Abstract:
A method and system for configuring the transmit and receive elements or structures in connector such that crosstalk can be reduced. The connector connects serdes modules in first PCB to serdes modules in one or more second PCBs via a backplane. The connector includes: first and second transmit connection positions in a first direction; first and second receive connection positions; and a ground shield positioned in the first direction between the first and second transmit connection positions and the first and second receive connection positions, wherein the first and second transmit connection positions do not have an interposing ground shield in another direction.

Description:
FIELD OF THE INVENTION 
   The present invention relates generally to backplanes and more specifically, transmitter and receiver connection arrangements in a high-speed serial backplane. 
   BACKGROUND 
   Serial backplanes have become popular for providing high-speed connections between printed circuit boards (PCBs). Typically, serial backplanes employ a serializer at a transmitting end to convert and transmit data in serial order, and a deserializer at a receiving end to convert the data back to parallel form once received. Such serializer/deserializer (“serdes”) modules have become the benchmark for asynchronous communication and have provided clear advantages over parallel busses. 
     FIG. 1  is a diagram of two PCBs  110  and  112  connected together via a high-speed serial backplane  114 . Printed circuit board  110  includes a central processing unit (CPU)  120  connected to a random access memory (RAM)  122  and logic  124 . PCB board  110  also includes a serdes  126  connected to logic  124 . The CPU  120 , RAM  122 , logic  124 , and serdes  126  may be part of a programmable logic device (PLD), for example, a field programmable gate array (FPGA) such as Virtex II Pro™ from Xilinx Corp. of San Jose, Calif., which is attached to board  110 . Printed circuit board  112  includes circuitry similar to board  110  (and also may be part of a second FPGA), such as serdes  140  connected to logic  142 , which in turn is connected to CPU  144  and RAM  146 . Serdes  126  is connected to serdes  140  via high-speed serial backplane  114 . Serdes  126  transmits serial data over signal line  132  to the receiver at serdes  140 . Serdes  140  transmits serial data over signal line  136  to the receiver at serdes  126 . Connection points  130 ,  133 ,  134 , and  137  indicate were a connector may be used to connect the PCBs e.g., boards  110  and  112 , to backplane  114 . 
   The PCBs (normally called daughtercards), e.g., PCBs  110  and  112 , are affixed to circuit board connectors, which allow the PCBs to be electrically connected to the backplane  114 . Typically a series of circuit board connectors are spaced regularly along the length of the backplane. Multiple circuit layers of the backplane route the transmit and receive signals and power to the connectors and hence connect the PCBs to each other. Plated through holes electrically interconnect runs of different circuit layers as needed. 
     FIG. 2  is a simplified side view of an example of a daughter card connector  210  and its associated backplane connector  220  of the prior art. This simplified view represents the GbX™ 4-Pair daughtercard signal module, i.e., a daughtercard connector, and backplane signal module, i.e., a backplane connector, of Teradyne Inc. of Boston, MA. A daughtercard  212  may be, for example, board  110  or board  112  of  FIG. 1 . The daughtercard  212  is affixed to daughtercard connector  210 . Daughtercard connector  210  is plugged into backplane connector  220 . Backplane connector  220  has the pins, e.g., pins  230 ,  231 ,  232 ,  233 ,  234 ,  235 ,  236 , and  237 . Daughtercard connector  210  has an area  214 , which has the corresponding female structures to receive the pins. 
   Backplane connector  220  is affixed to backplane  222  (which is similar to backplane  114  of  FIG. 1 ). Backplane connector  220  includes an array of pins (e.g., 8×25).  FIG. 2  shows a sideview subset of eight pins, e.g.,  230 – 237 , and three ground shields  240 ,  242  and  244  interposed between each pair of pins, e.g., pin pairs  230 / 231 ,  232 / 233 ,  234 / 235 , and  236 / 237 , respectively. The pin pairs, e.g.,  230  and  231 , may receive/transmit a differential signal, where, for example, pin  230  may be the positive(P) part and pin  231  may be the negative(N) part of the differential signal. For purposes of illustration, the pins  230 – 237  are part of a “column”, e.g., column  310 , in a connector pin assignment array as shown in  FIG. 3 . Each ground shield, e.g.,  240 ,  242  or  244 , is made up of a metal plate and is connected to ground to provide shielding between the pin pairs. 
