SOLUTION MANUAL
Aircraft Performance, An Engineering Approach
2nd Edition by Sadraey All Chapters 1 to 10 Covered
SOLUTION MANUAL
1
, Table of Contents
1. Atmosphere.
2. Equations of Motion.
3. Drag Force and Drag Coefficient.
4. Engine Performance.
5. Straight-Level Flight – Jet Aircraft.
6. Straight-Level Flight: Propeller-Driven Aircraft.
7. Climb and Descent.
8. Takeoff and Landing.
9. Turn Performance and Flight Maneuvers.
10. Aircraft Performance Analysis Using Numerical Methods and
MATLAB(R)
2
, Ch. 1
The software package Mathcad is used to solve problems.
1.1. Determine the temperature, pressure and air density at 5,000 m and ISA condition.
There are two methods:
a. Using appendix:
From Appendix A:
- Temperature: 255.69 K
- Pressure: 54,048 Pa
- Air density: 0.7364 kg/m3
b. Calculations:
K J
h 5000m ISA L1 6.5 R1 287 Po 101325Pa
1000m kgK
Sea level: To (15 273)K 288 K
5000 m: T5 To L1h 255.5 K (Equ 1.6)
5.256
T5
P5 Po 54000.3 Pa (Equ 1.16)
T o
P5 kg
5 0.736 (Equ 1.23)
R1T5 3
m
Same results.
3
, 1.2. Determine the pressure at 5,000 m and ISA-10 condition.
K J
h 5000m ISA 10 L1 6.5 R1 287 Po 101325Pa
1000m kgK
Sea level: To (15 273 10)K 278 K
5000 m: T5 To L1h 245.5 K (Equ 1.6)
5.256
T5
P5 Po 52714.2 Pa (Equ 1.16)
T o
1.3. Calculate air density at 20,000 ft altitude and ISA+15 condition.
K J
h 20000ft ISA 15 L1 2 R1 287 Po 101325Pa
1000ft kgK
Sea level: To [(15 273) 15]K 303 K To 545.4R
20000 ft: T20 To L1h 263 K T20 473.4R (Equ 1.6)
5.256
T20 lbf
P20 Po 48143.9 Pa P20 1005.5
(Equ 1.16)
T o ft
2
P20 kg slug
20 0.638 20 0.001238 (Equ 1.23)
R1T20 3 3
m ft
1.4. An aircraft is flying at an altitude at which its temperature is -4.5 oC. Calculate:
4
Aircraft Performance, An Engineering Approach
2nd Edition by Sadraey All Chapters 1 to 10 Covered
SOLUTION MANUAL
1
, Table of Contents
1. Atmosphere.
2. Equations of Motion.
3. Drag Force and Drag Coefficient.
4. Engine Performance.
5. Straight-Level Flight – Jet Aircraft.
6. Straight-Level Flight: Propeller-Driven Aircraft.
7. Climb and Descent.
8. Takeoff and Landing.
9. Turn Performance and Flight Maneuvers.
10. Aircraft Performance Analysis Using Numerical Methods and
MATLAB(R)
2
, Ch. 1
The software package Mathcad is used to solve problems.
1.1. Determine the temperature, pressure and air density at 5,000 m and ISA condition.
There are two methods:
a. Using appendix:
From Appendix A:
- Temperature: 255.69 K
- Pressure: 54,048 Pa
- Air density: 0.7364 kg/m3
b. Calculations:
K J
h 5000m ISA L1 6.5 R1 287 Po 101325Pa
1000m kgK
Sea level: To (15 273)K 288 K
5000 m: T5 To L1h 255.5 K (Equ 1.6)
5.256
T5
P5 Po 54000.3 Pa (Equ 1.16)
T o
P5 kg
5 0.736 (Equ 1.23)
R1T5 3
m
Same results.
3
, 1.2. Determine the pressure at 5,000 m and ISA-10 condition.
K J
h 5000m ISA 10 L1 6.5 R1 287 Po 101325Pa
1000m kgK
Sea level: To (15 273 10)K 278 K
5000 m: T5 To L1h 245.5 K (Equ 1.6)
5.256
T5
P5 Po 52714.2 Pa (Equ 1.16)
T o
1.3. Calculate air density at 20,000 ft altitude and ISA+15 condition.
K J
h 20000ft ISA 15 L1 2 R1 287 Po 101325Pa
1000ft kgK
Sea level: To [(15 273) 15]K 303 K To 545.4R
20000 ft: T20 To L1h 263 K T20 473.4R (Equ 1.6)
5.256
T20 lbf
P20 Po 48143.9 Pa P20 1005.5
(Equ 1.16)
T o ft
2
P20 kg slug
20 0.638 20 0.001238 (Equ 1.23)
R1T20 3 3
m ft
1.4. An aircraft is flying at an altitude at which its temperature is -4.5 oC. Calculate:
4