RU2566967C2 - Antenna device - Google Patents

Abstract

FIELD: radio engineering, communication.

SUBSTANCE: invention relates to an antenna device. The antenna device includes an antenna element and a substrate unit, wherein the antenna element includes an antenna base, a radiating electrode, first and second power supply elements and a ground electrode. The substrate unit includes a distribution circuit unit C1 and a phase-shifting circuit unit C2, wherein the distribution circuit unit C1 includes a connecting element 321, channel elements 322A, 322B having a channel length of 1/4λ, and a resistor 323, and the phase-shifting circuit unit C2 includes a channel element 324A to a first power supply element and a channel element 324B to a second power supply element which, is longer than the channel element 324A by 1/4 λ. The phase-shifting circuit unit C2 and the distribution circuit unit C1 are on the same surface of the substrate unit. The phase-shifting circuit unit C2 is located within the channel elements 322A, 322B of the distribution circuit unit C1.

EFFECT: enabling reception of signals in two frequency bands.

2 cl, 14 dwg

Description

FIELD OF TECHNOLOGY

This invention relates to an antenna device with two feed feeders.

BACKGROUND OF THE INVENTION

Generally, a global positioning system (GPS) is known as the standard of a satellite-based positioning system that measures the location of a moving object, such as a bicycle. In GPS, a GPS receiver provided on a moving object receives a GPS signal transmitted from a GPS satellite through, for example, a patch antenna and measures the location of the moving object itself by using the received GPS signal.

GPS is an American standard, and the average carrier frequency of its carrier waveband is 1.57542 GHz. In addition, the global satellite navigation system (GLONASS) is known as the standard of the Russian satellite positioning system. In GLONASS, a receiver provided on a moving object receives the signal from the GLONASS satellite through, for example, a patch antenna and measures the location of the moving object itself by using the received signal in the same way as in GPS. The average frequency range of the GLONASS carrier waves is approximately 1.602 GHz. In the sense in which they are described here, the frequency ranges of the GPS and GLONASS carrier waves are relatively close to each other. In addition, GPS and GLONASS are standards for communication through the use of a circular polarization signal with clockwise rotation.

In addition, a dual-band antenna is known that can receive a normal frequency signal and a frequency signal that creates a delay for GPS and GLONASS (see, for example, patent document 1). For example, such a dual-band antenna for GPS receives a normal frequency of 1.575 GHz and a frequency of 1.277 GHz, which creates a delay. Such a dual-band antenna is equipped with two sets of conductor, which is a radiating electrode and a grounding conductor.

KNOWN DOCUMENTS

Patent document

Patent Document 1: Japanese Patent Application Laid-Open No. H7-288420

SUMMARY OF THE INVENTION

The problem solved by the invention

There is a need for an antenna device that can receive both a GPS signal and a GLONASS signal. The above conventional dual-band antenna is designed to receive a signal of a normal frequency and a frequency that creates a delay that are relatively far apart so that they can be used in GPS and GLONASS. In view of the foregoing, a conventional dual-band antenna is configured to receive signals from two frequency ranges - GPS and GLONASS. However, this configuration requires two sets of antennas, including a radiating electrode and a ground conductor, and this configuration is complex.

In view of the foregoing, for GPS and GLONASS, you can apply a patch antenna that includes one power supply point and one emitting electrode to receive signals of two frequencies that are relatively close to each other. Since the GPS and GLONASS signals are a circular polarization wave signal, this circular polarization wave signal can be received by providing a disturbing element (notch, bulge) in one radiating electrode of the patch antenna. However, although the patch antenna, which includes one power supply point and one radiating electrode, has a simple structure, a range having a satisfactory ellipticity coefficient is narrow.

Therefore, the idea arises to use a patch antenna for GPS and GLONASS, which includes two power supply points and one emitting electrode, for receiving signals of two frequencies that are relatively close to each other. A patch antenna with two power supply points and one radiating electrode does not require a disturbing element in the radiating electrode, but due to a phase shift of one electrical signal by 90 degrees relative to the other electrical signal - both electrical signals are electrical signals supplied to the power supply points , - it becomes possible to emit a radio signal of a circular polarization wave, and vice versa, it is possible to receive a radio signal of a circular polarization wave. In a patch antenna with two power supply points and one radiating electrode, the range having a satisfactory ellipticity coefficient is wide because the patch antenna includes two power supply points. However, in a patch antenna with two power supply points and one radiating electrode, it is difficult to isolate the path for supplying power to one of the power supply points from the path for supplying power to another of the power supply points.

