I 03-FEB-2005 LEGENDS AND TABLES LIST OF CONTENTS 1. General . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1 2. Airport Operational Information (AOI) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5 3. Terminal and approach charts . . . . . . . . 3.1 3.2 3.3 3.4 3.5 3.6 3.7 3.8 Planview in general . . . . . . . . . . . . . . . . . . . . . . . 6 Meters to feet conversion . . . . . . . . . . . . . . . . . . 21 Airport Facility Chart (AFC) specific . . . . . . . . . . . . 24 Standard Arrival Route (STAR) specific . . . . . . . . . 25 Instrument Approach Chart (IAC) specific . . . . . . . 26 3.5.1 Planview . . . . . . . . . . . . . . . . . . . . . . . . 27 3.5.2 Runway description . . . . . . . . . . . . . . . . 27 3.5.3 Profile and distance/altitude table . . . . . . 30 3.5.4 Approach minima table . . . . . . . . . . . . . . 36 Standard Instrument Departure (SID) specific . . . . . . . . . . . . . . . . . . . . . . . . . . . 39 Standard Instrument Departure Procedure Text (SIDPT) . . . . . . . . . . . . . . . . . . . . . . . . . . . . 40 Minimum Radar Vectoring Chart (MRC) specific . . . . . . . . . . . . . . . . . . . . . . . . . . 42 E 2005 4. Ground charts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.1 Planview in general . . . . . . . . . . . . . . . . . . . . . . 4.2 Airport parking chart specific . . . . . . . . . . . . . . . . 4.3 Low visibility chart specific . . . . . . . . . . . . . . . . . Change: Update 43 44 48 48 LAT General Part 03-FEB-2005 E 2005 1. 1 LEGENDS AND TABLES GENERAL HEADER The manual is set up in a way to allow easy and quick handling by the pilot in daily operations. The sequence of airports in the manual is determined by: country name city name airport name. The charts are organized in chart types with colored header labels for quick and easy recognition and have a fixed sequence within each individual airport. The following examples also indicate the numbering and the sequence of the charts within each airport section. The page number consists of a chapter number for each chart type and a sequential chart number within the chapter. Note: Continuous numbering is made within the chart types of the Lido master manual. This can cause interruptions of page numbering within a customized manual, where the customer is not using all charts available. Therefore the check for completeness has to be made with the list of contents, rather than with the page numbers only. Change: NIL LAT General Part LEGENDS AND TABLES 2 03-FEB-2005 Special color codes In all parts of the manual a special color code is used to identify temporary or company information. Special coloring appears as hatching in chart labels, as border marking on text pages or as color coded charts. Temporary charts are shown with white stripes on the respective chart type color. Company text information is either marked with a yellow stripe or printed on yellow paper. The following colors are used: Tailored or customized charts always carry the logo of the respective customer in the page frame. Any customer defined information being displayed on the charts is shown in magenta color (except for customized minima). AIRPORT CHARTS General purpose and use of All types of airport charts in Lido’s Route Manual Standard use the same symbology, adapted for every specific chart type. Consistent elements are handled in the same way as on RFCs whenever possible. The Airport Facility Chart (AFC) supports flight operations within the Terminal Control Area (TMA) after take-off or before landing. Single AFCs are always shown on the front side of the sheet with the Airport Ground Chart (AGC) on the reverse side. The Airport Ground Chart (AGC) covers the airport ground layout and shows the runways, taxiways and apron areas. The AGC is normally shown on the reverse side of the AFC. RWY information used for takeoff is provided on the AGC. The Airport Parking Chart (APC) is the supplement to the AGC showing details concerning the apron situation and parking stands. The Low Visibility Chart (LVC) is very similar to the AGC. Differences include additional symbols, format and the low visibility taxi procedure text. The Engine Out Standard Instrument Departure chart (EOSID) is published whenever operationally required or officially published in the AIP and displays engine out procedures to be followed after take off for the individual customer and/or aircraft type. The layout is based on the SID, slightly differing in format or layout. The Standard Instrument Departure Chart (SID) displays the published departure routes and procedures. The textual description for the procedure is separated from the planview and available in the Standard Instrument Departure Procedure Text (SIDPT). Change: NIL E 2005 LAT General Part E 2005 03-FEB-2005 3 LEGENDS AND TABLES The Standard Instrument Departure Procedure Text (SIDPT) provides the textual description of the SID procedures wherever published in the respective AIP. The SIDPT is organized in three columns: SID, ROUTING, ALTITUDES. The contents of the SID text page correspond to the procedures on the SID charts. The Standard Arrival Route Chart (STAR) displays the published arrival routes and procedures. The STARs are generally published without a textual description. If however a textual description is necessary it is either printed on the chart planview or on a separate STAR procedure text page (STARPT). The Instrument Approach Chart (IAC) supports pilots during approach and missed approach. The IAC provides a sophisticated approach profile for vertical navigation, detailled information for conduct of continuous descent for non precision approaches, detailled RWY information and approach minima. The Visual Approach Chart (VAC) supports official visual procedures providing detailed information about man made and topographical features within the visual maneuvering area. No vertical profile is shown for visual procedures.Visual approach minima are listed at the lower end of the VAC. The Minimum Radar vectoring Chart (MRC) provides radar vectoring sectors with associated minimum altitudes wherever available in official sources (AIP). Page frame information Depending on the paper size of the manual - either A4 or A5 format - the headers appear in the following way: A5 manual: Large planview: Small planview: Change: NIL LAT General Part LEGENDS AND TABLES 4 03-FEB-2005 A4 manual: E 2005 LAT General Part Explanation of the individual items 1 Change remark providing information about the revised items. 2 Chart name. 3 City and airport name (if deviating). 4 Copyright note. 5 Country. 6 7 Customer logo on tailored charts (containing customer specific, additional or deviating information). Header label colored according to chart type (see also AIRPORT CHARTS). 8 IATA and ICAO airport code. 9 Page Identification Number. 10 Page number according to chart type. Change: NIL 5 03-FEB-2005 LEGENDS AND TABLES The Revision date is always a sheet date. If two or more charts are combined on one sheet, and during a revision cycle only one chart is affected by to changes this revised chart determines the revision date. The change remark of the unaffected chart still carries the change remark of its last revision but is dimmed to indicate that it was not changed in the current cycle (equivalent to “Change: NIL”). 12 With Effect From (WEF) date, only added if the chart becomes effective later than indicated in the revision date. For Tempo Charts two dates (begin-, end-date) indicating the period of affectiveness for a certain chart can be added instead of a single WEF date. Begin- and end-date are separated by a slash. Abbreviations may be used to describe - especially - the end of the period of effectiveness. E 2005 11 2. AIRPORT OPERATIONAL INFORMATION (AOI) The AOI is the textual description of the basic general information about the airport as well as possible differences to the country standard General – Airport hours – Airport information – Operation – Warnings – Other information Arrival – Speed restrictions – Communication – Communication failure – Arrival Procedure – Company information – Other information Departure – Take-off minima – Speed restrictions – Communications – Communication failure – Departure Procedure – ATC Slot, Clearance – De-icing – Warnings – Company information – Other information Headers are omitted in case of NIL information. If a separate AOI chapter is unnecessary and not printed for a certain airport, a remark is added on the AFC accordingly. Change: Update LAT General Part LEGENDS AND TABLES 3. TERMINAL AND APPROACH CHARTS 3.1 PLANVIEW IN GENERAL 6 03-FEB-2005 All the terminal and approach charts feature planviews being very similar and only having slight differences between the different chart types. Therefore a general explanation of all features on these planviews will be provided followed by a detailled description of the chart specifics. All chart planviews feature a topographical display, are oriented to magnetic north and provide to scale information. AFC sample: Change: NIL E 2005 LAT General Part 03-FEB-2005 E 2005 IAC sample: Change: NIL 7 LEGENDS AND TABLES LAT General Part LEGENDS AND TABLES 8 03-FEB-2005 The Aerodrome Elevation is provided in feet and shown in bold font in the chart information pictograph generally positioned in the lower left part of the chart planview. Also see under Chart Information. 1 E 2005 LAT General Part Airports: Generally only airports that are in civil use and provide at least one runway with minimum dimensions of 30m width and 1500m length are shown on the chart. The airports will be charted with city- and/or airport name, 4 letter code and longest runway in hundreds of meters . Airport with largest RWY ≥45m width and ≥1500m length. Airport with largest RWY ≥30m width and ≥1500m length. As exceptions airports that are not meeting the above requirements but are mentioned in the context of warning and/or caution notes in the corresponding AIP or are upon customer request will also be displayed. customer request caution/warning note with runway layout Note: As an exeception and to avoid congestion only airports with a minimum RWY length of 2000m will be charted for the territory of the United States (excluding Alaska). 2 Airspaces: Only controlled airspace – with sectors – class D, C, B or A related to the charted airport, are labeled with lower limit, upper limit and airspace class. (Generally airspaces are shown with limiting up to FL 100). Note: Not on IACs. 3 Airways will be labeled as follows (if applicable) – MAA (see Maximum Authorized Altitude) – airway name (with type information) – segment distance – MEA (see Minimum Enroute Altitude) – MTCA (see Minimum Terrain Clearance Altitude) – even/odd indicator (see Even/Odd Indicator) – different to procedures, consistent with RFC. Multiple airway names are separated by a slash. Change: Update 9 03-FEB-2005 LEGENDS AND TABLES E 2005 If an airway is limited to one direction a direction indicator arrow is added to the name. The airway type can either be conventional or RNAV. – On conventional charts only the connecting RNAV airways will be labeled as RNAV airways. Either with ”R” or the RNP value, if available (e.g. RNP 5). – On RNAV charts only the conventional airways will be labeled with ”C”. – On combined charts either type of airway will be labeled. 4 Altitude limitation at defined procedure points. S Maximum altitude ”at or below” S At altitude S Minimum altitude ”at or above” 5000 5000 5000 S In between 8000 6000 ”at or between” 5 Approach data box is provided on AFCs only. For details refer to AFC legend. 6 Approach Procedure Designator Box is provided on IACs only. For details refer to IAC legend. 7 By ATC: For segments that are only available by special ATC clearance a remark (ATC) is added. 8 Border Text: Waypoints or navaids of procedure or airway legs which lie outside of the chart frame, are shown along the border. Waypoint name or navaid identification with frequency are indicated in such cases. Change: Editorial LAT General Part LEGENDS AND TABLES 10 9 Chart information is normally placed in the lower left part of the chart, providing S Local magnetic variation. S Chart orientation S Aerodrome elevation 10 COM Frequencies are provided on procedure charts in the upper right corner of the chart frame. The box may be moved for optimal placement. The callsign prefix is assumed to be the city name of the respective airport. Only if the callsign prefix is deviating from the city name, the prefix will be added in the communications box, e.g. City name is ”Windsor Locks”, the callsign prefix is ”Bradley”. Frequencies operating hours deviating from H24, as well as other restrictions/instructions related to the relevant frequencies are provided in the communications box on the AFC. Times are generally shown in UTC (for more information about World Local Times see the corresponding chapter). 03-FEB-2005 E 2005 LAT General Part If ATIS broadcast is available via data link, a preceding ”D-” is added. Company Information Company derived information displayed on chart planviews is always shown in magenta. This can be textual and/or graphical information. 11 Compass rose is shown centered to an airport facility with a radius of 10NM on IACs and 20NM on the other charts. The compass rose is part of the distance circles. 12 Distance circles: are shown in 10NM steps up to 50NM, labeled with distance and reference fix. The compass rose forms part of the distance circles. Change: Update 03-FEB-2005 11 E 2005 The Even/Odd Indicator is only provided on airway segments, if the respective airway requires different flight levels (even/odd) than specified in officially published cruising tables. FIR boundaries are provided on all chart types (except IACs) indicating the FIR name followed by the suffix ”FIR” and 4 letter identifier. 13 Grid lines are oriented to true north. The grid size (magnitude) of the grid is depending on the chart scale, generally 1°, 30’ or 15’. The grid lines are not shown on IACs. 14 Grid ticks: The chart frame provides coordinate grid information aligned to true north. At least two coordinates are shown along the left and upper frame. 15 Headings are shown as a three digit number with a degree symbol and a preceding ”H”. 16 Highest obstruction within the chart planview or inset. This might either be a terrain high spot, a man made obstacle or a topographical area. 17 Holding patterns: Standard timed holding pattern with minimum and maximum holding altitude or FL if officially published. Standard timed holding patterns are generally shown with a fixed symbol thus being not to scale. Exceptions can be made on special charts or when operationally required. Any standard timed racetrack pattern will generally be shown to scale, taking the maximum procedure design speeds into account (e.g. New PANS OPS, TERPS). Holding patterns being defined by DME distances and/or waypoint definition lines are shown to scale. Blue figures in a holding pattern are missed approach altitudes and are shown if deviating from the respective minimum holding altitude (MHA). Change: Update LEGENDS AND TABLES LAT General Part LEGENDS AND TABLES 12 03-FEB-2005 A holding altitude or FL with the remark (ATC), is only permitted to fly with ATC clearance. E 2005 LAT General Part Holding insets are used whenever necessary because of congestion or holding patterns lying outside the chart planview. 