KH2026 Manta Radar
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Transcript of KH2026 Manta Radar
PUBLICATION KH 2026
Issue 2 July 2003
Software Version 2.0x
ARPA 3 Software Version 4.xRIU Software Version 1.0xTIU Software Versiion 1.0x
KELVIN HUGHESKelvin Hughes LimitedNew North Road, Hainault, Ilford, Essex IG6 2UR, UKTelephone: +44 20 8500 1020Facsimile: +44 20 8559 8526Telex: 896401www.kelvinhughes.comwww.smiths-aerospace.com
Registered Office:765 Finchley Road, London NW11 8DSIncorporated in England No. 1030135
A part of Smiths Aerospace - Marine Systems VAT No: GB 226 6019 770 1
SYSTEM HANDBOOKfor the
MANTA RADAR SYSTEMS
CON FOR MITY STATE MENT
This system has been designed to comply with IMO regulations and IEC standards.
EQUIPMENT IMO REGULATION(S) IEC STANDARD(S)
Radar IMO A.477(XII)MSC 64(67) Annex 4
IEC 936.1988IEC 60936-1
HSC Radar IMO A.820(19) IEC 60936-2
ARPA IMO A.422(XI)IMO A. 823(19)
IEC 872-1987IEC 60872-1
ATA MSC 64(67) Annex 4 IEC 60872-2
EPA MSC 64(67) Annex 4 IEC 60872-3
COPY RIGHT
ã Copyright Kelvin Hughes Ltd. 2002, 2003
All rights reserved. No part of this publication may bereproduced, transmitted, transcribed, translated or stored
in any form or by any means, without the writtenpermission of Kelvin Hughes Limited.
Technical details contained in this publication are subject to
change without notice.
July 03 ii Issue 2
KH 2026
AMENDMENT RECORD
When an amendment is incorporated into this handbook, the details should be recorded below. If the equipment
has been modified, the modification number is shown on the Amendment instruction page.
No. Date Inserted Initials Mod
No.
No. Date Inserted Initials Mod
No.
1 10/03 CJB 31
2 03/04 GJS 32
3 33
4 34
5 35
6 36
7 37
8 38
9 39
10 40
11 41
12 42
13 43
14 44
15 45
16 46
17 47
18 48
19 49
20 50
21 51
22 52
23 53
24 54
25 55
26 56
27 57
28 58
29 59
30 60
Issue 2, Amdt 2 iii March 03
KH 2026
THIS PAGE INTENTIONALLY BLANK
July 03 iv Issue 2
KH 2026
CONTENTS
Pre lim i nary Pages
Title PageConformity & Copyright PageAmendment Record PageContents (this page)Electric Shock ResuscitationWarning PagesCaution PagePrefaceList of Abbreviations
IN TRO DUC TION
OP ER ATING IN FOR MA TION
CHAPTER 1 - OPERATING INSTRUCTIONSCHAPTER 2 - RADAR PLOTTING AIDS - EPACHAPTER 3 - RADAR PLOTTING AIDS - ATA/ARPACHAPTER 4 - INTERPRETING THE DISPLAY & SART OPERATION
IN STAL LA TION & COM MIS SIONING
CHAPTER 1 - DISPLAY AND PROCESSOR UNIT - INSTALLATION & INTERCONNECTIONSCHAPTER 2 - TRANSCEIVERS MKIV - INSTALLATION & INTERCONNECTIONSCHAPTER 3 - TRANSCEIVERS MKV - INSTALLATION & INTERCONNECTIONSCHAPTER 4 - TRANSCEIVERS MKVI - INSTALLATION & INTERCONNECTIONSCHAPTER 5 - TRANSCEIVERS MKVII (S-Band) - INSTALLATION & INTERCONNECTIONSCHAPTER 6 - TRANSCEIVERS MKVII (X-Band) - INSTALLATION & INTERCONNECTIONSCHAPTER 7 - DISPLAY COMMISSIONING & DEFAULT SETTINGS
MAIN TE NANCE
CHAPTER 1 - DISPLAY AND PROCESSOR UNITCHAPTER 2 - MKIV TRANSMITTER/RECEIVERS & ANTENNACHAPTER 3 - MKV TRANSMITTER/RECEIVERS & ANTENNACHAPTER 4 - MKVI TRANSMITTER/RECEIVERS & ANTENNACHAPTER 5 - MKVII TRANSMITTER/RECEIVERS & ANTENNA (S-Band)CHAPTER 6 - MKVII TRANSMITTER/RECEIVERS & ANTENNA (X-Band)
SYS TEM IN FOR MA TION
CHAPTER 1 - SYSTEM OPTIONSCHAPTER 2 - DUAL INTERSWITCH UNITCHAPTER 3 - TRANSMITTER INTERSWITCH UNITCHAPTER 4 - RADAR INTERSWITCH UNITCHAPTER 5 - ERGOPODCHAPTER 6 - UNINTERRUPTIBLE POWER SUPPLYCHAPTER 7 - REMOTE DISPLAY TRANSCEIVERCHAPTER 8 - MANTA RADAR CONTROL PANEL
Re cord Pages
INSTALLATION RECORDDEFAULT SETTINGS
Issue 2 v July 03
KH 2026
July 03 vi Issue 2
KH 2026
LOOSEN NECKWARETILT HEAD BACKWARDSAND PUSH CHIN UPWARDS
PINCH THE NOSECOMMENCE VENTILATIONFOUR GOOD INFLATIONSMOUTH TO MOUTH
IF CHEST DOES NOT RISERE-CHECK AIRWAY.REMOVE OBSTRUCTIONAND RE-INFLATE
CHECK PULSE
POSITION OF PULSE
ONE FIRST AIDER
TWO FIRST AIDERS
15 Compressions of 80 perminute followed by twoinflations
One conducts chestcompressions, withoutpause at 60 per minute.The other administersmouth-to-mouth ventilation -after each 5th compression
HEART HAS STOPPED BEATINGLAY ON BACK ON FIRM SURFACEeg FLOORCOMMENCE EXTERNAL CHESTCOMPRESSION AND CONTINUEMOUTH-TO-MOUTH VENTILATION
Check heart beat after first fiveminutes and then after every threemintutes. Continue external chestcompression and mouth-to-mouthventilation until a normal pulse isfelt and colour improves
WHEN NORMAL BREATHING COMMENCESPLACE CASUALTY IN RECOVERY POSITION
Keep casualty at rest. Remove on a stretcher.Watch closely, particularly for difficulty inbreathing. Lightly cover with blankets or othermaterials.
ELECTRIC SHOCKRESUSCITATION
1 32SHOUT FOR HELP. SWITCHOFF ELECTRICITY IF POSSIBLE. REMOVE FROM DANGER.
REMOVE OBVIOUSOBSTRUCTION TOBREATHING.
Do this immediately. If not possible, don't waste timesearching for a switch.
Safeguard yourself when removing casualty from hazard.If casualty is still in contact with electricity, and the supplycannot be isolated, stand on a dry non-conductingmaterial (rubber mat, wood, linoleum).
If casualty is not breathing startresuscitation at once.
PULSE PRESENT
CONTINUE INFLATIONSUNTIL RECOVERY OFNORMAL BREATHING
CONTINUE INFLATIONSUNTIL RECOVERY OFNORMAL BREATHING
MEDICAL ASSISTANCE MAY BE OBTAINED ON / AT ...............................
PULSE ABSENT
Use rubber gloves, dry clothing, length of dry rope or woodto pull or push casualty away from the hazard.
SAFETY WARN INGS
Issue 2 vii July 03
KH 2026
WARNING
THIS EQUIPMENT CONTAINS MATERIALS WHICH PRODUCE TOXIC FUMES WHEN BURNT.
CD-0844
WARNING
ENSURE THAT THE DISPLAY IS SWITCHED OFF PRIOR TO CLEANING THE SCREEN. OTHERWISESTATIC BUILD-UP MAY PRODUCE ELECTRICAL DISCHARGES WHICH, IN EXTREME CASES, COULD BE HAZARDOUS.
