Section 3. En Route Procedures
5-3-1. ARTCC Communications
a. Direct Communications, Controllers and Pilots.
1. ARTCC's are capable of direct communications with IFR air
traffic on certain frequencies. Maximum communications coverage is possible through the
use of Remote Center Air/Ground (RCAG) sites comprised of both VHF and UHF transmitters
and receivers. These sites are located throughout the U.S. Although they may be several
hundred miles away from the ARTCC, they are remoted to the various ARTCC's by land lines
or microwave links. Since IFR operations are expedited through the use of direct
communications, pilots are requested to use these frequencies strictly for communications
pertinent to the control of IFR aircraft. Flight plan filing, en route weather, weather
forecasts, and similar data should be requested through FSS's, company radio, or
appropriate military facilities capable of performing these services.
2. An ARTCC is divided into sectors. Each sector is handled by one
or a team of controllers and has its own sector discrete frequency. As a flight progresses
from one sector to another, the pilot is requested to change to the appropriate sector
discrete frequency.
b. ATC Frequency Change Procedures.
1. The following phraseology will be used by controllers to effect
a frequency change:
EXAMPLE-
(Aircraft identification) contact (facility name or location name and terminal function)
(frequency) at (time, fix, or altitude).
NOTE-
Pilots are expected to maintain a listening watch on the transferring controller's
frequency until the time, fix, or altitude specified. ATC will omit frequency change
restrictions whenever pilot compliance is expected upon receipt.
2. The following phraseology should be utilized by pilots for
establishing contact with the designated facility:
(a) When operating in a radar environment:
On initial contact, the pilot should inform the controller of the aircraft's assigned
altitude preceded by the words "level," or "climbing to," or
"descending to," as appropriate; and the aircraft's present vacating altitude,
if applicable.
EXAMPLE-
1. (Name) CENTER, (aircraft identification), LEVEL (altitude or flight
level).
2. (Name) CENTER, (aircraft identification), LEAVING (exact altitude or flight
level), CLIMBING TO OR DESCENDING TO (altitude of flight level).
NOTE-
Exact altitude or flight level means to the nearest 100 foot increment. Exact altitude or
flight level reports on initial contact provide ATC with information required prior to
using Mode C altitude information for separation purposes.
(b) When operating in a nonradar environment:
(1) On initial contact, the pilot should inform the controller of
the aircraft's present position, altitude and time estimate for the next reporting point.
EXAMPLE-
(Name) CENTER, (aircraft identification), (position), (altitude), ESTIMATING
(reporting point) AT (time).
(2) After initial contact, when a position report will be made, the
pilot should give the controller a complete position report.
EXAMPLE-
(Name) CENTER, (aircraft identification), (position), (time), (altitude), (type of
flight plan), (ETA and name of next reporting point), (the name of the next succeeding
reporting point), AND (remarks).
REFERENCE-
AIM, Position Reporting, Paragraph 5-3-2.
3. At times controllers will ask pilots to verify that they are at
a particular altitude. The phraseology used will be: "VERIFY AT (altitude)." In
climbing or descending situations, controllers may ask pilots to "VERIFY ASSIGNED
ALTITUDE AS (altitude)." Pilots should confirm that they are at the altitude
stated by the controller or that the assigned altitude is correct as stated. If this is
not the case, they should inform the controller of the actual altitude being maintained or
the different assigned altitude.
CAUTION-
Pilots should not take action to change their actual altitude or different assigned
altitude to the altitude stated in the controllers verification request unless the
controller specifically authorizes a change.
c. ARTCC Radio Frequency Outage. ARTCC's normally have at least one
back-up radio receiver and transmitter system for each frequency, which can usually be
placed into service quickly with little or no disruption of ATC service. Occasionally,
technical problems may cause a delay but switchover seldom takes more than 60 seconds.
