JP2014042345A - High frequency switch circuit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a switch circuit that has low loss and high isolation characteristics, suppresses an increase in the number of inductors and copes with a multiband application.SOLUTION: In the high frequency switch circuit having a plurality of switch sections for controlling a high frequency signal between a plurality of high frequency terminals with a potential of one or more control terminals, an inductor circuit is connected between a high frequency terminal common to the plurality of switch sections and a ground terminal, a variable capacitance circuit is connected between the high frequency terminal common to the plurality of switch sections and the ground terminal, and the inductor circuit and the variable capacitance circuit are connected in parallel.

Description

  The present invention relates to a high frequency switch circuit.

  As a switch circuit for controlling (passing or blocking) a high-frequency signal, a circuit using a diode or a circuit using a field effect transistor (FET) is known.

  An example of a switch circuit using an FET (SP3T (single pole three (or triple) through) type switch circuit)) is shown in FIG. The SP3T type switch circuit includes a first switch unit 21, a second switch unit 22, and a third switch unit 23. The switch units 21, 22, and 23 are SPST (single pole single through) type switches that control high-frequency signals. The first switch unit 21 is provided between the first high frequency terminal 1 and the second high frequency terminal 2. The second switch unit 22 is provided between the first high-frequency terminal 1 and the third high-frequency terminal 3. The third switch unit 23 is provided between the first high frequency terminal 1 and the fourth high frequency terminal 4. The first switch unit 21, the second switch unit 22, and the third switch unit 23 share the first high-frequency terminal 1 for high-frequency signal input / output.

  The first switch unit 21 includes a plurality (for example, three) of FETs 31, 32, and 33. The FETs 31, 32, and 33 are connected in series. That is, the drain (or source) and the adjacent source (or drain) are connected. The FETs 31 and 33 at both ends are connected to the high frequency terminals 1 and 2. The gate electrodes of the FETs 31, 32, and 33 are connected to the control terminal 11 through resistance elements 41, 42, and 43.

  The second switch unit 22 includes a plurality of (for example, three) FETs 34, 35, and 36. The FETs 34, 35, and 36 are connected in series. That is, the drain (or source) and the adjacent source (or drain) are connected. The FETs 34 and 36 at both ends are connected to the high frequency terminals 1 and 3. The gate electrodes of the FETs 34, 35, and 36 are connected to the control terminal 12 through resistance elements 44, 45, and 46.

  The third switch unit 23 includes a plurality of (for example, three) FETs 37, 38, and 39. The FETs 37, 38, and 39 are connected in series. That is, the drain (or source) and the adjacent source (or drain) are connected. The FETs 37 and 39 at both ends are connected to the high frequency terminals 1 and 4. The gate electrodes of the FETs 37, 38 and 39 are connected to the control terminal 13 through resistance elements 47, 48 and 49.

  The gate electrodes of the FETs 31 to 39 are formed with a large gate width in order to suppress the on-resistance in the on state. The resistance elements 41 to 49 connected to the gate electrodes of the FETs 31 to 39 have high resistance (several kΩ to several hundred kΩ).

  The operation of the switch circuit of FIG. 12 will be described.

  A high level signal is input to any one of the control terminals 11, 12, and 13, and a low level control signal is input to the other two terminals, whereby the first switch unit 21, the second switch unit 22, And on / off of the 3rd switch part 23 is controlled. When a high level signal is input to any one of the control terminals 11, 12, and 13 and a low level binary control signal is complementarily input to the remaining two control terminals, the signal is input from the first high frequency terminal 1. The high frequency signal is output from any one of the high frequency terminals 2, 3 and 4. Conversely, any one high-frequency signal input from the high-frequency terminals 2, 3, 4 is output from the high-frequency terminal 1.

As the performance required for the switch circuit of FIG.
(1) Low passage loss of high frequency signals,
(2) It is mentioned that the isolation between high frequency terminals is large.

  The passage loss and isolation of the switch circuit depend on the resistance value of the path through which the signal of the switch circuit passes and the values of various capacitors connected to the path. In the high frequency switch, since the passing frequency is high, the power leaking through the connected capacitor cannot be ignored from the resistance value. For this reason, it is essential to reduce the capacity. In order to reduce the capacitance, it is important to reduce the gate width of the FET. However, reducing the gate width increases the on-state resistance. For this reason, there is a trade-off relationship.

  An example of a switch circuit using CMOS is shown in FIG. When CMOS is used, the above trade-off relationship appears remarkably. A substrate electrode (back gate) exists in an FET using a CMOS. For this reason, there is a signal leak via the back gate. Therefore, a method of shielding by the n layers 102 and 103 (referred to as the deep N-well name because the n layer is driven deep in the substrate) is used (see FIG. 18). Even in this case, a capacitance of a pn junction exists (see FIG. 18). There is a problem of signal leakage via the above-described capacity.

  An example of the SP3T switch circuit is shown in FIG. In this switch circuit, inductors 51 to 59 are connected in parallel to FETs 31 to 39 of the switch circuit of FIG. In this switch circuit, loss and isolation of a switch circuit having a large capacity is reduced.

  The operation of the switch circuit of FIG. 13 will be described.

The operation mechanism of the SP3T switch circuit of FIG. 13 and the operation mechanism of the switch circuit of FIG. 12 are basically the same. However, the inductors 51 to 59 exhibit operations different from those of the circuit of FIG. 12 in terms of loss and isolation during high-frequency signal passage. Inductors 51-59 and FETs 31-39 are connected in parallel. When the FET is in an off state, the FET can be regarded as a capacitive element. As a result, a parallel resonance phenomenon between the inductor and the capacitor occurs. The impedance is ideally infinite, and there is no leakage via the capacitance at the resonance frequency. The resonance frequency f is represented by 1 / {2π (LC) ^1/2 } [where, the capacitance when the FET is off is Cfet, and the value of the inductor is L]. There is a switch circuit that utilizes the principle of parallel resonance of such an inductor and a capacitor. These switch circuits are referred to herein as “LC resonant switch circuits”. The LC resonant switch circuit is disclosed in the following patent document.

