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NASA Contractor Report 3073
Investigation of Aircraft Landing in Variable Wind Fields
Walter Frost and Kapuluru Ravikumar Reddy
CONTRACT DECEMBER
NASS-29584 1978
NASA Contractor Report 3073
TECH LIBRARY KAFB, NM
Investigation of Aircraft Landing in Variable Wind Fields
Walter Frost and Kapuluru Ravikumar Reddy The University of Tennessee Space Irzstitute Tdahoma, Temessee
Prepared for George C. Marshall Space Flight under Contract NASS-29584
Center
MSA
National Aeronautics and Space Administration
Scientific and Technical Information Office
1978
AUTHORS ACKNOWLEDGMENTS
The work reported herein was supported by the National Aero-
nautics and Space Administration,
Marshall Space Flight Center,
Space Sciences Laboratory, Atmospheric Sciences Division , under
contract number NAS8-29584.
The authors are indebted to Mr. John H. Enders of the
Aviation Safety Technology Branch, Office of Aeronautics and Space
Technology (OAST), NASA Headquarters, Washington, D. C., for his
support of this research. Special thanks also go to Dr. G. H. Fichtl
and Mr. Dennis Camp of the Marshall Space Flight Center who were
the scientific
monitors of the program.
ii
TABLE OF CONTENTS
CHAPTER
I. INTRODUCTION. . . . . . . . . . . . . . . . . . . . . . . . . . 1
II. AIRCRAFT LANDING MODEL. ....................
6
1. Equations of Motion ....................
6
2. Incorporation of Wind Shear ................
11
III. MATHEMATICAL MODELS FOR VARIABLE WIND FIELDS. .........
15
1. Atmospheric Flow Over a Homogeneous Terrain ........
15
2. Atmospheric Flow Over Buildings ..............
15
3. Atmospheric Flow Associated with Thunderstorm Gust Fronts . 25
IV. AUTOMATIC CONTROLSYSTEM. ...................
29
1. Mode Selector .......................
33
2. Altitude Hold Mode. ....................
36
Capture Mode. .......................
38
1: Glide-Slope Tracking Mode .................
40
5. Flare Mode. .........................
42
6. Calculation of the Feed-Back Controls ...........
46
V. RESULTS AND DISCUSSION. . . . . . . . . . . . . , . . . . . . . 51
VI. CONCLUSIONS . . . . . . . . . . . . . . . . . . . . . . . . . . 76
BIBLIOGRAPHY. ............................
77
APPENDIX. ..............................
80
. . .
111
LIST OF FIGURES
FIGURE
PAGE
1. Relationship between the various forces acting on an
aircraft [121. .......................
7
2. Logarithmic wind profile ..................
16
3. Definition of flow zones near a sharp-edged block [22] ...
18
4. Description of flow region considered for a block
building [22]. .......................
19
5. Description of flow region considered for a long, wide
building [23]. .......................
20
6. Vorticity contour [22] ...................
21
7. Streamline patterns [22] ..................
22
8. Velocity profiles over an obstruction on the surface [22]. . 23
9. Velocity profiles over a step geometry long, wide
building [23]. .......................
24
10. Overall block diagram of control system. ..........
31
11. Automatic landing geometry using ILS ............
34
12. Mode control logic .....................
35
13. Altitude hold mode .....................
37
14. Glide slope capture mode ..................
39
15. Glide slope tracking mode. .................
41
16. Flaremode .........................
44
17. Feedback loop-thrust ....................
47
18. Feedback loop-elevator angle ................
49
19. Fixed control landing over a block building. ........
52
20. Fixed control landing over a step. .............
53
iv
FIGURE
21. Fixed control landing in the atmospheric boundary
layer,.
..........................
22. Fixed control landing in thunderstorm gust front ......
23. Wind.distribution
over a block building along the flight
path ............................
24. Wind distribution
over 6 long; wide building along the
flight path. ........................
25. Wind distribution
in the thunderstorm gust front along
the flight path. ......................
26. Automatic landing in atmospheric boundary layer, ......
27. Automatic landing over block building. ...........
28. Automatic landing over a long, wide building ........
29. Automatic landing in the flow associated with thunderstorm gust front. ...................
30. Controls required for landing over a block building. ....
31. Controls required for landing over a step. .........
32. Controls required for automatic landing in thunderstorm
gustfront
.........................
33. DHC-6 landing through atmospheric flow over a block building ..........................
34. Automatic landing reference trajectory ...........
PAGE
55 56
57 58
59 60 61 62
63 65 66
67
68 70
NOMENCLATURE
cD
Drag coefficent, D/(l/2)pV2S
cL
Lift coefficent, L/(l/2)pV2S
C m
Pitching-moment coefficent, M/(l/2)pV2SE
E
Wing mean aerodynamic chord, m
cl, c2 l . . cy Constants
D
Magnitude of aerodynamic drag, N
FT
G(s)
Magnitude of thrust, N Filter transfer function
9
Magnitude of acceleration due to gravity, 9.8 m/sec2
h
Altitude of aircraft measured from ground, m
hr
Reference altitude, m
hf
Initiation
altitude
the flare, m
of the feedback control law in
Altitude at which the predictive begins, m
pitch ramp command
h step
Altitude at which the predictive begins, m
pitch step command
ILS
Instrument Landing System, standard radio guidance
installed at major airports
I
Aircraft moment of inertia around y-axis, kg-m2
YY
K
Filter gain constants
L
Magnitude of aerodynamic lift force, N
L'
Vertical extent of major vertical updraft relative to
the flight path
i
Monin-Obukhov stability length
m
Airplane weight, N
vi
u*
V
'a
wX
wz
X Z 2 a Y YILS 6e
9 P -I
Tl
TO
-+ ('>
Pitch angular velocity, radians/set
Wing reference area, m2
Laplace transform operator
Sampling Friction
time interval, velocity given
set by u,
r-iTO =-It T
Magnitude of aircraft m/set
velocity with respect to ground,
Magnitude of airspeed, m/set
Magnitude of x-component of wind speed in earth axis, m/set
Magnitude of z-component of wind speed in earth axis, m/set
Horizontal coordinate, m
Vertical coordinate, m
Z-transform operator
Angle of attack, radians
Flight path angle, radians
ILS glide path angle, radians
Elevator deflection, radians
Glide slope error angle, radians
Pitch angle, radians
Air density, g/m3
Filter constant
Filter constant
Surface shear stress
Designates vector
Time derivative
vii
CHAPTER I
INTRODUCTION
Wind is an important consideration in the analysis of airplane
flight in the atmospheric boundary layer, both because of short-scale
gusts or turbulence and because of large-scale variations of the mean
wind. In the planetary boundary layer the mean wind decays toward the
ground and has considerable horizontal variations due to irregulari-
ties in terrain.
Thus, both spatial and temporal variations occur in
near surface winds encountered along ascending and descending flight
paths,
Previous analyses of airplane motion that have been carried out
[1, 2, 31 consider, in general, only constant winds and thus neglect
the effects of wind shear. This report, however, investigates the
influence of variable mean wind fields and discrete gusts on the
dynamics of aircraft during terminal flight operations,
Mathematical
models of the winds are introduced into the equations of aircraft
motion, both with fixed and automatic controls; computer solutions of
the resulting motion are carried out.
As an aircraft descends on its glide slope, a sudden change in
horizontal wind or vertical wind, or both, will instantaneously affect
the velocity of the aircraft relative to the air mass. If the shear
is such that the relative velocity of the aircraft increases, the lift
force will increase and the aircraft will tend to rise above the glide
slope. If the shear causes a sudden decrease in the relative
velocity, the aircraft will respond by falling below the glide slope,
and a hazardous condition may result.
Several reports have been published which link short and long
touchdowns to a sudden wind shear occurrence during final approach
C4, 5, 6, 71, Recent accident reports also have found wind shear to
be at least a contributing cause for several accidents [8, 91. In
addition, it is believed that wind has been responsible for many other
accidents, though it remained undetected at the time [lo, 111. The
problem of quantitatively
defining the effect of shear of given magni-
tude on an aircraft during descent has not been completely resolved.
Noteworthy studies that have-investigated
wind shear and/or turbulence
during landing include References 3, 6, 7, and 10 through 14.
Although a very complete development of the system of equations
governing airplane motion is available [1, 21, most analyses reported
to date reduce the equations to those for a constant wind or employ a
linearized model which requires the assumption of a uniform wind field
and is not applicable for non-uniform winds.
Ramifications of the airplane motion due to the effects of
temporally and spatially varying mean winds are studied in this
report, Analyses of flight paths through changing mean wind fields
reported in the literature are primarily two-dimensional and deal only
with vertically varying horizontal winds (i.e., having a component
parallel to the flat earth only).
