the first frequency band, the matching circuit is configured to reduce interference between the first antenna and the second antenna. The matching circuit to adjust the frequency characteristic of the isolation element to match the first frequency band, and to reduce interference between the first antenna and the third antenna when the detected operating frequency band is the second frequency band An antenna assembly including a controller configured to match the frequency characteristic of the isolation element to the second frequency band may be provided.

1 is a diagram illustrating an example of an installation position of an antenna assembly for a vehicle according to an embodiment of the present specification

Conventional vehicle antennas have been installed to protrude from the outside of the vehicle to facilitate communication with the outside. However, in recent years, as an aesthetic factor for a vehicle has become important, a hidden antenna installed inside a vehicle is also widely used.

Referring to FIG. 1, the vehicle antenna assembly may be installed on the rear surface 100 of a vehicle roof.

For example, the vehicle antenna assembly may be installed by being inserted into the interior of the vehicle roof rear surface 100. Here, the vehicle antenna assembly, which is inserted and installed inside the vehicle roof rear surface 100, is physically separated from the external region by an external cover composed of at least a part of the non-metal, but since radio waves can be transmitted, the external region and the electrical May be connected to.

As described above, an antenna assembly for a vehicle that is inserted and installed inside the rear side surface 100 of the vehicle roof may be referred to as a hidden antenna.

Alternatively, a shark-fin antenna in which the vehicle antenna assembly is included in the shark fin-shaped housing may be installed on the rear side surface 100 of the vehicle roof. The shark pin antenna is an antenna in which a design element of an outer housing is considered to give a user an aesthetic feeling, and may be disposed to protrude from the rear surface 100 of a vehicle roof so as to effectively perform external communication.

The above description is an embodiment of the installation position of the vehicle antenna assembly according to the present invention, and is not limited to the above description, and the vehicle antenna assembly may be installed in various locations such as the inside of the spoiler, the vehicle bumper, and the rear view mirror. It should be noted that the installation position of the vehicle antenna assembly in the specification is not limited to the above-described position.

2 is a configuration diagram of a module-integrated smart antenna module according to an embodiment of the present specification.

Referring to FIG. 2, the module-integrated smart antenna module 200 may include an antenna module 220, a control module 240, and an isolation module 260.

The antenna module 220 may include at least one antenna capable of transmitting and receiving radio frequency signals for each operating frequency. The antenna module 220 may obtain an electric signal of an operating frequency band of each antenna, and provide the electric signal to the control module 240 connected to the antenna module 220 by a predetermined connection means. have. Details of the detailed configuration of the antenna module 220 will be described later.

The control module 240 may process radio frequency signals, process information, and perform calculations. The radio frequency signal is an analog signal that is an electric signal, and the control module 240 may convert the radio frequency signal into a digital signal and output it. The control module 240 may provide the converted digital signal to the head unit. The control module 240 may be expressed as a term having the same meaning, such as a controller.

The head unit may be a component controlled by a user interface such as a radio receiver, a touch screen display, a navigation device, and a mobile device.

Alternatively, the control module 240 may process the command signal provided from the head unit and provide it to the antenna module. Here, the control module 240 may convert the command signal, which is a digital signal, into an analog signal.

The control module 240 may be implemented as a CPU or a similar device according to hardware, software, or a combination thereof. Alternatively, in terms of hardware, the control module 240 may be provided in the form of an electronic circuit that performs a function of processing and controlling an electrical signal. Individual constituent modules included in the control module 240 may perform the functions of the control module 240 described above, and details that may be duplicated will be omitted.

The control module 240 may be referred to as a telematics control unit (TCM) or a tuner module.

The control module 240 may be electrically connected to the antenna module 220 through a coaxial cable. In this case, the length of the coaxial cable may vary depending on the installation positions of the antenna module 220 and the control module 240. When the antenna module 220 and the control module 240 are installed far apart, manufacturing cost for the coaxial cable may increase.

The electric signal provided from the antenna module 220 to the control module 240 or the control module 240 to the antenna module 220 may be transmitted as an analog signal, and attenuation loss for the electric signal may occur during the transmission process. .

To prevent this, the antenna module 220 and the control module 240 may be installed adjacent to each other so as to be located within a predetermined distance from each other.

For example, while the antenna module 220 is a shark pin antenna mounted on the roof, the control module 240 may be installed under the roof on which the antenna module 220 is mounted. In this case, the antenna module 220 and the control module 240 may be spaced apart by a predetermined distance including the thickness of the loop, and the antenna module 220 and the control module 240 may be spaced apart from the predetermined distance. On the other hand, it may be connected with a connector or a coaxial cable.

Alternatively, the antenna module 220 and the control module 240 may be located inside the same housing. In this case, the antenna module 220 and the control module 240 may be electrically connected by a conductive pattern or signal connection line formed on a printed circuit board.

As the antenna module 220 and the control module 240 are installed adjacent to each other, the manufacturing cost for the coaxial cable may be reduced compared to a case where the antenna module 220 and the control module 240 are disposed to be spaced apart from each other by a predetermined distance or more, and the antenna module 220 and the Attenuation loss related to a radio signal that may occur in the process of being transmitted between the control modules 240 may be reduced.

The isolation module 260 may improve isolation between a plurality of antennas included in the antenna module 220 and may minimize mutual interference between the plurality of antennas.

Here, the isolation module 260 may provide a frequency adaptive isolation degree. For example, the isolation module 260 may be electrically connected to a matching circuit capable of corresponding to a specific frequency characteristic through a feed point, and may have different frequency isolation characteristics according to a predetermined criterion by the matching circuit. have.

