Introduction:
 The following represents both a curriculum, and a guide to instructors which, if followed, should produce 
competent pilots in minimum time, and with minimum effort. While individual instructors may find variations 
useful, most will find it advantageous to try the methods listed.  The order listed is also important as one area 
of exercise is designed to lead the student logically to the next.
This Guide has been adopted for use by the NZMAA with kind permission of RCAS (Australia).
(c) 1988 RCAS
1. 	ATTENTION SPAN AND OVERLOADING
1.1.	 It is most important to clearly establish the amount of commitment expected from the student 
prior to commencing his initial training. Once this has been agreed the Instructor should then also be 
committed to continuous and regular teaching sessions. It usually takes the average newcomer 
between five and six hours actual flying time to reach competent unassisted solo standard. 
Obviously, this varies with age, regularity of sessions and serviceability of equipment. Every effort 
should be made to achieve this within a six to twelve weeks period, depending on local factors and 
personal considerations.
1.1.1.	 It is necessary that the instructor be familiar with these phenomena, as he must, to be 
effective as an instructor, continually be aware of and monitor both items.
1.2.	 Most people have an attention span in an intensive situation such as flight instruction of little 
more than 10 to 15 minutes at best. Beyond this point nothing more is absorbed, thus continued 
instruction beyond this point is wasted. The instructor must learn to monitor the attention span of 
each student as each will have a different attention span depending on many variables, including the 
particular student, his disposition on the day, the stage of instruction and not least, the expertise and 
behaviour of the instructor.
1.3.	 For instance, an instructor who shouts at students should be instantly banished from all 
instructing as by upsetting the student he destroys the concentration and attention span of the student, 
thus making it impossible to carry out meaningful instruction. The student needs to be coaxed along, 
not terrorised!

1.4.	 Similarly, an instructor who talks too much can destroy the student's application to learning. 
He should be told what he is to do, shown what to do, if necessary, and left to do it. When he makes 
the same mistakes several times, then point out to him, as concisely as possible how to correct the 
situation.
1.5. 	Which leads us to overloading. This is a situation where the student is fed more information 
than he can handle at once, or where he is called upon to carry out more actions or make more 
decisions in a given time than he is capable of at the particular stage of his flying experience. A 
typical example is the common practice of expecting a new student to handle both elevator and 
rudder (or aileron) simultaneously, rather than teaching one, then the other, then combining the two. 
Additionally, if a model is flying too fast for the student this will lead to a shorter attention span and 
subsequent overloading.
1.6.	 Always remember - that a student who is overloaded will be confused and will lose attention 
and concentration. One who has passed out of his attention span will overload very easily. Thus the 
two are interlinked and equally crucial to effective, safe, instructing.
1.7.	 An example would be the student who, having flown for 10 minutes, is called on to essay his 
first landing. The result can well be disaster, caused by a student who is near to the end of his 
attention scan becoming overloaded by suddenly having the trauma of a first landing thrust upon 
him. In fact, the cause would really be a poor instructor who chose this moment to introduce the high 
workload of a landing.

2.	BEHAVIOUR OF THE INSTRUCTOR

2.1.	 The case of the shouting instructor has already seen mentioned. The behaviour of the 
instructor is crucial to the whole process of learning. He must present the whole thing in a palatable 
attractive form.
2.2.	It must be remembered that the flying student, full size or RC, is going to be in most cases. 
quite terrified of the whole thing. He is terrified that he will bend his new aeroplane, and terrified of 
making a fool of himself. There is also a good deal of apprehension to being taught by someone who 
obviously knows it all; someone to whom flying is easy.
2.3. 	Therefore, a gentle, smooth, considerate approach, recognising the terror of  the student, is 
essential. The necessary information must be supplied by the instructor, clearly and precisely, 
without unnecessary verbosity, and the student allowed to get on with it.
2.4. 	A good instructor will rarely, if ever, have to take the transmitter from the Student in other 
than a controlled and anticipated way. In other words, he will not usually allow an emergency type of 
situation to develop. He will achieve this by close control of height and position, and by careful 
instruction so that the student we be properly prepared for what he is called upon to do. In the event 
that it becomes necessary for the instructor to take the transmitter it should be done with as little 
drama as possible and should never be the start of a shouting match. The aeroplane should be righted, 
set in a safe position, and the transmitter returned to the student as soon as possible.
2.5.	 A good instructor will spend very little time flying the model himself, conversely, the 
instructor who does fly the model much of the time himself is a bad instructor, irrespective of his 
other attributes.
2.6. 	Most instruction will be carried out in a club type of situation where there will be other 
people flying, standing about, etc. It will sometimes be necessary for the instructor to protect the 
student from the eager beaver type who will try to talk to the student while flying, often doing untold 
harm This type must be taken aside and a sharp word or two delivered out of earshot of the student
2.7. With all the best intentions in the world, an Instructor must not neglect his own flying skills and 
should take steps to make sure that he retains his own expertise by setting aside flying time for 
himself without the burden of anxious students awaiting further instruction. Additonally, a good 
Instructor must at all times fly within his own limitations because overloading and attention span can 
and does affect everyone to some degree. Prior to taking on a new student, it is most important to 
clearly ascertain his/her previous aviation/aeromodelling experience. This will give you a solid basis 
from which to commence an efficient teaching programme. From this you can decide just how much, 
if any, 'JARGON' you can use and, how much you actually need to teach. Initially keep normal 
jargon to a minimum, or at least, explain it as you use it; after a short period of time it will become 
self explanatory.