18 Initial Approach Altitude is the minimum altitude between the IAF and IF providing an obstacle clearance of at least 300m (984ft) in the primary area. For further details refer to part Rules and Regulations (RAR). 19 Insets are used to either show: S Blow ups of congested areas (e.g. initial climbs), S Continuations of procedures lying outside the chart planview. Insets can either be: S To scale with or without scale information (topography), S Not to scale (without topography). 20 Intermediate Approach Altitude is the minimum altitude between the IF and FAF/FAP with a reducing obstacle clearance from 300m (984ft) to 150m (492ft) in the primary area. For further details refer to part Rules and Regulations RAR). 21 Main airport of the corresponding chart is charted with its main runway layout and the city and/or airport name. 22 Maximum Authorized Altitude (MAA): The MAA is presented on each airway segment whenever published in the AIP either in FL or ft) and is different from the associated airspace limitations (e.g. lower vs. upper airspace). If different MAAs apply for each direction on the same airway segment, a direction indicator is added. Change: Editorial 03-FEB-2005 13 E 2005 Different MAAs applied to different airways on the same segment are separated by a slash. If one of a combination of MAAs is according the associated airspace limitations (lower vs. upper airspace) that is indicated by three dots. 23 Minimum Enroute Altitude (MEA) is presented on each airway segment whenever it is published in the AIP (either in FL or ft) and is deviating from the associated airspace limitations (e.g. lower vs. upper airspace). If different MEAs apply for each direction on the same airway segment, a direction indicator is added. Multiple MEAs applied for different airways on the same segment are separated by a slash. If one of a combination of MEAs is according the associated airspace limitations (lower vs. upper airspace) that is indicated by three dots. 24 Minimum Grid Altitude (MGA) is the lowest safe altitude to be flown off-track. The MGA is calculated by rounding up the elevation of the highest obstruction within the respective grid area to the next 100ft and adding an increment of S 1000ft for terrain or obstructions up to 6000ft or S 2000ft for terrain or obstructions above 6000ft. e.g. 6345ft obstacle = 6400ft rounded up + 2000ft buffer = 8400ft MGA Shown in hundreds of feet. Lowest indicated MGA is 2000ft. This value is also provided for terrain and obstacles that would result in a MGA below 2000ft. Exception is over water areas where the MGA can be omitted. MGAs below 10’000ft are shown in purple, at and above 10’000ft in red. Change: Update LEGENDS AND TABLES LAT General Part LEGENDS AND TABLES 14 25 Minimum Sector Altitude (MSA) is shown for each MSA sector. The sector boundaries are formed by limiting radials, QDMs or tracks depending on the reference facility and the limiting circle. 26 MSA limiting circle is shown centered to the reference navaid or the Airport Reference Point (ARP), normally having a radius of 25NM. 03-FEB-2005 E 2005 LAT General Part A MSA pictograph is used when the characteristics of the MSA sectors cannot completely be drawn from the chart planview alone. 27 According to ICAO regulations the MSA provides an obstacle clearance of at least 300m (984ft). Minimum Terrain Clearance Altitude (MTCA): The MTCA is provided for all airway segments, on STARS (to the IAF) and on selected SIDs (for segments lying outside the coverage of the MSA) always shown in red italic font. For SIDs and STARS the MTCA is calculated for an area of 5 NM on either side of the centerline of each procedure segment and around a navaid/waypoint where the MTCA is provided. For airways the buffering area extends to 10NM. The MTCA is calculated by rounding up the elevation of the highest obstruction within the respective safety area to the next 100ft and adding an increment of S 1000ft for terrain or obstructions up to 6000ft or S 2000ft for terrain or obstructions above 6000ft. e.g. 2345ft obstacle = 2400ft rounded up + 1000ft buffer = 3400ft MTCA Values shown in feet. Lowest indicated MTCA is 3100ft, meaning that wherever no MTCA is provided 3000ft can be considered a safe flight altitude. Consecutive segments having an identical MTCA can be combined by MTCA break symbols providing the label only once. Change: Editorial 03-FEB-2005 15 E 2005 Any MTCA being calculated with other than the above mention policies will be shown in brackets with reference to the calculation method. In rare cases the MTCA calculated for a specific segment can be higher than the respective published official minimum altitude. 28 29 This is due to the difference in buffer calculation and/or the definition of the safety area. For details refer to part Rules and Regulations (RAR) Missed approach: All items related to the missed approach procedure are shown in blue color. Navaids are shown with the navaid symbol and the navaid flag including: Navaid name (the name will be omitted if multiple navaids of the same type share the name) S frequency and identifier S morse code S INS coordinates (not on IACs) ILS DME ILS LLZ DME LLZ VOR/DME, VORTAC VOR with ATIS broadcast with HIWAS broadcast with meteo broadcast oriented to true north Change: Editorial LEGENDS AND TABLES LAT General Part LEGENDS AND TABLES 16 03-FEB-2005 with FSS information E 2005 LAT General Part DME only/ TACAN only NDB If two navaids are co-located and have the same name and indentifier only one symbol and a combined navaid flag is charted. Outer marker Middle marker Inner marker 30 Obstacles with their associated top elevation that might appear as: Lighted obstacle Single obstacle Group of obstacles The display of obstacles is filtered to display an obstacle only if: a) its top elevation is more than 100ft above aerodrome elevation in a 1NM radius around the airport reference point (ARP), climbing 100ft with each NM up to a distance of 5NM. Change: Editorial LEGENDS AND TABLES 17 03-FEB-2005 E 2005 b)outside the 5NM radius - the obstacle ALT protrudes the upper limit of the topographical layer which it is located in (also refer to section “topography”). 31 Procedure designator: SID and STAR designators are shown in colored arrows with procedure name(s) indicating the direction of the procedure. For details refer to the relevant chapter within SID/STAR specifics. 32 Procedure tracks are drawn by specific lines that are interrupted by heading or track indication. terminal procedure line airway procedure line transitions missed approach procedure line visual track terminal procedure continued by radar vectors 33 Procedure fixes: IAF: Initial Approach Fix, placed above navaid box or WPT name. IF: Intermediate Fix FAF: Final Approach Fix FAP: Final Approach Point MAPt: Missed Approach Point D: descent point for continuous descent The identical symbology is used to indicate RNAV procedure fixes such as initial approach waypoint (IAWP), intermediate waypoint (IWP), etc. Change: Update LAT General Part LEGENDS AND TABLES 18 34 Radials are shown as a three digit number with a preceding ”R” on procedures or waypoint definition lines. 35 Remarks, cautions, warnings and special notes are shown on the chart planview in white boxes. FPL relevant notes are published in the Airport Operational Information (AOI). Scalebar is generally shown in 2NM steps on the left-hand side of planview frame, allowing deviations depending on the chart size and scale. 03-FEB-2005 E 2005 LAT General Part 36 37 Special Use Airspaces (SUAs) Danger and restricted areas are displayed with the airspace identification. Prohibited areas are displayed with the airspace name and its vertical limits. 38 Speed Limit Point (SLP) 39 Terrain high spot elevation representing the local maximum within the surrounding topography. Total Approach Distance from Initial Approach Fix (IAF to Final Approach Fix / Final Approach Point (FAF/FAP). May differ from sum of legs due to rounding. 40 Change: Editorial 03-FEB-2005 E 2005 41 19 LEGENDS AND TABLES Topography is shown to locate high terrain elevation as well as coastlines, water surface, rivers, cities or other geographic information of interest. The color coding of terrain elevation on IACs starts with white at airport elevation changing to darker brown in the following way: 1st layer: white, max. 500ft above aerodrome elevation (rounded mathematically to the nearest 500ft step). 2nd layer: light beige, 501-max. 1000ft above aerodrome elevation. 3rd layer: beige, 1001-max. 2000ft above aerodrome elevation. 4th layer: dark beige, 2001-3000ft above aerodrome elevation. 5th layer: light brown, 3001-4000ft above aerodrome elevation (flexible). 6th layer: brown, beyond 4001ft above aerodrome elevation (flexible to cover the highest topographical feature within the planview). On AFC, SID, STAR and MRC the first two layers are combined to one layer of a maximum vertical extension of 1000ft. Change: Editorial LAT General Part LEGENDS AND TABLES 20 03-FEB-2005 The topographical steps shown in the legend on each planview indicate the maximum elevation in feet above MSL. No man-made obstacles are included in the respective maximum elevations which is symbolized by the obstacle symbol in the respective altitude box. For obstacle policy refer to section “obstacles”. Exception: The last layer covers the highest topographical feature and any man-made obstacle. 42 Track distance is provided for each segment. terminal procedure AWY 43 Tracks or bearings are shown as a three digit number with a degree symbol on procedures or waypoint definition lines. Transition Level and Transition Altitude are shown in the lower right corner. 44 45 Waypoint coordinate: A waypoint will always be shown with INS coordinates (except on IACs) whenever it is serving in a conventional procedure. 46 Waypoint name 47 Waypoint or procedure point definition can either be by a bearing or radial, or a DME distance 48 Waypoint symbols S Conventional: Whenever a waypoint is defined exclusively as a conventional waypoint. S RNAV: Whenever a waypoint is defined as RNAV waypoint, even for combined conventional and RNAV procedures. S Compulsory: Whenever a waypoint is defined as compulsory for at least one procedure. S Fly over: Whenever a waypoint is defined as fly-over for at least one procedure. S Fly-by: Whenever a waypoint is defined exclusively as a fly-by waypoint. Change: Editorial E 2005 LAT General Part 21 03-FEB-2005 E 2005 49 LEGENDS AND TABLES Whichever is earlier: Conditional AIP text instructions such as “... at 2000ft or 3 DME3 CHE (whichever is earlier) turn left ...“ are symbolized in the chart planview. Whichever is later: Conditional AIP text instructions such as “... at 3500ft or DME4 FKO (whichever is later) turn left ...” are symbolized in the chart planview. 3.2 METERS TO FEET CONVERSION The m-ft conversion is provided whenever m-values are published in the respective AIP. In general only those values applying to a specific procedure are converted. As an exception on SID, STAR and AFC a table with the officially published cruising levels above transition altitude is provided. The reference for QFE to QNH conversions (AD or THR elevation) is used according to the respective AIP guidelines. LIDO does not provide an in-house policy. All procedure values being at or below transition altitude are converted from meters to feet and rounded up to the next ten feet. All values above transition altitude are taken from the officially published cruising tables (FL conversion). For the procedures displayed on chart planviews the corresponding official meter value is given in the conversion table only. Exceptions: Aerodrome Elevation and Threshold Elevation are generally only provided with their converted feet-value. On some charts however (QNH-QNH-conversion) the original m-value for the Aerodrome Elevation is additionally provided in brackets. QNH QFE MSA QNH Change: Update LAT General Part LEGENDS AND TABLES 22 03-FEB-2005 QFE E 2005 LAT General Part Transition altitude QNH QFE Note: m values referenced to QFE carry the suffix ”QFE”, QNH values are printed without suffix. Conversion tables are provided on the chart planview. Altitude conversion (below transition altitude) QNH / QNH: Indication of conversion datum: Change: Editorial 03-FEB-2005 23 E 2005 Altitude conversion (below transition altitude) QFE / QNH: Indication of conversion and reference datum: Pressure difference: The QNH can be calculated from a given QFE. For example: QFE (as by ATC/ATIS) 998hPa Delta hPa + 23hPa QNH 1021 hPa Flight level conversion (above transition altitude) according the officially published cruising tables: On SID, STAR and AFC a table derived from the officially published cruising tables with all values above the transition altitude is provided. Change: Editorial LEGENDS AND TABLES LAT General Part LEGENDS AND TABLES 3.3 24 03-FEB-2005 AIRPORT FACILITY CHART (AFC) specific The AFC consists of the components: S Planview S RWY information S COM information E 2005 LAT General Part The AFC planview features a general overview over the aerodrome area, displays all navaids within the coverage of the chart planview and provides information about all arrival and departure procedures. The procedures are displayed and labeled only with their last (SID) or first segment (STAR). COM frequencies: Frequencies are shown in a green box. Frequencies operation hours are only shown if the FREQ is not operative 24h. Times are shown in UTC. The Symbol ‡ indicates that during periods of Daylight Savings Time effective hours will be one hour earlier than shown (for more information about World Local Times see the corresponding chapter). RWY information For all runways on the respective airport. For details refer to IAC RWY description section. Change: Editorial 03-FEB-2005 E 2005 5 25 LEGENDS AND TABLES Approach Data Box: The approach data box with its pointer to the approach direction, inbound track and glidepath figures, features the best approach for the corresponding RWY including: S The approach type having the lowest minimum. S Corresponding frequency and callsign S Morse code S Minimum altitude steps with distance reference. For any non precision approach every altitude step would relate to the continuous descent angle. The first altitude to be the descent point and all LIDO calculated crossing altitudes printed in italic font. 3.4 STANDARD ARRIVAL ROUTE (STAR) specific The STAR generally only consists of the chart planview. A separate STAR procedure text is only provided in exceptional cases. If provided, a note is given in the upper right corner. Change: Editorial LAT General Part LEGENDS AND TABLES 31 26 03-FEB-2005 Procedure Designator: The procedure designator is generally provided on the first segment of the respective procedure. The designator consists of: S orange arrow S procedure name (with suffix if applicable). E 2005 LAT General Part If procedures are combined they will be in alphabetical order and separated by a slash. On combined charts (conventional and RNAV) RNAV procedures will carry the suffix RNAV. Other suffixes indicate other constraints on combined charts (e.g. prop only, jet only). 