WARNING
THIS EQUIPMENT IS NOT FITTED WITH SAFETY INTERLOCKS. LETHAL VOLTAGES ARE PRESENTWHEN THE UNITS ARE OPEN AND EXPOSED. BEFORE REMOVING ANY SUB-UNIT OR PCB, ALLSUPPLIES MUST BE SWITCHED OFF.
CD-0845
SAFETY WARN INGS
July 03 viii Issue 2
KH 2026
WARNING
DO NOT OPEN ANY OF THE EQUIPMENT UNITS WHEN THE RADAR IS OPERATIONAL.
AN TENNA RO TA TION
ANTENNA ROTATION CAN BE HALTED BY SWITCHING THE DISPLAY TO STANDBY OR OFF.
SER VICING
THE EQUIPMENT SHOULD BE SERVICED BY AUTHORISED AGENTS ONLY.
AN TENNA RA DI A TION HAZ ARD
INJURY CAN RESULT FROM EXPOSURE TO THE MAIN BEAM OF A RADAR ANTENNA AT A DISTANCE FROMTHE CENTRAL FRONT FACE, OF LESS THAN:
1.3m (X-Band) Antenna: 3.0 metres1.8m (X-Band) Antenna: 2.3 metres2.4m (X-Band) Antenna: 1.5 metres2.9m (S-Band) Antenna: 1.1 metres3.9m (S-Band) Antenna: 0.8 metres
SAFETY WARN INGS
WARNING
The nav i ga tion sys tems and equip ment sup plied by Kel vin Hughes com ply with the rel e vant SOLAS reg u la tions and are pro vided as aids to nav i ga tion and should be used in ac cor dance
with the SOLAS reg u la tions.
Issue 2 ix July 03
KH 2026
Picture Freeze
The rare event of Processor failure is indicated by non-operation of the trackerball, no update of screen data and a frozen tune bar indicator. The radar picture may be updated, but plotting is not possible.
The display is to be switched OFF and ON again to reset the Processor.
ARPA Failure
The ARPA computer is protected by a watchdog circuit, which monitors the ARPA for correct operation.
In the unlikely event of computer failure, the Operator observes vector footprints becoming detached fromtargets. If this occurs, reset the computer, by pressing the “Delete All Targets” pushbutton twice.
If the ARPA fails while running, an ARPA FAILURE message is indicated. If the ARPA fails to start, a TESTINGARPA message remains on the screen after the initial self-test period of 10 seconds.
Mains Voltage
All Kelvin Hughes equipment is supplied with Mains Voltage set for 220V, unless stated otherwise onlabels attached to the equipment.
S-Band Tuning
It may be necessary to re-tune the transmitter when changing the pulse length.
July 03 x Issue 2
KH 2026
CAU TION
HAN DLING OF ELEC TRO STATIC-SENSITIVE SEMI CON DUC TOR DE VICES
Certain semiconductor devices used in the equipment are liable to damage due tostatic voltage. Observe the following precautions when handling these devices in theirunterminated state, or sub-units containing these devices:
Persons removing sub-units from an equipment containing these devices must beearthed by a wrist strap and a resistor at the point provided on the equipment.
Soldering irons used during the repair operations must be low voltage types withearthed tips and isolated from the mains voltage by a double insulated transformer.
Outer clothing worn must be unable to generate static charges.
Printed Circuit Boards (PCBs) fitted with these devices must be stored andtransported in anti-static bags.
Fit new devices in a special handling area.
For detailed information, refer to IEC Standard IEC 61340-5-1:1998 or otherequivalent standard.
PREFACE
Manta is designed to be flexible and expandable making it ideal for use in Integrated Bridge Systems (IBS), aswell as for standalone Radar Systems and Electronic Chart Display Information Systems (ECDIS).
When used in standalone systems the Manta Display is dedicated for use as either a Radar Display or as anECDIS Display.
When used in Integrated Bridge Systems the Manta Display can be configured as a networked Multi-FunctionalDisplay, which can be switched between different functions, e.g. Radar, ECDIS or Conning Display, depending onthe function required by the operator. This allows a single display to control a number of functions, although onlyone function can be accessed at any time.
Manta is designed so that, when required, the displays can be controlled from an Ergopod.
The operation, installation and maintenance of Manta is covered in the following manuals:
KH2024 - System Manual for the Manta Networked Multi-Functional Display. This covers the operation,installation and maintenance of the Manta display when used as a networked multi-functional display. Thecontent of this manual is limited to the functions specific to the networked multi-functional display, anddoes not cover features common to the Radar and ECDIS Systems.
KH2026 - System Manual for the Manta Radar Systems. This covers operation, installation andmaintenance of the Manta Radar System, including the displays and radars. This provides all theinformation required for standalone radar systems, and for the networked multi-functional display in radarmode.
KH2027 - System Manual for the Manta ECDIS Displays. This covers operation, installation andmaintenance of the Manta ECDIS system. This provides all the information required for standalone ECDIS systems, and for the networked multi-functional display in ECDIS mode.
Issue 2 xi July 03
KH 2026
ACQ Acquire
ADS Adjust
AFC Automatic Frequency Control
ARPA Automatic Radar Plotting Aid
AUD Audible
BCR Bow Crossing Range
BCT Bow Crossing Time
BRG Bearing
CPA Closest Point of Approach
CSE Course
DIU Dual Interswitch Unit
EBL Electronic Bearing Line
ENH Enhanced
EPA Electronic Plotting Aid
EPROM Erasable Programmable Read OnlyMemory
ERBL Electronic Range & Bearing Line
EXT External
FTC Fast Time Constant
GPS Global Positioning System
HL Heading Line
IR Interference Rejection
LCD Liquid Crystal Display
LP Long Pulse
MINIM Minimum
MP Medium Pulse
NMEA National Maritime Electronics Association
PCB Printed Circuit Board
PI Parallel Index
PM Performance Monitor
PPI Plan Position Indicator
RADAR Radio Detection And Ranging
RAM Random Access Memory
RATS Rate Aided Tracking System
RCGA Radar Control Gate Array
RIU Radar Interswitch Unit
RM(R) Relative Motion, Relative Trails
RM(T) Relative Motion, True Trails
Rx Receiver
SATNAV SATellite NAVigation
SC/SC Scan to Scan (Correlation)
SP Short Pulse
STC Swept Time Constant
TCPA Time to Closest Point of Approach
TIU Transceiver Interface Unit
TM(T) True Motion, True Trails
TTL Transistor Transistor Logic
Tx Transmitter
VDU Video Display Unit
VRM Variable Range Marker
July 03 xii Issue 2
KH 2026
LIST OF AB BRE VI A TIONS
INTRODUCTION
TABLE OF CONTENTS
Issue 2 i July 03
KH 2026, IntroductionContents
Page
• INTRODUCTION 1
• OPERATION 1
• DIS PLAY TYPES AND PLOT TING AIDS 1
• MAPPING 1
• STRUC TURE OF THIS MAN UAL 1
• MANTA DIS PLAYS - CON TROLS AND INDICATORS 2
• Desk Top Dis play 2
• Con sole Mounted and Flush Con sole Mounted Displays 2
• DIS PLAY FACILITIES 3
• Range Scales 3
• Screen Modes of Op er a tion 3
• Op tions (True Mo tion and Rel a tive Mo tion with True Trails) 3
• Offcentre 3
• Head ing Line 3
• Vari able Range Marker 3
• Elec tronic Bear ing Line 3
• Sig nal Con trols - Gain, Sea, Rain 3
• Ownship and Plotting Pa ram e ters 3
• Tar get Data 3
• Par al lel In dex Lines 3
• RA DAR PLOT TING AIDS 4
• Elec tronic Plotting Aid (EPA) 4
• Au to matic Tracking Aid (ATA) 4
• Au to matic Ra dar Plotting Aid (ARPA) 4
• SYS TEM CON FIG U RA TIONS 4
• TECH NI CAL OVER VIEW 5
• Manta Dis plays 5
• Desk Top Dis play 5
• Con sole Mounted and Flush Con sole Mounted Dis plays 5
• Ra dar Pro ces sor Unit 6
• Ra dar Trans ceiv ers/Antennas 6
• In ter face Units 7
ILLUSTRATIONS
July 03 ii Issue 2
KH 2026, IntroductionContents
Page
• Figure 1 - Desk Top Display 2
• Figure 2 - Console Mounted Console Display 2
• Figure 3 - Flush Console Mounted Display 2
• Figure 4 - Single Display with single Upmast Transmitter/Receiver and Antenna. 12
• Figure 5 - Single Display with Single Downmast Transmitter/Receiver and Antenna 12
• Figure 6 - Two Displays interswitched (via RIU) with Two Upmast Transmitter/Receivers and Antenna 13
• Figure 7 - Two Displays Interswitched (via a DIU) with a Single Transmitter/Receiver and Antenna 13
• Figure 8 - Two Displays interswitched (via an RIU) with Two Upmast Transmitter/Receivers and Antenna 14
• Figure 9 - Two Displays Interswitched (via a DIU) with Two Upmast Transmitter/Receivers and Antenna 14
