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The lines running around the earth, parallel to the equator, are called lines of parallel (or parallels). They are measured from the equator to the poles in terms called degrees of latitude. They range from 0° latitude at the equator to 90° latitude at the poles. They are termed North latitude in the Northern Hemisphere, and South latitude in the Southern Hemisphere. Unlike Meridian Lines, lines of parallel are equidistant between them (since they are parallel and do not converge). One minute of latitude equals a nautical mile. The Latitude of the dot shown on the earth’s surface in the diagram above is defined as 35° 20’ N. Therefore, the location of the dot can be explicitly defined as 35° 20’N - 30° 45’ W. Aeronautical charts show horizontal latitude lines and vertical longitude lines at 30 minute intervals. They are labeled near the edges of the chart, and periodically along the line. There are 30 “tick” marks between each 30 minute line, each representing one minute. The 10 minute marks are long, and the 5 minute marks are intermediate in length. One can determine latitude by locating the line below the point in question, then count upward, adding the number of tick marks from the reference line. When parallel with the point, the latitude location has been reached. (NOTE: If the latitude line is above the point in question, count the tick marks downward. Subtract them from the latitude line value. When moving North, add degrees and minutes. When moving South, subtract degrees and minutes). To find the longitude of a point is similar. Count the tick marks either East or West from the reference longitude line to the point in question. When going in a westerly direction, add degrees and minutes. Subtract degrees and minutes when going in an easterly direction. (Note: these rules apply only in the North and Western Hemisphere.) Three airport locations are shown below. Listed below are their ID, Latitude and Longitude. The diagram shows how to find the location of each airport. (Note: These points are shown on the Charlotte Sectional Aeronautical Chart). Chart Symbols http://www.uncletom2000.com/gs/chartsym.htm (2 of 9) [1/23/2003 11:19:04 AM] SVH 35° 46’ N 80° 57’ W LEX 35° 47 N 80° 18’ W 3N8 35° 23’ N 80° 42’ W Note: The 36 degree North Latitude line simply has the number 36° on it at the left end of the line. The line below it has 30’ on it. Although the number 35° does not occur on the chart, the line is 35° 30’ by inference. Charts such as this can occur on the Private Pilot Written Exam, so learn how to interpret the degree and minute legends on the charts. To find the Lat/Lon of SVH, project a line both vertically and horizontally from the center of the airport (follow the blue dotted lines). Go to the 81° Longitude line, and count horizontally eastward by 3 minutes (3 tick marks east). When counting a number of tick marks toward the East, treat the count as a negative value. This yields a latitude = 81° 0’ - 0° 03’ = 80° 57’ W. Likewise, go to the 35° 30’ Latitude line. Count upward 0° 16’ (16 tick marks). When counting northward, the count of the tick marks is positive) The Latitude of the airport is therefore 35° 30’ + 0°16 ‘ = 35° 46’ N. You could also have gone up to the 36° 00’ line and counted downward 14 minutes to also get a 46’ point north of Latitude 35°. In this case, you would have counted toward the South, so that the count of tick marks is negative. In the US, when you encounter a line marked 30’ (30 minute), you must go to the next Lower Latitude Line to determine the degrees. Similarly, when a longitude line has only a 30’ (30 minute ) label, you will have to go to Chart Symbols http://www.uncletom2000.com/gs/chartsym.htm (3 of 9) [1/23/2003 11:19:04 AM] the right (eastward) to the next line to determine the degree of Longitude. Time Zones The United States lies between 67°W and 125° W. This spans 4 time zones. Meridians are useful in determining time zones. When the sun is directly above a meridian, it is noon at that meridian. To the West of that meridian, it is forenoon; to the East, it is afternoon. Since it is impractical to define 360 noon’s, the surface of the earth is divided into time zones, approximately 15° apart. However, as noted, due to local geographical and jurisdictional variations in the U. S., the actual time zone lines are irregular. Since Greenwich, England is at the zero meridian, all time references used in flying is to the time at the zero meridian. This used to be Greenwich Mean Time. The terminology is now Coordinated Universal Time (abbreviated UTC). In aviation terminology, the word ZULU refers to UTC time, and is written with a Z suffix. Examples: 1450Z, 0024Z, 0400Z, etc. A conversion from local time in the US to UTC time is required for flight plans and communications with ATC. To convert local times to UTC, add the following values: From EST to UTC add 5 hours. From CST to UTC add 6 Hours. From MST to UTC add 7 hours. From PST to UTC add 8 hours. NOTE: If the local time is Daylight Savings Time, reduce the added hours by 1 Hour (4, 5, 6, 7 respectively). Controlled Airport Legend CHARLOTTE DOUGLAS INTERNATIONAL (CLT) CT - 118.1 126.4 ATIS 121.15 749 L 100 122.95 Controlled airports with control towers (Class B, C, D) show information about the airport in BLUE lettering near the airport symbol, which is also blue. This type of data is typical of the airport information for Controlled airports with a control tower. Chart Symbols http://www.uncletom2000.com/gs/chartsym.htm (4 of 9) [1/23/2003 11:19:04 AM] The data is interpreted as follows. Airport Name: CHARLOTTE DOUGLAS INTERNATIONAL USA Airport Identifier: CLT Control Tower Frequency (CT) - 118.1 - 126.4 Automated Terminal Information Service (ATIS) 121.15 Airport Altitude - 749 feet MSL L = Lighted Longest Runway (100) = 10,000 feet UNICOM frequency (for fuel, etc.) = 122.95 Non-Controlled Airport Legend STATESVILE (SVH) 965 *L 50 123.05 Airports colored magenta on the charts have no control tower. The data associated with these airports is in magenta color also. Airport Name: STATESVILLE USA Identifier: SVH Airport Altitude: 965 feet MSL *L = Lighted part time (indicated by the *). Pilot controlled at other times. Longest Runway (50) = 5,000 feet. Common Traffic Advisory Frequency = 123.05 Plotting the Course An instrument called a plotter is used to determine course distance and direction. It has a transparent scale and a protractor. It usually has both Sectional and WAC scales in both Nautical Mile and Statute Mile dimensions. When measuring distances from point to point, one must be careful to use the appropriate scale for the chart in use. Also, one must guard against mixing the use of the Nm and Sm scales. The scale shown on the diagram is in Nm for simplicity of the diagram. The outer scale on the protractor is in degree divisions from 0° at the right to 180° at the left. The inner scale is from 180° at the right to 360° at the left side of the protractor. Measuring Distance Chart Symbols http://www.uncletom2000.com/gs/chartsym.htm (5 of 9) [1/23/2003 11:19:04 AM] To find the distance between two points (A and B), draw a line between the two points and place the appropriate scale along the line. Read the distance from the scale. In the example, the Sectional Nautical scale is being used. The distance is 44 Nm. When measuring from an airport as one of the points, place the index end (zero end) at the CENTER of the airport symbol. If measuring along a Victor Airway, measure from the center dot of the VOR. Sometimes, the center of the VOR is on an airport surface. To place a VOR symbol over the airport symbol would be confusing. Therefore, the center of the VOR is represented by small white dot on the airport symbol. Measure from the white dot. Measuring the Course The True Course is the degrees between the direction of flight and True North measured clockwise from a Longitude Line. Shown is a course from point A to point B. The course line, A and B are shown in red. For the most accurate measurement, measure where the course line crosses a longitude line. If such an intersection does not exist between A and B, extend the course line until it does cross a longitude line. Chart Symbols http://www.uncletom2000.com/gs/chartsym.htm (6 of 9) [1/23/2003 11:19:04 AM] The protractor has a small hole at the center. Place the hole over the intersection of the course line and the longitude line. The edge of the plotter on the protractor side must be along the course line. Read the true course degrees at the top of the protractor at the longitude line. If the direction of flight is from point A to point B, read the True Course in degrees on the outer protractor scale (39° shown in red). If the direction of flight is from B to A, read the True Course in degrees on the inner protractor scale (219). NOTE: When the True Course (TC) is toward the East, use the outer scale. If the TC is toward the west, use the inner scale. Aeronautical Chart Symbols The following are some of the other symbols also shown on the aeronautical charts. Airport Synbols The symbols in Magenta are airports without a control tower. Symbols in Blue have a Control Tower. Chart Symbols http://www.uncletom2000.com/gs/chartsym.htm (7 of 9) [1/23/2003 11:19:04 AM] Paved airport with a runway longer than 8096 feet Paved airport with longest runway less than 8096 feet. Un-paved airport Private airport Heliport Sea Plane Base Obstruction Symbols Obstruction symbols have two elevations shown near them. The one in BOLD letters (top number) is the elevation above mean sea level (MSL). The smaller numbers enclosed in parenthesis (bottom number) indicate the height above ground level (AGL). The symbols in the left hand column are less that 1000 feet AGL. The ones on the right are above 1000 feet AGL. Single Un-lighted Obstruction Lighted Obstruction Group of Obstructions Radio Navigation Beacons VHF OmniRange Beacon (VOR) A VOR is indicated on the chart as a compass rose. It is oriented toward Magnetic North, as indicated by the long arrow extending from the center to the zero degree mark. An information box near the VOR Compass Rose provides information such as the radio frequency, 3 letter Identification Code, and the morse code of the identifier. There is other miscellaneous data that may be contained in the box. There are 3 types of VOR Ranges. They are indicated at the center of the rose. Symbol A. VOR with no distance measuring capability. Symbol B. VOR-DME: A VOR with distance measuring capability. Chart Symbols http://www.uncletom2000.com/gs/chartsym.htm (8 of 9) [1/23/2003 11:19:04 AM] Symbol C. VORTAC: A VOR which has DME and military VORTAC capability. For more detailed information on the VOR, see Aeronautical Information Manual: Chapter 1-3 VOR Chapter 1-4 VOR Receiver Check Chapter 1-5 Military TACAN Chapter 1-6 VORTAC Chapter 1-7 Distance Measuring Equipment Non-Directional Beacon (NDB) A Non-directional Beacon is shown on the chart as a concentric series of Magenta colored dots, with the center of the circle being the location of the radio station. A magenta colored box near the circle shown the station name, the 2 or 3 letter station ID, and the morse code of the ID. This beacon is used by a navigation instrument in the aircraft called an "Automatic Direction Finder" (ADF). For detailed information, see Aeronautical Information Manual Ch. 1-2 NDB Back to Home Back to Table of Conents To Airport Information Chart Symbols http://www.uncletom2000.com/gs/chartsym.htm (9 of 9) [1/23/2003 11:19:04 AM] Airport Info Airport Information Runways There are a variety of runway types and markings. They range from sophisticated Instrument Landing System runways to small grass strips. The FAA has established a standard set of markings identifying the characteristics of the runway. Markings for runways are white. Markings on taxiways, closed or hazardous areas, and holding positions are Yellow. Runway Markings A number of standardized markings exist on the surfaces of paved runways. The runway markings identify whether the runway is equipped for Precision or Non-precision Instrument Approaches (IFR), or whether only Visual approaches are allowed (VFR). A combination of the following marking elements are used. · Runway Number Designation · Centerline Marking · Threshold marking · Aiming Point · Touchdown Zone · Side Stripes Runway Numbering Runway numbers and letters are determined based on the approach direction to the runway. The number is the whole number nearest one-tenth the magnetic azimuth of the runway centerline. For example, a runway with a magnetic heading from 035° through 044° is numbered 04. The third digit of the magnetic heading is dropped. The range of numbers is from runway 01 through 36. The letters “L”, “C”, or ”R” is added to the number to identify the runway as being the left, center or right runway respectively. At some very large airports, there may be one set of parallel runways on one side of the airport (say 27L and 27R). On the other side of the airport another set of runways may exist with just one number difference (28L and 28R). See AIM 2-31. AIRPORT MARKING AIDS for further information on airport markings from the Aeronautical Information Manual. Centerline Marking The runway centerline identifies the center of the runway. It is comprised of evenly spaced white line http://www.uncletom2000.com/gs/aptinfo.htm (1 of 14) [1/23/2003 11:19:06 AM] stripe and unpainted gaps.The centerline provides visual alignment during takeoff and landing. Runway Aiming Point Marker These markings are white rectangular line segments located on each side of the centerline, located approximately 1000 feet down the runway from the threshold. They serve as a visual aiming point for landing aircraft. Touchdown Zone Markers These markers are white stripes identifying the touchdown area of the runway. They are coded in groups of one, two and three rectangular bars, spaced 500 feet apart down the runway. The grouped bars are symmetrically placed on each side of the runway centerline. Threshold Markings They are longitudinal stripes located at the threshold end of the runway. There are usually eight bars, but wide runways may have a different configuration. They identify the beginning of the runway surface suitable for landing. Side Stripes These are continuous white lines along the edge of the runway to delineate the edge of the runway from surrounding terrain or other surfaces. Runway Types There are three types of paved runways. Each has a different set of markings. They are: · VFR Runways · Non-precision Instrument Approach Runways · Precision Instrument Approach Runways VFR Runways. The runway depicted is a "VFR" runway only; i.e. it has no Instrument Approach Procedure. Airport Info http://www.uncletom2000.com/gs/aptinfo.htm (2 of 14) [1/23/2003 11:19:06 AM] The runway threshold shown identifies a VFR only runway. It contains a runway number and an aiming point marker on each side. It may also contain threshold markings, fixed distance markers down runways long enough for jet aircraft (4000 feet and greater).. Yellow holding position lines occur on taxiways approaching the runway. Double solid yellow lines are on the “holding” side, and double yellow dashed lines on the runway side. There may also be a red holding sign with white runway numbers located at the hold line. Non-Precision Instrument Approach Runways A non-precision Instrument Approach runway, is one for which VOR or ADF instrument approach procedures are published and approved by the FAA. They do not have full Instrument Landing System (ILS) facilities. Runways with non-precision instrument approaches are similar to the VFR runway with the addition of threshold markings. Precision Approach Runway A precision Approach Runway is one equipprd with a full ILS capability. The precision approach runway markings exist on runways equipped with ILS approach or other precision approach methods. Besides the non-precision markings, additional markings exist. Airport Info http://www.uncletom2000.com/gs/aptinfo.htm (3 of 14) [1/23/2003 11:19:06 AM] · Touchdown zone marking · Line (ILS Hold Yellow lines) · ILS Hold Sign (white ILS on red background) Other Runway Markings A Number of markings are used to indicate unuseable runway and airport areas. These are: l Displaced Threshold l Unuseable Surface l Closed Runway Displaced Thresholds Some runways have displaced thresholds marked with white arrows leading to the threshold line. The area with the arrows maybe used for taxi and takeoff, but not for landing. On landing, the wheels of the aircraft should not touch the runway before crossing the lateral threshold line. There can be a number of reasons for the threshold displacement. The end of the runway may be too close to a road or other obstructions or hazards. The displaced area may not have sufficient runway strength to sustain the impact of landing aircraft. Unusable Areas Airport Info http://www.uncletom2000.com/gs/aptinfo.htm (4 of 14) [1/23/2003 11:19:06 AM] An area containing yellow chevrons depict areas that cannot be used either for taxi, takeoff or landing. Often they are older or inadequate runway sections or used as an over-run area. They may be at either the approach or over-run end of the runway. Closed Runway An X on a runway indicates the runway is closed. It has become dangerous due to structural or other reasons. Use may be hazardous. Taxiways Taxiways provide paved surfaces connecting the parking ramps to the runways. Their centerlines are marked with a continuous yellow line. If the edge of the taxiway is marked, two yellow lines 6 inches apart are used. See AIM 2-9. TAXIWAY LIGHTS for more information on taxiway lighting. VFR Holding Line Holding positions where aircraft must hold before crossing or entering the runway are marked by two dashed yellow lines nearest the runway, and two solid yellow lines are furthest from the runway. There may also be a white runway number on a red painted square located in front of the double solid lines. Do not cross until clearance is given by the tower at a controlled airport. At an un-controlled airport, do not cross the solid lines until all aircraft are clear of the runway, no aircraft is on final approach. When taxiing to a runway, do not cross the solid lines untilon final approach, and it is determined that takeoff can be performed safely. ILS Critical Holding Area

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At larger airports where ILS instrument approaches are being made, taxiing aircraft should hold at the ILS Holding position line. The lines are yellow in color. A red ILS Holding sign will be along side the taxiway at this point. If the tower has instructed you to hold at the ILS Holding Line you should not taxi beyond this point until cleared by the tower. Airport Signs See AIM 2-32. AIRPORT SIGNS for additional information on Airport Signs from the Aeronautical Information Manual. There are 5 types of signs used on airports. They are: · Mandatory Instruction Signs Airport Info http://www.uncletom2000.com/gs/aptinfo.htm (5 of 14) [1/23/2003 11:19:06 AM] · Location Signs · Direction Signs · Destination Sign · Runway Distance Remaining Signs Mandatory Instruction Signs These signs are White lettering on a Red background. Holding position signs are used on taxiways that intersect runways at a point other than at the runway end. Holding position signs are also located at the yellow hold line on the taxiway at the end of the respective runway. it may be necessary to hold aircraft at a position on the taxiway other than at the runway end. These holding points prevent interference with landing or departing aircraft. An ILS Critical Holding Area sign is used on taxiways serving a Precision Instrument Approach runway. It is used to hold departing aircraft farther from the ILS runway when instrument landings are in progress. It will be co-located with the ILS critical area taxiway marking. A No Entry sign is used on taxiways with “one-way” traffic only, or at intersection with roadways that could be confused for a taxiway. For further information on Mandatory signs, see AIM 2-33. MANDATORY INSTRUCTION SIGNS from the Aeronautical Information Manual. Location Signs Location signs are advisory in nature. They are yellow characters on a black background. They provide visual assistance to pilots in determining location on the runway or taxiway, and helps them determine when they have exited an area. · Taxiway Location Signs.
