JP4072904B2 - High frequency switch - Google Patents

Description

【００２９】
図２は、シングルモード１、すなわち、送信用ポートＴｘとアンテナ用ポートＡＮＴ１のみを繋げた場合の信号伝送経路を示すものである（図２の太線参照）。この場合は、主スイッチング素子３０と送信側パス回路４０のスイッチング素子４２と補助スイッチング素子６９，６５，６６，６８の全部もしくは一部をＯＮ状態にし、残りのスイッチング素子をＯＦＦ状態にする。基本的には、使用していないポートの補助スイッチング素子をＯＮ状態にする。スイッチング素子４１をＯＦＦ状態にすれば、信号はデュプレクサ用ポートＤＵＰ２の方に流れないと考えられるが、実際は、デュプレクサ用ポートＤＵＰ２の方に流れてしまう。そこで、補助スイッチング素子６９，６５，６６，６８をＯＮ状態にしておく。これにより、スイッチング素子４１をＯＦＦ状態にすることによるオープンと、補助スイッチング素子６９，６５，６６，６８をＯＮ状態にすることによるシャント接続との組み合わせで、確実にデュプレクサ用ポートＤＵＰ２への信号の流れを防止する。ただし、必ずしも全部の補助スイッチング素子６９，６５，６６，６８をＯＮ状態にしなくてもよい。なお、図２において、位相補正回路８１，８２は省略されている。以下、図３〜図１４においても同様である。
【００３０】
また、図３は、シングルモード２、すなわち、送信用ポートＴｘとアンテナ用ポートＡＮＴ２のみを繋げた場合の信号伝送経路を示すものである（図３の太線参照）。この場合、主スイッチング素子３１と送信側パス回路４０のスイッチング素子４２と補助スイッチング素子６９，６６，６７，６８の全部もしくは一部をＯＮ状態にし、残りのスイッチング素子をＯＦＦ状態にする。
【００３１】
さらに、図４は、シングルモード３、すなわち、送信用ポートＴｘと外部接続用ポートＥＸＴ１のみを繋げた場合の信号伝送経路を示すものである（図４の太線参照）。この場合、主スイッチング素子２９と送信側パス回路４０のスイッチング素子４２と補助スイッチング素子６９，６５，６６，６７の全部もしくは一部をＯＮ状態にし、残りのスイッチング素子をＯＦＦ状態にする。
【００３２】
以上のように、シングルモード１〜３の送信の際（言い換えると、パケット通信をしないとき）には、送信側パス回路４０のスイッチング素子４１，４２をＯＮ／ＯＦＦ制御して送信信号伝送経路をシングルモード系統にする。これにより、送信信号がデュプレクサ３５の送信側フィルタ３７を通らないようにすることができ、送信時の損失を抑えることができる。この結果、送信電力増幅器の消費電力を抑え、携帯電話の通話時間を長くすることができる。
【００３３】
図５は、シングルモード４、すなわち、受信用ポートＲｘとアンテナ用ポートＡＮＴ１のみを繋げた場合の信号伝送経路を示すものである（図５の太線参照）。この場合は、主スイッチング素子２４と補助スイッチング素子６９，７０，６５，６６，６８の全部もしくは一部をＯＮ状態にし、残りのスイッチング素子をＯＦＦ状態にする。
【００３４】
また、図６は、シングルモード５、すなわち、受信用ポートＲｘとアンテナ用ポートＡＮＴ２のみを繋げた場合の信号伝送経路を示すものである（図６の太線参照）。この場合、主スイッチング素子２２と補助スイッチング素子６９，７０，６６，６７，６８の全部もしくは一部をＯＮ状態にし、残りのスイッチング素子をＯＦＦ状態にする。
【００３５】
さらに、図７は、シングルモード６、すなわち、受信用ポートＲｘと外部接続用ポートＥＸＴ１のみを繋げた場合の信号伝送経路を示すものである（図７の太線参照）。この場合、主スイッチング素子２５と補助スイッチング素子６９，７０，６５，６６，６７の全部もしくは一部をＯＮ状態にし、残りのスイッチング素子をＯＦＦ状態にする。
【００３６】
さらに、図８は、シングルモード７、すなわち、受信用ポートＲｘと外部接続用ポートＥＸＴ２のみを繋げた場合の信号伝送経路を示すものである（図８の太線参照）。この場合、主スイッチング素子２３と補助スイッチング素子６９，７０，６５，６７，６８の全部もしくは一部をＯＮ状態にし、残りのスイッチング素子をＯＦＦ状態にする。
【００３７】
図９は、デュプレクスモード１、すなわち、送受信用ポートＲｘ，Ｔｘを同時に、アンテナ用ポートＡＮＴ１に繋げた場合の信号伝送経路を示すものである（図９の太線参照）。この場合、主スイッチング素子２４，２７と送信側パス回路４０のスイッチング素子４１と補助スイッチング素子７０，６５，６６，６８の全部もしくは一部を同時にＯＮ状態にし、残りのスイッチング素子をＯＦＦ状態にする。
【００３８】
図１０は、デュプレクスモード２、すなわち、受信用ポートＲｘをアンテナ用ポートＡＮＴ２に繋げると同時に、送信用ポートＴｘをアンテナ用ポートＡＮＴ１に繋げた場合の信号伝送経路を示すものである（図１０の太線参照）。この場合、主スイッチング素子２２，２７と送信側パス回路４０のスイッチング素子４１と補助スイッチング素子７０，６６，６８の全部もしくは一部を同時にＯＮ状態にし、残りのスイッチング素子をＯＦＦ状態にする。この場合、受信用ポートＲｘと送信用ポートＴｘはそれぞれ別のアンテナ用ポートＡＮＴ２，ＡＮＴ１に繋がっているため、Ｔｘ−Ｒｘ間のアイソレーションとして、１５〜２０ｄＢ程度ある空中のアイソレーションを使用可能である。このとき、デュプレクサ３５のＴｘ−Ｒｘ間のアイソレーション（減衰）特性を補助することが可能となり、デュプレクサ３５として、より損失の小さいフィルタ３６，３７を使用可能となる。
【００３９】
