1. Technical Field of the Invention
The present invention relates to wideband code division multiple access (WCDMA) receivers and, in particular, to the initial acquisition of synchronization code group and frame alignment data by a UMTS-FDD receiver.
2. Description of Related Art
The cell search procedure for wideband CDMA receivers in general, and UMTS-FDD receivers in particular, to acquire the scrambling code group and frame synchronization of a cell is typically carried out in three steps: slot synchronization (step 1); frame synchronization and code-group identification (step 2); and scrambling code identification (step 3). In slot synchronization (step 1), the receiver uses the primary synchronization code (PSC) of the primary synchronization channel (P-SCH) to acquire slot synchronization to a given cell. This is typically accomplished with a single matched filter (or any similar device) matched to the primary synchronization code (which is common to all cells). The slot timing of the cell can then be obtained by detecting peaks in the matched filter output. Next, this slot timing is fed to the frame synchronization and code-group identification (step 2) process, the receiver uses the secondary synchronization codes (SSC) of the secondary synchronization channel (S-SCH) to find frame synchronization and identify the code group of the cell found in step 1. This is typically accomplished by correlating, over several slots, the received signal with all possible secondary synchronization code sequences and then identifying the maximum correlation value. Since the cyclic shifts of the sequences are unique, not only the code group, but also the frame synchronization, is determined by this correlation. Finally, scrambling-code identification (step 3) is achieved by determining the exact primary scrambling code used by the found cell. This primary scrambling code is typically identified through symbol-by-symbol correlation over the common pilot channel (CPICH) with all codes within the code group identified in the second step. After the primary scrambling code has been identified, the primary common control physical channel (CCPCH) can be detected, and the system- and cell-specific broadcast control channel (BCH) information can be read.
The primary synchronization code Cpsc is constructed as a so-called generalized hierarchical Golay sequence chosen to have good aperiodic auto correlation properties:
PSC=(1+j)·<a,a,a,−a,−a,a,−a,−a,a,a,a,−a,a,−a,a,a>
wherein: a=<a0,a1, . . . , a15>, and more specifically:
a=<1,1,1,1,1,1,−1,−1,1,−1,1,−1,1,−1,−1,1>
in the case of UMTS-FDD. The PSC is defined for the first 256 chips of 2560-chip long slot, and takes 0 values for the 2304 remaining chips of the slot. Thus, the PSC may be rewritten as:
PSC=(1+j)·<A0a,A1a, . . . ,A14a,A15a>
wherein: a=<a0,a1, . . . ,a15>, and more specifically:
a=<1,1,1,1,1,1,−1,−1,1,−1,1,−1,1,−1,−1,1>, and
A=<1,1,1,−1,−1,1,−1,−1,1,1,1,−1,1,−1,1,1>
in the case of UMTS-FDD.
With respect to the plurality of secondary synchronization codes (SSC), a first 256-chip long code z is defined as:
z=<b,b,b,−b,b,b,−b,−b,b,−b,b,−b,−b,−b,−b,−b>
wherein: b[0-7]=a[0-7], i.e., the first eight chips of sequence b are the same as the first eight chips of sequence a; and
wherein: b=<b0b1, . . . ,b15>, and more specifically:
b=<1,1,1,1,1,1,−1,−1,−1,1,−1,1,−1,1,1,−1>, and
B=<1,1,1,−1,1,1,−1,−1,1,−1,1,−1,−1,−1,−1,−1>
in the case of UMTS-FDD.
The sixteen secondary synchronization code sequences Cssc are then constructed from a position wise multiplication of a Hadamard sequence and the code sequence z. The Hadamard sequences are obtained as the rows m in a matrix H8 constructed recursively by:
The rows m=16k of the matrix H8 possess the property that their elements are equal within a group of sixteen consecutive values, where the first group starts with the first element of a row. In other words, the i-th element of row m takes on a value hm,1 such that:
hm,1=hm,16n (2)
where n is the integer division of i by sixteen:
i=16n+r, 0≦r≦15 (3)
For the sake of simplicity, denote h′k,n such that:
hm,1=hm,16n=h16k,16n=h′k,n (4)
with n specified as set forth above in Equation (3), and n corresponding to the index of a group of sixteen consecutive chips within the 256-chip long sequence. Thus, the k-th secondary synchronization code sequence is:
which can be reformatted as:
SSCk=(1+j)·<h′k,0B0b,h′k,1B1b, . . . ,h′k,14B14b,h′k,15B15b>.
