The present invention relates generally to the initial synchronization methods and more specifically to an improvement in the steps of the initial synchronization methods.
Although the method will be described for mobile WiMAX systems (IEEE 802.16e, WiBro) as an example, it is applicable to other communication systems and protocols. The initial synchronization methods generally include a frame boundary search, fractional/integer frequency offset estimation, and segment/cell ID searches.
The present method of initial synchronization of a communication signal includes the steps of symbol boundary search, fractional frequency offset estimation, fractional frequency offset compensation, frame boundary search, integer frequency offset estimation, integer frequency offset compensation, preamble segment ID search and preamble cell ID search.
The symbol boundary search includes estimating the boundary of a present data symbol by a correlation index for the present data symbol and the correlation index for the next data symbol. The combined correlation index is
where i denotes the correlation index, G the cyclic prefix length, y the observed time domain samples, and NFFT the size of the symbol. The combined correlation index i is calculated iteratively as follows:
The frame boundary search includes identifying the preamble symbol in the symbols found in the symbol boundary search to determine the frame boundary. Identifying the preamble symbol includes grouping the subcarriers into K subgroups of N consecutive subcarriers, where K is the number of subcarriers that define a specific segment group of subcarriers; collecting the distributed energies on subcarriers; and making a decision if the current symbol is preamble based on a threshold that is estimated by stochastic count process model.
The integer frequency offset is estimated from the pilot subcarriers of the frame control header of the frame without decoding the down load MAP.
The preamble segment ID search is based on:
where PremableCarrierSetnk=n+N·k, the group index of N groups n=0, 1, 2 . . . N−1, and the subcarrier index of a K length PN sequence k={0, 1, 2 . . . K−1}.
The preamble cell ID search includes estimating the symbol timing offset {circumflex over (ε)}|nr by:
where the group index of N groups n=0, 1, 2 . . . N−1, cell ID of R cell IDs in a segment group rε{0, 1, . . . , R−1}, mk and mk+1 are two neighboring subcarrier positions, the subcarrier index of a K length PN sequence k={0, 1, 2 . . . K−1} and pilotmr,n represents the modulated PN sample for the preamble.
The preamble cell ID is estimated by:
where
mε{non-zero subcarriers}, NFTT is the symbol size.
These and other aspects of the present invention will become apparent from the following detailed description of the invention, when considered in conjunction with accompanying drawings.
The method of initial synchronization of a communication signal is illustrated in
If a preamble has been found at Step 16, the integer frequency offset is estimated using the frame control head or FCH at Step 20. Next the integer frequency offset compensation for the preamble is performed at Step 22. Finally, a segment/cell ID search is performed on the preamble at Step 24. This is the end of the synchronization process.
Each frame in the downlink transmission begins with a preamble followed by down load DL and up load UL transmission periods as shown in
Although the initial synchronization algorithms is described for the WiBro system as an example, all these algorithms can be applied to 802.16e WMAN-OFDMA as well.
The first symbol of DL burst in every frame is the preamble. In the preamble, there are N or in this example three different segment groups, and each group has different PN sequences. The indices of these groups can be defined as
PremableCarrierSetnk=n+N·k, (1)
where the group index of N groups n=0, 1, 2 . . . N−1, and the subcarrier index of a K length PN sequence k={0, 1, 2 . . . K−1} which will be mapped through.
For example, in 1024 FFT mode, there are 114 different PN sequences (see Table 1), and out of them each 38 sequences are defined for a specific subcarrier group. Within a subcarrier group, each of the 38 sequences indicates a specific cell. There are 284 subcarriers defined for a specific segment group. The index variable n and k in equation (1) determines the segment of the cell and subcarrier index of the preamble subcarriers, respectively.
The PN sequence to be assigned onto the preamble carrier set is modulated as
where wk denotes the PN sequence in Table 1. Finally, the modulated preamble sequence is assigned to preamble subcarriers according to the index defined in equation (1).
In addition to modulated preamble subcarriers, for 1024 FFT mode, there will be 86 guard band subcarriers on the left and right.
The frame boundary search consists of two steps; the symbol boundary search and preamble identification. Once stream of filtered samples are available, the symbol boundary search block compute correlations between one sample to other sample with distance of symbol size. This correlation utilizes the repeating characteristic of the guard period (CP: Cyclic Prefix). Let NFFT and G be the OFDMA symbol size and the CP size. The correlation window size is set to NFFT+G and within the window, a position of the correlated samples which provides the maximum correlator outputs is regarded as the symbol boundary. As discussed below, the frame boundary search scheme based on the symbol boundary search result.