図１１は、デュプレクスモード３、すなわち、受信用ポートＲｘをアンテナ用ポートＡＮＴ１に繋げると同時に、送信用ポートＴｘをアンテナ用ポートＡＮＴ２に繋げた場合の信号伝送経路を示すものである（図１１の太線参照）。この場合、主スイッチング素子２４，２６と送信側パス回路４０のスイッチング素子４１と補助スイッチング素子７０，６６，６８の全部もしくは一部を同時にＯＮ状態にし、残りのスイッチング素子をＯＦＦ状態にする。この場合、受信用ポートＲｘと送信用ポートＴｘはそれぞれ別のアンテナ用ポートＡＮＴ１，ＡＮＴ２に繋がっているため、Ｔｘ−Ｒｘ間のアイソレーションとして、１５〜２０ｄＢ程度ある空中のアイソレーションを使用可能である。このとき、デュプレクサ３５のＴｘ−Ｒｘ間のアイソレーション（減衰）特性を補助することが可能となり、デュプレクサ３５として、より損失の小さいフィルタ３６，３７を使用可能となる。
【００４０】
図１２は、デュプレクスモード４、すなわち、送受信用ポートＲｘ，Ｔｘを同時に、アンテナ用ポートＡＮＴ２に繋げた場合の信号伝送経路を示すものである（図１２の太線参照）。この場合、主スイッチング素子２２，２６と送信側パス回路４０のスイッチング素子４１と補助スイッチング素子７０，６６，６７，６８の全部もしくは一部を同時にＯＮ状態にし、残りのスイッチング素子をＯＦＦ状態にする。
【００４１】
図１３は、デュプレクスモード５、すなわち、送受信用ポートＲｘ，Ｔｘを同時に、外部接続用ポートＥＸＴ１に繋げた場合の信号伝送経路を示すものである（図１３の太線参照）。この場合、主スイッチング素子２５，２８と送信側パス回路４０のスイッチング素子４１と補助スイッチング素子７０，６５，６６，６７の全部もしくは一部を同時にＯＮ状態にし、残りのスイッチング素子をＯＦＦ状態にする。
【００４２】
図１４は、デュプレクスモード６、すなわち、受信用ポートＲｘを外部接続用ポートＥＸＴ２に繋げると同時に、送信用ポートＴｘを外部接続用ポートＥＸＴ１に繋げた場合の信号伝送経路を示すものである（図１４の太線参照）。この場合、主スイッチング素子２３，２８と送信側パス回路４０のスイッチング素子４１と補助スイッチング素子７０，６５，６７の全部もしくは一部を同時にＯＮ状態にし、残りのスイッチング素子をＯＦＦ状態にする。
【００４３】
以上のように、デュプレクスモード１〜６は、主スイッチング素子２２〜３１などをＯＮ／ＯＦＦ制御することにより、送信用ポートＴｘおよび受信用ポートＲｘを、アンテナ用ポートＡＮＴ１，ＡＮＴ２や外部接続用ポートＥＸＴ１，ＥＸＴ２（同一ポートであってもよい）に同時に接続することができる。この結果、デュプレクスモードに対応可能な高周波スイッチ２１を得ることができる。
【００４４】
さらに、図１０に示したデュプレクスモード２および図１１に示したデュプレクスモード３のように接続した場合には、アンテナ素子６０，６１を介して相手側帯域（送信信号にとっては受信信号帯域、受信信号にとっては送信信号帯域）が妨害波となるが、１０〜１５ｄＢ程度の空中のアイソレーションにより、ある程度の減衰量を確保することができる。この減衰量の分だけ、デュプレクサ３５の減衰特性を軽減することができ、デュプレクサ３５の損失を改善することができる。そして、図１０に示したデュプレクスモード２のように接続した場合にも、同様の作用効果が得られる。
【００４５】
なお、本発明に係る高周波スイッチは前記実施形態に限定するものではなく、その要旨の範囲内で種々に変更することができる。例えば、図１に示した高周波スイッチ２１において、シャント接続された補助スイッチング素子６５〜７０やコンデンサＣ１〜Ｃ６、あるいは、カプラ４５やローパスフィルタ５０などを省いたものであってもよい。逆に、デュプレクサ３５や抵抗Ｒを内蔵した高周波スイッチであってもよい。
【００４６】
また、本発明に係る高周波スイッチは、複数の絶縁体層と、ローパスフィルタ５０のコンデンサ導体やコイル導体、あるいは、カプラ４５の主線路４６や副線路４７の導体などを積層して構成した積層体の表面に、送信用ポートＴｘや受信用ポートＲｘなどの各ポートを設けるとともに、主スイッチング素子２２〜３１のＧａＡｓスイッチを搭載することにより、積層構造のものを得ることができる。また、ＧａＡｓスイッチは複数の制御用端子を備えており、これらを制御するためのＩＣを搭載してもよい。この場合、この制御用ＩＣの入力は、簡略化された制御信号群ですむようになる。
【００４７】
【発明の効果】
以上の説明で明らかなように、本発明によれば、複数の受信信号伝送経路の少なくとも一つと複数の送信信号伝送経路の少なくとも一つとを同時に使用することができる。この結果、デュプレクスモードに対応可能な高周波スイッチを得ることができる。さらに、送信側パス回路は、送信信号伝送経路を、シングルモード系統とデュプレクスモード系統の２系統に分ける機能を有する。そして、シングルモードの送信の際（言い換えると、パケット通信をしないとき）には、送信信号がデュプレクサの送信側フィルタを通らないようにして、送信時の損失を抑えることができる。これにより、送信時の電力増幅器のゲインを抑えることができ、消費電流を低減することが可能となり、電池の使用量を抑えることができる。
【図面の簡単な説明】
【図１】本発明に係る高周波スイッチの一実施形態を示す電気回路図。
【図２】図１に示した高周波スイッチの動作を説明するための電気回路図。
【図３】図１に示した高周波スイッチの別の動作を説明するための電気回路図。
【図４】図１に示した高周波スイッチのさらに別の動作を説明するための電気回路図。
【図５】図１に示した高周波スイッチのさらに別の動作を説明するための電気回路図。
【図６】図１に示した高周波スイッチのさらに別の動作を説明するための電気回路図。
【図７】図１に示した高周波スイッチのさらに別の動作を説明するための電気回路図。
【図８】図１に示した高周波スイッチのさらに別の動作を説明するための電気回路図。
【図９】図１に示した高周波スイッチのさらに別の動作を説明するための電気回路図。
