|
FIELD SERVICE MEMO
ELECTROMAGNETIC RADIATION
AND
HOW IT AFFECTS YOUR
INSTRUMENTS | PURPOSE: The purpose of this field service
memo is to provide OSHA compliance officers with basic principles of electromagnetic (EM) radiation. It discusses the effects
of radio frequency interference (RFI) on the operation of industrial hygiene instruments, explains why special isotropic probes
are used for making non-ionizing radiation surveys, and emphasizes the need for special attention in measuring radio frequency
fields.
PREFACE: Some discussion of the following subject matter has been simplified for the
sake of handling the subject in this limited space.
If this is your first exposure to the subject, some terms and
concepts in this memo might be unfamiliar to you. By reading the entire service memo completely at one sitting, some of your
initial questions raised in one section may get answered in subsequent sections. Once you make it through the material one
time, it is recommended you read the entire service memo over again a second time at another sitting.
I. WAVES IN GENERAL AND ELECTROMAGNETIC WAVES:
Electromagnetic radiation
is a wave phenomena. Before attempting to understand electromagnetic radiation, let's first review a few properties of waves.
A "wave" is a disturbance that is a function of time and/or space. A wave moves through a medium or space and transfers energy
from point to point as it moves.
"Wave motion can be thought of as the transport of energy and momentum from one point in space
to another without the transport of matter. In mechanical waves, e.g., water waves, waves on a string, or sound waves, the
energy and momentum are transported by means of a disturbance in the medium that is propagated because the medium has elastic
properties. On the other hand, in electromagnetic waves, the energy and momentum are carried by electric and magnetic fields,
which can propagate through a vacuum."
"Although the variety of wave phenomena observed in nature is immense, many
features are common to all kinds of waves, and others are shared by a wide range of wave phenomena.[1] The "size" or "height" of a water wave is called its amplitude and tells us of its
strength. All waves can be described in reference to their "amplitude" or "strength". As a wave travels (propagates) out from
the source, the total energy radiated from the source remains the same, but the strength of the wave decreases as the distance
from the source increases. A classic two dimensional example shows the ripple rings expanding out from a disturbance over
the surface of a calm pond. Three dimensional waves require going one step farther by imagining expanding spheres instead
of expanding rings. As the wave travels from the center disturbance, the wave energy is spread out thinner over larger areas,
resulting in less energy per unit area, thus decreased "strength". The total energy stays the same, but it is distributed
over a larger area.
Now let's "switch gears" and look at another property of waves. If we could observe a wave as it
passes by a point in space, we would notice the amplitude of the wave changing with time in a periodic or cyclical manner.
Because a wave is periodic, we can count the number of complete wave cycles that pass by that point each second. This would
be the "frequency" of the wave.
"Frequency" is measured in Hertz (Hz), wave cycles per second. All waves are composed
of at least one sine wave or frequency element. Waves that have non-sinusoidal looking waveforms are actually a combination
of two or more sine waves of different frequencies
NOTE: Mathematics shows us that every wave shape is actually a combination
of individual sine waves of different frequencies. A whole area of mathematics called "Fourier Analysis" is dedicated to analyzing
the sinusoidal component frequencies of waveforms. Electromagnetic radiation is a
wave phenomena and has all of the above qualities of waves. An electromagnetic (EM) wave can be defined as a "wave characterized
by variations of electric and magnetic fields". [2] EM waves can travel through space while carrying energy at the speed of light. Many people think of them simply as radio
waves, but EM waves cover a much broader frequency spectrum. EM waves extend from the very lowest frequency (Hz) to frequencies
beyond radio waves, light waves, X-rays, and gamma rays.1 This broad energy range is know as the electromagnetic spectrum. Depending on their frequency, EM waves are known as radio
waves, heat rays, light rays, etc. In this field service memo, we will be mostly concerned with radio waves ranging from 10
kHz to 3 GHz. A diagram of this portion of the spectrum is shown in Section VIII, Figure 2.
While radio frequency EM waves are intentionally generated by cellular phones, walkie talkies, garage door openers,
radio stations, and television (TV) stations, they are unintentionally generated by electric motor brushes, ignition systems
of gasoline engines, medical equipment, computer systems, and lightning. Even the sun produces radio frequency electromagnetic
radiation. The effects of unintentionally generated EM waves will be discussed in Section VII and Section VIII.
