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I3101 WORKSHEET
Planned Route: Takeoff: KNPA, RWY 25R Altitude: 6000’ Route: Radar departure from KNPA BFM (VOR holding) SQWID Approaches: KMOB VOR-A (arcing approach),
KMOB RVFAC ILS RWY 15 KMOB RVFAC LOC RWY 15
Prerequisites: -IN1203-4, IN1206-7, IN1209-11, and IN1301-3 (Instruments CAI) -Q4390 (NATOPS check-ride) Syllabus Notes: -IUT shall meet or exceed these approach-type requirements. A minimum of six approaches are required for this block. GCA 1 (PAR or ASR) ILS 1 LOC 1 VOR 2 Special Syllabus Requirements: -None Discuss Items
a. UFCP DME HOLD function
b. FMS setup Flight plan and approaches may be loaded for training however flight should
be conducted PFD Source to VOR/LOC
c. Scan Patterns FTI information
d. Any emergency procedure
CNATRAINST 1552.165B IUT T-6B RADIO INSTRUMENTS I3100 BLOCK
IUT GRADE SHEET DATE __________________ INSTRUCTOR __________________________ MEDIA: OFT/UTD VT- ________ BRIEF TIME: ________ NAME: ________________________________ EVENT:__________
CTS REF
MANEUVER
MIF I3101 I3102 1 GENERAL KNOWLEDGE / PROCEDURES 3+ X X 2 EMERGENCY PROCEDURES 3+ X X 3 HEADWORK / SITUATIONAL AWARENESS 3+ X X 4 BASIC AIRWORK 4+ X X 5 IN-FLIGHT CHECKS / FUEL MANAGEMENT 3+ X X 6 IN-FLIGHT PLANNING /
AREA ORIENTATION 4+ X X
7 TASK MANAGEMENT 3+ X X 8 COMMUNICATION 4+ X X 9 MISSION PLANNING / BRIEFING /
DEBRIEFING 3+ X X
10 GROUND OPERATIONS 4 11 TAKEOFF 4+ X X 12 DEPARTURE 4+ X X 13 INSTRUCTIONAL SKILLS / STUNDENT
MANAGEMENT 3+ X X
41 STEEP TURNS 4+ X 42 IFR UNUSUAL ATTITUDES 4+ X 43 POINT-TO-POINT 3+ X 44 HOLDING 4+ X 45 ENROUTE PROCEDURES 4+ X X 46 ENROUTE DESCENT 4+ X X 47 HIGH-ALTITUDE APPROACH 3 48 TEARDROP APPROACH 4 49 ARCING APPROACH 4 X 50 HILO APPROACH 4 X 51 PROCEDURE TURN APPROACH 4 52 RVFAC APPROACH 4 X X 53 GPS APPROACH 4 54 PAR APPROACH 4 X 55 ASR APPROACH 4 X 56 VOR FINAL 3+ X X 57 ILS FINAL 3+ X 58 LOC FINAL 3+ X 59 GPS FINAL 3 60 BACKUP FLIGHT INSTRUMENT APPROACH 3 61 CIRCLING APPROACH 3 62 MISSED APPROACH 4 63 TRANSITION TO LANDING / LANDING 4+ X X
Syllabus Notes: a. I3101 shall be conducted in the OFT. I3102 should be conducted in the OFT, but it may be conducted in the
UTD. b. IUTs shall meet or exceed the following approach-type requirements:
1 GCA (PAR or ASR),1 ILS,1 LOC, 2 VOR A minimum of six approaches are required for this block.
Discuss 13101: UFCP, FMS Setup, Scan Patterns I3102: Battery Failure, Generator Failure, Backup Flight Instrument
1542.165B Rev 03/16/2017
348TWR
310
304
283
271
320
A5
A5
P
P
IAFSEMMES
115.3 SJI
Chan 100
540
321
SJI 7
BFM 9.2
SAINT
1800
(7)
BROOKLEY
112.8 BFM
Chan 75
MSA SJI 25 NM
3100
062°
242°
CATEGORY B C DA
CIRCLING 680-1 461 (500-1)780-2
561 (600-2)
1801501209060Knots
Min:Sec
FAF to MAP 5.6 NM
5:36 3:44 2:48 2:14 1:52
MOBILE, ALABAMA (MOB)
VOR or TACAN-A
ELEV 219
1800
within 10 NM
Remain
1800
5.6 NM
9002000
Chan
APP CRS
219Apt Elev
TDZE
Rwy Idg
115.3
100
MOBILE, ALABAMA
(MOB)
AL-267 (FAA)
ASR
N/AN/A
VORTAC SJIVOR or TACAN-A
SJI 5.6
UBACE
SAINT
MOBILE RGNL
MOBILE RGNL
GND CON UNICOM
122.95119.85
ATIS CLNC DEL
118.5 269.3 (CTAF)124.75 257.85
MOBILE APP CON MOBILE TOWER
118.3 239.0 L 121.9 348.6
480
T
SJI R-140
hdg 200°
373
104°
from FAF
104° 5.6 NM
284°
104°
30°41'N-88°15'W
104°
059°
239°
to SAINT INT/BFM 9.2 DME and hold.
right turn to 2000 on heading 200° and SJI R-140
MISSED APPROACH: Climb to 900, then climbing
C521 (600-1 )
SJI VORTAC
TACCU
(IF)
428
SJI 5.6
UBACE
380
365
744
Amdt 2A 29MAY14
17117
HIRL Rwy 15-33
MIRL Rwy 18-36
348
740-11212
3633
15
18
8502 X 1
50
xx
4376 X 1
50
R-242
R-140
R-284
R-238
1800
No
T
SJI
7Arc
Chan 1
04
R-1
74
115.7 G
CV
(IAF)
SJI 7
SQWID
P
H
HH
SE
-4, 17 AU
G 2017 to 14 S
EP
2017 SE
-4,
17 A
UG
201
7 to
14
SE
P 2
017
348TWR
310
304
283
271
320
A5
A5
P
P
A5
3633
15
18
8502 X 1
50
xx
4376 X 1
50
MOBILE, ALABAMA (MOB)
SEMMES
Chan 100
LOC I-MOB
APP CRS
109.9 145°
MOBILE, ALABAMA
ASR
A
Rwy Idg
TDZE
Apt Elev
from FAF
145° 4.8 NM
BROOKLEY
112.8 BFM
Chan 75
219
8502
AL-267 (FAA)
(MOB)
R-301
T
R-1
74
GC
V 1
15.7
Chan 1
04
061°
241°
R-061
R-1
74
ALTERNATE MISSED APCH FIX
Chan 104
GCV 115.7
BFM
MOBILE RGNL
MOBILE RGNL
R-061
Chan 27GPT
109
Chan 27GPT
109
GND CON UNICOM
122.95119.85
ATIS CLNC DEL
118.5 269.3 (CTAF)124.75 257.85
MOBILE APP CON MOBILE TOWER
L 121.9 348.6
1801501209060Knots
Min:Sec
FAF to MAP 4.8 NM
4:48 3:12 2:24 1:55 1:36
MALSR
30°41'N-88°15'W
ELEV TDZE219 215
Remain
within 10 NM
2000
325°
900 2000
4.8 NM
RADAR
CAYAT INT
1800
SAINT
145°
GS 3.00°
TCH 55
1800Angle 3.00/TCH 50).
not coincident (VGSI
VGSI and ILS glidepath
S-LOC 15
CIRCLING
CATEGORY
S-ILS 15
A
NA
B C D E
200°
hdg
**
700-1 481 (500-1)780-2
561 (600-2)
700/24 700/50
MSA SJI 25 NM
3100
280°
100°
145°
325°
x
(CFLSL)
SAINT
BFM 9.2
321
744
115.3 SJI
LOCALIZER 109.9
I-MOB
RADAR
CAYAT INT
(IAF)
521 (600-1 )
R-140 to SAINT INT/BFM 9.2 DME and hold.
right turn to 2000 on heading 200° and SJI VORTAC
MISSED APPROACH: Climb to 900 then climbing
118.3 239.0
RADAR REQUIREDCat E Procedure Turn NA -
SQWID
GPT 34.8
SQWID
GPT 34.8
R-140
SJI
380
215 ILS or LOC RWY 15
ILS or LOC RWY 15
38
**
4000 and S-LOC 15 Cats C/D/E visibility to 1 mile.