In addition, there was a need to make the area of the circuit, which is connected to the antenna element, small in order to reduce the size of the antenna device.

The objective of this invention is that in an antenna device having two power supply points and one radiating electrode, make the range having a satisfactory ellipticity coefficient wide, improve the insulation between two paths from the input terminal to two power supply points and make the circuit area, which is connected to the antenna element, small.

MEANS OF SOLVING THE PROBLEM

In order to solve the aforementioned problem, the antenna device, which is the invention described in claim 1, includes an antenna element and a substrate unit that is provided on the bottom surface of the antenna element, the antenna element including an antenna base made of a dielectric , a magnetic body or a magnetic dielectric, a radiating electrode that is provided on the upper surface of the base of the antenna, a first power supply element and a second power supply element, which are connected They are provided with a radiating electrode and which penetrate the base of the antenna, and a ground electrode, which is provided on the lower surface of the base of the antenna, the substrate unit includes a distribution circuit unit that includes a connecting element that is connected to an input terminal for supplying power, the first element the path and the second path element having a path length of 1/4 λ shared in the connecting element, and a resistor that is connected to the output terminals of the first path element and the second path element, and bl ok phase shifting circuit, which includes a third path element, which is a path to the first power supply element from the resistor, where an input terminal is provided near the first power supply element, and a fourth path element, which is a path to the second power supply element of the resistor having a path length greater than the third path element by 1/4 λ, while the distribution circuit block and the phase-shifting block are made on the same surface of the substrate block, and the phase-shifting block Hema located inside the first path member and the second tract of the distribution element circuit block.

In the invention described in claim 2, the substrate unit of the antenna device according to claim 1 includes an amplifier circuit unit that is formed on the same surface as the distribution circuit unit and the phase-shifting circuit unit and which amplifies the signal generated from the connecting element of the distribution circuit block.

Advantage of the Invention

In accordance with this invention, in an antenna device including two power supply points and one radiating electrode, the range having a satisfactory ellipticity coefficient can be made wide, the isolation between two paths from the input terminal to two power supply points can be improved, and the area a circuit that is connected to an antenna element can be made small.

BRIEF DESCRIPTION OF THE DRAWINGS

1 is an exploded view of an antenna device in an embodiment of the present invention.

Figure 2 presents a view in section of an antenna device.

Figure 3 presents a schematic drawing of an antenna device.

Figure 4 presents a schematic drawing of an antenna element, a block of a substrate and a stand.

Figure 5 presents a view in plan of the antenna element and block substrate.

FIG. 6 is a plan view of a circuit block in a substrate block.

On figa presents a drawing illustrating the connecting element of the circuit block in a disconnected state. 7B is a drawing illustrating a connecting element of a circuit in a connected state.

On Fig presents a view in plan of the phase-shifting circuit.

9 is a graph illustrating the dependence of S11 on the frequency of the antenna device.

Figure 10 presents a pie chart of the impedances of the antenna device.

11 is a graph illustrating the dependence of the ellipticity coefficient on the frequency of the antenna device.

12 is a graph illustrating the dependence of gain — toward the zenith — on the frequency of the antenna device.

On Fig presents a pie chart illustrating the radiation pattern of the antenna device.

PREFERRED EMBODIMENT OF THE INVENTION

Below, with reference to the accompanying drawings, a detailed description of an embodiment of the present invention is given. However, the scope of the claims of the invention is not limited to the examples shown in the drawings.

An embodiment of the invention is described below with reference to figures 1-13. First, with reference to FIGS. 1-8, a device configuration inherent in the antenna device 1 in this embodiment is described.

The configuration of the antenna device 1 is generally described below with reference to FIGS. 1-3. Figure 1 shows the exploded configuration of the antenna device 1. Figure 2 shows the configuration of the antenna device 1 in section. Figure 3 shows a schematic configuration of an antenna device 1.

The antenna device 1 in this embodiment is a patch antenna for both GPS and GLONASS, both standards for frequency ranges that are relatively close to each other. The carrier wave frequency range is 1.57542 ± 0.1 GHz, and the average frequency is 1.57542 GHz. The average frequency range of the GLONASS carrier wave frequency is 1.602 + k × 0.0005625 GHz (k: frequency channel number for each satellite). In addition, GPS and GLONASS are standards for communicating using a circular polarization signal with clockwise rotation.

