Ballistic Missiles and Getting Into Orbit

1. Ballistic Missiles and Getting Into Orbit

2. Ballistic Missiles and Getting Into Orbit • Intercontinental Ballistic Missiles (ICBMs) • Understanding Ballistic Missiles and Trajectories • Conic Sections • ICBM Trajectories • ICBM Development • The Anti-Ballistic Missile Treaty • Launch Windows and Times • Getting Into Orbit • Launch Windows • Launch Time Unit 2, Chapter 7, Lesson 7: Ballistic Missiles and Getting into Orbit

3. Understanding Ballistic Missiles and Trajectories • Not all spacecraft launched into space stay there. • Ballistic missiles only travel through space. Unit 2, Chapter 7, Lesson 7: Ballistic Missiles and Getting into Orbit SECTION 7.1

4. Conic Sections • All objects moving under the influence of gravity must follow paths that form conic sections. • Circles, ellipses, parabolas and hyperbolas are all conic sections because they are all ‘slices’ of a cone. • Parabolas and hyperbolas are useful only for interplanetary motion. • Circular and elliptical paths are for near Earth work. Unit 2, Chapter 7, Lesson 7: Ballistic Missiles and Getting into Orbit

5. Conic SectionsBallistic Trajectories The shape of a Ballistic Trajectory is an ellipse that intersects the Earth at two points Unit 2, Chapter 7, Lesson 7: Ballistic Missiles and Getting into Orbit

6. ICBM Trajectories • Ballistics: • Science dealing with motion, behavior, and effects of projectiles—especially bullets, bombs, rockets, and missiles. • Science or art of designing and hurling projectiles to achieve a desired effect. Unit 2, Chapter 7, Lesson 7: Ballistic Missiles and Getting into Orbit

7. ICBM Trajectories (cont’d) • Ballistic trajectories • Paths followed by non-thrusting objects • Objects moving under the influence of gravity • Most of the trajectory is outside Earth’s atmosphere (ignore all other forces except for gravity). Unit 2, Chapter 7, Lesson 7: Ballistic Missiles and Getting into Orbit

8. ICBM Trajectories (cont’d)Trajectory Example • As the man in the figure tries to squirt the dog, he has three basic options similar to the options with ballistic trajectories of rockets: • He can squirt the stream of water directly at the dog (low trajectory). • Aim the stream of water at a 45 degree angle (maximum range or accuracy). • Or, squirt the stream high into the air (high trajectory). Unit 2, Chapter 7, Lesson 7: Ballistic Missiles and Getting into Orbit

9. ICBM Trajectories (cont’d)Ballistic Trajectories • Define ballistic trajectories by: • Rocket’s position (radius from the Earth’s center) at burnout • Rocket’s velocity at burnout • Flight-path angle at burnout • Direction of flight at burnout • Latitude at burnout • Longitude at burnout • Shape of ballistic trajectory: ellipse intersecting Earth’s surface at launch and impact Unit 2, Chapter 7, Lesson 7: Ballistic Missiles and Getting into Orbit

10. ICBM Development • ICBMs are long-range missiles using a ballistic trajectory. • ICBMs differ little technically from other ballistic missiles. • Ballistic trajectories have focused on being able to throw things farther and faster. Unit 2, Chapter 7, Lesson 7: Ballistic Missiles and Getting into Orbit

11. ICBM Development (cont’d) • V2 was first real intermediate range ballistic missile. • After the war, U.S. and USSR began race to develop ICBMs. • Key players in global space program also took part in developing ICBMs. Unit 2, Chapter 7, Lesson 7: Ballistic Missiles and Getting into Orbit

12. ICBM DevelopmentModern ICBMs and MIRVs • Modern ICBMs typically deliver multiple independently targetable re-entry vehicles (MIRVs). • Each Re-entry Vehicle (RV) carries a nuclear-weapon warhead. • Allows a single missile launch to strike a handful of targets. • Proved to be an “easy answer” to deploying anti-ballistic missile (ABM) systems: adding more warheads to a missile costs less than building the missiles to shoot down the additional warheads. Unit 2, Chapter 7, Lesson 7: Ballistic Missiles and Getting into Orbit

