Abstract:
In accordance with the teachings described herein, systems and methods are provided for calibrating DC offset in a receiver. A DC calibration circuit may be used that is configured to remove DC offset from a digital multi-carrier modulated (MCM) signal that includes a sequence of MCM symbols. The DC calibration circuit may include an accumulator and a compensator. The accumulator may be used to determine an estimated DC offset of a current MCM symbol in the sequence of MCM symbols. The compensator may be used to remove the estimated DC offset from a next MCM symbol in the sequence of MCM symbols. The accumulator may also be used to receive a plurality of digital samples that comprise the current MCM symbol and to determine the estimated DC offset by calculating an average of the plurality of digital samples.

Description:
CROSS-REFERENCE TO RELATED APPLICATION 
     This application is a continuation of U.S. application Ser. No. 12/353,391, filed on Jan. 14, 2009, which claims priority from U.S. Provisional Patent Application No. 61/021,173, filed on Jan. 15, 2008, and entitled “Digital Baseband DC Offset Calibration Methods for OFDM Systems,” the entirety of which is incorporated herein by reference. 
    
    
     FIELD 
     The technology described in this patent document relates generally to receivers. More specifically, systems and methods are provided for calibrating digital baseband DC offset in a multi-carrier modulation (MCM) receiver. The technology described herein is particularly well-suited for use in an orthogonal frequency-division multiplexing (OFDM) system, but may also have utility with other multi-carrier modulation schemes. 
     BACKGROUND 
     DC offset is a common problem in direct-conversion receivers. DC offset in the received signal may be caused by several factors, such as self mixing at the receiver&#39;s RF mixers, calibration residue at the receiver&#39;s analog components and carrier leakage from the transmitter. This DC offset is typically less of a problem in OFDM systems because the DC tone is not used for signal transmission. However, there may still be a need to reduce or eliminate DC offset in an OFDM system in order to improve system performance. For example, reducing or cancelling DC offset may reduce the headroom requirement for each module in the analog and data path, prevent clipping during FFT processing due to DC accumulation, and reduce interference leakage from DC tone to other adjacent tones. 
     Traditionally, DC offset in a received communication signal is calibrated by applying a high pass filter after analog-to-digital conversion. With this method, the performance of DC calibration is dependent on the high-pass corner frequency of the filter. A high corner frequency will add more distortion to the signal, but will require less time to remove the DC offset. A lower corner frequency will result in less distortion, but will take longer to remove the DC offset. Consequently, the receiver either suffers from signal distortion by using a fast high pass filter or suffers from strong DC interference leakage during the first few symbols of a frame by using a slower high pass filter. This tradeoff often proves to be extremely challenging for system designers. 
     SUMMARY 
     In accordance with the teachings described herein, systems and methods are provided for calibrating DC offset in a receiver. A DC calibration circuit may be used that is configured to receive a digital multi-carrier modulated (MCM) signal that includes a sequence of MCM symbols. The DC calibration circuit may include an accumulator and a compensator. The accumulator may be used to determine an estimated DC offset of a current MCM symbol in the sequence of MCM symbols. The compensator may be used to remove the estimated DC offset from a next MCM symbol in the sequence of MCM symbols. The accumulator may also be used to receive a plurality of digital samples that comprise the current MCM symbol and to determine the estimated DC offset by calculating an average of the plurality of digital samples. In one embodiment, the modulated digital signal may be modulated with an orthogonal frequency-division multiplexing (OFDM) scheme. 
     A DC calibration circuit may also include a first timer configured to couple the accumulator to the digital MCM signal while the current MCM symbol is received by the DC calibration circuit, and a second timer configured to pass the estimated DC offset from the accumulator to the compensator such that the estimated DC offset is applied to the digital MCM signal by the compensator while the next MCM symbol is received by the DC calibration circuit. 
     The accumulator in a DC calibration circuit may include a multiplier configured to divide each of the plurality of digital samples by a total number of digital samples to output a plurality of divided samples, and a memory element coupled in a feedback loop with a summation element and configured to accumulate a sum of the plurality of divided samples as the estimated DC offset. The compensator in a DC calibration circuit may include a memory element configured to receive the estimated DC offset from the accumulator, and a summation element configured to subtract the estimated DC offset from the next MCM symbol in the sequence of MCM symbols. 
