Patent Document

BACKGROUND OF THE INVENTION  
         [0001]    1. Field of the Invention  
           [0002]    This invention relates to modems, and in particular to systems and methods for detecting call-waiting tones during modem connection.  
           [0003]    2. Description of the Related Art  
           [0004]    Modems are communications devices which employ digital modulation techniques to transmit binary data over analog communications channels, e.g., telephone lines. Typically, two modems communicate over a single channel, with one modem at each end of the-channel. Signal processing structures implemented at each modem provide encoding, modulation, filtering, interpolation, echo cancellation, signal detection, equalization, demodulation, and decoding functions. Modems typically conform to international standards to ensure interoperability with modems from other manufacturers. One such standard is the V.34 specification described in ITU-T Recommendation V.34 , A Modem Operating at Data Signalling Rates of up to  28 800  bits/s for Use on the General Switched Telephone Network and on Leased Point - to - Point  2- Wire Telephone - Type Circuits , dated September, 1994 (previously CCITT Recommendation V.34), which is hereby incorporated herein, in its entirety, by reference.  
           [0005]    Traditional modem implementations include one or more dedicated digital signal processors (or DSPs) on which signal processing algorithms execute during periods of modem operation. A computer system may incorporate such a modem implementation, and in addition, typically includes application and operating system software executable on a general purpose processor. Software executing on the general purpose processor sends and receives data via the modem implementation using input/output (I/O) ports, direct memory access (DMA), or other I/O structures and methods suitable for a particular general purpose processor and operating system combination.  
           [0006]    Since a typical modem implementation includes a dedicated DSP not shared with other signal processing functions of a larger computer system, the modem&#39;s DSP and the signal processing algorithms designed to run thereon are selected and designed to meet the peak computation load of the modem. DSP cycles are either used or lost For this reason, signal processing algorithms implementing the complete steady-state functionality of modem transmit and receive paths are typically execued on a DSP at full speed for the duration of a modem connection.  
           [0007]    For many portable device applications such as Personal Digital Assistants (PDAs), portable computers, and cellular phones, power consumption, battery life, and overall mass are important design figures of merit. In addition, very small part counts are desirable for extremely-small, low-cost consumer devices. Modem communications are desirable in many such portable device applications. However, traditional DSP implementations of the underlying signal processing capabilities create substantial power demands, require increased part counts, and because of the power consumption of a discrete DSP, typically require larger heavier batteries.  
           [0008]    A modem implemented as software executable on a general purpose computer may reduce part count, power demands, and overall size and mass of a computer system by eliminating the DSP, its power consumption, and some of the battery capacity otherwise required. Even non-portable device applications such as set top boxes (e.g., WebTV™ internet terminal devices or satellite/pay TV authorization devices), fax machines, etc. may benefit from the reduced part count, low cost, and reduced size and mass benefits of a software modem.  
           [0009]    Many of these devices, whether or not portable, will be connected to the public switched telephone network on a single telephone line shared for voice communications. Such a configuration, which is typical in a residential service setting, may tie up the single phone line for extended periods of time during which the modem is communicating over the line. During such time, incoming callers may receive a busy signal.  
           [0010]    A call waiting feature offered by many local exchange carriers alerts a person using a telephone for conventional voice communication that a third party is attempting to call the user while the user is still making a call. In such a system, the called party is notified and has the option to interrupt the ongoing call to take the waiting call. Typically, the local exchange carrier provides the call waiting feature by providing a call waiting tone of 440 Hz on the telephone line. The user typically hears the tone and may accept the waiting call by depressing, or “flashing” the switch hook.  
           [0011]    Features such as the call waiting feature, while convenient, present problems when the initial call includes a modem data communications session. For example, when a modem is used, the call waiting signal is typically not recognized by the modem because the modem is not adapted to recognize the call waiting signal during data communications. As a result, “waiting calls” may go unanswered. This is particularly problematic in single-line residential settings where a phone subscriber may miss incoming calls when, for example, an internet terminal device is downloading data associated with a universal resource locator (URL) or a satellite/pay TV authorization device is using the phone line to transact a pay-per-view charge. Additionally, the call waiting signal can disrupt the modem communications session and cause its premature termination.  