The antenna device 1 is attached to the dashboard of the vehicle as a moving object. As shown in FIGS. 1 and 2, the antenna device 1 includes an antenna element 2, a substrate unit 3, a shielding casing 4, a spacer sheet 5, a top cover 6, a stand 7, and screws 8.

Antenna element 2 is the main body of the patch antenna of the antenna device 1 and is a receiving antenna that receives the GPS or GLONASS radio signal sent from the satellite. Antenna element 2 has, for example, the shape of a square plate measuring 40 × 40 × 4t mm.

The substrate block 3 is a printed circuit board (PCB) that is connected to the bottom surface (rear surface) of the antenna element 2, and one end of the coaxial cable 3a is connected to this substrate block. The other end of the coaxial cable 3a is connected to a terminal for connecting to an antenna, GPS receiver, or GLONASS. The shape of the substrate unit 3 may be the shape of a square plate corresponding to the lower surface of the antenna element 2. However, the above-mentioned unit is not limited to such a shape and may be made in a shape having an area smaller than the lower surface of the antenna element 2. The substrate unit 3 has, for example, a square shape measuring 40 × 40 × 0.8t mm. The antenna element is connected and fixed to the block 3 of the substrate, for example, using double-sided adhesive tape. The antenna element and the block 3 of the substrate are described below.

The shielding casing 4 is a casing that covers the substrate block from the bottom, and this shielding casing 4 blocks the electron wave from entering the substrate 3 from the outside and prevents the introduction of noise into the signal that passes through the substrate block 3. The shielding casing 4 has the configuration of a metal conductor, for example, of tin. The spacer sheet 5 is a sheet that acts as a spacer, being enclosed between the shielding casing 4 and the stand 7, when the shielding casing 4 needs to be connected to the stand 7. The spacer sheet 5 has, for example, a configuration of double-sided adhesive tape.

The top cover 6 is a cover that covers the antenna element 2, the substrate unit 3, the shielding casing 4 and the spacer sheet 5 on top (from the top surface). The top cover 6 is made of rubber and protects the antenna element 2, the substrate unit 3, the shielding casing 4 and the gasket sheet 5 from external influences, etc. The top cover 6 includes four female threaded portions (not shown in the drawing) that correspond to the screws 8. In addition, the top cover 6 includes hooks (not shown in the drawing) for connecting the antenna element 2 and the substrate unit 3 to each other . By attaching the antenna element 2 and the substrate unit 3 using the hooks of the upper cover 6, the antenna element 2 and the substrate unit 3 can be more accurately positioned on the upper cover 6. The upper cover 6 is, for example, a square plate in the size of 44.2 × 44.2 × 12.5t mm.

The stand 7 also acts as a grounding plate and a fastener for connecting the antenna device 1 to a dashboard or the like. The stand 7 has the configuration of a metal conductor, for example, of copper, and is grounded. Four holes 7a for screws 8 are made in the stand 7. The stand 7 is, for example, in the form of a square plate 70 × 70 mm or 90 × 90 mm in size.

The screws 8 are four male screws for attaching the top cover 6 to the stand 7. The screws 8 are respectively threaded through the through holes 7a that are made in the stand 7, and respectively screwed to the female threaded portions of the top cover 6. Therefore, the top cover 6 can be accurately positioned on the stand 7. Thus, the antenna element 2 and the block 3 of the substrate are also precisely positioned on the stand 7.

As shown in FIG. 3, the coaxial cable 3a, the top cover 6 and the stand 7 (and screws 8) are open in the antenna device 1 after assembly.

Next, with reference to FIGS. 4-8, the antenna element 2 and the substrate unit 3 will be described in detail. Figure 4 shows a schematic configuration of the antenna element 2, the block 3 of the substrate and the stand 7. Figure 5 shows the planar configuration of the antenna element 2 and the block 3 of the substrate. Figure 6 shows the planar configuration of the circuit block 32 of the block 3 of the substrate. FIG. 7A shows a connecting member 32c of a circuit in a disconnected state. FIG. 7B is a drawing illustrating a connecting element 32c of a circuit in a connected state. On Fig shows a planar configuration of the block 32A distribution and phase-shifting circuits.

As shown in FIGS. 4 and 5, for the antenna element 2, the substrate unit 3, and the stand 7 in the antenna device 1, after assembly, the X axis, Y axis, and Z axis are defined. The Z axis passes through the center in the flat surfaces of the antenna element 2, block 3 substrates and supports 7. FIG. 4 shows that the antenna element 2 and the substrate unit 3 are separated from the stand 7 by a predetermined distance due to the presence of a shielding casing 4 and a spacer sheet 5 between them. This predetermined distance is, for example, 3 mm.

