JP2004007756A - High frequency switch - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a triple-band high frequency switch module capable of switching over transmission circuits and reception circuits of a plurality of transceiver systems which share an antenna. <P>SOLUTION: A high frequency switch for switching over the connection of a transmission circuit common to a first and second transceiver systems with an antenna circuit, the connection of the antenna circuit with a reception circuit of the first transceiver system and the connection of the antenna circuit with a reception circuit of the second transceiver system comprises a first diode disposed between the common transmission circuit and the antenna circuit, a second diode disposed between the antenna circuit and a reception circuit of the first transceiver system, a transmission line disposed between the antenna circuit and the reception circuit of the second transceiver system, and a third diode disposed between the reception circuit of the second transceiver system on the transmission line and the ground. The third diode is connected to the first and the second diodes through the transmission line which is formed as line electrodes in a laminate of a dielectric layer and an electrode pattern, and has dielectric layers with ground electrodes on the upside and downside of the dielectric layer having the line electrodes. <P>COPYRIGHT: (C)2004,JPO

Description

【００３１】
次に、本発明に係る一実施例の平面図を図３に、その実施例の積層体部分の斜視図を図４に、その積層体の内部構造図を図５に示す。この実施例では、分波回路、ローパスフィルタ回路、スイッチ回路の伝送線路を積層体内に構成し、ダイオード、チップコンデンサをその積層体上に搭載して、ワンチップ化されたトリプルバンド用高周波スイッチモジュールを構成したものである。図４に示す斜視部の外部端子に付与したＰ１〜Ｐ１６は、図２の等価回路のＰ２、Ｐ４等のＰ数字と合致している。
【００３２】
この積層体の内部構造について説明する。この積層体は、低温焼成が可能なセラミック誘電体材料からなるグリーンシートを用意し、そのグリーンシート上にＡｇを主体とする導電ペーストを印刷して、所望の電極パターンを形成し、それを適宜積層し、一体焼成させて構成される。
【００３３】
この内部構造を積層順に従って説明する。まず、下層のグリーンシート１１上には、グランド電極３１がほぼ全面に形成されている。そして、側面に形成される端子電極８１、８３、８７、８９、９１、９３、９５に接続するための接続部が設けられている。
【００３４】
次に、電極パターンの印刷されていないダミーのグリーンシート１２を積層する。その上のグリーンシート１３には、１つのライン電極４１が形成され、その上のグリーンシート１４には、４つのライン電極４２、４３、４４、４５が形成され、その上のグリーンシート１５には、４つのライン電極４６、４７、４８、４９が形成されている。その上に、２つのスルーホール電極（図中、十字の印を付けたものがスルーホール電極である、以下同様）が形成されたグリーンシート１６を積層し、その上に、グランド電極３２が形成されたグリーンシート１７が積層される。
【００３５】
この２つのグランド電極３１、３２に挟まれた領域に形成されたライン電極は適宜接続され、第１及び第２のスイッチ回路ＳＷ用の伝送線路を形成している。ライン電極４１と４２と４６はスルーホール電極で接続され、等価回路の伝送線路ＬＧ１を構成し、ライン電極４５と４９はスルーホール電極で接続され、等価回路の伝送線路ＬＧ２を構成し、ライン電極４３と４７はスルーホール電極で接続され、等価回路の伝送線路ＬＰ１を構成し、ライン電極４４と４８はスルーホール電極で接続され、等価回路の伝送線路ＬＰ２を構成している。
【００３６】
グリーンシート１７の上に積層されるグリーンシート１８には、コンデンサ用の電極６１、６２、６３、６４、６５、６６が形成されている。その上に積層されるグリーンシート１９にもコンデンサ用の電極６７、６８、６９が形成されている。その上に積層されるグリーンシート２０には、コンデンサ電極７０が形成されている。
【００３７】
更にその上には、ライン電極５０、５１、５２、５３、５４が形成されたグリーンシート２１が積層され、その上に、ライン電極５５、５６、５７、５８、５９が形成されたグリーンシート２２が積層される。そして、最上部のグリーンシート２３には、搭載素子接続用のランドが形成されている。
【００３８】
上側のグランド電極３２が形成されたグリーンシート１７の上に積層されたグリーンシート１８のコンデンサ用電極の６１、６２、６３、６４、６６は、グランド電極３２との間で容量を形成し、コンデンサ用電極６１は、等価回路のＣＰ３を、コンデンサ用電極６２は、等価回路のＣＰ４を、コンデンサ用電極６３は、等価回路のＣＧ４を、コンデンサ用電極６４は、等価回路のＣＧ３を、コンデンサ用電極６６は、等価回路のＣＦ３を構成している。
【００３９】
またグリーンシート１８、１９、２０に形成されたコンデンサ電極は互の間で容量を形成し、コンデンサ電極６５と６８の間で、等価回路のＣＦ４を構成し、同様にコンデンサ電極６１、６２と６７の間で、等価回路のＣＰ７を構成し、コンデンサ電極６９と７０の間で、等価回路のＣＦ１を構成し、コンデンサ電極６８と７０の間で、等価回路のＣＦ２を構成している。このコンデンサ電極６５では、コンデンサ電極６８と対向して容量を形成するが、このとき、グランド電極３２とは対向しないように、グランド電極３２には、切り欠き部が形成されている。また、この切り欠き部を利用して、伝送線路に導通するスルーホール電極が形成されている。
【００４０】
またグリーンシート２１、２２では、ライン電極５２、５９が等価回路のＬＦ１を構成し、ライン電極５４、５８が等価回路のＬＦ２を構成し、ライン電極５３が等価回路のＬＦ３を構成し、ライン電極５１、５７が等価回路のＬＧ３を構成し、ライン電極５５が等価回路のＬＰ３を構成している。また、ライン電極５０、５６は配線用のラインである。また、ライン電極５１、５７とにより等価回路のＬＧ３を構成しているが、このライン電極５１、５７とは一部対向するように形成され、その対向部分で等価回路のＣＧ７を構成している。
【００４１】