           [0012]    A prior art method of call waiting signal detection for a modem is disclosed in U.S. Pat. No. 4,852,151, issued Jul. 25, 1989, and entitled MODEM WITH CALL WAITING. The disclosed modem includes a data mode filter that is adapted to detect the presence of the carrier signal during the data transfer operation of the modem (i.e., the data mode), and a call progress management filter to detect incoming signals during the modem&#39;s call connection operation (i.e., the call progress mode.) The call waiting signal is typically not within the bandwidth of the data mode filter, but the call waiting signal is typically within the bandwidth of the call progress management filter. The method disclosed in the &#39;151 patent switches the data mode filter to the call progress management filter once the data mode filter detects a loss of the carrier signal. If the call progress management filter then detects energy in its bandwidth, the call waiting signal has been detected.  
           [0013]    Another prior art method of call waiting signal detection for a modem is disclosed in U.S. Pat. No. 5,287,401, issued Feb. 15, 1994, and entitled APPARATUS AND METHOD FOR A MODEM FOR DETECTING A CALL WAITING SIGNAL. The disclosed modem detects a cadence of carrier loss, carrier re-detect, carrier loss that is characteristic of local exchange carrier supply of call waiting tones. If the characteristic carrier loss/carrier detect cadence is detected, then the modem switches to its call progress management (CPM) filter. If the CPM filter then detects energy in its bandwidth, the call waiting signal has been detected.  
           [0014]    Unfortunately, carrier loss can and does occur for reasons other than supply of call waiting tones. For example, carrier can be temporarily lost due to telephone line transmission problems. If the data mode filters are switched off because of a carrier loss or a cadence not generated by a call waiting tone, subsequent data in a returning carrier signal would not be detected. Furthermore, each of the above prior-art methods relies on energy detected in the CPM filter band and is not specific to the 440 Hz call waiting tone. Thus, noise in the CPM filter band may trigger an errant call waiting detection.  
           [0015]    Another method of call waiting signal detection for a modem has been employed in at least some versions of WebTv™ set top boxes. The method, referred to as “LineShare” in WebTV™ documentation is to monitor the signal-to-noise-ratio (SNR) of a modem connection, and when the SNR drops significantly for a period of time, a call-waiting tone is assumed to have caused the reduced SNR. Unfortunately, many other conditions can cause reduced SNR, so call-waiting tone detection may be unreliable.  
         SUMMARY OF THE INVENTION  
         [0016]    It has been discovered that reliable detection of a call-waiting tone can be provided by employing a correlation based technique disclosed herein. A modem employing such a technique need not rely on carrier drop detection and is generally insensitive to other energy or noise on the line.  
           [0017]    In one embodiment in accordance with the present invention, a method of detecting a call-waiting tone in a signal includes sampling the signal to form a first sequence including signal samples, cross-correlating the first sequence with a second sequence to form a first cross-correlation value, and cross-correlating the first sequence with a third sequence to form a second cross-correlation value. The second sequence is derived from the first sequence and is temporally displaced by a first lag therefrom. The third sequence is derived from the first sequence and is temporally displaced by a second lag therefrom. A call-waiting tone is identified in the signal by comparing the first cross-correlation value with a first threshold percentage of a signal power value for the first sequence and by comparing the second cross-correlation value with a second threshold percentage of the signal power value. First and second threshold percentages may be the same or different percentages.  
           [0018]    In another embodiment in accordance with the present invention, an apparatus includes a signal sampler and a call-waiting tone detector. The signal sampler is coupled to receive a signal from a communications medium and to form a sampled sequence of values corresponding to the signal. The call-waiting tone detector is coupled to operate on a stored representation of a first sequence corresponding to the sampled sequence, and includes a first correlator, a second correlator, a third correlator and decision logic responsive to the first, the second, and the third correlators. The first correlator has access to the stored representation to calculate a power value of the signal. The second correlator has access to the stored representation to cross-correlate the stored representation with a first temporal displacement thereof to produce a first cross-correlation value. The third correlator has access to the stored representation to cross-correlate the stored representation with a second temporal displacement thereof to produce a second cross-correlation value. The decision logic signals detection of a call-waiting tone if the power value exceeds a threshold power level, the first cross-correlation value exceeds a first threshold percentage of the power value, and the additive inverse of the second cross-correlation value exceeds a second threshold percentage of the power value. The first and second temporal displacements are each by integer numbers of samples, the first temporal displacement corresponds to an integer multiple of the period of a call-waiting tone, and the second temporal displacement corresponds to a half-integer multiple of the period of the call-waiting tone. 
