| In recent years there has been considerable discussion and concern about
the possible hazards of electromagnetic radiation (EMR), including
both RF (Radio Frequency) energy and power frequency (50-60 Hz) electromagnetic
fields.
All life on Earth has adapted to survive in an environment of weak,
natural low-frequency electromagnetic fields (in addition to the
Earth's static geomagnetic field). Natural low-frequency EM fields
come from two main sources: the sun and thunderstorm activity. But
in the last 100 years, man-made fields at much higher intensities
and with a very different spectral distribution have altered this
natural EM background in ways that are not yet fully understood.
It has been known since the early days of radio that RF energy can
cause interference in most of the wireless operated systems and
in devices which process extremely low power signals associated
with control systems and in medical equipments. Very high density
of Electromagnetic Fields have been known to have resulted in injuries
by heating body tissue. These heat-related health hazards are called
thermal effects. In addition, there is evidence that magnetic fields
may produce biological effects at energy levels too low to cause
body heating. The proposition that these thermal effects may produce
harmful health consequences has produced a great deal of research.
Human body nervous system is also known to work on extremely low
intensities of electrical signals. Very little has been done to
investigate the effect of Electromagnetic Fields on the human nervous
and control system which as such leaves a lot of scope for future
research.
Potential Sources of EMR
The list could be endless starting with seemingly harmless AC (alternating
current) operating devices to all the intentional and non- intentional
transmitters. Appreciable radiation occurs as the size of the components
and connecting wires approaches one tenth of the wavelength of the
operating frequency. The intensity of the field so radiated also
depends on the power handled by the device. To name a few tube lights,
spark plugs, washing machines, music systems, power amplifiers,
computers, lifts, air conditioners, cable TV, computer screen etc
all fall in the category of non-intentional transmitters but can
be potential source of Electromagnetic Radiations. All radio and
TV broadcasting systems, telecommunication systems and equipments,
RADARS, mobile phones etc are intentional transmitters of Electromagnetic
Radiations and may result in typical effects on various systems
in addition to causing serious interference problems and affecting
human body.
With ever increasing use of modern digital technology in almost
all the modern processing and communication equipments the threat
of unintentional Electromagnetic Radiation is further enhanced.
As all digital signals positively have a very large bandwidth, its
increasing use will result in Electromagnetic Radiations in almost
all the frequency ranges there by leaving a possibility of affecting
most of electronic devices and also human beings.
Some Typical Effects of EMR
Electromagnetic Interference: Interference is the energy levels
introduced by electronic or communications systems that have a detrimental
effect on other systems. Any electronic system is capable of receiving
Electromagnetic Radiations if the size of the components or connecting
wires approaches one tenth of frequency that may be present in the
surrounding environment due to any intentional or unintentional
transmitter. Depending on the intensity of this unwanted received
radiation there could be instances of malfunctioning of the device
receiving this energy. There have been number of instances where
such a condition had resulted in catastrophic failure of the equipments.
The most famous example is the failure of the Electronic surveillance
system installed at one of the ships of United Kingdom Naval forces
during Falkland war due to operation of its own Radar system installed
on the same warship. As a result of this only one system could be
operated at one time resulting in the loss of the ship. Intentional
Jamming of the radio receivers by the security and police forces
is the utilization of this effect to make the enemies receivers
inoperative, however it can also happen due to unwanted and unintentional
Radiation of Electromagnetic fields.
Effects on Human Body: Body tissues that are subjected to very
high levels of RF energy may suffer serious heat damage. These effects
depend upon the frequency of the energy, the power density of the
RF field that strikes the body, and even on factors such as the
polarization of the wave.
However, additional longitudinal resonances occur at about 1 GHz
near the body surface.
Health Care Engineering: Is electromagnetic Interference (EMI)
becoming a problem in the healthcare environment? Although electrical
interference in hospitals is often regarded as no more than a minor
nuisance, there are documented cases in which equipment failures
due to Electromagnetic Interference (EMI) have lead to injury or
death. Some examples fare as follows: -
• In 1992, a patient attached to a monitor-defibrillator
in an ambulance died because of interference from the ambulance
radio prevented the machine from working (1).
• In 1987, patient monitoring systems failed to sound alarms
because of interference; two patients died as a result (2).
• In 1993, a patient fitted with a pacemaker went into ventricular
fibrillation shortly after being scanned with a metal detector outside
a courtroom (2).
As in many other fields, the amount and complexity of electronics
in hospitals and other medical environments is increasing year by
year. Despite this, the number of reported incidents of EMC (Electromagnetic
Compatibility) problems fortunately does not appear to be growing.
This is probably because most manufacturers and designers of medical
electronic products have developed a good awareness of EMC. Pacemakers
are typical examples, where their design with respect to compactness
and immunity to radio frequency interference has greatly improved
over the years. Nowadays, pacemakers are very reliable, but can
still fail under extreme conditions. Pacemakers have failed in patients
undergoing electro surgery (2) and in other cases where patients
kept mobile phones in their chest pockets, a few centimeters from
the pacemaker leads (3). The powered Wheelchair is another typical
example: there are many stories of radio frequency interference.