The symbol boundary search relies on the characteristic of the guard period repetition in OFDM symbol. In this case, the ML estimate of the Symbol boundary is well known and is given by:
where i, G, y, and NFFT denote the correlation index, the cyclic prefix length, the observed time domain samples, and the number of the OFDM symbol subcarriers, respectively. The correlation of the repeating pattern of guard period for the next data symbol and add this additional correlation result to equation (3). This is the double correlator shown in
The estimation based on the double correlator can be shown as
Simply speaking, it is doubling the amount of statistics to provide better ML estimation results. The correlation in equation (4) can be calculated in iterative manner like below:
The number of computations in equation (4) does not require twice the number of computations than in equation (3). To explain the computational complexity for equation (4), let Stn be the correlator outputs through sample n and n+NFFT within a correlation window t, where n=0, 1, . . . , NFFT+G−1 and t=0, 1, 2, 3, . . . . Also, let St={Stn}n=0N
That is, the terms (yi+Gy*i+G+N
The difference in the slot boundary estimation performance between the method in equation (3) and equation (4) is significant. Following Table 2 shows the variances for the double and single correlator for the case of SNRs; 3 dB, 6 dB, and 9 dB. The number of trials were 10,000 per each SNR case.
The results clearly show that the variances of the symbol boundary estimator from double correlator are about two times smaller than one from single correlator.
In the following table 3, another measurement is presented in which the performances of double and single correlator can be compared. The metric is defined as
In Table 3, this metric is computed 10,000 times for SNR of 3 dB, 6 dB, and 9 dB.
Once the symbol boundary is estimated, the frame boundary has to be determined. In the system, since the first symbol in the frame is the preamble, searching for the frame boundary is the same as identifying the preamble symbol out of the symbols whose boundary has been found.
Without loss of generality, the search procedure based on the WiBro system (1024 FFT mode) will be explained. In the WiBro system, after disregarding guard bands, a preamble is composed of 852 subcarriers (284 non-zero subcarriers+568 zero subcarriers). There are 284 subcarriers defined for a specific segment group, j,j=0, 1, 2. Let us define a subgroup which includes 3 consecutive subcarriers. There will be 284 subgroups and within each subgroup, the index j,j=0, 1, 2, represents corresponding segment ID. The approach for identifying preamble is based on a count process, in which the energies per each subcarrier are computed and the computed energies of three consecutive subcarriers are grouped as three vectors, say (e0k,e1k,e2k), k=0, . . . , 283, as discussed above. Within each group, a subcarrier position, j,j=0, 1, 2, corresponds to the maximum energy in the group are searched and counted.
For clarification purpose, this procedure is explained in the following example. Suppose the sequence of subcarrier energies for the FFTed and guard band removed preamble symbol is (1.0, 3.6, 0.9, 1.2, 3.3, 0.7, . . . , 2.1, 1.3, 0.7, 1.1, 3.3, 0.7). First, the sequence of subcarrier energies are grouped as three vectors in consecutive manner and let {tilde over (j)}k denote the position of subcarrier which provide maximum energy in group k. The following is the count process
At k=0: (e00,e10,e20)=(1.0,3.6,0.9),∴{tilde over (j)}0=2,
At k=1: (e01,e11,e21)=(1.2,3.3,0.7),∴{tilde over (j)}1=2,
At k=100: (e0100,e1100,e2100)=(2.1,1.3,0.7),∴{tilde over (j)}100=1,
At k=283: (e0283,e1283,e2283)=(1.1,3.3,0.7),∴{tilde over (j)}283=2,
After counting {tilde over (j)}k, a dominant j,j=0, 1, 2, in the groups is determined from the number of its occurrences. The number of occurrences for {tilde over (j)}k ε {0, 1, 2} can be interpreted as the weight of its significance, and the normalized version of these weights can be used as the probabilities of j,j=0, 1, 2, being a dominating subcarrier position. These probabilities can be well modeled by a conjugate prior distribution to multinomial distribution, Dirichlet distribution described in J. M. Bernardo and A. F. M. Smith, “Bayesian Theory”, Wiley 1994.
A continuous random vector x=(x1, x2, . . . , xk) has a Dirichlet distribution of dimension k, with parameters α=(a1, a2, . . . , ak+1) (αi>0, i=1, . . . , k=1) if its probability density Dk(x|α), 0<xi<1 and x1+x2+ . . . +xk<1, is
where c is the normalization constant and is defined by
The mean vector are given by
Let Pj, j=0, 1, 2, be the probability of j,j=0, 1, 2, being dominant in groups, and let Nj, j=0, 1, 2, be the counted numbers which says how many times j being dominant in 284 groups. Then, the Dirchlet distribution of Pj, j=0, 1, 2, can be expressed by
The mean of the distribution is used for the probability estimation. That is,
The estimated probability {circumflex over (P)}j, j=0, 1, 2, is used as the threshold for determining the preamble. Following Table 4 shows the estimated probability of j,j=0, 1, 2, for SNR of 0 dB, 3 dB, and 6 dB when the true segment ID is 1. The number of trials were 10,000 for each SNR case.