When it appears that the outage will not be quickly remedied, the ARTCC will usually
request a nearby aircraft, if there is one, to switch to the affected frequency to
broadcast communications instructions. It is important, therefore, that the pilot wait at
least 1 minute before deciding that the ARTCC has actually experienced a radio frequency
failure. When such an outage does occur, the pilot should, if workload and equipment
capability permit, maintain a listening watch on the affected frequency while attempting
to comply with the following recommended communications procedures:
1. If two-way communications cannot be established with the ARTCC
after changing frequencies, a pilot should attempt to recontact the transferring
controller for the assignment of an alternative frequency or other instructions.
2. When an ARTCC radio frequency failure occurs after two-way
communications have been established, the pilot should attempt to reestablish contact with
the center on any other known ARTCC frequency, preferably that of the next responsible
sector when practicable, and ask for instructions. However, when the next normal frequency
change along the route is known to involve another ATC facility, the pilot should contact
that facility, if feasible, for instructions. If communications cannot be reestablished by
either method, the pilot is expected to request communications instructions from the FSS
appropriate to the route of flight.
NOTE-
The exchange of information between an aircraft and an ARTCC through an FSS is quicker
than relay via company radio because the FSS has direct interphone lines to the
responsible ARTCC sector. Accordingly, when circumstances dictate a choice between the
two, during an ARTCC frequency outage, relay via FSS radio is recommended.
5-3-2. Position Reporting
The safety and effectiveness of traffic control depends to a large extent
on accurate position reporting. In order to provide the proper separation and expedite
aircraft movements, ATC must be able to make accurate estimates of the progress of every
aircraft operating on an IFR flight plan.
a. Position Identification.
1. When a position report is to be made passing a VOR radio
facility, the time reported should be the time at which the first complete reversal of the
"to/from" indicator is accomplished.
2. When a position report is made passing a facility by means of an
airborne ADF, the time reported should be the time at which the indicator makes a complete
reversal.
3. When an aural or a light panel indication is used to determine
the time passing a reporting point, such as a fan marker, Z marker, cone of silence or
intersection of range courses, the time should be noted when the signal is first received
and again when it ceases. The mean of these two times should then be taken as the actual
time over the fix.
4. If a position is given with respect to distance and direction
from a reporting point, the distance and direction should be computed as accurately as
possible.
5. Except for terminal area transition purposes, position reports
or navigation with reference to aids not established for use in the structure in which
flight is being conducted will not normally be required by ATC.
b. Position Reporting Points. CFR's require pilots to maintain a
listening watch on the appropriate frequency and, unless operating under the provisions of
subparagraph c, to furnish position reports passing certain reporting points. Reporting
points are indicated by symbols on en route charts. The designated compulsory reporting
point symbol is a solid triangle  and the "on request" reporting point symbol is the open
triangle  .
Reports passing an "on request" reporting point are only necessary when
requested by ATC.
c. Position Reporting
Requirements.
1. Flights along airways or routes. A position report is required
by all flights regardless of altitude, including those operating in accordance with an ATC
clearance specifying "VFR- on-top," over each designated compulsory
reporting point along the route being flown.
2. Flights Along a Direct Route. Regardless of the altitude or
flight level being flown, including flights operating in accordance with an ATC clearance
specifying "VFR-on-top," pilots shall report over each reporting point
used in the flight plan to define the route of flight.
3. Flights in a Radar Environment. When informed by ATC that their
aircraft are in "Radar Contact," pilots should discontinue position reports over
designated reporting points. They should resume normal position reporting when ATC advises
"RADAR CONTACT LOST" or "RADAR SERVICE TERMINATED."
NOTE-
ATC will inform pilots that they are in "radar contact":
(a) when their aircraft is initially identified in the ATC system; and
(b) when radar identification is reestablished after radar service has been
terminated or radar contact lost.
