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JP5647031B2 - High frequency coupler - Google Patents

High frequency coupler Download PDF

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JP5647031B2
JP5647031B2 JP2011041155A JP2011041155A JP5647031B2 JP 5647031 B2 JP5647031 B2 JP 5647031B2 JP 2011041155 A JP2011041155 A JP 2011041155A JP 2011041155 A JP2011041155 A JP 2011041155A JP 5647031 B2 JP5647031 B2 JP 5647031B2
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coil
frequency
transmission
electrode plate
coupling
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JP2012178760A (en
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肇 寺山
肇 寺山
洋一 井戸
洋一 井戸
井上 洋光
洋光 井上
辰夫 戸羽
辰夫 戸羽
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Yazaki Corp
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Description

本発明は、高周波結合器に係り、高周波結合によって通信を可能とする高周波結合器に関する。   The present invention relates to a high frequency coupler, and more particularly to a high frequency coupler that enables communication by high frequency coupling.

超近距離向けの通信技術の一つであるUWB(Ultra Wide Band)は伝送速度が高く、他の無線システムとの共存を図りやすいなどの利点があり、超近距離向け高速通信技術を必要とする様々な分野で有力な技術の一つとして注目されている。そして、UWBを用いた通信を行う情報機器間の高周波結合を効果的に行う技術が開示されている。   UWB (Ultra Wide Band), one of ultra-short-distance communication technologies, has advantages such as high transmission speed and easy coexistence with other wireless systems. It is attracting attention as one of the leading technologies in various fields. And the technique which effectively performs the high frequency coupling between the information apparatuses which communicate using UWB is disclosed.

そのような技術の一つとして、送信機及び受信機の高周波結合器間における電界結合により高周波信号を伝送する通信システムが提案されている(例えば、特許文献1参照)。この通信システムは、図6に示すように、データ処理を行う回路部と高周波信号を静電界若しくは誘導電界として送出する高周波結合器を備えた送受信機と、送信機及び受信機の高周波結合器間におけるインピーダンスの整合をとるインピーダンス整合部を有している。高周波結合器は、極板で構成されている。そして、送信機及び受信機の高周波結合器である極板同士が対向し、2つの極板の間にキャパシタンスが発生すれば通信が可能になる。インピーダンス整合部は、送信機と受信機の極板間すなわち結合部分において、インピーダンス・マッチングをとり、反射波を抑えている。その結果、送信機及び受信機の高周波結合器間において所望の高周波帯域を通過するバンドパス・フィルタとして動作するように構成されている。つまり、送信機と受信機がそれぞれ持つ高周波結合器間における電界結合によりUWB信号を伝送する、高速データ伝送が可能な超近距離通信システムであり、通信したい通信機同士を物理的に近づけることによって、複雑な設定なしに直感的に通信したい相手を選択して通信動作が開始される。その結果、通信相手が近くに存在しないときには、結合関係が生じない、すなわち電波を放射しないので、他の通信システムを妨害することはない。また、遠方から電波が到来してきても、結合器が電波を受信しないので、他の通信システムからの干渉を受けなくて済むという効果を実現している。   As one of such techniques, a communication system that transmits a high-frequency signal by electric field coupling between a high-frequency coupler of a transmitter and a receiver has been proposed (see, for example, Patent Document 1). As shown in FIG. 6, this communication system includes a circuit unit that performs data processing, a transceiver including a high-frequency coupler that transmits a high-frequency signal as an electrostatic field or an induction electric field, and a high-frequency coupler of a transmitter and a receiver. The impedance matching unit for matching the impedance in The high frequency coupler is composed of an electrode plate. And if the pole plates which are the high frequency couplers of the transmitter and the receiver face each other and a capacitance is generated between the two pole plates, communication becomes possible. The impedance matching unit performs impedance matching between the electrode plates of the transmitter and the receiver, that is, at the coupling portion, and suppresses reflected waves. As a result, it is configured to operate as a bandpass filter that passes a desired high frequency band between the high frequency coupler of the transmitter and the receiver. In other words, it is an ultra-short-range communication system capable of high-speed data transmission that transmits UWB signals by electric field coupling between the high-frequency couplers of the transmitter and the receiver. Then, the communication operation is started by selecting the other party who wants to communicate intuitively without complicated settings. As a result, when there is no communication partner in the vicinity, no coupling relationship occurs, that is, no radio waves are radiated, so that other communication systems are not disturbed. In addition, even when radio waves arrive from a distance, the coupler does not receive radio waves, so that it is possible to avoid the interference from other communication systems.