3. 	THE CURRICULUM

3.1. 	INTRODUCTION
3.1.1. 	From the outset it should be understood that the ultimate aim of any instructor training people 
to operate R/C aircraft is to turn out pupils who are capable of flying safely, and who can fit into a 
busy club or contest scene with a minimum of discomfort to themselves and existing club members.
3.1.2.	In the past, there has been a tendency to accept a pupil as trained when he reaches a level of 
keeping the aircraft airborne and being able to put it down more or less upright
3.1.3.	To often, these flyers, when faced with the additional workload found on busy flying fields, 
go into overload and the result is what appears to be unsafe or dangerous flying when in fact they 
simply cannot cope with the restrictions (e.g. right hand circuits, sun or pits in the wrong place etc.), 
noise and presence of other aircraft, and so on, because during their training they developed bad 
habits, such as only doing left hand circuits, flying on quiet days, and generally avoiding unpleasant 
situations.
3.1.4. 	Obviously then, it is up to the training system to prepare pupils adequately for real life 
situations, and this must be done from the beginning, before the bad or restrictive habits start to form.
3.1.5. 	Consequently, it is important to vary the pupils training so that all manoeuvres are attempted 
in the reverse directions, e.g. left and right hand circuits, loops and rolls from left to right and right to 
left. This is absolutely vital during training, for any R/C pilot who has learned only one landing 
approach (left hand circuits for example) can relate just how difficult it is to attempt right hand 
circuits in emergency situations.
3.1.6.	 Keeping in mind then, that care must be exercised to avoid pupil overload, the required 
discipline must be introduced from the beginning and in readily absorbed portions.
3.1.7. 	Thus it should be pointed out to the pupil from the outset, that as he eventually has to guide 
the aircraft into a very narrow corridor in order to land on the flying field, he will be required to work 
in defined areas of the sky at all times during his training, in order that he learn the control skills 
required, to guide the aircraft, into the landing corridor. This becomes particularly important when 
one realises that the average student allows the aircraft to tow him around the sky, instead of guiding 
the aircraft in the correct general direction. Thus pupils end up with aircraft too far down wind, over 
pits and generally unsafe locations.
3.1.8. 	Actually it is reasonable to consider the entire training sequence as a preparation for landing. 
When taking into consideration, just how difficult it is to arrive over the landing spot, at the correct 
altitude, attitude and speed, it becomes obvious that the landing approach must be automatic in 
response if pupil overload is to be avoided at touchdown.
3.1.9. 	Thus during the entire training period increasing emphasis should be placed on the pupils 
ability to guide the aircraft into an increasingly narrow corridor thereby enhancing his skill at 
arriving over the landing Circle with a minimum of strain.
3.1.10. The approach to adopt in teaching an awareness of location is to define the flight area as 
illustrated in fig. 1. It must be understood by the student that each flypass regardless of height or 
direction should be made parallel with the strip, unless otherwise called for.

























Forbidden Area


Fig. 1
Note: Each individual club flying site will naturally have its own unique restrictions and 
limitations, because of the local layout. Consequently the left and right flanks and display 
area might have to be modified individually to accommodate these restrictions and local 
limitations.
3.1.11. Thus we now have a typical situation in which we have the Display Flying Area, Left and 
Right Flank, and the Forbidden or Pit Areas. Training can now proceed with even simple exercises to 
be carried out in one of the three acceptable areas. The instructor can now very easily ascertain the 
pupil's ability to hold the aircraft in the designated area and the pupil knows exactly what is required 
of him in advance of the training session. As the pupil becomes increasingly aware of his location 
and surroundings, this corridor should be narrowed down until at the final stages of the procedure 
turn training, the corridor should be precisely followed as this manoeuvre is the prelude to the 
landing approach, in that is contains all of the elements required in a correct approach. i.e. long 
straight flight, coming toward the pupil with controls reversed.
3.1.12. Time effort and care spent in the previous areas will pay handsome dividends when the first 
landings are attempted, as a well prepared student will find what is quite rightly accepted as the most 
grueling area of R/C flight training, reasonably simple, with the consequent reduction in repair times 
and a corresponding increase in confidence and enjoyment.
3.2. 	AIRFRAME CHECK-OUT
3.2.1. 	Sufficient time must be given to this item to ensure that the model is properly airworthy. 
Check engine mounting, plumbing, centre of gravity location, throttle setting, undercarriage secure, 
any signs of structural or covering problems which could affect flight, e.g. control neutrals and 
throws, presence of warps which could affect trim, battery states and range.
3.2.2. 	Do not take risks! Ensure that the aircraft is safe before flight. It may be practicable to lay off 
the job to a reliable and experienced club member, but do a final check yourself, particularly of 
control throws, sense and neutrals, as these, and a knowledge of any warps present will give some 
idea of what to expect in the air.

