JP7454389B2 - In-vehicle antenna device - Google Patents

Description

The present invention relates to an on-vehicle antenna device.

In recent years, various vehicle-mounted antenna devices have been developed, as described in Patent Document 1, for example. The in-vehicle antenna device according to an example of the description in Patent Document 1 is formed by windings connected to a common connector, and supports multi-band, for example, AM/FM (Amplitude Modulation/Frequency Modulation) radio band, LTE (Long The antenna is equipped with an antenna that operates in the Term Evolution band, the DAB (Digital Audio Broadcast) band, and the like. Further, an in-vehicle antenna device according to another example described in Patent Document 1 includes a telematics antenna.

Japanese Patent Application Publication No. 2015-142379

In recent years, in frequency bands for various uses, such as the LTE band, there has been a demand for increasing the sensitivity of vehicle-mounted antenna devices over a wide frequency band. However, when the antenna is formed by windings connected to a common connector, such as in the vehicle antenna device according to the above example of Patent Document 1, various factors (for example, harmonics of signals in a low frequency band) ), signals in high frequency bands are affected, and it may be difficult to increase the sensitivity of the vehicle antenna device over a wide band. On the other hand, a telematics antenna may be used, such as the vehicle-mounted antenna device according to the other example of Patent Document 1, for example. However, even if the shape of a telematics antenna is optimized so that it performs well in a particular frequency band, this shape may not be optimal for other frequency bands. be. In this case, even if the telematics antenna works well in a particular frequency band, the telematics antenna may not work well in other frequency bands.

One example of the object of the present invention is to increase the sensitivity of a vehicle-mounted antenna device over a wide frequency band. Other objects of the invention will become apparent from the description herein.

One aspect of the present invention is
a first antenna operable in a first frequency band;
a second antenna capable of operating in a second frequency band different from the first frequency band;
a first power feeding section connected to the first antenna;
a second power feeding unit connected to the second antenna;
a combining unit that combines a signal from the first power feeding unit and a signal from the second power feeding unit;
This is an in-vehicle antenna device.

According to the above aspect of the present invention, the sensitivity of the vehicle-mounted antenna device can be increased over a wide frequency band.

FIG. 1 is a perspective view of an in-vehicle antenna device according to an embodiment. FIG. 2 is a left side view of the vehicle-mounted antenna device shown in FIG. 1. FIG. FIG. 2 is a top view of the vehicle-mounted antenna device shown in FIG. 1. FIG. FIG. 3 is a bottom view of the first substrate. 5 is a circuit diagram showing the configuration of the first substrate shown in FIG. 4. FIG. 6 is a diagram showing a first modification example of FIG. 5. FIG. 6 is a diagram showing a second modification example of FIG. 5. FIG. 6 is a diagram showing a third modification example of FIG. 5. FIG. The length of the second MSL (second microstrip line) between the first filter circuit and the combining unit and the combining unit for the 2690 MHz signal of the second antenna in a circuit configuration similar to that shown in FIG. FIG. 2 is a graph showing an example of the relationship between FIG. 2 is a left side view of the vehicle-mounted antenna device according to Comparative Form 1. FIG. 7 is a left side view of an in-vehicle antenna device according to Comparative Form 2; The first antenna and the second antenna of the vehicle-mounted antenna device according to the embodiment, the multi-resonance antenna of the vehicle-mounted antenna device according to Comparative Form 1, and the telematics antenna of the vehicle-mounted antenna device according to Comparative Form 2. It is a graph which shows the frequency characteristic of the sensitivity in the low frequency band of LTE in each. The first antenna and the second antenna of the vehicle-mounted antenna device according to the embodiment, the multi-resonance antenna of the vehicle-mounted antenna device according to Comparative Form 1, and the telematics antenna of the vehicle-mounted antenna device according to Comparative Form 2. It is a graph which shows the frequency characteristic of the sensitivity in the high frequency band of LTE in each. 7 is a left side view of an in-vehicle antenna device according to Modification 1. FIG. 15 is a top view of the vehicle-mounted antenna device shown in FIG. 14. FIG. FIG. 7 is a left side view of an in-vehicle antenna device according to a second modification. 17 is a top view of the vehicle-mounted antenna device shown in FIG. 16. FIG. FIG. 7 is a left side view of an in-vehicle antenna device according to a third modification.

Embodiments of the present invention will be described below with reference to the drawings. Note that in all the drawings, similar components are given the same reference numerals, and descriptions thereof will be omitted as appropriate.

In this specification, ordinal numbers such as "first," "second," and "third" are used merely to distinguish structures with similar names, unless otherwise specified. , do not imply any particular feature of the configuration (eg, order or importance).

FIG. 1 is a perspective view of an in-vehicle antenna device 10 according to an embodiment. FIG. 2 is a left side view of the vehicle-mounted antenna device 10 shown in FIG. FIG. 3 is a top view of the vehicle-mounted antenna device 10 shown in FIG.

In addition to FIGS. 1 to 3, as well as FIGS. 4, 10 and 11, and FIGS. 14 to 18, which will be described later, the first direction X, second direction Y, and third direction Z are as follows. In addition, in each figure, an arrow indicating a first direction X, a second direction Y, or a third direction Z means that the direction toward the side indicated by the arrow is the positive direction of the direction indicated by the arrow. do. Further, a white circle with a black dot indicating the second direction Y or the third direction Z means that the direction from the back of the page to the front to which the white circle is attached is the positive direction of the direction indicated by the white circle. On the other hand, a white circle with an X mark indicating the third direction Z means that the direction from the front to the back of the paper surface to which the white circle is attached is the positive direction of the direction indicated by the white circle.

The first direction X is the front-rear direction of the vehicle-mounted antenna device 10. The positive direction of the first direction X is the front direction of the vehicle-mounted antenna device 10. The negative direction of the first direction X, that is, the direction opposite to the positive direction of the first direction X is the rear direction of the vehicle-mounted antenna device 10. The second direction Y is the left-right direction of the vehicle-mounted antenna device 10. The second direction Y intersects with the first direction X, and specifically, is perpendicular to it. The positive direction of the second direction Y is the left direction of the vehicle antenna device 10 when viewed from the rear of the vehicle antenna device 10. The negative direction of the second direction Y, that is, the opposite direction to the positive direction of the second direction Y is the right direction of the vehicle-mounted antenna device 10 when viewed from the rear of the vehicle-mounted antenna device 10. The third direction Z is the vertical direction of the vehicle-mounted antenna device 10. The third direction Z intersects both the first direction X and the second direction Y, and specifically, they are orthogonal to each other. The positive direction of the third direction Z is the upward direction of the vehicle-mounted antenna device 10. The negative direction of the third direction Z, that is, the direction opposite to the positive direction of the third direction Z is the downward direction of the vehicle-mounted antenna device 10. In the present specification, the first direction Sometimes.

The vehicle antenna device 10 includes a base 100, a first substrate 200, a first antenna 310, a second antenna 320, a second substrate 400, a GNSS (Global Navigation Satellite System) antenna 510, and an LTE antenna 520. The upper surface of the base 100, the first substrate 200, the second antenna 320, the second substrate 400, the GNSS antenna 510, and the LTE antenna 520 are covered by a case (not shown), and the first antenna 310 is 1 antenna 310 is exposed from the case except for the lower end and its vicinity.