3.5 INSTRUMENT APPROACH CHART (IAC) specific The chart sequence of the IACs is generally determined by, 1st priority: type of approach (ILS, RNAV GPS, VOR, NDB, Visual, Circling, ...), including subtypes 2nd priority: runway (RWY 07,RWY 18, RWY25, ...), left before center, before right (RWY 07L, RWY 07C, RWY 07R, RWY 18, ....) The IAC consists of the components: Planview S RWY description S Profile and distance/altitude table S Approach minima Subtypes to the IAC are – Letdown – VAC The VAC may either show a – Visual – Circling Change: Editorial E 2005 03-FEB-2005 27 LEGENDS AND TABLES LIDO defines the subtypes as follows: LETDOWN: An instrument procedure bringing the pilot into a position to land by visual means at airports where no instrument approach procedure to a specific runway is published. A letdown ends at the MAPt and usually has to be continued with a circling to the RWY of intended landing. VISUAL: A flight procedure that has to be executed by visual means but is due to a prescribed flight track that can either defined by visual- and/or instrumental means. A Visual may or may not begin at the end (MAPt) of a specific instrument part (ILS, LLZ; VOR; Letdown etc.) CIRCLING: A flight procedure within a specified area (NEW PANS-OPS or TERPS). The circling has to be executed solely by visual means and usually begins at the end (MAPt) of a specific instrument part (ILS, LLZ, VOR, Letdown etc.) 3.5.1 Planview Localizer symbol always reaching from threshold to FAP/ FAF without giving any reference to signal coverage. Note: May not yet be implemented on early charts. Airspaces: Terminal Areas (TMA) as well as Control Zones (CTR) are not provided on IACs. FIR boundaries: Not provided on IACs. Grid Line: Not provided on IACs. Minimum Grid Altitude (MGA): Not provided on IACs. 6 Approach Procedure Designator Box is provided on IACs only and placed in the upper right corner of the chart. The following information is provided. S Full procedure name (navaids that require tuning of a distinct frequency are separated by a “+” symbol) S All required navaids for the respective approach including identifier and frequency S The respective morse code will only be shown if not repeated in the planview (e.g. ILS). 3.5.2 Runway description The runway description shows the runway including approach lights with information relevant for landing. 1 Approach Light System (here:P2F) 2 Approach Light System Abbreviations Identification letter of the approach light system, with intensity (high, medium, low or variable: H, M, L or HL, ML). See also LIGHT, VISUAL AIDS, ARRESTING SYSTEMS part . Change: Editorial LAT General Part LEGENDS AND TABLES 28 03-FEB-2005 E 2005 LAT General Part P2: ICAO standard CAT II + III Approach light system with red side row lights the last 300m. Centerline lights white; longitudinal spacing 30m. Minimum two crossbars located 150m and 300m from THR. P1: ICAO standard CAT I Centerline lights white; longitudinal spacing 30m, except US lighting system spacing 60m. At least one crossbar located 300m from THR. S: ICAO standard simple approach light system MAX longitudinal spacing of lights 60m. At least one crossbar located 300m from THR. N: Non standard lights Any approach light system, which does not meet the above requirements. Suffix F: (P2F, SF, NF) Indicates that sequenced flashing lights are available (normally from beginning of approach light system to 300m from THR). Suffix R: (P1R) Runway alignment indicator lights (RAIL), mainly used in US approach light systems. Instead of barrettes from the beginning of the approach light system to 420m, there are only sequenced flashing lights available. 3 Approach light system length is provided whenever deviating from standard, which is 900m for ICAO and 720m for U.S. approach light systems. 4 Centerline lights (RCLL) (last 900-300m white/red intermittent, last 300-0m red). Change: Editorial 03-FEB-2005 E 2005 5 6 7 29 Centerline lights (RCLL) spacing in m and light intensity (high, medium, low or variable: H, M, L or HL, ML). For further details see LIGHT, VISUAL AIDS, ARRESTING SYSTEMS part. Centerline lights all white (other non-standard coloring is specified with additional text). Designator 8 Edge light spacing and intensity (high, medium, low or variable: H, M, L or HL, ML). For further details see LIGHT, VISUAL AIDS, ARRESTING SYSTEMS part. 9 Edge lights: non standard 10 Edge lights: standard edge lights with yellow caution zone (YCZ) featuring yellow lights for the last 600m but at least 1/3 of total RWY length. 11 Grooved (or similar): G, RWY ungrooved: x 12 14 Landing Distance Available (LDA) beyond THR and displaced THR (not scaled). Non standard centerline lights (RCLL), or touch-down zone lights (RTZL) are specified (RCLL only unless all white). PAPI - Precision Approach Path Indicator VASIS - Visual Approach Slope Indicator Systems 3-bar VASIS 2-bar VASIS T-bar VASIS 15 PAPI / VASIS calibration angle 16 Runway End Identifier Light (REIL): flashing lights on both sides of THR (example below: approach from the left). Slope information in % The average runway slope as wells as the touchdown zone slope (TDZ) (if available covering the first 900m of the landing RWY) are provided. A negative slope is indicated for downward slopes (e.g. -0.2%) a positive slope for upward slopes (e.g.+0.3%). 13 17 18 THR elevation and Pressure Difference in hPa. Change: Update LEGENDS AND TABLES LAT General Part LEGENDS AND TABLES 30 19 Runway Touchdown Zone Lights (RTZL), standard 900m. 20 Width in m. 03-FEB-2005 E 2005 LAT General Part 3.5.3 Profile and distance/altitude table Non Precision Approach: For all non-precision approaches a constant descent angle is provided, which is calculated from touchdown zone over a 50ft barrier at threshold and the highest limiting minimum crossing altitude (according to published AIP step down approach) up to the intermediate approach altitude. Any delayed descent point being different from the position of the respective final approach fix (FAF) as well as altitudes being calculated with a constant descent angle that are higher than the published corresponding step down descent altitudes are shown in the profile. Any calculated constant descent angle will have a minimum glide angle of 3°. The distance / altitude table is published for non-precision approaches providing the constant descent angle altitudes and normally shows the corresponding minimum altitude for every other NM. Note: Also on ILS charts the distance/altitude table refers to the non-precision approach, meaning - in most cases - the respective localizer approach, or any other non-precisicion approach being combined with the ILS approach. Official AIP values are shown in normal font, Lido calculated values in italic font. The Info table shows in the 1st row 2nd row 3rd row 4th row The type of non-precision approach (only for ILS charts with associated non-precision approach) and the calculated descent angle. The distance reference. When a suitable DME facility is not available (or for RNAV GPS approaches) the distance/altitude table will be referenced to threshold (or displaced threshold if applicable). The inbound track (only if RWY QFU differs 1° or more, but less than 20° from inbound track). The RWY QFU (only if RWY QFU differs 1° or more, but less than 20° from inbound track). Change: Editorial E 2005 LEGENDS AND TABLES 31 03-FEB-2005 ILS Approach: The profile for the ILS approach covers also the Non Precision LLZ approach. In case of glideslope incompatibility of the two approach profiles, the secondary profile (LLZ) is shown with a special symbolic providing descent point, LLZ approach glidepath and calculated step altitudes accordingly. The Distance/Altitude Table and the Ground Speed/Rate Of Descent Table are based on the non precision LLZ approach. Samples 14 8 1 6 16 8 13 12 6 4 5 11 16 9 2 10 6 8 3 7 15 12 11 16 9 2 15 The delayed Descent Point indicates the point where the calculated continuous descent is commenced. The distance fix associated with the descent point is printed in bold font. Change: Editorial 7 LAT General Part LEGENDS AND TABLES 32 03-FEB-2005 Differing Final Descent: If the final descent for ILS and LLZ differs in a way that two flight paths need to be displayed the ILS related information is printed in grey font. E 2005 LAT General Part 1 Distance Reference can either be a facility providing DME information or runway threshold and is always provided with the first distance fix. Associated distances are shown at specified step points. A distance reference navaid will not be shown if it is located behind the runway. All distance fixes (as well as all required navaids)are presented by a vertical line and the respective distance. 2 Distance Scale in NM adjusted to read 0NM at the RWY threshold or displaced threshold. The distances from defined fixes to threshold or displaced threshold is given between the outer marker (or OM substitute) to threshold (or displaced threshold). 3 Final Approach Fix (FAF): Whenever published in the AIP. The FAF marks the beginning of the final segment. If both FAF and FAP are at the same position, only the FAP symbol is shown. Final Approach Point (FAP): Is provided whenever published in the AIP or can be calculated by LIDO (distance printed in italic font). The FAP determines the point where the intermediate approach altitude intersects the glide slope and marks the beginning of the precision approach segment. If both FAF and FAP are at the same position, only the FAP symbol is shown. 4 5 Final or Outer Marker Altitude: Minimum crossing ALT at Outer Marker (OM) or substitute. If different minimum crossing altitude values apply for different procedures on combined charts (e.g. ILS and LLZ) each displayed altitude (except ILS) will carry a prefix related to the type of approach. Change: Update 03-FEB-2005 E 2005 6 33 Glidepath (ILS): The ILS glidepath will be charted in the glide path feather with the value published in the respective AIP independent of its mathematical correctness. The Glide Path Symbol always reaches from threshold to FAP (if published in the AIP) or glide slope intercept altitude without giving any reference to signal coverage. Constant Descent Angle (CDA): The constant descent angle is calculated with exact values then rounded mathematically to the tenth of a degree. The CDA is depicted in the info table. The fact that the given ILS GP value is the published AIP value and the CDA is LIDO calculated might lead to profiles that seem to be inconsistent. In most cases this is due to inaccuracies and unknown rounding policies of the publishing state authorities. In the above case the ILS GP is steeper than the published 3.0°, namely 3.1° as calculated by Lido with exact values. Glide Slope Intercept Altitude: If a glide slope intercept altitude is published in the AIP differing from the corresponding LLZ minimum crossing altitudes, this GS intercept altitude is charted in grey font with the prefix ”ILS” and represented by a grey box. Change: Editorial LEGENDS AND TABLES LAT General Part LEGENDS AND TABLES 7 34 03-FEB-2005 Ground Speed (GS in KT) / Rate Of Descent Table (ROD in ft/MIN) always refers to the non precision approach, meaning that for example on ILS charts only the LZZ approach is supported. The calculation is based on the flight portion from outer marker (or substitute) to the missed approach point (MAP). 1st row GS in KT (120/140/160KT for ADs below 5000ft AD elevation and 140/160/180KT above) 2nd row rate of descent in ft/min 3rd row time If according to the relevant AIP the definition/ identification of the missed approach point is not authorized based on timing NA is published. E 2005 LAT General Part ILS check altitude to verify glide slope indication. 8 Initial and/or intermediate approach altitude. Marker beacons (outer, middle, inner) are shown with one identical grey symbol and without designator. 9 10 Minimum Crossing Altitude for non-precision approach. The altitude value is represented by the vertical extension (to scale) of the associated grey box. The vertical extension of the MDA box is related to the highest MDA but maximum 80% of the preceding minimum crossing altitude. The minimum crossing altitudes provide an obstacle clearance of at least 90m (295ft) without FAF or 75m (246ft) with FAF. Minimum Descent Altitude (MDA) Also refer to minimum crossing altitude. Change: Editorial 03-FEB-2005 35 E 2005 Missed Approach Point (MAPt) Coordinates will be provided for all RNAV approaches. 11 Missed Approach Point (MAPt) with an arrow indicating the missed approach track. The related distance fix and the missed approach point symbol are printed in blue font. If the MAPt is defined by time only Lido will calculate a distance reference/equivalent which is printed in italic font. Following the continuous descent angle the MDA might be reached prior to the missed approach point. 12 Missed Approach Text: The routing is described based on the AIP and adopted to Lido text specifications. All required Navaids (as well as distance fixes) are presented by a vertical line and their respective identifier. 13 14 Reversal procedure Terrain in Profile: The presentation of terrain in the profile view will be limited to selected airports. Whenever a terrain feature in a profile view is provided it has to be considered as: – not to scale – without specified buffers or splays – intended to create pilot‘s “alertness”. A future version will provide precise data. 15 Threshold Crossing Height (TCH): ILS glidepath height over threshold as published in AIP. Note: Non precision approaches are calculated to cross over RWY THR at 50ft. This value is not shown in the profile. Change: Editorial LEGENDS AND TABLES LAT General Part LEGENDS AND TABLES 16 36 03-FEB-2005 Tracks will be shown directly after the fix from where they apply. E 2005 LAT General Part 3.5.4 Approach Minima Table LIDO standard is to publish minima according JAR, if not below state minima. Minima deviating from JAR will be published only on customized charts following customer guidelines. The presentation sequence starts on the left side with the lowest approach MNM and continues to the right with the circling MNM at the right end of the table. If more than five minima in addition to the circling MNM exist, they are on a separate page at the end of the IAC chapter. 6 Only the lowest permissible minimum for the respective approach is presented in the minima table. Any restriction or limitation is either mentioned in the minima notes or is due to customer policies and operations. 1 Approach RWY designator. For prescribed flight track minima (visual) of multiple RWYs in the same minima strip both RWY directions are shown, separated by a slash. Circling minima are always found at the right end of the minima strip. Change: Editorial 03-FEB-2005 E 2005 2 3 37 Aircraft category or aircraft type. Standard charts featuring minima for categories C and D, “on request” standard charts featuring minima for categories A and B. Also combinations on customized charts are possible. Measuring unit. A: System line 4 Approach type (in case of a precision approach, only the clarifier is shown). Circling minima are generally calculated according NEW PANS OPS regulations. Whenever circling minima are calculated according to TERPS this is indicated by a ”TERPS-flag”. For details concerning the relevant safety area and obstacle clearance refer to part Rules and Regulations (RAR). 