Saturn V Instrument Unit

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Diagram of Saturn V Instrument Unit.

The Saturn V Instrument Unit is a ring-shaped structure fitted to the top of the Saturn V rocket's third stage (S-IVB) and the Saturn IB's second stage (also an S-IVB). It was immediately below the SLA (Spacecraft/Lunar Module Adapter) panels that contained the Lunar Module. The Instrument Unit contains the guidance system for the Saturn V rocket. Some of the electronics contained within the Instrument Unit are a digital computer, analog flight control computer, emergency detection system, inertial guidance platform, control accelerometers and control rate gyros. The instrument unit (IU) for Saturn V was designed by NASA at Marshall Space Flight Center (MSFC) and was developed from the Saturn I IU.[1] NASA's contractor to construct the Saturn V Instrument Unit was International Business Machines (IBM).[2]

One of the unused Instrument Units is currently on display at the Steven F. Udvar-Hazy Center in Chantilly, Virginia. The plaque for the Unit has the following inscription[citation needed]:

The Saturn V rocket, which sent astronauts to the Moon, used inertial guidance, a self-contained system that guided the rocket's trajectory. The rocket booster had a guidance system separate from those on the command and lunar modules. It was contained in an instrument unit like this one, a ring located between the rocket's third stage and the command and lunar modules. The ring contained the basic guidance system components—a stable platform, accelerometers, a digital computer, and control electronics—as well as radar, telemetry, and other units.

The instrument unit's stable platform was based on an experimental unit for the German V-2 rocket of World War II. The Bendix Corporation produced the platform, while IBM designed and built the unit's digital computer.

View of IU-514 from the floor of UHC
Instrument Unit No. 514 at National Air & Space Museum, Udvar-Hazy Center, Dulles, Virginia; the nose of Space Shuttle Enterprise is visible at left.

Instrument Unit specifications

  • Diameter: 260 inches (6.6 m)
  • Height: 36 inches (914 mm)
  • Weight at launch: ~4,400 lb (1996 kg)

Mission history

There was no Instrument Unit for Saturn I Block I boosters (SA-1 to SA-4). Guidance and control equipment was carried in canisters on top of the S-I first stage, and included the ST-90 stabilized platform, made by Ford Instrument Company and used in the jupiter missile.[3]

The IU made its debut with SA-5, the first Saturn I Block II launch. The first version of the IU was 154 inches (3,900 mm) in diameter and 58 inches (1,500 mm) high, and was both designed and built by MSFC. Guidance, telemetry, tracking and power components were contained in four pressurized, cylindrical containers attached like spokes to a central hub.[4]

MSFC flew version 2 of the IU on SA-8, 9 and 10. Version 2 was the same diameter as version 1, but only 34 inches (860 mm) high. Instead of pressurized containers, the components were hung on the inside of the cylindrical wall, achieving a reduction in weight.[5]

The last version, number 3, was 260 inches (6,600 mm) in diameter and 36 inches (910 mm) tall. It was designed by MSFC but manufactured by IBM in their factory at Huntsville, and flew on all Saturn IB and Saturn V launches. This is the version that is on display in Washington, Huntsville, Houston, and the Apollo/Saturn V Center.

Saturn Launch History[6]
PROGRAM VEHICLE MISSION LAUNCH DATE PAD IU VERSION
Saturn I SA-1 SA-1 27-Oct-61 34 -
Saturn I SA-2 SA-2 25-Apr-62 34 -
Saturn I SA-3 SA-3 16-Nov-62 34 -
Saturn I SA-4 SA-4 28-Mar-63 34 -
Saturn I SA-5 SA-5 29-Jan-64 37B 1
Saturn I SA-6 A-101 28-May-64 37B 1
Saturn I SA-7 A-102 18-Sep-64 37B 1
Saturn I SA-9 A-103 16-Feb-65 37B 2
Saturn I SA-8 A-104 25-May-65 37B 2
Saturn I SA-10 A-105 30-Jul-65 37B 2
Saturn IB SA-201 AS-201 26-Feb-66 34 3
Saturn IB SA-203 AS-203 5-Jul-66 37B 3
Saturn IB SA-202 AS-202 25-Aug-66 34 3
Saturn V SA-501 Apollo 4 9-Nov-67 39A 3
Saturn IB SA-204 Apollo 5 22-Jan-68 37B 3
Saturn V SA-502 Apollo 6 4-Apr-68 39A 3
Saturn IB SA-205 Apollo 7 11-Oct-68 34 3
Saturn V SA-503 Apollo 8 21-Dec-68 39A 3
Saturn V SA-504 Apollo 9 3-Mar-69 39A 3
Saturn V SA-505 Apollo 10 18-May-69 39B 3
Saturn V SA-506 Apollo 11 16-Jul-69 39A 3
Saturn V SA-507 Apollo 12 14-Nov-69 39A 3
Saturn V SA-508 Apollo 13 11-Apr-70 39A 3
Saturn V SA-509 Apollo 14 31-Jan-71 39A 3
Saturn V SA-510 Apollo 15 26-Jul-71 39A 3
Saturn V SA-511 Apollo 16 16-Apr-72 39A 3
Saturn V SA-512 Apollo 17 7-Dec-72 39A 3
Saturn V SA-513 Skylab 1 14-May-73 39A 3
Saturn IB SA-206 Skylab 2 25-May-73 39B 3
Saturn IB SA-207 Skylab 3 28-Jul-73 39B 3
Saturn IB SA-208 Skylab 4 16-Nov-73 39B 3
Saturn IB SA-210 ASTP 15-Jul-75 39B 3

