RU97104011A - MULTIPLE ACCESS CODING USING FOLDED SEQUENCES FOR MOBILE RADIO SYSTEMS - Google Patents

Claims (50)

1. A transmitter of a communication system for transmitting a sequence of information symbols, comprising means for expanding each information symbol with an appropriate extension sequence to form a sequence of extended symbols, the extension sequences being selected from a set of extension sequences that are mutually orthogonal or bi-orthogonal, means for scrambling each expansion symbol using a common scrambling mask to form sequentially ty of scrambled symbols, wherein the common scramble mask selected from a set of scramble masks having optimal or semi-optimal correlation properties, and means for transmitting the sequence of scrambled symbols over a communication channel.  2. The transmitter according to claim 1, characterized in that the sum modulo two of any two scrambling masks is a sequence that is substantially equally correlated in magnitude with each of the expansion sequences.  3. The transmitter according to claim 1, characterized in that the sum modulo two of any two scrambling masks is a sequence that is substantially equally correlated in magnitude with each expansion sequence in a subset of expansion sequences and has substantially zero correlation with other expansion sequences.  4. The transmitter according to claim 1, characterized in that the optimal correlation properties include the property that the sum modulo two of any two scrambling masks is a folded sequence.  5. The transmitter according to claim 1, characterized in that the semi-optimal correlation properties include the property that the sum modulo two of any two scrambling masks is a partially collapsed sequence.  6. The transmitter according to claim 1, characterized in that the extension sequences are permutations of Walsh-Hadamard codewords.  7. The transmitter according to claim 1, characterized in that said means for transmitting includes means for additionally scrambling scrambled symbols, for generating a sequence of additionally scrambled symbols, and means for transmitting additionally scrambled symbols over a communication channel.  8. The transmitter according to claim 1, characterized in that the expansion means is designed to expand each information symbol of a plurality of sequences of information symbols using an appropriate extension sequence to form a plurality of sequences of extended symbols, the scrambling means is intended to scramble each extended symbol in each sequence of extended symbols with using an appropriate common scrambling mask to form a plurality of sequences atelnostey scrambled symbols, wherein the transmitter further comprises means for combining the plurality of sequences of scrambled symbols to form a sequence of combined scrambled symbols, and transmitting means transmits the sequence of combined scrambled symbols over the communication channel.  9. The transmitter of claim 8, wherein the plurality of information symbol sequences correspond to all information signals transmitted in a cell of a cellular communication system.  10. The transmitter of claim 8, wherein the plurality of information symbol sequences correspond to a subset of all information signals transmitted in a cell of a cellular communication system.  11. The transmitter according to claim 1, characterized in that the expansion means and the scrambling means are combined into one means for expanding and scrambling each information symbol using an appropriate effective extension sequence to form a sequence of scrambled extended symbols, effective extension sequences are selected from a set of effective extension sequences while pairs of effective extension sequences are either mutually orthogonal or bi-orthogonal us or have optimal or semi-optimal correlation properties, and the transmitting means transmits the scrambled spread symbols over the communication channel.  12. The transmitter according to claim 11, characterized in that the expansion and scrambling means expand each information symbol of a plurality of information symbol sequences with an appropriate effective extension sequence to form a plurality of scrambled expansion symbol sequences, the transmitter further comprises means for combining a plurality of scrambled expansion symbols to form a sequence of combined scr sampled expansion symbols, and the transmission means provides a sequence of combined scrambled expansion symbols over the communication channel.  13. The transmitter according to claim 1, characterized in that the extension means expands each information symbol of a plurality of sequences of information symbols with an appropriate extension sequence to form a plurality of sequences of extended symbols, the transmitter further comprises means for combining a plurality of sequences of extended symbols to form a sequence of combined extended characters, a scrambler provides a scrambler vanie each combined spread symbol in the sequence of combined spread symbols with a common scramble mask to form a sequence of scrambled combined spread symbols, and the transmitting means transmits the sequence of scrambled combined spread symbols over the communication channel.  14. The transmitter according to claim 1, characterized in that it further comprises means for converting the sequence of information symbols into a sequence of blocks of binary digits, means for generating the first pseudo-random numbers, wherein each first pseudo-random number is associated with a corresponding block, and for generating a second pseudo-random number means for combining the first pseudorandom numbers with corresponding blocks to form a sequence of encrypted characters; and means for shifting the second pseudo-random number to form a scramble mask index, wherein the expansion means expands each encrypted character with an appropriate extension sequence to form a sequence of extended characters, the scrambling mask scrambles each extended character with a common scramble mask to form a sequence of scrambling characters , and the scrambling mask is selected based on the index ma ski scrambling.  15. The transmitter according to claim 14, characterized in that the second pseudo-random number depends on the multi-bit digital control signal and on the block corresponding to the extended symbol scrambled by the scramble mask selected on the basis of the scramble mask index formed by the offset of the second pseudorandom number.  16. The transmitter according to claim 14, characterized in that the combining means and the scrambling means are made in the form of adders modulo two.  17. The transmitter according to 14, characterized in that the sum modulo two of any two scrambling masks is a sequence essentially equal in magnitude to each of the expansion sequences.  