The frame synchronization and code-group identification (step 2) process for UMTS-FDD (WCDMA) cell search amounts to determining which of the k secondary synchronization code SSCk sequences is transmitted every slot (where it is assumed from completion of step 1 that the slot beginning time t0 is already known). This is equivalent to finding the row k of the Hadamard matrix H8 that is used for the given time slot. In accordance with well known prior art techniques, the row k is typically identified by correlating the complex-valued input signal s(t) by every possible secondary synchronization code SSCk to obtain sixteen estimates as follows:
to generate secondary synchronization energies. In the foregoing Equation (5), the signal s(t) is correlated over 256 samples, and the correlation by all sixteen possible hk rows is known as a reverse Hadamard transform. The energy of each of the sixteen correlations is then calculated by the searcher and used in the step 2 frame synchronization and code-group identification processing in a manner well known to those skilled in the art.
In a prior art implementation, the inner sum of the correlation defined by Equation (5) above is accomplished using a dedicated hardware device and the outer sum is taken care of by a complementary software process. That inner sum comprises N=16 separate inner sum (IS) calculations as follows:
wherein: 0≦n<N=16,
with the sixteen consecutive inner sums being used to perform the reverse Hadamard transform, and each and every one of them being used in any secondary synchronization code SSCk processing to produce correlations as follows:
The entire step 2 process may last over many slots, and in fact may take more than a frame to complete.
Notwithstanding the use of combined dedicated hardware device and software process for performing the step 2 frame synchronization and code-group identification process, it would be advantageous if the number of slots are required for step 2 completion were reduced thus producing enhanced receiver performance. The present invention addresses the foregoing need with a method and associated apparatus that outperforms conventional step 2 processes and allows for code group and frame alignment acquisition to occur at Eb/No levels lower (i.e., under more adverse conditions) than possible with prior art solutions.
Code group acquisition is accomplished by the present invention by correlating an input signal at a known time slot location against a synchronization code to acquire code group and frame synchronization information. The synchronization code used for this correlation is a combination of the primary synchronization code (PSC) and the secondary synchronization code (SSC). Use of such a combined code for step 2 demodulation of the input signal, instead of just the secondary synchronization code alone, provides for improved performance.
In accordance with one embodiment of the invention, a complete synchronization channel correlator is used for step 2 demodulation of an input signal to recover code group and frame alignment data. The complete synchronization channel correlator receives the input signal at a known time slot location. The input signal is then correlated against a synchronization code for the complete synchronization channel correlator to acquire code group and frame synchronization data. The synchronization code used by the correlator is a combination of the primary synchronization code (PSC) and the secondary synchronization code (SSC).
The complete synchronization channel correlator may be implemented within a synchronization device of a receiver. The demodulator may include a primary synchronization channel correlator that is used to correlate the input signal against the primary synchronization code to recover slot timing information and thus identify the known time slot location.
The synchronization device may be implemented within an integrated circuit chip.