As shown in FIG. 4, the antenna element 2 includes a radiating electrode 21, an antenna base 22, power supply elements 23A and 23B, and a ground electrode 24. The radiating electrode 21 is a metal conductor electrode formed on an upper surface of the antenna base 22. The radiating electrode 21 is made, for example, on the base of the antenna 22 by forming a pattern using a square silver foil of size 43.1 × 34.1 mm, which is smaller than the upper surface of the base 22 of the antenna. The power supply elements 23A and 23B are electrically connected to the radiating electrode 21. The radiating electrode 21 does not have a distribution element (notch, bulge).

The base 22 of the antenna is a board made of a dielectric having a predetermined relative permittivity. The relative dielectric constant εr of the base 22 of the antenna is, for example, 6.8. The dimensions of the antenna element 2 can be reduced due to the effect of shortening the wavelength caused by the relative dielectric constant εr. The antenna base 22 is not limited to a dielectric and may be a magnetic body having a predetermined relative permittivity εr, or may be a magnetic dielectric having a predetermined relative permittivity μr. Relative magnetic permeability µr creates the effect of shortening the wavelength. The base 22 of the antenna is, for example, in the form of a square plate measuring 40 × 40 × 4t mm.

The power supply elements 23A and 23B are power supply contacts made, for example, of a metal conductor, and the radiating electrode 21 is electrically connected to the ends of the power supply elements 23A and 23B. In addition, the power supply elements 23A and 23B penetrate the ground electrode 24 and the substrate body 31 of the substrate unit 3 so that their other ends are connected to the aforementioned distribution and phase shifting unit 32a of the circuit unit 32. The power supply elements 23A and 23B are two power supply points. The power supply elements 23A and 23B may have a through-hole configuration that permeate the base of the antenna 22, and these power supply elements 23A and 23B are connected to the distribution and phase shifting unit 32a of the circuit unit 32 by soldering or a similar method.

The ground electrode 24 is an electrode made of a metal conductor, which is formed on the lower surface of the base of the antenna 22 and is grounded. For example, the ground electrode 24 is made on the basis of the antenna 22 by forming a pattern using a square silver foil of size 38 × 38 mm, which is smaller than the lower surface of the base 22 of the antenna.

The substrate block 3 includes a substrate main body 31 and a circuit block 32. The circuit block 32 includes a distribution and phase-shifting circuit block 32a and an amplifier circuit block 32b (the circuit diagram of FIGS. 4 and 5 is omitted).

The main body 31 of the substrate is an insulating substrate of type FR 4 (flame retardant type), in which the glass fiber is soaked with epoxy resin or the like. The main body 31 of the substrate is made, for example, in the form of a square plate with a size of 40 × 40 × 0.8t mm. A ground electrode (not shown in the drawings) is formed by forming a pattern on the entire upper surface (on a flat surface on the side facing the antenna element 2) of the main body 31 of the substrate. The ground electrode of the main body 31 of the substrate is made of a metal conductor, such as silver foil, and is grounded.

The circuit block 32 is a circuit block made on the lower surface (on a flat surface on the side facing the stand 7) of the main body 31 of the substrate by forming a pattern using a metal conductor, such as, for example, copper foil. Block 32a of the distribution and phase-shifting circuits is a circuit that divides the electric signal transmitted to the elements 23A and 23B of the power supply of the radiating electrode 21 from the input terminal (connecting element 321) by two and performs a phase shift.

As shown in FIG. 5, the power supply element 23A is located on a flat surface of the antenna element 2 and the substrate unit 3 in a position spaced from the Z axis to the X axis in a positive direction by the length L1. Similarly, the power supply member 23B is in a position spaced from the Z axis to the Y axis in a positive direction by a length L2. For example, L1 is 3.5 mm and L2 is 3.5 mm.

The amplifier circuit unit 32b is, for example, a low noise amplifier (LNA) and is connected to the distribution and phase-shifting circuitry unit 32a and a coaxial cable 3a. The amplifier circuit unit 32 amplifies the electrical signals that are output from the power supply elements 23A and 23B and are phase shifted by the distribution and phase shifting circuit unit 32a, and outputs these signals to the coaxial cable 3a.

