Source: https://patents.google.com/patent/KR101318707B1/en
Timestamp: 2020-02-19 19:17:23
Document Index: 693804633

Matched Legal Cases: ['art 21', 'art 22', 'art 21', 'art 22', 'art 21', 'art 22', 'art 22', 'art 21', 'art 22', 'art 22', 'art 21', 'art 22', 'art 22', 'art 22', 'art 22', 'art 22', 'art 20']

KR101318707B1 - Antenna device and mobile communication terminal - Google Patents
KR101318707B1
KR101318707B1 KR1020127008125A KR20127008125A KR101318707B1 KR 101318707 B1 KR101318707 B1 KR 101318707B1 KR 1020127008125 A KR1020127008125 A KR 1020127008125A KR 20127008125 A KR20127008125 A KR 20127008125A KR 101318707 B1 KR101318707 B1 KR 101318707B1
KR1020127008125A
KR20120049930A (en
2009-11-20 Priority to JP2009265219 priority Critical
2009-11-20 Priority to JPJP-P-2009-265219 priority
2010-11-18 Application filed by 가부시키가이샤 무라타 세이사쿠쇼 filed Critical 가부시키가이샤 무라타 세이사쿠쇼
2010-11-18 Priority to PCT/JP2010/070607 priority patent/WO2011062238A1/en
2012-05-17 Publication of KR20120049930A publication Critical patent/KR20120049930A/en
2013-10-17 Publication of KR101318707B1 publication Critical patent/KR101318707B1/en
The gain of the transmission / reception signal is improved, and an antenna device and a mobile communication terminal having good communication performance are obtained.
An antenna including a power feeding member 10 including a coil pattern 15 and a radiation member 20 that radiates a transmission signal supplied from the power feeding member 10 and receives a received signal and supplies the received signal to the power feeding member 10. Device. The radiation member 20 has the opening part 21 and the slit part 22 connected to the opening part 21 in the part, and when viewed in plan view from the winding-axis direction of the coil pattern 15, the radiation member 20 The openings 21 and the inner region of the coil pattern 15 overlap, and the radiating member 20 and the coil pattern 15 overlap at least in part.
ANTENNA DEVICE AND MOBILE COMMUNICATION TERMINAL}
The present invention relates to an antenna device and a mobile communication terminal, in particular an antenna device used for a radio frequency identification (RFID) system and the like, and a mobile communication terminal including the same.
In recent years, as a management system for articles and information, a reader / writer for generating an induction magnetic field and a wireless IC device such as an IC tag attached to the article and storing predetermined information are communicated in a non-contact manner using an electromagnetic field to provide predetermined information. An RFID system for transmitting and receiving electric power has been developed.
For example, Patent Document 1 discloses a cellular phone incorporating a contactless IC card. However, since mobile communication terminals such as mobile phones are compact and multifunctional, various metal parts are mounted in high density in small casings. For example, a ground conductor etc. are arrange | positioned in multiple layers in the printed wiring board used as a mother board, and components containing metals, such as an IC chip and a capacitor, are mounted in high density on the surface of the said printed wiring board. A battery pack serving as a power source is also disposed in the casing, and metal parts such as a frame are used for the battery pack.
Therefore, the antenna device, such as an IC card mounted in the casing, has a problem that communication performance deteriorates under the influence of the metal component provided in the casing. In order to secure a predetermined communication performance, it is necessary to increase the size of the antenna or to reconsider the shape of the casing, the layout of the metal parts, and the like.
Japanese Unexamined Patent Publication No. 2003-37861
SUMMARY OF THE INVENTION The present invention has been made in view of the above-mentioned present situation, and an object thereof is to provide an antenna device and a mobile communication terminal with improved communication performance and a good communication performance.
In order to achieve the above object, a first aspect of the present invention is an antenna device,
A feeding member including a coil pattern,
A radiating member for radiating a transmission signal supplied from said feeding member and / or receiving a received signal and supplying it to said feeding member,
The radiation member has an opening portion and a slit portion connected to the opening portion, and the opening portion of the radiation member and the inner region of the coil pattern are at least partially viewed in a plan view from the winding axis direction of the coil pattern. Overlapping, characterized in that the radiating member and the coil pattern overlap at least in part.
