Time to get accurate Atomic clock time servers for computer networks

  |   By

Accurate and precise time is increasingly becoming a necessity for computer systems. From corporate networks to public service technologies such as ATMs, traffic lights or CCTV cameras – precise time is what keeps them ticking.

Inaccurate or unsynchronised time is the root cause for many technology breakdowns and failures.  For instance, failing to synchronize a traffic lights system can lead to all sorts of confusion of the lights change at the wrong time – and the consequences for systems belonging to industries such as air traffic control could be even worse.

And even a standard computer network such as those used in most offices requires accurate synchronisation to prevent errors, enable debugging and to ensure the system is secure.

Most system administrators are now aware of the importance of accurate and precise time synchronisation but getting a source of accurate time is often where many people make mistakes.

Many network administrators are aware of the time protocol NTP (Network Time Protocol) which is used to ensure accurate synchronisation between computers.

However, many administrators make the mistake of using a source of time from across the internet to distribute with NTP – a common pitfall that can have disastrous consequences.

The internet is not the best source of tine. While it is true, many online NTP servers are available as a source of atomic time or UTC (Coordinated Universal Time) but are they accurate. The truth is it is almost impossible to know. Internet time sources can be affected by the distance of the client (the network) from the time source – it also can’t be authenticated by NTP.

Even more important, internet time sources operate through the firewall which can allow the time signal to be hijacked by malicious programs.

The only secure and accurate method of synchronising a computer network or other technology system is to use an NTP server. These devices receive an external atomic clock time signal often by GPS or even by radio transmissions.

These signals are come direct from atomic clocks so are highly accurate they also can’t be hijacked as they are not connected to the internet.

The World Cup and the NTP Server

  |   By

As half the world is engrossed in the four yearly football tournament, it is a good opportunity to highlight the importance of accurate time and how it enables the entire world to watch events such as the Fifa World Cup.

Many of us have been glued to the love football coverage that is being broadcast by a multitude of different broadcasters and TV companies to nearly all countries across the globe.

But nearly all the technologies that enable this mass global live transmission: from the communication satellites that beam the signal across the globe, to the receivers that distribute them to our dishes, cable boxes and aerials.

And with online broadcasting now part and parcel of the whole live sporting event package – accurate time is even more important.

NTP time servers

With signals being bounced from football stadiums to satellites and then to our homes, it is essential that all the technologies involved are synchronised as accurately as possible. Failure to do so could cause the signals to get lost, create interferences or cause a qhole host of other problems.

Most technologies rely on time servers to ensure accuracy and synchronisation. Most time synchronisation servers use the protocol NTP (Network Time Protocol) to distribute time across technology networks.

These devices use a single time source, often acquired from an external atomic clock that is used to set all system clocks on devices to.

Most modern computer networks have a NTP time server that controls the time. These devices are simple to set up and in a modern, global world, are a must have for anybody conscious about accuracy and security (Many security and malicious network attacks are caused due to a lack of synchronisation).

A single NTP time server can keep a network of hundreds and even thousands of machines accurate to within a few milliseconds to the world’s global timescale UTC (Coordinated Universal Time).

A New Slim 1U Rackmount Dual Time Server from Galleon Systems

  |   By

Leading providers of time synchronisation equipment and Network Time Protocol Products, Galleon Systems, have released a compact new 1U rackmountable dual time server.

Galleon’s new NTS 6001 1U rackmountable NTP time server can receive atomic clock timing signals from both the Global Positioning System (GPS) and national time and frequency radio transmissions.

Designed to fit snugly into any server rack, the 1U NTS 6001 is a stratum 1 time server capable of symphonizing a network of hundred of machines to within a few
milliseconds of UTC (Coordinated Universal Time).

The NTS 6001 consists of both an integral GPS receiver that can simultaneously track up to 12 satellites, and a high gain radio receiver that can receive the MSF (UK), WWVB (USA) and DCF (Germany) radio transmissions.

The NTS- 6001 dual time server features:

  • NTP Version 4
  • Ethernet NTP output jitter typically within 50 microseconds of UTC.
  • High Reliability – solid state design and convection cooled
  • Easy to use – web based user interface for system configuration and management.
  • Free firmware upgrades.
  • LCD display
  • 3 Year Warranty.

The NTS 6001 is the latest in a long line of highly precise NTP time synchronisation devices from atomic clock experts Galleon Systems.

Manufactured in the UK, Galleon Systems have a wide range of other NTP and time synchronisation devices used worldwide by thousands of organizations who need accurate, reliable and precise time.

For more information please contact:
https://www.galsys.co.uk/
0121 608 4433
sales(at)galleonmail(dot)com

Ensure Accurate Time with an Atomic Wall Clock

  |   By

Written By Richard Williams for Galleon Systems

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.

Do I Really Need A NTP Server For Time Synchronisation?

  |   By

Time synchronisation is a critical aspect to modern computing, especially when computers are on a network or need to communicate with other networked machines.

