Peak to sigma ratio measurement with active geo-location for wireless local area network devices

What is claimed is: 1. A method in a first wireless device (WD) to discriminate between valid round trip time (RTT) measurements arising from reception of a signal from a second WD and false RTT measurements arising from noise, the method comprising: transmitting a plurality of ranging signals to the second WD; receiving from the second WD a plurality of ranging response signals responsive to the plurality of ranging signals; and for each ranging response signal of the plurality of ranging response signals: determining a sum of correlations, each correlation being between an expected bit sequence and a received bit sequence in the ranging response signal; determining a standard deviation of the sum of correlations; determining a first ratio of a peak value of the sum of correlations to the standard deviation to obtain a peak to standard deviation ratio (PSR); and rejecting an RTT measurement corresponding to the peak value of the sum correlations when the PSR is less than a threshold. 2. The method of claim 1 , the method further comprising: for N previous ranging signals, recording PSRs for each ranging signal of the plurality of ranging signals; grouping and summing the PSRs for the N ranging signals in specific ranges; determining a second ratio of the sum of the PSRs in a first range to a sum of PSRs in a second range, the second range having lower values than the first range; and rejecting an RTT measurement for a ranging response signal of the plurality of ranging response signals when a corresponding PSR is less than a threshold and the ratio is also less than a threshold. 3. The method of claim 2 , further comprising, when a PSR is above a threshold, using a time of occurrence of the PSR to determine a distance between the first WD and the second WD. 4. The method of claim 3 , wherein the threshold R is 0.4. 5. The method of claim 2 , further comprising, when a PSR is above a threshold and the second ratio is within a specified range, then using a time of occurrence of the PSR to determine a distance between the first WD and the second WD. 6. The method of claim 2 , further comprising, when the second ratio is less than the threshold and a PSR is within a specified range, then not using a time of occurrence of the peak value to determine a distance between the first WD and the second WD. 7. The method of claim 2 , further comprising accepting an RTT measurement for a ranging response signal of the plurality of ranging response signals when at least one of the following occurs: a PSR for the RTT measurement is equal or greater than a first threshold T 1 ; the PSR for the RTT measurement is greater than a second threshold T 2 and less than the first threshold T 1 and the first ratio is greater than a threshold R; and the PSR for the RTT measurement is greater than a third threshold T 3 and less than the second threshold T 2 and the first ratio is greater than a threshold R. 8. The method of claim 7 , wherein: the first PSR threshold T 1 is 5; the second PSR threshold T 2 is 4.5; and the third PSR threshold T 3 is 3.5. 9. The method of claim 2 where the first range of the sum of PSRs is 4 to 4.5, and the second range of the sum of PSRs is 3.5 to 4. 10. The method of claim 2 , further comprising, based at least in part on the second ratio, performing one of: indicating that a valid RTT measurement has been received; using a time of occurrence of a peak value corresponding to the valid RTT measurement to determine a distance between the first WD and the second WD; and discarding a time of occurrence of the peak value. 11. A first wireless device (WD) configured to discriminate between valid round trip time (RTT) measurements arising from reception of a signal from a second WD and false RTT measurements arising from noise, the first WD comprising: a radio interface configured to: transmit a plurality of ranging signals to the second WD; and receive from the second WD a plurality of ranging response signals responsive to the plurality of ranging signals; and processing circuitry in communication with the radio interface, the processing circuitry configured to: for each ranging response signal of the plurality of ranging response signals: determine a sum of correlations, each correlation being between an expected bit sequence and a received bit sequence in the ranging response signal of the plurality of ranging response signals; determine a standard deviation of the sum of correlations; determine a first ratio of a peak value of a sum of the correlations to the standard deviation to obtain a peak to standard deviation ratio (PSR); and reject an RTT corresponding to the peak value when the PSR is less than a threshold. 12. The first WD of claim 11 , wherein the processing circuitry is further configured to: for N previous ranging signals, record PSRs for each ranging signal of the plurality of ranging signals; group and sum the PSRs for the N previous ranging signals in specific ranges; and determine a second ratio of the sum of the PSRs in a first range to a sum of PSRs in a second range, the second range having lower values than the first range; and reject an RTT measurement for a ranging response signal of the plurality of the ranging response signals when a corresponding PSR is less than a threshold and the ratio is also less than a threshold. 13. The first WD of claim 12 , wherein, when a PSR is above a threshold, the processing circuitry is further configured to use a time of occurrence of the PSR to determine a distance between the first WD and the second WD. 14. The first WD of claim 13 , wherein the threshold R is 0.4. 15. The first WD of claim 12 , wherein, when a PSR is above a threshold and the second ratio is within a specified range, the processing circuitry is further configured to use a time of occurrence of the PSR to determine a distance between the first WD and the second WD. 16. The first WD of claim 12 , wherein, when the second ratio is less than the threshold and a PSR is within a specified range, the processing circuitry is further configured to refrain from using a time of occurrence of the peak value to determine a distance between the first WD and the second WD. 17. The first WD of claim 12 , wherein the processing circuitry is further configured to accept an RTT measurement for a ranging response signal of the plurality of ranging response signals when at least one of the following occurs: a PSR for the RTT measurement is equal or greater than a first threshold T 1 ; the PSR for the RTT measurement is greater than a second threshold T 2 and less than the first threshold T 1 and the first ratio is greater than a threshold R; and the PSR for the RTT measurement is greater than a third threshold T 3 and less than the second threshold T 2 and the first ratio is greater than a threshold R. 18. The first WD of claim 17 , wherein: the first PSR threshold T 1 is 5; the second PSR threshold T 2 is 4.5; and the third PSR threshold T 3 is 3.5. 19. The first WD of claim 12 , where the first range of the sum of PSRs is 4 to 4.5, and the second range of the sum of PSRs is 3.5 to 4. 20. The first WD of claim 12 , wherein the processing circuitry is further configured to, based at least in part on the second ratio, perform one of: indicating that a valid RTT measurement has been received; using a time of occurrence of a peak value corresponding to the valid RTT measurement to determine a distance between the first WD and the seco