Patent Abstract:
Predetection noise bandwidth reduction is effected by a pre-averager capable of digitally averaging the samples of an input data signal over a single symbol, the averaging interval being defined by the input sampling rate divided by the output sampling rate. As the averaged sample is clocked to a suitable detector at a much slower rate than the input signal sampling rate the noise bandwidth at the input to the detector is reduced, the input to the detector having an improved signal to noise ratio as a result of the averaging process, and the rate at which such subsequent processing must operate is correspondingly reduced. The pre-averager may form a data filter when the output sampling rate is reduced to one sample per symbol of received data.

Full Description:
FIELD OF THE INVENTION 
     The invention is in the field of signal demodulation and has application in information transmission systems where pre-demodulation, that is, pre-detection, noise bandwidth reduction is advantageous to increase the signal-to-noise (S/N) ratio prior to signal detection. 
     BACKGROUND OF THE INVENTION 
     Modulated signals, carrying information such as video, data, music and speech are generally contaminated by noise. Efficient demodulation requires distinguishing the information from the noise. 
     The demodulation process includes several steps. The receiver may receive, at its antenna, an information signal modulated on a radio frequency (RF) carrier. The signal may then undergo frequency conversion to the intermediate frequency (IF) band. The information signal, at baseband, is recovered from the IF signal by a suitable detector. Considering, for example, a conventional receiver in a variable rate digital data transmission system, the IF signal, produced from a received RF signal by subjecting the RF signal to a mixing or filtering process, is subsequently applied to a data detector for recovering, at baseband, the information content of the input signal. As the system must be responsive to a variable rate signal, the IF bandwidth must be broad enough to process the highest expected data rate, although at any point in time the receiver may be detecting a lower rate and thus narrower band signal. As the noise bandwidth is not limited to the frequency spectrum, that is, bandwidth, of the received signals, the bandwidth of the receiver&#39;front-end, that is, prior to detection, must be scaled with the received signalling rate to prevent noise overload, signal suppression, and distortion in subsequent digital processing stages. To effect this scaling it is conventional to use some type of filter switching mechanism limiting the IF bandwidth based on the received signalling rate. 
     A conventional filter switching arrangement for limiting the noise bandwidth at a receiver front end is illustrated in FIG. 1. This arrangement may be used in a receiver of a digital data transmission system to select a bandwidth at IF sufficient to pass data signals transmitted at a selected one of several data rates, while suppressing noise outside that bandwidth. 
     The FIG. 1 arrangement includes an input terminal 6 receiving the incoming modulated signal and noise at IF. The input terminal 6 is connected to a commutator 4 of a rotary switch 2. The switch 2 has a number of fixed contacts 8 1  --8 n  each selectively connected to the commutator 4 through rotation of the commutator. Each fixed contact 8 l&#39;  --8 n  is electrically connected to a respective IF filter 10 l  --10 n . The center frequencies F l  --F n  and bandwidths BW l  --BW n  of the IF filters 10 l  --10 n  are selected on the basis of the data rates the receiver is designed to accept. The outputs from the IF filters are input to a power combiner 12. The output from the power combiner is an IF signal whose bandwidth is scaled to the signalling rate of the received signal, that is, somewhat greater than, but proportional to, the bandwidth of the received data or symbol rate, thereby reducing the noise bandwidth prior to data detection in a detector 14. The reduced noise bandwidth prevents noise overload, signal suppression and distortion in the latter processing stages of the detector 14. 
     More specifically, in operation of the conventional arrangement of FIG. 1,an RF signal, modulated by a data signal at the selected symbol rate, is converted to IF by conventional mixing or filtering and then applied to input terminal 6. One of the parallel sets of filter paths is selected by rotating commutator 4 based on the symbol rate of the data signal modulating the IF signal. The selected one of the IF filters 10 l  --10 n  limits the bandwidth of the IF signal prior to detection, thereby reducing the noise bandwidth which initially extends over the entire IF spectrum. This conventional arrangement suffers from several disadvantages. For example, it is expensive and cumbersome to implement, and it produces gain and phase variations from one path to another as well as from one unit to another. 