       
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS  
       [0019]    The present invention may be better understood, and its numerous objects, features, and advantages made apparent to those skilled in the art by referencing the accompanying drawings. The use of the same reference symbols in different drawings indicates similar or identical items.  
         [0020]    [0020]FIG. 1 is a block diagram depicting a communications device including a modem having a call-waiting tone detector in accordance with an embodiment of the present invention.  
         [0021]    [0021]FIG. 2 is a flow chart depicting operation (in accordance with an embodiment of the present invention) of the communications device and modem of FIG. 1 together with other communications devices in response to detection of a call-waiting tone in a received signal.  
         [0022]    [0022]FIG. 3 is a block diagram depicting functional modules and data flows for a modem including a call-waiting tone detector in accordance with an embodiment of the present invention.  
         [0023]    [0023]FIG. 4 is a flow chart depicting operation of the call-waiting tone detector of FIG. 3 in accordance with an embodiment of the present invention.  
         [0024]    [0024]FIG. 5 is a block diagram of an exemplary communications device embodiment including a processor, and memory for executing a software implementation of a modem including a call-waiting tone detector such as that depicted in FIG. 3. 
     
    
     DETAILED DESCRIPTION  
       [0025]    [0025]FIG. 1 depicts a communications device  110  including a modem  120  providing call-waiting tone detection in accordance with an embodiment of the present invention. In the embodiment of FIG. 1, modem  120  includes software modem code executable on a processor of communications device  110  to provide encoding, modulation, filtering, interpolation, echo cancellation, signal detection, equalization, demodulation, and decoding functions in accordance with a predetermined set of telecommunications standards, e.g., ITU-T Recommendation V.34 or V.32bis. Modem  120  is coupled to a public switched network  140  via line  180 . Another telecommunications device, illustratively telephone  130 , is also coupled to the public switched network  140  via line  180 . Therefore, both modem  120  and telephone  130  share line  180  at premises  170 .  
         [0026]    In operation, a data communications session is initiated between modem  120  and modem  150 . Like modem  120 , modem  150  may be a software modem; however, modem  150  may also be a traditional hardware modem. During data communications between modems  150  and  120 , yet another telecommunications device, illustratively telephone  160 , may initiate a call to the number associated with line  180 . Public switched network  140  supplies a call waiting tone at 440 Hz on line  180 . Typically, the call-waiting tone is supplied from a central office of the local exchange carrier.  
         [0027]    Referring to FIG. 2, modem  120  detects ( 210 ) the call waiting tone as described in greater detail below and supplies ( 220 ) an incoming call indication. Depending on the particular type of communications device  110 , the incoming call indication may be provided visually, audibly, or by other means. For example, in a television set top box embodiment, the incoming call may be indicated on television screen (not shown). Alternatively, the incoming call may be signaled audibly by communications device  110 , or by the ringer of telephone  130  if coupled thereto (e.g., as shown). A user may accept or ignore the incoming call. If the user ignores the incoming call, modem  120  will continue to communicate data and data lost due to interruption of carrier by the central office will be retransmitted according to an error-correction protocol after the physical layer reestablishes connection.  
         [0028]    If the user accepts the incoming call, the central office is signaled and, in response, telephone  160  is coupled to line  180 . In some embodiments, telephone  130  may be integrated with communications device  110  such that supply of the incoming call acceptance signal is provided by the combined device. In others, telephone  130  may be coupled to line  180  via communications device  110  such that a ring indication is synthesized on line  190  and such that communications device  110  generates a flash indication on line  180  and couples line  180  through to telephone  130  in response to pickup at telephone  130 .  