Subsequent to being advised that the controller has established radar contact, this fact
will not be repeated to the pilot when handed off to another controller. At times, the
aircraft identity will be confirmed by the receiving controller; however, this should not
be construed to mean that radar contact has been lost. The identity of transponder
equipped aircraft will be confirmed by asking the pilot to "ident," "squawk
standby," or to change codes. Aircraft without transponders will be advised of their
position to confirm identity. In this case, the pilot is expected to advise the controller
if in disagreement with the position given. Any pilot who cannot confirm the accuracy of
the position given because of not being tuned to the NAVAID referenced by the controller,
should ask for another radar position relative to the tuned in NAVAID.
d. Position Report Items:
1. Position reports should include the following items:
(a) Identification;
(b) Position;
(c) Time;
(d) Altitude or flight level (include actual altitude or flight
level when operating on a clearance specifying VFR-on-top);
(e) Type of flight plan (not required in IFR position reports made
directly to ARTCC's or approach control);
(f) ETA and name of next reporting point;
(g) The name only of the next succeeding reporting point along the
route of flight; and
(h) Pertinent remarks.
5-3-3. Additional Reports
a. The following reports should be made to ATC or FSS facilities
without a specific ATC request:
1. At all times.
(a) When vacating any previously assigned altitude or flight level
for a newly assigned altitude or flight level.
(b) When an altitude change will be made if operating on a
clearance specifying VFR-on-top.
(c) When unable to climb/descend at a rate of a least 500
feet per minute.
(d) When approach has been missed. (Request clearance for specific
action; i.e., to alternative airport, another approach, etc.)
(e) Change in the average true airspeed (at cruising altitude) when
it varies by 5 percent or 10 knots (whichever is greater) from that filed in the flight
plan.
(f) The time and altitude
or flight level upon reaching a holding fix or point to which cleared.
(g) When leaving any
assigned holding fix or point.
NOTE-
The reports in subparagraphs (f) and (g) may be omitted by pilots of aircraft involved in
instrument training at military terminal area facilities when radar service is being
provided.
(h) Any loss, in controlled airspace, of VOR, TACAN, ADF, low
frequency navigation receiver capability, complete or partial loss of ILS receiver
capability or impairment of air/ground communications capability. Reports should include
aircraft identification, equipment affected, degree to which the capability to operate
under IFR in the ATC system is impaired, and the nature and extent of assistance desired
from ATC.
NOTE-
Other equipment installed in an aircraft may effectively impair safety and/or the ability
to operate under IFR. If such equipment (e.g. airborne weather radar) malfunctions and in
the pilot's judgment either safety or IFR capabilities are affected, reports should be
made as above.
(i) Any information relating to the safety of flight.
2. When not in radar contact.
(a) When leaving final approach fix inbound on final approach
(nonprecision approach) or when leaving the outer marker or fix used in lieu of the outer
marker inbound on final approach (precision approach).
(b) A corrected estimate at anytime it becomes apparent that an
estimate as previously submitted is in error in excess of 3 minutes.
b. Pilots encountering weather conditions which have not been
forecast, or hazardous conditions which have been forecast, are expected to forward a
report of such weather to ATC.
REFERENCE-
AIM, Pilot Weather Reports (PIREP's), Paragraph 7-1-19.
14 CFR Section 91.183(B) and (C).
5-3-4. Airways and Route Systems
a. Two fixed route systems are established for air navigation
purposes. They are the VOR and L/MF system, and the jet route system. To the extent
possible, these route systems are aligned in an overlying manner to facilitate transition
between each.
1. The VOR and L/MF Airway System consists of airways designated
from 1,200 feet above the surface (or in some instances higher) up to but not including
18,000 feet MSL. These airways are depicted on Enroute Low Altitude Charts.
NOTE-
The altitude limits of a victor airway should not be exceeded except to effect transition
within or between route structures.
(a) Except in Alaska and coastal North Carolina, the VOR airways
are predicated solely on VOR or VORTAC navigation aids; are depicted in blue on
aeronautical charts; and are identified by a "V" (Victor) followed by the airway
number (e.g., V12).