これらのグリーンシートを圧着し、一体焼成して積層体を得た。この積層体の側面に端子電極８１、８２、８３、８４、８５、８６、８７、８８、８９、９０、９１、９２、９３、９４、９５、９６を形成した。この外観図を図４に示す。
【００４２】
この積層体の上に、ダイオードＤＧ１、ＤＧ２、ＤＰ１、ＤＰ２、ＤＰ３、チップコンデンサＣＧ１、ＣＧ６、ＣＧＰ、ＣＰ６、チップ抵抗Ｒ３を搭載した。図３に、この搭載素子を搭載した様子を示す平面図を示す。また、図３に、この高周波スイッチモジュールの実装構成（各端子の接続構造）を合わせて示す。この図３で、ＧＲＤはグランド接続される端子であることを意味する。この実施例では、図２に示す等価回路のうち、ＣＰ２、ＣＰ５、ＣＧ２、ＣＧ５、Ｒ１、ＬＧ、Ｒ２、ＬＰ、ＣＰ７は、この実施例のチップ部品の搭載される回路上に形成される。
【００４３】
この実施例によれば、第１及び第２のスイッチ回路の伝送線路を積層体内に形成する際に、グランド電極で挟まれた領域内に配置している。これにより、スイッチ回路と分波回路、ローパスフィルタ回路との干渉を防いでいる。そして、このグランド電極で挟まれた領域を積層体の下部に配置し、グランド電位を取り易くしている。そして、グランドとの間に接続されるコンデンサを構成する電極を、その上側のグランド電極に対向させて形成している。
【００４４】
また、この実施例では、積層体の側面に各端子が形成され、面実装可能な構造となっている。側面の各端子は、それぞれＡＮＴ端子、ＤＣＳ系／ＰＣＳ系のＴＸ端子、ＧＳＭ系ＴＸ端子、ＧＳＭ系ＲＸ端子、ＤＣＳ系ＲＸ端子、ＰＣＳ系ＲＸ端子、グランド端子（ＧＲＤ）又はコントロール端子（ＶＣ１、ＶＣ２、ＶＣ３）となっている。また、この積層体の各側面には、少なくとも１つのグランド端子が配置されている。
【００４５】
また、この実施例の積層体の側面に形成された端子電極において、アンテナＡＮＴ端子に対して積層体を実装面に垂直な面で２分した反対側に、ＤＣＳ系／ＰＣＳ系のＴＸ端子、ＧＳＭ系ＴＸ端子、ＧＳＭ系ＲＸ端子、ＤＣＳ系ＲＸ端子、ＰＣＳ系ＲＸ端子がそれぞれ形成されている。さらに、そのＴＸ端子群、ＲＸ端子群が形成されているＡＮＴ端子の反対側において、その半分の片側に、送信ＴＸ端子群が形成され、もう一方の片側に受信ＲＸ端子群が形成されている。
【００４６】
また、この実施例では、アンテナＡＮＴ端子はグランド端子で挟まれ、送信ＴＸ端子もグランド端子で挟まれ、受信ＲＸ端子群もグランド端子で挟まれている。また、アンテナＡＮＴ端子、送信ＴＸ端子、受信ＲＸ端子のそれぞれの間にはグランド端子が形成されている。また、ＶＣ１、ＶＣ２、ＶＣ３もグランド端子で挟まれている。
【００４７】
本発明の実施例によれば、ＧＳＭシステムとＤＣＳ１８００システムとＰＣＳシステムの３つのバンドを扱うトリプルバンド携帯電話において、アンテナＡＮＴと、ＧＳＭ系の送信系、受信系、ＤＣＳ１８００系の送信系、受信系、ＰＣＳ系の送信系、受信系を切り換えることができる高周波スイッチモジュールを得ることができた。また、本発明は、上記実施例に限られるものでなく、通過帯域の異なる３つの送受信系を取り扱うトリプルバンド用高周波スイッチモジュールを得ることができるものである。
【００４８】
また、ＤＣＳ系の送信系とＰＣＳ系の送信も分ける回路とすると、スイッチ回路が２つ必要であるが、ＤＣＳ系とＰＣＳ系の送信系の端子を共用とすることにより、スイッチ回路を２個で構成することができる。また、これにより、トリプルバンド用高周波スイッチモジュールのＤＣＳ系とＰＣＳ系の送信系の端子の前段のアンプの共用化も可能となる。
【００４９】
本発明に係る別の実施例の等価回路図を図６に、平面図を図７に、積層体の内部構造図を図８に示す。この実施例は、上記した実施例と類似する部分が多く、異なる部分を説明する。
【００５０】
まず、分波器部分は同一である。第一の送受信系（ＧＳＭ）の第１のスイッチ回路部分もほぼ同一であり、異なるのは、伝送線路ＬＧ１がアースに接続されるのではなく、第２のスイッチ回路の伝送線路ＬＰ１とともに、コントロール回路ＶＣ３に接続されるところである。第２のスイッチ回路においては、ダイオードＤＰ１、ＤＰ２、ＤＰ３（第１乃至第３のダイオード）の向きが逆となっている。そして、ダイオードＤＰ２（第３のダイオード）とコンデンサＣＰ６との間に、インダクタＬＤと抵抗Ｒ３の直列回路を経て、コントロール回路ＶＣ４が接続されている。
【００５１】
積層構造では、グリーンシート１１のグランド電極３１の端子電極８９への接続部を無くしている。グリーンシート１５では、ライン電極４６の引き出し端子が変更されている。グリーンシート１７では、グランド電極３２の端子電極８９への接続部を無くしている。また、グリーンシート２１では、ライン電極７１が追加されている。ライン電極７１は、配線用のラインである。グリーンシート２２では、ライン電極７１に接続されるスルーホールが追加されている。また、グリーンシート２３では、ランド形状が適宜変更されている。
【００５２】
そして、積層体上には、ダイオードＤＧ１、ＤＧ２、ＤＰ１、ＤＰ２、ＤＰ３、チップコンデンサＣＧ１、ＣＧ６、ＣＧＰ、ＣＰ６を搭載した。図７に、この搭載素子を搭載した様子を示す平面図を示す。また、図７に、この高周波スイッチモジュールの実装構成（各端子の接続構造）を合わせて示す。この図７で、ＧＲＤはグランド接続される端子であることを意味する。この実施例では、図６に示す等価回路のうち、ＣＰ２、ＣＰ５、ＣＧ２、ＣＧ５、Ｒ１、ＬＧ、Ｒ２、ＬＰ、ＣＰ７、Ｒ３、ＬＤは、この実施例のチップ部品の搭載される回路上に形成される。
【００５３】
尚、この実施例のスイッチモジュールの各コントロール回路ＶＣ１、ＶＣ２、ＶＣ３、ＶＣ４の制御ロジックを表２に示す。これにより、各モードを変更する。
【００５４】
【表２】

【００５５】
この実施例においても、トリプルバンド用高周波スイッチモジュールとして、上記実施例と同様の効果を有している。
【００５６】
【発明の効果】
本発明によれば、アンテナを共通とし、複数の送受信系の送信回路と受信回路を切り換えることが可能な高周波スイッチを小型に構成することが出来、例えばトリプルバンド携帯電話などにおいて、極めて有益となるトリプルバンド用高周波スイッチモジュールを提供することができる。本発明によれば、このトリプルバンド用高周波スイッチモジュールを、積層構造を用いることにより、小型に、しかもワンチップに構成できるものである。これにより、トリプルバンド携帯電話などにおいて、機器の小型化に有効なものとなる。
【図面の簡単な説明】
【図１】本発明に係る一実施例の回路ブロック図である。
【図２】本発明に係る一実施例の等価回路図である。
【図３】本発明に係る一実施例の平面図である。
【図４】本発明に係る一実施例の積層体の斜視図である。
【図５】本発明に係る一実施例の積層体の内部構造図である。
【図６】本発明に係る別の実施例の等価回路図である。
【図７】本発明に係る別の実施例の平面図である。
【図８】本発明に係る別の実施例の積層体の内部構造図である。
【符号の説明】
１１、１２、１３、１４、１５、１６、１７、１８、１９、２０、２１、２２、２３　誘電体グリーンシート
３１、３２グランド電極
４１、４２、４３、４４、４５、４６、４７、４８、４９、５０、５１、５２、５３、５４、５５、５６、５７、５８、５９、７１　ライン電極
６１、６２、６３、６４、６５、６６、６７、６８、６９、７０　コンデンサ電極
８１、８２、８３、８４、８５、８６、８７、８８、８９、９０、９１、９２、９３、９４、９５、９６　端子電極[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a high-frequency switch that handles a plurality of transmission / reception systems.
[0002]
[Prior art]