         [0029]    Can-Waiting Tone Detection  
         [0030]    Whatever the method of signaling acceptance of the incoming call, modem  120  must first detect the call-waiting tone. At any time during the data communications session between modems  120  and  150 , a new incoming call can be made to line  180 , causing a central office of public switched network  140  to supply a call-waiting tone of 440 Hz that appears at the line input of modem  120 .  
         [0031]    [0031]FIG. 3 depicts signal processing structures of modem  120  including call-waiting tone detector  399 . In the embodiment of FIG. 3, call-waiting tone detector  399  receives output of A/D converter  392  and includes bandpass filtering to limit echo. In this way operation of call-waiting tone detector  399  is independent of the current modulation scheme for modem  120 .  
         [0032]    Operation of modem  120  is described in greater detail below. FIG. 4 depicts operation of call-waiting tone detector  399  for reliably detecting the call waiting tone in accordance with an embodiment of the present invention Referring to FIG. 4, modem  120  receives samples Y(n) for a current block of data Typically, a block will include 48 samples of data from line  180  although other block sizes are also suitable. Using a subset of the samples from the block, call-waiting tone detector  399  first performs bandpass filtering  470  to remove echo then performs a series of correlations  410 ,  420 , and  430  on the bandpass filtered data.  
         [0033]    The correlation based detection method of call-waiting tone detector  399  can be better understood as follows. For a given sampling frequency, two integer numbers N 1  and N 2  can be found such that:  
           N   1   =K   1   *P   (1)  
           N   2 =( K   2 +1/2)* P   (2)  
         [0034]    where both K 1  and K 2  are integers and where P is the period (in samples) of the 440 Hz tone. P can be a fractional number of samples. Given the above definitions and a sampled sequence x(n) of a pure 440 Hz tone, then:  
           x ( n )= x ( n+N   1 )  (3)  
           x ( n )=− x ( n+N   2 )  (4)  
         [0035]    That is, x(n+N 1 ) represents a net 2π (or 1/440=0.0022{overscore (72)}second) phase shift of the sampled sequence and x(n+N 2 ) represents a net π (or 1/220=0.00{overscore (45)} second) phase shift of the sampled sequence.  
         [0036]    Call-waiting tone detector  399  utilizes correlations of a sampled sequence y(n) for a signal on line  180  with phase shifted versions thereof (net 2π 440Hz  and net π 440Hz ) to detect the 440 Hz tone amongst other energy on line  180 . Energy on line  180  will typically include that supplied by transmit path  301  of modem  120  as well as that transmitted by modem  150 , but may include a 440 Hz call-waiting tone component.  
         [0037]    For samples y(n) from line  180 , call-waiting tone detector  399  performs the following correlations:  
                 S   0          (   n   )       =       ∑     i   =   0       M   -   1              y        (     n   -   i     )            y        (     n   -   i     )                   (   5   )                   S   1          (   n   )       =       ∑     i   =   0       M   -   1              y        (     n   -   i     )            y        (     n   -   i   -     N   1       )                   (   6   )                   S   2          (   n   )       =       ∑     i   =   0       M   -   1              y        (     n   -   i     )            y        (     n   -   i   -     N   2       )                   (   7   )                               
 
         [0038]    where a subset of samples, numbering M, are used in the respective correlations. Typically, the correlations need only be performed once per block of 48 samples. Therefore, the correlations per block can be represented as:  
               S     0   ,     current                 block         =       ∑     i   =   0       M   -   1              y        (   i   )            y        (   i   )                   (   8   )                 S     1   ,     current                 block         =       ∑     i   =   0       M   -   1              y        (   i   )            y        (     i   -     N   1       )                   (   9   )                 S     2   ,     current                 block         =       ∑     i   =   0       M   -   1              y        (   i   )            y        (     i   -     N   2       )                   (   10   )                               
 
         [0039]    As long as M samples correspond to a period longer than that of the 440 Hz call-waiting tone, any subset of M samples from the current block is suitable.  