【図１０】図１に示した高周波スイッチのさらに別の動作を説明するための電気回路図。
【図１１】図１に示した高周波スイッチのさらに別の動作を説明するための電気回路図。
【図１２】図１に示した高周波スイッチのさらに別の動作を説明するための電気回路図。
【図１３】図１に示した高周波スイッチのさらに別の動作を説明するための電気回路図。
【図１４】図１に示した高周波スイッチのさらに別の動作を説明するための電気回路図。
【図１５】従来の高周波スイッチを示す電気回路図。
【符号の説明】
２１…高周波スイッチ
２２〜３１…主スイッチング素子
３５…デュプレクサ
３６…受信側フィルタ
３７…送信側フィルタ
４０…送信側パス回路
４１，４２…スイッチング素子
４５…カプラ
４６…主線路
４７…副線路
５０…ローパスフィルタ
６５〜７０…補助スイッチング素子
８１…受信側位相補正回路
８２…送信側位相補正回路
Ｒｘ…受信用ポート
Ｔｘ…送信用ポート
ＡＮＴ１，ＡＮＴ２…アンテナ用ポート
ＥＸＴ１，ＥＸＴ２…外部接続用ポート
ＤＵＰ１，ＤＵＰ２…デュプレクサ用ポート
Ｄ１，Ｄ２…ショットキーダイオード[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a high frequency switch, and more particularly to a high frequency switch used by being incorporated in a mobile communication device such as a mobile phone.
[0002]
[Prior art]
Conventionally, what is shown in FIG. 15 is known as a high frequency switch corresponding to antenna diversity. The high frequency switch 1 includes six switching elements 2 to 7. The transmission port Tx of the high-frequency switch 1 is electrically connected to the antenna port ANT1 via the switching element 6 and electrically connected to the external connection port EXT1 via the switching element 7. Similarly, the reception port Rx is electrically connected to the antenna port ANT2, the external connection port EXT2, the antenna port ANT1, and the external connection port EXT1 through the switching elements 2, 3, 4, and 5, respectively. ing. The antenna ports ANT1 and ANT2 are electrically connected to the antenna elements 10 and 11, respectively.
[0003]
[Problems to be solved by the invention]
In this high-frequency switch 1, the switching elements 2 to 7 are turned ON / OFF to connect the transmission port Tx to the antenna port ANT1 or the external connection port EXT1, or the reception port Rx to the antenna port. It is connected to ANT1, ANT2 or external connection ports EXT1, EXT2. However, since the conventional high-frequency switch 1 is used in a TDMA system, either one of the antenna ports ANT1, ANT2 or the external connection ports EXT1, EXT2 and the transmission / reception ports Tx, Rx are connected. The configuration is such that only one signal transmission path is connected, so-called single mode configuration. For this reason, the conventional high-frequency switch 1 is in a duplex (simultaneous transmission / reception communication) mode in which both the transmission port Tx and the reception port Rx are simultaneously connected to the antenna ports ANT1, ANT2 and the external connection ports EXT1, EXT2. Could not respond.