II. UNITS:
All electromagnetic fields (EM waves) consist of two component fields, electric
fields (E fields) and magnetic fields (H fields). E fields and H fields are companions and together make up the total EM field.
Where one is, so is the other. Electric field strength (E) is measured in units of volts per meter (V/m). Magnetic field strength
(H) is measured in amperes per meter (A/m).
Power is the time rate of energy transfer. This applies to waves, too.
Radiated power is that power given off by a radiation source (antenna) and carried through space by the EM wave. Power is
measured in watts (W). Power density is the amount of power distributed over a given unit area perpendicular to the direction
of travel. Power density is expressed in watts per square meter (W/m2 ) or milliwatts per square centimeter (mW/cm2).
EM radiation is a periodic wave motion. The number of repetitions of the waveform, or cycles per second, is called
the frequency and is measured in Hertz (Hz). 1 kilohertz (kHz) = 1000 Hz, 1 megahertz (MHz) = 1 million Hz, 1 gigahertz (GHz)
= 1 billion Hertz, 1 terahertz (THz) = 1 trillion Hertz, etc.
Related to frequency is the term wavelength. It is the
distance a wave travels during the time period of one complete oscillation cycle. The wavelength of an EM wave is the wave's
speed of travel (usually the speed of light) divided by the frequency of the wave. The symbol for wavelength is l (Lambda). It is measured in units of length, such as meters, centimeters, angstroms, feet, etc. The table
on the next page shows the wavelength (l) of certain frequencies (f) when the speed
of transmission is the speed of light (C), 300,000,000 meters per second (186,280 miles per second). l = C/f.
TABLE 1
Wavelength to Frequency Relationship |
| FREQUENCY (f) |
WAVELENGTH (l
=C/f) |
| 1Hz |
186,280 miles (300,000 km) |
| 10Hz |
18,628 miles (30,000 km) |
| 60Hz |
3105 miles (5,000 km) |
| 1000Hz (1 kHz) |
1863 miles (300 km) |
| 10kHz |
186 miles (30 km) |
| 100kHz |
9836 feet (3,000 meters) |
| 1000kHz (1 MHz) (AM radio) |
984 feet (300 meters) |
| 10MHz |
98.4 feet (30 meters) |
| 27MHz (many RF sealers) |
36.4 feet (11 meters) |
| 30MHz |
32.8 feet (10 meters) |
| 100MHz (FM radio) |
9.8 feet (3 meters) |
| 300MHz |
3.28 feet (1 meter) |
| 1000MHz (1GHz) |
11.8 inches (30 cm) |
| 2.45GHz (Microwave ovens) |
4.8 inches (12.2 cm) |
| 10GHz (Satellite data links) |
1.18 inches (3 cm) | III. RELATIONSHIP BETWEEN ELECTRIC AND MAGNETIC FIELDS:
Understanding
electromagnetic field relationships is difficult, but compliance officers are faced with measuring these fields. It is critical
for us to know and understand what the EM field components are and the relationship between them so that meaningful measurements
and accurate data are taken.
As mentioned earlier, electromagnetic fields (EM waves) are composed of two types of
fields, electric fields and magnetic fields. The relationship of electric fields to magnetic fields can be compared to the
relationship between voltage and current in a simple electric circuit. The electric (E) field is much like the electric voltage
potential (E) of an electric circuit. The magnetic (H) field is much like the electric current (I) of an electric circuit.
NOTE: In this text, the symbol "E" usually refers to the electric
field component of an EM field. In a few cases where it is used for electric voltage potential "E", it will be specifically
identified and will usually be accompanied by "I" (electric current). Electric voltage
potential and electric current are measured in volts and amperes respectively; E fields and H fields are measured in volts
per meter and amperes per meter, respectively. Where there is electrical current flowing, there also is a voltage associated
with it. Where there is an H field, there also is an E field associated with it.
The complete mathematical relationship
between E fields and H fields is complicated and involves terms expressed in 4 dimensions. The complete mathematical picture
is too involved for this field service memo. However, most applications allow for the math terms to be reduced to simple formulas.