• Figure 10 - Manta Radar System Schematic Diagram 15
INTRODUCTION
1 This section provides an introduction to the MantaRadar Systems.
2 The Manta Radar systems can be configured to suitcustomer requirements, according to the quantity and
types of display, transmitter/receiver and Interswitch unitused. Typical configurations are shown in the Figures at theend of this Introduction.
3 The comprehensive use of colour, provides anoptimum display of radar picture, selectable functions,
warnings, target information and Ownship navigation data.
4 The Manta series equipment is designed for use aseither a panel mounted Console or a Desk Mounted
Display with a separate Processor Unit.
OPERATION
5 Manta colour Radar Displays utilise a unique methodof operation. The entire operation of the radar (apart
from power ON/OFF switching) can be controlled by usingthe trackerball and the three pushbutton keys located on aspecially designed and ergonomic control unit, featuring acontoured hand rest.
6 The operation of the Manta range of radars is designed to be simple and intuitive. A cursor is moved by the
trackerball inside and outside the radar circle. When thecursor is moved to be within the confines of a ‘Status Box’(located outside the radar circle) the box is automaticallyhighlighted; pop-down boxes provide abbreviatedpushbutton functionality. Simultaneously, function optionsare displayed as a labelled diagrammatic view of the threepushbuttons in the ‘Pushbutton Selection Box’. Thefunctions are accessed by pressing the appropriatepushbutton. The ‘Status Box’ changes to display the newstatus and the cursor can then be moved back to the radarcircle or to another function box.
7 When the cursor is inside the radar circle, the threebuttons are used for plotting targets, positioning
markers and mapping graphics. A diagrammatic labelledview of the pushbutton functionality is displayed in thepushbutton selection box.
8 Where the operator requires discrete controls for Gain, Sea, Rain, Range Up, Range Down, VRM, EBL,
Parallel Index and Vector mode functions, these can beprovided by the optional Radar Control Panel. This unit canbe mounted in Desk Mounted Displays, but is a separate unitwhen Console Mounted Displays are used.
9 Detailed Operating Information is provided inOperating Information, Chapter 1.
DIS PLAY TYPES AND PLOT TING AIDS
10 The Manta series of displays provide the followingoperational facilities, with three types of radar plotting
aid:
(1) Automatic Radar Plotting Aid (ARPA) - offeringmanual and automatic acquisition and automatictracking. Relative Motion RM(R) and True MotionTM(T) and Relative Motion RM(T) modesincorporate True Motion and ARPA (AutomaticRadar Plotting Aid) facilities.
(2) Automatic Tracking Aid (ATA) - providing manualacquisition and automatic tracking. Relative Motion RM(R), True Motion TM(T) and RelativeMotion RM(T) modes incorporate True Motionfacilities and ATA (an Automatic Tracking Aid)facilities.
(3) Electronic Plotting Aid (EPA) System - for manualplotting. Relative Motion RM(R), True MotionTM(T) and Relative Motion RM(T) mode,incorporate True Motion and Electronic Plottingfacilities.
11 Day/night operation is optimised by colour andintensity selection.
12 Radar Plotting Aids are described in OperatingInformation, Chapters 2 and 3.
MAPPING
13 The mapping facility has a capacity of 350kbytes usedin a flexible partition arrangement. Maps can be
ground stabilised in any mode using a reference target, or byexternal position fixing systems (e.g. GPS).
14 The maps are stored on internal non-volatile Flashmemory.
STRUC TURE OF THIS MAN UAL
15 This manual is divided into 5 sections, as follows:
(1) Introduction (this section).
(2) Operating Information, which describes operationof the Manta Radar from the Radar Display, andincludes information on EPA, ATA, ARPA andAutomatic Identification Systems (AIS).
(3) Installation & Commissioning for the MantaDisplay and Radar Processor Unit, and thevariants of Kelvin Hughes transceivers/antennas.
(4) Maintenance for the Manta Display and RadarProcessor Unit, and the variants of Kelvin Hughes transceivers/antennas, including a brief functional description of the each of the units.
(5) System Information on the various optional unitsavailable with Manta radars, which enable a widevariety of configurations to be provided.
Issue 2 1 July 03
KH 2026, Introduction
INTRODUCTION
MANTA DISPLAYS - CONTROLS ANDINDICATORS
16 The Manta Radar Displays use flat screen technologyand are available in three sizes (17", 20" and 23"), with
the option of desk mounting, console mounting, or flushconsole mounting.
17 The Desk Mounted Displays have the controls built into the display unit, whereas the Console Mounted
Displays are designed to be used in conjunction with aRemote Trackerball (complete with three pushbuttons).
18 The Manta Radar Displays are designed to control theManta Radar Processor Unit and provide the controls
and indicators for the processor unit. The Manta processingunits can also be controlled from an Ergopod, if required.
Desk Top Display
19 The Desk Top Display comprises a plastic moulding,which houses a flat screen LCD display and
trackerball. The Desktop Radar Display unit is shown inFigure 1.
20 The Desk Top Display has the following controls andindicators:
(1) An ON/OFF switch located on the front panel ofthe display housing. The switch is fitted flush withthe housing to prevent it from being operatedinadvertently.
(2) A SEL (Select) switch located on the front of thedisplay housing. this switch allows the operator toselect different system functions for viewing andcontrol. This switch is only applicable toIntegrated Bridge Systems using networkeddisplays and processors and is not used withstand-alone Radar workstations. The switch isfitted flush with the housing to prevent it from beingoperated inadvertently.
(3) Brightness + and - controls are provided on thefront of the display, below the screen on theleft-hand side. These set the brightness of thebacklight of the display.
(4) A SYS FAIL indicator (red) with integralpushbutton switch (later units only), lit when a faultis detected in the processor. An audible alarm alsosounds. Pressing the pushbutton silences theaudible alarm, but the indicator remains lit until thefault has cleared.
(5) A trackerball and its pushbuttons are mounted onthe bezel in front of the display. The optional radarcontrol panel is also fitted in front of the display.
Console Mounted and Flush Console Mounted Displays
21 The Console Mounted Display comprises a plasticbezel moulding, fitted around the flat screen display.
22 The Flush Mounted Console Display has a flat metalbezel surround and is designed to fit flush with the
console.
23 The Console Radar Display is shown in Figure 2 andthe Flush Console Display in Figure 3.
24 The Console and Flush Console Mounted Displayshave the following controls and indicators:
(1) Brightness + and - controls are provided on thefront of the display, below the screen on theleft-hand side. These set the brightness of thebacklight of the display.
(2) An ON/OFF switch located on the front of the unitunder the display. This is a push button switchmounted flush with the bezel to prevent it frombeing operated inadvertently. On earlier units thisswitch is on the underside of the bezel on the frontleft hand side of the display.
(3) A SYS FAIL indicator (red) with integralpushbutton switch (later units only), lit when a faultis detected in the processor. An audible alarm alsosounds. Pressing the pushbutton silences theaudible alarm, but the indicator remains lit until thefault has cleared.
25 The Console and Flush Mounted Console Displaysrequire the use of a remote trackerball unit. The remote
trackerball unit comprises a large diameter trackerball andthree pushbuttons for control. Where discrete radar controlsare required, they also require the optional Radar ControlPanel, which is mounted separately in the console or as afree standing unit.