     If the filter responses are relatively simple, a single filter implementation with switched elements might be used instead of the plural paths of the filters. However, even in this case, the disadvantages stated above exist. 
     Boxcar filtering is another technique which might be used to reduce pre-detection noise. Boxcar filtering involves averaging the incoming signal, with noise reduction the expected result since noise is theoretically random. Over a period of time many random signals have substantially equal positive and negative components, and thus averaging will tend to reduce the noise component of such a signal toward zero. However, note that boxcar filtering is not applicable to digital data demodulation since with the boxcar technique averaging must be done over many symbols and the exact period of the signal to be averaged must be known. 
     The present invention is directed to a technique and implementing apparatus which do not experience the aforementioned disadvantages of either the conventional bandwidth switching technique or boxcar filtering technique. 
     SUMMARY OF THE INVENTION 
     An object of the invention is to reduce the predetection noise bandwidth of a modulated communication signal. 
     Another object of the invention is to reduce predetection noise bandwidth without expensive and cumbersome equipment. 
     Another object of the invention is to reduce the rate at which samples need be handled in subsequent processing. 
     A still further object of the invention is to reduce pre-detection noise bandwidth using averaging over a single data symbol and without prior determination of the exact signal period. 
     It is also an object of the invention to utilize the pre-detection averaging of the invention to form a data filter thus combining the function of noise bandwidth reduction and data shaping in a single unit. 
     These and other objects as will become apparent are achieved by the invention described herein with reference to the following description of the preferred embodiments. According to the invention, a pre-averager is positioned in a receiver front end for processing the input signal. Assuming the information signal to be digital data, averaging of the samples will be over a single symbol. While the invention is not limited to digital data transmission systems, for convenience it will be described hereinafter in connection with such a system since the pre-averager according to the invention may be configured as a data filter for data detection. However, the pre-averager of the invention may also be used in receivers for other types of information signals such as video, speech and music. 
     The pre-averager of the invention includes a digital averaging module which samples an incoming signal, converted to baseband, at least at twice the noise bandwidth determined by the single, input IF filter. The samples are averaged over a defined averaging interval, ordinarily set as a function of the input data rate, and are then clocked out of the averager at a lower output data rate. An output sampling rate of two samples per symbol has been found acceptable in the embodiment hereinafter described for noise bandwidth reduction, although other output rates may also be acceptable. When implemented as a data filter, the output rate will be reduced to one sample per symbol in the detection path as is also described hereinafter in detail. The defined averaging interval is the input sampling rate divided by the output sampling rate. The averaging technique implemented by the pre-averager of the invention permits averaging over a single symbol when used in a digital data transmission system and is not dependent on a prior knowledge of the exact signal period. It is also inexpensive and relatively simple to implement. 
     Significantly, the invention appears to conflict with well known sampling theory concepts in that the output sample rate of the pre-averager is typically lower than twice the input noise bandwidth, although it is never less than twice the input signal bandwidth. Further, groups of incoming samples may be replaced by a single sample which is representative of their average value. While the output sample will be slightly contaminated with aperture distortion, this may be easily compensated for by transmit side equalization, for example. 
     In accordance with another embodiment of the invention, the pre-averager is configured to form a data filter. An optimum data filter in digital data transmission must have two fundamental attributes. One, its frequency response should be matched to the transmitted signal spectrum. Two, its combined transmission and reception impulse response should exhibit equally spaced zero crossings so that interference does not occur in the detection of adjacent symbols. Surprisingly, a data filter approaching the optimum conditions is realized by the pre-averager of the invention when the output sampling rate is reduced to one sample per symbol in the detection path. 