Under the simple conditions of wave travel through free space, the relationship of electromagnetic fields is reduced
to:
E = H x 377 (Under free space conditions.)
| where |
E = the electric field strength,
H = the magnetic field strength,
377
= the characteristic impedance of free space, Ö(µv /ev)
a
constant with units expressed in Ohms. | The equation for electromagnetic
waves in free space, E = H x 377, and the equation for Ohm's Law, E = I x R, are very similar. Both equations are special
case simplifications of some very complex mathematical statements defining electromagnetic theory. Fortunately, some very
intelligent men have reduced this math into a few simple formulas like these, which we can use under certain ordinary conditions.
Three of these men are Maxwell, Gauss, and Ohm. Thanks to them, we don't have to be expert mathematicians to make electromagnetic
surveys. If you are familiar with Ohm's law, Appendix C, "Comparing the E = H x 377 Equation with E = I x R," may be helpful in understanding the electromagnetic field equation
given above.
As an electromagnetic wave travels through space, energy is transferred from the source to other objects
(receivers). The rate of this energy transfer depends on the strength of the EM field components. Keeping it simple, the rate
of energy transfer per unit area (power density) is the product of the electric field strength (E) times the magnetic field
strength (H).
| Pd |
= |
E |
x |
H |
| Watts/meter2 |
= |
Volts/meter |
x |
Amperes/meter |
where |
Pd = the power density,
E = the electric field strength
in volts per meter,
H = the magnetic field strength in amperes per meter. |
The above equation yields units of W/m2 . The units of mW/cm2 are
more often used when making surveys. One mW/cm2 is the same power density as 10 W/m2 The following equation
can be used to obtain these units directly:
Pd = 0.1 x E x H mW/cm2
The
simple relationships stated above apply at distances of about two or more wavelengths from the radiating source. This distance
can be a far distance at low frequencies, and is called the far field. Here the ratio between E and H becomes a fixed constant
(377 Ohms) and is called the characteristic impedance of free space. Under these conditions we can determine the power density
by measuring only the E field component (or H field component, if you prefer) and calculating the power density from it.
We
take advantage of this fixed relationship when we measure potentially hazardous EM fields during an RF hazard survey. Exposure
hazards that are due to absorption by the human body are ultimately evaluated with respect to the actual energy absorbed.
Since power is the rate of energy transfer, and the squares of E and H are proportional to power, E2 and H2
are proportional to the energy transfer rate and the energy absorbed by the subject. Because compliance officers find it convenient
to measure EM fields in terms of E2 and H2 survey meters usually readout in terms of E2 or
H2 .
Electromagnetic field exposure limits which were set for human exposure are listed in ANSI C95.1-1982
[4] as Radio Frequency Protection Guides (RFPG). There, values for electromagnetic field levels are listed in terms of E2
, H2 and equivalent power density. These values are based on the rate of energy absorbed into the human body. The
term Specific Absorption Rate (SAR) is used in the standard to describe this absorption rate. There is a very good discussion
of SAR measurements in ANSI C95 (1990) [5]. More discussion of SAR will be presented in a follow-up field service memo which will be issued at a later date, "Measurement
Practices for Non-ionizing Radiation Surveys".
IV. PROPAGATION OF ELECTROMAGNETIC ENERGY:
Most people, including most electrical engineers,
think of electricity as electrons flowing in a wire, much like water flowing in a hose. The idea of electrical energy moving
through free space in a wave is a completely foreign concept. Yet, electromagnetic radiation is exactly that, electrical energy
moving through space as a wave, and electrical energy in a wire is a special case in which the energy is guided by a wire.
Some of the energy is internal to the wire, and some of the energy is external to the wire. When we plug an appliance into
the receptacle, the power delivered to the appliance does not actually "go through the cord", but is electromagnetic energy
being "guided" by the electron activity in the power cord. The electromagnetic energy delivered to the load is external to
the wire. The electron activity oscillating back and forth in the wire is a result of the external electromagnetic energy
and in turn serves as a way of telling the electromagnetic wave to follow the wire. The electron movement in the wire is proportional
to the strength of the wave being guided. Don't be disturbed if you have difficulty grasping this concept. Even engineering
students have difficulty understanding it.
Fortunately, to analyze and solve most problems in DC and low frequency
AC circuits, it is sufficient to apply the simple Ohm's law equation. Normally it does not require thinking in terms of electromagnetic
fields. Low frequency electromagnetic field theory is typically applied only when analyzing the coils of relays, inductors,
transformers, and motors. Electromagnetic wave theory becomes more important as frequency climbs into the Megahertz range,
such as in analyzing wireless electromagnetic energy transmission, radio frequency circuits, light wave analysis, etc.
