The present invention relates to a directional coupler, and more particularly, to arrangements and structures of conductor patterns for accomplishing both of reduction in size and height and good electrical characteristics of the directional coupler.
A directional coupler (hereinafter simply referred to as the “coupler”) which has a function of branching or combining high frequency power propagated on a transmission line has become an indispensable component for designing a transmitter circuit for a variety of wireless communication devices such as portable telephones, wireless LAN communication device, communication devices based on Bluetooth (registered tradename) standard, and the like.
The coupler comprises a first line which has a first port at one end and a second port at the other end, respectively, and a second line which has a third port on one end and a fourth port on the other end, respectively. The first line and second line are disposed in close proximity to each other such that they are electromagnetically coupled to each other.
Such a coupler comprising coupling lines can be used as detector means for monitoring a transmitter circuit of a communication device for the level of a transmitted signal. Specifically, the coupler is inserted between a power amplifier (PA) for amplifying the transmitted signal and an antenna. The transmitted signal from PA is inputted to a first line (primary line) through a first port (input port) of the coupler, and is then outputted from a second port (output port) toward the antenna. In this event, part of the transmitted signal propagating through the first line is extracted through a second line (secondary line) which electromagnetically couples to the first line, and outputted from a third port (coupling port) to an automatic output control circuit (APC circuit) as a monitor signal. The APC circuit controls the gain of PA such that PA provides a constant output in accordance with the level of the monitor signal (i.e., the level of the transmitted signal). Such a PA feedback control enables the transmission output to be stabilized.
The coupler can also divide high-frequency power to two lines with a phase difference of 90°, or can combine high-frequency power from two lines with a phase difference of 90°. As such, the coupler can also be used, for example, for a differential power amplifier as an input divider or as an output combiner. Specifically, the coupler can be applied with a transmitted signal from the first port, divide the transmitted signal into two halves, and output the halves from the second port and third port, respectively, with a phase difference of 90°. In this way, the coupler can be used for a differential power amplifier as an input divider. Alternatively, the coupler can be applied with high-frequency signals with a phase difference of 90° from the second port and third port, respectively, combine these signals, and deliver the resulting single signal from the first port. In this way, the coupler can also be used for a differential power amplifier as an output combiner.
Further, the following patent documents disclose such couplers:
For designing a coupler, satisfactory characteristics can be generally achieved in a used frequency band when the length of a first line and a second line is set to be approximately one-quarter wavelength of the used frequency band.
However, in regard to a sub-microwave band mainly used for mobile wireless devices such as portable phones, the one-quarter wavelength is as long as several centimeters. Thus, it is not feasible from a viewpoint of the size to employ coupling lines of this length for a coupler for use in a mobile wireless device such as portable phone, which is required to be reduced in weight, thickness, length, and size. Also, the employment of long coupling lines of several centimeters or more would cause fatal disadvantages for the mobile wireless device, such as an extremely larger insertion loss which would result in a significantly shortened battery lifetime. For this reason, couplers generally employed in this application have coupling lines shorter than one-quarter wavelength of used frequency band, however, ideal characteristics cannot be easily accomplished with such couplers.
Here, known methods of forming coupling lines involve disposing two lines in close proximity to and in parallel with each other on the same plane (on the same conductor layer) to make coupling between the two lines (hereinafter such a coupling form is referred to as “intra-layer coupling”), as implemented by the invention described in Patent Document 1 cited above, or disposing a first line and a second line on different conductor layers, respectively, such that they overlap with each other when viewed in plan (hereinafter, such a coupling form is referred to as “inter-layer coupling), as implemented by the invention described in Patent Document 2 cited above. Although a larger number of layers are required, the inter-layer coupling allows the planes of both lines to be placed opposite to each other and coupled to each other, and is therefore advantageous in that the coupling of both lines can be made stronger to provide satisfactory characteristics.
While
Further, in the figures, reference numeral P1 designates a first port; P2, a second port; P3, a third port; and P4, a fourth port, respectively. Also, the coupler is assumed to be used in a 2.6-GHz band, and can have functional layers, the size of which may be 1.0 mm long, 0.5 mm wide, and 0.142 mm high (thick).
However, the foregoing structure of the coupler requires four conductor layers for forming the coupling lines, causing the height dimension of the coupler to be large. On the other hand, when an attempt is made to reduce the height (number of layers), the planar shape inevitably becomes larger to compensate for the reduced height. In addition, further improvements in characteristics are requested to keep abreast with increasing reduction in size and thickness of devices and with incorporation of more functions and higher functions in the devices. The aforementioned coupler encounters difficulties in responding the request while maintaining the size of the functional layer.
