Category: Time Synchronisation

Closed Circuit Cameras are Useless Without a Network Time Server

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For those of us that live in Britain, the CCTV camera (closed circuit TV) will be a familiar site on the high streets. Over four million cameras are in operation throughout the British Isles with every major city being monitored by state funded cameras which has cost the British taxpayer over £200 million ($400 million).

The reasons for use of such widespread surveillance have always been declared as to prevent and detect crime. However, critics argue that there is little evidence that CCTV cameras have done anything to dent the rising street crime on the UK’s streets and that the money could be better well spent.

One of the problems of CCTV is that many cities have both cameras controlled by local councils and privately controlled cameras. When it comes to crime detection the police often have to obtain as much evidence as possible which often means combining the different local authority controlled CCTV cameras with the privately controlled systems.

Many local authorities synchronise their CCTV cameras together, however, if the police have to obtain images from a neighbouring borough or from a private camera these may not be synchronised at all, of if so, synchronised to a different time completely.

This is where CCTV falls down in the fight against crime. Just imagine a suspected criminal is spotted on one CCTV camera committing a criminal act. The time on the camera could say 11.05pm but what if the police follow the suspects movements across a city and use footage from a privately owned camera or from other boroughs and while the CCTV camera that caught the suspect in the act may say 11.05, the other camera could spot the suspect minutes later only for the time to be even earlier. You could imagine a good defence lawyer taking full advantage of this.

To ensure their worth in the fight against crime, it is imperative that CCTV cameras are time synchronized using a network time server. These times servers ensure every device (in this case camera) is running the exact same time. But how do we ensure all cameras are synchronised to the same time source. Well fortunately, a global time source known as UTC (coordinated Universal Time) has been developed for this exact purpose. UTC is what governs computer networks, air traffic control and other time sensitive technologies.

A CCTV camera using a NTP server that receives a UTC time source from an atomic clock will not only be accurate but the time told on the devices will be provable in court and accurate to a thousandth of a second (millisecond).

2038 The Next Computer Time Bug

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Remember the turn of the millennium. Whilst many of us were counting down the seconds until midnight, there were network administrators across the globe with their fingers crossed hoping their computer systems will still be working after the new millennium kicked in.

The millennium bug was the result of early computer pioneers designing systems with only two digits to represent the time as computer memory was very scarce at the time. The problem didn’t arise because of the turn of the millennium, it arose because it was the end of the century and two digit year flicked around to 00 (which the machines assume was 1900)

Fortunately by the turn of the millennium most computers were updated and enough precautions were taken that meant that the Y2K bug, as it became known, didn’t cause the widespread havoc it was first feared.

However, the Y2K bug is not the only time related problem that computer systems can be expected to face, another problem with the way computers tell the time has been realised and many more machines will be affected in 2038.

The Unix Millennium Bug (or Y2K38) is similar to the original bug in that it is a problem connected with the way computers tell the time. The 2038 problem will occur because most machines use a 32 bit integer to calculate the time. This 32 bit number is set from the number of seconds from 1 January 1970, but because the number is limited to 32 digits by 2038 there will be no more digits left to deal with the advance of time.

To solve this problem, many systems and languages have switched to a 64-bit version, or supplied alternatives which are 64-bit and as the problem will not occur for nearly three decades there is plenty of time to ensure all computer systems can be protected.

However, these problems with timestamps are not the only time related errors that can occur on a computer network. One of the most common causes of computer network errors is lack of time synchronization. Failing to ensure each machine is running at an identical time using a NTP time server can result in data being lost, the network being vulnerable to attack from malicious users and can cause all sorts of errors such as emails arriving before they have been sent.

To ensure your computer network is adequately synchronized an external NTP time server is recommended.

Parking Tickets and the NTP Server

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There is nothing worse than returning to your car only to discover that your parking meter time limit has expired and you’ve got a parking ticket slapped on to your windscreen.

More-often-than-not it’s only a matter of being a couple of minutes late before an over eager parking attendant spots your expired meter or ticket and issues you a fine.

However, as the people of Chicago are discovering, whilst a minute may be the difference between getting back to the car in time or receiving a ticket, a minute may also be the difference between different parking meters.