Etkin [1] has a very complete development of the general
equations of unsteady motion. Normally, the wind components of
velocity are not included in the equations since it is assumed that
2
no wind is present. Luers and Reeves [7] developed a system of
equations in two dimensions which incorporate only horizontal wind.
Later in this report, a general form for the two-dimensional equations
of motion is developed. This accounts for both vertical and horizontal
mean wind components with both time and spatial variations.
Using this later set of equations, analyses both with fixed and
automatic feedback control were carried out. In the fixed control
simulation, the aircraft is trimned at an altitude of 91 m and on a
glide slope of -2.7 degrees. The corresponding throttle setting and
elevator angle setting are then fixed for the remainder of the
landing. These fixed control landing simulations were carried out for
several different wind fields and the deviations in the glide slope
and touchdown points are compared. In the cases with high wind shear,
the deviations are very large and in some cases the aircraft
trajectories
with fixed controls are not realistic.
To overcome this difficulty
an automatic control system was
developed for the same two-dimensional system of equations. Every
phase of the flight of an aircraft can be regarded as the accomplish-
ment of a set task, i.e., flight on a specified trajectory.
That
trajectory may simply be a straight horizontal line traversed at
constant speed or it may be a turn, a transition from one symmetric
flight path to another. All of these situations are characterized by
two corrPnon features, namely, the presence of a desired state and the
departures from it, designated as errors. These errors are, of
course, a consequence of the unsteady nature of the environment.
3
The correction of errors requires a method of measuring the error
or the desired state. Some of the state information needed (i.e., air-
speed, altitude, rate-of-climb,
heading, etc.) is measured by standard
flight instrumentation.
This information is not generally sufficient,
however, when both guidance and altitude stabilization
are considered.
For this case, the state information needed may include [1, 161
position and velocity vectors relative to a suitable reference frame,
vehicle altitude, aerodynamic angles, etc. A wide variety of devices
are used to measure these and other variables, and range from pitot-
static tubes to sophisticated inertial-guidance
platforms.
Gyro-
scopes, accelerometers, magnetic and gyrocompasses, angle-of-attack
and sideslip vanes, and other devices, all find applications as
sensors. The most common form of output is an electrical signal, but
fluidic devices [17] are receiving increased attention.
In this study we assume that the desired variable can be measured
independently and linearly, which is of course, an idealization.
Since every sensing device, together with its associated transducer
and amplifier, is itself a dynamic system with characteristic
frequency response, noise, nonlinearity and cross-coupling,
these
attributes cannot be ignored in the final design of real systems,
although one can usefully do so in preliminary work [l].
In the automatic control simulation, the aircraft is tritnned
initially
at an altitude of 91 m on a straight horizontal line
trajectory and is automatically controlled by actuation of thrust and
elevator angle. In this first phase the aircraft remains in an
altitude hold mode until it intersects the Instrument Landing System
4
(ILS) guidance beam, It then switches to the glide-slope capture mode
which actuates the thrust and elevator controls so as to capture the
-2.7 degree glide path specified by the ILS guidance beam. As soon as
the specified glide path is captured, the third phase, glide-slope
tracking mode, becomes effective.
In this mode the controls are
actuated such that the aircraft remains on the glide path. At an
altitude of approximately 18 m, flare initiation
altitude along with
other necessary parameters are calculated to begin the flare mode.
The flare mode is switched on as soon as the aircraft reaches the
flare initiation
altitude.
The aircraft remains in this mode until
the final touchdown.
For this investigation,
the scope of the automatic landing
problem was restricted in two ways. First, the aircraft simulation
equations are restricted to three degrees of freedom by considering
the longitudinal axis only. This restriction
is reasonable in the
light of the accident statistics
compiled in References [8, 91,
which conclude that accidents due to longitudinal more often than accidents due to lateral errors.
errors are fatal Second, the system
guidance information was assumed to come from error-free sensors and
an error-free ILS beam. This is beneficial to maintain simplicity of
the automatic control subroutines, since the objective of this study
is the effects of wind shear, and not a study of ILS system errors.
5
CHAPTER II
AIRCRAFT LAND1NG MODEL
1. Eauations of Motion
The two-dimensional model for aircraft motion presented in this
section follows the general form developed by Frost [12]. It accounts
for both vertical and horizontal mean wind components having both time
and spatial variations.
The aircraft trajectory model employed in this study was derived
based on the following assumptions:
a) The earth is flat and non-rotating.
b) The acceleration of gravity, g, is constant (9.8 m/sec2).
c) Air density is constant (1.23 kg/m3).
d) The airframe is a rigid body.
e) The aircraft is constrained to motion in the vertical plane.
f) The aircraft has a symmetry plane (the x-z plane).
g) The mass of the aircraft is constant.
h) Initial flight conditions are for steady-state flight.
Figure 1 illustrates
the forces acting on the aircraft.
These
include:
iT thrust of the engines L lift
d drag
fi wind velocity
4 gravitational
force.
6
FRL /
-+
-.
+ D &
_______! Z
'?L X
Figure 1 Relationship between the various forces acting on an
aircraft
[lZ]
7
The figure shows the orientation of the forces with respect to
the ve1ocit.v relative to the earth (c), the velocity relative to the
air mass (Ta), and the fuselage reference line (FRL) of the aircraft.
The x-axis in Figure 1 is parallel to the surface of the earth and the
z-axis is perpendicular to the surface of the earth (positive down-
ward).
From a direct force balance along the direction c and along the
direction perpendicular to 3, respectively,
it follows from Figure 1
that
mi = - L sin 6 - D cos 6 - mg sin y + FT cos (6T + a)
0)
and
mV+ = L cos y - D sin 6 - mg cos 6 + FT sin (6T + a) .
(2)
The aerodynamic forces and the thrust from the engines exert a
pitching moment on the aircraft.
The equation describing the momentum
balance about y is
2 ;I=d=-
FTLT - M
(3)
dt2 'yy + IYY '
where the dot refers to the derivative with respect to time, and !3 is the magnitude of the acceleration of gravity, V is the magnitude of the velocity relative to the earth, Y is the angle between 3 and the x-axis (the flight path angle), FT is the magnitude of the thrust vector, m is the aircraft mass,
8
6T is the angle between the thrust vector and the fuselage reference line (FRL),
a is the angle between 3 and the FRL, 6 is the angle between ia and ?, 4 is the time derivative of the pitching rate, q, LT is the effective moment arm of the thrust vector, M is the pitching moment, and I yy is the moment of inertia about the symmetry plane of the
aircraft.
By considering a different coordinate system in which the x-axis is along the vector qa, called "wind" frame of reference by Etkin [l], similar force equations can be developed by summing up the forces parallel and perpendicular to Ta. These are
m(\ja + fix ) + mq, Wz = F.,- - D - mg sin y'
(4)
W
W
X W
and
mljz - ww(Va + W, ) = FT -L+mgcosy'
.
(5)
W
W
z W
It is convenient to express these in terms of the wind components relative to an earth fixed coordinate system, since most wind correlations from the meteorological literature are expressed in such coordinates.
wX W = Wx cos y' - W, sin y' ,
(6)
wz= Wx sin y' + W, cos y' .
(7)
W
Taking the time derivative
of Wx , we get
W
= Ij,
9X W
cos y'
- AZ sin
y'
- Wx sin
y'
ddty'
- wz cos y'
$$
.
(8)
Then, since q, = -ddyt-' ,
iX W = W, cos y'
- iz
sin
y'
- W, q,
W
.
(9)
Also, since
= FT cos(bT + a') , and
FTX W
= FT sin(bT + a') ,
FTz W
Equation (4) becomes
m\j, = FT cos(AT + CL') - D - mg sin y' - m(i, cos y' - iz sin y') . (10)
From Equation (7), taking the time derivative
of Wz , we get
W
% = ix sin y' + W, cos y' + w, cos y' g- - Wz sin y' *d' ,
(11)
W
and Equation (5) becomes
- mV, q, = - FT sin(6T + a') - L + mg COS y'
- m(dx sin y' + Wz cos y') .
(12)
The moment equation remains the same as Equation (3). The governing force equations in "wind" frame of reference are thus
10
mSa = FT COS(~~ t cl') -r D - mg sin y'.
- m(rjx cos y' - tiz sin y') ,
(13)
mV,+' = FT sin(6T + a') t L - mg cos y'
t m(cix sin y' + Pz cos y'i ,
(14)
qw=r FTLT + -3M
(15)
YY
IYY
where Wx is the horizontal wind speed, W, is the vertical wind speed, and ~1' (the angle of attack) is the angle between ca and the FRL.