Japanese Utility Model Publication No. 03-120102 JP-A-10-270903 JP 2002-271103 A JP 2005-31447 A Japanese Patent Laid-Open No. 11-046101 JP 2001-007604 A JP 2004-289228 A Japanese Patent Application Laid-Open No. 11-074703 JP 09-181641 A JP 2003-318717 A Japanese Patent Laid-Open No. 2004-207437

  When the frequency is high or the capacity (due to the relationship of the semiconductor material used) is large, the switch circuit of FIG. 12 is difficult to use. In such a case, a parallel resonant switch circuit (LC resonant switch circuit: see FIG. 13) is used.

  This LC resonant switch circuit has two major problems in its circuit configuration.

  The first problem is the area occupied by the inductor used. For example, in the case of FIG. 13, nine inductors are required. Even in the case of FIG. 14, three inductors are required. That is, the number of inductors is large. Therefore, a large area is required. As a result, the manufacturing cost increases.

  The second problem is that since a parallel resonant circuit (inductor element and capacitive element) is used, the frequency characteristic at the resonance frequency is good, but the frequency characteristic other than the resonance frequency is deteriorated. Usually, the semiconductor switch is used for a wireless device (for example, a mobile phone) or the like. Recent mobile phones require multi-band support and multi-mode support. For this reason, the switch also handles signals of a plurality of frequencies. However, in the LC resonance switch circuit, the resonance frequency is one. And it cannot cope with a plurality of frequencies. For this reason, it was difficult to support multiband and multimode.

  Below, the relationship between the switch circuit of the said patent document and the said problem is demonstrated concretely.

  The switch circuit of Patent Documents 1, 2, 3, and 4 is basically the circuit of FIG. As described above, this switch circuit cannot solve the first and second problems.

  The switch circuits of Patent Documents 5 and 6 are circuits in which an inductor and a capacitor are connected in parallel to an FET. This circuit has a slight effect of stabilizing the resonance frequency and reducing the inductor size. However, this is basically the same as Patent Documents 1, 2, 3, and 4. This switch circuit also cannot solve the first and second problems.

  The switch circuit of Patent Document 7 is a circuit in which a series circuit of an inductor element and a capacitor element is connected to an FET. This circuit uses series resonance to improve the characteristics when the switch circuit is in the ON state. However, there is only one resonance frequency. This switch circuit cannot solve the first and second problems as well as the switch circuits disclosed in Patent Documents 1-6.

  The switch circuit of Patent Document 8 is a circuit in which the switch circuits of FIGS. This switch circuit is a circuit in which a plurality of inductors are connected to a high-frequency terminal, and the other terminal of the inductor is grounded. In the switch circuit of FIG. 14, the high-frequency terminal of the switch in the off state is terminated with a termination resistor when in use. For this reason, the inductor element of FIG. 14 has substantially the same configuration even when connected between the RF terminal and GND. Therefore, this switch circuit cannot solve the first and second problems.

  The switch circuit of Patent Document 9 is an improved version of the switch circuit of Patent Document 8. It can be considered that the plurality of inductors of Patent Document 8 are bundled into one. Patent Document 9 proposes connecting a variable capacitor and changing the variable capacitor. However, there is no description about the specific method. [0029] of Patent Document 9 has a description “For example, a configuration in which a diode or the like is voltage-controlled to make its junction capacitance variable” or the like can be used. However, in an actual switch circuit, an amplitude of several volts may pass. Therefore, it is not possible to use an element whose capacitance changes with a bias applied between terminals, such as a junction capacitance. That is, even in this case, the second problem “difficult to cope with multiband / multimode” cannot be solved. In other words, Patent Document 9 does not have an idea of having a plurality of resonance frequencies.

  In Patent Document 10, the inductor is varied by a switch, and the resonance frequency changes. In this method, a plurality of resonance frequencies can be switched. Therefore, the second problem can be solved. However, conversely, the number of FETs and inductor elements for switching the inductor increases. For this reason, the first problem occurs. That is, in the switch circuit of Patent Document 10, the area of the inductor switching switch and the inductor portion increases depending on the number of switching frequencies. Therefore, the switch circuit of Patent Document 10 has a trade-off relationship between the first problem and the second problem. There is no fundamental solution.

  Patent Document 11 shows a countermeasure against substrate leakage in a CMOS switch. That is, in order to prevent leakage through the substrate, the n-type semiconductor 103 blocks the gap between the p-type semiconductor substrate 105 and the p-type semiconductor 104 having the back gate terminal (see FIG. 18). By supplying power to the internal p-type semiconductor 104, the circuit shown in FIG. 16 (corresponding to FIG. 4 in Patent Document 11) can be realized. However, in this method, although a direct current can be prevented, a capacitance is generated at the pn junction between the adjacent n layers 103. This results in a high frequency leak path. The circuit of FIG. 17 is a circuit corresponding to FIG. This circuit uses an inductor element instead of a resistor. Thereby, leakage can be prevented by LC resonance. However, the first and second problems are not solved.

  Therefore, the problem to be solved by the present invention is to solve the first and second problems. That is, it is to provide a switch circuit that has characteristics of low loss and high isolation, can suppress an increase in the number of inductors, and can be used for multiband applications.

The problem is
A high-frequency switch circuit having a plurality of switch units for controlling a high-frequency signal between a plurality of high-frequency terminals by the potential of one or more control terminals,
An inductor circuit is connected between a high-frequency terminal common to the plurality of switch parts and a ground terminal,
A variable capacitance circuit is connected between a high-frequency terminal common to the plurality of switch parts and a ground terminal,
The inductor circuit and the variable capacitance circuit are solved by a switch circuit that is connected in parallel.

  The switch circuit of the present invention has characteristics of low loss and high isolation. In addition, the number of inductors is small and the cost is low. It has a plurality of resonance frequencies and can support multiband and multimode.

