JP2004274223A - Antenna and electronic apparatus using the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To miniaturize an antenna and reduce the cost thereof along with an electronic apparatus using the antenna. <P>SOLUTION: The antenna comprises an antenna electrode 18 made of a conductive material, a signal electrode 20 electrically coupled with the antenna electrode 18, and a ground electrode 19 provided at an opposite part of the antenna electrode 18. The antenna electrode 18 comprises one or a plurality of reactance elements 21, 22 on one or both axes X, Y perpendicular or approximately perpendicular to each other, and the signal electrode 20 is formed on a body approximately 45° to the intersection of the axes X, Y. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an antenna and an electronic device using the same.
[0002]
[Prior art]
2. Description of the Related Art In a conventional electronic device, for example, a personal computer, various communication services can be performed using the personal computer by inserting a communication module into a throttle portion. An antenna is provided inside the communication module to enable such communication (for example, see Patent Document 1).
[0003]
[Patent Document 1]
JP-A-9-98015
[0004]
[Problems to be solved by the invention]
The problem with the above conventional example is that the antenna becomes large. That is, in recent communication systems, the operating frequency is widened, and in order to cope with such a communication system, the antenna must be widened. When trying to form such a broadband antenna, it is necessary to make the volume of the antenna larger than the general logic of the antenna.
[0005]
In addition, when communication is actually performed indoors or the like, signals are reflected, attenuated, and diffracted by ceilings, walls, and floors, so that areas having high and low electric field strengths occur in the indoor space. The distribution of the density of the electric field intensity changes when the frequency used is different, and changes with time when a moving object (for example, a person) exists in the indoor space. In such a radio wave environment, a diversity antenna configured by preparing a plurality of antennas is used to maintain good communication quality. However, in order to form a diversity antenna, it is necessary to prepare a plurality of antennas, which increases the mounting area and antenna cost of the antenna.
[0006]
Therefore, an object of the present invention is to reduce the size of an antenna and to realize a diversity antenna at a small size and at low cost.
[0007]
[Means for Solving the Problems]
In order to achieve the above object, the invention according to claim 1 of the present invention provides an antenna electrode made of a conductive material, a signal electrode electrically coupled to the antenna electrode, and a portion facing the antenna electrode. A ground electrode provided, the antenna electrode includes one or a plurality of reactance elements on one or both axes of an X axis and a Y axis orthogonal or substantially orthogonal to the X axis, and the signal electrode has an X axis and a Y axis. An antenna formed on a straight line having an angle of approximately 45 degrees from the intersection of the axes. The antenna electrode has an X-axis and a Y-axis. It will resonate. This antenna can form a wide-band antenna by bringing the resonance frequencies of both the X axis and the Y axis close to each other, so that a low-profile antenna can be realized, and the X axis and the Y axis can be realized. Since the resonance frequency of each axis can be lowered by the reactance element provided above, the antenna electrode can be designed to be small, and the antenna can be downsized. Also, by changing the reactance element values connected on the X axis and the Y axis, the resonance frequency of each axis can be finely adjusted without changing the antenna electrode shape, and the input impedance of the antenna can be adjusted. Matching can be easily achieved.
[0008]
According to a second aspect of the present invention, in the antenna according to the first aspect, an end of the reactance element not electrically connected to the antenna electrode is connected to a ground electrode, and the reactance element is a capacitor. In the case of, the resonance frequency on the axis can be lowered, and when the reactance element is an inductor, the resonance frequency can be raised, so that the impedance characteristics of the antenna can be set freely without changing the shape of the antenna electrode Can be.
[0009]
According to a third aspect of the present invention, there is provided the antenna according to the first aspect, wherein a reactance element is provided at a position substantially point-symmetric with respect to the intersection of the X-axis and the Y-axis of the antenna electrode. It becomes easy to form radiation characteristics that are axisymmetric with respect to the axis.
[0010]
According to a fourth aspect of the present invention, there is provided the antenna according to the first aspect, wherein a switch is provided in the vicinity of the reactance element together with the reactance element, and a resonance frequency and a radiation characteristic are changed by turning on and off the switch. Since one antenna can have two or more functions, a small and low-cost diversity antenna can be realized.
[0011]
According to a fifth aspect of the present invention, in the antenna according to the fourth aspect, the reactance element and / or the switch are mounted on a high-frequency circuit board, and the high-frequency operation is performed without changing the electrode shape of the antenna. By changing the value of the reactance element mounted on the circuit board, the input impedance and radiation pattern of the antenna can be adjusted, making it very easy to adjust the antenna characteristics when the antenna is mounted on various housings Can be provided.
[0012]
The invention according to claim 6 of the present invention is the antenna according to claim 1, wherein the second signal electrode is provided at a position substantially at the intersection of the X axis and the Y axis of the antenna electrode. The two secured signal electrodes can be embodied in one antenna, and the antenna can be reduced in size.
[0013]
According to a seventh aspect of the present invention, there is provided the antenna according to the first aspect, wherein the electrical length of the antenna electrode on the X axis and the Y axis is substantially a half wavelength, whereby two independent resonances are provided. The mode can be generated for one antenna, and a wider band and a lower profile of the antenna can be achieved.
[0014]
According to an eighth aspect of the present invention, in the antenna according to the fourth aspect, a reactance element and a switch are provided on both the X axis and the Y axis of the antenna electrode, and the switch on the X axis is turned on. When the switch on the Y-axis is OFF, the antenna on the X-axis is OFF when the switch on the Y-axis is ON. The resonance on the X-axis when the switch on the X-axis is OFF The frequency is A, the resonance frequency on the X axis when the X axis switch is ON is B, the resonance frequency on the Y axis is Y when the Y axis switch is OFF, and Y when the Y axis switch is ON. Assuming that the resonance frequency on the axis is D, the resonance frequencies A and B radiate with the polarization parallel to the X axis, and the resonance frequencies C and D radiate the polarization with the polarization parallel to the Y axis. Rear so that frequencies B and C have the same frequency. Wardrobe element values, adjusted for the antenna electrode shape, etc., in this frequency will be switched between the polarization generated by the switch of the X-axis and Y-axis, it can be used as a polarization diversity antenna which is switched in time. When the frequencies A, B, C, and D are designed as separate frequencies, they can be used as frequency diversity antennas.
[0015]
According to a ninth aspect of the present invention, in the antenna according to the eighth aspect, when the switch on the X axis of the antenna electrode is ON and the electrical length on the X axis is ON, the switch on the Y axis is ON. And the electrical length on the Y-axis is equal, and the electrical length on the X-axis when the switch on the X-axis is OFF is equal to the electrical length on the Y-axis when the switch on the Y-axis is OFF. When the resonance frequency when the switch is ON is A and the resonance frequency when the switch is OFF is B, the switch on the X-axis is ON and the switch on the Y-axis is OFF. At the resonance frequency A, emission can be performed with a polarization parallel to the X axis, and at the resonance frequency B, emission can be performed with a polarization parallel to the Y axis, and the switch on the X axis is OFF and the switch on the Y axis is ON. The state β is parallel to the Y axis at the resonance frequency A. And at the resonance frequency B, it is possible to radiate with a polarization parallel to the X-axis. That is, by changing the state of the switch, the polarization directions at the resonance frequencies A and B can be changed by 90 degrees, and a polarization diversity antenna that can be switched over in time can be realized. Furthermore, by designing the resonance frequencies A and B close to each other, a wideband characteristic is realized, and by switching the polarization direction in the band over time, it is possible to cope with a time-varying indoor fading environment. Can be realized.