EM
waves can travel without the guiding action of wires. The points where EM waves leave the guiding influence of wires and move
to free and unbounded travel are called antennas. Antennas act as coupling points for electromagnetic energy to leave the
guidance of wires for free space, and visa versa. The area near this coupling activity is exactly where compliance officers
have to deal with electromagnetic fields, as in the case of RF heat sealers. In general, an antenna might be one of the conductors
in an electronic circuit, a metal object such as your front porch railing, or even nonmetallic objects like a tree limb or
an extended arm. The effectiveness of an antenna to transmit or receive EM waves depends on the conductivity of the material
used, the antenna's shape, and the physical dimensions of the antenna relative to the wavelength of the EM field.
The
best broadcast and reception of EM waves is obtained when the dimensions of the antenna properly match the wavelength of the
electromagnetic field. That is why the length of TV "rabbit ear" and "whip" antennas need adjustment each time the channel
is changed, and why roof mounted TV antennas have so many different sized elements.
When measuring worker exposure
to non-ionizing radiation (EM fields), it is important to be aware that the probe is also an antenna. The antenna and circuitry
of an RF probe are arranged so it can function over a range of operational frequencies. The width of this operational frequency
range is called the bandwidth. If measurements are attempted outside the probe's frequency range, the measurements will be
inaccurate and could severely damage the probe. Always choose the proper probe based on both power rating and the frequency.
V. POLARIZATION OF THE ELECTROMAGNETIC FIELDS:
Polarization is another important concept
to keep in mind when making electromagnetic measurements. Polarization explains why walkie talkie antennas need to be pointed
in the same direction to get best reception and why the probes of RF survey meters must be rotated while you are making measurements.
It
should suffice here to define polarization as a characteristic of radiated EM waves which deals with the direction and amplitude
relationship of the E field "vector" in relation to the direction of travel.
NOTE: A vector is a mathematical representation of a force or other
quantity in terms of both direction and strength. It is because of this characteristic
that we usually use an "isotropic" probe as the receiving antenna when performing a non-ionizing radiation survey. An isotropic
probe receives electromagnetic signals regardless of polarization or direction of travel. An isotropic probe is designed to
give the same reading, no matter which way it is pointed in the EM field.
Since no probe is perfectly isotropic, survey
probes should be rotated about the axis of its handle during measurements (use a rotating wrist motion like you would to turn
a door knob). An average of the minimum and maximum reading is used as the reading value.
EM wave reflections caused
by metal beams, gratings, etc. can cause a phenomenon called "multipath interference". The reflected wave can have different
polarization than the original wave. This can have significant interference impact on the measurement results as the probe
is moved from point to point. Therefore, it is good practice not only to rotate the probe, but also to move the probe about
in a circular pattern to obtain a general sampling of the area. As the measurements are made closer to the radiating source,
it is even more important to carefully survey the general area to find any such localized radiation beams.
Polarization
is discussed in greater detail later in Appendix D, "More on Polarization."
VI. NEAR-FIELD VS FAR-FIELD:
Certain behavior characteristics of EM fields dominate at
one distance from the radiating antenna, while a completely different behavior can dominate at another location. Electrical
engineers define boundary regions to categorize behavior characteristics of electromagnetic fields as a function of distance
from the radiating source. These regions are: the "Near-Field", "Transition Zone", and "Far-Field". The regional boundaries
are usually measured as a function of the wavelength. Figure 1 shows these regions and boundaries.
Two things should
be stressed: these regions categorize behaviors which vary even within each region; and the boundaries for these regions are
approximate "rules of thumb" (more precise boundaries can be defined based primarily on antenna type and antenna size, and
even then the experts differ). 
Figure 1. Antenna field Regions for Typical Antennas
FAR-FIELD: The region
extending farther than 2 wavelengths away from the source is called the "Far-Field". In the far-field, E, H, and power density
are related by the equations: E = H x 377 and Pd = E x H. These equations were explained in Section III. Combining these two equations together we get:
Pd = H2 x 377 and Pd = E2÷377
| where Pd |
= |
the power density in watts per square meter (one W/m2 is equal to 0.1 mW/cm2
), |
|
H2 |
= |
the square of the value of the magnetic field in amperes
squared per meter squared, |
|
E2 |
= |
the square of the value of the electric field in volts squared
per meter squared.
| The above equations show that in the far-field, all
you really need to measure is the E field, actually E2 . From this measurement, the power density and value of
the H field can be calculated. For reasons explained in Section III, health compliance measurements are more convenient to
evaluate when they are measured in terms of the square of the field strength.