特開2008−271606号公報JP 2008-271606 A

ところで、特許文献1に開示の極板を用いた容量結合方式(図6)では、低周波で広帯域伝送特性を持たせることが難しいという課題があった。例えばUWB以下の周波数で、1GHz以下の数百MHz帯域の信号伝送をする場合、低周波での伝送効率を上げる為に極板サイズを拡大する必要がある。その場合、極板サイズの問題に加えて、帯域の高周波部で信号が減衰する為、広帯域特性を保つことが難しい。逆に、高周波特性を保持する為、極板サイズを抑えた場合、そのまま帯域の低周波部が悪いというトレードオフの関係が生じる。いずれにせよ、帯域中の低周波部か高周波部のいずれかの伝送特性の悪化を妥協しなければならないという課題があった。   By the way, in the capacitive coupling method (FIG. 6) using the electrode plate disclosed in Patent Document 1, there is a problem that it is difficult to provide broadband transmission characteristics at a low frequency. For example, when transmitting a signal in a band of several hundreds of MHz below 1 GHz at a frequency equal to or lower than UWB, it is necessary to enlarge the electrode plate size in order to increase transmission efficiency at a low frequency. In this case, in addition to the problem of the electrode plate size, the signal is attenuated at the high frequency part of the band, so it is difficult to maintain the wide band characteristics. On the contrary, in order to maintain the high frequency characteristics, when the electrode plate size is suppressed, there is a trade-off relationship that the low frequency part of the band is bad as it is. In any case, there is a problem that the deterioration of the transmission characteristics of either the low frequency part or the high frequency part in the band must be compromised.

さらに、伝送する周波数帯域の調節は高周波結合部の電極形状に加え、チップ部品も含めたインピーダンス整合部の形成が必須であり、インピーダンス調節が煩雑で部品コストも要するという課題があった。   Furthermore, in order to adjust the frequency band to be transmitted, in addition to the electrode shape of the high-frequency coupling portion, it is essential to form an impedance matching portion including a chip component, and there is a problem that impedance adjustment is complicated and component costs are required.

本発明は、このような状況に鑑みてなされたものであり、上記の課題を解決する技術を提供することを目的とする。   This invention is made | formed in view of such a condition, and it aims at providing the technique which solves said subject.

本発明の高周波結合器は、基板上に形成されたスパイラル形状かつ非ループ状のコイル部と、前記基板上に形成され、前記コイル部の前記スパイラル形状の内部側の一端に設けられたキャパシタ部と、を備え、前記コイル部と前記キャパシタ部は、高周波結合手段として機能する。
また、前記コイル部と前記キャパシタ部とは、前記基板上の同一面に形成されてもよい
また、前記コイル部と前記キャパシタ部とは、一体にパターンニングされて形成されてもよい。
The high-frequency coupler of the present invention includes a spiral and non-loop coil portion formed on a substrate, and a capacitor portion formed on the substrate and provided at one end on the inside of the spiral shape of the coil portion. The coil part and the capacitor part function as a high frequency coupling means.
The coil part and the capacitor part may be formed on the same surface on the substrate .
The coil part and the capacitor part may be formed by patterning together.

本発明によれば、基板上に形成されたコイルと極板を用いることで、非接触で広帯域にわたって良好な伝送特性を持つ結合器を提供することができる。   According to the present invention, it is possible to provide a coupler having good transmission characteristics over a wide band in a non-contact manner by using a coil and an electrode plate formed on a substrate.