The antenna module 220 may include a 5G antenna, a V2X antenna, a 4G antenna, a satellite antenna, and a broadcast antenna.

The 5G (5 Generation) antenna may be an antenna operating in a frequency band for 5G communication.

Here, the 5G communication method may use a millimeter waver band. For example, the frequency band for the fifth generation communication may be 3.5 GHz as an intermediate band or 28 GHz as an ultra-high frequency band.

The operating frequency of the 5G antenna is a high frequency, has strong straightness, and is liable to cause loss in the signal transmission process. In order to compensate for this and have improved frequency performance, the 5G antenna may be configured with a multi-in-multi-out (MIMO) antenna array. For example, the 5G antenna may be implemented on a first antenna and a second antenna respectively installed in separate antenna configurations.

The V2X antenna may be an antenna operating in a frequency band for V2X communication.

V2X stands for Vehicle-to-Everything and refers to a technology that can exchange information that may exist on the road between objects or infrastructure through wired and wireless signals. At this time, V2X is a vehicle-to-vehicle (V2V), vehicle-to-infra (V2I), vehicle-to-pedestrian (V2P), and vehicle-to-personal terminal. (Vehicle to Nomadic Devices, V2N) can include all communications.

The V2X antenna is operated to comply with the V2X IEEE802.11p standard, and may be an antenna operating on radio waves in a 5.9 GHz band. Alternatively, the V2X antenna may be an antenna for C-V2X (Cellular-V2X) communication.

The V2X antenna may be composed of at least two or more antennas. According to an embodiment, the V2X antenna may be configured with two separate antennas. For example, the frequency band for the V2X antenna may be a frequency band operated by separate first and second antennas, respectively.

The radio signal of the frequency band for V2X communication has strong linearity, so omni-directional characteristics may be somewhat insufficient.

In order to compensate for this, it is possible to perform smooth communication with the outside by transmitting and receiving wireless signals through a plurality of antennas directed in multidirectional directions. In this case, each of the plurality of antennas may be installed at a sufficient distance apart to ensure isolation from each other.

The 4G antenna is a cellular antenna or a telematics antenna, and may be an antenna for a fourth generation (4G) communication scheme including a Long-Term Evolution (LTE) antenna or a Mobile WiMAX (Wibro) antenna.

Here, the LT antenna may be configured as a mimo antenna array. In the case of the 4G antenna, a mimo antenna mode may be supported to improve transmission speed. In order to support the mimo antenna mode, the degree of isolation between the 4G antennas must be secured, and this can be achieved by the isolation module according to an embodiment of the present invention.

The 4G antenna may operate on an LTE frequency band, and the LTE frequency band may include a low frequency band and a high frequency band.

The low frequency band may be 800 to 900 Mhz, and the high frequency band may be 1.7 to 2.3 GHz.

The 5G antenna and the 4G antenna can be implemented through a multi-band antenna capable of operating both for each operating frequency.

For example, an antenna capable of operating in each frequency band of a 5G frequency band, a low frequency band of LTE, and a high frequency band of LTE may be implemented through one multi-band antenna. That is, the multi-band antenna may be a multi-band antenna capable of operating for three frequency bands as one antenna configuration.

The satellite antenna may include an antenna for receiving satellite information capable of obtaining location information on a desired point in a specific time zone. The satellite antenna may be a Global Navigation Satellite System (GNSS), a Satellite Digital Audio Radio Service (SDARS), a Global Positioning System (GPS), a GALILEO, or a Global Orbiting Navigational System (GLONASS), but is not limited to the above-described example.

The broadcast antenna may be an antenna for satellite broadcast reception capable of performing a broadcasting operation on a broadcast signal having a satellite frequency band. According to an example, the antenna for receiving satellite broadcasting may be an antenna for SXM (SiriusXM) communication.

Alternatively, the broadcast antenna is an antenna for receiving signals related to radio broadcasting, and operates in the AM/FM antenna operating in the AM/FM frequency band or in the DAB (Digital Audio Broadcasting) frequency band, which is a frequency for receiving signals related to terrestrial broadcasting. It may be a DAB antenna.

The control module 240 may include a V2X communication module, an LTE communication module, a Bluetooth/Wifi communication module, and a communication interface.

The V2X communication module may acquire information on a V2X frequency signal based on a radio frequency signal provided from an antenna operating in the V2X frequency band.

The V2X communication module may include a satellite information receiver, and position information on a vehicle or a specific target may be acquired based on a signal obtained by an antenna for receiving satellite information included in the antenna module.

For example, the V2X communication module may be configured to enable vehicle-to-infrastructure and communication between a vehicle and another vehicle, thereby providing a service regarding real-time traffic information to passengers of the vehicle.

The LTE communication module may process a radio signal provided from an antenna operating in an LTE frequency band. In addition, the LTE communication module may provide information based on a radio signal provided from an antenna operating in the LTE frequency band to the head unit through a digital cable.

The Bluetooth/Wifi communication module may obtain a WI-FI signal and a Bluetooth signal provided from the outside or from the inside of the vehicle, and process it into a digital signal to be provided to the head unit. In the case of a Wifi signal and a Bluetooth signal, it may be provided from the antenna module, and may be provided from an external area installed at a location separate from the antenna module.

The communication interface may provide a communication environment for smoothly connecting the head unit and the control module. Since the control module and the head unit communicate through digital signals, the communication interface may be configured to transmit and receive digital signals.

