A device is provided for correlating at least one noisy analog signal which is one of a plurality of signals obtained by a plurality of receivers. The device comprises a 1-bit quantization element to which the noisy signal is supplied; a comparator configured to compare the quantized signal with a r
A device is provided for correlating at least one noisy analog signal which is one of a plurality of signals obtained by a plurality of receivers. The device comprises a 1-bit quantization element to which the noisy signal is supplied; a comparator configured to compare the quantized signal with a reference signal which is a consensus signal obtained by averaging data from the plurality of receivers; and an up/down counter that is configured to be incremented by a subset of the comparison signal.
대표청구항▼
1. A method of correlating at least one noisy analogue signal, wherein the noisy signal is one of a plurality of signals obtained by a plurality of receivers, the method comprising: 1-bit quantising the noisy signal by 1-bit quantising each of in-phase and quadrature components of the noisy signal;c
1. A method of correlating at least one noisy analogue signal, wherein the noisy signal is one of a plurality of signals obtained by a plurality of receivers, the method comprising: 1-bit quantising the noisy signal by 1-bit quantising each of in-phase and quadrature components of the noisy signal;comparing the quantised signal with a quantised reference signal by comparing each of the quantised in-phase and quadrature components of the noisy signal with each of quantised in-phase and quadrature components of the reference signal, wherein the reference signal is a consensus signal obtained by combining data from the plurality of receivers and if the quantised in-phase components of the noisy signal and the reference signal are equal, incrementing or decrementing a first counter value in a first direction and, if not, incrementing or decrementing the first counter value in a second direction; andif the quantised quadrature components of the noisy signal and the reference signal are equal, incrementing or decrementing the first counter value in the first direction and, if not, incrementing or decrementing the first counter value in the second direction; andif the quantised in-phase component of the noisy signal and the quantised quadrature component of the reference signal are equal, incrementing or decrementing a second counter value in a first direction and, if not, incrementing or decrementing the second counter value in a second direction; andif the quantised quadrature component of the noisy signal and the quantised in-phase component of the reference signal are equal, incrementing or decrementing the second counter value in the second direction and, if not, incrementing or decrementing the second counter value in the first direction. 2. The method according to claim 1, comprising: stopping incrementing or decrementing the first and second down counter values when one of the first and second counter values reaches full scale. 3. The method according to claim 1, comprising: determining the phase offset between the phase of the noisy signal and the phase of the reference signal by considering the first and second counter values;altering the phase of the noisy signal in order to correct for the phase offset; andresetting the first and second counter values. 4. The method according to claim 1, comprising inverting the quantised signal if there is a strong negative correlation. 5. The method according to claim 1, comprising excluding the noisy signal from the consensus signal if the noisy signal consistently sits beyond a predetermined range of the consensus signal. 6. The method according to claim 1, wherein the reference signal is obtained by at least one of summing and averaging data from the plurality of receivers. 7. A device for correlating at least one noisy analogue signal, wherein the noisy signal is one of a plurality of signals obtained by a plurality of receivers, the device comprising: a 1-bit quantisation to which is supplied, in use, the noisy signal, wherein the 1-bit quantisation element is configured to 1-bit quantise each of in-phase and quadrature components of the noisy signal;a comparator configured to compare the quantised signal with a reference signal to generate a comparison signal, wherein the comparator is configured to compare each of the quantised in-phase and quadrature components of the noisy signal, with each of quantised in-phase and quadrature components of the reference signal, wherein the reference signal is a consensus signal obtained by combining data from the plurality of receivers; andfirst and second counters that are each configured to be incremented or decremented by at least some of the comparison signal, wherein:if the quantised in-phase components of the noisy signal and the reference signal are equal, the first counter is configured to be incremented or decremented in a first direction and, if not, the first counter is configured to be incremented or decremented in a second direction; andif the quantised quadrature components of the noisy signal and the reference signal are equal, the first counter is configured to be incremented or decremented in the first direction and, if not, the first counter is configured to be incremented or decremented in the second direction;if the quantised in-phase component of the noisy signal and the quantised quadrature component of the reference signal are equal, the second counter is configured to be incremented or decremented in a first direction and, if not, the second counter is configured to be incremented or decremented in a second direction; andif the quantised quadrature component of the noisy signal and the quantised in-phase component of the reference signal are equal, the second counter is configured to be incremented or decremented in the second direction and, if not, the second counter is configured to be incremented or decremented in the first direction. 8. The device according to claim 7, further comprising a sampling device configured to sample the comparison signal, and wherein the up/down each counter is configured to be incremented each time the sampling device samples the comparison signal. 9. The device according to claim 7, comprising an oscillator configured to modify the phase of the quantised signal. 10. The device according to claim 7, wherein the comparator is an XOR gate. 11. The device according to claim 7, wherein: the first and second counters are configured to be stopped when one of the first and second counters reaches full scale. 12. The device according to claim 7, wherein: the device is configured to determine the phase offset between the phase of the noisy signal and the phase of the reference signal from the values of the first and second counters andthe device comprises a control block configured to control an oscillator which alters the phase of the noisy signal in order to correct for the phase offset. 13. The device according to claim 7, comprising a control block configured to reset each counter. 14. The device according to claim 7, comprising an inverting element configured to invert the quantised signal if there is a strong negative correlation. 15. The device according to claim 7, comprising a control circuit configured to exclude the noisy signal from the consensus signal if the noisy signal consistently sits beyond a predetermined range of the consensus signal. 16. Apparatus comprising the plurality of receivers, each of the plurality of receivers comprising the device according to claim 7. 17. The device according to claim 7, wherein the reference signal is obtained by at least one of summing and averaging data from the plurality of receivers. 18. A method of correlating at least one noisy analogue signal, wherein the noisy signal is one of a plurality of signals obtained by a plurality of receivers, the method comprising: 1-bit quantising the noisy signal by 1-bit quantising each of in-phase and quadrature components of the noisy signal;1-bit quantising a reference signal, wherein the reference signal is a consensus signal obtained by combining data from the plurality of receivers,comparing the quantised noisy signal with the quantised reference signal by comparing each of the quantised in-phase and quadrature components of the noisy signal with each of quantised in-phase and quadrature components of the reference signal,performing at least one of the following steps (a) and (b);(a) incrementing or decrementing a first counter value as follows: if the quantised in-phase components of the noisy signal and the reference signal are equal, incrementing or decrementing the first counter value in a first direction and, if not, incrementing or decrementing the first counter value in a second direction, andif the quantised quadrature components of the noisy signal and the reference signal are equal, incrementing or decrementing the first counter value in the first direction and, if not, incrementing or decrementing the first counter value in the second direction;(b) incrementing or decrementing a second counter value as follows: if the quantised in-phase component of the noisy signal and the quantised quadrature component of the reference signal are equal, incrementing or decrementing the second counter value in a first direction and, if not, incrementing or decrementing the second counter value in a second direction; andif the quantised quadrature component of the noisy signal and the quantised in-phase component of the reference signal are equal, incrementing or decrementing the second counter value in the second direction and, if not, incrementing or decrementing the second counter value in the first direction. 19. The method according to claim 18, further comprising inverting the quantised noisy signal if there is a strong negative correlation. 20. The method according to claim 18, further comprising excluding the noisy signal from the consensus signal if the noisy signal consistently sits beyond a predetermined range of the consensus signal. 21. The method according to claim 18, wherein the reference signal is obtained by at least one of summing and averaging data from the plurality of receivers.
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