The circuit diagram which shows the structure of the switch circuit of 1st reference embodiment A circuit diagram showing composition of a switch circuit of a 1st embodiment Circuit diagram showing an example of the first embodiment Circuit diagram showing the configuration of the switch circuit of the second reference embodiment A circuit diagram showing composition of a switch circuit of a 2nd embodiment. Circuit diagram showing an example of the second embodiment Circuit diagram showing configuration example of inductor circuit Circuit diagram showing configuration example of inductor circuit Circuit diagram showing configuration example of inductor circuit Circuit diagram showing configuration example of inductor circuit Circuit diagram showing configuration example of inductor circuit Circuit diagram showing switch circuit Circuit diagram of switch circuit using parallel resonance of inductor and capacitance Circuit diagram of switch circuit using parallel resonance of inductor and capacitance Circuit diagram of switch circuit using CMOS Circuit diagram of switch circuit using CMOS Circuit diagram of switch circuit using CMOS Schematic cross-sectional view of a semiconductor used in a CMOS switch circuit

  The present invention is a high-frequency switch circuit. In particular, it is a high-frequency switch circuit having a plurality of switch units for controlling a high-frequency signal between a plurality of high-frequency terminals (for example, controlling passage or blocking) by the potential of one or more control terminals. A circuit constituting an inductor element is connected between a high frequency terminal and a ground terminal common to the plurality of switch portions. A circuit constituting a variable capacitance element is connected between the plurality of high frequency terminals. Alternatively, an inductor that uses the principle that the impedance increases at the resonance point of the parallel resonance circuit of the inductor and capacitor in order to improve the introduction loss and cutoff characteristics of the high-frequency signal path between the high-frequency terminals where the high-frequency signal can pass A circuit constituting the element and a circuit constituting the capacitive element are connected between the high-frequency signal path and the ground terminal. The resonance frequency of the high-frequency switch circuit is changed by changing the capacitance value of the circuit including the capacitive element in the high-frequency signal path selected by the control signal. The switch unit preferably includes a field effect transistor. A drain and a source of the field effect transistor are connected between high frequency terminals, and a signal from a control terminal is input to the gate of the field effect transistor. Alternatively, the switch unit preferably includes a plurality of field effect transistors. The plurality of field effect transistors are connected in series. The drain (or source) of a field effect transistor on one end side in the plurality of field effect transistors is connected to a common high-frequency terminal, and the field effect on the other end side in the plurality of field effect transistors. A source (or drain) of the transistor is connected to another high frequency terminal. A signal from a control terminal is input to the gate of the field effect transistor. The capacitive element is preferably configured by a parasitic capacitance when the field effect transistor constituting the switch unit is in a cut-off state, and the resonance frequency is changed by changing the parasitic capacitance by changing the gate width of the field effect transistor. It is configured to change. The capacitive element is preferably connected in parallel with a field effect transistor constituting the switch unit. The resonance frequency is changed by changing the capacitance of the capacitive element. The capacitive element is preferably composed of a variable capacitance circuit independent of the switch unit. The variable capacitance circuit includes a plurality of field effect transistors. A signal from the control terminal is input to the gate terminal of each field effect transistor constituting the field effect transistor array. A capacitive element is preferably connected between the drain and source of the field effect transistor constituting the variable capacitance circuit.

  The present invention will be described in detail below.

  The switch circuit of the present invention is composed of a combination of two (generally two) elements.

  The first element is a technique of connecting an inductor element between a shared high-frequency terminal and a ground terminal when bundling a plurality of switch portions (see FIG. 1). This reduces the number of inductors.

  The second element is a method of changing the value of the capacitance instead of changing the value of the inductor. Thereby, the resonance frequency can be changed.

  The following methods can be considered as a method of changing the capacitance value.

  One is a method of connecting the variable capacitor to the shared terminal of the antenna. In general, the signal passing through the switch circuit is high power. The switch circuit itself is required to have low distortion. Therefore, it is difficult to use a general variable capacitor. Therefore, this variable capacitor was realized by connecting FETs in series. By switching on / off of each FET, the capacitance value can be changed while keeping the entire FET connected in series in the OFF state. A method for controlling the gate width of the FET may be used in combination. The capacitance of the FET in the off state is proportional to the gate width. In the LC resonant switch circuit, the resonant frequency is determined by the off-state FET capacitance and the inductor value. Therefore, the capacitance value is controlled by controlling the capacitance value of the route excluding the route that is turned on, that is, the gate width. When used in combination, the resonance frequency can be set over a wide range.

  By inserting a capacitive element in parallel with the FET, the capacitance value of the capacitive element inserted into the off-capacitance of the FET is low when the FET is off, and the resistance is low when the FET is on. Therefore, the insertion capacitance value can be ignored, and a capacitance larger than the capacitance value that can be controlled by the gate width of the FET can be controlled.

  In the FET used in the switch circuit, the drain and the source usually have the same structure. Therefore, there is a case where the source and the drain are not distinguished from each other. However, in the following, for the sake of convenience, the drain and the source of the FET are distinguished from each other in order to clarify the connection relationship between the elements included in the switch circuit.

[First embodiment]
FIG. 1 shows a switch circuit (SP3T type switch circuit) of the first reference embodiment.

  The switch circuit of the present embodiment includes a first switch unit 21, a second switch unit 22, and a third switch unit 23. Each switch unit 21, 22, 23 controls a high frequency signal (controls the passage or blocking of the high frequency signal). Each switch unit 21, 22, 23 is an SPST type switch. The switch circuit further includes an inductor circuit 71. The inductor circuit 71 is connected between the terminal (high frequency terminal) 1 and the ground terminal (GND). The terminal 1 is a common terminal when high-frequency signals are input to and output from the switch units 21, 22, and 23.

  The first switch unit 21 includes a plurality of (for example, three) FETs 31, 32, and 33. The FETs 31, 32, and 33 are connected in series. That is, the drain (or source) and the adjacent source (or drain) are connected. The FETs 31 and 33 at both ends are connected to the high frequency terminals 1 and 2. The gate electrodes of the FETs 31, 32, and 33 are connected to the control terminal 11 through resistance elements 41, 42, and 43.

  The second switch unit 22 includes a plurality of (for example, three) FETs 34, 35, and 36. The FETs 34, 35, and 36 are connected in series. That is, the drain (or source) and the adjacent source (or drain) are connected. The FETs 34 and 36 at both ends are connected to the high frequency terminals 1 and 3. The gate electrodes of the FETs 34, 35, and 36 are connected to the control terminal 12 through resistance elements 44, 45, and 46.

  The third switch unit 23 includes a plurality of (for example, three) FETs 37, 38, and 39. The FETs 37, 38, and 39 are connected in series. That is, the drain (or source) and the adjacent source (or drain) are connected. The FETs 37 and 39 at both ends are connected to the high frequency terminals 1 and 4. The gate electrodes of the FETs 37, 38, 39 are connected to the control terminal 13 via resistance elements 47, 48, 49.