         [0040]    The first correlation (i.e., equation 8, above) corresponds to auto-correlation  410  (i.e., correlation of the subset with itself) to produce a measure S 0  of the power level of the incoming signal. The second correlation (i.e., equation 9, above) corresponds to cross-correlation  420  (i.e., correlation of the subset with a version thereof phase shifted by N 1  samples or an integer multiple of the call waiting tone period) to produce a measure S 1 . The third correlation (i.e., equation 10, above) corresponds to cross-correlation  430  (i.e., correlation of the subset with a version thereof phase shifted by N 2  samples or a half multiple of the call waiting tone period) to produce a measure S 2 .  
         [0041]    Given the above-described correlations, if  
         S 0 &gt;threshold power     —     level ;  (11)  
         S 1 &gt;threshold 1 *S 0 ; and  (12)  
         S 2 &lt;−threshold 2 *S 0   (13)  
         [0042]    for some consecutive blocks N 3 , then a 440 Hz tone is present in sampled signal y(n) and a call-waiting tone is detected by call-waiting tone detector  399 . The use of both second and third crosscorrelations discriminates a sampled signal y(n) including a call-waiting tone component from a DC signal on line  180 .  
         [0043]    If S 0  is not greater than power threshold (decision  440 ), then no call-waiting tone is present. Selection of a power threshold can be better understood as follows. If line  180  (FIG. 1) has the call waiting feature enabled, when a call is made by telephone  160  to line  180  during communications between modems  120  and  150 , the central office interrupts the modem  150  to modem  120  connection for 300 ms (resulting in a carrier drop) and provides a −13 dBm 440 Hz call-waiting tone on line  180  (i.e., to modem  120 ). Typically, two instances of the call-waiting tone are supplied at a 10 second interval. As a result, receive path structures of modem  120  receive only the 440 Hz tone and the local hybrid echo (near-end echo). Since the 13 dBm 440 Hz tone is supplied only on the local loop, it will be received normally around −19 dBm. Bandpass filter  470  reduces the near-end echo signal level below that of the received call-waiting tone. In such case, a power threshold of −30 dBm discriminates between sequences possibly including a call-waiting tone component and those certainly not including a call-waiting tone component. Power threshold values as low as 43 dbm are also suitable. The bandpass filter is used so that the call waiting detector is independent of current modem modulation scheme, e.g., V.34, V.32 or even V.22. Values for threshold 1  and threshold 2  are chosen to reflect the relative near-end echo level. Suitable values are typically in the range of 0.2 to 0.75 for configurations such as that depicted in FIG. 3.  
         [0044]    An exemplary embodiment of call-waiting tone detector  399  includes code executable on a processor, e.g., of communications device  110 , although the invention is not limited to such an embodiment. In particular, the source code which follows is functionally descriptive of various implementations in accordance with the present invention, including e.g., implementations in custom circuitry, using a programmed custom (or commercially-available) DSP, as software executable on a general purpose processor, or as any combination of the above.  
