Patent Document

A portion of the disclosure of this patent application contains material which is subject to copyright protection. The copyright owner has no objection to the facsimile reproduction by anyone of the patent document or the patent disclosure, as it appears in the Patent and Trademark patent file or records, but otherwise reserves all copyright rights whatsoever. 
     BACKGROUND OF THE INVENTION 
     Digital circuitry is commonplace in today&#39;s electronic systems, such as computers, printers, servers, and telecommunications hardware. The complexity of such systems often involves lengthy internal signal lines spanning up to twenty inches or more through printed circuit board tracks or traces and back-planes. One problem with these signal lines is that they generate noise for the associated digital circuitry; they also often act as antennae to couple unwanted noise signals to the digital circuitry. In one example, certain electronic systems incorporate a voltage signal coupled to a field programmable gate array (FPGA) along a voltage signal line, to indicate power quality; however noise coupled to the signal line may generate a false reading in the FPGA, resulting in unwanted shut-off or other malfunction. 
     More generally, noise coupled to digital signal lines can create false triggers and metastability problems when a noise spike is latched into a digital circuit. This may happen, for example, when the noise spike coincides with a clock edge in the digital circuit. 
     Noise in digital circuits may also cause particular problems for signals with slow rise or fall times: when a slowly changing signal is transitioning on a signal line to a digital circuit, noise on that line may result in false detections, by the digital circuit, of multiple edges. 
     The prior art incorporates several techniques to filter noises on signal lines to digital circuits. A particularly popular approach is to incorporate an analog filter near to the input of the digital circuitry. For example a low pass filter may be implemented at the input to remove high frequency spikes on the signal line. Incorporating low pass filter however also slows down the desired signal edges, which may induce other problems. Analog filters have other problems in that they may utilize resistors and capacitors that are relatively expensive to incorporate on each signal line. An approach utilizing a series of analog filters also typically requires lists and tracking to facilitate configuration management and best practices design engineering, adding additional costs. Stray inductances and capacitance may also induce unwanted resonances within the underlying digital circuit, creating further difficulties. 
     The prior art has also attempted to filter noises on signal lines to digital circuits by incorporating hysterisis, as with a Schmidt trigger; however, Schmidt trigger devices are susceptible to large voltage spikes, creating unpredictable operation. 
     The prior art has also utilized the microprocessor to sample the signal line to digital circuitry. The microprocessor may for example pass along a signal line value to the digital circuitry when sampling of the signal line provides a statistically stable line value. Sophisticated versions of this technique may include sampling the signal line at varying frequencies in an attempt to de-couple the sampling from any signal line harmonics. However, systems that incorporate such microprocessors incorporate an expensive and complicated overhead, particularly when the processor is dedicated for this purpose. Furthermore, similar to the low-pass filter problems described above, the delay caused by sampling of the signal line acts as a lag to signal acquisition to the underlying digital circuit. In addition, the electrical designer of the system must meaningfully manage the many processor cycles used in sampling the signal line. 
     One other popular approach in the prior art to filter noise on digital signal lines, input to an accompanying digital circuit, is the use of cascaded D flip-flops. In this approach, every input clock cycle is clocked into the first D flip-flop, and then progresses down the chain of D flip-flops. After a sufficient number of clock cycles—typically corresponding to the length of the D flip-flop chain—the input is sampled and fed to the digital circuit if all the outputs of the D flip-flops are the same. A significant problem with this approach is that a large number of flip-flops is often required, adding design complexity and cost, and decreasing board real estate available for core system components. 
     It is, accordingly, one object of the invention is to provide methods and apparatus for filtering signals on a signal line so that noise pulses are not latched into the accompanying digital circuit, and without the afore-mentioned problems. Another object of the invention is to provide a digital filter without the use of analog components or microprocessors. Yet another object of the invention is to provide a method for ensuring a single transition to digital circuitry by filtering unwanted noise components on a signal line to the circuitry. Other objects of the invention are apparent within the description that follows. 
     SUMMARY OF THE INVENTION 
     In one aspect, the invention provides a method of separating noise from a signal on a signal line to a digital circuit. The method includes the steps of: determining one or more edges of the noise relative to a fast clock; resetting a timer according to the edges; clocking output from the timer relative to a slow clock, the slow clock being slower than the fast clock; and communicating a first value from the signal line to the digital circuit after a period, defined by the slow clock, within which the timer has not reset. Preferably, the step of resetting the timer occurs asynchronously with timing of the edges of the noise. 