The mobile communication terminal which is a 2nd aspect of this invention,
A radiation member that radiates a transmission signal supplied from the power supply member and / or receives a received signal and supplies it to the power supply member;
A casing incorporating the power feeding member and the radiation member,
The radiation member has an opening portion and a slit portion connected to the opening portion, and when viewed in a plan view from the winding axis direction of the coil pattern, the opening portion of the radiation member and an inner region of the coil pattern overlap at least partially. The radiating member and the coil pattern overlap each other.
The radiation member has an opening formed in a portion thereof and a slit portion connected to the opening, and when viewed in a plan view from the winding axis direction of the coil pattern included in the power feeding member, at least a portion of the opening of the radiation member and the inner region of the coil pattern Since the radiating member and the coil pattern overlap at least in part, when current flows in the coil pattern, the excited magnetic field is ideally distributed through the opening of the radiating member, and the induced magnetic field causes the An induced current is excited around the opening of the. As a result, the gain of the transmission / reception signal is improved and the communication distance can be widened.
According to the present invention, it is possible to improve the gain of the transmission / reception signal and obtain good communication performance.
1 shows a mobile communication terminal equipped with the antenna device according to the first embodiment, (A) is a rear view of the casing, and (B) is an AA sectional view.
FIG. 2 is an explanatory view showing an exploded view of the antenna device according to the first embodiment. FIG.
3 is an explanatory diagram showing coupling between a coil pattern and a radiation member in the antenna device according to the first embodiment.
FIG. 4 is an explanatory diagram showing an induced current generated around an opening of a radiation member in the antenna device of Example 1. FIG.
FIG. 5 is an explanatory diagram showing an induced current flowing in the peripheral portion of the radiation member in the antenna device of the first embodiment. FIG.
6 is an explanatory diagram showing a magnetic coupling state between the antenna device and the reader / writer antenna, (A) shows Example 1, and (B) shows a comparative example.
7 is an explanatory diagram of the operation when the radio signal is in the UHF band in the antenna device according to the first embodiment.
8 shows an antenna device according to a second embodiment, (A) is an exploded perspective view, and (B) is a sectional view.
9 is a simplified operation explanatory diagram of the antenna device according to the second embodiment.
FIG. 10: shows the outline of the mobile communication terminal equipped with the antenna apparatus of Example 3, (A) is a top view, (B) is a side view.
Fig. 11 shows an outline of a mobile communication terminal equipped with the antenna device according to the fourth embodiment, (A) is a plan view, and (B) is a side view.
FIG. 12: shows the outline of the mobile communication terminal equipped with the antenna apparatus of Example 5, (A) is a top view, (B) is a side view.
Fig. 13 shows an outline of a mobile communication terminal equipped with the antenna device according to the sixth embodiment, (A) is a plan view, and (B) is a side view.
14 shows the antenna device according to the seventh embodiment, (A) is an exploded perspective view, and (B) is a plan view.
Fig. 15 shows an antenna device according to the eighth embodiment, (A) is an exploded perspective view, and (B) is a plan view.
Hereinafter, an antenna device and a mobile communication terminal according to the present invention will be described based on specific embodiments. In addition, the same code | symbol is attached | subjected to the components and parts common in each figure, and the overlapping description is abbreviate | omitted.
(Example 1, see FIGS. 1 to 7)
In the antenna device 1A according to the first embodiment, as shown in Figs. 1A and 1B, the coil pattern 15 provided on the back side of the casing 5 of a mobile communication terminal (for example, a cellular phone) is provided. And a magnetic member 19 made of a ferrite sheet attached to the power feeding member 10, and a radiation member 20.
The radiation member 20 functions as an antenna for radiating a signal supplied from the power supply member 10 and receiving a received signal and supplying the received signal to the power supply member 10. The radiation member 20 serves as a film on the back surface of the casing 5. Or by providing a foil. The power feeding member 10 is composed of a laminate in which a plurality of dielectric layers (thermoplastic resin sheets) are laminated, and the coil pattern 15 includes a plurality of annular conductors disposed in the plurality of dielectric layers, respectively, via-hole conductors and the like. Through the interlayer conductor (not shown in FIG. 1 (B)), the coil is connected in a helical shape so as to have a winding axis in the stacking direction of the laminate. Both ends of the coil pattern 15 are connected to a radio circuit such as an IC tag embedded in the casing 5.
