Cessna 620 -- Linear Model

Graduate Research done by Jeff Scott
Advisor: Prof. Michael Selig
Applied Aerodynamics Group
Department of Aeronautical and Astronautical Engineering
University of Illinois at Urbana-Champaign, Urbana, Illinois 61801

Last updated June 1, 2000

The linear aerodynamics model uses stability derivatives to approximate actual aircraft behavior. The Cessna 620 linear model is based on the following flight conditions (cruise):

Variable	Variable in Code	Description	Units	Value(s)	Source	Notes
Flight Conditions
h	Altitude	altitude above sea level	ft	18000	Roskam pg 515
	Alpha	angle of attack	deg	0	Roskam pg 515
V	V_true_kts	velocity (true air speed)	kts	217.2	Roskam pg 515	Mach 0.351
q	Dynamic_pressure	dynamic pressure	lb/ft²	91.1	Roskam pg 515
C.G.	-	center of gravity location	%	25	Roskam pg 515
C_L	CL	lift coefficient	-	?		not available
C_D	CD	drag coefficient	-	?		not available
C_m	Cm	pitching moment coefficient	-	?		not available

The data input into the simulator is listed in the following tables:

Variable	Variable in Code	Description	Units	Value(s)	Source
Geometry
b	bw	wingspan	ft	55.1	Roskam pg 515
	cbar	wing mean aerodynamic chord	ft	6.58	Roskam pg 515
S	Sw	wing surface area	ft²	340	Roskam pg 515

Control Surface Geometry

Variable Variable
in Code Description Units Value(s) Source Notes

e_max demax maximum elevator deflection deg +20 - guess

e_min demin minimum elevator deflection deg -20 - guess

a_max damax maximum aileron deflection deg +20 - guess

a_min damin minimum aileron deflection deg -20 - guess

r_max drmax maximum rudder deflection deg +20 - guess

r_min drmin minimum rudder deflection deg -20 - guess

Control Surface Geometry
Variable	Variable in Code	Description	Units	Value(s)	Source	Notes
e_max	demax	maximum elevator deflection	deg	+20	-	guess
e_min	demin	minimum elevator deflection	deg	-20	-	guess
a_max	damax	maximum aileron deflection	deg	+20	-	guess
a_min	damin	minimum aileron deflection	deg	-20	-	guess
r_max	drmax	maximum rudder deflection	deg	+20	-	guess
r_min	drmin	minimum rudder deflection	deg	-20	-	guess

Mass Data

Variable Variable
in Code Description Units Value(s) Source Notes

W Weight weight at flight condition lb 15000 Roskam pg 515 converted to Mass
[slug/ft³] in code

I_xx I_xx roll inertia slug ft² 64811 Roskam pg 515

I_yy I_yy pitch inertia slug ft² 17300 Roskam pg 515

I_zz I_zz yaw inertia slug ft² 64543 Roskam pg 515

I_xz I_xz lateral cross inertia slug ft² 0 Roskam pg 515

Mass Data
Variable	Variable in Code	Description	Units	Value(s)	Source	Notes
W	Weight	weight at flight condition	lb	15000	Roskam pg 515	converted to Mass [slug/ft³] in code
I_xx	I_xx	roll inertia	slug ft²	64811	Roskam pg 515
I_yy	I_yy	pitch inertia	slug ft²	17300	Roskam pg 515
I_zz	I_zz	yaw inertia	slug ft²	64543	Roskam pg 515
I_xz	I_xz	lateral cross inertia	slug ft²	0	Roskam pg 515

Propulsion Data

Variable Variable
in Code Description Units Value(s) Source Notes

T_max simpleSingleMaxThrust maximum thrust lb 1300 Roskam pg 516 estimated from C_{T_x}
at cruise

Propulsion Data
Variable	Variable in Code	Description	Units	Value(s)	Source	Notes
T_max	simpleSingleMaxThrust	maximum thrust	lb	1300	Roskam pg 516	estimated from C_{T_x} at cruise

Aerodynamic Data

Variable Variable
in Code Description Units Value(s) Source Notes

C_D₀ CDo drag coefficient at =0 - 0.0322 Roskam pg 516

C_D CD_a drag curve slope 1/rad 0.269 Roskam pg 516

C_{D_e} CD_de drag due to elevator 1/rad 0 Roskam pg 516 e positive down

C_L₀ CLo lift coefficient at =0 - 0.48 Roskam pg 516

C_L CL_a lift curve slope 1/rad 5.55 Roskam pg 516

C_L CL_adot lift due to angle of attack rate 1/rad 2.7 Roskam pg 516

C_{L_q} CL_q lift due to pitch rate 1/rad 7.5 Roskam pg 516

C_{L_e} CL_de lift due to elevator 1/rad 0.58 Roskam pg 516 e positive down

C_m₀ Cmo pitch moment coefficient at =0 - 0.06 Roskam pg 516

C_m Cm_a pitch moment due to angle of attack 1/rad -1.18 Roskam pg 516

C_m Cm_adot pitch moment due to angle of attack rate 1/rad -8.17 Roskam pg 516

C_{m_q} Cm_q pitch moment due to pitch rate 1/rad -22.4 Roskam pg 516

C_{m_e} Cm_de pitching moment due to elevator 1/rad -1.73 Roskam pg 516 e positive down

