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Techniques for detecting discontinuous transmission (DTX) are disclosed. In an example method, given a sequence of bits that is known by a wireless receiver to be included in transmission bursts targeted to the wireless receiver and given a series of received signal samples corresponding to an expec

Techniques for detecting discontinuous transmission (DTX) are disclosed. In an example method, given a sequence of bits that is known by a wireless receiver to be included in transmission bursts targeted to the wireless receiver and given a series of received signal samples corresponding to an expected transmission burst for the wireless receiver, the wireless receiver estimates a channel response and a location for the sequence within the series. The wireless receiver generates a plurality of bit estimates from the subset of received signal samples, based on the estimated channel response, compares the bit estimates to bits in the sequence of bits, and determines whether a valid burst for the wireless receiver is present, based on said comparing. The disclosed techniques are particularly suitable for use in detecting DTX in VAMOS scenarios.

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1. A method, in a first wireless receiver, for detecting discontinuous transmission (DTX), the method comprising: given a first sequence of bits that is known by the first wireless receiver to be included in transmission bursts targeted to the first wireless receiver and given a series of received s

1. A method, in a first wireless receiver, for detecting discontinuous transmission (DTX), the method comprising: given a first sequence of bits that is known by the first wireless receiver to be included in transmission bursts targeted to the first wireless receiver and given a series of received signal samples corresponding to an expected transmission burst for the first wireless receiver, estimating a channel response and a location for the first sequence within the series, the location for the first sequence indicating a subset of the received signal samples in the series;generating a plurality of bit estimates from the subset of received signal samples, based on the estimated channel response;comparing the bit estimates to bits in the first sequence of bits, wherein said comparing comprises comparing each bit estimate to a corresponding bit from the first sequence of bits and counting a number of matches between the bit estimates and corresponding bits in the first sequence of bits; anddetermining whether a valid burst for the first wireless receiver is present, based on said comparing. 2. The method of claim 1, wherein determining whether a burst for the first wireless receiver is present comprises concluding that a burst is present if the number of matches is greater than a predetermined threshold. 3. The method of claim 1, wherein generating the plurality of bit estimates from the subset of received signal samples comprises: demodulating only the subset of received signal samples, to obtain a series of demodulated soft bits; andobtaining the bit estimates for said comparing by converting the soft bits to hard bits. 4. The method of claim 3, further comprising discarding one or more soft bits at each end of the series of demodulated soft bits before converting the remaining soft bits to hard bits. 5. The method of claim 4, wherein the first sequence of bits is 26 bits in length, and wherein 16 soft bits are converted to 16 hard bits for comparing to corresponding bits in the first sequence. 6. A method, in a first wireless receiver, for detecting discontinuous transmission (DTX), the method comprising: given a first sequence of bits that is known by the first wireless receiver to be included in transmission bursts targeted to the first wireless receiver and given a series of received signal samples corresponding to an expected transmission burst for the first wireless receiver, estimating a channel response and a location for the first sequence within the series, the location for the first sequence indicating a subset of the received signal samples in the series;generating a plurality of bit estimates from the subset of received signal samples, based on the estimated channel response;comparing the bit estimates to bits in the first sequence of bits; anddetermining whether a valid burst for the first wireless receiver is present, based on said comparing; wherein generating the plurality of bit estimates from the subset of received signal samples comprises: copying the subset of received signal samples to a first position in the series of received signal samples and copying the subset of received signal samples to a second position in the series of received signal samples, wherein the first and second positions are before and after the location for the first sequence, respectively; anddemodulating the received signal samples in the first and second positions in the series, to obtain the bit estimates for comparing. 7. The method of claim 6, wherein the first and second positions correspond to information bit positions in a normal burst, as defined by GSM specifications. 8. The method of claim 6, wherein said demodulating the received samples in the first and second positions produces a first and second series of soft bits, wherein generating the plurality of bit estimates further comprises: discarding one or more soft bits at each end of the first and second series of demodulated soft bits; andobtaining the bit estimates for said comparing by converting the remaining soft bits to hard bits. 9. The method of claim 8, wherein the first sequence of bits is 26 bits in length, and wherein 16 soft bits from the first series and 16 soft bits from the second series are converted to hard bits for said comparing. 