For inop MALSR increase S-ILS 15 Cat E visibility to RVR
RVR 1800 authorized with use of FD or AP or HUD to DA.
C
415/24
485 (500- ) 485 (500-1)
498
(16)
301°
2000 to CAYAT
HIRL Rwy 15-33
MIRL Rwy 18-36
Amdt 31A 29MAY14
17117
540
480
373365
348
200 (200- )12
12
740-11212
H
H
R-242
R-140
R-04
2
242°
062°
042° (3.6)
2000 to CAYAT
H
SE
-4, 17 AU
G 2017 to 14 S
EP
2017 SE
-4,
17 A
UG
201
7 to
14
SE
P 2
017
ILS NAVAID Setup - D LIDS
D LIDS is a useful acronym to help set up for the ILS approach.
• DME Hold (as required)
• Localizer Set ( Set frequency in UFCP )
• Inbound course (set FAC in the CDI )
• Display (set PFD NAV source for LOC)
• Speed Some examples: Radar downwind - 200 Straight-in - cruise speed until 5 nm from FAF Procedure track - 150 until 5 NM from FAF Procedure Turn - 150 until 5 NM from FAF
ILS NAVAID Setup - D LIDS
Lets look at the ILS RWY 13R at KNGP. Prior to turning off the ARC onto the Final Approach course or while being
vectored to final D LIDS would be need to be accomplished.
• DME Hold From the approach plate we can see that the DME for the approach is NOT from the Localizer I-NGP 111.3 but from the TRUAX VORTAC NGP 114.0 114.0 would be entered into the UFCP via W3 on the UFCP’s persistent display page. Once a VHF NAV frequency is loaded, it’s associated DME can be “locked IN” using the DME HOLD function.
ILS NAVAID Setup - D LIDS
On the UFCP press the NAV TUNE button until the DME page is displayed along with the NAVAID frequency you wish to HOLD
ILS NAVAID Setup - D LIDS
On the UFCP press the NAV TUNE button until the DME page is displayed along with the NAVAID frequency you wish to HOLD Press the W2 button to activate the DME Hold function. This will be indicated by an (H) following the frequency. (The (H) can be toggled on/off using the W2 button) Once set, the DME will remain referenced from this NAVAID until the (H) is removed.
ILS NAVAID Setup - D LIDS
•Localizer Set Using the UFCP return to the persistent display page and load the Localizer frequency I-NGP 111.3 into W3.
•Inbound Course Set the FAC into the CDI
ILS NAVAID Setup - D LIDS
•DISPLAY Ensure that PFD Source is set to LOC On the PFD note the Localizer frequency I-NGP 111.3 shown below the PFD SOURCE
ILS NAVAID Setup - D LIDS
•DISPLAY Ensure that PFD Source is set to LOC
On the PFD note the Localizer frequency shown below the PFD SOURCE •Below the Localizer frequency the Distance in NM and the DME hold NAVAID (NGP 114.0) appear in amber colored type.
•SPEED Maintain the speed appropriate for your position along the approach.
CHAPTER TWO PRIMARY INSTRUMENT NAVIGATION T-6B
204. SCAN PATTERNS
Once PAT is accomplished, SCAN to maintain the desired performance.
Scan is the systematic process of monitoring the crosscheck/performance instruments to detect deviation from desired flight parameters (error detection), then applying the proper controls to make an appropriate timely correction.
The goal is:
Early Error Detection and Correction!
In any scan method there are two basic groups of instruments:
Power/Control Instruments: The four basic inputs that the pilot can make in the aircraft are:
1. PITCH
2. ROLL
3. POWER
4. YAW
Initial Power and Attitude inputs are made referencing the Power/Control Instruments:
1. ADI
2. TORQUE
Crosscheck/Performance Instruments: These instruments are used to detect deviations from required performance and inform you of the inputs required to regain the desired flight parameters.
