Presentation is loading. Please wait.

Presentation is loading. Please wait.

. Mr. K. NASA/GRC/LTP Part 5 Pathfinder’s Path II.

Published byAndrea Cooper Modified over 9 years ago

Similar presentations

Presentation on theme: ". Mr. K. NASA/GRC/LTP Part 5 Pathfinder’s Path II."— Presentation transcript:

1 . Mr. K. NASA/GRC/LTP Part 5 Pathfinder’s Path II

2 Preliminary Activities In the following preliminary activities, five real-world problems are given that will require mathematical thought. The lecture portion of the lesson will go over each of these problems with the students and allow them to compare and discuss their results with the presenter. Discussion is encouraged during the lecture portion!

3 1. The Earth is 150 million km from the sun. It completes one orbit in a period of approximately 365.25 days. Calculate its orbital speed in km/sec and mph. 2. Mars is 230 million km from the sun. It completes one orbit in a period of approximately 687 days. Calculate its orbital speed in km/sec and mph. 3. Review the material from “Pathfinder’s Path I”. Be sure that you understand the ellipse, and the Vis-Viva equation!

4 Semi-major axis = a Semi-minor axis = b Focal length = f f *Remember: f 2 = a 2 - b 2 #1 4. Using the following two sketches and Kepler’s law of orbits, identify the semi-major axis, the semi-minor axis, and the focal length of Pathfinder’s Hohmann transfer ellipse. Given the astronomical information in problems 1 and 2, and your knowledge of the ellipse*, specify each of these quantities for Pathfinder in millions of km (Mkm).

5 #2 Remember: Every planet travels in an ellipse with the sun at one focus.

6 5. Use the Vis-Viva equation to predict the orbital velocity (in km/sec and mph) of the Pathfinder spacecraft at the point of departure (marked with an  in the accompanying diagram) and the point of arrival (marked with a  in the accompanying diagram). Completion of these five exercises will give you a rough idea of some of the basic orbit calculations necessary for sending the Pathfinder to Mars.

7 E H M  

8 Solutions to Problems in Preliminary Activities 1 - 5.

9 Activities 1 & 2 Orbital velocities of Earth and Mars 1. Distance from planet to sun = d 2. Circumference = 2  d 3. Orbital speed = 2  d Period Sun’s mass = M Setup Planet or spacecraft mass = m

10 Earth d = 150 X 10 6 km 2  d = 9.4 X 10 8 km T = 365.25 days = 3.2 X 10 7 sec Orbital speed = 29 km/sec = 66,000 mph Mars d = 230 X 10 6 km 2  d = 1.5 X 10 9 km T = 687 days = 5.9 X 10 7 sec Orbital speed = 25 km/sec = 57,000 mph Calculations

11 Activity 3: The Vis-Viva Equation (Only) The vis viva equation is v = {2(K + GMm/r)/m } 1/2 This equation gives the velocity of an object at various ponts on an elliptical orbit. I need to tell you that, with differential equations, we show that K = -GMm/2a Therefore v = {2GM (1/r - 1/2a) } 1/2 = 1.6 X 10 10 (1/r - 1/2a) 1/2 … (MKS Units!)

12 E M H Activity 4 150 Mkm 230 Mkm 230Mkm + 150Mkm 2 Setup The Hohmann Transfer Ellipse

13 Semi-major axis: a = ½(230Mkm + 150Mkm) = 190Mkm Focal length: f = 190Mkm - 150Mkm = 40Mkm Semi-minor axis: b = (a 2 - f 2 ) 1/2 = 186Mkm Calculations

14 Activity 5 Pathfinder Velocities at  and . 1. At  : r = 150 Mkm a = 190Mkm 1.6 X 10 10 (1/r - 1/2a) 1/2 … (MKS Units!)  v  = 32 km/sec = 72,000 mph 2. At  : r = 230Mkm a = 190Mkm  v  = 21 km/sec = 47,000 mph

15 Follow-Up Activities 1. Compare the Pathfinder velocity at  with earth’s orbital velocity at . What is the difference and why? (Express your answer in terms of total orbital energy.) 2. Compare the Pathfinder velocity at  with mars’ orbital velocity at . Again, what is the difference and why? (Express your answer in terms of total orbital energy.) 3. The earth has a radius of 6400 km and spins once on its axis in 24 hours. Calculate the velocity of a point at the equator in km/sec and mph.

16 4. When viewed from celestial north, the Earth both rotates and revolves counter- clockwise. Do the orbital and rotational velocities add or subtract at local midnight? How about at local noon? What considerations might affect the time of day for a launch? Why did NASA launch the Pathfinder spacecraft eastward? 5. In spacecraft design, energy is sometimes expressed in terms of change in velocity required to achieve orbit ( “delta- vee” or  v). Given what we’ve just done, what  v does the Pathfinder require at  ?