Alphabetic letters identifying taxiways. · Runway Identification Signs. This runway identification sign indicates the runway number on which the aircraft is located.. See AIM 2-34. LOCATION SIGNS from the Aeronautical Information Manual for further data. Direction Signs These are signs of a general informative nature. They show exits to runways, directions to parking ramps, etc. They are black letters or markings on a yellow background. Airport Info http://www.uncletom2000.com/gs/aptinfo.htm (6 of 14) [1/23/2003 11:19:06 AM] Taxi Boundary Sign This is a runway boundary sign, as seen by the pilot exiting a runway onto the taxiway. The aircraft is “clear” of the runway after it has taxied beyond this sign. ILS Critical Area Boundary Sign This is an ILS Area Boundary sign. When the aircraft is exiting the runway, it is “clear” of the ILS Critical Area when past this sign. The sign is co-located with the ILS Critical marking on the taxiway. Exit Signs Direction signs show how to exit from an intersection. When used on a runway to indicate an exit, the sign is on the same side as the exit. They are black letters on a yellow background. See AIM 2-35. DIRECTION SIGNS from the Aeronautical Information Manual for further information. Destination Signs These signs are black letters on a yellow background. They usually contain an arrow pointing to the destination, sych as General Aviation Ramp, Terminal, Parking Area, etc. See AIM 2-36. DESTINATION SIGNS for additional information on these signs. Information Signs General information signs have black characters on a yellow background. They provide the pilot of about such things as areas hidden from the control tower view, applicable radio frequencies, and noise abatement procedures. The airport operator determines the need, size and location for these signs. See AIM 2-37. INFORMATION SIGNS for further information. Runway Distance Remaining Signs Runway distance remaining signs have white numbers on a black background. They are placed along side some runways to indicate remaining runway in thousands of feet. See AIM 2-38. RUNWAY DISTANCE REMAINING SIGNS for additional information. Other Sign and Lighting Information Airport Info http://www.uncletom2000.com/gs/aptinfo.htm (7 of 14) [1/23/2003 11:19:06 AM] See Airport Markings Markings for runways and Taxiways. for additional FAA information about airport signs, markings and aids. Landing Indicators A number of different wind and landing indicators are in use at airports. Virtually all airports have one or more of these indicators. A segmented circle will be located near the center of the airport. The "L" shaped ears indicate landing pattern direction. The red cone is called a wind sock and indicates wind direction. The Tetrahedron (T) indicates the runway in use. It is usually manually set. Wind Indicators · Wind Sock - This is a cone shaped fabric indicator showing the wind direction. It also provides some measure of the wind velocity. The large open end of the cone faces the wind. Wind entering the open end fills the cone with air and it becomes more erect. The direction of the wind is from the large toward the small end of the cone. If the wind is calm, the cone will be limp. As wind velocity increases, the cone becomes more erect (in a horizontal direction). · Wind Tee - (not shown) This looks like a small airplane with a body, vertical tail fin, and a wing. It orients with the wind with the wing on the upwind side and the tail downwind. The direction of the wind tee suggests the landing direction. · If there is no wind indicator, observe smoke from factories, ground fires, etc. These will indicate wind direction. Also, the lee side of a lake (upwind direction) tends to be smooth. Landing Indicators A device called a Tetrahedron at some airports indicates the active runway. It is a pointed triangular shaped object shown in the diagram above as (T). One end configured in a long point (the front end). The rear end has a short, blunt triangular shape. Most are lighted to be visible at night. It is usually set into a Airport Info http://www.uncletom2000.com/gs/aptinfo.htm (8 of 14) [1/23/2003 11:19:06 AM] fixed position by the airport personnel to indicate landing direction. It does not necessarially indicate true wind direction. The pilot should not rely on a tetrahedron as a wind indicator. Some are fixed and are not free to swing with the wind. Segmented Circle A dashed circle known as that Segmented Circle ( shown below) is located in a position near the center of the airport. A wind cone, a tetrahedron or wind tee will be contained inside the circle. Outside the circle are landing traffic pattern indicators (the “L” shaped objects). Assume that there are 2 runways at this airport; one 9 - 27 (East/West) and the other 18 - 36 (South/North) The tetrahedron is set to indicate landing on runway 9 to the East. The wind cone indicates the wind from the Southeast. The pattern indicators show the required direction of flight on the Base and Final legs of the approach to the runway. Departure flight pattern is defined by the pattern indicator for the departure end of the runway. The traffic pattern indicators specify a left hand pattern for runways 9 (landing east shown by the indicator at the left) and 36 (landing north shown by the indicator at the bottom). The other indicators specify a right hand pattern for runways 27 (landing west as shown by the indicator on the right) and 18 (landing south as shown by the indicator on the top) Traffic Pattern The pattern of traffic around a non-controlled airport is as shown below. Airport Info http://www.uncletom2000.com/gs/aptinfo.htm (9 of 14) [1/23/2003 11:19:06 AM] An aircraft taking off eastward on runway 9 and staying in the traffic pattern will turn Crosswind (position 5) at approximately 400 feet above the runway, then Downwind to fly parallel the runway as shown at number 2 at an altitude approximately 800 feet above the runway. (Note: Some airports designate the pattern altitude to be 1000 feet.). Then when past the end of the runway will turn to Base between positions 2 and 3, while descending. The aircraft will the turn to Final at position 3. This is known as a Standard Left Hand Pattern. Also, according to the pattern indicators, a pattern for runway 36 is left hand. The downwind leg is on the west side of the airport, with all turns to the left. The pattern indicators indicate landings on Runways 27 and 18 are right hand patterns. The downwind leg for runway 27 is north of the airport, with all turns to the right. Landing on 18, the downwind leg will be west of the airport, with all turns to the right. Aircraft outside the pattern should enter the pattern approximately at mid point of the airport at a 45° angle to downwind (position 1). Aircraft leaving the traffic pattern should depart anywhere from “straight out" (position 6) to “crosswind” (position 5. A right turn departure from a left hand pattern is prohibited. At airports with parallel runways, left hand pattern is used on the left runway; a right hand pattern is used on the right runway. Traffic patterns at controlled airports with an operating control tower follow generally the same procedures. However, since the tower controller is responsible for traffic separation within the tower jurisdiction, the controller may grant or require other procedures. In all cases, except emergency, obey the controllers' instructions. The traffic pattern at tower-controlled airports is usually 1000 feet Above Ground Level (AGL). Airport Lighting Runway Lighting Airport Info http://www.uncletom2000.com/gs/aptinfo.htm (10 of 14) [1/23/2003 11:19:06 AM] A lighted airport has runway lights situated on both sides of the runway. Some systems are able to operate at High (HIRL) Medium (MIRL) and Low (LIRL) intensity. Many airports have the lighting off during certain night hours, and the pilot must make active by clicks of the microphone. The intensity of HIRL and MIRL runway lights can be controlled by personnel on the ground. The pilot can control the intensity by clicking the microphone on the published Common Traffic Advisory Frequency (CTAF) for the airport. It takes 7 clicks to turn lights to high, 5 to medium, and 3 for low. Some airports may only provide medium and/or low brightness. At large airports, there may also be high intensity centerline lighting. Some precision instrument runways have edge touchdown zone lights for the first 3000 feet of runway. These are transverse light bars on each side of the runway. These runways also have yellow end zone lights for the last 2000 feet. The end zone lights are yellow only to the pilot from the landing direction. They appear white from the opposite direction. For further information on runway lighting, see AIM 2-4. RUNWAY EDGE LIGHT SYSTEMS AIM 2-5. IN-RUNWAY LIGHTING AIM 2-6. CONTROL OF LIGHTING SYSTEMS AIM 2-7. PILOT CONTROL OF AIRPORT LIGHTING Taxiway Lighting Taxiways edge lights are blue, and are on at night and during the day at times of reduced visibility. At larger airports, the tower personnel can control the intensity of the lights. Also, some taxiways may have imbedded green lights along the centerline of the taxiway. They are on during times of reduced visibility to mark the way between the runways and ramp areas. Approach Lighting There are numerous approach light systems at large airports with Instrument Landing Systems. These are beyond the scope of the beginning private pilot, and will not be addressed in detail in this material. For information on these systems, see AIM 2-1. APPROACH LIGHT SYSTEMS (ALS) Several approach light systems are of interest to the VFR pilot. These are: · Runway End Identifier Lights (REIL) · Visual Approach Slope Indicators (VASI) · Precision Approach Slope Indicators (PAPI) Runway End Identifier Lights (REIL) Airport Info http://www.uncletom2000.com/gs/aptinfo.htm (11 of 14) [1/23/2003 11:19:06 AM] REIL’s at many airports provide rapid and positive identification of the approach end of a runway. The system consists of a pair of synchronized high intensity flashing lights located on either side of the runway. They are particularly useful when the runway is surrounded with many other lights, in poor visibility conditions, and when the runway lacks contrast with the surrounding terrain. They may be omnidirectional, or may be focused toward the final approach path from the end of the runway. See AIM 2-3. RUNWAY END IDENTIFIER LIGHTS (REIL) for more information. Visual Approach Slope Indicators (VASI, PAPI) There are several forms of VASI’s. All employ lights that indicate a correct slope(s) for approach to landing. They may be used both for day and night operation. They provide an “on slope” glideslope angle of approximately 3°. The 2 bar VASI has 2 ranks of lights. Each rank may consist of one light or two lights side by side. You are “on glide slope” as shown in the center diagram (red over white). You are too high if both ranks are white, as on right. You are too low then both ranks are red as shown on left. The 3 bar VASI has 3 ranks of lights, The two center show “on glide path” indications. The leftmost is a low path, and the rightmost is a high path. The all red is too low. The all white indication is too high.

