Accuracy in timekeeping is forever becoming more important in the modern global economy. Industries and business around the globe are now often communicating with each despite the time zone differences.

There was a time when a few minutes here or there rarely mattered but now, knowing exactly what time it is has become more and more important as conference calls and over-the-internet webinars are often scheduled as part of regular business.

Global Timescale

Fortunately, to prevent the headache of working out all the different time-zones you may have to deal with, there is a global timescale that is now adopted by the global community. UTC (Coordinated Universal Time) is an atomic clock controlled time used globally and kept precise and accurate by physics laboratories around the world.

UTC enables accurate communication and forms and is used by many high end technologies to ensure accuracy such as the network time server (NTP server – Network Time Protocol). Often these devices receive the UTC time directly from atomic clocks thanks to radio broadcasts from people like NIST (USA’s National Institute for Standards and Time) and NPL (UK’s National Physical Laboratory)

Atomic Wall Clocks

And when it comes to people telling the time, these same radio signals can also be utilised by an atomic wall clock. Atomic wall clocks, despite what the name suggests, are not atomic clocks. In essence they are comprised of a standard clock device and a radio antenna and receive. The atomic clocks signals broadcast by the physics laboratories can be received and the clock regularly adjusts itself to ensure that the clock is accurate to UTC to the second.

Ensure Accurate Time with an Atomic Wall Clock is a post from: Galleon Systems

There is no single master clock used for the world’s timing but there are a constellation of clocks that are used as a basis for a universal timing system known as UTC (Coordinated Universal Time).

UTC enables all the world’s computer networks and other technology to talk to each other in perfect synchronicity which is vital in the modern world of internet trading and global communication.

But as mentioned controlling UTC is not down to one master clock, instead, a serious of highly precise atomic clocks based in different countries all work together to produce a timing source that is based on the time told by them all.

These UTC timekeepers include such notable organisations as the USA’s National Institute of Standards and Time (NIST) and the UK’s National Physical Laboratory (NPL) amongst others.

These organisations don’t just help ensure UTC is as accurate as possible but they also provide a source of UTC time available to the world’s computer networks and technologies.

To receive the time from these organisations, a NTP time server (Network Time Server) is required. These devices receive the broadcasts from places like NIST and NPL via long wave radio transmissions. The NTP server then distributes the timing signal across a network, adjusting individual system clocks to ensure that they are as accurate to UTC as possible.

A single dedicated NTP server can synchronize a computer network of hundreds and even thousands of machines and the accuracy of a network relying in UTC time from the broadcasts by NIST and NPL will also be highly precise.

The NIST timing signal is known as WWVB and is broadcast from Boulder Colorado in the heart of the USA whilst the UK’s NPL signal is broadcast in Cumbria in the North of England and is known as MSF – other countries have similar systems including the DSF signal broadcast out of Frankfurt, Germany.

The Worlds Atomic Clock Timekeepers is a post from: Galleon Systems

There are many technologies that require extremely accurate precision between systems, from satellite navigation to many internet applications, accurate time is becoming increasingly important.

However, achieving precision is not always straight forward, especially in modern computer networks. While all computer systems have inbuilt clocks, these are not accurate time pieces but standard crystal oscillators, the same technology used in other electronic clocks.

The problem with relying on system clocks like this is that they are prone to drift and on a network consisting of hundreds or thousands of machines, if the clocks are drifting at a different rate – chaos can soon ensue. Emails are received before they are sent and time critical applications fail.

Atomic clocks are the most accurate time pieces around but these are large scale laboratory tools and are impractical (and highly expensive) to be used by computer networks.

However, physics laboratories like the North American NIST (National Institute of Standards and Time) do have atomic clocks which they broadcast time signals from. These time signals can be used by computer networks for the purpose of synchronization.

In North America, the NIST broadcasted time code is called WWVB and is transmitted out of Boulder, Colorado on long wave at 60Hz. The time code contains the year, day, hour, minute, second, and as it is a source of UTC, any leap seconds that are added to ensure parity with the rotation of the Earth.