17 6. Actually, additional energy (velocity) is required for a spacecraft just to escape the Earth’s gravitational field. This velocity is given by the expression v Escape = (2GM Earth /r Earth ) 1/2. With M Earth = 6 X 10 24 kg, calculate this velocity in km/sec and mph. This velocity must be added to the  v calculated in Problem 5. How much, as a percent, does the result change compared to the value obtained in Problem 5? Does leaving the Earth’s gravity well cost a lot in fuel?

18 joseph.c.kolecki@grc.nasa.gov

Download ppt ". Mr. K. NASA/GRC/LTP Part 5 Pathfinder’s Path II."

Similar presentations

Objective Writing very large and very small numbers in standard form.

Objective Writing very large and very small numbers in standard form.
Newton’s Law of Universal Gravitation

Newton’s Law of Universal Gravitation
All of the planets in our solar system revolve around our sun. Today you will investigate the speeds at which they move around. Orbiting Our Sun.

All of the planets in our solar system revolve around our sun. Today you will investigate the speeds at which they move around. Orbiting Our Sun.
Chapter 8 Gravity.

Chapter 8 Gravity.
Rotational Motion and The Law of Gravity

Rotational Motion and The Law of Gravity
Gravity.

Gravity.
Physics 151: Lecture 28 Today’s Agenda

Physics 151: Lecture 28 Today’s Agenda
Other “planets” Dimensions of the Solar System 1 Astronomical Unit = 1 AU = distance between the Sun and Earth = ~150 million km or 93 million miles.

Other “planets” Dimensions of the Solar System 1 Astronomical Unit = 1 AU = distance between the Sun and Earth = ~150 million km or 93 million miles.
NJIT Physics 320: Astronomy and Astrophysics – Lecture II Carsten Denker Physics Department Center for Solar–Terrestrial Research.

NJIT Physics 320: Astronomy and Astrophysics – Lecture II Carsten Denker Physics Department Center for Solar–Terrestrial Research.
Chapter 13 Gravitation.

Chapter 13 Gravitation.
Gravitational Potential energy Mr. Burns

Gravitational Potential energy Mr. Burns
Formulas Finding the semi major axis. This is the average distance from the orbiting body Aphelion, perihelion refer to farthest distance, and closest.

Formulas Finding the semi major axis. This is the average distance from the orbiting body Aphelion, perihelion refer to farthest distance, and closest.
Circular Motion and Gravitation

Circular Motion and Gravitation
Welcome to the Neighborhood Our Solar System. What’s the difference between rotation and revolution? Each planet spins on its axis. Each planet spins.

Welcome to the Neighborhood Our Solar System. What’s the difference between rotation and revolution? Each planet spins on its axis. Each planet spins.
Newton and Kepler. Newton’s Law of Gravitation The Law of Gravity Isaac Newton deduced that two particles of masses m 1 and m 2, separated by a distance.

Newton and Kepler. Newton’s Law of Gravitation The Law of Gravity Isaac Newton deduced that two particles of masses m 1 and m 2, separated by a distance.
AE 1350 Lecture #14 Introduction to Astronautics.

AE 1350 Lecture #14 Introduction to Astronautics.
Monday, Nov. 25, 2002PHYS 1443-003, Fall 2002 Dr. Jaehoon Yu 1 PHYS 1443 – Section 003 Lecture #20 Monday, Nov. 25, 2002 Dr. Jaehoon Yu 1.Simple Harmonic.

Monday, Nov. 25, 2002PHYS , Fall 2002 Dr. Jaehoon Yu 1 PHYS 1443 – Section 003 Lecture #20 Monday, Nov. 25, 2002 Dr. Jaehoon Yu 1.Simple Harmonic.
Gravity & orbits. Isaac Newton (1642-1727) developed a mathematical model of Gravity which predicted the elliptical orbits proposed by Kepler Semi-major.

Gravity & orbits. Isaac Newton ( ) developed a mathematical model of Gravity which predicted the elliptical orbits proposed by Kepler Semi-major.
Planetary Dynamics § 13.4–13.8. Closed Orbits U g + K tr = constant < 0 The closer the satellite is to the main body, the faster it moves Objects do not.

Planetary Dynamics § 13.4–13.8. Closed Orbits U g + K tr = constant < 0 The closer the satellite is to the main body, the faster it moves Objects do not.
Rotational Motion and The Law of Gravity 1. Pure Rotational Motion A rigid body moves in pure rotation if every point of the body moves in a circular.

Rotational Motion and The Law of Gravity 1. Pure Rotational Motion A rigid body moves in pure rotation if every point of the body moves in a circular.

Similar presentations

Ads by Google