The radiation member 20 has an opening 21 in a part thereof and a slit portion 22 communicating with an edge portion of the opening 21. One end of the slit portion 22 is in contact with the opening 21, and the other end is open at the side edge of the radiation member 20. That is, the slit part 22 is provided so that the side edge of the opening part 21 and the radiation member 20 may communicate. When viewed in a plan view from the winding axis direction of the coil pattern 15, the entire region of the opening 21 overlaps the inner region of the coil pattern 15, and the coil pattern 15 overlaps the radiation member 20.
The assembling procedure of the antenna device 1A is as shown in FIG. 2. First, the magnetic member 19 is attached to the power feeding member 10 having the coil pattern 15 embedded therein, and the power feeding member 10 is attached to the radiation member 20. Attach on).
In the antenna device 1A having the above configuration, the radiation member transmits a transmission signal from a wireless circuit electrically connected to both ends of the coil pattern 15 by the power supply member 10 including the coil pattern 15. 20, and the received signal (received power) from the radiation member 20 is supplied to the wireless circuit through the power supply member 10. This operation is described in detail below.
As described above, when viewed in a plan view from the winding axis direction of the coil pattern 15 provided in the power feeding member 10, the opening 21 of the radiation member 20 and the inner region of the coil pattern 15 overlap each other. Therefore, as shown in FIG. 3, for example, at the time of transmission of a radio signal, a signal current flows from the radio circuit to the coil pattern 15, and the induction magnetic field H generated by the current causes the opening 21 to open. Ideally distributed as shown by the dotted line in the drawings. The ideal distribution of the magnetic field H means that the center B of the two magnetic fields H coincides with the center of the opening portion 21, and the gain of the radiation member 20 is maximized in this state.
By the induction magnetic field H, as shown in FIG. 4, induced currents I1 and I2 (however, the propagation directions of the currents I1 and I2 differ by 180 °) in the peripheral portion of the opening 21. Occurs. Specifically, as shown in FIG. 5, the circumference of the radiating member 20 is passed through the opening 21 and the slit part 22 by the plane and edge effects of the radiating member 20. Induction currents I1 and I2 flow at the edges. In addition, although the current I2 is not shown in FIG. 5, it flows in the opposite direction to the current I1. Since the induction currents I1 and I2 overlap the radiation member 20 and the coil pattern 15 in plan view, the induction currents I1 and I2 are different from the current flowing in the coil pattern 15 so as to block the induction magnetic field generated from the coil pattern 15. Flow in the opposite direction.
Here, the magnetic field is generated from the radiating member 20 by the induced currents I1 and I2, and the induced currents I1 and I2 flow through the entire radiating member 20. In particular, when the radio signal handled by the antenna device 1A is in the HF band, as shown in Fig. 6A, since the magnetic flux does not penetrate the radiating member 20, the opening 21 of the radiating member 20 is provided. In the path where the outer edge of the radiating member 20 is outside, the loop with relatively large magnetic flux? Is drawn. Thereby, the communication distance with the antenna 40 of a reader / writer can be extended.
The magnetic coupling state of the antenna device 1A and the antenna 40 of the reader / writer is as shown in Fig. 6A. The case where the radiation member 20 is omitted is shown in FIG. 6B as a comparative example. In this comparative example, since the radiation member 20 does not exist, the magnetic flux φ does not widen, and the coupling amount with the antenna 40 is small. Therefore, as both approaches, communication becomes unstable.
Here, the result which measured the distance which can communicate with the antenna 40 of the reader / writer with respect to the various size (length and breadth size) of the power supply member 10 is shown. In addition, in the parenthesis, the communication distance in the comparative example in which the radiation member 20 is omitted.