TRANSITION ZONE:
The region between the near-field and the far-field is called the "Transition Zone". It has a combination of the characteristics
found in both the near-field and the far-field. Here it may not always be necessary to measure both E and H to obtain a good
approximation of the EM field, but several measurements are needed to characterize the field.
NEAR-FIELD:
The region located less than one wavelength from the source is called the "Near-field". Here, the relationship between
E and H becomes very complex, and it requires measurement of both E and H to determine the power
density. Also, unlike the far-field where EM waves are usually characterized by a single polarization type (horizontal, vertical,
circular, or elliptical), all four polarization types can be present in the near-field.
Since both the E field and
the H field components of electromagnetic waves are absorbed by living tissue, and since the relationship between E and H
is complicated in the near-field, we must measure both E and H when evaluating near-field hazards. This includes all low frequency
sources, such as RF heat sealers.
The near-field is further divided into the "reactive" near-field and the "radiative"
near-field. The outer boundary of the reactive near-field region is commonly considered to be a distance of 1/2p times the wavelength (l/2p
or 0.159 x l) from the antenna surface. The radiative near-field covers the remainder
of the near-field region, from l/2p out
to l (one full wavelength).
In the reactive near-field (very close to the
antenna), the relationship between the strengths of the E and H fields is too complex to predict. Either field component (E
or H) may dominate at one point, and the other way dominate at a point only a short distance away. This makes it extremely
difficult to find the true power density there. Not only would E and H both have to be measured, but a new term called the
phase relationship between E and H is needed. Present survey meters (such as OSHA's Narda and Holaday units) measure only
the magnitude E or H, not this phase relationship. Although it would be very helpful to know the true power density, our present
compliance efforts do not require us to determine it. During a compliance survey, both the E field and the H field components
are measured separately, read from the meter as E2 and H2 quantities, and each quantity is compared
individually against the Radio Frequency Protection Guides (RFPG) of the ANSI C95.1-1982 standard. If either the E field or the H field component exceeds the limits of the RFPG, the level is considered high.
As you
might have guessed, the reactive near-field region has another surprise in store for you. In this reactive region, not only
is the EM wave being radiated outward into space, but there is a "reactive" component to the EM field. Very close to the antenna,
energy of an unknown amount is held back and is stored very near the antenna surface. This reactive component can be the source
of confusion and danger in attempting measurements in this region. In other regions the power density is inversely proportional
to the square of the distance from the antenna. In the vicinity very close to the antenna, the energy level can rise dramatically
with only a small additional movement towards the antenna. This energy can be very dangerous (even hazardous) to both humans
and measurement equipment where high powers are involved.
CAUTION: When the radiating dimensions of the antenna are much
smaller than one wavelength and/or the frequency is low (as with heat sealers), it is especially important to be aware
of the POTENTIALLY HAZARDOUS REACTIVE FIELDS WHICH MAY EXIST IN THE REACTIVE NEAR-FIELD. Exercise
extreme caution for both your safety and the equipment when making near-field measurements, in the case of heat sealing machines.
As you move nearer to the antenna in the reactive near-field, the energy can increase much quicker than what is computed by
the inverse-square law. Some electromagnetic energy is stored in the near-field in the vicinity of the antenna that can be
an unsuspected source of dangerous energy. This "reactive field" energy is especially dangerous with high power systems. The
closer to the radiating source you get, the more caution should be exercised. The
radiative near-field does not contain any reactive field components from the source antenna. The energy is all radiant energy.
As you move further out into the radiative near-field (one half wavelength to 1 wavelength from the source), the E and H field
relationship does not have so many surprises as in the reactive near-field, but the E to H relationship is still complex.
Since the radiative near-field is still part of the near-field, caution should still be exercised in relation to personal
safety and equipment safety. Metal objects such as steel beams can act as antennas by receiving and then "re-radiating" some
of the energy, forming a new radiating surface to consider. Not only does this new radiating surface have its own near-field
regions, the energy levels might be shockingly high. Exercise caution near such metal objects.
