Category: atomic clocks

The Measuring of Time

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Measuring the passing of time has been a preoccupation of humans since the dawn of civilization. Broadly speaking, measuring time involves using some form of repetitive cycle to work out how much time has passed. Traditionally this repetitive cycle has been based on the movement of the heavens such as a day being a revolution of the Earth, a month being an entire orbit of the Earth by the moon and a year being earth’s orbit of the sun.

As our technology progressed we have been able to measure time in smaller and smaller increments from sundials that allowed us to count the hours, mechanical clocks that let us monitor the minutes, electronic clocks that let is for the first time accurately record seconds to the current age of atomic clocks where time can be measured to the nanosecond.

With the advancement in chronology that has led to technologies such as NTP clocks, time servers, atomic clocks, GPS satellites and modern global communications, comes with another conundrum: when does a day start and when does it finish.

Most people assume a day is 24 hours long and that it runs from midnight to midnight. However, atomic clocks have revealed to us that a day is not 24 hours and in fact the length of a day varies (and is actually increasing gradually over time).

After atomic clocks were developed there was a call from many sectors to come up with a global timescale. One that uses the ultra precise nature of atomic clocks to measure its passing but also one that takes into account the Earth’s rotation. Failing to account for the variable nature of a day’s length would mean any static timescale would eventually drift with day slowly drifting into night.

To compensate for this the world’s global timescale, called UTC (coordinated universal time) has additional seconds added (leap seconds) to ensure that there is no drift. UTC time is kept true by a constellation of atomic c clocks and it is utilised by modern technologies such as the NTP time server which ensures computer networks all run  the exact same precise time.

Germans Enter Race to Build the Worlds Most Accurate Clock

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Following the success of Danish researchers working in conjunction with NIST (National Institute for Standards and Time), who unveiled the world’s most accurate atomic clock earlier this year; German scientist have entered the race to build the world’s most precise timepiece.

Researchers at the Physikalisch-Technische Bundesanstalt (PTB) in Germany are using use new methods of spectroscopy to investigate atomic and molecular systems and hope to develop a clock based around a single aluminium atom.

Most atomic clocks used for satellite navigation (GPS), as references for computer network NTP servers and air traffic control have traditionally been based on the atom caesium. However, the next generation of atomic clocks, such as the one unveiled by NIST which is claimed to be accurate to within a second every 300 million years, uses the atoms from other materials such as strontium which scientists claim can be potentially more accurate than caesium.

Researchers at PTB have opted to use single aluminium atoms and believe they are on the way to developing the most accurate clock ever and believe there is huge potential for such a device to help us understand some of the more complicated aspects of physics.

The current crop of atomic clocks allow technologies such as satellite navigation, air traffic control and network time synchronisation using NTP servers but it is believed the increases accuracy of the next generation of atomic clocks could be used to reveal some of the more enigmatic qualities of quantum science such as string theory.

Researchers claim the new clocks will provide such accuracy they will even be able to measure the minute differences in gravity to within each centimetre above sea-level.

Milestones in Chronology From Crystals to Atoms

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Telling the time may seem a simple affair these days with the number of devices that display the time to us and with the incredible accuracy of devices such as atomic clocks and network time servers it is quite easy to see how chronology has been taken for granted.

The nanosecond accuracy that powers technologies such as the GPS system, air traffic control and NTP server systems (Network Time Protocol) is a long way from the first time pieces that were invented and were powered by the movement of the sun across the heavens.

Sun dials were indeed the first real clocks but they obviously did have their downsides – such as not working at night or in cloudy weather, however, being able to tell the time fairly accurately was a complete innovation to civilisation and helped for more structured societies.

However, relying on celestial bodies to keep track of time as we have done for thousands of years, would not prove to be a reliable basis for measuring time as was discovered by the invention of the atomic clock.

Before atomic clocks, electronic clocks provided the highest level of accuracy. These were invented at the turn of the last century and while they were many times more reliable than mechanical clocks they still drifted and would lose a second or two every week.