18. The transmitter of claim 14, wherein the sum modulo two of any two scrambling masks is a sequence that is substantially equally correlated in magnitude with each expansion sequence in a subset of the expansion sequences and having substantially zero correlation with the remaining expansion sequences.  19. A receiver of a communication system for transmitting sequences of information symbols, comprising means for receiving a composite signal including a plurality of spectrally overlapping sequences of extended scrambled information symbols, means for descrambling a composite signal using a scrambling mask selected from a set of scrambling masks having optimal or semi-optimal correlation properties to form a sequence of descrambled symbols fishing, means for compressing a descrambled symbol sequence using extension sequences, including means for correlating at least one shift of each descrambled symbol with at least one of the extension sequences to generate at least one correlation value for each descrambled symbol, the sequences extensions are mutually orthogonal or bi-orthogonal, and means for processing correlation values for updating Arming at least one sequence of information symbols.  20. The receiver according to claim 19, characterized in that the processing means comprises a RAKE coherent adder for processing a multipath signal.  21. The receiver according to claim 19, characterized in that the processing means comprises an incoherent RAKE adder for processing a multipath signal.  22. The receiver according to claim 19, characterized in that the descrambling means is for generating a plurality of descrambled symbol sequences, wherein each descrambled symbol sequence corresponds to a corresponding sequence of information symbols, the compression means is for generating at least one correlation value from each descrambled symbol by correlation at least one shifted value of each descrambled symbol n with at least one corresponding extension sequence, and the processing means provides correlation value processing to detect a plurality of information symbol sequences.  23. The receiver according to claim 19, characterized in that the descrambling means and the compression means are combined into a single means for scrambling and compressing the composite signal using an effective expansion sequence selected from a set of effective expansion sequences to generate correlation values and a pair of effective extension sequences either have optimal or semi-optimal correlation properties, or are mutually orthogonal or bi-orthogonal.  24. The receiver according to item 23, wherein the descrambling and compression means is designed to descramble and compress the composite signal using at least one effective extension sequence selected from a set of effective extension sequences, to generate correlation values for multiple sequences of information symbols, each effective extension sequence corresponds to a corresponding sequence of information symbols, and pairs of effective sequences Extensions can either have optimal or semi-optimal correlation properties, or are mutually orthogonal or bi-orthogonal.  25. The receiver according to claim 19, wherein the composite signal includes multiple spectrally overlapping sequences of encrypted extended scrambled information symbols, the receiver further comprises means for generating a scramble mask address and for selecting, based on the scramble mask address, a scramble mask from the set scrambling masks having optimal or semi-optimal correlation properties, the descrambling means is intended for descrambling composite of the signal using the selected scrambling mask to form a sequence of descrambled symbols, the processing means is designed to process correlation values to detect at least one sequence of encrypted information symbols, and the receiver further comprises means for decrypting at least one sequence of encrypted information symbols detected by the processing means using a pseudo-random number associated with information symbols.  26. A method of transmitting a sequence of information symbols, comprising the following operations: expanding each information symbol using an appropriate extension sequence to generate a sequence of extended symbols, the extension sequences being selected from a set of extension sequences that are mutually orthogonal or bi-orthogonal, scrambling each extended symbol using a common scrambling mask to form a sequence of scrambling nnyh symbols, wherein the common scramble mask selected from a set of scramble masks having optimal or semi-optimal correlation properties, and transfer of the sequence of scrambled symbols over a communication channel.  27. The method according to p. 26, characterized in that the sum modulo two of any two scrambling masks is a sequence that is essentially equally correlated in magnitude with each of the expansion sequences.  28. The method according to p. 26, characterized in that the sum modulo two of any two scrambling masks is a sequence that is essentially equally correlated in size with each expansion sequence in a subset of expansion sequences and essentially has zero correlation with other expansion sequences.  29. The method according to p. 26, wherein the optimal properties include the property that the sum modulo two of any two scrambling masks is a folded sequence.  30. The method according to p. 26, characterized in that the semi-optimal correlation properties include the property that the sum modulo two of any two scrambling masks is a partially collapsed sequence.  31. The method according to p, characterized in that the extension sequence is obtained by permutation of the Walsh-Hadamard codewords.  32. The method according to p. 26, wherein the transmission operation includes the operation of additional scrambling scrambled characters to form a sequence of additional scrambled characters, and transmitting additional scrambled characters over the communication channel.  33. The method of claim 26, wherein each information symbol from the plurality of sequences of information symbols is expanded using an appropriate extension sequence to form a plurality of sequences of extended symbols, each extended symbol in each sequence of extended symbols is scrambled using a corresponding common scramble mask to form multiple sequences of scrambled characters, the method further comprising the operation of combining The number of sequences of scrambled symbols for forming a sequence of combined scrambled symbols, and a sequence of combined scrambled symbols are transmitted over the communication channel.  34. The method according to p, characterized in that the set of sequences of information symbols corresponds to all information signals transmitted to a cell in a cellular communication system.  35. The method according to p. 33, characterized in that the set of sequences of information symbols corresponds to a subset of all information signals transmitted to a cell in a cellular communication system.  