13. ICBM DevelopmentMinuteman • Minuteman I and II were U.S. ICBMs in service from 1960 to 1997. • Minuteman III entered service in 1978. • Minuteman had two innovations that gave it a long practical service life. • Solid-rocket fuel technology. • Earliest use of integrated circuit for digital flight computer. Unit 2, Chapter 7, Lesson 7: Ballistic Missiles and Getting into Orbit

14. ICBM DevelopmentMinuteman (cont’d) Unit 2, Chapter 7, Lesson 7: Ballistic Missiles and Getting into Orbit

15. ICBM DevelopmentMinuteman (cont’d) Early trajectory of a Minuteman Missile shown on it’s way to a test range Unit 2, Chapter 7, Lesson 7: Ballistic Missiles and Getting into Orbit

16. ICBM DevelopmentPeacekeeper • First deployed in 1986. • Canceled, modified, and reinstated over several administrations. • U.S. had to remove it from service to meet SALT II treaty. Unit 2, Chapter 7, Lesson 7: Ballistic Missiles and Getting into Orbit

17. ICBM DevelopmentPeacekeeper (cont’d) Unit 2, Chapter 7, Lesson 7: Ballistic Missiles and Getting into Orbit

18. ICBM DevelopmentICBM Missile Silos Unit 2, Chapter 7, Lesson 7: Ballistic Missiles and Getting into Orbit

19. The Anti-Ballistic Missile Treaty • Between U.S. and USSR to limit use of anti-ballistic missile systems in defending against missile attack. • Only two nuclear powers—kept both from believing they could avoid a counter-strike. • In force for 30 years from 1972-2002. • U.S. withdrew from treaty in 2002. Unit 2, Chapter 7, Lesson 7: Ballistic Missiles and Getting into Orbit

20. ABM Treaty (cont’d)Arguments for Withdrawal • Allow U.S. to develop a ballistic missile-defense system to protect against rogue nations developing weapons. Unit 2, Chapter 7, Lesson 7: Ballistic Missiles and Getting into Orbit

21. ABM Treaty (cont’d)Arguments against Withdrawal • “Fatal blow” to the Nuclear Non-Proliferation Treaty. • Would lead to a world without effective legal limits on nuclear growth. • Reaction from Russia and China would hinder other arms negotiations (but offsetting pluses have made that reaction milder than expected). Unit 2, Chapter 7, Lesson 7: Ballistic Missiles and Getting into Orbit

22. Launch Windows and Times Above: September 1997—The Shuttle Endeavour waits for launch time. Left: April 1998—The Columbia Shuttle propels off the launch pad and accelerates into orbit. Unit 2, Chapter 7, Lesson 7: Ballistic Missiles and Getting into Orbit SECTION 7.2

23. Getting into Orbit • To meet the conditions of a space mission, launch-team members need to: • Launch the spacecraft from a specific place. • Launch the spacecraft at a specific time. • Launch the spacecraft in a specific direction. Unit 2, Chapter 7, Lesson 7: Ballistic Missiles and Getting into Orbit

24. Launch WindowsDefinition • An opportunity to launch a satellite from Earth directly into the desired orbit from a given launch site. Unit 2, Chapter 7, Lesson 7: Ballistic Missiles and Getting into Orbit

25. Launch WindowsConcept • A launch window is an opportunity to launch a satellite from Earth directly into the desired orbit from a given launch site. • We can always launch into parking orbit and then perform a Hohmann Transfer to put a spacecraft in the desired orbit, but this is complicated and requires more fuel. • A launch window means getting directly into the desired orbit without having to maneuver. Unit 2, Chapter 7, Lesson 7: Ballistic Missiles and Getting into Orbit

26. Launch WindowsConcept (cont’d) • Launch windows are like bus schedules. • Launch windows normally cover a period of time. • Launch vehicles must follow trajectory rules by Newton’s Laws of Motion. Unit 2, Chapter 7, Lesson 7: Ballistic Missiles and Getting into Orbit

27. Launch Windows and Launch Time Columbia accelerates into orbit on STS-87 Endeavour clears the tower on STS-47 Unit 2, Chapter 7, Lesson 7: Ballistic Missiles and Getting into Orbit

28. Launch Time • To determine what time a launch site passes into a launch window, we need a new definition of how to tell time. Unit 2, Chapter 7, Lesson 7: Ballistic Missiles and Getting into Orbit

