A high frequency signal switching unit includes a printed circuit board accommodated in the casing and having a ground layer formed on substantially one entire surface thereof. Input and output terminals are mounted on the casing, and a high frequency relay is mounted on the printed circuit board for switching between the input terminal and the output terminal. The high frequency relay has a plurality of relay contact terminals and a grounding terminal. A plurality of coaxial cables having respective internal and external conductors connect the input and output terminals to the relay contact terminals. The grounding terminal of the high frequency relay and the external conductors of the coaxial cables are connected to the ground layer of the printed circuit board, while each of the internal conductors of the coaxial cables is connected to one of the relay contact terminals of the high frequency relay.
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1. A high frequency signal switching unit comprising:
a casing; a printed circuit board accommodated in said casing and having a first surface and a second surface opposite to each other, said printed circuit board also having a ground layer formed on substantially the entire first surface; at least one input terminal and at least one output terminal both mounted on said casing; at least one high frequency relay mounted on said printed circuit board for switching between said input terminal and said output terminal so that a high frequency signal inputted into said input terminal is selectively outputted from said output terminal, said high frequency relay having a plurality of relay contact terminals and a grounding terminal; and a plurality of coaxial cables accommodated in said casing and having respective internal and external conductors for connecting said input and output terminals to said relay contact terminals of said high frequency relay; wherein said grounding terminal of said high frequency relay and said external conductors of said coaxial cables are connected to said ground layer of said printed circuit board, while each of said internal conductors of said coaxial cables is connected to one of said relay contact terminals of said high frequency relay; and wherein said printed circuit board has a plurality of recesses defined therein in which end portions of said coaxial cables are respectively received; said recesses having a depth that is determined such that said internal conductors are aligned with the second surface of said printed circuit board.
5. A high frequency signal switching unit comprising:
a casing; a printed circuit board accommodated in said casing and having a first surface and a second surface opposite to each other, said printed circuit board also having a ground layer formed on substantially the entire first surface; at least one input terminal and at least one output terminal both mounted on said casing; at least one high frequency relay mounted on said printed circuit board for switching between said input terminal and said output terminal so that a high frequency signal inputted into said input terminal is selectively outputted from said output terminal, said high frequency relay having a plurality of relay contact terminals and a grounding terminal; and a plurality of coaxial cables accommodated in said casing and having respective internal and external conductors for connecting said input and output terminals to said relay contact terminals of said high frequency relay; wherein said grounding terminal of said high frequency relay and said external conductors of said coaxial cables are connected to said ground layer of said printed circuit board, while each of said internal conductors of said coaxial cables is connected to one of said relay contact terminals of said high frequency relay; wherein said printed circuit board has a plurality of recesses defined therein in which end portions of said coaxial cables are respectively received; and wherein each of said internal conductors has a planar free end and a through-hole defined therein, into which one of said relay contact terminals is inserted.
2. A high frequency signal switching unit comprising:
a casing; a printed circuit board accommodated in said casing and having a first surface and a second surface opposite to each other, said printed circuit board also having a ground layer formed on substantially the entire first surface; at least one input terminal and at least one output terminal both mounted on said casing; at least one high frequency relay mounted on said printed circuit board for switching between said input terminal and said output terminal so that a high frequency signal inputted into said input terminal is selectively outputted from said output terminal, said high frequency relay having a plurality of relay contact terminals and a grounding terminal; and a plurality of coaxial cables accommodated in said casing and having respective internal and external conductors for connecting said input and output terminals to said relay contact terminals of said high frequency relay; wherein said grounding terminal of said high frequency relay and said external conductors of said coaxial cables are connected to said ground layer of said printed circuit board, while each of said internal conductors of said coaxial cables is connected to one of u said relay contact terminals of said high frequency relay, and wherein said printed circuit board has a plurality of grooves defined therein so as to extend across a thickness thereof, in which end portions of said coaxial cables are respectively received, said external conductors of said coaxial cables are directly connected to said ground layer of said printed circuit board along said plurality of grooves.
