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Icom aircraft radio communication program has satellite walkie talkie addressed all the essential requirements for large quality prolonged assortment communication and consequently it is deemed to be the greatest in the business.Up-to-date technology, secured communication, straightforward managing, quickly and high pace info transmission, and so forth are some of the functions which are essential for an efficient plane radio communication technique.Icom constantly designs merchandise with these attributes and continuously involve in analysis and improvement to boost the overall performance of the items.Aircraft radio communications are mission-vital programs and when you chat about such purposes, precision and high quality are of utmost relevance.Icom has a dedicated testing centre wherever each and every and every products is examined for best high quality and precision.Icom understand the require of the hour and we assist in supplying the best achievable items for all sort of aircraft radio communication wants

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Portable Icom Aviation Radio

By: Simone IcoughArticle Source: ezinearticles.com/?Aircraft-Radio-Communications&id=2499596

Researchers at the Fraunhofer Institute for High Frequency Physics and Radar Techniques (FHR; Wachtberg, Germany) have developed a standalone millimeter-wave imager (SAMMI) that can see through non-transparent materials.

According to the researchers, the imager could be used for quality control purposes as well as to analyze materials in a laboratory. Dr. Helmut Essen, head of the FHR’s millimeter-wave radar and high-frequency sensors department, said it could be used to detect wooden splinters lurking in diapers, air pockets in plastic, breaks in bars of marzipan, and foreign bodies in foodstuffs.

Inside the imager, a transmitting and a receiving antenna are mounted on each of two opposing rotating plates. when a conveyor belt transports a sample between the antennae, it is bombarded with electromagnetic waves from the transmitters at a frequency of 78 GHz. different areas of the sample then absorb the signal to different degrees. the resulting signals picked up by the transmitters can then be used to construct an image of the sample showing its composition on the scanner’s fold-out display.

At present, SAMMI is only suitable for spot checks. However, the FHR researchers are working on adapting the millimeter-wave sensor for industrial assembly lines where it could be used to automatically inspect products. they envision mounting a line of sensors over the conveyor belt, so that, in the future, products can be scanned at a speed of up to 6 m/s.

They also plant to upgrade the system to work at terahertz frequencies of 2 THz. "then we’ll be in a position not just to detect different structures but also to establish which type of plastic a product is made from. That’s not possible at the moment," says Essen.

– By Dave Wilson, Senior Editor, Vision Systems Design

Radio is one of the oldest means of communication and it is used by the people even now. there are many people around the world who use the radio now. In a radio certain frequencies has to be set so that you can listen to the station. But there are some people who hack the frequencies with the help of the radio scanner frequencies. this hacking is mainly done by the deceitful people. The radio frequencies are also used for providing the people with many types of information and news and many more. there are many radio users in the world even now so this business has been gaining grounds in the recent past. The radio is very common nowadays as many stations provide many services to their listeners.

The radio scanner frequencies are nowadays used for fun. The people across the world listen to the songs and moreover there are people who listen to the news in the radio. there are many places in the world where other medium of communication are not present and so the radio is the most common mode of communication. these radio scanner frequencies are also used for the high frequency communication for very private communications. The scanners are most common in the radio stations and so they send signals in the form of frequencies. The radio stations have been using very high level technologies for the improvement of the scanner frequencies so that their users can be provided with a very clear sound.

Toronto, Canada - GAO RFID inc. (GAORFID.com) has launched this rugged handheld HF RFID reader which is a rugged mobile computer device suitable for outdor work, in the warehouses, on the manufacturing line or anywhere asset tracking is required. Featuring a small size, light weight, long operation time and durable design, this mobile computer with HF RFID reader is ideal for workforce deployment.

This mobile computer, Model 243003, provides audio feedback, a TFT color display with touch screen, Bluetooth, barcode scanning and RFID capabilities. It operates under the Microsoft ® Windows ® CE. NET system and is equipped with a Marvell PXA270 processor operating at a frequency of 520 MHz. This rugged mobile computer is configured with either a 26 key or a 41 key alpha-numeric keypad and can be further optionally tailored to a specific application. It offers128 MB SRAM and 128 MB internal FLASH as well as a user accessible SD card slot for additional mass storage. This high frequency RFID reader provides an IP65 rating and is encapsulated within an ABS/Polycarbonate blend plastic case which offers extreme resistance to environmental stresses and a wide variety of chemical substances.

This rugged mobile computer with high frequency RFID reader belongs to GAO’s family of 13.56 MHz (HF) RFID Readers. the line includes a wide variety of RFID readers to meet customers’ different needs. Featured product in this line is High Frequency (HF) PDA CF RFID Reader/Writer. some similar products are offered for selection such as 13.56 MHz. RFID UTE Handheld Reader / Writer, 13.56 MHz HF Pistol Grip Portable Reader/Writer and Rugged Handheld RFID Reader/Mobile Computer the Jett which is an ideal solution for any number of vertical markets such as asset tracking and inventory management, event attendance or personnel access control, fleet maintenance, in the warehouse or on the hospital floor.

For sales inquiries please contact:

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About GAO RFID inc.

GAO RFID inc. (GAORFID.com) is committed to providing superior, cost-efficient and complete product lines which includes Low Frequency (LF), High Frequency (HF), Ultra High Frequency (UHF), semi-passive and active RFID labels, tags, readers, modules, antennas and RFID software. GAORFID’s products are widely deployed in such applications as parking control, railway management, building and personnel access control, event management, document control and asset tracking to name a few. GAORFID’s products, including the software, are fully customizable and scalable.

GAO RFID will be exhibiting at the RFID Journal LIVE! Conference and Exhibition. Visit us at Booth 116.

Purchasing two-way radios for commercial or personal use can prove to be a wise investment for anyone wanting a reliable cost-effective communication system. BUT, the decision as to which radio is right for you requires careful consideration.

Operating environments vary greatly from one consumer to the next and there is no such thing as a ‘one size fits all’ approach when choosing ‘the best’ radio. while they can be pricey, two-way radios are a very useful and cost-effective piece of kit to have in your communication armoury.

Before breaking out the cheque book, you need to consider:

Frequency: UHF or VHF?

It is essential to understand the frequency differences on offer so that communication is reliable and as interference free as possible depending on the environment the radios operate in. VHF, or very High Frequency, operates on frequencies in the 136 Mhz – 174 Mhz range and are typically best suited for use outside on open land or rolling hills with few trees.

UHF, or Ultra High Frequencies operate on frequencies in the 450 Mhz – 470 Mhz range and are generally more popular than VHF because they offer better range inside steel or concrete structures and crowded inner-city areas.

Licenced or Licenced-Free?

The choice between whether to invest in licenced or licence-free radios largely depends on three factors: budget, operating environment and security. Licence-free (PMR-446) radios operate on 8 general channels and share the frequencies with every other PMR-446. The only downfall with is that in certain instances anybody within range of you using a PMR446 radio has the potential to listen in to your conversation or interfere with your signal. Licence-free radios require no licence, no network, no call fees and no contract. they are an ideal cost-effective entry-level radios for anyone wanting to operate within line of sight up to approx. 3km of range.