A more complete understanding of the method and apparatus of the present invention may be acquired by reference to the following Detailed Description when taken in conjunction with the accompanying Drawings wherein:
The primary synchronization code and one secondary synchronization code are transmitted at the same time during the first 256 chips of each slot. It is common, and in fact required by the UMTS-FDD standard, for the synchronization codes to be broadcast with equal power. If the broadcast power is the same, the resulting complete k-th synchronization code (SCk) (i.e., the code for a complete synchronization channel (SCH) correlator as opposed to separate codes for primary and secondary synchronization channel correlators) is thus:
SCk=(1+j)·<A0a+h′k,0B0b,A1a+h′k,1B1b, . . . ,A14a+h′k,14B14b,A15a+h′k,15B15b>
where An,h′k,n and Bn can take on only values of +1 or −1. Given the relationship:
b[0-7]=a[0-7] and b[8-15]=−a[8-15]
as defined above, and considering the equal broadcast power between the primary and secondary synchronization codes, a group of sixteen consecutive chips for the secondary synchronization code SSCk can take on only one of the following four 16-chip long sequences at a time:
a+b=<2a0,2a1, . . . ,2a7,0,0, . . . ,0> (8a)
a−b=<0,0, . . . ,0,2a8,2a9, . . . ,2a15> (8b)
−a+b=−<0,0, . . . ,0,2a8,2a9, . . . ,2a15> (8c)
−a−b=−<2a0,2a1, . . ,2a7,0,0, . . . ,0> (8d)
Equations (8a-8d) thus show that half the samples of the 256-chip long synchronization channel (broadcasting the complete k-th synchronization code (SCk) described above) do not convey any bits (i.e., they equal “0”) concerning the secondary synchronization code (SSC) since the primary and secondary synchronization channels cancel each other due to their equal broadcast power. It will, of course, be understood that they still carry information since the absence of ak or −ak in the sequences of Equations (8a-8d) makes up a piece of information. The present invention takes advantage of the foregoing characteristics of Equations (8a-8d), and the complete synchronization channel (SCH), to improve step 2 processing by utilizing the zero instants to avoid correlating with noise only. This is accomplished by correlating the input signal s(t) with the complete k-th synchronization code (SCk) (which additionally include the primary synchronization code), instead of just the k-th secondary synchronization code (SSCk). Given that for step 2 processing the timing of the primary synchronization code (PSC) is assumed to be known, correlating the input signal s(t) by either the k-th secondary synchronization code (SSCk) or complete k-th synchronization code (SCk) (PSC+SSCk), will generate the same amount of information. However, if the complete k-th synchronization code (SCk) (PSC+SSCk) is used for the correlation, an improvement in signal-to-noise ratio over conventional SSCk processing alone is experienced.
The complete k-th synchronization code (SCk) (PSC+SSCk) correlation may accordingly be estimated as:
to produce complete synchronization channel correlation. Now, recalling the discussion above concerning the SSC and the sequence z, Equation (9) may be rewritten as follows:
In Equation (10), it will be recognized that one-half the terms are zero since for any given value of n:
either An+h′k,nBn=±2 and An−h′k,nBn=0 (11a)
or An+h′k,nBn=0 and An−h′k,nBn=±2 (11b)
In comparison to the prior art Equations (5) and (7) discussed elsewhere herein, the correlation performed by Equation (10) for one particular k requires the use of only 128 s(t) samples as opposed to the 256 samples required when correlating the SSC alone. In this regard, it will be recognized that these 128 samples span over 256 chips, in general, and that all 256 chips are needed to perform the correlations for all values of k. It is further recognized that the correlation operation performed in accordance with the present invention provides improved performance with lower Eb/No levels. The sixteen complete synchronization channel correlations of the synchronization code (SCk) that are calculated in accordance with the process of the present invention may be used (without modification or adjustment) in place of the sixteen secondary synchronization code energy values (one per k) of the prior art process for step 2 frame synchronization and code-group identification in a manner well known to those skilled in the art.
To implement the processing operation of the present invention, it is noted that two different inner sums (low and high) may be defined for each set of sixteen consecutive chips as follows:
It is noted that the total inner sum (ISn) is equal to:
ISn=IShi,n−ISlo,n (13)
in the same manner as in Equation (6) of the prior art step implementation. Thus, any device designed to compute the high and low inner sums in accordance with Equations (12-13) may also be used to implement the prior art Equation (6) inner sum calculation (thus providing backward compatibility).