2. Incorporation of Wind Shear The wind is seen to enter the equations in the form of a gradient
or wind shear ix and fiz. The expanded form of these equations is:
lj,=+-- aw or
awx dX -a-wx dZ
ax d-t az dt
fix = -a-gw-X+ v [ cos y -aawx)(- si.n Y -a1awz,X
(16)
and, similarly,
aw
aw
aw
iz = +tV[cosy$-siny-$].
(17)
Thus, both spatial variations and tempo;-al variations motion influence the equations in the wind coordinate
in atmospheric system.
11
Generally, care is needed in evaluating aazwX and aazwZ since the
wind speed is normally expressed in terms of altitude measured upward
from the surface of the earth, whereas in aerodynamic coordinates, Z
is measured downward. Additional kinematic
relationships
necessary to solve for the
aircraft motion are as follows: The relative velocity as a function
of inert ial and wind velocity
is
= [ (i - wx)2 + (i - wzj2 1l/2
'a
,
08)
and, in turn, V= wx cos y - Wz sin y + [(Wz sin y - Wx cos y12
l/2
t vz - (w2 + Wf, 1 X
*
(19)
The angle between ? and ca is given by
Wx sin y + Wz cos y
sin fS=
.
(20)
va
Other angular relationships
are
a = e-y-6=0-y,
(21)
a =e-y.
(22)
The derivative of a' is
a*I =f? -i/L
q - ; )
12
where y' is given by Equation (14), hence,
a*I =q-
FT sin(6T + a')
L
--
mVa
mVa
+ 9 cos y' tf
[Ox sin y' + iz cos y'] .
(23)
va
a
Also required for solution aerodynamic coefficients
of the preceding equations are the
cL = cL b', &E, va' q, 4') ,
$, = CD b, $ va q, i, cL) 9
cm = cm b, 6E va 93 i> ,
(24)
where 6E is the elevator deflection angle. As indicated above, the
aerodynamic expressions
coefficients
are functions of a number of variables.
The
for CL, CD, and Cm, along with the stability
derivative
data and aircraft physical data are given in the Appendix.
The equations of motion discussed in this chapter can be solved
for the flight of an aircraft flying through spatially and temporally
varying two-dimensional wind fields.
In this study we have used three
different wind shear models,
1) atmospheric flow over homogeneous terrain,
2) atmospheric flow over buildings, and
3) atmospheric flow associated with thunderstorm gust fronts.
The initial conditions used in this simulation are for that of a
pitch stabilized aircraft,
given by
13
Altitude = 91 m
'a
= 70 m/set
'a
= 0
Y.I
=
0
;r
=
0
4
= 0
a*I
= 0.
Under these conditions the initial values of thrust, elevator angle and angle of attack were calculated from Equations (13), (14) and (15).
14
CHAPTER III
MATHEMATICAL MODELS FOR VARIABLE WIND FIELDS
1, Atmospheric Flow Over a Homogeneous Terrain
The mean velocity in the region of the atmosphere near the ground
is described by a logarithmic function of altitude.
The surface
roughness characteristic
of most natural terrains is generally
described in terms of a vertical scale, Zo. For a neutral atmosphere,
experimental evidence [18, 191 confirms that the mean wind velocity in
the region near the ground can be described by a logarithmic wind pro-
file (Figure 2). The logarithmic wind profile is thus [20], given as
a function of altitude Z,
z t z.
Wx(z) = : In ( z ) ,
(25)
0
where Z. represents the surface roughness, and K is von Karman's
T
constant.
u, is the friction
velocity given by u, =I/- $ , where ~~
is the surface shear stress, and p is the air density. Observed
wind profiles up to 150 m, over reasonably level and uniformly rough
terrain, with neutrally stable conditions, obey this law reasonably
well [20].
2-.- Atmospheric Flow Over Buildings Since the wind shear models for the flow over a block building
and a step are completely described by Sheih, et al. [22] and Bitte
15
Z
Figure 2 Logarithmic wind profile 16
and Frost [23], respectively,
only a cursory description of the models
is presented here.
The distorted shear flows approaching and passing over a building
can be divided into a displacement zone, an upstream bubble or down-
wash zone, and a wake zone which includes the rear separation bubble
or cavity zone (see Figure 3). The effect of shear in the approaching
flow creates a downwash on the front face and a swirling flow in the
wake or cavity zone. Undisturbed, neutrally stable atmospheric wind
perpendicular to the axis of the building is assumed far upstream and
far downstream of the obstacle (see Figures 4 and 5). The atmospheric
wind field is analyzed by using the Navier-Stokes equations with a
two-equation model, one for the turbulence kinetic energy and the
other for turbulence length scale. In this approach, the partial
differential
equations for the vorticity,
stream function, turbulence
kinetic energy, and turbulence length scale are solved by a finite-
difference technique.
Both vorticity contours (Figure 6) and streamline patterns
(Figure 7) confirm the experimental evidence of a small downwash zone
near the front lower corner and a large recirculation
zone behind the
obstruction.
Figures 8 and 9 show the computed velocity profiles at
selected X-stations in the region close to the wall. The flow is
decelerated as it approaches the obstruction and is accelerated as it
passes over the obstruction.
In the region above the recirculation
zone, the flow is accelerated because of the displacement of the flow.
The flow re-attaches near X = 12.3H and the logarithmic boundary
17
Upstream separation bubble or down wash zone
Rear separation bubble or cavity zone
Approaching
'
velocity
profile I
Redeveloping, boundary layer I
Reattachment flow zone Figure 3 Definition of flow zones near a sharp-edged block [22]
18
Z = 6.0 H
l I
El 2 Neutrallv stable inflow
Upper Boundary
z 0.75 H
r
Block geometry obstacle
X = -10.0 H
Wall Boundary
I I
X = 20.75 H
Figure 4 Description of flow region considered for a block building [22]
Z = 9.0 H
Upper Boundary
c Velocity Profile
X = -10 H
X=lOH
Figure 5 Description of flow region considered for a long, wide building [23]
Vorticity
-9.97 -7.97 -5.97 -3.97 -1.97
0.03 2.03 Horizontal
4.03 6.03 8.03 10.03 12.03 14.03 16.03 18.03 20.03 Distance X/H
Figure 6 Vorticity contour [22]
-1.97
0.03
2.03
4.03
6.03
8.03
10.03
12.03
14.03
16.03
18.03
20.03
Horizontal Distance X/H
Figure 7 Streamline patterns [22]
Z/H t
6.0
0 5 10 m/set
N w
-10.0
-1.25
0 0.75 2.75
5.75
9.75
17.0
20.0
X/H (H = 3.2 m)
Figure 8 Velocity profiles over an obstruction on the surface [22]
Scale 0 10 , . *
20 Cm/set) for u* = 0.75 m/set I
Horizontal
Distance X/H
Figure 9 Velocity profiles over a step geometry long wide building [23]
layer begins to re-establish downstream. These results seem to agree
very well with the limited experimental data available.
The velocity distributions
of the atmospheric flow around
buildings are especially important in the design and operational pro-
cedures for helicopters and V/STOL aircraft operating in large
metropolitan areas.
& Atmospheric Flow Associated with Thunderstorm G-u~s-t Fronts Gusty winds are undoubtedly the most hazardous for an aircraft to
negotiate.
One of the most common causes of significant
wind shear is
the gust front associated with thunderstorms.
The thunderstorm gust
front is believed responsible for several accidents [S, 221. The
severe wind shear accompanying thunderstorms is generated by a
vigorous rain-cooled downdraft, which spreads out horizontally
from
the storm cell as it approaches the ground. The cold outflow is led
by a strong, gusty wind which often occurs as much as 16 km ahead of
the storm, called the gust front.
Mathematical schemes for computing wind fields associated with
thunderstorm gust fronts are still in the formative stages. After
extensive study of gust front characteristics
and the available gust
front data, Fichtl and Camp [26] have presented a mathematical model
which describes updrafts and downdrafts associated with gust fronts
along a given approach path. This model incorporates both scaled vertical wind speeds along a -2.7 degree glide slope from the gust
front data of Goff [27], and the vertical wind speeds reconstructed
from the digital flight data record of Eastern 66 [8]. The sequence
25
of vertical wind speeds encountered by an aircraft given by the following:
during landing is
Major downdraft:
X -X
wz = - P1 A sin (r
9
q1
; z. 1 z > zr
Major updraft:
(1- 2q,)U-$J3+(1- 3qpx - XJ2 + (2q, - 3q@ - $1
wz =A - s;bl, - u2
; Zr)Z,Zr
- L
Minor downdraft:
wz = - P2 A sin (K 'r -1-x 42
> ; (Z,-L)
> z -> (zr-(1+q2)L')
Minor updraft:
wz = P2 A sin(n where
'r -1-x 92
1 ; c zr - (1 + 42) Ll z 2 I: zr - (1 + 2q2) L'l
x, = p'r- ; x=3.
