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1. Cable Landing Station
Cable Landing Station is one important component of a submarine cable system which
comprises of Wet Plant and Dry Plant.
The Dry Plant of a submarine cable system is a segment between the beach manhole and the
cable landing station, comprises of land cable, power feeding equipment (PFE) and submarine
line terminal equipment(SLTE), etc. The Wet Plant of a submarine cable system lies between the
beach manholes, consists of submarine cable, repeater/gain equalizer, branching unit. A typical
schematic of a submarine cable system is shown below.
Typical Schematic for a Submarine Cable System
The PFE and the SLTE of a submarine cable system are installed at the cable landing station. In
some cases, the PFE is installed at a cable landing station nearby the cable landing site, while the
SLTE may be installed in another cable landing station much faraway. For example, the terminal
station at Hillsboro for the SLTE of the TPE cable system is about 150 mile away from the cable
landing site at Nedonna Beach.
Multiple submarine cable systems may share the same cable landing stations. The submarine
cable system is connected with the terrestrial network at the cable landing station, through the so
called backhaul system.
The cable landing site is usually carefully chosen to be in areas:
that have little marine traffic to minimise the risk of cables being damaged by ship
anchors and trawler operations;
with gently sloping, sandy or silty sea-floors so that the cable can be buried to minimise
the chance of damage;
without strong currents that would uncover buried cables and potentially move cables.
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Multiple types of submarine cables may be used in a submarine cable system, subject to depth of
the seabed where the cable lies.
1. Various Types of Submarine Cables
There are four types of optical fibers which are used inside the sea. All fibers differ with each
other in just protection and uses in different conditions.
DA stands for Double armored optical fiber. DA is used in shallow water where cable is more
vulnerable for damage by environment or other factors. SA stands for Single armored optical
fiber. SA is used in less vulnerable but dangerous environment. SA has single armored layer
whereas DA has double armored layer around it.
SL Lightweight (LW) Cable
Light weight cable, and is used in deep sea areas of around 1,000m to 8,500m depth.
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Structure of light weight optical submarine cable
The other is an armored cable being attached a steel wire to the light weight cable, and is used in
a shallower area than about 1,000m depth.
Structure of single armored submarine cable
The other two fiber cables are used in deep water where optical fibers are less disturbed or less
vulnerable. LWP stands for Light Weight Protected optical fiber and LW stands for Light
Weight unprotected optical fiber.
The double armored submarine cable is used at the shore-end, terminated at the beach manhole
at the cable landing site, and is interconnected with much lighter land cable going onward to the
cable landing station.
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2. Optical Submarine Cable Laying Procedure
1. Towards the cable landing station A, one end of the cable is paid out by the cable ship and
landed. During this phase, the balloon buoys are attached along the cable to prevent possible
damages to the cable.
Finally, the buoys are detached, allowing the cable to sink to the seabed.
2. The ship lays the cable towards the opposite station B or the designated point in mid-ocean.
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3. At the designated point, the ship connects the cable with the end point of the previously laid
cable from the station B.
4. After the final splice, the cable is released on the seabed.
4. Optical Submarine Cable Burial Method
In the water area shallower than the depth of 1,000 meters, cables are buried under the seabed
mainly by two ways in order to protect them from damages, which might be caused by fishing
activities or anchors of large vessels.
The one is to use the towed type burying machine, PLOW-II, which performs the simultaneous
operation of cable laying and burial.
PLOW-II makes the installation period shorter because of the simultaneous operation of cable
laying and burial, and is suitable for new and long distance operations.
Since PLOW-II is towed by the vessel on the seabed after threading the cable through it, it
cannot be used for the burial operation after laying(burial after laying).
The working area of PLOW-II is limited depending on the seabed form or the slope.
The other is burial by ROV(MARCAS-III, MARCAS-IV).
ROV digs, by blasting waterjet into the seabed, a trench with the targeted burial depth by coming
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and going several times at the same section, and drops the cable into the trench. Because of this
method, the construction efficiency of ROV is not better than PLOW-II. However, ROV has the
capability that it can float and move around on the sea bed, and ROV can work for the carved
cable section which was caused by the final bight release, or in the area where PLOW-II can not
be operated due to severe condition of the seabed.
Example of Cable Searching and Burial after Laying by ROV
1. Launching ROV and Localizing Failure Point
The cable ship arrives at the cable failure point which is estimated by the electrical and optical
measurement from the cable landing station in advance. The ship launches ROV onto the seabed.
The precise cable failure location is specified by using the subsea cameras and cable sensors
system of ROV.
2. Cable Cutting and Cable Recovery
ROV cuts the cable failure section by the manipulator and cutting tool. It attaches the cable
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holding tool(gripper) to either cable end. After connecting the gripper with the rope paid out
from the ship by the manipulator, the cable is recovered onto the ship. The transponder is
installed around the other cable end, and ROV is recovered onto the ship.
3. Buoy Installation, Cable Search and Recovery
The buoy is attached to the cable on the ship, and is released once on the sea. Again, ROV is
launched on the seabed, and searches the cable's other end relying on the transponder previously
installed. By the same procedure as above item 2, the cable is recovered on the ship.
4. Insertion of Spare Cable and Cable Jointing
The recovered cable in above item 3 and the spare cable in the ship are jointed. After the
jointing, the ship approaches to the buoy in the item 3 laying the spare cable, and recovers the
buoy and cable. After jointing the laying spare cable and the recovered cable, the cables are
released to the seabed.