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Another approach slope indicator is the Precision Approach Path Indicator (PAPI). The system provides a more precise glideslope indication than does VASI. When all 4 lights are white, you are too high. When all are red, you are too low. When 2 are red and 2 are white you are on a 3° path. Three white on the left indicate a path of 3.2°. Three red on right indicate a 2.8° path. The open clear circles indicate white. The darkened circles indicate red. The Tri-Color system is a single light that projects 3 colors. The above glide path indication is amber. On glide slope is Green. Below glide slope is red. When the aircraft descends from green to red, the pilot may see amber during the transition. There is a similar system called the Pulsating Visual Approach Slope Indicator.(Not shown). It is somewhat similar to the Tri-color except a solid white indicates on glide path; steady red on a slightly low path. Pulsating white indicates too high. Pulsating red means too low. See AIM 2-2. VISUAL GLIDESLOPE INDICATORS for additional information from the Aeronautical Information Manual. Airport Beacons Rotating beacons which operate at night and during times of poor weather assist the pilot to locate the airport from the air. Airport Info http://www.uncletom2000.com/gs/aptinfo.htm (12 of 14) [1/23/2003 11:19:06 AM] See AIM 2-8. AIRPORT (ROTATING) BEACONS for information on rotating beacon operation. Wake Turbulence All aircraft generate some turbulence, called Wake Turbulence. The turbulence from small aircraft is of little consequence. When the size and weight of the aircraft are great, the turbulence can be severe to other aircraft. Cause A number of factors contribute to wake turbulence. These are slipstream turbulence, jet blast, propeller wash, and wingtip vortices. The most severe of these disturbances is Wingtip Vortices. To over simplify, they are small tight horizontal tornadoes of air leaving the wing tips. The turbulence is a byproduct of the wing creating lift. A pressure differential is created between the upper and lower surface of the wing. The low pressure is on the upper surface. This pressure differential creates a rolling airflow at the wing tip inward toward the fuselage. The ritating air mass trailis rearward. he right vortex rolls counterclockwise; the left vortex is clockwise. Vortex Avoidance Wingtip vortices have certain predictable characteristics. A large aircraft generates vortices from the moment of takeoff rotation. Takeoff rotation causes significant vortex. In flight, the sink rate of the vortices is 400 to 500 feet per minute, and levels out 900 to 1000 feet below the aircraft. Near the runway surface, a tailwind can cause the vortex to persist near the ground for several minutes if the wind is light. Large heavy aircraft generates significant vortex on landing. It has a high angle of attack of attack, and is slow and heavy. The point of greatest wing loading and vortex is the flare to touchdown. This is due to additional wing load caused by centrifugal force generated in the flare. When operating on and near large airports with large aircraft operations, caution concerning wake turbulence must be observed. The strength of the wingtip vortices is greatest then the aircraft is HEAVY, CLEAN and SLOW. The greatest hazard to small aircraft is coming across a vortex while operating near the ground. Each vortex is about 2 wingspans in width and one wingspan in depth. They remain spaced about one wingspan apart, drifting with the wind. In a no-wind situation, the vortices will persist on the runway. They move laterally outward about 2 to 3 knots on each side when striking the ground. Airport Info http://www.uncletom2000.com/gs/aptinfo.htm (13 of 14) [1/23/2003 11:19:06 AM] A cross wind will add or subtract from the natural 2 - 3 knot lateral movement of each vortex. With a light crosswind component of about 3 knots, the upwind vortex can persist for a considerable time. The vortex movement and the opposing crosswind oduce a stationary vortex. STAY ABOVE AND UPWIND FROM THE VORTEX. . Plan your strategy accordingly. 1. When landing on the same runway behind a large aircraft, stay at or above the larger aircraft’s approach path. Note the touchdown point, and plan to land beyond that point. 2. If landing on a runway parallel to and within 2500 feet of one being used by a large aircraft, use the same procedure as in 1 above. 3. If landing on a runway crossing the larger aircraft’s runway, cross the other runway above the large aircraft’s flight path. 4. Land well short of a large departing aircraft’s rotation point. 5. If a large aircraft is departing a crossing runway, note the rotation point of the large craft. · If rotation is past the intersection, continue to land as you would normally. · If it rotates before the intersection, avoid flight below the aircraft’s flight path. Execute a missed approach unless you are sure you can stop well before the intersection. 6. If departing behind a departing large aircraft, note the rotation point of the departing aircraft. Become airborne before the rotation point, and stay higher and upwind of the larger aircraft’s flight path. If unable, request the control tower for a change in flight direction away from the path of the larger aircraft. 7. If you takeoff at an intersection, be cautious that your departure path will not cross under the path of a larger aircraft. 8. You should ensure an interval of at least 2 minutes before takeoff or landing across or behind the path of a large aircraft that has executed a low pass, touch-and-go, or a missed approach. 9. Avoid flight below the path of a larger aircraft when enroute at altitude. Try to stay above or upwind of larger aircraft near your altitude. See the Aeronautical Information Manual Wake Turbulence for further information. Other Airport Operations Data AIM Chapters Aeronautical Information Manual by Chapter. Back to Home Back to Table of Conents Methods of Navigation Airport Info http://www.uncletom2000.com/gs/aptinfo.htm (14 of 14) [1/23/2003 11:19:06 AM] Navigation Navigation Navigation is the procedure by which the pilot flies from one point to another. A single method of navigation is rarely used by the pilot operating under Visual Flight Rules (VFR). There are several methods of navigation in use today by the VFR pilot. Methods of Navigation The principal methods of navigation used today by light aircraft are: l Dead Reckoning l Pilotage l VOR l ADF l LORAN l GPS Dead Reckoning This is the primary navigational method used in the early days of flying before adequate aeronautical charts and electronic navigation were available. It is the method on which Lindberg relied during his first trans-Atlantic flight. It is based on Time, Distance, and Direction only. The pilot must know the distance from one point to the next, the magnetic heading to be flown, and have some idea of the effects of the winds expected to be encountered during the flight. It is the most fundamental aspect of VFR flight. Even in todays environment, the pilot should prepare a basic planning log of check points along the route of flight. This planning log should include such data as True Course (TC), Distance, anticipated wind drift (or wind correction angle), estimated ground speed and magnetic heading by which to steer. This data should be measured, or in some cases estimated, for each leg of the flight. The purpose for this log is to allow the pilot to estimate the time and heading for each leg, and to make minor corrections to the plan for the next leg based on the experience of the previous leg. A sample flight planning log will be demonstrated later in this section. Pilotage Pilotage is the art of following an aeronautical chart to fly from one point to another. True pilotage may not always follow straight lines for long distances, but rather may follow terrain features such as rivers, coastlines, mountain ridges, roads, railroads, etc. The pilot is relying on the recognition of major features shown on the chart, and correlating them to what is seen below.. The pilot may keep a primitave log of checkpoints, or may even write the time directly on the chart as prominant features are passed over. During training, instructors will usually train student pilots to navigate over a course of 50 to 100 miles, using a combination of dead reckoning and pilotage. This type training is important for later use, since electrical and http://www.uncletom2000.com/gs/navigate.htm (1 of 10) [1/23/2003 11:19:08 AM] electronic navigation equipment may occasionally malfunction. The experienced pilot should be able to fly relatively long distances using a combination of these two basic methods. Even when using electronic means of navigation, it is a good procedure to also utilize dead reckoning and pilotage procedures in addition to the electronic instruments. VOR Navigation The principal electronic navigational system in use today is the VHF Omni-Range (VOR). This navigational method relies on a system of ground-based transmitters which emit signals that a VOR receiver can interpret. The VOR receiver can use the signal emitted by a selected ground station to arrive at an azimuth reading from the station. This azimuth FROM the station is called a RADIAL of the VOR. Another way to envision the VOR radial is to think of a wagon wheel with 360 spokes. One is called 360 (representing Magnetic North). The others are numbered 1 through 359. If a fly lands on spoke 37, the fly is on the 037° RADIAL of the wheel. It makes no difference which way the fly is headed. He can turn adound in a complete circle; but as long as he stays on the same spoke, he is on the 037° radial. The diagram below demonstrates an aircraft (#1) flying on a Victor Airway (V54) whose outbound radial from VOR (A) is 095°. The VOR instrument shown on the bottom of the diagram is called a Omni Bearing Selector (OBS) (the ADJ knob and numbers on top and bottom) and then Omni Bearing Indicator (OBI) comprised of the needle, white dots and Yellow/Blue arcs and the TO/FROM flags.. When the needle of the instrument is centered, and the FROM FLAG is showing (is WHITE), the radial is indicated by the marks and numbers at the top of the instrument Navigation http://www.uncletom2000.com/gs/navigate.htm (2 of 10) [1/23/2003 11:19:08 AM] To fly an outbound radial of 095°, rotate the selector knob labled ADJ until the needle centers and the FROM (white) flag is showing. When this is achieved, you are on the 095° radial of VOR (A). Note that the heading of the aircraft has no effect on the presentation of the instrument, or the radial you are on.. The radial and the instrument presentation of aircraft #2 and #3 are the same as aircraft #1. When you are about half way to VOR B, you can tune the same ( or a second) VOR receiver to the frequency of VOR B. Again, you will rotate the ADJ knob (if necessary) in order to center the needle: but this time you want the TO FLAG to be showing (WHITE) since you are flying TO station B. As you pass over station B, you will encounter a zone of indecision. The needle may swing wildly from one side to the other, and both the TO and FROM flag will be off (dark). Note in the diagram above, you will want to start tracking the 110° outbound from station B. When the FROM flag shows white, turn the aircraft to the new heading of 110° and rotate the ADJ knob until the 110° mark is under the selector arrow. You may need to turn a few degrees more until the needle centers, then track the 110° outbound radial. The VOR station makes a good checkpoint. Not only do you get the "station passage" indication on the OBI, but you can visually see the VOR ground station in good visibility conditions. It is a low building with a truncated cone on the top, which houses the antenna. The truncated cone is fiberglass and white in color. Whenever you tune the VOR receiver to a new station frequency, you should always turn the VOR receiver volume up to hear the 3 letter morse code identifier. The dots and dashes are shown in the VOR identification box near the VOR compass rose. Some stations may have voice identification in lieu of the Morse code. In this case, the full name of the VOR is spoken. See the VOR OmniRange description in the previous section titled Chart Symbols to review the how the station frequency, name, ID and morse code is indicated on the charts. For additional information on VOR operation, see the Aeronautical Information Manual chapters for further information on VOR, TACAN and VORTAC stations. AIM 1-3. VHF OMNI-DIRECTIONAL RANGE (VOR) AIM 1-5. TACTICAL AIR NAVIGATION (TACAN) AIM 1-6. VHF OMNI-DIRECTIONAL RANGE/TACTICAL AIR NAVIGATION (VORTAC) Correcting for Wind Drift Seldom when flying a course will the pilot encounter a "no wind" condition. Wind will always add or subtract from Indicated Airspeed to create a different speed across the ground called Ground Speed (GS). Wind will also drift you off course. The OBS Selector (your radial) indicates the Magnetic Course (say 095°) that you want to fly over the ground. Seldom will the wind allow you to track your radial without making some correction to the left or right. The wind, will drift you off course, either to the left or right of your radial. The OBI needle will start drifting to the left or right rather than staying centered. If you are flying the 095° radial from VOR A for example, and the needle drifts right, it means the wind is blowing from your right ( South ), thus drifting you off course to the left. The needle always points in the direction toward which you need to make correction in order to get back on the selected radial. Take the 095° radial for example. After flying for a while holding a steady 095° heading on the compass (Magnetic Heading Navigation http://www.uncletom2000.com/gs/navigate.htm (3 of 10) [1/23/2003 11:19:08 AM] MH) you see the needle has drifted to first dot on the right. This first dot represents a 5° deviation from the radial. What do you do to correct for the wind drift, and get back on course? If you said, change the OBS to 100°, WRONG!. Do not change the OBS, because that is the Magnetic Course (MC) of 095° is what you want to track over the ground.