NOTE-
Segments of VOR airways in Alaska and North Carolina (V56, V290) are based on L/MF
navigation aids and charted in brown instead of blue on en route charts.
(1) A segment of an airway which is common to two or more routes
carries the numbers of all the airways which coincide for that segment. When such is the
case, pilots filing a flight plan need to indicate only that airway number for the route
filed.
NOTE-
A pilot who intends to make an airway flight, using VOR facilities, will simply specify
the appropriate "victor" airways(s) in the flight plan. For example, if a flight
is to be made from Chicago to New Orleans at 8,000 feet, using omniranges only, the route
may be indicated as "departing from Chicago-Midway, cruising 8,000 feet via Victor 9
to Moisant International." If flight is to be conducted in part by means of L/MF
navigation aids and in part on omniranges, specifications of the appropriate airways in
the flight plan will indicate which types of facilities will be used along the described
routes, and, for IFR flight, permit ATC to issue a traffic clearance accordingly. A route
may also be described by specifying the station over which the flight will pass, but in
this case since many VOR's and L/MF aids have the same name, the pilot must be careful to
indicate which aid will be used at a particular location. This will be indicated in the
route of flight portion of the flight plan by specifying the type of facility to be used
after the location name in the following manner: Newark L/MF, Allentown VOR.
(2) With respect to position reporting, reporting points are
designated for VOR Airway Systems. Flights using Victor Airways will report over these
points unless advised otherwise by ATC.
(b) The L/MF airways (colored airways) are predicated solely on
L/MF navigation aids and are depicted in brown on aeronautical charts and are identified
by color name and number (e.g., Amber One). Green and Red airways are plotted east and
west. Amber and Blue airways are plotted north and south.
NOTE-
Except for G13 in North Carolina, the colored airway system exists only in the state of
Alaska. All other such airways formerly so designated in the conterminous U.S. have been
rescinded.
2. The jet route system consists of jet routes established from
18,000 feet MSL to FL 450 inclusive.
(a) These routes are depicted on Enroute High Altitude Charts. Jet
routes are depicted in black on aeronautical charts and are identified by a "J"
(Jet) followed by the airway number (e.g., J12). Jet routes, as VOR airways, are
predicated solely on VOR or VORTAC navigation facilities (except in Alaska).
NOTE-
Segments of jet routes in Alaska are based on L/MF navigation aids and are charted in
brown color instead of black on en route charts.
(b) With respect to position reporting, reporting points are
designated for jet route systems. Flights using jet routes will report over these points
unless otherwise advised by ATC.
3. Area Navigation (RNAV) Routes.
(a) RNAV is a method of navigation that permits aircraft operations
on any desired course within the coverage of station referenced navigation signals or
within the limits of a self-contained system capability or combination of these.
(b) Fixed RNAV routes are permanent, published routes which can be
flight planned for use by aircraft with RNAV capability. A previously established fixed
RNAV route system has been terminated except for a few high altitude routes in Alaska.
(c) Random RNAV routes are direct routes, based on area navigation
capability, between waypoints defined in terms of latitude/longitude coordinates,
degree-distance fixes, or offsets from established routes/airways at a specified distance
and direction. Radar monitoring by ATC is required on all random RNAV routes.
b. Operation above FL 450 may be conducted on a point-to-point
basis. Navigational guidance is provided on an area basis utilizing those facilities
depicted on the enroute high altitude charts.
c. Radar Vectors. Controllers may vector aircraft within controlled
airspace for separation purposes, noise abatement considerations, when an operational
advantage will be realized by the pilot or the controller, or when requested by the pilot.
Vectors outside of controlled airspace will be provided only on pilot request. Pilots will
be advised as to what the vector is to achieve when the vector is controller initiated and
will take the aircraft off a previously assigned nonradar route. To the extent possible,
aircraft operating on RNAV routes will be allowed to remain on their own navigation.
d. When flying in Canadian airspace, pilots are cautioned to review
Canadian Air Regulations.
1. Special attention should be given to the parts which differ from
U.S. CFR's.
