Geo-locating of wireless devices using a “pass filter” function

What is claimed is: 1. A method for a measuring station for determining a best fit geo-location of a target station, the target station responding to ranging packets transmitted by the measuring station, the method comprising: measuring a plurality of round-trip times, RTTs, y i , each RTT being a time elapsed between a transmission of a ranging packet and a reception of a response packet; for each of a plurality measuring station location variables, x i , determining a first difference, Δ i , between a RTT measurement, y i , and a first function, f(x i , α) of measuring station location variables, x i , and target station location parameters, α; and determining values of the plurality of target station location parameters, α, that minimize a sum of squared missed probabilities, SSMPs, a missed probability, MP, being a second function of the first difference Δ i . 2. The method of claim 1 , wherein the second function includes a second difference between 1 and a decaying exponential function of the first difference, Δ i . 3. The method of claim 2 , wherein the decaying exponential function is approximated by a first two terms of a Taylor series approximation to the decaying exponential function. 4. The method of claim 3 , wherein minimizing the sum of SSMPs includes multiplying a pass filter weight factor by a gradient of the first function, f(x i , α) with respect to the target location parameters α, the pass filter weight factor being a reciprocal of a variance, σ 2 , multiplied by the decaying exponential function. 5. The method of claim 2 , wherein the decaying exponential function is a function of difference, Δ i /σ, where a is a standard deviation, such that a smaller weight is given to a first RTT measurement having the first difference that is larger than a second difference, Δ i /σ, of a second RTT measurement. 6. The method of claim 5 , wherein the standard deviation Δ is chosen to selectively suppress spurious RTT measurements. 7. The method of claim 5 , wherein a first value of the difference, Δ i /σ, is selected at a start of minimizing the sum of SSMPs and a second value of the difference, Δ i /σ, smaller than the first value is selected after a start of minimizing the sum of SSMPs. 8. The method of claim 7 , wherein a first set of target location parameters a is determined based on the first value of the difference, Δ i /σ, and using the first set of target location parameters a in a subsequent iteration of minimizing the sum of SSMPs. 9. The method of claim 5 , wherein the standard deviation a is selected based at least in part on a standard deviation of the measured RTTs. 10. The method of claim 1 , wherein minimizing the sum of SSMPs includes performing successive iterations of the minimizing until a second difference between successive SSMPs is less than a threshold. 11. A wireless device for a measuring station for determining a best fit geo-location of a target station, the target station responding to ranging packets transmitted by the measuring station, the wireless device comprising: a transmitter receiver configured to: measure a plurality of round-trip times, RTTs, y i , each RTT being a time elapsed between a transmission of a ranging packet and a reception of a response packet; processing circuitry in communication with the transmitter receiver, the processing circuitry being configured to: for each of a plurality measuring station location variables, x i , determine a first difference, Δ i /σ, between a RTT measurement, y i , and a first function, f(x i , α) of measuring station location variables, x i , and target station location parameters, α; and determine values of the measuring station location variables, x i , and target station location parameters, α, that minimize a sum of squared missed probabilities, SSMPs, a missed probability, MP i , being a second function of the first difference Δ i . 12. The wireless device of claim 11 , wherein the second function includes a second difference between 1 and a decaying exponential function of the first difference, Δ i . 13. The wireless device of claim 12 , wherein the decaying exponential function is approximated by a first two terms of a Taylor series approximation to the decaying exponential function. 14. The wireless device of claim 13 , wherein the decaying exponential function is a function of a difference, Δ i /σ, where σ is a standard deviation, such that a smaller weight is given to a first RTT measurement having the first difference, Δ i /σ, that is larger than a second difference, Δ i /σ, of a second RTT measurement. 15. The wireless device of claim 12 , wherein the decaying exponential function is a function of a difference, Δ i /σ, such that the difference, Δ i /σ, results in smaller weight given to a first RTT measurement having a difference, Δ i /σ, that is larger than a standard deviation of a second RTT measurement. 16. The wireless device of claim 15 , wherein the standard deviation a is chosen to selectively suppress spurious RTT measurements. 17. The wireless device of claim 15 , wherein a first value of the difference, Δ i /σ, is selected at a start of minimizing the sum of SSMPs and a second value of the difference, Δ i /σ, smaller than the first value is selected after a start of minimizing the sum of SSMPs. 18. The wireless device of claim 17 , wherein a first set of target location parameters α is determined based on the first value of the difference, Δ i /σ, and using the first set of target location parameters α in a subsequent iteration of minimizing the sum of SSMPs. 19. The wireless device of claim 15 , wherein the standard deviation σ is selected based at least in part on a standard deviation of the measured RTTs. 20. The wireless device of claim 11 , wherein minimizing the sum of SSMPs includes performing successive iterations of the minimizing until a second difference between successive SSMPs is less than a threshold.