[0016]
According to a tenth aspect of the present invention, in the antenna according to the fourth aspect, the reactance element and the switch are provided on both the X axis and the Y axis of the antenna electrode, and the switch on the X axis is provided. This is an antenna in which the electrical length on the X axis when ON is different from the electrical length on the Y axis when the switch on the Y axis is ON. Both the X axis and the Y axis switches are turned ON. Thus, the antenna electrodes can be reduced in size by the reactance elements on each axis, and the resonance frequencies of the resonance currents on the X-axis and the Y-axis when both switches are ON are close to each other, so that the antenna can be reduced in size. A broadband antenna can be realized. Further, by turning off the switches on the X-axis and / or the Y-axis, the usable frequency can be switched over time, and it can be used for a frequency diversity antenna or the like.
[0017]
According to an eleventh aspect of the present invention, in the antenna according to the fourth aspect, the reactance element and the switch are provided on both the X axis and the Y axis of the antenna electrode, and the switch on the X axis is provided. Since the electrical length on the X-axis when OFF is different from the electrical length on the Y-axis when the switch on the Y-axis is OFF, the reactance element does not function when both switches are OFF. Since there is no loss there, a high radiation gain can be realized. Further, by making the resonance frequencies of the resonance currents on the X-axis and the Y-axis close to each other when the switch is OFF, a wideband antenna can be realized, and the switches on the X-axis and / or the Y-axis are turned OFF. Can be used to switch the frequency that can be used in time, and can be used for a frequency diversity antenna or the like.
[0018]
According to a twelfth aspect of the present invention, in the antenna according to the tenth or eleventh aspect, when the switch on the X axis of the antenna electrode is OFF and the switch on the Y axis is ON, the clockwise rotation is performed. Operates as a circularly polarized antenna or left-handed circularly polarized antenna, and operates as a circularly polarized antenna in the opposite turning direction when the switch on the Y axis is OFF and the switch on the X axis is ON. Antenna, and the direction of rotation of the circularly polarized wave can be switched depending on the state of the switches on the X axis and the Y axis. It is possible to realize a circularly polarized diversity antenna that is effective when the phase difference changes with time. Moreover, a wideband antenna is realized by making the resonance frequencies of the resonance currents on the X axis and the Y axis close when both the switches on the X axis and the Y axis are OFF. A polarization diversity antenna that operates as a linearly polarized antenna and switches as a circularly polarized antenna by turning on one of the X-axis and the Y-axis can be realized.
[0019]
According to a thirteenth aspect of the present invention, in the antenna according to the tenth or eleventh aspect, when both the switches on the X-axis and the Y-axis of the antenna electrode are ON, the antenna is a broadband antenna or a two-band antenna. An antenna configured to operate. When both switches are ON, the reactance elements on the X axis and the Y axis function, so that the antenna electrode can be reduced in size. The resonance frequency at which linear polarization occurs can be changed depending on the state of the switch on the axis, and an effective frequency diversity antenna in a frequency selective fading environment can be realized.
[0020]
According to a fourteenth aspect of the present invention, in the antenna according to the fourth aspect, the antenna electrode which operates alone as a circularly polarized antenna by adjusting the lengths of the X axis and the Y axis includes: An antenna in which the reactance element and the switch are provided on one axis of the Y axis, and the value of the reactance element is selected such that the antenna electrode operates as a circularly polarized antenna even when the switch is ON. , OFF, the direction of rotation of the circularly polarized wave can be switched, so that a circularly polarized diversity antenna capable of temporally switching the direction of rotation can be realized at a small size and at low cost.
[0021]
According to a fifteenth aspect of the present invention, in the antenna according to the fourth aspect, an antenna electrode which operates alone as a circularly polarized antenna by adjusting the lengths of the X-axis and the Y-axis is provided. An antenna in which a capacitor element and a switch are provided on the shorter axis of the electrical length when the Y axis is compared, and the capacitor element value is selected so that the antenna electrode operates as a circularly polarized antenna even when the switch is ON. For example, if a switch and a capacitor element are provided in a series configuration between an antenna electrode and a ground electrode at an arbitrary position on the X-axis, and when the switch is OFF, the resonance frequency A of the X-axis resonance current Is higher than the resonance frequency B of the resonance current on the Y-axis. Here, at a frequency C between the resonance frequencies A and B, the phase of the X-axis resonance current is ahead of the phase of the Y-axis resonance current by 90 degrees. Next, the resonance frequency D on the X axis when the switch is turned on is set lower than the resonance frequency B, and the phase of the resonance current on the X axis is Y at a frequency E between the resonance frequency B and the resonance frequency D. By setting the element value of the capacitor so as to be delayed by 90 degrees from the phase of the resonance current on the axis, the turning direction of the circularly polarized wave can be temporally reversed by turning on and off the switch. It is possible to realize a circularly polarized diversity antenna that can be switched to any other frequency.
[0022]
According to a sixteenth aspect of the present invention, in the antenna according to the fourth aspect, an antenna electrode that operates alone as a circularly polarized antenna by adjusting the lengths of the X axis and the Y axis, and An antenna in which an inductor element and a switch are provided on the axis having a longer electrical length when the Y axis is compared, and the inductor element value is selected so that the antenna electrode operates as a circularly polarized antenna even when the switch is ON. For example, if a switch and an inductor element are provided in a series configuration between an antenna electrode and a ground electrode at an arbitrary position on the X axis, and the switch is OFF, the resonance frequency A of the X axis resonance current is Is lower than the resonance frequency B of the resonance current on the Y axis. Here, it is assumed that the phase of the X-axis resonance current is ahead of the phase of the Y-axis resonance current by 90 degrees at a frequency C intermediate between the resonance frequencies A and B. Next, the resonance frequency D on the X-axis when the switch is turned on is set higher than the resonance frequency B, and the phase of the resonance current on the X-axis is Y at a frequency E between the resonance frequency B and the resonance frequency D. By setting the element value of the inductor so as to be delayed by 90 degrees from the phase of the resonance current on the axis, the turning direction of the circularly polarized wave can be temporally reversed by turning on and off the switch. It is possible to realize a circularly polarized diversity antenna that can be switched to any other frequency.