Electronic clocks worked by using the oscillations (vibrations under energy) of crystals such as quartz, however, atomic clocks use the resonance of individual atoms such as caesium which is such a high number of vibrations per second it makes the incredibly accurate (modern atomic clocks do not drift by even a second every 100 million years).

Once this type of time telling accuracy was discovered it became apparent that our tradition of using the rotation of the earth as a means of telling time was not as accurate as these atomic clocks. Thanks to their accuracy it was soon discovered the Earth’s rotation was not precise and would slow and speed up (by minute amounts) each day. To compensate for this the world’s global timescale UTC (Coordinated Universal Time) has additional seconds added to it once or twice a year (Leap seconds).

Atomic clocks provide the basis of UTC which is used by thousands of NTP servers to synchronise computer networks to.

Worlds Most Famous Clock Reaches 150

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It’s one of the world’s most iconic land marks. Standing proudly over the Houses of Parliament, Big Ben celebrates its 150th birthday. Yet despite living in an age of atomic clocks and NTP time servers, it is one of the most used timepieces in the world with hundreds of thousands of Londoners relying on its chimes to set their watches to.

Big Ben is actually the name of the main bell inside the clock that creates the quarter hourly chimes but the bell didn’t start chiming when the clock was first built. The clock began keeping time on 31 May 1859, while the bell didn’t strike for the first time until July 11.

Some claim the twelve tonne bell was named after Sir Benjamin Hall the Chief Commissioner of Works who worked on the clock project (and was said to be a man of great girth). Others claim the bell was named after heavyweight boxer Ben Caunt who fought under the moniker Big Ben.

The five-tonne clock mechanism works like a giant wristwatch and is wound three times a week. Its accuracy if in tuned by adding or removing old pennies on the pendulum which is quite far removed from the accuracy that modern atomic clocks and NTP server systems generate with near nanosecond precision.

While Big Ben is trusted by tens of thousands of Londoners to provide accurate time, the modern atomic clock is used by millions of us every day without realising it. Atomic clocks are the basis for the GPS satellite navigation systems we have in our cars they also keep the internet synchronised by way of the NTP time server (Network Time Protocol).

Any computer network can be synchronised to an atomic clock by using a dedicated NTP server. These devices receive the time from an atomic clock, either via the GPS system or specialist radio transmissions.

The Atom and Time keeping

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Nuclear Weapons, computers, GPS, atomic clocks and carbon dating – there is much more to atoms than you think.

Since the beginning of the twentieth century mankind has been obsessed with atoms and the minutiae of our universe. Much of the first part of the last century, mankind became obsessed with harnessing the hidden power of the atom, revealed to us by the work of Albert Einstein and finalised by Robert Oppenheimer.

However, there has been much more to our exploration of the atom than just weapons. The studying of the atoms (quantum mechanics) has been at the root of most of our modern technologies such as computers and the Internet.  It is also in the forefront of chronology – the measuring of time.

The atom plays a key role in both timekeeping and time prediction. The atomic clock, which is utilised all over the world by computer networks using NTP servers and other technical systems such as air traffic control and satellite navigation.

Atomic clocks work by monitoring the extremely high frequency oscillations of individual atoms (traditionally caesium) that never changes at particular energy states. As caesium atoms resonate over a 9 billion times every second and never alters it its frequency it makes the m highly accurate (losing less than a second every 100 million years)

But atoms can also be used to work out not just accurate and precise time but they can also be utilised in establishing the age of objects. Carbon dating  is the name given to this method which measures the natural decay of carbon atoms. All of us are made primarily of carbon and like other elements carbon ‘decays’ over time where the atoms lose energy by emitting ionizing particles and radiation.

In some atoms such as uranium this happens very quickly, however, other atoms such as iron are highly stable and decay very, very slowly. Carbon, while it decays quicker than iron is still slow to lose energy but the energy loss is exact over time so by analysing carbon atoms and measuring their strength it can be quite accurately ascertained when the carbon originally formed.

Computers, Communications, Atomic Clocks and the NTP Server

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Time synchronisation on computer networks is often conducted by the NTP server. NTP time servers do not generate any timing information themselves but are merely methods of communicating with an atomic clock.

