International Journal

on Marine Navigation

and Safety of Sea Transportation

Volume 5

Number 1

March 2011

1 INTRODUCTION

The current infrastructures of the Global Navigation

Satellite System (GNSS) applications are represent-

ed by old fundamental solutions for Position, Ve-

locity and Time (PVT) of the satellite navigation and

determination systems such as the US GPS and Rus-

sian (former-USSR) GLONASS military require-

ments, respectively. The GPS and GLONASS are

first generation of GNSS-1 infrastructures giving

positions to about 30 metres, using simple

GPS/GLONASS receivers (Rx) onboard ships or

aircraft, and they therefore suffer from certain

weaknesses, which make them impossible to be used

as the sole means of navigation for ships, particular-

ly for land (road and rail) and aviation applications.

In this sense, technically GPS or GLONASS sys-

tems used autonomously are incapable of meeting

civil maritime, land and especially aeronautical mo-

bile very high requirements for integrity, position

availability and determination precision in particular

for Traffic Control and Management (TCM) and are

insufficient for certain very critical navigation and

flight stages. [01, 02].

Because these two systems are developed to pro-

vide navigation particulars of position and speed on

the ship’s bridges or in the airplane cockpits, only

captains of the ships or airplanes know very well

their position and speed, but people in Traffic Con-

trol Centers (TCC) cannot get in all circumstances

their navigation or flight data without service of new

CNS facilities. Besides of accuracy of GPS or

GLONASS, without new CNS is not possible to

provide full TCM in every critical or unusual situa-

tion. Also these two GNSS systems are initially de-

veloped for military utilization only, and now are al-

so serving for all transport civilian applications

worldwide, so many countries and international or-

ganizations would never be dependent on or even

entrust people’s safety to GNSS systems controlled

by one or two countries. However, augmented

GNSS-1 solutions of GSAS network were recently

developed to improve the mentioned deficiencies of

Maritime Communication, Navigation and

Surveillance (CNS)

S. D. Ilcev

Durban University of Technology (DUT), Durban, South Africa

ABSTRACT: This paper introduces development and implementation of Maritime Satellite Communications,

Navigation and Surveillance (CNS) of GPS or GLONASS for enhancement of safety and emergency systems

including security and control of vessels, logistic and freight at sea, on inland waters and the security of crew

and passengers on board ships, cruisers, boats, rigs and hovercrafts. These improvements include many appli-

cations for the better management and operation of vessels and they are needed more than ever because of

world merchant fleet expansion. Just the top 20 world ships registers have more than 40,000 units under their

national flags. Above all, the biggest problem today is that merchant ships and their crews are targets of the

types of crime traditionally associated with the maritime industries, such as piracy, robbery and recently, a

target for terrorist attacks. Thus, International Maritime Organization (IMO) and flag states will have a vital

role in developing International Ship and Port Security (ISPS). The best way to implement ISPS is to design

an Approaching and Port Control System (APCS) by special code augmentation satellite CNS for all ships in-

cluding tracking and monitoring of all vehicle circulation in and out of the seaport area. The establishment of

Maritime CNS is discussed as a part of Global Satellite Augmentation Systems (GSAS) of the US GPS and

Russian GLONASS for integration of the existing Regional Satellite Augmentation Systems (RSAS) such as

the US WAAS, European EGNOS and Japanese MSAS, and for development new RSAS such as the Russian

SDMC, Chinese SNAS, Indian GAGAN and African ASAS. This research has also to include RSAS for Aus-

tralia and South America, to meet all requirements for GSAS and to complement the services already provid-

ed by Differential GPS (DGPS) for Maritime application of the US Coast Guard by development Local Satel-

lite Augmentation System (LSAS) in seaports areas.

current military systems and to meet the present

transportation civilian requirements for high-

operating Integrity, Continuity, Accuracy and Avail-

ability (ICAA). These new developed and operation-

al CNS solutions are the US Wide Area Augmenta-

tion System (WAAS), the European Geostationary

Navigation Overlay System (EGNOS) and Japanese

MTSAT Satellite-based Augmentation System

(MSAS), and there are able to provide CNS data

from mobiles to the TCC via Geostationary Earth

Orbit (GEO) satellite constellation.

These three RSAS are integration segments of the

GSAS network and parts of the interoperable GNSS-

1 architecture of GPS and GLONASS and new

GNSS-2 of the European Galileo and Chinese Com-

pass, including Inmarsat CNSO (Civil Navigation

Satellite Overlay) and new projects of RSAS infra-

structures. The additional four RSAS of GNSS-1

networks in development phase are the Russian Sys-

tem of Differential Correction and Monitoring

(SDCM), the Chinese Satellite Navigation Augmen-

tation System (SNAS), Indian GPS/GLONASS and

GEOS Augmented Navigation (GAGAN) and Afri-

can Satellite Augmentation System (ASAS). Only

remain something to be done in South America and

Australia for establishment of the GSAS infrastruc-

ture globally, illustrated in Figure 1.

Figure 1. GSAS Network Configuration

Courtesy of Book: “Global Aeronautical CNS” by Ilcev [01]

The RSAS solutions are based on the GNSS-1

signals for augmentation, which evolution is known

as the GSAS network and which service provides an

overlay function and supplementary services. The

future ASAS Space Segment will be consisted by

existing GEO birds, such as Inmarsat-4 and Artemis

or it will implement own satellite constellation, to

transmit overlay signals almost identical to those of

GPS and GLONASS and provide CNS service. The

South African firm IS Marine Radio, as designer of

the Project will have overall responsibility for the

design and development of the ASAS network with

all governments in the region.

1.1 GNSS Applications

The RSAS infrastructures are available globally to

enhance current standalone GPS and GLONASS

system PVT performances for maritime, land (road

and rail) and aeronautical transport applications. Us-

er devices can be configured to make use of internal

sensors for added robustness in the presence of

jamming, or to aid in vehicle navigation when the

satellite signals are blocked in the “urban canyons”

of tall city buildings or mountainous environment. In

the similar sense, some special transport solutions,

such as maritime and especially aeronautical, require

far more CNS accuracy and reliability than it can be

provided by current military GPS and GLONASS

space infrastructures [01, 03].