Depending on the particular secondary synchronization code SSCk sequence under investigation, and considering the actual sixteen chip group within the 256-chip long SSCk, only either IShi,n or ISlo,n is considered at one time since the other inner sum will produce only noise that is of no importance to the step 2 process. More specifically, it is recognized that some SSCk calculations make use of IShi,n for a given index of n, while others make use of ISlo,n.
The low and high inner sums are used for the synchronization code (SCk) calculation of Equation (10). If you now define:
then, the prior synchronization code (SCk) calculation of Equation (10) may be rewritten as follows:
and simplified using Equation (12) as:
It will be noted and remembered, from the discussion above, that for any given value of n, either Equation (14a) or Equation (14b) will be zero. Thus, the execution of Equation (16) will require a total of 128 values of the input signal s(t), instead of the 256 values required for the execution of Equation (7) in accordance with the prior art to produce the sixteen complete synchronization channel correlations.
Reference is now made to
In step 12, the input signal (having know time slot locations and an unknown frame alignment) undergoes a complete synchronization channel (SCH) correlation for step 2 code group and frame alignment acquisition (that is distinct as discussed herein from the step 1 process performed for PSC correlation 10). This operation in step 12 is to be contrasted with the prior art process of performing only a secondary synchronization channel (SSC) correlation (following completion of step 1 correlation in step 12). This complete synchronization channel (SCH) correlation demodulates that received input signal using a code comprising a combination of a primary synchronization code (PSC) and a k-th secondary synchronization code (SSCk). Notably, the step 12 process for complete synchronization code correlation utilizes the time slot(s) and boundary data produced from the step 1 operation.
The primary synchronization code (PSC) is a pattern array as generally described above. In a preferred embodiment of the present invention relating to a UMTS-FDD implementation, the pattern array for the PSC is 256-chips long and equals Aa. The k-th secondary synchronization code (SSCk) is a pattern array as generally described above. In a preferred embodiment of the present invention relating to a UMTS-FDD implementation, the pattern array for the k-th SSCk is 256-chips long and equals h′kBb. More specifically, for the correlation processing performed in the complete synchronization channel (SCH), the 256-chip long pattern array for the SSC is multiplied by a row k of the Hadamard matrix and thus equals h′kBb wherein h′k is a sequence made from elements taken from the Hadamard matrix, and more specifically elements taken from a common, single, row of that matrix.
The complete synchronization channel correlation of the input signal s(t) is made against all k sequences of the complete synchronization code (Sck=PSC+SSCk) at each time slot, thus using both the PSC pattern array and the k-th SSC pattern array, to acquire code group related information by performing a reverse Hadamard transformation. Notably, and importantly, this correlation against the complete synchronization code (SC) is made in step 12 instead of performing a correlation against the k secondary synchronization codes alone, as taught by the prior art step 2 process. Given the complex nature of the input signal s(t), the correlation process is performed against both in-phase (I) and quadrature phase (Q) components.
The code group related information acquired from the processing performed in step 12 comprises a plurality of correlation values. The magnitude of these correlation values is considered in a maximum energy finding operation performed in step 14 to identify code group and frame synchronization. Importantly, the use of the primary synchronization code (PSC) in conjunction with the k secondary synchronization codes (SSCk) for the complete synchronization channel (SCH) correlation of step 12 results in the generation of the same amount of information but with a significantly higher signal-to-noise ratio.
Since the cyclic shifts in the secondary synchronization code sequences are unique, once a match between one sequence and the input signal is found (using the maximum energy finding operation discussed above), the particular code group as well as the frame synchronization may be determined in step 14. This then completes the frame synchronization and code-group identification (step 2) process.
The step 12 process generally described in
a=<1,1,1,1,1,1,−1,−1,1,−1,1,−1,1,−1,−1,1> for UMTS-FDD.