13. A high frequency signal switching unit comprising:
a casing; a printed circuit board accommodated in said casing and having a first surface and a second surface opposite to each other, said printed circuit board also having a ground layer formed on substantially the entire first surface; at least one input terminal and at least one output terminal both mounted on said casing; at least one high frequency relay mounted on said printed circuit board for switching between said input terminal and said output terminal so that a high frequency signal inputted into said input terminal is selectively outputted from said output terminal, said high frequency relay having a plurality of relay contact terminals and a grounding terminal; and a plurality of coaxial cables accommodated in said casing and having respective internal and external conductors for connecting said input and output terminals to said relay contact terminals of said high frequency relay; wherein said grounding terminal of said high frequency relay and said external conductors of said coaxial cables are connected to said ground layer of said printed circuit board, while each of said internal conductors of said coaxial cables is connected to one of said relay contact terminals of said high frequency relay; wherein said printed circuit board has a plurality of grooves defined therein so as to extend across a thickness thereof, in which end portions of said coaxial cables are respectively received; and wherein each of said internal conductors has a planar free end and a through-hole defined therein, into which one of said relay contact terminals is inserted.
6. A high frequency signal switching unit comprising:
a casing; a printed circuit board accommodated in said casing and having a first surface and a second surface opposite to each other, said printed circuit board also having a ground layer formed on substantially the entire first surface; at least one input terminal and at least one output terminal both mounted on said casing; at least one high frequency relay mounted on said printed circuit board for switching between said input terminal and said output terminal so that a high frequency signal inputted into said input terminal is selectively outputted from said output terminal, said high frequency relay having a plurality of relay contact terminals and a grounding terminal; and a plurality of coaxial cables accommodated in said casing and having respective internal and external conductors for connecting said input and output terminals to said relay contact terminals of said high frequency relay; wherein said grounding terminal of said high frequency relay and said external conductors of said coaxial cables are connected to said ground layer of said printed circuit board, while each of said internal conductors of said coaxial cables is connected to one of said relay contact terminals of said high frequency relay; wherein said printed circuit board has a plurality of grooves defined therein so as to extend across a thickness thereof, in which end portions of said coaxial cables are respectively received; and wherein said printed circuit board is a multi-layered construction having two layers formed one upon another with strip lines made of an electrically conductive material interposed therebetween, said printed circuit board also having two ground layers formed on external surfaces of said two layers, respectively, said strip lines connecting said relay contact terminals of said high frequency relay to said internal conductors of said coaxial cables, said external conductors of said coaxial cables are directly connected to said ground layer of said printed circuit board along said plurality of grooves.
9. A high frequency signal switching unit comprising:
a casing; a printed circuit board accommodated in said casing and having a first surface and a second surface opposite to each other, said printed circuit board also having a ground layer formed on substantially the entire first surface; at least one input terminal and at least one output terminal both mounted on said casing; at least one high frequency relay mounted on said printed circuit board for switching between said input terminal and said output terminal so that a high frequency signal inputted into said input terminal is selectively outputted from said output terminal, said high frequency relay having a plurality of relay contact terminals and a grounding terminal; and a plurality of coaxial cables accommodated in said casing and having respective internal and external conductors for connecting said input and output terminals to said relay contact terminals of said high frequency relay; wherein said grounding terminal of said high frequency relay and said external conductors of said coaxial cables are connected to said ground layer of said printed circuit board, while each of said internal conductors of said coaxial cables is connected to one of said relay contact terminals of said high frequency relay; wherein said printed circuit board has a plurality of recesses defined therein in which end portions of said coaxial cables are respectively received; wherein said printed circuit board is of a multi-layered construction having two layers formed one upon another with strip lines made of an electrically conductive material interposed therebetween, said printed circuit board also having two ground layers formed on external surfaces of said two layers, respectively, said strip lines connecting said relay contact terminals of said high frequency relay to said internal conductors of said coaxial cables; and wherein said printed circuit board has a plurality of recesses defined therein on one side thereof where connecting portions between said internal conductors of said coaxial cables and said strip lines are exposed.