Moreover, positioning accuracy can be improved

by removing the correlated errors between two or

more satellites GPS and/or GLONASS Rx terminals

performing range measurements to the same satel-

lites. This type of Rx is in fact Reference Receiver

(RR) surveyed in, because its geographical location

is precisely well known. In such a manner, one

method of achieving common error removal is to

take the difference between the RR terminals sur-

veyed position and its electronically derived position

at a discrete time point. These positions differences

represent the error at the measurement time and are

denoted as the differential correction, which infor-

mation may be broadcast via GEO data link to the

user receiving equipment. In this case the user GPS

or GLONASS augmented Rx can remove the error

from its received data.

Alternatively, in non-real-time technique GNSS

solutions, the differential corrections can be stored

along with the user’s positional data and will be ap-

plied after the data collection period, which is typi-

cally used in surveying applications [04].

If the RR or Ground Monitoring Station (GMS)

of the mobile users, the mode is usually referred to

as local area differential, similar to the US DGPS for

Maritime applications. In this way, as the distance

increases between the users and the GMS, some

ranging errors become decorrelated. This problem

can be overcome by installing a network consisting a

number of GMS reference sites throughout a large

geographic area, such as a region or continent and

broadcasting the Differential Corrections (DC) via

GEO satellites. In such a way, the new projected

ASAS network has to cover entire African Continent

and the Middle East region.

Therefore, all GMS sites connected by Terrestrial

Telecommunication Networks (TTN) relay collected

data to one or more Ground Control Stations (GCS),

where DC is performed and satellite signal integrity

is checked. Then, the GCS sends the corrections and

integrity data to a major Ground Earth Station (GES)

for uplink to the GEO satellite. This differential

technique is referred to as the wide area differential

system, which is implemented by GNSS system

known as Wide Augmentation Area (WAA), while

another system known, as Local Augmentation Area

(LAA) is an implementation of a local area differen-

tial [05].

The LAA solution is an implementation for sea-

ports and airport including for approaching utiliza-

tions. The WAA is an implementation of a wide area

differential system for wide area CNS maritime,

land and aeronautical applications, such as Inmarsat

CNSO and the newly developed Satellite Augmenta-

tion WAAS in the USA, the European EGNOS and

Japanese MSAS [03].

Figure 2. ASAS Network Configuration

Courtesy of Book: “Understanding GPS - Principles and Ap-

plications” by E.D. Kaplan [03]

These three operational systems are part of the

worldwide GSAS network and integration segments

of the future interoperable GNSS-1 architecture of

GPS and GLONASS and GNSS-2 of Galileo and

Compass, including CNSO as a part of GNSS offer-

ing this service via Inmarsat-3/4 and Artemis space-

craft. The author of this paper for the first time is us-

ing more adequate nomenclature GSAS than

Satellite-based Augmentation System (SBAS) of

ICAO, which has to be adopted as the more common

designation in the field of CNS [06].

As discussed earlier, the current three RSAS net-

works in development phase are the Russian SDCM,

Chinese SNAS and Indian GAGAN, while African

Continent and Middle East have to start at the be-

ginning of 2011 with development ASAS project. In

this sense, development of forthcoming RSAS pro-

jects in Australia and South America will complete

Augmented CNS system worldwide, known as an

GSAS Network [04].

Three operational RSAS together with Inmarsat

CNSO are interoperable, compatible and each con-

stituted of a network of GPS or GLONASS observa-

tion stations and own and/or leased GEO communi-

cation satellites. Namely, the Inmarsat CNSO

system offers on leasing GNSS payload to the Euro-

pean system EGNOS, which will provide precision

to within about 5 metres and is operational from

2009. In fact, it also constitutes the first steps to-

wards forthcoming Galileo, the future European sys-

tem for civilian global navigation by satellite. The

EGNOS system uses leased Inmarsat AOR-E and

IOR satellites and ESA ARTEMIS satellite. Thus,

the US-based WAAS is using Inmarsat satellites and

Japanese MSAS is using its own multipurpose

MTSAT spacecraft, both are operational from 2007

and 2008, respectively. Although the global posi-

tioning accuracy system associated with the overlay

is a function of numerous technical factors, includ-

ing the ground network architecture, the expected

accuracy for the US Federal Aviation Administra-

tion (FAA) WAAS will be in the order of 7.6 m (2

drms, 95%) in the horizontal plane and 7.6 m (95%)

in the vertical plane [04, 05].

1.2 RSAS System Configuration

The RSAS network are designed and implemented

as the primary means of satellite CNS for maritime

course operations such as ocean crossings, naviga-

tion at open and close seas, coastal navigation,

channels and passages, approachings to anchorages

and ports, and inside of ports, and for land (road and

railways) solutions. In this sense, it will also serve

for aviation routes in corridors over continents and

oceans, control of airports approachings and manag-

ing all aircraft and vehicles movements on airports

surface [03]:

It was intended to provide the following services:

1 The transmission of integrity and health infor-

mation on each GPS or GLONASS satellite in re-

al time to ensure all users do not use faulty satel-

lites for navigation, known as the GNSS Integrity

Channel (GIC).

2 The continuous transmission of ranging signals in

addition to the GIC service, to supplement GPS,

thereby increasing GPS/GLONASS signal avail-

ability. Increased signal availability also trans-

lates into an increase in Receiver Autonomous In-

tegrity Monitoring (RAIM) availability, which is

known as Ranging GIC (RGIC).

3 The transmission of GPS or GLONASS wide area

differential corrections has, in addition to the GIC

and RGIC services, to increase the accuracy of

civil GPS and GLONASS signals. Namely, this

feature has been called the Wide Area Differen-

tial GNSS (WADGNSS).