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Rather , change your magnetic heading to the right, say 10°, to a MH of 105°. Hold that for a while. If the needle drift ceases (it steadies), you are now flying parallel to your course, but to the left of course. You now need to get back on course, so take another 10° correction to the right (now a 20° total correction) to a MH of 115°. When the needle comes back to center, you are back on the desired radial. Now remove that last 10° correction (i.e. come back to a Magnetic Heading (MH) of 105°). That should now hold you approximately on the 095° radial by holding a 10° right Wind Correction Angle (WCA) (i.e. holding a 105° MH on the compass). However, if the initial 10° R WCA fails to stop the needle from drifting right, increase the WCA to 20° R (MH=115°). If the needle steadies, increase the MH to 120-130° to get back on course, then hold a 20° WCA (MH=115°). Maintain this for a while to see if that holds the needle centered. Continue to make this type of correction, left or right until you have the correct WCA pinned down to hold you "on course" with needle remaining centered. Usually when flying cross country, you do not make large radial changes; so the WCA you held on the last leg should be close to appropriate for the next leg. After some practice, you will be able to estimate the WCA fairly quickly by watching how fast the needle drifts from center. Testing the VOR Indicator for Accuracy Generally, the accuracy of the VOR is within one degree. However, due to age or other factors, the error may increase. The accuracy of a VOR receiver can be checked several ways. · FAA VOR Test Facilities (VOT) · Airborne Check Points · Ground Check Points The Airport/Facility Directory is a document describing all public airports and navigational facilities. It can be purchased at most airports and pilot supply stores for a nominal fee. This document lists certified checkpoints that may be used to check VOR Receiver accuracy. These are selected ground or in-flight checkpoints which have a known radial bearing from the specified VOR. The FAA VOR Test facility is called a VOT. These facilities are usually found at larger airports. It is a special test facility which can be tuned while on the ground at the airport. When you tune the VOT frequency, you will hear a series of dots, or a steady tone as the VOT identifier. Turn the OBS until the CDI centers. The course indicator should read either 0° or 180°. If 180°, the flag should be TO. If the OBS reads 0°, the flag should be FROM. The OBS reading must be accurate to +/- 4 degrees for ground based checkpoints and +/- 6° for airborne checkpoints.. For mor information on VOR testing procedures, consult AIM 1-4. VOR RECEIVER CHECK Using VOR Intersections Navigation http://www.uncletom2000.com/gs/navigate.htm (4 of 10) [1/23/2003 11:19:08 AM] You can determine your position by using a radial readin receiver to one of the stations. Rotate the OBS knob u station. Draw a line from the center of the the VOR com of the compass rose). Now do the same for the radial re position at the time the readings were made. For best In the example, you read a radial of 150° from the top VOR, and 060° from the lower VOR. By drawing lines on the chart representing these radials, you are at the intersection of the lines. Often, where Victor Airways cross, the intersection will be indicated on the chart by crossed arrows and an intersection name. Distance Measuring Equipment (DME) VOR/DME and VORTAC stations provide distance information for aircraft equipped with Distance Measuring Equipment (DME). DME operates in the UHF radio band on frequencies from 962 MHz to 1213 MHz. Whenever you tune the VOR station frequency, the DME receiver automatically selects the correct UHF frequency. This is called “paired frequency selection”. The pilot need not be concerned with the UHF frequency. Some DME systems can also be “slaved” from a normal VOR receiver, so that the DME automatically operates on the VOR station selected by the VOR receiver. Tuning a DME receiver is similar to tuning the VOR receiver; i.e. the frequency of the VOR is selected on the DME tuner dials. The DME unit uses a “shark fin” appearing antenna, normally mounted underneath the aircraft. The aircraft DME unit sends an interrogation signal to the VOR/DME or VORTAC station. The ground station then transmits a responding signal. The DME unit measures the time elapsed between sending the interrogating signal and receipt of the response signal. From this information, the DME unit calculates the distance to the station. Some units also calculate groundspeed and “time to the station”. However, GS and time to the station are only valid if you are flying directly to or from the station. If you are flying in any other direction, these values will be incorrect. However, the distance to the station will be correct. The indicated distance is known as are some distance from the statio distance will be very close to the g VOR station, the slant range error Navigation http://www.uncletom2000.com/gs/navigate.htm (5 of 10) [1/23/2003 11:19:08 AM] For example, if you are flying at 6000 feet, the DME will register 1 NM to the station when you are directly over the station. See the Aeronautical Information Manual AIM 1-7. DISTANCE MEASURING EQUIPMENT (DME) for further information. Automatic Direction Finder (ADF) Some aircraft are equipped with an ADF receiver. See the Aeronautical Information Manual AIM 1-2. NONDIRECTIONAL RADIO BEACON (NDB) for more information. They receive radio signals in the medium frequency band of 190 Khz to 1750 Khz. The ADF receiver can “Home” on both AM radio stations and Non- Directional Beacons. Commercial AM radio stations broadcast on 540 to 1620 Khz. Non-Directional Beacons (NDBs) operate in the frequency band of 190 to 535 Khz. The aircraft equipment consists of two antennas, the ADF Receiver, and the ADF Instrument. The two antennas are called the (1) LOOP antenna and the (2) SENSE antenna. The loop antenna can sense the direction of the signal from the station, but cannot discriminate whether the station is in front or behind the aircraft. The sense antenna can discriminate direction, and solves the ambiguity of the loop antenna. The receiver unit has tuning dials to select the station frequency A volume control allows the audible volume to be controlled for identifying the station. The volume can be reduced to prevent interference with other communications. You should, however, continuously monitor the identifier while using the NDB for navigation. The navigational display contains a compass rose dial gr end, and a square form on the other end. We will call the ar identification. There are 2 types of compass rose dials that can exist in the navigational unit. One is a fixed compass rose, called a “Fixed Card” ADF. Zero degrees is always shown on top of the card. The “Rotateable Card” ADF allows the compass rose card to be rotated. Interpretation of these displays will be more fully described in later paragraphs. Non-Directional Beacon (NDB) Non-Directional Beacons are depicted on aeronautical charts as a the name of the station, the 2 or 3 letter identifier, and the Mors NDBs may be located on the surface of airports, or may be within a few miles from an airport. Sometimes they are co-located with the Outer Marker in ILS approaches. The NDB provides two principal functions; (1) homing for VFR operations, and (2) ADF instrument approach capability for IFR operations. Because the frequency is below and within the commercial AM band, reception is subject to the same atmospheric disturbances as AM radio, in particular, noise generated by lightening. Navigation http://www.uncletom2000.com/gs/navigate.htm (6 of 10) [1/23/2003 11:19:08 AM] ADF Orientation The pointer end of the ADF navigation unit ALWAYS POINTS TO THE STATION. The degree reading on the display is dependent on the aircraft heading. In the diagram if the heading of the aircraft changes, the arrow will always point to the station and the degree reading on the instrument which the pointer indicates also changes.. Fixed Card ADF The relationship of the aircraft to the station elements to determining MB. One is the Relative Magnetic Heading (MH) of the aircraft. This rel MB (to the station) = RB + MH In the example, the MH of the aircraft is 270° as read on the compass. The RB read from the ADF dial is 45° . Therefore the MB to the station = 270° + 45° = 315°. This equation applies to any problem on the FAA Written Exam relating to the Fixed Card ADF. If any two values are known, the third can be computed. Moveable Card ADF Some aircraft are equipped with an ADF instrument in which the dial face of the instrument can be rotated by a knob. This is called a Moveable Card ADF. By rotating the card such that the Magnetic Heading (MH) of the aircraft is adjusted to be under the pointer at the top of the card, the Bearing to the Station (MB) can be read directly from the compass card. More sophisticated instruments of later design automatically rotate the compass card of the instrument to agree with the magnetic heading of the aircraft. Thus MB to the station can be read at any time without manually rotating the compass card on the ADF face. Area Navigation Three types of navigation receivers can be called Area Navigation. They are: · RNAV · LORAN · GPS RNAV This type of navigation allows a pilot to fly a selected course to a predetermined point without the need to overfly Navigation http://www.uncletom2000.com/gs/navigate.htm (7 of 10) [1/23/2003 11:19:08 AM] ground-based navigation stations. Flight can be from waypoint to waypoint. A waypoint is a position determined either by Latitude/Longitude or Radial and distance from a VORTAC or VOR/DME station. These navigation receivers use VOR/DME or VO distance along a radial of the VOR. The RNAV eq the waypoint position. You then fly the VOR as location.

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Through triangulation, the navigation unit measures the radial and distance of leg A. By knowing the entered data for leg B, the azimuth and distance to the waypoint along path C is repeatedly calculated calculated. It is as though the VOR were located at the waypoint position. Long Range Navigation (LORAN) LORAN operates on the principle of time meas transmit a synchronized pulse. The time diff pulses is measured. From this data, the com within 0.25 Nm or better. The North East LOR facilities can be loaded into the memory of th The LORAN unit can indicate: · Present Position - in Latitude/Longitude and/or relative to a destination, waypoint or checkpoint. · Bearing and distance to your destination. · Groundspeed and estimated time enroute. · Course Deviation Indicator. Navigation http://www.uncletom2000.com/gs/navigate.htm (8 of 10) [1/23/2003 11:19:08 AM] · Storage in memory of all US airports, pilot selected fixes, minimum enroute and obstruction clearance altitudes, and Class B and C airspace warnings. · Continuous computation of bearings and distances to the nearest airports. Computation of wind direction and velocity. · Add ons, such as fuel flow analyzers to estimate fuel needed to reach destination and alternates; ELT’s to transmit exact location of ELT. · Add-on programmable and updatable databases. Since LORAN operates on a low-frequency signal, it is subject to the same disturbances that AM radio sustains. It is possible to loose signal when operating near thunderstorm and in heavy rain areas. The LORAN receivers know the frequency of the Master and secondary stations; no tuning by the pilot is necessary. For more technical data about LORAN see, Loran C General LORAN Information. Also see Aeronautical Information Manual AIM 1-17. LORAN Global Positioning System (GPS) The GPS system is the latest in technology that can be used by aircraft. It has many of the attributes of LORAN. The complete system will contain up to 21 satellites in earth orbit. The "clocks" and "positional data" is updated periodically to insure accuracy of the data from the satellites. It sense 4 or more satellites in orbit. The system is maintained by the US Department of Defense. See an GPS Overview Pictoral for a general concept of the GPS system. See GPS Constellation to see the satellite orbits. Like LORAN, it operates on a time-based methodology. Each satellite transmits coded pulses indicating it’s position, and the precise time the pulses are sent. The GPS unit listens to the satellite’s signal, and measures the time between the satellites transmission and receipt of the signal. By the process of triangulation among the several satellites being received, the unit computes the location of the GPS receiver. Not only can Latitude and Longitude be calculated, but altitude as well. See Geodetic Coordinate System for a pictoral showing how the GPS system can indicate these 3 parameters of LAT, LON, and HEIGHT. Like LORAN, the GPS unit contains data about all the commercial airports in the US, including runway lengths, directions, and location. There are numerous forms of display among the various manufacturer. The units can range from “hand held” to “panel mount” with altitude information input from an encoding altimeter. They can warn of Class B, C, and Prohibited and Restricted airspace. They can calculate direction and time to nearest suitable alternate airports in event of emergency. The database in most units can be updated via a connection to a Personal Computer. The maximum error is within 100 meters (0.05 Nm). Work is in progress to give the GPS system adequate precision for instrument approaches. No frequency tuning is required, as the frequency of the satellite transmissions are already known by the receiver. Work is currently underway to provide sufficient accuracy for use of GPS for instrument approaches. For more technical data on GPS, see: Navigation http://www.uncletom2000.com/gs/navigate.htm (9 of 10) [1/23/2003 11:19:08 AM] AIM 1-23. GLOBAL POSITIONING SYSTEM (GPS) GPS Back to Home Back to Table of Conents To Flight Planning Navigation http://www.uncletom2000.com/gs/navigate.htm (10 of 10) [1/23/2003 11:19:08 AM] Flight Planning Flight Planning When planning a cross country flight of any distance, the pilot is required by Federal Aviation Regulations to have knowledge of the destination airport, fuel requirements, estimated time enroute, weather expected along the route and destination, and any other information which may affect the safety of the flight. The pilot should get a thorough weather briefing from a Flight Service Station (FSS), and the filing of a flight plan for VFR flight is strongly recommended. This section will cover the time, distance, groundspeed, heading, and fuel required aspects of the flight planning proccess. Basic Parameters The planning log must address several factors: l Selection of Ckeckpoints l Distances l True Course l Magnetic Variation l Magnetic Course l True Heading l Magnetic Heading l Wind Correction l Ground Speed l Time Enroute l Fuel On-Board l Fuel Duration l Fuel Consumption Definitions Checkpoints The pilot should determine the type of navigation to be used; Pilotage, VOR and/or Victor Airways, LORAN, GPS, etc. From that information, the pilot should establish checkpoints over which the flight is to pass. They may be prominent landmarks, VOR's, RNAV, LORAN or GPS waypoints. It is suggested for small slow speed aircraft that these checkpoints be within reasonable distances, say 50 Nm or so. Distances shorter than this requires a lot of record keeping for long flights. Distances much longer than this does not allow the pilot to verify actual performance versus the plan sufficiently often enough. Generally a checkpoint every 30-40 minutes is a suitable procedure for the experienced pilot. The pilot should plot the Course of flight by drawing lines on the chart from checkpoint to checkpoint. It's like drawing your roadway in the sky which you plan to follow. These checkpoints should be written on the flight http://www.uncletom2000.com/gs/fltpln.htm (1 of 7) [1/23/2003 11:19:10 AM] planning log in the Check Point column of your planning log. An example flight is illustrated below. The flight is a simple one which a beginning student may be asked to fly. It is a triangular course, from SVH, LEX, 3N8, and back to SVH. You will note later that the wind will have a different effect on ground speed and headings for each leg. Note: This flight will be used as the basis for planning a simple flight and the associated flight planning log. A simple example log is shown below to demonstrate the basic values to be determined. This is a sample log designed by the author for teaching purposes only. There are numerous commercially prepared log forms on the market. You can purchase them at most airports and pilot supply shops. Flight Planning http://www.uncletom2000.com/gs/fltpln.htm (2 of 7) [1/23/2003 11:19:10 AM] You will note that there are a number of items of information whick the pilot must consider: l Basic Information m Date m Winds Aloft - Get from Winds Aloft Forecast m True Airspeed (TAS) - Get from Pilot Operating Handbook See -- Cruise Performance for an example table. m Fuel Use (gph) - Get from Pilot Operating Handbook See -- Cruise Performance for an example table. m Fuel on Board - Based on refueling records l Course Data m Leg Distances - From the chart - See -- Measuring the distance m True Course (TC) - From the chart -- See - Measuring the course Note: COURSE always refers to the "track over the ground". m Wind Correction Angle (WCA) - Calculated m True Heading (TH) - Calculated Note: HEADING always refers to the "direction in which the nose of the aircraft is pointed". m Magnetic Variation (VAR) - From the chart See -- Magnetic Variation m Magnetic Heading (MH) - Calculated l Time, Distance, Ground Speed, Fuel Computation m Calculate Ground Speed (GS) using E6B Computer (Wind triangle) m Use GS and Distance to calculate leg Time m Use Leg Time and Fuel Flow to calculate Fuel Used m Calculate Estimated Time of Arrival (ETA) to next check point. m Calculate Cumulative Time Enroute and Fuel Used.