Next, with reference to FIGS. 6 and 7, a circuit connection in a circuit block 32 of a substrate unit 3 is described. As shown in FIG. 6, the circuit unit 32 includes a distribution and phase shifting circuit unit 32a, an amplifier circuit unit 32b, and a circuit connecting member 32c. The connecting element 32c of the circuit is a circuit structure, for example, of a conductor in the form of a copper foil, which connects the block 32a of the distribution and phase-shifting circuits and the block 32b of the amplification circuit. In addition, the amplifier circuit unit 32b includes an output element 32b1, which is a connection terminal connected to the coaxial cable 3a.

As shown in FIG. 7A, the connection element 32c of the circuit includes connection terminals 32c1 and 32c2. The connection terminal element 32c1 is a semicircle-shaped circuit structure connected to the terminal on the side of the antenna element 2 of the amplifier circuit unit 32b. The connection terminal member 32c2 is a semicircle-shaped circuit structure connected to a terminal on the receiver side of the distribution and phase-shifting circuits 32a. That is, the connection terminals 32c1 and 32c2 form a circuit structure of approximately circular shape. However, this form is not a limiting feature of the circuit structure.

In one process, in the manufacture of the antenna device 1, the circuit block 32 of the substrate block 3 and the antenna element 2 are connected and, first, the connecting elements 32c1 and 32c2 of the connection leads are separated from each other and are in a disconnected state where they are not electrically connected as shown in FIG. 7A. When the connecting element 32c of the circuit is in a disconnected state in the antenna device 1, only the output signal of the distribution and phase-shifting circuits 32a is evaluated by the connecting output element 32c2. Similarly, when the connecting element 32c of the circuit is in a disconnected state, only the output signal of the distribution and phase-shifting circuits 32b is evaluated by the connecting output element 32c1.

Then, after the evaluations of the distribution and phase-shifting circuit unit 32a and the amplification circuit unit 32b, the distribution and phase-shifting circuit unit 32a and the amplification circuit unit 32b are soldered with solder S so that they are in a connected state where they are electrically connected, as shown in FIG. 7B.

Next, with reference to FIG. 8, a distribution unit 32a of a distribution and phase shifting circuit is described in detail. In this case, the description is given with the assumption that the antenna device 1 — in the order of the working hypothesis — is a transmitting antenna, and the electric power signal is supplied to the radiating electrode 21 through the power supply elements 23A and 23B by the distribution and phase-shifting circuitry 32a.

The distribution and phase shifting circuit unit 32a includes a distribution circuit unit C1 and a phase shifting circuit unit C2. Distribution circuit block C1 is a Wilkinson distribution circuit.

The distribution circuit block C1 includes a connecting element 321, path elements 322A and 322B and a resistor 323. The connecting block 321 is a connection electrically connected to the amplification circuit block 32b. Each of the path elements 322A and 322B represents a path structure to the resistor 323 from the connecting element 321. The resistor 323 is located between two output terminals of the path elements 322A and 322B (two output terminals of the path elements 324A and 324B).

The phase shifting circuit unit C2 includes path elements 324A and 324B and contact connecting elements 325A and 325B. The path element 324A represents the path structure to the contact connecting element 325A from the resistor 323. The path element 324A represents the path structure to the contact connecting element 325B from the resistor 323. The contact connecting element 325A is a connecting element to which the power supply element 23A is electrically connected. The contact connecting member 325B is a connecting member to which the power supply member 23B is electrically connected.

That is, in block 32a of the distribution and phase-shifting circuits, the path between the block 32b of the amplifying circuit and the power supply elements 23A and 23B is divided into a path P1, which is a path through a connecting element 321 - path element 322A - (resistor 323) - path element 324A - connecting element 325A contact, and the path P2, which is the path through the connecting element 321 - element 322B path - (resistor 323) - element 324B path - connecting element 325A contact. In this case, when the wavelength of the (emitted) radio signal is expressed by the symbol λ, the path length of the path element 322A is 1/4 λ and the path length of the path element 322B is 1/4 λ.

The contact connecting element 325A is located near the resistor 323. Therefore, the path length of the path element 324A can be considered insignificant compared to the path element 324B. The path length of the path element 324B is 1/4 λ longer than the path length of the path element 324A. This length difference of 1/4 λ corresponds to a phase difference of 90 °. That is, the phase of the signal that is introduced into the connecting element 321 and passes along the path P1, is shifted 90 ° compared with the signal that passes along the path P2.