The combination of the Inmarsat overlay services

and Artemis spacecraft will be referred to as the

ASAS network illustrated in Figure 2. As observed

previous figure, all mobile users (3) receive naviga-

tion signals (1) from GNSS-1 of GPS or GLONASS

satellites. In the near future can be used GNSS-2

signals of Galileo and Compass satellites (2). These

signals are also received by all reference GMS ter-

minals of integrity monitoring networks (4) operated

by governmental agencies in all countries within Af-

rica and Middle East.

The monitored data are sent to a regional Integri-

ty and Processing Facility of GCS (5), where the da-

ta is processed to form the integrity and WADGNSS

correction messages, which are then forwarded to

the Primary GNSS GES (6). At the GES, the naviga-

tion signals are precisely synchronized to a reference

time and modulated with the GIC message data and

WADGNSS corrections. The signals are sent to a

satellite on the C-band uplink (7) via GNSS payload

located in GEO Inmarsat and Artemis spacecraft (8),

the augmented signals are frequency-translated to

the mobile user on L1 and new L5-band (9) and to

the C-band (10) used for maintaining the navigation

signal timing loop. The timing of the signal is done

in a very precise manner in order that the signal will

appear as though it was generated on board the satel-

lite as a GPS ranging signal. The Secondary GNSS

GES can be installed in Communication CNS GES

(11), as a hot standby in the event of failure at the

Primary GNSS GES. The TCC ground terminals

(12) could send request to all particular mobiles for

providing CNS information by Voice or Data, in-

cluding new Voice, Data and Video over IP

(VDVoIP) on C-band uplink (13) via Communica-

tion payload located in Inmarsat or Artemis space-

craft and on C-band downlink (14) to mobile users

(3). The mobile users are able to send augmented

CNS data on L-band uplink (15) via the same

spacecraft and L-band downlink (16). The TCC

sites are processing CNS data received from mobile

users by Host and displaying on the surveillance

screen their current positions very accurate and in

the real time [03]. Therefore, the ASAS will be used

as a primary means of navigation during all phases

of traveling for all mobile applications [06].

The RSAS space constellation could be formally

consisted in the 24 operational GPS and 24

GLONASS satellites and of 2 Inmarsat and 1 Arte-

mis GEO satellites. The GEO satellites downlink the

data to the users on the GPS L1 RF with a modula-

tion similar to that used by GPS. Information in the

navigational message, when processed by an RSAS

Rx, allows the GEO satellites to be used as addition-

al GPS-like satellites, thus increasing the availability

of the satellite constellation. At this point, the RSAS

signal resembles a GPS signal origination from the

Gold Code family of 1023 possible codes (19 signals

from PRN 120-138).

2 MARITIME TRANSPORTATION

AUGMENTATION SYSTEM (MTAS)

The navigation transponder of GEO payload is a key

part of the entire system. Thus, it sends GNSS sig-

nals to mobiles in the same way as GPS or

GLONASS satellites and improves the ICAA posi-

tioning system. Thanks to the large number of mo-

biles, the GNSS signal is able to incorporate data on

GPS spacecraft status and correction factors, greatly

improving the reliability and accuracy of the present

GPS system, which comes to few tenths of metres.

The augmented GPS and GLONASS accuracy will

be just a few metres, allowing maritime and land

traffic to be controlled solely by satellite, without

ground radar or radio beacons facilities.

To complement the GPS channel, communication

channels allow bidirectional transmission between

ships and GES. The ship sends its position and navi-

gation data to the Port authorities, TTC and to the

relevant ship-owner. This enables ship movements

to be managed and to enhance safety at sea and to

improve operating efficiency. The satellite will for-

ward flexible and safe routing information to ships,

as determined by the shore centre, decreasing fuel

consumption, reducing sailing times and enhancing

the safety and security systems in all sailing stages.

The CNS/MTAS mission is divided into three Mari-

time CNS systems, such as Communication, Naviga-

tion and Surveillance. As usual, the MTAS system

consists in space and ground infrastructures [2].

2.1 Space Segment

The space segment for MTAS infrastructure and

mission, as a part of GSAS configuration, can be the

same new designed GEO and/or leased Inmarsat,

Japanese MTSAT, European Artemis of ESA or any

existing GEO with enough space for GNSS tran-

sponder inside of payload. The spacecraft GNSS

payload can provide global and spot beam coverage

with determined position on about 36,000 km over

the equator.

The MTAS spacecraft also can have an innova-

tive communication purpose payload for Maritime

Mobile Satellite Service (MMSS), which will be

similar to the Inmarsat system of Mobile Satellite

Communications (MSC). The heart of the payload is

an IF processor that separates all the incoming chan-

nels and forwards them to the appropriate beam in

both directions: forward (ground-to-ship) and return

(ship-to-ground). In fact, global beam covers 1/3 of

the Earth between 75

North and South latitudes.

Thus, spot beam coverage usually consists in 6 spot

beams over determined regions including heavy traf-

fic areas at sea, to meet the demands of increasing

maritime transport operations and for enhanced safe-

ty and security [6].

The GNSS signal characteristics are generally

based on the ICAO Annex 10 (SARP), IMO and

Inmarsat SDM and comply with the Radio Regula-

tions and ITU-R Recommendations. This type of

spacecraft has two the following types of satellite

links related to the maritime Ship Earth Stations

(SES) and Ground Earth Stations (GES):

Figure 3. SES or Shipborne DVB-RCS Terminal

Courtesy of Book: “Global Mobile Satellite Communications”

by Ilcev [6]

2.1.1 Forward GES to Satellite Direction

The GES terminals are located throughout the re-

gion coverage and their signals are received by L,

Ku or a Ka-band ships antenna. Thanks to the very

high Radio Frequency (RF) used, the reflector size

of the antennas is quite small, 500 mm for Ku-band,

450 mm for Ka-band and double size for L-band.