Oct 03 2 Issue 2, Amdt 1
KH 2026, Introduction
CURSOR INSIDE CIRCLE
CURSOR OUTSIDE CIRCLE
RADAR CIRCLE
PUSHBUTTONS
TRACKERBALL
I0
ON/OFF SWITCH CD-5316
BRIGHTNESS + -
RADAR CONTROL PANEL(IF FITTED)
SEL (SELECT)
SYS FAIL
Figure 1 - Desk Top Display
CURSOR INSIDE CIRCLE
CURSOR OUTSIDE CIRCLE
RADAR CIRCLE
CD-5338
BRIGHTNESS + -
ON/OFF SWITCH(EARLY VERSIONS)
ON/OFF SWITCH (POWER)(LATER VERSIONS)
SYS FAIL
Figure 2 - Console Mounted Console Display
BRIGHTNESS + -
ON/OFF SWITCH (POWER)
SYS FAIL
CURSOR INSIDE CIRCLE
CURSOR OUTSIDE CIRCLE
RADAR CIRCLE
CD-5991
Figure 3 - Flush Console Mounted Display
DISPLAY FACILITIES
26 For information on how to select any facility on thedisplay, refer to Operating Information, Chapter 1.
Range Scales
27 The PPI range scales are: 0.125nm, 0.25nm, 0.5nm,0.75nm, 1.5nm, 3nm, 6nm, 12nm, 24nm, 48nm and
96nm.
Screen Modes of Operation
28 The following modes of operation and presentation areavailable for selection, depending on the type of
display installed:
(1) Relative Motion,Relative Trails RM(R)
(2) True Motion,True Trails TM(T)
(3) Relative Motion,True Trails RM(T)
(4) Head Up.
(5) North Up.
(6) Course Up.
Options (True Motion and Relative Motion with TrueTrails)
29 True Motion (True Trails), TM(T) is available - whereOwnship moves across the screen at a velocity
equivalent to the Ownship’s speed and heading.
30 Relative Motion (True Trails) mode offers relativemotion, fixed centred or off-centred Ownship’s
position, with true trails.
Offcentre
31 The display can be offcentred by up to two thirds, on allrange scales, except 96nm, which cannot be off
centred.
Heading Line
32 The ship’s heading line and all other computergenerated graphics can be temporarily removed from
the radar display, to present the operator with a clear radaronly picture.
Variable Range Marker
33 The Variable Range Markers (VRM1 & VRM2) areshown on the radar display as dashed rings (colour
coded; Green for VRM1 and Red for VRM2) and areavailable over the entire radar range. The VRMs ranges aredisplayed by an alphanumeric readout in a box (colourcoded; Green for VRM1 and Red for VRM2), located in thelower left-hand side of the screen.
Electronic Bearing Line
34 The Electronic Bearing Lines (EBL1 & EBL2) areshown on the radar display as lines colour coded;
(Green for EBL1 and Red for EBL2), emanating fromOwnship. The EBLs are True in North Up display mode andRelative in Head Up mode. The bearings of the EBLs aredisplayed by alphanumeric readout in a box (colour coded;Green for EBL1 and Red for EBL2), located beneath theVRM box.
35 The EBL can be off-centred with its origin set to thecursor position. This enables measurement of the
bearing of a target from a point other than the Ownship.
Signal Controls - Gain, Sea, Rain
36 The Gain facility sets the basic threshold level of theradar video displayed on the screen. The Sea facility
reduces sea clutter returns and features an "AUTO"(automatic) option. The Rain facility reduces clutter fromrain, snow and hail precipitation.
Ownship and Plotting Parameters
37 Ownship and Plotting parameters are displayed in abox (located on the right-hand side of the screen)
which contains Gyro, Heading, Speed, Set & Drift Input,Vector, Trails, CPA and TCPA.
Target Data
38 Target data is displayed on demand, for any selectedtracked target, in a box located beneath the Ownship
and Plotting parameter data box.
Parallel Index Lines
39 Four colour-coded Parallel Index Lines are providedto enable the operator to navigate in difficult areas
(e.g. an estuary). Each line is independent.
Issue 2, Amdt 1 3 Oct 03
KH 2026, Introduction
Presentation
Modes
Motion
Modes
RADAR PLOTTING AIDS
Electronic Plotting Aid (EPA)
40 The Electronic Plotting Aid (EPA) is a manual plottingsystem equivalent to, but superior than, a reflection
plotter. Up to 20 targets can be plotted in all display modes.EPA is fitted to all Relative and True Motion display systems.
41 The operator manually selects and enters target plots,and at regular intervals updates the plots by entering
the new position of the targets.
42 Refer to Chapter 2 of the Operating Informationsection for a full description of EPA facilities.
Automatic Tracking Aid (ATA)
43 The Automatic Tracking Aid (ATA) is based on theARPA system and offers 20 target capacity. Trial
manoeuvre, target history and automatic acquisition areexcluded from the ATA facility. ATA performance is fullycompliant with IMO requirements.
44 The ATA utilises a computer which employs advancedprocessing techniques to track targets automatically.
45 Refer to Chapter 3 of the Operating Informationsection for a full description of ATA facilities.
Automatic Radar Plotting Aid (ARPA)
46 The Automatic Radar Plotting Aid (ARPA) facilitycomplies with and exceeds the IMO requirements for
an Automatic Radar Plotting aid. Up to 50 targets can beacquired (automatically or manually) and tracked.
47 The ARPA includes Simulat ions and TrialManoeuvres.
48 Refer to Chapter 3 of the Operating Informationsection for a full description of ARPA facilities.
SYSTEM CONFIGURATIONS
49 The Manta System can be configured in a number ofdifferent ways. Typical examples are shown in the
figures at the end of this Introduction.
50 The control and status interface between the Displaysand the Transceivers is either via a parallel
connection, using 38-core cable, or via a CAN bus interface,using 12-core composite cable. The MkIV, MkV and MkVItransceivers can only use the parallel interface, whereas theMkVII transceivers can use either parallel or CAN businterfaces, depending on system requirements.
51 Note that the Radar Interswitch Unit (RIU) can only usethe CAN bus interface, with an option of a parallel to
CAN bus adaptor on a limited number of transceiverinterfaces only. If a Radar Interswitch Unit is used withadditional non-MkVII transceivers, a Transmitter InterfaceUnit (TIU) is required for each of the other non-MkVIItransceivers to convert the signals between parallel andCAN bus formats.
52 Note that all the examples, with one exception, showthe Desk Mounted Display. However the Desk,
Console or Flush Console Mounted Display can be used withany configuration.
53 The typical configurations shown are as follows:
(1) A single Desk Top Display and a dedicatedUpmast Transmitter/Receiver and Antenna, with aparallel interface.
(2) A single Console Mounted Display, with RemoteTrackerball , and a dedicated DownmastTransmitter/Receiver and Antenna, with a CANbus interface.
(3) Two Desk Top Displays Interswitched via a RadarInterswitch Unit (RIU) to two UpmastTransmitter/Receivers and Antennas, withparallel interfaces.
(4) Two Desk Top Displays interswitched via a DualInterswitch Unit (DIU) to one Transmitter/Receiverand Antenna, with a parallel interface.
(5) Two Desk Top Displays interswitched via a RadarInterswitch Unit (RIU) to two UpmastTransmitter/Receivers and Antennas, one withthe internal CAN bus to parallel adaptor, and onewith a Transmitter Interface Unit.
(6) Two Desk Top Displays interswitched via a DualInterswitch Unit (DIU) to two UpmastTransmitter/Receivers and Antennas, withparallel interfaces.
54 The Manta Radar System can be supplied with anUninterruptible Power Supply (UPS), which uses
internal batteries to maintain power to the Radar System inthe event of mains failure. Information on the UPS isprovided in Chapter 6 of the System Information section.
Oct 03 4 Issue 2, Amdt 1
KH 2026, Introduction
TECHNICAL OVERVIEW
55 The basic Manta Radar consists of a Manta Displayand associated Radar Processor Unit, together with
Radar Transceivers/Antennas and Interface Units asrequired. A typical schematic is shown in Figure 10. Thisshows one Display/Processor Unit and oneTransceiver/Antenna with an interface unit, with the option toconnect to other transceivers/antennas anddisplay/processor units via the interface unit.