[0004]
In recent years, in PDC (Personal Digital Cellular) packet communication, which has attracted particular attention, it is expected that the amount of data during reception will be enormous. Therefore, in order to increase the transmission amount at the time of reception, it is necessary to operate the cellular phone in a duplex (simultaneous transmission / reception communication) mode in which reception is performed simultaneously with transmission. However, as described above, the conventional high-frequency switch 1 has a configuration in which only one signal transmission path is connected, and thus cannot support a duplex mode in which two signal transmission paths need to be connected simultaneously. It was.
[0005]
Therefore, an object of the present invention is to provide a high-frequency switch that can support a duplex mode.
[0006]
[Means and Actions for Solving the Problems]
In order to achieve the above object, a high frequency switch according to the present invention comprises:
(A) a reception port connected to the reception circuit and a transmission port connected to the transmission circuit;
(B) a plurality of ports including antenna ports or external connection ports;
(C) a plurality of reception signal transmission paths that connect the reception port and at least one of the antenna port and the external connection port;
(D) a plurality of transmission signal transmission paths that connect the transmission port to at least one of the antenna port and the external connection port;
(E) at least one main switching element connected to each of the reception signal transmission paths and including a path ON / OFF switch;
(F) at least one main switching element connected to each of the transmission signal transmission paths and including a path ON / OFF switch;
(G) a reception-side filter connected between the reception circuit and a main switching element connected on the reception signal transmission path;
(H) a transmission-side filter connected between the transmission circuit and a main switching element connected on the transmission signal transmission path;
(I) said plural Of the multiple main switching elements connected on the received signal transmission path ,and, Above plural Among a plurality of main switching elements connected on the transmission signal transmission path Connected on the reception signal transmission path and the transmission signal transmission path, which should be available at the same time Main switching element of ON / OFF is synchronized and at the same time turned ON so that at least one of the plurality of reception signal transmission paths and at least one of the plurality of transmission signal transmission paths can be used simultaneously,
It is characterized by.
[0007]
Here, a GaAs switch (MOS FET transistor) or the like is used as the plurality of main switching elements. . Duplicate Phase correction of at least one of a reception-side phase correction circuit connected to at least one of the plurality of reception signal transmission paths and a transmission-side phase correction circuit connected to at least one of the plurality of transmission signal transmission paths It is preferable to provide a circuit. Further, a low-pass filter may be connected to at least one transmission path of a plurality of reception signal transmission paths or a plurality of transmission signal transmission paths.
[0008]
With the above configuration, at least one of the plurality of reception signal transmission paths and at least one of the plurality of transmission signal transmission paths can be used at the same time, and a high-frequency switch that can support a duplex (simultaneous transmission / reception communication) mode is obtained.
[0010]
The In addition, It may have a transmission side path circuit for switching a plurality of transmission signal transmission paths. The transmission side path circuit has a function of dividing the transmission signal transmission path into two systems, a single mode system and a duplex mode system. When transmitting in the single mode (in other words, when packet communication is not performed), the transmission signal is prevented from passing through the transmission-side filter of the duplexer to suppress transmission loss. As a result, the gain of the power amplifier at the time of transmission can be suppressed, the current consumption can be reduced, and the battery usage can be suppressed.
[0011]
Furthermore, it is preferable to shunt-connect the auxiliary switching element to at least one transmission path of the plurality of reception signal transmission paths or the plurality of transmission signal transmission paths. This auxiliary switching element prevents load fluctuation when the main switching element is OFF, and prevents deterioration of isolation characteristics when the main switching element is OFF. As the auxiliary switching element, a GaAs switch (MOS FET transistor) or the like is used.
[0012]
Further, a coupler may be provided in at least one of the plurality of transmission signal transmission paths, and a Schottky diode may be connected to the coupler. As a result, the coupler extracts an output proportional to the transmission signal (-10 to -20 dBc power of the transmission signal) as a detection signal. This detection signal is fed back and used for gain control of the transmission power amplifier via an automatic gain control circuit or the like.
[0013]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of a high frequency switch according to the present invention will be described below with reference to the accompanying drawings.
[0014]
As shown in FIG. 1, the high-frequency switch 21 corresponding to antenna diversity is roughly shunt-connected with ten main switching elements 22 to 31, a transmission-side path circuit 40, a coupler 45, and a low-pass filter 50. The auxiliary switching elements 65 to 70 are configured.
[0015]
As the main switching elements 22 to 31, GaAs switches (MOS FET transistors) that can easily synchronize ON / OFF control with each other are used. One end of the main switching element 22 is connected to the antenna port ANT2, one end of the main switching element 23 is connected to the external connection port EXT2, one end of the main switching element 24 is connected to the antenna port ANT1, and the main switching element 25 Is connected to an external connection port EXT1 through a low-pass filter 50. The other ends of the main switching elements 22 to 25 are connected to the reception port Rx.