  The gate widths of the gate electrodes of the FETs 31 to 39 used in the switch circuit are different in the switch units 21, 22 and 23. For example, the gate width Wg21 of the FETs 31, 32, 33 of the switch unit 21, the gate width Wg22 of the FETs 34, 35, 36 of the switch unit 22, and the gate width Wg23 of the FETs 37, 38, 39 of the switch unit 23 are all Different. Resistance elements 41 to 49 connected to the gate electrode have high resistance (several kΩ to several hundred kΩ).

  An inductor circuit 71 is connected to the high-frequency terminal 1 shared by the switch units 21, 22, and 23. For this inductor circuit 71, for example, the elements shown in FIGS. FIG. 7 shows an example in which only the inductor element 51 is used. 8 and 9 are examples in which an inductor element 51 and a capacitive element 61 are connected in series. FIG. 10 shows an example in which the inductor element 51 and the inductor element 52 are connected in parallel, and the switch element 81 is connected to one inductor element 51. FIG. 11 shows an example in which an FET 31 is used for the switch element of FIG. As the inductor circuit 71, the one shown in FIG. 7 is basically sufficient. The examples of FIGS. 8 and 9 are used when the potential of the high frequency terminal cannot be set to the GND potential. In this case, the series resonance frequency of the inductor element 51 and the capacitive element 61 is set to a value away from the signal frequency that passes through the switch circuit.

  Next, the operation when the inductor element 51 is used in the inductor circuit 71 (see FIG. 7) will be described.

First, a high level signal is first applied to the control terminal 11 (control terminal of the first switch unit 21), and the control terminals 12 (control terminal of the second switch unit 22) and 13 (of the third switch unit 23). A case where a low level signal is input to the control terminal) is considered. At this time, the switch unit 21 is in an on state, and the switch units 22 and 23 are in an off state. The off-state capacitance is proportional to the gate width. Therefore, C22 (off capacity of the switch unit 22) = S · Wg22. C23 (off capacity of the switch unit 23) = S · Wg23. S is a proportionality constant. f21 (resonance frequency when the switch unit 21 is on) = 1 / [2π {LS (Wg22 + Wg23)} ^1/2 ]. L is the value of the inductor of the inductor circuit 71.

A high level signal is supplied to the control terminal 12 (control terminal of the second switch unit 22), and a low level signal is supplied to the control terminals 11 (control terminal of the first switch unit 21) and 13 (control terminal of the third switch unit 23). It is conceivable that this signal is input. f22 (resonance frequency when the switch unit 22 is in the on state) = 1 / [2π {LS (Wg21 + Wg23)} ^1/2 ]. A high level signal is supplied to the control terminal 13 (control terminal of the third switch unit 23), and a low level signal is supplied to the control terminals 11 (control terminal of the first switch unit 21) and 12 (control terminal of the second switch unit 22). It is conceivable that this signal is input. f23 (resonance frequency when the switch unit 23 is in the ON state) = 1 / [2π {LS (Wg21 + Wg22)} ^1/2 ].

α＝１／（８π^２ＬＳ）である。 By setting the gate widths of the FETs in the plurality of switch portions to different values, different resonance frequencies can be set for the switch portions in the on state. Once the resonance frequency is determined, the gate width is determined. This is represented by the following formula A.

α = 1 / (8π ² LS).

  As can be seen from the above description, the number of inductors is reduced. Since the number of inductors is small, there is no need for a large area. As a result, the manufacturing cost is low. Three resonance frequencies are secured. Therefore, it becomes possible to cope with multiband / multimode applications.

[Second embodiment]
FIG. 4 shows a switch circuit (SP3T type switch circuit) of the second reference embodiment.

  The switch circuit of the present embodiment includes a first switch unit 21, a second switch unit 22, and a third switch unit 23. Each switch unit 21, 22, 23 controls a high frequency signal (controls the passage or blocking of the high frequency signal). Each switch unit 21, 22, 23 is an SPST type switch. The switch circuit further includes an inductor circuit 71. The inductor circuit 71 is connected between the terminal (high frequency terminal) 1 and the ground terminal (GND). The terminal 1 is a common terminal when high-frequency signals are input to and output from the switch units 21, 22, and 23.

  The first switch unit 21 includes a plurality of (for example, three) FETs 31, 32, and 33. The FETs 31, 32, and 33 are connected in series. That is, the drain (or source) and the adjacent source (or drain) are connected. The FETs 31 and 33 at both ends are connected to the high frequency terminals 1 and 2. The gate electrodes of the FETs 31, 32, and 33 are connected to the control terminal 11 through resistance elements 41, 42, and 43. A capacitive element 61 is connected in parallel to the FETs 31, 32 and 33.

  The second switch unit 22 includes a plurality of (for example, three) FETs 34, 35, and 36. The FETs 34, 35, and 36 are connected in series. That is, the drain (or source) and the adjacent source (or drain) are connected. The FETs 34 and 36 at both ends are connected to the high frequency terminals 1 and 3. The gate electrodes of the FETs 34, 35, and 36 are connected to the control terminal 12 through resistance elements 44, 45, and 46. A capacitive element 64 is connected in parallel to the FETs 34, 35 and 36.

  The third switch unit 23 includes a plurality of (for example, three) FETs 37, 38, and 39. The FETs 37, 38, and 39 are connected in series. That is, the drain (or source) and the adjacent source (or drain) are connected. The FETs 37 and 39 at both ends are connected to the high frequency terminals 1 and 4. The gate electrodes of the FETs 37, 38, 39 are connected to the control terminal 13 via resistance elements 47, 48, 49. A capacitive element 67 is connected between the drain and source of the FET 37. A capacitive element 68 is connected between the drain and source of the FET 38. A capacitive element 69 is connected between the drain and source of the FET 39.

  In the case of this embodiment, the gate widths of the gate electrodes of the FETs 31 to 39 used in the switch circuit may be different or the same in each of the switch units 21, 22, and 23. In the case of the present embodiment, there is no limitation as in the first embodiment. Resistance elements 41 to 49 connected to the gate electrode have high resistance (several kΩ to several hundred kΩ).

  An inductor circuit 71 is connected to the high-frequency terminal 1 shared by the switch units 21, 22, and 23. For this inductor circuit 71, for example, the elements shown in FIGS.