Mission profile

Saturn Apollo flight profiles varied considerably by mission.[7][8][9] All missions began, however, with liftoff under power of the first stage. To more smoothly control engine ignition, thrust buildup and liftoff of the vehicle, restraining arms provided support and hold down at four points around the base of the S-IC stage. A gradual controlled release was accomplished during the first six inches of vertical motion.

After clearing the launch tower, a flight program stored in the launch vehicle digital computer (LVDC) commanded a roll of the vehicle to orient it so that the subsequent pitch maneuver pointed the vehicle in the desired azimuth. The roll and pitch commands were controlled by the stored program, and were not affected by navigation measurements. Until the end of the S-IC burn, guidance commands were functions only of time.

First stage cutoff and stage separation were commanded when the IU received a signal that the tank's fuel level had reached a predetermined point. Guidance during the second and third stage burns depended both on time and navigation measurements, in order to achieve the target orbit using the minimum fuel.

Second stage engine cutoff was commanded by the IU at a pre-determined fuel level, and the stage was separated. By this time, the vehicle had reached its approximate orbital altitude, and the third stage burn was just long enough to reach a circular parking orbit.

During manned Apollo missions, the vehicle coasted in Earth orbit for 2-4 passes as the crew performed checks of systems status and other tasks, and as ground stations tracked the vehicle. During the hour and a half after launch, tracking stations around the world had refined estimates of the vehicle's position and velocity, collectively known as its state vector. The latest estimates were relayed to the guidance systems in the IU, and to the Command Module Computer in the spacecraft. When the Moon, Earth, and vehicle were in the optimum geometrical configuration, the third stage was reignited to put the vehicle into a translunar orbit. For Apollo 15, for example, this burn lasted 5 minutes 55 seconds.

After translunar injection came the maneuver called transposition, docking, and extraction. This was under crew control, but the IU held the S-IVB/IU vehicle steady while the Command/Service Module (CSM) first separated from the vehicle, rotated 180 degrees, and returned to dock with the Lunar Module (LM). When the CSM and LM had "hard docked" (connected by a dozen latches), the rearranged spacecraft separated from the S-IVB/IU.

The last function of the IU was to command the very small maneuver necessary to keep the S-IVB/IU out of the way of the spacecraft. On some missions the S-IVB/IU went into high Earth or Solar orbit, while on others it was crashed into the Moon; seismometers were left on the Moon during Apollo 11, 12, 14, 15, and 16, and the S-IVB/IUs of Apollo 13, 14, 15, 16, and 17 were directed to crash. These impacts provided impulses that were recorded by the seismometer network to yield information about the geological structure of the Moon.

Subsystems

Interior of IU-514, with components labeled
Diagram of exterior of IU-514

The IU consists of six subsystems: structure, guidance and control, environmental control, emergency detection, radio communications (for telemetry, tracking, and command), and power.

Structure

The basic IU structure is a short cylinder, 36 inches high and 260 inches (6,600 mm) in diameter, fabricated of an aluminum alloy honeycomb sandwich material 0.95 inches (24 mm) thick. The cylinder is manufactured in three 120-degree segments, which are joined by splice plates into an integral structure. The top and bottom edges are made from extruded aluminum channels bonded to the honeycomb sandwich. This type of construction was selected for its high strength to weight ratio, acoustical insulation, and thermal conductivity properties. The IU supported the components mounted on its inner wall and the weight of the Apollo spacecraft above (the Lunar Module, the Command Module, the Service Module, and the Launch Escape Tower). To facilitate handling the IU before it was assembled into the Saturn, the fore and aft protective rings, 6 inches tall and painted blue, were bolted to the top and bottom channels. These were removed in the course of stacking the IU into the Saturn vehicle.