                                                                                                                                                                                                                                                                                                                                               #define kMinDetectSensitivity   1       #define kMinPower   1000            Public void       CallWaitingDetector(int nSamps, short *srcPtr)                {           if (gDetectorSensitivity != 0)                {           long power, corr1, corr2;           short *srcEndPtr = srcPtr + nSamps;           short *dstPtr = gFltDLineWritePtr;           long temp0, temp1, temp2;           /* IIR bandpass filter to filter out near-end echo */           do                {           temp1 = (long)dstPtr[−1];           temp2 = (long)dstPtr[−2];           temp0 = ((long) (*srcPtr++) &gt;&gt; 6) + (temp1 &lt;&lt; 1) −                (((temp1 &lt;&lt; gFilterShift1) +            (temp1 &lt;&lt; gFilterShift2)) &gt;&gt; 4) −           temp2 + (temp2 &gt;&gt; 6);                *dstPtr++ = (short) (temp0);           } while (srcPtr != srcEndPtr);                BlockShortSubtract(nSamps,gFltDLineWritePtr,                gFltDLineWritePtr-gFilterDelay,           gDelayLineWritePtr);                BlockshortMove(kCallWaitingFilterMaxDelay,                gFilterDelayLine+nSamps,           gFilterDelayLine);                /* run correlators to detect call waiting tone */           power = BlockCorrelate(nSamps, gDelayLineWritePtr,                gDelayLineWritePtr);                if (power &gt; kMinPower)                {           corr1 = BlockCorrelate(nSamps,gDelayLinewritePtr,                gDelayLineWritePtr −           gperiodGap);                corr2 = BlockCorrelate(nSamps, gDelayLineWritePtr,                gDelayLineWritePtr −           gHalfPeriodGap);                power = (power &gt;&gt; 2);           if ((corr1 &gt;= power) &amp;&amp; (corr2 &lt;= −power))                {           if (++gDetectCount == gDetectorSensitivity)                {           modemstatusStruct status;           status.code = kCallWaitingToneDetected;           DataModemStatusHandler(&amp;status);           }                }                else                gDetectCount = 0;                }                else                gDetectCount = 0;                BlockShortMove(kCallWaitingMaxDelay, gDelayLine+nSamps,                gDelayLine);                }                }                      
 
         [0045]    In the exemplary source code above, threshold, and threshold 2  are both 25% (power=(power&gt;&gt;2)) and gDetectorsensitivity (or N 3 ) is set to eight (8) consecutive blocks to guard against false detections. Other threshold values and consecutive block counts are also suitable and will depend on relative near-end echo level.  
         [0046]    Although in an exemplary embodiment (see FIG. 3), call-waiting tone detector  399  is positioned to receive sample data at the front end receive path structures  302 , alternative embodiments may position a call-waiting tone detector after echo cancellation in the modem front-end data path, e.g., at the input of automatic gain control  389 , at the output of automatic gain control  389 , or elsewhere downstream of echo cancellation. Such embodiments may obviate the bandpass filtering of call-waiting tone detector  399 , at least during when a then current modulation scheme includes echo cancellation. Based on the description herein, suitable modifications to include bandpass filtering or alternative near-end echo suppression, e.g., selectively during V.22 modulation, will be appreciated by those skilled in the art.  
         [0047]    An Exemplary Software Modem Embodiment  
         [0048]    [0048]FIG. 3 depicts transmit path structures  301  and receive path structures  302  for an exemplary V.34 modem  120  embodiment, including call-waiting tone detector  399 . Transmit path structures  301  and receive path structures  302  include fixed and adaptive filter implementations and other signal processing structures for modulation and demodulation of signals in accordance with the signaling requirements of ITU-T Recommendation V.34. In the exemplary embodiment of FIG. 3, filter implementations and other signal processing structures are implemented as software executable on a general purpose processor and call-waiting tone detection is accomplished in software.  
         [0049]    Transmit path structures  301  include encoder  320 , modulator  330 , and pre-emphasis and shaping filter  341 . Receive path structures  302  include decoder  360 , demodulation and channel impairment compensation module  370 , and receive front end module  380 .  
         [0050]    Those of skill in the art will recognize a variety of suitable software implementations for structures along transmit and receive data paths, including algorithms for both performing the signal processing functions defined by the structures and for adaptively updating the structure definitions, e.g., by adaptively updating filter coefficients. The particular structures depicted in FIG. 3 are merely illustrative of an exemplary set of suitable implementations. Alternative embodiments may incorporate transit and receive path structures of any suitable design. Such structures, including the call-waiting tone detector described above, may be suitably implemented in custom circuitry, using a programmed custom (or commercially-available) DSP, as software executable on a general purpose processor, or as any combination of the above.  
         [0051]    Referring now to the receive data path of V.34 modem  120 , receive path structures  302  (i.e., software implementations thereof) for receive front end module  380 , demodulation and channel impairment compensation module  370 , and decoder  360  are all active (enabled) while V.34 modem  120  is operating in steady state communications state. Receive front end module  380  receives the output of the A/D converter  392  as an input A/D converter  392  couples to transmission line  395 . Preliminary echo canceler  390  is implemented as a real data/real coefficients adaptive filter using any suitable filter implementation. Preliminary echo canceler  390  receives as an input a white signal from the output of the modulator  330 . Preliminary echo canceler  390  uses a stochastic gradient updating algorithm for adaptation during half duplex of V.34 training and is not updated during data mode. This preliminary stage of echo cancellation reduces echo level relative to the receive signal level so that subsequent stages such as clock recovery, S and A/B signal detection, and automatic gain control will not be significantly affected by the echo. Alternative embodiments may provide distinct near- and far-end preliminary echo canceler structures.  