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Flight Planning http://www.uncletom2000.com/gs/fltpln.htm (3 of 7) [1/23/2003 11:19:10 AM] Filling out the Planning Log Heading Information l Obtain Winds aloft data from pre-flight briefing by a Flight Service Station for the expected flight time. l Consult the Pilot Operating Handbook for estimated Fuel consumption and TAS figures. l If you know fuel amount on board, calculate flight duration from the POH. Winds Aloft Winds aloft are forecast by the Weather Bureau for numerous regions in the U.S. At the levels at which small aircraft fly, the forecasts will give wind direction and velocity in Kts. for 3, 9, and 12 thousand feet. You use the wind forecast nearest the altitude which you plan to fly to calculate whe wind drift you expect to encounter. This calculation also derives an estimated Ground Speed which you will use in further calculations. The Wind Correction Calculations are covered later. True Airspeed and Fuel Consumption Consult the Pilot Operating Handbook for the aircraft to be flown to determine the power setting you plan to use at the planned flight altitude. See -- Cruise Performance for an example table. From the cruise performance table for the aircraft you should be able to derive estimated TAS and Fuel Consumption in gph. You will later use this TAS to calculate both the estimated WCA and Ground Speed. You will use the fuel consumption figure (gph) to calculate the estimated fuel consumption for each leg. Course Planning Information Identify each checkpoint on the chart in some way. It may be a number, an airport name, a VOR name, or city, etc. Write the identification of the each checkpoint in the CHK PT column of the log. Note that the checkpoint lines are not aligned with the other lines in the blank log form shown above. In our example, our checkpoints are: CHECK POINTS CHK PT SVH LEX 3N8 SVH Distance Flight Planning http://www.uncletom2000.com/gs/fltpln.htm (4 of 7) [1/23/2003 11:19:10 AM] Measure the distance as shown in Measuring the distance . Enter the distance in Nautical Miles (preferred) in the DIST column for each leg. DIST 32 31 26 True Course Using the plotter, measure the TC for each leg, using the example in - Measuring the course example. True Course is always measured in relation to a Longitude Line on the chart ( i.e. relative to True North). Enter the TC for each leg in the TC Column. Compentating for Wind In order to keep being blown "off course" by the wind, you probably will have to maintain a heading to either left or right of course to stay on track(TC). This requires that you calculate a Wind Correction Angle (WCA) in order to stay on track. You can use a manual or electronic E6B Flight computer to compute the WCA. Obviously, when you are riding in a moving air mass, the wind will tend to drift you "Off Course" from your intended ground track. A Graphical Illustration of WCA Shown below is a graphical illustration of calculating WCA. Flight Planning You want to fly a True Course (TC) of 360°. The wind is from 290° at 20 Kts. Obviously the aircraft will drift right and off course unless a correction is made. The problem can be solved graphically. On paper, draw a TC line at 360°. Draw a wind vector to some scale (line B-A) at 290° and 20kts http://www.uncletom2000.com/gs/fltpln.htm (5 of 7) [1/23/2003 11:19:10 AM] Flight Planning according to your scale. Draw a TAS line to the same scale from point B to intersect the TC line at point C. In this example TAS = 100 kts. You have now constructed a Wind Triangle. The Wind Correction Angle (WCA) is the angle between line B-C and A-C. In this example it is 10° L. The Ground Speed is line A-C, which measures 90 Kts. It is obvious from this triangle, you have a 10 knot headwind, and must steer a heading 10° to the Left. Therefore to convert your True Course (TC) over the ground to a True Heading (TH) to which to steer, you: TH = TC + WCA TH = 360° + (- 10°) = 350° Treat R WCA as plus Treat L WCA as minus Normally the pilot will use eithae a manual or electronic E6B Flight Computer to solve WCA problems. Consult your E6B computer manual for problem solution methods. WCA for the Example Flight The example flight from SVH, LEX, 3N8, SVH is shown below. The wind aloft for this problem is 270 degrees true at 35 knots.On your planning chart, add and subtract the WCA's to the TC's to fill out the TH column. True Course, Wind Correction, True Headings (degrees) TC WCA TH 088 01 L 087 220 15 R 235 332 17 L 315 http://www.uncletom2000.com/gs/fltpln.htm (6 of 7) [1/23/2003 11:19:10 AM] Correcting for Magnetic Variation As a refresher on Magnetic variation, see Magnetic Variation . True North and Magnetic North are not at the same location on the earth. In the eastern US, the Magnetic North Pole is west (left facing north) of the True North pole. The AGONIC LINE (where true and magnetic north are the same) runs from uper eastern Wisconsin, diagonally Southeastward through the central South Carolina coast. The difference between the True and Magnetic Norths is called Magnetic Variation (VAR). It is called Westerly Variation east of the agonic line; i.e. Magnetic north is west of True North. It is called Easterly Variation west of the agonic line. To convert from TH to Magnetic Heading (MH), Add Westerly VAR, Subtract Easterly VAR. The variation is shown on the Aeronautical Charts as dashed magenta lines, running from the top to the bottom of the chart. They will be labled 6°W, 10°E, etc. In your planning log, write the magnetic variation down in the VAR column (denoted by the *). Add or Subtract the VAR (W = +, E = -) to the TH to get the Magnetic Heading (MH) values. This portion of the example SVH, LEX, 3N8, SVH flight is shown below. The flight is totally within a region where the Magnetic Variation is 6 degrees WEST. Course, Headings, Wind Correction, Magnetic Variation (degrees) TC WCA TH VAR (*) MH 088 01 L 087 06 W 093 220 15 R 235 06 W 241 332 17 L 315 06 W 321 This completes the Course and Heading definition of the log. Distance and Time As a by-proudct of the wind triangle calculations to arrive at a Magnetic Heading for each leg, you also found the Ground Speed for each leg. Using this GS, and the DIST (distance) for each leg (or segment) of the flight, the time and estimated fuel usage can be calculated. Time, Distance, Groundspeed, Fuel Used per Leg DIST GS TIME FUEL RATE FUEL USE 32 139 :14 8.9 gph 2.0 31 78 :24 8.9 gph 3.5 26 83 :19 8.9 gph 2.8 Back to Home Back to Table of Conents To Communication Flight Planning http://www.uncletom2000.com/gs/fltpln.htm (7 of 7) [1/23/2003 11:19:10 AM] Radio Communication Radio Communication Flying is greatly facilitated by the ability of the pilot to communicate with ground facilities and other aircraft. In the Navigation chapter, the term “NAV/COM” was used. This chapter will deal with the “COM” part of the radio. Communication with the following facilities enhances safety, and in many cases is required; These are: l 1. ATC m - Ground Control for taxi instructions m - Tower for takeoff and landing instructions m - Approach and Departure Radar m - ATC enroute Centers for clearances, radar surveillance, and traffic separation l 2. FSS - Contact with Flight Service Stations for weather information and Flight Plans . l 3. FBO - Contact Fixed Based Operators for fuel, airport advisories and service. l 4. AIRCRAFT- Aircraft to aircraft communications. Announce takeoff and landing intentions. Frequencies The communication band for civilian aircraft operate in the range of 118.00 MHz to 135.975mhz. Many transceivers can be tuned to only 360 frequencies( called 360 channels). The frequencies that can be selected are 118.00 to 135.95. Channels exist every 0.05 MHz. Later models are capable of 720 channel operation. They allow a 0 or 5 to be selected for the 6th digit by use of a toggle switch. In one position the 6th digit is zero; in the other position, it is 5. However, to date, virtually all FAA frequencies operate on the 360 channel frequencies. Phraseology Good phraseology and standard communication techniques enhance pilot-controller understanding. Jargon, “CB” slang, and vulgarities have no place in aviation communication. When initially identifying your aircraft “N” number, you should use the Phonetic Alphabet. Examples: 7434 X-Ray (7434X), 738 Alpha Lima (738AL), etc. Thereafter, following the initial call-up, controller and pilot will use only the last 3 numbers/letters. Example, 34 X-Ray, or 8 Alpha Lima. The phonetic alphabet can also be used to spell out words or phrases when communication is difficult to understand. As shown in the table below, a Morse code is also associated with each letter and number. These codes will be heard over NDB and VOR stations as station identifiers. Phonetic Alphabet and Morse Codes http://www.uncletom2000.com/gs/comm.htm (1 of 12) [1/23/2003 11:19:12 AM] Letter Phonetic Morse Code Letter Phonetic Morse Code Digit Phonetic Morse Code A Alpha . - N November - . 1 One . - - - B Bravo- . . . O Oscar - - - 2 Two . . - - - C Charlie - . - . P Papa . - - . 3 Three. . . - - D Delta - . . Q Quebec- - . - 4 Four . . . . - E Echo . R Romeo . - . 5 Five . . . . . F Foxtrot- . S Sierra. . . 6 Six - . . . . G Golf - - . T Tango - 7 Seven- - . . . H Hotel. . . . U Uniform. . - 8 Eight- - - . . I India . . V Victor. . . - 9 Nin-er- - - - . J Juliet. - - - W Whiskey . - - 0 Zero - - - - - K Kilo - . - X X-Ray - . . - L Lima . - . . Y Yankee- . - - M Mike - - Z Zulu - - . . Pronunciation of Figures

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Figures indicating hundreds and thousands are pronounced as follows: · 500 is FIVE HUNDRED · 5,000 is FIVE THOUSAND · 4,500 is FOUR THOUSAND FIVE HUNDRED · 10,000 is ONE ZERO THOUSAND · 12,600 is ONE TWO THOUSAND SIX HUNDRED Victor airway numbers such as V12 are pronounced as “VICTOR TWELVE”. When reciting other number combinations pronounce each digit. For 10, say “ONE ZERO”. Altitudes are pronounced as ONE ZERO THOUSAND FIVE HUNDRED. Altitudes at and above 18,000 feet are called FLIGHT LEVELS, such as FL180, ( Flight level One Eight Zero), FL230 (Flight Level Radio Communication http://www.uncletom2000.com/gs/comm.htm (2 of 12) [1/23/2003 11:19:12 AM] Two Three Zero), FL 390, etc. Magnetic Headings are pronounced as: - Magnetic Course 005° pronounced as “Zero Zero Five” -True Course 050° as “Zero Five Zero True” - Magnetic Bearing 256° as “Two Five Six” - Magnetic Heading 125° as “One Two Five” - Wind Direction and Velocity 220° at 35kt as “Two Two Zero at Three Five” Note: Wind direction is given by ATC (Towers etc.) in Magnetic Direction. Wind given in Weather reports, forecasts, etc. is True Direction Speeds such as 125 kts. are pronounced as One Two Five Knots”. In communications where speed is implicit, such as a controller instruction to increase speed to 150 kts., the controller may omit the word “Knots”; i.e. may use the term “increase speed to 150”. Coordinated Universal Time (UTC) In aviation terminology, time is related to the time at the Zero Meridian, which runs North/South through Greenwich, England. It was formerly called Greenwich Mean Time (GMT). The current terminology is Coordinated Universal Time (abbreviated UTC). When speaking time, pilots and FAA personnel refer to UTC time as ZULU time. The time 1345Z would be pronounces as “One Three Four Five Zulu”. To convert US time zones to UTC time, add the following hour values. Local to UTC Time Conversion Local Standard Time add Local Daylight Time add EST CST MST PST EDT CDT MDT PST + 5 hr + 6 hr + 7 hr + 8 hr + 4 hr + 5 hr + 6 hr + 7 hr To convert from ZULU time back to US time zones, subtract the number of hours shown. In addition, time is expressed in Military Time (24 hour time). Examples: 0000 is pronounced Zero Zero Zero Zero ( midnight) 0925 is pronounced Zero Niner Two Five (9:25 a.m.) 1830 is pronounced One Eight Three Zero (6:30 p.m.) Initial Call-Up Terminology At your initial call-up, you generally use the following format: Radio Communication http://www.uncletom2000.com/gs/comm.htm (3 of 12) [1/23/2003 11:19:12 AM] · Who you are calling · Who are you · Where are you · What you want to do or are doing. Examples : 1. New York Approach, Bonanza Two Three Six Seven Yankee , Over When calling Approach Control, or other ATC facilities, monitor how busy the controller is. If calling at an active time, simply state the ATC name, your identification, ending with the word OVER. This term means you are requesting the called party to respond.If the controller does not appear busy, and your message is short, you can state the entire message on initial call-up You could have also given your position and altitude. This shortens the total conversation time by initially providing the comtroller more information. Judgement is required here. If the controller cannot respond to your call immediately, their response will be “aircraft calling New York, stand by” or with “Bonanza Three Six Seven Yankee, stand by”. Note that the controller does NOT say OVER, as no communication by the pilot is required until requested by the controller. The controller has recognized you and will come back as soon as possible. 2. Statesville Unicom, Beech Two Three Alpha Bravo TEN EAST, Airport Advisory, Over End with the term OVER, since you are requesting a response. 3. Zahns Traffic, Bonanza Seven Four Three Four X-Ray turning base runway Two Zero. You are announcing to other aircraft in the area where you are, and what you are doing. You do NOT end with the term OVER, as you are not requesting a response. 4. Gainsville Departure, Four Five Foxtrot, Out. You use the term OUT to indicate the communication is ended, and no further response is expected. Uncontrolled Airports At airports without a control tower, it is very important to be alert for other aircraft which may be operating in close proximity to the airport. Other aircraft close to you may not have radio equipment. All radio equipped aircraft operating around an uncontrolled airport should communicate on a Common Frequency. Common Traffic Advisory Freqiency (CTAF) Radio Communication http://www.uncletom2000.com/gs/comm.htm (4 of 12) [1/23/2003 11:19:12 AM] Most uncontrolled airports are equipped with a ground station for communication with ground personnel and air to air communication between aircraft operating in the vicinity. This frequency is published within the airport information block on the aeronautical chart. It is called the Common Traffic Advisory Frequency (CTAF) and is denoted by the letter C within either a Magenta or Blue filled circle following the frequency number. The frequencies will normally be in the range of 122.7 to 122.95. Occasionally, due to a high volume of communication traffic within a geographical area, frequencies above 123.0 MHz may be used. When approaching such airports, call about ten miles out, requesting airport advisory. Normally ground personnel will respond with information about traffic, active runway and wind. It is important to note that such information is advisory in nature. The pilot is the final authority for operation of the aircraft. You should announce your position and/or intentions for the following situations. INBOUND · Entry into downwind Leg · Turn to Base Leg · Turn to Final Leg · Clear of the active runway OUTBOUND · On the ramp, ready to taxi to departure runway · Ready for departure, runway to be used , and direction of departure Ground based stations at uncontrolled airports. · LLA - Local Airport Advisory - used at airports where a FSS is located. Call the FSS on 123.6 and request airport advisory. Example: “Hickory Radio, Skyhawk 53417 is 10 miles East, at Three Thousand five hundred, landing Hickory. Request airport advisory”. The FSS will respond with Wind direction and Velocity, Altimeter setting, active runway, and any known traffic. · UNICOM - these are non-government stations operated by the local operator or airport management, to advise about known traffic, which runway is being used, and may advise wind condition. They transmit on 122.7, 122.725, 1228, 122.975 and 123.0 · MULTICOM - frequency 122.9 MHz. Pilots should use this frequency at airports where there is no ground-based communication facility such as UNICOM or LAA. The pilot is to self-announce position and intentions the same as on UNICOM. This procedure allows other aircraft in the area to know where you are and your intentions. The MULTICOM frequency of 122.9 is shown on the charts the same as LAA and UNICOM, with the circled C indicator following the frequency. Controlled Airports