0 to 44 mm (0 to 24 mm) at 22.5 mm x 20 mm
0 to 43 mm (0 to 23 mm) at 22.5 mm x 19 mm
0 to 41 mm (0 to 19 mm) at 22.5 mm x 18 mm
0 to 39 mm (-) at 22.5 mm x 17 mm
0 to 38 mm (-) at 22.5 mm x 16 mm
As described above, in the radiating member 20, the magnetic field H is induced by the induced currents I1 and I2. When the radio signal handled by the antenna device 1A is a high frequency band, particularly in the UHF band, As shown in FIG. 7, the electric field E is induced by the magnetic field H, and the magnetic field H is induced by the electric field E, and thus the electromagnetic field is spread over the whole of the radiation member 20. The distribution is widened in two dimensions. The wireless signal is transmitted by this electromagnetic field distribution, and the communication distance can be widened by the induction currents I1 and I2 flowing through the entire radiating member 20.
Moreover, since the slit part 22 is connected to the opening part 21, the flow of this induced current I1 and I2 is restrict | limited in the slit part 22, and a potential difference is provided (capacitance is formed). Therefore, by controlling the amount or distribution of the induced currents I1 and I2 at the length L1 and the width L2 of the slit portion 22, the amount of electric field and magnetic field generated in the entire region of the radiating member 20 is controlled. can do. As a result, the gain of the transmission signal can be controlled.
As described above, the gain of the radio signal transmitted / received to / from the radiation member 20 can be controlled by the length L1 and the width L2 of the slit portion 22. Specifically, the larger the length L1 of the slit portion 22, the smaller the width L2 tends to be.
As shown in FIG. 1 (B), the annular conductors provided in the dielectric layers of the power supply member 10 are preferably formed of a plurality of parallel line conductors at predetermined intervals. That is, in the first embodiment, the conductors formed in an annular shape are formed as two parallel line conductors, whereby the magnetic flux passes between the two line conductors, and the excited magnetic field is the coil pattern ( It becomes wider in the center direction of 15), ie, the direction orthogonal to the winding axis, and can use a magnetic flux efficiently. In addition, by increasing the parallel number of the annular conductors, the effect of reducing the DC resistance of the annular conductors is produced. As a result, the gain of the radio signal can be improved.
In the equivalent circuit shown in FIG. 3, only the coil pattern 15 is shown as a power supply circuit, except that the inductance of the coil pattern 15 itself is used as an inductance component, and the coil pattern 15 was laminated | stacked as mentioned above. Since it is formed by the annular electrode, the floating capacitance formed between the annular electrodes of each layer is used as a capacitance component. The power supply member 10 may include at least one coil pattern 15. When the power supply circuit has a predetermined resonance frequency, for example, a capacitance component or an inductance component for adjusting the resonance frequency may be provided. You may have more.
In the first embodiment, the power supply circuit (coil pattern 15) has a predetermined resonance frequency, and it is preferable that the frequency of the radio signal transmitted and received by the radiation member 20 corresponds substantially to this resonance frequency. . Here, " substantially substantial " means that the band of the resonant frequency of the power feeding circuit and the frequency band of the radio signal transmitted / received by the radiating member 20 substantially match. As described above, since the frequency of the transmission signal and / or the reception signal substantially corresponds to the resonant frequency of the power supply circuit, the shape and material of the radiation member 20, the shape of the casing 5 supporting the radiation member 20, An antenna device having stable frequency characteristics that are almost independent of material and the like is obtained.
In other words, in the shape and material of the opening 21 and the slit part 22 in the radiation member 20, or the shape and material of the coil pattern 15 in the power supply member 10, the frequency band of the radio signal is While being determined, matching of impedance between the radiation member 20 and the radio circuit (signal processing unit) is also realized. Therefore, the antenna apparatus corresponding to various mobile communication terminals can be realized, without changing the shape of the opening part 21, the slit part 22, or the shape of the coil pattern of the radiation member 20. FIG.
In addition, the magnetic member 19 superimposed on the power supply member 10 efficiently couples the magnetic field generated in the coil pattern 15 with the radiation member so as not to leak to the outside, and also blocks the externally generated magnetic field to communicate performance. It has a function to prevent deterioration.
In addition, in the first embodiment, since the power supply member 10 and the radiation member 20 are electromagnetically coupled, it is not necessary to consider the impedance matching between the power supply member 10 and the radiation member 20. That is, according to the first embodiment, as described above, by preferably designing the shape of the slit portion 22, the gain of the radio signal can be controlled very easily.