56 Depending on the system configuration, single phasemains power for the Transceiver/Antenna may be
supplied from the Processor Unit, or directly from the shipsmains supply. Where a Transceiver/Antenna requires 3phase supplies, these are supplied directly from shipsmains.
57 An Uninterruptible Power Supply (UPS) may be usedon the single phase mains supplies to maintain power
to the Display/Processor Unit and Transceiver/Antenna inthe event of a loss of ships mains. Note that the batteries inthe UPS will only maintain supplies for a limited period.
Manta Displays
58 The basic Manta Radar display options are as follows:
FSD-A7 17-inch Manta 1700 Desk Top RadarFSD-A9 17-inch Manta 1700 Console Mounted
ECDIS/Radar DisplayFSD-A9-ABAA 17-inch Manta 1700 Flush Console
Mounted ECDIS/Radar DisplayFSD-A1 20-inch Manta 2000 Desk Top RadarFSD-A3 20-inch Manta 2000 Console Mounted
ECDIS/Radar DisplayFSD-A3-ABAA 20-inch Manta 2000 Flush Console
Mounted ECDIS/Radar DisplayFSD-A4 23-inch Manta 2300 Desk Top RadarFSD-A6 23-inch Manta 2300 Console Mounted
ECDIS/Radar DisplayFSD-A6-ABAA 23-inch Manta 2300 Flush Console
Mounted ECDIS/Radar Display
59 The Manta Radar Displays are designed to beconnected to the Radar Processor Unit.
60 The Manta display is a Thin Film Transistor (TFT) flatscreen display with associated interface and control
circuitry. The Manta display may contain an integraltrackerball (desk top mounted) or a remote trackerball(console and flush console mounted). The interfaces to theRadar Processor Unit are:
(1) Mains power supplies from the processor to thedisplay.
(2) An ON/OFF control to the processor.
(3) Video from the processor to the display.
(4) An audio signal from the processor to the displayto drive the loudspeaker.
(5) A PS2 interface for the trackerbal l andpushbuttons.
61 The cable used for the PS2 interface must generally beless than 3 metres long, in order to meet the
specification for the interface. In systems where it isnecessary to separate the display and processor by greaterthan 3 metres, the optional Remote Display Transceiver maybe installed at both ends of the link. This unit converts thePS2 link to and from RS485 format thus allowing a greaterseparation of the display and associated processor unit. TheRemote Display Transceiver, if fitted, is usually locatedwithin the Radar Processor Unit and the Desk Top Display,but is mounted remotely from the Console Mounted andFlush Console Mounted Displays and is connected to theremote trackerball.
62 When fitted, the optional Radar Control Panel is eitherlocated in the Desk Top Display or separately console
mounted as a remote unit for the Console and Flush ConsoleMounted Displays. A further option allows the Radar ControlUnit to be hand held with a flying lead connection to theconsole. When used the Radar Control Panel is connectedto the Radar Processor Unit via an RS232 link.
63 When the Radar Control Panel is used the trackerballcan be connected to the PS2 port on the Radar Control
Panel, which then combines the signals to and from thetrackerball with the local control signals to provide a singleRS232 connection to the Radar Processor Unit. There isthen no PS2 connection between the display and theprocessor unit. Therefore, when the display and processorunit are more than 3 metres apart there is no need for aRemote Display Transceiver if the Radar Control Panel isfitted, as the interface is via an RS232 link.
Desk Top Display
64 The Desk Top Display comprises a plastic moulding,which houses a flat screen LCD display, trackerball
and tactile feel compact keyboard. The external electricalinterface is accessible from the back of the display via adetachable rear cover. The terminations for the insulationcables are located at the bottom of the LCD flat panelassembly. The cables are EMC clamped at the cableentrance of the display housing.
65 The Display Units utilise a daylight/dimmable colourhigh definition LCD Flat Screen display mounted in
landscape orientation. The display is designed for daylightand night viewing by means of a dimmable backlight.
Console Mounted and Flush Console Mounted Displays
66 The Console Mounted Display comprises a plasticbezel moulding, fitted around the flat screen display.
The bezel is hinged at the bottom to allow the display to betilted forward enabling front access for maintenancepurposes. The display can also lift off its hinges, if required.
67 The Flush Mounted Console Display has a flat metalbezel surround and is designed to fit flush with the
console. It is not hinged and has to be unscrewed from theconsole for maintenance purposes.
68 The Console and Flush Console Mounted Displaysutilise a daylight/dimmable colour high definition LCD
Flat Screen display mounted in the landscape position. Thedisplay is designed for daylight and night viewing by meansof a dimmable backlight.
69 The terminations for the insulation cables are locatedat the bottom of the LCD flat panel assembly.
Issue 2, Amdt 1 5 Oct 03
KH 2026, Introduction
Radar Processor Unit
70 Three basic versions of Radar Processor Unit areavailable:
(1) Radar Processor Unit with Automatic RadarPlotting Aid (ARPA) NNR-A59
(2) Radar Processor Unit with Automatic Tracking Aid(ATA) NNR-A60
(3) Radar Processor Unit with Electronic Plotting Aid(EPA) NNR-A61
NOTE:
When optional items are fitted into the Processor Unit, theidentity will be given a suffix to identify the additional itemsfitted.
71 The Radar Processor Unit controls the designatedmaster radar transceiver/antenna and receives status
signals from the transceiver. It processes the video from thetransceiver for application to the display in VGA format. Forslave displays, the status of the transceiver may be sent tothe display, but the transceiver/antenna control lines aredisabled.
72 The master transceiver/antenna can be controlled byone of the following types of interface:
(1) An parallel link, using discrete connections foreach of the control and status lines.
(2) A CAN bus link, where all the control and statussignals with the exception of sync, azimuth andheading line from the transceiver are multiplexedonto a single CAN bus.
73 The Radar Processor Unit provides the interface toexternal equipment. The following standard interfaces
are provided:
(1) Analogue gyro compass input.
(2) Analogue speed log input.
(3) Four configurable NMEA serial interfaces areprovided. These are opto-isolated from theinternal circuitry of the Radar Processor Unit. Allfour interfaces can be configured for RS232operation, serial input 4 can also be configured forRS422 operation. GPS is normally input on one ofthe serial ports.
NOTE:
Serial port 3 is configured to output diagnostic data andtherefore this port should be used for receive signals only.The other three ports can be used with bi-directional serialdata.
(4) Relay isolated outputs are provided for visual,audible and fail alarms.
(5) RS232 link to external Trackerball/Ergopod. Thislink is receive only from the Trackerball/Ergopod.
Radar Transceivers/Antennas
74 The following types of Kelvin Hughes RadarTransceivers/Antennas can be used with Manta:
(1) MkIV, which is available in an Upmast 25 kWX-Band configuration, with low speed antennaonly. This transceiver/antenna requires singlephase mains only.
(2) MkV, which is available in an Upmast 10 kWX-Band configuration with low or high speedantennas. This transceiver/antenna requires DCpower only. For the low speed antenna this isnormally supplied from the processor unit, for thehigh speed antenna it is supplied from a separatepower supply unit.
(3) MkVI, which is available in an Upmast 30 kWS-Band configuration with low or high speedantennas. This transceiver/antenna requires 3phase mains supplies, which are supplied by a softstart unit. The soft start unit ensures thatexcessive torque is not applied to the antenna atstart up.
(4) MkVII S-Band, which is available in a Downmast30 kW configuration with low or high speedantennas. This transceiver/antenna requiressingle phase and 3 phase mains. The singlephase mains is used to drive the transceiver andthe 3 phase mains is used to drive the antennaturning mechanism. The 3 phase mains issupplied via a soft start unit, which ensures thatexcessive torque is not applied to the antenna atstart up.
(5) MkVII X-Band, which is available in a Downmast25 kW configuration with low or high speedantennas. This transceiver/antenna requiressingle phase mains only. The transceiver providesthe DC supplies for the turning mechanism.