The in-vehicle antenna device 10 is attached to the roof of an automobile (not shown). Specifically, the base 100 is placed on the top side of the roof of the automobile. Note that the matters described in this embodiment regarding the vehicle-mounted antenna device 10 can also be applied to an antenna device that is attached to an object other than the roof of a vehicle.

The length of the base 100 in the front-back direction of the vehicle-mounted antenna device 10 is longer than the length of the base 100 in the left-right direction of the vehicle-mounted antenna device 10. Furthermore, the base 100 has a thickness in a direction parallel to the height direction of the vehicle-mounted antenna device 10.

The first substrate 200 is placed on the top surface of the base 100. The first substrate 200 is, for example, a PCB (Printed Circuit Board). The first substrate 200 has a thickness in a direction parallel to the height direction of the vehicle-mounted antenna device 10.

The first antenna 310 and the second antenna 320 are arranged on the upper surface side of the first substrate 200. The first antenna 310 and the second antenna 320 are arranged in a predetermined direction, specifically, in the front-rear direction of the vehicle-mounted antenna device 10. More specifically, the first antenna 310 is located behind the second antenna 320, and the second antenna 320 is located in front of the first antenna 310. However, the arrangement of the first antenna 310 and the second antenna 320 is not limited to the arrangement according to this embodiment. For example, the first antenna 310 may be located in front of the second antenna 320.

A lower end of the first antenna 310 is connected to the first power feeding section 210 of the first substrate 200. A lower end of the second antenna 320 is connected to the second power feeding section 220 of the first substrate 200. The first power feeding unit 210 and the second power feeding unit 220 are physically separated from each other. In this case, isolation between the first antenna 310 and the second antenna 320 can be ensured compared to the case where the power feeding part of the first antenna 310 and the power feeding part of the second antenna 320 are common. , interference between the signal transmitted and/or received by the first antenna 310 and the signal transmitted and/or received by the second antenna 320 can be reduced. Therefore, the sensitivity of the first antenna 310 and the second antenna 320 of the vehicle-mounted antenna device 10 can be increased over a wide frequency band. Note that the antenna transmits and/or receives a signal means that the antenna transmits and/or receives a signal.

The first antenna 310 is operable in multiple bands including a predetermined first frequency band. Specifically, the first antenna 310 is operable in three frequency bands, that is, the low frequency band of the LTE band, the DAB band, and the AM/FM radio band. Further, the first antenna 310 functions as a TEL (telephone) main antenna in the low frequency band of the LTE band. In the present embodiment, the first frequency band is a low frequency band of the LTE band, and includes, for example, at least a portion of 699 MHz to 960 MHz. However, the first frequency band may be a band different from the low frequency band of the LTE band. Further, the first antenna 310 may be operable only in the first frequency band without operating in the DAB band and the AM/FM radio band.

The first antenna 310 has a rod shape extending in one direction. In this embodiment, the first antenna 310 is tilted from the front of the vehicle antenna device 10 toward the rear of the vehicle antenna device 10 . The first antenna 310 includes a winding (not shown) spirally extending in the direction in which the first antenna 310 extends, and an antenna cover 312 that covers the winding and extends in the direction in which the first antenna 310 extends. It has . In this case, the first antenna 310 can operate in multiple bands depending on the manner of the winding, such as the number of turns, the winding pitch, the winding diameter, and the shape. For example, the portions of the first antenna 310 that operate in the three frequency bands have a common winding. In this case, the shorter the length of the winding in the extending direction of the first antenna 310, the shorter the corresponding frequency band. Therefore, for example, if the length of the winding from the bottom end of the winding is winding length A, B, and C, the winding will function as an antenna operating in the low frequency band of the LTE band at winding length A. , the winding length B functions as an antenna operating in the DAB band, and the winding length C functions as an antenna operating in the AM/FM radio band. In this case, the winding length A is shorter than the winding length B, and the winding length B is shorter than the winding length C. By configuring the first antenna 310 to share the winding in this way, parts can be used effectively, and the space in which the first antenna 310 is arranged can be used effectively. Note that a portion of the winding having a winding length A may not be wound around a support such as a core wire, but adjacent winding portions of the winding may be brought into close contact with each other to form a tightly wound structure. By doing so, it is possible to prevent the portion of the winding wire having the winding length A from breaking. Furthermore, by increasing the wire diameter of the portion of the winding having a winding length A, it is possible to provide the wire with spring properties that allow it to return to its original shape even if it is bent by an external force. In addition, since the winding diameter is thick, the conductor resistance is reduced, and the operating gain can be improved and the band can be expanded in the low frequency band of the LTE band.

The second antenna 320 is operable in a predetermined second frequency band. The second frequency band is different from the first frequency band. In this embodiment, the second frequency band is a high frequency band of the LTE band, and includes, for example, at least a portion of 1710 MHz to 2690 MHz. That is, the second frequency band is a higher frequency band than the first frequency band. Further, the second antenna 320 functions as a TEL main antenna in the high frequency band of the LTE band. However, the second frequency band may be a different frequency band from the high frequency band of the LTE band. Further, the second frequency band may be a lower frequency band than the first frequency band.

The second antenna 320 has a first conductor plate part 322 and a second conductor plate part 324. The first conductor plate portion 322 is arranged on the upper surface of the first substrate 200. The first conductor plate section 322 is connected to the second power supply section 220. Further, the first conductor plate portion 322 has a thickness in a direction parallel to the second direction Y, and a width in a direction parallel to the first direction X. The second conductor plate portion 324 extends from the upper end of the first conductor plate portion 322 in a direction perpendicular to the third direction Z, specifically, in the positive direction of the second direction Y. More specifically, when viewed from the front of the vehicle-mounted antenna device 10, the second conductor plate portion 324 extends from the upper end of the first conductor plate portion 322 toward the right side of the first conductor plate portion 322. There is. Further, the second conductor plate portion 324 has a thickness in a direction parallel to the height direction of the vehicle-mounted antenna device 10. According to the present embodiment, for example, the second conductor plate portion 324 does not extend in a direction that intersects the extending direction of the first conductor plate portion 322, but in the same direction as the first conductor plate portion 322. The height of the second antenna 320 in the height direction of the vehicle-mounted antenna device 10 can be lowered compared to the case where the second antenna 320 simply extends in the height direction.

In the present embodiment, the first conductor plate part 322 and the second conductor plate part 324 are made by separating a conductor plate such as a sheet metal into a part that becomes the first conductor plate part 322 and a part that becomes the second conductor plate part 324. It is formed by folding it in between. However, the first conductor plate part 322 and the second conductor plate part 324 can be formed by using other methods, for example, a conductor plate such as a sheet metal which becomes the first conductor plate part 322 and a sheet metal etc. which becomes the second conductor plate part 324. It may be formed by joining the conductor plate and the conductive plate to each other, for example, by welding.

In this way, the second antenna 320 has a first part connected to the second power feeding section 220 and a second part connected at an angle with respect to the first part. . In this embodiment, the first portion and the second portion of the second antenna 320 correspond to the first conductor plate portion 322 and the second conductor plate portion 324, respectively. According to the second antenna 320 having this shape, it is possible to configure a low-profile antenna of, for example, 40 mm or less while ensuring a desired frequency band. Furthermore, since the overlapped portion of the second antenna 320 with the first antenna 310 in the height direction is reduced, spatial isolation between the first antenna 310 and the second antenna 320 can be ensured. Note that the sensitivity of the second antenna 320 and the spatial isolation between the first antenna 310 and the second antenna 320 depend on the connection position (bending position) between the first conductor plate part 322 and the second conductor plate part 324. , can be adjusted.