According to an example, the communication interface may include an Ethernet interface. In the case of wired connection, information can be transmitted and received through a digital cable. The digital cable may include an Ethernet cable, a B2B socket, or the like.

Alternatively, the communication interface may include a wireless local area network (WLAN), a cellular interface, a Bluetooth interface, or other RF communication interface. However, in some cases, the control module and the head unit may be connected through controller area network (CAN) communication to perform an operation related to data communication, and the exemplary method and means are not limited thereto.

In addition, it should be noted that the control module of the vehicle antenna may include various configurations such as a communication module for AM/FM antenna and a communication module for Dedicated Short Range Communication (DSRC), and is not limited to the above configuration.

3 is a block diagram illustrating an antenna assembly according to an exemplary embodiment.

Referring to FIG. 3, the antenna assembly 2000 may include a first antenna 2001, a second antenna 2002, a control module 240, and an isolation module 260.

The first antenna 2001 and the second antenna 2002 may be provided as one of the antenna modules 220 described above. For example, the first antenna 2001 and the second antenna 2002 may be MIMO antennas operable in a plurality of frequency bands. The first antenna 2001 and the second antenna 2002 may constitute a MIMO antenna array.

Meanwhile, electromagnetic mutual interference may occur between the first antenna 2001 and the second antenna 2002. Accordingly, transmission/reception performance of the first antenna 2001 and the second antenna 2002 may be reduced.

For example, a first electromagnetic signal generated from the first antenna 2001 may affect a second electromagnetic signal generated from the second antenna 2002. As a result, the pattern of the second electromagnetic signal may be distorted differently from a predetermined pattern. Likewise, the pattern of the first electromagnetic signal may be distorted differently from a predetermined pattern by the second electromagnetic signal. Accordingly, transmission performance of the first antenna 2001 and the second antenna 2002 may be reduced.

An isolation module 260 may be provided to prevent electromagnetic interference between the plurality of antennas. The isolation module 260 may include a stub.

The isolation module 260 may improve the degree of isolation between the first antenna 2001 and the second antenna 2002. The isolation module 260 may suppress electromagnetic mutual interference between the first antenna 2001 and the second antenna 2002. The isolation module 260 may suppress coupling between the first antenna 2001 and the second antenna 2002.

For example, the isolation module 260 may reflect or shield an electromagnetic signal generated from the first antenna 2001 and directed to the second antenna 2002. In addition, the isolation module 260 may reflect or shield an electromagnetic signal generated from the second antenna 2002 and directed to the first antenna 2001.

The isolation module 260 or the stub may have several isolation modes depending on the operating frequency of the antenna. For example, when the first antenna 2001 and the second antenna 2002 operate at a first frequency, the isolation module 260 may have a first isolation mode having a frequency characteristic corresponding to the first frequency. have. Alternatively, when the first antenna 2001 and the second antenna 2002 operate at a second frequency different from the first frequency, the isolation module 260 is a second isolation module having a frequency characteristic corresponding to the second frequency. You can have a mode.

Meanwhile, the first antenna 2001 and the second antenna 2002 may be MIMO antennas. For example, the first antenna 2001 and the second antenna 2002 may operate at 800 MHz to 3.5 GHz. When the impedance value of the isolation module 260 has a single value, it may not be possible to secure isolation for the entire frequency band.

In order to secure isolation between antennas in various frequency bands, the isolation module 260 may include a matching circuit. The matching circuit may be connected to the stub through a feed point of the stub.

The matching circuit may include a capacitor, an inductor, and a switch. For example, the capacitor may be a variable capacitor, and the inductor may be a variable inductor. In this case, the capacitance of the capacitor and the inductance of the inductor may be changed. In addition, the matching circuit may include various elements.

The impedance value of the isolation module 260 may be determined based on numerical values of elements included in the matching circuit. The frequency characteristics of the isolation module 260 may vary according to the impedance value of the isolation module 260. Here, the frequency characteristic may mean a frequency characteristic at which transmission/reception performance of the first antenna 2001 and the second antenna 2002 is improved by the isolation module 260.

The control module 240 may match the frequency characteristic of the isolation module 260 with the operating frequencies of the first antenna 2001 and the second antenna 2002.

The control module 240 may adjust the impedance value of the matching circuit. For example, the control module 240 may generate a command signal for adjusting the impedance value of the matching circuit.

The control module 240 may set the impedance value of the matching circuit based on the antenna operating frequency. For example, the control module 240 may obtain information on operating frequencies of the first antenna 2001 and the second antenna 2002. The control module 240 may set an impedance value of the matching circuit based on the obtained information.

For example, when the operating frequency of the first antenna 2001 and the second antenna 2002 is a first frequency, an impedance value of the matching circuit corresponding to the first frequency may be set. Specifically, the first antenna 2001 and the second antenna 2002 may operate in an LTE frequency band. In this case, the impedance value of the isolation module 260 may be set to a value corresponding to the LTE frequency.

The isolation module 260 may provide an isolation degree between the first antenna 2001 and the second antenna 2002 based on the set impedance value. That is, when the first antenna 2001 and the second antenna 2002 operate in the LTE frequency band, the isolation module 260 determines the degree of isolation between the first antenna 2001 and the second antenna 2002 in the LTE frequency band. Can provide. Accordingly, transmission/reception performance of the first antenna 2001 and the second antenna 2002 in the LTE frequency band may be improved.

The impedance value of the matching circuit may be set based on previously stored data. For example, an impedance value indicating optimum transmission/reception performance at various operating frequencies of the first antenna 2001 and the second antenna 2002 may be stored in a memory. Alternatively, an impedance value having the highest degree of isolation between the first antenna 2001 and the second antenna 2002 for each frequency may be stored in the memory. The impedance value may be a value calculated based on various experiments. The impedance value may be stored in the memory in the form of a look-up table.