Licenced radios usually offer increased features and improved communication with larger range and less interference. Frequencies are allocated on a case-by-case basis and can cost anything from 75-200 depending on the operating environment (i.e. rural, urban, inner-city). Licenced radios are more suited towards business use and offers additional security, making it difficult for people to listen in on the conversation.

Analogue or Digital?

Digital or analogue simply determines the way the radio signal is transmitted and received. Analogue radios are less complex than digital radios and have a better ability to communicate in cases where a received signal is weak or noisy. however, analogue operation only enables one conversation at a time on each channel.

Digital mobile radio (DMR) is a method of digitising speech and transmitting it over radio waves, whereas analogue equipment uses ‘audible speech’, digital radios ‘digitise’ the speech similar to how a mobile phone does; allowing uninterrupted two-way conversation.Users of digital radios benefit from improved speech quality, greater security, direct calling, more channels, stronger range, text messaging & longer battery life. however, digital radios are more complicated, must be designed and programmed to the same standard to be compatible with one another and considerably more expensive.

Channels required

The number of channels available on two-way radios varies with each model. If all your employees need to communicate with each other, then one channel works well. however, if you operate a business such as a hotel, you’ll want multiple channels. Then your kitchen, housekeeping, and valet service each can stay in touch on one channel with security and hotel management on another channel.

You need to determine how many different departments will be communicating among themselves and across departments when deciding how many channels your radios need.

Environment

You need to consider the environment the radio is required to operate in. If radio communication is required in potentially hazardous environments (i.e. oil refineries, chemical plants and flour mills) where the presence of inflammable gases or explosive dust creates a danger for any normal radio or electrical equipment then you need to consider ATEX radios. ATEX approved or Intrinsically Safe (IS) radios are designed to prevent the possibility of sparks being generated by high electric fields and intermittent electrical connections etc.

If the radio is likely to be submersed in water or operated in damp and dusty environments for any considerable period of time then you need to consider selecting a radio with an IP rating of 66 or above. This ensures that the equipment is protected (to varying degrees) against dust and water intrusion.

Conclusion

There are many different factors which determine the radio that’s best for you. as well as the factors above, there are many features which also need to be considered such as Man Down, GPS, Lone Worker, Voice Activation (VOX) etc.

It is fairly easy to identify the type of radio required but more difficult to pin down the exact make and model that is most suited to your needs without testing in the operating environment. many radio companies offer free on-site demonstrations and testing and also have radios which are available for hire.

This can be an ideal opportunity to try before you buy and is definitely advised before making a substantial investment.

At the age of fifteen, I obtained my first amateur radio license. I became interested in this hobby after visiting a neighbor’s home in the town where I grew up. Doug Manza had a complete Ham Shack in his house and I listened to him talk on his transceiver to other hams from around the world. I had a short wave radio that my dad had bought me and I was fascinated with this medium of communications.

Doug also introduced me to Morse code and I studied one whole summer listening to the code on a record at home. In those days, it was a requirement to learn the code which is a system of dots and dashes, in order to get a beginners license. Once I had mastered this, Doug ordered the written exam for me and I passed it and received my Novice Class license from the FCC. My call sign was WN1EYO.

To get on the air, I purchased a 75 watt HT-40 transmitter which was powerful enough to transmit for many miles on high frequency. I already had my S-120 Halicrafters receiver, so it was a matter of putting up my antenna and building my Morse code keyer. it wasn’t long before I was in operation. Code was received from all over North America and when atmospheric condition permitted, I could reach South America too. After a while, I had a whole wall of QSL cards from many hams that lived in several states and provinces.

Eventually, I wanted to talk on the radio so I purchased a Gonsett Communicator II which had frequencies for 2 meters and 6 meters. this is the same unit found in several of the civil defense shelters at that time. these were the only channels a Novice was allowed to transmit in voice and only a narrow part of the bandwidth which required certain crystals to be plugged in. this opened up a whole new world although I continued to use the Morse code at other times. I talked regularly with several different hams. My friend Burns had a teletypewriter in his shack and another by the name of Al, was blind. it amazed me that Al could take his radio completely apart and put it back together. he could also work on his car and play the piano. I visited several of the guys at their homes and went to ham meetings and get-togethers.

Later, I tested for a technician grade license and was then the owner of call sign WA1IZH. Amateur radio was a fun hobby for me. Some of the hams who advised me and supported me were Doug, Al McQuoid, Burns Getchell, Gene Merrithew and Roy MacLeod. these kind men influenced and encouraged me at my young age. I will always remember them. later, I entered a career in electronics with my first job at Honeywell in Boston.

The equipment today is far more advanced from those early days of tube radios. somehow, the challenge of building my own gear was fun and interesting back then. Some of my friends took up this hobby too. I attended gatherings from St Andrews, NB. to Swampscott, MA and met a lot of interesting people both in person and over the air waves.

SafeOne personal RF safety monitors are an effective and economical means to monitor the strength of electromagnetic (RF) fields from mobile phone towers, microwave ovens, radio and television installations, high frequency welders, and other common workplace RF sources between 10 and 10,000 MHz. the Personal RF Monitor is essential RF safety equipment in complying with FCC, OSHA, and other workplace rf safety requirements.

SafeOne personal RF safety monitors give you audio and visual warning when the IEEE and ICNIRP limit is exceeded on your body. It immediately alerts you to high frequency radiation fields that could be a health hazard. SafeOne gives an approximate value of RF strength to help you determine how long you can stay in the radiation field.

Extremely convenient to wear and use, the SafeOne personal RF safety monitor is the size of a cell phone and weighs under 3 ounces It’s smaller and much lighter than competing units
Using Your SafeOne Personal RF Monitor

Wearing Your Monitor
The SafeOne personal RF monitor should be worn on the belt with the supplied belt clip, or clipped to a harness in the included carry pouch. Position the Personal Monitor clear of metallic objects, such as a tool pouch. the SafeOne personal RF monitor should not be used with an RF protective suit.

Preparation for Use
To start using SafeOne personal RF protection, simply unscrew the battery cover on the back and insert two triple-A alkaline batteries, perform a functional test, and set desired alarm parameters.

No need to worry about the batteries – the SafeOne pocket RF monitor’s batteries can last over 500 days

The monitor incorporates a self-test function to be used whenever the monitor is turned on.

Interpreting Your Monitor
The SafeOne personal RF monitor uses a simple set of audible and visual alarms to alert you to dangerous radio frequency (RF) fields. Those alarms can be set for your convenience.

When SafeOne RF radiation monitors give an alarm, it means that your RF exposure may be above FCC, OSHA, or ICNIRP limits. When this occurs, you should leave the area and proceed in accordance with your company’s RF safety plan or consult the appropriate workplace authority.

