Wednesday, 18 November 2015

Components

C. ADF COMPONENTS2-71.jpg (15025 bytes)
The NDB Control Panels figure, on the right, shows the major ADF components except the receiving antenna, which on most light aircraft is a length of wire running from an insulator on the cabin to the vertical stabilizer.
l . RECEIVER: Controls on the ADF receiver permit the pilot to tune the station desired and to select the mode of operation. \When tuning the receiver the pilot must positively identify the station. The low or medium frequency radio beacons transmit a signal with 1,020 Hertz (cycles per second [Hz]) modification keyed to provide continuous identification except during voice communications. All air facilities radio beacons transmit a continuous two- or three-unit identification in Morse code, except for ILS front course radio beacons which normally transmit a continuous one letter identifier in Morse code. The signal is received, amplified, and converted to audible voice or Morse code transmission. The signal also powers the bearing indicator.
Tuning the ADF- To tune the ADF receiver, the pilot should follow these steps:
  1. turn the function knob to the RECEIVE mode. This turns the set on and selects the mode that provides the best reception. Use the RECEIVE mode for tuning the ADF and for continuous listening when the ADF function is not required;
  2. select the desired frequency band and adjust the volume until background noise is heard;
  3. with the tuning controls, tune the desired frequency and then re-adjust volume for best listening level and identify the station;
  4. to operate the radio as an automatic direction finder, switch the function knob to ADF; and
  5. the pointer on the bearing indicator shows the bearing to the station in relation to the nose of the aircraft. A loop switch aids in checking the indicator for proper operation. Close the switch. The pointer should move away from the bearing of the selected station. Then release the switch; the pointer should return promptly to the bearing of the selected station. A sluggish return or no return indicates malfunctioning of the equipment or a signal too weak to use.
2. CONTROL BOX - DIGITAL READOUT TYPE: Most modern aircraft have this type of control in the cockpit. In this equipment the frequency tuned is displayed as a digital readout of numbers rather than tuning a frequency band.
a) Function Selector (Mode Control). Allows selection of OFF, ADF, ANT or TEST Position.
  • ADF - Automatically determines bearing to selected station and displays it on the RMI. Uses sense and loop antennae.
  • ANT - Reception of Radio signals using the sense antenna. Recommended for tuning.
  • TEST - Performs ADF system self-test. RMI needle moves to 315°.
b) Frequency Selector Switches. Three concentric knobs, permit selection of operating frequency. Two frequencies can be preselected. Only one can be used at a time. The transfer switch indicates the frequency in use.
c) Selected Frequency Indicators. Provides a visual read-out of the frequencies selected. The numbers can be printed on drums that rotate vertically or, in more modern sets, they arc displayed by light emitting diodes.
3. ANTENNAE: The ADF receives signals on both loop and sense antennae. The loop antenna in common use today is a small flat antenna without moving parts. Within the antenna are several coils spaced at various angles. The loop antenna senses the direction of the station by the strength of the signal on each coil but cannot determine whether the bearing is TO or FROM the station. The sense antenna provides this latter information, and also voice reception when the ADF function is not required.
2-72.jpg (23083 bytes)4. BEARING INDICATOR: As mentioned above, the bearing indicator (see Fixed Card Bearing Indicator figure, on the right) displays the bearing to the station relative to the nose of the aircraft. If the pilot is flying directly to the station, the bearing indicator points to 0°. An ADF with a fixed card bearing indicator always represents the nose of the aircraft as 0° and the tail as 180°.
2-73.jpg (13403 bytes)Relative bearing (see NDB Bearings figure, on the left) is the angle formed by the intersection of a line drawn through the centerline of the aircraft and a line drawn from the aircraft to the radio station. This angle is always measured clockwise from the nose of the aircraft and is indicated directly by the pointer on the bearing indicator.
Magnetic bearing (see NDB Bearings figure, on the left) is the angle formed by the intersection of a line drawn from the aircraft to the radio station and a line drawn from the aircraft to magnetic north. The pilot calculates the magnetic bearing by adding the relative bearing shown on the indicator to the magnetic heading of the aircraft. For example, if the magnetic heading of the aircraft is 40° and the relative bearing 210°, the magnetic bearing to the station is 250°. Reciprocal bearing is the opposite of the magnetic bearing, obtained by adding or subtracting 180° from the magnetic bearing. The pilot calculates it when tracking outbound and when plotting fixes.
D. ADF OPERATIONS