18. A high frequency signal switching unit comprising:
a casing; a printed circuit board accommodated in said casing and having a first surface and a second surface opposite to each other, said printed circuit board also having a ground layer formed on substantially the entire first surface; at least one input terminal and at least one output terminal both mounted on said casing; at least one high frequency relay mounted on said printed circuit board for switching between said input terminal and said output terminal so that a high frequency signal inputted into said input terminal is selectively outputted from said output terminal, said high frequency relay having a plurality of relay contact terminals and a grounding terminal; and a plurality of coaxial cables accommodated in said casing and having respective internal and external conductors for connecting said input and output terminals to said relay contact terminals of said high frequency relay; wherein said grounding terminal of said high frequency relay and said external conductors of said coaxial cables are connected to said ground layer of said printed circuit board, while each of said internal conductors of said coaxial cables is connected to one of said relay contact terminals of said high frequency relay; wherein said printed circuit board has a plurality of grooves defined therein so as to extend across a thickness thereof, in which end portions of said coaxial cables are respectively received; wherein said printed circuit board is of a multi-layered construction having two layers formed one upon another with strip lines made of an electrically conductive material interposed therebetween, said printed circuit board also having two ground layers formed on external surfaces of said two layers, respectively, said strip lines connecting said relay contact terminals of said high frequency relay to said internal conductors of said coaxial cables; and wherein said printed circuit board has a plurality of recesses defined therein on one side thereof where connecting portions between said internal conductors of said coaxial cables and said strip lines are exposed.
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1. Field of the Invention
The present invention relates to a high frequency signal switching unit for switching a plurality of output terminals to selectively output therefrom a high frequency signal inputted from an input terminal or for switching between at least one input terminal and at least one output terminal.
2. Description of the Related Art
Each high frequency relay 10 is provided with a shielding plate 4 disposed around the relay contact terminals 11. Each coaxial cable 30 includes an internal conductor (core) 31 connected to one of the relay contact terminals 11 by soldering, and also includes an external conductor (in the case of the illustrated coaxial cable 30, the whole sheath is the external conductor) 32 joined to the shielding plate 4, which is in turn grounded. The shielding plate 4 is provided with chip capacitors C mounted thereon for absorbing high frequency signals that leak from the coaxial cables 30 to the lead wires 41.
By the above-described construction, the high frequency relays 10 are supplied with electricity via the relay connector 40 so that the high frequency signal inputted from one of the coaxial connectors 3 forming the input terminal may be selectively outputted from any one of the remaining four coaxial connectors 3.
In the conventional high frequency signal switching unit of the above-described construction, because the high frequency relays 10 are fixed to the metallic casing 1 by means of the conductive material, the positions of the high frequency relays 10 are not always fixed. Furthermore, because the coaxial cables 30 are supported by only the opposite connecting portions, a difficulty is encountered in positioning and temporarily fixing the coaxial cables 30 during assembling, thus lowering the working efficiency and increasing variation in the product characteristics. Also, shielding is not performed between the relay contact terminals 11 of the neighboring high frequency relays 10, thus deteriorating the insulation properties (high frequency characteristics).
The present invention has been developed to overcome the above-described disadvantages.
It is accordingly an objective of the present invention to provide a high frequency signal switching unit having improved high frequency characteristics, wherein the positions of the high frequency relays are fixed, and the coaxial cables can be readily positioned and temporarily fixed.
In accomplishing the above and other objectives, the high frequency signal switching unit according to the present invention includes a casing and a printed circuit board accommodated in the casing and having a first surface and a second surface opposite to each other. The printed circuit board also has a ground layer formed on substantially the entire first surface. The high frequency signal switching unit also includes at least one input terminal and at least one output terminal both mounted on the casing, and at least one high frequency relay mounted on the printed circuit board for switching between the input terminal and the output terminal so that a high frequency signal inputted into the input terminal is selectively outputted from the output terminal. The high frequency relay has a plurality of relay contact terminals and a grounding terminal. A plurality of coaxial cables having respective internal and external conductors are accommodated in the casing to connect the input and output terminals to the relay contact terminals of the high frequency relay. The grounding terminal of the high frequency relay and the external conductors of the coaxial cables are connected to the ground layer of the printed circuit board, while each of the internal conductors of the coaxial cables is connected to one of the relay contact terminals of the high frequency relay.
With this arrangement, because the high frequency relay is secured to the printed circuit board, the position thereof is fixed. Accordingly, the positioning and temporary fixing of the coaxial cables within the casing can be readily carried out. Furthermore, the grounding terminal of the high frequency relay and the external conductors of the coaxial cables are all connected to the ground layer of the printed circuit board, making it possible to improve the high frequency characteristics.
The printed circuit board has a plurality of recesses defined therein in which end portions of the coaxial cables are respectively received. This arrangement further facilitates the positioning of the coaxial cables relative to the printed circuit board.