It seems the clocks on the 3000 new parking meter pay boxes in Cale, Chicago have been discovered to be unsynchronized. In fact, of the nearly 60 pay boxes observed, most are off at least a minute and in some cases, nearly 2 minutes from what is “actual” time.

This has posed a headache to the firm in charge of parking in the Cale district and they could face legal challenges from the thousands of motorists that have been given tickets from these machine.

The problem with the Cale parking system is that while they claim they regularly calibrate their machine there is no accurate synchronization to a common time reference. In most modern applications UTC (Coordinated Universal Time) is used as a base timescale and to synchronize devices, like Cale’s parking meters, a NTP server, linked to an atomic clock will receive UTC time and ensure every device has the exact time.

NTP servers are used in the calibration of not just parking meters but also traffic lights, air traffic control and the entire banking system to name but a few applications and can synchronize every device connected to it to within a few milliseconds of UTC.

It’s a shame Cale’s parking attendants didn’t see the value of of a dedicated NTP time server – I’m sure they are regretting not having one now.

Which time signal? GPS or WWVB and MSF

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Dedicated NTP time server devices are the easiest, most accurate, reliable and secure method of receiving a source of UTC time (Coordinated Universal Time) for synchronizing a computer network.

NTP servers (Network Time Protocol) operate outside the firewall and are not reliant on the Internet which means they are highly secure and not vulnerable to malicious users who, in the case of Internet time sources can use the NTP client signals as a method of accessing the network or penetrating the firewall.

A dedicated NTP server will also receive it’s time code direct from an atomic clock, this makes it a stratum 1 time server as opposed to online time servers which are stratum 2 time servers, that is they get the time from a stratum 1 server and so are not as accurate.

In using a NTP time server there is only really one decision to make and that is how the time signal is to be received and for this there is only two choices:

The first is to make use of the time standard radio transmissions broadcast by national physics laboratories such as NIST in the USA or the UK’s NPL. These signals (WWVB in the US, MSF in the UK) are limited in range although the USA signal is available in most parts of Canada and Alaska. However, they are vulnerable to local interference and topography as other long wave radio signals are.

The alternative to the WWVB/MSF signal is to utilise the GPS satellite network (Global Positioning System). Atomic clocks are used by GPS satellites as the basis for navigational information used by satellite receivers. These atomic clocks can be used by using a NTP time server fitted with a GPS antenna.

Whilst the GPS time signal is strictly speaking not UTC- it is 17 seconds behind as leap seconds have never been added to GPS time (as the satellites are unreachable) but NTP can account for this (by simply adding 17 whole seconds). The advantage of GPS is that it is available anywhere on the planet just as long as the GPS antenna has a clear view of the sky.

Duel systems that can utilise both types of signal are also available.

Reasons for Atomic Clock Timing

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Atomic clocks have, unbeknown to most people, revolutionised our technology. Many of the ways we trade, communicate and travel are now solely dependent on timing from atomic clock sources.

A global community often means that we have to communicate with people on other areas of the world and in other time zones. For this purpose a universal time zone was developed, known as UTC (Coordinated Universal Time), which is based on the time told by atomic clocks.

Atomic clocks are incredibly accurate, losing only a second in every hundred million years, which is staggering when you compare it to digital clocks that will lose that much time in a week.

But why do we need such accuracy in timekeeping? Much of the technology we employ in modern times is designed for global communication. The Internet is a good example. So much trade is done across continents in fields such as the stock exchange, seat reservation and online auctioning that exact time is crucial. Imagine you are bidding for an item on the Internet and you place a bid a few seconds before the end, the last and highest bid, would it be fair to lose the item because the clock on your ISP was a little fast and the computer therefore thought the bidding was over. Or what about seat reservation; if two people on different sides of the globe book a seat at the same time, who gets the seat. This is why UTC is vital for the internet.

Other technologies too such as global positioning and air traffic control are reliant on atomic clocks to provide accuracy (and in the case of air traffic is paramount for safety). Even traffic lights and speed cameras have to be calibrated with atomic clocks otherwise speeding ticket may not be valid as they could be questioned in court.

For computer systems NTP time servers are the preferred method for receiving and distributing a source of UTC time.

Time Server Basic Questions Answered

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What is a time server?