Setting Alarm / Function Features
SafeOne has 2 alarm levels and 3 alarm functions. all functions are controlled by pressing the SELECT pushbutton. When SELECT is pushed there is audio and visual feedback.

The World Health Organization has established health hazard limits that are accepted in most parts of the world as standards. in the United States, these are standards of the FCC and OSHA. the radiofrequency exposure, Maximum Permissable Exposure (MPE) limits are divided into two levels, one for General Public use and one for persons trained to work in high frequency radiation areas, referred to as Occupational.

Your RF monitor can be set to these two alarm levels. the lower Public level is automatically chosen when SafeOne personal RF protection is turned on. To choose Occupational, press and hold the SELECT pushbutton for more than 5 seconds. the unit will respond with 10 long or 10 short beeps. the chosen level is indicated by a lighted bar.

* Normal (one beep): in this position the SafeOne personal RF safety monitor will give both audible and visual warning, when the chosen alarm limit is exceeded.
*Timer (two beeps): SafeOne will only give visual warning, when the chosen alarm limit is exceeded. After approximately 5 minutes SafeOne will beep and return to normal position.
*Silent (three beeps): SafeOne will only give visual warning when the chosen RF safety alarm limit is exceeded.

There are two major formats for two-way radios. They are Ultra High Frequency (UHF) radio and very High Frequency (VHF) radio. Neither frequency band is inherently better than the other. They each have their pluses and minuses. Both formats are effective ways to communicate with another person. but how do you decide which one will fit your needs? Let’s go over the key components of both frequencies to help you decide.

Two-way radios communicate with each other through use of radio waves. Radio waves have different frequencies, and by tuning a radio receiver to a specific frequency you can pick up a specific signal.

Radio waves are transmitted as a series of cycles, one after the other. You will always see the Hz abbreviation used to indicate the frequency of a radio. Hertz is equal to one cycle per second.

Radio waves are measured by kilohertz (kHz), which is equal to 1000 cycles per second, or megahertz (MHz), which is equal to 1,000,000 cycles per second–or 1000 kHz. the relationship between these units is like this: 1,000,000 Hertz = 1000 kilohertz = 1 megahertz.

You may also hear the term wavelength when you hear about radio waves. This term is from the early days of radio when frequencies were measured in terms of the distance between the peaks of two consecutive cycles of a radio wave instead of the number of cycles per second. lower frequencies produce a longer wavelength.

While wavelength measures distance between the peaks of cycles, frequency refers to how long the measured time is between the crest and trough of a wave arriving at the source. So frequency measures time instead of distance, but they are essentially both saying the same thing.

What is significant about wavelength for two-way radios is that it affects transmission range under certain conditions. a longer wavelength as a general rule lets a radio signal travel a greater distance.

Lower frequencies or wavelengths have greater penetrating power. That’s one of the reasons they are used for communicating with submarines. VLF radio waves (3-30 kHz) can penetrate sea water to a depth of approximately 20 meters. So a submarine at shallow depth can use these frequencies.

So from what you read above you may think VHF is always the better choice for a two-way radio no matter where you are using it. That’s not necessarily true. even though VHF has better penetrating capabilities, that doesn’t necessarily make it the better choice for buildings. Remember the conversation about wavelength above? Wavelength has a big impact on transmission.

To explain this let’s assume we are communicating from one side of a commercial building to the other. In between these two points is a metal wall with a three foot door in it. Metal is an enemy to radio waves and they typically don’t pass through it.

For our example let’s assume that the UHF wavelength the radio uses is about a foot and a half long and a similar VHF radio is around five feet long. These are in the ballpark of their normal wavelengths.

When the UHF transmits its signal the foot and a half long wave will pass through the door since the door is wider than the wavelength. the VHF signal will be totally reflected since it is wider than the opening to the door.

Your microwave oven is an example of this. the glass front door has a metal mesh with very small holes. Microwaves being a very high frequency have wavelengths that are only several inches long. the mesh keeps the microwaves trapped in the oven but it allows you to see inside because light waves have a microscopic wavelength.

Just imagine walking through the building carrying a five foot wide pole. You will encounter the same challenges a VHF signal encounters. now imagine walking through the building with a pole that’s only a foot and a half wide like a UHF wave. there are lots fewer doorways you couldn’t get through.

The one difference is that wireless signals will penetrate through drywall, masonry, human bodies, furniture, wall paneling, and other solid objects. All these objects will reduce the signal strength though. the more dense the object, the more it reduces the signal. VHF will penetrate these obstacles better than UHF, but that doesn’t necessarily mean that VHF is better for indoor applications as we will talk about in the UHF section below.

In our example above we assumed you had a metal wall with an opening. if you reverse this and you have a three foot metal object in front of the transmitting radio, then VHF would win. since the object is three foot wide it will totally block the UHF signal whereas the VHF signal will get around it. lower frequencies such as VHF diffract around large smooth obstacles more easily, and they also travel more easily through brick and stone.

For most applications, lower radio frequencies are better for longer range. a broadcasting TV station illustrates this. a typical VHF station operates at about 100,000 watts and has a coverage radius range of about 60 miles. a UHF station with a 60-mile coverage radius requires transmitting at 3,000,000 watts.

So there is no clear choice for which is better, VHF or UHF. there is a lot of black magic to radio technology so it’s not always easy to tell which will work better for your application. To help you decide on the best technology for you, more detail about each one is included below.

UHF Radio

UHF equipment operates between the frequencies of 300 MHz and 3000 MHz. until recently, it wasn’t widely used. now, the UHF radio frequency is used for GPS, Bluetooth, cordless phones, and WiFi.

There are more available channels with UHF so in more populated areas UHF may be less likely to have interference from other systems. if you are in an area where population is thin, VHF should work fine for you. not too long ago the FCC also opened up a new VHF frequency called MURS that is so far not heavily used in most areas. There’s more about MURS below in the VHF section. if you are in an area where interference from other radios may be an issue, UHF transmitters and receivers could be your best choice unless you use a MURS VHF radio. UHF is better at squeezing through physical barriers like walls, buildings, and rugged landscape. Anything that obstructs a radio wave, will weaken a radio signal. UHF lessens that effect. Though it may not travel as far, UHF radio waves will traverse around obstacles better than VHF.

To highlight the differences in indoor range, below is an excerpt from a brochure of a leading two-way radio maker on the predicted range of one of their lines of handheld VHF and UHF two-way radios:

Coverage estimates: At full power, line-of-sight, no obstructions the range is approximately 4+ miles. Indoor coverage at VHF is approximately 270,000 sq ft and 300,000 sq ft at UHF. Expect about 20 floors vertical coverage at VHF and up to 30 floors at UHF. Note: Range and coverage are estimates and are not guaranteed.

VHF waves are not very good at finding their way around walls, buildings and rugged landscape. therefore range will be significantly reduced for VHF radios in these environments. That may not necessarily be a problem if the range needed is only a few hundred feet. You can also add an external antenna to an indoor VHF base station that will reduce or eliminate this problem.