In junction block 321, the line width is set such that the impedance is 50 ohms. The path elements 322A and 322B have an impedance of 100 Ω from the side of the connecting element 321 and have an impedance of 50 Ω from the side of the power supply elements. In particular, in the path elements 322A and 322B, the line width is set such that they have an impedance of about 71 (70.7) ohms. In path elements 324A and 324B, the line width is set such that they have an impedance of about 50 ohms. In the connecting elements 325A and 325V of the contact, the impedance is 50 Ohms. In the connecting element 321 and the path elements 322A and 322B, the line width is, for example, 0.8 mm. In path elements 324A and 324B, the line width is, for example, 1.5 mm. Furthermore, in the connecting member 321, the line width in practice is actually greater than 0.8 mm.

Resistor 323 is provided in order to improve insulation between path P1 and path P2. In addition, as shown in FIG. 8, the corner portions (parts where the paths are bent at right angles) in the paths P1 and P2 are beveled at an angle of 45 °. That is, the electric current that flows along the paths P1 and P2 flows along the inner side — along the width of the path — so that the paths are short. Consequently, the external parts — along the width of the path — are not needed in the paths P1 and P2, and mowing in the paths P1 and P2 helps prevent an increase in the capacitive component.

The electrical signal for supplying power, which is input to the connecting element 321, is divided into two and passes through the path elements 322A and 322B as paths P1 and P2, respectively, and reaches the resistor 323. The electrical signal of the path P1 after the resistor 323 passes through the path element 324A and inserted into the contact connecting element 325A. The electrical signal of the path P2 after the resistor 323 passes through the path element 324B and is input to the contact connecting element 325B. When each signal has reached the connecting elements 324A, 325B of the contacts, the phase of the electrical signal of the path P2 is delayed by 90 ° compared with the electrical signal of the path P1. Therefore, a circularly polarized wave is emitted from the radiating electrode 21.

In this case, the characteristic of transmitting the antenna (input of an electrical signal to the antenna) is equivalent to the characteristic of receiving the antenna (issuing an electrical signal from the antenna). Therefore, the distribution and phase shifting circuit unit 32a can be applied to the GPS and GLONASS antenna device 1, which is intended solely for reception.

Next, with reference to Figs. 9-13, the antenna characteristic of the antenna device 1 will be described. Fig. 9 shows the dependence of S11 on the frequency of the antenna device 1. Fig. 10 shows a pie chart of the impedances of the antenna device 1. Fig. 11 shows dependence of the ellipticity coefficient on the frequency of the antenna device 1. FIG. 12 shows the dependence of the gain — towards the zenith — on the frequency of the antenna device 1. FIG. 13 is a pie chart illustrating the radiation pattern of the antenna device 1.

Various types of characteristics of the antenna device 1 are simulated. First, as shown in Fig. 9, the dependence of the S parameter S11 on the frequency of the antenna device 1 is obtained. The symbols m1, m2 and m3 in Fig. 9 denote the points of specific frequencies on the characteristic curve (in this case , the curve of the line S11). The m1 point is set as 1.5750 GHz, and this is the average frequency in the GPS frequency range. The m2 point is set as 1.5900 GHz, and this is the frequency in the range between the m1 and m3 points. The m3 point is 1.6050 GHz, and this is the average frequency in the GLONASS frequency range. These frequency values according to points m1, m2 and m3 are the same in FIGS. 10-12.

From the result of FIG. 9, it can be seen that S11 (dV) is substantially lower than the value of -10 dB as a reference value for determining a satisfactory or unsatisfactory overall characteristic at each of the points m1, m2 and m3. Therefore, the resonance in the antenna device 1 is acceptable in a wide frequency range corresponding to GPS and GLONASS.

Further, as shown in FIG. 10, a pie chart of the impedances of the antenna device 1 is obtained. In FIG. 10, 1.00 in the center of the circle corresponds to 50 Ohms. In addition, the circle that connects 0.50 and 2.00 and in which 1.00 is set as the center corresponds to -10 dB according to S11. From the result of FIG. 10, it can be seen that the points m1, m2 and m3 are collected on a -10 dB circle according to S11. Therefore, the impedance in the antenna device 1 is matched at a level of 50 ohms in a wide frequency range corresponding to GPS and GLONASS.

Further, as shown in FIG. 11, the dependence of the ellipticity coefficient (dB) on the frequency of the antenna device 1 is obtained. The lower the ellipticity coefficient in FIG. 11, the closer to the ideal wave of circular polarization. From the result of FIG. 11, it can be seen that the ellipticity coefficient (dB) is significantly lower than 3 dB as a reference value for determining a satisfactory or unsatisfactory overall characteristic at each of the points m1, m2 and m3. Therefore, a low and preferred ellipticity coefficient in the antenna device 1 can be obtained in a wide frequency range corresponding to GPS and GLONASS. When the ellipticity coefficient is low, the signal becomes an almost perfect wave of circular polarization. Therefore, the sensitivity can be constant (gain can be constant) regardless of the direction of the antenna device 1.