5 Approach minimum designator subtype. All required facilities between FAP/FAF and MAPt are listed. 6 Approach remark designator. B: Description line 7 A “+” between two idents means that two physically separated navaids have to be used. A “/” between two idents means that one of the two shown navaids (either the one or the other) is to be used. 8 Special restrictions: >60/6 refers to aircraft with a wingspan of more than 60m or a vertical distance between flight path of landing gear and glide path antenna of more than 6m. This category comprises among others A330 (all types), A340 (all types), B744 and A380. Other defined categories are >65/7. Affected by this category is the A380. All restrictions applying to the restrictive MNM, are stated e.g. APL U/S, HJ only, GA 3.2%, etc. Change: Update LEGENDS AND TABLES C A B D B C LAT General Part LEGENDS AND TABLES 38 03-FEB-2005 C: Weather line 9 Minimum descent heigt (MDH) / Decision Height (DH) for non-precision or precision approaches respectively. 10 If a particular ceiling is required by the state authority for a specific approach this is indicated by the prefix ”C” to the numeric value. In this case the given value must not be considered as MDH/ DH but as required ceiling and has to be accounted for during flight planning. 11 Any restriction to RVR and/or visibility will be shown by a limiting letter (R or V), meaning that any given value followed by a letter must not be converted. R: measured RVR. V: visibility which cannot be converted. E 2005 LAT General Part Values without a letter can be converted according JAR. Wherever required RVR and visibility have the same value, both values will be charted. D: Operational line 12 ’Company’ means that aircraft specific regulation has to be observed within JAR/state limitation for ILS Cat 3 minimum. Whenever an additional descision hight is required by state authorities this is indicated by the suffix ”DH”. “Old” form of presentation. ”New” form of presentation. 13 Radio Altimeter Height (RA) Change: Update E 2005 03-FEB-2005 39 14 Decision altitude (DA) and radio altimeter height (RA) for CAT 1 approaches. The radio altimeter height (RA) will only be shown where officially published. 15 Minimum Descent Altitude (MDA) Decision Altitude (DA) . 16 An overflow arrow indicates that additional minima for the approach can be found on the last IAC page. 3.6 LEGENDS AND TABLES STANDARD INSTRUMENT DEPARTURE (SID) SPECIFIC The SID generally only consists of the chart planview. The corresponding procedure text description is provided in the SID procedure text (SIDPT). Only in exceptional cases the text description can be given on the chart planview. Minimum Terrain Clearance Altitude (MTCA): On SIDs the MTCA is generally provided only for those segments lying outside the coverage of the MSA. The beginning of display of the MTCAs is indicated by a red arrow. If no red arrow is provided within the SID procedures , the display of MTCAs begins with the first airway segment. Procedure Designator: The procedure designator is generally provided on the first segment of the respective procedure. The designator consists of: S green arrow S procedure name (with suffix if applicable). Change: Update LAT General Part LEGENDS AND TABLES 40 03-FEB-2005 If procedures are combined they will be in alphabetical order and separated by a slash. E 2005 LAT General Part On combined charts (conventional and RNAV) RNAV procedures will carry the suffix RNAV. Other suffixes indicate other constraints on combined charts (e.g. prop only, jet only). 3.7 STANDARD INSTRUMENT DEPARTURE PROCEDURE TEXT (SIDPT) The SIDPT is divided in the follow mean Parts: Header line Communication instructions Climb gradient table Procedures description Remarks Header line The header line contains SID procedure names and the corresponding RWY designators with RWYQFU. Change: Editorial 03-FEB-2005 41 LEGENDS AND TABLES E 2005 Communication instructions The COM procedure describes any published radio communications procedure except the applicable frequency. The frequency is shown in the SID column. Climb gradient table A climb gradient table is shown, whenever a procedure requires a climb gradient greater than 3.3%. Procedure description The SIDPT shows the text description of the procedures organized in three columns: SID, ROUTING, ALTITUDES. The contents of the SID text page correspond to the procedures on the SID charts. SID The information is displayed in the following order: S long procedure designator S short procedure designator S FMS procedure designator (If either of these are identical only one designator is displayed) S Minimum climb gradient. If the AIP states that a given minimum climb gradient of more than 3.3% is not due to terrain and/or obstacles in the departure area the prefix ” PDG ” (procedure design gradient) shall be added to the gradient value. This procedure design gradient (PDG) may - for example - account for airspace structure and/or noise abatement reasons. In this case a special note shall explain the reason for the restriction (e.g. to avoid airspace class G).” S departure frequency S remark ball flags Change: Editorial HOCHWALD 3Y HOC 3Y 6.0% to 2500 PDG 4.3% 125.950 LAT General Part LEGENDS AND TABLES 42 03-FEB-2005 ROUTING The routing is described according to the shown procedures on the SID chart including transition and continuation remarks. ALTITUDES All altitude flight restrictions and the initial climb altitude or FL are shown in this column. The initial altitude (if officially published) is always shown as the last information in the “Altitudes” column. Remarks Remarks according the remark ball flags in the SID column. No flightplan relevant remarks are shown on the SIDPTs. Those remarks are shown in the AOI. 3.8 MINIMUM RADAR VECTORING CHART (MRC) SPECIFIC The minimum radar vectoring chart provides a chart planview with radar sectors and their respective minimum altitudes. Airspaces: Terminal Areas (TMA) as well as Control Zones (CTR) are not provided on MRCs. Radar Sectors are shown with black lines. Minimum Radar Altitude as the lowest permissible altitude for radar vectoring If different values apply for e.g. different seasons the more restrictive value is put in brackets. Change: Editorial E 2005 LAT General Part 03-FEB-2005 E 2005 4. GROUND CHARTS Airport Ground Chart (AGC) Change: Editorial 43 LEGENDS AND TABLES LAT General Part LEGENDS AND TABLES 44 03-FEB-2005 Airport Parking Chart (APC) E 2005 LAT General Part 4.1 PLANVIEW IN GENERAL 1 Airport reference point 2 Apron with designator or name in italic font. 3 C Location of Flight Information Center. 4 Chart information is placed in the lower part of the chart, providing: S Local magnetic variation. S Chart orientation S Aerodrome elevation in ft and m The chart information may be moved for optimal placement. Change: Editorial 03-FEB-2005 Communication competence boundaries. E 2005 5 45 Communication frequencies Frequencies are shown in a green box. Frequencies operation hours are only shown if the FREQ is not operative 24h. Times are shown in UTC (for more information about World Local Times see the corresponding chapter). 6 Company Information Company derived information displayed on chart planviews is always shown in magenta. This can be textual and/or graphical information. De-icing holding position with known direction De-icing holding position with unknown direction 7 De-icing pad with frequency. 8 Displaced landing threshold 9 Helipad with or without designator. Jet Arresting Device/Net Barrier 10 11 Landing threshold given by the beginning of the paved surface. Navaids are shown as defined for terminal charts. 12 Obstacles and its elevation Single obstacle/group of obstacles Illuminated single obstacle/group of obstacles Tree symbols may be used instead of the standard obstacle symbols for trees up to 92ft. 13 Parking Stand: Push back position with known direction. Change: Editorial LEGENDS AND TABLES LAT General Part LEGENDS AND TABLES 46 03-FEB-2005 Parking position with known direction and either: self maneuvering maneuvering unknown E 2005 LAT General Part Parking position with unknown direction. 14 Runway designator 15 Runway direction (magnetic) 16 Runway end elevation 17 Runway grooved or similar: G, ungrooved: x 18 20 Runway length: Is provided as physical or total runway length in m. If not otherwise indicated in the chart planview this distance is identical with the TORA from physical RWY beginning. Runway visual range (RVR) measuring point. RVR measuring direction right RVR measuring direction left RVR measuring direction left and right. Runway width in m 21 Scalebar: Distances are shown in ft and m. 22 Stopbar 23 Stopbar Cat 2/3, if indicated in AIP. 24 Stopbar lighted, if indicated in AIP. 19 Stopway with distance in m. 25 Intersection Take-off position with direction indication and taxiway designator. Mandatory take-off position. 26 Take-off run available (TORA) from the intersection position. Change: Editorial 03-FEB-2005 47 E 2005 Taxiways are generally shown in grey. If a taxiway features either limitation of: – a width of less than 22m – a maximum wingspan of less than 50m – an all up weight of less than 120t it is presented with a brown shading. The exact restriction/limitation of the TWY can be drawn from the AOI. If a taxiway features a width of less than 15m it is symbolized by X or multiple X in brown color. Taxiway bridge Taxiway holding position Taxiway one way 27 28 Taxiway or runway closed: The symbol X or multiple X in a row. Taxiway with designator Tower Tower and Aerodrome Beacon (ABN) symbols. Windsock Work in progress Change: Editorial LEGENDS AND TABLES LAT General Part LEGENDS AND TABLES 4.2 48 03-FEB-2005 AIRPORT PARKING CHART SPECIFIC E 2005 LAT General Part 29 The APC generally only consists of the chart planview with parking stand coordinates on a separate page. Displaced threshold 30 Runway designator 31 Taxiway with centerline lights 32 Taxiway with guide line 4.3 LOW VISIBILITY CHART SPECIFIC The LVC generally only consists of the chart planview and a text part containing the taxi procedure text. Change: Editorial 03-FEB-2005 Low visibility taxi route E 2005 Low visibility reporting point. No entry Runway: red guard lights Taxiway (regular) Taxiway NA during LV OPS Change: Editorial 49 LEGENDS AND TABLES LAT General Part Table of Contents LAT Page I GENERAL INFORMATION General . . . . . . . . . . . . . . . . . . . . . . . . . . . . Header . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Colour codes and labeling . . . . . . . . . . . . . . . . . Charting definitions . . . . . . . . . . . . . . . . . . . . . . 1 1 3 RFC general . . . . . . . . . . . . . . . . . . . . . . . . General purpose . . . . . . . . . . . . . . . . . . . . . . . . . Cover panel . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Grid . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Variation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Chart frames . . . . . . . . . . . . . . . . . . . . . . . . . . . . Inset . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3 4 6 6 7 7 RFC content . . . . . . . . . . . . . . . . . . . . . . . . Airports . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Airspace boundaries . . . . . . . . . . . . . . . . . . . . . Airways . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Communications . . . . . . . . . . . . . . . . . . . . . . . . . Maximum authorized altitude MAA . . . . . . . . . Minimum enroute altitude MEA . . . . . . . . . . . . . Minimum grid altitude MGA . . . . . . . . . . . . . . . . Minimum terrain clearance altitude MTCA . . . Navaids . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Restricted airspace . . . . . . . . . . . . . . . . . . . . . . Terrain features . . . . . . . . . . . . . . . . . . . . . . . . . Waypoints . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8 8 9 9 10 10 10 11 12 12 13 13 Airport operational information AOI. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15 E 2005 Airport charts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16 Airport facility chart AFC . . . . . . . . . . . . . . . . . . 17 Standard instrument departure SID/ Standard instrument terminal arrival STAR . . . 18 Instrument approach chart IAC . . . . . . . . . . . . . 19 Airport ground chart AGC . . . . . . . . . . . . . . . . . 20 Airport parking chart APC . . . . . . . . . . . . . . . . . 21 Vertical profile . . . . . . . . . . . . . . . . . . . . . . . . . . . 27 Approach minima . . . . . . . . . . . . . . . . . . . . . . . . 29 Legends to the aerodrome list . . . . . . . . . . . . 29A Lights, visual aids, arresting systems. . . . Approach lighting systems ICAO . . . . . . . . . . . Approach lighting systems USA . . . . . . . . . . . . Runway end identification lights . . . . . . . . . . . . Visual approach slope indicator system . . . . . Change: NIL 31 32 32 33 23 SEP 04 LAT Page II Table of Contents Standard runway lighting system . . . . . . . . . . . 35 Visual ground aids . . . . . . . . . . . . . . . . . . . . . . . 36 Aeroplane nose-in parking systems . . . . . . . . . 39 Aeroplane radio control of aerodrome . . . . . . . . . . lighting system (ARCAL) . . . . . . . . . . . . . . . . . . 49 Conversion tables . . . . . . . . . . . . . . . . . . . . Conversion factors . . . . . . . . . . . . . . . . . . . . . . . Distances . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Weights . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Determination of actual altitude/ FL . . . . . . . . . Altimeter corrections during approach . . . . . . . Sunrise and sunset diagram . . . . . . . . . . . . . . . Climb and descent gradients . . . . . . . . . . . . . . . 50 50 52 53 54 55 57 23 SEP 04 Change: Editorial E 2005 World local times . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 59 General Information CHARTING DEFINITIONS Procedures Bearing/ Track/ Distance Flight patterns of low and high level holdings and procedures are presented by standard symbols -not to scale. For extension of holding areas (basic figures for rate of turns). ---> see RAR Bearings and tracks are magnetic, distances are given in nautical miles (nm). All figures defining a direction (0°-360°) are to be interpreted as tracks unless heading is specifically mentioned. Within Europe: for a one-way leg or direction towards a VOR, based on a radial from that VOR, the radial may be supplemented by its reciprocal value. In a holding pattern towards a VOR, only the reciprocal (inbound) value is given. Tracks in base turn procedures are indicated for CAT D aircraft. On IAC for aerodromes in Africa, Europa and Middle East areas are indicated with reference letter and remarks. In Scandinavia and Finland different tracks for CAT B aircraft will also be indicated. Distance between radio aids or intersections are given along the procedure line and up to a point on the final approach from where the distance can be obtained from the profile. Speed range of published procedures Published procedures on IAC are based on speed-range of category D aircraft, unless specific speed restrictions are indicated. Exceptions: CAT C circling minimum based on CAT C speed. CAT D circling minimum based on CAT D speed. Elevations/ altitudes/ obstructions Elevations and altitudes are given in feet above Mean Sea Level (MSL). High points and obstructions are shown according to official documents. When several points or obstructions are close to each other, the highest ones are selected if required to omit clutter in the chart. All official notes for high terrain and obstructions are given. Hours of operation E 2005 LAT Page 3 All hours of operation of radio aids, service hours of aerodromes, etc. are indicated in UTC (UTC, GMT, or Z not shown). In countries applying “daylight saving time” these times shall be adjusted during the relevant period according to List “World local times”. The symbol } indicates that during periods of Daylight Saving Time, effective hours will be one hour earlier than shown. Times given in local time are followed by letters LT. Change: Update If a racetrack approach procedure altitude or minimum sector altitude (MSA) is higher than the initial approach altitude, and if not otherwise instructed the descent is to be made within the holding procedure area. ---> see RAR Approach procedures indicated on the IAL are only authorized if corresponding minima are given. RFC GENERAL GENERAL PURPOSE The RFC are published as: – High Level – Low Level High Level and Low Level charts are produced on separate sheets and cover the same area and be presented in the same scale. Whenever possible Lido FlightNav will provide High and Low Level Information together with RNAV Airways within one chart. Front and reverse side of a chart should always consists of the same genre and with the same scale, except for extensions or insets (blowups of densed areas). Identification and Number The coverage is devided into regions, indicated by color and RFC Number. Low Level Charts are numbered with the pre-fix zero. EUR Europe, Mediterranean 1-9 AFI Africa 20 - 29 ATL NAM CAR SAM MES PAC Atlantic North America / Canada Caribbean South America Middle East/ Asia (incl. Former USSR) Pacific 40 - 49 50 - 59 60 - 69 70 - 79 80 - 89 90 - 99 Each RFC code is completed by: – Chart number – Level Type 11 MAR 04 LAT General Information Page 4 COVER PANEL 1 2 3 Eff 17 OCT2002 4 5 6 7 1 2 3 4 5 6 7 8 9 9 Chart date = Date when the chart revision is effective. Effective date = If effectiv date is different then chart date. Logo of issuing company. RFC chart number. Chart type indication (eg. HL high level, LL low level, HL/LL combined) including scale in inch equals nautical miles. Region and area indication. Indicating which side of the RFC below mentioned information can be found. Coverage diagram with chart coverage shaded. Lambert conformal projection with two standard parallels. Copyright. 11 MAR 04 Change: NIL E 2005 8 General Information LAT Page 5 10 11 12 13 Limits of designated airspace and airways VHF / HF frequencie coverage IFR cruising levels covering all RFC areas Supplementary information E 2005 10 11 12 13 Change: NIL 17 JUL 03 LAT Page 6 General Information GRID Graticule of meridians and parallels with latitude and longitude values outside and close to chart border. Graduation of ticks spaced at 5 minutes intervals. At high latitudes and in charts with small scale a bigger spacing may be used. Latitude and longitude figures are placed outside and close to the chart borders. VARIATION E 2005 - Variation line 5E 17 JUL 03 Change: Update General Information LAT Page 7 CHART FRAMES – Chart border – Chart number (placed on the left side of each double panel) – Chart border measurements – Scale Bar and Statement (placed on the upper left side of the chart E 2005 INSET Change: NIL 17 JUL 03 LAT General Information Page 8 RFC CONTENT AIRPORTS Aerodrome with city name and 4-letter ICAO code. Two or more aerodromes for the same city, the city name (once) followed by 4-letter ICAO code. HOBART D 112.7 HB S42 50.8 E147 31.9 For each represented airport the designator of the main VHF radio aid (VOR or VORDME only) serving the airport is shown. h YMHB a AIRSPACE BOUNDARIES ASMARA FIR HHAA The regions name in English is indicated together with the corresponding ICAO location indicator FIR / UIR boundary TMA / CTA / CTR / TCA / OCA boundaries ADIZ RFC frames Chart frame E 2005 RVSM airspace If RVSM coincides with FIR boundary, only FIR boundary will be shown. Indication of RVSM will be written in grey letters. 17 JUL 03 Change: Update LAT General Information Page 9 AIRWAYS High level airways are indicated in black colours Low level airways are indicated in blue colours The airway name is placed in the centerline and in the middle of the airway UN999 Directional airways (one-way) are marked with an arrow at the airway name V888 A1B1 A1/B7/C10/G450 093 A500 267 Track value ”From” / “To” is placed at the beginning of the first airway segment or at the enroute Navaid. Radial / bearing changes at reporting points are shown if > 3 degrees. Total distance between compulsory reporting points. No track change. 150 True track values are shown with the letter T 031T 100 Combined airway names are published as follows 218 118 N999 Distance between compulsory and non compulsary reporting point including total distance Low level airways UN999/ N999 High low airways combined COMMUNICATIONS Frequencies are indicated by 6 figures BRISBAINE CENTER 128.600 AIR-to-AIR pilot FREQ Pilot FREQ ASIA PACIFIC Region 123.450 ATHENS CONTROL 1) 124.475 2) 132.000 1) below FL 245 2) above FL 245 E 2005 Contact Tripoli 10 min prior to crossing on 136.150, 5517 11300 Change: NIL 05 AUG 04 LAT Page 10 General Information MAXIMUM AUTHORIZED ALTITUDE (MAA) Definition The MAA is the highest usable enroute cruising level established by the appropriate authorities along the published routes. Indication The MAA is indicated when lower than the upper limit of the airway, or the upper limit of the designated airspace. Maximum level indicated is FL 400. MAA in hundred feet units The MAA always assumes the colour of the airway effected MINIMUM ENROUTE ALTITUDE (MEA) Definition MEA is the lowest usable enroute cruising altitude. Indication The MEA, if published by state, is always indicated. Exception: Will not be represented if the same as the lower limit of the designated airspace in that specific area. The value is shown in hundred feet without the prefix FL. MEA is shown as published, either as flight level without the prefix “FL” or in feet MINIMUM GRID ALTITUDE (MGA) Definition MGA is the lowest safe altitude to be flown off-track. Determination The MGA applies within the area of two neighbouring latitude and longitude lines. The MGA is taken from the ONC Charts provided by FAA. These source is recommended by ICAO for the determination of heights on Radio Facility Charts. Wherever no value available at the ONC chart, MGA is calculated by Lido, based on a digital terrain model without manmade Obstructions. Calculation: Elevation of the highest point within the respective grid area. The MGA is calculated by adding an increment of 2000ft to the highest terrain elevation within the respective grid area. The resulting value is adjusted to the nearest 100ft. Exception: No MGA values for grid areas over sea without land (island or part of mainland). E 2005 Lowest indicated MGA is 2000ft. 05 AUG 04 Change: MGA General Information LAT Page 11 Altitudes 10 000ft and above are displayed with an intense red colour. MINIMUM TERRAIN CLEARANCE ALTITUDE (MTCA) Definition An area of 10nm on each side of an airway centerline and around a Navaid / waypoint where a MTCA is provided. This altitude is calculated automatically with two indipendant terrain databases without man-made obstructions. The safety buffer provided by Lido is 2000 ft above the highest terrain highspot, rounded up to the hundred. This value is shown from 7000 ft up. Determination The elevation of the highest terrain highspot within the protected area determines the MTCA value. Only values at and above 7000 feet are shown on chart. Rounding values 5000 ft or more: round to next higher 100, and add 2000 ft. E 2005 The colour of the MTCA value is shown in red colour. Change: New 03 APR 03 LAT General Information Page 12 NAVAIDS Radio facility box. h Mc Adoo 245 MDO S32 45.3 E151 31.9 WEST MAITLAND 114.6 WME 224 h h Hazardous Inflight Weather Advisory Service (HIWAS). NDB with name, frequency and identification VOR / NDB collocated. Same identification. S32 45.3 E151 31.9 Casino 111.1 CAS 332 h VOR / NDB collocated. Same identification. S32 45.3 E151 31.9 h VOR / NDB not collocated. Same identification. Cecil 115.5 CEL 268 CEL h WAGGA D115.0 WG h VOR/DME collocated with name, frequency paired and same identification. h VOR/DME collocated, frequency paired and same identification. S35 09.0E147 28.1 Nantucket D112.7 ACK S32 45.3 E151 31.9 VOR / DME or VOR and NDB collocated. Different identification. Hehlingen D117.3 HLZ 403.5 HLI S32 45.3 E151 31.9 Clayton 115.7 CN S32 45.3 E151 31.9 116.0 PSO h h VOR with name, frequency and identification. Name omitted when identical to adjacent aerodrome. RESTRICTED AIRSPACE P12 R 102 Prohibited area. Restricted area. Danger area. D5 Military area. E 2005 M 53 03 APR 03 Change: New LAT General Information Page 13 TERRAIN FEATURES – Ocean, Sea, Important lakes are shown in blue colour. – Important Mountain range is shown in a grey topography pattern. WAYPOINTS Compulsory reporting point P P Non compulsory reporting point All reporting points adapt the colour of the airspace they are in (high = black, low = blue) MARLN S34 02.1 E152 04.0 P N774 Restrictions on reporting point Waypoint valid for N774 non compulsory Reporting point GIRSA only on UM321 The next intersection outside the frame of the chart is indicated by the five letter code placed in the border. E 2005 Met report required Change: New 10 APR 03 LAT Page 14 General Information E 2005 Intentionally left blank 10 APR 03 Change: New C:\Minima_Project\Runway_Images\GBY D.BMP 4 10 9 11 15 5 Change: Update RVR (Runway Visual Range) (Convertible) RVR, reported RVR or MET visibility: 24 Alternate LFML Circling T: 23 LFSB C: 800-V2.4 EDDS D: 800-V3.6 T LSGG Circling minima 14 OA1,N N OA2,N – 84 116 184 363 Alternate Disstatus tance = RVR value which may be: --- a reported RVR, or --- a converted visibility. R0.3 = RVR must be a reported RVR value. R6000f= Reported RVR value in feet. V1.6 = Value must be a reported MET visibility. No conversion according conversion table allowed. V1.25s = Visibility in Statute Miles. 18 Approach procedures and Landing minima (except Circling minima) are according to TERPS (Terminal Instrument Procedures). 19 Radar Termination Range (RTR) and distance from RTR to landing threshold. 20 Approach procedure designator. Slash (/) means VOR or NDB approach procedure. 21 JAR meteorological minima:Required ceiling (CLG) 22 All bearings are orientated towards true north. 23 All Circling minima are according to TERPS. 24 Specific minima is according to TERPS. 0.55 460--- 1.6 400--- V1.5 19 12 Approach facility leading down to circling minimum. OR: Approach with difference between final track and runway track 13 FMS equipped ACFT permission with 1 NDB only 14 Explanations; see ADR Dest. Alternate--Supplementary information para 1.2 LEGENDS. 15 Minima for aircraft with wingspan of 65 meters and more, or vertical distance between the flight path of the wheels and the glide path antenna of 7 meters and more 16 ATIS FREQ for standard procedures and ARR only. 17 JAR meteorological minima: DH or MDH--- RVR c300---1.4 7c200---0.55 SRA RTR 2NM 13 c350--- 1.2 350--- 1.2 400--- 1.5 210--- 0.8 220--- 0.8 220--- 0.6 21 ETOPS 2 ETOPS 1 LLZ VOR --- 191 NDB 12 NDB KE+F HL/HL ILS C 17 ILS D ILS ACFT>65/7 Approach type minima ILS+DME PrefA 600---V3.2 HL/HL 32 3600 Runway information 400--- 2.0 14 8 400--- 2.0 3600 G 0---R75 0 (DH)---R75 20 17 ILS SIDEST.14 1660--- V10.0 6 ILS CAT 3B VOR/NDB NDB ILS 3% 3 Aerodrome opening hours Fuel restrictions MISAP minimum climb gradient Lowest possible ILS CAT 3 minima. (DH): application of DH required. This CAT 3 minima shows the lowest possible system minima depending on state and aerodrome requirement. The pilot must always use the higher of this system minima of his aircraft type (according to LAT, Company Information, CAT 3 minima). AVRO: If for CAT 3A the RVR of 150m can not be applied then a separate CAT 3A minima with 200m will be published. 5 ETOPS---minima (explanation on reverse side) 6 Sidestep approach ILS16 with landing on RWY 14 7 State preflight alternate minima 8 Runway designator 9 Approach/runway light facility 10 Runway grooved 11 LDA 1 2 3 4 TN 22 AD: 1 Non SKED PPR 72HR Fuel: MON--- FRI 08--- 12 2 SAT 13--- 20 SUN 08--- 12 else O/R TWR 118.300 TERPS 18 GBYD -- BJL (10˚W) BANJUL YUNDUM INTL GAMBIA ATIS 119.200 16 LEGENDS TO THE AERODROME LIST Aerodrome information Runway Approach type minima layout E 2005 General Information Page 29A LAT 17 MAR 05 LAT General Information Diese Seite wird von Swiss geliefert! Page 30A 19 FEB 04 Change: NIL Change: Update 13 7 8 9 10 11 12 5 6 1 2 3 4 ETOPS 2 ETOPS 1 10 c200---0.55 c300---1.4 600--- V3.2 1660--- 10.0 0---R75 HL/HL 0(DH)---R75 4 400--- 2.0 14 8 400--- 2.0 3600 G 9 11 HL/HL 32 3600 Runway information 15 18 14 350--- 1.2 400--- 1.5 c350 --- 1.2 210--- 0.8 220--- 0.8 220--- 0.6 RVR (Runway Visual Range) (Convertible) RVR, reported RVR or MET visibility: 0.55 = RVR value which may be: --- a reported RVR, or --- a converted visibility. R0.3 = RVR must be a reported RVR value. R6000f= Reported RVR value in feet. Circling T: 21 C: 800/V3.7 D: 800/V4.6 T 22 Circling minima = Value must be a reported MET visibility. No conversion according conversion table allowed. V1.25s = Visibility in Statute Miles. 17 Approach procedures and Landing minima (except Circling minima) are according to TERPS (Terminal Instrument Procedures). 18 Radar Termination Range (RTR) and distance from RTR to landing threshold. 19 Approach procedure designator. Slash (/) means VOR or NDB approach procedure. 20 All bearings are orientated towards true north. 21 All Circling minima are according to TERPS. 