The present invention relates generally to data communications, and in particular, to a method and apparatus for transmission and reception of data within such communication systems.
Each of these proposals provide increased data rates along with some (but not all) additional advantages that include backwards compatibility with existing High Rate Packet Data (HRPD)/1XEV-DO (DO) transceivers, no inter-block interference, an FDM (frequency division multiplexed) pilot orthogonal to the data symbols, a single receiver which can handle a unicast and efficient broadcast service, and a simple channel estimator. Since none of the present proposals provide all of these advantages in a single solution, it would be desirable to have a method and apparatus for providing enhanced broadcast-multicast service (BCMCS) that was able to provide all of these advantages.
Specific embodiments of the present invention are disclosed below with reference to
Various embodiments are described to provide for the transmission and reception of data in an improved manner. Data transmission is improved by including in a transmitter a null generator to generate an output data symbol sequence that exhibits nulls in the frequency domain at particular frequencies that an input data symbol sequence does not. A pilot inserter then adds a pilot symbol sequence to this output data symbol sequence to create a combined symbol sequence. Since the pilot symbol sequence exhibits pilot signals corresponding to the nulls of the output data symbol sequence in the frequency domain, the combined symbol sequence exhibits pilots that are orthogonal to the data in the frequency domain.
Operation of embodiments in accordance with the present invention occurs substantially as follows with reference to
Null generator 110 creates output data symbol sequence 103 from input data symbol sequence 102. As compared to input sequence 102, output sequence 103 exhibits nulls in the frequency domain at particular frequencies that input sequence 102 does not. Moreover, if each input data symbol (in sequence 102) is independent of each other and has the same variance, the variance of each output data symbol (in sequence 103) will be the same.
Pilot inserter 120 then adds a pilot symbol sequence to output data symbol sequence 103 to create combined symbol sequence 104. The pilot symbol sequence comprises pilot symbols 107, which are block repeated as required. In the end, the pilot symbol sequence should exhibit pilot signals in the frequency domain that correspond to the nulls of the output data symbol sequence. Therefore, the pilot signals will replace the nulls when the sequences are added.
For example,
It can be easily verified that the pilot frequency response is zero on all frequencies except subcarriers n=0, 9, 18, . . . , 351 (total 40 points), i.e.,
Pilot insertion 410 depicts the symbol-by-symbol addition of the output data symbol sequence and the pilot symbol sequence in the time domain, while pilot insertion 420 depicts the corresponding addition in the frequency domain. Pilot insertion result 430 depicts the combined symbol sequence with pilot signals on subcarriers 0, 9, 18, . . . , and 351, which correspond to the nulls in the frequency response of the output data symbol sequence.
For embodiments in which content-based spreader 130 is located after pilot inserter 120, spreader 130 modifies combined symbol sequence 104 to shift the pilot signals to particular subcarriers in the frequency domain according to what content the combined symbol sequence is conveying. In other words, different content is shifted different amounts. To provide an example, content-based spreading may be accomplished using a modulation sequence as follows:
exp(jΦkn), n=0, 1, . . . 359
where
k=0, 1, . . . 8 corresponds to the k-th content. Therefore, if the pilot signals of combined symbol sequence 104 are on subcarriers 0, 9, 18, . . . , and 351, the pilot signals of symbol sequence 105 may be shifted to subcarriers 2, 11, 20, . . . , and 353 in the case where content k=3 is being conveyed
With multiple contents being transmitted by neighboring cells, using the modulation sequence above for different contents can aid in unbiased pilot detection and can reduce the interference in channel estimation.
For embodiments in which content-based spreader 130 is located before null generator 110, spreader 130 spreads input data symbol sequence 101 and pilot symbols 106 using a particular code division multiple access (CDMA) long spreading code according to what content the input data symbol sequence is conveying. In other words, a different spreading code sequence is used for different content. Spreaded symbol sequences 102 and 107 are otherwise processed as described above.
Generally, M*N subcarriers are used to transmit pilot and data. Among the M*N subcarriers, N evenly spaced subcarriers are allocated for pilot, and N(M−1) subcarriers are allocated for data.
As in an HRPD/DO transmitter, the physical layer packets to be transmitted by transmitter 200 are encoded by a channel encoder, interleaved by an interleaver, modulated by a modulator, and spread by a spreader to produce an input data symbol sequence. This symbol sequence serves as input to symbol inserter 210, which is a type of null generator such as that depicted in
Null generator 300 allocates N evenly spaced subcarriers for pilots and N(M−1) subcarriers for data. Each block contains N symbols, and as depicted, null generator 300 generates N padding symbols. In detail, adder 310 linearly adds together symbols having the same position in their respective groups/blocks of input data symbol sequence 301. Normalizer 320 scales the result by a first normalization factor to produce padding symbols 321. Normalizer 330 scales padding symbols 321 by a second normalization factor to produce normalized padding symbols. Adder 340 linearly adds to each symbol from input data symbol sequence 301 a symbol having the same position in the normalized padding symbols as shown. Padding symbols 321 are appended as block 0 to the result of adder 340, creating output data symbol sequence 351. This is the output of null generator 300.
