Acceleration - Deceleration
An aircraft in flight retains energy in two forms; kinetic energy and potential
energy. Kinetic energy is related to the speed of the airplane, while potential
energy is related to the altitude above the ground. The two types of energy can
be exchanged with one another. For example when a ball is thrown vertically into
the air, it exchanges the kinetic energy (velocity imparted by the thrower), for
potential energy as the ball reaches zero speed at peak altitude.
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| Excess Thrust Energy Exchange |
When an airplane is in stabilized, level flight at a constant speed, the power
has been adjusted by the pilot so that the thrust is exactly equal to the drag.
If the pilot advances the throttle to obtain full power from the engine, the thrust
will exceed the drag and the airplane will begin to accelerate. The difference
in thrust between the thrust required for level flight and the maximum available
from the engine is referred to as "excess thrust". When the airplane finally reaches
a speed where the maximum thrust from the engine just balances the drag, the "excess
thrust" will be zero, and the airplane will stabilize at its maximum speed.
Notice that this "excess thrust" can be used either to accelerate the airplane
to a higher speed (increase the kinetic energy) or to enter a climb at a constant
speed (increase the potential energy), or some combination of the two.
There are energy exchange equations which can be used to relate the rate of
change of speed (or acceleration) to the rate of change of altitude (or rate of
climb). (These equations are introduced later.) In this way, level flight accelerations
(accels.) at maximum power can be used to measure the "excess thrust" over the
entire speed range of the airplane at one altitude. This "excess thrust" can then
be used to calculate the maximum rate of climb capability for an aircraft.
Level flight accelerations and decelerations (accels - decels.) are also used
to determine the stability of the airplane with respect to speed. As speed increases
a stable airplane will require more nose-down elevator and forward stick force
in order to keep the airplane from climbing. The magnitude of this change in trim
is a measure of the longitudinal stability of the airplane. At transonic speeds
there is a region of speed instability for most supersonic airplanes. The level
flight accel.-decel. defines the magnitude and the Mach region where this instability
occurs.
For a low performance airplane, such as a Cessna, the stick forces are directly
related to the elevator position, since the elevator is connected directly to
the stick through a system of cables or pushrods. For a high performance airplane,
such as an F-18 fighter, the elevator is moved by hydraulic actuators. The stick
forces that the pilot feels are produced artificially by a seperate "artificial
feel system". These stick forces may, or may not, be directly related to the position
of the elevator. In a modern fly-by-wire flight control system the electronic
computer serves to completely separate the commanded elevator position from the
pilots stick force, thus hiding any instabilities or trim changes (such as the
transonic instability mentioned above) from the pilot. The airplane will always
appear to be stable with regard to stick force, even though the elevator position
may clearly show an instability.
Accels. and decels. are also performed at constant altitude in turning flight,
especially for fighter aircraft. These maneuvers are used to identify the maximum
turning capability of an airplane at different altitudes and power settings and
are often referred to as windup turns, although they are usually flown at constant
"g". These maneuvers are used to define a term called "specific energy" (referred
to as "P sub s") for an airplane. This term is very useful in comparing friendly
and enemy aircraft. It helps identify which aircraft will have the advantage in
a dog-fight, and where within the flight envelope that advantage will be the greatest.
Specific Objective of the Test
Determine the acceleration capability (excess thrust) at a particular altitude
over the entire speed range of the airplane. Indirectly determine the rate of
climb capability at the selected altitude over the entire speed range of the airplane.
Determine the longitudinal speed stability of the airplane over the entire
speed range at a selected altitude.
For turning accels. and decels. (primarily for fighters), determine the thrust-limited
turning capability of the airplane at the selected altitude and also the specific
energy capability of the aircraft.
Critical Flight Conditions
There are several conditions that will influence the data collected during
an accel.-decel. The important ones are:
- Altitude - (must be maintained constant.)
- Thrust level - (must be maintained constant.)
- Atmospheric temperature
- Weight
- Center of gravity
- Configuration (flaps and landing gear position)
The need to maintain a precisely constant altitude has influenced the manner
in which accels. and decels. are performed. Position error and thrust effects
influence the altimeter readings especially during the transonic region, so the
altimeter is a poor indicator of precise altitude during an accel. Most accels.
are flown along a smoke or condensation trail that has been produced by another
airplane flying at constant speed and ahead of the test aircraft.
The limits of stall speed at the low end, and maximum speed at the high end
must be observed during the maneuver. For decels. performed in turning flight,
the "g" limits must also be observed. Abrupt pitch trim changes and heavy buffet
often occur while accelerating or decelerating in the transonic region. The pilot
must exercise both caution and skill to maintain the desired g level during the
maneuver.
Required Instrumentation
The parameters usually measured and recorded during an accel.-decel. are shown
in Table (1-1). The engine instruments shown are representative but not complete.
The engine instrumentation will be used to correct the acceleration data to standard
day pressures and temperatures, rather than to compute actual engine thrust.