The IU is divided into 24 locations, which are marked on the interior by numbers 1-24 on the aluminum surface just above the blue flange.

Guidance and control

The Saturn V launch vehicle was guided by navigation, guidance, and control equipment located in the IU. A space stabilized platform (the ST-124-M3 inertial platform at location 21) measured acceleration and attitude. A launch vehicle digital computer (LVDC at location 19) solved guidance equations, and an analog flight control computer (location 16) issued commands to steer the vehicle.

The attitude of the vehicle was defined in terms of three axes:

  • The roll axis (X) runs from tail to nose and was vertical at time of launch.
  • The pitch axis (Y) is at right angles to the roll axis, and is marked on the exterior of the IU by +Y above the viewport, outside location 21.
  • The yaw axis (Z) is at right angles to both the pitch and roll axis, and is marked by +Z outside location 3.[10]

The ST-124-M3 inertial platform contains three gimbals: the outer gimbal (which can rotate 360° about the roll or X axis of the vehicle), the middle gimbal (which can rotate ±45° about the yaw or Z axis of the vehicle), and the inner or inertial gimbal (which can rotate 360° about the pitch or Y axis of the vehicle). The inner gimbal is a platform to which are fixed several components:

  • Two vertical alignment pendulums sent signals before launch to ground support equipment, which generated signals to the platform gyro torque generators to level the inner gimbal. The vertical alignment system levelled the platform to an accuracy of ±2.5 arc seconds.
  • Two prisms, one fixed and one servo-driven, were used with an external theodolite which sighted through the viewport outside location 21 to set the azimuth of the inner gimbal before launch. The azimuth could be set to an accuracy of ±5 arc seconds.
  • Three single-degree-of-freedom gyroscopes have their input axes aligned along an orthogonal inertial coordinate system. Three signal generators, fixed to the output axis of each gyro, generated electrical signals proportional to the torque disturbances. The signals were transmitted through the servo electronics which terminated in the gimbal pivot servotorque motors. The servoloops maintained the inner gimbal rotationally fixed in inertial space. That is, while the vehicle rolled, pitched, and yawed, the inner gimbal remained in the same attitude to which it was set just before launch. Though it was being translated during the launch and orbit process, it was rotationally fixed.
  • Three integrating accelerometers measured the three components of velocity resulting from vehicle propulsion. The accelerometer measurements were sent through the launch vehicle data adapter (LDVA at location 19) to the LVDC. In the LVDC the accelerometer measurements were combined with the computed gravitational acceleration to obtain velocity and position of the vehicle.

The angular positions of gimbals on their axes were measured by resolvers, which sent their signals to the LVDA. The LVDA was the input/output device for the LVDC. It performed the necessary processing of signals to make these signals acceptable to the LVDC.

The instantaneous attitude of the vehicle was compared with the desired vehicle attitude in the LVDC. Attitude correction signals from the LVDC were converted into control commands by the flight control computer. The required thrust direction was obtained by gimbaling the engines in the propelling stage to change the thrust direction of the vehicle. Gimbaling of these engines was accomplished through hydraulic actuators. In the first and second stages (S-IC and S-II), the four outboard engines were gimbaled to control roll, pitch, and yaw. Since the third (S-IVB) stage has only one engine, an auxiliary propulsion system was used for roll control during powered flight. The auxiliary propulsion system provides complete attitude control during coast flight of the S-IUB/IU stage.

Environmental control

The environmental control system (ECS) maintains an acceptable operating environment for the IU equipment during preflight and flight operations. The ECS is composed of the following:

  • The thermal conditioning system (TCS), which maintains a circulating coolant temperature to the electronic equipment of 59° ± 1 °F (15 ± 5/9 °C).
  • Preflight purging system, which maintains a supply of temperature- and pressure-regulated mixture of air and gaseous nitrogen (air/GN2) in the IU/S-IVB equipment area.
  • Gas bearing supply system, which furnishes GN2 to the ST-124-M3 inertial platform gas bearings.
  • Hazardous gas detection sampling equipment which monitors the IU/S-IVB forward interstage area for the presence of hazardous vapors

Thermal conditioning

Thermal conditioning panels, also called cold plates, were located in both the IU and S-IVB stage (up to sixteen in each stage). Each cold plate contains tapped bolt holes in a grid pattern which provides flexibility of component mounting.