Generally, output data symbol sequence 351 has some noteworthy properties. First, the variance of each symbol of output data symbol sequence 351 is identical if each symbol of input data symbol sequence 301 is independent and has an identical variance. For example, if the 320 input data symbols have a normalized variance of 1, the corresponding 360 output symbols will have a variance of 8/9. This property guarantees that the peak-to-average power ratio of the transmitted signal will be relatively low. Second, (again the example of 360 output symbols is assumed) the output symbols satisfy:
Thus the frequency response of the output data signal has nulls on subcarriers n=0, 9, 18, . . . , and 351 (40 total points):
Returning to
In general, cyclic prefix remover 510 removes the cyclic prefix from a first receiver symbol sequence to produce a second receiver symbol sequence. A content-based demodulator (i.e., content-based modulation sequence 520 and despreader 530) then restores pilot and data signals in the second receiver symbol sequence to designated subcarriers in the frequency domain to produce a received symbol sequence. Frequency domain equalizer (FDE) 540 then recovers an equalized data symbol sequence from the received symbol sequence, which exhibits pilots at specific subcarriers in the frequency domain.
FDE 540 comprises channel estimator 542 that produces channel estimates from the known transmitted pilots and the received symbol sequence pilots, obtained from their specific subcarriers. FDE 540 also comprises equalizer 544 that generates the equalized data symbol sequence in the time domain using the received symbol sequence and the channel estimates. Depending on the embodiment, equalizer 544 may generate the equalized data symbol sequence by inversing a channel frequency response (zero forcing) or by minimizing the mean square of the equalization error (MMSE). Symbol detector 550 then modifies the equalized data symbol sequence in the time domain to create an output data symbol sequence. Finally, in accordance with an HRPD/DO receiver, this output data symbol sequence is further processed to obtain decoded data by a despreader, a demodulator, a deinterleaver, and a channel decoder.
A more detailed description of key receiver 500 components follows with respect to a receive configuration where N=40 and M=9 (i.e., having 320 data symbols and 40 pilot symbols/block). Given the transmitter of
where I40 is an identity matrix with dimension of 40,
E(DD*)=I320
After removing the cyclic prefix, the received signal through a fading channel can be presented as
where F is the normalized Fourier transform matrix, i.e., F*F=I. Ω=diag{ω0, . . . , Ω360} is a diagonal matrix, with the diagonal terms corresponding to the channel frequency response on each of the subcarriers. In the following, we assume the noise N0 is a white noise random process, and E(N0N0*)=σ02I.
For zero forcing embodiments, the zero forcing receiver is
{circumflex over (D)}=(T*T)−1T*R
Since
T=GdF*ΩFH
we have
T*T=Gd2H*F*Ω*ΩFH
The rows 1, 10, 19, . . . , and 352 of the matrix FH correspond to the frequency response on the 0, 9, . . . , and 351 subcarriers of the transmitted data sequence. Thus, we have
(FH)(i)=[0, . . . 0], i=0, 9, . . . 351
where (FH)(i) is the (i+1)-th row of the matrix FH. E denotes an elementary transform matrix which rearranges the rows of the matrix FH. Thus
Since E is an elementary transform matrix, it follows that ETE=I and
Thus
T*T=Gd2H*F*Ωd*ΩdFH=Gd2M*Ωd*ΩdM
With a direct calculation, it can be verified that H*H=M*M=I. Therefore
In sum, zero forcing receiver embodiments of the present invention may be directly based on a zero forcing frequency domain equalizer (ZF-FDE). Note that in a zero forcing equalizer, the equalized channel gains on sub channels 0, 9, . . . , and 351 do not affect the equalizer output, since the transmitted data signal is not allocated to the subchannels 0, 9, . . . , and 351 through the transform H at the transmitter. Thus, the optimized receiver should not collect information on the sub channels 0, 9, . . . , and 351 to avoid collecting unnecessary noise and interference. This frequency selecting operation is implemented through the transform H* at the receiver.
The derivation of the MMSE receiver follows the same line as the derivation of the zero forcing receiver above. The MMSE estimation of the transmitted signal is
In sum, MMSE receiver embodiments of the present invention may be directly based on the MMSE frequency domain equalizer (MMSE-FDE). As with the zero forcing receiver, the equalized channel gains on sub channels 0, 9, . . . , 351 do not affect the equalizer output.
Symbol detector 550, for either the zero forcing or MMSE embodiments, is a type of symbol detector such as that depicted in
Benefits, other advantages, and solutions to problems have been described above with regard to specific embodiments of the present invention. However, the benefits, advantages, solutions to problems, and any element(s) that may cause or result in such benefits, advantages, or solutions, or cause such benefits, advantages, or solutions to become more pronounced are not to be construed as a critical, required, or essential feature or element of any or all the claims. As used herein and in the appended claims, the term “comprises,” “comprising,” or any other variation thereof is intended to refer to a non-exclusive inclusion, such that a process, method, article of manufacture, or apparatus that comprises a list of elements does not include only those elements in the list, but may include other elements not expressly listed or inherent to such process, method, article of manufacture, or apparatus. The terms a or an, as used herein, are defined as one or more than one. The term plurality, as used herein, is defined as two or more than two. The term another, as used herein, is defined as at least a second or more. The terms including and/or having, as used herein, are defined as comprising (i.e., open language).
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