Meanwhile, when the isolation module 260 has a specific frequency characteristic, it is not necessarily capable of providing isolation in a single frequency band corresponding to the frequency characteristic, and even if it has one frequency characteristic, the isolation degree for several frequency bands. Can provide.

For example, even when the isolation module 260 reduces interference between the first antenna 2001 and the second antenna 2002 in the 5G frequency band, the isolation module 260 simultaneously operates the first antenna in the 4G frequency band. Interference between 2001 and the second antenna 2002 may be reduced.

4 is a diagram illustrating an antenna assembly according to an exemplary embodiment.

Referring to FIG. 4, the antenna assembly 2000 may include a first antenna 2001, a second antenna 2002, a substrate 2100, a control module 240, and an isolation module 260. The isolation module 260 may include a stub 261 and a matching circuit 262. The stub 261 and the matching circuit 262 may correspond to the stub and the matching circuit described in FIG. 3, respectively.

Hereinafter, each configuration will be described in detail, but portions that overlap with the content described in FIG. 3 will be omitted, and a description will be made focusing on differences.

As described above, the first antenna 2001 and the second antenna 2002 may be MIMO antennas capable of operating in a plurality of frequency bands.

The first antenna 2001 and the second antenna 2002 may have a mono-pole shape. However, the present invention is not limited thereto, and the first antenna 2001 and the second antenna 2002 may have various shapes. For example, the first antenna 2001 and the second antenna 2002 may have a dipole shape, a loop shape, a helical shape, and a planar shape.

The first antenna 2001 and the second antenna 2002 may be disposed on the substrate 2100. The first antenna 2001 and the second antenna 2002 may be disposed on the same surface of the substrate 2100. The substrate 2100 may be a printed circuit board (PCB). The substrate 2100 may include a ground plane.

The first antenna 2001 and the second antenna 2002 may be disposed orthogonal to each other. Accordingly, coupling between the first antenna 2001 and the second antenna 2002 can be prevented. The first antenna 2001 and the second antenna 2002 may form radiation patterns that are orthogonal to each other.

The first antenna 2001 and the second antenna 2002 may be sufficiently spaced apart so as to prevent mutual coupling.

The first antenna 2001 and the second antenna 2002 may have the same height. Here, the height may be defined as a value at which a distance from the substrate 2100 in a direction perpendicular to the substrate 2100 to the first antenna 2001 or the second antenna 2002 becomes a maximum.

The control module 240 may be disposed on the substrate 2100. The control module 240 may be disposed on the same surface. Alternatively, the control module 240 may be disposed on a surface opposite to the same surface. The control module 240 may be disposed between the first antenna 2001 and the second antenna 2002.

The isolation module 260 may be disposed between the first antenna 2001 and the second antenna 2002.

The stub 261 may be disposed on the same surface of the substrate 2100. The stub 261 may be formed on the ground plane of the substrate 2100. However, the present invention is not limited thereto, and the stub 261 may be disposed on the same surface and on a different surface. One end of the stub 261 may be connected to the substrate 2100 in a direction perpendicular to the substrate 2100.

The stub 261 may have a monopole shape. However, the present invention is not limited thereto, and the stub 261 may have various shapes. For example, the stub 261 may have a planar shape and other shapes. Alternatively, the stub 261 may be provided in a form printed on the substrate 2100.

The stub 261 may be disposed between the first antenna 2001 and the second antenna 2002.

The stub 261 may have the same height as the first antenna 2001 and the second antenna 2002. However, the present invention is not limited thereto, and the height of the stub 261 may be different from the height of the antenna. For example, the height of the stub 261 may be smaller than the height of the first antenna 2001 or the second antenna 2002. Alternatively, the height of the stub 261 may be greater than the height of the first antenna 2001 or the second antenna 2002.

The matching circuit 262 may be disposed on the same surface of the substrate 2100. Alternatively, the matching circuit 262 may be disposed on a surface opposite to the same surface.

The control module 240 may be electrically connected to the matching circuit 260. The control module 240 may adjust the impedance value of the matching circuit 260.

Meanwhile, the isolation module 260 does not necessarily improve the degree of isolation between two antennas, and may improve the degree of isolation between three or more antennas.

5 is a diagram for describing an antenna assembly according to another exemplary embodiment.

Referring to FIG. 5, the antenna assembly 2000 includes a first antenna 2001, a second antenna 2002, a third antenna 2003, a substrate 2100, a control module 240, and an isolation module 260. Can include. The isolation module 260 may include a stub 261 and a matching circuit 262.

Configurations other than the third antenna 2003 may correspond to the configuration of the antenna assembly according to FIG. 4.

The third antenna 2003 may be an antenna that transmits and receives electromagnetic signals in a single frequency band. Alternatively, the third antenna 2003 may be a MIMO antenna that transmits and receives electromagnetic signals in a plurality of frequency bands.

The third antenna 2003 may be disposed on the substrate 2100. For example, the third antenna 2003 may be disposed orthogonal to the second antenna 2002. Accordingly, coupling between the second antenna 2002 and the third antenna 2003 can be prevented.

On the other hand, when the second antenna 2002 and the third antenna 2003 are disposed together within a limited space, coupling may occur even if the second antenna 2002 and the third antenna 2003 are disposed orthogonally to each other in some cases. I can.