It is therefore an object of the present invention to provide a coupler which is reduced in size and height and exhibits more satisfactory characteristics.
To solve the problem and achieve the object, a coupler (directional coupler) according to the present invention comprises intra-layer coupling which involves disposing two conductor lines in close proximity to and in parallel with each other on the same conductor layer to generate electromagnetic coupling between the two conductor lines, as well as inter-layer coupling which involves disposing two conductor lines on different conductor layers, respectively, such that they overlap with each other in a length-wise direction, when viewed in plan, to generate electromagnetic coupling between the two conductor lines.
Specifically, a coupler according to the present invention is a coupler which comprises, as a basic aspect, a first line capable of transmitting a high-frequency signal therethrough; a second line arranged for electromagnetic coupling with the first line; a first port disposed at one end of the first line; a second port disposed at the other end of the first line; a third port disposed at one end of the second line; and a fourth port disposed at the other end of the second line, wherein the first and second lines and the first, second, third, and fourth ports are arranged in a laminated board having a plurality of conductor layers including a first conductor layer and a second conductor layer laminated through an insulating layer, the first line and the second line are disposed on the first conductor layer, the first line and the second line are routed on the first conductor layer to extend in close proximity to and in parallel with each other, to form an intra-layer coupling zone for developing electromagnetic coupling between the first line and the second line, and the second line is routed on the second conductor layer such that the second line partially overlaps with the first line disposed on the first conductor layer with respect to a length-wise direction, when viewed in plan, to form an inter-layer coupling space for developing electromagnetic coupling between the second line on the second conductor layer and the first line on the first conductor layer.
Also, as preferred aspects, it is preferable to employ respective aspects as described below in the basic aspect for accomplishing a coupler which is reduced in size and height and exhibits satisfactory characteristics.
(1) In the basic aspect described above, the first line is routed on the second conductor layer such that the first line partially overlaps with the second line disposed on the first conductor layer with respect to the length-wise direction, when viewed in plan, to further form an inter-layer coupling space for developing electromagnetic coupling between the first line on the second conductor layer and the second line on the first conductor layer. In this event, the first line may be a primary line, and the second line may be a secondary line, or conversely, the first line may be a secondary line, and the second line may be a primary line (the same goes for the following description).
(2) In the basic aspect or aspect (1) described above, the second line routed on the second conductor layer is arranged to electromagnetically couple to the first line on the intra-layer coupling zone, so that the intra-layer coupling zone is associated with both of intra-layer coupling which is electromagnetic coupling on the same conductor layer and inter-layer coupling which is electromagnetic coupling across different conductor layers.
(3) In the aspect (2) described above, the first line routed on the second conductor layer is arranged to electromagnetically couple to the second line in the intra-layer coupling zone, so that the intra-layer coupling zone is associated with both of intra-layer coupling which is electromagnetic coupling on the same conductor layer and inter-layer coupling which is electromagnetic coupling across different conductor layers.
(4) In the aspect (2) or (3) described above, the directional coupler comprises a double coupling space which is associated simultaneously with the intra-layer coupling and the inter-layer coupling, where the first line and second line are disposed within the laminated board such that the double coupling space is formed in a loop shape.
(5) In the basic aspect described above, the laminated board is rectangular in shape when viewed in plan, the first conductor layer and the second conductor layer are both arranged horizontally within the laminated board and each have a first corner, a second corner adjacent to the first corner, a third corner located diagonal to the first corner when viewed in plan, and a fourth corner located diagonal to the second corner. The first port is disposed at a first corner on the first conductor layer, and the third port is disposed at a second corner adjacent to the first corner on the first conductor layer. The first line extending from the first port and the second line extending from the third port extend in close proximity to and in parallel with each other to form the intra-layer coupling zone on the first conductor layer, and the first line and the second line spirally extend to each draw a spiral from a peripheral area to a central area of the first conductor layer, and the first line is connected to a first via hole in the central area of the first conductor layer, and is routed to a central area of the second conductor layer through the first via hole, and the second line is connected to a second via hole and routed to the central area of the second conductor layer through the second via hole. The third port is disposed at one of the third corner and fourth corner on the second conductor layer, and the fourth port is disposed at the other of the third corner and fourth corner on the second conductor layer. The first line extending from the first via hole to the second port and the second line extending from the second via hole to the fourth port extend in close proximity to and in parallel with each other to form the intra-layer coupling zone within the second conductor layer, where the first line and second line spirally extend to each draw a spiral from a central area to a peripheral area of the second conductor layer. The intra-layer coupling zone spirally extending on the first conductor layer overlaps with the intra-layer coupling zone spirally extending on the second conductor layer, when viewed in plan, such that the first line on the first conductor layer and the second line on the second conductor layer overlap with each other, while the second line on the first conductor layer and the first line on the second conductor layer overlap with each other, when viewed in plan, to form the inter-layer coupling space, in a manner that a double coupling space is formed for developing the electromagnetic coupling on the same conductor layer and the electromagnetic coupling across different conductor layers.