Receiving the WWVB signal and using it to synchronize a computer network is simple to do. Radio reference network time servers can receive this broadcast throughout North America and by using the protocol NTP (Network Time Protocol).

A dedicated NTP time server that can receive the WWVB signal can synchronize hundreds and even thousands of different devices to the WWVB signal ensuring each one is to within a few milliseconds of UTC.

Using the WWVB Signal for Time Synchronization is a post from: Galleon Systems

The DCF 77 signal is a long wave transmission broadcast at 77 KHz from Frankfurt in Germany. DCF -77 is transmitted by Physikalisch-Technische Bundesanstalt, the German national physics laboratory.

DCF-77 is an accurate source of UTC time and is generated by atomic clocks that ensure its precision. DCF-77 is a useful source of time that can be adopted all over Europe by technologies needing an accurate time reference.

Radio controlled clocks and network time servers receive the time signal and in the case of time servers distribute this time signal across a computer network. Most computer network use NTP to distribute the DCF 77 time signal.

There are advantages of using a signal like DCF for time synchronisation. DCF is long wave and is therefore susceptible to interference from other electrical devices but they can penetrate buildings that give the DCF signal an advantage over that other source of UTC time generally available – GPS (Global Positioning System) – which requires a open view of the sky to receive satellite transmissions.

Other long wave radio signals are available in other countries that are similar to DCF-77. In the UK the MSF -60 signal is broadcast by NPL (National Physical Laboratory) from Cumbria while in the USA, NIST (National Institute of Standards and Time) transmit the WVBB signal from Boulder, Colorado.

NTP time servers are an efficient method of receiving these long wave transmissions and then using the time code as a synchronisation source. NTP servers can receive DCF, MSF and WVBB as well as many of them also being able to receive the GPS signal too.

European Time Synchronisation with DCF-77 is a post from: Galleon Systems

A NTP time server provides precise timing information 24 hours-a-day, 365 days-a-year anywhere on the entire globe. A dedicated NTP time server is the only secure, safe and reliable method of synchronizing a computer network to UTC (Coordinated Universal Time). External to the firewall, an NTP time server does not leave a computer system vulnerable to malicious attacks unlike Internet timing sources via the TCP-IP port.

A NTP time server is not only secure, it receives a UTC time signal direct from atomic clocks unlike Internet timing sources which are really time servers themselves. NTP servers and other time synchronization tools can synchronize entire networks, single PCs, routers and a whole host of other devices. Using either GPS or the North American WWVB signal, a dedicated NTP time server from will ensure all your devices are running to within a fraction of UTC time.

A NTP time server will:

•    Increase network security
•    Prevent data loss
•    Enable logging and tracking of errors or security breaches
•    Reduce confusion in shared files
•    Prevent errors in billing systems and time sensitive transactions
•    Can be used to provide incontestable evidence in legal and financial disputes

Perfect Time Synchronization for Windows is a post from: Galleon Systems

Computer networks are normally synchronised to the global timescale UTC (Coordinated Universal Time) enabling them to communicate efficiently with other networks also running UTC.

Whilst UTC time sources are available across the Internet these are not secure (being outside the firewall) and many are either too far away to provide adequate precision or are too inaccurate to begin with.

The most secure methods of receiving a UTC time source are to use a dedicated NTP Time Server. These devices can receive a secure and accurate time signal either the GPS network (Global Positioning System) available anywhere across the globe with a good view of the sky or through specialist radio transmission broadcast by national physics laboratories.

In the US the National Institute for Standards and Time (NIST) broadcast a time signal from near Fort Collins, Colorado. The signal, known as WWVB can be received all over North America (including many parts of Canada) and provides an accurate and secure method of receiving UTC.

As the signal is derived from atomic clocks situated at the Fort Collins site, WWVB is a highly accurate method of synchronising time and is also secure as a dedicated NTP time server acts as an external source.

WWVB Explained is a post from: Galleon Systems