(a) The Canadian Airways Class B airspace restriction is an
example. Class B airspace is all controlled low level airspace above 12,500 feet MSL or
the MEA, whichever is higher, within which only IFR and controlled VFR flights are
permitted. (Low level airspace means an airspace designated and defined as such in the Designated
Airspace Handbook.)
(b) Regardless of the weather conditions or the height of the
terrain, no person shall operate an aircraft under VFR conditions within Class B airspace
except in accordance with a clearance for VFR flight issued by ATC.
(c) The requirement for entry into Class B airspace is a student
pilot permit (under the guidance or control of a flight instructor).
(d) VFR flight requires visual contact with the ground or water at
all times.
2. Segments of VOR airways and high level routes in Canada are
based on L/MF navigation aids and are charted in brown color instead of blue on en route
charts.
5-3-5. Airway or Route Course Changes
a. Pilots of aircraft are required to adhere to airways or routes
being flown. Special attention must be given to this requirement during course changes.
Each course change consists of variables that make the technique applicable in each case a
matter only the pilot can resolve. Some variables which must be considered are turn
radius, wind effect, airspeed, degree of turn, and cockpit instrumentation. An early turn,
as illustrated below, is one method of adhering to airways or routes. The use of any
available cockpit instrumentation, such as Distance Measuring Equipment, may be used by
the pilot to lead the turn when making course changes. This is consistent with the
intent of 14 CFR Section 91.181, which requires pilots to operate along the centerline of
an airway and along the direct course between navigational aids or fixes.
b. Turns which begin at or after fix passage may exceed airway or
route boundaries. FIG 5-3-1 contains an example flight track
depicting this, together with an example of an early turn.
c. Without such actions as leading a turn, aircraft operating in
excess of 290 knots true air speed (TAS) can exceed the normal airway or route boundaries
depending on the amount of course change required, wind direction and velocity, the
character of the turn fix (DME, overhead navigation aid, or intersection), and the pilot's
technique in making a course change. For example, a flight operating at 17,000 feet MSL
with a TAS of 400 knots, a 25 degree bank, and a course change of more than 40 degrees
would exceed the width of the airway or route; i.e., 4 nautical miles each side of
centerline. However, in the airspace below 18,000 feet MSL, operations in excess of 290
knots TAS are not prevalent and the provision of additional IFR separation in all course
change situations for the occasional aircraft making a turn in excess of 290 knots TAS
creates an unacceptable waste of airspace and imposes a penalty upon the preponderance of
traffic which operate at low speeds. Consequently, the FAA expects pilots to lead turns
and take other actions they consider necessary during course changes to adhere as closely
as possible to the airways or route being flown.
FIG 5-3-1
Adhering to Airways or Routes
d. Due to the high airspeeds used at 18,000 feet MSL and above, FAA
provides additional IFR separation protection for course changes made at such altitude
levels.
5-3-6. Changeover Points (COP'S)
a. COP's are prescribed for Federal airways, jet routes, area
navigation routes, or other direct routes for which an MEA is designated under 14 CFR Part
95. The COP is a point along the route or airway segment between two adjacent navigation
facilities or waypoints where changeover in navigation guidance should occur. At this
point, the pilot should change navigation receiver frequency from the station behind the
aircraft to the station ahead.
b. The COP is normally located midway between the navigation
facilities for straight route segments, or at the intersection of radials or courses
forming a dogleg in the case of dogleg route segments. When the COP is NOT located at the
midway point, aeronautical charts will depict the COP location and give the mileage to the
radio aids.
c. COP's are established for the purpose of preventing loss of
navigation guidance, to prevent frequency interference from other facilities, and to
prevent use of different facilities by different aircraft in the same airspace. Pilots are
urged to observe COP's to the fullest extent.
5-3-7. Holding
a. Whenever an aircraft is cleared to a fix other than the
destination airport and delay is expected, it is the responsibility of the ATC controller
to issue complete holding instructions (unless the pattern is charted), an EFC time and
best estimate of any additional en route/terminal delay.