Listing of Instrumentation Parameter
| Parameter |
Used For |
| Airspeed |
Computer Mach and dyn. pres. |
| Pressure Altitude |
| Outside Air Temperature |
| Normal Acceleration |
"g" and buffet levels |
| Elevator Stick Force |
pilot effort req'd to change speed |
| Elevator Position |
longitudinal stability and transonic trim change |
| Angle of Attack |
longitudinal stability |
| Engine RPM |
Thrust corrections to standard-day conditions |
| Engine tailpipe pres. & temp |
| Engine inlet pres. & temp. |
A continuous time history of these parameters is needed for the trim point,
and throughout the actual maneuver. A sampling rate of at least 10 data samples
every second is necessary to accurately record the maneuver, and each data sample
must be accurately time correlated with the data samples of the other parameters.
That is, we must be able to relate a particular measurement of elevator position
with a measurement of speed or Mach number at the same instant in time.
In recent years the use of Inertial Navigation Systems and have been applied
quite successfully to the measurement of accelerations and inertial velocities.
Starting Trim Point
The flight test engineer will establish a table of altitudes and starting
flight conditions where accels.-decels. are desired. This table usually calls
for particular trim speed in the center of the speed range of the aircraft. Level
flight accels and decels for stability purposes are usually repeated at the same
flight condition, but at different values of center of gravity position to identify
the "neutral point" of the airplane. A typical sample table of flight conditions
for accels-decels is shown in Table (1-2).
Accel - Decel. Flight Test Conditions
| Config |
Alt |
Trim Speed |
Min Speed |
Max Mach |
cg |
| Clean |
10,000 |
300 |
190 |
.95 |
Fwd and Aft |
| 20,000 |
300 |
190 |
1.2 |
| 30,000 |
300 |
190 |
1.7 |
| 35,000 |
300 |
190 |
1.8 |
| 45,000 |
300 |
190 |
1.8 |
| Gear, Flaps |
5,000 |
180 |
140 |
220 knts |
A test begins with the initial trim point. The pilot establishes the airplane
in level flight at the desired starting flight conditions of speed and altitude.
The pilot then uses the trim devices in the airplane's control system to allow
the airplane to continue in stable, level flight, but with the pilot's hands and
feet off of the controls. A short data recording is taken of this condition, usually
referred to as a "trim shot".
Description of a Level Flight Accel.-Decel
The chase airplane that is to generate the smoke/condensation trail is established
on a constant heading and constant speed. The test aircraft pilot establishes
a position behind the smoke-trail aircraft such that he will not pass the airplane
during the acceleration. After the trim shot, the pilot reduces the power to idle
and decelerates to the minimum desired speed (usually a few knots above stall),
while holding the airplane at exactly the same altitude as the smoke trail by
using only the pitch control. The pilot will then move the throttle, smoothly
but quickly, to full power and allow the airplane to accelerate while maintaining
the same altitude as the smoke, again using only the pitch control. When the maximum
speed has been reached the pilot will reduce the power to idle and decelerate
back to the starting trim speed, continuing to stay at the same altitude as the
smoke trail.
The accel. - decel. should be performed as smoothly as possible. The intent
is to maintain th eairplane in steady trimmed flight without any undue oscillations
(similar to the piloting technique used in performing pushover-pullups and windup
turns).
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| A sample accel.-decel time history. |
Measures of Success
A successful accel.-decel. will meet the following test criteria:
- All instrumented parameters recorded properly.
- Altitude (after correction for position error) did not change more than 100
feet during the maneuver.
- A smooth application of stick force which stays on one side of the friction
band throughout the maneuver.
- Smooth power transitions between idle and max.
- Data successfully crossplots with sawtooth climbs.
Several additional decels may be performed at the same altitude in turning
flight while holding the g constant at various selected values. For example, starting
at maximum speed and with maximum power, decelerating turns may be accomplished
while turning and holding 5, 6 and 7 g.
The energy exchange relationship mentioned in the introduction is defined
by the following mathematical expression:
Where Fne = Excess thrust - lbs
W = Weight of the airplane - lbs
g = Acceleration due to gravity 32.16 - ft/sec/sec
V = Velocity - ft/sec
= Calculus terminology for acceleration (rate of change of velocity) - ft/sec/sec
= Calculus terminology for rate of climb (rate ofchange of altitude) - ft/sec
During a level flight acceleration we have forced the second term in the equation
to be zero by flying at constant altitude (zero rate of climb). The excess thrust
can be computed by measuring the acceleration and weight.
The equivalent rate of climb can be computed by forcing the first term to
zero by assuming a climb at constant velocity (zero acceleration).
or, rearranging,
This calculation will produce a value for maximum rate of climb capability
(dh/dt) for the flight condition where the weight and acceleration were measured
during the accel. The value should be nearly the same as that measured during
the sawtooth climbs for the same condition. (There is a small acceleration correction
required in order to make a direct comparison between these two measurements).
Longitudinal speed stability can be identified by plotting the elevator position
vs. Mach number. The effect of power on longitudinal stability can be seen by
comparing the elevator position during the accel. (max power), with that obtained
during the decel (idle power).
Author: Robert G. Hoey
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Acceleration-
Deceleration