2. Description of the Related Art In a digital mobile phone or the like, a high-frequency switch is used to switch a connection between an antenna ANT and a transmission circuit TX and a connection between an antenna ANT and a reception circuit RX. As this high-frequency switch, there is one disclosed in Japanese Patent Application Laid-Open No. Hei 6-197040.
[0003]
This conventional high-frequency switch includes a first diode having an anode connected to the transmission circuit and a cathode connected to the antenna, a strip line connected between the antenna and the reception circuit, and an anode connected to the reception circuit. And a second diode whose cathode is connected to the ground side, the strip line is built in the multilayer substrate, and the first diode and the second diode are mounted on the multilayer substrate. Further, this conventional high-frequency switch simply corresponds to one transmission / reception system (single band).
[0004]
[Problems to be solved by the invention]
In recent years, the spread of mobile phones has been remarkable, and the functions and services of mobile phones have been improved. As a new mobile phone, a dual-band mobile phone, a triple-band mobile phone, and the like have been proposed. The dual-band mobile phone handles two transmission / reception systems while a normal mobile phone handles only one transmission / reception system, and the triple-band mobile phone handles three transmission / reception systems. As a result, the user can select and use a convenient transmission / reception system.
[0005]
In this dual- or triple-band mobile phone, if dedicated circuits are configured for the respective transmission / reception systems, the size and cost of the device are increased. It is advantageous to use a common part as much as possible for the common part to reduce the size and cost of the device.
[0006]
SUMMARY OF THE INVENTION An object of the present invention is to provide a compact high-frequency switch capable of switching between a transmission circuit and a reception circuit of a plurality of transmission / reception systems by using a common antenna, and using the same, three transmission / reception systems having different pass bands are used. The high frequency switch module for triple band to be handled can be constituted by one chip.
[0007]
[Means for Solving the Problems]
The present invention relates to a connection between a transmission circuit common to first and second transmission / reception systems and an antenna side circuit, a connection between the antenna side circuit and a reception circuit of the first transmission / reception system, and a connection between the antenna side circuit and a second transmission / reception system. What is claimed is: 1. A high-frequency switch for switching connection with a receiving circuit of a transmitting / receiving system, comprising: a first diode disposed between said common transmitting circuit and an antenna-side circuit; A second diode disposed between the antenna, the transmission line disposed between the antenna-side circuit and a reception circuit of a second transmission / reception system, and a reception circuit of a second transmission / reception system of the transmission line A third diode disposed between a first side and a ground side, wherein the third diode is connected to the first and second diodes via the transmission line, and the transmission line includes a dielectric. Laminate of layers and electrode patterns In, is formed as a line electrode, the upper and lower forming dielectric layers of the line electrodes, a high frequency switch dielectric layer ground electrode is formed is provided.
