Electromagnetic interference


Electromagnetic interference, also called radio-frequency interference when in the radio frequency spectrum, is a disturbance generated by an external source that affects an electrical circuit by electromagnetic induction, electrostatic coupling, or conduction. The disturbance may degrade the performance of the circuit or even stop it from functioning. In the case of a data path, these effects can range from an increase in error rate to a total loss of the data.
Both human-made and natural sources generate changing electrical currents and voltages that can cause EMI: ignition systems, cellular network of mobile phones, lightning, solar flares, and auroras. EMI frequently affects AM radios. It can also affect mobile phones, FM radios, and televisions, as well as observations for radio astronomy and atmospheric science.
EMI can be used intentionally for radio jamming, as in electronic warfare.

History

Since the earliest days of radio communications, the negative effects of interference from both intentional and unintentional transmissions have been felt and the need to manage the radio frequency spectrum became apparent.
In 1933, a meeting of the International Electrotechnical Commission in Paris recommended the International Special Committee on Radio Interference be set up to deal with the emerging problem of EMI. CISPR subsequently produced technical publications covering measurement and test techniques and recommended emission and immunity limits. These have evolved over the decades and form the basis of much of the world's EMC regulations today.
In 1979, legal limits were imposed on electromagnetic emissions from all digital equipment by the FCC in the US in response to the increased number of digital systems that were interfering with wired and radio communications. Test methods and limits were based on CISPR publications, although similar limits were already enforced in parts of Europe.
In the mid 1980s, the European Union member states adopted a number of "new approach" directives with the intention of standardizing technical requirements for products so that they do not become a barrier to trade within the EC. One of these was the EMC Directive and it applies to all equipment placed on the market or taken into service. Its scope covers all apparatus "liable to cause electromagnetic disturbance or the performance of which is liable to be affected by such disturbance".
This was the first time there was a legal requirement on immunity, as well as emissions on apparatus intended for the general population. Although there may be additional costs involved for some products to give them a known level of immunity, it increases their perceived quality as they are able to co-exist with apparatus in the active EM environment of modern times and with fewer problems.
Many countries now have similar requirements for products to meet some level of electromagnetic compatibility regulation.

Types

Electromagnetic interference divides into several categories according to the source and signal characteristics.
The origin of interference, often called "noise" in this context, can be human-made or natural.
Continuous, or continuous wave, interference arises where the source continuously emits at a given range of frequencies. This type is naturally divided into sub-categories according to frequency range, and as a whole is sometimes referred to as "DC to daylight". One common classification is into narrowband and broadband, according to the spread of the frequency range.
  • Audio frequency, from very low frequencies up to around 20 kHz. Frequencies up to 100 kHz may sometimes be classified as audio. Sources include:
  • * Mains hum from: power supply units, nearby power supply wiring, transmission lines and substations.
  • * Audio processing equipment, such as audio power amplifiers and loudspeakers.
  • * Demodulation of a high-frequency carrier wave such as an FM radio transmission.
  • Radio frequency interference, from typically 20 kHz to an upper limit which constantly increases as technology pushes it higher. Sources include:
  • * Wireless and radio frequency transmissions
  • * Television and radio receivers
  • * Industrial, scientific and medical equipment
  • * Digital processing circuitry such as microcontrollers
  • *Switched-mode power supplies
  • Broadband noise may be spread across parts of either or both frequency ranges, with no particular frequency accentuated. Sources include:
  • * Solar activity
  • * Continuously operating spark gaps such as arc welders
  • * CDMA mobile telephony
An electromagnetic pulse, sometimes called a transient disturbance, arises where the source emits a short-duration pulse of energy. The energy is usually broadband by nature, although it often excites a relatively narrow-band damped sine wave response in the victim.
Sources divide broadly into isolated and repetitive events.
Sources of isolated EMP events include:
  • Switching action of electrical circuitry, including inductive loads such as relays, solenoids, or electric motors.
  • Power line surges/pulses
  • Electrostatic discharge, as a result of two charged objects coming into close proximity or contact.
  • Lightning electromagnetic pulse, although typically a short series of pulses.
  • Nuclear electromagnetic pulse, as a result of a nuclear explosion. A variant of this is the high altitude EMP nuclear weapon, designed to create the pulse as its primary destructive effect.
  • Non-nuclear electromagnetic pulse weapons.
Sources of repetitive EMP events, sometimes as regular pulse trains, include:
  • Electric motors
  • Electrical ignition systems, such as in gasoline engines.
  • Continual switching actions of digital electronic circuitry.
Conducted electromagnetic interference is caused by the physical contact of the conductors as opposed to radiated EMI, which is caused by induction. Electromagnetic disturbances in the EM field of a conductor will no longer be confined to the surface of the conductor and will radiate away from it. This persists in all conductors and mutual inductance between two radiated electromagnetic fields will result in EMI.

Coupling mechanisms

Some of the technical terms which are employed can be used with differing meanings. Some phenomena may be referred to by various different terms. These terms are used here in a widely accepted way, which is consistent with other articles in the encyclopedia.
The basic arrangement of noise emitter or source, coupling path and victim, receptor or sink is shown in the figure below. Source and victim are usually electronic hardware devices, though the source may be a natural phenomenon such as a lightning strike, electrostatic discharge or, in one famous case, the Big Bang at the origin of the Universe.
There are four basic coupling mechanisms: conductive, capacitive, magnetic or inductive, and radiative. Any coupling path can be broken down into one or more of these coupling mechanisms working together. For example the lower path in the diagram involves inductive, conductive and capacitive modes.
Conductive coupling occurs when the coupling path between the source and victim is formed by direct electrical contact with a conducting body, for example a transmission line, wire, cable, PCB trace or metal enclosure. Conducted noise is also characterised by the way it appears on different conductors:
  • Common-mode coupling: noise appears in phase on two conductors.
  • Differential-mode coupling: noise appears out of phase on two conductors.
Inductive coupling occurs where the source and victim are separated by a short distance. Strictly, "Inductive coupling" can be of two kinds, electrical induction and magnetic induction. It is common to refer to electrical induction as capacitive coupling, and to magnetic induction as inductive coupling.
Capacitive coupling occurs when a varying electrical field exists between two adjacent conductors typically less than a wavelength apart, inducing a change in voltage on the receiving conductor.
Inductive coupling or magnetic coupling occurs when a varying magnetic field exists between two parallel conductors typically less than a wavelength apart, inducing a change in voltage along the receiving conductor.
Radiative coupling or electromagnetic coupling occurs when source and victim are separated by a large distance, typically more than a wavelength. Source and victim act as radio antennas: the source emits or radiates an electromagnetic wave which propagates across the space in between and is picked up or received by the victim.

ITU definition

Interference with the meaning of electromagnetic interference, also radio-frequency interference is according to Article 1.166 of the International Telecommunication Unions Radio Regulations defined as "The effect of unwanted energy due to one or a combination of emissions, radiations, or inductions upon reception in a radiocommunication system, manifested by any performance degradation, misinterpretation, or loss of information which could be extracted in the absence of such unwanted energy".
This is also a definition used by the frequency administration to provide frequency assignments and assignment of frequency channels to radio stations or systems, as well as to analyze electromagnetic compatibility between radiocommunication services.
In accordance with ITU RR variations of interference are classified as follows:
  • permissible interference
  • accepted interference
  • harmful interference

    Conducted interference

Conducted EMI is caused by the physical contact of the conductors as opposed to radiated EMI which is caused by induction.
For lower frequencies, EMI is caused by conduction and, for higher frequencies, by radiation.
EMI through the ground wire is also very common in an electrical facility.