The isolation module 260 may improve the degree of isolation between the second antenna 2002 and the third antenna 2003. The isolation module 260 may suppress electromagnetic interference between the second antenna 2002 and the third antenna 2003. The isolation module 260 may suppress coupling between the second antenna 2002 and the third antenna 2003.

For example, the isolation module 260 may reflect or shield an electromagnetic signal generated from the second antenna 2002 and directed to the third antenna 2003. In addition, the isolation module 260 may reflect or shield an electromagnetic signal generated from the third antenna 2003 and directed to the second antenna 2002. Similarly, the isolation module 260 may improve the degree of isolation between the first antenna 2001 and the third antenna 2003.

The control module 240 may obtain information on the operating frequency of the third antenna 2003. The control module 240 may match the impedance value of the isolation module 260 based on the obtained frequency information.

Meanwhile, in order to further improve the degree of isolation between antennas, a plurality of isolation modules may be provided.

6 is a diagram for describing an antenna assembly according to another embodiment.

6, the antenna assembly 2000 includes a first antenna 2001, a second antenna 2002, a substrate 2100, a control module 240, a first isolation module 270, and a second isolation module ( 280) may be included.

The first isolation module 270 may include a first stub 271 and a first matching circuit 272. The second isolation module 280 may include a second stub 281 and a second matching circuit 282.

Each of the first isolation module 270 and the second isolation module 280 may correspond to the isolation module 260.

The first matching circuit 272 may be connected to the first stub 271 through a feed point of the first stub 271. The second matching circuit 282 may be connected to the second stub 281 through a feed point of the second stub 281.

The control module 240 acquires operating frequency information of the first antenna 2001 and the second antenna 2002, and based on the obtained information, the first isolation module 270 and the second isolation module 280 Impedance values can be matched. Accordingly, the degree of isolation between the first antenna 2001 and the second antenna 2002 may be improved. Accordingly, transmission/reception performance and bandwidth of the first antenna 2001 and the second antenna 2002 may be improved.

The impedance values of the first isolation module 270 and the second isolation module 280 may be different or the same.

Meanwhile, although the first stub 271 and the second stub 281 are illustrated to have the same shape, the first stub 271 and the second stub 281 may have different shapes.

7 is a flowchart illustrating a method of providing a frequency adaptive isolation diagram according to an embodiment.

Referring to FIG. 7, the method is to obtain information on the operating frequency band of a MIMO antenna array including a first antenna and a second antenna provided as a multi-band antenna (S2000), and determine the frequency characteristics of the isolation element. Matching to the operating frequency band (S2100), and reducing the interference between the first antenna and the second antenna by the isolation element (S2200). On the other hand, it may be understood that each step is performed by the control module unless otherwise specified.

Hereinafter, each step will be described in detail.

First, the control module may acquire information on an operating frequency band of a MIMO antenna array including a first antenna and a second antenna provided as a multi-band antenna (S2000). The first antenna and the second antenna may be operable for a plurality of frequency bands.

The control module may correspond to the control module 240 described in FIGS. 2 to 6. In addition, the first antenna and the second antenna may correspond to the first antenna 2001 and the second antenna 2002 described in FIGS. 3 to 6, respectively, which is the same in the following.

The control module may match the frequency characteristic of the isolation element to the operating frequency band (S2100). The control module and the isolation element may correspond to the control module 240 and the stub 261 described in FIG. 4, respectively.

The control module may match the frequency characteristic of the isolation element to the operating frequency band by changing the impedance value of the isolation element. For example, a matching circuit for adjusting the frequency characteristic of the isolation element may be provided. The matching circuit may be electrically connected to the isolation element through a feed point of the isolation element.

For example, the control module may adjust the impedance value of the isolation element by controlling a switch or an adaptive capacitor included in the matching circuit.

The isolation element may reduce interference between the first antenna and the second antenna (S2200). The frequency characteristic of the isolation element may be matched to the operating frequency bands of the first antenna and the second antenna by the control module.

Accordingly, isolation between the first antenna and the second antenna in the operating frequency band is improved, and a bandwidth may be increased. In addition, transmission/reception performance of the first antenna and the second antenna in the operating frequency band may be improved.

8 is a flowchart illustrating a method of providing a frequency adaptive isolation diagram according to another embodiment.

Referring to FIG. 8, in the method, a first antenna and a second antenna operate in the same operating frequency band (S2300), obtaining information on the operating frequency band (S2400), and the operating frequency band is a first frequency band. In this case, matching the frequency characteristic of the isolation element to the first frequency band (S2501) and, when the operating frequency band is the second frequency band, matching the frequency characteristic of the isolation element to the second frequency band (S2502) Can include.

Hereinafter, each step will be described in detail.

First, the first antenna and the second antenna may operate in the same operating frequency band (S2300). Meanwhile, the first antenna and the second antenna may each be a multi-band antenna capable of operating in a plurality of frequency bands. For example, the first antenna and the second antenna may be operable in a first frequency band and a second frequency band, respectively.

The control module may acquire information on the operating frequency band (S2400). For example, when the first antenna and the second antenna operate in a first frequency band, the control module may obtain information on the first frequency band.

When the acquired operating frequency band is the first frequency band, the control module may match the frequency characteristic of the isolation element to the first frequency band (S2501). Accordingly, the isolation element may reduce interference between the first antenna and the second antenna in the first frequency band.

When the acquired operating frequency band is the second frequency band, the control module may match the frequency characteristic of the isolation element to the second frequency band (S2502). Accordingly, the isolation element may reduce interference between the first antenna and the second antenna in the second frequency band.