Here, it is preferable that the first to third diodes are mounted on the laminate.
[0008]
The present invention also provides a connection between the transmission circuit common to the first and second transmission / reception systems and the antenna circuit, a connection between the antenna circuit and the reception circuit of the first transmission / reception system, and a connection between the antenna circuit and the second transmission / reception system. A high-frequency switch for switching the connection with the receiving circuit of the transmitting / receiving system, comprising: a first diode disposed between the common transmitting circuit and the antenna-side circuit; A second diode disposed between the receiving circuit, a transmission line disposed between the antenna-side circuit and a receiving circuit of a second transmission / reception system, and reception of a second transmission / reception system of the transmission line. A third diode disposed between a circuit side and a ground side, wherein the third diode is connected to the first and second diodes via the transmission line; Product of body layer and electrode pattern The first to third diodes are formed in a body as line electrodes, and the first to third diodes are mounted on the laminate, and the dielectric layer on which the line electrodes are formed and the first to third diodes are mounted. This is a high-frequency switch in which a dielectric layer on which a ground electrode is formed is provided between the switch and a body surface.
[0009]
The present invention also provides a connection between the transmission circuit common to the first and second transmission / reception systems and the antenna circuit, a connection between the antenna circuit and the reception circuit of the first transmission / reception system, and a connection between the antenna circuit and the second transmission / reception system. A high-frequency switch for switching the connection with the receiving circuit of the transmitting / receiving system, comprising: a first diode disposed between the common transmitting circuit and the antenna-side circuit; A second diode disposed between the receiving circuit, a transmission line disposed between the antenna-side circuit and a receiving circuit of a second transmission / reception system, and reception of a second transmission / reception system of the transmission line. A third diode disposed between a circuit side and a ground side, wherein the third diode is connected to the first and second diodes via the transmission line; Product of body layer and electrode pattern Formed as a line electrode in the body, the first to third diodes are mounted on the laminate, and the first and second diodes and the transmission line are connected via a through-hole electrode formed on the laminate. High-frequency switch connected.
Here, a dielectric layer on which a ground electrode is formed is provided between the dielectric layer on which the line electrode is formed and the surface of the laminate on which the first and second diodes are mounted. Preferably, the first and second diodes and the transmission line are connected via a through-hole electrode formed in the dielectric layer on which the ground electrode is formed.
[0010]
In the present invention, the transmission line is connected to a cathode side of the first and second diodes, and is connected to an anode side of the third diode, and the transmission line is connected to the first and second diodes. The second diode can be connected to the anode side and the third diode can be connected to the cathode side. Preferably, the antenna-side circuit is a branching circuit, and the branching circuit is formed of an inductance component and a capacitance component.
[0011]
BEST MODE FOR CARRYING OUT THE INVENTION
The present invention relates to a high-frequency switch that handles a plurality of transmission / reception systems having different passbands, and has a small size by arranging chip components on the multilayer structure. An embodiment of the present invention will be described below based on a triple-band high-frequency switch module configured using the switch circuit of the present invention. This triple-band high-frequency switch module shares a common antenna, and includes a transmission system and a reception system of a first transmission / reception system, a transmission system and a reception system of a second transmission / reception system having a different passband from the first transmission / reception system, This is a triple-band high-frequency switch module capable of connecting the transmission system and the reception system of the third transmission / reception system of different passbands and the antenna and switching them appropriately, and is effective, for example, in a triple-band mobile phone.
[0012]
In the triple-band high-frequency switch module, the first transmission / reception system is separated from the second and third transmission / reception systems by the branching circuit of the antenna-side circuit, and the first switch circuit is provided in the first transmission / reception system. The transmission and reception systems of the first transmission / reception system are provided separately. Further, a second switch circuit (the high-frequency switch of the present invention) is provided in the second and third transmission / reception systems, and a transmission system common to the second and third transmission / reception systems and a reception system of the second transmission / reception system are provided. , The receiving system of the third transmitting / receiving system is divided, and the transmitting terminal of the second transmitting / receiving system and the transmitting terminal of the third transmitting / receiving system are shared.
[0013]
In the present invention, the common terminal of the plurality of transmission / reception systems, the transmission system terminal of each transmission / reception system, and the reception system terminal are formed on the side surface of the multilayer body so that they can be surface-mounted. Each terminal formed on this side surface may be extended to its upper surface or lower surface. At least one ground terminal is formed on each side surface. By arranging the ground terminals on each side surface, it is possible to reduce the loss of the triple-band high-frequency switch module of the present invention.
[0014]
The switch circuit of each transmission / reception system of the present invention can use a diode switch circuit. In this diode switch circuit, a control terminal for applying a predetermined voltage to the diode is used. This control terminal is formed on the side surface of the laminate.
[0015]
Further, in the present invention, it is preferable that the transmission system terminal and the reception system terminal are arranged close to each other in the transmission system terminal and the reception system terminal. In addition, it is preferable that the transmission system terminal and the reception system terminal are respectively arranged in different regions with respect to a center line that is divided into two in the longitudinal direction when the laminate is viewed in the lamination direction. With this configuration, in a device that handles a plurality of transmission / reception systems on which the high-frequency switch module is mounted, it is easy to connect to the transmission system circuit and the reception system circuit, and it is possible to prevent extra loss.
[0016]
In the present invention, it is preferable that the common terminal and the transmission terminal and the reception terminal of each transmission / reception system are formed in different regions when the laminate is divided into two parts by a plane perpendicular to the mounting surface. That is, when the laminated body is viewed in the laminating direction, a common terminal is arranged on one side and a transmitting terminal and a receiving terminal are arranged on the other side with respect to a center line bisected in the lateral direction. Since the high-frequency switch module is disposed between the antenna and the transmission / reception circuit, this terminal arrangement allows the antenna and the high-frequency switch module and the transmission / reception circuit and the high-frequency switch module to be connected with the shortest line, and an extra loss Can be prevented.