3.3. 	TEST FLIGHT
3 3.1. 	Fly safely! The worst sin an instructor can commit is to damage a student's aeroplane 
(excluding system failure). Check flight characteristics at high and low speed, stall and spin 
characteristics, trim accurately and check engine idle setting. Set control throws, not for your 
enjoyment but for the beginner. Enough elevator to flare on landing, enough rudder or aileron, 
whichever is the primary directional control, to control the aircraft at low speed on approach, which 
means usually not enough rudder to roll the model, or in the case of ailerons, 3 rolls in 7 or 8 
seconds. Remember, a beginner does not want a "touchy" aeroplane, but rather one which has 
smooth and progressive responses which allow him to feel how much control input he is applying. 
You are not setting the aeroplane up for you to go hot-dogging, you are setting it for a beginner. In 
general, most people use too much control sensitivity.

3 .4.	 FIRST FLIGHT
3.4.0.	 Note: Dexterity training has in the past been overlooked and this has become obvious by the 
lack of awareness of the difficulties students face in merely handling the transmitter controls. 
Consequently some basic form of finger exercises should be given in order that controls be 
located automatically and without distraction. Too often the student is preoccupied in 
locating the required control instead of flying the aircraft. This is particularly important in 
co-coordination the double axis controls. The student should be asked to practise finger 
dexterity at home, rather than taking up valuable time at the field, initially with the model 
pointing away from the operator, then towards himself until fully familiar with the operation. 
Then also practice with the model pointing at various angles to and from the operator. 
Practice should take place using the main sticks and also the trims until fully conversant with 
all inputs operated in the correct sense. A useful exercise to aid this practice is to place the 
TX under the table so that inputs are being made without being able to see the TX  Box. (In 
any real emergency situation, corrective action must be applied without looking at the TX.).

3.4.1. The student should be instructed in the use of the controls before the flight commences. The 
aircraft should then be flown to altitude high enough for safety, but not too high for the untrained 
eyes to see it clearly. The throttle should be retarded to about half power (correct setting depending 
on the particular aircraft) and the elevator trim set to maintain level flight 
Note: From this point on altitude control should be maintained by small, subtle, throttle 
adjustments. The aircraft should be positioned facing into wind, just upwind and out from the 
student.
3.4.1A. At this point it should be demonstrated that the aircraft will glide should the motor cut This 
will reduce the student's fear of the model crashing due to loss of power.
3.4.2. 	The student should now be handed the TX and asked to place the right thumb on top of the 
rudder or aileron stick whichever is the primary roll control (which will henceforth be referred to as 
aileron in the hope it will be such ). The instructor should stand on the student's left side and 
command the elevator.
Note. Where a three channel installation is used (throttle, rudder and elevator), the rudder 
should be arranged to be controlled by the aileron stick, i.e. right hand stick when using 
mode 1, as it will be the primary roll control.
3.4.3. The student should now be asked to bank the aircraft gently to the left by easing the stick to the 
left, then to bring the wing level again. Then to the right. He should be asked to bank the aircraft, to 
reduce bank, increase bank, hold bank angle constant, and to hold wings perfectly level during 
straight flight.
Note: It is important to stress that after having applied the initial control input, the main 
contral must be allowed to reccenter as the aircraft will continue to, e.g. roll, so long as that 
control is deflected. In preparation for a turn the procedure is as follows: With the aircraft 
flying straight, aileron on, aileron off, elevator on and hold. Opposite aileron to correct for 
straight flight when the turn is completed.
3.4.4. During this time the instructor must hold the aircraft perfectly level at all times with the 
elevator and make any altitude corrections by asking the student to "push the throttle forward 2 
notches", or, pull the throtte back 3 notches", whatever is needed. These commands should be called 
for at quiet times when no other command is needed in order to avoid overloading. In this way use of 
throttle is taught without it intruding on the primary controls.
3.4.5.	 The correct position for a pilot to stand on the flightline, whether a student or not, is at right 
angles to the runway direction. He should not stand either facing towards the model or facing away 
from the model. Bearing in mind that a model should normally be flown in front of the pilot, not 
overhead or around him.