[0016]
One end of the main switching element 26 is connected to the antenna port ANT2, one end of the main switching element 27 is connected to the antenna port ANT1, and one end of the main switching element 28 is connected to the external connection port EXT1 via the low-pass filter 50. Has been. The other ends of the main switching elements 26 to 28 are connected to the duplexer port DUP1.
[0017]
One end of the main switching element 29 is connected to the external connection port EXT1 through the low-pass filter 50, one end of the main switching element 30 is connected to the antenna port ANT1, and one end of the main switching element 31 is connected to the antenna port ANT2. Has been. The other ends of the main switching elements 29 to 31 are connected to the transmission port Tx via the transmission side path circuit 40 and the coupler 45.
[0018]
Between the ports ANT1, ANT2, EXT1, EXT2 and the main switching elements 22 to 31, series circuits of auxiliary switching elements 65 to 70 and capacitor elements C1 to C6 are shunt-connected, respectively. The auxiliary switching elements 65 to 70 operate in conjunction with the main switching elements 22 to 31 connected to the shunt-connected signal transmission paths and the switching elements 41 and 42 of the transmission side path circuit 40, respectively. These shunt-connected series circuits prevent load fluctuations when the main switching elements 22 to 31 and the like are OFF, and prevent deterioration of isolation characteristics.
[0019]
A reception side filter 36 of a duplexer 35 which is a separate component is connected to the reception port Rx, and a transmission side filter 37 of the duplexer 35 is connected between the duplexer ports DUP1 and DUP2. Instead of using one duplexer 35, a combination of two filters may be used.
[0020]
The transmission-side path circuit 40 has two switching elements 41 and 42 connected in an L shape. One end of the switching element 41 is connected to the duplexer port DUP2, and one end of the switching element 42 is connected to the main switching elements 29 to 31. The other ends of the switching elements 41 and 42 are connected to the transmission port Tx via the coupler 45. The transmission side path circuit 40 is used for dividing the transmission signal transmission path into two systems, a single mode system and a duplex mode system.
[0021]
That is, as will be described in detail later, the transmission signal transmission path becomes a single mode system by turning off the switching element 41 and turning on the switching element 42. In this case, the high frequency switch 21 is used in a single mode configuration. In other words, the transmission / reception ports Tx and Rx are used so that only one signal transmission path is connected to the antenna ports ANT1 and ANT2 and the external connection ports EXT1 and EXT2. In this case, since the transmission signal does not pass through the transmission filter of the duplexer, loss during transmission can be suppressed. On the other hand, when the switching element 41 is turned on and the switching element 42 is turned off, the transmission signal transmission path becomes a duplex mode system. In this case, the high-frequency switch 21 has a duplex mode configuration, in other words, a configuration in which both the transmission port Tx and the reception port Rx are simultaneously connected to either the antenna port ANT1, ANT2 or the external connection port EXT1, EXT2. become.
[0022]
The coupler 45 includes a main line 46 and a sub line 47 that is electromagnetically coupled to the main line 46. The main line 46 is connected between the transmission port Tx and the transmission-side path circuit 40. One end of the sub line 47 is terminated with a resistor R via a port P, and the other end is connected to a detection port DET via a capacitor C8 and two Schottky diodes D1 and D2.
[0023]
The coupler 45, the Schottky diodes D1, D2, and the like constitute a power amount detection circuit for power feedback to the transmission power amplifier. That is, the transmission signal output from the transmission power amplifier (not shown) is transmitted to the main line 46 of the coupler 45 via the transmission port Tx. The sub-line 47 is coupled to the transmission signal transmitted to the main line 46, extracts an output proportional to the transmission signal (power of -10 to -20 dBc of the transmission signal), and an automatic gain control circuit via the detection port DET. (Not shown). The automatic gain control circuit monitors the output taken out from the sub line 47 and controls the gain of the transmission power amplifier.
[0024]
The low-pass filter 50 is connected between the main switching element 28 and the external connection port EXT1. The low-pass filter 50 is not always necessary and may be omitted depending on the specification. The low-pass filter may also be connected between the external connection port EXT2, the antenna ports ANT1 and ANT2, and the main switching elements 23, 27, and 22, respectively.
[0025]
The reception side phase correction circuit 81 is connected between the reception port Rx and the main switching elements 22 to 25. The transmission-side phase correction circuit 82 is connected between the transmission port Tx (more specifically, the duplexer port DUP1) and the main switching elements 26 to 28. The phase correction circuits 81 and 82 are configured by a distributed constant circuit composed of transmission lines, a lumped constant circuit composed of a combination of an inductor and a capacitor, or a delay line. Furthermore, a phase correction circuit may be appropriately provided at the position b in FIG.