     In a preferred aspect, the fast clock has a rate of about 8 MHz and the slow clock has a periodic rate of about four milliseconds. The ratio between the fast clock frequency and the slow clock frequency is typically greater than at least 1000 and is preferably greater than about 10,000. 
     In another aspect, the method utilizes an edge detector in determining the edges. The edge detector may include a flip-flop coupled to the signal line. The flip-flop may be a D flip-flop with a D input that couples to the signal line. An output of the D flip flop may be used to communicate an intermediate “B” signal value to other components of the edge detector. The B signal value is preferably latched to an “A” signal value corresponding to a value of the signal line at a rising edge of the fast clock. In a preferred aspect, signal values A and B are compared such as with an XOR gate; the output of the XOR gate may be fed to the timer as an “E” signal value. 
     In one aspect, the step of communicating includes the step of utilizing a second flip-flop, e.g., a D flip-flop. The second flip-flop may include the step of clocking the second flip-flop from an output of the timer. The signal line feeds the D input to the second flip-flop; and the timer feeds the clock input to the second flip-flop. The output of the second flip-flop is input to the digital circuit. 
     The invention also provides, in another aspect, logic apparatus for filtering noise signals on a signal line to a digital circuit. An edge detector detects edges of the noise signals and relative to a fast clock. A timer clocks a latch to a value of the signal line and relative to a slow clock. The slow clock is slower than the fast clock. The timer is asynchronously reset by one or more signals from the edge detector and corresponding to the edges. The latch occurs after a time period defined by the slow clock within which the timer has not reset. 
     In one aspect, the logic apparatus includes a first flip-flop, e.g., a D flip-flop, connected to the timer and the signal line. The first flip flop latches the value of the signal line when clocked by the timer. 
     The edge detector may include a second flip-flop, e.g., a D flip-flop, and a digital comparator. The signal line is coupled to an input to the second flip flop; the second flip flop is clocked by the fast clock to produce a B signal value at an output of the second flip flop. The B signal value corresponds to an A value of the signal line at a rising edge of the fast clock. A digital comparator, e.g., an XOR gate, compares the A signal value of the signal line to the B signal for input to the timer. 
     The invention is next described further in connection with preferred embodiments, and it will become apparent that various additions, subtractions, and modifications can be made by those skilled in the art without departing from the scope of the invention. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       A more complete understanding of the invention may be obtained by reference to the drawings, in which: 
         FIG. 1  shows a system incorporating a digital noise filter, in accord with the invention; 
         FIG. 2  illustrates logic, including edge detector logic, suitable for use as the filter of the system of  FIG. 1 ; 
         FIG. 3  illustrates one edge detector suitable for use as the edge detector of  FIG. 2 ; 
         FIG. 4  illustrates typical timing diagram characteristics of the edge detector of  FIG. 3 ; 
         FIG. 5  illustrates representative sampling characteristics implementing the logic of FIG.  2  and  FIG. 3  in the digital logic circuitry of FIG.  1 . 
     
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
       FIG. 1  shows a system  10  incorporating a digital circuit  12  and associated digital logic  14 , in accord with the invention. In operation, digital circuit  12  may acquire signals from a variety of sources, such as from a signal line  16 A. Signal line  16 A may derive from points external to system  10  or within system  10 . Digital logic  14  ensures that data acquired from signal line  16 A is substantially noise-free. Specifically, logic  14  filters signals on line  16 A to provide clean signals to digital circuit  12  on signal line  16 B. Logic  14  thus filters out undesirable noise pulses on signal line  16 A so that these noise pulses are not input to digital circuitry  12 , on signal line  16 B. Logic  14  may for example filter out noise generated by asynchronous signals  18  coupled into line  16 a from an unrelated device  20 . This ensures that such noise pulses are not latched to affect processing within digital circuit  12   
     Digital filter logic  14  is further illustrated in FIG.  2 . Signal line  16 A couples to the input  22  of edge detector  24 . One embodiment of edge detector  22  is shown in FIG.  3 . Edge detector  22  has an output  26  coupled to the asynchronous reset  28  of a timer  30  via signal line  32 . The output  34  of timer  30  couples to the clock input  36  of a D flip-flop  38  along signal line  40 . Signal line  16 A also couples to the D input  42  of flip-flop  38 , as shown. The output  44  of flip-flop  38  couples to digital circuit  12 ,  FIG. 1 , as signal line  16 B. 