3.4.6.	 As soon as some competence becomes evident, the instructor should move to the right of the 
student, take over the aileron stick, and ask the student to place his thumb on top of the elevator 
stick. It is important that the aircraft be suitably positioned so that as the exercise is commenced 
there will be as long a period of time as possible before a turn is needed.
3.4.7. 	The student should now be called on to "pull the nose or the aircraft up a little with the stick" 
Do now allow the aircraft to approach the stall, but as point cut the reduction in speed. Now call for 
the nose to be returned to level flight. Then call for the nose to be pushed down a little, and again 
point out the increase in speed. Now ask the student to hold the nose level as you make a turn. Show 
him that the nose will always drop in a turn and have him hold it level as you make a series of turns, 
gentle at first, then steeper, then varying. Again, as soon as competence is shown move on to the next 
part of the lesson.
Note: The order laid out here for the first flight is very important and should not be altered. 
As mentioned earlier the student will at this stage be very nervous. Thus it will be better to 
teach bank control first as this hasn't the overtones of disaster carried by elevator. Similarly 
'up' is taught before 'down' so that the student will have the feel of he elevator before he 
tries 'down ' and will make a better job of it.
3.4.8. 	While it is necessary to ensure that the student has a proper grounding on each control it is 
also well not to dwell longer than necessary on each section. Keep it interesting and the student will 
remain receptive to teaching.
3.4.9. The student should now be given both elevator and aileron and will not usually experience any 
real difficulty in using them together. He should still be under full guidance, that is, he should be 
called upon to make a "90 degree turn left", "270 degree turn right" etc. He should be made to fly 
straight and level between turns, as this is one of the hardest things to do. 
3.4.10. During this period, and all subsequent ones, it should be emphasised that the aircraft is never 
to be flown overhead but always out in front of the pilot, as flying overhead is dangerous due to the 
inability to accurately judge the pitch angle.
3.4.11.	 Unless wind or a difficult field precludes, it is a good idea to allow the motor to run out of 
fuel in the air. Have the student continue flying, keeping close control of the position of the aircraft 
so that the instructor can take over and land without problems. The object is to prove to the student 
that the loss of the motor does not mean the end of the world, and also to allow him to experience the 
different feel of the aircraft without the engine.


3.5. 	SUBSEQUENT FLIGHTS
3.5.1. 	As soon as turns are reasonable, the student should be introduced to flying figure eight 
patterns of varying sizes. This is used as an exercise in coordination between elevator and aileron.11

3 5.2. Begin with the outward figure 8 (fig. 3), and progress to the inward figure 8 (fig. 2).

	

Tx ?				    Tx ?
Fig 2: Inward		Fig 3: Outward
3.5.3. 	This manoeuvre is much more difficult than the outward figure 8 as the final turn is made 
whilst the aircraft is crossing in front of the pupil hence he must cope with apparent control reversal 
as well. This manoeuvre also forms the basis of the Right Hand Circuit (and the outward left hand 
circuit). For this reason it is a must in any training.
3.5.4. 	At about this point in the training program, increasing emphasis should be placed on 
positional accuracy. Figure 8's being ideal for this as a definite cross-over point can be defined, and 
the pupil made aware of his ability to achieve cross-over accuracy.
3.5.5. 	Even free flying should be carried out in a designated quadrant if this can be achieved 
without pupil overloading.
3.5.6. 	As competence is established, the time has come to relax the full guidance used to date, and 
also to instill more confidence. To this end the student should be told that the instructor wishes him 
to practice turns and straight flight without the instructor's help. Stay close to the student, let him 
sort himself out if possible. As soon as he can look after himself move away a little - far enough not 
to be looking over the student's shoulder, close enough in case of emergency, and watching the 
model always.
3.5.7. 	As the student progresses to the point where he can manage on his own, albeit well up, move 
further away. Do not relax vigilance. Stay close enough that you can reach the TX at a run if things 
should go wrong. Now is the time to let the student know that you have faith in his ability, that he is 
doing OK on his own, by letting him know that you are not standing with him any more. Use most 
any pretext, speak to someone or call a word of encouragement from some distance away, anything 
to unobtrusively let him know that you are no longer standing over him.
3.6. 	PREPARATORY EXERCISE FOR TAKEOFF AND LANDING
3.6.1. 	With both competence and confidence becoming established, it is now time to begin an 
exercise at preparing the student for take-off and landing. Have him fly the aircraft in toward himself 
from some distance out, passing by at normal cruise altitude, and flying on out away from himself. 
As soon as this can be done well, keeping a straight path with wings level, the takeoff can be taught.
Note: Because of the extreme effect of aircraft trim on flight performance, particularly take-
off and landings, some introductory instruction into the fundamentals of trimming should be 
given by demonstration of the degree to which all flying exercises may be simplified with the 
correct application of trim, Conversely, flying an out of trim aircraft can become almost 
impossible for the student and this should be demonstrated by the instructor in order that the 
lesson be driven home. Trimming exercises to be carried out by the student will be introduced 
at a later date. (See 3.9.)
3.7. 	TAKEOFF
3.7.1. 	With most modern models, take-off should be easily accomplished. Emphasis should be laid 
on gradual application of power while keeping the model straight, and using a little elevator to lift 
off, and make a gentle climb out with wings level until safe altitude is reached. Verbal instruction 
should be all that is necessary as the student has been well prepared and has watched the instructor 
take off on a number of occasions.
3 7.2. 	The possibility of an engine failure on take-off should always be taken into consideration. Up 
unto a certain critical point (depending on the individual design of the aircraft) during the take-off 
sequence, very little if anything can be done to cope effectively with the situation. However, there 
are a number of logical steps that can be followed that should eliminate the remote possibility of a 
dead stick during takeoff procedure:
a) Do not attempt to carry out a take off if not completely satisfied with engine perforrnance.
b) Always make full use of the available amount of runway. (Remember the runway behind you is 
of no use to you during an emergency.)
c) During the takeoff run, allow the wing to do the work, don't climb out too steeply, give the motor 
a chance without overloading it.
d) If the engine should give any signs or trouble during the take-off once committed in the air, 
quickly reduce the throttle, say back to half power,  and then carefully nurse the aircraft around 
the circuit, land it and re-adjust the motor.
e) If the engine does fail when still low and slow, don't try to turn back onto the runway, keep the 
wings level and land long - say down the runway or into the overshoot area (A turn should not be 
initiated after take off [except in some emergency, i.e. perhaps personal injury to someone] until 
the aircraft has reached a height from which it could be reasonably expected to be able to carry 
out a safe emergency landing if required.)
3.7.3.	The pilot's position should always be on the flightline including during the take-off sequence. 
However, during the initial take-off learning process, after carefully liaising with other modellers, the 
take-off should be practiced with the student standing behind the aircraft. Once this has been 
achieved safely and consistently, the student should be gradually required to move further away, in 
stages from behind the aircraft after each take-off until finally he is carrying out all take-offs from 
the correct t position on the flightline.
Note: Don't proceed out onto the runway until engine checks have seen carried out.
3.8. 	PROCEDURE TURNS
3.8.1. This sequence is included as it introduces overhead flying, sequential controlled turns, (in both 
position and altitude) and reinforces the pupil's ability to fly a straight line, both away from, and 
toward himself. As such it really is the most important manoeuvre when wishing to prepare a pupil 
for an accurate landing approach.
3.8.2. The pupil's ability to perform the following steps in the Procedure turn should be monitored 
and relayed to him in easy stages:
a) Level flight segment should be straight and level.
b) Aircraft should pass directly over landing area. 
c) Turns should be at a constant altitude. 
d) Turns should be completed in order that upwind and downwind tracks are superimposed. 