The cooling fluid circulated through the TCS was a mixture of 60 percent methanol and 40 percent demineralized water by weight. Each cold plate was capable of dissipating at least 420 watts.

During flight, heat generated by equipment mounted on the cold plates was dissipated to space by a sublimation heat exchanger. Water from a reservoir (water accumulator) was exposed to the low temperature and pressure environment of space, where it first freezes and then sublimates, taking heat from the heat exchanger and transferring it to the water molecules which escape to space in gaseous state. Water/methanol was cooled by circulation through the heat exchanger.

Preflight air/GN2 purge system

Before flight, ground support equipment (GSE) supplies cooled, filtered ventilating air to the IU, entering via the large duct in the middle of the umbilical panel (location 7), and branching into two ducts at the top that are carried around the IU in the cable rack. Downward pointing vents from these ducts release ventilating air to the interior of the IU. During fueling, gaseous nitrogen was supplied instead of air, to purge any propellant gases that might otherwise accumulate in the IU.

Gas bearing supply

To reduce errors in sensing attitude and velocity, designers cut friction to a minimum in the platform gyros and accelerometers by floating the bearings on a thin film of dry nitrogen. The nitrogen was supplied from a sphere holding 2 cu ft (56.6 l) of gas at 3,000 psig (pounds per square inch gauge, i.e. psi above one atmosphere) (20,7 MPa). This sphere is 21 inches (0,53 m) in diameter and is mounted at location 22, to the left of the ST-124-M3. Gas from the supply sphere passes through a filter, a pressure regulator, and a heat exchanger before flowing through the bearings in the stable platform.

Hazardous gas detection

The hazardous gas detection system monitors the presence of hazardous gases in the IU and S-IVB stage forward compartments during vehicle fueling. Gas was sampled at four locations: between panels 1 and 2, 7 and 8, 13 and 14, and 19 and 20. Tubes lead from these locations to location 7, where they were connected to ground support equipment (external to the IU) which can detect hazardous gases.

Emergency detection

The emergency detection system (EDS) sensed initial development of conditions in the flight vehicle during the boost phases of flight which could cause vehicle failure. The EDS reacted to these emergency situations in one of two ways. If breakup of the vehicle were imminent, an automatic abort sequence would be initiated. If, however, the emergency condition were developing slowly enough or were of such a nature that the flight crew can evaluate it and take action, only visual indications were provided to the flight crew. Once an abort sequence had been initiated, either automatically or manually, it was irrevocable and ran to completion.

The EDS was distributed throughout the vehicle and includes some components in the IU. There were nine EDS rate gyros installed at location 15 in the IU. Three gyros monitored each of the three axes (pitch, roll and yaw), providing triple redundancy. The control signal processor (location 15) provided power to and received inputs from the nine EDS rate gyros. These inputs were processed and sent to the EDS distributor (location 14) and to the flight control computer (location 16). The EDS distributor served as a junction box and switching device to furnish the spacecraft display panels with emergency signals if emergency conditions existed. It also contained relay and diode logic for the automatic abort sequence. An electronic timer (location 17) was activated at liftoff and 30 seconds later energized relays in the EDS distributor which allowed multiple engine shutdown. This function was inhibited during the first 30 seconds of launch, to preclude the vehicle falling back into the launch area. While the automatic abort was inhibited, the flight crew can initiate a manual abort if an angular-overrate or two-engine-out condition arose.

Radio communications

The IU communicated by radio continually to ground for several purposes. The measurement and telemetry system communicated data about internal processes and conditions on the Saturn V. The tracking system communicated data used by the Mission Ground Station (MGS) to determine vehicle location. The radio command system allowed the MGS to send commands up to the IU.

Measuring and telemetry

Approximately 200 parameters were measured on the IU and transmitted to the ground, in order to

  • Assist in the checkout of the launch vehicle prior to launch,
  • Determine vehicle condition and to verify received commands during flight, and
  • Facilitate postflight analysis of the mission.