     Edge detector  24  is clocked at clock input  24 A with a fast clock signal “FCLK”. FCLK may have a frequency of 8 MHz. Timer  30  is clocked at clock input  30 A with a slow clock signal “SCLK”. SCLK may have a clock period of 4.2 milliseconds. The frequency of FCLK is therefore much greater than the frequency of SCLK. With these clocking arrangements, timer  30  outputs a pulse on signal line  40  at the end of each sample period defined by SCLK. This pulse is then used to “latch” the input signal on line  32  (this input signal is also shown as signal E, FIG.  3 ). If noise occurs on input signal line  32  before timer  30  creates the pulse, then timer  30  resets and restarts the sample period defined by SCLK. Logic  14  thus ensures signals on line  16 B are stable for sample time SCLK before it latches through to digital circuit  12 , FIG.  1 . 
       FIG. 3  shows schematic logic  50  suitable for implementing edge detector  24 , FIG.  2 . Logic  50  includes a D flip-flop  52  and an XOR gate  54 . “A” corresponds to the signal value on signal line  16 A,  FIG. 2 ; A thus couples to the data input D  22 ′ of flip-flop  52  (data input  22 ′ may for example represent input  22 , FIG.  2 ). XOR gate  54  compares D input  22 ′ to the Q output  58  of flip-flop  52 . “B” corresponds to the signal value from Q output  58 . “E” corresponds to the digital difference comparison of A and B through XOR gate  54 . Signal E is input to timer  30 ,  FIG. 2 , on signal line  32 . 
       FIG. 4  illustrates typical timing signals through logic  50 , FIG.  3 . Signal value A may have one or more noise spikes  60 ,  62  that are sampled at points  64  to set signal B; points  64  are determined at the rising edges of the FCLK signal. Signal E produced through XOR gate  54  thus has four pulses  66  corresponding to each change in signal A. 
       FIG. 5  illustrates representative timing signals and signal values obtained through digital logic  14 , FIG.  1 . Signal line A again corresponds to input on signal line  16 A, for filtering through digital logic  14 . Values “S” correspond to the latched values of A (or A′) sent to digital circuitry  12  on signal line  16 B. A′ corresponds to a non-noise change in signal A that is desired for input to circuitry  12 . A also shows typical noise pulses  70  (e.g., similar to pulses  60 ,  62 ,  FIG. 4 ) filtered out by logic  14 . Timing through timer  30  is shown at  74 . At each noise pulse  70 , timer  30  is reset at time locations  80 ; each value S is therefore latched through to digital circuitry  12  only after a full timeout period  84  of timer  30 . Desired signal change A′ also resets timer  30  at time locations  82 . Only after full timeout periods  84  of timer  30  is A (or A′) latched through as value S, at points  90 , to circuitry  12 , as shown. 
     The following Verilog source code provides a non-limiting simulation of processor reset detect circuitry constructed according to the invention. Those skilled in the art should appreciate that other simulations, source code, hardware design and/or electronic detail, as a matter of design choice, can similarly provide processor reset detect circuitry without departing from the scope of the invention. Those skilled in the art should thus appreciate that the digital logic of FIG.  2  and  FIG. 3  may be implemented as a single integrated circuit, stand-alone or embedded within other chips, to perform the functions herein and without departing from the scope of the invention. 
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                         ***            //           // FileName   : timer.v       //   :       // Title   : Timer       //   :       // Purpose   : A general purpose timer       //   : When timer is enabled, it counts continuously,       //   : outputting a pulse every &lt;divideby&gt; CLK periods.       //   : Pulse duration is one clock period       //   :       // IncludeFiles   : none       //   :       // Conventions   : Active low signals are identified with ‘_l’ or ‘_L’            module timer (                CLK,           RESET,           QOUT);            parameter width = 3;   //number of flipflops required       parameter divideby = 6;   //length of pulse = divideby clock periods            input   CLK;       input   RESET;       output   QOUT;            reg QOUT;       reg [width-1:0] cnt;       always @(posedge CLK or posedge RESET)       begin                //RESET           if (RESET)                begin                cnt &lt;= 0;           QOUT &lt;= 0;                end                //Hit &lt;divideby&gt; time           else if (cnt == divideby)                begin                cnt &lt;= 0;           QOUT &lt;= 1;                end                //Enabled and counting           else                begin                cnt &lt;= cnt + 1;           QOUT &lt;= 0;                end            end       endmodule //timer       //            // FileName   : retrig_timer.v       //   :       // Title   : Digital retriggerable timer       //   :       // Purpose   : A general purpose retriggerable timer       //   : When module is enabled (not RESET), any change in       //   : the TRIG input will cause QOUT to stay low for       //   : a user-specified period of time.       //   : A slower clock (SCLK) is used for the timer       //   : A faster clock (FCLK) is used for detecting an edge       //   : Timeout is determined by SCLK frequency and       //   : divideby parameter.       //   :       // IncludeFiles   : timer.v       //   : Edge_Detect.v       //   :       // Conventions   : Active low signals are identified with ‘_l’ or ‘_L’       //   :            module retrig_timer (                SCLK,           FCLK,           TRIG,           RESET,           QOUT);            parameter width = 7;   //number of flipflops required       parameter divideby = 100;   //length of pulse = divideby clock periods            input   SCLK;       input   FCLK;       input   TRIG;       input   RESET;       output   QOUT;            wire reset_timer;       //Detect change in TRIG       Edge_Detect Edge_Detect(                .CLK (FCLK),           .DIN (TRIG),           .RESET(RESET),           .QOUT (reset_timer));            //pulse timer       timer #(width,divideby) timer(                .CLK   (SCLK),           .RESET   (RESET | reset_timer),           .QOUT   (QOUT));            endmodule//retrig_timer       //            // FileName   : Glitch_Filter.v       //   :       // Title   : Digital glitch filter       //   :       // Library   : WORK       //   :       // Purpose   : A general purpose glitch filter       //   : When module is enabled (not RESET), any change in       //   : the IN input will restart a timer. If the timer       //   : expires w/ no further changes in the IN input, then       //   : IN gets latched through to the output.       //   : This prevents glitches from passing       //   : The timeout is determined by the parameter divideby       //   : The number of flipflops used in the counter is       //   : determined by the parameter width.       //   : SCLK is used for timer length       //   : FCLK is used to detect changes in IN       //   :       // IncludeFiles   : retrig_timer.v       //   :       // Conventions   : Active low signals are identified with ‘_l’ or ‘_L’       //   :            module Glitch_Filter (                SCLK,           FCLK,           IN,           RESET,           QOUT);            parameter width = 7;   //number of flipflops required       parameter divideby = 100;   //length of pulse = divideby clock periods            input   SCLK;       input   FCLK;       input   IN;       input   RESET;       output   QOUT;       reg   QOUT;       wire   sel;            //implement retriggerable timer       retrig_timer #(width,divideby) timer(                .SCLK (SCLK),           .FCLK (FCLK),           .TRIG (IN),           .RESET(RESET),           .QOUT (sel));            //implement selector       always @(posedge sel or posedge RESET)       begin                //RESET, QOUT &lt;= 0           if (RESET)                QOUT &lt;=0;                else                QOUT &lt;= IN;            end       endmodule//Glitch_Filter       //            // FileName   : Edge_Detect.v       //   :       // Title   : Edge Detector       //   :       // Library   : WORK       //   :       // Purpose   : This module detects any edge of an input and       //   : generates a pulse on the output one CLK wide.       //   : The pulse appears 2 clocks after the change in DIN       //       // IncludeFiles   : none       //   :       // Conventions   : Active low signals are identified with ‘_l’ or ‘_L’       //   :            module Edge_Detect (                RESET,   // in, asynchronous reset           CLK,   // in, general purpose clock           DIN,   // in, data input with edge we&#39;re looking for           QOUT) ;   // out, rising edge pulse output            input RESET;       input DIN;       input CLK;       output QOUT;                reg QOUT;                reg re_q0;           reg re_q1;           reg reset0;           req reset1;           always @(posedge CLK or posedge RESET)           begin                if (RESET)                begin                re_q0 &lt;= 0;                re_q1 &lt;= 0;           reset0 &lt;= 1;           reset1 &lt;= 1;           QOUT &lt;= 0;                end                else                begin                re_q0 &lt;= DIN;           re_q1 &lt;= req0;                reset0 &lt;= RESET;           reset1 &lt;= reset0;           QOUT &lt;= ((˜re_q1 == re_q0) &amp; !reset1 ? 1 : 0);                end                end            endmodule       ***                    
© 2001 Hewlett-Packard Company
 
     The invention thus attains the objects set forth above, among those apparent from the preceding description. Since certain changes may be made in the above methods and systems without departing from the scope of the invention, it is intended that all matter contained in the above description or shown in the accompanying drawing be interpreted as illustrative and not in a limiting sense. It is also to be understood that the following claims are to cover all generic and specific features of the invention described herein, and all statements of the scope of the invention which, as a matter of language, might be said to fall there between.

Technology Category: 5