     In one embodiment, the DC calibration circuit may also include a filter circuit configured to correct for DC offset in a first of the sequence of MCM symbols. The filter circuit may be configured to receive a plurality of digital samples that comprise the first of the sequence of MCM symbols and to apply a filter coefficient to the plurality of digital samples to correct for DC offset. The filter circuit may include a multiplier configured to multiple each of the plurality of digital samples by a the filter coefficient to output a plurality of filtered samples, a memory element coupled in a feedback loop with a first summation element and configured to accumulate a sum of the plurality of filtered samples as a DC correction value, and a second summation element configured to subtract the DC correction value from the first of the sequence of MCM symbols to correct for DC offset. The filter circuit may also include a timer configured to couple the DC correction value to the second summation element while the first of the sequence of MCM symbols is received by the DC calibration circuit. 
     In another embodiment, a DC calibration circuit for a receiver may include an accumulator configured to determine an estimated DC offset for each of the sequence of MCM symbols as it is received by the DC calibration circuit, a memory element configured to store a current MCM symbol in the sequence of MCM symbols while the accumulator is determining the estimated DC offset for the current MCM symbol, and a compensator configured to remove the estimated DC offset from current MCM symbol. The receiver may includes a down converter that down-samples the digital MCM signal prior to its reception by the DC calibration circuit. 
     In another embodiment, a DC calibration circuit for a receiver may include a means for determining an estimated DC offset of a current MCM symbol in the sequence of MCM symbols, and a means for removing the estimated DC offset from a next MCM symbol in the sequence of MCM symbols. 
     A method for calibrating digital baseband DC offset in a multi-carrier modulation (MCM) receiver may include the following steps: receiving a digital MCM signal that includes a sequence of MCM symbols, each of the sequence of MCM symbols including a plurality of digital samples; determining an average of the plurality of digital samples for a current MCM symbol in the sequence of MCM symbols, the average being an estimated DC offset for the current MCM symbol; and subtracting the estimated DC offset from a next MCM symbol in the sequence of MCM symbols. In certain embodiments, the method may also include the step of applying a filter coefficient to a first of the sequence of MCM symbols to correct for DC offset. 
     Another method for calibrating digital baseband DC offset in a multi-carrier modulation (MCM) receiver may include the following steps: receiving a digital MCM signal that includes a sequence of MCM symbols, each of the sequence of MCM symbols including a plurality of digital samples; determining an average of the plurality of digital samples for a current MCM symbol in the sequence of MCM symbols, the average being an estimated DC offset for the current MCM symbol; and subtracting the estimated DC offset from a next MCM symbol in the sequence of MCM symbols. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1  is a block diagram of an example direct-conversion receiver. 
         FIG. 2  is a block diagram of a first example DC calibration circuit in a receiver. 
         FIG. 3  is a block diagram of a second example DC calibration circuit in a receiver. 
         FIG. 4  is a block diagram of a third example DC calibration circuit in a receiver. 
         FIG. 5  is a flow diagram of a first example method for calibrating digital baseband DC offset in a multi-carrier modulation (MCM) receiver 
         FIG. 6  is a flow diagram of a second example method for calibrating digital baseband DC offset in a MCM receiver. 
         FIG. 7  is a flow diagram of a third example method for calibrating digital baseband DC offset in a MCM receiver. 
     
    
    
     DETAILED DESCRIPTION 
       FIG. 1  is a block diagram depicting an analog portion of an example direct-conversion receiver  10 , and illustrating how DC offset is typically introduced in the receiver  10 . The example receiver  10  receives a multi-carrier modulated (MCM) signal, such as an OFDM signal, via an external front end module (FEM)  12  that connects the receiver to an antenna (not shown). The received signal is first amplified by an external (off-chip) low-noise amplifier (LNA)  14  and the amplified signal is directed to a receiver integrated circuit (IC) via an internal FEM  16 . Within the receiver IC, the signal is further amplified by an internal LNA  18  and is then combined with a local reference signal by a mixer  20 . To help illustrate how DC offset is introduced by the mixer  20 , a model of the mixer  20  is shown in  FIG. 1  with three components  22 ,  24 ,  26 . The first mixer component  22  in the mixer  20  depicts the mixing function, the second mixer component  24  is included in the model to show the introduction of DC offset, and the third mixer component  26  is included to illustrate the gain introduced by the mixer  20 . The output of the mixer  20  is filtered by an adjustable gain low-pass filter (LPF)  28 , further amplified by a variable gain amplifier (VGA)  30 , and converted into a digital signal by an analog-to-digital converter  32 . 