NOTE:
Low speed antennas normally rotate at 25 rpm and highspeed antennas at 40 rpm.
75 The Kelvin Hughes MkIV, MkV and MkVItransceivers/antennas can only be interfaced to the
Radar Processor Unit via the parallel control lines. They donot have the CAN bus interface fitted.
76 The Kelvin Hughes MkVII transceiver/antenna can beinterfaced to the Radar Processor Unit either by the
parallel control lines or by the CAN bus link. Normally, theCAN bus interface is used as it reduces the amount of wiringrequired.
77 If the Radar Interswitch Unit (RIU) is used to interfacethe Radar Processor Unit to the transceivers/antennas
the interconnections to the RIU must be via CAN businterfaces. When the MkIV, MkV and MkVItransceivers/antennas are used with the RIU an InterfacePCB is required to convert the control and status signalsbetween parallel format and CAN bus format. This InterfacePCB may be located in the RIU or may be in a separateTransmitter Interface Unit (TIU).
Oct 03 6 Issue 2, Amdt 1
KH 2026, Introduction
Interface Units
78 The interface units are fully described in the SystemInformation section.
79 The following main Interface Units are used withManta:
(1) Dual Interswitch Unit (DIU), which provides ameans of interconnecting any two displays withany two transceivers, and providing controlfacilities to enable either display to control eithertransceiver.
(2) Radar Interswitch Unit (RIU), which provides aninterface between up to 6 displays and 6transceivers/antennas. Displays 5 and 6 can beconfigured to provide radar signals to any slavedisplay or to a Kelvin Hughes ECDIS. The RIUuses the CAN bus interface only, so where thetransceiver/antenna requires an parallel interface,either an internally mounted Interface PCB isrequired, or the transceiver must be interfaced tothe RIU via the Transmitter Interface Unit.
(3) Transmitter Interface Unit (TIU), which providesan interface to MkIV, MkV and MkVItransceivers/antennas and large interswitchedsystems. The TIU converts parallel control andstatus signals from the transceiver to CAN busformat for the RIU and Radar Processor Unit.
(4) Ergopod, allowing control of the radar to beundertaken remotely.
(5) Uninterruptible Power Supply, which maintainsthe power to up to one display and onetransceiver/antenna in the event of short termship’s mains failure.
(6) Remote Display Transceiver, used where theDisplay and Processor Unit are more than 3metres apart.
(7) Manta Radar Control Panel, which can be usedinstead of the trackerball and pushbuttons, whenrequired for operational reasons.
80 The following are provided to allow the Manta tointerface to a wide variety of equipment:
(1) 3-phase transformer, allowing Manta to be usedwith 440 V 3-phase supplies.
(2) Low ratio compass kit, allowing Manta to interfacewith synchro compasses with ratios between 1:1and 128:1.
(3) Master/slave kit, allowing Manta to interface twotransceivers, one as allocated as master to thedisplay and the other as slave to the display.
(4) Slave Synchro PCB used where the slave radarprovides a synchro or resolver azimuth output.The PCB converts the signal into azimuth pulsesand produces a heading line pulse for the display.
(5) Divide by 4 PCB, allowing Manta to interface tonon-Kelvin Hughes transceivers with an azimuthratio of 1024:1, and no separate heading linepulse.
(6) Buffer amplifiers to amplify the video and syncsignals when long cable runs are used betweenthe display and transceiver.
Issue 2, Amdt 1 7 Oct 03
KH 2026, Introduction
July 03 8 Issue 2
KH 2026, Introduction
DIS PLAY SYS TEM SPEC I FI CA TION
The following table contains a Summary of Data for all Manta Displays
Manta 1700 Manta 2000 Manta 2300
Display 17-inch TFT LCD Colour Flat Panel *
20-inch TFT LCD Colour Flat Panel *
23-inch TFT LCD Colour Flat Panel *
PPI minimum diameter - 250 mm *
PPI minimum diameter - 295 mm *
PPI minimum diameter - 340 mm *
Zoned operational data/control fields. * * *
Active picture size: 1280x1024 pixels. * *
Active picture size: 1365x1024 pixels. *
Operational controls facilitated by use of atrackerball and three pushbuttons.
* * *
Optional Radar Control Panel. * * *
Day/Night operation optimised by colourselection.
* * *
Video Processing Re-timed processed multi-level video.Multi-plane recycled raster memory.Manual/Auto selectable STC, interferencerejection, target enhancement and scancorrelation.
* * *
Target Trails Relative and True Target Trails variable 0.75, 1.5, 3 and then 3 minute stepsto 99 minutes.
* * *
Range Scales/Rings and
Pulse Lengths
Range Range Pulse Scale Rings Length (Nautical Miles) (Nautical Miles) (PL Option)
0.125 0.025 Short0.25 0.05 Short0.5 0.1 Short0.75 0.25 Short (medium)1.5 0.25 Short (medium)3.0 0.5 Medium
(long/short)6.0 1 Medium
(long/short)12.0 2 Medium
(long/short)24.0 4 Medium
(long/short)48.0 8 Long (medium)96.0 16 Long
* * *
Motion Modes Relative Motion RM(R), True Motion TM(T)and Relative Motion RM(T),
* * *
PresentationModes
Head Up / North Up/ Course Up. * * *
Issue 2 9 July 03
KH 2026, Introduction
Manta 1700 Manta 2000 Manta 2300
Gyro Input All types stepper, synchro, “M” type with90:1, 180:1 and 360:1 ratios.
* * *
IEC 1162-2 High Speed Serial GyroInterface.
* * *
PrimarySpeed Input
Single Axis 100, 200, 400, Pulses/nm,Manual, VHW
* * *
Secondary Speed Input
Fixed Track TargetVTG from GPSVBW from Doppler Log.
* * *
Drift Input Manual: 0-99.9kts, derived from VTG, VBW,ref target
* * *
Range Data Minimum Range: Better than 30m on 10m2 target withshort pulse, 4.5m aerial height and 4.5m waveguide.
* * *
Range Discrimination: Better than 30m on 0.75 scale * * *
Range RingAccuracy: 1% of range scale in use or 10m,
whichever is greater. * * *
Lat/Lon Readout of Ownship’s lat/lon and cursorrange/bearing and lat/lon. * * *
Range Variable Range Markers (1 & 2): VRMs 1 & 2 variable from 0.01 to 96nm
displayed on screen.* * *
Bearing Data Bearing Scale: Electronically generated 1°, 5°, and10° from 0° - 359.9°.
* * *
Electronic BearingLines (EBL1& 2): (EBLs) Variable in 0.1° increments.
Accuracy ± 0.5°. Centred or Offcentred.* * *
Parallel Index: Four Navigation Lines. * * *
Mapping Facilities 350Kbytes internal memory * * *
4 user options of line and 16 symbol types. * * *
5 Map colours * * *
True Map positioning facility, via positionfixing input from GPS.
* * *
July 03 10 Issue 2
KH 2026, Introduction
Manta 1700 Manta 2000 Manta 2300
Power Supplies 110V nominal, 220V nominal (50-60Hz) -Single Phase.
115/380/440V 3 phase with optionaltransformer.
Power corruption protected defaultparameters.
*
*
*
*
*
*
*
*
*
Interfacing Standard: 4 x NMEA Input (RS422/RS232) * * *
1 x NMEA Output RS4223 x NMEA Output RS232Serial Trackerball InputPS/2 Trackerball Input
Optional: Radar Control Panel
*
*
*
*
*
*
*
*
*
*
*
*
*
*
*
Inputs NMEA 0183/IEC 61162-1 E2: * * *
DPT (depth) * * *
GGA, GLL (position) * * *
RNN, RTE (route) * * *
VHW (water speed) * * *
HDT (heading) * * *
RNN, RTE (route) * * *
VHW (water speed) * * *
VBW (ground/water speed) * * *
VTG (ground speed/heading) * * *
WPL (waypoints) * * *
ZDA, ZZU (UTC) * * *
Outputs: OSD (Ownship data) * * *
TTM (Target data) * * *
RSD (Radar System data) * * *
Standard Azimuth Interface, 90:1, 180:1, 10V - 150V amplitude or 4096 TTL. * * *
Remote Monitor up to 20m separation (daisy chain).