9 is a diagram illustrating an external structure of an antenna assembly according to an embodiment.

This embodiment is an exemplary view showing an external structure surrounding the vehicle antenna assembly 1000 when the vehicle antenna assembly 1000 is embedded inside the rear roof of the vehicle.

The interior of the vehicle antenna assembly 1000 may include components sensitive to external influences, such as a printed circuit board and antenna configuration in which circuit elements are implemented. Accordingly, the vehicle antenna assembly 1000 may require an external housing to protect the components contained therein.

The vehicle antenna assembly may include a connection part 1020, a cover part 1040, and a mounting part 1060.

The connection unit 1020 may provide a communication environment for networking between an antenna included in the vehicle antenna assembly 1000 and an external configuration of the vehicle antenna assembly 1000. The connection unit 1020 may have various types of connection according to a communication method between the inside and outside of the antenna.

For example, when the control module of the vehicle antenna assembly 1000 is installed outside the vehicle antenna assembly, the signal output from the vehicle antenna assembly 1000 is an analog signal that is an electric signal, and the connection part 1020 Connection means for transmitting analog signals, such as a coaxial cable, may be installed.

Alternatively, when a control module for the vehicle antenna assembly 1000 is installed inside the vehicle antenna assembly 1000, the control module processes an electric signal provided from an antenna to include information based on the electric signal. Digital signals can be output. Accordingly, a signal provided to the outside from the vehicle antenna assembly 1000 is a digital signal, and an environment for transmitting and receiving a digital signal may be provided to the connector 1020. In this case, the contents of the connection means between the control module and the head unit described above with reference to FIG. 2 may be equally applied, and descriptions of overlapping contents will be omitted.

The cover part 1040 is a component for protecting the internal configuration of the vehicle antenna assembly from external influences, and may be embedded and installed in the vehicle through the mounting part 1060.

The cover part 1040 may include a lower cover 1042 and an upper cover 1044. Here, the lower cover 1042 may be a position where a base portion to which an antenna internal structure is to be installed is installed.

In order for the vehicle antenna assembly 1000 to sufficiently secure communication and networking performance with the outside, at least a part of the cover part 1040 may be formed of a non-conductor. For example, the constituent material of the outer cover may be polycarbonate (PC).

The mounting unit 1060 may mount the vehicle antenna assembly 1000 according to the present invention to one side of the vehicle using a bolt-nut coupling method or an adhesive means. One side of the mounting part 1060 may be integrally formed with the lower cover 1042, and a through hole may be formed in the middle of the mounting part 1060. When the vehicle antenna assembly 1000 is mounted inside a vehicle, a bolt for mounting passes through the front hole of the through hole, and the bolt protruding through the rear hole of the through hole is inserted into a nut or a coupling hole previously provided in the vehicle. By coupling, the vehicle antenna assembly 1000 can be coupled to the interior of the vehicle.

10 is a view showing the inside of the antenna assembly according to FIG. 9.

10, the vehicle antenna assembly includes a base unit 1030, a first antenna 1100, a second antenna 1102, a third antenna 1104, a fourth antenna 1106, and an antenna for receiving satellite information. (1103) may be included.

The base unit 1030 may provide a space in which the internal configuration of the vehicle antenna assembly is mounted. Referring to FIG. 10, the base portion 1030 may be positioned on one side of the cover portions 1042 and 1044 supporting the external shape of the vehicle antenna assembly. For example, it may be coupled to the lower cover 1042 through a predetermined connection means. The predetermined connection means may be a bolt-nut coupling method, a known assembly method such as an adhesive means, but is not limited thereto.

The base unit 1030 may include a printed circuit board (PCB) capable of implementing a circuit element capable of transmitting an electric signal related to an antenna operation or providing information about other operation commands. Here, the circuit element may be implemented through a conductive pattern printed on at least a portion of the printed circuit board.

The first to fourth antennas 1100, 1102, 1104, and 1106 may be multi-band antennas capable of operating for two or more frequency bands.

The first antenna 1100 is a multi-band antenna capable of operating for three different frequency bands, and may be a multi-band antenna capable of operating for an intermediate frequency band of 5G, a high frequency of 4G, and a low frequency of 4G.

The second antenna 1102 may be configured to operate in substantially the same frequency band as the first antenna 1100. That is, the second antenna 1102 may be a multi-band antenna capable of operating in an intermediate frequency band of 5G, a high frequency of 4G, and a low frequency of 4G, similar to the first antenna 1100.

The third antenna 1104 is a multi-band antenna capable of operating on two different frequency bands, and may be an antenna for V2X communication and an antenna of a 5G intermediate frequency band.

The fourth antenna 1106 may be configured to operate in substantially the same frequency band as the third antenna 1104. That is, like the third antenna 1104, the fourth antenna 1106 may be an antenna for V2X communication and a 5G intermediate frequency band antenna.

Here, the intermediate frequency band of the 5G may be a 3.5 GHz band, the 4G high frequency band may be a 2.3 GHz band, the 4G low frequency band may be an 800 MHz band, and a frequency for the V2X communication may be a 5.9 GHz band. Alternatively, the 5G intermediate frequency band may be a 3.6 GHz band, the 4G high frequency band may be a 1.7 to 2.4 GHz band, and the 4G low frequency band may be a 0.67 to 0.96 GHz band.