  The operation when the inductor element 51 (see FIG. 7) is used in the inductor circuit 71 will be described. In the embodiment, the gate width of the FET is different. However, in the present embodiment, since a capacitive element such as a capacitor is connected, the gate widths of the FETs may be the same. In order to simplify the description, the gate widths of all the FETs will be described as the same value Wg. It is assumed that the capacitance value of the capacitive element 61 is C61, the capacitive value of the capacitive element 64 is C64, and the capacitive elements 67, 68, and 69 are all the same C67.

First, a high level signal is supplied to the control terminal 11 (control terminal of the first switch unit 21), and the control terminals 12 (control terminal of the second switch unit 22) and 13 (control terminals of the third switch unit 23). ), A low level signal may be input. At this time, the switch unit 21 is in an on state, and the switch units 22 and 23 are in an off state. The off-state capacitance is proportional to the gate width. Therefore, C22 (off capacity of the switch unit 22) = S · Wg + C64. C23 (off-capacitance of the switch unit 23) = S · Wg + (1/3) C67. S is a proportionality constant. A high level signal is supplied to the control terminal 12 (control terminal of the second switch unit 22), and a low level signal is supplied to the control terminals 11 (control terminal of the first switch unit 21) and 13 (control terminal of the third switch unit 23). It is conceivable that this signal is input. f21 (resonance frequency when the switch unit 21 is on) = 1 / [2π {L (SWg + C61)} ^1/2 ]. f22 (resonance frequency when the switch unit 22 is in the ON state) = 1 / [2π {L (SWg + C64)} ^1/2 ]. f23 (resonance frequency when the switch unit 23 is in the ON state) = 1 / [2π {L (SWg + C67 / 3)} ^1/2 ].

  As described above, by connecting a capacitor in parallel to the FET of the switch unit and changing the off-capacitance, it is possible to set different resonance frequencies for the switch unit in the on state. If the resonance frequency is determined, the capacitance of the capacitive element can be determined. The capacitive element may be connected in parallel to the FET array (see the switch units 21 and 22 in FIG. 4). Or you may connect in parallel with respect to each FET (refer the switch part 23 of FIG. 4). Or these may be mixed. Although not shown, capacitive elements may be connected in parallel only to some FETs or FET rows. The capacitive element 68 of the switch unit 23 may be removed (see FIG. 4).

  The capacitive element used in this embodiment can be ignored when the FET is in the on state because the on-resistance of the FET is very small. There is no adverse effect on the operation.

  As can be seen from the above description, the number of inductors is small. Since the number of inductors is small, there is no need for a large area. As a result, the manufacturing cost is low. In addition, it is possible to cope with a plurality of frequencies by setting the capacitance value connected to each switch unit to a capacitance value corresponding to the passing frequency. As a result, it is possible to cope with multiband / multimode applications.

[First Embodiment]
FIG. 2 shows a switch circuit (SP3T type switch circuit) according to the first embodiment of the present invention.

  The switch circuit of the present embodiment includes a first switch unit 21, a second switch unit 22, and a third switch unit 23. Each switch unit 21, 22, 23 controls a high frequency signal (controls the passage or blocking of the high frequency signal). Each switch unit 21, 22, 23 is an SPST type switch. The switch circuit further includes an inductor circuit 71. The inductor circuit 71 is connected between the terminal (high frequency terminal) 1 and the ground terminal (GND). The switch circuit further includes a variable capacitance circuit 91. The variable capacitance circuit 91 is connected between a terminal (high frequency terminal) 1 and a ground terminal (GND). The terminal 1 is a common terminal when high-frequency signals are input to and output from the switch units 21, 22, and 23.

  The first switch unit 21 includes a plurality of (for example, three) FETs 31, 32, and 33. The FETs 31, 32, and 33 are connected in series. That is, the drain (or source) and the adjacent source (or drain) are connected. The FETs 31 and 33 at both ends are connected to the high frequency terminals 1 and 2. The gate electrodes of the FETs 31, 32, and 33 are connected to the control terminal 11 through resistance elements 41, 42, and 43.

  The second switch unit 22 includes a plurality of (for example, three) FETs 34, 35, and 36. The FETs 34, 35, and 36 are connected in series. That is, the drain (or source) and the adjacent source (or drain) are connected. The FETs 34 and 36 at both ends are connected to the high frequency terminals 1 and 3. The gate electrodes of the FETs 34, 35, and 36 are connected to the control terminal 12 through resistance elements 44, 45, and 46.

  The third switch unit 23 includes a plurality of (for example, three) FETs 37, 38, and 39. The FETs 37, 38, and 39 are connected in series. That is, the drain (or source) and the adjacent source (or drain) are connected. The FETs 37 and 39 at both ends are connected to the high frequency terminals 1 and 4. The gate electrodes of the FETs 37, 38, 39 are connected to the control terminal 13 via resistance elements 47, 48, 49.

  In the case of this embodiment, the gate widths of the gate electrodes of the FETs 31 to 39 used in the switch circuit may be different or the same in each of the switch units 21, 22, and 23. In the case of this embodiment, there is no limitation in the case of the first reference embodiment. Resistance elements 41 to 49 connected to the gate electrode have high resistance (several kΩ to several hundred kΩ).

  An inductor circuit 71 and a variable capacitance circuit 91 are connected to the high frequency terminal 1 shared by the switch units 21, 22 and 23. For the inductor circuit 71, for example, circuits such as those shown in FIGS. 7, 8, 9, 10, and 11 are used. The variable capacitance circuit 91 has control terminals 14 to 19. Resistance elements 141 to 146 are connected between the control terminals 14 to 19 and the gate terminals of the FETs 131 to 136. The FETs 131 to 136 have their drains (or sources) connected (shared) in series with the sources (or drains) of adjacent FETs. The FETs 131 to 136 are connected between the high frequency terminal 1 and GND. In FIG. 2, the number of FETs is six, but is not limited thereto. Even if a capacitive element is connected in series to the series circuit of the FETs 131 to 136, it can serve as a variable capacitor. The gate widths of the FETs 131 to 136 may all be the same or different. Signals (high level / low level) logically operated from the control terminals 11, 12, and 13 of the switch units 21, 22, and 23 are applied to the control terminals 14 to 19. As a result, the on / off states of the FETs 131 to 136 are switched by the switch portion in the on state, and the overall capacitance changes.