* * *
Transceiver - Full operation with MkIV/V/VI/VII transceivers 5/10/25/30kW, “X”and “S” band.
* * *
Display / Transceiver Separation - Up to 60metres standard. * * *
Power Supply - Capable of providing powerfor 5kW/10kW upmast transceivers andaerials.
* * *
VDR Video Output * * *
Mechanical Construction: Aluminium fabricated sheet metal. * * *
Mounting: Desk Top MountConsole MountFlush Console Mount
*
*
*
*
*
*
*
*
*
Viewing Angle: 34 degrees to vertical80 degrees (typical) to vertical andhorizontal.
* *
*
Issue 2 11 July 03
KH 2026, Introduction
Manta 1700 Manta 2000 Manta 2300
Orientation: Landscape * * *
Display Size: Height: 408 mm (17-inch)(desktop) 457 mm (20-inch)
480 mm (23-inch)
**
*
Width: 514 mm (17-inch)538 mm (20-inch)615 mm (23-inch)
**
*
Depth: 606 mm (17-inch)608 mm (20-inch)615 mm (23-inch)
**
*
Display Size: Height: 425 mm (17-inch)(console) 475 mm (20-inch)
520 mm (23-inch)
**
*
Width: 485 mm (17-inch)542 mm (20-inch)615 mm (23-inch)
**
*
Depth: 123 mm (17-inch)123 mm (20-inch)123 mm (23-inch)
**
*
Display Size Height: TBA (17-inch)(flush console) TBA (20-inch)
TBA (23-inch)
**
*
Width: TBA (17-inch)TBA (20-inch)TBA (23-inch)
**
*
Depth: TBA (17-inch)TBA (20-inch)TBA (23-inch)
Configuration: Display Unit with Separate Processor
*
*
*
*
*
*
Cooling: Fan re-circulated cooling. * * *
Electrostatic Damage: Provision for wrist strap point. * * *
Environmental: To IEC 945-3Ergonomic design to ISO recommendations
* * *
Paint Colour: Console: Fern Blue RAL colour 5023Desktop: Bezel - Fern Blue RAL colour 5023, Body- Slate Grey RAL 7015, with durable finish.
* * *
Cables: Individually clamped at entry.Cable entries to allow for rear or bottomentry
* * *
Provision for earthing bolt * * *
July 03 12 Issue 2
KH 2026, Introduction
KELVIN HUGHES
X BAND ANTENNA
UPMAST TxTx MONITOR
KELVIN
HUGHES
I0
CD-5343
LOGGYRODGPSPOWER 110/220V AC
RADARPROCESSOR
UNIT PS2SOUNDVIDEOPOWER
MANTA
DISPLAY
SIG
NA
L A
ND
PO
WE
R C
AB
LE
(38
CO
RE
)
Figure 4 - Single Display with single Upmast Transmitter/Receiver and Antenna.
KELVIN HUGHES
X BAND ANTENNA
Tx MONITOR
CD-5344
LOGGYRODGPSPOWER 110/220V AC
RADARPROCESSOR
UNITSOUNDVIDEOPOWER
MANTA
DISPLAY
SIGNAL &POWER CABLE
(12 CORE)
25kWX BAND
TRANSMITTER
TURNING MECH
WAVEGUIDE
12-CORE COMPOSITE CABLE(SIGNAL & POWER)
POWER 110/220V AC
KES LE VINGH HU
REMOTETRACKERBALL
PS2
Figure 5 - Single Display with Single Downmast Transmitter/Receiver and Antenna
Issue 2 13 July 03
KH 2026, Introduction
KELVIN
HUGHES
I0
CD-5340
KELVIN HUGHES
RADARINTERSWITCH
UNIT
UPMAST Tx/Rx
Tx MONITOR
SOFTSTARTUNIT
S BAND ANTENNA
AE
RIA
L P
OW
ER
CA
BL
E(3
CO
RE
)
LOGGYRODGPSPOWER 220V AC
RADARPROCESSOR
UNIT PS2SOUNDVIDEOPOWER
KELVIN
HUGHES
I0
LOGGYRODGPSPOWER 220V AC
RADARPROCESSOR
UNITPS2SOUNDVIDEOPOWER
MANTA
DISPLAY MANTA
DISPLAY
KELVIN HUGHES
X BAND ANTENNA
25kW UPMAST Tx/RxTx MONITOR
38-CORE CABLE (SIGNAL & POWER)
110/220V MAINS
PO
WE
R &
SIG
NA
L C
AB
LE
(38
CO
RE
)
38-CORE CABLE (SIGNAL & POWER)
POWER 110/220V (2 CORE)
3 PHASE MAINS (3 CORE)
12-CORECOMPOSITE CABLE
(SIGNAL & POWER)
12-CORECOMPOSITE CABLE
(SIGNAL & POWER)
Figure 6 - Two Displays interswitched (via RIU) with Two Upmast Transmitter/Receivers and Antenna
KELVIN
HUGHES
I0
CD-5341
DUAL SYSTEMINTERSWITCH
UNIT
SIGNAL CABLE
POWER CABLE
SIGNAL CABLE
POWER CABLE
LOGGYRODGPSPOWER 220V AC
RADARPROCESSOR
UNIT PS2SOUNDVIDEOPOWER
KELVIN
HUGHES
I0
LOGGYRODGPSPOWER 220V AC
RADARPROCESSOR
UNITPS2SOUNDVIDEOPOWER
MANTA
DISPLAY MANTA
DISPLAY
SIG
NA
L &
PO
WE
R C
AB
LE
(38
CO
RE
)
KELVIN HUGHES
X BAND ANTENNA
10kW X BAND TRANSCEIVEROPTIONAL Tx MONITOR
Figure 7 - Two Displays Interswitched (via a DIU) with a Single Transmitter/Receiver and Antenna
July 03 14 Issue 2
KH 2026, Introduction
CD-5342
12-CORE COMPOSITE CABLE
(SIGNAL & POWER)
AERIAL POWER 220/440V AC3 PHASE CABLE
KELVIN HUGHESKELVIN HUGHESX BAND HIGH SPEED ANTENNA
HSC 10kW UPMAST Tx/RxTX MONITOR
RADARINTERSWITCH
UNIT
HSC 30kW UPMAST Tx/Rx
Tx MONITOR
SOFTSTARTUNIT
S BAND HIGH SPEED ANTENNA
SIGNAL CABLE (38 CORE)
POWER CABLE AE
RIA
L P
OW
ER
CA
BL
ETRANSMITTERINTERFACE
UNIT
KELVIN
HUGHES
I0
LOGGYRODGPSPOWER 220V AC
RADARPROCESSOR
UNIT PS2SOUNDVIDEOPOWER
KELVIN
HUGHES
I0
LOGGYRODGPSPOWER 220V AC
RADARPROCESSOR
UNITPS2SOUNDVIDEOPOWER
MANTA
DISPLAY MANTA
DISPLAY
12-CORECOMPOSITE CABLE
(SIGNAL & POWER)
12-CORECOMPOSITE CABLE
(SIGNAL & POWER)
38-CORE CABLE
POWER 110/220V AC
PO
WE
R &
SIG
NA
L C
AB
LE
(38
CO
RE
)
Figure 8 - Two Displays interswitched (via an RIU) with Two Upmast Transmitter/Receivers and Antenna
KELVIN
HUGHES
I0
CD-5339
POWER & SIGNAL CABLE (38 CORE)AERIAL POWER 220/440V AC
3 PHASE CABLE
KELVIN HUGHESKELVIN HUGHESX BAND HIGH SPEED ANTENNA
HSC 10kW UPMAST Tx/RxTX MONITOR
DUAL SYSTEMINTERSWITCH
UNIT
HSC 30kW UPMAST Tx/Rx
Tx MONITOR
SOFTSTARTUNIT
S BAND HIGH SPEED ANTENNA
SIGNAL CABLE
POWER CABLE
SIGNAL CABLE
POWER CABLE
SIGNAL & POWER CABLE (38 CORE)
POWER CABLE
AE
RIA
L P
OW
ER
CA
BL
E
40V MOTORPOWER UNIT
(CZZ-A22)
SIGNAL CABLE
POWER CABLE
LOGGYRODGPSPOWER 220V AC
RADARPROCESSOR
UNIT PS2SOUNDVIDEOPOWER
KELVIN
HUGHES
I0
LOGGYRODGPSPOWER 220V AC
RADARPROCESSOR
UNITPS2SOUNDVIDEOPOWER
MANTA
DISPLAY MANTA
DISPLAY
SIG
NA
L &
PO
WE
R C
AB
LE
(38
CO
RE
)
Figure 9 - Two Displays Interswitched (via a DIU) with Two Upmast Transmitter/Receivers and Antenna
Issue 2 15 July 03
KH 2026, Introduction
RADARPROCESSOR UNITNNR-A59/A60/A61
RADARTRANSCEIVER
MANTA FLAT PANELDISPLAY
TRACKER-BALL
VIDEO
TRACKERBALL/ERGOPODSHIP'S MAINS
ALARMS (RELAY ISOLATED)
PS2
ON/OFFSWITCH SPEAKER
AUDIOPROCESSOR ON/OFF
REMOTE DISPLAYTRANSCEIVER
(OPTIONAL)
REMOTE DISPLAYTRANSCEIVER
(OPTIONAL)
PS2
RS485
ANALOGUE GYRO INPUTANALOGUE LOG INPUTSERIAL INPUTS/OUTPUTS (4 OFF)
SERIAL/ANALOGUEINPUTS/OUTPUTSFROM EXTERNAL
EQUIPMENT
NOTE: REMOTE DISPLAY TRANSCEIVERS REQUIRED WHEN CABLE LENGTH FROM RADAR PROCESSOR UNIT TO MANTA FLAT PANEL DISPLAY EXCEEDS 3 METRES.