Preferably, the external conductors have a diameter substantially equal to a width of the recesses. With this configuration, when the coaxial cables are inserted into respective recesses, the former are temporarily fixed. Accordingly, the distance between the relay contact terminals of the high frequency relay and the internal conductors of the associated coaxial cables is made substantially constant, thus stabilizing the high frequency characteristics.
The recesses are elongated in the axial directions of the coaxial cables. By so doing, the temporary fixing of the coaxial cables relative to the printed circuit board can be readily carried out, making it possible to enhance the working efficiency during assemblage of the coaxial cables.
The depth of the recesses is determined such that the internal conductors are aligned with the second surface of the printed circuit board. By so doing, the distance between the relay contact terminals of the high frequency relay and the internal conductors of the associated coaxial cables can be reduced, enhancing the high frequency characteristics.
The printed circuit board has a plurality of grooves defined therein so as to extend across a thickness thereof, in which end portions of the coaxial cables are respectively received. Because the formation of the grooves in the printed circuit board is relatively easy, the manufacturing cost of the high frequency signal switching unit can be reduced.
Advantageously, each of the grooves has an electrically conductive layer formed on an inner wall thereof, which is connected to the ground layer of the printed circuit board. The formation of the electrically conductive layer increases the contact area and connecting strength of the coaxial cables. Furthermore, the external conductors of the coaxial cables and the ground layer of the printed circuit board are connected at a reduced distance, resulting in an increase in ground strength and ensuring more reliable grounding.
Again advantageously, the printed circuit board has a plurality of through-holes defined therein, each of which communicates with a neighboring one of the grooves to accommodate one of the relay contact terminals of the high frequency relay. Each of the through-holes has an electrically conductive layer formed on an inner wall thereof, which is connected to the ground layer of the printed circuit board. The electrically conductive layer acts to shield the relay contact terminals, making it possible to enhance the insulation properties.
Conveniently, each of the internal conductors has a planar free end and a through-hole defined therein, into which one of the relay contact terminals is inserted. This configuration facilitates the assembling work and enhances the connecting strength between the internal conductors and the relay contact terminals.
The printed circuit board may be of a multi-layered construction having two layers formed one upon another with strip lines made of an electrically conductive material interposed therebetween. The strip lines are intended to connect the relay contact terminals of the high frequency relay to the internal conductors of the coaxial cables. In this case, the printed circuit board also has two ground layers formed on external surfaces of the two layers, respectively. By this construction, the positions of the coaxial cables and those of the relay contact terminals relative to the printed circuit board can be changed while suppressing the insertion loss as small as possible. Accordingly, the lengths of the coaxial cables can be made substantially constant, making it possible to reduce the manufacturing cost thereof.
The high frequency signal switching unit further includes a relay connector mounted on the casing for supplying the high frequency relay with electricity, wherein the high frequency relay has coil terminals, and the printed circuit board has a wiring pattern formed in the ground layer for connecting the relay connector to the coil terminals. The formation of the wiring pattern can reduce the number of the component parts and the size of the high frequency signal switching unit, compared with the case wherein the relay connector and the coil terminals are connected via lead wires.
Advantageously, the printed circuit board has a plurality of grooves defined therein so as to extend across a thickness thereof, in which end portions of the coaxial cables are respectively received. Each of the grooves has an electrically conductive layer formed on an inner wall thereof, which is connected to the two ground layers of the printed circuit board. With this arrangement, the two ground layers of the printed circuit board and the external conductors of the coaxial cables are all connected together via the electrically conductive layers, making it possible to further improve the high frequency characteristics.
It is preferred that the printed circuit board be made of a fluorine-contained resin. Because the fluorine-contained resin has a small dielectric dissipation factor, not only can the printed circuit board be made thin, but the insertion loss can also be reduced.
Advantageously, the printed circuit board has a plurality of recesses defined therein on one side thereof where connecting portions between the internal conductors of the coaxial cables and the strip lines are exposed. With this arrangement, the internal conductors of the coaxial cables can be connected directly to the strip lines and, hence, the insertion loss can be reduced. Also, the shielding between the neighboring strip lines can be achieved.
The high frequency signal switching unit further includes a conductor connected to the two ground layers of the printed circuit board, wherein the recesses of the printed circuit board are closed by the conductor. The conductor acts to enhance the shielding properties.