It is preferable that the opening 21 and the inner region of the coil pattern 15 of the radiating member 20 substantially overlap each other, and the area of the opening 21 and the inner region of the coil pattern 15 are substantially the same. This is because the magnetic field H (see FIG. 3) by the coil pattern 15 propagates efficiently with respect to the radiation member 20, the loss is suppressed, and the gain is improved. In addition, by overlapping the opening 21 and the inner region of the coil pattern 15 almost entirely, the whole of the coil pattern 15 can be overlapped with the radiation member 20. As a result, a large induced current can be generated by the radiating member 20, so that the communication distance can be further improved. However, the opening 21 and the inner region of the coil pattern 15 may overlap at least in part, and the radiation member 20 and the coil pattern 15 may overlap in part.
Moreover, it is preferable that the area of the radiation member 20 is larger than the area of the part in which the coil pattern 15 was formed. Since the area of the radiation member 20 is larger than the area of the portion formed by the coil pattern 15, the communication current can be further improved because the induced current flows in a loop.
Regarding the shape of the slit portion 22, it is advantageous in terms of workability as in the first embodiment, but may be formed in a meandering shape or a curved shape. In addition, the power supply member 10 may be a coil pattern 15 formed on a single layer substrate.
(See Example 2, Figs. 8 and 9)
As shown in Figs. 8A and 8B, the antenna device 1B according to the second embodiment basically has the same configuration as the antenna device 1A according to the first embodiment, and the other is a mobile communication terminal. The conductive member (hereinafter referred to as the ground conductor 7) and the radiating member 20 provided on the printed wiring board 6 mounted in the structure are coupled to each other via a capacitor C (see FIG. 9). More specifically, the ground conductor 7 and the radiating member 20 are disposed to face each other, and the conductive member (capacity supplementary element) 8 and the radiating member 20 electrically connected to the ground conductor 7 are arranged. The capacitor C is formed between the conductive member 8 and the radiating member 20 by interposing the dielectric layer 18, which is an adhesive, between the layers.
The operation and effect of the antenna device 1B according to the second embodiment are basically the same as those of the antenna device 1A according to the first embodiment, and the radiation member 20 and the ground conductor 7 are coupled by capacitance C. The following effects are exhibited in that point.
That is, during communication, induced currents I1 and I2 flow through the radiating member 20 as shown in FIG. 9 by an induction magnetic field generated due to the signal current flowing through the coil pattern 15. 9 is a simplified view of FIG. 5 referred to in the first embodiment. Due to the induced currents I1 and I2, eddy currents I3 and I4 are generated in the ground conductor 7 facing the radiating member 20 in a direction of negating the magnetic field caused by the induced current. Eddy currents I3 and I4 are originally dissipated as heat, and the energy of the eddy currents I3 and I4 is reduced to the radiating member 20 by the capacitance C, and as a result, the gain of the radiating member 20 is reduced. It can improve the communication distance. In addition, since the magnetic field excited by the coil pattern 15 is absorbed by the radiation member 20 through the ground conductor 7, the necessity of considering the arrangement relationship with other metal parts mounted in the casing 5 becomes small.
As described above, in the second embodiment, a parallel resonant circuit is formed of the combined inductance of the radiation member 20 and the ground conductor 7 and the capacitance C. The resonance point of this parallel resonance circuit needs to be higher than the frequency transmitted and received by the radiation member 20. That is, when the use frequency is lower than the resonant frequency of the parallel resonant circuit, the parallel resonant circuit becomes magnetic field radioactivity (L characteristic), and when it is high, it becomes electric field radioactivity (C characteristic). Therefore, when magnetic field radiation is used for communication, the resonance point of the parallel resonance circuit needs to be higher than the use frequency (frequency transmitted and received by the radiation member 20).
In addition, in Embodiment 2, the conductor member which capacitively couples with the radiation member 20 may be other than the ground conductor 7 as long as it is a conductor member provided in the printed wiring board 6. Moreover, the form which capacitively couples a conductor member with the radiation member 20 is arbitrary, For example, you may use the metal frame mounted in the casing 5 as the conductive member 8. Moreover, it is preferable that the electroconductive member (capacity replenishment element) 8 is arrange | positioned near the slit part 22. FIG. Since the capacitor replenishment element and the slit part 22 are arranged in close proximity, one LC parallel between the inductance component of the slit part 22 and the radiating member 20 and the ground conductor 7 containing the capacitor replenishment element A resonant circuit is formed. By setting this resonance frequency higher than the use frequency, magnetic field radiation occurs from the slit portion 22 as a starting point. At this time, the current of the parallel resonant circuit also flows to the ground conductor 7, so that the ground conductor 7 can be used as a part of the radiating portion, and magnetic field radiation can be emitted from the large ground conductor 7.