     FIG. 3  shows a prior art connector pin assignment  300  for multiple serdes modules on a daughter card. The connector positions TXP  320  and TXN  322  indicate that the positive transmit signal (TXP) of a first serdes and the negative transmit signal (TXN) of the first serdes is assigned to pins  230  and  231  in a first column  310  and first row  350 . The connector positions RXP  324  and RXN  326  indicate that the positive receive signal (RXP) of the first serdes and the negative receive signal (RXN) of the first serdes is assigned to pins in row  350  and column  312  (not shown in  FIG. 1 ). Similarly, the connector positions TXP  330  and TXN  332  indicate that the positive transmit signal (TXP) of a second serdes and the negative transmit signal (TXN) of the second serdes is assigned to row  350  and column  314  (not shown in  FIG. 1 ). The connector positions RXP  334  and RXN  336  indicate that the positive receive signal (RXP) of the second serdes and the negative receive signal (RXN) of the second serdes is assigned to row  350  and column  316  (not shown in  FIG. 1 ). In addition, the connector positions TXP  340  and TXN  342  indicate that the positive transmit signal (TXP) of a third serdes and the negative transmit signal (TXN) of the third serdes is assigned to pins  232  and  233  in column  310  and row  352 . The connector positions RXP  344  and RXN  346  indicate that the positive receive signal (RXP) of the third serdes and the negative receive signal (RXN) of the third serdes is assigned to other pins in a second row  352  and column  312  (not shown in  FIG. 1 ). Connector positions TXP  360  and TXN  362  are assigned to pin positions of  234  and  235  in  FIG. 1 . Connector positions TXP  364  and TXN  366  are assigned to pin positions of  236  and  237  in  FIG. 1 . 
   The connector pin assignment  300  of  FIG. 3  forms an array with columns  310 ,  312 ,  314  and  316 , and rows  350 ,  352 ,  354 , and  356 . In each element of the array, for example, column  310  and row  350 , is a differential pair, e.g., TXP  320  and TXN  322 , indicating a positive and negative portion of a differential signal. Ground shields, e.g.  240 ,  242 , and  244 , are interposed between each row, e.g.,  350 / 352 ,  352 / 354 , and  354 / 356 , respectively. The side view in  FIG. 2  of backplane  220  shows only the first column  310  and for the example of the GbX™ connector, there may be 25 columns of which only four columns are shown in  FIG. 3 . 
   As the speed of data transmission increases into the gigahertz range and beyond, near-end cross talk becomes a significant problem for connector pin assignments such as that of  FIG. 3 . As the transmit signal, is relatively much larger than the receive signal, the transmit signal couples with the receive signal. For example, the differential transmit signal from TXP  320  and TXN  322  couples into the signal received by RXP  324  and RXN  326  and also the signal received by RXP  334  and RXN  336 . Since linear equalization circuits cannot typically distinguish a signal from the crosstalk, it is difficult to correct for the crosstalk using circuitry alone. In addition, the transmit circuits may have a transmit pre-emphasis which aggravates the crosstalk. 
   One prior technique used to reduce cross talk was to either completely shield the transmitters or the receivers. For example, in  FIG. 3 , TXP  320  and TXN  322  would have a ground shields on all four sides. Or, for example, RXP  334  and RXN  336  would have ground shields on all four sides. In effect there would not only be ground shields  240 ,  242 , and  244  in the horizontal direction, but ground shields in the vertical direction (not shown) between columns  310 / 312 ,  312 / 314 ,  314 / 316 , and so forth. In the case of the GbX™ 4-Pair backplane signal module, there may be 25 columns. This is a difficult and expensive solution and is typically impractical to implement. 
   Therefore, an improved connector pin assignment is needed to reduce the crosstalk in a high-speed serial backplane, where the ground shields are substantially in only one direction. 
   SUMMARY 
   The present invention relates generally to a method and system for configuring the transmit and receive elements or structures in connector such that crosstalk can be reduced. The connector connects serdes modules in first PCB to serdes modules in one or more second PCBs via a backplane. 
   An embodiment of the present invention includes a connector for connecting a circuit board to a backplane. The connector includes: first and second transmit connection positions in a first direction; first and second receive connection positions; and a ground shield positioned in the first direction between the first and second transmit connection positions and the first and second receive connection positions, wherein the first and second transmit connection positions do not have an interposing ground shield in another direction. 
