Abstract:
In one embodiment, a decision feedback equalizer helps mitigate intersymbol interference in a bi-directional signaling environment. In the particular embodiment, the decision feedback equalizer includes a voltage-to-current converter to source a received differential current to first and second node, a latch to provide logic signal when comparing currents sourced to the first and second nodes, a memory unit to store the logic signals, and a mapping circuit to source first and second feedback currents to the first and second nodes. This embodiment further includes a transmitter to transmit data over a transmission line during receiving, and a digital-to-analog converter to provide a differential current to the first and second nodes to substantially cancel that part of the received differential currents contributed by the transmitter. In this embodiment, the mapping circuit may comprise a lookup table to map the stored logic signals into code words, and another digital-to-analog converter to source differential current to the first and second nodes in response to the code words. Other embodiments are described and claimed.

Description:
FIELD  
       [0001]     The present invention relates to circuits, and more particularly, to a decision feedback equalizer circuit for mitigating intersymbol interference in a communication channel.  
       BACKGROUND  
       [0002]     Communication channels are seldom ideal. Intersymbol interference may result due to channels having a bandwidth smaller than the signal bandwidth, as well as signal reflections from discontinuities on the communication channel. Channel equalization is a method to help mitigate this type of interference. In particular, a decision feedback equalizer (DFE) utilizes past decisions of the receiver to help mitigate intersymbol interference arising from signal reflections. Decision feedback equalizers find application in many communication systems, such as for example a computer server or system such as that depicted in  FIG. 1 .  FIG. 1  provides a high-level abstraction of a portion of a computer server or system, where microprocessor  102  resides on board  104  and communicates with memory  106  on board  108 . The communication is by way of striplines on backplane  110 . Backplane  110  is connected to boards  104  and  108  by connectors  112 . Not shown in  FIG. 1  are other memory units and microprocessors, where the various microprocessors and memory units may communicate to one another so as to access or write data and instructions.  
         [0003]     Communication of signals over backplane  110  may be modeled by transmission line theory. Often, the signaling is based upon differential signaling, whereby a single bit of information is represented by a differential voltage. For example,  FIG. 2   a  shows drivers  202  and  204  driving transmission lines  206  and  208 , respectively. For differential signaling, drivers  202  and  204  drive their respective transmission lines to complementary voltages. Typical curves for the node voltages at nodes n 1  and n 2  for a bit transition are provided in  FIG. 2   b,  where the bit transition is indicated by a dashed vertical line crossing the time axis. The information content is provided by the difference in the two node voltages.  
         [0004]     For short-haul communication, such as for the computer server in  FIG. 1 , the signal-to-noise ratio is relatively large. If the transmission lines are linear, time-invariant systems having a bandwidth significantly greater than that of the transmitted signal, and if there are no impedance mismatches, then a relatively simple receiver architecture may be employed to recover the transmitted data. Such a receiver is abstracted by comparator  210 , which provides a logic signal in response to the difference in the two received voltages at ports  212  and  214 .  
         [0005]     However, every transmission line has a finite bandwidth, and for signal bandwidths that are comparable to or exceed the transmission line (channel) bandwidth, intersymbol interference may present a problem. Furthermore, actual transmission lines may have dispersion, whereby different spectral portions of a signal travel at different speeds. This may result in pulse spreading, again leading to intersymbol interference. As a practical example, for high data rates such as 10 Gbs (Giga bits per second), the transmission lines used with backplanes or motherboards are such that intersymbol interference is present. Furthermore, there may be transmission lines mismatches, causing signal reflections, which may contribute significantly to intersymbol interference.  
         [0006]     A decision feedback equalizer may be used in conjunction with other filters, such as an FIR (Finite Impulse Response) receiver, to help mitigate intersymbol interference. It is desirable for a DFE to allow for bi-directional signaling for simultaneous transmission and reception, to be easily integrated with a FIR equalizer, and to allow for high data rate signaling. 
     
    
     BRIEF DESCRIPTION OF THE DRAWINGS  
       [0007]      FIG. 1  is a high-level abstraction of a server system, illustrating signaling between boards via a backplane.  
         [0008]      FIG. 2   a  illustrates differential signaling on two transmission lines.  