Now, the inner sum arrays ISI,hi[], ISI,lo[], ISQ,hi[] and ISQ,lo[] are initialized to zero as follows:
for (p=0; p<16; p++)
ISI,hi[]=ISI,lo[]=ISQ,hi[]=ISQ,lo[]=0;
Next, preprocessing to fill the inner sum arrays ISI,hi[], ISI,lo[], ISQ,hi[] and ISQ,lo[] in accordance with Equation (12) is performed as follows:
The foregoing process first tests whether the current time index modulo the length of the slot equals the actual start time for the slot. The effect of this test is to divide the first 256 chips of each time slot into N=16 groups of sixteen consecutive values where the groups are tracked by the index n and the values in each group are tracked by the index p as set forth in the (t0+16*n+p) index for the I and Q samples of the input signal s(t). It is these groups of consecutive values against which the correlation operation is performed. As a part of the correlation, the inner sums must first be determined. The remainder of the process above makes those inner sum determinations. More specifically, and with reference to Equation (12) above, high and low inner sums (tracked by the index p), for both in-phase and quadrature phase components, are calculated. Notably, these inner sums are calculated using the a sequence component of the primary synchronization code as indicated by the a [p] portion of the calculation. The inner sum for a given index value of n is equal to an accumulation, over the nested incrementing index p, of the product (S*a) of the complex input signal sample (s(t)=I(t)+jQ(t)) at an index defined by (t0+16n+p) and the corresponding p-th value of the a portion of the PSC.
Next, a reverse Hadamard transform is performed. Before discussing the specifics of the reverse transform, however, some additional definitions are required:
Before starting the reverse Hadamard transformation, the synchronization code arrays SCI[] and SCQ[] are initialized to zero as follows:
for (k=0; k<16; k++)
SCI[k]=SCQ[k]=0
Next, the reverse Hadamard transformation is performed as follows:
The loop defined by the incrementing index k cycles the reverse Hadamard transformation through each possible Hadamard sequence. The nested loop defined by the incrementing index n cycles the process through each group of sixteen consecutive values (resulting from the division of the first 256 chips of each slot into groups). This, in essence computes Equation (16) using the properties of Equations (11a-11b) (or the set of properties of Equations (8a-8d), which are equivalent). It will be noted, however, that for ease of this code implementation, the coefficient “2” in Equations (11a-11b) is dropped and replaced by “1”.
The first if statement then tests whether both 1) the product of the n-th value in row k of the Hadamard matrix and the n-th value of the B pattern, and 2) the n-th value of the A pattern, are equal to one. This test implements the particular case recited in Equation (8a) above (or the Equation (11a) subcase=2). If so, then the k-th value of complete synchronization code SC correlation includes a positive accumulation of the n indexed, precomputed, high inner sum value.
The next if statement then tests whether 1) the product of the n-th value in row k of the Hadamard matrix and the n-th value of the B pattern is equal to minus one, and 2) the n-th value of the A pattern is equal to one. This test implements the particular case recited in Equation (8b) above (or the Equation (11b) subcase=2). If so, then the k-th value of complete synchronization code SC correlation includes a positive accumulation of the n indexed, precomputed, low inner sum value.
The next if statement then tests whether 1) the product of the n-th value in row k of the Hadamard matrix and the n-th value of the B pattern is equal to one, and 2) the n-th value of the A pattern is equal to minus one. This test implements the particular case recited in Equation (8c) above (or the Equation (11b) subcase=−2). If so, then the k-th value of complete synchronization code SC correlation includes a negative accumulation of the n indexed, precomputed, low inner sum value.
Finally, the last if statement tests whether both 1) the product of the n-th value in row k of the Hadamard matrix and the n-th value of the B pattern, and 2) the n-th value of the A pattern, are equal to minus one. This test implements the particular case recited in Equation (8d) above (or the Equation (11a) subcase=−2). If so, then the k-th value of complete synchronization code SC correlation includes a negative accumulation of the n indexed, precomputed, high inner sum value.