[0017]
The laminate of the present invention can incorporate the transmission lines of the branching circuit and the switch circuit. The transmission line of the switch circuit is preferably formed in a region between the ground electrodes. Further, the branching circuit can be configured by an inductance component and a capacitance component. This branching circuit is preferably disposed above the transmission line in the laminate. Then, it is preferable that the capacitance component is disposed further above the ground electrode above the ground electrode sandwiching the transmission line, and the inductance component is disposed further above the ground electrode.
[0018]
In the present invention, it is preferable to provide each transmission system with a low-pass filter function. As one means for providing this low-pass filter function, a low-pass filter circuit can be built in the laminate. This low-pass filter circuit can be composed of an inductance component and a capacitance component. The low-pass filter circuit is preferably disposed above the transmission line in the laminate. That is, it is preferable that the capacitance component is disposed further above the ground electrode above the ground electrode with the transmission line interposed therebetween, and the inductance component is disposed further above the ground electrode. Further, it is preferable that the low-pass filter circuit and the demultiplexing circuit are arranged in different regions in the horizontal direction of the laminate.
[0019]
A cutout portion is provided in the ground electrode above the ground electrode sandwiching the transmission line, and a through-hole conducting to the transmission line is formed in the cutout portion, and the cutout portion is connected to the upper branching circuit and the low-pass filter circuit. be able to.
[0020]
In the present invention, it is preferable to arrange the metal case so as to surround the chip components arranged on the laminate. It is preferable that the metal case is mounted with the terminal electrodes on the side surfaces of the laminate exposed. Further, the metal case can be fixed to the upper surface of the laminate by soldering. Further, the high-frequency switch module of the present invention can be mounted by the mounter device using the metal case.
[0021]
【Example】
FIG. 1 shows a circuit block diagram of a first embodiment according to the present invention. In FIG. 1, the high-frequency switch of the present invention is a lower switch circuit in the figure, and a portion surrounded by a broken line is a triple-band high-frequency switch module. The high-frequency switch module for triple band using the high-frequency switch of the present invention is, for example, a GSM system (TX 880-915 MHz, RX RX 925-960 MHz) as a first transmission / reception system, and a DCS1800 system as a second transmission / reception system. (Transmission TX. 1710 to 1785 MHz, reception RX. 1805 to 1880 MHz), and as a third transmission / reception system, a PCS system (transmission TX. 1850 to 1910 MHz, reception RX. 1930 to 1990 MHz) has a triple configuration. It can be used for distribution between the antenna ANT of the band portable telephone and the respective transmission / reception circuits of the GSM system, the DCS system, and the PCS system. The transmission system of the DCS system and the transmission system of the PCS system are shared.
[0022]
The first embodiment has a demultiplexing circuit for demultiplexing a first transmission / reception system (GSM) and second and third transmission / reception systems (DCS, PCS) from terminals connected to the ANT. A first switch circuit SW for switching between a transmission signal (GSM TX) and a reception signal (GSM RX) of a first transmission / reception system (GSM) separated by a wave circuit, and a transmission line of the first switch circuit. It has a first low-pass filter circuit (LPF) connected. In the second and third transmission / reception systems (DCS, PCS) demultiplexed by the demultiplexing circuit, the reception signal (DCS RX) of the second transmission / reception system (DCS) and the transmission / reception system of the third transmission / reception system (PCS) are used. A second switch circuit SW for switching between a reception signal (PCS RX) and second and third transmission signals (DCS, PCS TX), and a second low-pass connected to the transmission line of the second switch circuit It has a filter circuit (LPF).
[0023]
FIG. 2 shows an equivalent circuit diagram of an embodiment according to the present invention. In the branching circuit portion connected to the antenna ANT, two notch circuits are the main circuit. That is, one notch circuit is formed by the inductor LF1 and the capacitor CF1, and another notch circuit is formed by the inductor LF2 and the capacitor CF2. Further, a capacitor CF3 connected to the ground is connected to one notch circuit. This capacitor CF3 is connected for the purpose of improving the low-pass filter characteristics of the demultiplexing characteristics. The other notch circuit has an inductor LF3 connected to the ground and a capacitor CF4 connected in series. The inductor LF3 and the capacitor CF4 are connected for the purpose of improving the high-pass filter characteristic of the demultiplexing characteristic.
[0024]
This demultiplexing circuit may be only two notch circuits. In addition, for example, a band-pass circuit, a low-pass circuit, a high-pass circuit, or the like, other than the notch circuit, may be used as the branching circuit, and these may be appropriately combined.
[0025]
Next, the first switch circuit will be described. The first switch circuit is a switch circuit on the upper side in FIG. 2 and switches between the GSM transmission circuit TX and the reception circuit RX. This switch circuit has two diodes DG1 and DG2 and two transmission lines LG1 and LG2 as main components. The diode DG1 has an anode connected to the antenna ANT side, a cathode connected to the transmission circuit TX side, and a cathode side thereof. Is connected to a transmission line LG1 connected to the ground. A transmission line LG2 is connected between the antenna side and the receiving circuit RX, a diode DG2 having a cathode connected to the receiving circuit RX is connected, and a capacitor CG6 is connected between the anode of the diode DG2 and the ground. And a series circuit of an inductor LG and a resistor R1 is connected therebetween, and is connected to a control circuit VC1.
[0026]
The low-pass filter circuit inserted on the transmission TX circuit side includes an inductor LG3 and capacitors CG3, CG4, and CG7, and is inserted between the diode DG1 of the switch circuit and the transmission line LG1.