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Radio Communication http://www.uncletom2000.com/gs/comm.htm (5 of 12) [1/23/2003 11:19:12 AM] Communication at control towered airports involve communication with at least 3 facilities. · Automatic Terminal Information Service (ATIS) (Listen only) · Ground Control · Tower Additionally, at larger airports, there will be: · Clearance Delivery · Approach Control · Departure Control ATIS ATIS broadcasts a repetitive tape containing information such as runways in use, altimeter setting, weather conditions, wind direction and velocity, communication frequencies and other information pertinent to operating in the vicinity of or on the airport. Prior to departure, you should listen to ATIS before to calling Clearance Delivery or Ground Control. On arrival, listen to ATIS before callingApproach Control. Whenever the weather or other conditions change during the day, the recording is updated. Each time a new recording is made, it is assigned an identifier name, starting with ALPHA. Subsequent updates are identified as BRAVO, CHARLIE, etc. When making initial contact with approach Control or Tower on arrival, and Clearance Delivery or Ground Control on departure you should state that you have the ATIS information. Use it’s identifier name; i.e. CHARLIE. EXAMPLES: · “Raleigh Clearance Delivery, Bonanza 345 Yankee Foxtrot, ready to depart VFR to the WEST, with information BRAVO. Request clearance.” · “Greensboro Approach, Cherokee 8734 Juliet, Two Zero East, Three Thousand, inbound Greensboro, with information GOLF”. Clearance Delivery At larger airports which have a high volume of operations, Clearance Delivery provides initial departure information to the pilot. This frees Ground Control to concentrate directing traffic on the ramps and taxiways. Clearance Delivery coordinates information with Departure Control by assigning a transponder code prior to becoming airborne. This saves time both for the Ground Controller and the Departure Controller. It allows the pilot to set-up the transponder and departure frequencies prior to dparture, as well as giving the pilot advance information on departure procedures. The Clearance Delivery Frequency is listed in the Airport/Facility Directory and is included in the ATIS information. In your call-up, state your aircraft type and identification, VFR or IFR, departure direction or destination, and planned altitude. Radio Communication http://www.uncletom2000.com/gs/comm.htm (6 of 12) [1/23/2003 11:19:12 AM] Clearance delivery will respond like this: Seven Four Three Fouur X-Ray, you are cleared to depart runway 27 Right VFR westbound. Squawk One Three Five Two. Departure Control frequency is One Two Six Point Seven Five .Contact Ground Control on One Two One Point Niner prior to taxi. Ground Control Ground Control is responsible for the flow of aircraft taxiing on the ramps and taxiways. On your call up, identify your aircraft type and number, your location on the airport, with request to taxi. If no Clearance Delivery is at the airport, include the ATIS Identifier. Ground control frequencies can be found on the front panel of the Aeronautical Chart and the Airport/Facility Directory. EXAMPLE: “Daytona Ground, Beech Six Three Five Four Two at Jet Service Ramp, request taxi, VFR southbound with information GOLF”. The controller’s response will be similar to: Beech Six Three Five Four Two taxi straight ahead to taxiway Alpha, turn left and taxi to One Eight Right. Contact tower on One Two Seven Point Five Five when ready. You respond: Roger, taxi to Alpha, then left to One Eight Right. (Note: the term ROGER means that you understand the instruction, and know how to comply). You should read back the controllers instructions, in particular any HOLD SHORT instructions. You are under the supervision of Ground Control during your taxi and run-up. When you are ready to depart, you then switch to the tower frequency. Ground and tower controllers are in the same room in the tower, and coordinate the hand-off of traffic to each other. Tower Control The tower controls operations on the runways and in the airspace around the airport. After you have completed all pre-flight actions, call the tower on their frequency with the following information. · Address the Tower. “Memphis Tower · Who you are . “Skyhawk Five Six Two Three ALFA “ · Your intention. “ ready for takeoff runway Five RIGHT”. The tower may respond: Roger, Two Three ALFA cleared to Five Right and Hold. Radio Communication http://www.uncletom2000.com/gs/comm.htm (7 of 12) [1/23/2003 11:19:12 AM] You acknowledge the instruction, and read back the holding instruction: Roger Tower. Two Three Alpha, Holding Five Right. The tower will subsequently clear you for takeoff. 1. It may be in the form : TwoThree Alpha, taxi into position and hold. You respond: Roger, Position and Hold. You taxi onto the runway, but do not take off. OR 2. It may be clearance for takeoff without holding: Two Three Alpha, Cleared for Takeoff: You may respond with “Roger”, or may simply depart. You should monitor the tower frequency until told by the tower to contact Departure Control or until tower ends the communication. Tower will shortly hand you off to the Departure Control: Two Three ALFA, contact Departure on One Three Two point Five Five. You respond: Departure, One Three Two point Five Five. Two Three ALFA out. Departure Control Departure Control is a Radar Service at Class B and C airports. To operate in this environment, you must be equipped with a Mode C (altitude reporting) transponder. The Departure Controller will assign altitudes and headings as required to provide traffic separation. If the controller’s instructions place you into a position to violate VFR rules (such as clearance from clouds) , you should inform the controller to get an amended clearance. Your initial call to departure control will be something like this: Memphis Departure, Shyhawk Five Six Two Three ALFA, climbing through One Thousand Niner Hundred, westbound. Departure may respond: Roger Two Three ALFA, Radar contact. Turn left to Two Three Zero and climb to two thousand five hundred. After you are clear of the airport traffic area, the controller may terminate radar: Two Three ALFA, radar service terminated. Resume your own navigation. Radio Communication http://www.uncletom2000.com/gs/comm.htm (8 of 12) [1/23/2003 11:19:12 AM] You respond: Roger. Two Three ALFA Out. The word “OUT” terminates the communication. However, often controllers and pilots will use “good day” as a more congenial ending. Approach Control Approach Control is a radar service similar to Departure Control. Contact with Approach Control is mandatory prior to entry into Class B and C airspace. On initial call-up, identify type and number of aircraft, position, altitude and destination. The controller will respond with a “SQUAWK” code for the transponder. Example: The initial call-up can be: Daytona Approach, Cherokee Six Five Two Three ROMEO, Saint Augustine VOR, Three Thousand Five Hundred, inbound Daytona. Response: Cherokee Six Five Two Three ROMEO, this is Daytona Approach. Squawk Two Three One Five and Ident. You set the squawk code 2315 into the transponder, press the ident button, and respond: Roger, Two Three One Five and ident. After the controller identifies you on the radar screen, the controller will confirm: Two Three ROMEO Radar Contact , Two miles south of Saint Augustine VOR. Descend to two thousand five hundred. You respond: Roger, Two Three ROMEO descending to two thousand five hundred. You acknowledge the instruction. The radar controller will continue to track your “blip” on the radar screen, give traffic advisories as necessary, and may vector you into the downwind leg in the pattern. The controller will then hand you off to the tower controller for landing instructions. If you are flying through Class C airspace without landing, tell the controller the planned route of flight and altitude you wish to maintain. Radar Flight Following will be granted outside the class B or C airspace on a “workload permitting” basis upon pilot request. The radar surveillance usually can be provided up to 20 or 30 miles from the radar site. Transponder Operation Radio Communication http://www.uncletom2000.com/gs/comm.htm (9 of 12) [1/23/2003 11:19:12 AM] There have been a number of modes of transponder operation during it’s history. The mode now required for operation in Class B and C airspace is Mode C. This mode couples an encoder in the altimeter which reports the altitude in hundreds of feet. The Transponder also has 4 digital dials, each with numbers 0 through 7. Therefore, number combinations from 0000 to 7777 can be dialed in. This is called the “SQUAWK code. The numbers 7500, 7600 , 7700 and 7777 are reserved for special use: · 7700 - emergency · 7600 - lost radio communications · 7500 - code for hijacking · 7777 - used by military The transponder operates by receiving an interrogation signal from the radar station. It in turn returns certain coded information back to the radar when the transponder is set for normal operation. The SQUAWK code and the altitude in hundreds of feet are returned to the radar. The controllers radar scope shows a “blip” on the radar screen along with the SQUAWK code and altitude. A Mode C altitude reporting transponder is required: · When flying at or above 10,000 feet · When flying within Class B Mode C veil (30 Nm around a Class B airport). (Note: there are exceptions for operations into smaller airports which lie within the 30 Nm veil). · When flying in or above Class C airspace · When crossing the U.S Air Defence Identification Zone (ADIZ). The unit is equipped with a rotary switch with several positions. · OFF - turns the transponder off · STY - (Standby) - turns the transponder for warm-up. The transponder does NOT respond to the radar interrogation signals. · ON - Turns the transponder on and allows it to respond in Mode A (No altitude reporting). This shown a blip on the radar screen but NO ALTITUDE DATA. · ALT - Allows a reply in either Mode A ( no altitude report) or Mode C (altitude report) as requested by the radar interrogating signal. A button, called the IDENT BUTTON, when depressed sends a special identifying signal to the radar. The IDENT should only be sent when requested by the controller. Controllers may use the following terminology when referring to transponder operation · SQUAWK (number) - set the 4 digit code into the transponder. Example: Squawk 4316. · IDENT - depress the IDENT Button · Squawk (number) and IDENT - set code into the transponder dials, then IDENT. · SQUAWK STANDBY - Switch function switch to STY · SQUAWK ALTITUDE - Switch to ALT position · STOP ALTITUDE SQUAWK - Switch from ALT to ON · SQUAWK MAYDAY - select code 7700 Radio Communication http://www.uncletom2000.com/gs/comm.htm (10 of 12) [1/23/2003 11:19:12 AM] · STOP SQUAWK - turn transponder off · SQUAWK VFR - select code 1200 when operating without ATC contact. 1200 is known as the VFR squawk code. Radar Assistance to Lost Aircraft Never hesitate to contact radar services when in serious doubt of your location, are encountering poor weather, or are in need of other assistance. When flying cross untry, it is good practice to keep track of, or know where to find, the various approach control services available along your route. This should be a part of your flight planning. Even the Air Traffic Control Centers (ARTC) which normally handle enroute IFR flight will render assistance to lost aircraft. If radar frequencies are not readily available, contact the nearest Tower or FSS, and provide then with the best location data you can. They will coordinate with, or refer you to the nearest radar facility. Usually an emergency situation can be avoided by requesting assistance as soon as you are not sure of your position. ATC can give you radar vectors to your destination or suitable alternate airport. Emergency Locator Transmitter (ELT) Emergency locator Transmitters have been developed to transmit a locating signal in the event of significant impact. They are battery powered, and self contained. When activated by impact, they transmit a homing signal on 121.5 and 243.9 Mhz. This signal provides homing for search and rescue equipment. The power source must be capable of sustaining the signal for 48 hours. The ELT is equipped with a gravity activated switch, which automatically activated the ELT upon significant impact. They generally have 3 switch positions: · ON - causes a continuous broadcast of the signal on 121.5 and 243.0 MHz. This position is used for test purposes. · OFF - no broadcast is possible · ARMED - means the gravity switch can be activated in the event of sufficient impact. DO NOT INADVERTENTLY ACTIVATE THE ELT WHILE ON THE GROUND. THIS COULD CAUSE AN UNNECESSARY EXPENSIVE SEARCH. Aerobatics, or hard landing have been known to set off an ELT. A good check for a false ELT signal is to turn a radio receiver to 121.5 MHz prior to engine shut-down. If the ELT has been triggered, you will hear a steady signal on this frequency. Corrective action should be taken. Radio Communication http://www.uncletom2000.com/gs/comm.htm (11 of 12) [1/23/2003 11:19:12 AM]

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ELT’s should be tested in accordance to manufacturers instructions. Testing should preferably be done in a shielded room. Tests should be conducted only during the first 5 minutes after the hour. If a test is to be made at any other time, it should be coordinated with the Control Tower or FSS. ELT batteries must be replaced or recharged: · If the battery has been used more than one hour cumulative. · When 50% of the useful life of the battery has expired. Back to Home Back to Table of Conents To Weather Information Radio Communication http://www.uncletom2000.com/gs/comm.htm (12 of 12) [1/23/2003 11:19:12 AM] Principles of Weather Principles of Weather Weather for Pilots USA Today Pilots Information. How The Weather Works Good classroom on weather. Index of Weather Subjects USA Today General Weather Info. Pressure Systems Explanation of Atmospheric Pressure. The Atmosphere A guide to the atmosphere. A Guide to Sattelite Images...Interpreting Sattelite Images Back to Home Back to Table of Conents To Weather Reports http://www.uncletom2000.com/gs/weather.htm [1/23/2003 11:19:12 AM] Engine and Systems Weather Reports and Services The U.S. Weather Service provides numerous weather forecasts, reports and warnings significant to aviation operations. These are generally of the following categories. Aviation Forecasts and Reports Weather Pictorials Sattelite and Radar Images Forecasts Area, Terminal (TAF) and Winds Aloft Forecasts Current reports Hourly Terminal Weather Reports (METAR) Warnings PIREPS, SIGMETS, AIRMETS l Weather Pictorials include Radar Images and Sattelite Images. This allows the pilot to "get the big picture" of Highs, Lows and Fronts. l Forecasts are of the type m Area Forecasts - this describes the weather patterns for a wide area, covering several states. They are designated by as an "FA" type designator. They are issued 3 times a day, It includes a 12 hour forecast plus a 6 hour outlook. This link will connect you to the current National Weather Service Current Area Forecast page. m Terminal Forecasts (TAF) - these are forecasts made for large cities, and cover the general area around the designated city. See the METAR and TAF link below for a more detailed description. They are issued 3 times a day, and contain a 12 hour forecast plus a 6 hour outlook.See the METAR/TAF conversion card definition for more information on TAF report format and interpretation. m Winds Aloft Forecasts (FD) - these are issued every 6 hours, and give the wind speed, direction and temperature at certain designated cities at graduated altitudes. These are 3000, 6000, 9000, 12,000, 18,000, 24,000, 30,000, 34,000 and 39,000 feet altitude. The forecast generally covers a fairly wide area around a central designated city. Click here for current Winds Aloft Forecasts. They are needed to calculate Wind Correction Angle and Estimated Groundspeed for your flight. l Actual Weather Reports m METAR reports are the hourly terminal aviation reportsof the actual weather conditions at airports which have weather oberservation capability. The observation is usually made about 10 minutes before the hour, each hour. Therefore a report of actual weather conditions at the reported airports is available every hour. See the METAR/TAF conversion card definition for more information on METAR report format and interpretation. For actual current briefing information, view the National Weather Bureau's Standard Briefing Page. Caution: this is to be used for general information purposes only. You should get a formal pre-flight http://www.uncletom2000.com/gs/wxrepts.htm (1 of 2) [1/23/2003 11:19:13 AM] briefing from the FFS station in your area prior to your flight. l Warnings and In-flight Reports m PIREPS - Pilot Reports - These are in-flight reports made by pilots to ground stations whenever