     The pre-averager implemented data filter for the detection of asynchronous data may be constructed as two parallel paths, each containing a pre-averager. By asynchronous, we mean digital data for which the exact clock frequency and phase are unknown and must be recovered. The first of the two pre-averagers supplies a sample used for data detection, carrier phase recovery and AGC estimation. The second of the two pre-averagers provides a sample used for clock recovery. Since averaging according to the teachings of the invention produces only one output sample per symbol in each of two paths, a feature of the invention is the reuse of input samples t provide the necessary samples for data detection and clock recovery. 
     In all cases, the preaverager performs the function of rate reduction, that is, it reduces the rate at which subsequent circuits must operate in processing the data to a new, lower, fixed, rate. This reduces the complexity and expense of those circuits. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 illustrates a conventional bandwidth switching arrangement for reducing pre-detection noise bandwidth in variable rate data receiver. 
     FIG. 2 illustrates a pre-detection noise bandwidth reducing pre-averager according to a first embodiment of the invention. 
     FIG. 3 is a timing diagram for illustrating the operation of the FIG. 2 circuit. 
     FIG. 4 is a general representation of the sin x/x versus x relationship for an input information signal and the overall signal bandwidth including noise at several sampling rates. 
     FIG. 5 illustrates a pre-averager data filter according to a second embodiment of the invention. 
     FIG. 6 is a representation of the sampling point offset and sample reuse features incorporated in the pre-averager data filter of FIG. 5. 
     FIG. 7 is a timing diagram for illustrating the operation of the FIG. 5 circuitry. 
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     According to a first embodiment of the invention an IF filter and a pre-detection digital averaging module effect noise bandwidth and rate reduction. Noise bandwidth reduction according to this invention could take place at baseband, carrier, or IF frequencies. However, it is convenient to initiate the noise bandwidth reduction at baseband and therefore, a preferred embodiment of the invention has the pre-averaging according to the invention initiated there. Also, as previously stated herein, noise bandwidth reduction may be accomplished for video, speech, music or other signals besides data signals. As the present invention is especially useful in data transmission systems, the preferred embodiment is disclosed in relation to a data transmission system. In systems other than data transmission systems, variable rate reduction might be used to narrow the signal bandwidth in response to varying noise conditions. 
     Referring to FIG. 2 a preferred embodiment of the pre-averager apparatus for noise bandwidth reduction includes an IF filter 20 passing the carriermodulated information signals and noise. The output from the IF filter is connected to a first input of a mixer 22. A second input to the mixer is connected to local oscillator 24 for converting the IF signal to baseband.The output from mixer 22 is an analog baseband signal i(t) which includes noise whose frequency spectrum is limited by the bandwidth of IF filter 20. The signal i(t) is input to analog-digital (A/D) converter 26 which converts signal i(t) including its noise components to digital form. The input sampling rate R SAMP  is relatively high to prevent aliasing of noise. Typically, the input sampling rate would be at or greater than twice the noise bandwidth of the IF filter 20. The sampling rate R SAMP  for the A/D conversion is set by a clock signal generated by a sample clock (not shown) input at terminal 39. 
     The output I k  from the A/D converter 26 is applied to an accumulator 28, where it is added to the value, Σ k , output from the accumulator in response to the preceding sample I k-l . This accumulated value is fed back from the accumulator output to a second input thereto, through a one sample delay 30. The one sample delay 30 may be a latch circuit. It is to be understood that the output from A/D converter 26 is a parallel arrangement of M bits. 
     The delay 30 is reset by a reset pulse from a timing generator 38. The reset pulse determines the averaging interval as it sets to zero the second input to the accumulator 26 at the end of the averaging interval. The averaging interval is conveniently set to a power of two (2 N ). Anaveraging interval of 2 N  causes the accumulator output to have a bit width of M+N. Since the magnitude of the accumulator output increases by Nbits as the averaging interval increases in steps of 2 N , a binary point shifter 32 is used to select the L most significant bits where L typically=M, thereby effecting a division by N, the result then representing the average &lt;I k/N  &gt; of the digital inputs I k  to theaccumulator over the averaging interval. The averaging interval informationis input to the binary point shifter 32 at a second input thereto connectedto line 33. 
