Detection of parking lot context

What is claimed: 1 . A global navigation satellite system (GNSS) receiver in a vehicle, comprising: a radio frequency (RF) receiving circuit configured to receive GNSS signals from a plurality of GNSS satellites orbiting Earth at different elevations; and a processor configured to: calculate a first signal to noise ratio (SNR) of the received GNSS signals for a first GNSS satellite of the plurality of GNSS satellites, calculate a second SNR of the received GNSS signals for a second GNSS satellite of the plurality of GNSS satellites, monitor a relative change in the first SNR with respect to the second SNR over time, determine that the GNSS receiver has entered a parking garage at an entrance based on the relative change in the first SNR with respect to the second SNR, in response to determining that the GNSS receiver is located in the parking garage, restrict a positioning algorithm to estimate the position of the vehicle upon the vehicle exiting the parking garage to be within a specified range of a known position of the entrance of the parking garage, and execute the restricted positioning algorithm to estimate a position of the GNSS receiver based on the received GNSS signals. 2 . The GNSS receiver of claim 1 , wherein the first GNSS satellite is a low elevation satellite, the second GNSS satellite is a medium elevation satellite, and a third GNSS satellite of the plurality of satellites is a high elevation satellite, wherein the processor is further configured to: compare the first SNR, the second SNR and a third SNR of the GNSS signals received from the third GNSS satellite to each other, and determine that the GNSS receiver is located in the parking garage based on the comparison. 3 . The GNSS receiver of claim 2 , wherein the processor is further configured to: determine that the GNSS receiver is located in a parking garage when: the comparison indicates that first SNR and the second SNR are both greater than the third SNR, or the comparison indicates that the first SNR and second SNR have an inverse relationship with respect to each other over time. 4 . The GNSS receiver of claim 1 , wherein the processor is further configured to: determine motion of the vehicle using a time series of position estimates of the positioning algorithm or based on dead reckoning sensors, and determine that the GNSS receiver is located in the parking garage when the motion of the vehicle indicates at least one of circular motion of the vehicle and low speed travel of the vehicle. 5 . The GNSS receiver of claim 1 , wherein the positioning algorithm is implemented as a Kalman filter that includes a position restriction when estimating the position of the vehicle upon the vehicle exiting the parking garage. 6 . The GNSS receiver of claim 1 , wherein the processor is further configured to: distinguish between the parking garage and a tunnel based on the change in the first SNR, the second SNR and a third SNR for received GNSS signals of a third high elevation GNSS satellite of the plurality of satellites, and upon determining that the GNSS receiver is located in the tunnel, suspending the positioning algorithm from estimating the position of the GNSS receiver. 7 . The GNSS receiver of claim 1 , wherein the processor is further configured to: determine and set the known position of an entrance of the parking garage based on a drop in a third SNR of signals received by a third high elevation GNSS satellite of the plurality of satellites as the vehicle enters the parking garage. 8 . A method for estimating position of a global navigation satellite system (GNSS) receiver, comprising: receiving, by a radio frequency (RF) receiving circuit, GNSS signals from a plurality of GNSS satellites orbiting Earth at different elevations; calculating, by a processor, a first signal to noise ratio (SNR) of the received GNSS signals for a first GNSS satellite of the plurality of GNSS satellites; calculating, by the processor, a second SNR of the received GNSS signals for a second GNSS satellite of the plurality of GNSS satellites; monitoring, by the processor, a relative change in the first SNR with respect to the second SNR over time; determining, by the processor, that the GNSS receiver has entered a parking garage at an entrance based on the relative change in the first SNR with respect to the second SNR over time; in response to determining that the GNSS receiver has entered the parking garage, restricting, by the processor, a positioning algorithm to estimate the position of the vehicle upon the vehicle exiting the parking garage to be within a specified range of a known position of the entrance of the parking garage; and executing, by the processor, the restricted positioning algorithm to estimate a position of the GNSS receiver based on the received GNSS signals. 9 . The method of claim 8 , further comprising: calculating, by the processor, a third SNR of the received GNSS signals for a third GNSS satellite of the plurality of GNSS satellites; comparing the first SNR, second SNR and the third SNR to each other over time; and determining that the GNSS receiver is located in a parking garage based on the comparison, wherein the first GNSS satellite is a low elevation satellite, the second GNSS satellite is a medium elevation satellite, and the third GNSS satellite is a high elevation satellite. 10 . The method of claim 9 , further comprising: determining that the GNSS receiver is located in a parking garage when the comparison indicates that: the first SNR and the second SNR are both greater than the third SNR, or the first SNR and second SNR have an inverse relationship with respect to each other over time. 11 . The method of claim 8 , further comprising: determining motion of the vehicle using a time series of position estimates of the positioning algorithm or based on dead reckoning sensors; and determining that the GNSS receiver is located in the parking garage when the motion of the vehicle indicates at least one of circular motion of the vehicle and low speed travel of the vehicle. 12 . The method of claim 8 , wherein the positioning algorithm is implemented as a Kalman filter that includes a position restriction when estimating the position of the vehicle upon the vehicle exiting the parking garage. 13 . The method of claim 8 , further comprising: distinguishing between the parking garage and a tunnel based on the change in the first SNR, the second SNR and a third SNR of the received GNSS signals for a third GNSS satellite of the plurality of GNSS satellites; and upon determining that the GNSS receiver is located in the tunnel, suspending the positioning algorithm from estimating the position of the GNSS receiver. 14 . The method of claim 8 , further comprising: determining and setting the known position of an entrance of the parking garage based on a drop in a third SNR of the received GNSS signals for a third high elevation GNSS satellite of the plurality of GNSS satellites as the vehicle enters the parking garage. 15 . A mobile phone, comprising: a radio frequency (RF) receiving circuit configured to receive GNSS signals from a plurality of GNSS satellites orbiting Earth at different elevations; and a processor configured to: calculate a first signal to noise ratio (SNR) of the received GNSS signals for a first GNSS satellite of the plurality of GNSS satellites, calculate a second SNR of the received GNSS signals for a second GNSS satellite of the plurality of GNSS satellites, monitor a relative change in the first SNR wi