NOTE-
Only those holding patterns depicted on U.S. government or commercially produced (meeting
FAA requirements) low/high altitude enroute, and area or STAR charts should be used.
b. If the holding pattern is charted and the controller doesn't
issue complete holding instructions, the pilot is expected to hold as depicted on the
appropriate chart. When the pattern is charted, the controller may omit all holding
instructions except the charted holding direction and the statement AS PUBLISHED; e.g.,
HOLD EAST AS PUBLISHED. Controllers shall always issue complete holding
instructions when pilots request them.
c. If no holding pattern is charted and holding instructions have
not been issued, the pilot should ask ATC for holding instructions prior to reaching the
fix. This procedure will eliminate the possibility of an aircraft entering a holding
pattern other than that desired by ATC. If unable to obtain holding instructions prior to
reaching the fix (due to frequency congestion, stuck microphone, etc.), then enter a
standard pattern on the course on which the aircraft approached the fix and request
further clearance as soon as possible. In this event, the altitude/flight level of the
aircraft at the clearance limit will be protected so that separation will be provided as
required.
d. When an aircraft is 3 minutes or less from a clearance limit and
a clearance beyond the fix has not been received, the pilot is expected to start a speed
reduction so that the aircraft will cross the fix, initially, at or below the maximum
holding airspeed.
e. When no delay is expected, the controller should issue a
clearance beyond the fix as soon as possible and, whenever possible, at least 5 minutes
before the aircraft reaches the clearance limit.
f. Pilots should report to ATC the time and altitude/flight level
at which the aircraft reaches the clearance limit and report leaving the clearance limit.
NOTE-
In the event of two-way communications failure, pilots are required to comply with 14 CFR
Section 91.185.
g. When holding at a VOR station, pilots should begin the turn to
the outbound leg at the time of the first complete reversal of the to/from indicator.
h. Patterns at the most generally used holding fixes are depicted
(charted) on U.S. Government or commercially produced (meeting FAA requirements) Low or
High Altitude Enroute, Area and STAR Charts. Pilots are expected to hold in the pattern
depicted unless specifically advised otherwise by ATC.
NOTE-
Holding patterns that protect for a maximum holding airspeed other than the standard may
be depicted by an icon, unless otherwise depicted. The icon is a standard holding pattern
symbol (racetrack) with the airspeed restriction shown in the center. In other cases, the
airspeed restriction will be depicted next to the standard holding pattern symbol.
REFERENCE-
AIM, Holding, Paragraph 5-3-7j2.
i. An ATC clearance requiring an aircraft to hold at a fix where
the pattern is not charted will include the following information: (See FIG 5-3-2.)
1. Direction of holding from the fix in terms of the eight cardinal
compass points (i.e., N, NE, E, SE, etc.).
2. Holding fix (the fix may be omitted if included at the beginning
of the transmission as the clearance limit).
3. Radial, course, bearing, airway or route on which the aircraft
is to hold.
4. Leg length in miles if DME or RNAV is to be used (leg length
will be specified in minutes on pilot request or if the controller considers it
necessary).
5. Direction of turn if left turns are to be made, the pilot
requests, or the controller considers it necessary.
6. Time to expect further clearance and any pertinent additional
delay information.
FIG 5-3-2
Holding Patterns
j. Holding pattern airspace protection is based on the following
procedures.
1. Descriptive Terms.
(a) Standard Pattern. Right turns
(See FIG 5-3-3.)
FIG 5-3-3
Holding Pattern Descriptive Terms
(b) Nonstandard Pattern. Left turns
2. Airspeeds.
(a) All aircraft may hold at the following altitudes and maximum
holding airspee
ds:
TBL 5-3-1
Altitude (MSL) |
Airspeed (KIAS) |
MHA - 6,000' |
200 |
6,001' - 14,000' |
230 |
14,001' and above |
265 |
(b) The following are exceptions to the maximum holding airspeeds:
(1) Holding patterns from 6,001' to 14,000' may be restricted to a
maximum airspeed of 210 KIAS. This nonstandard pattern will be depicted by an icon.
