Not exact matches
This
method simulates the
distances in space across which absorption
measurements are taken, but in a sample length of 75 cm.
For instance, the range of the
method is still limited to typical
distances of less than 1 m. Moreover, today's standard processors do not permit real - time evaluation of the large amount of data generated by the
measurement.
Matching those redshifts to
distance measurements calculated from gravitational waves should give estimates of the current rate of cosmic expansion, known as the Hubble constant, that are independent — and potentially more precise — than calculations using current
methods.
Unfortunately, if
distance measurements using this
method are reported in the popular press, usually only the determined
distance is given, not the measured red shift nor the used cosmological parameters; this can lead to the result that at different places, different
distances are reported for the same object and the same study.
So, instead of relying on this
method, Melis» team used radio
measurements to perform the work, which opened up a more reliable
distance beacon: quasars, amazingly bright galactic cores powered by supermassive black holes.
This
method measures and uses the
distance of the thumbstick position relative to the center focus point of the thumbstick base, instead of the standard
method, which calculates the
measurement using a two - dimensional plane.