[0023]
According to a seventeenth aspect of the present invention, in the antenna according to the fourth aspect, a first reactance element and a first switch are provided at a first point on the X axis of the antenna electrode, and A second point has a second reactance element and a second switch, a third point on the Y axis has a third reactance element and a third switch, and a fourth point on the Y axis has a fourth point. 4 reactance elements and a fourth switch, the electrical length on the X axis when the second switch and the fourth switch are OFF and the first switch is ON, the second switch and the fourth switch Is OFF and the third switch is ON, the electrical lengths on the Y axis are equal, and when the first switch and the second switch are ON and the third switch and the fourth switch are OFF, the right-handed circularly polarized Works with wave or left-hand circular polarization When the first switch and the second switch are OFF and the third switch and the fourth switch are ON, the antenna is configured to operate as a circularly polarized antenna in the opposite turning direction. When the first switch, the third switch, and the fourth switch are OFF and the first switch is ON, the resonance frequency α on the X-axis and the resonance frequency β on the Y-axis are close to each other, so that broadband characteristics can be realized as a whole. By selecting the first reactance element value at the same time as the second reactance element value and selecting the same value as the first reactance element value, the second switch and the fourth switch are turned off. Switching the polarization direction between the resonance frequencies α and β by temporally switching so that only one of the first switch and the third switch is turned on. And a wideband diversity antenna capable of switching the polarization plane in time can be realized. Further, for example, in a state where the third switch and the fourth switch are OFF and the first switch and the second switch are ON, the resonance frequency of the resonance current on the X axis and the resonance frequency of the resonance current on the Y axis The second reactance value is set so that the phase of the resonance current on the X-axis at the center frequency of the first axis advances 90 degrees from the phase of the resonance current on the Y-axis, and the first switch and the second switch are turned off and When the third switch and the fourth switch are ON, the phase of the resonance current on the X axis at the center frequency between the resonance frequency of the resonance current on the X axis and the resonance frequency of the resonance current on the Y axis is on the Y axis. By setting the fourth reactance value so as to delay by 90 degrees from the phase of the resonance current, the clockwise rotation is performed when the first switch and the second switch are ON and the third switch and the fourth switch are OFF. When a polarized wave or a left-handed circularly polarized wave is radiated and the first switch and the second switch are OFF and the third switch and the fourth switch are ON, an antenna having a turning direction opposite to the turning direction can be realized. Thus, it is possible to realize a circularly polarized diversity antenna capable of switching the turning direction with time. In other words, a single antenna can realize a broadband antenna whose polarization direction can be temporally switched according to the state of each switch, and a circular polarization diversity antenna that can temporally switch the circular polarization turning direction.
[0024]
According to an eighteenth aspect of the present invention, in the antenna according to the fourth aspect, a first reactance element and a first switch are provided at a first point on the X axis of the antenna electrode; A second point has a second reactance element and a second switch, a third point on the Y axis has a third reactance element and a third switch, and a fourth point on the Y axis has a fourth point. 4 reactance elements and a fourth switch, the electrical length on the X axis when the second switch and the fourth switch are OFF and the first switch is ON, the second switch and the fourth switch Is OFF and the third switch is ON, the electrical lengths on the Y axis are equal, and when the first switch and the fourth switch are ON and the second switch and the third switch are OFF, the right-handed circularly polarized Works with wave or left-hand circular polarization When the first switch and the fourth switch are OFF and the second switch and the third switch are ON, the antenna is configured to operate as a circularly polarized antenna in the opposite turning direction. When the first switch, the third switch, and the fourth switch are OFF and the first switch is ON, the resonance frequency α on the X-axis and the resonance frequency β on the Y-axis are close to each other, so that broadband characteristics can be realized as a whole. The first reactance element value is selected at the same time, the second reactance element value is selected to be the same value as the first reactance element value, and the second switch and the third switch are turned off and the first reactance element value is turned off. When the switch and the fourth switch are ON, the position of the resonance current on the X axis at the center frequency between the resonance frequency of the resonance current on the X axis and the resonance frequency of the resonance current on the Y axis Sets the second reactance value so that the first switch and the third switch are turned off and the second switch and the third switch are turned on by setting the second reactance value so as to advance by 90 degrees from the phase of the resonance current on the Y axis. The fourth phase is such that the phase of the resonance current on the X axis at the center frequency of the resonance frequency of the resonance current on the X axis and the resonance frequency of the resonance current on the Y axis is delayed by 90 degrees from the phase of the resonance current on the Y axis. When all the switches are OFF when the reactance values are set to, the antenna functions as an antenna having two orthogonal polarizations (polarizations parallel to each of the X axis and the Y axis) in one frequency band, When the second switch and the fourth switch are off and one of the first switch and the third switch is turned on while being temporally switched, the wideband characteristic is obtained. And functions as a diversity antenna whose polarization direction can be temporally switched between two bands constituting the band. The first switch and the fourth switch are turned on and the second switch is turned on. When the first switch and the third switch are OFF, or when the first switch and the fourth switch are OFF and the second switch and the third switch are ON, the turning directions are different from each other. It can function as a wave antenna, and can realize antennas having various functions depending on the state of each switch, and can be a small-sized and low-cost antenna. When functioning as a circularly polarized antenna, the number of functioning reactance elements is one on each of the X axis and the Y axis, and the functioning reactance elements do not concentrate on either axis. The resonance current values generated on the two axes can be made substantially the same, and therefore, a circularly polarized wave characteristic with a small axial ratio can be realized.
[0025]
According to a nineteenth aspect of the present invention, in the antenna according to the first aspect, a first reactance element and a first switch are provided at a first point on the X axis of the antenna electrode, A second point has a second reactance element and a second switch, a third point on the Y axis has a third reactance element and a third switch, and a fourth point on the Y axis has a fourth point. 4 reactance elements and a fourth switch, the electrical length on the X axis when the second switch and the fourth switch are OFF and the first switch is ON, the second switch and the fourth switch Are OFF, the electrical lengths on the Y axis when the third switch is ON are equal, the first switch and the second switch are ON, the third switch and the fourth switch are OFF, and the first Switch and second switch Switch is OFF and the third switch and the fourth switch are both ON, the antenna is configured to operate in only one of the right-handed circular polarization and the left-handed circular polarization. When the first switch and the second switch are ON and the third switch and the fourth switch are OFF, and when the first switch and the second switch are OFF and the third switch and the fourth switch are The second reactance element value and the fourth reactance element value are set such that the phase of the resonance current on the Y-axis advances or delays by 90 degrees with respect to the phase of the resonance current on the X-axis in both states when ON. This makes it possible to shift the resonance frequency of the circularly polarized antennas having the same turning direction, thereby realizing a circularly polarized diversity antenna capable of temporally changing the resonance frequency. Theft is possible. Of course, it can also be used as a diversity antenna that can switch the polarization direction temporally depending on the state of the switch.
[0026]
According to a twentieth aspect of the present invention, in the antenna according to the fourth aspect, a first reactance element and a first switch are provided at a first point on the X axis of the antenna electrode, A second point has a second reactance element and a second switch, a third point on the Y axis has a third reactance element and a third switch, and a fourth point on the Y axis has a fourth point. 4 reactance elements and a fourth switch, the electrical length on the X axis when the second switch and the fourth switch are OFF and the first switch is ON, the second switch and the fourth switch Are OFF, the electrical lengths on the Y-axis when the third switch is ON are equal, the first switch and the fourth switch are ON, the second switch and the third switch are OFF, and the first Switch and fourth switch Switch is OFF and both the second switch and the third switch are ON, the antenna is configured to operate in only one of the right-handed circular polarization and the left-handed circular polarization. When the first switch and the fourth switch are ON and the second switch and the third switch are OFF, and when the first switch and the fourth switch are OFF and the second switch and the third switch are The second reactance element value and the fourth reactance element value are set such that the phase of the resonance current on the Y-axis advances or delays by 90 degrees with respect to the phase of the resonance current on the X-axis in both states when ON. This makes it possible to shift the resonance frequency of the circularly polarized antennas having the same turning direction, thereby realizing a circularly polarized diversity antenna capable of temporally changing the resonance frequency. Theft is possible. In addition, as a matter of course, it can also be used as a diversity antenna that can switch the polarization direction temporally according to the state of the switch. With this configuration, the number of reactance elements that function at an arbitrary time is one on the X axis and one on the Y axis, and the reactance elements that function on either axis are not concentrated. The resonance current values generated on the three axes can be made substantially the same, and therefore, a circularly polarized wave characteristic with a small axial ratio can be realized.