The results in the table above shows us that even in hostile environment (SNR=0 dB case), the estimated probability of dominating subcarrier position is as clear as 0.96.
The probability can be used as the threshold for preamble decision. For example, the probability 0.96 can be interpreted as like one subcarrier position occurred in about 272 times in SNR 0 dB. Thus, in SNR 0 dB environment, if the number of occurrences of a subcarrier position is over 272 times, the current symbol is the preamble.
The frequency offset is estimated after symbol synchronization. In the offset, there are integer parts and fractional parts, and both have to be estimated. Let ε, εf, and εl denote frequency offset, integer frequency offset, and fractional frequency offset, respectively.
The relationship among frequency offset, the integer frequency offset, and fractional frequency offset can be given as
ε=(εl×subcarrier spacing+εf)Hz. (7)
ML estimation of the fractional frequency offset based on correlator outputs have been well known [2]. The fractional frequency offset εf can be estimated from
where C(î) is the maximum correlation calculated in (5), D denotes the delay, and Ts the sample time.
The pilot subcarriers in FCH (Frame Control Header) is used to estimate the integer frequency offset. Since the subchannelization scheme used for FCH is always PUSC, we do not need to decode DL MAP to check the subchannelization mode of FCH. Thus, upon reception of the symbol following the preamble, the exact location of pilot subcarriers is after taking FFT of the symbol. In the WiBro system, the power of each pilot tone should be boosted 2.5 dB higher than the average power level of data tones. With this constraint, the integer frequency offset which can cause cyclic shift of subcarrier position in a symbol is estimated.
The segment ID and cell ID search are performed after preamble identification. The post-FFT processing for both segment ID and the cell ID search are used. As shown in
Let yFFT be the FFTed frequency samples of the preamble after removing guard subcarriers. The segment ID can be then searched based on the following criterion (See equation (1) for the description of index variables):
After the segment ID is determined, the number of candidates for the true preamble sequence is reduced to one third of the number. With regard to each candidate sequence, the symbol timing offset is estimated from the possible frame boundary estimation error. Symbol timing offset can be estimated by averaging the phase differences among neighbor frequency samples:
where {circumflex over (ε)}|nr denotes the symbol timing error estimate based on assumption that the preamble is member of a segment group n, n=0, 1, 2, and cell ID, rε{0, 1, . . . , R−1}, R denotes the number of cell IDs in a segment group. The mk and mk+1, k=0, 1, . . . , K−1 (see equation (1) for the description of K), are two neighboring subcarrier positions, and pilotmr,n represents the modulated PN sample for the preamble. See K. Nikitopoulos and A. Polydoros, “Post-FFT Fine Frame Synchronization for OFDM system” in VTC 1997.
The average operation in equation (9) can be replaced by simple summation. Also since the phase difference is only of interest, calculation can be further simplified as:
For each r, the symbol timing error can be compensated (or corrected) by
where mε {non-zero subcarriers}, r={0, 1, . . . , R−1}.
The cell ID is estimated by choosing the maximum output of the dot products (cross-correlating equation (7) and r modulated pilot patterns with lag zero). That is,
Although the present invention has been described and illustrated in detail, it is to be clearly understood that this is done by way of illustration and example only and is not to be taken by way of limitation. The scope of the present invention is to be limited only by the terms of the appended claims.
Number | Name | Date | Kind |
---|---|---|---|
6618452 | Huber et al. | Sep 2003 | B1 |
6690680 | Marchok et al. | Feb 2004 | B1 |
6937586 | Asokan | Aug 2005 | B2 |
20020021684 | Toshimitsu et al. | Feb 2002 | A1 |
20040081131 | Walton et al. | Apr 2004 | A1 |
20040082356 | Walton et al. | Apr 2004 | A1 |
20040114551 | Gavillero Martin et al. | Jun 2004 | A1 |
20040120410 | Priotti | Jun 2004 | A1 |
20050120097 | Walton et al. | Jun 2005 | A1 |
20050226418 | Lee et al. | Oct 2005 | A1 |
20050229230 | Santoru et al. | Oct 2005 | A1 |
20070280098 | Bhatt et al. | Dec 2007 | A1 |
Number | Date | Country |
---|---|---|
1 389 835 | Feb 2004 | EP |
Number | Date | Country | |
---|---|---|---|
20080075212 A1 | Mar 2008 | US |