The reflector onboard mobile is movable via focus-

ing tracking motors automatically correcting Azi-

muth and Elevation angles. The focusing motors are

connected to the Gyrocompass onboard ships, so

that it can work with the communications satellite

payloads in any of the possible vessel positions in

four GEO coverages, see Figure 3. The GES uses C-

band feeder link and SES uses L-band service link

with larger size of antenna than antennas using Ku

and Ka-band. The SES standards are using new

broadband technique and are capable to provide

Broadcast, Multimedia and Internet service for

Voice, Data and Video over IP (VDVoIP) and IPTV.

Incoming signals are then amplified, converted to IF,

filtered and routed within the IF processor where

they are then up-converted and transmitted to the

SES. Otherwise, the author of this paper proposed

this solution in 2000 in his book [6] as Maritime

Broadband, seven years before Inmarsat offered and

promoted its FleetBroadband.

2.1.2 Return Satellite to GES Direction

The L-band signal received from approaching

SES are processed in the same way and retransmit-

ted to GES via Ku and Ka-band GES antennas, alt-

hough the GES system can also employ Inmarsat C-

band transmitter and antenna. The output power of

the Ku and Ka-band SES transmitters is just 2W

thanks to the high gain satellite antenna. It is also

possible to provide station-to-station channels in ei-

ther the Ku or Ka-band to enable stations working

with different spots to communicate with one anoth-

er. The GNSS channel is also routed to GES on

same two bands for calibration purposes [7].

2.2 Ground Segment

The MTAS Ground Segment consists in several

GES and Ground Control Terminal (GCT) located in

any corresponding positions. Thus, an important fea-

ture of these stations is that they have been built to

withstand earthquakes, which also required a special

antenna design.

2.2.1 Ground Earth Stations (GES)

In order to provide continuous service, even dur-

ing natural disasters, two GES can be implemented

at two different locations separated by about 500

km. The MMSS provided by GES is in charge of all

communication functions via satellites. With a 13 m

antenna diameter GES transmits and receives signals

in the Ku, Ka and C-band. A very high EIRP of 85

dBW and a high G/T ratio of 40 dB/K are achieved

in the Ku and Ka-band, respectively and ensure very

high availability of the feeder link. The L-band ter-

minal similar to the SES is used for the system test-

ing and monitoring. About 300 circuits are available

simultaneously in both: transmit and receive direc-

tions. It also includes dedicated equipment for test-

ing the satellite performance after launch and for

permanent monitoring of the traffic system. Top-

level management software is provided to configure

the overall system and check its status.

2.2.2 Ship Earth Stations (SES)

Special part of the MTAS Ground Segment are

SES terminals approaching to the entire region in-

cluding GNSS. It is similar to the Inmarsat standards

containing: ADE (Above Deck Equipment) as an an-

tenna and BDE (Below Deck Equipment) as a trans-

ceiver with peripheral equipment using L-band. The

BDE Voice, Data and Video (VDV) terminals can

be used for ship crew and cabin crew including pas-

senger applications. The SES is a ship-mounted ra-

dio capable of communications via spacecraft in the

MTAS system, providing VDV and Fax two-way

service anywhere inside the satellite footprint.

2.2.3 Satellite Control Stations (SCS)

The SCS terminal is usually located in the same

building as the GES and utilizes an antenna with the

same diameter. This station has to control the satel-

lite throughout its operational life in the Network.

Two Radio Frequency (RF) bands can be used: S-

band in normal operation and Unified S-band (USB)

while the satellite is being transferred to its final or-

bit, or in the event of an emergency when satellite

loses its altitude. Accordingly, in S-band the EIRP is

84 dBW and for security reasons, the EIRP in USB

is as high as 104 dBW. An SCS displays the satel-

lite’s status and prepares telecommands to the satel-

lite. Furthermore, the satellite position is measured

very accurately (within 10 m) using a trilateral rang-

ing system instead of measuring one signal, which is

sent to the satellite then returned to the Earth. On the

other hand, the Station sends out two additional sig-

nals, which are retransmitted by the satellite to two

dedicated ranging stations on the ground, which re-

turn the same signals to the SCS via satellite. This

technique allows the satellite’s position to be meas-

ured in three dimensions. On the other hand, a dy-

namic spacecraft simulator is also provided to check

telecommands.

2.2.4 GNSS System

The GNSS system known as the MTAS for mari-

time applications consists in a large number of

GMS, GCS, GES and few Geostationary Ranging

Stations (GRS) to implement a wide triangular ob-

servation base for GEO satellite ranging. The GMS

terminals are very small autonomous sites housed in

a shelter of some adequate building with appropriate

antenna system and trained staff. Each GMS com-

putes its location using GPS and MTAS communica-

tion signals over the coverage area. Any differences

between the calculated and real locations are used by

the system to correct the satellite data. Data is sent to

the GCS via the public network or satellite links,

while the GCS collects all the information from each

GMS. Complex software is able to calculate accu-

rately the position and internal times of all GPS and

MTAS satellites. The GNSS signal, incorporating

the status of the GPS spacecraft and corrections, is

calculated and sent to the traffic station known as

GES for transmission to MTAS satellites [7].

3 COMPARISON OF THE CURRENT AND

NEW MARITIME CNS SYSTEM

Business or corporate shipping and airways compa-

nies have used for several decades HF communica-

tion for long-range voice and telex communications

during intercontinental sailing and flights. Mean-

while, for short distances mobiles have used the

well-known VHF onboard ships and VHF/UHF ra-

dio on aircraft. In the similar way, data communica-

tions are recently also in use, primarily for travel

plan and worldwide weather (WX) and navigation

(NX) warning reporting. Apart from data service for

cabin crew, cabin voice solutions and passenger te-

lephony have also been developed. Thus, all mobiles

today are using traditional electronic and instrument

navigations systems and for surveillance facilities

they are employing radars.