The precision of an atomic clock is widely talked about. Many of them can maintain time to nanosecond precision (billionths of a second) which means they won’t drift beyond a second in accuracy in hundreds of millions of years.

However, what is less understood and talked about is why we need to have such accurate clocks, after-all the traditional methods of keeping time such as mechanical clocks, electronic watches and using the rotation of the Earth to keep track of the days has proved reliable for thousands of years.

However, the development of digital technology over recent years has been nearly solely reliant on the ultra high precision of an atomic clock. One of the most widely used applications for atomic clocks is in the communications industry.

For several years now telephone calls taken in most industrialized countries are now transmitted digitally. However, most telephone wires are simply copper cables (although many telephone companies are now investing in fibre optics) which can only transmit one packet of information at a time. Yet telephone wires have to carry many conversations down the same wires at the same time.

This is achieved by computers at the exchanges switching from one conversation to another thousands of times every second and all this has to be controlled by nano-second precision otherwise  the calls will become out of step and get jumbled – hence the need for. Atomic clocks; mobile phones, digital TV and Internet communications use similar technology.

The accuracy of atomic clocks is also the basis for satellite navigation such as GPS (global positioning system). GPS satellites contain an onboard atomic clock that generates and transmits a time signal. A GPS receiver will receive four of theses signals and use the timing information to work out how long the transmissions took to reach it and therefore the position of the receiver on Earth.

Current GPS systems are accurate to a few metres but to give an indication of how vital precision is, a one second drift of a GPS clock could see the GPS receiver be inaccurate by over 100 thousand miles (because of the  huge distances light and therefore transmissions take in one second).

Many of these technologies that depend on atomic clocks utilise NTP servers as the preferred way to communicate with atomic clocks making the NTP time server one of the most crucial pieces of equipment in the communication industries.

The NTP Time Server Essential Network Protection

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There are a myriad of hardware and software methods of protecting computers. Anti-virus software, firewalls, spyware and routers to name but a few yet perhaps the most important tools for keeping a network safe is often the most overlooked.

One of the reasons for this is that the network time server’s often referred to as the NTP time server (after the protocol Network Time Protocol) primary task is time synchronisation and not security.

The NTP server’s primary task is to retrieve a time signal from a UTC source (Coordinated Universal Time) which it then distributes it amongst the network, checking the clock on each system device and ensuring its running in synchronisation with UTC.

Here is where many network administrators fall down. They know that time synchronisation is vital for computer security. Without it, errors can not be logged (or even spotted) network attacks can’t be countered, data can be lost and if a malicious user does get into the system it is near impossible to discover what they were up to without all machines on a network corresponding to the same time.

However, the NTP server is where many network administrators think they can save a little money. ‘Why bother?’ ‘They say, ‘when you can log on to an Internet NTP server for free.’

Well, as the old saying goes there is no such thing as a free lunch or as it goes a free source of UTC time. Using internet time providers may be free but this is where many computer networks leave themselves open to abuse.

To utilise an internet source of time such as Microsoft’s, NIST or one of those on the NTP pool project may be free but they are also outside a networks firewall and these is where many network administrators come unstuck.

How to Synchronise Your PC to an Atomic Clock

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The world’s technologies have advanced dramatically over the last few decades with innovations likes the internet and satellite navigation having changed the way we live our lives.

Atomic clocks pay a key role in these technologies; their time signals are what are used by GPS receivers to plot location and many applications and transactions across the internet if it wasn’t for highly precise synchronisation.

In fact a global timescale has been developed that is based on the time told by atomic clocks. UTC (Coordinated Universal Time) ensures that computer networks across the globe can be synchronised to the exact same time.

Synchronising computers and networks to atomic clocks is relatively straight forward thanks in part to NTP (Network Time Protocol), a version of which is included in most operating systems and is also thanks to the number of public NTP servers that exist on the internet.

To synchronise a Windows PC to an atomic clock is done by simply double clocking the clock on the task bar and then configuring the Internet Time tab to a relevant NTP server. A list of public NTP servers can be found at the NTP pool website.