[0027]
Next, a second switch circuit of the high-frequency switch according to the present invention will be described. The second switch circuit is a switch circuit on the lower side of FIG. 2 and switches between a DCS-system receiving circuit RX, a PCS-system receiving circuit RX, and a DCS-system and PCS-system transmitting circuit TX. This switch circuit has three diodes DP1, DP2, DP3 (first to third diodes) and two transmission lines LP1, LP2 as main components, and the diode DP1 (first diode) is a cathode on the antenna ANT side. Is connected to the transmission circuit TX side of the DCS and PCS, and the transmission line LP1 connected to the ground via the capacitor CGP is connected to the anode side. A control circuit VC3 is connected between the transmission line LP1 and the capacitor CGP. The transmission line LP2 is connected between the antenna side and the DCS receiving circuit RX, a diode DP2 (third diode) having an anode connected to the DCS receiving circuit RX side, and a cathode of the diode DP2 is connected to the diode DP2. , And the ground, a capacitor CP6 and a resistor R3 are connected. A diode DP3 (second diode) is connected between the antenna side and the receiving circuit RX of the PCS, a cathode of the diode DP3 is connected to the antenna side, and an anode LP is controlled via an inductor LP and a resistor R2. The circuit VC2 is connected.
[0028]
The low-pass filter circuit inserted on the transmission circuit TX side of the DCS and PCS includes an inductor LP3 and capacitors CP3, CP4, and CP7, and is inserted between the diode DP1 of the switch circuit SW and the transmission line LP1. .
[0029]
Table 1 shows the control logic of each control circuit VC1, VC2, VC3 of the switch module of this embodiment. Thereby, each mode is changed.
[0030]
[Table 1]

[0031]
Next, FIG. 3 is a plan view of an embodiment according to the present invention, FIG. 4 is a perspective view of a laminated body portion of the embodiment, and FIG. 5 is an internal structure diagram of the laminated body. In this embodiment, a transmission line of a demultiplexing circuit, a low-pass filter circuit, and a switch circuit is configured in a multilayer body, and a diode and a chip capacitor are mounted on the multilayer body. It is what constituted. P1 to P16 given to the external terminals of the perspective portion shown in FIG. 4 match P numbers such as P2 and P4 in the equivalent circuit of FIG.
[0032]
The internal structure of the laminate will be described. In this laminate, a green sheet made of a ceramic dielectric material that can be fired at a low temperature is prepared, and a conductive paste mainly composed of Ag is printed on the green sheet to form a desired electrode pattern. It is configured by laminating and integrally firing.
[0033]
This internal structure will be described in the order of lamination. First, the ground electrode 31 is formed on almost the entire surface of the lower green sheet 11. Further, connection portions for connecting to the terminal electrodes 81, 83, 87, 89, 91, 93, 95 formed on the side surfaces are provided.
[0034]
Next, a dummy green sheet 12 on which no electrode pattern is printed is laminated. One line electrode 41 is formed on the green sheet 13 thereon, four line electrodes 42, 43, 44, 45 are formed on the green sheet 14 thereon, and the green sheet 15 thereon is formed on the green sheet 15. , Four line electrodes 46, 47, 48, 49 are formed. A green sheet 16 on which two through-hole electrodes (those marked with a cross in the drawing are through-hole electrodes, the same applies hereinafter) is laminated thereon, and a ground electrode 32 is formed thereon. Green sheets 17 are stacked.
[0035]
Line electrodes formed in a region sandwiched between the two ground electrodes 31 and 32 are appropriately connected to form a transmission line for the first and second switch circuits SW. The line electrodes 41, 42, and 46 are connected by through-hole electrodes to form a transmission line LG1 of an equivalent circuit, and the line electrodes 45 and 49 are connected by through-hole electrodes to form a transmission line LG2 of an equivalent circuit. 43 and 47 are connected by through-hole electrodes to form an equivalent circuit transmission line LP1, and line electrodes 44 and 48 are connected by through-hole electrodes to form an equivalent circuit transmission line LP2.
[0036]
On the green sheet 18 laminated on the green sheet 17, electrodes 61, 62, 63, 64, 65 and 66 for capacitors are formed. Electrodes 67, 68, and 69 for capacitors are also formed on the green sheet 19 laminated thereon. On the green sheet 20 laminated thereon, a capacitor electrode 70 is formed.
[0037]
A green sheet 21 on which line electrodes 50, 51, 52, 53, 54 are formed is further laminated thereon, and a green sheet 22 on which line electrodes 55, 56, 57, 58, 59 are formed. Are laminated. In the uppermost green sheet 23, lands for mounting element connection are formed.
[0038]
Capacitor electrodes 61, 62, 63, 64 and 66 of the green sheet 18 laminated on the green sheet 17 on which the upper ground electrode 32 is formed form a capacitance with the ground electrode 32, The electrode for use 61 is CP3 of the equivalent circuit, the electrode for capacitor 62 is CP4 of the equivalent circuit, the electrode for capacitor 63 is CG4 of the equivalent circuit, the electrode for capacitor 64 is CG3 of the equivalent circuit, and the electrode for capacitor is 66 constitutes the equivalent circuit CF3.
[0039]
The capacitor electrodes formed on the green sheets 18, 19 and 20 form a capacitance between each other, and constitute CF4 of an equivalent circuit between the capacitor electrodes 65 and 68. Similarly, the capacitor electrodes 61, 62 and 67 Constitutes an equivalent circuit CP7, constitutes an equivalent circuit CF1 between the capacitor electrodes 69 and 70, and constitutes an equivalent circuit CF2 between the capacitor electrodes 68 and 70. In the capacitor electrode 65, a capacitance is formed facing the capacitor electrode 68. At this time, a cutout portion is formed in the ground electrode 32 so as not to face the ground electrode 32. In addition, a through-hole electrode that conducts to the transmission line is formed by using the notch.