36. The method according to p. 26, characterized in that the expansion operation and the scrambling operation are combined in the operation of expanding and scrambling each information symbol using the corresponding effective extension sequence to form a sequence of scrambled extended symbols, effective expansion sequences are selected from a set of effective expansion sequences wherein pairs of effective extension sequences are either mutually orthogonal or bi-orthogonal, either have optimal or semi-optimal correlation properties, and scrambled extended symbols are transmitted over the communication channel.  37. The method according to clause 36, wherein the expansion and scrambling operations expand each information symbol from a plurality of information symbol sequences using an appropriate effective expansion sequence to generate a plurality of scrambled extended pulse sequences, the method further comprising combining sets of sequences of scrambled extended pulses to form a sequence of union of scrambled spread pulse, and the sequence of combined scrambled spread symbols is transmitted over the communication channel.  38. The method according to p. 26, characterized in that in the expansion operation, each information symbol is expanded from a plurality of information symbol sequences using an appropriate expansion sequence to form a plurality of extended pulse sequences, the method further comprising combining a plurality of extended symbol sequences to form sequences of combined extended pulses, each combined extended symbol in the last sequence of scrambled combined spread symbols with a common scramble mask to form a sequence of scrambled combined spread symbols and the sequence of scrambled combined spread symbols is transmitted over the communication channel.  39. The method according to p. 26, characterized in that it further comprises the operation of converting a sequence of information symbols into a sequence of blocks of binary digits, generating the first pseudo-random numbers and the second pseudo-random number, each first pseudo-random number associated with the corresponding block, combining the first pseudo-random numbers blocks for generating a sequence of encrypted characters, and shifting the second pseudo-random number to form the index of the scramble mask ation, each encrypted symbol spread with a respective spreading sequence to form a sequence of spreading symbols, each symbol scrambled is scrambled with a common scramble mask to form a sequence of scrambled symbols, and scrambling mask is selected based on the scramble mask index.  40. The method according to § 39, wherein the second pseudo-random number depends on the multi-bit digital control signal and on the block corresponding to the extended symbol scrambled by the scramble mask selected on the basis of the scramble mask index formed by the offset of the second pseudo-random number.  41. The method according to § 39, wherein the combining operation and the scrambling operation is carried out in the form of a summation modulo two.  42. The method according to § 39, wherein the sum modulo two of any two scrambling masks is a sequence that is essentially equally correlated in magnitude with each of the expansion sequences.  43. The method according to § 39, wherein the sum modulo two of any two scrambling masks is a sequence that is substantially equally correlated in magnitude with each expansion sequence from a subset of expansion sequences and has substantially zero correlation with other expansion sequences.  44. A method for detecting information symbols, comprising the following operations: receiving a composite signal containing multiple spectrally overlapping sequences of extended scrambled information symbols, descrambling the composite signal with a scramble mask selected from a set of scramble masks having optimal or semi-optimal correlation properties to form a descrambled sequence characters, compression of descrambled characters using expansion sequences, including correlating at least one biased value of each descrambled symbol with at least one extension sequence to generate at least one correlation value for each descrambled symbol, wherein the extension sequences are mutually orthogonal or bi-orthogonal, and processing the correlation values for detecting at least one sequence of information symbols.  45. The method according to item 44, wherein the processing operation includes coherent combining according to the RAKE method of processing multipath signals.  46. The method according to item 44, wherein the processing operation includes incoherent combining according to the RAKE method of processing multipath signals.  47. The method of claim 44, wherein the descrambling operation generates a plurality of descrambled symbol sequences, each descrambling symbol sequence corresponding to a corresponding sequence of information symbols, and at least one correlation value is generated from each descrambled symbol by performing correlation at least one offset value of each descrambled symbol of at least m D one respective spreading sequence, and the correlation values are processed to detect the plurality of sequences of information symbols.  48. The method according to item 44, wherein the descrambling operation and the compression operation are combined into a single descrambling and compression operation of the composite signal using an effective expansion sequence selected from a set of effective expansion sequences to generate correlation values and a pair of effective sequences extensions either have optimal or semi-optimal correlation properties, or are mutually orthogonal or bi-orthogonal.  49. The method of claim 48, wherein the descrambling and compressing operations descramble and compress the composite signal using at least one effective expansion sequence selected from a set of effective expansion sequences to generate correlation values for a plurality of information symbol sequences, each selected effective extension symbol sequence corresponds to a corresponding extension symbol sequence, and pairs are effective spreading sequences either have optimal or semi-optimal correlation properties or are mutually orthogonal or bi-orthogonal.  50. The method according to item 44, wherein the composite signal includes many spectrally overlapping sequences of encrypted, extended, scrambled information symbols, the method further includes the steps of generating the address of the scrambling mask, and selecting, based on the address of the scrambling mask, a scrambling mask from set of scramble masks having optimal or semi-optimal correlation properties, the composite signal is descrambled using the selected scramble mask for of the sequence of descrambled symbols, the correlation values are processed to detect at least one sequence of encrypted information symbols, the method further comprising decrypting at least one detected sequence of encrypted information symbols using a pseudorandom number associated with the corresponding information symbols.