The present application is based on Japanese patent application No. 2014-135991 filed on Jul. 1, 2014, the entire contents of which are incorporated herein by reference.
1. Field of the Invention
The present invention relates to an active cable.
2. Description of the Related Art
A cable with a connector, the cable including a cable provided with a plurality of differential signal transmission cables that are built therein and a connector provided at each of both ends of the cable, is used.
A paddle card that electrically connects a connection target device and the differential signal transmission cables to one another is built in the connector. A cable including a compensation circuit that actively compensates an electric signal in accordance with a loss property of the differential signal transmission cables and outputs the compensated electric signal to a transmission channel at a reception side in the paddle card, that is, a transmission channel through which an electric signal input from the differential signal transmission cable to the device, is also referred to as an active cable (an active direct-attach cable, an active DAC, or an active copper cable (ACC)).
As illustrated in
A plurality of transmission side electrodes 46 and a plurality of reception side electrodes 47, which are electrically connected to the device, are formed at one end portion of the paddle card 45. Also, a plurality of for-cable-connection transmission side electrodes 48 to which the differential signal transmission cables 42 for transmission are electrically connected and a plurality of for-cable-connection reception side electrodes 49 to which the differential signal transmission cables 42 for reception are connected are formed in the other end portion of the paddle card 45.
The transmission side electrodes 46 and the for-cable-connection transmission side electrodes 48 corresponding thereto are electrically connected to one another via a transmission side transmission channel 50. The reception side electrodes 47 and the for-cable-connection reception side electrodes 49 corresponding thereto are electrically connected to one another via a reception side transmission channel 51. A compensation circuit 52 that actively compensates an electric signal in accordance with a loss property of the differential signal transmission cables 42 and outputs the compensated electric signal is provided in the reception side transmission channel 51.
Ground layers 53 that are shared by a transmission side and a reception side are formed in an inner layer and a back layer (other layers than layers in which the transmission channels 50 and 51 are formed) of the paddle card 45.
In the known active cable 41, each of the transmission side transmission channel 50 and the reception side transmission channel 51 has a microstrip structure, and both of the transmission side transmission channel 50 and the reception side transmission channel 51 are formed in the same layer (a surface layer of the paddle card 45).
Note that, as relevant art document information related to the present invention, there is Japanese Unexamined Patent Application Publication No. 2013-122825.
In general, however, in an active cable, in particular, when long distance transmission is performed using a long cable, a difference in signal level between a transmission side and a reception side is increased, and the active cable is more likely to be influenced by near-end crosstalk caused by a common mode.
In the known active cable 41, the transmission side transmission channel 50 and the reception side transmission channel 51 are formed in the same layer, and therefore, a problem arises in which, in particular, crosstalk tends to be increased due to connection between lines.
It is therefore an object of the present invention to solve the above-described problem and provide an active cable which is capable of reducing crosstalk.
According to one exemplary aspect of the invention, an active cable includes a cable provided with a plurality of differential signal transmission cables, a connector provided at each of both ends of the cable, a paddle card formed of a multilayer substrate which is built in the connector and is configured such that an electrode electrically connected to a connection target device is formed at one end thereof and the differential signal transmission cables are electrically connected to the other end thereof to electrically connect the device and the differential signal transmission cables to one another, a transmission side transmission channel formed in the paddle card and configured to transmit an electric signal input from the device to the differential signal transmission cables, a reception side transmission channel formed in the paddle card and configured to transmit an electric signal input from the differential signal transmission cables to the device, and a compensation circuit provided in the reception side transmission channel and configured to compensate an electric signal input from the differential signal transmission cables in accordance with a loss property of the differential signal transmission cables and output the compensated electric signal, and in which a ground pattern is formed so as to sandwich one or both of a part of the transmission side transmission channel located at a side closer to the other end than the compensation circuit and a part of the reception side transmission channel located at a side closer to the other end than the compensation circuit.
In the above exemplary invention, the following exemplary modifications and changes can be made alone or in any combination thereof.
(i) The transmission side transmission channel and the reception side transmission channel may be formed in a surface layer of the paddle card, and the ground pattern may be formed so as to sandwich one or both of the part of the transmission side transmission channel located at a side closer to the other end than the compensation circuit and the part of the reception side transmission channel located at a side closer to the other end than the compensation circuit in a direction parallel to a surface of the paddle card, thereby providing a transmission channel having a coplanar structure.
(ii) One of the part of the transmission side transmission channel located at a side closer to the other end than the compensation circuit and the part of the reception side transmission channel located at a side closer to the other end than the compensation circuit may be formed in an inner layer of the paddle card via a via and the ground pattern may be formed so as to sandwich the transmission channel formed in the inner layer in a thickness direction of the paddle card, thereby providing a transmission channel having a strip structure.
(iii) The reception side transmission channel may be formed in the surface layer of the paddle card and the transmission side transmission channel may be formed in an inner layer of the paddle card, thereby providing a strip structure.
(iv) The paddle card may include a ground layer which is divided into a first ground layer corresponding to the transmission side transmission channel and a second ground layer corresponding to the reception side transmission channel.