What will be noted from a review of the algorithm for the reverse Hadamard transformation is that only one of the if sections is satisfied and implemented for indexed value of n. This not only defines which of the high or low inner sum values is used, but also defines whether a positive or negative accumulation of the inner sum value toward the complete synchronization code (SC) correlation value is performed. It will also be noted that the algorithm processes the input signal s(t), through the precalculated inner sum values, for correlation against the combination of both the primary synchronization code (PSC) and the k-th secondary synchronization code (SSCk), instead of solely against the SSCk as set forth by the prior art step 2 process.
Reference is now made to
After each slot, an “energy” is computed for each of the sixty-four possible scrambling code groups. This energy is the sum of the secondary synchronization channel correlation energies E (SSCk)'s in the conventional prior art method or the sum of the complete synchronization channel correlation energies E(SCk)'s in the algorithm set forth above in accordance with the complete synchronization channel correlation solution of the present invention. These energies are then sorted in decreasing order, with the selected scrambling code group corresponding to the one of the energies having the highest value. Notably, for each of the 64 code groups, the 15 possible offsets of the boundary are studied. For example, and with reference to
With specific reference now to the graph of
Reference is now made to
In another, more optimal procedure, the processing for producing frame synchronization data and code-group identification data occurs as follows in accordance with a recognized comprehensive detection method. A code group is “coded” by a 15-long series of SSCk. Let us define these series as:
In SSC′ (j′,k), j′ is the slot index and k denoted a particular line of the Hadamard transform as defined by Equations (1) and (4). At this point, the processor calculates 64 cumulated energies. These energies are used as likelihoods relating to whether each code group candidate matches the actual transmitted group, assuming that the first slot when the step 2 procedure was activated was aligned with the first slot of a frame. In other words Slot j′=0 matches j=0 in the definition of pairs (i,j) above. The procedure then repeats calculating 64 cumulated energies, assuming Slot j′=1 matches j=0, j′=14 matches j=13 and cycling over to j′=0 matches j=14. The process is iterated for each of the 15 possible slot alignments. In the end, there exist a total of 15×64 cumulated energies of SSCk (or SCk) indexed by j′ for the 15 possible slot offsets and i for the 64 possible code groups. The maximum one of these 15×64=960 values is then selected. Its corresponding pair (j′,i) gives the code group (i) and the slot offset (j′) between the local timing and the base station timing. Of course, if there is no obvious maximum, the procedure can be deemed to have failed.
Now assume that the procedure has run for less than 15 slots. The same algorithm can already be applied, by setting the SSCk energies (or SCk) to zero for those slots that have not yet been received. On the contrary, assume that the procedure has run for more than 15 slots, the algorithm can still be used by continuing to accumulate new incoming energies. In the implementation of the present invention (comparison results shown on
With respect to a simplified detection method, the SSCk (or SCk) is selected which corresponds to the highest energy value after each slot. After p slots, a series of likely SSCk (or SCk) is built:
SSC(0), SSC(1), . . . , SSC(p)
This series is matched against all 64 possible series, each of them in their 15 shifted positions. At this point no energy value is retained. The best match (if unique) is then selected.
Turning now to
Each of the channel implementations 50/50′ may be included in a demodulator 80 for a UMTS-FDD (or WCDMA) receiver 82 (shown in both
The receiver, and more specifically, the demodulator for the receiver, may be implemented in hardware, software and/or a combination of both. More specifically, the receiver and/or demodulator may be implemented using integrated circuit techniques in a single integrated circuit or as a chip set.
Although the preferred embodiment assumes an equal transmission power of the PSC and SSC, it will be recognized that the technique of the present invention is equally useful in situations where the power levels are not equal. In such a situation, the algorithm discussed and implemented above can be adjusted through the use of appropriate weights on each channel to account for the difference in power levels. For example, the processing of the channels by the algorithm may be weighted in proportion to the respective power level of the PSC and SSC.
Although preferred embodiments of the method and apparatus of the present invention have been illustrated in the accompanying Drawings and described in the foregoing Detailed Description, it will be understood that the invention is not limited to the embodiments disclosed, but is capable of numerous rearrangements, modifications and substitutions without departing from the spirit of the invention as set forth and defined by the following claims.
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