The current communication facilities between

ships and Maritime Traffic Control (MTC) are exe-

cuted by Radio MF/HF voice and telex and by VHF

voice system; see Previous Communication Subsys-

tem in Figure 4. The VHF link between ships on one

the hand and Coast Radio Station (CRS) and TCC

on the other, may have the possibility to be inter-

fered with high mountainous terrain and to provide

problems for MTC. The HF link may not be estab-

lished due to lack of available frequencies, high fre-

quency jamming, bad propagation, intermediation,

unstable wave conditions and to very bad weather,

heavy rain or thunderstorms.

The current navigation possibilities for recording

and processing Radio Direction Information (RDI)

and Radio Direction Distance Information (RDDI)

between vessels and TCC or MTC centre are per-

formed by ground navigation equipment, such as the

shore Radar, Racons (Radar Beacon) and Passive

Radar Reflectors, integrated with VHF CRS facili-

ties, shown by Previous Navigation Subsystem in

Figure 4. However, this subsystem needs more time

for ranging and secure navigation at the deep seas,

within the channels and approachings to the anchor-

ages and ports, using few onboard type of radars and

other visual and electronic navigation aids.

The current surveillance utilities for receiving

Radar and VHF Voice Position Reports (VPR) and

HF Radio Data/VPR between ships and TCC and

Maritime Traffic Management (MTM) can be de-

tected by Radar and MF/HF/VHF CRS. This subsys-

tem may have similar propagation problems and lim-

ited range or when ships are sailing inside of fiords

and behind high mountains Coastal Radar cannot de-

tect them; see the Surveillance Subsystem in Figure

4. The very bad weather conditions, deep clouds and

heavy rain could block radar signals totally and on

the screen will be blanc picture without any reflected

signals, so in this case cannot be visible surrounded

obstacles or traffic of ships in the vicinity, and the

navigation situation is becoming very critical and

dangerous causing collisions and huge disasters [8,

9, 10].

On the contrary, the new Communication

CNS/MTM System utilizes the communications sat-

ellite and it will eliminate the possibility of interfer-

ence by very high mountains, see all three CNS Sub-

systems in Figure 4.

At this point, satellite voice communications, in-

cluding a data link, augments a range and improves

both the quality and capacity of communications.

The WX and NX warnings, sailing planning and

NAVAREA information may also be directly input

to the Navigation Management System (NMS).

Figure 4. Current and New CNS/MTM System

Courtesy of Book: “Global Mobile Satellite Communications”

by Ilcev [6]

The new Navigation CNS/MTM System is

providing improved GPS/GLONASS navigation da-

ta, while Surveillance CNS/MTM System is utilizing

augmented facilities of GPS or GLONASS signals.

Thus, if the navigation course is free of islands or

shallow waters, the GPS Navigation Subsystem data

provides a direct approaching line and the surveil-

lance information cannot be interfered by mountain-

ous terrain or bad weather conditions. The display

on the screen will eliminate misunderstandings be-

tween controllers and ship’s Masters or Pilots [02,

10].

4 MARITIME MOBILE SATELLITE SERVICE

(MMSS)

The MMSS functions in frame of the new MTAS in-

frastructure include the provision of all the mobile

maritime communications defined by the IMO, such

as new Global Maritime Distress and Safety System

(GMDSS), Inmarsat and Cospas-Sarsat systems, in-

cluding new systems with nomenclatures such as

Maritime Commercial Communications (MCC) and

Maritime Crew and Passenger Communications

(MCPC).

Figure 5. Future MTAS Navigation

In a more general sense, these MSC service solu-

tions could be available for MTM, Maritime Traffic

Control (MTC) and Maritime Traffic Service (MTS)

providers and maritime operators in all ocean re-

gions through data link service providers. Direct ac-

cess to the MTAS network could also be possible

through the implementation of dedicated GES in

other states covered by MTAS spacecraft.

The MTAS system for the SES is interoperable

with MSC system of the Inmarsat Space and Ground

network. It can be connected directly to the naviga-

tion bridge GMDSS operator (Master, duty-deck or

radio officer) by VDV, Fax, video, GPS augmenta-

tion information and Automatic Dependent Surveil-

lance System (ADSS).

The MTAS will not only be capable of handling

MTS for ocean going vessels, but will also be of-

fered to the Civil Maritime Community (CMC) in all

coastal regions as an infrastructure, which could fa-

cilitate the implementation of the future IMO

CNS/MTM systems.

The MTAS service provides all ocean going ves-

sels with GPS augmentation information to improve

safety and security at sea and all navigational per-

formance requirements, namely to find out the re-

sponse to the demands of ICAA, which are essential

to the use of GPS or GLONASS for vessels opera-

tion as the sole means of navigation. Using previous

not augmented system, ship navigation officers

know very well where their ship is in space and

time, but offshore MTC terminals don’t know. In

order to provide all ships and MTC with sufficient

GPS augmentation information and satellite surveil-

lance, a certain number and location of GMS will be

required. At this point, the number and location of

GMS required for each state in the region will de-

pend on the requirements for the level of navigation

services and reception of GPS signals. The MTAS

system needs number of GMS, few GCS and GES

for the each region [6, 10].

4.1 Current Radio and MSC System

The previous Maritime Radio Communications

(MRC) system for general international purposes has

been operational over 100 years and recently was

replaced by MSC system to enhance ship-to-shore

voice and data traffic for both commercial and safety

applications. In general, the initial development will

have been established by using a service of MRC on

MF and HF Morse radiotelegraphy, radio telex and

radiotelephony (voice) for maritime medium and

long distance communications, respectively. The lat-

ter progress was in order to promote advanced mari-

time short distance commercial, safety, approaching

and on scene distress communications on VHF voice

frequency band. Finally, global DCS MF/HF/VHF

Radio subsystem was developed by IMO in frame of

GMDSS system and integrated with Inmarsat and

Cospas-Sarsat facilities.