A time server is a device that receives and distributes a single time source across a computer network for the purposes of time synchronization. These devices are often referred to as a NTP server, NTP time server, network time server or dedicated time server.

And NTP?

NTP – Network Time Protocol is a set of software instructions designed to transfer and synchronize time across LANs (Local Area Network) or WANS (Wider Area Network). NTP is one of the oldest known protocols in use today and is by far the most commonly used time synchronization application.

What timescale should I use?

Coordinated Universal Time (UTC) is a global timescale based on the time told by atomic clocks. UTC doesn’t take into account time zones and is therefore ideal for network applications as in principle by synchronizing a network to UTC you are in effect synchronizing it to every other network that utilises UTC.

Where does a time server receive the time from?

A time server can utilise the time from anywhere such as a wrist watch or wall clock. However, any sensible network administrator would opt to use a source of UTC time to ensure the network is as accurate as possible. UTC is available from several ready sources. The most used is perhaps the internet. There are many ‘time servers’ on the internet that distribute UTC time. Unfortunately, many are not at all accurate an in using an internet time source you could be leaving the network vulnerable as malicious users can take advantage of the open port in the firewall where the timing information flows.

It is far better to use a dedicated NTP time server that receives the UTC time signal external to the network and firewall. The best methods for doing this is to either use the GPS signals transmitted from space or the national time and frequency transmissions broadcast by several countries in long wave.

Computer Network Timing Solutions

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Computer networks and the internet have dramatically changed the way we live our lives. Computers are now in constant communication with each other making possible transactions such as online shopping, seat reservation and even email.

However, all this is only possible thanks to accurate network timing and in particular the use of Network Time Protocol (NTP) used to ensure all machines on a network are running the same time.

Timing synchronization is crucial for computer networks. Computers use time in the form of timestamps as the only marker to separate two events, without synchronization computers have difficulty in establishing the order of events or indeed if an event has happened or not.

Failing to synchronize a network can have untold effects. Emails may arrive before they are sent (according to the computer’s clock), data may get lost or fail to store and worst-of-all, the entire network could be vulnerable to malicious users and even fraudsters.

Synchronization with NTP is relatively straight forward as most operating systems have a version of the time protocol already installed; however, choosing a timing reference to synchronize to is more challenging.

UTC (Coordinated Universal Time) is a global timescale governed by atomic clocks and is used by nearly all computer networks across the globe. By synchronizing to UTC a computer network is essentially synchronizing the network time with ever other computer network in the world that uses UTC.

The internet has plenty of sources of UTC available but security issues with the firewall means the only safe method of receiving UTC is externally. Dedicated NTP time servers can do this using either long wave radio or GPS satellite transmissions.

Using Atomic Clocks to Synchronize a Network

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Most computer networks have to be synchronized to some degree. Allowing the clocks on computers across a network to all be telling different times is really asking for trouble. All sorts of errors can occur such as emails not arriving, data getting lost, and errors get unnoticed as the machines struggle to makes sense of the paradoxes that unsynchronized time can cause.

The problem is computers use time in the form of timestamps as the only point of reference between different events. If these don’t match then computers struggle to establish not only the order of events but also if the events took place at all.

Synchronizing a computer network together is extremely simple, thanks largely to the protocol NTP (Network Time Protocol). NTP is installed on most computer operating systems including Windows and most versions of Linux.

NTP uses a single time source and ensures that every device on the network is synchronized to that time. For many networks this single time source can be anything from the IT manager’s wrist watch to the clock on one of the desktop machines.

However, for networks that have to communicate with other networks, have to deal with time sensitive transactions or where high levels of security are required then synchronization to a UTC source is a must.

Coordinated Universal Time (UTC) is a global timescale used by industry all over the world. It is governed by a constellation of atomic clocks making it highly accurate (modern atomic clocks can keep time for 100 million years without losing a second).

For secure synchronization to UTC there is really only one method and that is to use a dedicated NTP time server. Online NTP servers are used by some network administrators but they are taking a risk not only with the accuracy of the synchronization but also with security as malicious users can imitate the NTP time signal and penetrate the firewall.

As dedicated NTP servers are external to the firewall, relying instead on the GPS satellite signal or specialist radio transmissions they are far more secure.