According to the present invention, an active cable which is capable of reducing crosstalk can be provided.
The foregoing and other exemplary purposes, aspects and advantages will be better understood from the following detailed description of the invention with reference to the drawings, in which:
Referring now to the drawings, and more particularly to
As illustrated in
In this embodiment, a case where the active cable 1 is configured such that single-channel transmission and reception is enabled will be described. In this case, the active cable 1 includes one differential signal transmission cable 2 for each of transmission and reception, that is, two differential signal transmission cables 2 in total.
A plurality of transmission side electrodes 6 and a plurality of reception side electrodes 7, which are electrically connected to the device, are formed in one end portion (an end portion at an opposite side to a connection side to which the cable 3 is connected) of a surface of the paddle card 5. In addition to the transmission side electrodes 6 and the reception side electrodes 7, a ground electrode 15, a for-power-supply electrode (not illustrated), a for-control-signal electrode (not illustrated), and the like, are formed in the one end portion of the surface of the paddle card 5 so as to align with one another, thereby forming a card edge connector.
A plurality of for-cable-connection transmission side electrodes 8 to which a differential signal transmission cable 2a for transmission is electrically connected and a plurality of for-cable-connection reception side electrodes 9 to which a differential signal transmission cable 2b for reception is electrically connected are formed in the other end portion (an end portion at the connection side to which of the cable 3 is connected) of the paddle card 5. Note that outputting an electric signal from the paddle card 5 to the differential signal transmission cables 2 is herein referred to as transmission, and inputting an electric signal from the differential signal transmission cables 2 to the paddle card 5 is herein referred to as reception.
Each of the transmission side electrodes 6 and a corresponding one of the for-cable-connection transmission side electrodes 8 are electrically connected to one another via a transmission side transmission channel 10. The transmission side transmission channel 10 is used in transmitting an electric signal input from the device via the transmission side electrodes 6 to the for-cable-connection transmission side electrodes 8 and then transmitting the electric signal to the differential signal transmission cable 2a, and is formed of a wiring pattern formed mainly on the paddle card 5.
Each of the reception side electrodes 7 and a corresponding one of the for-cable-connection reception side electrodes 9 are electrically connected to one another via a reception side transmission channel 11. The reception side transmission channel 11 is used in transmitting an electric signal input from the differential signal transmission cable 2b via the for-cable-connection reception side electrodes 9 to the reception side electrodes 7 and then transmitting the electric signal to the device, and is formed of a wiring pattern formed mainly on the paddle card 5.
A compensation circuit 12 that actively compensates an electric signal input from the differential signal transmission cable 2b in accordance with a loss property of the differential signal transmission cable 2b and outputs the compensated electric signal is provided on the reception side transmission channel 11.
In this embodiment, a four-layer substrate is used as the paddle card 5, the transmission side transmission channel 10 and the reception side transmission channel 11 are formed in a first layer (a surface layer), and a ground layer 13 is formed in each of second to fourth layers.
In this embodiment, each of the ground layers 13 formed in the second to fourth layers of the paddle card 5 is divided into a ground layer 13a (first ground layer) corresponding to the transmission side transmission channel 10 and a ground layer 13b (second ground layer) corresponding to the reception side transmission channel 11. A slit 16 is formed between the ground layer 13a and the ground layer 13b and the ground layers 13a and 13b are separated from one another by the slit 16. Reduction in crosstalk between transmission and reception is enabled by dividing the ground layer 13 between the transmission side and the reception side.
Since the transmission side transmission channel 10 and the reception side transmission channel 11 are formed at a left side and a right side of
In the active cable 1 according to this embodiment, the ground pattern 14 is formed so as to sandwich a part of the transmission side transmission channel 10 located at a side (a differential signal transmission cable 2 side) closer to the other end than the compensation circuit 12.
In this embodiment, a case where the ground pattern 14 is formed so as to sandwich the entire transmission side transmission channel 10 is described, but the ground pattern 14 may be formed so as to sandwich at least the part of the transmission side transmission channel 10 located at a side closer to the other end than the compensation circuit 12. This is because, in particular, in long distance transmission, an electric signal at the reception side before being compensated by the compensation circuit 12 has a low signal level and is likely to be influenced by crosstalk from the transmission side.
In this embodiment, the ground pattern 14 is formed so as to sandwich the transmission side transmission channel 10 in a direction parallel to the surface of the paddle card 5, thereby providing a transmission channel having a coplanar structure. In this case, the transmission side transmission channel 10 is formed so as to extend linearly along a length direction (a left-and-right direction in
The ground pattern 14 is formed so as to extend from a ground electrode 15 to the other end of the paddle card 5 and to have a strip shape extending across substantially the entire paddle card 5.
By forming the ground pattern 14, leakage of electric field to the reception side may be reduced, and thus, reduction in crosstalk may be enabled.