The various quantities in the above equations are defined as follows: W, = thunderstorm cold air downdraft, Z = vertical coordinate, ZD = altitude of the top of the major downdraft,
26
'r = altitude zB = altitude A = amplitude
of the top of the major updraft, of the bottom of the minor downdraft,
of major vertical velocity updraft,
L' = vertical extent of major vertical velocity updraft relative
to<he flight path,
p1 = ratio P2 = ratio
of major downdraft of minor downdraft
to major updraft or minor updraft
velocities, to major updraft
velocity,
q, = (Zr - Z,VL,.
q1 = (Zr - Z&L', q2 = (Zr - ZB - L')/L'.
The values for the cold air outflow lation study are that of typical vertical provided by NOAA/NSSL [27]:
parameters used in this simuwind speeds derived for data
L' = 91 m ZR = 152 m A = 15.0
P1 = 1.2
P2 = 0.35
90 = -0.36
q1 = 2.0 92 = 2.3.
In this wind shear model, the vertical winds due to the thunderstorm gust front described above are superimposed on a stable
27
atmospheric boundary layer. ditions is given by
The mean wind velocity
under stable con-
Wx(z) = 2
1 z + z.
ln(
z ) + 5.2 ; ,
0
where i is the Monin-Obukhov stability length.
28
CHAPTER IV
AUTOMATIC CONTROLSYSTEM
The two principal quantities that need to be controlled in
symmetric flight are speed and flight path angle, i.e., the vehicle
velocity.
To achieve this, control forces are needed both parallel
and perpendicular to the flight path. Parallel force is provided by
thrust or drag control, and perpendicular force by lift control
achieved via elevator deflection.
It is evident from simple physical
reasoning (or from the equations of motion) that the main initial
response to opening the throttle (increasing the thrust) is a forward
acceleration,
i.e., speed control,
The main initial response to
elevator deflection is a rotation in pitch, with subsequent changes
in angle of attack and lift, and hence, development of ;, a rate of
change of flight path angle. When the transients that follow such
control actions have died away, a new steady state is achieved.
In this section the longitudinal automatic landing system will be
described, and some of the design considerations will be given.
It has been shown in Reference [24] that turbulence causes larger
deviations from the desired flight path than the errors in ILS
guidance. This study, therefore, concentrates on the effect of wind
shear on safe automatic landings. assumed to come from an error-free
The system guidance information is
ILS beam and altimeter.
Reference
[S] has an excellent discussion on longitudinal automatic landing and
aircraft control laws. The overall control system can be represented
29
I-
in the form of a block diagram as shown in Figure 10. The flight
control laws are segmented into control modes for different portions
of the approach and landing,
In the various control modes the linear filters are described by
transfer functions.
The filtering
function, however, is actually per-
formed in the digital computer by solving difference equations.
Simulating a linear system with the appropriate difference
equation is more efficient than solving the differential
equations
directly by numerical integration.
Numerical integration would be
rather a lengthy process and may be unstable for large sampling
intervals [3]. The difference equation for one of the linear filters
used in this simulation can be derived as follows:
---Y- (s) - KS Gk4 - x(s) s+a '
The response of the filter to a unit step input is
y(S) = &$=
Ks+a or y(t) = K eBat 6(t) .
Taking the z-transform,
Y(Z) = zD:aT
'
Factoring the z-transform of a unit step function from y(z),
y(z) = K '-'
--? .
z-e-aT Z-l
30
Initial conditions
t
Aircraft
5
dynamics
Position
W L
Mode Selector
1
Figure 10 Overall block diagram of control system
Since the response to a general input is wanted, replace the step input by a general input x(z). The actual input is approximated by a linear combination of unit step functions and is equal to the general input at the sampling points,
y(z) = K '-'
x(z) .
z - ewaT
Cross-multiplying, (z - e -aT) y(z) = K(z - 1) x(z) , Dividing throughout by z,
-)Y(z)
= K (1 - t, x(z) .
Transforming to the discrete time domain,
-aT Y, - e yn-l
= K$,
- xnml) 9
and rearranging, the final form of the difference equation is obtained,
yn = eBaT ynel + K(x, - x,,-~) .
At the sampling points the difference equation is the exact solution for the response of the equivalent analog system. The difference equations for the various filters were compared to those obtained using numerical integration (fourth-order Adams-Bashford); it was concluded that the computation efficiency of the difference
32
equations is better nique [3].
than that of the numerical
integration
tech-
1. Mode Selector
The mode selector automatically selects the proper control mode
in sequence (i.e., the altitude hold, glide slope capture, glide-slope
tracking, and flare mode) according by the desired flight path.
to predetermined
criteria
defined
In accordance with conventional practice [25], the control modes
operate on the velocity and pitch stabilized aircraft and therefore
operate with only two command variables:
speed command, Vc, and
pitch angle command, 8,.
The mode selector is best described by considering a landing
approach (see Figure 11) and the flow chart (Figure 12). The aircraft
approaches the ILS glide slope at a constant altitude of 91 m until
the aircraft intercepts the ILS beam. During this time the mode
selector maintains Mode 1, i.e., the altitude hold mode. As soon as
the aircraft penetrates the ILS beam, the mode selector compares the
aircraft position to the point of intersection of the horizontal
flight path and the ILS glide slope; when the aircraft reaches that
point it switches to Mode 2, the capture mode. The capture mode is
timed and the flight path angle is compared with the desired glide slope; as soon as the desired glide slope is reached the mode selector
switches to Mode 3, the glide-slope tracking mode. Glide-slope
tracking proceeds to a preselected altitude, at which point the sink rate and velocity of the aircraft are used to calculate the flare
33
Altitude
Glide-slope capture
hold 1
I Flare I I I
Figure 11 Automatic landing geometry using ILS 34
Altitude hold
Calculate
initiation
\/
altitudes
F
F
1
T
Glide-slope
5 tracking
Glide-slope capture
Y To next subroutine
Figure 12 Mode control logic
35
Flare
initiation
altitude (hstep ) and other initiation
parameters described
in the flare-mode selection.
The mode selector then switches to
Mode 4, the flare mode, when hStep is reached.
Notice that no automatic go-around mode is provided; the simu-
lated aircraft is forced to land so that the conditions can be found
that result in unsatisfactory
landings.
2. Altitude Hold Mode
A simple hold mode incorporated in the system keeps the aircraft
flying at a constant altitude.
The digital control was modeled after
the representative analog system shown in Figure 13. The system con-
sists of a differencing circuit for calculating the altitude error,
Ah, followed by a low pass filter, a gain, and a low gain integrator.
For comparison, digital equivalent equations are as follows:
8
3
= c1 OCjBl
+ c2 ecje2
t
c3 Ahj
+ cy AhJ.-1
Ahj = h.J - href ,
8. J
= cl
j-1
+ ~2 Ahj-1 3
8, = ec t k2 ej t c3 ejml .
j
j-l
These equations are solved once each computation cycle. The constants, cl, c2 and c3, are given by
36
h 4 +
IAh
t K1
s+a 1 -
Typical values K1 = 0.1 al = 1.0 K2 = 0.05 a2 = 0.1
K2
*
1+ ya-2
Figure 13 Altitude hold mode
37
c1
=e
alT ,
c2 =qk”l -cl) ,
c3 = k2 (a2 T - 1) , where T is the sampling interval.
3. Capture Mode
The capture mode (Figure 14) provides for a smooth rotation from
level flight to the glide-slope angle. In this mode a step pitch
angle command, A0 is applied to rotate the airplane. P'
The magnitude
of the step is based upon the glide slope angle of the beam to be
captured. In addition, an inertial vertical velocity error signal is
generated to increase the sink rate for a given glide-slope angle.
The error signal, 8e, is then integrated and filtered to produce the
pitch angle command. The integrator provides an error signal pro-
portional to the altitude error. Since the sink rate reference value
is the proper sink rate of the aircraft on the glide slope, the
resulting altitude reference is a parabolic curve that smoothly
intersects the glide slope.