1. ALTIMETER
2. VSI
3. AIRSPEED
4. ANGLE OF BANK (ROLL POINTER)
5. TURN NEEDLE
6. HSI
2-2 FUNDAMENTAL INAV CONCEPTS
CHAPTER TWO PRIMARY INSTRUMENT NAVIGATION T-6B
7. SIDESLIP INDICATOR
An active scan will let you know which control needs adjusted, the direction it needs to be moved, and a sense of how much it should be moved.
HUB and SPOKE Method:
The Hub is the Attitude Gyro (ADI). The Spokes are the crosscheck/performance instruments. A basic instrument scan sequence consists of:
GYRO - Set required Attitude for desired performance
NOSE - Crosscheck nose instrument(s)
GYRO - Adjust Pitch to keep or return to desired parameters
WING - Crosscheck wing performance instrument(s)
GYRO - Adjust Roll to keep or return to desired parameters
PERFORMANCE/PROGRESS - Crosscheck aircraft performance/maneuver progress
GYRO - Stabilize attitude
ADDITIONAL - Fine tune the rudder for Yaw (sideslip) and Power for needed changes in torque
NOTE
Approximately 50% of the time the pilot should be looking at the ADI. This will aid in preventing unintended inputs while insuring desired inputs are appropriate and controlled. ADI is big picture, crosscheck/performance instruments are for fine tuning.
The crosscheck/performance instruments for Pitch, Roll, and Power depend upon the maneuver being conducted. The crosscheck for Yaw is always the sideslip indicator.
The following table outlines the different flight maneuvers you will encounter in this stage of training and the appropriate crosscheck/performance instruments.
FUNDAMENTAL INAV CONCEPTS 2-3
CHAPTER TWO PRIMARY INSTRUMENT NAVIGATION T-6B
MANEUVER NOSE CROSSCHECK
WING CROSSCHECK
PERFORMANCE/ PROGRESS INSTRUMENT
ADDITIONAL INSTRUMENTS
STRAIGHT AND LEVEL
ALTIMETER, VSI HSI AIRSPEED SIDESLIP, TORQUE
CONSTANT ANGLE OF BANK TURNS
ALTIMETER, VSI AOB HSI
AIRSPEED SIDESLIP, TORQUE
CONSTANT AIRSPEED CLIMBS & DESCENTS AIRSPEED HSI ALTIMETER SIDESLIP, TORQUE
CONSTANT RATE TURNS
ALTIMETER, VSI
TURN NEEDLE AOB
HSI CLOCK AIRSPEED
SIDESLIP, TORQUE
CONSTANT RATE CLIMBS & DESCENTS
AIRSPEED
HSI
ALTIMETER VSI CLOCK
SIDESLIP, TORQUE
CLIMBING OR DESCENDING TURN AT CONSTANT ANGLE OF BANK & AISPEED
AIRSPEED
AOB
HSI AIRSPEED
SIDESLIP, TORQUE
Figure 2-1 Crosscheck/Performance Instruments
205. SPATIAL DISORIENTATION
Spatial disorientation can be defined simply as a body sensation which tells the aviator that his aircraft is in a particular attitude, when the aircraft is actually in an entirely different position relative to the horizon. This false sensation is derived from a number of sources: the inner ear and vestibular stimulation are the most common.
Spatial disorientation usually does not occur when a pilot has visual reference to the horizon, or at least, the pilot pays little attention to his body feelings, since his sight simply overcomes them. Disorientation occurs when there is no reference to the horizon; however, this does not necessarily limit vertigo to flying in the clouds. It can occur when the aircraft is flying in visual meteorological conditions (VMC), on a day when there are large buildups, when flying above a layer of clouds, when flying in and out of a broken layer, or when launching at night with no clear horizon. Vertigo or the disorientation sensation is, and always will be, a factor in aviation, but is dangerous only when the pilot believes and flies his senses instead of the reliable instruments.
The spatial disorientation training in the T-6B will demonstrate and emphasize three specific facts:
1. A pilot’s attitude sensations are generally unreliable.
2. The pilot cannot recover to straight and level flight using these sensations.
3. Instruments are the only way to recognize and recover from unusual attitudes in Instrument Meteorological Conditions (IMC).
2-4 FUNDAMENTAL INAV CONCEPTS