       Tx ?
Fig 4
3.8.3.	It is fairly obvious that this manoeuvre will require considerable practice, however once 
mastered the pupil will be able to exert considerable control ever his model in all phases of R/C 
flying.
3.8.4. 	By the time this manoeuvre is mastered, the pupil will be ready to begin landing approaches 
with a great deal of confidence in his ability to position his aircraft accurately.
Note: This manoeuvre is excellent to establish positional accuracy over the runway, however, 
it does have one limitation. During busy club flying activities, say when left hand circuits are 
the norm by other pilots, the right to left portion of this procedure is in conflict to the normal 
traffic pattern, and can result in possible head-on conflictions. This situation is reversed 
when carrying right hand circuits.
3.8.5. While the various exercises have been listed in a logical order which should basically be 
followed, in fact there is often an overlapping between the various exercises. This is because 
it is not wise to spend a whole flight, or a whole afternoon, hammering away at one particular 
aspect. Both student and instructor tend to become heartily sick of the whole bit if this is 
attempted.

3.9.	SIMPLE AEROBATICS TRAINING & TRIMMING
3.9.1. 	Orientation training should be inserted into the training program at the instructors discretion 
and is best described as being that part of training aimed at teaching or preparing the student to 
recover from difficult or out of control situations. This is best used as part of the monotony relief 
aspect of flight training and should include recovery from inverted flight, spins, loops, roils etc.
3.9.2.	However, this phase of training should also include trimming of an "out of trim aircraft". The 
devastating effect of a badly trimmed model on a novice flier, must not be overlooked, as many 
crashes are caused by this problem.
3.9.3. At first the model should be taken to a reasonable altitude. The student should be asked to 
displace initially the primary roll trim. He then notes the effect on the aircraft i.e. rolling with hands 
off. He should now be taught to retrim by setting the aircraft level with the main stick, applying some 
trim, resetting level again with stick and noting the result, repeating this procedure as necessary to 
achieve final trim. This procedure must be followed in order to prevent over-trimming in the 
opposite direction. The Instructor must remain extremely alert to the fact that the student may not be 
able to rectify this situation, and it is important that only one trim at a time initially be tampered 
with. Commensurate with the students progress, the instructor should follow up in stages, with single 
out of trim, then more than one out of trim situation, without the student's prior knowledge. The latter 
should be carried out during subsequent normal flight training, bearing in mind that even the more 
experienced fliers have difficulty in correct recovery, hence diligence on the instructor's part is 
essential.
3.10. 	CIRCUITS
3.10.1. The student should now be told the reason for the circuit i.e. the establishment of height, 
distance judgment explained to him. Varying wind and sun position should be used to build the 
ability to land from a right or left circuit. The ability to do this cannot be overstressed.

Power reduced here				Downwind Leg (level flight)


Base leg


"Gate"  		Final    		        Tx?