実施形態に係る、高周波結合器の外観を示す図である。It is a figure which shows the external appearance of the high frequency coupler which concerns on embodiment. 実施形態に係る、通信を行う二つの高周波結合器の外観を示す図である。It is a figure which shows the external appearance of the two high frequency couplers which perform communication based on embodiment. 実施形態に係る、高周波結合器の結合原理を示す図である。It is a figure which shows the coupling principle of the high frequency coupler based on embodiment. 実施形態に係る、シミュレーションコイル形状を示す図である。It is a figure which shows the simulation coil shape based on embodiment. 実施形態に係る、広帯域特性に関するシミュレーション結果を示す図である。It is a figure which shows the simulation result regarding a broadband characteristic based on embodiment. 従来技術に係る、高周波結合器の結合原理を示す図である。It is a figure which shows the coupling principle of the high frequency coupler based on a prior art.

以下、発明を実施するための形態(以下、「実施形態」という)を、図面を参照しつつ説明する。本実施形態の概要は次の通りである。   Hereinafter, modes for carrying out the invention (hereinafter referred to as “embodiments”) will be described with reference to the drawings. The outline of the present embodiment is as follows.

図1は、本実施形態に係る高周波結合器10の構成を示す図である。また、図2は、二つの高周波結合器10で通信を行う状態を示した図であり、図2(a)は二つの高周波結合器10が離れており通信ができない状態を示し、図2(b)は二つの高周波結合器10が近接して通信が可能となった状態の外観を示している。   FIG. 1 is a diagram illustrating a configuration of a high-frequency coupler 10 according to the present embodiment. FIG. 2 is a diagram showing a state where communication is performed by two high-frequency couplers 10, and FIG. 2A shows a state where two high-frequency couplers 10 are separated and communication is not possible, and FIG. b) shows the external appearance of a state where two high frequency couplers 10 are close to each other and can communicate with each other.

図1に示すように、高周波結合器10は、スパイラル形状のコイル部30と、コイル形状内部に形成された極板部40と、給電部32とを、備えている。それらは、基板12の一方の面上(表面)に導体を一体としてパターンニングすることによって形成されている。コイル部30と極板部40は、高周波結合部20として機能する。なお、基板12の他方の面(裏面)はグランドに接地される。   As shown in FIG. 1, the high-frequency coupler 10 includes a spiral coil portion 30, an electrode plate portion 40 formed inside the coil shape, and a power feeding portion 32. They are formed by patterning conductors integrally on one surface (surface) of the substrate 12. The coil unit 30 and the electrode plate unit 40 function as the high-frequency coupling unit 20. The other surface (back surface) of the substrate 12 is grounded.

コイル部30は、スパイラル形状のパターンとなっており、具体的には、コイル外周から巻き始まりコイル中央に内包した極板部40に接続する形となっている。ここで、スパイラル形状とは、少なくとも略一周の巻き数を備えていることを想定している。コイル外周の巻き始め部分には、給電部32が接続している。上述のように基板12の裏面はグランドに落ちているが、コイル部30自体はグランドに落ちていない。つまり、ループコイル形式とはなっていない。なお、本実施形態では、スパイラル形状は、8角形によって形成された形状であるが、当然に円形であってもよいし、6角形や4角形などの形状が採用されてもよい。   The coil portion 30 has a spiral pattern. Specifically, the coil portion 30 starts from the outer periphery of the coil and is connected to the electrode plate portion 40 included in the center of the coil. Here, it is assumed that the spiral shape has at least approximately one turn. A power feeding unit 32 is connected to a winding start portion on the outer periphery of the coil. As described above, the back surface of the substrate 12 falls to the ground, but the coil portion 30 itself does not fall to the ground. That is, it is not a loop coil format. In the present embodiment, the spiral shape is an octagonal shape, but naturally it may be a circular shape, or a hexagonal shape or a quadrangular shape may be adopted.