可変容量回路９１、スイッチ部２１，２２，２３における全てのＦＥＴのゲート幅は、動作の説明の簡略化の為、同一値Ｗｇであるとした。 Next, the operation of this embodiment will be described (see FIG. 3). The inductor 51 shown in FIG. 7 is used for the inductor circuit 71. A logic circuit unit 92 is connected to the control terminals 14 to 19. The logic circuit unit 92 generates control signals for the control terminals 14 to 19 of the variable capacitance circuit 91 using the logic circuits 151 to 154 based on the inputs of the control terminals 11 to 13 of the switch units 21 to 23. Here, the following truth table is assumed.

The gate widths of all the FETs in the variable capacitance circuit 91 and the switch units 21, 22, and 23 are assumed to be the same value Wg in order to simplify the explanation of the operation.

First, a high level signal is supplied to the control terminal 11 (control terminal of the first switch unit 21), and the control terminals 12 (control terminal of the second switch unit 22) and 13 (control terminals of the third switch unit 23). ), A low level signal may be input. At this time, the switch unit 21 is in an on state, and the switch units 22 and 23 are in an off state. In the variable capacitance circuit 91, all the FETs 131 to 136 are turned off. The off-state capacitance is proportional to the gate width. C22 (off capacity of the switch section 22) = C23 (off capacity of the switch section 23) = S · Wg. S is a proportionality constant. Cvar (capacitance of the variable capacitance circuit) = S · Wg / 2. f21 (resonance frequency when the switch unit 21 is in the ON state) = 1 / {2π (2.5LSWg) ^1/2 }.

Similarly, a high level signal is supplied to the control terminal 12 (control terminal of the second switch unit 22), and the control terminals 11 (control terminal of the first switch unit 21) and 13 (control terminal of the third switch unit 23). ), A low level signal may be input. At this time, the switch unit 22 is turned on, and the switch units 21 and 23 are turned off. In the variable capacitance circuit, the FETs 131 to 135 are turned off and the FET 136 is turned on. The off-state capacitance is proportional to the gate width. C21 (off capacity of the switch section 21) = C23 (off capacity of the switch section 23) = S · Wg. S is a proportionality constant. Cvar (capacitance of the variable capacitance circuit) = 3S · Wg / 5. f22 (resonance frequency when the switch unit 22 is in the ON state) = 1 / {2π (2.6LSWg) ^1/2 }.

Similarly, a high level signal is supplied to the control terminal 13 (control terminal of the third switch unit 23), and the control terminals 11 (control terminal of the first switch unit 21) and 12 (control terminals of the second switch unit 22). ), A low level signal may be input. At this time, the switch unit 23 is turned on, and the switch units 21 and 22 are turned off. In the variable capacitance circuit, the FETs 131 to 133 are turned off and the FETs 134 to 136 are turned on. The off-state capacitance is proportional to the gate width. C21 (off capacity of the switch unit 21) = C22 (off capacity of the switch unit 22) = S · Wg. S is a proportionality constant. Cvar (capacitance of the variable capacitance circuit) = S · Wg. f23 (resonance frequency when the switch unit 23 is in the ON state) = 1 / {2π (3LSWg) ^1/2 }.

  As can be seen from the above description, the number of inductors is reduced. Since the number of inductors is small, there is no need for a large area. As a result, the manufacturing cost is low. In addition, the resonance frequency can be changed by turning on and off the control terminal of the variable capacitance circuit. That is, it is possible to cope with a plurality of frequencies. As a result, it is possible to cope with multiband / multimode applications.

  In the description of the operation of the first embodiment (SP3T in FIG. 3), only one of the control terminals 11 to 13 is at a high level and the rest is at a low level. The logic circuit is not limited to this. The truth table of the logic circuit is not limited to this. For ease of explanation, the gate width is the same. However, in order to change the capacitance value in a wide range, the gate widths of the FETs 131 to 136 in the variable capacitance circuit 91 are preferably made different from each other.

[Second Embodiment]
FIG. 5 shows a switch circuit (SP3T type switch circuit) according to the second embodiment of the present invention.

  The switch circuit of the present embodiment includes a first switch unit 21, a second switch unit 22, and a third switch unit 23. Each switch unit 21, 22, 23 controls a high frequency signal (controls the passage or blocking of the high frequency signal). Each switch unit 21, 22, 23 is an SPST type switch. The switch circuit further includes an inductor circuit 71. The inductor circuit 71 is connected between the terminal (high frequency terminal) 1 and the ground terminal (GND). The switch circuit further includes a variable capacitance circuit 91. The variable capacitance circuit 91 is connected between a terminal (high frequency terminal) 1 and a ground terminal (GND). The terminal 1 is a common terminal when high-frequency signals are input to and output from the switch units 21, 22, and 23.

  The first switch unit 21 includes a plurality of (for example, three) FETs 31, 32, and 33. The FETs 31, 32, and 33 are connected in series. That is, the drain (or source) and the adjacent source (or drain) are connected. The FETs 31 and 33 at both ends are connected to the high frequency terminals 1 and 2. The gate electrodes of the FETs 31, 32, and 33 are connected to the control terminal 11 through resistance elements 41, 42, and 43.

  The second switch unit 22 includes a plurality of (for example, three) FETs 34, 35, and 36. The FETs 34, 35, and 36 are connected in series. That is, the drain (or source) and the adjacent source (or drain) are connected. The FETs 34.36 at both ends are connected to the high frequency terminals 1 and 3. The gate electrodes of the FETs 34, 35, and 36 are connected to the control terminal 12 through resistance elements 44, 45, and 46.

  The third switch unit 23 includes a plurality of (for example, three) FETs 37, 38, and 39. The FETs 37, 38, and 39 are connected in series. That is, the drain (or source) and the adjacent source (or drain) are connected. The FETs 37 and 39 at both ends are connected to the high frequency terminals 1 and 4. The gate electrodes of the FETs 37, 38, 39 are connected to the control terminal 13 via resistance elements 47, 48, 49.

  In the case of the present embodiment, the gate widths of the gate electrodes of the FETs 31 to 39 used in the switch circuit may be different or the same in the switch units 21, 22 and 23. In the case of this embodiment, there is no limitation in the case of the first embodiment. Resistance elements 41 to 49 connected to the gate electrode have high resistance (several kΩ to several hundred kΩ).