Timestamps are crucial for computers to acknowledge when an event occurred and it is the only information they have to ascertain if an event has occurred. Without accurate time stamps the consequences can include:

• Loss of data
• Difficult to log errors
• Difficult to debug
• Failure to save
• Time sensitive applications may fail

Modern operating systems like Windows 7 have automatic synchronisation software already installed. W32Time has been a part of Microsoft’s different generations of operating systems for some time but in Windows 7 it is set to be automatically on (Rather than the user having to set it) – synchronising your PC straight out of the box.

With such NTP (Network Time Protocol) based synchronisation available by using internet time servers (normally Microsoft and NIST) many people may wonder if a dedicated time server is still required.

Problems with Internet Time Servers

There are several drawbacks to using this Internet time as a source of UTC (Coordinated Universal Time – the global timescale often referred to as GMT).

The first and most important drawback to internet time servers is their location through the firewall. Having to rely on a source of time across the internet means keeping the TCP port open – a crucial security weakness that can be used by malicious users or bots.

Another downside to internet time servers is their lack of guaranteed accuracy. While places like NIST (National Institute for Standards and Time) and Microsoft have reliable and accurate time servers – the accuracy can be dependent on how far away you are peering from. And many other time servers available as a source of internet time are less reliable – and as NTP can’t authenticate a time signal from across the internet – it can be difficult to assess.

Benefits of an External NTP Server

Dedicated external NTP servers are far more secure. They receive their tie from GPS satellites of Long Wave transmissions so the signals can’t be intercepted by computer hackers or malicious software. Also, NTP can authenticate the signals ensuring you know where they are coming from and how accurate they are.

With time being so important on modern networked computers, taking a risk with internet time may cost a lot more than any minor investment in a dedicated NTP time server.

Competition for GPS Ever Closer

  |   By

Written by Richard N Williams for Galleon Systems

Since its release to the civilian population the Global Positioning System (GPS) has greatly improved and enhanced our world. From satellite navigation to the precise time used by NTP servers (Network Time Protocol) and much or our modern world’s technology.

And GPS has for several years been the only Global Navigation Satellite Systems (GNSS) and is used the world over, however, times are now changing.

There are now three other GNSS systems on the horizon that will not only act as competition for GPS but will also increase its precision and accuracy.

Glonass is a Russian GNSS system that was developed during the Cold War. However, after the fall of the Soviet Union the system fell into disrepair but it has finally been revamped and is now back up and running.

The Glonass system is now being used as a navigational aid by Russian airlines and their emergency services with in-car GNSS receivers also being rolled out for the general population to use. And the Glonass system is also allowing time synchronisation using NTP time servers as it uses the same atomic clock technology as GPS.

And Glonass is not the only competition for GPS either. The European Galileo system is on track with the first satellites expected to be launched at the end of 2010 and the Chinese Compass system is also expected to be online soon which will make four fully operational GNSS systems orbiting above Earth’s orbit.

And this is good news for those interested in ultra high time synchronisation as the systems should all be interoperable meaning anyone looking to GNSS satellites can use multiple systems to ensure even greater accuracy.

It is expected that interoperable GNSS NTP time servers will soon be available to make use of these new technologies.

Understanding GPS Time in Relation to UTC

  |   By

Accurate time is so important for modern computer systems that it is now unimaginable for any network administer to configure a computer system without any regard to synchronisation.

Ensuring all machines are running an accurate and precise time, and that the entire network is synchronised together, will prevent problems arising such as data loss, failure of time sensitive transactions and enable debugging and error management which can be near impossible on networks that lack synchronicity.

There are many sources of accurate time for use with NTP time servers (Network Time Protocol). NTP servers tend to use time that is controlled by atomic clocks to ensure accuracy, and there are advantages and disadvantages to each system.

Ideally as a source of time you want it to be a source of UTC (Coordinated Universal Time) as this is the international time standard as used by computer systems worldwide. But UTC is not always accessible but there is an alternative.

GPS time

GPS time is the time as relayed by the atomic clocks on board GPS satellites. These clocks form the basic technology for the Global Positioning System and their signals are what are used to work out positing information.

But GPS time signals can also provide an accurate source of time for computer networks – although strictly speaking GPS time does differ to UTC.

No Leap Seconds

GPS time is broadcast as an integer. The signal contains the number of seconds from when the GPS clocks were first turned on (January 1980).

Originally GPS time was set to UTC but since GPS satellite have been in space the last thirty years, unlike UTC, there has been no increase to account for leap seconds – so currently GPS is running exactly 17 seconds behind UTC.

Conversion

Whilst GPS time and UTC are not strictly the same as they were originally based on the same time and only the lack of leap seconds not added to GPS makes the difference, and as this is exact in seconds, conversion of GPS time is simple.

Many GPS NTP servers will convert GPS time to UTC time (and local time if you so wish) ensuring you can always have an accurate, stable, secure and reliable source of atomic clock based time.

Choosing a Source of Time for Computer Network Synchronization

  |   By

You don’t need me to tell you how important computer network time synchronization is. If you are reading this then you are probably well aware of the importance in ensuring all your computers, routers and devices on your network are running the same time.