[0027]
According to a twenty-first aspect of the present invention, there is provided an electronic apparatus in which at least one of a transmitting circuit and a receiving circuit is electrically coupled to the antenna according to the first aspect, wherein the antenna and the diversity antenna are small in size and low in height. Therefore, a small and easily portable electronic device can be realized, and since the antenna can be manufactured at low cost, the electronic device can be manufactured at low cost.
[0028]
BEST MODE FOR CARRYING OUT THE INVENTION
An embodiment of the present invention will be described below with reference to the drawings.
[0029]
In FIG. 1, reference numeral 1 denotes a notebook computer, and the notebook computer 1 includes an input unit 2 and a display unit 3. A slot 4 is provided on the side of the input unit 2, and a communication module 5 is inserted into the slot 4.
[0030]
As shown in FIG. 2, the communication module 5 is provided with a circuit board 7 in a plate-shaped main body case 6, and various electronic components 8 are mounted on the circuit board 7. On the right side of the circuit board 7 in FIG. 2, there is provided a connector 9 which is inserted into the slot 4 to obtain electrical connection. An antenna 10 is mounted on the left side of the circuit board 7 in FIG.
[0031]
That is, when the main body case 6 shown in FIG. 2 is inserted into the slot 4 shown in FIG. 1, only the antenna 10 protrudes from the slot 4 to the outside, so that transmission and reception of signals using the antenna 10 can be performed. . Now, such a state is also shown in FIG. In FIG. 3, the antenna 10 is connected to a first switch 11, a contact 11a of the first switch 11 is connected to a filter 14, a transmission circuit 12 via an amplifier 13, and a contact 11b is connected to a filter 16, The receiving circuit 15 is connected via the amplifier 17. Thereby, communication with another electronic device can be performed via the antenna 10.
[0032]
FIG. 4 shows an example of the antenna 10. As shown in FIG. 4, an antenna electrode 18 made of a flat conductive material is disposed above and opposed to a ground electrode 19 also made of a flat conductive material. A first reactance element 21 is electrically connected between the antenna electrode 18 and the ground electrode 19 at substantially the end of the antenna electrode 18 on the X axis. Second reactance element 22 is electrically connected between antenna electrode 18 and ground electrode 19. Further, at the intersection of the X axis and the Y axis, the signal electrode 20 is disposed at the end of the antenna electrode 18 on the axis having an angle of 45 degrees with respect to both axes, and the signal electrode 20 is electrically connected to the antenna electrode 18 and the ground electrode 19. It is connected.
[0033]
By arranging the signal electrode 20 at this position, high-frequency signal power can be supplied on the X-axis and the Y-axis. For example, the shape of the antenna electrode 18 and the connection position of the reactance elements 21 and 22 and the element value are determined by the antenna When the electrode 18 is point-symmetric with respect to the intersection of the X axis and the Y axis, and the electric lengths on the X axis and the Y axis are equal, the power supplied from the signal electrode 20 is equally distributed on the X axis and the Y axis. Supplied.
[0034]
One of the features of this antenna is that the electric lengths of the X axis and the Y axis can be appropriately varied by adjusting the shape of the antenna electrode 18 and the element values and positions of the first reactance element 21 and the second reactance element 22. This makes it possible to realize broadband characteristics.
[0035]
FIG. 5 shows an example of the VSWR characteristic of the present antenna. The characteristics shown here are obtained when the resonance frequency of the resonance current on the X-axis is set to be higher than the resonance frequency of the resonance current on the Y-axis. The setting of the resonance frequency of the resonance current on the X-axis and the Y-axis is performed by setting the electrical length on each axis in FIG. 4 to half the wavelength of the desired resonance frequency. By appropriately bringing the resonance frequencies on the X-axis and the Y-axis close to each other, it is possible to widen the bandwidth of VSWR <3.
[0036]
FIG. 6 shows the effect on the antenna characteristics of the reactance elements 21 and 22 arranged on the X axis and the Y axis. FIG. 6A shows the direction of the VSWR characteristic transition of the antenna when a capacitor is used as a reactance element. When a capacitor is used, it is equivalent to an increase in the capacitance between the antenna electrode 18 and the ground electrode 19, so that the resonance frequency of the antenna can be reduced as the element value of the capacitor increases. That is, by adding a capacitance to the antenna electrode 18, the antenna size required to obtain the same resonance frequency can be reduced. With respect to the position where the capacitor is disposed, the effect of lowering the frequency increases as the position is closer to the end of the antenna electrode 18. This is because the electric field intensity generated between the antenna electrode 18 and the ground electrode 19 becomes higher as it is closer to the end of the antenna electrode.
[0037]
FIG. 6B shows a change in VSWR characteristic of the antenna when an inductor is used as a reactance element. When an inductor is connected between the antenna electrode 18 and the ground electrode 19, there is an effect equivalent to a reduction in capacitance generated between the antenna electrode 18 and the ground electrode 19. As the value of the inductor decreases from ∞, the resonance frequency of the antenna increases. FIG. 6 shows the effect when the reactance element on the X-axis (first reactance element 21) is changed for convenience, but the reactance element on the Y-axis (second reactance element 22) is shown. Needless to say, the same effect can be obtained. Further, although the antenna electrode 18 in FIG. 5 is shown in a square shape, it goes without saying that the present antenna can be realized in a circular shape or an elliptical shape.
[0038]
FIG. 7 shows another embodiment of the present invention. On a surface side of a plate-shaped main body 26 made of an antenna or the like, a square antenna electrode 18 made of a silver-palladium alloy is sintered on almost one surface. A ground electrode 19 made of a silver / palladium electrode is sintered on almost the entire back surface of the main body 26.
[0039]
Further, a signal electrode 20 is provided on the outer peripheral surface of the main body 26 in a non-contact state with the antenna electrode 18 and the ground electrode 19. By supplying power in a non-contact manner, the capacitance between the antenna electrode 18 and the signal electrode 20 can be easily adjusted by changing the shape of the non-contact portion by polishing. It can contribute to reduction of variation in characteristics.
[0040]
A first reactance element 21 and a second reactance element 22 are provided on an outer peripheral surface portion of the main body 26 on the X axis. In FIG. 7, an inductor is formed by the conductive pattern line. Further, a third reactance element 23 and a fourth reactance element 24 are provided on an outer peripheral surface portion of the main body 26 on the Y axis. In FIG. 7, a capacitor is formed by a conductive pattern line having a gap in the middle. These reactance elements can be changed by polishing their shapes, and their respective element values can be changed, and can be used for adjusting antenna characteristics during mass production. In the antenna of FIG. 7, since the inductor is provided on the X axis and the capacitor is provided on the Y axis, the resonance frequency of the resonance current on the X axis is higher than that on the Y axis. By optimizing the reactance values, the characteristics shown in FIG. 5 can be obtained.