One of the downsides to UHF is that the FCC requires you to get a license to operate in these frequencies. Although many frequencies in the VHF business band also require a license. if you choose a radio in the VHF MURS frequencies you can operate it without a license. UHF equipment is usually more expensive. the components need to be finely tuned and are more expensive to construct. This does not mean it’s necessarily better, just more expensive.

One advantage of UHF transmission is the physically short wave that is produced by the high frequency. That means the antenna on the radio can be shorter than an equivalent VHF radio.

VHF Radio

VHF equipment operates between the frequencies of 30 MHz and 300 MHz. FM radio, two-way radios, and television broadcasts operate in this range.

Both UHF and VHF radios are prone to line of sight factors, but VHF a little more so. the waves make it through trees and rugged landscapes, but not as well as UHF frequencies do. however, if a VHF wave and a UHF wave were transmitted over an area without barriers, the VHF wave would travel almost twice as far. This makes VHF easier to broadcast over a long range. if you are working mostly outdoors, a VHF radio is probably the best choice, especially if you are using a base station radio indoors and you add the external antenna.

Since VHF has been around longer and isn’t as complicated to make, equipment is usually cheaper when compared to similar UHF equipment. one disadvantage to this equipment can be its size. since the frequency waves are bigger, an antenna must be bigger.

VHF radios also have a smaller number of available frequencies. Interference with other radios could be more likely to be a problem. however, the FCC recently made this less of a problem when they opened up the MURS frequencies. the 150 MHz frequency is a Citizens Band radio spectrum that is called the MURS service. MURS stands for Multi-Use Radio Service. This service is for use in the United States and Canada. It is a low power, short range service in the VHF 150 MHz Citizens Band radio spectrum. there are 5 channels in the MURS frequencies with 38 privacy codes under each one that enable you to only pick up conversations on your code. the FCC does not require users of products for MURS to be licensed.

With MURS you can add a larger or external antenna to improve range. if you want to put an antenna on top of your house or business, you can do it with MURS. some antenna manufacturers claim an external antenna can increase the effective radiated power of a transmitter by a factor of 4. These MURS intercoms can transmit up to four miles, and perhaps more with an external antenna depending on the terrain.

One benefit of VHF wireless radios is that battery life is almost always better than for similar UHF units. For handheld radios this is a plus.

VHF equipment is usually lower cost for those on a budget. Equipment can be more economical than similar UHF products.

In summary, if you are planning on using your two-way radios mainly inside buildings, then UHF is likely the best solution for you. if you are mainly using your two-way radios for communication outside, then VHF would be a good choice. either radio technology can work for you if you don’t really have a long range to cover. In that case you may want to choose VHF for it’s lower cost.

Flex Semi Dry

How it works

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Coaxial cable cutaway

Like any electrical power cord, coaxial cable conducts AC electric current between locations. Like these other cables, it has two conductors, the central wire and the tubular shield. At any moment the current is traveling outward from the source in one of the conductors, and returning in the other. however, since it is alternating current, the current reverses direction many times a second. Coaxial cable differs from other cable because it is designed to carry radio frequency current. This has a frequency much higher than the 50 or 60 Hz used in mains (electric power) cables, reversing direction millions to billions of times per second. Like other types of radio transmission line, this requires special construction to prevent power losses:

If an ordinary wire is used to carry high frequency currents, the wire acts as an antenna, and the high frequency currents radiate off the wire as radio waves, causing power losses. To prevent this, in coaxial cable one of the conductors is formed into a tube and encloses the other conductor. This confines the radio waves from the central conductor to the space inside the tube. To prevent the outer conductor, or shield, from radiating, it is connected to electrical ground, keeping it at a constant potential.

The dimensions and spacing of the conductors are uniform. Any abrupt change in the spacing of the two conductors along the cable tends to reflect radio frequency power back toward the source, causing a condition called standing waves. This acts as a bottleneck, reducing the amount of power reaching the destination end of the cable. To hold the shield at a uniform distance from the central conductor, the space between the two is filled with a semirigid plastic dielectric. Manufacturers specify a minimum bend radius to prevent kinks that would cause reflections. The connectors used with coax are designed to hold the correct spacing through the body of the connector.

Each type of coaxial cable has a characteristic impedance depending on its dimensions and materials used, which is the ratio of the voltage to the current in the cable. in order to prevent reflections at the destination end of the cable from causing standing waves, any equipment the cable is attached to must present an impedance equal to the characteristic impedance (called ‘matching’). Thus the equipment “appears” electrically similar to a continuation of the cable, preventing reflections. Common values of characteristic impedance for coaxial cable are 50 and 75 ohms.

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Coaxial cable design choices affect physical size, frequency performance, attenuation, power handling capabilities, flexibility, strength and cost. The inner conductor might be solid or stranded; stranded is more flexible. To get better high-frequency performance, the inner conductor may be silver plated. Sometimes copper-plated iron wire is used as an inner conductor.

The insulator surrounding the inner conductor may be solid plastic, a foam plastic, or may be air with spacers supporting the inner wire. The properties of dielectric control some electrical properties of the cable. a common choice is a solid polyethylene (PE) insulator, used in lower-loss cables. Solid Teflon (PTFE) is also used as an insulator. some coaxial lines use air (or some other gas) and have spacers to keep the inner conductor from touching the shield.

Conventional coaxial cable has braided copper wire forming the shield. This allows the cable to be flexible, but it also means there are gaps in the shield layer, and the inner dimension of the shield varies slightly because the braid cannot be flat. Sometimes the braid is silver plated. For better shield performance, some cables have a double-layer shield. The shield might be just two braids, but it is more common now to have a thin foil shield covered by a wire braid. some cables may invest in more than two shield layers, such as “quad-shield” which uses four alternating layers of foil and braid. other shield designs sacrifice flexibility for better performance; some shields are a solid metal tube. those cables cannot take sharp bends, as the shield will kink, causing losses in the cable.

Coaxial cables require an internal structure of an insulating (dielectric) material to maintain the spacing between the center conductor and shield. The dielectric losses increase in this order: Ideal dielectric (no loss), vacuum, air, Polytetrafluoroethylene (PTFE), polyethylene foam, and solid polyethylene. a low relative permittivity allows for higher frequency usage. an inhomogeneous dielectric needs to be compensated by a non-circular conductor to avoid current hot-spots.

Most cables have a solid dielectric; others have a foam dielectric which contains as much air as possible to reduce the losses. Foam coax will have about 15% less attenuation but can absorb moisturespecially at its many surfacesn humid environments, increasing the loss. Stars or spokes are even better but more expensive. Still more expensive were the air spaced coaxials used for some inter-city communications in the middle 20th Century. The center conductor was suspended by polyethylene discs every few centimeters. in a miniature coaxial cable such as an RG-62 type, the inner conductor is supported by a spiral strand of polyethylene, so that an air space exists between most of the conductor and the inside of the jacket. The lower dielectric constant of air allows for a greater inner diameter at the same impedance and a greater outer diameter at the same cutoff frequency, lowering ohmic losses. inner conductors are sometimes silver plated to smooth the surface and reduce losses due to skin effect. a rough surface prolongs the path for the current and concentrates the current at peaks and thus increases ohmic losses.