Meanwhile, in order to respond to the significant

increase in the volume of communications data that

has accompanied the large increases in cargo mari-

time traffic, periodic communications have moved to

the satellite communications low, medium and high

speed data link and data transmission has become

the core type of maritime communications. The me-

dia needs to be divided to reflect this change in

communications content, which has seen voice (Tel)

communications used mainly for irregular safety and

security or even for emergency situations in general.

A transmission system based on fundaments new

GMDSS digital technology (bit-based) needs to be

integrated by the MTAS, to introduce wholesale im-

provements in Satellite CNS ability and to enhance

current system for emergency (distress, safety and

security) [06, 10].

Gradually, new MMSS VDV and VDVoIP links

have come into use and totally may replace old HF

and VHF traditional radio. Because of any emergen-

cy and very bad weather conditions ship can be ex-

tremely affected, it is necessary to keep them as al-

ternative solutions and to employ again a well-

trained Radio Officer on board every oceangoing

ship. However, in normal circumstances and for fast

communication impact SES can be used for commu-

nications with corresponding GES via any MATS or

Inmarsat GEO satellite for maritime commercial,

emergency and social purposes [6].

Figure 6. Future MTAS Surveillance System

Courtesy of Book: “Global Mobile Satellite Communications”

by Ilcev [6]

4.2 Integration of RSAS and GNSS

The GPS or GLONASS can be used worldwide to

control the positions of vessels and to manage mari-

time traffic for oceangoing and coastal navigation.

They support vessel’s navigation well in all routing

phases, including approaching to the port and moor-

ing utilities. In fact, they have some performance

limitations and they cannot consistently provide the

highly precise and quite safe information in the sta-

ble manner required for wide-area navigation ser-

vices. To assure safe and efficient sea traffic naviga-

tion of civil vessels, GPS and GLONASS

performance needs to be augmented with another

system that provides ICAA essential elements well

for sea navigation. The MTAS augmentation solu-

tion for GPS/GLONASS can be integrated with ade-

quate Land Transportation Augmentation System

(LTAS) and Aeronautical Transportation Augmenta-

tion System (ATAS) into the US WAAS, Japanese

MSAS, European EGNOS, Russian SDCM, Chinese

SNAS, Indian GAGAN and new systems such as

ASAS, Australian and South American RSAS. Once

in operation, this new state-of-the-art system will as-

sure full navigation services for vessels in all navi-

gation phases within the oceanwide, coastal, ap-

proaching and channel waters through GSAS

coverage.

The L1/L2 RF band is nominated for the trans-

mission of signals from GNSS spacecraft in ground

and air directions, which can be detected by the

GMS, GES and GNSS-1 onboard ship’s receivers.

Otherwise, the MTAS GNSS satellite transponder

uses the L1 RF band to broadcast GNSS augmenta-

tion signals in the direction from GES to SES. The

L, Ku or Ka-band is used for unlinking GNSS aug-

mentation data from SES via GEO spacecraft to

TCC. The whole ground infrastructure and Commu-

nication System is controlled by GCS and Network

Control System (NCS). The components of the

MTAS navigation system are illustrated in Figure 5.

To provide GNSS augmentation information, all

ground stations, which monitor GNSS signals, are

necessary in addition to MTAS. This special naviga-

tion infrastructure, which is composed by MTAS,

GPS/GLONASS or GNSS wide-area augmentation

system and these ground stations, is called the

MTAS network [02, 06].

4.3 Wide Area Navigation (WANAV) System

The Wide Area Navigation (WANAV) system is a

way of calculating own precise position using the

Ship Surveillance Satellite Equipment (SSSE) facili-

ties and other installed onboard ship navigation de-

vices to navigate the desired course and to send this

position to TCC. In the case of WANAV routes it

has been possible to connect in an almost straight

line to any desired point within the area covered by

the satellite equipment and service.

In any event, setting the WANAV routes has

made it possible to ease congestion on the main sea

routes and has created double tracks. This system

enables more secure, safety and economical sea nav-

igation routes.

4.4 MTAS Automatic Dependent Surveillance

System (ADSS)

The current radio surveillance system is mainly sup-

ported by VHF CRS. Namely, this system enables

display of real-time positions of the nearby ap-

proaching ships using radar and VHF voice radio

equipment. Due to its limitations, the VHF service

being used for domestic sea space, channels and

coastal waters cannot be provided over the ocean.

Meanwhile, out of radar range and VHF coverage on

the oceanic routes, the ship position can be regularly

reported by HF radio voice or via data terminals to

the HF CRS.

Consequently, the advanced CNS/MTM system

utilizes the ADSS data function, which automatical-

ly reports all current ships positions measured by

GPS to MTC, as illustrated in Figure 6. In this way,

the approaching vessels receives positioning data

from GPS spacecraft or GPS augmented data via

GEO satellite transponder, as illustrated in Figure 5,

and then sends via GES its current position for re-

cording and processing to the MTC terminal and

displaying on the like radar screen. This service en-

hances safety, security and control of vessels in

ocean and coastal navigation.

The screen display of satellite ADSS looks just

like a pseudo-radar coverage picture showing posi-

tions of the ships. The new ADSS system will in-

crease safety and security at sea and reduce ships

separation, improve functions and selection of the

optimum route with more economical courses. It

will also increase the accuracy of each ship position

and reduce the workload of both controller and

ship’s Master or Pilot, which will improve safety

and security. In this sense, ships can be operated in a

more efficient manner and furthermore, since the ar-

eas where VHF radio does not reach due to the short

range, mountainous terrain or bad weather will dis-

appear, small ships, including Pilot boats and heli-

copters, will be able to obtain any data and safety in-

formation on a regular basis. These functions are

mandatory to expand the traffic capacity of the en-

tire ocean or coastal regions for all ships and for the

optimum navigation and safety route selection under

limited space and time restraints [02, 06].

