In time-related applications, it is important to determine which clock will be used as the primary time reference for all other clocks, and then to understand how to transfer the time from that reference clock to the others. 

The best solution is to use a special timing reference clock, or master clock. The method by which the accuracy of the master clock is transferred to another slave, or secondary clock, is known as “synchronization.” 

Typically, GNSS satellite signals are utilized for synchronization to ensure accurate time, but other references such as embedded atomic clocks can also be used.

What is a Master Clock?

Picture3.pngMaster Clocks take one or more precise timing reference signals as inputs, then convert and distribute those timing references to other devices to improve their accuracy.

Master clock systems are used in a variety of applications and industries, including:

  • Aerospace
  • Defense
  • Broadcast 
  • Radio 
  • Telecom
  • Network systems
  • Financial services
  • Emergency operations
  • Call centers
  • Healthcare
  • Anywhere that reliability of data and signals is critical

Network master clocks distribute their timing references over local or wide area networks. There are also highly accurate master clock solutions that utilize copper or fiber connections for signal distribution of precise analog and digital signals, such as IRIG, HAVEQUICK and ASCII timecodes.

Master clocks can differ in the source of their timing reference. It is rare for a master clock not to be synchronized to a continuous external reference. So, a core feature of all master clock systems is that they must accept precise timing reference signals as inputs. 

Orolia’s SecureSync modular time and frequency synchronization system can accept over 14 different signal types to discipline its local clock, which can generate a similar number of signal types to synchronize other devices. If an external reference is lost, SecureSync will automatically switch to a remaining available reference. If no other references are available, the local clock maintains timing accuracy until the reference(s) can be restored. Orolia offers several local clock oscillator options, depending on the accuracy required during the “holdover” period.

Common Uses of Master Clocks

Orolia master clocks deliver precise signalling and Legally Traceable Time™ to all timekeeping functions in any network.

  • Orolia master clocks are used to record emergency calls to improve response times and to settle legal disputes
  • Digital broadcast systems rely on master clocks to align frequency and time to ensure the reliability of wireless transmissions  
  • Military C4ISR platforms (radar, satcom, simulation, electronic warfare) require master clock precision for accurate timing.
  • Telemetry and flight test systems need to correlate sensor and other data with precisely synchronized time  
  • Commercial enterprises, data centers and financial services leverage NTP Servers for records accuracy, troubleshooting and security, as well as to enable time-sensitive applications to operate at extremely accurate levels.

Rack Mount Instruments, Display Clocks, Plug-in Cards, OEM Boards & Modules, and Mobile Master Clocks

Orolia also offers synchronized rack mount appliances, plug-in computer/server slot cards, OEM boards, and rugged modules that can be used as master clocks for many applications. In addition, Orolia offers VersaSync, a rugged timing platform with a small size, weight and power (SWaP) master clock, as well as VersaPNT, a single compact unit for high dynamic vehicle applications that includes an inertial measurement unit (IMU).

David Sohn
ABOUT THE AUTHOR
David Sohn

David Sohn is a Solution Architect at Orolia, designing and developing solutions leveraging the organization's precision timing solution portfolio, including their flagship SecureSync and VersaSync products, and contributing to its entire portfolio of resilient PNT solutions. He has more than 10 years of experience designing, developing, and managing precision timing solutions and holds a BS in computer engineering from The Pennsylvania State University.

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