         [0009]      FIG. 3  illustrates a decision feedback equalizer architecture according to an embodiment of the present invention.  
         [0010]      FIG. 4   a  illustrates an example of an impulse response for a channel with intersymbol interference.  
         [0011]      FIG. 4   b  illustrates a tap delay line used in an decision feedback equalizer according to an embodiment of the present invention.  
         [0012]      FIG. 5  illustrates a 2-bit DAC.  
         [0013]      FIG. 6  illustrates a voltage-to-current converter.  
         [0014]      FIG. 7  illustrates a latch. 
     
    
     DESCRIPTION OF EMBODIMENTS  
       [0015]     A decision feedback equalizer is shown in  FIG. 3  at a high-level architectural level. Differential signals are transmitted and received over transmission line  302 . V-I (Voltage-to-Current) converter  304  sources a differential current to nodes  306  and  308  in response to a voltage signal at nodes  310  and  312 . (For simplicity, we use “source” to mean either “source” or “sink”. That is, currents may be sourced to or sunk from nodes  306  and  308 , but for simplicity we write that current is sourced to nodes  306  and  308 .) Driver  314  is also connected to nodes  310  and  312  to transmit a voltage signal on transmission line  302 . To allow for bi-directional communication, the transmit data available to driver  314  is also made available to 1-bit DAC (Digital-to-Analog Converter)  316  so that DAC  316  provides a differential current to nodes  318  and  320  opposite to the differential current contributed by driver  314 .  
         [0016]     Currents sourced at nodes  306  and  308  are summed and latched by latch functional unit  324  so that latch functional unit  324  outputs a logical (binary) signal indicative of the total differential current sourced into nodes  306  and  308 . The logical signals provided by latch  324  during a time interval are stored in memory functional unit  326 . Memory functional unit  326  may be a register set, a tap delay line, or other memory structure for storing past outputs of latch  324 . At any given bit time, a subset of these stored logical signals are utilized by lookup table  328  to provide a set of logical signals to N-bit DAC  330 . The output provided by DAC  330  is a differential current sourced to nodes  306  and  308 . The combination of memory  326 , lookup table  328 , and DAC  330  is to provide a mapping from a subset of past logical signals outputted by latch  324  to a differential current sourced to nodes  308  and  306 . In this way, decision feedback is implemented, where the “decisions” are the logical signals outputted by latch  324 .  
         [0017]     A relatively simple example may serve to illustrate how the mapping realized by the combination of memory  326 , lookup table  328 , and N-bit DAC  330  may be chosen. Suppose that when an impulse is transmitted over the communication channel, the difference in currents outputted by V-I converter  304  is as shown in  FIG. 4   a,  where for convenience the time index is chosen so that the peak of the response ( 402 ) is at time t and the peak is normalized to unity. Due to reflections, there is a local maximum ( 404 ) at time t−3 with height a and a local minimum ( 406 ) at time t−5 with height −b, where a and b are both positive and less than one. For the impulse response of  FIG. 4   a,  the tap delay line shown in  FIG. 4   b  serves as memory functional unit  326 , where the taps after unit delay element  408  and  410  provide the input to lookup table  328 . The unit delay elements shown in  FIG. 4   b  may be realized by flip-flop circuits. Let x 3  and x 5  denote logical variables for the logical values at nodes (taps)  412  and  414 , where the subscripts for these variables were chosen to indicate the positions of their corresponding taps. For the example impulse response shown in  FIG. 4   a,  the mapping provided by the combination of lookup table  328  and N-bit DAC  330  is indicated in the table below.  
                             TABLE 1                           (Example Mapping for Lookup Table and N-bit DAC)            x 3     x 5     Output of N-bit DAC               0   0   a − b       1   0   −a − b       0   1   a + b       1   1   −a + b                  
 
         [0018]     It should be noted that the output of N-bit DAC  330  in  FIG. 3  is a differential current, but for simplicity the entries in the last column of Table 1 are given as single-ended values. It should be understood that an entry such as a−b is in practice realized by a differential current I 0 −(a−b) and I 0 +(a−b) outputted by N-bit DAC  330 , where I 0  is the common-mode current.  