[0040]
In the green sheets 21 and 22, the line electrodes 52 and 59 constitute the equivalent circuit LF1, the line electrodes 54 and 58 constitute the equivalent circuit LF2, the line electrode 53 constitutes the equivalent circuit LF3, and the line electrode 51 and 57 constitute the equivalent circuit LG3, and the line electrode 55 constitutes the equivalent circuit LP3. The line electrodes 50 and 56 are wiring lines. The line electrodes 51 and 57 constitute the equivalent circuit LG3. The LG3 is formed so as to partially oppose the line electrodes 51 and 57, and the opposing portion constitutes the equivalent circuit CG7. .
[0041]
These green sheets were pressed and fired integrally to obtain a laminate. Terminal electrodes 81, 82, 83, 84, 85, 86, 87, 88, 89, 90, 91, 92, 93, 94, 95, 96 were formed on the side surfaces of the laminate. This external view is shown in FIG.
[0042]
Diodes DG1, DG2, DP1, DP2, DP3, chip capacitors CG1, CG6, CGP, CP6, and a chip resistor R3 were mounted on the stacked body. FIG. 3 is a plan view showing a state where the mounting element is mounted. FIG. 3 also shows the mounting configuration (connection structure of each terminal) of the high-frequency switch module. In FIG. 3, GRD means a terminal connected to the ground. In this embodiment, of the equivalent circuit shown in FIG. 2, CP2, CP5, CG2, CG5, R1, LG, R2, LP, and CP7 are formed on a circuit on which the chip component of this embodiment is mounted.
[0043]
According to this embodiment, when the transmission lines of the first and second switch circuits are formed in the laminate, they are arranged in a region sandwiched between the ground electrodes. This prevents interference between the switch circuit, the demultiplexing circuit, and the low-pass filter circuit. A region sandwiched between the ground electrodes is arranged below the stacked body to make it easier to obtain a ground potential. Then, an electrode constituting a capacitor connected to the ground is formed so as to face the upper ground electrode.
[0044]
Further, in this embodiment, each terminal is formed on the side surface of the laminate, and has a structure that can be surface-mounted. The terminals on the side are ANT terminal, DCS / PCS TX terminal, GSM TX terminal, GSM RX terminal, DCS RX terminal, PCS RX terminal, ground terminal (GRD) or control terminal (VC1, VC2, VC3). Also, at least one ground terminal is disposed on each side surface of the laminate.
[0045]
In the terminal electrode formed on the side surface of the laminate of this embodiment, a DCS / PCS TX terminal is provided on the opposite side of the antenna ANT terminal from which the laminate is bisected by a plane perpendicular to the mounting surface. A GSM TX terminal, a GSM RX terminal, a DCS RX terminal, and a PCS RX terminal are formed respectively. Further, on the opposite side of the ANT terminal on which the TX terminal group and the RX terminal group are formed, a transmission TX terminal group is formed on one half, and a reception RX terminal group is formed on the other half. .
[0046]
In this embodiment, the antenna ANT terminal is interposed between the ground terminals, the transmission TX terminal is interposed between the ground terminals, and the reception RX terminal group is interposed between the ground terminals. In addition, a ground terminal is formed between each of the antenna ANT terminal, the transmission TX terminal, and the reception RX terminal. VC1, VC2, and VC3 are also sandwiched between ground terminals.
[0047]
According to an embodiment of the present invention, in a triple-band mobile phone that handles three bands of a GSM system, a DCS1800 system, and a PCS system, an antenna ANT, a GSM transmission system, a reception system, a DCS1800 transmission system, and a reception system Thus, a high-frequency switch module capable of switching the transmission system and the reception system of the PCS system was obtained. Further, the present invention is not limited to the above embodiment, and can obtain a high frequency switch module for triple band which handles three transmission / reception systems having different pass bands.
[0048]
Further, if a circuit for separating the transmissions of the DCS system and the transmission of the PCS system is required, two switch circuits are required. However, by sharing the terminals of the transmission systems of the DCS system and the PCS system, two switch circuits are required. Can be configured. In addition, this makes it possible to share the amplifier preceding the DCS and PCS transmission system terminals of the triple band high frequency switch module.
[0049]
FIG. 6 shows an equivalent circuit diagram of another embodiment according to the present invention, FIG. 7 shows a plan view thereof, and FIG. 8 shows an internal structure diagram of the laminate. In this embodiment, many parts are similar to the above-described embodiment, and different parts will be described.
[0050]
First, the demultiplexer part is the same. The first switch circuit portion of the first transmission / reception system (GSM) is also substantially the same, except that the transmission line LG1 is not connected to the ground, but is controlled together with the transmission line LP1 of the second switch circuit. It is about to be connected to the circuit VC3. In the second switch circuit, the directions of the diodes DP1, DP2, and DP3 (first to third diodes) are reversed. The control circuit VC4 is connected between the diode DP2 (third diode) and the capacitor CP6 via a series circuit of the inductor LD and the resistor R3.
[0051]
In the laminated structure, the connection between the ground electrode 31 of the green sheet 11 and the terminal electrode 89 is eliminated. In the green sheet 15, the lead terminal of the line electrode 46 is changed. In the green sheet 17, the connection portion of the ground electrode 32 to the terminal electrode 89 is eliminated. In the green sheet 21, a line electrode 71 is added. The line electrode 71 is a line for wiring. In the green sheet 22, a through hole connected to the line electrode 71 is added. In the green sheet 23, the land shape is appropriately changed.
[0052]
Then, diodes DG1, DG2, DP1, DP2, DP3 and chip capacitors CG1, CG6, CGP, CP6 were mounted on the laminate. FIG. 7 is a plan view showing a state where the mounting element is mounted. FIG. 7 also shows a mounting configuration (connection structure of each terminal) of the high-frequency switch module. In FIG. 7, GRD means a terminal connected to the ground. In this embodiment, among the equivalent circuits shown in FIG. 6, CP2, CP5, CG2, CG5, R1, LG, R2, LP, CP7, R3, and LD are mounted on the circuit on which the chip components of this embodiment are mounted. It is formed.