[0041]
In the band of VSWR <3 of the VSWR characteristic in FIG. 5, the polarization parallel to the Y axis is dominant on the low frequency side, and the polarization parallel to the X axis is dominant on the high frequency side. Become. When a circularly polarized antenna is realized by the antenna configuration of FIG. 7, since the antenna structure is point-symmetrical at the intersection of the X axis and the Y axis, the value of the resonance current generated on the X axis and the Y axis is reduced. Almost the same can be obtained, and a high axial ratio can be easily obtained. The fixing terminal 25 in the figure is fixed to the high-frequency circuit board by soldering when the antenna is mounted on the high-frequency circuit board, and can prevent the antenna from peeling off from the high-frequency circuit board due to vibration or the like.
[0042]
8A and 8B show another embodiment of the present invention. In the antenna shown in FIG. 8A, an antenna electrode 18 made of a planar conductive material is arranged above a ground electrode 19 made of a planar conductive material. A first reactance element 21 and a first switch 27 are electrically connected between the antenna electrode 18 and the ground electrode 19 in series at a substantially end of the antenna electrode 18 on the X axis. At the upper end of the shaft, a second reactance element 22 and a second switch 28 are electrically connected in series between the antenna electrode 18 and the ground electrode 19. Further, at the intersection of the X axis and the Y axis, the signal electrode 20 is disposed at the end of the antenna electrode 18 on the axis having an angle of 45 degrees with respect to both axes, and the signal electrode 20 is electrically connected to the antenna electrode 18 and the ground electrode 19. It is connected.
[0043]
The shape of the antenna electrode 18 is designed such that when the first switch 27 and the second switch 28 are OFF, the electrical lengths of the X axis and the Y axis are equal. The element values of the first reactance element 21 and the second reactance element 22 are such that the electrical lengths on the X axis and the Y axis when the first switch 27 and the second switch 28 are ON are equal. Designed to. 8B shows a case where the switches 27 and 28 and the reactance elements 21 and 22 are arranged in parallel, and the reactance value loaded on the antenna electrode 18 is changed according to the state of the switch. Can change the resonance frequency, bandwidth, and radiation characteristics.
[0044]
FIG. 9 shows a change in the VSWR characteristic according to the state of the first switch 27 and the second switch 28 of the antenna of FIG. FIG. 9A shows the VSWR characteristics when the first switch 27 is ON and the second switch 28 is OFF. Since the first switch 27 is ON, the capacitor serving as the first reactance element 21 functions, indicating that the resonance frequency F1 on the X axis is lower than the resonance frequency F2 on the Y axis. Therefore, the polarization in the X-axis direction is dominant on the low band side in the band of VSWR <3, and the polarization in the Y-axis direction is dominant on the wide band side.
[0045]
On the other hand, FIG. 9B shows the VSWR characteristics when the first switch 27 is OFF and the second switch 28 is ON. In this case, only the capacitor that is the reactance element 22 on the Y axis functions, and the resonance frequency shifts to F1. In other words, depending on the states of the first switch 27 and the second switch 28, it is possible to switch the polarization direction between the X axis and the Y axis while maintaining the same resonance frequency and bandwidth of the antenna, It is possible to realize a polarization diversity antenna capable of changing the polarization plane.
[0046]
When both the first switch 27 and the second switch 28 are ON, the antenna can function as an antenna having a resonance frequency of F1 and having both X-axis and Y-axis polarizations. When both the switch 27 and the second switch 28 are OFF, the antenna functions as an antenna having a resonance frequency of F2 and having both X-axis and Y-axis polarizations. Further, the first switch 27 and the second switch 28 are embodied by a PIN diode, a mechanical switch, a MEMS switch, or the like. Further, in the embodiment of FIG. 8, the first reactance element 21 and the second reactance element 22 are embodied by capacitors, but a polarization diversity in which the polarization direction is temporally switched by an inductor is also configured. It is possible. However, in this case, when the first switch 27 and the second switch 28 are ON, the resonance frequencies of the X-axis and the Y-axis are higher than those at the time of OFF, so the antenna is designed in consideration of this. There is a need.
[0047]
FIG. 10 shows another embodiment of the antenna of the present invention. An antenna electrode 18 made of a flat conductive material is disposed above and opposed to a ground electrode 19 also made of a flat conductive material. A first reactance element 21 and a first switch 27 are electrically connected between the antenna electrode 18 and the ground electrode 19 in series at a substantially end of the antenna electrode 18 on the X axis. At the upper end of the shaft, a second reactance element 22 and a second switch 28 are electrically connected in series between the antenna electrode 18 and the ground electrode 19. Further, at the intersection of the X axis and the Y axis, the signal electrode 20 is disposed at the end of the antenna electrode 18 on the axis having an angle of 45 degrees with respect to both axes, and electrically connected to the antenna electrode 18 and the ground electrode 19. It is connected.
[0048]
The shape of the antenna electrode 18 is designed such that when the first switch 27 and the second switch 28 are OFF, the electrical length on the X axis is shorter than the electrical length on the Y axis. The value of the capacitor, which is the first reactance element 21, is the resonance current on the Y-axis with respect to the phase of the resonance current on the X-axis when the first switch 27 is ON and the second switch 28 is OFF. Is set to advance by 90 degrees. The value of the inductor, which is the second reactance element 22, is the resonance current on the Y-axis relative to the phase of the resonance current on the X-axis when the first switch 27 is off and the second switch 28 is on. Are set to be delayed by 90 degrees. In this way, it is designed so that the electrical lengths are equal. The element value of the second reactance element 22 is designed so that the electrical lengths on the X axis and the Y axis when the first switch 27 and the second switch 28 are ON are equal.
[0049]
FIG. 11 shows the characteristics of this antenna. FIG. 11A shows the VSWR characteristics when the first switch 27 and the second switch 28 are OFF. Since the electrical length on the X axis is shorter than the electrical length on the Y axis, VSWR <3. The polarization in the X-axis direction is dominant on the low band side in the band, and the polarization in the Y-axis direction is dominant on the wide band side. FIG. 11B shows the VSWR characteristics and the phase characteristics of the resonance current on the X axis and the Y axis when the first switch 27 is ON and the second switch 28 is OFF. The resonance frequency on the X axis decreases from F2 to F3 due to the effect of the first reactance element 21, and the phase of the resonance current on the X axis changes at the frequency F4 intermediate between the frequency F1 and the frequency F3. It can be seen that the phase is advanced by 90 degrees from the phase. As a result, the antenna operates as a left-hand circularly polarized antenna at the frequency F4.
[0050]
FIG. 11C shows the VSWR characteristics and the phase characteristics of the resonance current on the X axis and the Y axis when the first switch 27 is OFF and the second switch 28 is ON. The resonance frequency on the Y axis rises from F1 to F5 due to the effect of the second reactance element 22, and the phase of the resonance current on the X axis changes at the frequency F6 between the frequencies F2 and F5. It can be seen that the phase is delayed by 90 degrees from the phase. Thus, at the frequency F6, the antenna operates as a right-handed circularly polarized antenna.
[0051]
From the above, depending on the state of each switch, it can be operated as a wideband antenna, a left-handed circularly polarized antenna, or a right-handed circularly polarized antenna, and is embodied as a diversity antenna capable of shifting the polarization direction and frequency band over time. be able to. Note that, depending on how the first reactance element 21 and the second reactance element 22 are selected, a right-handed circularly polarized wave is generated when the first switch 27 is on and the second switch 28 is off. It goes without saying that it is possible to generate left-handed circularly polarized waves while the first switch 27 is OFF and the second switch 28 is ON. When the first switch 27 and the second switch 28 are both OFF and the electrical length on the X axis is longer than the electrical length on the Y axis, the first reactance element 21 is formed of an inductor, By configuring the second reactance element 22 with a capacitor, similar characteristics can be obtained.