   Another embodiment of the present invention includes a connector to a serial backplane. The connector includes: first receive connection elements on the connector for at least two serializer/deserializer modules, wherein two of the first receive connection elements do not have a first interposing ground plane; second transmit connection elements for the at least two serializer/deserializer modules, wherein the second transmit connection elements are separated from the first receive connection elements by a second interposing ground plane. The connector may further include: third transmit connection elements for other serializer/deserializer modules, the third transmit connection elements positioned adjacent to the second transmit connection elements, wherein the third transmit connection elements are separated from the second transmit connection elements by a third interposing ground plane; and fourth receive connection elements for the other serializer/deserializer modules, where the fourth receive connection elements are positioned adjacent to the third transmit connection elements, wherein the fourth receive connection elements are separated from the third transmit connection elements by a fourth interposing ground plane. 
   Yet another embodiment of the present invention has a method for connecting serializer/deserializer modules to a backplane. The method includes a step of selecting transmit/receive pairs from the serializer/deserializer modules, where each transmit/receive pair has an associated transmit connection structure and an associated receive connection structure in a connector; and a step of configuring a ground structure between the associated transmit connection structures and the associated receive connection structures, wherein there is no interposing ground structure between the associated receive connection structures or the associated transmit connection structures. 
   The present invention will be more full understood in view of the following description and drawings. 

   
     BRIEF DESCRIPTION OF THE DRAWINGS 
       FIG. 1  is a diagram of two PCBs connected together via a high speed serial backplane of the prior art; 
       FIG. 2  is a simplified side view of an example of a daughter card connector and its associated backplane connector of the prior art; 
       FIG. 3  shows a prior art connector pin assignment for multiple serdes modules on a daughtercard; 
       FIG. 4  is a partial connector pin assignment of a preferred embodiment of the present invention; 
       FIG. 5  is a diagram of some of the connections between two board connectors of an aspect of the present invention; 
       FIG. 6  is a backplane specification of an aspect of the present invention; 
       FIG. 7  is a table of the layers of a backplane of an aspect of the present invention. 
   

   DETAILED DESCRIPTION 
   In the following description, numerous specific details are set forth to provide a more thorough description of the specific embodiments of the invention. It should be apparent, however, to one skilled in the art, that the invention may be practiced without all the specific details given below. In other instances, well known features have not been described in detail so as not to obscure the invention. 
   For serdes modules there is typically a transmit/receive pair of circuits, hence an associated pair of transmit/receive connection elements or structures. In one embodiment of the present invention, the transmit connection elements (or structures) and receive connection elements (or structures) may be pairs of pins indicated by differential pin assignments TXP/TXN and RXP/RXN, respectively. In another embodiment the transmit/receive connection elements or structures may be the corresponding female elements or structures to receive the pairs of pins. In other embodiments rather that differential signals, the signals may be single-ended, e.g., only one pin rather than a pair of pins, and while the following description of the preferred embodiment is for a differential signal, it should be understood that single-ended signals and a mixture of differential and single-ended signals are also included in the scope of the present invention. 
   From  FIG. 3 , one of the reasons there is crosstalk is that there is a mixture of receive connection positions and transmit connection positions in a single row. A preferred embodiment of the present invention has all transmit differential pairs (TXP/TXN) on a first row and the corresponding serdes receive differential pairs (RXP/RXN) on a second row (which may be adjacent to the first row), where the first row and second row are separated by a ground plane or structure, such as a ground shield of  FIG. 1 . In the preferred embodiment the ground shields are configured in the backplane connector  220  of  FIG. 2 . In an alternative embodiment the ground shields are configured in the daughtercard connector  210 . 
     FIG. 4  is a partial connector pin assignment  400  of a preferred embodiment of the present invention. The complete connector assignment in the preferred embodiment includes four rows and 25 columns.  FIG. 4  shows four columns  410 ,  412 ,  414 , and  416  and four rows  450 ,  452 ,  454 , and  456 . The ground planes or structures, for example, ground shields  240 ,  242  and  244  (from  FIG. 1 ) separate each row.  FIG. 4  is similar to  FIG. 3 , except the connector pin positions have been reassigned so that each row has only differential receive pin pair connection positions (RXP/RXN) or differential transmit pin pair connection positions (TXP/TXN). The labels for the differential pin pair connection positions in  FIG. 4  have been maintained from  FIG. 3  to show how the pin pair connection positions have been moved. 