[0026]
Next, transmission / reception using the high-frequency switch 21 will be described. As shown in FIG. 1, the high-frequency switch 21 has a main antenna element 60 and a sub-antenna (built-in antenna) element 61 connected to the antenna ports ANT1 and ANT2, respectively, and a data transmission device connected to the external connection ports EXT1 and EXT2, respectively. (Not shown) etc. are connected. On the other hand, a reception circuit (not shown) of a PDC 1500 (packet) is connected to the reception port Rx of the high-frequency switch 21 via a reception-side filter 36 of the duplexer 35, and the PDC 1500 (packet) of the transmission port Tx is connected to the reception port Rx. A transmission circuit (not shown) is connected.
[0027]
As shown in Table 1, this high-frequency switch 21 has a total of 13 signal transmission paths with 7 modes in single mode and 6 modes in duplex mode by ON / OFF control of switching elements 22 to 31, 41, 42, etc. Have. Note that the conventional high-frequency switch 1 shown in FIG. 15 can obtain only a total of six modes of signal transmission paths of single modes 1, 3, 4, 5, 6, and 7 in Table 1.
[0028]
[Table 1]

[0029]
FIG. 2 shows a signal transmission path in the single mode 1, that is, when only the transmission port Tx and the antenna port ANT1 are connected (see the thick line in FIG. 2). In this case, all or part of the main switching element 30, the switching element 42 of the transmission side circuit 40, and the auxiliary switching elements 69, 65, 66, 68 are turned on, and the remaining switching elements are turned off. Basically, auxiliary switching elements of unused ports are turned on. If the switching element 41 is turned off, it is considered that the signal does not flow toward the duplexer port DUP2, but actually, the signal flows toward the duplexer port DUP2. Therefore, the auxiliary switching elements 69, 65, 66, 68 are turned on. Thereby, the combination of the opening by turning off the switching element 41 and the shunt connection by turning on the auxiliary switching elements 69, 65, 66, 68 ensures the signal to the duplexer port DUP2. Prevent flow. However, not all of the auxiliary switching elements 69, 65, 66, 68 need be turned on. In FIG. 2, the phase correction circuits 81 and 82 are omitted. The same applies to FIGS. 3 to 14 below.
[0030]
FIG. 3 shows a signal transmission path in the single mode 2, that is, when only the transmission port Tx and the antenna port ANT2 are connected (see the thick line in FIG. 3). In this case, all or part of the main switching element 31, the switching element 42 of the transmission side path circuit 40, and the auxiliary switching elements 69, 66, 67, 68 are turned on, and the remaining switching elements are turned off.
[0031]
Further, FIG. 4 shows a signal transmission path when the single mode 3, that is, only the transmission port Tx and the external connection port EXT1 are connected (see the thick line in FIG. 4). In this case, all or part of the main switching element 29, the switching element 42 of the transmission side path circuit 40, and the auxiliary switching elements 69, 65, 66, 67 are turned on, and the remaining switching elements are turned off.
[0032]
As described above, at the time of transmission in the single modes 1 to 3 (in other words, when packet communication is not performed), the switching elements 41 and 42 of the transmission side path circuit 40 are ON / OFF controlled to change the transmission signal transmission path. Use single mode. As a result, the transmission signal can be prevented from passing through the transmission-side filter 37 of the duplexer 35, and loss during transmission can be suppressed. As a result, the power consumption of the transmission power amplifier can be suppressed, and the call time of the mobile phone can be extended.
[0033]
FIG. 5 shows a signal transmission path in the single mode 4, that is, when only the reception port Rx and the antenna port ANT1 are connected (see the thick line in FIG. 5). In this case, all or a part of the main switching element 24 and the auxiliary switching elements 69, 70, 65, 66, and 68 are turned on, and the remaining switching elements are turned off.
[0034]
FIG. 6 shows a signal transmission path in the case of the single mode 5, that is, when only the reception port Rx and the antenna port ANT2 are connected (see the thick line in FIG. 6). In this case, all or a part of the main switching element 22 and the auxiliary switching elements 69, 70, 66, 67, 68 are turned on, and the remaining switching elements are turned off.
[0035]
Further, FIG. 7 shows a signal transmission path when the single mode 6 is connected, that is, only the reception port Rx and the external connection port EXT1 are connected (see the thick line in FIG. 7). In this case, all or a part of the main switching element 25 and the auxiliary switching elements 69, 70, 65, 66, and 67 are turned on, and the remaining switching elements are turned off.
[0036]
Furthermore, FIG. 8 shows a signal transmission path when the single mode 7, that is, only the reception port Rx and the external connection port EXT2 are connected (see the thick line in FIG. 8). In this case, all or a part of the main switching element 23 and the auxiliary switching elements 69, 70, 65, 67, 68 are turned on, and the remaining switching elements are turned off.
[0037]
FIG. 9 shows a signal transmission path when duplex mode 1, that is, transmission / reception ports Rx and Tx are simultaneously connected to antenna port ANT1 (see thick lines in FIG. 9). In this case, all or part of the main switching elements 24, 27, the switching element 41 of the transmission side path circuit 40, and the auxiliary switching elements 70, 65, 66, 68 are simultaneously turned on, and the remaining switching elements are turned off. .