Figure 7. SESR Subsystem

Courtesy of Paper, “Satellite CNS for MTAS” by St. D. Il-

cev [2]

5 SPECIAL EFFECTS OF THE MTAS SYSTEM

Special effects of the MTAS system used for secure

communications, navigation, ranging, logistics and

control of the vessels at sea, in the channels, around

the coastal waters and in the port surface ship traffic

are Safety Enhancements on Short and Long Rang-

es, Reduction of Separation Minima, Flexible Sail-

ing Profile Planning and Coastal Movement Guid-

ance and Control.

These effects of the MTAS are very important to

improve maritime communication facilities in any

phase of sailing, to enable better control of ships,

provide flexible and economic trip with optimum

routes, to enhance surface guidance and control in

port and in any case to improve safety and security

at sea and in the ports.

5.1 Safety Enhancements at Short and Long Ranges

A very important effect of the new MTAS system

for CNS/MTM is to provide Safety Enhancement at

Short Ranges (SESR) via GES, as illustrated in Fig-

ure 7.

Current radio system for short distances between

vessels and CRS is provided by VHF voice or by

new DSC VHF voice and data equipment, so the

ship’s Master or Pilot will have many problems es-

tablishing voice bridge radio communications when

the ship position is in the shadow of high mountains

in coastal waters.

Meanwhile, all vessels sailing in coastal waters or

fiords and in ports can receive satellite navigation

and communications even at short distances and

where there is no navigation and communications

coverage due to mountainous terrain. This is very

important for safety and secure navigation during

bad weather conditions and reduced visibility in

channels, approachings and coastal waters, to avoid

collisions and disasters.

The MTAS system is also able to provide Safety

Enhancement at Long Rangers (SELR) illustrated in

Figure 8, by using faded HF radio system or the

noise-free satellite system. In such a way, many

ships out of VHF range can provide their augmented

or not augmented positions to MTC or will be able

to receive safety and weather information for secure

navigation [02, 06].

5.2 Reduction of Separation Minima (RSM)

One of the greatly important MTAS safety naviga-

tion effects is the Reduction of Separation Minima

(RSM) between ships or other moving object on the

sea routes by almost half, as shown in Figure 9. The

current system has an RSM controlled by conven-

tional VHF or HF Radio system and Radar Control

System (RCS), which allows only large distances

between vessels. However, the new CNS/MTM sys-

tem controls and ranges greater numbers of vessels

for the same sea corridors (channels), which enables

minimum secure separations, with a doubled capaci-

ty for vessels and enhancements of safety and secu-

rity. Therefore, a significant RSM for sailing ships

will be available with the widespread introduction

and implementation worldwide of the new RSAS

technologies on the CNS system [6, 7].

Figure 8. SELR Subsystem

Courtesy of Paper, “Satellite CNS for MTAS” by St. D. Il-

cev [2]

Figure 9. RSM Subsystem

Courtesy of Book, “Maritime CNS” by St. D. Ilcev [4]

5.3 Flexible Sailing Profile Planning (FSPP)

The next positive effect of MTAS system is Flexible

Sailing Profile Planning (FSPP) of shortest or opti-

mal course, shown in Figure 10. The current system

uses fixed courses of orthodrome, loxodrome and

combined navigation by navaids. Thus, the fixed

course is controlled by the vessel’s on-board naviga-

tion instruments only, which is a composite and not

the shortest possible route from departure to arrival

at the destination port. The FSPP allows the selec-

tion of the shortest or optimum course between two

ports and several sub points. With thanks to new

RSAS technologies on CNS/MTM system FSPP will

be available for more economic and efficient sailing

operations. This means that the ship’s engines will

use less fuel by selecting the shortest sailing route of

new CNS/MTM system than by selected the fixed

courses of current route composition [6, 7].

6 LSAS SYSTEM CONFIGURATION

The LSAS system configuration is intended to com-

plement the CNS service for local environment of

seaport using a single differential correction that ac-

counts for all expected common errors between a lo-

cal reference and mobile users. The LSAS infra-

structure will broadcast navigation information in a

localized volume area of seaports or airports using

satellite service of satellite CSN solutions or any of

mentioned RSAS networks developed in Northern

Hemisphere.

As stated earlier, any hypothetical RSAS network

will consist a number of GMS (Reference Stations),

several GCS (Master Stations) and enough GES

(Gateways), which service has to cover entire mo-

bile environment of dedicated region as an integrat-

ed part of GSAS. Inside of this coverage the RSAS

network will also serve to any other customers at

sea, on the ground and in the air users, who needs

very precise determinations and positioning, such as:

1 Maritime (Shipborne Navigation and Surveil-

lance, Seafloor Mapping and Seismic Surveying);

2 Land (Vehicleborne Navigation, Transit, Track-

ing and Surveillance, Transportation Steering and

Cranes);

3 Aeronautical (Airborne Navigation and Surveil-

lance and Mapping);

4 Agricultural (Forestry, Farming and Machine

Control and Monitoring);

5 Industrial, Mining and Civil Engineering;

6 Structural Deformations Monitoring;

7 Meteorological, Cadastral and Seismic Survey-

ing; and

8 Government/Military Determination and Surveil-

lance (Police, Intelligent services, Firefighting);

etc.

In a more general sense, all above fixed or mobile

applications will be able to assess CNS service in-

side of RSAS coverage directly by installing new

equipment known as augmented GPS or GLONASS

Rx terminals, and so to use more accurate position-

ing and determination data.

Figure 10. FSPP Subsystem

Courtesy of Book, “Maritime CNS” by St. D. Ilcev [4]

Figure 11. CMGC Subsystem

Courtesy of Paper, “Satellite CNS for MTAS” by St. D. Il-

cev [02]

In Figure 2 is illustrated scenario that all mobiles

and GMS terminals directly are using not augmented

signals of GPS or GLONASS satellites. To provide

augmentation will be necessary to process not aug-

mented signals in GCS, to eliminate all errors and

produce augmented signals. However, in this stage

any RSAS network standalone will be not able to

produce augmented service for seaports, airports or

any ground infrastructures.