All near-field readings
require special attention. In general, readings taken closer than one wavelength require measurement of both the E and H fields.
A good general rule of thumb is "Measure the E field above 300 MHz and measure both-the E field and the H
field below 300 MHz". For example, when surveying radio frequency heat sealer machinery at 27 MHz (l = 11.1 meters, or 36.4 feet), both E and H must be measured, since the measurement is in the near-field.
Two wavelengths at 27 MHz is 22.2 meters (72.8 feet) away.
While taking measurements in the near-field, you may notice
the values for E and H vary considerably from point to point. A very strong E or H field strength may exist only inches away
from a very weak E or H field strength. When attempting "power measurement" in the near-field, make an effort to take both
the E field and the H field measurements at the exact same physical location,
especially if unusual peaks and valleys are observed from point to point. The variation may be only centimeters apart or may
be as much as one meter. How much care to be taken will be obvious to you by observing the meter display for abrupt changes.
NOTE: Throughout this section the boundaries for the near and far-field
regions have been defined only in terms of wavelength. Actually, the boundaries are based on more. The maximum overall dimension
(D) of the radiating antenna is a prime factor in determining these boundaries. This dimension is a physically measured length.
Above we assumed that "D" was one wavelength or less. For antennas like the ones mounted on houses for TV (dipole antennas),
"D" would be the length of the radiating arm; and for a radar set or heat sealer, "D" might be the maximum dimension of the
port opening (or aperture) through which the EM wave passes.
In most situations "D" is between one-fourth to one whole
wavelength (l) long, but there are some situations where "D" might be much larger
or much smaller than "l". When "D" is much larger 2 than "l", the far-field boundary is not 2l as shown in figure 1, but is
2 D2 /l.
Far-field boundary = 2 D2/l
where D = the largest radiating dimension
of the antenna
l = (lambda) one wavelength
Therefore, if the maximum overall dimension exceeds
"l", the far-field boundary extends farther out than 2l.
Thus we might be required to measure both the E and H field components, even beyond the 2l
distance or when the frequency is above the 300 MHz "rule of thumb". But don't panic, these situations are usually the exception,
but you should be aware of their existence.
More commonly, an antenna may be such that the maximum overall dimension
(D) is much less than one wavelength. In these cases, the "radiative" portion of the near-field region may not even exist
at all. However, the nastier "reactive" near-field still exists, and it extends out to X/2p
from the source. So, even in cases where "D" is much less than "l", it is best to
follow the "rule of thumb" practice of measuring both the E field and H field for frequencies below
300 MHz. The boundaries shown in Figure 1. should not to be considered rigid, but
they are values obtained by consensus to help categorize wave motion characteristics and behavior into regions. Characteristic
behavior expressed in one region is not fully excluded from existing to a lesser extent in an adjacent region. The multiple
characteristics of the transition zone are a prime example of overlapping behavior. The regional boundaries primarily indicate
where certain characteristics require special attention.
Perhaps in a summary we can best look at two examples. The
far-field for microwave oven emissions at 2.45 GHz is only inches from the source, so it is sufficient to measure only the
E field. However, for radio frequency (RF) heat sealers operating at 27 MHz, both E and H must be measured, because we are
in the near-field. Even when "D" is very small, the "reactive" near-field boundary of l/2p at 27 MHz is 1.77 meters (5.8 feet). Thus RF heat sealers and all near-field measurements
require special attention to both field components.
VII. ELECTROMAGNETIC FIELDS AND CIRCUITRY:
This section describes two related topics, electromagnetic
interference (EMI) and electromagnetic susceptibility (EMS). The term EMI is mostly used to describe electrical signals that
are given off from one source and interfere with the operation of another electronic appliance. Comparing with sound waves,
music to one person can be noisy interference to someone in the next room. EMS deals with the way EMI disrupts the normal
operation of the victim appliance.
OSHA's compliance instruments are small, light-weight, and battery operated appliances.
To achieve light weight, they use small batteries and low-power circuits. Some of the circuits use analog signals (voltages
and currents of varying amplitude) and some are digital (voltage pulses to indicate 1's and 0's). When low power levels are
used in either of these circuits, they become more susceptible to interference from external electromagnetic fields.
The
universe is full of EM fields, and they are constantly mixing with the EM fields that are operating our electronic circuits.