     A latching circuit 34 receives the L bits from the binary point shifter. The latching circuit functions as a buffer to assure the presence of all Lbits representing the average &lt;I k/N  &gt; for further processing. The latching circuit, which may be comprised of L parallel flip flops, is clocked at the lower output sampling rate of R SAMP  /2 H  Significantly, according to the present invention, further processing of the information signal and particularly detection thereof by a suitable detector is at the lower R SAMP  /2 H  output sampling rate. FIG. 2 includes a digital lowpass filter 36 with sinc -1  compensation. This conventional device is optional and used when further shaping of an averaged data signal is desirable. 
     The operation of the embodiment of the invention depicted in FIG. 2 may best be understood when considered with the timing diagrams of FIGS. 3, representing the timing of the various stages of the averaging performed by the FIG. 2 circuitry when N=1. The waveform i(t) represents an input signal at the mixer 22 output terminal. This signal is sampled at the rateR SAMP  and converted to a digital signal in A/D converter 26. The output of the A/D converter I k  is a stream of M bit-wide samples, designated in FIG. 3 by sample numbers 0, 1, 2, 3 . . .. That is, the first sample is designated, 0, the second sample, 1, and so forth. As N=1 in this example, the averaging interval is taken over two samples. Therefore, after the first sample, 0, passes through the accumulator, it is delayed by one sampling period, T S , in the delay 30 as illustratedin the Σ k-l  timing diagram where T S  =1/R SAMP . The delayed first sample coincides in time with the next sample, 1, as can be readily seen from the I k  and Σ k-l  diagrams. The first sample, 0, is added to the second sample 1 in accumulator 28 as illustrated in timing diagram, Σ K  of FIG. 3. Since N=1, R SAMP  /2 N  =R SAMP  /2 and therefore, a reset pulse is appliedto the delay 30 after the second sample as shown in the Reset diagram of FIG. 3. The output from the delay 30 is thus zero when the third sample, 2, is input to the accumulator. The process continues as illustrated in FIG. 3, with every two samples being added and the delay 30 output being reset to zero after the sum is generated. At the conclusion of the first averaging interval, 1/R SAMP  /2,  the sum of the first and second samples passes through the binary point shifter, clocked at R SAMP  /2 in this example, to produce a signal representing the average value of thesum, &lt;I k/N  &gt;. 
     As can be seen from FIG. 3, averaging takes place within a single symbol, thus eliminating the prior art requirement for averaging over several symbols and the need to know the exact symbol period to accomplish the averaging process. Also, as the output sampling rate is lower than the input sampling rate the output bandwidth is narrowed to reduce the noise bandwidth prior to detection. This feature may be understood from FIG. 4 which represents the sin x/x versus x plot for various sampling rates, R SAMP  /2 N . The cross-hatched portion represents the information signal bandwidth. B N  is the noise equivalent bandwidth of the IF filter. R SAMP , in accordance with conventional sampling theory, is selected to be more than twice B N . As the sampling rate R SAMP  /2 N  is reduced, the response of the pre-averager represented by the plot approaches the information signal bandwidth, simultaneously reducing the noise bandwidth. Thus, as described above, reducing the output sampling rate according to the teachings of this invention, by averaging the signal samples taken at R SAMP , and clocking the averaged samples at the lower rate, R SAMP  /2 N , reduces the noise bandwidth. 
     Returning to FIG. 3 and particularly diagram &lt;I k/N  &gt;, a number of output samples (0+1, 2+3, etc.), equal to one half the number of input samples of the input waveform, each output sample being an average of two input samples, are latched and then may be applied to digital lowpass filter 36 to produce a properly shaped digital baseband output, reduced innoise by the above described averaging process. Note that this filter will operate at a lower sample rate due to the preceding pre-averager and the rate reducing aspect of the invention. The noise reduced digital baseband output is applied to a suitable detector (not shown) for demodulation. 