(2) Holding patterns may be restricted to a
maximum airspeed of 175 KIAS. This nonstandard pattern will be depicted by an icon.
Holding patterns restricted to 175 KIAS will generally be found on instrument approach
procedures applicable to Category A and B aircraft only.
(3) Holding patterns at USAF airfields only - 310 KIAS maximum,
unless otherwise depicted.
(4) Holding patterns at Navy fields only - 230 KIAS maximum, unless
otherwise depicted.
(5) When a climb-in hold is specified by a published procedure
(e.g., "Climb-in holding pattern to depart XYZ VORTAC at or above 10,000." or
"All aircraft climb-in TRUCK holding pattern to cross TRUCK Int at or above 11,500
before proceeding on course."), additional obstacle protection area has been provided
to allow for greater airspeeds in the climb for those aircraft requiring them. The holding
pattern template for a maximum airspeed of 310 KIAS has been used for the holding pattern
if there are no airspeed restrictions on the holding pattern as specified in subparagraph j2(b)(2) of this paragraph. Where the holding pattern is restricted
to a maximum airspeed of 175 KIAS, the 200 KIAS holding pattern template has been applied
for published climb-in hold procedures for altitudes 6,000 feet and below and the 230 KIAS
holding pattern template has been applied for altitudes above 6,000 feet. The airspeed
limitations in 14 CFR Section 91.117, Aircraft Speed, still apply.
(c) The following phraseology may be used by an ATCS to advise a
pilot of the maximum holding airspeed for a holding pattern airspace area.
PHRASEOLOGY-
(AIRCRAFT IDENTIFICATION) (holding instructions, when needed) MAXIMUM HOLDING AIRSPEED IS
(speed in knots).
3. Entry Procedures.
(See FIG 5-3-4.)
FIG 5-3-4
Holding Pattern Entry Procedures
(a) Parallel Procedure. When approaching the holding fix from anywhere in sector (a),
the parallel entry procedure would be to turn to a heading to parallel the holding course
outbound on the nonholding side for one minute, turn in the direction of the holding
pattern through more than 180 degrees, and return to the holding fix or intercept the
holding course inbound.
(b) Teardrop Procedure. When approaching the holding fix from
anywhere in sector (b), the teardrop entry procedure would be to fly to the fix, turn
outbound to a heading for a 30 degree teardrop entry within the pattern (on the holding
side) for a period of one minute, then turn in the direction of the holding pattern to
intercept the inbound holding course.
(c) Direct Entry Procedure. When approaching the holding fix from
anywhere in sector (c), the direct entry procedure would be to fly directly to the fix and
turn to follow the holding pattern.
(d) While other entry procedures may enable the aircraft to enter
the holding pattern and remain within protected airspace, the parallel, teardrop and
direct entries are the procedures for entry and holding recommended by the FAA.
4 Timing.
(a) Inbound Leg.
(1) At or below 14,000 feet MSL: 1 minute.
(2) Above 14,000 feet MSL: 11/2 minutes.
NOTE-
The initial outbound leg should be flown for 1 minute or 1 1/2
minutes (appropriate to altitude). Timing for subsequent outbound legs should be adjusted,
as necessary, to achieve proper inbound leg time. Pilots may use any navigational means
available; i.e. DME, RNAV, etc., to insure the appropriate inbound leg times.
(b) Outbound leg timing begins over/abeam the fix, whichever
occurs later. If the abeam position cannot be determined, start timing when turn to
outbound is completed.
5. Distance Measuring Equipment (DME). DME holding is
subject to the same entry and holding procedures except that distances (nautical miles)
are used in lieu of time values. The outbound course of a DME holding pattern is
called the outbound leg of the pattern. The length of the outbound leg will be specified
by the controller. The end of the outbound leg is determined by the odometer reading.