極板部40は、コイル部30が呈するスパイラル形状の中央部分に内包して配置されている。ここでは、極板部40は、正方形の形状となっているが、これに限る趣旨ではなく、円形や、8角形の多角形、さらには、任意の形状とすることもできる。詳細は後述するが、コイル部30に極板部40を追加して設けることで、コイル部30だけの構成における周波数特性を改善することができる。そして、極板部40の形状、大きさを適宜選択することで、改善が必要とされる周波数特性を設定及び調整することができる。   The electrode plate portion 40 is disposed so as to be included in the spiral central portion of the coil portion 30. Here, the electrode plate portion 40 has a square shape, but is not limited to this, and may be a circular shape, an octagonal polygon shape, or an arbitrary shape. Although details will be described later, the frequency characteristics in the configuration of only the coil unit 30 can be improved by providing the coil unit 30 with the electrode plate unit 40 added thereto. And the frequency characteristic which needs an improvement can be set and adjusted by selecting the shape and magnitude | size of the electrode plate part 40 suitably.

給電部32は、グラウンデッドコプレーナウェーブガイドによって50Ωラインで設計されている。   The power feeding section 32 is designed with a 50Ω line by a grounded coplanar waveguide.

そして、高周波結合器10を用いた信号の伝達では、図2(b)に示すように、コイル部30や極板部40などのコイルパターンが形成された基板12をお互い近接させることで、非接触で信号伝送を行う。   In signal transmission using the high-frequency coupler 10, as shown in FIG. 2B, the substrate 12 on which the coil pattern such as the coil portion 30 and the electrode plate portion 40 is formed is brought close to each other. Signal transmission by contact.

以上の構成のように、高周波結合器10にコイル部30と極板部40とを用いることで、コイル部30の磁界結合と極板部40の容量結合の共振により数百MHzの周波数から数GHzの周波数の広帯域伝送が可能となる。つまり、図3の伝送原理に示すように、コイル部30の中央に配された極板部40と、対向する相手側のコイル部30の中央に配置された極板部40とが容量結合し、更に周囲のコイル部30と磁界結合をすることで信号伝達がなされる。   As described above, by using the coil unit 30 and the electrode plate unit 40 in the high-frequency coupler 10, the resonance of the magnetic field coupling of the coil unit 30 and the capacitive coupling of the electrode plate unit 40 causes a frequency from several hundred MHz to several. Broadband transmission with a frequency of GHz is possible. That is, as shown in the transmission principle of FIG. 3, the electrode plate part 40 arranged in the center of the coil part 30 and the electrode plate part 40 arranged in the center of the opposite coil part 30 facing each other are capacitively coupled. Further, signal transmission is performed by magnetic coupling with the surrounding coil unit 30.

一般に、コイルと極板の磁界、電界結合の共振による信号伝送の、それぞれの伝送方式のみでは数百MHzの低周波域を含む広帯域伝送は困難である。UWB帯域の高周波になると、周波数的に信号が放射しやすく波長的に極板も小さく出来る為、容量結合のみでもある程度広帯域伝送が可能である。しかし、GHz以下、例えば100MHz〜200MHz等のMHzの信号伝送を極板での容量結合で行う場合、極板のサイズ拡大の必要性、また極板同士の近接、インピーダンス・マッチング部品が必要という様々な困難性がある。   In general, it is difficult to perform broadband transmission including a low frequency range of several hundreds of MHz by using only the respective transmission methods of signal transmission based on resonance between magnetic field and electric field coupling between a coil and an electrode plate. At high frequencies in the UWB band, signals can be radiated easily in terms of frequency, and the electrode plate can be made smaller in wavelength. However, when signal transmission at GHz or lower, for example, 100 MHz to 200 MHz, is performed by capacitive coupling between the plates, there is a need to increase the size of the plates, the proximity between the plates, and the need for impedance matching parts. There is a difficulty.