[0038]
FIG. 10 shows a signal transmission path in duplex mode 2, that is, when the reception port Rx is connected to the antenna port ANT2, and at the same time the transmission port Tx is connected to the antenna port ANT1 (FIG. 10). (See bold line). In this case, all or part of the main switching elements 22 and 27, the switching element 41 of the transmission side path circuit 40, and the auxiliary switching elements 70, 66 and 68 are simultaneously turned on, and the remaining switching elements are turned off. In this case, since the reception port Rx and the transmission port Tx are connected to different antenna ports ANT2 and ANT1, respectively, an isolation in the air of about 15 to 20 dB can be used as the isolation between Tx and Rx. is there. At this time, the isolation (attenuation) characteristic between the Tx and Rx of the duplexer 35 can be assisted, and the filters 36 and 37 with smaller losses can be used as the duplexer 35.
[0039]
FIG. 11 shows a signal transmission path in duplex mode 3, that is, when the reception port Rx is connected to the antenna port ANT1, and at the same time the transmission port Tx is connected to the antenna port ANT2. (See bold line). In this case, all or part of the main switching elements 24, 26, the switching element 41 of the transmission side path circuit 40, and the auxiliary switching elements 70, 66, 68 are simultaneously turned on, and the remaining switching elements are turned off. In this case, since the reception port Rx and the transmission port Tx are connected to different antenna ports ANT1 and ANT2, respectively, an isolation in the air of about 15 to 20 dB can be used as the isolation between Tx and Rx. is there. At this time, the isolation (attenuation) characteristic between the Tx and Rx of the duplexer 35 can be assisted, and the filters 36 and 37 with smaller losses can be used as the duplexer 35.
[0040]
FIG. 12 shows a signal transmission path when duplex mode 4, that is, transmission / reception ports Rx and Tx are simultaneously connected to antenna port ANT2 (see thick lines in FIG. 12). In this case, all or part of the main switching elements 22, 26, the switching element 41 of the transmission side path circuit 40, and the auxiliary switching elements 70, 66, 67, 68 are simultaneously turned on, and the remaining switching elements are turned off. .
[0041]
FIG. 13 shows a signal transmission path when duplex mode 5, that is, transmission / reception ports Rx and Tx are simultaneously connected to external connection port EXT1 (see thick lines in FIG. 13). In this case, all or part of the main switching elements 25, 28, the switching element 41 of the transmission side path circuit 40, and the auxiliary switching elements 70, 65, 66, 67 are simultaneously turned on, and the remaining switching elements are turned off. .
[0042]
FIG. 14 shows a signal transmission path in duplex mode 6, that is, when the reception port Rx is connected to the external connection port EXT2 and at the same time the transmission port Tx is connected to the external connection port EXT1 (FIG. 14). 14 thick line). In this case, all or part of the main switching elements 23, 28, the switching element 41 of the transmission side path circuit 40, and the auxiliary switching elements 70, 65, 67 are simultaneously turned on, and the remaining switching elements are turned off.
[0043]
As described above, in duplex modes 1 to 6, the main switching elements 22 to 31 and the like are ON / OFF controlled, so that the transmission port Tx and the reception port Rx are connected to the antenna ports ANT1 and ANT2 and the external connection ports. It is possible to connect to EXT1 and EXT2 (which may be the same port) at the same time. As a result, it is possible to obtain the high frequency switch 21 that can support the duplex mode.
[0044]
Further, when connected as in duplex mode 2 shown in FIG. 10 and duplex mode 3 shown in FIG. 11, the other side band (received signal band, received signal for the transmitted signal) is provided via antenna elements 60 and 61. However, a certain amount of attenuation can be secured by isolation in the air of about 10 to 15 dB. The attenuation characteristic of the duplexer 35 can be reduced by this amount of attenuation, and the loss of the duplexer 35 can be improved. Similar effects can be obtained also in the case of connection as in duplex mode 2 shown in FIG.
[0045]
The high-frequency switch according to the present invention is not limited to the above embodiment, and can be variously modified within the scope of the gist. For example, the high-frequency switch 21 shown in FIG. 1 may omit the shunt-connected auxiliary switching elements 65 to 70, the capacitors C1 to C6, the coupler 45, the low-pass filter 50, and the like. Conversely, a high-frequency switch incorporating a duplexer 35 or a resistor R may be used.
[0046]
In addition, the high frequency switch according to the present invention is a laminate in which a plurality of insulator layers and capacitor conductors and coil conductors of the low-pass filter 50 or conductors of the main line 46 and the sub line 47 of the coupler 45 are laminated. By providing each port such as the transmission port Tx and the reception port Rx on the surface, and mounting the GaAs switches of the main switching elements 22 to 31, a layered structure can be obtained. The GaAs switch includes a plurality of control terminals, and an IC for controlling these terminals may be mounted. In this case, the input of the control IC can be a simplified control signal group.
[0047]
【The invention's effect】
As is apparent from the above description, according to the present invention, at least one of a plurality of reception signal transmission paths and at least one of a plurality of transmission signal transmission paths can be used simultaneously. As a result, it is possible to obtain a high-frequency switch that can support the duplex mode. Furthermore, the transmission side path circuit has a function of dividing the transmission signal transmission path into two systems, a single mode system and a duplex mode system. When transmitting in the single mode (in other words, when packet communication is not performed), it is possible to suppress transmission loss by preventing the transmission signal from passing through the transmission-side filter of the duplexer. As a result, the gain of the power amplifier at the time of transmission can be suppressed, the current consumption can be reduced, and the battery usage can be suppressed.