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5. Cable Burial after Laying
The attached spare cable and the exposed cable on the seabed due to the repair work are buried
under the seabed by the waterjet of ROV
5. Optical Submarine Cable Repair Method
There is a case in which an optical fiber cable is cut or damaged due to ocean earthquakes and
fishing gears etc..
In the situation, the cable ship is urgently dispatched to the cable failure site and repairs the
cable.
The cable repair procedure normally consists of the followings:
1) Localization of the cable failure point.
2) Recovery of the failure cable onto the ship
3) Cutting and removal of the cable failure section
4) Jointing of the recovered cable and the spare cable in the cable tank of the ship
5) Confirmation test and reburial of the cable
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Optical Submarine Cable Repair Procedure
1. The distance of the cable failure location from the landing station is estimated by several tests
in advance. The cable ship is navigated to the location by DGPS. At the place, the tool for cable
search and cutting, which is attached to the rope end, is paid out to the sea. By dragging the
grapnel tool on the seabed, the cable is cut.
2. The rope with the grapnel at its end is paid out from the ship, and one end of the cut cable is
caught by the grapnel(Cable Catch), and is recovered to the ship(Cable Recovery). It might take
more than one day to recover the cable from the sea of 8,000m depth. The optical fiber test and
electrical test of its power feed conductor is carried out. If there is still a failure, the cable is
recovered further, the failure section is cut and removed.
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3. At the end of the cable from which the failure section is removed, the waterproof treatment is
carried out. After the attachment of the mooring rope and buoy to it, the cable is once dropped in
the sea. The cable ship moves for searching the other end of the cable, and repeats the same
procedure as above item 2.
4. The optical fiber test and electrical test of its power feed conductor on the recovered cable is
carried out in the same way as above item 2. If there is a failure, the failure section is cut and
removed. The cable is jointed with the spare cable which is stored in the cable tank(normally,
Universal Joint technology is used). The cable ship approaches to the previously installed buoy
together with paying out the spare cable.
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5. Holding the spare cable, the cable ship recovers the cable attached to the buoy again, and
joints it with the opposite end of the spare cable. For the final confirmation, the test is held
between two cable landing stations of the cable. After the confirmation of the communication
normality, the on-board cable is released to the seabed, and the repair work is completed.
6. Equipment in CLS
1. Power Feeding Equipment (PFE)
The power feeding equipment supplies constant DC current to the submarine repeaters. To
improve the reliability of the system power feeding, power feeding equipment sets with the
capability of feeding all of the system voltages requirement are installed at landing station at
both ends of the system. The voltages to be supplied to the submarine repeaters are allocated to
supply the power feeding equipment at both ends. All PFE’s are duplicated, i.e. they consist of
two suites of generator units. In normal operation, the load is shared between them, but if one
unit were to fail the remaining one will take up the load. A suite can be equipped with up to four
generator units, thus providing up to 10 KV.
Figure 2 shows an example of voltage allocation for a case in which power is fed from both
stations. Usually, each of the two landing stations feeds both positive and negative voltage
corresponding to 1/2 of the total system voltage. If a fault occurs in either of the power feeding
equipments, the one at the opposite landing station feeds the total system voltage in order to
enable a constant current supply to the submarine repeaters. This system redundancy is intended
to improve the system reliability.
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2. Submarine Line Terminal Equipment (SLTE)
SLTE is the equipment where the double armored submarine fiber cable ends towards the CLS.
At SLTE optical fiber separates from conductor cable. Conductor cable is connected to PFE.
SLTE comprises of the latest technologies (DWDM, SDH, etc.) depending upon the make and
model. SLTE is the equipment which multiplexes the optical signal. The capacity of the optical
link depend on the capacity of the SLTE.
3. Optical Distribution Frame (ODF)
Optical distribution frame is a fiber optic management unit used to organize the fiber optic cable
connections. The optic distribution frame is usually used indoor and the ODF could be very big
size frame or small size similar like the patch panel boxes. All the testing can be done at ODF so
that no other part of the equipment is disturbed at that time.
4. Submarine Interface Equipment (SIE)
Submarine Interface Equipment is used at the end where optical fiber is connected towards
terrestrial network. In other words SIE is the interface between subsea network and terrestrial
network. One more ODF is used after SIE for easy arrangement of fiber connections at the
equipment and for testing purpose. i
5. Submarine Fiber Cables
The inner most component of the cable are optical fibers, covered by unit fiber structure. The
fiber structure is then wrapped around by strength wires which give strength to sustain from
tension and pressure under the sea. The strength wires are then covered by copper sheath or
copper wires which are used for transmitting electricity for the repeaters and branching unit.
copper wires are then covered by insulation jacket which is then covered by armored protection
layer.
There are four types of optical fibers which are used inside the sea. All fibers differ with each
other in just protection and uses in different conditions.
DA stands for Double armored optical fiber. DA is used in shallow water where cable is more
vulnerable for damage by environment or other factors. SA stands for Single armored optical
fiber. SA is used in less vulnerable but dangerous environment. SA has single armored layer
whereas DA has double armored layer around it.
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The other two fiber cables are used in deep water where optical fibers are less disturbed or less
vulnerable. LWP stands for Light Weight Protected optical fiber and LW stands for Light
Weight unprotected optical fiber.
Structure of Land Cable