  An inductor circuit 71 and a variable capacitance circuit 91 are connected to the high frequency terminal 1 shared by the switch units 21, 22 and 23. For this inductor circuit 71, for example, the elements shown in FIGS. The variable capacitance circuit 91 has control terminals 14-19. Resistance elements 141 to 146 are connected between the control terminals 14 to 19 and the gate terminals of the FETs 131 to 136. The FETs 131 to 136 have their drains (or sources) connected (shared) in series with the sources (or drains) of adjacent FETs. The FETs 131 to 136 are connected between the high frequency terminal 1 and GND. The number of FETs is not limited to six. Capacitance elements 61 to 66 are connected between the sources and drains of the FETs 131 to 136. Although capacitive elements are connected to all FETs, a capacitive element may be connected to only one FET. That is, an arbitrary FET may be connected to any arbitrary number of capacitive elements. The capacitance values of the capacitive elements may all be the same or different. That is, the capacitance value may be an arbitrary value. The gate widths of the FETs 131 to 136 may all be the same or different. Signals (high level / low level) logically operated from the control terminals 11, 12, and 13 of the switch units 21, 22, and 23 are applied to the control terminals 14 to 19. As a result, the on / off states of the FETs 131 to 136 are switched by the switch portion in the on state, and the overall capacitance changes.

  Next, the operation of the present embodiment will be described (see FIG. 6). The inductor circuit 71 is the inductor 51 of FIG. A logic circuit unit 92 is connected to the control terminals 14 to 19. This logic circuit unit 92 has been described in the third embodiment. The gate widths of all the FETs in the variable capacitance circuit 91 and the switch units 21, 22, and 23 are assumed to be the same value Wg in order to simplify the explanation of the operation. The capacitance values of the capacitive elements 61 to 66 are set to the same value C61 for simplification of description.

First, a high level signal is supplied to the control terminal 11 (control terminal of the first switch unit 21), and the control terminals 12 (control terminal of the second switch unit 22) and 13 (control terminals of the third switch unit 23). ), A low level signal may be input. At this time, the switch unit 21 is turned on, and the switch units 22 and 23 are turned off. In the variable capacitance circuit 91, all the FETs 131 to 136 are turned off. The off-state capacitance is proportional to the gate width. Therefore, C22 (off capacity of the switch section 22) = C23 (off capacity of the switch section 23) = S · Wg. S is a proportionality constant. Cvar (capacitance of the variable capacitance circuit) = (S · Wg / 2) + (C61 / 6). f21 (resonance frequency when the switch unit 21 is on) = 1 / [2π {L (2SWg + C61 / 6)} ^1/2 ].

Similarly, a high level signal is supplied to the control terminal 12 (control terminal of the second switch unit 22), and the control terminals 11 (control terminal of the first switch unit 21) and 13 (control terminal of the third switch unit 23). ), A low level signal may be input. At this time, the switch unit 22 is turned on, and the switch units 21 and 23 are turned off. In the variable capacitance circuit, the FETs 131 to 135 are turned off and the FET 136 is turned on. The capacitor 66 inserted in parallel with the on-state FET can be ignored because the impedance of the on-state FET is small. The off-state capacitance is proportional to the gate width. Therefore, C21 (off capacity of the switch section 21) = C23 (off capacity of the switch section 23) = S · Wg. S is a proportionality constant. Cvar (capacitance of the variable capacitance circuit) = (3S · Wg / 5) + (C61 / 5). f22 (resonance frequency when the switch unit 22 is in the on state) = 1 / [2π {L (2SWg + C61 / 5)} ^1/2 ].

Similarly, a high level signal is supplied to the control terminal 13 (control terminal of the third switch unit 23), and the control terminals 11 (control terminal of the first switch unit 21) and 12 (control terminals of the second switch unit 22). ), A low level signal may be input. At this time, the switch unit 23 is turned on, and the switch units 21 and 22 are turned off. In the variable capacitance circuit, the FETs 131 to 133 are turned off and the FETs 134 to 136 are turned on. Capacitors 64, 65, and 66 inserted in parallel with the on-state FET can be ignored because the impedance of the on-state FET is small. The off-state capacitance is proportional to the gate width. Therefore, C21 (off capacity of the switch unit 21) = C22 (off capacity of the switch units 21 and 22) = S · Wg. S is a proportionality constant. Cvar (capacitance of the variable capacitance circuit) = (S · Wg) + (C61 / 3). f23 (resonance frequency when the switch unit 23 is in the ON state) = 1 / [2π {L (2SWg + C61 / 3)} ^1/2 ].

  As can be seen from the above description, the number of inductors is reduced. Since the number of inductors is small, there is no need for a large area. As a result, the manufacturing cost is low. In addition, the resonance frequency can be changed by turning on and off the control terminal of the variable capacitance circuit. That is, it is possible to cope with a plurality of frequencies. As a result, it is possible to cope with multiband / multimode applications.

  In the description of the operation of the third embodiment in FIG. 6, in the SP3T in FIG. 6, only one of the control terminals 11 to 13 is at a high level, and the remaining is at a low level. The logic circuit is not limited to this. The truth table of the logic circuit is not limited to this. For ease of explanation, the gate width is assumed to be the same. However, in order to change the capacitance value in a wide range, the gate widths of the FETs 131 to 136 in the variable capacitance circuit 91 are preferably made different from each other.

Two or more arbitrary ones of the first embodiment, the second embodiment, and the third embodiment can be combined. This improves the degree of freedom in designing the gate width and other parameters. And it is also possible to make it compatible with designs other than loss and isolation.

  In the embodiment, the switch circuit has been described in SP3T. This is simply because SP3T was suitable for simply explaining the correspondence to a plurality of frequencies. Therefore, it is not limited to SP3T. For example, other switches (for example, a switch with one input and multiple outputs such as SPDT and SPnT (n ≧ 2)) can be used. Multi-input multi-output switches (switches represented by DPDT and DP3T) can also be used.

  The first and second embodiments are examples in which an input signal to the control terminal of the FET constituting the variable capacitance circuit is generated using a logic circuit. However, the use of a logic circuit is not the main element, and other methods may be used.

  Further, the GaAs semiconductor and Si CMOS, which are materials used as switches, have been described as examples, but the present invention is not limited to this.