(6) Also, in the aspect (5) described above, the double coupling space is preferably formed substantially over the entire length of the first and second lines except for an end connected to the first port, an end connected to the third port, an end connected to the second port, an end connected to the fourth port, an end connected to the first via hole, and an end connected to the second via hole, in view of reducing the coupler in size.
(7) Further, in the basic aspect or any of the preferred aspects, the coupler may comprise a terminal resistor disposed within the laminated board to be connected between the second line and the fourth port. According to such an aspect, a coupler can be provided to exhibit satisfactory characteristics even without additionally connecting a terminal resistor to the fourth port.
As described above, the present invention implements, within a single coupler, a combined use of intra-layer coupling which involves a first line and a second line disposed in close proximity to each other to develop coupling therebetween and inter-layer coupling which involves a first line and a second line disposed on different conductor layers such that they overlap with each other, when viewed in plan, to develop coupling therebetween, thereby simultaneously enabling the coupler to be reduced in size and height and to exhibit satisfactory characteristics.
Particularly, by routing the first line and second line such that an intra-layer coupling zone simultaneously forms inter-layer coupling, in other words, by providing a double coupling space which is a line coupling space that provides for intra-layer coupling and inter-layer coupling (serves as an intra-layer coupling zone as well as an inter-layer coupling space), the first and second lines can be enhanced in coupling, as compared with before, thus making it possible for the coupler to exhibit more satisfactory characteristics than before, in spite of its smaller size and lower height. In regard to specific pattern shapes of the coupling lines and their benefits on characteristics, a further discussion will be given in description of embodiments below with reference to the drawings.
While the coupler of the present invention is not particularly limited in its application, the coupler can form part of detecting means, by way of example, for monitoring a transmitted signal for the level in a wireless communication device, as described above. In this application, one of the first line and second line may be a primary line for transmitting a transmitted signal therethrough, and the other may be a secondary line for extracting a monitor signal indicative of the level corresponding to the transmitted signal, and the first port may be used as an input port (or a coupling port); the second port as an output port (or an isolation port); the third port as a coupling port (or an input port); and the fourth port as an isolation port (or an output port), respectively.
Additionally, the coupler can also form part of an input divider or an output combiner for a differential power amplifier as described above. For designing an input divider, a transmitted signal may be inputted from the first port (or third port), and this transmitted signal may be divided into two halves, each of which may be outputted from the second port (or fourth port) and third port (or first port), respectively. Alternatively, for designing an output combiner, high-frequency signals to be combined may be inputted from the second port (or fourth port) and third port (or first port), respectively, and a combined signal may be outputted from the first port (or third port).
According to the present invention, it is possible to accomplish a coupler which is reduced in size and height and exhibits satisfactory characteristics.
Other objects and features of the present invention will become apparent from the following detailed description considered in connection with the accompanying drawings. In the drawings, similar reference characters denote similar elements throughout the several views.
As shown in
In the following description, the first port is designated as “P1”; the second port as “P2”; the third port as “P3”; and the fourth port as “P4.” These ports P1, P2, P3, and P4 are connected to terminals T1, T2, T3, and T4 for external connection, respectively, through vias. Further, a terminal resistor (for example, 50-Ω resistor) is provided between P4 and the fourth terminal T4 for external connection. Also, as described above, satisfactory characteristics could be provided if the length of the primary line and secondary line were set to approximately one-quarter wavelength of a used frequency band, but such a length would result in extremely long lines, so that this embodiment employs the primary line and secondary line, both of which have a shorter line length than the one-quarter wavelength of the used frequency band.
The coupler 11 of this embodiment is fabricated in a manner similar to the coupler according to the comparative example, by forming a laminated board which comprises a plurality of conductor layers and has a rectangular shape, as viewed in plan, with the primary line and secondary line, and the respective ports on internal wiring layers (conductor layers) of the laminated board.