The conductor may be a ground layer formed on substantially one entire surface of another printed circuit board and connected to the two ground layers of the printed circuit board. The ground layer acts to enhance the shielding properties. In this case, if a component part adjacent to the strip lines is an insulator (substrate), short-circuiting can be prevented.
The high frequency signal switching further includes a relay connector mounted on the casing for supplying the high frequency relay with electricity, wherein the high frequency relay has coil terminals, and the another printed circuit board has a wiring pattern formed in the ground layer for connecting the relay connector to the coil terminals. With this arrangement, the possibility of high frequency signals jumping from the strip lines of the multi-layered printed circuit board to the wiring pattern for connecting the relay connector and the coil terminals of the high frequency relay is reduced. As a result, capacitors that have been hitherto used to absorb leakage of the high frequency signals can be dispensed with, making it possible to reduce the number of the component parts and the manufacturing cost.
The above and other objectives and features of the present invention will become more apparent from the following description of preferred embodiments thereof with reference to the accompanying drawings, throughout which like parts are designated by like reference numerals, and wherein:
This application is based on an application No. 2000-157256 filed May 26, 2000 in Japan, the content of which is, herein expressly incorporated by reference in its entirety.
The term "grounding terminal" as employed throughout this application is defined as a terminal required to obtain high frequency matching, which creates a specific impedance to provide required high frequency characteristics.
Referring now to the drawings, there is shown in
Each high frequency relay 10 is a mechanical relay having a metallic casing in which relay contacts, a coil and the like are accommodated and through which relay contact terminals 11 leading to the relay contacts (switching contacts in this embodiment), coil terminals 12 for supplying electricity to drive the coil, and a grounding terminal 13 extend outwardly. This mechanical relay is superior in high frequency characteristics such, for example, as isolation or insertion loss, the voltage standing wave ratio (VSWR), or the like.
Discussion and Illustration of the construction of the high frequency relay 10 is omitted, because it is well known.
The coaxial connector 3 is a high frequency one that has a threaded connecting portion and a coaxial cable 30 having an internal conductor (core) 31 and an exposed external conductor 32 in which the internal conductor 31 is accommodated. The whole sheath, made of knitted wires, forms the external conductor 32.
As shown in
As best shown in
As described above, the grounding terminals 13 of the high frequency relays 10 and the external conductors 32 of the coaxial cables 30 are connected to the ground layer 21 of the printed circuit board 20, while the internal conductors 31 of the coaxial cables 30 are connected to the relay contact terminals 11 of the high frequency relays 10. That is, all the high frequency relays 10 are secured to the printed circuit board 20 and, hence, the positions of the high frequency relays 10 are fixed, unlike the conventional high frequency signal switching unit shown in FIG. 17. Accordingly, the positioning and temporary fixing of the coaxial cables 30 within the metallic casing 1 can be readily carried out, thus facilitating the assembling work. Furthermore, the grounding terminals 13 of the high frequency relays 10 and the external conductors 32 of the coaxial cables 30 are all connected to the same ground layer 21 of the printed circuit board 20. Because the ground is integrated in this manner, the high frequency characteristics are improved. If a fluorine-contained resin having a small dielectric dissipation factor such, for example, as a polymer of ethylene tetrafluoride (trade name: Teflon) is used for the substrate of the printed circuit board 20, not only can the printed circuit board 20 be made thin, but the insertion loss can also be reduced.
As shown in
Because the end portion of each coaxial cable 30 is received in the associated elongated recess 25 in the printed circuit board 20, the positioning of the coaxial cable 30 relative to the printed circuit board 20 is further facilitated. Also, because the width of the elongated recess 25 is substantially equal to the diameter of the external conductor 32, the end portion of the coaxial cable 30 is fast held by opposite inner side walls of the elongated recess 25 and, hence, it is unlikely that the coaxial cable 30 received in the elongated recess 25 moves laterally. Accordingly, the distance between the relay contact terminal 11 of the high frequency relay 10 and the internal conductor 31 of the coaxial cable 30 is kept substantially constant, making it possible to stabilize the high frequency characteristics. Moreover, because the recess 25 is elongated in the axial direction of the coaxial cable 30, the temporary fixing of the coaxial cable 30 relative to the printed circuit board 20 can be readily carried out, thus enhancing the working efficiency during assemblage of the coaxial cable 30.