The first to fourth antennas 1100, 1102, 1104, and 1106 may be separated by a sufficient distance from each other in order to reduce mutual interference and provide an improved degree of isolation between the antennas. For example, the second antenna 1102 may be configured to face outward indicating different directions in order to reduce mutual interference caused by the first antenna 1100. The direction in which the first antenna 1100 faces may be a direction toward the antenna element of the first antenna 1100 that is furthest apart from the feed point of the first antenna 1100. The direction of the second antenna 1102 may be similarly defined.

Referring to FIG. 10, an end portion of the first antenna 1100 and an end portion of the second antenna 1102 may be configured to face different directions. Here, the distal end may be defined as a point farthest from the feed point of each antenna. In detail, the first antenna 1100 may be positioned on the upper left side of the vehicle antenna assembly, but the first antenna 1100 may be configured to face the left side. In addition, the second antenna 1102 may be positioned at a lower right of the vehicle antenna assembly, but the second antenna 1102 may be configured to face downward.

A direction toward the first antenna 1100 and a direction toward the second antenna 1102 may be orthogonal to each other. For example, referring to FIG. 10, the first antenna 1100 may be configured to face a 9 o'clock direction, and the second antenna 1102 may be configured to face a 6 o'clock direction. Therefore, the axis from the feed point of the first antenna 1100 toward the distal end of the first antenna 1100 and the axis toward the distal end of the second antenna 1102 from the feed point of the second antenna 1102 are each Can be orthogonal. Accordingly, a radiation pattern corresponding to a specific frequency band by the first antenna 1100 may be orthogonal to a radiation pattern corresponding to the specific frequency band by the second antenna 1102, Accordingly, the degree of isolation between the first antenna 1100 and the second antenna 1102 for the specific frequency band may be ensured.

Each of the first to fourth antennas 1100, 1102, 1104, and 1106 may include at least one filter. A filter included in each antenna may block electric flow for a specific frequency band, and may provide improved isolation for an antenna operating for the specific frequency band. For example, the first antenna 1100 and the second antenna 1102 may operate for a first frequency band. Since the first antenna 1100 includes a first filter capable of blocking the first frequency band, isolation with respect to the first frequency band may be secured in relation to the second antenna 1102. Alternatively, the first antenna 1100 may have a second filter capable of blocking the second frequency band, thereby securing an isolation degree for the second frequency band in relation to the second antenna 1102.

Similar to the relationship between the first antenna 1100 and the second antenna 1102, a direction toward the third antenna 1104 and a direction toward the fourth antenna 1106 may be orthogonal to each other. Contents related to the direction in which each antenna is arranged may be duplicated with the above description, and thus will be omitted.

The third antenna 1104 and the fourth antenna 1106 may also be spaced apart from each other by a sufficient distance to reduce mutual interference.

Referring to FIG. 10, the third antenna 1104 may be positioned at a lower left side of the vehicle antenna assembly, and the fourth antenna 1106 may be positioned at an upper right side of the vehicle antenna assembly.

The installation positions of the first to fourth antennas 1100, 1102, 1104, and 1106 in the interior of the vehicle antenna assembly are one of exemplary embodiments, and are not limited to the above-described arrangement positions.

The satellite information receiving antenna 1103 is an antenna capable of operating in a satellite frequency band, and may acquire an electric signal including at least location information about a specific point. An electric signal including at least location information about the specific point is provided to a control module for a vehicle antenna assembly, and the control module may output a digital signal including location information about the specific point.

The satellite information reception antenna 1103 may be a patch antenna having a low profile.

The satellite information receiving antenna 1103 may be installed at a predetermined position of the base 1030. Referring to FIG. 10, the antenna 1103 for receiving satellite information may be installed at a position corresponding to a position between the connection unit 1020 and the second antenna 1102.

Here, the satellite information receiving antenna 1103 may be related to the satellite antenna described above with reference to FIG. 9, and a description of the content overlapping with the above description will be omitted.

The vehicle antenna assembly according to the present invention may further include an antenna for receiving satellite broadcasting information. The satellite broadcasting information reception antenna 1105 has an operating frequency of a satellite broadcasting frequency band, and can receive a broadcasting signal. According to an example, the antenna 1105 for receiving satellite broadcasting information is an antenna for SXM communication, and may be installed at a position corresponding to a central portion of the base unit when referring to FIG. 10.

Here, the antenna 1105 for receiving satellite broadcast information may be related to the broadcast antenna described above with reference to FIG. 2, and details overlapping with the above description will be omitted.

The vehicle antenna assembly according to the invention may further comprise an isolation element. The isolation element 1107 provides improved isolation between the first to fourth antennas 1100, 1102, 1104, 1106, the satellite information receiving antenna 1103 and the satellite broadcasting information receiving antenna 1105 can do. Here, the isolation element 1107 may be disposed between the satellite information receiving antenna 1103 and the satellite broadcasting information receiving antenna 1105 when referring to FIG. 10, but its installation position is relative to the above-described position. It is not limited to an example. The isolation element 1107 may correspond to the stub 261.

The isolation element 1107 may in particular provide an improved degree of isolation between the first to fourth antennas 1100, 1102, 1104, and 1106 that perform beauty operations with each other. The first to fourth antennas 1100, 1102, 1104, 1106 are micro-antenna arrays that operate for at least one or more of the same frequency band, and when two or more antennas operate for the same frequency band, A MIMO Fading phenomenon that deteriorates operating performance may occur.

For example, when the first and second antennas 1100 and 1102 simultaneously operate for a frequency of a 3.5 GHz band, the operating performance of the first and second antennas 1100 and 1102 for a 3.5 GHz band is Can be reduced. The isolation element 1107 may reduce mutual interference between antenna elements, including a fading phenomenon.