     A second embodiment of the invention will now be discussed with reference to FIGS. 5, 6, and 7. In accordance with this further embodiment, the digital pre-averager described hereinabove is configured as a receive datafilter, eliminating the need for a separate data filter following the pre-averager. As discussed previously herein, a data filter in a digital data transmission system should have two fundamental attributes. One, its frequency response should be matched to the transmitted signal spectrum. Two, its combined transmission and reception impulse response should exhibit equally spaced zero crossings. As can be appreciated from a reviewof FIG. 4, the averaging and reduced sampling rate realized with the preaverager of the invention provides a mechanism by which the frequency response can be substantially matched to the frequency spectrum of the transmitted signal. From FIG. 4 it is seen that as 2 N  increases, the frequency spectrum of the averaged signal approaches that of the transmitted signal. According to a feature of this invention, a data filter is realized with the pre-averager disclosed herein when averaging occurs over a single symbol and the averaging is effected to produce one output sample per symbol in the detection path. With these criteria implemented by the pre-averager, the preaverager output bandwidth closely approximates that of the transmitted signal. That is, when the pre-averager output is one sample per symbol, the sin x/x aperture response emulates the receive data filtering operation. 
     It is to be noted that the pre-averager data filter of the invention has a filter response slightly different from that of a conventional data filter. To compensate for the slightly changed shape of the filter response, predistortion, that is equalization, may be applied at the transmit end. Specifically, the transmit end equalization must compensate for a 0.9dB excess loss at the Nyquist frequency and a softer overall response. 
     An embodiment of the data filter according to the second embodiment of the invention is illustrated in FIG. 5. In this arrangement, implemented to detect asynchronous data, the data filter includes two parallel paths. An even or detection sampling point path is for data detection, carrier phaserecovery, and AGC estimation. An odd or zero crossing path is for clock recovery. Implementation of the data filter using parallel arranged pre-averagers includes at least the following two novel concepts. First, in averaging down to one sample per symbol and concomittently reducing thebandwidth to the range of a data filter, input samples must be reused. Second, the sampling points of the incoming data must be offset to provideproperly centered samples to avoid attendant performance loss resulting from distortion in the averaged output. 
     Referring to FIG. 5, like elements in FIGS. 2 and 5 are identified by the same reference numeral, with duplications of an element in the same figureidentified by subscripted reference numerals. The pre-averager data filter includes an A/D converter 26 receiving baseband signal i(t) and outputtingthe digitized samples, I k , representing input signal, i(t). The digitized samples are simultaneously applied to the even output sample accumulator and odd output sample accumulator. The even output sample accumulator includes accumulator 28 E  in the form a summing circuit, aone sample delay 30 E  in the form of flip-flop circuits, a binary pointshifter 32 E  in the form of a barrel shifter, and latching circuit 34 E  in the form of flip-flop circuits. The odd output sample accumulator is similarly constituted. Operation of each of the parallel paths is the same as the operation of the circuitry of FIG. 3. However, toobtain the necessary output samples, I e  and I o , for data and clock recovery, sampling points are offset from the ideal sample points atthe peaks and zero crossings and samples are reused. This concept of samplereuse will be discussed with reference to FIG. 6 which illustrates sample reuse together with the sampling point offset feature of the invention. The input symbols represent a 1/0 symbol pattern, with FIG. 6, for simplicity, illustrating two input samples per symbol which are to be averaged down to one output sample per symbol in each of the even and odd output paths. 