  A part or all of the above-described embodiment can be described as in the following supplementary notes, but is not limited thereto.

(Supplementary note 1) A high-frequency switch circuit having a plurality of switch units for controlling a high-frequency signal between a plurality of high-frequency terminals by a potential of one or more control terminals,
A circuit constituting an inductor element is connected between a high-frequency terminal and a ground terminal common to the plurality of switch parts,
A switch circuit in which a circuit constituting a variable capacitance element is connected between the plurality of high frequency terminals.

  (Appendix 2) In order to improve the introduction loss and cutoff characteristics of the high-frequency signal path between the high-frequency terminals in which the high-frequency signal can pass between the high-frequency signal path and the ground terminal, The switch circuit according to appendix 1, wherein a circuit constituting an inductor element using a principle that impedance increases at a resonance point of the parallel resonance circuit is connected to a circuit constituting a capacitive element.

  (Supplementary Note 3) The high-frequency switch circuit is configured such that the resonance frequency of the high-frequency switch circuit is changed by changing the capacitance value of the circuit formed of the capacitive element in the high-frequency signal path selected by the control signal. The switch circuit according to appendix 1.

(Additional remark 4) The said switch part comprises a field effect transistor,
The switch circuit according to claim 1, wherein a drain and a source of the field effect transistor are connected between high frequency terminals, and a signal from a control terminal is input to a gate of the field effect transistor.

(Supplementary Note 5) The switch unit includes a plurality of field effect transistors connected in series,
The drain (or source) of a field effect transistor on one end side in the plurality of field effect transistors is connected to a common high-frequency terminal, and the field effect on the other end side in the plurality of field effect transistors. 2. The switch circuit according to appendix 1, wherein a source (or drain) of the transistor is connected to another high-frequency terminal, and a signal from a control terminal is input to the gate of the field effect transistor.

  (Additional remark 6) The said capacitive element is comprised by the parasitic capacitance when the field effect transistor which comprises the said switch part is the interruption | blocking state, The parasitic capacitance is changed by changing the gate width of this field effect transistor. The switch circuit according to appendix 1, wherein the switch circuit is configured to change a resonance frequency.

  (Supplementary note 7) The switch circuit according to supplementary note 1, wherein the capacitive element is connected in parallel with a field effect transistor constituting a switch unit, and the resonance frequency is changed by changing a capacitance of the capacitive element.

(Appendix 8) The capacitive element is composed of a variable capacitance circuit independent of the switch unit,
2. The switch circuit according to claim 1, wherein the variable capacitance circuit includes a plurality of field effect transistors, and is configured such that a signal from a control terminal is input to a gate terminal of each field effect transistor constituting the field effect transistor array. .

  (Supplementary note 9) The switch circuit according to supplementary note 1, wherein the capacitive element is connected between a drain and a source of a field effect transistor constituting a variable capacitance circuit.

DESCRIPTION OF SYMBOLS 1 1st high frequency terminal 2 2nd high frequency terminal 3 3rd high frequency terminal 4 4th high frequency terminal 11-19 Control terminal 21 1st switch part 22 2nd switch part 23 3rd switch part 31-39 131-136 FET
41-49, 141-146 Resistance element 51-59 Inductor element 61-69 Capacitance element 71 Inductor circuit 81 Switch 91 Variable capacity circuit 92 Logic circuit part 101,102,103 n layer 104 p layer 105 p base 106 drain electrode 107 source Electrode 108 Gate electrodes 151 to 154 AND circuit

Claims (11)

A high-frequency switch circuit having a plurality of switch units for controlling a high-frequency signal between a plurality of high-frequency terminals by the potential of one or more control terminals,
An inductor circuit is connected between a high-frequency terminal common to the plurality of switch parts and a ground terminal,
A variable capacitance circuit is connected between a high-frequency terminal common to the plurality of switch parts and a ground terminal,
A switch circuit, wherein the inductor circuit and the variable capacitance circuit are connected in parallel. 2. The switch circuit according to claim 1, wherein the variable capacitance circuit is a circuit whose capacitance value can be changed to a plurality of values when the conduction state is removed. 3. The switch circuit according to claim 1, wherein the variable capacitance circuit includes a plurality of capacitance elements, and the capacitance value of the variable capacitance circuit can be changed to a plurality of values by turning on and off the capacitance elements. . In order to improve the introduction loss and cut-off characteristics of the high-frequency signal path between the high-frequency terminals where the high-frequency signal can pass between the high-frequency signal path and the ground terminal, 4. The switch circuit according to claim 1, wherein a circuit that constitutes an inductor element using a principle of increasing impedance and a circuit that constitutes a capacitive element are connected. The high-frequency switch circuit is configured to change a resonance frequency of the high-frequency switch circuit by changing a capacitance value of the variable capacitance circuit in the high-frequency signal path selected by the control signal. Item 4. The switch circuit according to any one of items 4. The switch part comprises a field effect transistor,
The drain and the source of the field effect transistor are connected between high frequency terminals, and a signal from a control terminal is input to the gate of the field effect transistor. Either switch circuit. The switch part comprises a plurality of field effect transistors connected in series,
The drain (or source) of a field effect transistor on one end side in the plurality of field effect transistors is connected to a common high-frequency terminal, and the field effect on the other end side in the plurality of field effect transistors. The source (or drain) of the transistor is connected to another high-frequency terminal, and a signal from a control terminal is input to the gate of the field effect transistor. Switch circuit. The variable capacitance circuit is configured by a parasitic capacitance when the field effect transistor constituting the switch unit is in a cut-off state, and the resonance frequency is changed by changing the parasitic capacitance by changing the gate width of the field effect transistor. 8. The switch circuit according to claim 1, wherein the switch circuit is configured. The variable capacitance circuit is connected in parallel with a field effect transistor constituting a switch unit, and the resonance frequency is changed by changing the capacitance of the variable capacitance circuit. 8 switch circuit. The variable capacitance circuit is composed of a variable capacitance circuit independent of the switch unit,
The variable capacitance circuit includes a plurality of field effect transistors, and is configured such that a signal from a control terminal is input to a gate terminal of each field effect transistor constituting the field effect transistor array. The switch circuit according to claim 1. 11. The switch circuit according to claim 1, wherein the variable capacitance circuit is connected between a drain and a source of a field effect transistor constituting the variable capacitance circuit.

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