     As illustrated in  FIG. 1 , there are typically three predominant sources of DC offset from the analog domain in a direct-conversion receiver  10 . The primary source is typically self mixing at the RF mixer  20 . In addition, each analog component in the receiver introduces some amount of DC offset, and DC offset is typically introduced due to carrier leakage from the transmitter. The technology described herein proposes ways to reduce or eliminate this DC offset using average-based processes applied after analog-to-digital conversion. These average-based approaches introduce less distortion and take less time compared to traditional high pass filter methods. 
       FIG. 2  is a block diagram of a first example DC calibration circuit  40  in a receiver. Also shown in the receiver chain is an analog-to-digital converter  32  that converts a MCM signal (e.g., an OFDM signal) from the analog domain to the digital domain, a digital mixer  44  that compensates for the carrier frequency offset, a digital low pass filter  46 , and a down converter  48  that down-samples the signal to the Nyquist rate. The DC calibration circuit  40  may, for example, be included after the analog-to-digital converter (ADC)  32  in the direct-conversion receiver  10  illustrated in  FIG. 1 . 
     In operation, the DC calibration circuit  40  takes a symbol average of received digital samples as the estimated DC offset, and applies the estimated DC offset to correct the next MCM symbol in the digital MCM signal. In one implementation, the DC calibration circuit  40  includes an accumulator  50 , a compensator  52 , a first timer  54  and a second timer  56 . The first timer  54  is turned on at the start of a current MCM symbol in the digital MCM signal and is turned off at the current MCM symbol end in order to input the current MCM symbol to the accumulator  50 . The accumulator  50  includes a multiplier and a memory element (Z −1 ), such as a shift register, that is coupled in a feedback loop with a summation element. The accumulator  50  determines the symbol average of the current MCM symbol by dividing each received digital sample by the total number of digital samples in the current MCM symbol (8N) and then accumulating the summation of the divided samples in the memory element (Z −1 ). The symbol average provides an estimate of the DC offset in the current MCM symbol. In the illustrated example, the received MCM signal is over-sampled by a predetermined factor (R), and thus the total number of digital samples in a MCM symbol is R*N, where N is the number of digital samples if sampled at Nyquist rate. For instance, in one example the received MCM signal may be over-sampled by a factor of eight, and thus the total number of digital samples in the MCM symbol would be 8N. 
     At the start of the next MCM symbol, the second timer  56  in the DC calibration circuit  40  is turned on to pass the DC estimate from the accumulator  50  to the compensator  52 . The compensator  52  includes a memory element (Z −1 ), such as a shift register, for storing the DC estimate, and a summation element for subtracting the DC estimate from the digital MCM signal. After the DC estimate is loaded to the compensator, the second timer  56  is turned off and the compensator  52  subtracts the DC estimate from the next MCM symbol to compensate for DC offset in the MCM signal. In this manner, the DC calibration circuit  40  provides DC cancellation for all MCM symbols except for the first (beginning) MCM symbol. 
     Some amount of DC offset may be acceptable in the first MCM symbol for many applications. For example, a WiMax system uses the first MCM symbol as a preamble that does not carry any data information, and so more performance degredation in the first MCM symbol is typically acceptable. Accordingly, the DC calibration circuit depicted in  FIG. 2  will provide sufficient DC offset calibration for many applications, even though DC offset remains in the first MCM symbol. 
       FIG. 3  is a block diagram of a second example DC calibration circuit  60  in a receiver. This example DC calibration circuit  60  is similar to the example shown in  FIG. 2 , with the addition of a filter circuit  66  that is used to compensate for DC offset in the first MCM symbol. Specifically, the DC calibration circuit  60  includes an accumulator  62  that takes a weighted symbol average of received digital samples as the estimated DC offset, and a compensator  64  that applies the estimated DC offset to correct the next MCM symbol in the digital MCM signal, as described above with reference to  FIG. 2 . In addition, the DC calibration circuit  60  also includes a filter circuit  66  that corrects for DC offset in the first MCM symbol. The filter circuit  66  is a fast-loop digital high-pass filter that is coupled to the digital MCM signal by a third timer  68  during the first MCM symbol and is then turned off during the rest of the sequence of MCM symbols. The filter circuit  66  includes a multiplier  70  for applying a programmable filter coefficient (μ) to the received digital samples of the first MCM symbol and an accumulator  72  for summing the filtered digital samples to produce a DC correction value that is subtracted from the digital MCM signal. 