22 Specific minima is according to TERPS. V1.6 SRA RTR 2NM 460---1.6 VOR --- 191 NDB 12 LLZ ILS C 16 ILS D ILS ACFT>65/7 Approach type minima 14 JAR meteorological minima: Required ceiling (CLG) 15 Minima for aircraft with wingspan of 65 meters and more, or vertical distance between the flight path of the wheels and the glide path antenna of 7 meters and more. 16 JAR meteorological minima: DH or MDH--- RVR 5 ILS+DME PrefA 7 13 6 ILS SIDEST.14 ILS CAT 3B VOR/NDB 19 NDB 16 ILS 3% 3 Approach type minima Aerodrome opening hours Fuel restrictions MISAP minimum climb gradient Lowest possible ILS CAT3 weather minima values ETOPS--- minima Sidestep approach ILS16 with landing on RWY 14 State preflight alternate minima Runway designator Approach/runway light facility Runway grooved LDA Approach facility leading down to circling minimum. OR: Approach with difference between final track and runway track Lowest possible ILS CAT3 weather minima with required DH Non SKED 1 PPR 72HR Fuel: MON--- FRI 08--- 12 13--- 20 2 SAT SUN 08--- 12 else O/R C:\Minima_Project\Runway_Images\GBYD. BMP GBYD -- BJL (10˚W) BANJUL YUNDUM INTL GAMBIA ATIS NIL TWR 118.30 TERPS 17 TN 20 AD: Runway layout Aerodrome information LEGENDS TO THE AERODROME LIST AND PALM/SMART COMPANION E 2005 General Information Page 29A LAT 17 MAR 05 LAT Page 30A General Information 17 MAR 05 E 2005 Intentionally left blank LAT General Information Page 31 LIGHTS, VISUAL AIDS, ARRESTING SYSTEMS APPROACH LIGHTING SYSTEMS ICAO Approach Lighting Systems (APL) with identification letter as indicated on Airport Facility Chart AFC. Standard length of APL are 900 meters, deviations are indicated on AFC. ICAO STANDARD CAT 2/3 C DISTANCE CODED CENTRE (CALVERT) LINE 150m 300m 300m 150m Runway 300m 150m Runway B Runway A ICAO STANDARD CAT 2/3 Sequenced flashing lights - EFAS (except Canada) 5 lights in a row D BARRETTE CENTRE LINE E Runway SINGLE ROW 300m Runway with cross or roll guidance bars, F PARALLEL ROW Runway without cross or roll guidance bars, Sequenced flashing lights - EFAS (except Canada) 5 lights in a row E 2005 If no ICAO standard is applicable the APL is named ICAO-X. Change: Update 25 SEP 03 LAT General Information Page 32 APPROACH LIGHTING SYSTEM USA Including US AFB and countries with US approach light standard. Approach Lighting Systems (APL) with identification letter as indicated on Airport Facility Chart AFC. Standard length of APL is 730m, except type K and L, deviations are indicated on AFC. 300m 300m 150m BARRETTE CENTRE LINE CAT 2 Runway Sequenced flashing lights - EFAS - SINGLE ROW (430m) 5 lights in a row Runway 5 lights in a row Sequenced flashing lights - RAIL - 5 lights in a row L SINGLE ROW (460m) Runway 300m 430m Runway SINGLE ROW Sequenced flashing lights - EFAS - 5 lights in a row K I 300m H Runway ICAO STANDARD CAT 2/3 460m G Sequenced flashing lights - RAIL - Omnidirectional sequenced flashing lights - EFAS - RUNWAY END IDENTIFICATION LIGHTS Runway End Identification Lights (REIL) consist of a pair of synchronized flashing lights, one on each side of the runway threshold facing the approach area. Runway 25 SEP 03 Change: Update E 2005 REIL LAT General Information Page 33 VISUAL APPROACH SLOPE INDICATOR SYSTEM 2-BAR VASIS and AVASIS VASIS are called AVASIS if consisting of less components (lights) than standard or if installed on only one side of the runway. Can be used down to 200ft by aeroplanes having pilot’s eye-to-wheel heights of approximately 4.5m or less e.g. A320, MD80, DC9, 737, F100, F28, F50. VASIS must not be used for positive indication below: 300ft by DC10, 767, 757 and A330; 500ft by MD11, B747 and A310. ON GLIDE SLOPE LOW HIGH Examples of VASIS and AVASIS designations on LC VASIS 3.00 (written sometimes as 2 ---B VASIS 3.00) AVASIS 3.00L AVASIS 3.00 3-BAR VASIS and AVASIS 3-BAR VASIS are called 3-BAR AVASIS if installed on only one side of runway. 3-BAR VASIS resp. 3-BAR AVASIS shall consist of VASIS resp. AVASIS plus the installation of a pair of additional upwind wing bars. Provided for aeroplanes having a pilot’s eye-to-wheel heights exceeding approximately 4.5m but not more than approximately 16m e.g. B747, MD11, DC10, 767, 757, A330, A300, A310. 3-BAR VASIS must not be used for positive indication below 200ft. Bars crossed out in drawings below should be ignored. B747-DC10-MD11-B767-B757-A330-A300-A310 LOW ON GLIDE SLOPE HIGH A320--- MD80--- DC9--- 737--- F100--- F28--- F50 LOW ON GLIDE SLOPE HIGH Examples of 3-BAR VASIS and 3-BAR AVASIS designations on LC E 2005 3 ---B VASIS 2.75/ 3.25 Change: New 3 ---B AVASIS 2.50/ 3.00R 3 ---B AVASIS 2.75/ 2.75L 03 APR 03 LAT General Information Page 34 T ---VASIS and AT ---VASIS T-VASIS are called AT-VASIS if installed on only one side of the runway. T-VASIS may be used by all aeroplanes down to 200ft. VERY LOW LO W LO W HIGH LO W A320, MD80, DC9, B737, F100, F28, F50 = HIGH A320, MD80, DC9, B737, F100, F28, F50 = HIGH A320, MD80, DC9, B737, F100, F28, F50 = On Glide Slope B747, MD11, DC10, B767, B757, A330, A300, A310 = On Glide Slope B747, MD11, DC10, B767, B757, A330, A300, A310 = LOW B747, MD11, DC10, B767, B757, A330, A300, A310 = LOW PAPI and APAPI (Precision Approach Path Indicator) PAPI are called APAPI if consisting of two lights only. PAPI are normally installed on the left side of the runway. PAPI may be used by all aeroplanes down to 200ft. 3 2 SLIGHTLY LOW (Approximately 0.30°) 4 LOW (More than 0.50°) 5 Change: New E 2005 1 03 APR 03 ON GLIDE SLOPE SLIGHTLY HIGH (Approximately 0.30°) HIGH (More than 0.50°) LAT General Information Page 35 STANDARD RUNWAY LIGHTING SYSTEMS Runway End Lights (REL) 600m 600m 300m Intermediate holding position lights (unidirectional) Taxiway egde Lights (TWL) 7.5 or 15 or 30m Taxiway Centre Line Lights (TWY-CLL) Taxiway stop bar lights (unidirectional) ILS critical sensitive area (bi-directional lights) maximum 3m 30m or Touchdown Zone Lights (TDL) 900m 60m Runway Edge Lights (RWL) 30m or 60m Runway Centre Line Lights (RWY-CLL) Displaced Threshold Lights (THL) E 2005 or one-third of runway length, whichever is less Change: Update Approach direction 02 DEC 04 LAT General Information Page 36 VISUAL GROUND AIDS RWY Designation Markings 20 Standard runway designation. Runway centre line. Runway threshold. 20 L Runway designation for parallel runway. Runway centre line. Runway threshold. 20 Alternative runway designation for runway width 45m and greater. Runway centre line. Runway threshold. Threshold markings The number of stripes are in accordance with the RWY width: Runway width Number of stripes 18m 23m 30m 45m 60m 4 6 8 12 16 Displaced THR and restricted use area markings Temporarily displaced landing threshold. Temporarily or permanently displaced landing threshold. Temporarily or permanently closed runway or part of runway (normally closed for use by all aeroplanes). Temporarily or permanently closed taxiway or part of taxiway (normally closed for use by all aeroplanes). 02 DEC 04 Change: NIL E 2005 Undershoot or overrun area (not suitable for normal use by aeroplanes). LAT General Information Page 37 Runway fixed distance / aiming point markings a 20 a = DIST from THR to beginning of marking LDA > 1200m a = 300m LDA ≥ 2400m a = 400m Runway touchdown zone markings with distance coding 150m 150m 150m 150m 150m 150m 20 Taxi holding position markings (ILS sensitive area) a) Where a taxiway intersects a non-instrument, non-precision approach, a precision approach Category I or take-off runway; or where a single taxi-holding position is provided at an intersection of a taxiway and a Category II / III runway. b) Category II or III taxi-holding position marking where a closer taxi-holding position to the runway is available. E 2005 b) Category II or III Change: Update a) Category I 25 SEP 03 LAT Page 38 General Information Information signs Information signs shall include: direction signs, location signs, destination signs, runway exit signs, runway vacated signs and intersection take-off signs. Location / TWY Direction Location / Runway Vacated Runway Exit TWY Direction / Location / TWY Direction / TWY Direction Intersection Take-Off Mandatory Instruction signs A mandatory instruction sign shall be provided to identify a location beyond which an aircraft taxiing or vehicle shall not proceed unless authorized by the aerodrome control tower. Mandatory instruction signs shall include runway designation signs, category I, II or III holding position signs, runway-holding position signs, road-holding position signs and NO ENTRY signs. Sign Right Side of TWY Sign Left Side of TWY Runway-Holding Position Location / Runway Designation Runway Designation / Location Runway Designation / Category II Holding Position 25 SEP 03 Change: NIL E 2005 No Entry LAT General Information Page 39 AEROPLANE NOSE-IN PARKING SYSTEMS Safegate Docking System DISPLAY BOARD B A 7 4 7 S TO P H G F D E C B Form of display Indication for A Alphanumerical Aeroplane type (preselected). Final stop confirmation. B GREEN bottom lights Permission to enter gate. C GREEN bar / aeroplane symbol Azimuth guidance (parallax). D Pair of GREEN lights Stop position reference. E Vertical row of GREEN lights Closing rate to stop position. Each light corresponds to an inductive loop spaced at 1 meter intervals. F YELLOW lights Nosegear 1 meter before stop position. G Pairs of RED lights Stop position reached. H Alphanumerical Stop command. E 2005 Routine docking manoeuvre 1. Line-up to center aeroplane symbol with GREEN reference bar. 2. Check aeroplane type displayed (flashing). 3. Check GREEN bottom lights (flashing). 4. When nosegear passes over first sensor, aeroplane type display and GREEN bottom lights will both change from flashing to steady. 5. GREEN closing rate lights will move upwards in relation to actual aeroplane speed. 6. At 1 meter before the stop position, YELLOW lights will illuminate. 7. Reaching the stop position, all four RED lights will illuminate concurrent with the displayed command “STOP”. 8. If correctly positioned, “OK!” will be displayed. Beyond 1 meter of the nominal stop position “TOO FAR” will be displayed. in the system after initiation by the nose wheel), hold short immediately and ask for marshaller. If safegate not illuminated: Hold before entering and advise ground control to switch the lights on. Emergency stop: All 4 RED stop position lights and “STOP” at full brilliance will flash. Warning: If wrong aeroplane type displayed, or if closing rate lights do not move upwards when nosewheel enters the sensor area (orange markings), or when “ERR+STOP” is displayed (error Change: New 03 APR 03 LAT Page 40 General Information Aeroplane Parking and Information System APIS DISPLAY BOARD Aeroplane type (preselected) and stop position indication --- OK --- TOO FAR Stop command Closing rate “THERMOMETER“ Showing 0--- 14m to stop position On centreline INOGON CENTRELINE GUIDANCE Warning: Final 15m slow taxiing to allow correct “THERMOMETER” indication. 03 APR 03 Steer left Change: New E 2005 Steer right LAT General Information Page 41 Docking Guidance System SAFEDOCK DISPLAY BOARD Aeroplane type (preselected) indication: – STOP – TOO FAR – STOP ID FAIL The floating yellow arrows indicate that the system is activated and “Ready to enter” Watch the red arrow in relation to the green centre line indicator for correct azimuth guidance. Green centre line Follow the Lead-in line. When the two vertical closing rate fields turn yellow the aeroplane is caught by the laser and being identified. When the aeroplane is 16m from the stop position, the closing rate starts indicating distance to go by turning off one pair of LEDs for each half meter the aeroplane advances into the gate. During approach into the gate, the aeroplane will be identified. If, for any reason, identification is not made 12m before the stop position, the system will show “ STOP“ and “ ID FAIL “ and the azimuth guidance field will turn red. The aeroplane will now be identified, and docking can proceed. E 2005 When the correct stop position is reached the display will show “STOP“ and the azimuth field will turn red. All yellow closing rate LED’s will be switched off. When the aeroplane is correctly parked “OK“ will be displayed after a few seconds. If the aeroplane has overshot the stop position “TOO FAR“ will be displayed. Change: New 03 APR 03 LAT General Information Page 42 RLG automated system for visual docking RLG stand for: Robert L. Gugenmeier, the inventor of the system. The system is in a metal enclosure housing attached to the terminal building precisely lined up perpendicular to and 21 inches left of the taxi line of the gate area, aligned for interpretation by the pilot in the left hand seat. Aeroplane type indicator Stopping guidance 747 10 737 GREEN (start) 8 SP 300 AMBER (caution) 727 707 11 RED (stop) Centreline guidance RED neon numbers GREEN neon tube ( centreline ) YELLOW neon tube ( off left or right ) FRONT Docking procedure Prior to entering bay, confirm aeroplane type displayed on the aeroplane type indicator. Discontinue docking when wrong aeroplane type is shown. Taxi into bay at minimum speed. Interpret vertical neon lights for centerline guidance as follows: GREEN GREEN YELLOW or RED On the left of the centreline GREEN YELLOW or RED On the centreline On the right of the centreline 03 APR 03 Change: New E 2005 Discontinue docking when lights go off. LAT General Information Page 43 INOGON airpark system Stop Beacon STOP LINE MD11 DC10 B747 MD80 DC9 Centre line Beacon The beacon is equipped with a moire screen and lighting designated for the guidance of aeroplanes on the ground. The beacon observed by the pilot indicates, in the form of arrows, the direction in which he should steer and when the correct stop position is reached. Centre Line Guidance Steer right On line YELLOW Steer left Centre line To guide the pilot along a line without any requirement for exact stop positioning (used on open ramps). BLA CK One stop For exact positioning of one type of aeroplane or approximate positioning of a group of aeroplanes (used for docking or on open ramps). Stop Line Guidance Slow forward E 2005 Change: NIL BLACK STOP LINE STOP LINE YELLOW Correct stop position STOP LINE Forward Multi stop For exact positioning of a limited number of aeroplane or approximate positioning of groups of aeroplanes (used when docking). Type of aeroplane/ stop line will be selected at the gate. 17 JUL 03 LAT General Information Page 44 Stand entry guidance system The system consists of a centreline guidance named AGNIS (Azimuth Guidance for Nose-in Stand) and a stop element named Side Marker Board or Stop Element Marker Board, Parallax Aeroplane Parking Aid or Stop Light System. Azimuth Guidance for Nose-In Stand (AGNIS) Mounted on the face of the pier and aligned for the pilot sitting in the left-hand seat. It emits red and/or green beams through two parallel vertical slots. RED GREEN LEFT of centerline, turn towards GREEN GREEN GREEN GREEN RED RIGHT of centerline, turn towards GREEN On centerline Side Marker Board It consists of a steel frame on the pier side of the nose loader with vertical slats. The edge of each slat is BLACK with a WHITE segment, the side facing the taxiway is GREEN and the side facing the pier is RED. Each slat bears an aeroplane type tab. The pilot entering the stand will see the GREEN side. In correct STOP position the BLACK egde only (with WHITE segment). Passing the STOP position the RED side of the slat will begin to appear. At certain gates, the DC9/MD80 - with pilot’s position abeam the air jetty - will not be served by SMB. Instead the correct stopping position will be given by a STOP MARK on the air jetty itself. B747 FRAME GREEN AIR JETTY PIER WHITE DC9 AEROPLANE IDENTIFICATION TAB AGNIS RED SIDE MARKER BOARD WHITE WHITE BLACK BLACK GREEN B747 WHITE WHITE BLACK 17 JUL 03 CONTINUE TAXIING STOP Change: Update E 2005 Air jetty in retracted position LAT General Information Page 45 Stop Element Marker Board The aeroplane is stopped at the correct position by means of the Stop Element. When the tubular light, visible through the horizontal slot in the marker board, registers in line with the appropriate vertical reference mark, the aeroplane has reached the correct stopping position. WARNING Be sure to select the correct vertical reference mark corresponding to your type of aeroplane. Marker board layouts are different for the various nose-in parking positions. Typical examples of Stop Element Marker Board B747 MD11 DC10 A310 B747 other types All types: continue taxiing. SIGHTING SLOT B747 other types max. B767 B747 B767 other types B747 B767 MD11 DC10 A310 B747 other types MD11 DC10 A310 B767 other types Other types: stop. B747, MD11, DC10, A310, B767: continue taxiing. MD11, DC10, A310: stop. B747, B767: continue taxiing. B747, B767: stop. B747 B747 B747 MD80 DC9 All types: continue taxiing. MD11 DC10 A310 other types max. B767 MD80 DC9 DC9, MD80: stop. Other types: continue taxiing. SIGHTING SLOT CENTERLINE GUIDANCE ELEMENT LIGHT TUBE other types max. B767 other types max. B767 MD80 DC9 MD80 DC9 Other types max. B767: stop. B747: continue taxiing. B747: stop. LIGHT TUBE STOP ELEMENT MARKER BOARD E 2005 YELLOW CENTERLINE Change: New 03 APR 03 LAT General Information Page 46 Parallax Aeroplane Parking Aid The Parallax Aeroplane Parking Aid is provided on aprons where apron-drive air jetties (Aeroways) are installed. It indicates the correct forward stopping position. It consists of a reference board with a horizontal slot running across its center. This board is supported on a frame projecting 5ft from the face of the pier. Behind it is a 5ft weatherproof white fluorescent tube mounted vertically and slightly to the right of the board. FACE PIER OF TUBE MARKER BOARD Accuracy of this system is very much dependent upon the accuracy of stand centerline. It has been set up for interpretation by the pilot occupying the left-hand position. Marker board and tube B747 B757 B767 WHITE MARKER SLOT THROUGH WHICH FLUORESCENT TUBE TUBE IS SIGHTED WHITE MARKER MD11 A310 B707 Position of the fluorescent tube with respect to the WHITE marker when aeroplane is correctly parked. 