Parameters measured include acceleration, angular velocity, flow rate, position, pressure, temperature, voltage, current, frequency, and others. Sensor signals were conditioned by amplifiers or converters located in measuring racks. There are four measuring racks in the IU at locations 1, 9, and 15 and twenty signal conditioning modules in each.[clarification needed] Conditioned signals were routed to their assigned telemetry channel by the measuring distributor at location 10. There were two telemetry links. In order for the two IU telemetry links to handle approximately 200 separate measurements, these links must be shared. Both frequency sharing and time sharing multiplexing techniques were used to accomplish this. The two modulation techniques used were pulse code modulation/frequency modulation (PCM/FM) and frequency modulation/frequency modulation (FM/FM).

Two Model 270 time sharing multiplexers (MUX-270) were used in the IU telemetry system, mounted at locations 9 and 10. Each one operates as a 30×120 multiplexer (30 primary channels, each sampled 120 times per second) with provisions for submultiplexing individual primary channels to form 10 subchannels each sampled at 12 times per second. Outputs from the MUX-270 go to the PCM/DDAS assembly model 301 at location 12, which in turn drives the 245.3 MHz PCM VHF transmitter.

The FM/FM signals were carried in 28 subcarrier channels and transmitted by a 250.7 MHz FM transmitter.

Both the FM/FM and the PCM/FM channels were coupled to the two telemetry antennas on opposite sides of the IU outside locations 10 and 22.

Tracking

C-band radar transponders carried by the IU provided tracking data to the ground which were used to determine the vehicle's trajectory. The transponder received coded or single pulse interrogation from ground stations and transmitted a single-pulse reply in the same frequency band (5.4 to 5.9 GHz). A common antenna was used for receiving and transmitting, The C-band transponder antennas are outside locations 11 and 23, immediately below CCS PCM omni receive antennas.

Radio command

The command communications system (CCS) provided for digital data transmission from ground stations to the LVDC. This communications link was used to update guidance information or command certain other functions through the LVDC. Command data originated in the Mission Control Center, Houston, and was sent to remote stations for transmission to the launch vehicle. Command messages were transmitted from the ground at 2101.8 MHz. The received message was passed to the command decoder (location 18), where it was checked for authenticity before being passed to the LVDC. Verification of message receipt was accomplished through the IU PCM telemetry system. The CCS system used five antennas:

  • A single directional antenna outside location 3-4,
  • Two omni transmit antennas outside locations 11 and 23, and
  • Two omni receive antennas outside locations 12 and 24.

Power

Power during flight originated with four silver-zinc batteries with a nominal voltage of 28±2 vdc. Battery D10 sat on a shelf at location 5, batteries D30 and D40 were on shelves in location 4, and battery D20 was at location 24. Two power supplies converted the unregulated battery power to regulated 56 vdc and 5 vdc. The 56 vdc power supply was at location 1 and provided power to the ST-124-M3 platform electronic assembly and the accelerometer signal conditioner. The 5 vdc power supply at location 12 provided 5 ±.005 vdc to the IU measuring system.

Gallery

These images show the development of the IU. The first four Saturn launches did not have an IU, but used guidance, telemetry and other equipment installed on top of the first stage.

The first IU flew on the fifth Saturn launch, SA-5, and was 12 feet 10 inches (3.91 m) in diameter and 4 feet 10 inches (1.47 m) high. The components it carried were in pressurized containers. This version flew on SA-5, SA-6 and SA-7. The IU carried by missions SA-8, -9, and -10 was only 2 feet 10 inches (0.86 m) high, and was not pressurized.[11]

With the Saturn IB and Saturn V launches, a third version was used, 21.6 feet (6.6 m) in diameter and 3 feet (0.91 m) high. Comparison of these photographs of the Instrument Unit shows that the configuration of components carried by this version changed, depending on the mission. Some equipment was deleted (e.g. the Azusa tracking system was deleted from later IUs), some equipment was added (e.g. a fourth battery for longer missions), and other components were moved around.

These images also show that some components (e.g. batteries, the ST-124 inertial platform) were installed in the IU after it had been stacked in the VAB on top of the S-IVB third stage.