[0053]
Table 2 shows the control logic of each control circuit VC1, VC2, VC3, VC4 of the switch module of this embodiment. Thereby, each mode is changed.
[0054]
[Table 2]

[0055]
This embodiment also has the same effect as the above embodiment as a triple band high frequency switch module.
[0056]
【The invention's effect】
According to the present invention, a high-frequency switch capable of switching between a transmission circuit and a reception circuit of a plurality of transmission / reception systems with a common antenna can be miniaturized, which is extremely useful, for example, in a triple-band mobile phone. A high frequency switch module for triple band can be provided. According to the present invention, the triple-band high-frequency switch module can be made compact and one-chip by using a laminated structure. This is effective for miniaturization of devices such as a triple band mobile phone.
[Brief description of the drawings]
FIG. 1 is a circuit block diagram of one embodiment according to the present invention.
FIG. 2 is an equivalent circuit diagram of one embodiment according to the present invention.
FIG. 3 is a plan view of one embodiment according to the present invention.
FIG. 4 is a perspective view of a laminate according to one embodiment of the present invention.
FIG. 5 is an internal structural view of a laminate according to one embodiment of the present invention.
FIG. 6 is an equivalent circuit diagram of another embodiment according to the present invention.
FIG. 7 is a plan view of another embodiment according to the present invention.
FIG. 8 is an internal structural view of a laminate according to another embodiment of the present invention.
[Explanation of symbols]
11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23 dielectric green sheet 31, 32 ground electrode 41, 42, 43, 44, 45, 46, 47, 48, 49, 50, 51, 52, 53, 54, 55, 56, 57, 58, 59, 71 Line electrodes 61, 62, 63, 64, 65, 66, 67, 68, 69, 70 Capacitor electrodes 81, 82, 83, 84, 85, 86, 87, 88, 89, 90, 91, 92, 93, 94, 95, 96 terminal electrodes

Claims (9)

Connection between a transmission circuit common to the first and second transmission / reception systems and the antenna side circuit, connection between the antenna side circuit and the reception circuit of the first transmission / reception system, reception of the antenna side circuit and the second transmission / reception system A high-frequency switch for switching connection with a circuit,
A first diode disposed between the common transmitting circuit and the antenna-side circuit, a second diode disposed between the antenna-side circuit and a first transmitting / receiving system receiving circuit, A transmission line disposed between the side circuit and the reception circuit of the second transmission / reception system, and a third diode disposed between the reception circuit side of the second transmission / reception system and the ground side of the transmission line. Prepare,
The third diode is connected to the first and second diodes via the transmission line,
The transmission line is formed as a line electrode in a laminate of a dielectric layer and an electrode pattern,
A high-frequency switch, wherein a dielectric layer on which a ground electrode is formed is provided above and below the dielectric layer on which the line electrode is formed. The high-frequency switch according to claim 1, wherein the first to third diodes are mounted on the stacked body. Connection between a transmission circuit common to the first and second transmission / reception systems and the antenna side circuit, connection between the antenna side circuit and the reception circuit of the first transmission / reception system, reception of the antenna side circuit and the second transmission / reception system A high-frequency switch for switching connection with a circuit,
A first diode disposed between the common transmitting circuit and the antenna-side circuit, a second diode disposed between the antenna-side circuit and a first transmitting / receiving system receiving circuit, A transmission line disposed between the side circuit and the reception circuit of the second transmission / reception system, and a third diode disposed between the reception circuit side of the second transmission / reception system and the ground side of the transmission line. Prepare,
The third diode is connected to the first and second diodes via the transmission line,
The transmission line is formed as a line electrode in a laminate of a dielectric layer and an electrode pattern,
The first to third diodes are mounted on the laminate,
A dielectric layer on which a ground electrode is formed is provided between the dielectric layer on which the line electrode is formed and the surface of the laminate on which the first to third diodes are mounted. And high frequency switch. Connection between a transmission circuit common to the first and second transmission / reception systems and the antenna side circuit, connection between the antenna side circuit and the reception circuit of the first transmission / reception system, reception of the antenna side circuit and the second transmission / reception system A high-frequency switch for switching connection with a circuit,
A first diode disposed between the common transmitting circuit and the antenna-side circuit, a second diode disposed between the antenna-side circuit and a first transmitting / receiving system receiving circuit, A transmission line disposed between the side circuit and the reception circuit of the second transmission / reception system, and a third diode disposed between the reception circuit side of the second transmission / reception system and the ground side of the transmission line. Prepare,
The third diode is connected to the first and second diodes via the transmission line,
The transmission line is formed as a line electrode in a laminate of a dielectric layer and an electrode pattern,
The first to third diodes are mounted on the laminate,
The high-frequency switch, wherein the first and second diodes and the transmission line are connected via a through-hole electrode formed in a laminate. A dielectric layer on which a ground electrode is formed is provided between the dielectric layer on which the line electrode is formed and the surface of the laminate on which the first and second diodes are mounted; The high-frequency switch according to claim 4, wherein the first and second diodes and the transmission line are connected via a through-hole electrode formed in a dielectric layer on which an electrode is formed. . The high-frequency switch according to claim 1, wherein the transmission line is connected to cathodes of the first and second diodes, and is connected to an anode of the third diode. The high-frequency switch according to any one of claims 1 to 5, wherein the transmission line is connected to anodes of the first and second diodes, and is connected to a cathode of the third diode. 8. The high-frequency switch according to claim 1, wherein the antenna-side circuit is a branching circuit. The high-frequency switch according to claim 8, wherein the branching circuit is formed by an inductance component and a capacitance component.

Images