そこでコイルのみの磁界結合での伝送が考えられる。コイルによる磁界結合のみの伝送は、一般的に、容量結合による伝送に比べ、数百MHz辺りの伝送特性は良好であり、距離に対する信号減衰も小さい。また、コイルのコイル巻き数が多いほど磁界結合力が増し、低周波の伝送特性が向上するという特徴がある。しかし、巻き数増加させた場合、サイズが大きくなる問題とともにコイルの自己共振周波数の影響から、特性の良い周波数、悪い周波数というように周波数特性が交互に現れ、広帯域にフラットな特性が得られないという課題がある。巻き数を削減すると伝送特性自体が低下して目標の特性を満たさなくなる、というようにコイル単体でも広帯域伝送特性を満たすことは難しい。   Therefore, transmission by magnetic field coupling using only the coil is considered. In general, transmission using only a magnetic field coupling by a coil has better transmission characteristics around several hundred MHz than transmission by capacitive coupling, and signal attenuation with respect to distance is small. In addition, there is a feature that as the number of turns of the coil increases, the magnetic field coupling force increases and the low frequency transmission characteristics are improved. However, when the number of turns is increased, the frequency characteristics appear alternately as a good frequency and a bad frequency due to the effect of the self-resonant frequency of the coil along with the problem of an increase in size, and a flat characteristic cannot be obtained in a wide band. There is a problem. If the number of turns is reduced, the transmission characteristic itself is lowered and the target characteristic is not satisfied. Thus, it is difficult to satisfy the broadband transmission characteristic even with a single coil.

そこで、本実施形態では、高周波結合部20(コイル部30及び極板部40)において、コイル部30の磁界結合のL(インダクタンス)と、極板部40の容量結合のC(キャパシタンス)を用いることで共振を発生させ、良好な広帯域伝送を実現する。特に、この共振の効果は、帯域中の低周波特性を向上に寄与する。   Therefore, in the present embodiment, in the high-frequency coupling unit 20 (the coil unit 30 and the electrode plate unit 40), L (inductance) of magnetic field coupling of the coil unit 30 and C (capacitance) of capacitive coupling of the electrode plate unit 40 are used. This generates resonance and realizes good broadband transmission. In particular, this resonance effect contributes to improving the low frequency characteristics in the band.

図4にシミュレーションモデル形状、図5にそれら形状の広帯域特性に関するシミュレーション結果を示す。シミュレーションモデル形状として4種類例示しており、図示のように、(a)本実施形態の高周波結合器10に対応するC内包コイル、(b)コイル単体、(c)内包C単体、及び(d)コイル同サイズCである。図5は、高周波伝送回路等の評価に一般に用いられることが多いSパラメータのS21特性を示すグラフで、伝送損失を示すものである。S21特性は伝送後の出力電力を入力電力で割り、10logをとったもので、0dBは無損失伝送を示す。つまり、0dBに近いほど、伝送特性が良好となる。本モデルには信号入力部にL(インダクタンス)やC(キャパシタンス)等の整合部品要素は含めておらず、グラフは単純な形状要素での伝送特性を示している。   FIG. 4 shows simulation model shapes, and FIG. 5 shows simulation results regarding the broadband characteristics of these shapes. Four types of simulation model shapes are illustrated. As shown in the drawing, (a) a C-containing coil corresponding to the high-frequency coupler 10 of the present embodiment, (b) a single coil, (c) a single included C, and (d ) Same coil size C. FIG. 5 is a graph showing the S21 characteristic of the S parameter that is generally used for evaluating a high-frequency transmission circuit or the like, and shows transmission loss. The S21 characteristic is obtained by dividing the output power after transmission by the input power and taking 10 logs, and 0 dB indicates lossless transmission. That is, the closer to 0 dB, the better the transmission characteristics. This model does not include matching component elements such as L (inductance) and C (capacitance) in the signal input section, and the graph shows transmission characteristics with simple shape elements.

シミュレーションは、図2で示したように、高周波結合器10同士を対向して配置することで行った。端子間距離は0.8mmで固定した。まず、内包コイル単体のみの伝送特性について説明する。一般には極板間の距離拡大と共に急激信号が減衰する傾向があるが、ここで例示する0.8mmの距離では、減衰が大きく、コイル単体の特性より悪いことが分かる。コイル内包C単体特性も減衰が大きい為、この距離ではC(キャパシタンス)のみでの効率よい伝送は困難なことが分かる。   The simulation was performed by arranging the high frequency couplers 10 to face each other as shown in FIG. The distance between terminals was fixed at 0.8 mm. First, the transmission characteristics of only the included coil will be described. Generally, there is a tendency that the signal suddenly attenuates as the distance between the electrode plates increases, but at the distance of 0.8 mm exemplified here, the attenuation is large and it is understood that the characteristics are worse than the characteristics of the single coil. Since the characteristic of the coil inclusion C alone is also greatly attenuated, it can be understood that efficient transmission using only C (capacitance) is difficult at this distance.