(See FIG 5-3-5 and FIG 5-3-6.)
FIG 5-3-5
Inbound Leg Toward NAVAID
NOTE-
When the inbound course is toward the NAVAID and the fix distance is 10 NM, and the leg
length is 5 NM, then the end of the outbound leg will be reached when the DME reads 15 NM.
FIG 5-3-6
Inbound Leg Away from NAVAID
NOTE-
When the inbound course is away from the NAVAID and the fix distance is 28 NM, and the leg
length is 8 NM, then the end of the outbound leg will be reached when the DME reads 20 NM.
6. Pilot Action.
(a) Start speed reduction when 3 minutes or less from the holding
fix. Cross the holding fix, initially, at or below the maximum holding airspeed.
(b) Make all turns during entry and while holding at:
(1) 3 degrees per second; or
(2) 30 degree bank angle; or
(3) 25 degree bank provided a flight director system is used.
NOTE-
Use whichever requires the least bank angle.
(c) Compensate for wind effect primarily by drift correction on the
inbound and outbound legs. When outbound, triple the inbound drift correction to avoid
major turning adjustments; e.g., if correcting left by 8 degrees when inbound, correct
right by 24 degrees when outbound.
(d) Determine entry turn from aircraft heading upon arrival at the
holding fix; +/-5 degrees in heading is considered to be within allowable good
operating limits for determining entry.
(e) Advise ATC immediately what increased airspeed is necessary, if
any, due to turbulence, icing, etc., or if unable to accomplish any part of the holding
procedures. When such higher speeds become no longer necessary, operate according to the
appropriate published holding speed and notify ATC.
7. Nonstandard Holding Pattern. Fix end and outbound end turns are
made to the left. Entry procedures to a nonstandard pattern are oriented in relation to
the 70 degree line on the holding side just as in the standard pattern.
k. When holding at a fix and instructions are received specifying
the time of departure from the fix, the pilot should adjust the aircraft's flight path
within the limits of the established holding pattern in order to leave the fix at the
exact time specified. After departing the holding fix, normal speed is to be resumed with
respect to other governing speed requirements, such as terminal area speed limits,
specific ATC requests, etc. Where the fix is associated with an instrument approach and
timed approaches are in effect, a procedure turn shall not be executed unless the pilot
advises ATC, since aircraft holding are expected to proceed inbound on final approach
directly from the holding pattern when approach clearance is received.
l. Radar surveillance of outer fix holding pattern airspace areas.
1. Whenever aircraft are holding at an outer fix, ATC will usually
provide radar surveillance of the outer fix holding pattern airspace area, or any portion
of it, if it is shown on the controller's radar scope.
2. The controller will attempt to detect any holding aircraft that
stray outside the holding pattern airspace area and will assist any detected aircraft to
return to the assigned airspace area.
NOTE-
Many factors could prevent ATC from providing this additional service, such as workload,
number of targets, precipitation, ground clutter, and radar system capability. These
circumstances may make it unfeasible to maintain radar identification of aircraft to
detect aircraft straying from the holding pattern. The provision of this service depends
entirely upon whether controllers believe they are in a position to provide it and does
not relieve a pilot of their responsibility to adhere to an accepted ATC clearance.
3. If an aircraft is established in a published holding pattern at
an assigned altitude above the published minimum holding altitude and subsequently cleared
for the approach, the pilot may descend to the published minimum holding altitude. The
holding pattern would only be a segment of the IAP if it is published on the
instrument procedure chart and is used in lieu of a procedure turn.
m. For those holding patterns where there are no published minimum
holding altitudes, the pilot, upon receiving an approach clearance, must maintain the last
assigned altitude until leaving the holding pattern and established on the inbound course.
Thereafter, the published minimum altitude of the route segment being flown will apply. It
is expected that the pilot will be assigned a holding altitude that will permit a normal
descent on the inbound course.
|