Failure to synchronize a network can cause all sorts of problems, although with a lack of synchronicity the problems may go unnoticed as error finding and debugging a network can be nigh on impossible without a source of synchronized time.

There are multiple options for finding a source of accurate time too. Most time sources used for synchronisation are a source of UTC (Coordinated Universal Time) which is the international timescale.
However, there are pro’s and con’s to all sources:

Internet time

There are an almost an endless number of sources of UTC time on the internet. Some of these time sources are wholly inaccurate and unreliable but there are some trusted sources put out by people like NIST (National Institute for Standards and Time) and Microsoft.

However, regardless of how trusted the time source is, there are two problems with internet time sources. Firstly, an internet time server is actually a stratum 2 device. In other words, an internet time server is connected to another time server that gets its time from an atomic clock, usually from one of the sources below. So an internet source of time is never going to be as accurate or precise as using a stratum 1 time server yourself.

Secondly, and more importantly, internet sources of time operate through the firewall so a potential security breach is available to any malicious user who wishes to take advantage of the open ports.

GPS Time

GPS time is far more secure. Not only is a GPS time signal available anywhere with a line of sight view of the sky, but also GPS time signals can be received externally to the network. By using a GPS time server the GPS time signals can be received and by using NTP (Network Time Protocol) this time can be converted to UTC (GPS time is currently 17 seconds exactly behind GPS time) then distributed around the network.

MSF/WWVB Time

Radio broadcasts in long wave are transmitted by several national physics labs. NIST and the UK’s NPL are two such organisations and they transmit the UTC signals MSF (UK) and WWVB (USA) which can be received and utilised by a radio referenced NTP server.

When Time Servers go Bad

  |   By

“Time is what prevents everything from happening at once,’ said eminent physicist John Wheeler. And when it comes to computers his words couldn’t be any more relevant.

Timestamps are the only method that a computer has to establish if an event has occurred, is meant to occur or shouldn’t be occurring just yet. For a home PC, the computer relies on the inbuilt clock that displays the time on the corner of your operating system, and for most home uses this is satisfactory enough.

However for computer networks that have to communicate with each other, relying in individual system clocks can cause untold problems:

All clocks drift, and computer clocks are no different and problems occur when two machines are drifting at different rates as the time does not match up. This poses a conundrum for a computer as it is unsure of which time to believe and time critical events can fail to occur and even simple tasks like sending an email can cause time confusion on a network.

For these reasons, time servers are commonly used to receive the time from an external source and distribute it around the network. Most of these devices use the protocol NTP (Network Time Protocol) which is designed to provide a method of synchronising time on a network.

However, time servers are only as good as the time source that they rely on and when there is a problem with that source, synchronisation will fail and the problems mentioned above can occur.

The most common cause for time server failure or inaccuracy is the reliance on internet based sources of time. These can neither be authenticated by NTP nor guaranteed to be accurate and they can also lead to security issues with firewall intrusion and other malicious attacks.

Ensuring the NTP time server continues to get a source of highly accurate time is fairly straight forward and is all a matter of choosing an accurate, reliable and secure time source.

In most parts of the world there are two methods that can provide a secure and reliable source of time:

  • GPS time signals
  • Radio referenced time signals

GPS signals are available anywhere on the planet and are based on GPS time which is generated by atomic clocks onboard the satellites.

Radio referenced signals like MSF and WWVB are broadcast on long wave from physics laboratories like NIST and NPL.

European Rival to GPS takes a Further Step Forward

  |   By

The long awaited European rival to the USA Global Positioning System, Galileo, has taken a step forward to realisation with the delivery of the payload for first satellite.

The payload, which contains the “brains” of the Galileo satellite, includes the atomic clocks that are the basis for all global navigation satellite systems (GNSS) and provide both the positing information and the GPS time signal used by so many GPS NTP time servers for network synchronisation.

Galileo is set to not only rival the current American run GPS system, but for time synchronisation applications it is expected to operate in tandem ensuring even greater accuracy for those seeking a source of UTC time.

Galileo has undergone a lot of uncertainty since the multi-billion Euro project was first designed over a decade ago but the delivery of the first satellite’s payload to Rome, where the equipment is being finalised in preparation for launch early next year, is a real boon to the project which has often fallen into doubt.

Just like GPS, Galileo will be a fully operation navigational satellite system but will offer even greater accuracy that its aging predecessor and provide Europe with their own navigational system that isn’t owned and controlled by the US military.

As well as the positing information that will be used by motorists, pilots and other travellers, Galileo will also provide a secure and accurate source of time for the world’s computer networks and technologies to ensure synchronicity.

Currently, GPS is alone in providing this secure service, although radio transmissions in some countries provide an alternative to the GPS time server signals, although they are not as wide spread as GPS.

The first Galileo satellite is expected to reach orbit in early 2011, with the entire network planned to be operation in 2014 – although if past experiences with the project are anything to go on – you should expect at least a few delays.