[0052]
FIG. 12 shows another embodiment of the present invention. An antenna electrode 18 made of a flat conductive material is disposed above and opposed to a ground electrode 19 also made of a flat conductive material. A first reactance element 21 and a first switch 27 are electrically connected in series between the antenna electrode 18 and the ground electrode 19 at the end of the antenna electrode 18 on the X axis. At the intersection, a signal electrode 20 is arranged at an end of the antenna electrode 18 on an axis having an angle of 45 degrees with respect to both axes, and is electrically connected to the antenna electrode 18 and the ground electrode 19. The end of the antenna electrode 18 on the X axis is omitted.
[0053]
As shown in FIG. 13A, when the first switch 27 is turned off, the resonance frequency F2 of the resonance current on the X-axis is designed to be higher than the resonance frequency F1 of the resonance current on the Y-axis. At the same time, at the intermediate frequency F3 between the frequencies F1 and F2, the amount of the antenna electrode to be deleted is adjusted so that the phase of the resonance current on the X axis advances 90 degrees from the phase of the resonance current on the Y axis. Thus, at the frequency F3, it operates as left-handed circularly polarized wave.
[0054]
Next, as shown in FIG. 13B, when the first switch 27 is ON, the resonance frequency of the resonance current on the X axis is lower than the resonance frequency F1 on the Y axis, and At the intermediate frequency F5 between the frequencies F1 and F4, the element value of the capacitor that is the first reactance element 21 is determined so that the phase of the resonance current on the X axis is delayed by 90 degrees from the phase of the resonance current on the Y axis. I have. As described above, since the turning direction of the circularly polarized antenna can be temporally switched depending on the state of the first switch 27, it is possible to realize circularly polarized wave diversity that can temporally switch the rotating direction. Can be. When the first reactance element 21 and the first switch 27 are provided on the Y axis instead of the X axis in FIG. 12, similar characteristics can be obtained by using an inductor as the first reactance element 21. it can.
[0055]
A second signal electrode 29 is provided at the intersection of the X axis and the Y axis. This is a point at which the resonance current generated on the X axis and the Y axis becomes maximum and the potential of the antenna electrode 18 and the potential of the ground electrode 19 become the same potential (zero potential). Large isolation is possible. Therefore, it is possible to provide two signal electrodes on one antenna, and it is possible to substantially reduce the size of the antenna. In addition, depending on the state of the first switch 27, the antenna is connected from the second signal electrode 29 to the antenna. In order to shift the resonance frequency when the user sees the data, it is possible to function as frequency diversity.
[0056]
FIG. 14 shows another embodiment of the present invention. An antenna electrode 18 made of a flat conductive material is disposed above and opposed to a ground electrode 19 also made of a flat conductive material. A first reactance element 21 and a first switch 27 and a second reactance element 22 and a second switch 28 are provided at an end of the antenna electrode 18 on the X axis. The section is provided with a third reactance element 23 and a third switch 30, and a fourth reactance element 24 and a fourth switch 31. Further, at the intersection of the X axis and the Y axis, the signal electrode 20 is disposed at the end of the antenna electrode 18 on the axis having an angle of 45 degrees with respect to both axes, and electrically connected to the antenna electrode 18 and the ground electrode 19. It is connected. The shape of the antenna electrode 18 is designed so that the electrical length of the X axis and the electrical length of the Y axis are equal when all the switches are OFF. Further, the value of the capacitor as the first reactance element 21 and the value of the capacitor as the third reactance element 23 are determined by setting the first switch 27 and the third switch 27 in a state where the second switch 28 and the fourth switch 31 are OFF. Are set so that the electrical lengths on the X axis and the Y axis when the switch 30 is ON are equal. The element value of the second reactance element 22 is such that when the first switch 27 and the second switch 28 are ON and the other switches are OFF, the phase of the resonance current on the X axis is the resonance current on the Y axis. And the element value of the fourth reactance element 24 is such that the third switch 30 and the fourth switch 31 are ON and the other switches are OFF. In this case, the phase of the X-axis resonance current is set to be 90 degrees earlier than the phase of the Y-axis resonance current.
[0057]
FIG. 15 illustrates the state of the switch, the resonance frequency and the polarization direction of the antenna at this time.
[0058]
When all the switches are OFF, or when only the first switch 27 and the third switch 30 are ON, since the electrical lengths on the X axis and the Y axis are equal, the operation is performed at the resonance frequency F1 or F2. It becomes an antenna, and the polarization direction at this time has two axes of an X axis and a Y axis. That is, the resonance frequency of the two-axis polarization diversity antenna can be switched with a simple structure. Also, it goes without saying that the number of switchable resonance frequencies can be increased by increasing the number of reactance elements and switches loaded on the X axis and the Y axis.
[0059]
Next, when only the first switch 27 is ON, only the resonance frequency of the resonance current on the X-axis changes to the frequency F2 due to the influence of the first reactance element 21, and operates at the resonance frequency F1 and the resonance frequency F2. It becomes an antenna. Here, if the value of the first reactance element 21 is determined so that F1 and F2 are close to each other, the antenna can be operated as a wideband antenna. Regarding the polarization direction, the light is radiated in the polarization direction parallel to the X axis at the frequency F2 and in the polarization direction parallel to the Y axis at the frequency F1. On the other hand, when only the third switch 30 is ON, the bandwidth and the resonance frequency of the antenna are the same, but the polarization directions are opposite. Thus, a polarization diversity antenna that can switch the polarization direction over time can be realized.
[0060]
Next, when only the first switch 27 and the second switch 28 are ON, the phase of the X-axis resonance current is delayed by 90 degrees with respect to the phase of the Y-axis resonance current at the frequency F5. , A right-handed circularly polarized wave is emitted. On the other hand, when only the third switch 30 and the fourth switch 31 are ON, the phase of the Y-axis resonance current is delayed by 90 degrees with respect to the phase of the X-axis resonance current at the frequency F5. , A left-handed circularly polarized wave is emitted. That is, it is possible to realize a diversity antenna capable of switching the turning direction of the circularly polarized wave with time.
[0061]
When the third switch 30 and the fourth switch 31 are ON, the resonance frequency of the resonance current on the Y axis is reduced on the X axis by reducing the element value of the inductor that is the fourth reactance element. The resonance current is set to a frequency F6 higher than the resonance frequency F1, and at a frequency F7 between the frequencies F1 and F6, the phase of the resonance current on the X axis is delayed by 90 degrees from the phase of the resonance current on the Y axis. By setting the element value of the inductor that is the fourth reactance element 24 as described above, the right-handed circularly polarized wave can be emitted. This also applies to the case where the value of the inductor that is the second reactance element 22 is reduced, and in this case, it is possible to operate as a left-handed circularly polarized antenna at two frequencies.
[0062]
As described above, by controlling the state of each switch, one antenna can have various features, and the size and cost of the antenna can be reduced.
