Transmission of electrical signals over wire lines
requires the use of two conductors to complete the circuit. One we call
the "go" wire; the other is the "return" wire.
For the purpose
of explaining coaxial cable, let’s examine a telephone installation
using conventional wire. The wires are paired on telephone poles; one
pair is used for each telephone circuit. On some circuits, only the "go"
wire is mounted on the pole and the earth itself is used as the "return".
Sometimes the pairs of wires for telephone circuits are bundled
together in groups of up to 1,800 pairs (3,600 separate wires) and are
then jacketed to form a "multi-pair cable".
In all of these
arrangements the wires carrying the very delicate electrical currents
conveying the telephone conversation are exposed to external
interference. Lightning, although it may not strike the wires directly,
will cause static. Wet weather can cause leakage across insulators,
giving a "frying" noise in your telephone receiver, and faults on power
transmission lines can cause pops and loud hums that interfere with the
conversation. The proximity of other wire pairs carrying conversations
to your pair, particularly in multi-pair cables, may cause you to
faintly hear another conversation in the background. This is called
"cross talk".
There are two other problems related to the use of
the conventional pair of wires for communication. One is that this type
of circuit has a high "attenuation", that is, the signals get weaker as
they travel along the wires and on a long-distance line, amplifiers are
necessary to boost the conversation every few miles so that the
conversation will not get lost below the line noise.
The other
problem, and economically the most important , is that of "bandwidth". A
telephone conversation can just satisfactorily be carried on if the
circuit transmits audible tones in the range from about 300 hertz (Hz)
to about 2,500 Hz, a total "band" of 2,200 Hz. It is possible to carry
more than one conversa- tion simultaneously on a pair of wires by
"frequency multiplexing" the conversations.
One conversation
will occupy frequencies of 300 to 2,500 Hz, the next from 3,000 to
5,200, the next from 5,700 to 7,900, and so on. Each conversation
requires 2,200 Hz and there is a "guard band" of at least 500 Hz between
each conversation to prevent their mixing. Each of these signals is
reconverted at the receiving end of the line to the 300 to 2,500 Hz
range before they appear at a telephone receiver. We can not keep adding
to the number of conversations that a pair of wires can carry
simultaneously because of the relatively low upper limit of frequency
that this system of conventional wires can transmit. Coaxial cable was
developed to alleviate the foregoing problems.
In coaxial cable,
the "go" wire is the center conductor, some form of copper wire, solid
or stranded, of comparatively small diameter, around which is a very
heavy insulation - the dielectric. But the "return" wire is no longer
another identical wire. Instead it is in the form of a copper tube
completely surrounding the "go" wire and dielectric, and concentric with
it; hence, the term "coaxial".Thus, no external interference can affect
your conversation (in the case of telephone usage) because it is
carried by currents completely shielded from external effects by the
tubular "return" conductor. Effects of weather are also excluded.
Coaxial
cable has an extremely broad bandwidth; it will transmit signals from
zero frequency (direct cur- rent) up to many millions of hertz.
Literally, hundreds of conversations (or messages) can be frequency
multiplexed and transmitted simultaneously over a single coaxial cable,
or a television program occupying about 3,500,000 Hz can be transmitted
simultaneously with hundreds of phone conversations.
Coaxial
cable, since it has a low attenuation, does not need as many amplifiers
as when using conventional wire. Those that are required are relatively
inexpensive as they simultaneously boost all the hundreds of signals on
the cable.
Besides its importance in the telephone industry, all
the major manufacturers of radio, television, radar, navigation aids,
fire control, aircraft, shipbuilding, underwater sound, and many other
types of transmitting equipment use coaxial cable. The cable TV and
closed circuit TV systems use miles of this type cable. Sophisticated
cable TV systems, for example, use a large diameter single or double
shielded cable as a main transmission line, with tap-offs of smaller
sizes for a secondary lead-in; a third size, even smaller, carries the
televised signal directly into the receiver.
The uses of coaxial
cable extend to any application in which signal loss and attenuation
must be kept to a minimum, or in which the elimination of outside
interference is important. Another application is its utilization in
various systems of instrumentation. Combining many coaxial cables under
one jacket to form an integral unit is used in the computerized
instrumentation field.