In addition, because the depth of the elongated recess 25 is so determined that the internal conductor 31 of the coaxial cable 30 is aligned with the front face of the printed circuit board 20, the internal conductor 31 of the coaxial cable 30 is placed on the front face of the printed circuit board 20 under the condition in which the coaxial cable 30 is appropriately received within the elongated recess 25, as shown in FIG. 5. As a result, the free end of the internal conductor 31 is positioned adjacent to the relay contact terminal 11, thus improving the high frequency characteristics.
As shown in
Compared with the elongated recess 25 shown in
As shown in
The formation of the electrically conductive layers 26a increases the contact area of the coaxial cables 30, resulting in an increase in the connecting strength. Also, because the ground layer 21 and the electrically conductive pattern 22 are connected to each other via the electrically conductive layers 26a and not via the through-holes, the external conductors 32 of the coaxial cables 30 are connected to the ground layer 21 at a reduced distance, making it possible to increase the strength of the ground.
As shown in
Because the electrically conductive layer 27a acts to shield the relay contact terminal 11, the insulation properties are enhanced. It is preferred that the free end of the relay contact terminal 11 be cut at a position lower than the thickness of the printed circuit board 20 so that the relay contact terminal 11 may not serve as an antenna that radiates noise.
As shown in
As shown in
The printed circuit board 50 has a plurality of grooves 53 (only one is shown) extending across the thickness thereof and each accommodating the end portion of one of the coaxial cables 30. Each groove 53 has electrically conductive layers 54 formed on opposite inner side walls thereof. The electrically conductive layers 54 are connected to both the upper and lower ground layers 51. The groove 53 has a width substantially equal to the diameter of the external conductor 32 of the coaxial cable 30 and, hence, if the coaxial cable 30 is received in the groove 53, the internal conductor 31 of the coaxial cable 30 is placed on the associated one of the strip lines 52, as best shown in FIG. 13. The electrically conductive layers 54 are formed by plating the inner side walls of the groove 53 with solder so that the electrically conductive layers 54 may be connected to the ground layers 51 on the opposite faces of the printed circuit board 50.
As shown in
The multi-layered construction of the printed circuit board 50 can considerably reduce the insertion loss and allows the positions of the coaxial cables 30 or those of the relay contact terminals 11 relative to the printed circuit board 50 to change. Because of this, all the coaxial cables 30 can have substantially the same length, making it possible to reduce the manufacturing cost thereof. Also, because the electrically conductive layers 54 leading to the ground layers 51 are formed on the inner side walls of each groove 53, the external conductors 32 of the coaxial cables 30 are connected to the ground layers 51 at a reduced distance, enhancing the high frequency characteristics. Furthermore, because the generally rectangular recesses 55 are provided where the connecting portions between the internal conductors 31 of the coaxial cables 30 and the strip lines 52 in the printed circuit board 50 are exposed, the internal conductors 31 can be directly connected to the strip lines 52, making it possible to reduce the insertion loss and shield each strip line 52 from the neighboring strip lines 52. In addition, because the openings of the generally rectangular recesses 55 are covered with the printed circuit board 60 having the ground layer 61, the ground layer 61 acts to enhance the shielding properties, and an insulator of the printed circuit board 60 positioned in the proximity of the strip lines 52 prevents short-circuiting from occurring.
If a wiring pattern 56 for use in connecting terminals (not shown) of the relay connector 40 and the coil terminals 12 of the high frequency relays 10 is formed in one of the ground layers 51, as shown in
Although in the above-described embodiments the high frequency signal switching unit has been described as having a plurality of high frequency relays, it may have only one high frequency relay, as shown in FIG. 15. Furthermore, although in the illustrated embodiments the high frequency signal switching unit has one input terminal and a plurality of output terminals, it may have a plurality of input terminals and a plurality of output terminals, as shown in FIG. 16. The present invention is applicable to high frequency signal switching units having at least one high frequency relay, at least one input terminal, and at least one output terminal.
Although the present invention has been fully described by way of examples with reference to the accompanying drawings, it is to be noted here that various changes and modifications will be apparent to those skilled in the art. Therefore, unless such changes and modifications otherwise depart from the spirit and scope of the present invention, they should be construed as being included therein.
Inoue, Kazuhiko, Nishikawa, Masakazu, Anzai, Tsunehiro, Fujii, Kazuhisa
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May 24 2001 | Matsushita Electric Works, Ltd. | (assignment on the face of the patent) | / |
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