At this point, it will be necessary to be estab-

lished some new infrastructure known as an LSAS,

which can provide service for collecting augmented

data from ships, land vehicles, airplanes or any

ground user. The navigation data of mobiles can be

processed in the TCC cites and shown on the sur-

veillance screen similar to the radar display and can

be used for traffic control system at the see, on the

ground and in the air. This scenario will be more

important for establishment MTC or Air Traffic

Control (ATC) service using augmented GNSS-1

signals from the ships or aircraft, respectively. In

this sense, the LSAS network can be utilized for

seaports known as Coastal Movement Guidance and

Control (CMGC) and airports as Surface Movement

Guidance and Control (SMGC) [04, 10].

7 COASTAL MOVEMENT GUIDANCE AND

CONTROL (CMGC)

The new LSAS network can be implemented as a

Coastal Movement Guidance and Control (CMGC)

system integrated in the CNS of any RSAS infra-

structure. It is a special maritime security and con-

trol system that enables a port controller from Con-

trol Tower at shore to collect all navigation and

determination data from all ships and vehicles, to

process these signals and display on the surveillance

screens. On the surveillance screen can be visible

positions and courses of all ships in vicinity sailing

areas, so they can be controlled, informed and man-

aged by traffic controllers in any real time and space

[6].

In this case, the LSAS traffic controller provide

essential control, traffic management, guide and

monitor all vessels movements in coastal navigation,

in the cramped channel strips and fiords, approach-

ing areas to the anchorage and harbours, ship

movement in the harbours, including land vehicles

in port and around the port’s coastal environment,

even in poor visibility conditions at an approaching

to the port. The controller issues instructions to the

ship’s Masters and Pilots with reference to a com-

mand surveillance display in a Control Tower that

gives all vessels position information in the vicinity

detected via satellites and by sensors on the ground,

shown in Figure 11.

The command monitor also displays reported po-

sition data of coming or departing vessels and all

auxiliary land vehicles (road and railways) moving

into the port’s surface. This position is measured by

GNSS, using data from GPS/GLONASS and GEO

satellite constellation. A controller is also able to

show the correct ship course to Masters and sea Pi-

lots under bad weather conditions and poor visibility

or to give information on routes and separation to

other vessels in progress. The following segments of

CMGC infrastructure are illustrated in Figure 11:

1 GPS or GLONASS GNSS Satellite measures the

vessel or port vehicle’s exact position.

2 GEO MSC Satellite is integrated with the GPS

positioning data network caring both communica-

tion and navigation payloads, In addition to com-

plementing the GPS satellite, it also has the fea-

ture of communicating data between the ships or

vehicles and the ground facilities, pinpointing the

mobile’s exact position.

3 Control Tower is the centre for monitoring the

traffic situation on the channel strips, approaching

areas, in the port and around the port’s coastal

surface. The location of each vessel and ground

vehicle is displayed on the command monitor of

the port control tower. The controller performs

sea-controlled distance guidance and movements

for the vessels and ground-controlled distance

vehicles and directions based on this data.

4 Light Guidance System (LGS) is managed by the

controller who gives green light or red light guid-

ance whether the ship should proceed or not by

pilot in port, respectively.

5 Radar Control Station (RCS) is a part of previous

system for MTC of ship movement in the chan-

nels, approaching areas, in port and around the

port’s coastal environment.

6 Very High Frequency (VHF) is Coast Radio Sta-

tion (CRS) is a part of RCS and VHF or Digital

Selective Call (DSC) VHF Radio communica-

tions system.

7 Ground Earth Station (GES) is a main part of sat-

ellite communications system between GES ter-

minals and shore telecommunication facilities via

GEO satellite constellation.

8 Pilot is small boat or helicopter carrying the spe-

cial trained man known as a Pilot, who has to

proceed the vessel to the anchorage, in port, out

of port or through the channels and rivers.

9 Bridge Instrument of each vessel displays the ship

position and course [02, 06].

8 CONCLUSION

The CNS has been set up to identify the possible ap-

plications for global radio and satellite CNS, safety

and security and control of aircraft, freight and pas-

sengers and SAR service in accordance with IMO

and ICAO regulations and recommendations. The

new satellite CNS using GEO satellites with Com-

munication and GNSS payloads for MTC/MTM is

designed to assist navigation both sailing at open sea

and approaching to the anchorages and seaports. The

potential benefits will assist MTC to cope with in-

creased maritime traffic and to improve safety and

reducing the infrastructures needed at shore. The

Communication payloads usually at present employ

transponders working on RF of L/C, Ku and recently

on Ka-bands for DVB-RCS scenario. Because that

Ku-band is experiencing some transmission prob-

lems and is not so cost effective, there is proposal

that Ka-band will substitute Ku-band even in mobile

applications including maritime and aviation.

When planning maritime routes and berthing

schedules at busy seaports, it is essential to ensure

that ships are always at safe distance from each other

and that they are passing some critical channels safe-

ly. The trouble is that it is not always possible to

figure out where the ships are, especially during very

bad weather conditions. It is necessary to reduce the

margins of critical navigation and increase the safety

of ships in each sea and passage corridors. The new

CNS GNSS-1 networks of MTAS and forthcoming

European Galileo and Chinese Compass GNSS-2

will provide a guaranteed service with sufficient ac-

curacy to allow ship’s masters and pilots including

MTC to indicate a current position and safety mar-

gins reliably and precisely enough to make substan-

tial efficiency sailing. The GNSS helps masters to

navigate safely, especially in poor weather condi-

tions and dense fog, in which sailing using CNS via

RSAS system or DGPS is reliable. Any seaports are

unlikely to invest in this system, but they can use

CNS of global or local augmented system or when

Galileo and Compass become operational, the need

for a differential antenna will reduce costs. Galileo

and Compass will also need implementation of CNS

via RSAS, so their guaranteed service and use of du-

al frequencies will increase accuracy and reliability

to such an extent that vessels will be able to use

safely their navigational data for guidance including

their on-board technology alone.

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