Note that, although, in this embodiment, a case where the ground pattern 14 is formed so as to sandwich the transmission side transmission channel 10 has been described, the ground pattern 14 is not limited thereto, the ground pattern 14 may be formed so as to sandwich a part of the reception side transmission channel 11 located at a side closer to the other end than the compensation circuit 12, and the ground pattern 14 may be formed so as to sandwich each of both of a part of the transmission side transmission channel 10 located at a side closer to the other end than the compensation circuit 12 and a part of the reception side transmission channel 11 located at a side closer to the other end than the compensation circuit 12.
As has been described above, in the active cable 1 according to this embodiment, the ground pattern 14 is formed so as to sandwich one of the part of the transmission side transmission channel 10 located at the side (the differential signal transmission cable 2 side) closer to the other end than the compensation circuit 12 and the part of the reception side transmission channel 11 located at the side closer to the other end than the compensation circuit 12, or both of the parts.
Thus, in a region located at a side closer to the other end than the compensation circuit 12, which is a region that is likely to be influenced by crosstalk, at least one of the transmission side transmission channel 10 and the reception side transmission channel 11 is sandwiched by the ground pattern 14 and thus is shielded, so that leakage of electric field from the transmission side to the reception side may be reduced and reduction in crosstalk may be enabled.
Also, in a related art technique, in order to reduce the influence of crosstalk, the compensation circuit 12 has to be formed in as a close position to the for-cable-connection reception side electrodes 9 as possible, but in this embodiment, the influence of crosstalk may be reduced, and therefore, the compensation circuit 12 may be formed in any position on the paddle card 5, thus resulting in increase in the degree of freedom of layout.
Next, another embodiment of the present invention will be described.
An active cable 21 illustrated in
The via 22 is formed in each of a position immediately near each for-cable-connection transmission side electrode 8 and a position immediately near each transmission side electrode 6 so as to connect the transmission side transmission channel 10 formed in the inner layer to each of the for-cable-connection transmission side electrodes 8 and to the transmission side electrodes 6.
In this case, the transmission side transmission channel 10 is formed in the second layer of the paddle card 5, but may be formed in another layer. The ground pattern 23 is formed in a layer in which the transmission side transmission channel 10 is formed and an adjacent layer thereto. In this case, the ground pattern 23 is formed in the first layer (the surface layer) and the third layer. Note that the ground pattern 23 is a part of the ground layer 13 and is also the ground layer 13a corresponding to the transmission side transmission channel 10.
Also, in this embodiment, substantially the entire transmission side transmission channel 10 is formed into a strip structure, but at least a part of the transmission side transmission channel 10 located at a side closer to the other side than the compensation circuit 12 may be formed to have a strip structure.
Furthermore, in this embodiment, the transmission side transmission channel 10 has a strip structure, but the reception side transmission channel 11 may be formed to have strip structure. However, since there is the compensation circuit 12, in order to form the reception side transmission channel 11 having a strip structure, many vias 22 have to be formed (or only a part thereof located at a side closer to the other side than the compensation circuit 12 may be formed into a strip structure). Therefore, the transmission side transmission channel 10 the entire part of which may be formed into a strip structure is preferably formed into a strip structure.
Note that forming each of the transmission side transmission channel 10 and the reception side transmission channel 11 into a strip structure is another option, but in this case, at least the transmission side transmission channel 10 and the reception side transmission channel 11 have to be formed in different layers. It costs to form the via 22 in each of the transmission channels 10 and 11, and therefore, it is preferable to form only one of the transmission channels 10 and 11 into a strip structure.
The ground pattern 23 formed in the surface layer is formed so as to cover a part surrounding the for-cable-connection transmission side electrodes 8, the transmission side electrodes 6, and the vias 22 formed immediately near the for-cable-connection transmission side electrodes 8 and the transmission side electrodes 6 such that electric field does not leak from the transmission side to the reception side.
In the active cable 21, the transmission channels 10 and 11 are formed in different layers, and the transmission side transmission channel 10 is formed so as to be sandwiched by the ground pattern 23 having a large area in the thickness direction, so that further reduction in influence of crosstalk from the transmission side to the reception side may be enabled.
The present invention is not limited to the above-described embodiments and it is needless to say that modifications may be made thereto without departing from the gist of the present invention.
For example, in the above-described embodiments, a case where a configuration which enables single-channel transmission and reception is has been described, but the present invention is not limited thereto, a configuration which enables transmission and reception using a plurality of channels may be provided.
For example, as an active cable 31 illustrated in
In order to form the transmission side transmission channel 10 into a strip structure, three layers are needed, and the transmission side transmission channel 10 has to be formed in each of the surface side and the back surface side of the paddle card 5 in the active cable 31. Therefore, a paddle card 5 including six or more layers has to be used.
Number | Date | Country | Kind |
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2014-135991 | Jul 2014 | JP | national |
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5999796 | Tresness | Dec 1999 | A |
20060089053 | Morlion | Apr 2006 | A1 |
20080266019 | Fusayasu | Oct 2008 | A1 |
20110100694 | Regnier | May 2011 | A1 |
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Number | Date | Country |
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2013-122825 | Jun 2013 | JP |
Number | Date | Country | |
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20160006181 A1 | Jan 2016 | US |