         [0052]    S signal detector  386  is employed to detect S-to-{overscore (S)} transitions indicative of rate re-negotiation and cleardown requests as described in ITU-T Recommendation V.34, §§ 11.6-7 of which are hereby incorporated by reference. Similarly, A/B tone detector  387  is employed to detect tone A (if V.34 modem  120  is the call modem) or tone B (if V.34 modem  120  is the answer modem) indicative of retrain requests as described in ITU-T Recommendation V.34, § 11.5 of which is hereby incorporated by reference. Call waiting tone detector  399  is described above.  
         [0053]    Receive path structures  302  implemented along the receive data path should be synchronized with the remote modem signal. In the exemplary embodiment of FIG. 3, an adaptive FIR filter is used to perform the interpolation. Adaptive FIR filters are used to interpolate the receive signal (at receive signal interpolator  385 ) as well as to interpolate delayed and undelayed versions of the modulator output (at far-end echo interpolator  383  and near-end echo interpolator  381 ) used as inputs for corresponding far- and near-end main echo cancelers  373  and  374 . The filter coefficients are adjusted based on timing phase and frequency recovered from the remote modem signal by clock recovery module  384 . The adaptation algorithm is performed by a two-stage combination of a poly-phase filter and linear interpolations. Those of skill in the ad will appreciate a variety of suitable implementations of poly-phase filters, as well as alternative adaptation algorithms.  
         [0054]    Demodulator  372 , a corresponding inverse structure (demodulators −1    371 ), and decoder  360  provide a feedback loop for adaptive updates to the coefficients defining main near-end echo canceler  373 , main far-end echo canceler  374 , and equalizer  375 . V.34 modem  120  may optionally include a phase locked loop to compensate for frequency offset and phase jitter on transmission line  395 . Regarding demodulation and channel impairment compensation module  370 , a variety of alternative echo canceler and equalizer configurations are suitable. Several such configurations are described in greater detail in a copending patent application Serial No. 08/761,405 entitled, “SYSTEM AND METHOD FOR IMPROVING CONVERGENCE DURING MODEM TRAINING AND REDUCING COMPUTATIONAL LOAD DURING STEADY-STATE MODEM OPERATIONS,” naming Gonikberg and Liang as inventors and filed on Dec. 6, 1996, the entirety of which is hereby incorporated by reference.  
         [0055]    Decoder  360  converts the demodulated complex symbols into a bit stream which is supplied to receiver process  397 . Transmit process  396  and receiver process  397  may be the same process. Decoder  360  performs nonlinear decoding, linear prediction, trellis decoding, constellation decoding, shell demapping, and data de-framing, all as described in respective sections of the V.34 recommendation, which is incorporated herein by reference. Those of skill in the art will recognize variety of alternative implementations of decoder  360  in accordance with the requirements the V.34 recommendation. In addition, those of skill in the art will recognize a variety of alternative configurations of decoder  360  suitable to modem implementations in accordance with other communications standards such as V.32, V.32bis, etc.  
         [0056]    Referring now to the transmit data path of V.34 modem  120 , transmit process  396  supplies a bit stream to a V.34 implementation of encoder  320 . Encoder  320  converts the input bit stream into a baseband sequence of complex symbols which is used as input to modulator  330 . Encoder  320  performs shell mapping, differential encoding, constellation mapping, precoding and 4D trellis encoding, and nonlinear encoding, all as described in respective sections of ITU-T Recommendation V.34, §§ 9.1-9.7 of which are hereby incorporated by reference.  
         [0057]    Modulator  330  converts the baseband sequence of complex symbols from the output of the encoder into a passband sequence of real samples. In particular, modulator  330 :  
         [0058]    1. multiplies the complex baseband sequence by the carrier frequency; and  
         [0059]    2. converts the complex signal to real.  