次に、コイル単体の特性について説明する。図示のように、100MHz〜300MHzあたりの特性が悪化している。この帯域を改善するには、コイル巻き数増による磁界結合力を上げる方策が考えられるが、コイル長延長による信号減衰、コイルの自己共振による周波数特性が発生し、広帯域にわたってフラットな伝送特性を保てなくなる。   Next, the characteristics of a single coil will be described. As shown, the characteristics around 100 MHz to 300 MHz are deteriorated. In order to improve this band, measures to increase the magnetic field coupling force by increasing the number of coil turns can be considered. However, signal attenuation due to coil length extension and frequency characteristics due to coil self-resonance occur, and flat transmission characteristics are maintained over a wide band. It ’s gone.

つづいて、本実施形態の高周波結合器10に対応するC内包コイルについて説明する。C内包コイルでは、コイル部30のL(インダクタンス)とコイル中央に位置する極板部40によるC(キャパシタンス)の共振特性より、100MHz〜300MHzの伝送特性が改善され、広帯域にわたって良好な伝送特性を保つことが可能となっている。つまり、低周波域以外の周波数帯域では、コイル部30のみの伝送特性が主とし貢献している。そして、低周波域では、コイル部30のL(インダクタンス)と中央に配置された極板部40のC(キャパシタンス)とによって発生する弱い共振が、L(インダクタンス)のみでの伝送では困難な低周波域の伝送を可能としている。   It continues and demonstrates the C inclusion coil corresponding to the high frequency coupler 10 of this embodiment. In the C inclusion coil, the transmission characteristic of 100 MHz to 300 MHz is improved from the L (inductance) of the coil part 30 and the resonance characteristic of C (capacitance) by the electrode plate part 40 located in the center of the coil, and a good transmission characteristic over a wide band. It is possible to keep. That is, in the frequency band other than the low frequency range, the transmission characteristic of only the coil unit 30 mainly contributes. In the low frequency range, the weak resonance generated by L (inductance) of the coil portion 30 and C (capacitance) of the electrode plate portion 40 disposed in the center is low, which is difficult to transmit only by L (inductance). Transmission in the frequency range is possible.

以上、本実施形態をまとめと、次の様な効果を得られる。
(1)スパイラル形状のコイル部30による磁界結合と極板部40の電界結合による共振で、数百MHz〜数GHzの広帯域伝送を小型の結合部で実現することができる。
(2)コイル部30の磁界結合での数百MHz前後の良好な特性と、極板部40による電界での容量結合のもつ広帯域性というそれぞれの両方のメリットを合わせ持つ高周波結合器10を実現できる。
(3)従来技術では高周波結合部に加え、インピーダンスを調節する為のインピーダンス整合部が必要である。本発明は、結合部においてコイル部30のL(インダクタンス)、極板部40でのC(キャパシタンス)の要素を含んでいる為、コイル部30の形状でインピーダンス整合が可能である。つまり、高周波結合部20のパターンの形状設計次第で整合部を必要としない高周波結合器10を実現できる。
(4)アナログ、デジタル両方の元信号伝送を可能とする。デジタルのパルス信号伝送に関して、従来技術の極板による容量結合方式では広帯域の伝送特性を持たずパルス伝送は困難なことから変調等を行う必要が生じるが、本実施形態ではその処理が不要である。
(5)コイル部30のサイズの拡大により、更に低周波での広帯域特性を持たせることが可能であり、非接触での給電コイルへの適用の可能である。
As described above, this embodiment can be summarized and the following effects can be obtained.
(1) Broadband transmission of several hundred MHz to several GHz can be realized with a small coupling portion by resonance by magnetic field coupling by the spiral coil portion 30 and electric field coupling of the electrode plate portion 40.
(2) Realization of the high-frequency coupler 10 having both of the good characteristics of several hundred MHz in the magnetic field coupling of the coil section 30 and the wide band characteristic of the capacitive coupling in the electric field by the electrode plate section 40. it can.
(3) In the prior art, an impedance matching unit for adjusting the impedance is required in addition to the high frequency coupling unit. Since the present invention includes elements of L (inductance) of the coil section 30 and C (capacitance) of the electrode plate section 40 in the coupling section, impedance matching is possible with the shape of the coil section 30. That is, the high-frequency coupler 10 that does not require a matching unit can be realized depending on the shape design of the pattern of the high-frequency coupling unit 20.
(4) Both analog and digital original signal transmission is enabled. Regarding digital pulse signal transmission, the capacitive coupling method using the electrode plate of the prior art does not have a broadband transmission characteristic and pulse transmission is difficult, so that it is necessary to perform modulation or the like, but this embodiment does not require such processing. .
(5) By expanding the size of the coil section 30, it is possible to have a broadband characteristic at a lower frequency, and it can be applied to a power supply coil in a non-contact manner.