         [0019]     The above entries in Table 1 assume antipodal signaling, where a decision having a value of logical 1 is for the case in which a positive current difference is inputted to latch  324 , and a decision having a value of logical 0 is for the case in which a negative current difference is inputted to latch  324 .  
         [0020]     It is not difficult to see how the entries in Table 1 are obtained from the impulse response of  FIG. 4   a.  For example, assuming that correct decisions are being made, and assuming for simplicity that the current bit time is t, then x 3 =0 implies a previous transmission of a signal for which a negative current difference was received at time t−3, and this contributes a current difference of −a for the current bit time t. Furthermore, x 5 =0 implies a previous transmission of a signal for which a negative current different was received at time t−5, contributing a current difference of −(−b)=b. Consequently, if x 3 =0 and x 5 =0, there would be a contribution of −a+b from the previous transmitted signals, in which case N-bit DAC  330  should provide a current difference of −(−a+b)=−a+b to cancel out the intersymbol interference. Other entries in Table 1 are also straightforward to verify upon inspection of  FIG. 4   a.    
         [0021]     The particular mapping of lookup table  328  depends upon the input-output relationship of N-bit DAC  330 . For example, suppose in some suitable units of current that a=0.2 and b=0.1. Suppose N-bit DAC  330  is a 3-bit DAC, and is constructed so that its input-output relationship is as indicated in Table 2 using the same suitable units of current, where again for simplicity only single-ended output current values are provided.  
                                           TABLE 2                           (Example Input-Output for N-bit DAC)                Input Code   Output Current                            000   0           001   0.1           010   0.2           011   0.3           100   0           101   −0.1           110   −0.2           111   −0.3                      
 
         [0022]     Then, with these values, the logical mapping provided by lookup table  328  should be as indicated in Table 3 so that the effective combination of memory unit  326 , lookup table  328 , and N-bit DAC  330  provides the proper mapping to cancel intersymbol interference.  
                             TABLE 3                           (Example Lookup Table Mapping)            x 3     x 5     Lookup Table Output               0   0   001       1   0   111       0   1   011       1   1   101                  
 
         [0023]     Implementation of a lookup table mapping in logic is straightforward and need not be described herein. N-bit DAC  330  may be implemented in a number of ways. One such embodiment is provided in  FIG. 5 . For simplicity,  FIG. 5  illustrates a 2-bit DAC, but its generalization to arbitrary bit size is straightforward. In  FIG. 5 , a 2-bit word (D 2 , D 1 ) is mapped into a differential current (I − , I + ) at output ports  502  and  504 . The bit D 1  next to a transistor gate indicates that a HIGH voltage V cc  is applied to the gate when D 1 =1 and a LOW voltage V ss  is applied to the gate when D 1 =0. Similar remarks apply to the bit D 2 . A bar over the bit indicates its complement. The mapping from the word (D 2 , D 1 ) to the differential current is obtained by shunting a portion of the current from current sources  506  and  508  to ground as indicated in  FIG. 5 , and allowing the remainder to flow through output ports  502  and  504 . The relative effective width-to-length ratios of the transistors in  FIG. 5  are indicated as shown. Other embodiments may utilize a different set of relative ratios.  
         [0024]     It is relatively straightforward to implement a V-I converter. One such embodiment is provided in  FIG. 6 , where a differential voltage is applied at input ports  602  and  604  to modulate the gates of differential transistor pair  606  and  608 , so that a differential current is provided at output ports  610  and  612 .  
         [0025]     An embodiment of latch  324  is illustrated in  FIG. 7 . A differential input current (I + , I − ) is applied to input ports  702  and  704 , which are connected to nodes  306  and  308 . A differential voltage output (V OUT   + , V OUT   − ) is developed at output ports  702  and  704 , where one of these voltages may be taken for a single-ended output. The particular connection of input ports and output ports, that is, whether input ports  702  and  704  are connected to nodes  306  and  308 , respectively, or to nodes  308  and  306 , respectively, and whether V OUT   +  or V OUT   −  is taken as the output voltage of the latch, determines the overall algebraic sign of the filter, and should be chosen accordingly.  