Specifically, as shown in
In the central area of the board, the primary line 12 is connected to a via V1, and the secondary line 13 is connected to a via V2, respectively. These vias V1, V2 extend from the fourth layer (
In this regard, P4 is formed closer to the center in the vertical direction of
Again on the third layer, the spiral lines in the central area of the board are similar to those on the fourth layer in that the primary line 12 and secondary line 13 are spirally wound with a certain narrow spacing interposed therebetween. However, when viewed in plan, the primary line 12 on the third layer is disposed to overlap with the secondary line 13 on the fourth layer, while the secondary line 13 on the third layer is disposed to overlap with the primary line 12 on the fourth layer. Accordingly, these spiral lines form intra-layer coupling, and simultaneously form inter-layer coupling between the third layer and the fourth layer as well.
By forming such double coupling, the coupling can be enhanced between the primary line 12 and the secondary line 13. For clarity,
Also, in this embodiment, an insulating layer (third insulating layer) is interposed between the conductor layers (third and fourth layers) which are involved in the inter-layer coupling. Alternatively, however, the inter-layer coupling may be implemented between conductor layers which adjoin in the direction of lamination (for example, without intervention of another insulating layer such as that between the third layer and the fourth layer), or one or more conductor layers may be interposed, depending on the thickness and the like of the insulating layer interposed between respective conductor layers.
Further, as shown in
Also, as shown in
The external connection terminals TG placed near the centers of both horizontal sides are provided for connection to the ground electrodes G1, G2, and these ground terminals TG are connected to the ground electrode G2 on the fifth layer through vias V. The ground electrode G1 on the second layer, in turn, is connected to the ground electrode G2 on the fifth layer through a via formed in a central area of the board to perpendicularly extend through the second insulating layer, third layer, third insulating layer, fourth layer, and fourth insulating layer (
Moreover, while the coupler of the comparative example requires eight conductor layers (a total of four layers for forming the coupling lines, i.e., the second and third layers and the fifth and sixth layers), this embodiment requires only five layers (except for the first layer for forming the terminal resistor R) (a total of two layers for forming the coupling lines, i.e., the third and fourth layers), thus making it possible to substantially reduce the number of laminated layers. Consequently, the functional layers can be implemented in a size of 1.0 mm long, 0.5 mm wide, and 0.082 mm high (thick), for example, for a 2.6-GHz band.
Further,
A first aspect separately implements intra-layer coupling (this coupling and associated zone are hereinafter labeled “C1”) and inter-layer coupling (this coupling and associated space are hereinafter labeled “C2”), but does not implement double-coupling.
As described above, this embodiment implements both of the intra-layer coupling C1 and inter-layer coupling C2, but does not implement double coupling. The present invention also includes such a coupler that does not implement double coupling. While a coupler implemented with double coupling is advantageous in simultaneously accomplishing a reduction in size and height and more satisfactory characteristics, even a coupler implemented with both intra-coupling C1 and inter-coupling C2 is more advantageous over a conventional coupler which implements only one of intra-layer coupling C1 or inter-layer coupling C2, in that it can increase the degree of freedom in arrangement of pattern by selecting one of intra-layer or inter-layer coupling schemes in a single coupler, i.e., extending the flexibility in arrangement of patterns for each line (first line and second line), ports, external connection electrodes, and the like within the laminated board, and increasing the degree of freedom in designing of the coupler.
In a second aspect, a coupler provides for double coupling, but inter-layer coupling is only for one (first line or second line) of lines associated with intra-layer coupling (this coupling and associated space are hereinafter labeled “C3”). For reference, in a third aspect later described, a coupler provides for double coupling which involves mutual inter-layer coupling between intra-layer coupled lines, i.e., a second line and a first line on a second conductor are inter-layer coupled to both lines (first line and second line), respectively, which are intra-layer coupled on a first layer (this coupling and associated space are hereinafter labeled “C4”).
In a third aspect, a coupler comprises the aforementioned double coupling space C4 which involves mutual inter-layer coupling between intra-layer coupled lines.
A fifth embodiment shown in
Among these embodiments, the couplers according to the seventh and eighth embodiments, and the aforementioned first embodiment, in particular, have the primary line 12 and secondary line 13 patterned such that the double couplings C3, C4 are formed in a spiral shape by a majority of the line length except for connection ends to the ports P1-P4 and vias V1, V2 (see
It should be understood by those skilled in the art that the foregoing description has been made on embodiments of the invention and that various changes and modifications may be made in the invention without departing from the spirit of the invention and the scope of the appended claims.
Number | Date | Country | Kind |
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2012-020258 | Feb 2012 | JP | national |