10. The method of claim 1, further comprising skipping channel decoding of one or more subsequent transmission bursts in response to determining that a burst is not present, based on said comparing. 11. A method, in a first wireless receiver, for detecting discontinuous transmission (DTX), the method comprising: given a first sequence of bits that is known by the first wireless receiver to be included in transmission bursts targeted to the first wireless receiver and given a series of received signal samples corresponding to an expected transmission burst for the first wireless receiver, estimating a channel response and a location for the first sequence within the series, the location for the first sequence indicating a subset of the received signal samples in the series;generating a plurality of bit estimates from the subset of received signal samples, based on the estimated channel response;comparing the bit estimates to bits in the first sequence of bits;determining whether a valid burst for the first wireless receiver is present, based on said comparing;given a second sequence of bits that is known by the first wireless receiver to be included in transmission bursts targeted to a second wireless receiver in the event that orthogonal transmission bursts are simultaneously transmitted to the first and second wireless receivers, estimating a second channel response and a location for the second sequence within the series of received signal samples, the location for the second sequence indicating a second subset of the received signal samples in the series;generating a plurality of second bit estimates from the second subset of received signal samples, based on the second estimated channel response;comparing the second bit estimates to bits in the second sequence of bits; anddetermining whether a burst for the second wireless receiver is present, based on said comparing of the second bit estimates to bits in the second sequence of bits. 12. The method of claim 11, further comprising, in response to determining that bursts for both the first and second wireless receivers are present, estimating a ratio of received powers for the bursts for the first and second wireless receivers. 13. The method of claim 11, further comprising, in response to determining that bursts for both the first and second wireless receivers are present: demodulating first information bits targeted to the second wireless receiver, from the received signal samples;generating reduced-interference signal samples by subtracting an estimated interference signal from the received signal samples, wherein the estimated interference signal is based on the demodulated first information bits; anddemodulating second information bits targeted to the first wireless receiver, from the reduced-interference signal samples. 14. A wireless receiver, comprising a receiver circuit adapted to receive transmission bursts in a wireless communications network and to produce received signal samples corresponding to said transmission bursts, anda processing circuit adapted to control the receiver circuit, to process the received signal samples, and, given a first sequence of bits that is known by the wireless receiver to be included in transmission bursts targeted to the wireless receiver and given a series of received signal samples corresponding to an expected transmission burst for the wireless receiver, to: estimate a channel response and a location for the first sequence within the series, the location for the first sequence indicating a subset of the received signal samples in the series;generate a plurality of bit estimates from the subset of received signal samples, based on the estimated channel response;compare the bit estimates to bits in the first sequence of bits by comparing each bit estimate to a corresponding bit from the first sequence of bits and counting a number of matches between the bit estimates and corresponding bits in the first sequence of bits; anddetermine whether a valid burst for the wireless receiver is present, based on said comparing. 15. The wireless receiver of claim 14, wherein the processing circuit is adapted to conclude that a burst is present if the number of matches is greater than a predetermined threshold. 16. The wireless receiver of claim 14, wherein the processing circuit is adapted to generate the plurality of bit estimates from the subset of received signal samples by: demodulating only the subset of received signal samples, to obtain a series of demodulated soft bits; andobtaining the bit estimates for said comparing by converting the soft bits to hard bits. 17. The wireless receiver of claim 16, wherein the processing circuit is further adapted to discard one or more soft bits at each end of the series of demodulated soft bits before converting the remaining soft bits to hard bits. 18. The wireless receiver of claim 17, wherein the first sequence of bits is 26 bits in length, and wherein the processing circuit is adapted to convert 16 soft bits to 16 hard bits for comparing to corresponding bits in the first sequence. 