     The example DC calibration circuit  60  of  FIG. 3  may offer better performance than the example shown in  FIG. 2  because the DC calibration circuit  60  also corrects for DC offset in the first MCM symbol. However, the example DC calibration circuits in  FIGS. 2 and 3  may both suffer from performance degradation in the case of time-varying DC offset (i.e., DC offset that varies from symbol to symbol).  FIG. 4  is a block diagram of a third example DC calibration circuit  80  that also corrects for time-varying DC offset. 
     The DC calibration circuit  80  shown in  FIG. 4  includes a memory element  82 , such as a shift register, that stores the received MCM symbol so that DC offset may be estimated and corrected for the current MCM symbol. This offers improved performance over the examples illustrated in  FIGS. 2 and 3 . However, the improved performance is provided at the cost of adding an additional memory element to the circuit that needs to be sufficiently large to store an entire MCM symbol. In order to reduce the size of the memory element  82 , the DC calibration circuit  80  may be added to the receiver after the down-converter  84 , as shown in  FIG. 4 . In this way, the OFDM signal is down sampled to the Nyquist rate prior to DC correction, and a smaller memory element  82  may be used. 
     In operation, the DC calibration circuit  80  stores each successive MCM symbol in the memory element  82  as the MCM symbol is received from the down-converter  84 . At the same time, the symbol average of the received digital samples is determined by the accumulator  86  to provide an estimate of the DC offset in the MCM symbol. The accumulator  86  operates similarly to the accumulator  50  described above with reference to  FIG. 2 , except that each digital sample is divided by N (the Nyquist rate) instead of R*N because the MCM symbol has been down-sampled by a factor of R. When the DC estimate is determined, the DC estimate is passed from the accumulator  86  to the compensator  88 , which subtracts the DC estimate from the MCM symbol stored in the memory element  82 . 
       FIG. 5  is a flow diagram of a first example method  100  for calibrating digital baseband DC offset in a MCM receiver. In step  102 , a digital MCM signal (e.g., a digital OFDM signal) is received that includes a sequence of MCM symbols, with each of the sequence of MCM symbols including a plurality of digital samples. The digital MCM signal may, for example, be received from an analog-to-digital converter in a receiver chain. In step  104 , an average of the plurality of digital samples is determined for a current MCM symbol in the sequence of MCM symbols. The average provides an estimated DC offset for the current MCM symbol. In step  106 , the estimated DC offset is subtracted from a next MCM symbol in the sequence of MCM symbols. The method  100  then repeats to step  104  such that the symbol average for each received MCM symbol is used to correct the DC offset in the subsequently received MCM symbol. 
       FIG. 6  is a flow diagram of a second example method  110  for calibrating digital baseband DC offset in a MCM receiver. In step  112 , a digital MCM signal (e.g., a digital OFDM signal) is received that includes a sequence of MCM symbols, with each of the sequence of MCM symbols including a plurality of digital samples. The digital MCM signal may, for example, be received from an analog-to-digital converter in a receiver chain. In step  116 , the DC offset in the first MCM symbol in the sequence is corrected using a high pass filter circuit. In step  118 , an average of the plurality of digital samples is determined for the current MCM symbol in the sequence of MCM symbols. The average provides an estimated DC offset for the current MCM symbol. In step  120 , the estimated DC offset is subtracted from a next MCM symbol in the sequence of MCM symbols. The method  110  then repeats to step  118  such that the symbol average for each received MCM symbol is used to correct the DC offset in the subsequently received MCM symbol. 
       FIG. 7  is a flow diagram of a third example method  130  for calibrating digital baseband DC offset in a MCM receiver. In step  132 , a digital MCM signal (e.g., a digital OFDM signal) is received that includes a sequence of MCM symbols, with each of the sequence of MCM symbols including a plurality of digital samples. The digital MCM signal may, for example, be received from an analog-to-digital converter in a receiver chain. In step  134 , the digital MCM signal is down-sampled, for example to the Nyquist rate. After step  134 , the method  130  proceeds simultaneously to steps  136  and  138 . 
     In step  136 , an average of the plurality of digital samples is determined for a current MCM symbol in the sequence of MCM symbols. The average provides an estimated DC offset for the current MCM symbol. At the same time, the current MCM symbol is stored in a memory element, such as a shift register, at step  138 . In step  140 , the estimated DC offset is subtracted from the current MCM symbol that was stored in the memory element. The method  130  then repeats to steps  136  and  138  to process the next MCM symbol in the sequence. 
     This written description uses examples to disclose the invention, including the best mode, and also to enable a person skilled in the art to make and use the invention. The patentable scope of the invention may include other examples that occur to those skilled in the art.