It is the most inexpensive, compact, and widely used type of atomic clock, used not only in Galileo and GPS but also to control the frequency of television stations, cell phone base stations, etc.
Galileo Rubidium Atomic Clock
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Author Archives: Galileo GNSS
Voyager 1 has left the Solar System
Voyager 1 has marked one of the most significant technological achievements in the annals of the history of science. It is currently where no probe has gone before.
It is a 722 kg spacecraft launched by NASA on 5 Sept 1977 to study the outer Solar System. Currently it is the farthest manmade object from Earth. Read more…
Galileo Atomic Clocks
An atomic clock works like a conventional clock but the time-base of the clock, instead of being an oscillating mass as in a pendulum clock, is based on the properties of atoms when transitioning between different energy states.
When an atom is excited by an external energy source, it goes to a higher energy state. Then, from this state, it goes to a lower energy state. In this transition, the atom releases energy at a very precise frequency which is characteristic of the type of atom. Read more…
PHM or Passive Hydrogen Maser (2/2)
Video explanation on how PHM works:
PHM or Passive Hydrogen Maser (1/2)
The Passive Hydrogen Maser (PHM) is the master clock on the Galileo satellite’s payload. Its extremely good performance makes it the most stable of all clocks currently in space, better than 1 nanosecond per day. Some other features: 18 Kg of mass, 28 liters of volume and 20 years lifetime.
The hydrogen maser uses the properties of the hydrogen atom to serve as a precision frequency reference. But, how does it work? Let’s see what is the process: Read more…
GIOVE-B, Second Galileo Satellite
GIOVE-B (Galileo In-Orbit Validation Element) was launched by a Soyuz rocket from Baiknour on 27 April 2008, carrying the most accurate atomic clock ever flown into space at that moment.
The 500 kg satellite was left into a circular orbit at an altitude of 23,173 km, inclined at 56 degrees to the Equator, 3 hours and 45 minutes after the launch. It makes a complete journey around the Earth in 14 hours and 3 minutes. Read more…
Galileo Signal Polarization
Polarization is a property of electromagnetic waves that can oscillate with more than one orientation. By convention, the orientation of the wave’s electric field at a point in space over one period of the oscillation specifies its orientation.
The magnitude and direction of an electric field is defined by what is called an electric field vector. The Galileo transmitted signals are Right-Hand Circularly Polarized (RHCP), which means that the electric field vectors have a constant magnitude but the direction changes in a rotary manner. If the wave is frozen in time, the electric field vector of the wave describes a helix along the direction of propagation. Read more…