03 APR 03 Change: New E 2005 Taxiing into the stand, pilot will see the fluorescent tube appear to move along the slot towards the reference marks. Correct stopping position is reached when the tubular light registers in line with the appropriate vertical reference mark. LAT General Information Page 47 Stop Light System Two-colour light indicator Signification of light signals Steady RED Not yet cleared to enter bay Steady or flashing GREEN Cleared to enter bay Alternating GREEN/RED Aeroplane should reduce speed and prepare to stop Steady RED Aeroplane reaches stopping point Note: Lights RED or lights not visible or Stop aeroplane GREEN light not visible A stopping light comprises a single luminous slot which changes progressively from GREEN to RED as the aeroplane proceeds towards the desired stopping position. When the stopping position is reached the separation between RED and GREEN is situated opposite the index corresponding to the type of aeroplane. GREEN RED Burroughs Optical Lens Docking System Module indicating the centreline Position stop module Stop bar (moving downwards) Fixed centreline indicator 747 Left / right indicator Position stop cue (fixed) Example: Docking B747 747 E 2005 Align lower vertical bar with upper datum bar. Horizontal stop cue bar comes into view. Change: New Type indication 747 Maintain centreline alignment, horizontal bar moves down towards 747. 747 Horizontal bar in line with 747 stop cue perfect alignment. 03 APR 03 LAT Page 48 General Information Side Marker Light Within Australia, the Side Marker Light is used in connection with Upper Centerline Guidance Light (B747 types only). The Side Marker Light provides the pilots of B747 aeroplanes with a longitudinal stopping position. It is mounted at a height of 9 meters. As the pilot approaches the aerobridge, he will observe the following sequence of signals from the Side Marker Light. DULL GREEN A preliminary “dull” GREEN light can be seen through the arrow-shaped aperture at the front of the Side Marker Light unit. This indicates the location of the signal. The initial indication may be seen at an early stage of the docking approach, and the intensity gradually increases as the aeroplane proceeds. At 3.7m from the stopping position, a more intense and definite GREEN signal begins to replace the preliminary indication. When this signal becomes a full arrow, the pilot is approximately 1.8m from the stopping position. INTENSE GREEN As the pilot approaches the stopping position, the arrowhead reduces in size, thus providing rate-of-closure information. GREEN By the time the stopping position is reached, the arrowhead has completely diminished, and two WHITE bars appear, indicating that the correct STOPPING position has been reached. WHITE B747 STOP If the pilot proceeds further, a single RED bar will replace the two WHITE ones, indicating that he has overshot and must stop immediately. 03 APR 03 Change: New E 2005 RED General Information AEROPLANE RADIO CONTROL OF AERODROME LIGHTING SYSTEM (ARCAL) With the ARCAL system the pilot can switch-on approach, runway (including VASIS, REIL etc.) and other aerodrome lightings. System available called “Aircraft Radio Control of Aerodrome Lighting (ARCAL)”, “Pilot Control of Airport Lighting” and “Remote Switching of runway lights”. In Route Manual all systems are named with heading ARCAL. Heading ARCAL is located, if available, on landing chart in the left information area. ARCAL type J (Canada only) To operate all aerodrome lighting for duration of approximately 15min, key mike 5 times within 5sec. The timing cycle may be restarted at any time by repeating the keying sequence. Note: Some systems will indicate when the duration period is over by flashing once., then remaining on for a further 2min before extinguishing completely. Other systems offer no indication that the period is ending. The control system may operate 24hr or between SS and SR. LAT Page 49 ARCAL type L To operate all aerodrome lighting for a duration of approximately 15min, click microphone button as indicated on landing chart. If required the procedure may be repeated for a further 15min period. Example of ARCAL type L: ARCAL: 118.10 type L (RWY 02/20 4 clicks within 4sec). ARCAL type PAL (Australia only) Australian type of ARCAL is called PAL (Pilot Activated Lighting) with following activation procedure: On departure: Before taxi, resp. on arrival: Within 15nm of aerodrome. 1. Transmit pulse must be between 1 and 5sec. 2. 3 pulses must be transmitted within 25sec. Ensure that the 3rd pulse ends before the 25th sec. 3. Break between transmissions can be more or less than 1sec. PAL will remain illuminated for 30-60min. The wind indicator light will flash continuously during the last 10min to warn users that the lights are about to extinguish. To maintain continuity of lighting, repeat the activation sequence. Example of ARCAL type PAL: ARCAL: 122.80 type PAL Example of ARCAL type J: ARCAL: 122.80 type J ARCAL type K (Canada and USA) To operate all aerodrome lighting for a duration of approximately 15min, key mike 7 times initially within 5sec. This will ensure all lights are on maximum intensity. The intensity may be adjusted up or down to any one of three settings by keying the mike: – 7 times within 5sec for high intensity setting. – 5 times within 5sec for medium intensity setting. – 3 times within 5sec for low intensity setting. The timing cycle may be restarted at any time by repeating the initial key sequence. E 2005 Examples of ARCAL type K: ARCAL: 122.80 type K ARCAL: 122.80 type K (RWY 18/36) Change: NIL 06 NOV 03 LAT General Information Page 50 CONVERSION TABLES CONVERSION FACTORS Into To convert Distances Metres Feet Yards Inches Millimetres Kilometres Statute Miles Nautical Miles Liquid Litres US Gallons Multiply by Feet Yards Metres Yards Feet Metres 3.280833 1.093611 0.3048006 0.3333333 3 0.9144018 Millimetres Inches Statute Miles Nautical Miles Kilometres Nautical Miles Statute Miles Kilometres 25.40 0.03937 0.62137 0.54000 1.609347 0.869047 1.150685 1.851852 Imp. Gallons US Gallons Litres Imp. Gallons 0.219975 0.264178 3.785332 0.832680 Windspeed Velocity m/sec Knots m/sec ft/min To convert Weights Kilograms Pounds Fuel weight Litres Kilograms Imp. Gallons Pounds US Gallons Pressure Inches HG PSI 2.0 ~200 Into Multiply by Pounds Kilograms 2.204622 0.453592 Specific weight 0.7100 0.8000 1.4085 1.2500 0.3717 0.3299 0.3095 0.2747 3.2305 3.6400 7.1220 8.0248 0.1404 0.1246 0.1686 0.1496 2.6909 3.0320 5.9323 6.6843 Kilograms Litres US Gallons Imp. Gallons Kilograms Pounds Imp. Gallons US Gallons Kilograms Pounds PSI Inches HG HPA/BAR 0.491157 2.036009 0.0689 HPA/BAR Temperature Celsius PSI 14.5038 Fahrenheit 1.8 and add 32 Fahrenheit Celsius subtract 32 and multiply by 0.555 DISTANCES Kilometres to ft/m ft sm km 0.305 0.610 0.914 1.219 1.524 1.829 2.134 2.438 2.743 1 2 3 4 5 6 7 8 9 3.281 6.562 9.842 13.123 16.404 19.685 22.966 26.247 29.528 0.62 1.24 1.86 2.49 3.11 3.73 4.35 4.97 5.59 1 2 3 4 5 6 7 8 9 06 NOV 03 nm Statute Miles to Nautical Miles to km 0.54 1.61 1.08 3.22 1.62 4.83 2.16 6.44 2.70 8.05 3.24 9.66 3.78 11.27 4.32 12.88 4.88 14.49 Metres-Yards sm nm km nm sm m Yd/m Yd 1 2 3 4 5 6 7 8 9 0.87 1.74 2.61 3.47 4.34 5.21 6.08 6.95 7.82 1.85 3.71 5.56 7.41 9.27 11.12 12.97 14.83 16.68 1 2 3 4 5 6 7 8 9 1.15 2.30 3.46 4.61 5.76 6.91 8.06 9.21 10.36 91.4 182.8 274.2 365.6 457.0 548.4 639.8 731.2 822.6 100 200 300 400 500 600 700 800 900 109.4 218.8 328.2 437.6 547.6 656.4 765.8 875.2 984.6 Change: Editorial E 2005 Metres-Feet m LAT General Information Page 51 Meters to feet (rounded up to next 10ft) m 0 0 3290 6570 9850 13130 16410 19690 22970 26250 29530 32810 36090 39380 42660 45940 49220 0 1000 2000 3000 4000 5000 6000 7000 8000 9000 10000 11000 12000 13000 14000 15000 100 330 3610 6890 10180 13460 16740 20020 23300 26580 29860 33140 36420 39700 42980 46260 49550 200 660 3940 7220 10500 13780 17070 20350 23630 26910 30190 33470 36750 40030 43310 46590 49870 300 990 4270 7550 10830 14110 17390 20670 23960 27240 30520 33800 37080 40360 43640 46920 50200 400 1320 4600 7880 11160 14440 17720 21000 24280 27560 30840 34130 37410 40690 43970 47250 50530 ft 500 1650 4930 8210 11490 14770 18050 21330 24610 27890 31170 34450 37730 41020 44300 47580 50860 600 1970 5250 8540 11820 15100 18380 21660 24940 28220 31500 34780 38060 41340 44620 47910 51190 700 2300 5580 8860 12140 15420 18710 21990 25270 28550 31830 35110 38390 41670 44950 48230 51510 800 2630 5910 9190 12470 15750 19030 22310 25600 28880 32160 35440 38720 42000 45280 48560 51840 900 2960 6240 9520 12800 16080 19360 22640 25920 29200 32490 35770 39050 42330 45610 48890 52170 Example: 9500m = 31170ft Slant range in Nautical Miles (nm) 40 0 5 10 - 3.0 15 20 25 30 35 - 2.0 - 0.5 nm 35 ALTITUDE ( 1000 ft ) 40 - 1.0 “When range in nm is greater than altitude in thousands of feet, forget about slant range”. 30 25 Example: 20 15 ALT 35000 ft DME DIST 17 nm GND DIST 16 nm 10 Radio horizon for VHF facilities E 2005 ft 1000 2000 3000 4000 Change: NIL nm 39 54 66 77 ft 6000 8000 10000 12000 nm 95 109 123 134 ft 15000 20000 25000 30000 nm 150 174 194 213 ft 35000 40000 45000 50000 nm 230 D = 246 D = 260 H = 275 1.23 x p H Distance in nm Height g in ft 23 SEP 04 LAT General Information Page 52 WEIGHTS Liquids and weights Litres (l) to IMG I 0.22 1 0.44 2 0.66 3 0.88 4 1.10 5 1.32 6 1.54 7 1.76 8 1.98 9 USG 0.26 0.53 0.79 1.06 1.32 1.59 1.85 2.11 2.38 US Gallons (USG) to I USG IMG 3.79 1 0.83 7.57 2 1.67 11.36 3 2.50 15.14 4 3.33 18.93 5 4.16 22.71 6 5.00 26.50 7 5.83 30.28 8 6.66 34.07 9 7.49 Imp. Gallons (IMG) to I IMG USG 4.55 1 1.20 9.09 2 2.40 13.64 3 3.60 18.18 4 4.80 22.73 5 6.00 27.28 6 7.21 31.82 7 8.41 36.37 8 9.61 40.91 9 10.81 kg and lb kg lb/kg 0.45 1 0.91 2 1.36 3 1.81 4 2.27 5 2.72 6 3.18 7 3.63 8 4.08 9 lb 2.20 4.41 6.61 8.82 11.02 13.23 15.43 17.64 19.84 Jet fuel weight ) (specific weight: 0.80) kg USG/ IMG kg USG kg IMG LB USG/ IMG 3.0283 1 3.6368 0.330223 1 0.274969 6.6843 1 6.0565 2 7.2736 0.660445 2 0.549937 13.3686 2 9.0848 3 10.9103 0.990668 3 0.824906 20.0529 3 12.1131 4 14.5471 1.320890 4 1.099875 26.7372 15.1413 5 18.1839 1.651113 5 18.1696 6 21.8207 1.981335 21.1979 7 24.2261 27.2544 LB USG LB IMG 8.0248 0.1496 1 0.1246 16.0496 0.2992 2 0.2492 24.0744 0.4488 3 0.3738 4 32.0992 0.5984 4 0.4984 1.374843 33.4215 5 40.1240 0.7480 5 0.6230 6 1.649812 40.1058 6 48.1488 0.8976 6 0.7476 25.4574 2.311558 7 1.924781 46.7901 7 56.1736 1.0472 7 0.8722 8 29.0942 2.641780 8 2.199749 53.4744 8 64.1984 1.1968 8 0.9968 9 32.7310 2.972003 9 2.474718 60.1587 9 72.2232 1.3464 9 1.1214 Litres to Kilograms (thousands of Litres) (specific weight: 0.80) Lit. 0 0.050 0.100 0.150 0.200 0.250 0.300 0.350 0.400 0.450 0.500 0.600 0.700 0.800 0.900 0 0 40 80 120 160 1 800 840 880 920 960 1000 1040 1080 1120 1160 1200 1280 1360 1440 1520 200 240 280 320 360 400 480 560 640 720 2 1600 1640 1680 1720 1760 1800 1840 1880 1920 1960 2000 2080 2160 2240 2320 3 2400 2440 2480 2520 2560 2600 2640 2680 2720 2760 2800 2880 2960 3040 3120 4 3200 3240 3280 3320 3360 3400 3440 3480 3520 3560 3600 3680 3760 3840 3920 5 4000 4040 4080 4120 4160 4200 4240 4280 4320 4360 4400 4480 4560 4640 4720 6 4800 4840 4880 4920 4960 5000 5040 5080 5120 5160 5200 5280 5360 5440 5520 7 5600 5640 5680 5720 5760 5800 5840 5880 5920 5960 6000 6080 6160 6240 6320 8 6400 6440 6480 6520 6560 6600 6640 6680 6720 6760 6800 6880 6960 7040 7120 9 7200 7240 7280 7320 7360 7400 7440 7480 7520 7560 7600 7680 7760 7840 7920 10 8000 8040 8080 8120 8160 8200 8240 8280 8320 8360 8400 8480 8560 8640 8720 23 SEP 03 9500 Lit. = 7600 kg Change: Update E 2005 Example: LAT General Information Page 53 DETERMINATION OF ACTUAL ALTITUDE / FL Temperature correction for MOCA calculation 250 OAT = STD Temp ( ˚C ) 250 - 30 100 - 25 LEVEL 150 200 - 20 150 - 15 FLIGHT REQUIRED MOCA (x 100ft) 200 STD Temp - 35 - 10 100 - 5 0 50 50 +5 +10 MSL - 1500ft - 1000ft - 500ft 0 +500ft ADD TO ( SUBTRACT FROM ) MOCA / figure MSL +1000ft +15 QNH-correction 940 + 2000ft 950 960 + 1500ft 970 980 990 1000 1010 1020 + 1000ft + 500ft 0 ADD TO ( SUBTRACT FROM ) MOCA / figure 1030 -- 500ft 1040 1050 -- 1000ft Example: Required MOCA OAT Graph OAT: Subtract from MOCA QNH Graph QNH: Add to MOCA Obtain corresponding indicated altitude = = = = == 18’000ft STD Temp + 10° -700ft 1008 MB/HPA +150ft 17’450ft E 2005 Note: If it is desired to calculate the true altitude from an actual flight level, the algebraic signs (+,-) of the two corrections to/from the FL figure ( instead of MOCA figure ) have to be reversed. Change: NIL 05 JUN 03 LAT General Information Page 54 Temperatures of standard atmosphere FL 0 10 20 30 40 °C 15 13 11 9 7 FL 50 60 70 80 90 °C 5 3 1 −1 −3 FL °C FL 100 −5 150 110 −7 160 120 −9 170 130 −11 180 140 −13 190 °C −15 −17 − −19 −23 FL 200 210 220 230 240 °C −25 −27 −29 −31 −33 FL 250 260 270 280 290 °C −35 −36 −38 −40 −42 FL 300 310 320 330 340 °C FL °C −44 350 −54 −46 360 −54 −48 and −50 higher −56 −52 ALTIMETER CORRECTIONS DURING APPROACH The altimeter error may be significant under conditions of extremely cold temperatures. Altimeter corrections during approach (recommendation): It is assumed that the aeroplane altimeter reading on crossing the fix is correlated with the published altitude, allowing for altitude error and altimeter tolerances. Values to be added by the pilot to published altitudes (ft) Height in ft above the elevation of the altimeter setting source (AGL) AD OAT °C 200 300 400 500 600 700 800 900 1000 1500 2000 3000 4000 5000 0° 0 20 20 20 20 40 40 40 40 60 80 140 180 220 −10° 20 20 40 40 40 60 80 80 80 120 160 260 340 420 −20° 20 40 40 60 80 80 100 120 120 180 240 380 500 620 −30° 40 40 60 80 100 120 140 140 160 240 320 500 660 820 −40° 40 60 80 100 120 140 160 180 200 300 400 620 820 1020 −50° 40 80 100 120 140 180 200 220 240 360 480 740 980 1220 Note: The table is based on aerodrome elevation of 2000ft; however, it can be used operationally at any aerodrome. Example: AD XYXZ Elevation OAT -10° min. ALT at FIX on GP AGL Correction Indicated ALT at FIX 2000ft 3500ft 1500ft 3500ft 120ft 3620ft 05 JUN 03 Change: Update E 2005 (4ft per 1000ft above the source per °C off standard) E 2005 Change: New 03 APR 03 Example: Determine the sunrise time in GMT at 40˚N, 77˚W on 20th January. Enter the diagram at the top of the scale on the line marked January 20, follow the line until the intersection with the 40˚ north latitude curve; at the vertical scale read off the local civil time, i.e. 0718; calculate the correction for the longitude, i.e. 4x77=308min (=5h08min), add the correction to the local civil time, i.e. 0718+5h08min=1226 GMT. Instructions for use 1) Enter the top or bottom scale with the proper date. 2) Move vertically down or up the curve for the observer’s latitude. 