The difference equations are as follows:
8EJ. =hc-h., 3
% j = 1 Cj_1 - 2 Cj-2 + 3 Ej-1 + 4 ~j-2 + aBp
38
@E *
K3 s
5
K4
-rls + 1
Typical values
K3 = 0.05 K4 = 0.01
T1 = 0.01
of capture
Figure 14 Glide slope capture mode
Rate limiter
39
where = 1 + ,-T/-c ,
c1
c3 = k3 k4 C T + y k2 - 1) 1 , c4 = k3 k4[T - c2 (T + T)] .
4. Glide-Slope Tracking Mode
After glide-slope capture the aircraft remains in the glide-slope
tracking mode (Figure 15) until flare. The glide-slope error angle,
E, is passed through a low-pass filter, a gain, and then a low-gain
integrator.
In addition, two differencing circuits are used which
estimate the approximate altitude error for the next step and give
pitch error signal, 8. This extension is a pitch altitude command,
eCy proportional
to h-h, and also 6 - Gc, where hr is the reference
altitude and Lc is the proper sink rate for the given glide slope.
The digital equivalent equations are as follows:
= Yj - yref '
3
8. = k4 (hj - hr) + kg (~j - ~c) )
J
ePj = '1 epj-l + '2 j-1
8E.
J
=
8
'j-1
k6 epj 3 epj-l
8 2
= ej + E.J
40
r
e
E
L
53
-c2 s+a 2
P * K6
Typical values
K3 = 1.0 K4 = 0.05 K5 = 0.00325 K6 = 0.00125
T2 = 0.01 a2 = 1.0 a3 = 0.01
c 1+y a3
%
Figure 15 Glide slope tracking mode 41
where
-- a2T
cl=e
T2 ,
c2 = qk3 (1 - Cl) 3
c3 = k6 (a3T - 1) .
5. Flare Mode The flare mode controls the traditional
The flare has three boundary conditions,
exponential flare [25].
hf initiation
altitude of feedback control law,
Lf initial
sink rate,
desired vertical touchdown velocity.
A flare law that satisfies these boundary conditions is developed
by Neuman and Foster [3]. A modified version of this flare law is
used in our simulation.
The equation that satisfies the boundary
condition is:
-t/a4
hr(t) =[hf - a4 if ]e
+ a4 i)f, ,
(26)
0
and a4 is calculated as
a4 = hf/(if
- r;, ) .
0
(27)
42
The reference sink rate is the derivative of Equation (26),
hr = - (l/a41
-t/a4 (hf - a4 lif > e
.
(28)
0
The predictive portion of the flare law (Figure 16) has two sections,
a step command in pitch, A8 which causes the aircraft P'
to begin to
rotate, an-d a ramp pitch command, AeR, which begins somewhat later.
With no other disturbance, the predictive flare commands will
generate an approximately exponential flare. Feed-back is used to
overcome disturbance.
Equation (26) is the solution of the following
differential
equation:
hr.+ a4 (t!~ - if ) = 0 ,
r 0
(2%
with the boundary conditions hr = hf at t = 0, and ir = if at h = 0.
The feed-back version of the flare law generates a correctgve signal
when Equation (29) is not fulfilled
by the actual altitude, h, and
sink rate, 6, in place of hr and ir. The corrective signal is (see
Figure 16):
'fb = Kf[l+
$][h+a4
(i - if) 1 3
(30)
which is added to the predictive pitch comnand. Hence, no correction signal is applied when the reference path is followed.
When the flare subroutine is entered for the first time, the sink rate is used to calculate decision altitudes for the predictive flare law connnands. The altitudes at which these initial calculations are made are somewhat above the highest value at which the flare may be
43
-
h
+ t T Kf
"fb -
2 1. of Ae,blO 2. If ABfb<O
h step h
ramp
hf 8
. = 1050 +
= 0.6 = 0.8 = 0.9
h step
h .steP Q
= CO.255 4 - 0.000132)T
= 0.00024 Kf
K
= 2.0
a4
= 5.0
a5
= 0.00333
a6
= 4.0
a5
1 -s
a5
2
Closed
'fb
h=hf
\
I
KS S + a6
Figure 16 Flare mode 44
started. The step command altitude is proportional to the flight-path
angle, y z i/v. The ramp begins at a proportionally
lower altitude.
Since the aircraft does not begin to deviate from a straight-line
glide path instantaneously , upon receiving the pitch step command, the
altitude for the corrective feed-back to begin is also selected pro-
portionally lower than the step command altitude.
After these
calculations are completed, the flare mode transfers the authority
back to the glide-slope tracking control.
When the step command altitude,
hstep' is reached, the flare
control mode takes over completely and from the sink rate, fi, dalcu-
lates and executes A0 Then the ramp increment, AOR, and the feedP'
back gain constant, a4, are calculated.
At this point the mode
controller is switched to its final submode.
In the final submode the predictive ramp pitch command is added
to the corrective feed-back flare command. The summed signals are
transmitted as the pitch change command, Bc.
Under disturbances, the feed-back term in the flare law does not
attempt to guide along a path fixed in space, or even hold h(t) and
e(t) at given values: As long as the feed-back signal of Equation
(30) is zero no correction is made. Disturbances, therefore, tend to
cause translations of the touchdown point rather than large maneuvers
to meet a given touchdown point, which would often cause hard
landings,
45
6. Calculation of the Feed-Back Controls
To control the flight path of an airplane automatically,
it would
be desirable to control the flight-path
angle, y, directly.
However,
there is no output control variable that controls y. In linearized
models [1], the steady velocity, d, at which the airplane flies is
governed by the lift coeff;cient;
which is in turn fixed by the
elevator angle, implying that a constant AE gives a fixed ?. Also,
the flight path angle, y, at any given speed is controlled by the
thrust in the long term, implying that the ultimate result of moving
the throttle at fixed elevator angle is a change in y without change
in speed. But, by physical reasoning [l], we know that initial
response to opening the throttle is a forward acceleration,
and
initial response to elevator deflection is a rotation in pitch; hence,
the short term and long term effects of these controls are quite
contrary.
The total picture of longitudinal
control is clearly far
from simple when we represent the aircraft motion with a non-linear
system of equations.
To make short and long term responses agree, the aircraft is
stabilized in the following manner. The speed of the aircraft is kept
nearly constant throughout the landing operation and flight path is
controlled by means of both throttle and elevator angle deflection.
The thrust control loop maintains constant airspeed by generating a
thrust command signal to drive the throttle servo (Figure 17). The
thrust command signal is derived from airspeed error, horizontal and
vertical acceleration,
and the pitch command signal. These four
signals are processed by passing through variable gains and a
46
a
D
K
T1
. x V
F T C
Figure 17 Feedback loop-thrust 47 -_-
differencing circuit so as to generate a thrust command signal of
correct magnitude. The elevator control loop generates an elevator
angle command signal to drive the elevator angle servo (Figure 18) so
as to maintain air velocity constant and control the flight path. The
elevator angle command signal is also derived from airspeed error,
horizontal and vertical acceleration,
and the pitch comnand signal,
and then passed through variable gains. The thrust command signal and
elevator angle command signal are given by
FTc = KT1 "a
6EC = KDIVa
.
.
- KT2 v'+K T3 'v + KT4 ec ,
.
.
- KD2 ; - KD3 f + KD4 ec ,
where KT1 and KD1 are the variable gains calculated from the system Equations (13), (14), and 15) under zero wind conditions, given by
Gil
-G12
0
0
-D2
0
-1
0
7
H9 H1O , L H1l
KD1
KD2 -1
KD3 -! KD4
-G1o Gil
= -D2
0
-
0
-D2
0
-1
-
I iH6 H7
c H8 -1
48
V a
c
K D1
% C -i
KS
hS+al) [(S+a212+b2] I-
Figure 18 Feedback loop-elevator angle 49
where
G1 = D7 G2 = - (C1+C2 a) cos(y' -y)-C3
sin(y' -y)
G3 = - C4 sin(y' -y)
G4 = D6 cos(6T+c) G5 = C3 cos(y' -y)-(C1+C2 G6 = c4 cos(y' -y) G7 = D6 sin(6T+a) G8 = C5
cd) sin(y' -y)
G9 = c6 G1o = c7vacos(y' - y)+(C8Va+C9q+ClD&')sin(y'-y) Gil = (C8Va+Cgq+Clo~')cos(y'-y)-C7Vasin(y'-y)
G12 = Cl1 va+c12q+c13c? H1 = G6G1 - G7G9 H2 = G5G1 - G7G8 H3 = G5Gg - G6G8 H4 = G2H1 - G3H2 + G4H3 H5 = vf H4 H6 = Hz/H5 H7 = (G2G1 - G4G8)/H5 H8 = (G2G7 - G4G5)/H5 H9 = H3/H4 H10 = (G2Gg - G3G8)/H4
Hll = (G2G6 - G3G5)/H4 ,
with the Cn values provided in the appendix.