When configuring networks to UTC however, a public NTP server is not suitable as there are security issues about polling a time source outside the firewall. Public servers are also known as stratum 2 servers which means they receive the time from another device that gets it from an atomic clock. This indirect method means that there is often a compromise in accuracy, furthermore if the internet connection goes down or the time server site then the network will soon drift away from UTC.

A far more secure and stable method is to invest in a dedicated NTP time server. These devices receive a time signal directly from an atomic clock, either produced by a national physics lab like NIST or NPL via long wave radio or from GPS satellites.

A single dedicated NTP server will provide a stable, reliable and highly precise source of UTC and allow networks of hundreds and even thousands of devices to be synchronised to NTP.

Bringing Atomic Clock Precision to your Desktop

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Atomic clocks have been a huge influence on our modern lives with many of the technologies that have revolutionised the way we live our lives relying on their ultra precise time keeping abilities.

Atomic clocks are far different to other chronometers; a normal watch or clock will keep time fairly accurately but will lose second or two each day. An atomic clock on the other hand will not lose a second in millions of years.

In fact it is fair to say that an atomic clock doesn’t measure time but is the foundations we base our perceptions of time on. Let me explain, time, as Einstein demonstrated, is relative and the only constant in the universe is the speed of light (though a vacuum).

Measuring time with any real precision is therefore difficult as even the gravity on Earth skews time, slowing it down. It is also almost impossible to base time on any point of reference. Historically we have always used the revolution of the earth and reference to the celestial bodies as a basis for our time telling (24 hours in a day = one revolution of the Earth, 365 days = one revolution of the earth around the Sun etc).

Unfortunately the Earth’s rotation is not an accurate frame of reference to base our time keeping on. The earth slows down and speeds up in its revolution meaning some days are longer than others.

Atomic clocks
however, used the resonance of atoms (normally caesium) at particular energy states. As these atoms vibrate at exact frequencies (or an exact number of times) this can be used as a basis for telling time. So after the development of the atomic clock the second has been defined as over 9 billion resonance ’ticks’ of the caesium atom.

The ultra precise nature of atomic clocks is the basis for technologies such as satellite navigation (GPS), air traffic control and internet trading. It is possible to use the precise nature of atomic clocks to synchronise computer networks too. All that is needed is a NTP time server (Network Time Protocol).
NTP servers receive the time from atomic clocks via a broadcast signal or the GPS network they then distribute it amongst a network ensuring all devices have the exact same, ultra precise time.

Essentials of Traffic Management NTP Server

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There are now reportedly as many cars on the road as there are households and it only takes a brief journey during rush hour to realise that this claim is quite possibly true.

Congestion is a huge problem in our towns and cities and controlling this traffic and keeping it moving is one of the most essential aspects of reducing congestion. Safety is also a concern on our roads as the chances of all those vehicles travelling around without occasionally hitting each other is close to zero but the problem can be exemplified by poor traffic management.

When it comes to controlling the traffic flows of our cities there is no greater weapon than the humble traffic light. In some cities these devices are simple timed lights that stop traffic one way and allow it the other and vice versa.

However, the potential of how traffic lights can reduce congestion is now being realised and thanks to the millisecond synchronisation made possible with NTP servers is now drastically reducing congestion is some of the world’s major cities.

Rather than just simple timed segments of green, amber and red, traffic lights can respond to the needs of the road, allowing more cars through in one direction whilst reducing it in others. They can also be used in conjunction with each other allowing green light passageways for cars in main routes.

However, all this is only possible if the traffic lights system throughout the whole city is synchronised together and that can only be achieved with a NTP time server.

NTP (Network Time Protocol) is simply an algorithm that is widely used for the purposes of synchronisation. A NTP server will receive a time signal from a precise source (normally an atomic clock) and the NTP software then distributes it amongst all devices on a network (in this case the traffic lights).

The NTP server will continually check the time on each device and ensure it corresponds to the time signal, ensuring all devices (traffic lights) are perfectly synchronised together allowing the entire traffic light system to be managed as a single, flexible traffic management system rather than individual random lights.