Fig 5

3.10.2. It is important to point out to the student that a correctly positioned circuit at the correct 
height leads to a good approach which in turn positions the aircraft for a good landing. To reduce the 
standard of the circuit and/or approach makes it all the more difficult for the landing. After 
demonstration, have the student fly the circuit pattern at the appropriate height and distance but 
initially maintaining height on base and final.
3.11. 	APPROACH
3.11.1. We now come to an important phase of our training - approach and landings. Despite their 
relevance and importance, there exists a lot of misunderstanding on the subject and before the 
instructor teaches this phase, it is paramount that he himself understands the  'why' philosophy in 
this area. Even more experienced fliers are to some degree unsure of executing a properly controlled 
approach and landing, basically because it has become oversimplified. N.B.There are no short cuts!
3.11.2. What follows is not intended to be exhaustive, nor is it an indication of the standard that a 
student must immediately reach, but rather to fully explain, and as a result initiate correct techniques 
that with practice, will reward all concerned.
3.11.3. It is important to point out to the student that a landing can only be expected to be made off a 
reasonably controlled approach, and that landings will not be attempted until the student can fly the 
aircraft reasonably well 'down the slot'. N.B. It is futile attempting landings before the approach is 
taught, as bad landings always result from poorly controlled approaches, and much harm can be 
done to a student's confidence and progress by pushing him into an unknown area too quickly.
3.11.4. The approach should be taught initially as an extension of the circuit and completed on final 
by 'going round' on the instructor's command. This is allowed to progress further and lower as the 
student gains experience and ability in flying the aircraft down the slot.
3.11.5. In order to be able to fly accurately down the final flight path or 'slot', the aircraft should 
pass through the 'gate' (see Fig.5) this gives the correct positional line-up down the centreline of the 
runway and, must therefore be continually monitored and maintained to achieve an accurate landing.
3.11.6. A landing is the result of an ACCURATELY FLOWN APPROACH, but before the correct 
techniques are explained, it is important to examine a common error. To do this, let us execute a 
glide approach to make a good landing on the field but whilst flying a square base. It is difficult to 
know under varying weather conditions, where to reduce power in order to arrive at the field in the 
correct landing configuration, and we must therefore assume that in most cases we end up either 
HIGH or LOW somewhere on final approach.

Fig 6
3.11.7. If approach is low, and we stretch the descent, we LOSE AIRSPEED, and consequently land 
SHORT and/or close to a STALLED condition. In the worst case, a flick roil will result.
3. 11.8. If approach is HIGH, and we dive slightly to prevent over-shooting, then we end up prior to 
landing with EXCESS AIRSPEED and consequently land FAST and LONG or FLOAT.
3.11.9. If we were now to make the approach power assisted, with flight path corrections being made 
by elevator as described, speed control remains erratic and power requirements also become 
confused. The fallacy that elevator is the primary control during final approach must be impressed 
upon the student.



3.12. THE CORRECT TECHNIQUE FOR A NORMAL APPROACH IS:
3.12.1.	Engine Assisted with approximately 1/4 power. It will be seen later that this is to correct 
BOTH high and low approach situations.
3.12.2. Attitude is controlled by ELEVATORS. Bear in mind that the modeller does not have direct 
airspeed indication and the only parameters available to him are his attitude along the flight path. The 
correct attitude throughout the approach is NOSE LEVEL (no flaps). Strictly speaking full size 
aircraft attitudes are constantly changing slightly in order to fly at the correct air speed irrespective of 
power output, but bear in mind the accurate information available to him in the way of e.g., airspeed 
indicators, rate of descent/climb indicators etc. The only major change in attitude is during the 
lowering of flaps where the nose attitude is LOWERED considerably. The only other variation to 
attitude throughout the approach is where a reducing airspeed approach is employed. Here, the nose 
attitude is gradually raised as speed drops off.
3.12.3. However, if we were to stand back for some distance and watch the full size aircraft fly a 
STABILIZED approach at the normal three degree approach angle, it would be difficult to notice any 
A TTITUDE CHANGES whatsoever. Reynolds number and other scale effects result in the model 
stalling and manoeuvring at far smaller angles to the airflow (angle of attack) than full size aircraft. It 
follows that any attitude changes on a model to produce a given result are generally less than the full 
size aircraft.
3.12.4. Due to the factors mentioned above, the 'model's' approach angle, and our airspeed 
requirements, the NOSE ATTITUDE for a no flapped approach is LEVEL. Impress on the student 
that he must do this continually with elevators. Provided our aircraft is established on the csorrect 
approach path and angle, the airspeed prior to landing will automatically be controlled within the 
required parameters.
3.12.5. Fight Path Angle (angle of descent) is controlled by THROTTLE.  Primarily power is used to 
'place' the aircraft on the correct approach path and not elevators. Power controls the rate of descent 
and hence the resultant flight path, and is normally reduced for approach at the commencement of 
base leg.
3.12.6. Any displacement from the correct approach path should be corrected so as to reintercept the 
required approach path as early and smoothly as possible, and not to continue high or low all the way 
in. This returns you to a situation where you regain maximum control over the aircraft, and one that 
you are most familiar with.
Fig 7
3.12.7. If approach is low:-lncrease power. This reduces the rate of descent and flattens the approach 
angle. Remember though, to keep the nose attitude level. With this attitude, too much power will 
stop the descent completely as models fly level quiet easily on 1/2 power so ease that throttle. Once 
the required approach is intercepted, reduce power back sufficiently to follow the correct path, but 
keeping nose attitude level.
3.12.8. If approach is high:-Reduce Power. This increases the rate of descent and therefore steepens 
the approach angle. N.B. Prolonged use of very low power settings will require a slight lowering of 
the nose attitude to prevent loss of airspeed. Once the required approach is intercepted, reintroduce 
power sufficeintly to follow the approach path and remember to return the nose attitude to level.
Note: The Approach Summarised: This must be understood and cannot be overemphasized to the 
student : 
a) EngineAssisted 1/4 power. 
b) Control Nose Attitude and therefore Airspeed, with Elevators. 
c) Use Throttle to place the aircraft where you want it to be.