PTFE (polytetrafluoroethylene) insulated
high temperature coaxial cable is used by aircraft and missile
manufacturers, inhigh temperature applications, and in products where
protection is desired against strong alkalies and acids or other highly
corrosive fluids.
How are coaxial cables identified? Only cables
made strictly to U.S. Government specifications can be marked with the
RG legend. The meanings of the abbreviations of this legend are as
follows:
R - RADIO FREQUENCY
G - GOVERNMENT
8- Is the number assigned to
the Government approval
/U - A universal specification
If the letters A, B, or C appear before the /,
it means a specification modification or revision. For example - RG 8/U
is superseded by RG 8A/U but both types are still being used.
Types
not marked RG are primarily intended for use where the application is
not met by some government type. There are many other types of cables
designed for specific applications. These are identified in vari- ous
ways by each individual manufacturer.
DEFINITIONS
1. ATTENUATION -
Attenuation is loss of power or signal expressed in decibels; it is
commonly written and spoken of as dB/100 ft. at a specific frequency. An
example is RG 8A/U which has a loss of 5.5 dB/100 ft. at 400 MHz.
2. FREQUENCY
- Frequency is the term designating the number of reverses or cycles in
the flow of alternating current (AC) in one second. For example, the
frequency of AC commonly used in the U.S. is 60 hertz and is usually
shown as 60 Hz. Broadcast stations operate at frequencies of thousands
of cycles per second and their frequencies are called kilohertz (kHz).
Your AM radio dial represents frequencies in kilohertz (kHz). High
frequencies are in millions of cycles per second and are called
megahertz (MHz). TV is broadcast in the MHz range.
3. IMPEDANCE
- Impedance is a term expressing the ratio of voltage to current in a
cable of infinite length. In the case of coaxial cables, impedance is
expressed in terms of "ohms impedance".The coaxial cables generally fall
into three main classes; 50 ohms, 75 ohms, and 95 ohms.
An example of each class is:
RG 8A/U 50 ohms impedance
RG 11A/U 75 ohms impedance
RG 22B/U 95 ohms impedance
4. CAPACITANCE (CAPACITY)
- Capacitance or capacity is the property of a system of conductors and
dielectrics which permits the storage of electricity when a potential
or voltage difference exists between the two conductors. A capacity
value is expressed in farads.When we deal with coaxial cable, the
capacity ranges we have are very small and are expressed in picofarads
(pF). Capacity is the major factor governing impedance. Examples of
cables with typical impedances have capacity as follows:
RG or M17
|
Cable Impedance (ohms)
|
Dielectric Type
|
Capacitance (pF/ft)
|
RG 8A/U |
50
|
PE
|
29.5
|
RG 231A/U
|
50
|
Foam PE
|
25.0
|
RG 188A/U
|
50
|
Solid TFE
|
29.0
|
M17/6
|
75
|
PE
|
20.6
|
RG 306A/U
|
75
|
FoamPE
|
16.5
|
RG 140
|
75
|
Solid TFE
|
21.0
|
M17/90
|
93
|
Air space PE
|
13.5
|
M17/56
|
95
|
PE
|
17.0
|
M17/95
|
95
|
Solid TFE
|
15.4
|
RG 24A/U
|
125
|
PE
|
12.0
|
RG 114A/U
|
185
|
Air space PE
|
6.5
|
5. VELOCITY OF PROPAGATION
- Velocity of propagation, commonly called velocity, is the ratio of
the speed of the flow of an electric current in an insulated cable to
the speed of light. All insulated cables have this ratio and it is
expressed in a percent- age. In the case of coaxial cables with
polyethylene dielectric, this ratio is in the range of 65% - 66%.