When the external field induces signals in an instrument's circuits that are significant in relation to normal circuit signals,
interference results. As the strength of the interfering field increases and the power level of the instrument's circuitry
decreases, the probability of unwanted responses increases significantly. The interference can cause erroneous data, unwanted
results, false alarms, or even complete shutdown of the instrument. The effects can be totally unpredictable. Adequate electromagnetic
protection is being recognized as a critical element in design of low power equipment.
To protect against EMI, circuits
are sometimes shielded in metal enclosures, called electromagnetic shielding. Shielding is also used to prevent EMI from radiating
out from the source. Parts of a stereo system handling low level signals are shielded to keep out the 60 Hz hum of power lines.
Large computers are shielded to prevent the electromagnetic fields from radiating and causing interference in other equipment.
Sometimes additional circuitry, called EMI filters, are added to redirect unwanted signals away from sensitive circuitry.
Typically, EMI filters are built into the equipment circuitry.
A circuit's susceptibility to interfering radio waves
is referred to as its Electromagnetic Susceptibility (EMS). Instruments showing no effect from signals at one frequency may
behave totally different at another. The instrument's physical circuit dimensions, electrical characteristics, and shielding
all influence the frequency dependency of an instrument's EMS performance. Often manufacturers take little or no concern about
EMI and EMS until someone complains of problems well after production has begun. Both EMI and EMS problems can be solved by
good design, sufficient testing, and proper safeguards by the user.
VIII. A PROBLEM FOR OSHA COMPLIANCE AND ACTION BEING TAKEN:
Veteran compliance officers
will agree that EMS has not been a significant problem with older instruments. The circuitry operated at power levels high
enough that the effects of external fields were not noticed. OSHA's newer instruments consume less power and are more portable,
but are more likely to be susceptible to EMI. EMI problems were experienced with the original purchase of DuPont Mark 1 dosimeters
and caused 400 units to be recalled and modified. To avoid having another such recall, instruments are now being thoroughly
tested by the Cincinnati Laboratory for EMS before purchase. Examples of instruments recently tested are audiodosimeters,
combustible gas meters, air sampling pumps, and air velocity meters.
As a result of this testing, many manufacturers
have become aware of EMS and have begun designing instruments to reduce the susceptibility. However, EMS is still not getting
proper attention by some manufacturers of industrial hygiene instruments. Some instruments show degraded performance when
exposed to EM field strengths as low as 0.01 mW/cm2 . By comparison, the OSHA worker safety standard of the 1970's
is 10 mW/cm2 , and the ANSI C95.1-1982 standard is 1 mW/cm2 for frequencies of greatest concern to us.
While non-ionizing radiation levels in violation of this OSHA standard are not very common, the lower levels found to effect
some industrial hygiene instruments are more common. It is reasonable to expect OSHA's instruments will be exposed to these
levels. Figure 2. graphically shows these levels. Figure 2. Plot Showing RF Levels for EMS Concern (Pd is Power Density
in mW/cm²)
In the presence of an electromagnetic field, degraded instrument performance shows itself as anything from
subtle deviations to gross errors, or even complete failure of the instrument. Symptoms of interference may include: false
alarming of the instrument, changes in reading with no obvious cause, intermittent failures, illogical displays, etc. Even
when these obvious symptoms are absent, EMS caused errors can still degrade the accuracy of the instrument readings.
To
assure OSHA's new instruments meet minimum criteria for EMS susceptibility, the OSHA Cincinnati Laboratory performs EMS tests
on portable instruments being considered for purchase by OSHA. This is part of the laboratory's equipment evaluation program.
Existing equipment is also scheduled for EMS testing to verify accurate performance. This testing is done in a special chamber
called a Transverse Electromagnetic (TEM) Cell.
IX. CONCLUSION:
Congratulations! You have now reached the end. Hopefully this explanation has
provided you with a better general understanding of electromagnetic (EM) waves and susceptibility to unwanted electromagnetic
waves. The topics are not easy, and require complex mathematics to better understand them.
A follow up field service
memo, to be issued at a later date, will describe "Measurement Practices for Non-ionizing Radiation Surveys". It will apply
the information of this memo to the task of taking actual field measurements of potentially hazardous radio frequency electromagnetic
fields.X. REFERENCES
[1] Tipler, Paul A., Physics, Worth Publishers, Inc., 1982, Page 396.