The insulating jacket can be made from many materials. a common choice is PVC, but some applications may require fire-resistant materials. Outdoor applications may require the jacket to resist ultraviolet light and oxidation. For internal chassis connections the insulating jacket may be omitted.

The ends of coaxial cables are usually made with RF connectors.

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Open wire transmission lines have the property that the electromagnetic wave propagating down the line extends into the space surrounding the parallel wires. these lines have low loss, but also have undesirable characteristics. they cannot be bent, twisted or otherwise shaped without changing their characteristic impedance, causing reflection of the signal back toward the source. they also cannot be run along or attached to anything conductive, as the extended fields will induce currents in the nearby conductors causing unwanted radiation and detuning of the line. Coaxial lines solve this problem by confining the electromagnetic wave to the area inside the cable, between the center conductor and the shield. The transmission of energy in the line occurs totally through the dielectric inside the cable between the conductors. Coaxial lines can therefore be bent and moderately twisted without negative effects, and they can be strapped to conductive supports without inducing unwanted currents in them. in radio-frequency applications up to a few gigahertz, the wave propagates primarily in the transverse electric magnetic (TEM) mode, which means that the electric and magnetic fields are both perpendicular to the direction of propagation. however, above a certain cutoff frequency, transverse electric (TE) and/or transverse magnetic (TM) modes can also propagate, as they do in a waveguide. it is usually undesirable to transmit signals above the cutoff frequency, since it may cause multiple modes with different phase velocities to propagate, interfering with each other. The outer diameter is roughly inversely proportional to the cutoff frequency. a propagating surface-wave mode that does not involve or require the outer shield but only a single central conductor also exists in coax but this mode is effectively suppressed in coax of conventional geometry and common impedance. Electric field lines for this TM mode have a longitudinal component and require line lengths of a half-wavelength or longer.

A coaxial connector (male N-type).

Main article: RF connector

Coaxial connectors are designed to maintain a coaxial form across the connection and have the same well-defined impedance as the attached cable. Connectors are often plated with high-conductivity metals such as silver or gold. Due to the skin effect, the RF signal is only carried by the plating and does not penetrate to the connector body. Although silver oxidizes quickly, the silver oxide that is produced is still conductive. while this may pose a cosmetic issue, it does not degrade performance.

important parameters

Coaxial cable is a particular kind of transmission line, so the circuit models developed for general transmission lines are appropriate. See Telegrapher’s equation.

Schematic representation of the elementary components of a transmission line.

Schematic representation of a coaxial transmission line, showing the characteristic impedance Z0.

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Outside diameter of inner conductor, d.

Inside diameter of shield, D.

Dielectric constant of the insulator, . The dielectric constant is often quoted as the relative dielectric constant r referred to the dielectric constant of free space 0: = r0. when the insulator is a mixture of different dielectric materials (e.g., polyethylene foam is a mixture of polyethylene and air), then the term effective dielectric constant eff is often used.

Magnetic permeability of the insulator. Permeability is often quoted as the relative permeability r referred to the permeability of free space 0: = r0. The relative permeability will almost always be 1.

Fundamental electrical parameters

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Shunt Capacitance per unit length, in farads per metre.

Series Inductance per unit length, in Henrys per metre.

Series Resistance per unit length, in ohms per metre. The resistance per unit length is just the resistance of inner conductor and the shield at low frequencies. At higher frequencies, skin effect increases the effective resistance by confining the conduction to a thin layer of each conductor.

Shunt Conductance per unit length, in siemens per metre. The shunt conductance is usually very small because insulators with good dielectric properties are used (a very low loss tangent). At high frequencies, a dielectric can have a significant resistive loss.

Derived electrical parameters

Characteristic impedance in ohms (). Neglecting resistance per unit length for most coaxial cables, the characteristic impedance is determined from the capacitance per unit length (C) and the inductance per unit length (L). The simplified expression is (). those parameters are determined from the ratio of the inner (d) and outer (D) diameters and the dielectric constant (). The characteristic impedance is given by

Assuming the dielectric properties of the material inside the cable do not vary appreciably over the operating range of the cable, this impedance is frequency independent above about five times the shield cutoff frequency. For typical coaxial cables, the shield cutoff frequency is 600 (RG-6A) to 2,000 Hz (RG-58C).

Attenuation (loss) per unit length, in decibels per meter. This is dependent on the loss in the dielectric material filling the cable, and resistive losses in the center conductor and outer shield. these losses are frequency dependent, the losses becoming higher as the frequency increases. Skin effect losses in the conductors can be reduced by increasing the diameter of the cable. a cable with twice the diameter will have half the skin effect resistance. Ignoring dielectric and other losses, the larger cable would halve the dB/meter loss. in designing a system, engineers consider not only the loss in the cable, but also the loss in the connectors.

Velocity of propagation, in meters per second. The velocity of propagation depends on the dielectric constant and permeability (which is usually 1).

Cutoff frequency is determined by the possibility of exciting other propagation modes in the coaxial cable. The average circumference of the insulator is (D + d) / 2. make that length equal to 1 wavelength in the dielectric. The TE01 cutoff frequency is therefore

Outside diameter, which dictates which connectors must be used to terminate the cable.

Significance of impedance

The best coaxial cable impedances in high-power, high-voltage, and low-attenuation applications were experimentally determined in 1929 at Bell Laboratories to be 30, 60, and 77 respectively. For an air dielectric coaxial cable with a diameter of 10 mm the attenuation is lowest at 77 ohms when calculated for 10 GHz. The curve showing the power handling maxima at 30 ohms can be found here:

CATV systems were one of the first applications for very large quantities of coaxial cable. CATV is typically using such low levels of RF power that power handling and high voltage breakdown characteristics were totally unimportant when compared to attenuation. moreover, many CATV headends used 300 ohm folded dipole antennas to receive off the air TV signals. 75 ohm coax made a nice 4:1 balun transformer for these antennas as well as presented a nice attenuation specification. But this is a bit of a red herring, when normal dielectrics are added to the equation the best loss impedance drops down to values between 64 and 52 ohms. Details and a graph showing this effect can be found here: [citation needed] 30 cable is more difficult to manufacture due to the much larger center conductor and the stiffness and weight it adds.

The arithmetic mean between 30 ohms and 77 ohms is 53.5, the geometric mean is 48 ohms. The selection of 50 ohms as a compromise between power handling capability and attenuation is generally cited as the reason for the number.

One reference to a paper presented by Bird Electronic Corp as to why 50 ohms was chosen can be found here:50 Ohms works out well for other reasons such as it corresponds very closely to the drive impedance of a half wave dipole antenna in real environments, and provides an acceptable match to the drive impedance of quarter wave monopoles as well. 73 is an exact match for a centre fed dipole aerial/antenna in free space (approximated by very high dipoles without ground reflections).

