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'''High Sensitivity ]''' receivers use large banks of ] and ] to search for GPS signals very quickly. This results in very fast ] when the signals are at their normal levels, for example outdoors. When GPS signals are weak, for example indoors, the extra processing power can be used to integrate weak signals to the point where they can be used to provide a position or timing solution. | '''High Sensitivity ]''' receivers use large banks of ] and ] to search for GPS signals very quickly. This results in very fast ] when the signals are at their normal levels, for example outdoors. When GPS signals are weak, for example indoors, the extra processing power can be used to integrate weak signals to the point where they can be used to provide a position or timing solution. | ||
GPS signals are already very weak when they arrive at the Earth’s surface. The GPS ]s have ]s that only deliver 27 ]s from a distance of 20,200 km in ] above the Earth. By the time the signals arrive at the user's receiver, they are typically as weak as –160], equivalent to one tenth of a millionth billionth of a watt. This is well below the thermal noise level in its bandwidth. Outdoors GPS signals are typically around the - |
GPS signals are already very weak when they arrive at the Earth’s surface. The GPS ]s have ]s that only deliver 27 ]s from a distance of 20,200 km in ] above the Earth. By the time the signals arrive at the user's receiver, they are typically as weak as –160 ], equivalent to one tenth of a millionth billionth of a watt. This is well below the thermal noise level in its bandwidth. Outdoors GPS signals are typically around the -155 dBW level. | ||
Conventional GPS receivers ] the received GPS signals for the same amount of time as the duration of a complete ] which is 1 ms. This results in the ability to acquire and track signals down to around the - |
Conventional GPS receivers ] the received GPS signals for the same amount of time as the duration of a complete ] which is 1 ms. This results in the ability to acquire and track signals down to around the -160 dBW level. '''High Sensitivity GPS''' receivers are able to integrate the incoming signals for up to 1,000 times longer than this and therefore acquire signals up to 1,000 times weaker. A good '''High Sensitivity GPS''' receiver can acquire signals down to -185 dBW, and tracking can be continued down to levels approaching -190 dBW. | ||
'''High Sensitivity GPS''' can provide positioning in many but not all indoor locations. Signals are either heavily ] by the building materials or reflected in as ]. Given that '''High Sensitivity GPS''' receivers may be up to 30 ] more sensitive this is sufficient to track through 3 layers of dry bricks or up to 20 cm of steel reinforced concrete for example. | '''High Sensitivity GPS''' can provide positioning in many but not all indoor locations. Signals are either heavily ] by the building materials or reflected in as ]. Given that '''High Sensitivity GPS''' receivers may be up to 30 ] more sensitive this is sufficient to track through 3 layers of dry bricks or up to 20 cm of steel reinforced concrete for example. |
Revision as of 18:21, 5 January 2008
It has been suggested that this article be merged into Global Positioning System and Talk:Global Positioning System#Merge proposal. (Discuss) Proposed since September 2007. |
High Sensitivity GPS receivers use large banks of correlators and digital signal processing to search for GPS signals very quickly. This results in very fast times to first fix when the signals are at their normal levels, for example outdoors. When GPS signals are weak, for example indoors, the extra processing power can be used to integrate weak signals to the point where they can be used to provide a position or timing solution.
GPS signals are already very weak when they arrive at the Earth’s surface. The GPS satellites have transmitters that only deliver 27 watts from a distance of 20,200 km in orbit above the Earth. By the time the signals arrive at the user's receiver, they are typically as weak as –160 dBW, equivalent to one tenth of a millionth billionth of a watt. This is well below the thermal noise level in its bandwidth. Outdoors GPS signals are typically around the -155 dBW level.
Conventional GPS receivers integrate the received GPS signals for the same amount of time as the duration of a complete C/A code cycle which is 1 ms. This results in the ability to acquire and track signals down to around the -160 dBW level. High Sensitivity GPS receivers are able to integrate the incoming signals for up to 1,000 times longer than this and therefore acquire signals up to 1,000 times weaker. A good High Sensitivity GPS receiver can acquire signals down to -185 dBW, and tracking can be continued down to levels approaching -190 dBW.
High Sensitivity GPS can provide positioning in many but not all indoor locations. Signals are either heavily attenuated by the building materials or reflected in as multipath. Given that High Sensitivity GPS receivers may be up to 30 dB more sensitive this is sufficient to track through 3 layers of dry bricks or up to 20 cm of steel reinforced concrete for example.