Not exact matches
A constellation of more
than two dozen GPS satellites broadcasts
precise timing
signals by radio to electronic GPS receivers which allow them to accurately determine their location (longitude, latitude, and altitude) in real time.
Because all three gravitational - wave detectors saw the
signal, physicists could triangulate and locate the source to within a 30 - square - degree patch of sky — about 60 times the size of the moon and much more
precise than Fermi's localization.
«The input
signals can be transmitted much more accurately
than before thanks to the
precise control over timing in the circuit,» says Benenson.
Reproducing an exact driving path from this limited and basic information is challenging — and it is less
precise than using GPS or cellular
signal tracking measurements.
However some technical challenges still need to be taken to make the technology more accessible and usable to its full potential: gaining selective and comprehensive genetic access to the neurons of interest, controlling variation in the expression of the optogenetic tools (when using viruses) and its
precise localization (axon vs. presynaptic terminals), tailoring light - delivery system
signals to individual cells in a population rather
than the population as a whole, developing observation techniques which have the same spatial and temporal resolution as those tools... to cite only a few of them.
For example, access to the in - vehicle GPS
signal can enable more
precise and accurate location - based services
than phone sensors More consistent user experience thanks to voice pass - through capability.
In any of these situations, knowing your phone's
precise signal strength rather
than just a vague range of 1 - 5 bars can really help you diagnose the problem, and figure out the best way to fix it.
Field Test Mode shows you more detailed information about your cellular
signal strength, including a
precise numerical value for your
signal strength rather
than the usual five dots.