In
selecting coaxial cable, we must carefully consider not only design
criteria, but use and application. Selection of materials in relation to
overall design considerations is tabulated in Tables 1 through 4,
below:
|
INNER CONDUCTORS |
SOFT BARE
COPPER |
TINNED SOFT
COPPER |
SILVER - PLATED
COPPER |
NICKEL - PLATED
COPPER |
TINNED - CADIMUM
BRONZE |
COPPER
WELD® |
Maximum operating temperature °C |
200 |
150 |
200 |
250 |
150 |
200 |
Resistivity at 20°C,ohms - circular mil / ft. |
10.371 |
11.133 |
10.371 |
12.5 |
11.92 |
25.928 |
Average tensile strength psi (1,000) |
37 |
37 |
37.5 |
37.5 |
45 |
130 |
Flexibility |
excellent |
excellent |
excellent |
excellent |
good |
good |
Remarks |
most popular - for extra flexibility use stranded |
for added resistance to oxidation and easy solderability, best for low frequency application |
elevated temperature usein aircraft, missile, and electronics, easy solderability |
extra high temperature use |
high tensilestrength with flexibility |
extra high tensile strength |
TABLE 1 - Inner Conductors
|
OUTER CONDUCTORS |
SOFT BARE
COPPER |
TINNED SOFT
COPPER |
SILVER - PLATED
COPPER |
ALUMINUM TUBE |
COPPER TUBE |
Maximum operating temperature °C |
200 |
150 |
200 |
- |
- |
Flexibility |
excellent |
excellent |
excellent |
poor |
poor |
Remarks |
most popular in braid, minimum .004" to .010", add second shield to improve flexibility |
most popular in braid, minimum .004" to .010", add second shield to improve flexibility, better for low frequency |
most popular in braid, minimum .004" to .010", add second shield to improve flexibility, for high temperature |
for high tensile and crushing loads and lower attenuation |
for high tensile strength and crushing loads |
TABLE 2 - Outer Conductors
|
PRIMARY DIELECTRICS |
POLYETHYLENE (PE) |
FOAMED POLYETHYLENE (PE) |
Fluorinated Ethylene Propylene (FEP) |
Poly Tetrafluoroethylene (PTFE) |
BUTYL RUBBER |
Maximum operating temperature °C |
-65 to 80 |
-65 to 80 |
-65 to 200 |
-65 to 260 |
-40 to 80 |
Average tensile strength psi (1,000) |
1.9 |
2.2 |
3.6 |
2.7 |
1.1 |
Flexibility |
good |
good |
excellent |
good |
excellent |
Cut-thru resistance |
good |
poor |
good |
fair |
excellent |
Water Resistance |
excellent |
poor |
excellent |
excellent |
good |
Resistance to organic solvents |
poor |
poor |
excellent |
excellent |
good |
Resistance to acids and alkalies |
excellent |
excellent |
excellent |
excellent |
good |
Remarks |
for use under 80°C maximum |
for use under 80°C maximum |
for high temperature use to 200°C |
for high temperature use to 260°C |
for pulse cables and extreme flexibility |
TABLE 3 - Primary Dielectrics
|
JACKETS |
POLYETHYLENE |
Tetrafluoroe-
thylene
(TFE) |
Fluorinated Ethylene
Propylene (FEP) |
PVC |
NEOPRENE® |
GLASS BRAID |
Maximum operating
temperature °C |
80 |
260 |
200 |
105 |
90 |
260 |
Average tensile strength
psi (1,000) |
1.9 |
3.5 |
2.7 |
2.5 |
3.2 |
- |
Flexibility |
good |
good |
good |
good |
excellent |
excellent |
Resistance to organic
solvents |
poor |
excellent |
excellent |
poor |
good |
excellent |
Resistance to acids and
alkalies |
excellent |
excellent |
excellent |
fair |
good |
excellent |
Abrasion resistance |
good |
excellent |
excellent |
good |
excellent |
poor |
Flame resistance |
slow burn |
nonflammable |
nonflammable |
self-extinguishing |
self-extinguishing |
nonflammable |
Remarks |
for added resistance
to weathering |
to mate with high
temperature dielectric |
to mate with high
temperature dielectric |
most widely used |
to mate with Butyl
dielectric |
to mate with high
temperature dielectric |
TABLE 4 - Jackets
The design formula for characteristic impedance of a single coaxial line is:
where:
Z0 = Characteristic impedance
E = Dielectric constant (air is 1.0), see Table 5.