29. Orbital Racetrack • If the car is one mile past the starting line, and the pit is one-half mile past the starting line, then the car must be one-half mile from the pit. • Given the car’s speed, we can figure out how long before the car reaches the pit. • Knowing this rate allows us to determine the best time to launch a spacecraft directly into orbit, or the launch window. Unit 2, Chapter 7, Lesson 7: Ballistic Missiles and Getting into Orbit

30. Launch TimeSolar Time • The spacecraft must launch in a specific direction: • The vernal equinox direction is the main direction we use to describe the motion of spacecraft that orbit the Earth. • Because the Earth and the launch site rotate, it’s an easy reference from which to measure the angular distance between the orbital plane and our launch site. • Knowing this angular distance and Earth’s rotation rate, we can figure out the best times to launch. Unit 2, Chapter 7, Lesson 7: Ballistic Missiles and Getting into Orbit

31. Launch TimeSolar Time (cont’d) • Greenwich Mean Time (GMT)— is the basis for the time kept on watches to handle daily business. • GMT is the mean solar time for the Prime Meridian (Greenwich, UK). • All other time zones are GMT plus or minus a certain number of hours. Unit 2, Chapter 7, Lesson 7: Ballistic Missiles and Getting into Orbit

32. Launch TimeSolar Time (cont’d) The Royal Observatory in Greenwich, England Unit 2, Chapter 7, Lesson 7: Ballistic Missiles and Getting into Orbit

33. Launch TimeSolar Time • Apparent Solar Day • An Apparent Solar Day is the time between successive passages of the Sun overhead, which is from noon one day to noon the next day. • Apparent solar day’s length varies throughout the year (Earth’s orbit around the Sun is elliptical). • Average of the lengths for one year gives us a mean solar day. Unit 2, Chapter 7, Lesson 7: Ballistic Missiles and Getting into Orbit

34. Launch TimeSidereal Time • Because there is a problem using solar time, the reference point for GMT rotates with the Earth, we seek an inertial (fixed) reference point: • We use the same reference point as the geocentric-equatorial coordinate frame—vernal equinox direction. • A sidereal day is the time between the subsequent passings of the vernal equinox direction overhead a particular longitude line. Unit 2, Chapter 7, Lesson 7: Ballistic Missiles and Getting into Orbit

35. Launch TimeSidereal Time (cont’d) • Because the inertial reference vernal equinox is so far away, the length of a sidereal day corresponds to exactly 360° of Earth rotation. • A sidereal day is slightly shorter than an apparent solar day: 23 hours, 56 minutes, 4 seconds in solar time. Unit 2, Chapter 7, Lesson 7: Ballistic Missiles and Getting into Orbit

36. Launch TimeSidereal Time (cont’d) • We can tell sidereal time in degrees. • Earth rotates 360° in 24 hours. • So, 3 a.m. (0300) is 45° of Earth’s full rotation. • Similarly, noon (1200) is 180° and 6 p.m. (1800) is 270°. Unit 2, Chapter 7, Lesson 7: Ballistic Missiles and Getting into Orbit

37. Launch TimeLocal Sidereal Time (LST) • Time since the first point of constellation Aries was last overhead. • Can be expressed in time or angle • If Earth has rotated 90° since the local longitude line was aligned with the vernal equinox direction, LST is: • 90° • 0600 hrs • Mission planners mathematically convert LST back to GMT for launch timing. Unit 2, Chapter 7, Lesson 7: Ballistic Missiles and Getting into Orbit

38. Launch TimeLocal Sidereal Time (LST) Unit 2, Chapter 7, Lesson 7: Ballistic Missiles and Getting into Orbit

39. Launch TimeSolar Time versus Sidereal Time Unit 2, Chapter 7, Lesson 7: Ballistic Missiles and Getting into Orbit

40. Summary • Intercontinental Ballistic Missiles (ICBMs) • Understanding Ballistic Missiles and Trajectories • Conic Sections • ICBM Trajectories • ICBM Development • The Anti-Ballistic Missile Treaty • Launch Windows and Times • Getting into Orbit • Launch Windows • Launch Time Unit 2, Chapter 7, Lesson 7: Ballistic Missiles and Getting into Orbit

41. Next • For some payloads, the mission requires us to get a payload into orbit and get it back to Earth from space. • On the next lesson we’ll tackle the last part of a space journey: atmospheric re-entry. Unit 2, Chapter 7, Lesson 7: Ballistic Missiles and Getting into Orbit