1. MONITORING: Since the ADF receiver normally has no system failure or "OFF warning flags to provide the pilot with immediate indication of a beacon failure or receiver failure, the ADF audio must be monitored. The "idents" should be monitored anytime the ADF is used as a sole means of en route navigation. During the critical phases of approach, missed approach and holding, at least one pilot or flight crew member shall aurally monitor the beacon "idents" unless the aircraft instruments automatically advise the pilots of ADF or receiver failure.
2. HOMING: One of the most common ADF uses is "homing to a station". When using this procedure, the pilot flies to a station by keeping the bearing indicator needle on 0° when using a fixed-card ADF (See Homing to an NDB figure, below right). The pilot should follow these steps: 2-74.jpg (18814 bytes)
  1. tune the desired frequency and identify the station. Set the function selector knob to ADF and note the relative bearing;
  2. turn the aircraft toward the relative bearing until the bearing indicator pointer is 0°; and
  3. continue flight to the station by maintaining a relative bearing of 0°.
The figure Homing to an NDB, on the right, shows that if the pilot must change the magnetic heading to bold the aircraft on 0° the aircraft is drifting due to a crosswind. If the pilot does not make crosswind corrections, the aircraft flies a curved path to the station while the bearing indicator pointer remains at zero. The aircraft in position 2 must keep changing its heading to maintain the 0° relative bearing while flying to the station.
The bracketing method used here is basically the same as that explained elsewhere. The major difference is that bracketing a VOR requires the pilot to bracket a radial identified by the TB needle, whereas bracketing an ADF magnetic bearing requires the pilot to identify it by using both the bearing indicator and the heading indicator.
2-75.jpg (45128 bytes)Assume the pilot of the aircraft in position l (see Bracketing an NDB Magnetic Bearing figure, on the right) desires to intercept the 090° magnetic bearing to the non-directional beacon. The pilot then sets up an intercept angle of 30° which is shown by the 120° heading of the aircraft. The ADF pointer indicates 340°. Because the magnetic bearing equals the magnetic heading of the aircraft and the relative bearing, the pilot adds 120° (the relative bearing) and finds that the aircraft is on the 100° magnetic bearing.
NOTE:
Whenever the aircraft heading and relative bearing equal more than 360° the pilot should subtract 360° from the resulting figure. The pilot then follows the rest of the bracketing procedure.
3. TRACKING FROM A STATION: A pilot can use ADF to track from a station by employing the principles of bracketing a magnetic bearing. The Tracking from an NDB figure, below left, illustrates an aircraft tracking outbound from a station with a crosswind from the north. The reciprocal bearing is 090°, and the pilot tracks this bearing by flying the aircraft with 10° of wind correction. The pilot knows that the aircraft is tracking a reciprocal bearing because the heading indicator (080°) and relative bearing (190°) equal the magnetic bearing (270°).2-76.gif (7856 bytes)
4. POSITION FIX BY ADF: The ADF receiver can help the pilot to make a definite position fix by using two or more stations and the process of triangulation. To determine the exact location of the aircraft, the pilot should use these procedures:
  1. locate two stations in the vicinity of the aircraft. Tune and identify each;
  2. set the function selector knob to ADF, then note the magnetic heading of the aircraft as read on the heading of the aircraft as read on the heading indicator. Continue to fly this heading and tune in the stations previously identified, recording the relative bearing for each station;
  3. add the relative bearing of each station to the magnetic heading to obtain the magnetic bearing. Correct the magnetic bearing for east-west variation to obtain the true bearing; and
  4. plot the reciprocal for each true bearing on the chart. The aircraft is located at the intersection of the bearing lines (see Position Fix by NDB figure, on the right).2-77.gif (1831 bytes)
5. TIME COMPUTATION TO FLY TO A STATION: Computing time to the station is basically the same for ADF as it is for VOR (refer to Article 2.2.3. E (2)) therefore, a brief example is sufficient here. The basic procedure is to:
  1. turn the aircraft until the ADF pointer is either at 090°s or 270°s and note the time; and
  2. fly a constant magnetic heading until the ADF pointer indicates a bearing change of 10°. Note the time again and apply the following formula:
(TIME IN SECONDS BETWEEN BEARING CHANGE)/(DEGREES OF BEARING CHANGE) equals TIME TO STATION IN MINUTES.
For example, if it takes 45 seconds to fly a bearing change of 10°, the aircraft is:
45 / 10 = 4.5 min from the station.
To find distance to a station multiply time by distance covered in one minute using TAS or preferably G/S.
As with VOR procedures, a 10° bearing change is the simplest and easiest to use in making this calculation. If the pointer moves so rapidly that a satisfactory time check cannot be obtained during a 10° bearing change, this rapid movement indicates that the aircraft is very close to the station

No comments:

Post a Comment