[0063]
FIG. 16A to FIG. 16H show details of the embodiment of the present invention. In this antenna, a rectangular antenna electrode 18 formed of a conductive material is provided on a flat upper surface of a main body 26 made of a dielectric material, and a convex portion is formed at the center of the lower surface of the main body 26 (on the X axis and on the X axis). It is formed from the lower surface position of the main body 26 facing the position of λ / 8 in electrical length from the peripheral portion of the antenna electrode 18 on the Y axis), and the ground electrode 19 is provided on almost the entire lower surface of the main body 26. is there. Further, a ground electrode non-forming portion is provided in a part of the ground electrode 19, and the signal electrode 20 and the connection line 32 to the first reactance element and to the second reactance element in a non-contact state with the ground electrode 19 there. Are provided, and the upper ends of the connection line 32 to the signal electrode 20 and the first reactance element and the connection line 33 to the second reactance element are electrically connected to the antenna electrode 18. .
[0064]
Reactance elements and switches connected to the antenna electrode 18 via a connection line 32 to the first reactance element and a connection line 33 to the second reactance element are mounted on the high-frequency circuit board 35 below the antenna electrode 18. . By adopting such a configuration, the distance between the antenna electrode 18 and the ground electrode 19 becomes large in the central portion of the antenna electrode 18, so that the characteristic impedance near the central portion of the antenna electrode 18 becomes large and the SIR (Stepped Impedance Resonator) becomes large. The antenna can be reduced in size according to the principle of the resonator. The size of the flat antenna electrode 18 can be further reduced by making the shape of the flat antenna electrode 18 a convex shape having a projection at the center. Further, only the lower surface convex portion of the main body 26 is mounted on the high-frequency circuit board 35, and the high-frequency circuit components 34 can be mounted on other areas on the high-frequency circuit board 35, so that the The mounting area can be increased, and the size of the communication device can be reduced.
[0065]
FIGS. 17A to 17H show another embodiment of the present invention. In the antennas shown in FIGS. 17A to 17H, a rectangular antenna electrode 18 is provided on an upper surface of a main body 26 made of a dielectric material, and a signal electrode 20 is provided at a peripheral corner of the antenna electrode 18. A second signal electrode 29 is provided on the intersection of the X-axis and the Y-axis of the antenna electrode 18, and a connection line 32 to the first reactance element and a connection line 33 to the second reactance element are provided on the X-axis. And a connection line 36 to the third reactance element and a connection line 37 to the fourth reactance element are provided on the Y axis. Further, the central portion of the lower surface of the main body 26 is formed in a concave shape, the second signal electrode 29 is formed of a conductive pin 38, and the lower end portion penetrates into the concave portion. Inside the concave portion, on the high-frequency circuit board 35, a reactance element and a switch connected to the antenna electrode 18 via a connection line to each reactance element, and other high-frequency circuit components 34 such as a matching circuit and an IC. Is implemented. The second signal electrode 29 is electrically connected to a transmission line connected to a high-frequency circuit formed on the high-frequency circuit board 35.
[0066]
By adopting such an antenna configuration, the mounting area of the antenna having two isolated signal electrodes can be reduced, and the impedance of the central portion of the antenna can be reduced by the air space formed by the concave portion on the lower surface of the main body 26. Therefore, the size of the antenna can be reduced. Further, the antenna electrode 18 is provided with four slots 41 so as to be line-symmetric with respect to both the X-axis and the Y-axis. As a result, the width of the antenna electrode 18 around the X axis and the Y axis becomes narrower at an electrical length of λ / 8 from the end of the antenna electrode 18. Therefore, the characteristic impedance on the X-axis and the Y-axis increases at an electrical length of λ / 8 from the end of the antenna electrode 18, so that the antenna can be reduced in size according to the principle of the SIR resonator.
[0067]
Further, the first substrate 39 constitutes the portion from the outer peripheral portion of the main body 26 to the position of λ / 8 in the electrical length inward, and the other portions are constituted by the second substrate 40. By setting the value obtained by dividing the relative permeability by the relative permittivity to be smaller than the value obtained by dividing the relative permeability of the second base material 40 by the relative permittivity, the characteristic impedance around the center of the antenna electrode 18 is set to be large. And the antenna can be reduced in size. The reason why the characteristic impedance is changed at a position of λ / 8 from the end of the antenna electrode 18 is that when the impedance is changed at this position, the antenna can be miniaturized most. It goes without saying that the same effect can be obtained even if the impedance is changed by the value.
[0068]
【The invention's effect】
As described above, the present invention includes an antenna electrode made of a conductive material, a signal electrode electrically coupled to the antenna electrode, and a ground electrode provided at a portion facing the antenna electrode. Provides one or more reactance elements on one or both axes of the X-axis and the Y-axis orthogonal or substantially orthogonal to the X-axis. The antenna is formed, and the antenna electrode can be reduced in size by using the reactance element, and the antenna has two resonance characteristics, so that a wideband antenna can be configured. Further, by providing a switch together with the reactance element, a diversity antenna capable of temporally changing the direction of polarization and the direction of rotation of circularly polarized wave can be embodied by one antenna, and cost reduction and size reduction can be achieved. Therefore, it is possible to reduce the size and cost of the communication device on which the antenna of the present invention is mounted.
[Brief description of the drawings]
FIG. 1 is a perspective view of an electronic device using an antenna according to an embodiment of the present invention.
FIG. 2 is a sectional view of a main part of the electronic device.
FIG. 3 is a circuit diagram of the electronic device.
FIG. 4 is a perspective view of an antenna according to the embodiment of the present invention.
FIG. 5 is a VSWR characteristic diagram of the antenna of FIG. 4;
FIGS. 6A and 6B are VSWR characteristic transition diagrams by reactance elements.
FIG. 7A is a front perspective view of an antenna according to another embodiment of the present invention.
(B) A perspective view of the back side of the antenna
8A and 8B are perspective views of an antenna according to another embodiment of the present invention.
9A and 9B are VSWR characteristic diagrams of the antenna of FIG. 8;
FIG. 10 is a perspective view of an antenna according to another embodiment of the present invention.
11 (a), (b), (c) are VSWR characteristic diagrams and phase characteristic diagrams of the antenna of FIG.
FIG. 12 is a perspective view of an antenna according to another embodiment of the present invention.
13A and 13B are VSWR characteristic diagrams and phase characteristic diagrams of the antenna of FIG.
FIG. 14 is a perspective view of an antenna according to another embodiment of the present invention.
FIG. 15 is a VSWR characteristic diagram of each switch of the antenna of FIG. 14;
FIG. 16A is a perspective view of an antenna according to another embodiment of the present invention.
(B) Sectional view of an antenna according to another embodiment of the present invention.
(C) Top view of antenna according to another embodiment of the present invention
(D) First side view of an antenna according to another embodiment of the present invention
(E) Second side view of antenna according to another embodiment of the present invention
(F) Third side view of an antenna according to another embodiment of the present invention
(G) Fourth side view of an antenna according to another embodiment of the present invention
(H) A bottom view of an antenna according to another embodiment of the present invention.
FIG. 17 (a) is a perspective view of an antenna according to another embodiment of the present invention.
(B) Sectional view of an antenna according to another embodiment of the present invention.
(C) Top view of antenna according to another embodiment of the present invention
(D) First side view of an antenna according to another embodiment of the present invention
(E) Second side view of antenna according to another embodiment of the present invention
(F) Third side view of an antenna according to another embodiment of the present invention
(G) Fourth side view of an antenna according to another embodiment of the present invention
(H) A bottom view of an antenna according to another embodiment of the present invention.