3.13. 	LANDING
3.13.1. Most students are apprehensive about their first landings. This can be overcome in a rather 
sneaky fashion. After the student has practiced a couple of reasonable approaches, pick one that is 
most likely to produce a reasonable landing. Allow him to continue the approach over the threshold. 
Meanwhile the student is waiting for the instructors command to go round - but instead, a call of 
keep her steady, close the throttle, begin feeding in some up, a little more up, up . . . and, the aircraft 
lands. After the stunned silence, congratulate him on his first landing. This way the student does not 
have any traumas in anticipation of a landing coming up, and he will be most relieved that his hidden 
fear of landings was totally unjustified. Now we simply polish the technique, and more importantly, 
he student is much more relaxed than he would have been otherwise.
3.13.2. It is prudent now to discuss the correct landing technique. If the correct approach has been 
flown, then our speed should be sufficiently accurate, i.e., nose attitude level, on a descending flight 
path and approximately 1/4 power. Only experience with a particular model will dictate minor 
variations where applicable.
3.13.3. The aircraft should be flown over the threshold at an altitude of approximately five feet, this 
will allow a landing at about fifty feet inside the threshold. Remember this is the final aim, and the 
instructor's discretion is used here to help the student correct any out of tolerance situations. At this 
time the throttle should be closed completely and as the aircraft settles towards the runway, the 
round-out or flare is initiated. Discretion is used at earlier power reductions. At completion of the 
flare, the 'hold off' period is commenced where the aircraft is slowed down further, held off the 
ground but gradually allowed to sink and settle on the ground in a slightly nose high attitude. The 
aircraft has now landed at an airspeed just above the stall.
Note. It is important that the instructor remind the student of the requirement that wherever 
an approach or landing becomes difficult to control and/or out of reasonable tolerance, to 
'go round' rather than persisting with complex situatons he may not be able to control.
3.13.4. The importance of practice with less and less reliance on the instructor cannot be over-
emphasized, however it is necessary that before too long, glide approaches must be taught and 
carried out for obvious reasons.
3.14. GLIDE APPROACH
3.14.1. The glide approach (usually due to engine failure or out of fuel) must be taught separate to 
and after the normal or on approach and landing sequences. The reason for this manoeuvre and its 
method of execution are entirely different. Basically the difference is that on a normal approach, 
power is used to place or position the aircraft on the correct approach path. On a glide approach, the 
approach angle is already predetermined, and the only way we can make a good landing on the field 
is to manoeuvre the aircraft during descent in order to vary distance from the landing field.
3.14.2. In early stages of training where an engine has stopped unexpectedly, it is important not to 
push the student into gliding the aircraft back onto the ground, 'somewhere'due to the high risk of 
damage. The student must not be led to believe that desperate situations are a normal part of our 
airsport. The glide approach is basically an emergency exercise, and like any other phase only proper 
instruction will enable the student to cope with this situation correctly. If engine stoppage does occur 
in earlier training, then this is an ideal opportunity for the instructor to tactfully take control and 
demonstrate this manoeuvre, for its purpose is only too real.
3.14.3. The idea after the engine has stopped, is to try and position the aircraft on base leg. This is a 
position the pilot is most familiar with. Due to the steeper approach angle with no power, base leg is 
positioned slightly closer than would be under a power approach.


3.14.4. It is important to point out to the student that the NOSE ATTITUDE should be kept slightly 
low and MAINTAINED. This then controls our airspeed. The only way to make good an approach to 
the field is to MANOEUVRE the aircraft towards or away from the field to save or get rid of excess 
height respectively. If we were to use elevators for the purpose of height control, then the results 
would be similar to that described in the beginning of the approach section (see fig. 6).

3.14.5. Before concluding, some pertinent points need bearing in mind. Remember that your student 
may not always be a beginner, some of the more experienced fliers may want your assistance in 
some particular area.
3.14.6 The overshoot should be considered as an alternative continuation of the approach  During the 
early stages of circuit practice the overshoot will be he normal option. A decision to overshoot 
should be made early, not when a situation has developed which becomes a last minute panic. Once 
the decision has been made, the first step is to regain airspeed, usually lost during the approach 
sequence. This is achieved by increasing throttle response. The heading of the model should be kept 
along the runway centreline maintaining wings level to the ground, until a safe airspeed and safe 
height has been reached, and, if flown correctly the model should rejoin the circuit on the crosswind 
leg as in Fig. 5.