(Examples 3 to 6 and 10 to 13)
Next, the antenna devices 1C to 1F of Embodiments 3 to 6 will be described. These antenna devices 1C to 1F have a predetermined directivity by varying the direction of the slit portion 22 of the radiation member 20 or the positional relationship between the ground conductor 7 and the radiation member 20 provided on the printed wiring board. Is getting.
As shown in FIG. 10, the antenna device 1C arranges the slit portion 22 toward the inside of the terminal casing 5 while overlapping the radiation member 20 at one end of the ground conductor 7. The magnetic flux φ1, φ2, φ3 represents the directivity of the magnetic field.
As shown in FIG. 11, the antenna device 1D arranges the slit portion 22 toward the outside of the terminal casing 5 while overlapping the radiation member 20 at one end of the ground conductor 7. The magnetic fluxes φ1 and φ2 indicate the directivity of the magnetic field.
As shown in FIG. 12, the antenna device 1E cuts the ground conductor 7 from the right side of the terminal casing 5, and prevents the radiating member 20 from overlapping with the ground conductor 7 and further includes a slit portion ( 22) is arranged toward the outside of the terminal casing (5). The magnetic flux φ1, φ2, φ3 represents the directivity of the magnetic field.
As shown in FIG. 13, the antenna device 1F bends the radiating member 20 so that the slit portion 22 is inclined, and the slit so that the opening portion 21 overlaps one end of the ground conductor 7. The part 22 is arrange | positioned toward the outer side of the terminal casing 5. The magnetic flux φ1, φ2, φ3 represents the directivity of the magnetic field.
(Example 7, FIG. 14)
As shown in FIG. 14, the antenna device 1G according to the seventh embodiment is provided with two conductive members (capacitive replenishment elements) 8 electrically connected to the ground conductor 7. Two capacitances C1 and C2 are formed between the radiation members 20. This antenna device 1G is an application example of the antenna device 1B described as the second embodiment, and can effectively return the eddy current energy consumed by the ground conductor 7 to the radiation member 20. In particular, in the present antenna device 1G, since the conductive members 8 are arranged one by one on both sides of the slit portion 22, the return of the eddy current energy is efficient. The feedback of the eddy current energy here refers to the formation of a capacitance by providing a supplementary capacitance element between both ends of the slit portion 22 of the radiating member 20 and the ground conductor 7 to form the slit portion 22 and the ground conductor 7. By forming one resonant circuit including), the ground conductor 7 can also be part of the radiating part. For this reason, even when the radiating part 20 is close to the ground conductor 7, magnetic field radiation (or electric field radiation) is possible, and the radiation of the magnetic field (or electric field) also occurs from the ground conductor 7. The ground conductor 7 may be a metal member such as a battery of a mobile phone other than the ground conductor, a negative electrode pattern that is electrically connected to nothing, or a wiring pattern through which other signals are passed.
Moreover, in order to return eddy current energy, you may provide so that the capacitor | capacitance replenishment element which couples between the ground conductor 7 and the radiation member 20 may be pinched | interposed by the chip capacitor between the ground conductor 7 and the radiation member 20. FIG. This is also true of the second embodiment (antenna device 1B).
(Example 8, see FIG. 15)
In the antenna device 1H according to the eighth embodiment, as shown in FIG. 15, the radiation member 20 is disposed so that the slit portion 22 overlaps the edge portion of the ground conductor 7. In this configuration, the radiating member 20 and the ground conductor 7 are joined by the capacitors C1 and C2, and the eddy current energy is supplied to the radiating member 20 without providing the conductive member 8 as the capacitance replenishment element. You can return. In addition, in the antenna device 1H, there is no problem in providing a capacitive supplemental element.