RG-62 is a 93 ohm coaxial cable. it is purported that RG-62 cable was originally used in mainframe computer networks. (1970′s / early 1980s). it was the cable used to connect the terminals to the terminal cluster controllers. later some manufacturers of LAN equipment such as ARCNET adopted RG-62 as a standard. it has the lowest capacitance per unit length when compared to other coaxial cables of similar size. Capacitance is the enemy of square wave data transmission and is much more important than power handling or attenuation specifications in these environments.

All of the components of a coaxial system should have the same impedance to reduce internal reflections at connections between components. Such reflections increase signal loss and can result in the reflected signal reaching a receiver with a slight delay from the original. in analog video or TV systems this visual effect is commonly referred to as ghosting. (see Impedance matching)

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Signal leakage is the passage of electromagnetic fields through the shield of a cable and occurs in both directions. Ingress is the passage of an outside signal into the cable and can result in noise and disruption of the desired signal. Egress is the passage of signal intended to remain within the cable into the outside world and can result in a weaker signal at the end of the cable and radio frequency interference to nearby devices.

For example, in the United States, signal leakage from cable television systems is regulated by the FCC, since cable signals use the same frequencies as aeronautical and radionavigation bands. CATV operators may also choose to monitor their networks for leakage to prevent ingress. Outside signals entering the cable can cause unwanted noise and picture ghosting. Excessive noise can overwhelm the signal, making it useless.

An ideal shield would be a perfect conductor with no holes, gaps or bumps connected to a perfect ground. however, a smooth solid copper shield would be heavy, inflexible, and expensive. Practical cables must make compromises between shield efficacy, flexibility and cost, such as the corrugated surface of hardline, flexible braid, or foil shields. Since the shields are not perfect conductors, electric fields can exist inside the shield, thus allowing radiating electromagnetic fields to go through the shield.

Consider the skin effect. The magnitude of an alternating current in a conductor decays exponentially with distance beneath the surface, with the depth of penetration being proportional to the square root of the resistivity. This means that in a shield of finite thickness, some small amount of current will still be flowing on the opposite surface of the conductor. With a perfect conductor (i.e., zero resistivity), all of the current would flow at the surface, with no penetration into and through the conductor. Real cables have a shield made of an imperfect, although usually very good, conductor, so there will always be some leakage.

The gaps or holes, allow some of the electromagnetic field to penetrate to the other side. For example, braided shields have many small gaps. The gaps are smaller when using a foil (solid metal) shield, but there is still a seam running the length of the cable. Foil becomes increasingly rigid with increasing thickness, so a thin foil layer is often surrounded by a layer of braided metal, which offers greater flexibility for a given cross-section.

This type of leakage can also occur at locations of poor contact between connectors at either end of the cable.

A continuous current flow, even if small, along the imperfect shield of a coaxial cable can cause visible or audible interference. in CATV systems distributing analog signals the potential difference between the coaxial network and the electrical grounding system of a house can cause a visible “hum bar” in the picture. This appears as a wide horizontal distortion bar in the picture that scrolls slowly upward. Such differences in potential can be reduced by proper bonding to a common ground at the house. See ground loop.

External current sources like switched-mode power supplies create a voltage across the inductance of the outer conductor between sender and receiver. The effect is less when there are several parallel cables, as this reduces the inductance and therefore the voltage. Because the outer conductor carries the reference potential for the signal on the inner conductor, the receiving circuit measures the wrong voltage.

The transformer effect is sometimes used to mitigate the effect of currents induced in the shield. The inner and outer conductors form the primary and secondary winding of the transformer, and the effect is enhanced in some high quality cables that have an outer layer of mu-metal. Because of this 1:1 transformer, the aforementioned voltage across the outer conductor is transformed onto the inner conductor so that the two voltages can be cancelled by the receiver. many sender and receivers have means to reduce the leakage even further. they increase the transformer effect by passing the whole cable through a ferrite core sometimes several times.

Common mode current and radiation

Common mode current occurs when stray currents in the shield flow in the same direction as the current in the center conductor, causing the coax to radiate.

Most of the shield effect in coax results from opposing currents in the center conductor and shield creating opposite magnetic fields that cancel, and thus do not radiate. The same effect helps ladder line. however, ladder line is extremely sensitive to surrounding metal objects which can enter the fields before they completely cancel. Coax does not have this problem since the field is enclosed in the shield. however, it is still possible for a field to form between the shield and other connected objects, such as the antenna the coax feeds. The current formed by the field between the antenna and the coax shield would flow in the same direction as the current in the center conductor, and thus not be canceled, and would actually cause energy to radiate from the coax itself, making it appear to be part of the antenna, affecting the radiation pattern of the antenna and possibly introducing dangerous radio frequency energy into areas near people, with the risk of radiation burns if the coax is being used for sufficiently high power transmissions. a properly placed and sized balun can prevent common mode radiation in coax.

Some senders and receivers use only a limited range of frequencies and block all others by means of an isolating transformer. Such a transformer breaks the shield for high frequencies. Still others avoid the transformer effect altogether by using two capacitors. If the capacitor for the outer conductor is implemented as one thin gap in the shield, no leakage at high frequencies occurs. At high frequencies, beyond the limits of coaxial cables, it becomes more efficient to use other types of transmission line such as wave guides or optical fiber, which offer low leakage (and much lower losses) around 200 THz and good isolation for all other frequencies.

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Most coaxial cables have a characteristic impedance of either 50, 52, 75, or 93 . The RF industry uses standard type-names for coaxial cables. Thanks to television, RG-6 is the most commonly-used coaxial cable for home use, and the majority of connections outside Europe are by F connectors.

A series of standard types of coaxial cable were specified for military uses, in the form “RG-#” or “RG-#/U”. they date from WW II and were listed in MIL-HDBK-216 published in 1962. these designations are now obsolete. The RG designation stands for Radio Guide, the U designation stands for Universal. The current military standard is MIL-SPEC MIL-C-17. MIL-C-17 numbers, such as “M17/75-RG214,” are given for military cables and manufacturer’s catalog numbers for civilian applications. however, the RG-series designations were so common for generations that they are still used, although critical users should be aware that since the handbook is withdrawn there is no standard to guarantee the electrical and physical characteristics of a cable described as “RG-# type”. The RG designators are mostly used to identify compatible connectors that fit the inner conductor, dielectric, and jacket dimensions of the old RG-series cables.

Table of RG standards

Low loss at high frequency for cable television, satellite television and cable modems

This is “quad shield RG-6″. it has four layers of shielding; regular RG-6 only has one or two

Amateur radio; Thicknet (10BASE5) is similar

A thinner version, with the electrical characteristics of RG-8U in a diameter similar to RG-6

Used for long drops and underground conduit

Used for radiocommunication and amateur radio, thin Ethernet (10BASE2) and NIM electronics. Common.