the pilot encounters conditions which are significant to other pilots operating in the area. They will usually report significant turbulence, change in weather conditions and cloud tops, etc. These are available only through the FSS station, and should be given to you, if applicable, during your Standard Weather Briefing. m SIGMETS- Significant Meterological Reports - are issued to advise pilots of nonconvective weather considered potetially hazardous to ALL aircraft. They include notification of Severe Icing, Severe or Extreme Turbulence, Duststorms, Volcanic Ash, or Sandstorms which lowers the in-flight or surface visibility below 3 Statute Miles. Volcanic eruption and tropical storms and hurricanes are also included. They are valid for 4 hours. m AIRMETS - These are reports of weather significant to light aircraft. They are valid for 6 hours. They indicate moderate Icing, moderate Turbulence, sustained Surface Winds of 30kt or more, ceiling less than 1000 ft. or visibility less than 3 miles. Extensive Mountain Obscurement is also included, This link is a source for many types of Aviation related Images, Forecasts and Reports. See this link for current SIGMETS and AIRMETS. This link will lead you to many National Weather Services. It should give you the latest up-to-date information on weather services. Back to Home Back to Table of Conents To Other Publications Engine and Systems http://www.uncletom2000.com/gs/wxrepts.htm (2 of 2) [1/23/2003 11:19:13 AM] Other Publications OTHER PUBLICATIONS There are several additional publications of interest to the pilot. These are: · Airport/Facility Directory (A/FD) · Aeronautical Information Manual (AIM) · Notices to Airmen (NOTAMs) All three of these publications are very important to the general knowledge of the pilot and to safe flight operations. The AIM and A/FD should be a part of every pilot’s library. Airport/Facility Directory The A/FD is published every eight weeks by the National Ocean Service (NOS), a division of NOAA. It is published for seven regions of the US. 1. Northwest 2. Southwest 3. North Central 4. South Central 5. East Central 6. Northeast 7. Southeast The A/FD is a very important part of your flight planning. Most airports which sell aeronautical charts and supplies will have the A/FD for their region. You may order any of the directories from National Chart Services (such as Jeppesen Sanderson, Inc.) or order directly from: NOAA, N/CG33, Distribution Branch Riverdale, MD 20737 Telephone (301) 436-6933 The directory covers the following information: · Abbreviations used in the directory · Legend for the A/FD information · Airport and Facility Information (Airports, VOR’s, NDB,s etc.) http://www.uncletom2000.com/gs/otherpub.htm (1 of 6) [1/23/2003 11:19:14 AM] · Heliports and Seaplane Bases · Special Notices on airports, temporary restricted/special use airspace) · FAA and Weather Service Telephone Numbers · Air Traffic Control Center information · Flight Service Station (FSS) communication frequencies. · Flight Safety District Offices (FSDOs) Addresses and telephone numbers · Preferred IFR routes · VOR Receiver Checkpoints · Parachute jumping areas · Aeronautical Chart Bulletins (changes to charts since last publication) · Enroute Flight Advisory Service (EFAS) · Directory Legend Aeronautical Information Manual See the complete Aeronautical Information Manual This publication contains extensive information for pilots. It is continually updated by the FAA and a complete re-write is published frequently. An individual update subscription service is available for those persons who need to be informed of the updates on a timely basis. The AIM covers the following subjects (Based on the 1996 edition). Chapter 1 Navigation Aids Aeronautical Information Manual Chapter 1 Section 1 Air Navigation Radio Aids Section 2 Radar Services and Procedures Chapter 2 Aeronautical Lighting and Other Airport Visual Aids Aeronautical Information Manual Chapter 2 Section 1 Airport Lighting Aids Section 2 Air Navigation and Obstruction Lighting Section 3 Airport Marking Aids and Signs Chapter 3 Airspace Aeronautical Information Manual Chapter 3 Section 1 Airport Lighting Aids Other Publications http://www.uncletom2000.com/gs/otherpub.htm (2 of 6) [1/23/2003 11:19:14 AM] Section 2 Controlled Airspace Section 3 Class G Airspace Section 4 Special Use Airspace Chapter 4 Air Traffic Control Aeronautical Information Manual Chapter 4 Section 1 Airport Lighting Aids Section 1 Services Available to Pilots Section 2 Radio Communication and Phraseology Section 3 Airport Operations Section 4 ATC Clearances and Separations Chapter 5 Air Traffic Procedures Aeronautical Information Manual Chapter 5 Section 1 Preflight Section 2 Departure Procedures Section 3 En Route Procedures Section 4 Arrival Procedures Section 5 Pilot/Controller Roles and Responsibilities Section 6 National Security and Interception Procedures Chapter 6 Emergency Procedures Aeronautical Information Manual Chapter 6

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Section 1 General Section 2 Emergency Services Available to Pilots Section 3 Distress and Urgency Procedures Section 4 Two-Way Radio Communication Failure Chapter 7 Safety of Flight Aeronautical Information Manual Chapter 7 Section 1 Meteorology Section 2 Altimeter Setting Procedures Section 3 Wake Turbulence Section 4 Bird Hazards and Flight Over National Refuges, Parks, Forests Other Publications http://www.uncletom2000.com/gs/otherpub.htm (3 of 6) [1/23/2003 11:19:14 AM] Chapter 8 Medical Facts for Pilots Aeronautical Information Manual Chapter 8 Section 1 Fitness for Flight Chapter 9 Aeronautical Charts Aeronautical Information Manual Chapter 9 Section 1 Types of Charts Available Pilot/Controller Glossary Airport Advisory Circulars Non-regulatory information type documents are available to the aviation community called Advisory Circulars. A listing of these circulars may be obtained from: U. S. Department of Transportation General Services Section, M-443.2 Washington, D. C. 20590 The circular numbers and ordering information is contained in a document called the “Advisory Circular Checklist AC.00-2 A major index of circular subjects is shown on the next page. The subjects are coded by General Subject Number and then by Specific Subject. The General Subject Number of greatest interest to the Private Pilot are: Notices to Airmen (NOTAM) Notices to Airmen (NOTAMs) contain time-critical information that is either of a temporary nature, or has not yet been reflected on the latest charts and publications. They cover airport and runway closures, navigational facility outages or frequency changes, etc. Other Publications http://www.uncletom2000.com/gs/otherpub.htm (4 of 6) [1/23/2003 11:19:14 AM] There are 3 typrs of NOTAMS of interest: 1. Locally Distributed NOTAMS(L) 2. NOTAMS Distributed to Distant Location - NOTAM(D) 3. Federal Distribution Center Notices (FDC NOTAMS) A bi-weekly Notices to Airmen Publication called NTAP is published. Once the information has been published, it will not be provided in your pre-flight briefing by the FAA unless you request such information. The publication contains two sections: 1. NOTAMs(D) that are expected to remain in effect for a long time and FDC NOTAMs which are expected to stay in effect for more than 7 days. Occasionally a NOTAM(L) will be included if it is deemed important to flight safety. 2. Special notices that are too long for normal publication or which cover large geographical areas. These are NOTAMS that relate principally to facilities and airports within the jurisdiction of the issuing FSS station. It covers information handy to know, such as runway closings, construction areas at airports, and information that is not critical to safety or navigation. It is distributed to Operators and Control Towers within the FSS jurisdiction. These NOTAMS are not routinely covered in pre-flight briefings unless requested by the pilot. NOTAM (D) These are notices about airports and facilities that are important to navigation and operational safety. They cover all navigational aids in the National Airspace System, and all airports listed in the A/FD. They are distributed broadly, and beyond the jurisdiction of the issuing FSS. They are significant to your flight planning, and should be included in your pre-flight briefing. You should always insure that you have been briefed on the NOTAMS along you route of flight. FDC NOTAMS These are NOTAMs issued by the Federal Distribution Center and are regulatory in nature. They cover such things as changes to aeronautical charts, new hazards to flight, new restrictions to flight, changes in instrument approach facilities and procedures, etc. Flight Service Stations are required to keep on file all FDC NOTAMS within 400 miles of their location. Other Publications http://www.uncletom2000.com/gs/otherpub.htm (5 of 6) [1/23/2003 11:19:14 AM] Back to Home Back to Table of Conents To Federal Aviation Regulations Other Publications http://www.uncletom2000.com/gs/otherpub.htm (6 of 6) [1/23/2003 11:19:14 AM] The Airplane Overview of Federal Aviation Regulations . Federal Aviation Regulations Back to Home Back to Table of Conents To Aeromedical Factors http://www.uncletom2000.com/gs/fars.htm [1/23/2003 11:19:14 AM] Aeromedical factors AEROMEDICAL FACTORS Medical Certification All airplane pilots must be in possession of a valid Medical Certificate whenever exercising the responsibility of Pilot in Command, or when acting as a required crew member. A THIRD CLASS certificate is required for the Private Pilot not flying for hire. The FAR’s prohibit a pilot from performing crew member duties when you have a known medical condition which would normally disqualify you for the certificate. This includes a relapse of a former condition, of an aggravation of a medical condition which would not qualify for the certificate during such aggravation. Personal Checklist Pilot impairment is a greater contributor to accidents than is aircraft failure. Such accidents may be due to medical conditions, exceeding your personal experience level, flying into weather conditions for which you are unqualified to handle, alcohol or drug use, stress, or an “attitude of get there at all cost”. A good personal checklist is “IM SAFE”. I llness M edication S tress A Alcohol F atigue E motion Illness Even minor illness can be a cause of concern. Fever, symptoms, and drugs can impair the ability to reason and calculate. Alertness and Memory may also be impaired. The best rule is “If not feeling well, don’t fly”. Medication Many medications such as antihistamines, blood pressure medication, tranquilizers, pain relievers, and cough suppressants may have narcotic effects affecting mental and physical faculties. The safest rule is not to fly while taking any medication. If in question about any medication, consult with an FAA http://www.uncletom2000.com/gs/aeromed.htm (1 of 8) [1/23/2003 11:19:15 AM] Designated Medical Examiner. Stress Stress, anger and worry can affect a persons rational thinking process. The stress and worries detract from the ability to remain mentally alert. Such mental interference can blur judgment, memory recall, and impede attention to the flight environment. It is best to wait until the stressful situation has passed, and to fly safely another day. Alcohol One ounce of liquor, a bottle of beer or four ounces of wine can significantly impair flying skills. Night flying and alcohol is a particularly deadly combination because if vision impairment. The FAR’s prohibit pilots from flying or acting as a crew member within 8 hours of consuming any alcohol. This is the MINIMUM. A much better rule is 24 hours from bottle to throttle. Alcohol can significantly contribute to altitude oxygen deficiency as alcohol inhibits adequate oxygen absorption by the brain. Fatigue Fatigue may not be apparent until you have made a serious mistake. It may be a short term condition such as too little sleep the night before. All you need to recover is a good nights rest. It may also be a long term condition to which you have become accustom, but which prevents you from your peak performance. Such a condition requires a prolonged period of rest. Fatigue leads to lethargy in the cockpit, impaired reasoning and judgment. It can lead to “getting behind the situation” if sudden unexpected situations occur. Emotion Emotion applies to your state of mind. You may be angry, irritated, or just mildly “out of sorts”. Obviously flying under these conditions is unwise. Emotion can also apply to your attitude about flying. Do you feel bold and invincible? Are you on the fence as whether the weather is go or no-go? Do you have a “must get there at all cost” mentality? Have you assessed your personal experience and capabilities for the given flight conditions? Have you set your “own go and no-go rules? Are you being bugged by a passenger “who has just got to get there NOW? A good strategy is to evaluate your own experience, capability, and personal flight rules before you plan any flight. If the situation does not fit your pre-determined rules, THEN DON’T. When you feel uneasy about the flight conditions, the safest rule is wait for a better day or time. There is no cowardice in setting down and setting out the weather. Aeromedical factors http://www.uncletom2000.com/gs/aeromed.htm (2 of 8) [1/23/2003 11:19:15 AM] Scuba Diving If you or a passenger have been scuba diving, you should allow sufficient time before flight to allow your body to rid itself of excess nitrogen in the blood. If this is not done, decompression sickness (the bends) can occur at altitude, creating a serious in-flight emergency. For a dive which has not required controlled ascent, you should wait at least 12 hours before flying above 8,000 feet cabin altitude. For a dive that has required controlled ascent (decompression), the time allowed should be 24 hours for flight above 8,000 feet cabin altitude. In-Flight Medical Conditions The pilot should remain aware of several In-Flight conditions which can occur which will impair your ability to adequately function. · Hypoxia · Hyperventilation · Carbon Monoxide · Motion Sickness · Sinus and Ear Block · Spatial Disorientation · Fear Hypoxia Hypoxia results from an oxygen deficiency. The lack of adequate oxygen affects the functioning of the brain and other organs. A sense of “well being”, belligerence, drowsiness, dizziness and headache can result. It has the same effect as early stages of inebriation. Pilot performance can deteriorate significantly if operating at 15,000 feet for even a short time without supplemental oxygen. Visual acuity becomes impaired. Pheriperal vision turns gray, with only the central vision functioning (tunnel vision). Blue color (cyanosis) occurs at the extremities such as fingernails, and in the lip color. At 15,000 feet you loose the ability to function correctly within 20 to 30 minutes. At 20,000 feet, these effects occur within 5 to 12 minutes. Significant effects of hypoxia can occur at lower altitudes as a result of: · Inhalation of carbon monoxide while smoking · Small amounts of alcohol or certain drugs (antihistamines, tranquilizers, analgesics, sedatives). · Extreme heat or cold Aeromedical factors http://www.uncletom2000.com/gs/aeromed.htm (3 of 8) [1/23/2003 11:19:15 AM] · Fever · Anxiety or fear Use of supplemental oxygen above 10,000 feet in day and 5,000 feet at night will inhibit the onset of hypoxia. Hyperventilation This is the abnormal increase in the volume of air breathed in and out. It can occur subconsciously when under stress or fear. The rapid breathing and excess oxygen flushes too much of the natural carbon dioxide from your system. The symptoms are dizziness, tingling of the extremities, hot and cold sensations, drowsiness, nausea and feelings of suffocation. Recognition of these symptoms often lead to more apprehension and fear resulting in increased hyperventilation. Disorientation, muscle spasms, and unconsciousness if corrective action is not taken. Corrective action can be breathing slowly into a paper bag held over your nose and mouth. Also, talking, singing, and counting out loud can assist in taking your mind off the apprehension causing the rapid breathing. It should be noted that many of the symptoms are common to both hypoxia and hyperventilation. If you are using an oxygen system when symptoms occur, turn the oxygen regulator to 100%. Carbon Monoxide Carbon monoxide results from the incomplete burning of materials. It is usually found in engine exhaust and cigarette smoke. Carbon monoxide is tasteless, odorless, and invisible. It is however usually present in fumes which are detectable. In an aircraft, cabin air is heated by intake air flowing across the exhaust manifold. Lleakage of fumes from the exhaust system into the heated airflow can be dangerous. You should be particularly cautions when operating in cold weather. Exposure of even a small amount of carbon monoxide over a long period of time can significantly impair pilot performance. Symptoms are feeling of sluggishness, headache, tightness across the forehead. These may be followed by increasing symptoms of throbbing in the temples, or ringing in the ears. Large accumulations can lead to vomiting, convulsions and death. Motion Sickness Motion sickness from the stimulation of the inner ear which controls your sense of balance. The symptoms are progressive. They are loss of desire for food, excessive saliva, perspiration, nausea, and tendency to vomit. If you or a passenger are suffering from airsickness, you should: Aeromedical factors http://www.uncletom2000.com/gs/aeromed.htm (4 of 8) [1/23/2003 11:19:15 AM] · Open air vents · Loosen clothing · Use supplemental oxygen if available · Keep eyes on a point outside the aircraft · Avoid rapid or unnecessary head movements · Land as soon as possible Pilots susceptible to motion sickness should NOT take motion sickness drugs. Research has shown these drugs may cause temporary disorientation, loss of navigational skills, or other functions which demand keen judgment. Sinus and Ear Block During ascent and decent the pressure inside the sinuses normally adjust to the cabin pressure. Conditions such as colds and nasal infections can significantly close the passages which permit this pressure equalization. This causes sinus block. It can cause significant pain in the affected sinus region, tooth ache, and mucus discharge from the nasal passages. During decent, the Eustachian tube of the middle ear opens to allow pressure relief into the nasal passages. During decent the pilot should periodically reopen the Eustachian tubes by swallowing, yawning, tensing muscles in the throat or chewing. If this fails, blowing with the nose with the mouth closed and the nose pinched off can usually equalize the pressure. A cold or ear infection can produce enough mucus in the Eustation tube to prevent pressure equalization. This results in ear block. If either sinus block or ear block persists for some period after landing , consult a physician. Rupture of the ear drum or infection in the ear can result from failure to relieve the condition after some period of time. Spatial Disorientation Spatial disorientation (formerly referred to as vertigo) results from loss of visual contact with terrain or other visual reference points. It is the result of confusing sensations sent to the brain by the muscles and inner ear when visual reference is lost. One cannot tell whether they are ascending, descending or turning. It is a REAL threat to the VFR pilot who has had insufficient training in flying solely by reference to instruments. Much of the training of instrument pilots is devoted to the reliance and interpretation of the instruments instead of their sensations. Situations which can quickly lead to spatial disorientation are: Aeromedical factors http://www.uncletom2000.com/gs/aeromed.htm (5 of 8) [1/23/2003 11:19:15 AM] · Flight into cloud · Flight at night over unlighted terrain (loss of horizon reference) · Facing the sun in haze condition · Flying above a cloud layer with sloping top If inadvertently caught in such condition, DON’T PANIC. If you have been trimmed out for straight and level, do not make any drastic or sudden moves in the attitude of the aircraft. LOOK AT YOUR COMPASS HEADING. Get On The Gauges. Concentrate on flying by the instruments. Learn how to use them and to trust them. Keep a level attitude. Your worst enemy is getting into a steep bank. If need be, turn the aircraft with light rudder pressure only, with hands off the wheel or stick. Even though this is an un-coordinated turn, you will not get the aircraft into a dangerous unusual attitude. Try to get out of the condition by slowly doing a 180° turn, or a turn away from the conditions causing the disorientation. Keep your angle of bank 15° or less. A 15° bank will take you 1 minute to complete a 180° turn. Fear We all at times experience fear. The question is how do we respond to fearsome situations. Flying is not without it’s anxious moments. It is easy to say “DON’T PANIC”; but that is exactly what is required of the pilot in command. The best defense against fear is TRAINING. This is why your instructor will put you into situations which will test your perception and judgment skills. Even after you obtain your private license, continue to train and learn. Flying is a lifetime learning experience. After you have achieved some experience, consider obtaining an instrument rating. Weather situations will be the prime cause for anxious moments. The more confidence you can gain in handling instrument conditions, the safer you will be. This does NOT mean pushing yourself beyond your training; rather it means getting the training and experience to handle whatever situation that may arise. There is a trite but true saying that “there are bold pilots, and there are old pilots; but there are no old bold pilots”. There are however many old experienced pilots around who have flown thousands of hours safely and with confidence. Ability and confidence is the key to handling fear. Vision Good vision is important to safe flying. The eye contains two different light sensitive nerve endings called the RODS and the CONES. They are located in the back of the eye in the area called the retina. The CONES are concentrated around the center of the retina, and decrease in number as the distance from the center of the retina increases. They are the nerves which predominately detect color, details and distant objects. They function in daylight and moonlight. Aeromedical factors http://www.uncletom2000.com/gs/aeromed.htm (6 of 8) [1/23/2003 11:19:15 AM] The RODS are concentrated around the area of the cones, and increase in number as the distance from the center of the retina increases. Their function is to detect objects in motion out of the corner of the eye (peripheral vision). They function in daylight, moonlight and darkness. This is an important concept to understand with regard conflict avoidance with other aircraft. During the day, objects can best be seen by looking directly at them. Your scan for other aircraft and objects should be in deliberate scan increments of about 10 degrees. Look at this area for several seconds, then look at the next 10 degree increment in your scan. Pausing to concentrate on a given area of vision is important since the eye cannot detect distant objects when in a continuous scan movement. At night, vision is more dependent on the RODS. “Off-center viewing” is best. The eye is more adept to seeing objects through the use of peripheral vision. With some practice, you can see objects better by using “off center” viewing rather than looking directly at them. When entering darkness, the pupils of the eye enlarge to receive as much of the light as possible. It will take 5 to 10 minutes for the adjustment to increase your “dark” vision by a factor of 100. After 30 minutes, the rods will be fully adjusted, and the rod’s sensitivity to light will become approximately 100,000 times more sensitive to light than in bright light. For night flight, you should allow your eyes to adapt to the darkness for some time to achieve best night vision acuity. Once your vision has adjusted, guard against exposing your eyes to bright light, as temporary blindness and illusion can result. Night vision can be adversely by low oxygen levels at altitude. It is best to keep cabin altitude to 5,000 feet or less at night. In higher altitude is necessary, use of oxygen is advised. Smoking can reduce night vision by as much as 20%. Personal Evaluation Often pilots are tempted to demonstrate their skill to others, and to prove they are made of the right stuff. This leads many pilots into serious pitfalls. Every pilot should continuously and HONESTLY evaluate their medical fitness for flight, and their skills and competency. Pitfalls All experienced pilots have at one time or another had to face some dangerous attitude situations and pressures. Some of these are: · Peer Pressure - This is based on an emotional response to equal or exceed the skills of your peers which push you beyond realistic evaluation of your situation · Mind Set - may make you fail to realistically recognize and cope with the situation. Aeromedical factors http://www.uncletom2000.com/gs/aeromed.htm (7 of 8) [1/23/2003 11:19:15 AM] · Get there at all Cost- this can result in business schedules or friends who are relying on you “to get there”. This is probably the greatest single cause of weather related accidents. It causes one to “press on” to the initial objective, rather than select safer alternative actions when things do not go as planned. There is no shame in “setting out the weather”. · Duck Under - the tendency for pilots to go below “minimums” on an instrument approach to “sneak a peek” hoping to avoid a “missed approach”. · Scud Running - is trying to fly below the scud (clouds) without hitting the ground. It’s trying to make it there in poor MVFR ( or less) conditions by dodging the clouds at low altitudes and visibility. · Continuing VFR into IFR conditions - Continuing flight into weather conditions adverse to VFR flight. · Getting behind the aircraft - this occurs when events are controlling you instead of you controlling the events. · Loss of positional awareness - its the situation where your instructor says “Enough for today, take me back to the airport”; and you have no idea which way it is. You have been so occupied with other matters that you do not know where you are. · Operating with inadequate Fuel Reserves - This occurs when the pilot fails to properly plan the trip, fails to observe flight progress, and becomes non-responsive to the VFR and IFR fuel reserve regulations. It also occurs to pilots who are lost, and delay getting help from ATC. · Inadequate Planning - Failure to plan the course and alternative actions. Negligent pre-flight inspection. Failure to use check lists. Failure to maintain positional awareness in flight. Hazardous Attitudes · Authority (Don’t tell me what to do) · Impulsivity - (Do Something NOW!) · Invulnerability - (It won’t happen to me) · Macho - (I can do anything) · Resignation - (What’s the use) Back to Home Back to Table of Conents Aeromedical factors http://www.uncletom2000.com/gs/aeromed.htm (8 of 8) [1/23/2003 11:19:15 AM] Preflight Services All Air Traffic Control Specialists assigned to AFSS are certified by the National Weather Service as Pilot Weather Briefers. Pilot Weather Briefers are authorized to translate and interpret available NWS products describing the enroute and destination weather. The leading contributing factor to general aviation accidents is weather. Pilot Weather Briefers are trained to help you avoid dangerous situations. PREFLIGHT BRIEFING The Airman's Information Manual states that pilots-in-command, BEFORE BEGINNING A FLIGHT, shall familiarize themselves with all available information concerning that flight. FSS's (Flight Servics Stations) are the primary source for obtaining preflight briefings and in-flight weather information. Pilots may walk into AFSS (Automated Flight Service Station) to review available aviation weather products and charts, or they may choose to use telephones or radio. Three types of preflight briefings are available: the Standard Briefing, Abbreviated Briefing, and the Outlook Briefing. Make it clear to the briefer at the outset what type of briefing you require, and then provide background information about the proposed flight. Required background information includes: l Type of Flight: VFR or IFR l Aircraft Identification or Pilot's Name l Aircraft Type l Departure Point l Estimated Time of Departure l Altitude l Route-of-Flight l Destination l Estimated Time Enroute Background information is mandatory data for the weather briefer. If any of these nine items are missing, a briefer may be unable to properly tailor the briefing to the specific flight the pilot has planned. STANDARD BRIEFING A Standard Briefing includes complete weather and aeronautical information for flight planning. Request a Standard Briefing when the flight will occur within six hours of the briefing. A Standard Weather Briefing includes: l Adverse Conditions - Current or forecast conditions which may adversely affect a planned flight, such as Convective SIGMETS, SIGMETS, AIRMETS, and Center Weather Advisories. Adverse conditions include (but are not limited to) icing, turbulence, thunderstorms, mountain obscuration, Preflight Services http://www.uncletom2000.com/gs/prefltbf.htm (1 of 3) [1/23/2003 11:19:17 AM] and instrument flight conditions. l VFR Flight Not Recommended (VNR) - When VFR flight is proposed and the actual or forecast conditions, surface based or aloft, in the briefer's judgment, make visual flight doubtful. Remember, the final go/no-go decision always belongs to the pilot. l Synopsis - A brief statement describing the type, location, and movement of weather systems affecting the flight. l Current Conditions - A summary of the current weather along the proposed route. The current weather is omitted when the estimated time of departure is more than two hours from the time of the briefing, unless requested by the pilot. l Enroute Forecast - Summarized from various sources, to provide forecast conditions along the proposed route of flight. l Destination Forecast - A destination forecast including significant changes one hour before and after the estimated time of arrival. l Winds Aloft Forecast - Available at 3,000; 6,000; 9,000; 12,000; 18,000; 24,000; 30,000; 34,000 and 39,000 feet. l Notices to Airmen - NOTAM D, NOTAM L, and non-published FDC NOTAMS. l ATC Delays - Information on known ATC delays (IFR only). Information on military training activity and published NOTAMS are provided upon request. View the National Weather Bureau's Standard Briefing Page. Caution: this is to be used for general information purposes only. You should get a formal pre-flight briefing from the FFS station in your area prior to your flight. ABBREVIATED BRIEFING Request an Abbreviated Briefing to supplement or update previously received information. Here are three examples of situations where an Abbreviated Briefing will work to your advantage: l You received a Standard Briefing earlier in the day. An Abbreviated Briefing could be requested for those items that have changed, such as current weather or updated forecasts. The briefer will need the background information and the time of the earlier briefing. l When you want only one or two items, request an Abbreviated Briefing and state the specific aviation weather products you need. "This is N12345, I would like an Abbreviated Briefing, the current and forecast weather at Bakersfield." Remember to provide the briefer with enough information to complete your request. In this example, Estimated Time of Arrival at Bakersfield would be required. The important point about an Abbreviated Briefing is what it does not do: it does not provide a complete weather picture of the route of flight. It should never be used as a shortcut for a standard briefing. An Abbreviated Briefing can save time if you have already received a Standard Briefing. OUTLOOK BRIEFING When the Estimated Time of Departure is more than six hours away, request an Outlook Briefing. After receiving the background information, the briefer will provide forecast data applicable to the proposed Preflight Services http://www.uncletom2000.com/gs/prefltbf.htm (2 of 3) [1/23/2003 11:19:17 AM] flight. If any portion of a briefing is unclear to you, stop the briefer and get the point clarified. Save your general questions until the end of the briefing. Preflight Services http://www.uncletom2000.com/gs/prefltbf.htm (3 of 3) [1/23/2003 11:19:17 AM] Other Aviation Sources OTHER AVIATION LINKS l Aviation Servers Harvard l The NASA Homepage l FAA Home Page l FAA Technical Center l Misc Aviation Misc Aviation Links This page hosted by Get your own Free Home Page Return to Index http://www.uncletom2000.com/gs/aviation.htm [1/23/2003 11:19:18 AM] Other Weather Sources OTHER WEATHER SOURCES l Ohio State U. Atmospheric Science Program l NCAR National Center for Atmospheric Research. l Michigan State U. Actual Weather Images l Indiana U. Actual Weather Images l Weather Channel Actual Weather Images l USA Today Weather Good Educational Stuff Also l U. North Carolina Weather Page l Intellicast Weather Search l U. North Carolina at Charlotte East Coast Weather l CNN WX Global Images l How the weather works Good Educational Material. l Weather Images. l PurdueWeather Dept WX Images and Maps l U. MichiganOver 300 Weather Locations http://www.uncletom2000.com/gs/wx.htm [1/23/2003 11:19:19 AM]