     Input samples are taken at offset sampling points a, b, c, d, and e. In theeven output sample accumulator, samples b and c are averaged, as are samples d and e. The average A of samples b and c are shown superposed on an imaginary waveform labelled Even Outputs. It is of course understood that average sample A occurs after both samples b and c have occurred and thus the even and odd outputs do not have the phase relationship illustrated in FIG. 6. This figure simply depicts the sampling point offset and sample reuse features of the invention. The average sample B isan average of input samples d and e. Thus, the even path provides one output sample per symbol which uniquely defines the symbol value, 1 or 0. 
     For detection of asynchronous signals it is necessary to recover the signalclock. Clock recovery by use of the zero crossing samples is achieved usingthe odd outputs illustrated in FIG. 6. A first zero crossing at output average sample C is generated by averaging input samples a and b. It is tobe noted that sample b is used both for the data detection path and the clock recovery path, thus the sample reuse feature of the invention may now be appreciated. A second zero crossing at output average sample D is generated by averaging input samples c and d. In this case, input sample dis reused for the same reason input sample b is reused. In fact, note that all samples are used twice. 
     It is to be understood that the invention is not limited to the case of only two input samples per symbol, nor is it limited to the use of two parallel paths. In addition, at low data rates it is possible to generate both the data detection and clock recovery samples with a single, shared, hardware path or a microprocessor. In cases where clock recovery is unnecessary, only a single path corresponding to the even output sample accumulator path is required, as only data detection is necessary. 
     Operation of the pre-averager data filter will now be described in detail with reference to FIGS. 5 and 7. FIG. 7 is a timing diagram showing the operation of the even and odd accumulator paths where four samples per symbol are taken on the input signal i(t). This signal is a typical preamble with alternating 1/0 symbols. That is, in the FIG. 7 example, theinput sampling rate R SAMP  equals 4 samples per symbol while the outputsampling rate R S  equals 1 sample per symbol, R S  is the complementof R S . 
     The digital samples I k  represent the input signal values at points 1-4of a first symbol, at points 5-8 of a second symbol and 9-12 of a third symbol. The timing of the four samples per symbol are illustrated in timing diagram E/0 Acc Input as timing blocks 1-12. In the even path, samples 1, 1+2 and 1+2+3 are fed back to the summing circuit through delay30 E  as shown in timing diagram Even Acc Feedback In. The summing circuit sums samples 1, 2, 3, and 4 to produce a summed output as shown intiming diagram Even Acc. After the summing of samples 1-4, an even reset pulse sets the delay 30 E  to zero to begin the summing process again, this time with samples 5-8. At the same time an output sample pulse R s  rises to clock the summed samples 1-4, scaled in the binary point shifter 32 E , to the parallel array of latching flip-flips representedby flip-flops 34 E . The outputs from the latching flip-flops is the signal I E  representing the data value for the symbol corresponding tosamples 1-4. 
     The odd path operates in the manner of the even path except that as a result of the timing differences between R S  and R S , and the evenreset, Reset, and odd reset, Reset&#39;, different input samples are averaged. The odd path, like the even path, receives the samples 1-12. By reason of the timing of the odd reset. Reset&#39;, the odd accumulator feedback input receives samples (-2), (-1), and 1 which are summed with sample 2 before the delay 30 o  is reset to zero by a Reset pulse. Substantially simultaneously with the Reset pulse, the output sampling pulse R S  rises to clock the sum of samples (-2), (-1), 1 and 2 into latching circuits 34 o  after being scaled by binary point shifter 32 o . This process continues with samples 3-6, and then samples 7-10 as can be appreciated from FIG. 7. As the odd path averages samples 3, 4 from a first symbol with samples 5, 6 of the next symbol the zero crossing samplebetween symbols is generated. Likewise, averaging of samples 7, 8 of the second symbol with samples 9, 10 of the third symbol generates the zero crossing sample between the second and third symbols. 
     The invention has been described with reference to preferred embodiments. However, it is to be understood that the invention is not limited to the preferred embodiments. Various modifications apparent to those skilled in the art are within the scope of the invention which is limited only by theappended claims.

Technology Classification (CPC): 7