50
CHAPTER V
RESULTS ANDDISCUSSION
The two-dimensional equations of motion, Equations (l), (2), and
(3), for the aircraft discussed in Chapter II were solved on a digital
computer using a fourth-order Runge-Kutta technique. Wind models
incorporated into the governing equations include (1) atmospheric flow
over simulated buildings, (2) atmospheric flow in the absence of
buildings, and (3) atmospheric flow associated with thunderstorm gust
fronts. The influence of these wind fields on the aircraft landing
under different conditions of terrain roughness is investigated,
The
aircraft characteristics
used in the simulation are that of the DC-8
and the DHC-6, specifications
of which are given in the Appendix. The
initialization
conditions for the simulated landings of the aircraft
with fixed controls are trimmed conditions on a -2.7 degree glide
slope, with the descent beginning at an altitude of 91.4 meters (300 feet).
This corresponds to a touchdown point of 1939 meters (6361 feet),
down range from where the descent begins. Any variation in
winds will cause the aircraft to deviate from the glide slope. The
deviation in touchdown point for fixed control conditions is defined as
the distance between the actual touchdown point and the intended glide
slope touchdown point.
Figures 19 and 20 show the descent trajectories
of the aircraft
into a wind blowing over a two-dimensional bluff-type body, similar to a block building, and a step, similar to a long, wide building,
51
zO = 0.2 m
0
zO = 0.4 m
D
zO = 0.8 m
0
Horizontal distance X (II-I) Figure 19 Fixed control landing over a block building
zO = 0.45 m -0 zO = 1.0 m -0
Horizontal
360 distance
X (m)
Figure 20 Fixed control landing over a step
respectively.
The heights of the simulated block building and the
step building are of 20 m and 10 m, respectively.
Figure 21 shows the
trajectories
of the aircraft in identical wind conditions without the
presence of the building (i.e., the neutral atmospheric boundary
layer), and Figure 22 shows the descent trajectories
of the aircraft
into the wind fields characteristic,
of a thunderstorm gust front.
Figures 23 and 24 show the winds, both horizontal and vertical,
that were encountered during the descent of the aircraft through the
building-disturbed
winds --a block building and a long, wide building,
respectively.
Figure 25 shows the horizontal and vertical winds that
were encountered by the aircraft during descent through the thunder-
storm gust front. Three flow conditions were used in each simulation
of the wind fields for the flow over the block building, for the
atmospheric boundary layer flow without the building present, and for
the thunderstorm gust front. The surface roughness parameter, Zo, was
parametrically
assigned the values of 0.2, 0.4 and 0.8 m, with corre-
sponding friction velocities,
u,, of 1.25 m/set, 1.4 m/set, and
1.6 m/set, respectively.
These combinations of friction velocity and
surface roughness give wind speeds of 12.3 m/set, 11.4 m/set, and
10.4 m/set, respectively,
at an altitude of 10 meters. For simu-
lation of flow over a long, wide building, surface roughness values of
0.45 meters and 1.0 meters were used, with an assigned wind speed of
10 m/set at an altitude of 10 meters. This corresponds to friction
velocities of 1.27 m/set and 2.5 m/set, respectively.
Figures 26, 27, 28 and 29 show the landing trajectories
of the
aircraft with automatic controls, through the atmospheric boundary
54
zO = 0.2
0
zO = 0.4 -D
zO = 0.8-
0
10'00
2600
Horizontal distance X (m)
Figure 21 Fi'xed control landing in the atmospheric boundary layer
26bO
1 1000
I 2000
1
2600
Horizontal
distance X (m)
Figure 22 Fixed control landing in thunderstorm gust front
24222018-
X
2.0
zN
a
1.0
.5
3
= 0.4 zO
-a
zO = 0.8 -0
Figure 23 Wind distribution flight path
over a block building along the
57
21.0 14.0
7.0 0.c
zO = 0.45 m
a
X
Z 0 = 1.0 m
0
Figure 24 Wind distribution the flight path
over a long, wide bui'lding along
58
3x 21-
423
l-l 14-
J
0"
.:
7-
g
X
0
X
14-r
2 -r: .E
aBN 7-
.35
7
.:
:s:
0
-3.5zO = 0.2 m-o
0 a
Cl
zO = 0.4 m-6
\ X
zO = 0.8 m-0
Figure 25 Wind distribution the flight path
in the thunderstorm gust front along
59
zO = 0.2
0
zO = 0.4-
0
zO = 0.8-
0
1000
2000
2600
Horizontal
distance X (m)
Figure 26 Automatic landing in atmospheric boundary layer
I -c-nI
zO = 0.2
0
zO = 0.4
a
zO = 0.8
0
10-00 Horizontal
distance X (m)
Figure 27 Automatic landing over block building
zO = 0.45 m
a
zO = 1.0 m
0
1600
2000
2600
Horizontal
distance X (m)
Figure 28 Automatic landing over a long, wide building
-
loo-/
z. s 0.2
0
za 3 0.4
a
z. s 0.8
0
m W
lQO0 Horizontal
distance X (JII)
2QQQ
26QQ
Figure 29 Automatic landing in the flow associated with thunderstorm gust front
layer without the presence of the building, flow over a block building,
flow over a long, wide building, and a thunderstorm gust front,
respectively;
The same wind field simulations that were used in the
landjng simulation with the fixed controls are applied here also.
Figures 30, 31 and 32 show the controls, thrust and elevator angle,
that were actuated by the automatic control system to track the glide
slope through the block building, the long, wide building, and the
thunderstorm gust front disturbed wind fields, respectively.
Addi-
tionally, Figure 33 shows the trajectory of an aircraft with the
characteristics
of a DHC-6 Twin Otter with automatic controls landing
through the atmospheric flow over a block geometry building.
The deviations from the touchdown point in the different wind
fields are presented in Table 1, Note that a positive deviation
indicates a long landing and a negative deviation indicates a short
landing. The deviation point for the automatically-controlled
air-
craft was taken as the difference between the actual touchdown point
and the touchdown point determined by the prescribed trajectory.
This value is computed, as illustrated
in Figure 34, by adding X = 3h,,
the specified condition for capture to begin, AX = 0.02hr required
cap for the glide slope to be captured, Z, cot yo, the horizontal distance
covered while on the glide slope, and 0.2hr cot yf, the horizontal
distance traversed during flare. The value of yf is specified as
1.35 degrees.
One observes that the aircraft made short landings in almost all
cases with fixed controls.
By comparing the landing of the aircraft
in the atmospheric
boundary layer,
with and without
64
the presence of the
w
0
2
-2
lFa
8
-4
4J
kz
-6
rl w
-8
2 - arl
x
LCD -mlJ 2 i2
1.81.40.910.45-
x
zQ =1 Q.2 m
0
zQ = 0.4 m
0
zO = 0.8 m
0
FPgure 30 Controls requi,red for 1andi:ng over a 61ock building
65
1.6
E 0.32-
X
zO = 0.45 m
n
= 1.0 m zO
0
Figure 31 Controls requi.red for landing over a step 66
-6 -8
* 2.70 d x 1.8-
B
b4 0.914J 3
X
zO = 0.2 m
0
zO = 0.4 m
n
zO = 0.8 m
0
Figure 32 Controls required for automatic landing in thunderstorm gust front
67
100 91.4
N
z
-34
50
x 4
zO = 0.4 m U* = 1.4 m/set
Wspeed = 11.42
m/set
at 10 m altitude
Horizontal
distance X (m)
Figure 33 DHC-6 landing through atmospheric flow over a block building
Table 1. Deviation from touchdown point
Wind Condition
With Fixed
Controls (meters)
With Automatic Controls (meters)
I. Flow over a building
(1) Block geometry
a. Zo=0.2m u,=1.25m/sec
-198
4-35
b. Zo=0.4m u,=1.4 m/set
-309
-30
C. Zo=0.8m u,=1.6 m/set
-415
-5
(2) Long step geometry
a. Zo=0.45m u,=1.27m/sec
-147
-15
b* Z0' =l.Om u,=2.5 m/set
-185
+ll
II. Flow without building present
a. Zo=0.2m u,=1.25m/sec
-313
-14
b. Zo=0.4m u,=1.4 m/set
-328
+7
C. Zo=0.8m u,=l.6 m/set
-350
+6
III. Flow associated with thunderstorm gust fronts
a. Zo=0.2m u,=1.25m/sec
-223
+19
b. Zo=0.4m u,=l.4 m/set
-80
+8
C. Zo=0.8m u,=1.6 m/set
+505
-27
69
-O.O2h,
T
3 = 0.78h 1:
0.2hr
t- 3-o --i-e
z1 cot Y. -----+-
0.2hr cot Yt --I
X
Hold Capture
Track
Flare
Figure 34 Automatic landing reference trajectory
building, one can observe the effect of complex wind patterns caused
by the presence of the large bluff objects. The aircraft lands
approximately 300 meters short of the touchdown point in the atmospheric
flow without the building, which is a direct result of the decreasing
head wind with elevation.
