Active geo-location for orthogonal frequency division multiplex wireless local area network devices using additive correlation in the time domain

What is claimed is: 1. A method in a wireless device (WD) for determining a geo-location of a target station using round-trip times (RTTs) of a plurality of signals transmitted by the WD to the target station and a plurality of response signals received from the target station corresponding to the plurality of signals transmitted by the WD, the method comprising: determining expected time domain symbols of an expected response signal; transmitting the plurality of signals; for each transmitted signal of the plurality of signals: determining a first time, the first time being a time of transmission of each transmitted signal; opening a reception window for receiving a response signal corresponding to one transmitted signal; receiving the response signal within the reception window, the received response signal including at least time domain symbols; frequency shifting the expected time domain symbols of the expected response signal; while the reception window is open, cross-correlating the time domain symbols of the received response signal with the frequency shifted expected time domain symbols, the cross-correlation generating a set of cross-correlation outputs; determining a peak correlation value based at least in part on the set of cross-correlation outputs; determining a second time, the second time being a time associated with the peak correlation value; and determining the RTT for each one of the transmitted plurality of signals based at least on the first time and the second time to determine the geo-location of the target station. 2. The method of claim 1 , the method further comprising: summing the set of cross-correlation outputs of the open reception window of each signal based at least on a predetermined criterion; and determining a set of rolling sums from the summed set of cross-correlation outputs to determine the peak correlation value. 3. The method of claim 2 , wherein cross-correlating the time domain symbols of the received response signal is performed in a set of branches, each branch of the set of branches tuning to a different frequency offset to cover a range of carrier frequency offsets, wherein summing the set of cross-correlation outputs is performed per each branch of the set of branches, and wherein determining the set of rolling sums is performed for each branch of the set of branches. 4. The method of claim 2 , wherein the predetermined criterion includes at least one of a plurality of samples, a plurality of frequency shifts, and the reception window of each transmitted signal, and summing the set of cross-correlation outputs is performed for any one of each sample of the plurality of samples, each frequency shift of the plurality of frequency shifts, and the reception window of each transmitted signal. 5. The method of claim 2 , wherein determining the set of rolling sums is based at least on an amount of samples in a rolling sum window, a number of samples in the reception window, and a number of packets in a burst. 6. The method of claim 2 , the method further including: detecting an end of transmission of the plurality of signals; and determining the set of rolling sums is performed after the end of transmission of the plurality of signals is detected. 7. The method of claim 1 , wherein the transmitted plurality of signals are orthogonal frequency diversity modulation (OFDM) signals transmitted in a burst of N transmissions, the transmitted plurality of signals having a time between each transmission and a wait time between the burst and a subsequent burst. 8. The method of claim 1 , wherein each transmitted signal is one of a request-to-send (RTS) signal and a data null signal. 9. The method of claim 1 , wherein the expected time domain symbols of the expected response signal include at least one of a OFDM preamble and a signal field. 10. A wireless device (WD) configured to determine a geo-location of a target station using round-trip times (RTTs) of a plurality of signals transmitted by the WD to the target station and a plurality of response signals received from the target station corresponding to the plurality of signals transmitted by the WD, the WD comprising: a transceiver configured to: transmit the plurality of signals; and receive a response signal within a reception window for each transmitted signal of the plurality of signals, the received response signal including at least time domain symbols; and processing circuitry in communication with the transceiver, the processing circuitry being configured to: determine expected time domain symbols of an expected response signal; transmitting the plurality of signals; for each transmitted signal of the plurality of signals: determine a first time, the first time being a time of transmission of each transmitted signal; open the reception window for receiving the response signal corresponding to one transmitted signal; frequency shift the expected time domain symbols of the expected response signal; while the reception window is open, cross-correlate the time domain symbols of the received response signal with the frequency shifted expected time domain symbols, the cross-correlation generating a set of cross-correlation outputs; determine a peak correlation value based at least in part on the set of cross-correlation outputs; determine a second time, the second time being a time associated with the peak correlation value; and determine the RTT for each one of the transmitted plurality of signals based at least on the first time and the second time to determine the geo-location of the target station. 11. The WD of claim 10 , the processing circuitry being further configured to: sum the set of cross-correlation outputs of the open reception window of each signal based at least on a predetermined criterion; and determine a set of rolling sums from the summed set of cross-correlation outputs to determine the peak correlation value. 12. The WD of claim 11 , wherein cross-correlating the time domain symbols of the received response signal is performed in a set of branches, each branch of the set of branches tuning to a different frequency offset to cover a range of carrier frequency offsets, wherein summing the set of cross-correlation outputs is performed per each branch of the set of branches, and wherein determining the set of rolling sums is performed for each branch of the set of branches. 13. The WD of claim 11 , wherein the predetermined criterion includes at least one of a plurality of samples, a plurality of frequency shifts, and the reception window of each transmitted signal, and summing the set of cross-correlation outputs is performed for any one of each sample of the plurality of samples, each frequency shift of the plurality of frequency shifts, and the reception window of each transmitted signal. 14. The WD of claim 11 , wherein determining the set of rolling sums is based at least on an amount of samples in a rolling sum window, a number of samples in the reception window, and a number of packets in a burst. 15. The WD of claim 11 , the processing circuitry being further configured to: detect an end of transmission of the plurality of signals; and determine the set of rolling sums is performed after the end of transmission of the plurality of signals is detected. 16. The WD of claim 10 , wherein the transmitted plurality of signals are orthogonal frequency diversity modulation (OFDM) signals transmitted in a burst of N transmissions, the transmitted plurality of signals having a time between each transmission and a wait time between the burst and a