[Explanation of symbols]
18 Antenna electrode
19 Ground electrode
20 signal electrodes
21 First reactance element
22 Second reactance element
27 First switch
28 Second switch

Claims (21)

An antenna electrode formed of a conductive material, a signal electrode electrically coupled to the antenna electrode, and a ground electrode provided at a portion facing the antenna electrode, wherein the antenna electrode is orthogonal to or substantially orthogonal to the X axis. An antenna in which one or more reactance elements are provided on one or both of the orthogonal Y axes, and signal electrodes are formed on a straight line having an angle of approximately 45 degrees from the intersection of the X axis and the Y axis. The antenna according to claim 1, wherein an end of the reactance element that is not electrically connected to the antenna electrode is connected to a ground electrode. The antenna according to claim 1, wherein the reactance element is provided at a position substantially point-symmetric with respect to an intersection of the antenna electrode with the X axis and the Y axis. The antenna according to claim 1, further comprising a switch provided near the reactance element. The antenna according to claim 4, wherein the reactance element and / or the switch are mounted on a high-frequency circuit board. The antenna according to claim 1, wherein the second signal electrode is provided at a position substantially at the intersection of the X axis and the Y axis of the antenna electrode. 2. The antenna according to claim 1, wherein the electrical length of the antenna electrode on the X axis and the Y axis is substantially a half wavelength. A reactance element and a switch are provided on both the X and Y axes of the antenna electrode. When the switch on the X axis is ON, the switch on the Y axis is OFF and the switch on the Y axis is ON. 5. The antenna according to claim 4, wherein a switch on the X axis is turned off at the time. The electrical length on the X-axis when the switch on the X-axis of the antenna electrode is ON is equal to the electrical length on the Y-axis when the switch on the Y-axis is ON, and when the switch on the X-axis is OFF. 9. The antenna according to claim 8, wherein the electrical length on the X axis is equal to the electrical length on the Y axis when the switch on the Y axis is OFF. A reactance element and a switch are provided on both the X axis and the Y axis of the antenna electrode, and the electrical length on the X axis when the switch on the X axis is ON and the electrical length on the X axis when the switch on the Y axis is ON. The antenna according to claim 4, wherein the electric length on the Y axis is different. A reactance element and a switch are provided on both the X axis and the Y axis of the antenna electrode, and the electrical length on the X axis when the switch on the X axis is OFF and the electrical length on the X axis when the switch on the Y axis is OFF. The antenna according to claim 4, wherein the electric length on the Y axis is different. When the switch on the X axis of the antenna electrode is OFF and the switch on the Y axis is ON, the antenna operates with the right-handed circularly polarized antenna or the left-handed circularly polarized antenna. The antenna according to claim 10 or 11, wherein the antenna is configured to operate as a circularly polarized wave antenna in the opposite turning direction when the on-axis switch is turned on. The antenna according to claim 10 or 11, wherein the antenna operates as a broadband antenna or a two-band antenna when both switches on the X axis and the Y axis of the antenna electrode are ON. An antenna electrode that operates alone as a circularly polarized antenna by adjusting the lengths of the X-axis and the Y-axis. The antenna electrode includes a reactance element and a switch on one of the X-axis or the Y-axis. The antenna according to claim 4, wherein the reactance element value is selected so that the antenna electrode also operates as a circularly polarized antenna. An antenna electrode that operates alone as a circularly polarized antenna by adjusting the lengths of the X axis and the Y axis. When the X axis and the Y axis are compared, a capacitor element and a switch are provided on the shorter electric length axis. The antenna according to claim 4, wherein the capacitor element value is selected such that the antenna electrode operates as a circularly polarized antenna even when the switch is ON. An antenna electrode that operates alone as a circularly polarized antenna by adjusting the lengths of the X axis and the Y axis. An inductor element and a switch are provided on the axis with the longer electrical length when the X axis and the Y axis are compared. The antenna according to claim 4, wherein the inductor element value is selected such that the antenna electrode operates as a circularly polarized antenna even when the switch is turned on. A first reactance element and a first switch are provided at a first point on the X-axis of the antenna electrode, a second reactance element and a second switch are provided at a second point on the X-axis, and a Y-axis is provided on the Y-axis. A third reactance element and a third switch at a third point, and a fourth reactance element and a fourth switch at a fourth point on the Y-axis, and a second switch and a fourth switch. Is OFF and the electrical length on the X-axis when the first switch is ON is equal to the electrical length on the Y-axis when the second switch and the fourth switch are OFF and the third switch is ON, When the first switch and the second switch are ON and the third switch and the fourth switch are OFF, the switch operates in right-handed circular polarization or left-handed circular polarization, and the first switch and the second switch are OFF. The third switch and the Antenna according to claim 4, the switch is configured to operate as the reverse of the turning direction of the circularly polarized wave antenna when is ON. A first reactance element and a first switch are provided at a first point on the X-axis of the antenna electrode, a second reactance element and a second switch are provided at a second point on the X-axis, and a Y-axis is provided on the Y-axis. A third reactance element and a third switch at a third point, and a fourth reactance element and a fourth switch at a fourth point on the Y-axis, and a second switch and a fourth switch. Is OFF and the electrical length on the X-axis when the first switch is ON is equal to the electrical length on the Y-axis when the second switch and the fourth switch are OFF and the third switch is ON, When the first switch and the fourth switch are ON and the second switch and the third switch are OFF, the switch operates in right-handed or left-handed polarization, and the first switch and the fourth switch are turned off. The second switch and the second Antenna according to claim 4, the switch is configured to operate as the reverse of the turning direction of the circularly polarized wave antenna when is ON. A first reactance element and a first switch are provided at a first point on the X-axis of the antenna electrode, a second reactance element and a second switch are provided at a second point on the X-axis, and a Y-axis is provided on the Y-axis. A third reactance element and a third switch at a third point, and a fourth reactance element and a fourth switch at a fourth point on the Y-axis, and a second switch and a fourth switch. Is OFF and the electrical length on the X-axis when the first switch is ON is equal to the electrical length on the Y-axis when the second switch and the fourth switch are OFF and the third switch is ON, When the first switch and the second switch are ON and the third switch and the fourth switch are OFF, and when the first switch and the second switch are OFF and the third switch and the fourth switch are ON. If both Antenna according to claim 4, in the state both configured to operate only on either of the polarization of the right-handed circularly polarized wave or left hand circular polarization. A first reactance element and a first switch are provided at a first point on the X-axis of the antenna electrode, a second reactance element and a second switch are provided at a second point on the X-axis, and a Y-axis is provided on the Y-axis. A third reactance element and a third switch at a third point, and a fourth reactance element and a fourth switch at a fourth point on the Y-axis, and a second switch and a fourth switch. Is OFF and the electrical length on the X-axis when the first switch is ON is equal to the electrical length on the Y-axis when the second switch and the fourth switch are OFF and the third switch is ON, When the first switch and the fourth switch are ON and the second switch and the third switch are OFF, and when the first switch and the fourth switch are OFF and the second switch and the third switch are ON. If both Antenna according to claim 4, in the state both configured to operate only on either of the polarization of the right-handed circularly polarized wave or left hand circular polarization. An electronic device in which at least one of a transmission circuit and a reception circuit is electrically coupled to the antenna according to claim 1.

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