   For example TXP  320  and TXN  322  which was in row  350  and column  310  of  FIG. 3  has been moved to row  452  and column  410  of  FIG. 4 . The associated serdes differential receive pair RXP  324  and RXN  326  located in row  350  and column  312  of  FIG. 3  has been moved to row  450  and column  410  of  FIG. 4 . TPX  340  and TXN  342  in row  352  and column  310  has been moved to row  452  and column  412 . RXP  344  and RXN  346  in row  352  and column  312  has been moved to row  450  and column  412 . TPX  330  and TXN  332  in row  350  and column  314  have been moved to row  452  and column  414 . RXP  334  and RXN  336  in row  350  and column  316  has been moved to row  450  and column  414 . Hence  FIG. 4  illustrates a row  450  of receive connection positions adjacent to a row  452  of transmit connection positions, where there is an interposing ground shield  240  between rows. The row  452  is adjacent to row  454  of transmit connection positions, where there is an interposing ground shield  242  between rows. The row  454  is adjacent to a row  456  of receive connection positions, where there is an interposing ground shield  244  between rows. Hence, crosstalk is significantly reduced because the transmit connection positions are shielded from the receiver connection positions. 
     FIG. 4  shows a row  450  of receive connection positions (abbreviated by “RX1” for discussion purposes). A row  452  of transmit connection positions (abbreviated by “TX1” for discussion purposes). A row  454  of transmit connection positions (abbreviated by “TX2” for discussion purposes). And a row  456  of receive connection positions (abbreviated by “RX2” for discussion purposes). In other words a partial connector pin assignment of [RX1, TX1, TX2, RX2]. Other permutations of partial connector pin assignments are [RX1, TX1, RX2, TX2][TX1, RX1, TX2, RX2] and [TX1, RX1, RX2, TX2]. 
   With reference to  FIGS. 2 and 4 , the pins  230 – 237  are reassigned to new values as given in column  410 . RXP  324  and RXN  326  are assigned to pins  230  and  231 . TXP  320  and TXN  322  are assigned to pins  232  and  233 . TXP  360  and TXN  362  are assigned to pins  234  and  235 . RXP  370  and RXN  372  are assigned to pins  236  and  237 . 
     FIG. 5  is a diagram of some of the connections between two board connectors of an aspect of the present invention. The first board connector includes connector pin assignment  400  and the second board connector includes connector pin assignment  500 . Connector pin assignment  400  was shown in  FIG. 4 . Connector pin assignment  500  is similar to connector pin assignment  400 . Connector pin assignment  500  has four rows  550 ,  552 ,  554 , and  556 , where there are interposing ground shields  502 ,  504 , and  506  between each row. Although, only four columns  510 ,  512 ,  514 , and  516  are shown, there may be 25 columns. Each element in each column of connector pin assignment  400 , e.g.,  410 ,  412 ,  414 , and  416 , is connected to an associated element in the associated column, e.g.,  510 ,  512 ,  514 , and  516 , respectively, in connector pin assignment  500 . For clarity of illustration only one differential connector pin pair position is shown for a row on  400 , e.g., RXP/RXN in column  416  of row  450  is connected to TXP/TXN in column  516  and row  552 . However, the other differential connector pin pair positions in the row on  400 , e.g. row  450 , are similarly connected to the associated differential connector pin pair positions in the row in  500 , e.g., row  552 . TXP/TXN in row  452  and column  414  is connected to RXP/RXN in column  514  and row  550 . TXP/TXN in row  454  and column  412  is connected to RXP/RXN in column  512  and row  556 . RXP/RXN in row  456  and column  410  is connected to TXP/TXN in column  510  and row  554 . 
   In the preferred embodiment each row in  400  is connected to its associated row in  500  on a different backplane layer. For example, RXP/RXN in row  450  and column  416  is connected to TXP/TXN in row  552  and column  516  via a first layer of the backplane. TXP/TXN in row  452  and column  414  is connected to RXP/RXN in column  514  and row  550  via a second layer of the backplane. TXP/TXN in row  454  and column  412  is connected to RXP/RXN in column  512  and row  556  via a third layer of the backplane. RXP/RXN in row  456  and column  410  is connected to TXP/TXN in column  510  and row  554  via a fourth layer of the backplane. Using different signal layers of the backplane, where there is an interposing ground layer between each signal layer in the backplane, reduces cross talk between signal wires (see U.S. Pat. No. 5,397,861, titled “Electrical Interconnection Board”, by David H. Urquhart, issued Mar. 14, 1995, which is incorporated by reference, herein). 
   Although the invention has been described in connection with several embodiments, it is understood that this invention is not limited to the embodiments disclosed, but is capable of various modifications, which would be apparent to one of ordinary skill in the art. For example, although only one processor is shown on FPGA  100 , it is understood that more than one processor may be present in other embodiments. Thus, the invention is limited only by the following claims.