However, this is a predictable effect and
all landings are within 37 meters of one another, as shown by Figure 21,
page 55. Landing through the same atmospheric flow over buildings,
however, causes larger variations in touchdown point between the
different wind conditions.
With a surface roughness value of 20 cm
the aircraft lands approximately 200 meters short, whereas for a Z. of
80 cm the aircraft lands approximately 400 meters short.
This variation in touchdown points can be explained by looking at
the winds encountered by the aircraft along the flight path; see
Figure 23, page 57, and Figure 24, page 58. The aircraft encounters
an increased head wind (positive horizontal shear) and a downdraft
just before the building.
An increasing head wind during approach
with fixed controls causes the aircraft to be high on the glide slope.
This effect is absent in the undisturbed atmospheric boundary layer
because of the continuously decreasing head wind, which causes the
aircraft with fixed controls to always be below the glide slope. The
aircraft does have a slight downdraft, but this is not sufficient
to
overcome the head wind influence.
Just past the building, there is a
sudden drop in horizontal wind and a sudden increase in updraft. This
reverses the previous effect and forces the aircraft to go below the
glide slope. Thus, competing wind effects occur relative to the
71
undisturbed wind field case, resulting in an unpredictable deviation
from touchdown.
One observes that the magnitude of the positive horizontal
(tail wind) shear is largest for the case of Z. = 20 cm and smallest
for the case of Z. = 80 cm. Thus, landing under the conditions of
Z. = 20 cm and Z. = 40 cm creates sufficiently
high positive hori-
zontal shears and updrafts to force the aircraft higher during part of
the approach than the case with no building present, resulting in
shorter deviation from touchdown. The case Z. = 80 cm does not create
as large a positive horizontal shear and updraft and the influence of
the decreasing head wind and downdraft in the wake of the building
produce a shorter touchdown than occurs with the undisturbed wind
field.
In the case of landings through the flow over the long building,
the aircraft lands 147 m short for the case Z. = 45 cm and 185 meters
short in the case Z. = 100 cm. One should notice that in this case the
descent starts from an altitude of about 33 meters. Therefore, these
touchdown points cannot be compared with the touchdowns in the
landings through the atmospheric boundary layer without the building.
However, by looking at the winds encountered by the aircraft
along the flight path, one can observe the similarity with the block
building case. Just as the aircraft passes over the edge of the
building, there is a sudden drop in horizontal wind which causes the
aircraft to go below the glide slope, and thereby resulting in an
unpredictable deviation from touchdown. One can observe that the dif-
ference between the case of Z, = 100 cm and Z. = 45 cm is that the
72
initial head wind is higher and decreases more rapidly. Also, the aircraft encounters a smaller updraft than in the former case which tends to decrease the sink rate. Both of these wind effects result in a shorter touchdown, as indicated by the results in Table '1, page 69.
In'the case of landings with automatic controls, the deviations
from the touchdown points are very small for landings through the
atmospheric flow without the building, as well as with buildings
present. Even though the deviations from the touchdown point are not
significant,
one can see that complex wind patterns created by the
presence of large buildings do create larger deviations in touchdown.
Moreover, a significant
factor on the safety of aircraft operations is
the rate at which the controls must be operated to track the glide
path. Figure 30, page 65, shows that the thrust must be reduced
significantly
as the aircraft passes over the building to compensate
for the sudden excursions in the horizontal and vertical winds.
Thrust was cut almost 50% in the case for Z. = 80 cm. Figure 31,
page 66, shows the controls that were used in the case of flight over
the long, wide building.
In this case the elevator angle changes
quite rapidly to compensate for the effects of changing winds.
Figure 22, page 56, and Figure 29, page 63, show the aircraft
landing trajectories
in the flow associated with a thunderstorm gust
front with fixed controls and with automatic controls, respectively.
In the case of fixed control landings, the deviations between touch-
down points are large, as much as 725 meters variation from the case
for Z, = 20 cm and for Z, = 80 cm. Figure 22 shows that there are
73
very large deviations from the flight path itself and thus would
result in unsatisfactory
landings.
Figure 25, page 59, shows the winds encountered by the aircraft
along the trajectory.
Initially,
there is high vertical updraft which
increases to approximately 13 m/set and then suddenly drops to almost
zero. Thus, the aircraft is initially
blown above the glide slope and
then suddenly this wind dies out, resulting in a high sink rate. In
the case for Z. = 20 cm, the head wind remains almost constant and
then starts decreasing very rapidly; at the same time the vertical
updraft suddenly drops to zero, creating a strong turning moment on
the aircraft which results in a shorter landing. For landing under
the conditions of Z. = 80 cm, head wind and vertical updraft remain
constant for a longer period of time, thus keeping the aircraft above
the glide path for a longer period of time.
In the case of landings with automatic controls through this wind
field, the deviations from the flight path are small, but the
influence of these severe winds is to cause rapid changes in the
controls.
Figure 32, page 67, shows the controls that were applied to
maintain the flight path. Here thrust starts out initially
at a high
magnitude, increases slightly and then drops very suddenly to almost
one-third of the initial value. This is because the pitch angle is
maintained constant in automatic landings, a vertical updraft causes a
larger angle of attack and increased drag. Therefore, when the
vertical updraft suddenly goes to zero, the angle of attack decreases
and drag drops, hence thrust is reduced to prevent going high on the
74
glide slope. The elevator angle also changes very rapidly from 0 to -6 degrees in the process to compensate for the sudden drop in vertical wind and counterclockwise moment produced by the vertical wind, since a negative elevator setting corresponds to a counterclockwise rotation with the airplane traveling in positive x-direction,
Figure 33, page 68, shows that the aircraft with the characteristics of a DHC-6 on a 6-degree glide path behaves basically the same as a DC-8. For the landing of this aircraft, few changes were required in the automatic control system. In the glide-slope capture mode the reference flight path angle was changed from 2.7 to 6 degrees and' the gain constant, k3, from 0.05 to 0.1. In the glide-slope tracking mode the constant, a3, is changed from 0.01 to 0.02, and in the flare mode the constant, a6, is changed from 4.0 to 5.0. These changes in different control modes increase the response of pitch angle command variable, ec,
75
CHAPTER VI
CONCLUSIONS
The two-dimensional aircraft landing simulation study has pro-
vided some basic results concerning the problems of wind shear due to
the presence of large buildings or other bluff geometries. The air-
craft encountering a strong wind shear caused by the edge of a
building is drawn towards the building,
With fixed controls,
deviation in touchdown point in excess of 400 m resulting from
variation of the horizontal wind during the final 100 m of descent has
been computed under wind shear conditions that may realistically
be
encountered around buildings or bluff terrain features.
Wind shear due to thunderstorm gust fronts can cause very severe
departures from the glide slope during landing. Although thunderstorm
gust fronts are not encountered too frequently, landing through such a
gust front can be very hazardous and requires rapid changes in the
controls required to maintain the flight path. Based on the model of
thunderstorm field investigated in this report, changes in the controls
at the rate of 7 degrees of elevator angle and 9072 kg of thrust per
one-half second for the DC-8 were required.
Although the surface roughness parameter, Zo, shows little
influence on touchdown points during the landings through the atmospheric flow over level terrains, it does have considerable effect on
aircraft landing when large buildings or bluff objects are present
near the airports. 76
BIBLIOGRAPHY
1. Etkin, B., Dynamics of Atmospheric Flight. Inc., New York, 1972.
John Wiley & Sons,
2. Blakelock, John H., Automatic Control of Aircraft John Wiley & Sons, Inc., New York, 1965.
and Missiles.
3. Neuman, F., and J. Foster, “Investigation
of a Digital Augo-
matic Aircraft Landing System in Turbulence," NASA
TN D-6066, October, 1970.
4. Melvin, W. W., "Wind Shear on the Approach," Shell Aviation News, 393:16-21, (1971).
5. Kraus, K., "Aspects of the Influence of Low-Level Wind Shear on
Aviation Operations," International
Conference on Aerospace
and Aeronautical Meteorology, Washington, D. C.,
May 22-26, 1972.