References

Saturn

  • Bilstein, Roger E. (1980). Stages to Saturn: A Technological History of the Apollo/Saturn Launch Vehicles. NASA SP-4206. ISBN 0-16-048909-1. Available on-line: HTML or PDF
  • David S. Akens. ‘’Saturn Illustrated Chronology. Saturn's First Eleven Years: April 1957 through April 1968’’. NASA - Marshall Space Flight Center, MHR-5, 20 Jan 1971. Available online: HTML
  • "Saturn I Summary." An 43-page popular account of the Saturn I program, dated 15 February 1966, covering missions SA-1 to SA-10. Available online from NTRS: PDF
  • "Saturn V Press Kit." Includes documents on Saturn V, first stage, F-1 engine, second stage, J-2 engine, Instrument Unit, facilities, testing, vehicle assembly and launch, program manager, flight history, STS-1, contractors, glossary, and index. Available online: HTML
  • "The Apollo "A"/Saturn C-1 Launch Vehicle System". NASA MSFC Saturn Systems Office, 17 July 1961. 410 pages. NASA TM X-69174. MOR-MSAT- 61-5. Available online: PDF Information and drawings about version 1 of the IU.
  • Duran, B.E. "Saturn I/IB Launch Vehicle Operational Status and Experience". Paper given at Aeronautic and Space Engineering and Manufacturing Meeting of the Society of Automotive Engineers, Los Angeles, CA, Oct 7-11, 1968. 30 pages. Duran worked for Chrysler, maker of the S-1 booster.
  • "Steps to Saturn". NASA MSFC, 106 pages. Available online:PDF Describes booster manufacture by MSFC and use of canisters containing guidance equipment before the IU.

Apollo

  • Charles D. Benson and William Barnaby Faherty. Moonport: A History of Apollo Launch Facilities and Operations. NASA SP-4204, 1978. Available online: HTML
  • "Apollo Program Summary Report." NASA Lyndon B. Johnson Space Center, Houston, Texas, April 1975. JSC-09423. Available online: PDF
  • Ivan D. Ertel, Mary Louise Mors, Jean Kernahan Bays, Courtney G. Brooks and Roland W. Newkirk. The Apollo Spacecraft: A Chronology. NASA SP-4009. Available online: HTML
  • Orloff, Richard W. "Apollo By The Numbers". NASA History Division, Washington, DC, 2000. NASA SP-2000-4029. 345 pages. Available online: HTML Appendices useful.
  • "Apollo Program Flight Summary Report Apollo Missions AS-201 through Apollo 16". NASA Office of Manned Space Flight, Une 1972. 125 pages. Available online: PDF

Specific missions

  • "Saturn SA-1 Flight Evaluation". NASA MSFC, December 14, 1961. MPRSAT- WF-61-8. Available online:PDF Describes the Saturn guidance system before the IU.
  • Brandner, F.W. "Technical Information Summary Concerning Saturn Vehicle SA-2". NASA MSFC Memo dated 5 April 1962. TMX 51831. 16 pages. Available online: PDF Describes the Saturn guidance system before the IU.
  • "Results of the Fourth Saturn IB Launch Vehicle Test Flight AS-204". NASA MSFC, 5 April 1968. 365 pages. MPR-SAT-FE-68-2. NASA TM X-61111. Available online: PDF Describes changes to the IU made on the basis of data from mission SA-204.
  • Chrysler Corporation, Huntsville Division. "Saturn Antenna Systems, SA-5". NASA MSFC Astrionics Division Instrumentation Branch, 18 June 1963. 439 pages. Available online: PDF Describes some aspects of version 1 of the IU.
  • Weichel, H.J. "SA-8 Flight Test Data Report". NASA Technical Memorandum TM X-53308. 2 August 1965. Available online:PDF According to this, the ASC-15 and the ST-90 were used in the active guidance system, while the ST-124 was part of the passenger system.
  • "Saturn V Flight Manual SA-507." A 244-page description of Saturn-Apollo 507, dated 5 October 1969. Includes a chapter about the instrument unit (Section VII, PDF page 149). Available on-line: PDF

Instrument Unit

  • IBM. "Instrument Unit System Description and Component Data." This lists, in Table 1, all components by name, part number, reference designation and location for IU-201 to -212 and IU-501 to -515. It also includes photos of many components. The change history page lists six changes, the latest being January 1970, the year IU-508 was launched.
  • "Instrument Unit Fact Sheet." An 8-page Saturn V News Reference, dated December 1968, about the time IU-505 was delivered to Cape Canaveral. Available online: PDF
  • "Saturn Instrument Unit." A 102-page description of the IU, dated April 1968, prepared by Boeing.
  • "Astrionics System Handbook for Saturn Launch Vehicles." A 417-page description of most of the functions and subsystems of the instrument unit, dated 1 November 1968. Available on-line: PDF
  • Lowery, H.R. "Saturn Instrument Unit Command System". NASA MSFC Huntsville, