The present invention pertains to a transmission circuit, an antenna duplexer, and a radio-frequency circuit.
Conventionally, there is proposed, as an example of a transmission line used in radio-frequency circuits, one where a meander-shaped line and a shield electrode are disposed inside a laminated substrate.
There is also proposed a delay line, comprising a spiral-shaped coil conductor and a shield electrode formed on top and bottom of the coil conductor so as to face this coil conductor through a dielectric ceramic layer, and formed with a strip line structure between the coil conductor and the shield electrode (e.g. JP-A-05-029819 (Patent Document 1)).
However, in the aforementioned technology where a meander-shaped transmission line and a shield electrode are disposed inside a laminated substrate, the characteristic impedance of the line is determined by the width of the meander-shaped line and the distance between the meander-shaped line and the shield electrode. In other words, as shown in
Also, in the delay line mentioned in the aforementioned Patent Document 1, the spiral-shaped coil conductor and the leader electrode to an external electrode face each other so there arises a cross-over part, or the outer part of the spiral-shaped coil conductor and the projected arrangement of the outer part of a shield electrode formed between the leader electrodes to the external electrodes coincide. In addition, the spiral-shaped coil conductor and the external electrode face each other. For this reason, since the electromagnetic field induced by the coil conductor and the electromagnetic field induced by the leader electrode are coupled, there is a risk that the characteristics of the transmission line are degraded. In other words, if there is a cross-over part, there occurs resonance due to the coupling capacitance between the input and output of the transmission line and the impedance of the transmission line, so there is a risk that operation in the radio-frequency domain becomes difficult.
Also, since coil conductors are laminated extending through several layers and are further connected by via holes so that an even longer delay time is obtained, the directions in which the electric current is flowing in the top-down adjacent conductor portions become opposite and the impedance portions of each coil conductor offset each other, so there is also a risk that the overall impedance ends up decreasing. For this reason, at operating frequencies from 0.5 GHz to 1 GHz used in actual products, i.e. SAW (Surface Acoustic Wave) filters or FBAR (Film Bulk Acoustic Resonator) filters mounted in mobile communication terminals, it becomes difficult to phase shift transmission signals 90° or more, so it becomes impossible to operate the mobile communication terminal accurately.
Moreover, in the case of using an antenna duplexer using SAW filters or FBAR filters and the like, the size of the antenna duplexer ends up being larger, since it is necessary to connect the terminals of these filters and the external terminals of the delay lines through a printed circuit board or the like.
In order to attain the aforementioned object, the present invention comprises a first shield layer being a first ground electrode, a second shield layer being a second ground electrode, a spiral-shaped transmission line facing the first shield layer and the second shield layer and disposed between the first shield layer and the second shield layer. The spiral portion of the transmission line is disposed on the inside of the first shield layer and the second shield layer when viewed from the top face or the bottom face of the transmission line.
According to the present invention, it becomes possible to provide, with improved transmission characteristics, a transmission line, an antenna duplexer, and a radio-frequency switch circuit.
These and other features, objects and advantages of the present invention will become more apparent from the following description when taken in conjunction with the accompanying drawings wherein:
In the embodiments of the present invention, an explanation will be made choosing as an example a transmission line using a radio frequency circuit dielectric substrate of LTCC (Low Temperature Co-fired Ceramic), HTCC (High Temperature Co-fired Ceramic), or the like. Also, this transmission line will be explained as being used in a radio-frequency circuit for nearly 0.5 GHz or more, used in antenna duplexers, antenna switches, front end modules, and the like, using SAW (Surface Acoustic Wave) filters or FBAR (Film Bulk Acoustic Resonator) filters or the like. Below, the embodiments of the present invention will be explained by using the drawings.
Transmission line 2 forms a path with a circular shaped spiral structure. A ground electrode 3 and a ground electrode 4 are disposed to cover transmission line 2, in the layer below transmission line 2 and in the layer below transmission line 2, respectively.
A land area 5 disposed on the surface of dielectric multilayer substrate 1 is connected by means of via holes 100a, 100b to one end of transmission line 2, the other end of transmission line 2 being connected by means of via holes 101a, 101b to a land area 6 disposed on the surface of dielectric substrate 1. Specifically, land areas 5 and 6 on the surface disposed at the top face of dielectric multi-layer substrate 1 serve respectively as the input and output ends of the transmission line of Embodiment 1.
Further, in the configuration of the present embodiment, ground electrodes 3, 4 are chosen to have a configuration which adequately covers the spiral-shaped portion of transmission line 2. It is because there is too much harmful influence of electric fields and magnetic fields to remove and there is a risk of bringing about a degradation in the transmission characteristics in case the spiral-shaped portion is not adequately covered, e.g. in case the spiral-shaped portion protrudes from the range covered by ground electrodes 3, 4. Also, in case the spiral-shaped portion has nearly the same size as ground electrodes 3, 4, because magnetic fields come entering by turning around, there is likewise a risk of a deterioration in the transmission characteristics. Consequently, it becomes necessary to choose a configuration devised so that ground electrodes 3, 4 cover the spiral-shaped portion of transmission line 2 sufficiently widely to adequately reduce the influence of the electric fields and the magnetic fields.
Moreover in the present configuration, it is possible to obtain desired impedance characteristics in a desired frequency domain by regulating the capacitance component between ground electrodes 3, 4 and transmission line 2, and the inductance component due to the circular shaped spiral structure with no transmission line 2 cross-over part.
According to the present embodiment, since it is possible, through the impedance component and the capacitance component due to the circular shaped spiral structure with no cross-over part, constituted by transmission line 2 and ground electrodes 3, 4, to obtain a much bigger phase shift than the phase shift that can be obtained by the length of the strip line alone, a transmission line with an extremely small structure can be constituted. Also, for the transmission line of the present embodiment, the phase shift per single layer can be increased and the number of layers constituting the line can be reduced. Therefore, the size of the transmission line can be made smaller and thinner. Moreover, by reducing the number of discontinuity points of the line due to connections of the line and the via holes, it is possible to reduce the losses as well as provide a transmission line with small variations due to lamination layer slippage.
In the present embodiment, on the inside of a dielectric multi-layer substrate 1, a first transmission line 8 is formed, and in the layer below first transmission line 8, a second transmission line 9 is formed. First transmission line 8 and second transmission line 9 respectively have a circular shaped spiral structure, the connection of first transmission line 8 and second transmission line 9 being carried out with a via hole 102b to constitute a transmission line spanning multiple layers.
Ground electrode 7 and ground electrode 10 are disposed, respectively, in the layer above first transmission line 8 and the layer below above second transmission line 9, to cover first transmission line 8 and second transmission line 9.
A land area 11 disposed on the surface of dielectric multi-layer substrate 1 is connected to one end of first transmission line 8 by means of a via hole 102a, and the other end of first transmission line 8 is connected to one end of second transmission line 9 by means of via hole 102b, the other end of second transmission line 9 being connected to a land area 12 disposed on the surface of dielectric substrate 1 by means of via holes 103b, 103a. Specifically, land areas 11 and 12 disposed on the surface of dielectric multi-layer substrate 1 are the input and output ends of the transmission line of Embodiment 2. According to the present configuration, since the result is that the electric current flowing through the transmission line of the present embodiment has nearly the same direction (a counter-clockwise direction) in first transmission line 8 and second transmission line 9, the impedance component of transmission line 8 and the impedance component of transmission line 9 are not offset. Consequently, it is possible to be able to obtain a big impedance component for the transmission line as a whole. In accordance with the present transmission line, the operating frequency of the transmission line can be lowered, since it is possible to obtain a big phase shift without increasing the product dimensions.
Also, in the present configuration, by regulating the capacitance components between ground electrodes 7, 10 and first transmission line 8 and second transmission line 9, and the inductance components due to the circular shaped spiral structure with no cross-over of first transmission line 8 and second transmission line 9, it is possible to obtain desired impedance characteristics in the desired radio frequency band.
According to the present embodiment, since it is possible, through the inductance component and the capacitance component due to the circular shaped spiral structure with no cross-over constituted by first transmission line 8 and second transmission line 9 and ground electrodes 7, 10, to obtain a much bigger phase shift than the phase shift that can be obtained by the length of the strip line alone, a transmission line with an extremely small structure can be constituted. Also, for the transmission line of the present embodiment, the phase shift per single layer can be increased and the number of layers constituting the line can be reduced. Therefore, the transmission line can be reduced in size and made thinner.
In the aforementioned embodiment, there were connected transmission lines 8 and 9, having a circular shaped spiral structure with no cross-over part and spanning two layers on the inside of a dielectric multi-layer substrate, but the present invention is not limited thereto, it also being possible to connect a circular shaped spiral structure having no cross-over part, so that the electric current flows in the same direction in three or more layers.
Impedance converter 14 of the present embodiment is connected between parallel connection point 20 and Surface Acoustic Wave filter 15 for reception. Specifically, the impedance seen from parallel connection point 20 of Surface Acoustic Wave filter 15 for reception is converted into a high impedance in the transmission band by impedance converter 14. Also, since the impedance seen from parallel connection point 20 of Surface Acoustic Wave filter 16 for transmission has become a high impedance in the reception band, reception filter 15 and transmission filter 16 are connected with little entry by leakage of each other's signals. In addition, since the impedance of impedance converter 14 is nearly 50Ω in the reception band, the radio-frequency signals in the reception frequency band are transmitted from terminal P1 to terminal P2 with little degradation in characteristics. Consequently, by using this impedance converter 14, it is possible to provide a high-performance antenna duplexer.
The reception filter and transmission filter used in the aforementioned embodiment are not limited to Surface Acoustic Wave filters, and it is e.g. possible to apply filters based on another method such as FBAR filters.
By applying a voltage on terminal V1, a direct electric current flows through a resistance R1, diodes D1, D2 enter the ON state, and the direct electric current is fed back by passing though an inductance L1. At this point, if a resonant frequency determined by a parasitic capacitance C3 of the diode is set to the vicinity of frequency fs, the output terminal (on the side of direct current blocking capacitance C2) of a transmission line 29 in the aforementioned embodiment is grounded in the vicinity of frequency fs. At this point, radio-frequency signals flow from terminal [P]4 to terminal P6, since the phase shift is 90° at frequency fs in transmission line 29, because high impedance results at frequency fs at the input terminal (on the side of direct current blocking capacitance C1) of transmission line 29. Also, when the bias voltage of terminal V1 is turned off, since diodes D1, D2 are off and the impedance of transmission line 29 is nearly 50Ω, the radio-frequency signals flow from terminal P4 to terminal P5. By using this transmission line 29, it is possible to obtain a small-sized radio-frequency switch circuit with high performance.
In Embodiment 5, an explanation was made concerning a λ/4 transformer at a specific frequency, but the invention is not limited to the frequency and impedance specifics shown in the embodiment, and can be applied with other frequencies and impedances.
Further, the transmission line, antenna duplexer and radio frequency switch circuit shown in each embodiment are elements which are used in communication terminals, starting with portable phones. In the communication terminals provided with these transmission lines, antenna duplexers or radio frequency switch circuits, it becomes possible to implement stable communications with higher reception sensitivity.
According to the technology described in the aforementioned embodiments mentioned above, by constituting a circular spiral shaped transmission line with no cross-over part inside a dielectric multi-layer substrate, it is possible to obtain excellent transmission line performance since it is possible to prevent electromagnetic field coupling of any portion between the input end and the output end of the transmission line.
Also, by making the shape of the transmission line circular, it is possible to prevent stagnation of the electric current flowing in the transmission line, and to reduce losses in the transmission line.
Moreover, by constituting the transmission line in multiple layers and choosing the electric current flowing in the transmission line to have the same direction in all the layers, since, for the overall transmission line, a big impedance part is obtained and a big phase shift can be obtained without an increase in the component dimensions.
Also, since the result is that the electric current flowing in adjacent conductors have the same direction, it is possible to obtain a big impedance part and to obtain stable characteristics without an increase in component dimensions, even in the frequency domain of 1 GHz or higher.
In addition, because it is possible to reduce the number of layers constituting the transmission line since the phase shift per single layer becomes bigger, there can be projected a miniaturization and a slimming of the transmission line, a reduction in the variations in characteristics due to lamination layer slippage, and a reduction in the transmission line losses due to a reduction in inter-layer connection points (a reduction in the number of transmission line discontinuity points).
Moreover, it is possible to apply the transmission line to an impedance converter and to provide a small-sized, high-performance radio-frequency circuit device such as an antenna duplexer, a radio-frequency switch circuit or the like.
While we have shown and described several embodiments in accordance with our invention, it should be understood that disclosed embodiments are susceptible of changes and modifications without departing from the scope of the invention. Therefore, we do not intend to be bound by the details shown and described herein but intend to cover all such changes and modifications within the ambit of the appended claims.
Number | Date | Country | Kind |
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2005-181402 | Jun 2005 | JP | national |