19. A wireless receiver, comprising a receiver circuit adapted to receive transmission bursts in a wireless communications network and to produce received signal samples corresponding to said transmission bursts, anda processing circuit adapted to control the receiver circuit, to process the received signal samples, and, given a first sequence of bits that is known by the wireless receiver to be included in transmission bursts targeted to the wireless receiver and given a series of received signal samples corresponding to an expected transmission burst for the wireless receiver, to: estimate a channel response and a location for the first sequence within the series, the location for the first sequence indicating a subset of the received signal samples in the series;generate a plurality of bit estimates from the subset of received signal samples, based on the estimated channel response;compare the bit estimates to bits in the first sequence of bits; anddetermine whether a valid burst for the wireless receiver is present, based on said comparing; wherein the processing circuit is adapted to generate the plurality of bit estimates from the subset of received signal samples by: copying the subset of received signal samples to a first position in the series of received signal samples and copying the subset of received signal samples to a second position in the series of received signal samples, wherein the first and second positions are before and after the location for the first sequence, respectively; anddemodulating the received signal samples in the first and second positions in the series, to obtain the bit estimates for comparing. 20. The wireless receiver of claim 19, wherein the first and second positions correspond to information bit positions in a normal burst, as defined by GSM specifications. 21. The wireless receiver of claim 19, wherein said demodulating the received samples in the first and second positions produces a first and second series of soft bits, and wherein the processing circuit is further adapted to generate the plurality of bit estimates by: discarding one or more soft bits at each end of the first and second series of demodulated soft bits; andobtaining the bit estimates for said comparing by converting the remaining soft bits to hard bits. 22. The wireless receiver of claim 21, wherein the first sequence of bits is 26 bits in length, and wherein the processing circuit is adapted to convert 16 soft bits from the first series and 16 soft bits from the second series to hard bits for said comparing. 23. The wireless receiver of claim 14, wherein the processing circuit is further adapted to skip channel decoding of one or more subsequent transmission bursts in response to determining that a burst is not present, based on said comparing. 24. A wireless receiver, comprising a receiver circuit adapted to receive transmission bursts in a wireless communications network and to produce received signal samples corresponding to said transmission bursts, anda processing circuit adapted to control the receiver circuit, to process the received signal samples, and, given a first sequence of bits that is known by the wireless receiver to be included in transmission bursts targeted to the wireless receiver and given a series of received signal samples corresponding to an expected transmission burst for the wireless receiver, to: estimate a channel response and a location for the first sequence within the series, the location for the first sequence indicating a subset of the received signal samples in the series;generate a plurality of bit estimates from the subset of received signal samples, based on the estimated channel response;compare the bit estimates to bits in the first sequence of bits; anddetermine whether a valid burst for the wireless receiver is present, based on said comparing; wherein the processing circuit, given a second sequence of bits that is known by the wireless receiver to be included in transmission bursts targeted to a second wireless receiver in the event that orthogonal transmission bursts are simultaneously transmitted to the wireless receiver and to the second wireless receiver, is further adapted to: estimate a second channel response and a location for the second sequence within the series of received signal samples, the location for the second sequence indicating a second subset of the received signal samples in the series;generate a plurality of second bit estimates from the second subset of received signal samples, based on the second estimated channel response;compare the second bit estimates to bits in the second sequence of bits; anddetermine whether a burst for the second wireless receiver is present, based on said comparing of the second bit estimates to bits in the second sequence of bits. 25. The wireless receiver of claim 24, wherein the processing circuit is further adapted, in response to determining that bursts are present for both the wireless receiver and the second wireless receiver, to estimate a ratio of received powers for the bursts for the first and second wireless receivers. 26. The wireless receiver of claim 24, wherein the processing circuit is further adapted, in response to determining that bursts are present for both the wireless receiver and the second wireless receiver, to: demodulate first information bits targeted to the second wireless receiver, from the received signal samples;generate reduced-interference signal samples by subtracting an estimated interference signal from the received signal samples, wherein the estimated interference signal is based on the demodulated first information bits; anddemodulate second information bits targeted to the wireless receiver, from the reduced-interference signal samples.