C_Y CY_beta side force fue to sideslip angle 1/rad -0.883 Roskam pg 517

C_{Y_p} CY_p side force due to roll rate 1/rad -0.227 Roskam pg 517

C_{Y_r} CY_r side force due to yaw rate 1/rad 0.448 Roskam pg 517

C_{Y_a} CY_da side force due to aileron 1/rad 0 Roskam pg 517 a positive
right aileron up

C_{Y_r} CY_dr side force due to rudder 1/rad 0.2 Roskam pg 517 r positive left

C_l Cl_beta dihedral effect 1/rad -0.1381 Roskam pg 517

C_{l_p} Cl_p roll damping 1/rad -0.566 Roskam pg 517

C_{l_r} Cl_r roll moment due to yaw rate 1/rad 0.1166 Roskam pg 517

C_{l_a} Cl_da roll moment due to aileron 1/rad -0.1776 Roskam pg 517 a positive
right aileron up

C_{l_r} Cl_dr roll moment due to rudder 1/rad 0.02 Roskam pg 517 r positive left

C_n Cn_beta weathercock stability 1/rad 0.1739 Roskam pg 517

C_{n_p} Cn_p adverse yaw 1/rad -0.0501 Roskam pg 517

C_{n_r} Cn_r yaw damping 1/rad -0.2 Roskam pg 517

C_{n_a} Cn_da yaw moment due to aileron 1/rad 0.0194 Roskam pg 517 a positive
right aileron up

C_{n_r} Cn_dr yaw moment due to rudder 1/rad -0.1054 Roskam pg 517 r positive left

Variable	Variable in Code	Description	Units	Value(s)	Source	Notes
Aerodynamic Data
C_D₀	CDo	drag coefficient at =0	-	0.0322	Roskam pg 516
C_D	CD_a	drag curve slope	1/rad	0.269	Roskam pg 516
C_{D_e}	CD_de	drag due to elevator	1/rad	0	Roskam pg 516	e positive down
C_L₀	CLo	lift coefficient at =0	-	0.48	Roskam pg 516
C_L	CL_a	lift curve slope	1/rad	5.55	Roskam pg 516
C_L	CL_adot	lift due to angle of attack rate	1/rad	2.7	Roskam pg 516
C_{L_q}	CL_q	lift due to pitch rate	1/rad	7.5	Roskam pg 516
C_{L_e}	CL_de	lift due to elevator	1/rad	0.58	Roskam pg 516	e positive down
C_m₀	Cmo	pitch moment coefficient at =0	-	0.06	Roskam pg 516
C_m	Cm_a	pitch moment due to angle of attack	1/rad	-1.18	Roskam pg 516
C_m	Cm_adot	pitch moment due to angle of attack rate	1/rad	-8.17	Roskam pg 516
C_{m_q}	Cm_q	pitch moment due to pitch rate	1/rad	-22.4	Roskam pg 516
C_{m_e}	Cm_de	pitching moment due to elevator	1/rad	-1.73	Roskam pg 516	e positive down
C_Y	CY_beta	side force fue to sideslip angle	1/rad	-0.883	Roskam pg 517
C_{Y_p}	CY_p	side force due to roll rate	1/rad	-0.227	Roskam pg 517
C_{Y_r}	CY_r	side force due to yaw rate	1/rad	0.448	Roskam pg 517
C_{Y_a}	CY_da	side force due to aileron	1/rad	0	Roskam pg 517	a positive right aileron up
C_{Y_r}	CY_dr	side force due to rudder	1/rad	0.2	Roskam pg 517	r positive left
C_l	Cl_beta	dihedral effect	1/rad	-0.1381	Roskam pg 517
C_{l_p}	Cl_p	roll damping	1/rad	-0.566	Roskam pg 517
C_{l_r}	Cl_r	roll moment due to yaw rate	1/rad	0.1166	Roskam pg 517
C_{l_a}	Cl_da	roll moment due to aileron	1/rad	-0.1776	Roskam pg 517	a positive right aileron up
C_{l_r}	Cl_dr	roll moment due to rudder	1/rad	0.02	Roskam pg 517	r positive left
C_n	Cn_beta	weathercock stability	1/rad	0.1739	Roskam pg 517
C_{n_p}	Cn_p	adverse yaw	1/rad	-0.0501	Roskam pg 517
C_{n_r}	Cn_r	yaw damping	1/rad	-0.2	Roskam pg 517
C_{n_a}	Cn_da	yaw moment due to aileron	1/rad	0.0194	Roskam pg 517	a positive right aileron up
C_{n_r}	Cn_dr	yaw moment due to rudder	1/rad	-0.1054	Roskam pg 517	r positive left

Cessna 620 -- Linear Model

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