The shape of the second antenna 320 is not limited to the shape according to this embodiment. For example, although the direction in which the first conductor plate portion 322 extends is set to be the positive direction of the third direction Z, it may be configured to extend inclined toward the second direction Y side. Further, the direction in which the first conductor plate portion 322 extends and the direction in which the second conductor plate portion 324 extends may not be orthogonal to each other, but may be oblique to each other. Furthermore, when viewed from the front of the vehicle-mounted antenna device 10, the second conductor plate portion 324 extends from the upper end of the first conductor plate portion 322 to the right side of the first conductor plate portion 322, that is, in the negative direction of the second direction Y. may extend toward a different side, for example, the left side of the first conductor plate portion 322, that is, the positive direction of the second direction Y. Furthermore, the second antenna 320 does not need to have a portion corresponding to the second conductor plate portion 324. For example, the second antenna 320 includes only a conductive plate such as a single sheet metal that is thick in a direction perpendicular to the height direction of the vehicle antenna device 10, for example, in the left-right direction of the vehicle antenna device 10. Good too. Further, although the second antenna 320 is arranged such that the surface of the first conductor plate portion 322 faces in the second direction Y, the present invention is not limited to this, and the surface of the first conductor plate portion 322 faces in the first direction They may be arranged so as to face each other.

Further, the second antenna 320 may be provided on a substrate and configured by a pattern instead of conductive plates such as the first conductive plate part 322 and the second conductive plate part 324. In this case, for example, a substrate on which a pattern constituting the second antenna 320 is formed is placed on the upper surface of the first substrate 200.

In this embodiment, the first antenna 310 can be made compatible with the low frequency band of LTE. Therefore, it is not necessary to design the second antenna 320 in consideration of the LTE low frequency band. Therefore, the degree of freedom in designing the second antenna 320 is improved compared to the case where the second antenna 320 also supports the low frequency band of LTE. In particular, in this embodiment, compared to the case where the second antenna 320 also supports the low frequency band of LTE, by adjusting the size and height of the second antenna 320, the second antenna 320 can support the low frequency band of LTE. The frequency band can be expanded towards higher frequency bands.

In this embodiment, the second antenna 320 can be made compatible with the high frequency band of LTE. Therefore, it is not necessary to design the first antenna 310 in consideration of the high frequency band of LTE. Therefore, the degree of freedom in designing the first antenna 310 is improved compared to the case where the first antenna 310 also supports the high frequency band of LTE. In particular, in this embodiment, compared to the case where the first antenna 310 also supports the low frequency band of LTE, the first antenna 310 is compatible by adjusting the above-mentioned winding aspect of the first antenna 310. The possible frequency band can be expanded towards lower frequency bands. Furthermore, if the first antenna 310 supports the high frequency band of LTE, it is necessary to consider the influence of the signal in the high frequency band of LTE from the harmonics of the signal in the frequency band lower than the high frequency band of LTE. . In contrast, in this embodiment, there is no need to consider such an influence when designing the first antenna 310.

The second substrate 400 is placed on the top surface of the base 100. The second substrate 400 is, for example, a PCB. The second substrate 400 has a thickness in a direction parallel to the height direction of the vehicle-mounted antenna device 10. The second substrate 400 is located in front of the first substrate 200. In this embodiment, each of the first substrate 200 and the second substrate 400 is a substrate spaced apart from each other. However, the first substrate 200 and the second substrate 400 may not be separated from each other, and may be connected to each other. When the first substrate 200 and the second substrate 400 are connected to each other, the first antenna 310, the second antenna 320, the GNSS antenna 510, and the LTE antenna 520 have a portion corresponding to the first substrate 200 and a portion corresponding to the second substrate 400. A portion corresponding to the . When the first antenna 310, the second antenna 320, the GNSS antenna 510, and the LTE antenna 520 are arranged on one substrate, the electrical characteristics of each antenna are more stable. Further, in this case, the signals of each antenna may be outputted through one integrated connector having a multi-pole configuration. By outputting the signals of each antenna through one integrated connector, the number of soldered cables can be reduced and cables can be easily attached and detached.

The GNSS antenna 510 and the LTE antenna 520 are arranged on the upper surface side of the second substrate 400. The GNSS antenna 510 and the LTE antenna 520 are arranged in a predetermined direction, specifically, in the front-rear direction of the vehicle-mounted antenna device 10. More specifically, GNSS antenna 510 is located behind LTE antenna 520, and LTE antenna 520 is located in front of GNSS antenna 510. However, the arrangement of the GNSS antenna 510 and the LTE antenna 520 is not limited to the arrangement according to this embodiment.

GNSS antenna 510 is, for example, a GPS (Global Positioning System) antenna. GNSS antenna 510 is connected to a power feeding section provided on second board 400. In this embodiment, the GNSS antenna 510 is a patch antenna. Specifically, when viewed from above the vehicle-mounted antenna device 10, the GNSS antenna 510 has a rectangular (for example, rectangular or square) shape. However, the shape of the GNSS antenna 510 is not limited to this example, and may be circular, for example. Further, the GNSS antenna 510 may be an antenna having a structure different from that of a patch antenna, for example, an antenna having a helical structure.

LTE antenna 520 functions as a TEL sub-antenna, for example. LTE antenna 520 is connected to a power feeding section provided on second board 400. The LTE antenna 520 has a third conductor plate section 522 and a fourth conductor plate section 524. The third conductor plate portion 522 is arranged on the upper surface of the second substrate 400. Further, the third conductor plate portion 522 has a thickness in a direction parallel to the first direction X, and a width in a direction parallel to the second direction Y. The fourth conductor plate portion 524 extends obliquely downward from the upper end of the third conductor plate portion 522 toward the front of the vehicle-mounted antenna device 10 . According to the present embodiment, for example, the fourth conductor plate portion 524 does not extend in a direction intersecting the extending direction of the third conductor plate portion 522, but in the same direction as the third conductor plate portion 522. The height of the LTE antenna 520 in the height direction of the vehicle-mounted antenna device 10 can be lowered compared to the case where the LTE antenna 520 simply extends in the height direction. As a result, the case can be designed with a gentle, streamlined shape, and the antenna placement space can be made more efficient. Further, according to the present embodiment, the fourth conductor plate portion 524 extends from the upper end of the third conductor plate portion 522 toward the side where the GNSS antenna 510 is located, that is, toward the rear of the vehicle-mounted antenna device 10. Spatial isolation between the GNSS antenna 510 and the fourth conductor plate portion 524 can be ensured compared to the case where the antenna 510 and the fourth conductive plate portion 524 are present. Furthermore, compared to the case where the fourth conductor plate portion 524 is present above the GNSS antenna 510 (in the positive direction of the third direction Z), interference to the GNSS antenna 510 is suppressed while securing the desired frequency band. be able to. However, the shape of the LTE antenna 520 is not limited to the shape according to this embodiment.