[2] ANSI/IEEE 100-1984, IEEE Standard Dictionary of Electrical and Electronics Terms, 1984,
page 305.
[3] Clayton, George D. and Florence E., Patty's Industrial Hygiene and Toxicology, John Wiley
& Sons, New York, 1978, Page 448.
[4] ANSI/IEEE C95.1-1982, "American National Standard Safety Levels with Respect to Human Exposure to Radio Frequency
Electromagnetic Fields, 300 kHz to 100 GHz", 1982.
[5] ANSI C95.3(1991) "American National Standard Recommended Practice for the Measurement of Potentially Hazardous Electromagnetic
Fields - RF and Microwave".
APPENDIX A
ABBREVIATIONS AND SYMBOLS USED IN THIS TEXT |
| Å |
Angstrom, unit of length, one ten billionth of a meter (0.0000000001),
used only in Figure 1 on page 3. All other uses of the abbreviation "A" in this text refer to "Amperes". |
| A |
Amperes, unit of electrical current |
| AC |
Alternating Current |
| A/m |
Amplitude modulated, also the frequency band of commercial radio extending
from 535 kHz to 1605 kHz |
| A2/m2 |
Amperes squared per Meter squared, in this text it is the quantity
of magnetic field strength multiplied by itself (Amperes per Meter, quantity squared) |
| CB |
Citizens Band |
| cm |
Centimeter, one hundredth of a meter (0.01 meter) |
| DC |
Direct Current |
| E |
Electric, In this text, unless otherwise identified, "E" is the electric
field component of an electromagnetic field. |
| E |
Electric voltage potential (When "E" is used for electric voltage
potential in this text, it well identified as such. All other uses of "E" in this text represent Electric field component
of EM fields. |
| E/M |
Ratio of the electric field (E) to the magnetic field (H), in the far-field this is the characteristic
impedance of free space, 377 Ohms. |
| EM |
Electromagnetic |
| EMI |
Electromagnetic Interference |
| EMS |
Electromagnetic Susceptibility |
| FM |
Frequency modulated, also the frequency band of commercial radio extending
from 88 MHz to 108 MHz |
| GHz |
Gigahertz, one billion Hertz (1,000,000,000 Hertz) |
| H |
Magnetic, In this text, unless otherwise identified, "H" is the magnetic
field component of an electromagnetic field. |
| Hz |
Hertz, unit of measurement for frequency (cycles per second) |
| I |
Electric current |
| kHz |
Kilohertz, one thousand Hertz (1000 Hertz) |
| l |
Lambda, symbol for wavelength, distance a wave travels during the
time period necessary for one complete oscillation cycle |
| MHz |
Megahertz, one million Hertz (1,000,000 Hertz) |
| µm |
Micrometer, unit of length, one millionth of an meter (0.000001 meter) |
| m |
Meter, the fundamental unit of length in the metric system |
| mil |
Unit of length, one thousandth of an inch |
| mW |
Milliwatt (0.001 Watt) |
| mW/cm2 |
Milliwatts per square centimeter (0.001 Watt per square centimeter
area), a unit for power density, one mW/cm2 equals ten W/m2 |
| nm |
Nanometer, one billionth of a meter (0.000000001 meter) |
| OSHA |
Occupational Safety and Health Administration |
| Pd |
Power density, unit of measurement of power per unit area (W/m2
or mW/cm2) |
| R |
Resistance |
| RF |
Radio Frequency |
| RFI |
Radio Frequency Interference |
| RFPG |
Radio Frequency Protection Guides, as listed in Table 1 of ANSI Standard
C95.1-1982 |
| SAR |
SPECIFIC ABSORPTION RATE, as described in of ANSI Standard C95.1-1982 |
| THz |
Terahertz, one trillion Hertz (1,000,000,000,000 Hertz) |
| TV |
Television, also the frequency band of commercial broadcast extending
from 54 to 72 MHz, 76 to 88 MHz, 174 to 216 MHz, and 470 to 806 MHz |
| V |
Volts, unit of electric voltage potential |
| V/m |
Volts per meter, unit of electric field strength |
| V2/m2 |
Volts squared per meter squared, in this text it is the quantity of
electric field strength multiplied by itself (volts per meter, quantity squared) |
| W/m2 |
Watts per square meter, a unit for power density, one W/m2
equals 0.1 mw/cm2 |
| W |
Ohms, unit of resistance |
|