         [0060]    If the spectrum of the modulator output is sufficiently white, it can be used as an input to receiver echo cancelers, as described below.  
         [0061]    Shaping and pre-emphasis filter  341  provides square-root-of-raised-cosine shaping as well as pre-emphasis filtering specified by section SA of the V.34 recommendation, which is incorporated herein by reference. Square-root raised cosine complex shaping and pre-emphasis filtering are implemented using any suitable filter implementation. The output of shaping and pre-emphasis filter  341  is an output of the transmitter portion of V.34 modem  120  and is provided to D/A converter  391 . D/A converter  391  couples to transmission line  395 .  
         [0062]    In one embodiment of V.34 modem  120 , portions of the receive path may be disabled during a doze mode. Operation of such an embodiment, including transitions between steady state communications state and doze state are described in greater detail in a co-pending patent application Ser. No. 08/780,611 entitled, “SYSTEM AND METHOD FOR REDUCING PROCESSING REQUIREMENTS OF MODEM DURING IDLE RECEIVE TIME,” naming Zarko Draganic as inventor and filed on Jan. 8, 1997, the entirety of which is hereby incorporated by reference. In such an embodiment, inclusion of call-waiting tone detector  399  in the set of undisabled receive path structures active during a doze state advantageously allows detection of an incoming call even during idle receive time. Because, call-waiting tone detection can be performed as described above by performing correlations on subsets of the received samples for a given block, call-waiting tone detector  399  consumes few processor cycles and does not significantly affect processor load during doze mode.  
         [0063]    Exemplary Device Embodiments  
         [0064]    [0064]FIG. 5 depicts a communications device  500  incorporating executable code of a SoftModem library  510  including modules providing a software implementation of a V.34 modem  120 . In a such an embodiment, input signal vectors (e.g., samples y(n)) and threshold values, as well as filter coefficient vectors suitable for providing the various filter implementations of interpolators, phase splitting filters, linear predictors, etc. are loaded from memory  530 . Output signal vectors are stored to memory  530 . In addition, executable instructions implementing the SoftModem library  510  (including implementations of transmit path structures  301  and receive path structures  302 ) and suitable for execution on general purpose processor  520  are also stored in, and loaded from) memory  530 . Alternative embodiments may include executable instructions and predetermined values, e.g., thresholds, in a non-volatile or read-only store.  
         [0065]    In an exemplary embodiment, general purpose processor  520  includes a MIPS R3000 RISC microprocessor, although a wide variety of alternative processor implementations are also suitable, including, for example, R4000 and R5000 processors, processors conforming to the StrongArm™, Sparc™, PowerPC™, Alpha™, PA-RISC™, or x86 processor architeetres, etc. General purpose processor  520  includes a DMA channel  521  for interfacing to telecommunication circuits (illustratively, phone line  590 ) via codec  570  and Digital-to-Analog/Analog-to Digital (DAA) converter  560 . Of course, memory  530  may include either read/write memory  531  or read/write memory  531  in combination with read-only memory  532 . Persons of ordinary skill in the art will recognize a variety of suitable allocations of code and data to each. Removable media  580  provides a mechanism for supplying the executable instructions implementing SoftModem library  510 .  
         [0066]    While the invention has been described with reference to various embodiments, it will be understood that these embodiments are illustrative and that the scope of the invention is not limited to them. For example, call waiting tone detection may be performed at a variety of points in the signal processing structure of a given implementation. Software, hardware, and hardware/software embodiments are all envisioned. Although described in the context of an exemplary software embodiment of a V.34 modem, call waiting tone detectors in accordance with the present invention may be employed in a wide variety of communications device applications including set top boxes, internet terminal devices, satellite/pay TV authorization devices, fax machines, Personal Digital Assistants (PDAs), portable computers, cellular phones, etc. with suitable modifications to the surrounding signal processing structures. Many variations, modifications, additions, and improvements of the embodiments described are possible and may fall within the scope of the invention as defined by the claims which follow.

Technology Category: 5