3.15. 	CIRCUIT SPEED CONTROL
3.15.1. This section is aimed primarily at the more high performance aircraft and is an area often 
overlooked entirely. A normal reaction even amongst the more experienced fliers, to powered 
approaches, is not being able to 'get down' or  'slow down enough' for landings. In the majority of 
cases their speed on downwind is still normal cruise or at least excessive. Make no mistake, unless 
you are flying the slower and/or older type of aircraft, you  MUST SLOW DOWN prior to entering 
or during the circuit appropriate to the aircraft type. The fact is and Note: DECELERATION IS 
GREATLY REDUCED on a descending flight path, so if they think they can slow down on base or 
final, then impress on them to forget it. Full size aircraft approach speeds, on late final , vary 
anything from 1/2  cruise speed for light aircraft to 1/3 to 1/4 FOR W.W.II fighters. Some high 
performance aircraft are already 1/2  cruise speed or less on downwind leg. Whilst various factors 
prevent the exact same ratios being used on model aircraft, the approximate relationship must surely 
apply. So the motto where applicable is "SLOW DOWN EARLY"!

3.16. 	CIRCUIT SIZE
3.16.1. Briefly, DON'T CROWD YOURSELF.  Fly a couple of circuits for the student where 
necessary in order to indicate to him the approximate size, and make sure you do give him plenty of 
room. Remember he can't think as quick as you can at the early stages.


3.16.2. Usually with a powered approach there is a tendency to result in an overshoot situation. It is 
generally caused by the following in any combination:
a) Downwind leg too close.
b) Base leg too close.
c) Excessive speed prior to or during approach.
d) Tailwind component on base leg and/or final approach.

3.17.	 WIND EFFECT ON BASE LEG
3.17.1. Crosswind landing situations have for too long caused unnecessary trauma and fear, if this is 
passed onto the student, then he would want to land from all directions at even the slightest 
crosswind. Except for strong crosswinds, reasonable approaches and landings can still be made with 
very little extra effort, provided we are prepared in advance of certain relevant factors. Students must 
be made aware of these in order to prevent their circuits from becoming guessing games.
3.17.2. In crosswind landing situations we must have either a tailwind or headwind component on 
base. Our aim is still to intercept final approach at the same height as usual, so we must compensate 
for wind effect and this can ONLY BE DONE with appropriate use of POWER, assuming our circuit 
size is still the same.
3.17.3. Headwind on base: As it now takes extra time to travel on base leg we risk losing too much 
height. We have a choice of either delaying the standard power reductions or by leaving on a little 
extra power. As the time spent on base leg is generally about five seconds, the time frame is 
relatively small and it is recommended that power reduction be made at the standard place, but to 
leave a little extra power than normal, and remember to take it off as soon as you turn onto final.
3.17.4. Tailwind on base: Travel along base leg with a tailwind is very rapid. No sooner you're on 
base and its time to turn onto final. Any power reduction greater than normal has very little time to 
take effect and this is clearly inadequate. You must reduce power EARLIER than normal even if it 
means reducing on late downwind, so that there is no delay in initiating approach descent.

4.	GENERAL OBSERVATIONS
4.1. 	It is wise to allow the student time to himself to practice without direct supervision. He needs 
this relaxation of authority, and the instructor his chance of a moment's break.
4.2. 	In the latter stages it is not unusual to find a situation where all aspects or flight are very 
good, with only perfection of he landing sequence remaining to be achieved.
4.3.	 Monotony can often be relieved here, by the introduction of some simple aerobatics. The 
loop should be taught first, as it is quite the simplest manoeuvre, yet has a very great mystique about 
it. In reality it requires use of only one control, and even that with no great precision in the simplest 
form.
4.4. 	The roll should be taught next, and is a much more difficult manoeuvre as it requires the 
coordinated use of elevator with rudder or aileron. It will also require that rudder or aileron travel be 
increased to allow a decent rate of roll, but by this stage the student should be able to handle this.
4.5. 	With the roll accomplished, the Immelman turn, Cuban eight, and split S turn can be easily 
added to the repertoire. One advantage of a working knowledge of simple aerobatics is that the pilot 
will be much better equipped to recover from unusual attitudes, he will also find his flying much 
more enjoyable.
4.6. 	During the course of this Instructor's Guide many references have been made to judgment of 
growing competence by the instructor. This judgment is something that takes time and experience to 
develop, as does each individual student. Instructing, or rather the art of instruction, is an art form in 
its own right, which can be raised to very high levels.
4.7. 	FINAL STUDENT BRIEFING
It is most important to emphasise to the student, once he/she has reached 'solo' standard that they are 
now at the basic minimum required standard and that to further improve, regular continuous flying 
practice is essential for overall enjoyment of the sport. Keeping a model in a serviceable and 
undamaged condition is directly related to consistency, especially close to the ground. In order to be 
reliable close to the ground, regular take-offs and landings should be practiced as often as possible, 
including both left hand and right hand circuits until all RESPONSES and reflexes become 
automatic. Additionally, at all stages of competence, fly within your own limitations. If it's too 
windy, wait for another day. If you wish to experiment with something new, do so at a safe height 
and, importantly think it out prior to attempting it. Especially about how you intend to recover from 
the new manoeuvre should you foul it up!  Learn to walk before you can run.  It helps keep models in 
one piece for your enjoyment!


 

NZMAA CLUB MANUAL		Section 8 : Instructor Guide			
	Page 8 - 1	Feb 98