SPACE FLIGHT SOLAR SYSTEM AND INTERSTELLAR

1. SPACE FLIGHTSOLAR SYSTEM AND INTERSTELLAR George Lebo 26 November 2012 AST 2037

2. ROBERT GODDARD, 1926

3. ROCKET SCIENTISTS AT THE ARMY BALLISTIC MISSILE AGENCY, 1956 FROM LEFT TO RIGHT, ERNST STUHLINGER, MAJOR GENERAL HOLGER TOFTOY, HERMANN OBERTH, Dr. WERNER VON BRAUN, Dr. ROBERT LUSSER

6. PROPOSED SLS – MAY 2011

11. Details of Apollo 11 Mission • The Apollo 11 spacecraft was launched from Cape Kennedy at 13:32:00 UT on July 16, 1969. After 2 hr and 33 min in Earth orbit, the S-IVB engine was reignited for acceleration of the spacecraft to the velocity required for Earth gravity escape. • Lunar-orbit insertion began at 75:50 ground elapsed time (GET). The spacecraft was placed in an elliptical orbit (61 by 169 nautical miles), inclined 1.25 degrees to the lunar equatorial plane. At 80:12 GET, the service module propulsion system was reignited, and the orbit was made nearly circular (66 by 54 nautical miles) above the surface of the Moon. Each orbit took two hours. Photographs taken from lunar orbit provided broad views for the study of regional lunar geology.

12. Apollo Cont’d (2) • The lunar module (LM), with Astronauts Armstrong and Aldrin aboard, was undocked from the command-service module (CSM) at 100:14 GET, following a thorough check of all the LM systems. At 101:36 GET, the LM descent engine was fired for approximately 29 seconds, and the descent to the lunar surface began. At 102:33 GET, the LM descent engine was started for the last time and burned until touchdown on the lunar surface. Eagle landed on the Moon 102 hr, 45 min and 40 sec after launch. • Immediately after landing on the Moon, Armstrong and Aldrin prepared the LM for liftoff as a contingency measure. Following the meal, a scheduled sleep period was postponed at the astronauts' request, and the astronauts began preparations for descent to the lunar surface.

13. Apollo 11 Cont’d (3) • Astronaut Armstrong emerged from the spacecraft first. While descending, he released the Modularized Equipment Stowage Assembly (MESA) on which the surface television camera was stowed, and the camera recorded humankind's first step on the Moon at 109:24:19 GET (pictured at left). A sample of lunar surface material was collected and stowed to assure that, if a contingency required an early end to the planned surface activities, samples of lunar surface material would be returned to Earth. Astronaut Aldrin subsequently descended to the lunar surface.

14. Armstrong – First Step on the Moon

15. Apollo 11 Cont’d (4) • The astronauts carried out the planned sequence of activities that included deployment of a Solar Wind Composition (SWC) experiment, collection of a larger sample of lunar material, panoramic photographs of the region near the landing site and the lunar horizon, closeup photographs of in place lunar surface material, deployment of a Laser-Ranging Retroreflector (LRRR) and a Passive Seismic Experiment Package (PSEP), and collection of two core-tube samples of the lunar surface.

16. Apollo 11 Cont’d (5) Approximately two and a quarter hours after descending to the surface, the astronauts began preparations to re-enter the LM, after which the astronauts slept. The ascent from the lunar surface began at 124:22 GET, 21 hours and 36 minutes after the lunar landing. In transearth coast only one of four planned midcourse corrections was required. The CM entered the atmosphere of the Earth with a velocity of 36,194 feet per second (~ mach 33) and landed in the Pacific Ocean.

17. URL – APOLLO 11 MISSION • http://www.nasm.si.edu/exhibitions/attm/flightpath/a11.steps.html

18. INTERSTELLAR TRAVEL • QUESTION: Shouldn’t we expect to conquer inter-stellar travel problems, given our past successes? A. Compare air-flight problems of the 19th century to space travel problems now. B. Fundamental limitations of interstellar travel 1. Spacecraft size a. Human habitat b. Fuel (Remember that we’ll need to undo all of the acceleration that we create.) 2. Elapsed time of mission 3. High velocity flight