In this embodiment, the third conductor plate part 522 and the fourth conductor plate part 524 are made by separating a conductor plate such as a sheet metal into a part that will become the third conductor plate part 522 and a part that will become the fourth conductor plate part 524. It is formed by folding it in between. However, the third conductor plate part 522 and the fourth conductor plate part 524 can be formed by using other methods, for example, a conductor plate such as a sheet metal which becomes the third conductor plate part 522 and a sheet metal etc. which becomes the fourth conductor plate part 524. It may be formed by joining the conductor plate and the conductive plate to each other, for example, by welding.

Furthermore, in the present embodiment, the extending direction of the fourth conductor plate part 524 from the upper end of the third conductor plate part 522 in the LTE antenna 520 is the same as the extension direction of the fourth conductor plate part 524 from the upper end of the first conductor plate part 322 in the second antenna 320. This is different from the direction in which the conductor plate portion 324 extends. In this case, the extending direction of the second conductor plate part 324 from the upper end of the first conductor plate part 322 in the second antenna 320 and the extension direction of the fourth conductor plate part 524 from the upper end of the third conductor plate part 522 in the LTE antenna 520 Interference between the radio waves transmitted and/or received by the second antenna 320 and the radio waves transmitted and/or received by the LTE antenna 520 can be reduced compared to the case where the extension directions of the two antennas are the same. .

Further, in this embodiment, the GNSS antenna 510 is located between the second antenna 320 and the LTE antenna 520. In this case, the second antenna 320 and the LTE antenna 520 are arranged so that interference between the radio waves transmitted and/or received by the second antenna 320 and the radio waves transmitted and/or received by the LTE antenna 520 is reduced. can be spaced apart from each other. Further, the GNSS antenna 510 can be placed in a space formed by arranging the second antenna 320 and the LTE antenna 520 apart from each other. Therefore, the second antenna 320, the GNSS antenna 510, and the LTE antenna 520 can be arranged in a small space so that the second antenna 320 and the LTE antenna 520 operate suitably.

FIG. 4 is a bottom view of the first substrate 200. FIG. 5 is a circuit diagram showing the configuration of the first substrate 200 shown in FIG. 4.

The first substrate 200 includes a first power supply section 210, a first matching circuit 212, a first filter circuit 214, a first microstrip line (first MSL) 216a, a second MSL 216b, a second power supply section 220, a second matching circuit 222, It has a second filter circuit 224, a third MSL 226a, a fourth MSL 226b, a combining section 250, and an output section 252. In the example shown in FIG. 4, each element shown in FIG. 5 is provided on the lower surface side of the first substrate 200. However, each element shown in FIG. 5 may be provided on the upper surface side of the first substrate 200. Further, some of the elements shown in FIG. 5 are provided on the lower surface side of the first substrate 200, and some other elements shown in FIG. 5 are provided on the upper surface side of the first substrate 200. You can. For example, the first power feeding section 210 may be provided on one side of the top surface and the bottom surface of the first substrate 200, and the second power feeding section 220 may be provided on the other side of the top surface and the bottom surface of the first substrate 200. can. In this case, compared to the case where the first power feeding section 210 and the second power feeding section 220 are provided on the same side of the upper surface and the lower surface of the first substrate 200, the first antenna 310 and the second antenna 320 are Isolation can be ensured, and by arranging the first antenna 310 and the second antenna 320 close to each other when viewed from a direction parallel to the thickness direction of the first substrate 200, the thickness of the first substrate 200 can be reduced. The area for providing the first antenna 310 and the second antenna 320 when viewed from a direction parallel to the direction can be reduced.

The first power feeding section 210 is connected to the combining section 250 via a first matching circuit 212, a first MSL 216a, a first filter circuit 214, and a second MSL 216b in this order. The second power feeding section 220 is connected to the combining section 250 via the second matching circuit 222, the third MSL 226a, the second filter circuit 224, and the fourth MSL 226b in this order. In this way, the combining unit 250 combines the signal sent from the first power feeding unit 210 and the signal sent from the second power feeding unit 220. Further, the signals combined in the combining section 250 are output from the output section 252.

The first matching circuit 212 has a filter structure including a capacitor and an inductor. This filter structure is shown as a lumped constant circuit. However, the circuit configuration of the first matching circuit 212 is not limited to the circuit configuration according to this embodiment, and may be a distributed constant circuit, for example.

In this embodiment, the first filter circuit 214 has one stage of LC parallel circuit. This LC parallel circuit includes an inductor and a capacitor connected in parallel. Also, this LC parallel circuit is shown as a lumped constant circuit. However, the circuit is not limited to this, and may be a distributed constant circuit, for example. Note that the first filter circuit 214 may include multiple stages of LC parallel circuits connected in series. That is, the first filter circuit 214 can include at least one stage of LC parallel circuit. The first filter circuit 214 passes signals in the first frequency band and blocks signals in the second frequency band. For example, in the circuit of FIG. 5, when the length of the second MSL 216b is 0 mm, the first filter circuit 214 becomes an open circuit having a high impedance 17 times the characteristic impedance for the second frequency band of 2690 MHz. ing. Therefore, in the circuit of FIG. 5, the first filter circuit 214 can reflect the signal with the best point at 2690 MHz in the second frequency band. Further, in the electrical path, the first filter circuit 214 is located between the first power feeding section 210 and the combining section 250. "Electrical path" means, for example, on the circuit diagram of the first substrate 200 such as the circuit diagram shown in FIG. This means that the first filter circuit 214 does not need to be physically located between the first power feeding section 210 and the combining section 250. When the first filter circuit 214 is provided, compared to the case where the first filter circuit 214 is not provided, the second The amount of signals in the frequency band can be reduced. That is, the first filter circuit 214 can separate the first power supply section 210 from the second power supply section 220 with respect to the signal in the second frequency band.

The second MSL 216b serves as a transmission path between the first filter circuit 214 and the combining section 250. As will be described later using FIG. 9, the physical length of the second MSL 216b is preferably short. That is, it is preferable that the first filter circuit 214 is directly connected to the synthesis section 250. The meaning that the first filter circuit 214 is directly connected to the synthesis section 250 will be explained in detail later.

The second matching circuit 222 has a filter structure including a capacitor and an inductor. This filter structure is shown as a lumped constant circuit. However, the circuit configuration of the second matching circuit 222 is not limited to the circuit configuration according to this embodiment, and may be a distributed constant circuit, for example.

In this embodiment, the second filter circuit 224 has one stage of LC parallel circuit. This LC parallel circuit includes an inductor and a capacitor connected in parallel. Also, this LC parallel circuit is shown as a lumped constant circuit. However, the circuit is not limited to this, and may be a distributed constant circuit, for example. Note that the second filter circuit 224 may include multiple stages of LC parallel circuits connected in series. That is, the second filter circuit 224 can include at least one stage of LC parallel circuit. The second filter circuit 224 passes signals in the second frequency band and blocks signals in the first frequency band. For example, in the circuit of FIG. 5, when the length of the fourth MSL 226b is 0 mm, the second filter circuit 224 is an open circuit having a high impedance 450 times the characteristic impedance at 840 MHz in the first frequency band. . Therefore, in the circuit of FIG. 5, the second filter circuit 224 can reflect the signal with the best point at 840 MHz in the first frequency band. Further, in the electrical path, the second filter circuit 224 is located between the second power feeding section 220 and the combining section 250. "Electrical path" means, for example, on the circuit diagram of the first substrate 200 such as the circuit diagram shown in FIG. This means that the second filter circuit 224 does not need to be physically located between the second power feeding section 220 and the combining section 250. When the second filter circuit 224 is provided, compared to the case where the second filter circuit 224 is not provided, the first The amount of signals in the frequency band can be reduced. That is, the second filter circuit 224 can separate the second power supply unit 220 from the first power supply unit 210 with respect to the signal in the first frequency band.

The fourth MSL 226b serves as a transmission path between the second filter circuit 224 and the combining section 250. The physical length of the fourth MSL 226b is preferably short, similar to the physical length of the second MSL 216b, which will be described later with reference to FIG. That is, it is preferable that the second filter circuit 224 is directly connected to the synthesis section 250. The meaning of the second filter circuit 224 being directly connected to the combining section 250 will be explained in detail later.

In this embodiment, isolation between the first antenna 310 and the second antenna 320 is achieved by the first filter circuit 214 and the second filter circuit 224. Therefore, there are no restrictions on the electrical length between the first antenna 310 and the first filter circuit 214 and the electrical length between the second antenna 320 and the second filter circuit 224. Therefore, the degree of freedom in the layout of the first antenna 310 and the second antenna 320 can be increased compared to the case where the first filter circuit 214 and the second filter circuit 224 are not provided.

FIG. 6 is a diagram showing a first modification of FIG. 5. The example shown in FIG. 6 is similar to the example shown in FIG. 5 except for the following points.

The second power feeding section 220 is directly connected to the combining section 250. That is, the first substrate 200 does not have the second matching circuit 222, the second filter circuit 224, the third MSL 226a, and the fourth MSL 226b shown in FIG. In the second power feeding section 220, even if the second matching circuit 222 is not provided, the output impedance is the characteristic impedance of the combining section 250, or even if the second filter circuit 224 is not provided, the output impedance is synthesized from the viewpoint of the signal in the first frequency band. When the second matching circuit 222 and the second filter circuit 224 are unnecessary, such as when loss is acceptable, the second power feeding section 220 may be directly connected to the combining section 250. In this case, it is possible to prevent the frequency band of the signal sent from the second antenna 320 to the combining section 250 from being narrowed by the second matching circuit 222. Furthermore, loss of the signal sent from the second antenna 320 to the combining section 250 by the second filter circuit 224 can be suppressed.

From the description of FIGS. 5 and 6, the first substrate 200 includes at least one of the first filter circuit 214 and the second filter circuit 224, for example, both the first filter circuit 214 and the second filter circuit 224. be able to.

FIG. 7 is a diagram showing a second modification of FIG. 5. The example shown in FIG. 7 is similar to the example shown in FIG. 5 except for the configuration of the first filter circuit 214 and the configuration of the second filter circuit 224.

The first filter circuit 214 has a T-type low-pass filter circuit. This T-type low-pass filter circuit includes two inductors connected in series, and a capacitor connected to a portion between the two inductors and a ground potential. Further, this T-type low-pass filter circuit is shown as a lumped constant circuit. However, the circuit is not limited to this, and may be a distributed constant circuit, for example. Also in the example shown in FIG. 7, the first filter circuit 214 can pass signals in the first frequency band and can block signals in the second frequency band. Furthermore, the number of inductors is increased by one compared to the first filter circuit 214 of FIG. Since the filter has multiple stages, it is possible to widen the frequency band in which the synthesis loss of the second frequency band can be reduced.

The second filter circuit 224 has a T-type high-pass filter circuit. This T-type high-pass filter circuit includes two capacitors connected in series, and an inductor connected to a portion between the two capacitors and a ground potential. Further, this T-type high-pass filter circuit is shown as a lumped constant circuit. However, the circuit is not limited to this, and may be a distributed constant circuit, for example. Also in the example shown in FIG. 7, the second filter circuit 224 can pass signals in the second frequency band and can block signals in the first frequency band. Furthermore, the number of capacitors is increased by one compared to the second filter circuit 224 of FIG. Since the filter has multiple stages, it is possible to widen the frequency band in which the synthesis loss in the first frequency band can be reduced.

FIG. 8 is a diagram showing a third modification of FIG. 5. The example shown in FIG. 8 is similar to the example shown in FIG. 5 except for the following points.

The vehicle-mounted antenna device 10 further includes a third antenna 330. The third antenna 330 operates in a third frequency band that is different from both the first frequency band of the first antenna 310 and the second frequency band of the second antenna 320. The third frequency band may include, for example, a frequency band higher than 2690 MHz, for example a 5 GHz band. When the third frequency band includes the 5 GHz band, the third antenna 330 may function as, for example, a W-LAN (Wireless Local Area Network) antenna, a V2X (Vehicle-to-everything) antenna, a 5G communication Sub6, etc. good.

Note that the third frequency band may be the same frequency band as the second frequency band. In this case, when the second frequency band and the third frequency band include the LTE high frequency band, the LTE high frequency band signal is transmitted and transmitted by the two antennas, that is, the second antenna 320 and the third antenna 330. / or can be received. Additionally, LTE high frequency band signals may be transmitted and/or received by two or more antennas.

The first substrate 200 further includes a third power feeding section 230, a third matching circuit 232, a third filter circuit 234, a fifth MSL 236a, and a sixth MSL 236b. The third power feeding section 230 is connected to a third antenna 330. The third power feeding section 230 is connected to the combining section 250 via a third matching circuit 232, a fifth MSL 236a, a third filter circuit 234, and a sixth MSL 236b in this order. In this way, the combining section 250 combines the signal sent from the third power feeding section 230 in addition to the signal sent from the first power feeding section 210 and the signal sent from the second power feeding section 220. do.

The third power supply section 230 is physically separated from the first power supply section 210 and the second power supply section 220. In this case, compared to the case where the power feeding part of the third antenna 330 is common to the power feeding part of the first antenna 310 and the power feeding part of the second antenna 320, the first antenna 310, the second antenna 320, and the third antenna Isolation from the antenna 330 can be ensured, so that the signals transmitted and/or received by the first antenna 310, the signals transmitted and/or received by the second antenna 320, and the signals transmitted and/or received by the third antenna 330 are separated. and/or interference with the received signal can be reduced. Therefore, the sensitivity of the first antenna 310, second antenna 320, and third antenna 330 of the vehicle-mounted antenna device 10 can be increased over a wide frequency band.

From the description of FIGS. 5 and 8, the combining unit 250 includes the first feeding unit 210, the second Signals sent from a plurality of power supply units, such as the power supply unit 220 and the third power supply unit 230, can be combined. In this case, the number of multiple antennas may be, for example, two as shown in FIG. 5, three as shown in FIG. 8, or four or more. You can. Further, some of the frequency bands of these plurality of antennas may be different from each other or may be the same.

FIG. 9 shows the length of the second MSL 216b between the first filter circuit 214 and the combining unit 250 and the combining unit for the 2690 MHz signal of the second antenna 320 in a circuit configuration similar to that shown in FIG. 25 is a graph showing an example of the relationship between

The horizontal axis of the graph shown in FIG. 9 indicates the length of the second MSL 216b between the first filter circuit 214 and the combining section 250. λ shown on the horizontal axis of the graph in FIG. 9 means the wavelength of the signal propagating through the second MSL 216b at 2690 MHz. This wavelength λ is a value that takes into consideration the wavelength shortening rate, and is 62.4 mm. The combined loss on the vertical axis of the graph shown in FIG. This refers to the loss caused by interference with the 2690 MHz signal sent to the first filter circuit 214 via the 2690 MHz signal, reflected by the first filter circuit 214, and sent to the combining section 250 via the second MSL 216b.

As shown in FIG. 9, the combined loss is approximately -2 dB or more in the ratios of the length of the second MSL 216b to the wavelength λ from 0 to 2/16, from 6/16 to 10/16, and from 14/16 to 18/16. It has become. On the other hand, with respect to the ratio of the length of the second MSL 216b to the wavelength λ, the combined loss is locally large at and around 4/16, at and around 12/16, and at and around 20/16. The reason for this is as follows. That is, when the ratio of the length of the second MSL 216b to the wavelength λ is 0 or around 0, or an integral multiple of 1/2 or around 0, the signal sent from the second feeder 220 to the combining unit 250 and the It is sent from the second power feeding section 220 to the combining section 250, from the combining section 250 to the first filter circuit 214 via the second MSL 216b, reflected by the first filter circuit 214, and sent to the combining section 250 via the second MSL 216b. Constructive interference of the signals occurs due to the transmitted signals. On the other hand, when the ratio of the length of the second MSL 216b to the wavelength λ is an odd multiple of 1/4 or in the vicinity thereof, the signal sent from the second feeding section 220 to the combining section 250 and the second feeding section 220 to the combining unit 250, from the combining unit 250 to the first filter circuit 214 via the second MSL 216b, reflected by the first filter circuit 214, and sent to the combining unit 250 via the second MSL 216b. Destructive interference of the signals occurs due to the signals and. Therefore, as shown in FIG. 9, the synthesis loss differs depending on the length of the second MSL 216b between the first filter circuit 214 and the synthesis section 250.

In the example shown in FIG. 9, it can be said that the ratio of the length of the second MSL 216b to the wavelength λ is preferably 0 to 2/16, 6/16 to 10/16, or 14/16 to 18/16. However, when the second frequency band of the second antenna 320 is wide, that is, the wavelength band corresponding to the second frequency band is wide, and the length of the second MSL 216b is relatively long, for example, in FIG. When the ratio of the lengths of is more than 1/8, even if the loss is low at the frequency in the example shown in FIG. 9, it does not necessarily mean that the loss will be low at a frequency different from the frequency in the example shown in FIG. Therefore, from the viewpoint of reducing the synthesis loss of signals in the second frequency band in the synthesis section 250, the length of the second MSL 216b between the first filter circuit 214 and the synthesis section 250, that is, the length of the second MSL 216b between the first filter circuit 214 and the synthesis section 250, It can be said that the length of the transmission path between the second frequency band and the second frequency band is preferably 1/8 times or less of the wavelength of the signal propagating through this transmission path at the maximum frequency within the second frequency band.

Note that the second frequency band of the second antenna 320 is relatively narrow, for example, the wavelength corresponding to the maximum frequency within the second frequency band is 3/4 times or less of the wavelength corresponding to the minimum frequency within the second frequency band. At some point, the length of the second MSL 216b between the first filter circuit 214 and the combining section 250 is equal to or less than 1/8 times the wavelength of the signal propagating through the second MSL 216b at the maximum frequency within the second frequency band, or The maximum frequency within the frequency band may be (4N-1)/8 times or more (4N+1)/8 times or less (N: an integer of 1 or more) of the wavelength of the signal propagating through the second MSL 216b.

The matters described using FIG. 9 also apply to the length of the fourth MSL 226b between the second filter circuit 224 and the combining section 250. That is, from the viewpoint of reducing the synthesis loss of signals in the first frequency band in the synthesis section 250, the length of the fourth MSL 226b between the second filter circuit 224 and the synthesis section 250 is equal to the maximum frequency in the first frequency band. It can be said that it is preferable that the wavelength is 1/8 times or less of the wavelength of the signal propagating through the fourth MSL 226b. Further, the first frequency band of the first antenna 310 is relatively narrow, for example, the wavelength corresponding to the maximum frequency within the first frequency band is 3/4 times or less of the wavelength corresponding to the minimum frequency within the first frequency band. At some point, the length of the fourth MSL 226b between the second filter circuit 224 and the combining section 250 is equal to or less than 1/8 times the wavelength of the signal propagating through the fourth MSL 226b at the maximum frequency within the first frequency band, or The maximum frequency within the frequency band may be (4M-1)/8 times or more (4M+1)/8 times or less (M: an integer of 1 or more) of the wavelength of the signal propagating through the fourth MSL 226b.

As described above, the fact that the first filter circuit 214 is directly connected to the combining section 250 means that the length of the transmission path between the first filter circuit 214 and the combining section 250 is λ/8 or less. do. However, as mentioned above, depending on the conditions, the fact that the first filter circuit 214 is directly connected to the combining section 250 means that the length of the transmission path between the first filter circuit 214 and the combining section 250 is (4N -1) It also means that it is λ/8 times or more (4N+1) or λ/8 times or less (N: an integer of 1 or more). Here, the wavelength λ is the wavelength of a signal propagating in the transmission path at the maximum frequency of the second frequency band, for example, 2690 MHz. Furthermore, the fact that the second filter circuit 224 is directly connected to the combining section 250 means that the length of the transmission path between the second filter circuit 224 and the combining section 250 is λ'/8 or less. . However, as mentioned above, depending on the conditions, the fact that the second filter circuit 224 is directly connected to the combining section 250 means that the length of the transmission path between the second filter circuit 224 and the combining section 250 is (4M -1) It also means that λ'/8 times or more (4M+1) λ'/8 times or less (M: an integer of 1 or more). Here, the wavelength λ' means the wavelength of a signal propagating in the transmission path at the maximum frequency of the first frequency band, for example, 960 MHz.

FIG. 10 is a left side view of the vehicle-mounted antenna device 10 according to Comparative Embodiment 1.

The vehicle-mounted antenna device 10 according to Comparative Embodiment 1 does not have a configuration corresponding to the second power feeding section 220 and the second antenna 320 of the embodiment. Furthermore, the vehicle-mounted antenna device 10 according to Comparative Embodiment 1 includes a multi-resonant antenna 910 instead of the first antenna 310 of the embodiment. The windings in the antenna cover 912 of the multi-resonant antenna 910 are adjusted so that the multi-resonant antenna 910 can operate in the low frequency band of the LTE band, the DAB band, and the AM/FM radio band. There is. The lower end of multi-resonance antenna 910 is connected to a power feeding section.

FIG. 11 is a left side view of the vehicle-mounted antenna device 10 according to Comparative Embodiment 2.

The in-vehicle antenna device 10 according to Comparative Embodiment 2 includes a telematics antenna 920. The shape of the telematics antenna 920 is optimized so that the telematics antenna 920 operates well in the high frequency band of LTE.

FIG. 12 shows the first antenna 310 and the second antenna 320 of the in-vehicle antenna device 10 according to the embodiment, the multi-resonance antenna 910 of the in-vehicle antenna device 10 according to Comparative Form 1, and the in-vehicle antenna according to Comparative Form 2. 9 is a graph showing frequency characteristics of sensitivity in the LTE low frequency band of each of the telematics antennas 920 of the device 10. FIG. FIG. 13 shows the first antenna 310 and the second antenna 320 of the in-vehicle antenna device 10 according to the embodiment, the multi-resonance antenna 910 of the in-vehicle antenna device 10 according to Comparative Form 1, and the in-vehicle antenna according to Comparative Form 2. 9 is a graph showing frequency characteristics of sensitivity in each of the telematics antennas 920 of the device 10. FIG.

The vertical axis of each graph in FIGS. 12 and 13 indicates sensitivity. The horizontal axis of each graph in FIGS. 12 and 13 indicates frequency. In the graph of FIG. 12, the area between the two dotted lines indicates the LTE low frequency band, ie, 699 MHz to 960 MHz. In the graph of FIG. 13, the area between the two dotted lines indicates the high frequency band of LTE, ie, 1710 MHz to 2690 MHz. The solid lines in each of the graphs in FIGS. 12 and 13 indicate the frequency characteristics of the sensitivity of the first antenna 310 and the second antenna 320 of the vehicle-mounted antenna device 10 according to the embodiment. The broken lines in each of the graphs in FIGS. 12 and 13 indicate the frequency characteristics of the sensitivity of the multi-resonance antenna 910 of the vehicle-mounted antenna device 10 according to the first comparative example. The dashed-dotted lines in each of the graphs in FIGS. 12 and 13 indicate the frequency characteristics of the sensitivity of the telematics antenna 920 of the vehicle-mounted antenna device 10 according to the second comparative embodiment.

As shown in FIG. 12, the multi-resonance antenna 910 of the vehicle-mounted antenna device 10 according to Comparative Form 1 has a high sensitivity of -2 dBi or more over the entire LTE low frequency band. On the other hand, in the multi-resonant antenna 910 of the in-vehicle antenna device 10 according to Comparative Form 1, as shown in FIG. are doing. This is presumed to be due to the effect that harmonics of signals in frequency bands lower than the LTE band, such as the DAB band and AM/FM radio band, are generated from the windings that constitute the multi-resonant antenna 910, that is, the helical antenna. be done. Further, as shown in FIG. 13, the sensitivity of the in-vehicle antenna device 10 according to Comparative Form 1 is lower than the sensitivity of the in-vehicle antenna device 10 according to the embodiment at any frequency in the high frequency band of LTE. ing. This is presumed to be due to attenuation and other losses caused by the multi-resonant antenna 910 and the fact that the length of the multi-resonant antenna 910 is not optimal for the high frequency band of LTE. Ru.

As shown in FIG. 13, the telematics antenna 920 of the vehicle-mounted antenna device 10 according to Comparative Form 2 has a high sensitivity of -2 dBi or more in most of the high frequency band of LTE. On the other hand, in the telematics antenna 920 of the vehicle-mounted antenna device 10 according to Comparative Form 2, as shown in FIG. 12, the sensitivity has decreased to −6 dBi or less in the entire LTE low frequency band. The reason for this can be said to be as follows. That is, the shape of the telematics antenna 920 is optimized so that the telematics antenna 920 operates well in the high frequency band of LTE. However, this shape of the telematics antenna 920 is not optimal for the low frequency band of LTE. Therefore, the sensitivity of the telematics antenna 920 in the LTE low frequency band is lower than the sensitivity of the telematics antenna 920 in the LTE high frequency band.

As shown in FIGS. 12 and 13, the first antenna 310 and the second antenna 320 of the in-vehicle antenna device 10 according to the embodiment have a sensitivity of −4 dB or more in both the LTE low frequency band and high frequency band. It's getting expensive.

From the results shown in FIGS. 12 and 13, the feeding section connected to the antenna that can operate in the low frequency band of LTE and the feeding section connected to the antenna that can operate in the high frequency band of LTE are separated from each other. By doing so, it can be said that the in-vehicle antenna device can operate well in both the low frequency band and the high frequency band of LTE. That is, according to this embodiment, the sensitivity of the vehicle-mounted antenna device 10 can be increased over a wide frequency band.

(Modification 1)
FIG. 14 is a left side view of the vehicle-mounted antenna device 10 according to the first modification. FIG. 15 is a top view of the vehicle antenna device 10 shown in FIG. 14. The vehicle-mounted antenna device 10 according to the first modification is the same as the vehicle-mounted antenna device 10 according to the embodiment except for the following points.

The first antenna 310 is a monopole antenna with a capacitive loading element. Specifically, the first antenna 310 has a radiating element 314a and a capacitive loading element 314b. The radiation element 314a has a shape that extends linearly in a predetermined direction, specifically, in the vertical direction of the vehicle-mounted antenna device 10. The lower end of the radiating element 314a is connected to the first power feeding section 210. A capacitive loading element 314b is attached to the upper end of the radiating element 314a. Note that in this modification, the second antenna 320 has the first conductor plate part 322 and does not have the second conductor plate part 324 shown in FIG. 1, for example. With such a configuration, isolation of each antenna can be ensured while supporting the wide LTE band in a low-profile case of, for example, 70 mm or less.

(Modification 2)
FIG. 16 is a left side view of the vehicle-mounted antenna device 10 according to the second modification. FIG. 17 is a top view of the vehicle-mounted antenna device 10 shown in FIG. 16. The vehicle-mounted antenna device 10 according to the second modification is the same as the vehicle-mounted antenna device 10 according to the first modification except for the following points.

The first antenna 310 is located in front of the second antenna 320, and the second antenna 320 is located behind the first antenna 310. The first antenna 310 is a plate-shaped inverted F antenna (PIFA). Specifically, the first antenna 310 has a radiation plate 316a, a feeding conductor part 316b, and a grounding conductor part 316c. The radiation plate 316a is located above the first substrate 200. The radiation plate 316a is connected to the first power supply section 210 via the power supply conductor section 316b. Furthermore, the radiation plate 316a is grounded via a ground conductor portion 316c. By adopting such a configuration, it is possible to provide isolation of each antenna while supporting the wide LTE band while being equipped with multiple antennas that support multiple frequency bands in a case that is even lower in height, for example, 40 mm or less. can be secured.

(Modification 3)
FIG. 18 is a left side view of the vehicle-mounted antenna device 10 according to the third modification. The vehicle-mounted antenna device 10 according to the third modification is the same as the vehicle-mounted antenna device 10 according to the first modification except for the following points.

The first antenna 310 includes an LTE antenna 318a, a trap coil 318b, a helical element 318c, and a capacitive loading element 318d. The lower end of the LTE antenna 318a is connected to the first power feeding section 210 of the first substrate 200. Trap coil 318b is connected to the upper end of LTE antenna 318a. One end of the helical element 318c is connected to the trap coil 318b. The other end of the helical element 318c is connected to a capacitive loading element 318d. Capacitive loading element 318d is located above second antenna 320.

Note that the first antenna 310 in the vehicle-mounted antenna device 10 according to the third modification is configured as a composite antenna by sharing some of the elements that constitute the first antenna 310. That is, the first antenna 310 can operate in the low frequency band of the LTE band and the DAB band or AM/FM radio band. As a result, in a low-profile case of, for example, 70 mm or less, it is possible to provide a plurality of antennas corresponding to a plurality of frequency bands, support the wide LTE band, and ensure isolation of each antenna.

Although the embodiments and modified examples of the present invention have been described above with reference to the drawings, these are merely examples of the present invention, and various configurations other than those described above may also be adopted.