6. Camp, D. W., W. Frost, and W. A. Crosby, "Flight Through Thunderstorm Outflows," to be presented at 11th International Congress of ICAS, Lisbon, Portugal, September
10-16, 1978.
7. Luers, J. K., and J. B. Reeves, "Effect of Shear on Aircraft Landing," National Aeronautics and Space Administration CR-2287, George C. Marshall Space Flight Center, Huntsville, Alabama, July, 1973.
8. National Transportation Safety Board, "Eastern Airlines, Inc.,
Boeing 727-225, John F. Kennedy International
Airport,
Jamaica, New York, June 24, 1975," Aircraft Accident Report
No. NTSB-AAR-76-8, National Transportation Safety Board,
Washington, D. C., March 12, 1976.
9. National Transportation Safety Board, “Iberia Lineas Aereas de
Espana (Iberian Airlines), McDonnel Douglas DC-10-30,
EC CBN, Logan International
Airport, Boston, Massachusetts,
December 17, 1973," Aircraft Accident Report No. NTSB-AAR-
74-14, National Transportation Safety Board, Washington,
D. C., November 8, 1974.
77
10. Frost, W,, and D, W. Camp, "Wind Shear Modeling for Aircraft
Hazard Definition."
Interim report No. FAA-RD-77-36 prepared
for U. S. Department of Transportation,
Federal Aviation
Administration,
Systems Research and Development Service,
by FWGAssociates, Inc., Tullahoma, Tennessee, March, 1977.
11. Haskins, G. L., "The X in WX," Aerospace Safety, April, 1969.
12. Frost, Walter, "Flight in Variable Mean Winds," Report in preparation for NASA Contract No. NAS8-29584.
13. Gera, J., "The Influence of Vertical Wind Gradients on the Longitudinal Motion of Airplanes," NASA TN D-6430, September, 1971.
14. Johnson, W. A., and D. T. McRuer, "A System Model for Low-Level Approach," Journal of Aircraft, December, 1971.
15. Farrell, J. L., Integrated Aircraft New York, 1976.
Navigation.
Academic Press,
16. Bosman, D., "Aircraft Flight Instrumentation
Integrated Data
Systems," AGARD Conference Proceedings Number Six,
November, 1967.
17. Tanney, J. W,, "Fluidics,"
Progress in Aeronautical
Volume 10. Pergamon Press, Oxford, 1970.
Sciences,
18. Blackadar, A. K., "The Vertical Distribution
of Wind and
Turbulent Exchange in a Neutral Atmosphere," Journal of
Geophysical Research, 67:3095-3102, April, 1962.
19. Lettau, H. H., "Wind Profile, Shear Stress and Geostropic Drag Coefficients in the Atmospheric Surface Layer," Advances in Geophysics. Academic Press, New York, 1962.
20. Frost, W., J. R. Maus, and W. R. Simpson, "A Boundary Layer
Approach to the Analysis of Atmospheric Motion Over a Surface
Obstruction,"
NASA CR-2182, January, 1973.
21. Panofsky, H. A., "The Atmospheric Boundary Layer Below 150 Meters, I Annual Review of Fluid Mechanics, Vol. 6, 1974.
22. Shieh, C. F., W. Frost, and J. Bitte, "Neutrally Stable Atmos-
pheric Flow Over a Two-Dimensional Rectangular Block,"
Report prepared under NASA Contract No. NAS8-29584, The
University of Tennessee Space Institute,
Tullahoma,
Tennessee, December, 1976.
78
23. Bitte, J., and W. Frost, "Atmospheric Flow Over Two-Dimensional
Bluff Surface Obstructions,"
NASA CR-2750, October, 1976.
24. Johnson, W. A., and D. T. McReur, "Development of a Category II Approach System Model," Technical Report 182-1, Systems Technology, Inc., December, 1969.
25. Osder, S. S,, "Avionics Requirements for All Weather Landing of Advanced SST's," Volume I, NASA CR-73092, 1967.
26. Fichtl, G. H., and D. W. Camp, Memo to Mr. Frank Coons, ARD 451, FAA, 2100 2nd Street, S. W., Washington, D. C., 20590, March 22, 1976.
27. Goff, R. C., "Thunderstorm Outflow Kinematics and Dynamics," NOAA Technical Memo ERL NSSL-75 (1975).
79
APPENDIX 80
APPENDIX
The aircraft characteristics
used in this simulation study are
for that of a DC-8 and a DHC-6. The initial conditions and aircraft
physical data are given as follows [7]:
DESCRIPTION
DC-8
DHC-6
H(m)
Reference altitude
91
91
V,(m/seC)
Initial velocity
70
46
v&d W(kd Iyy(kg-m2)
Initial flight path angle Aircraft weight Moment of inertia
-2.7 90700 5.3 x lo6
-6.0 4985 3.2 x lo4
LT(m)
Moment arm of thrust vector
1.2
-0.91
GT(dd 34 45
Angle between FT and FRL
3.15
0.0
Chord length
7
2
Wing area
256
39
The expressions aircraft are:
for the aerodynamic coefficients
of the DC-8
cL=cL +cL cx+cL
0
a
6E+j+ a Lq
c,=c,
+cm a+Cm 6E+gc
0
a
6E
a
mq + -a2v,
c
mAI
'
81
where the usual notation is used for the various stability derivatives.
The values of the stability derivatives are given as follows:
DC-8
DHC-6
cLO
cL a cL
"E cL
9 cL*ci
cDO
cDa 'Da2
0.90 5.30/rad O.O053/deg
7.68/rad 0.0 0.140 0.50l/rad 1.818/rad2
0.86 6.109/rad 0.5236/deg
2.152/rad 0.0 0.32 0.9832/rad 0.0
'm
0
'm cx C
m6E C
mq Cmae
-1.01 -l.O62/rad -O.O16l/deg -12.30/rad -4.Ol/rad
0.0/rad2 -2.026/rad -2.068/deg -28.76/rad -8.663lrad
The various dimensionless groups (normalizing factors) used in this
study are provided below:
D =P?!! 1 2w
D2 = e&! 'a2
82
H2 D3 = 7 a
D6 =
-3!L
2 w
v
a
LTD3 D7 = Iyy
The following are the "C" coefficents
and 6 :
FTC
EC
c1
= D, CD a
c2 = Dl 'DC,2
c3
= D, CL a
c4 = D, CL "E
c5
= D5 Cm a
6 = D5 Cm "E
c7 = Dl 'Do
used in variable gain computations of
8 = D1 CL0
c9 = Dl D4 CLq 83
clO = D, D4 Cc;
= D5 Cm
cll
0
= D5 D4 cm
52
9
cl3 = Dg D4 Cma.'
1. REPORT NO,
NASA CR - 3073 a TITLE AN0 SUBTITLE
Investigation of Aircraft
2. GOVERNMENT ACCESSION NO.
Landing in Variable Wind Fields
3. RECIPIENTS
CATALOG NO.
5. REPORT DATE
December 1978
6. PERFORMING ORGANIZATION
CODE
7. AUTHOR(S)
Walter Frost and Kapuluru Ravikumar
9. PERFORMING ORGANIZATION
NAME AND ADDRESS
Reddv
The University of Tennessee Space Institute TuIlahoma, Tennessee
12 SPONSORING AGENCY NAME AND ADDRESS
National Aeronautics and Space Administration Washington, D. C. 20546
6. PERFORMING ORGANIZATION
REPOR r
10. WORK UNIT, NO.
M-272
11. CONTRACT OR GRANT NO.
NAS8-29584
19. TYPE OF REPORi 8: PER100
COVERE
Contractor
1.1. SPONSORING AGENCY CODE
y SUPPLEMENTARY
NOTES
Prepared under the technical monitorship of the Atmospheric Sciences Division, Space Sciences Laboratory, Science and Engineering, NASA/Marshall Space Flight Center
16. ABSTRACT
This report describes a digital simulation study of the effects of gusts and wind shear on the approach and landing of aircraft. The gusts and wind shear are primarily those associated with wind fields created by surface wind passing around bluff geometries characteristic of buildings. Also, flight through a simple model of a thunderstorm is investigated.
A two-dimensional model of aircraft motion was represented by a set of nonlinear equations which accounts for both spatial and temporal variations of winds. The landings of aircraft with the characteristics of a DC-8 and a DHC-6 are digitally simulated under different wind conditions with fixed and automatic controls. The resulting deviations in touchdown points and the controls that are required to maintain the desired flight path are presented. The presence of large bluff objects, such as buildings in the flight path is shown to have considerable effect on aircraft landings.
7. KEr WOROS
Aviation Safety Aircraft Motion Simulation Low-Level Wind Wind Shear Turbulence
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