D = Inside diameter of the "return" (outer) conductor (conductive metal tube or one or more braids),
see Figure 1.
d = Outside diameter of the "go" (inner) conductor, see Figure 1. |
Dielectric Material
|
Dielectric
Constant
(E)
|
Power
Factor
(p)
|
Air
|
1.00
|
|
Polyethylene - cellular foam (PE)
|
1.40 - 2.10
|
0.0003
|
Polyethylene - solid (PE)
|
2.3
|
0.0003
|
Poly Tetrafluoroethylene
(PTFE)
|
2.1
|
0.0002
|
Cellular Poly Tetrafluoroethylene
(PTFE))
|
1.4
|
0.0002
|
Fluorinated Ethylene Propylene
(FEP)
|
2.1
|
0.0007
|
Cellular Fluorinated Ethylene
Propylene (FEP)
|
1.5
|
0.0007
|
Butyl rubber
|
3.1
|
-
|
Silicone rubber
|
2.08 - 3.50
|
0.007 - 0.01
|
MANUFACTURING
The group of RG cables known as semi-solid
dielectric cables, such as RG 62/U, RG 71/U, and RG 63/U, have one thing
in common. They have a center conductor around which a polyethylene
thread is helically wound and then over the thread, a polyethylene
dielectric is extruded. In this respect all of the various groups are
the same in basic design and construction up to the braid stage. We will
discuss the above group since they are the more difficult to
manufacture.
The "go" conductor used in the RG 62/U and RG 71/U
groups is a copper-clad steel core wire, "Copperweld ®". Copperweld® is
made by a carefully controlled process wherein a thick copper covering
is inseparably welded to a high strength steel core. In the case of RG
62/U and RG 71/U, the "go" conductor is 22 gauge with a nominal diameter
of 0.0253". Since high frequency currents travel mainly in the outer
skin of an electrical conductor, the Copperweld® is used in these cables
to provide the unique combination of high strength along with
electrical conductance.
The originality of such a design
exhibits the complexity of choice involved in selecting conductors for
coaxial cable. Table 1 lists some major characteristics of various
conductors in popular use today. Use and application of the finished
cable must not be slighted in the final design criteria. The
manufacturing process of RG 62/U or RG 71/U groups requires several
operations. In the first operation, the polyethylene thread is spiraled
around the conductor.
In the second operation, the dielectric is
extruded over the conductor and spiraled thread. In this operation,
there is a possibility of breakage of the conductor due to the fact that
the spiraled thread is not always even in diameter and it may cause a
jam in the extruder tip. This jam will cause a momentary stoppage and
the resulting jerk may cause breakage. The extruded insulation is "spark
tested" as part of the extrusion operation to make sure there are no
voids or holes in the dielectric. (The inner conductor is at ground
potential.) Any pinhole in the dielectric will result in a spark
failure, which is recorded as to location and reel number so that it may
be cut out before passing through remaining operations.
The
next operation is braiding. The extruded core is braided with one or two
shields as required by the specification. During this operation, and
all remaining operations, the cable is under constant tension. Following
the braiding operation, the cable receives an extruded jacket. Again,
the cable passes through a chain electrode at high potential to detect
any jacket deficiencies. (The braid in this case is at ground
potential.)
When the dielectric of polyethylene coaxial cable
(whether it is solid or semi-solid) is extruded, strains develop in the
material. In theory, these strains are reduced by the use of hot water
in the cooling trough. As the dielectric is run through the cooling
trough, it runs through very hot water to cool water in graduated steps;
therefore, most of the strain should have been relieved. The remaining
operations all keep this first extrusion under tension, so that any
strains which might have been retained from the extrusion operation have
little opportunity to be relieved. When the cable is unreeled, this
releases strains if any are present and there could be a conductor
movement disproportionate to dielectric movement which might show up
only in localized areas. To detect this possible trouble area, the
"sweep test " may be used.
As is seen from the preceding
explanation, there are possible problems arising in the manufacture of
coaxial cable. Some physical problems may lead to electronic problems.
For these reasons, manufacturers are constantly improving process
controls so that the finished cable will meet the highest standards.
The
manufacture of coaxial cable is an exacting process and the very
sophisticated application to which it is put, demands the highest
quality.
Coaxial cable is probably the most versatile type of
cable in existence today. Its development was one of the truly great
milestones in the science of long- distance communication as well as
transmission of highly complex signals within a relatively simple cable.