3) Move horizontally to the right or left and read local time on the vertical scales at the sides. 4) To find exact GMT add 4 minutes for each degree west of Greenwich Meridian and subtract 4 minutes for each degree east of Greenwich Meridian. The scales at the top and bottom of the page mark the date for every five days, while the vertical scales divide the Local Civil Time. Accuracy of the diagrams is to within one or two minutes. Sunrise and sunset diagrams These diagrams portray graphically for any year the times of rising and setting of the sun for latitudes up to 75˚ North and South. For high latitudes, not included on the diagram, twilight or half light will usually be found throughout the summer nights. General Information Page 55 LAT SUNRISE AND SUNSET DIAGRAM SUNRISE DIAGRAM Change: New 03 APR 03 E 2005 Example: What is GMT sunset in latitude 40˚N, longitude 77˚W, January 20th ? Enter at bottom for January 20th and move vertically up to 40˚N curve. Move horizontally right and read Local Civil Time of 1704. Add to Local Civil Time for 77˚W, 4 minutes for each degree, making a total of 308 minutes to be added to 1704 giving 2212 as GMT. Instructions for use 1) Enter the top or bottom scale with the proper date. 2) Move vertically down or up the curve for the observer’s latitude. 3) Move horizontally to the right or left and read local time on the vertical scales at the sides. 4) To find exact GMT add 4 minutes for each degree west of Greenwich Meridian and subtract 4 minutes for each degree east of Greenwich Meridian. Page 56 The scales at the top and bottom of the page mark the date for every five days, while the vertical scales divide the Local Civil Time. Accuracy of the diagrams is to within one or two minutes. Sunrise and sunset diagrams These diagrams portray graphically for any year the times of rising and setting of the sun for latitudes up to 75˚, North and South. For high latitudes, not included on the diagram, twilight or half light will usually be found throughout the summer nights. LAT General Information SUNSET DIAGRAM LAT General Information Page 57 CLIMB AND DESCENT GRADIENTS 8000 Ground speed p Glide (kt) path (degrees) 7.00 6.75 6.50 6.25 6.00 5.75 5.50 5.25 5.00 4.75 4.50 4.25 4.00 3.75 3.50 3.25 3.00 2.75 2.50 2.25 2.00 7000 6000 HEIGHT QFE (FT) 5000 Rate of descent ROD (FT/MIN and Rate of climb ROC (FT/MIN) Glide path vs Ground speed 120 125 130 135 140 145 150 155 160 165 170 175 180 1500 1400 1350 1300 1250 1200 1150 1100 1050 1000 950 900 850 800 750 700 600 600 550 450 400 1550 1500 1450 1400 1300 1250 1200 1150 1100 1050 1000 950 900 850 750 700 650 600 550 500 450 1600 1550 1500 1450 1350 1300 1250 1200 1150 1100 1050 950 900 850 800 750 700 600 550 500 450 1650 1600 1550 1500 1400 1350 1300 1250 1150 1100 1050 1000 950 900 800 750 700 650 600 550 450 1700 1650 1600 1550 1450 1400 1350 1300 1200 1150 1100 1050 1000 900 850 800 750 650 600 550 500 1800 1700 1650 1600 1500 1450 1400 1350 1250 1200 1150 1050 1000 950 900 850 750 700 650 550 500 1850 1750 1700 1650 1600 1500 1450 1400 1300 1250 1200 1100 1050 1000 900 850 800 700 650 600 550 1900 1850 1750 1700 1650 1550 1500 1450 1350 1300 1200 1150 1100 1000 950 900 800 750 700 600 550 1950 1900 1800 1750 1700 1600 1550 1450 1400 1350 1250 1200 1100 1050 1000 900 850 750 700 600 550 2050 1950 1900 1800 1750 1650 1600 1500 1450 1350 1300 1200 1150 1100 1000 950 850 800 750 650 600 2100 2000 1950 1850 1800 1700 1650 1550 1500 1400 1350 1250 1200 1100 1050 950 900 800 750 650 600 2150 2050 2000 1950 1850 1750 1700 1600 1500 1450 1400 1300 1250 1150 1050 1000 900 850 750 700 600 2200 2100 2050 2000 1900 1800 1750 1650 1550 1500 1400 1350 1250 1200 1100 1050 950 850 800 700 650 Gradient vs Ground Speed ROD (FT/MIN ! GS (KT) x Grad (%) 4000 Example: Required gradient = 5% GS = 160 KT 3000 ROD = 5 x 160 ! 800 FT/MIN (correct value = 810 FT/MIN) 2000 1000 E 2005 1 1 Change: Update 2 2 3 3 4 5 4 6 7 5 8 9 10 6 NM 7 11 KM 13 03 JUL 03 8 14 15 9 16 10 17 18 11 19 20 12 21 22 13 23 24 25 LAT Page 58 General Information E 2005 Intentionally left blank Change: NIL 03 JUL 03 LAT General Information Page 59 WORLD LOCAL TIMES Local time (LT) is Standard time (STD) or Daylight saving time (DST) Times given below should be added/subtracted (according signes) to UTC (Z,GMT). General All hours of operation of radio aids, service hours of aerodromes,etc. are indicated in Coordinated Universal Time UTC, sometimes also expressed as “Z” time or GMT (UTC, Z, or GMT not shown). Times given in Local Time are followed by letters LT. The symbol } indicates that during periods of Daylight Saving Time, effective hours will be one hour earlier than shown. Example: LSZH (STD +1, DST +2) During STD period: During DST period: E 2005 COUNTRY AFGHANISTAN ALBANIA ALGERIA ANDAMAN ISLAND ANDORRA ANGOLA ANGUILLA (Leeward Island) ANTARCTICA ANTIGUA & BARBUDA ARGENTINA ARMENIA ARUBA ASCENSION ISLAND AUSTRAL ISLAND AUSTRALIA: Capital Territory (Canberra) Lord Howe Island New South Wales (Sydney) Northern Territory (Darwin) Queensland South Australia (Adelaide) Tasmania (Hobart) Victoria (Melbourne) Western Australia (Perth) Whitsunday Islands (Hamilton, Hayman & Lindeman) AUSTRIA AZERBAIJAN AZORES BAHAMAS Change: Update No landings 2330-0430 } 2330-0430 UTC +1 = 0030-0530 LT. one hour earlier than shown 2230-0330 UTC +2 = 0030-0530 LT. STD DIFFERENCE DST DIFFERENCE PERIOD WHEN DST APPLIES +4½ +1 +1 +5½ +1 +1 -4 -4 -4 -3 +4 -4 UTC -10 +10 +10½ +10 +9½ +10 +9½ +10 +10 +8 +10 +1 +4 -1 -5 +2 27/03/05-30/10/05 +2 27/03/05-30/10/05 +5 27/03/05-30/10/05 +11 +11 +11 -26/03/05 26/03/05 ...........29/10/0529/10/05- +10½ +11 +11 -26/03/05 26/03/05 ...........29/10/0529/10/05- +2 +5 UTC -4 27/03/05-30/10/05 27/03/05-30/10/05 27/03/05-30/10/05 03/04/05-30/10/05 10 FEB 05 Page 60 COUNTRY General Information STD DIFFERENCE DST DIFFERENCE PERIOD WHEN DST APPLIES BAHRAIN BANGLADESH BARBADOS BELARUS BELGIUM BELIZE BENIN BERMUDA BHUTAN BOLIVIA BOSNIA & HERZOGOVINA BOTSWANA BRAZIL: Fernando do Noronha South/central coast Bahia, Goias, BSB/RIO/SAO Part of Northeast coast & east of Para Amazonas, Nortwest states and west of Para +3 +6 -4 +2 +1 -6 +1 -4 +6 -4 +1 +2 Mato Grosso and Mato Grosso do Sul Territory of Acre BRITISH VIRGIN ISLAND BRUNEI DARUSSALAM BULGARIA BURKINA FASO BURUNDI C AMBODIA CAMEROON CANADA: Newfoundland Island Labrador Atlantic Zone: New Brunswick, Nova Scotia, Prince Edward Is., Quebec (East of Pte. des Monts) Eastern Zone: North-West Territory (East) Ottawa, Ontario, Quebec (West of Pte. des Monts) Central Zone: Manitoba, North-West Territory (Central), Saskatchewan (West) -4 10 FEB 05 -2 -3 +3 +2 27/03/05-30/10/05 27/03/05-30/10/05 -3 03/04/05-30/10/05 +2 27/03/05-30/10/05 -2 -13/02/05 16/10/05- -3 -13/02/05 16/10/05- +3 27/03/05-30/10/05 -4 -5 -4 +8 +2 UTC +2 +7 +1 -3½ -4 -4 -2½ -3 -3 -5 -4 -6 -5 03/04/05-30/10/05 Change: Update E 2005 LAT LAT General Information COUNTRY Mountain Zone: Alberta, North-West Territory (Mountain), Saskatchewan(West) Some towns in NE British Columbia Pacific Zone: British Columbia Yukon Territory Whitehorse and Watson Lake Dawson City and Mayo CANARY ISLANDS CAPE VERDE ISLAND CAROLINE ISLAND CAYMAN ISLAND CENTRAL AFRICAN REP. CHAGOS ARCHIPELAGO CHATHAM ISLAND STD DIFFERENCE DST DIFFERENCE PERIOD WHEN DST APPLIES -7 -6 -8 -7 UTC -1 +11 -5 +1 +5 +12¾ +1 +13¾ CHILE -4 -3 CHINA (People’s Republic) +8 +7 CHRISTMAS ISLAND COCOS ISLANDS COLUMBIA COMOROS & MAYOTTE Isl. CONGO COOK ISLAND COSTA RICA CROATIA CUBA CURACAO CYPRUS CZECH REPUBLIC D ENMARK DJIBOUTI E 2005 Page 61 +6½ -5 +3 +1 -9½ -6 +1 -5 -4 +2 +1 +1 +3 DOMINICA DOMINICAN REPUBLIC E ASTER ISLAND -4 -4 -6 ECUADOR (except Galapagos Isl.) EGYPT EL SALVADOR EQUATORIAL GUINEA ERITREA ESTONIA -5 Change: Update +2 -6 +1 +3 +2 03/04/05 30/10/05 03/04/05-30/10/05 27/03/05-30/10/05 -19/03/05 01/10/05-13/03/05 09/10/05- +2 -4 27/03/05-30/10/05 -30/10/05 +3 +2 +2 27/03/05-30/10/05 27/03/05-30/10/05 27/03/05-30/10/05 -5 -13/03/05 09/10/05- +3 28/04/05-29/09/05 +3 27/03/05-30/10/05 03 MAR 05 Page 62 COUNTRY General Information STD DIFFERENCE DST DIFFERENCE PERIOD WHEN DST APPLIES ETHIOPIA FALKLAND ISLANDS +3 -4 FAROE ISLANDS FIJI FINLAND FRANCE FRENCH ANTILLES FRENCH GUIANA GABON GALAPAGOS ISLAND GAMBIER ISLAND GAMBIA GEORGIA GERMANY GHANA GIBRALTAR GREECE GREENLAND: Northeastern part Central part Western part GRENADA GUADELOUPE GUAM GUATEMALA GUINEA BISSAU GUINEA GUYANA HAITI HONDURAS HONG KONG UTC +12 +2 +1 -4 -3 +1 -6 -9 UTC +4 +1 UTC +1 +2 +1 -22/04/05 04/09/0527/03/05-30/10/05 +3 +2 27/03/05-30/10/05 27/03/05-30/10/05 +5 +2 26/03/05-29/10/05 27/03/05-30/10/05 +2 +3 27/03/05-30/10/05 27/03/05-30/10/05 -1 -2 -3 -4 -4 +10 -6 UTC UTC -4 -5 -6 +8 +1 UTC -1 -2 HUNGARY I CELAND INDIA INDONESIA: Western Zone Central Zone Eastern Zone IRAN IRAQ IRELAND Rep. ISRAEL ITALY 03 MAR 05 -3 27/03/05 30/10/05 27/03/05-30/10/05 +2 27/03/05-30/10/05 +4½ +4 +1 +3 +2 21/03/05-21/09/05 01/04/05-30/09/05 27/03/05-30/10/05 31/03/05-29/09/05 27/03/05-30/10/05 UTC +5½ +7 +8 +9 +3½ +3 UTC +2 +1 Change: NIL E 2005 LAT LAT General Information COUNTRY IVORY COAST JAMAICA JAPAN JOHNSTON ISLAND JORDAN K AZAZHSTAN: Western Zone – Aktau, Atyrau, Uralsk Central Zone – Aktyubinsk Eastern/Main Zone KENYA KIRIBATI: Line Isl. Phoenix Island Gilbert Isl. KOREA: Democratic People’s Republic Republic of KUWAIT KYRGYSTAN LAO (People’s Democratic Republic) LATVIA LEBANON LEEWARD ISLANDS LESOTHO LIBERIA LIBYA LIECHTENSTEIN LITHUANIA LUXEMBOURG MACAU MACEDONIA E 2005 MADAGASCAR MADEIRA ISLAND MALAWI STD DIFFERENCE DST DIFFERENCE PERIOD WHEN DST APPLIES UTC -5 +9 -10 +2 +3 +4 +5 +5 +6 +3 +6 +7 24/03/05-27/10/05 26/03/05 29/10/05 26/03/05-29/10/05 +14 +13 +12 +9 +9 +3 +5 +7 +2 +2 -4 +2 UTC +2 +1 +2 +1 +8 +1 MALAYSIA +3 UTC +2 +8 MALDIVES MALI MALTA MARIANA ISLAND MARQUESAS ISLAND MARSHALL ISLAND MARTINIQUE +5 UTC +1 +10 -9½ +12 -4 Change: Update Page 63 +6 27/03/05-30/10/05 +3 +3 27/03/05-30/10/05 27/03/05-30/10/05 +2 +3 +2 27/03/05-30/10/05 27/03/05-30/10/05 27/03/05-30/10/05 +2 27/03/05-30/10/05 +1 27/03/05-30/10/05 +2 27/03/05-30/10/05 10 FEB 05 Page 64 COUNTRY MAURITANIA MAURITIUS MAYOTTE MEXICO: Central including Mexico City, Guadalajara, Cancun Baja California Sur, Nayarit, Sinaloa, Chihuahua Baja California Norte including Tijuana, Mexicali MICRONESIA: Caroline Island (Gen) Pohnpei & Kosrae MIDWAY ISLAND MOLDOVA MONACO MONGOLIA MONTSERRAT MOROCCO MOZAMBIQUE General Information STD DIFFERENCE DST DIFFERENCE PERIOD WHEN DST APPLIES UTC +4 +3 -6 -5 -7 -6 -8 -7 +10 +11 MYANMAR -11 +2 +1 +8 -4 UTC +2 +6½ N AMIBIA +1 +3 +2 27/03/05-30/10/05 27/03/05-30/10/05 +2 -02/04/05 04/09/05- +2 27/03/05-30/10/05 NAURU NEPAL NETHERLANDS NETHERLAND ANTILLES NEW CALEDONIA NEW ZEALAND +12 +5¾ +1 -4 +11 +12 +13 NICARAGUA NIGER NIGERIA NIUE ISLAND NORFOLK ISLAND -6 +1 +1 -11 +11½ +1 +2 NORWAY OMAN PAKISTAN PALAU PANAMA PAPUA NEW GUINEA PARAGUAY PERU 10 FEB 05 03/04/05-30/10/05 +4 +5 +9 -5 +10 -4 -19/03/05 01/10/05- 27/03/05-30/10/05 +6 -3 -03/04/05 04/09/05- -5 Change: Update E 2005 LAT LAT General Information COUNTRY STD DIFFERENCE DST DIFFERENCE PERIOD WHEN DST APPLIES PHILIPPINES PHOENIX ISLAND POLAND PORTUGAL PUERTO RICO QATAR REUNION ROUMANIA RUSSIA (Federation of): Kalingrad Moscow, St.Petersburg, Astrakhan +8 -11 +1 UTC -4 +3 +4 +2 +2 +3 +3 +4 Izhevsk, Samara Perm-Nizhnevartovsk Omsk, Novosibirsk Norilsk, Kyzyl Bratsk, Ulan Ude Chita, Yakutsk Khabarovsk, Vladivostok Magadan, Yuzhno Sakhalinsk Petropavlovsk, Kamchatsky RWANDA +4 +5 +6 +7 +8 +9 +10 +11 +12 +2 UTC +5 +6 +7 +8 +9 +10 +11 +12 +13 ST. HELENA ST. KITTS & NEVIS ST. LUCIA ST. PIERRE & MIQUELON ST. VINCENT & GRENADINES SAMOA SAN MARINO SAO TOME & PRINCIPE SAUDI ARABIA SENEGAL SEYCHELLES SIERRA LEONE SINGAPORE E 2005 Page 65 SLOVAKIA -4 -4 -2 -4 -11 +1 UTC +3 UTC +4 UTC +8 +1 SLOVENIA SOCIETY ISLAND SOLOMON ISLAND SOMALI DEMOCRATIC REP. SOUTH AFRICA SPAIN SPANISH N.AFRICA SRI LANKA +1 -10 +11 +3 +2 +1 +1 +6 Change: Update +2 +1 27/03/05-30/10/05 27/03/05-30/10/05 +3 27/03/05-30/10/05 2603/05 29/10/05 2603/05-29/10/05 -1 03/04/05-30/10/05 +2 27/03/05-30/10/05 +2 27/03/05-30/10/05 +2 27/03/05-30/10/05 +2 +2 27/03/05-30/10/05 27/03/05-30/10/05 10 FEB 05 Page 66 COUNTRY SUDAN SURINAM SWAZILAND SWEDEN SWITZERLAND SYRIAN ARAB REPUBLIC TAHITI TAIWAN TAJIKISTAN TANZANIA THAILAND TOGO TONGA TRINIDAD & TOBAGO TUAMOTU ISLAND TUBUAI ISLAND TUNISIA TURKEY TURKMENISTAN TURKS & CAICOS ISLANDS TUVALU U GANDA UKRAINE UNITED ARAB EMIRATES UNITED KINGDOM UNITED STATES OF AMERICA: Eastern time Indiana (East) Central time Mountain time Arizona Pacific time Alaska – all locations (except Aleutian Islands West of W169°30’) Alaska - Aleutian Islands (West of W169°30’) Hawaiian Islands URUGUAY U.S. VIRGIN ISLAND UZBEKISTAN VANUATU VENEZUELA VIETNAM 10 FEB 05 General Information STD DIFFERENCE DST DIFFERENCE PERIOD WHEN DST APPLIES +2 -3 +2 +1 +1 +2 -10 +8 +5 +3 +7 UTC +13 -4 -10 -10 +1 +2 +5 -5 +2 +2 +3 27/03/05-30/10/05 27/03/05-30/10/05 31/03/05-31/10/05 +3 27/03/05-30/10/05 -4 03/04/05-30/10/05 +3 27/03/05-30/10/05 +1 27/03/05-30/10/05 -5 -5 -6 -7 -7 -8 -9 -4 03/04/05-30/10/05 -5 -6 03/04/05-30/10/05 -7 -8 03/04/05-30/10/05 -10 -9 +12 +3 +2 +4 UTC 03/04/05 30/10/05 03/04/05-30/10/05 -10 -3 -4 +5 +11 -4 +7 Change: Update E 2005 LAT LAT General Information COUNTRY E 2005 WAKE ISLAND WALLIS & FUTUNA ISLAND WINDWARD ISLAND YEMEN ARAB REPUBLIC YUGOSLAVIA Z AIRE: Kinshasa, Mbandaka Haut Zaire, Kasai, Kivu, Shaba ZAMBIA ZIMBABWE Change: Update Page 67 STD DIFFERENCE DST DIFFERENCE PERIOD WHEN DST APPLIES +12 +12 -4 +3 +1 +2 27/03/05-30/10/05 +1 +2 +2 +2 10 FEB 05 LAT Page 68 General Information 10 FEB 05 Change: NIL E 2005 Intentionally left blank