Satellite signal tracking method and receiver

What is claimed is: 1. A satellite signal tracking method performed by a receiver that receives a satellite signal from each of a plurality of positioning satellites, the satellite signal tracking method comprising: for each of the positioning satellites: computing a first Doppler frequency using a received signal obtained by receiving the satellite signal; computing an inertial position using acceleration measurement data from a sensor unit for measuring the acceleration of the receiver, the sensor unit including at least an acceleration sensor; computing a provisional position using the first Doppler frequency and the received satellite signal of each of the plurality of positioning satellites; correcting the inertial position using the provisional position to derive a corrected position of the receiver; for each of the positioning satellites: computing a second Doppler frequency using at least: the acceleration measurement data; and a computed viewing direction from the corrected position of the receiver to the positioning satellite obtained from satellite orbit information of the positioning satellite and the corrected position of receiver; and tracking the satellite signal using the second Doppler frequency. 2. The satellite signal tracking method according to claim 1 , wherein the computation of the second Doppler frequency includes: computing a third Doppler frequency using the acceleration measurement from the sensor unit and the computed viewing direction from the receiver to the positioning satellite; and computing a weighted-average of the first Doppler frequency and the third Doppler frequency to derive the second Doppler frequency. 3. The satellite signal tracking method according to claim 2 , wherein the computation of the third Doppler frequency includes: computing a Doppler frequency change amount using the computed viewing direction and the acceleration measurement from the sensor unit; and computing the third Doppler frequency by summing the Doppler frequency change amount with a latest second Doppler frequency. 4. The satellite signal tracking method according to claim 2 , wherein computing the weighted-average includes: scaling the third Doppler frequency by a first weight factor; and scaling the first Doppler frequency by a second weight factor, wherein the first weight factor is larger than the second weight factor. 5. The satellite signal tracking method according to claim 1 , further comprising: filtering via a first loop filter that filters the received signal of the satellite signal at a first loop bandwidth to derive a first filtered received signal; filtering via a second loop filter that filters the received signal of the satellite signal at a second loop bandwidth narrower than the first loop bandwidth to derive a second filtered received signal; computing a fourth Doppler frequency using the second filtered received signal and the second Doppler frequency; and tracking the satellite signal using the fourth Doppler frequency, wherein the computation of the first Doppler frequency includes computing the first Doppler frequency by filtering via the first loop filter. 6. The satellite signal tracking method according to claim 1 , further comprising: outputting a first position corresponding to tracking the satellite signal using the first Doppler frequency when a signal strength of the satellite signal is above a signal strength threshold, and outputting a second position corresponding to tracking the satellite signal using the second Doppler frequency when the signal strength of the satellite signal is not above the signal strength threshold. 7. A receiver that receives a satellite signal from each of a plurality of positioning satellites, the receiver comprising: a first Doppler computation unit that, for each of the positioning satellites, computes a first Doppler frequency using a received signal obtained by receiving the satellite signal; a provisional position computation unit that computes a provisional position using the first Doppler frequency and the received satellite signal of each of the plurality of positioning satellites; an inertial position computation unit that computes an inertial position using acceleration measurement data from a sensor unit for measuring the acceleration of the receiver, the sensor unit including at least an acceleration sensor; an inertial position correction unit that corrects the inertial position using the provisional position to derive a corrected position of the receiver; a second Doppler computation unit that, for each of the positioning satellites, computes a second Doppler frequency using at least: the acceleration measurement data; and a computed viewing direction from the corrected position of the receiver to the positioning satellite obtained from satellite orbit information of the positioning satellite and the corrected position of receiver; and a tracking unit that, for each of the positioning satellites, tracks the satellite signal using the second Doppler frequency.