According to this specification, the following aspects are provided.
(Aspect 1)
Aspect 1 is
a first antenna operable in a first frequency band;
a second antenna capable of operating in a second frequency band different from the first frequency band;
a first power feeding section connected to the first antenna;
a second power feeding unit connected to the second antenna;
a combining unit that combines a signal from the first power feeding unit and a signal from the second power feeding unit;
This is an in-vehicle antenna device.
According to aspect 1, the first power feeding section and the second power feeding section are physically separated from each other. In this case, compared to the case where the power feeding part of the first antenna and the power feeding part of the second antenna are common, isolation between the first antenna and the second antenna can be ensured, and the first antenna Interference between the signal transmitted and/or received by the second antenna and the signal transmitted and/or received by the second antenna can be reduced. Therefore, the sensitivity of the first antenna and the second antenna of the vehicle-mounted antenna device can be increased over a wide frequency band.
(Aspect 2)
Aspect 2 is
a first filter circuit located between the first power feeding unit and the combining unit in an electrical path and blocking signals in the second frequency band;
a second filter circuit located between the second power feeding unit and the combining unit in an electrical path and blocking signals in the first frequency band;
The vehicle-mounted antenna device according to aspect 1 further includes at least one of the above.
According to the second aspect, when the first filter circuit is provided, compared to the case where the first filter circuit is not provided, the first filter circuit that enters the first power feeding section from the second feeding section via the combining section is The amount of signals in two frequency bands can be reduced. That is, the first filter circuit can separate the first power feeding section from the second power feeding section with respect to the signal in the second frequency band. In addition, when the second filter circuit is provided, compared to the case where the second filter circuit is not provided, the first frequency band that enters the second feed section from the first feed section via the combining section is The amount of signal can be reduced. That is, the second filter circuit can separate the second power feeding section from the first power feeding section with respect to the signal in the first frequency band.
(Aspect 3)
Aspect 3 is
A mode in which the length of the transmission path between the first filter circuit and the combining section is 1/8 times or less of the wavelength of a signal propagating within the transmission path at the maximum frequency within the second frequency band. 2. The in-vehicle antenna device according to 2.
According to aspect 3, the signal sent from the second feeding section to the combining section, the signal sent from the second feeding section to the combining section, sent from the combining section to the first filter circuit, and reflected by the first filter circuit. Constructive interference of the signals occurs due to the signals sent to the combining section. Therefore, the synthesis loss of the second frequency band signals in the synthesis section can be reduced.
(Aspect 4)
Aspect 4 is
A mode in which the length of the transmission path between the second filter circuit and the combining section is 1/8 times or less of the wavelength of a signal propagating within the transmission path at the maximum frequency within the first frequency band. 3. The vehicle-mounted antenna device according to 2 or 3.
According to the fourth aspect, similarly to the third aspect, it is possible to reduce the combining loss of the signals in the first frequency band in the combining section.
(Aspect 5)
Aspect 5 is
The first frequency band includes at least a portion of 699MHz to 960MHz,
In the vehicle antenna device according to any one of aspects 1 to 4, the second frequency band includes at least a portion of 1710 MHz to 2690 MHz.
According to the fifth aspect, the sensitivity of the in-vehicle antenna device can be increased over 699 MHz to 960 MHz and 1710 MHz to 2690 MHz.
(Aspect 6)
Aspect 6 is
a third antenna capable of operating in a third frequency band different from both the first frequency band and the second frequency band;
a third power feeding section connected to the third antenna;
Furthermore,
The in-vehicle antenna device according to any one of aspects 1 to 5, wherein the combining unit also combines the signals from the third power feeding unit.
According to aspect 6, the third power feeding section is physically separated from the first power feeding section and the second power feeding section. In this case, the isolation between the first antenna, the second antenna, and the third antenna is higher than in the case where the power feeding part of the third antenna is common to the power feeding part of the first antenna and the power feeding part of the second antenna. and a signal transmitted and/or received by the first antenna, a signal transmitted and/or received by the second antenna, and a signal transmitted and/or received by the third antenna. Interference can be reduced. Therefore, the sensitivity of the first antenna, second antenna, and third antenna of the vehicle-mounted antenna device can be increased over a wide frequency band.
(Aspect 7)
Aspect 7 is
Any one of aspects 1 to 6, wherein the second antenna has a first part connected to the second power feeding part and a second part connected at an angle with respect to the first part. The vehicle antenna device according to item 1 above.
According to aspect 7, it is possible to configure a low-height antenna while ensuring a desired frequency band. Moreover, since the overlapped portion of the second antenna with the first antenna in the height direction is reduced, spatial isolation between the first antenna and the second antenna can be ensured.

10 Vehicle-mounted antenna device 100 Base 200 First board 210 First power feeding section 212 First matching circuit 214 First filter circuit 216a First MSL
216b 2nd MSL
220 Second power supply section 222 Second matching circuit 224 Second filter circuit 226a Third MSL
226b 4th MSL
230 Third power supply section 232 Third matching circuit 234 Third filter circuit 236a 5th MSL
236b 6th MSL
250 Combining section 252 Output section 310 First antenna 312 Antenna cover 314a Radiating element 314b Capacitive loading element 316a Radiation plate 316b Feeding conductor section 316c Grounding conductor section 318a LTE antenna 318b Trap coil 318c Helical element 318d Capacitive loading element 320 Second antenna 322 1 conductor plate part 324 2nd conductor plate part 330 3rd antenna 400 2nd board 510 GNSS antenna 520 LTE antenna 522 3rd conductor plate part 524 4th conductor plate part 910 Multi-resonance antenna 912 Antenna cover 920 Telematics antenna 1st direction Y 2nd direction Z 3rd direction

Claims (4)

a first antenna operable in a first frequency band;
a second antenna capable of operating in a second frequency band different from the first frequency band;
a first power feeding section connected to the first antenna;
a second power feeding unit connected to the second antenna;
a combining unit that combines a signal from the first power feeding unit and a signal from the second power feeding unit;
Equipped with
a first filter circuit that is located between the first power feeding section and the combining section in an electrical path and blocks signals in the second frequency band; a first filter circuit in which the length of the transmission path between the first filter circuit and the first filter circuit is equal to or less than 1/8 times the wavelength of a signal propagating within the transmission path at the maximum frequency within the second frequency band;
a second filter circuit located between the second power feeding section and the combining section in an electrical path and blocking signals in the first frequency band; a second filter circuit in which the length of the transmission path between the second filter circuit and the second filter circuit is equal to or less than 1/8 times the wavelength of a signal propagating within the transmission path at the maximum frequency within the first frequency band;
An in-vehicle antenna device further comprising at least one of the following . The first frequency band includes at least a portion of 699MHz to 960MHz,
The vehicle antenna device according to claim 1 , wherein the second frequency band includes at least a portion of 1710 MHz to 2690 MHz. a third antenna capable of operating in a third frequency band different from both the first frequency band and the second frequency band;
a third power feeding section connected to the third antenna;
Furthermore,
The vehicle-mounted antenna device according to claim 1 or 2 , wherein the combining section also combines the signals from the third power feeding section. 4. The second antenna according to claim 1, wherein the second antenna has a first part connected to the second feeding part and a second part connected at an angle with respect to the first part. The in-vehicle antenna device according to any one of the items.

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