By the way, in the said Example 7, 8, the resonance circuit is formed by the inductance of the radiation member 20, the capacitance formed between the radiation member 20, and the ground conductor 7, and the inductance of the ground conductor 7. . It is preferable to set the resonant frequency of the resonant circuit to be higher than the communication frequency transmitted and received by the radiating member 20. For example, when the present antenna device is used in an RFID system, the resonance frequency of the resonance circuit is set to, for example, 15.04 MHz which is slightly higher than the communication frequency of 13.56 MHz. As a result, the antenna of the present antenna device and the reader / writer are magnetically coupled to perform communication.
In addition, the antenna device and the mobile communication terminal according to the present invention are not limited to the above embodiments, and may be variously changed within the scope of the gist.
In particular, a mobile telephone as a mobile communication terminal is merely an example, and the present invention can be applied to various mobile communication terminals. Moreover, as a conductor member couple | bonded with a radiation member, it is not limited to the said ground conductor, The metal casing of a terminal may be sufficient.
As described above, the present invention is useful for an antenna device and a mobile communication terminal, and is particularly excellent in that the communication distance can be increased by increasing the gain of a transmission / reception signal.
1A ~ 1H: Antenna Unit 5: Casing
6: printed wiring board 7: ground conductor
8: conductive member (capacity supplementary element) 10: power feeding member
15: coil pattern 20: radiation member
21: opening 22: slit
The said radiation member has an opening part and the slit part connected to the said opening part in the part, and when it sees in plan view from the winding-axis direction of the said coil pattern, the opening part of the said radiation member and the inner region of the said coil pattern are at least The antenna device, characterized in that overlapping in some, the radiation member and the coil pattern at least in part.
At the time of radiation of the transmission signal, an induced current is excited around the opening of the radiation member by the current flowing through the coil pattern, and the magnetic field and the electric field caused by the induced current are widened throughout the radiation member. And the radiating member operates as an electric field antenna by reducing.
And the coil pattern and the radiation member are electromagnetically coupled to each other.
An antenna, characterized in that the opening of the radiating member and the inner region of the coil pattern overlap almost the entire area when viewed in a plan view from the winding axis direction of the coil pattern, and the area of the opening and the inner region are substantially the same. Device.
The said power feeding member is comprised by the laminated body by which the some dielectric layer was laminated | stacked, The said coil pattern has several winding conductors respectively arrange | positioned at the said several dielectric layer, and has the winding axis in the lamination direction of the said laminated body. An antenna device, characterized in that connected via a helical (interlayer) conductor.
The annular conductor provided in the dielectric layer is formed by a plurality of parallel line conductors arranged at predetermined intervals.
And the coil pattern has a predetermined resonance frequency, and the frequencies of the transmission signal and / or the reception signal substantially correspond to the resonance frequency.
The area of the said radiation member is larger than the area of the part in which the said coil pattern was formed, The antenna apparatus characterized by the above-mentioned.
And an conductor member facing the radiation member, wherein the conductor member and the radiation member are coupled via a capacitance supplemental element.
The capacitance replenishment element is provided between the conductor member and the radiating member, and the capacitance replenishment element is electrically connected to the conductor member, and a capacitance is formed between the capacitance replenishment element and the radiating member. Antenna device.
And the capacitance replenishment element is disposed in close proximity to the slit portion.
And the capacitive replenishment elements are arranged one by one on both sides of the slit portion.
An edge portion of the conductor member and the slit portion overlap each other.
A casing including the power supply member and the radiation member,
The radiation member has an opening portion and a slit portion connected to the opening portion, and the opening portion of the radiation member and the inner region of the coil pattern overlap at least in part when viewed in a plan view from the winding axis direction of the coil pattern. And at least a portion of the radiation member and the coil pattern overlap each other.
And a conductor member opposing the radiation member in the casing, wherein the conductor member and the radiation member are coupled via a capacity replenishment element.
And the conductor member is a ground conductor disposed on a printed wiring board.
KR1020127008125A 2009-11-20 2010-11-18 Antenna device and mobile communication terminal KR101318707B1 (en)
JPJP-P-2009-265219 2009-11-20
KR20120049930A KR20120049930A (en) 2012-05-17
KR101318707B1 true KR101318707B1 (en) 2013-10-17
KR1020127008125A KR101318707B1 (en) 2009-11-20 2010-11-18 Antenna device and mobile communication terminal
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