Used to carry baseband video in closed-circuit television, previously used for cable television. Generally it has poor shielding but will carry an HQ HD signal or video over short distances.

Used for high-definition cable TV and high-speed cable Internet.

Used for ARCNET and automotive radio antennas.

Used for NIM electronics

Common for wifi pigtails: more flexible but higher loss than RG58; used with LEMO 00 connectors in NIM electronics.

(Ag plated Cu clad Steel)

70.0296 in Cu

For radiocommunication and amateur radio, EMC test antenna cables. Typically lower loss than RG58. Common.

0.195 in Cu

Large diameter, not very flexible, low loss (2.5dB/100′ @ 400 MHz), 11kV dielectric withstand.

Sample RG-223 Datasheet

used with LEMO 00 connectors in NIM electronics;

PE is Polyethylene; PTFE is Polytetrafluoroethylene; ASP is Air Space Polyethylene

Commercial designations

lower loss at high frequency for radiocommunication and amateur radio

low loss at high frequency for radiocommunication and amateur radio

low loss drop-in replacement for RG-58

low loss communications, 0.554 dB/meter @ 2.4 GHz

low loss communications, 0.223 dB/meter @ 2.4 GHz

low loss communications, 0.144 dB/meter @ 2.4 GHz

low loss communications, 0.098 dB/meter @ 2.4 GHz

low loss communications, 0.075 dB/meter @ 2.4 GHz

low loss communications, 0.056 dB/meter @ 2.4 GHz

There are also other designation schemes for coaxial cables such as The URM, CT and WF series

References for this section

RF transmission lines and fittings. Military Standardization Handbook MIL-HDBK-216, U.S. Department of Defense, 4 January 1962.Withdrawal Notice for MIL-HDBK-216 2001

Cables, radio frequency, flexible and rigid. Details Specification MIL-DTL-17H, 19 August 2005 (superseding MIL-C-17G, 9 March 1990).Radio-frequency cables, International Standard IEC 60096.

Coaxial communication cables, International Standard IEC 61196.

Coaxial cables, British Standard BS EN 50117

H. P. Westman et al., (ed), Reference Data for Radio Engineers, Fifth Edition, 1968, Howard W. Sams and co., no ISBN, Library of Congress Card No. 43-14665

rfcafe.com/references/electrical/coax-chart.htm

Talley Communications CAxT Cable Assembly

Specs for MIL-C-17 Coaxial Cable Q.P.L.

Times Microwave Systems LMR Wireless Products Catalog

CFD Cable Specifications

Specs of RG174/U, RG58C/U etc.

RG213/8, RG218, CLX1/4″, CLX1/2″, CLX7/8″, CLX1+5/8″ Cable Power & Impedance Specs

Velocity factor of various coaxial cables

Pasternack 2009 Catalog

Union Copper site with pictures, diagrams, and spec sheet

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Short coaxial cables are commonly used to connect home video equipment, in ham radio setups, and in measurement electronics. they used to be common for implementing computer networks, in particular Ethernet, but twisted pair cables have replaced them in most applications except in the growing consumer cable modem market for broadband Internet access.

Long distance coaxial cable is used to connect radio networks and television networks, though this has largely been superseded by other more high-tech methods (fibre optics, T1/E1, satellite). it still carries cable television signals to the majority of television receivers, and this purpose consumes the majority of coaxial cable production.

Micro coaxial cables are used in a range of consumer devices, military equipment, and also in ultra-sound scanning equipment.

The most common impedances that are widely used are 50 or 52 ohms, and 75 ohms, although other impedances are available for specific applications. The 50 / 52 ohm cables are widely used for industrial and commercial two-way radio frequency applications (including radio, and telecommunications), although 75 ohms is commonly used for broadcast television and radio.

Hard line is often confused with waveguide but the two are not the same. Hard line is used in broadcasting as well as many other forms of radio communication. it is a coaxial cable constructed using round copper, silver or gold tubing or a combination of such metals as a shield. some lower quality hard line may use aluminum shielding, aluminum however is easily oxidized and unlike silver or gold oxide, aluminum oxide drastically loses effective conductivity. therefore all connections must be air and water tight. The center conductor may consist of solid copper, or copper plated aluminum. Since skin effect is an issue with RF, copper plating provides sufficient surface for an effective conductor. most varieties of hardline used for external chassis or when exposed to the elements have a PVC jacket; however, some internal applications may omit the insulation jacket. Hard line can be very thick, typically at least a half inch or 13 mm and up to several times that, and has low loss even at high power. these large scale hard lines are almost always used in the connection between a transmitter on the ground and the antenna or aerial on a tower. Hard line may also be known by trademarked names such as Heliax (Andrew), or Cablewave (RFS/Cablewave). Larger varieties of hardline may consist of a center conductor which is constructed from either rigid or corrugated copper tubing. The dielectric in hard line may consist of polyethylene foam, air or a pressurized gas such as nitrogen or desiccated air (dried air). in gas-charged lines, hard plastics such as nylon are used as spacers to separate the inner and outer conductors. The addition of these gases into the dielectric space reduces moisture contamination, provides a stable dielectric constant, as well as a reduced risk of internal arcing. Gas-filled hardlines are usually used on high powered RF transmitters such as television or radio broadcasting, military transmitters, as well as high powered amateur radio applications but may also be used on some critical lower powered applications such as those in the microwave bands. Although in the microwave region waveguide is more often used than hard line for transmitter to antenna, or antenna to receiver applications. The various shields used in hardline also differ; some forms use rigid tubing, or pipe, others may use a corrugated tubing which makes bending easier, as well as reduces kinking when the cable is bent to conform. Smaller varieties of hard line may be used internally in some high frequency applications, particularly in equipment within the microwave range, to reduce interference between stages of the device.

Main article: Leaky feeder

Radiating or Leaky Cable is another form of coaxial cable which is constructed in a similar fashion to hard line, however it is constructed with tuned slots cut into the shield. these slots are tuned to the specific RF wavelength of operation or tuned to a specific radio frequency band. This type of cable is to provide a tuned bi-directional “desired” leakage effect between transmitter and receiver. it is often used in elevator shafts, underground, transportation tunnels and in other areas where an antenna is not feasible. One example of this type of cable is Radiax (Andrew).

RG/6 is available in three different types designed for various applications. “Plain” or “house” wire is designed for indoor or external house wiring. “Flooded” cable is infused with heavy waterproofing for use in underground conduit (ideally) or direct burial. “Messenger” may contain some waterproofing but is distinguished by the addition of a steel messenger wire along its length to carry the tension involved in an aerial drop from a utility pole.

Main article: Triaxial cable

Triaxial cable or triax is coaxial cable with a third layer of shielding, insulation and sheathing. The outer shield, which is earthed (grounded), protects the inner shield from electromagnetic interference from outside sources.

Main article: Twinaxial cabling

Twin-axial cable or twinax is a balanced, twisted pair within a cylindrical shield. it allows a nearly perfect differential signal which is both shielded and balanced to pass through. Multi-conductor coaxial cable is also sometimes used.