CD-6023
RS232MAINSVISUAL/AUDIBLE/FAIL ALARMS
PARALLEL/CAN BUS CONTROL
AZIMUTH/HEADING LINE
VIDEO
SYNC
INTERFACE UNITS(IF REQUIRED)
PARALLEL/CAN BUS CONTROL
AZIMUTH/HEADING LINE
VIDEO
SYNC
POWER
RADAR CONTROLPANEL (OPTIONAL)
RS232
PARALLEL/CAN BUS CONTROL
AZIMUTH/HEADING LINE
VIDEO
SYNC
PARALLEL/CAN BUS CONTROL
AZIMUTH/HEADING LINE
VIDEO
SYNC
FROM OTHERTRANSCEIVERS/
ANTENNAS
TO OTHERDISPLAYS/PROCESSORS
POWER
SHIPS MAINS/PROCESSOR UNIT
ANTENNA
Figure 10 - Manta Radar System Schematic Diagram
July 03 16 Issue 2
KH 2026, Introduction
THIS PAGE INTENTIONALLY BLANK
A
ARPA 4
ATA 4
Automatic Radar Plotting Aid 4
Automatic Tracking Aid (ATA) 4
D
DISPLAY FACILITIES 3
Display System Specification 8
Display Types 1
E
EBL 3
Electronic Bearing Line 3
Electronic Plotting Aid (EPA) 4
G
Gain 3
Gyro Input 9
H
Heading Line 3
M
Mapping 1
O
Offcentre 3
Operation 1
OPTIONS 4
Options (True Motion and Relative Motion with True Trails)3
Ownship and Plotting Parameters 3
P
Parallel Index Lines 3
PLOTTING AIDS 1
Plotting Parameters 3
Presentation Modes 8
R
Radar Plotting Aids 4
Rain 3
Range 8
Range Scales/Rings and Pulse Lengths 8
Range Scales 3
Relative Motion (True Trails) 3
Relative Motion RM(R) 1
Relative Motion RM(T) 1
S
Screen Modes of Operation 3
Sea 3
Signal Controls - Gain, Sea, Rain 3
Speed Input 9
System Configurations 4
T
Target Data 3
Target Trails 8
True Motion (True Trails) 3
True Motion TM(T) 1
V
Variable Range Marker 3
Video Processing 8
Issue 2 i July 03
KH 2026, IntroductionIndex
Introduction Index
THIS PAGE INTENTIONALLY BLANK
July 03 ii Issue 2
KH 2026, IntroductionIndex
INSTALLATION RECORDTO BE COM PLETED ON IN STAL LA TION
NAME OF VESSEL: ..................................................................................
DISPLAY TYPE (1) : Manta ................................ SERIAL. NO. ....................
DISPLAY TYPE (2) : Manta ................................ SERIAL. NO. ....................
DISPLAY TYPE (3) : Manta ................................ SERIAL. NO. ....................
DISPLAY TYPE (4) : Manta ................................ SERIAL. NO. ....................
DISPLAY TYPE (5) : Manta ................................ SERIAL. NO. ....................
DISPLAY TYPE (6) : Manta ................................ SERIAL. NO. ....................
ANTENNA TYPE (1) : ............................................ SERIAL. NO. ....................
ANTENNA TYPE (2) : ............................................ SERIAL. NO. ....................
ANTENNA TYPE (3) : ............................................ SERIAL. NO. ....................
ANTENNA TYPE (4) : ............................................ SERIAL. NO. ....................
ANTENNA TYPE (5) : ............................................ SERIAL. NO. ....................
ANTENNA TYPE (6) : ............................................ SERIAL. NO. ....................
TX TYPE (1) : ............................................ SERIAL. NO. ....................
TX TYPE (2) : ............................................ SERIAL. NO. ....................
TX TYPE (3) : ............................................ SERIAL. NO. ....................
TX TYPE (4) : ............................................ SERIAL. NO. ....................
TX TYPE (5) : ............................................ SERIAL. NO. ....................
TX TYPE (6) : ............................................ SERIAL. NO. ....................
RAD 1 : ....................................................
RAD 2 : ....................................................
HL 1 SKEW : ....................................................
Issue 2 1 July 03
KH 2026Record Pages
HL 2 SKEW : ....................................................
LOG TYPE : ....................................................
GYRO TYPE : ....................................................
MAINS SUPPLY :MONITOR
...................... VOLTS : .............. PHASE : .............. FREQ.
PERFORMANCE MONITOR:
TX : ........................................ nm
RX : ........................................ nm
INSTALLATION ENGINEER : ...............................................................
DATE : ...............................................................
LOCATION : ...............................................................
July 03 2 Issue 2
KH 2026Record Pages
DE FAULT SET TINGS
FACTORY SETTINGS
RANGE CUSTOMER SETTINGS
RANGE 6nm 0.25 - 96nm
RINGS (ON/OFF) ON ON/OFF
EBL1/EBL2 OFF ON/OFF
VRM1/VRM2 OFF ON/OFF
VECTOR TIME 15min 1 - 30min
VECTOR MODE NORM NORM/NORM REVERSED
DAY/NIGHT DAY DAY/NIGHT
TRAILS ON/OFF ON ON/OFF
TRAILS TIME 3min 0.75 - 99min
AZIMUTH MODE N. UP N. UP/C. UP/ HEAD UP
MEDIUM PULSE 3nm Not Adjustable
LONG PULSE 48nm Not Adjustable
PULSE STATUS Normal Down/Normal/ Up
HISTORY OFF ON/OFF
STABILISATION EXT SEA/MANUAL/EXT
MOTION MODE RELATIVE R, T or CD
SEA CONTROL 0 0 - 9 or A
RAIN CONTROL 0 0 - 9
Issue 2 3 July 03
KH 2026Record Pages
FACTORY SETTINGS
RANGE CUSTOMER SETTINGS
GAIN CONTROL 6.5 0 - 9
CURSOR MODE Range/Bearing Range/Bearing or TCPA
CURSOR PARKING LOW LOW/HIGH
ENHANCE NORM NORM/ENH
CORRELATION IR OFF, IR or SC/SC
CPA 1nm 0.1 - 6nm
TCPA 15min 1 - 60min
LEVELS Maximum 0 to Maximum
SPEED INPUT LOG LOG, Man or Dop
July 03 4 Issue 2
KH 2026Record Pages