The vehicle antenna assembly according to the present invention removes noise from signals of the satellite information reception antenna 1103 and the satellite broadcast information reception antenna 1105 in addition to the above-described antenna internal configuration, and transmits electrical signals provided from each antenna. It may further include a low noise amplifier (Low Noise Amplifer, LNA) capable of amplifying. According to an example, the vehicle antenna assembly may further include a GNSS LNA and an SXM LNA.

In the above, the configuration and features of the present invention have been described based on the embodiments according to the present invention, but the present invention is not limited thereto, and various changes or modifications can be made within the spirit and scope of the present invention. It will be apparent to those skilled in the art, and therefore, such changes or modifications are found to belong to the appended claims.

Claims (12)

As an antenna assembly providing frequency adaptive isolation,
A MIMO antenna array including a first antenna and a second antenna, each provided as a multi-band antenna operable for a plurality of frequency bands, and simultaneously operating for the same operating frequency band;
An isolation element for reducing interference between the first antenna and the second antenna;
A matching circuit that is connected to the isolation element through a feed point of the isolation element and controls a frequency band in which the isolation element reduces interference in at least one of the plurality of frequency bands. ); And
A controller that obtains information on the operating frequency band and controls the matching circuit so that a frequency band in which the isolation element reduces interference corresponds to the operating frequency band;
When the first and second antennas operate in a first frequency band, the controller obtains information on the first frequency band, and the isolation element reduces interference of at least a portion of the first frequency band. Controlling the matching circuit,
When the first and second antennas operate in a second frequency band, the controller obtains information on the second frequency band, and the isolation element reduces interference of at least a portion of the second frequency band. Controlling the matching circuit
Antenna assembly.
The method of claim 1,
The isolation element is disposed between the first antenna and the second antenna
Antenna assembly.
The method of claim 1,
The plurality of frequency bands include at least one of an LTE frequency, a fifth generation (5G) frequency, and a GPS frequency.
Antenna assembly.
The method of claim 1,
The antenna assembly further includes a plate-shaped substrate,
The isolation element and the antenna array are disposed on the first side of the substrate,
The matching circuit is disposed on a second surface opposite to the first surface of the substrate
Antenna assembly.
The method of claim 4,
One end of the isolation element is connected to the substrate in a direction perpendicular to the substrate
Antenna assembly.
The method of claim 1,
The first antenna and the second antenna are disposed in a direction orthogonal to each other
Antenna assembly.
The method of claim 1,
The antenna assembly is characterized in that it is installed in a form embedded in the vehicle roof
Antenna assembly.
The method of claim 1,
The isolation element has a shape of at least one of a monopole shape and a planar shape.
Antenna assembly.
As an antenna assembly providing frequency adaptive isolation,
A first antenna and a second antenna operable in at least one of a first frequency band and a second frequency band; And
A first isolation mode providing an isolation degree between the first antenna and the second antenna with respect to the first frequency band, and a second isolation providing an isolation degree between the first antenna and the second antenna with respect to the second frequency band An isolation element for performing at least one isolation mode among the modes; And
Includes; a controller for changing the isolation mode of the isolation element,
The controller acquires information on the operating frequency bands of the first and second antennas,
Changing the isolation mode of the isolation element based on information on the operating frequency bands of the first and second antennas
Antenna assembly.
As a method of providing frequency adaptive isolation,
Acquiring information on an operating frequency band of a MIMO antenna array including a first antenna and a second antenna provided as a multi-band antenna operable for each of a plurality of frequency bands;
Operating a matching circuit to match a frequency characteristic of an isolation element for reducing interference between the first antenna and the second antenna with the operating frequency band; And
The isolation element reducing interference between the first antenna and the second antenna with respect to the operating frequency band; including
How to provide frequency adaptive isolation.
As a method of providing frequency adaptive isolation,
Operating a first antenna and a second antenna operable in the first frequency band and the second frequency band in the same operating frequency band;
Obtaining information on the operating frequency band;
When the operating frequency band is the first frequency band, operating a matching circuit to match a frequency characteristic of an isolation element providing an isolation degree between the first antenna and the second antenna to a first frequency band;
When the operating frequency band is the second frequency band, operating a matching circuit to match a frequency characteristic of the isolation element to a second frequency band; And
The isolation element reducing interference between the first antenna and the second antenna in the operating frequency band; including
How to provide frequency adaptive isolation.
As an antenna assembly providing frequency adaptive isolation,
A first antenna provided as a multi-band antenna operable for a plurality of frequency bands;
A second antenna operating on a first frequency band, which is one of the plurality of frequency bands;
A third antenna operating on a second frequency band, which is one of the plurality of frequency bands;
An isolation element for reducing interference between the first antenna and the second antenna or between the first antenna and the third antenna;
A matching circuit connected to the isolation element through a feed point of the isolation element and adjusting a frequency characteristic of the isolation element to at least one of the first frequency band and the second frequency band; And
Controller for controlling the matching circuit to selectively reduce interference between the first antenna and the second antenna or reduce interference between the first antenna and the third antenna according to the operating frequency of the first antenna Including ;,
The controller is
Obtaining information on the operating frequency band of the first antenna, and when the obtained operating frequency band is the first frequency band, controlling the matching circuit so that the frequency characteristic of the isolation element is matched to the first frequency band To reduce the interference between the first antenna and the second antenna, and when the obtained operating frequency band is the second frequency band, the matching circuit is configured to match the frequency characteristic of the isolation element to the second frequency band. To reduce the interference between the first antenna and the third antenna by controlling
Antenna assembly.

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