Main article: Twin-lead

Biaxial cable, biax or Twin-Lead is a figure-8 configuration of two 50 coaxial cables, externally resembling that of lamp cord, or speaker wire. Biax is used in some proprietary computer networks. others may be familiar with 75 biax which at one time was popular on many cable TV services.

Semi-rigid cable is a coaxial form using a solid copper outer sheath. This type of coax offers superior screening compared to cables with a braided outer conductor, especially at higher frequencies. The major disadvantage is that the cable, as its name implies, is not very flexible, and is not intended to be flexed after initial forming. (See “hard line”)

Conformable cable is a flexible reformable alternative to semi-rigid coaxial cable used where flexibility is required. Conformable cable can be stripped and formed by hand withouth the need for specialist tools, similar to standard coaxial cable.

Interference and troubleshooting

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Coaxial cable insulation may degrade, requiring replacement of the cable, especially if it has been exposed to the elements on a continuous basis. The shield is normally grounded, and if even a single thread of the braid or filament of foil touches the center conductor, the signal will be shorted causing significant or total signal loss. This most often occurs at improperly installed end connectors and splices. Also, the connector or splice must be properly attached to the shield, as this provides the path to ground for the interfering signal.

Despite being shielded, interference can occur on coaxial cable lines. Susceptibility to interference has little relationship to broad cable type designations (e.g. RG-59, RG-6) but is strongly related to the composition and configuration of the cable’s shielding. For cable television, with frequencies extending well into the UHF range, a foil shield is normally provided, and will provide total coverage as well as high effectiveness against high-frequency interference. Foil shielding is ordinarily accompanied by a tinned copper or aluminum braid shield, with anywhere from 60 to 95% coverage. The braid is important to shield effectiveness because (1) it is more effective than foil at absorbing low-frequency interference, (2) it provides higher conductivity to ground than foil, and (3) it makes attaching a connector easier and more reliable. “Quad-shield” cable, using two low-coverage aluminum braid shields and two layers of foil, is often used in situations involving troublesome interference, but is less effective than a single layer of foil and single high-coverage copper braid shield such as is found on broadcast-quality precision video cable.

In the United States and some other countries, cable television distribution systems use extensive networks of outdoor coaxial cable, often with in-line distribution amplifiers. Leakage of signals into and out of cable TV systems can cause interference to cable subscribers and to over-the-air radio services using the same frequencies as those of the cable system.

1866 first successful transatlantic cable, designed by William Thomson (Lord Kelvin, 1892); see Submarine communications cable.

1880 Coaxial cable patented in England by Oliver Heaviside, patent no. 1,407.

1884 Siemens & Halske patent coaxial cable in Germany (Patent No. 28,978, 27 March 1884).

1894 Oliver Lodge demonstrates waveguide transmission at the Royal Institution. Nikola Tesla receives U.S. Patent 0,514,167, Electrical Conductor, on February 6.

1929 first modern coaxial cable patented by Lloyd Espenschied and Herman Affel of AT&T’s Bell Telephone Laboratories, U.S. Patent 1,835,031.

1936 first transmission of TV pictures on coaxial cable, from the 1936 Summer Olympics in Berlin to Leipzig.

1936 World’s first underwater coaxial cable installed between Apollo Bay, near Melbourne, Australia, and Stanley, Tasmania. The 300 km cable can carry one broadcast channel and seven telephone channels.

1936 AT&T installs experimental coaxial telephone and television cable between new York and Philadelphia, with automatic booster stations every ten miles. Completed in December, it can transmit 240 telephone calls simultaneously.

1936 Coaxial cable laid by the General Post Office (now BT) between London and Birmingham, providing 40 telephone channels.

1941 first commercial use in USA by AT&T, between Minneapolis, Minnesota and Stevens Point, Wisconsin. L1 system with capacity of one TV channel or 480 telephone circuits.

1956 first transatlantic coaxial cable laid, TAT-1.

Radio frequency power transmission

^ Nahin, Paul J. (2002). Oliver Heaviside: The Life, Work, and Times of an Electrical Genius of the Victorian Age. ISBN 0801869099. 

^ smarthome.com/7807R/Right-Angle-F-Connector-Adapters-6-Pack-2125/p.aspx

^ Elmore, William C.; Heald, mark a. (1969). Physics of Waves. ISBN 0486649261. 

^ Ott, Henry W. (1976). Noise Reduction Techniques in Electronic Systems. ISBN 0471657263. 

^ RF Cafe – Coaxial Cable Specifications Cables Chart

^ “Radio City Inc”. radioinc.com/oscmax/catalog/product_info.php?name=LMR 400 UltraFlex (RG-8) 100 ft pre-cut&products_id=1121. 

^ “Andrew Heliax”. commscope.com/andrew/eng/product/trans_line_sys/coaxial/wireless/1206774_13612.html. 

^ “Cablewave Radio Frequency Systems (rfsworld.com)”. rfsworld.com/. 

^ “Andrew Radiax”. commscope.com/andrew/eng/product/trans_line_sys/coaxial/radiating/1206639_13611.html. 

^ IEEE – IEEE History Center: Landing of the Transatlantic Cable, 1866

^ Atlantic-cable.com – History of the Atlantic Cable & Undersea Communications from the first submarine cable of 1850 to the worldwide fiber optic network

^ HistoryMagazine.com – The Transatlantic Cable

^ PBS.org – The first Attempts to Lay the Transatlantic Cable (1857-1858)

^ Britannica.com – transatlantic cable

^ Google Book Search – Oliver Heaviside By Paul J. Nahin

^ Feldenkirchen, Wilfried (1994). Werner von Siemens – Inventor and International Entrepreneur. ISBN 0814206581. 

^ “Coaxial Debut,” Time, Dec. 14, 1936.

^ Boing Boing – Gallery: an illustrated history of the transoceanic cable

^ Google books – Broadcast engineer’s reference book By Edwin Paul J. Tozer

^ Radio-electronics.com – Coaxial feeder or RF coax cable

^ Atlantic-cable.com – 1956 TAT-1 Silver Commemorative Dish

^ Google books – The worldwide history of telecommunications By Anton a. Huurdeman

Wikimedia Commons has media related to: Coaxial cables

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RF connectors (coaxial)

APC-7  BNC  C  F  FME  Hirose U.FL  IPX  Motorola  MCX  MMCX  N  QLS  QMA/QN  RCA  SMA  SMB  SMC  Twin-lead  TNC  TV aerial plug  UHF / Mini-UHF

Variations and alternate names: 2.9 mm (SMA)  7 mm  Triax / Triaxial  Twin BNC / Twinax (BNC)  IPEX   MHF   AMC (UFL)  SnapN  RP-TNC  RP-SMA

Old or seldom used: EIA  GR  LEMO 00  Musa

See also: Radio frequency  Radio spectrum  Audio and video connectors  Audio and video interfaces and connectors

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