Further, as shown in FIG. 12, the dependence of the gain in decibels relative to the isotropic antenna (dBi) - towards the zenith - on the frequency of the antenna device 1 is obtained. The direction to the zenith is the positive direction along the Z axis shown in Figs. 4 and 5. 12, the solid line indicates the gain (dBi) towards the zenith in circular polarization with clockwise rotation, and the dashed line indicates the gain (dBi) towards the zenith in circular polarization with counterclockwise rotation. Points ml, m2, and m3 in FIG. 12 are points on a gain curve illustrating gain toward the zenith in circular polarization with clockwise rotation according to the same frequencies as above. Points m4, m5 and m6 are points on the gain curve illustrating gain towards the zenith in circular polarization with counterclockwise rotation according to the same frequencies as at points m1, m2 and m3, respectively.

From the result shown in Fig. 12, it is seen that at points m1, m2 and m3 a large gain (dBi) is obtained towards the zenith in circular polarization with clockwise rotation, and also that at points m4, m5 and m6 gain (dBi) towards the zenith in circular polarization with counterclockwise rotation. Therefore, a large gain (dBi) towards the zenith is obtained in the antenna device 1 in a wide frequency range corresponding to GPS and GLONASS, which are communication standards for polarization with clockwise rotation, designed to communicate with the satellite towards the zenith.

Further, as shown in FIG. 13, the radiation pattern characteristic of the antenna device 1 is obtained. The radiation pattern characteristic shown in FIG. 13 is the gain (dBi) at a frequency of 1.59 GHz on a flat surface in which the Y and Z axes lie (i.e., in the YZ plane) shown in FIGS. 4 and 5. In FIG. 13, the solid line indicates the gain (dBi) in circular polarization with clockwise rotation, and the dashed line indicates the gain (dBi) in circular polarization counterclockwise rotation. In addition, point m7 in FIG. 13 is a point on the Z axis on the gain curve for circular polarization with clockwise rotation.

From the result shown in FIG. 13, it follows that by setting the value to 5.6278 dBi, which is the gain at m7 as an apex, a large gain is obtained with circular polarization with clockwise rotation at the end of the hemisphere, where Z is a positive value, and the gain is kept small during circular polarization with clockwise rotation at the end of the hemisphere, where Z is a negative value. In addition, the gain is kept small during circular polarization with counterclockwise rotation at the end of the hemisphere, where Z is a positive value, and a large gain during circular polarization with counterclockwise rotation at the end of the hemisphere, where Z is a negative value, is obtained. Therefore, a large gain (dBi) is obtained at the end of the hemisphere towards the zenith in the antenna device 1 at a frequency (in the frequency range corresponding to GPS and GLONASS), enclosed between the GPS and GLONASS frequencies, which are communication standards for polarization with clockwise rotation, designed to communicate with the satellite towards the zenith.

As described above, in accordance with an embodiment, the antenna device 1 includes antenna elements 2 and a substrate unit 3. The antenna elements 2 include an antenna base 22, a radiating electrode 21 provided on the upper surface of the antenna base 22, power supply elements 23A and 23B that are connected to the radiating electrode 21 and which pierce the antenna base 22 and the ground electrode 24. The substrate unit 3 includes the distribution unit C1 and the phase shifting unit C2. The distribution circuit unit C1 includes a connecting element 321 where the input terminal of the amplification circuit unit 32b is connected, path elements 322A and 322B having a path length of 1/4 λ that are connected to the connecting element 321, and a resistor 323 connected to the elements 322A and 322B tracts. The phase shifting unit C2 includes a path element 324A, which is a path to a power supply element 23A from the resistor 323, where an input terminal is provided near the power supply element 23A, and a path element 324B having a path length that is longer than the path element 324A , by 1/4 λ, and representing a path to the power supply element 23B from the resistor 323. The distribution circuit block C1 and the phase shifting block C2 are made on the same surface on the substrate block 3, and the phase shifting block C2 is located inside the element 322A and 322B paths distribution circuit block C1.