(RFI) from mobile phones or police ‘walkie-talkies’
causing the wheelchair to drive itself and its occupant into traffic.
These stories are based on real occurrences; reports of incidents
in the USA in the early 1990s prompted the Food and Drug Administration
(FDA) to investigate the problem and recommend that the manufacturer
change the design to give an immunity of at least 20V/m to RFI.
The use of many items of electronics equipment in close proximity
in the hospital environment means that the same sort of EMC problems
are encountered as with other types of electronic products. However
there are some special features of the hospital EM environment:
• Failure of medical devices can lead to injury or death.
• Some equipment found in hospitals is intentionally designed
to emit electromagnetic energy, often for therapy. Other equipment,
which may be located nearby, is designed to detect very small physiological
signals. This combination has the potential to create EMC Problems.
• Also in hospitals, there is the question of whether to
ban or restrict the use of mobile phones. They improve communications
but can interfere with critical equipment.
• Many medical devices are connected directly to patients.
For mains-powered devices, the designer must prevent electric shock
as well as ensure EMC. Electronic equipment is constantly evolving,
so there is always the possibility of new problems arising, e.g.
interference from new types of mobile communications devices.
Some Remedial Measures
Ensuring EMC of the devices/ components: Electromagnetic compatibility
describes a state in which the electromagnetic environments produced
by natural phenomena and by other electrical and electronic devices
do not cause interference in electronic equipment and systems of
interest. In order to reach this state, it is necessary to reduce
the emissions from sources that are controllable, or to increase
the immunity of equipment that may be affected, or to do both.
To try to eliminate all possibility of interference by decreasing
emissions and increasing immunity further could incur a high cost
to industry and could prevent new technologies from emerging. For
example, a restriction lowering the transmitting power of cellular
telephones so that consumers could place their cell phones on top
of any electronic equipment might compromise the performance and
economic viability of such communication systems. On the other hand,
a requirement that all commercial electronic equipment perform without
malfunction at ambient levels of 50 V/m would place a financial
burden on manufacturers of a large range of equipment.
The following are some of the techniques used to counter the effects
of EMI:
Source Elimination: An effective technique to eradicate interference
is through identification and elimination of the source. In theory,
this represents arguably the most effective of any measures, but
is not practical in most situations, whereas this would require
the source to be periodically or permanently disabled from operation.
Grounding a grounding point represents a common reference point
for a device or multiple devices that functions to ensure the safety
or the equipment and operator, and its effects provide some immunity
to noise and interference. Certain transmission and other Electronic
equipment require adequate grounding to ensure proper operation.
The Conductor used to ground the equipment should be the shortest
necessary length to avoid a ground loop condition. This could result
in energy transfer through conduction to connected devices.
Filters The use of filters allows selected frequencies to pass
through to the connected device, while rejecting or attenuating
any frequencies that are outside the filter specifications. Examples
of filters include low-pass, band-pass, and high-pass.
Shielding. An effective manner used to minimize, and in some instances
eliminate, EMI is to effectively shield components from interaction
with electromagnetic energy. This technique is often expensive and
causes major design engineering challenges, especially to fully
shield a device, which requires that conductive material completely
enclose the equipment or circuitry. Any separation in the shielding
material reduces the effectiveness of the shielding technique.
Conclusion
With ever increasing use of the spectrum due to modern communication
equipments and also use of latest digital processing techniques
for most of the devices there is a need for laying down the guidelines
for Emission standards. The extent of the spurious radiation by
any device should be limited to the extent possible without increasing
the cost of the product. Various governmental and nongovernmental
agencies must come forward at national and international level to
coordinate and standardize the permissible radiation limits
REFERENCES
(1)Banana Skins’, UK EMC Journal, vol. 15, p. 8, February
1998.
(2)Healthcare Engineering: Latest Developments and Applications;
I Mech E, London, 25-26 Nov 2003 and Jeffrey L Silberberg, ‘Performance
degradation of electronic medical devices due to Electromagnetic
Interference Compliance Engineering vol. 10 p. 25 1993.
(3)Medical Devices Agency, Electromagnetic Compatibility of Medical
Devices with Mobile Communications, MDA DB 9702, 1997.
Lt Col A K Nigam is M. Tech from IIT Kanpur and fellow member of
IETE. He has Advance Diploma in Management and PG Diploma in Telecommunications
He was trained by Indian Telephone Industries (ITI) and Military
College of Telecommunication Engineering and has extensively worked
in the field of Telecom and Education for over 28 years. He has
distinction of being part of a core group for fielding a Packet
Switching Network of National Importance on western border covering
a span of over 1000 kms which was dedicated to nation by Prime Minister
in 1994. He had been head of a task force for provision of communication
in Ladakh region during outbreak of hostilities and was actively
involved in development & deployment of highly mobile Area Grid
Mobile Communication System developed for Indian army involving
switching equipments, RR, Radio, Satellites and other diverse media.
Currently he is serving as Professor with Institute of Technology
and Management at Gurgaon, Haryana (India).
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