以上、本発明を実施形態を基に説明した。この実施形態は例示であり、それらの各構成要素及びその組合せにいろいろな変形例が可能なこと、またそうした変形例も本発明の範囲にあることは当業者に理解されるところである。例えば、高周波結合器10では、極板部40の位置は、コイル部30の内部に配置されたが、コイル部30の外周部分や、スパイラル形状の途中に設けられてもよい。また、極板部40が別体のパターンとして形成されてもよい。周波数特性を改善したい帯域にあわせて設計することができ、また、その形状の調整、変更等が容易である。   The present invention has been described based on the embodiments. This embodiment is an exemplification, and it is understood by those skilled in the art that various modifications can be made to each of those components and combinations thereof, and such modifications are also within the scope of the present invention. For example, in the high frequency coupler 10, the position of the electrode plate portion 40 is disposed inside the coil portion 30, but may be provided in the outer peripheral portion of the coil portion 30 or in the middle of the spiral shape. Moreover, the electrode plate part 40 may be formed as a separate pattern. The frequency characteristics can be designed according to the desired band and the shape can be easily adjusted and changed.

なお、本発明は、日本国独立行政法人科学技術振興機構(JST)平成21年度委託開発採択課題「電磁界結合を利用した非接触コネクタの開発」の研究開発の成果にかかるものである。   Note that the present invention relates to the results of research and development of the Japan Science and Technology Agency (JST) 2009 Consignment Development Adoption Project “Development of Contactless Connectors Using Electromagnetic Field Coupling”.

10 高周波結合器
12 基板
20 高周波結合部
30 コイル部
40 極板部
DESCRIPTION OF SYMBOLS 10 High frequency coupler 12 Board | substrate 20 High frequency coupling part 30 Coil part 40 Electrode board part

Claims (3)

基板上に形成されたスパイラル形状かつ非ループ状のコイル部と、
前記基板上に形成され、前記コイル部の前記スパイラル形状の内部側の一端に設けられたキャパシタ部と、
を備え、
前記コイル部と前記キャパシタ部は、高周波結合手段として機能することを特徴とする高周波結合器。
A spiral and non-loop coil portion formed on the substrate;
A capacitor portion formed on the substrate and provided at one end of the coil portion on the inner side of the spiral shape ;
With
The coil unit and the capacitor unit function as high-frequency coupling means.
前記コイル部と前記キャパシタ部とは、前記基板上の同一面に形成されていることを特徴とする請求項1に記載の高周波結合器。   2. The high frequency coupler according to claim 1, wherein the coil part and the capacitor part are formed on the same surface on the substrate. 前記コイル部と前記キャパシタ部とは、一体にパターンニングされて形成されていることを特徴とする請求項1または2に記載の高周波結合器。 The high-frequency coupler according to claim 1 or 2, wherein the coil part and the capacitor part are integrally patterned .
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