Therefore, in an antenna device 1 with two power supply points and one radiating electrode, a range having a satisfactory ellipticity coefficient can be a wide range used for GPS and GLONASS, and the isolation between paths P1 and P2 from the input terminal to elements 23A and 23B can be improved. power supply (two power supply points). In addition, it is possible to reduce the size of the block 32a of the distribution and phase-shifting circuits connected to the antenna element 2. By balancing the impedance in the paths P1 and P2, it is easy to match the impedance in a wide range. By reducing the size of the area of the block 32a of the distribution and phase-shifting circuits, it is also possible to reduce the size of the block 3 of the substrate and the dimensions of the antenna device 1 can be reduced.

Moreover, since the path element 324A is connected to the power supply element 23A, and its output terminal is provided near the power supply element 23A, an optional path in the path elements 324A and 324B can be excluded. Therefore, the loss of introducing such an optional path can be eliminated, and the size of the block 32a of the distribution and phase shifting circuits can be further reduced.

In addition, the amplifier circuit unit 32b is formed on the same surface as the distribution circuit unit C1 and the phase shifting unit C2 of the substrate unit 3. Therefore, it is possible to reduce the number of components and make the antenna device 1 thinner, as well as further reduce the size of the antenna device 1. In particular, since the area of the distribution and phase-shifting circuit unit 32a is small, the amplification circuit unit 32b can be easily formed in a space where there is no distribution unit 32a and phase shifting circuits, on the lower surface of the block 3 of the substrate.

In this case, the foregoing description regarding an embodiment is an example of an antenna device in accordance with this invention, but the present invention is not limited to this example.

In an embodiment, GPS and GLONASS frequencies that are close to each other but different from each other are received as frequencies applicable to the antenna device 1. However, the frequencies are not limited to such frequencies. The antenna device 1 is applicable for communication according to many different frequency ranges or a single frequency range as a wide-range antenna device.

In addition, in the above embodiment, the antenna device 1 is described as a GPS and GLONASS antenna device, intended solely for reception. However, the present invention is not limited to such an antenna device. Antenna device 1 is applicable to an antenna for transmission or for transmission and reception.

In addition to the foregoing, it should be noted that the configuration described in detail and the operation of the antenna device in detail in the embodiment can be arbitrarily changed within the scope of the claims of the present invention.

All materials of application No. 2011-146981, filed July 1, 2011, including the description, claims, drawings and abstract, in their entirety are incorporated herein by reference.

EXPLANATION OF THE POSITIONS OF THE DRAWINGS

1 Antenna device

2 Antenna element

21 Radiating electrode

22 Antenna base

23A, 23B Power Supply Elements

24 Ground electrode

3 Substrate Block

31 The main body of the substrate

32 circuit block

32a Distribution and phase shifting unit

C1 Distribution block

C2 Phase Shift Block

321 Connecting element

322A, 322B, 324A, 324B Path Elements

323 Resistor

325A, 325B Contact Connector

32b Amplifier Block

32b1 Output Element

32c Connecting circuit element

32c1, 32c2 Elements of the connection terminals

P1, P2 Tracts

3a coaxial cable

4 shielding

5 Gasket sheet

6 top cover

7 Stand

7a Through hole

8 screw.

Claims (2)

1. An antenna device comprising:
antenna element and
the substrate unit, which is provided on the lower surface of the antenna element, and the antenna element contains:
an antenna base made of a dielectric, a magnetic body, or a magnetic dielectric;
a radiating electrode, which is provided on the upper surface of the base of the antenna;
a first power supply element and a second power supply element, which are connected to the radiating electrode and which penetrate the base of the antenna; and
a ground electrode, which is provided on the lower surface of the base of the antenna, and the substrate unit contains:
a distribution block unit that includes a connecting element that is connected to an input input terminal for supplying power, a first path element and a second path element having a path length of 1/4 λ shared in the connecting element, and a resistor that is connected to the output terminals of the first path element and the second element of the path; and
a phase-shifting circuit unit that contains a third path element, which is a path to a first resistor power supply element, where an input terminal is provided near a first power supply element, and a fourth path element, which is a path to a second resistor power supply element, having a path length greater than the third path element by 1/4 λ,
wherein the distribution circuit block and the phase-shifting circuit block are made on the same surface of the substrate block, and
the phase-shifting circuit unit is located inside the first path element and the second path element of the distribution circuit block. 2. The antenna device according to claim 1, wherein the substrate unit comprises an amplifier circuit unit that is formed on the same surface as the distribution circuit unit and the phase-shifting circuit unit, and which amplifies a signal output from the connecting element of the distribution circuit unit.

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