[Brief description of the drawings]
FIG. 1 is an electric circuit diagram showing an embodiment of a high-frequency switch according to the present invention.
2 is an electric circuit diagram for explaining the operation of the high-frequency switch shown in FIG.
FIG. 3 is an electric circuit diagram for explaining another operation of the high frequency switch shown in FIG. 1;
4 is an electric circuit diagram for explaining still another operation of the high-frequency switch shown in FIG. 1. FIG.
5 is an electric circuit diagram for explaining still another operation of the high-frequency switch shown in FIG. 1. FIG.
6 is an electric circuit diagram for explaining still another operation of the high-frequency switch shown in FIG.
7 is an electric circuit diagram for explaining still another operation of the high-frequency switch shown in FIG. 1. FIG.
8 is an electric circuit diagram for explaining still another operation of the high-frequency switch shown in FIG. 1. FIG.
FIG. 9 is an electric circuit diagram for explaining still another operation of the high-frequency switch shown in FIG.
10 is an electric circuit diagram for explaining still another operation of the high-frequency switch shown in FIG. 1. FIG.
11 is an electric circuit diagram for explaining still another operation of the high-frequency switch shown in FIG. 1. FIG.
12 is an electric circuit diagram for explaining still another operation of the high-frequency switch shown in FIG. 1. FIG.
13 is an electric circuit diagram for explaining still another operation of the high-frequency switch shown in FIG. 1. FIG.
14 is an electric circuit diagram for explaining still another operation of the high-frequency switch shown in FIG. 1. FIG.
FIG. 15 is an electric circuit diagram showing a conventional high-frequency switch.
[Explanation of symbols]
21 ... High frequency switch
22 to 31 ... main switching element
35 ... Duplexer
36 ... Reception side filter
37 ... Sending filter
40 ... Transmission side path circuit
41, 42 ... switching elements
45 ... coupler
46 ... Main track
47 ... Sub track
50 ... Low-pass filter
65-70 ... Auxiliary switching element
81. Reception side phase correction circuit
82. Transmission-side phase correction circuit
Rx ... Reception port
Tx: Transmission port
ANT1, ANT2 ... Antenna port
EXT1, EXT2 ... External connection port
DUP1, DUP2 ... Duplexer port
D1, D2 ... Schottky diode

Claims (9)

A receiving port connected to the receiving circuit and a transmitting port connected to the transmitting circuit;
Multiple ports consisting of antenna ports or external connection ports,
A plurality of reception signal transmission paths connecting the reception port and at least one of the antenna port and the external connection port;
A plurality of transmission signal transmission paths connecting the transmission port and at least one of the antenna port and the external connection port;
A main switching element comprising at least one path ON / OFF switch connected to each of the reception signal transmission paths;
A main switching element connected to at least one of the transmission signal transmission paths and including a path ON / OFF switch;
A reception-side filter connected between the reception circuit and a main switching element connected on the reception signal transmission path;
A transmission-side filter connected between the transmission circuit and a main switching element connected on the transmission signal transmission path;
Wherein among the plurality of received signals connected on the transmission path a plurality of main switching elements, and, among the plurality of transmission signals connected on the transmission path a plurality of main switching elements, the received signal should be available as soon the oN / OFF of the connected main switching element on the transmission signal transmission path and the transmission path and simultaneously oN state with synchronizing, at least one at least one said plurality of transmission signal transmission path of the plurality of receiving signal transmission path Having a configuration that allows the two to be used simultaneously,
High frequency switch characterized by A transmission-side path circuit for switching the plurality of transmission signal transmission paths;
Synchronizing ON / OFF of the main switching element for enabling simultaneous use among the plurality of main switching elements and the switching timing of the transmission signal transmission path of the transmission side path circuit,
The high-frequency switch according to claim 1.   3. The high-frequency switch according to claim 1, wherein an auxiliary switching element is shunt-connected to at least one transmission path of the plurality of reception signal transmission paths or the plurality of transmission signal transmission paths.   The high frequency switch according to any one of claims 1 to 3, wherein a coupler is provided in at least one of the plurality of transmission signal transmission paths.   5. The high frequency switch according to claim 4, wherein a Schottky diode is connected to the coupler.   6. The high frequency switch according to claim 1, wherein a low pass filter is connected to at least one transmission path of the plurality of reception signal transmission paths or the plurality of transmission signal transmission paths.   At least one of a reception-side phase correction circuit connected to at least one of the plurality of reception signal transmission paths and a transmission-side phase correction circuit connected to at least one of the plurality of transmission signal transmission paths The high-frequency switch according to claim 1, further comprising a phase correction circuit.   The high-frequency switch according to claim 1, wherein the plurality of main switching elements are GaAs switches.   The high frequency switch according to any one of claims 3 to 7, wherein the plurality of main switching elements and the auxiliary switching elements are GaAs switches.

Images