         [0026]     The embodiment of  FIG. 7  may be referred to as an active cascode differential latch. nMOSFETs  714  and  716  play the role of active cascode transistors, although they are not cascode transistors in the classical sense because their gate voltages are not biased to a constant voltage. A clock signal in  FIG. 7  is denoted by φ. When clock signal φ is HIGH, the differential latch is put into a pre-charge mode where the output voltages at output ports  706  and  708  are forced to be substantially equal to one another. When clock signal φ is LOW, the differential latch is placed into an evaluation mode, where a differential voltage at output ports  706  and  708  develops. Cross coupled pMOSFETs  718  and  720  are connected as a latch, so that the differential voltage developed at output ports  706  and  708  is amplified to a logic level. Device sizes may be easily chosen such that nMOSFETs  710  and  712  operate in their triode regions and nMOSFETs  714  and  716  operate in their active regions. With nMOSFETs  710  and  712  operating in their triode regions, the differential latch of  FIG. 7  has a relatively low input impedance, and furthermore, these nMOSFETs require a relatively small amount of headroom voltage.  
         [0027]     Other filters may be connected to nodes  306  and  308  to also help mitigate intersymbol interference. For example, a discrete-time analog finite impulse response filter utilizing past received data samples may have its differential output connected to nodes  306  and  308 .  
         [0028]     Various modifications may be made to the disclosed embodiments without departing from the scope of the invention as claimed below. For example, in  FIG. 3 , 1-bit DAC  316  may be combined with N-bit DAC  330  to realize a (N+1)-bit DAC, where now lookup table  328  is expanded to have an additional input provided by transmitter  314 .  
         [0029]     As another example, the mapping function of past decisions (outputs of latch  324 ) to differential current sourced to nodes  306  and  308  provided by the combination of memory  326 , lookup table  328 , and DACs  316  and  330 , may be realized in a number of ways. A lookup table was discussed earlier in reference to  FIG. 4   b.  Another embodiment is illustrated in  FIG. 8 , where now the values stored in the delay line of delay elements  806  are digital values representing −1 or 1. The values of the third and fourth taps are indicated by the variables y 3  and y 5 , respectively, where the correspondence with the variables x 3  and x 5  is: x=0→y=−1 and x=1→y=1, where subscripts on the variables have been suppressed to indicate that the correspondence is not a function of tap position. Multipliers  802   a  and  802   b  multiply the variables y 3  and y 5  by −a and b, respectively, and summer provides the sum −ay 3 +by 5 . This sum determines the differential current sourced to nodes  306  and  308 . The net result is that the same mapping function is provided as in the embodiment of  FIG. 4   b.    
         [0030]     The embodiment of  FIG. 8  is depicted at a high functional level. If the multiplication and summation is performed by digital logic, then an additional functional unit is added to convert the digital result −ay 3 +by 5  to a differential current. Or, multipliers  802   a  and  802   b  may perform digital multiplication and the conversion of the result to a current, where now summer  804  represents a current summing function.  
         [0031]     Furthermore, it is to be understood in these letters patent that the meaning of “A is connected to B” is that A and B are connected by a passive structure for making a direct electrical connection so that the voltage potentials of A and B are substantially equal to each other. For example, A and B may be connected by way of an interconnect, transmission line, etc. In integrated circuit technology, the “interconnect” may be exceedingly short, comparable to the device dimension itself. For example, the gates of two transistors may be connected to each other by polysilicon or copper interconnect that is comparable to the gate length of the transistors.  
         [0032]     It is also to be understood that the meaning of “A is coupled to B” is that either A and B are connected to each other as described above, or that, although A and B may not be connected to each other as described above, there is nevertheless a device or circuit that is connected to both A and B. This device or circuit may include active or passive circuit elements. For example, A may be connected to a circuit element which in turn is connected to B.  
         [0033]     It is also to be understood in these letters patent that a “current source” may mean either a current source or a current sink. Similar remarks apply to similar phrases, such as, “to source current”.  
         [0034]     It is also to be understood that various circuit blocks, such as current mirrors, amplifiers, etc., may include switches so as to be switched in or out of a larger circuit, and yet such circuit blocks may still be considered connected to the larger circuit because the various switches may be considered as included in the circuit block.  
         [0035]     It is also to be understood that a claimed equality or match is interpreted to mean an equality or match within the tolerances of the process technology.