Differences in Time

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We are all aware of the differences in time zones. Anybody that has travelled across the Atlantic or Pacific will feel the effects of jet lag caused by having to adjust our own internal body clocks. In some countries, such as the USA, several different time zones exist in the one country meaning there are several hours difference in time from the East Coast to the West.

This difference in time zones can cause confusion although for residents of countries that straddle more than one time zone they soon adapt to the situation. However, there are more timescales and differences in time than just time zones.

Different time standards have been developed for decades to cope with time zone differences and to allow for a single time standard that the whole world can synchronize too. Unfortunately since the first time standards were developed such as British Railway Time and Greenwich Mean Time, other standards have had to be developed to cope with different applications.

One of the problem of developing a time standard is choosing what to base it on. Traditionally, all systems of time have been developed on the rotation of the Earth (24 hours). However, following the development of atomic clocks, it was soon discovered that no two days are exactly the same length and quite often they can fall short of the expected 24 hours.

New time standards where then developed based on Atomic clocks as they proved to be far more reliable and accurate than using the Earth’s rotation as a starting point. Here is a list of some of the most common time standards in use. They are divided into two types, those that are based on Earth’s rotation and those that are based on atomic clocks:

Time standards based on Earth’s rotation
True solar time is based on the solar day – is the period between one solar noon and the next.

Sidereal time is based on the stars. A sidereal day is the time it takes Earth to make one revolution with respect to the stars (not the sun).

Greenwich Mean Time (GMT) based upon when the sun is highest (noon) above the prime meridian (often called the Greenwich meridian). GMT used to be an international time standard before the advent of precise atomic clocks.

Time standards based on atomic clocks

International Atomic Time (TAI) is the international time standard from which the time standards below, including UTC, are calculated. TAI is based on a constellation of atomic clocks from all over the world.

GPS Time Also based on TAI, GPS time is the time told by atomic clocks aboard GPS satellites. Originally the same as UTC, GPS time is currently 17 seconds (precisely) behind as 17 leap seconds have been added to UTC since the satellites were launched.
Coordinated Universal Time (UTC) is based on both atomic time and GMT. Additional Leap seconds are added to UTC to counter the imprecision of Earth’s rotation but the time is derived from TAI making it as accurate.

UTC is the true commercial timescale. Computer systems all over the world synchronize to UTC using NTP time servers. These dedicated devices receive the time from an atomic clock (either by GPS or specialist radio transmissions from organisations like NIST or NPL).

Does my Computer Network Need to be Synchronized to an Atomic Clock?

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Time synchronization with network time protocol servers (NTP servers) is now a common consideration for network administrators, although, keeping exact time as told by an atomic clock on a computer network is often seen as unnecessary by some administrators

So what are the advantages of synchronizing to an atomic clock and is it necessary for your computer network?  Well the advantages of having accurate time synchronization are manifold but it is the disadvantages of not having it that are most important.

UTC time (Coordinated Universal Time) is a global timescale that is kept accurate by a constellation of atomic clocks from all over the world. It is UTC time that NTP time servers normally synchronize too. Not just that it provides a very accurate time reference to for computer networks to synchronize too but also it is used by millions of such networks across the globe therefore synchronizing to UTC is equivalent to synchronizing a computer network to every other network on the globe.

For security reasons it is imperative that all computer networks are synchronized to a stable time source. This doesn’t have to be UTC any single time source will do unless the network conducts time sensitive transactions with other networks then UTC becomes crucial otherwise errors may occur and these can vary from emails arriving before they were despatched to loss of data.  However, as UTC is governed by atomic clocks it makes it a highly accurate and auditable source of time.

Some network administrators take the shortcut of using an internet time server as a source of UTC time, forgoing the need for a dedicated NTP device. However, there are security risks in doing such a thing. Firstly, the inbuilt security mechanism used by NTP, called authentication, which confirms a time source is where and who it claims it is, is unavailable across the internet. Secondly, internet time servers are outside the firewall which means a UDP port needs to be left open to allow the time signal traffic. This can be manipulated by malicious users or viral programs.

A dedicated NTP time server is external to the network and receives the UTC atomic clock time from with either the GPS satellite system (global positioning system) or specialist radio transmissions broadcast by national physics laboratories.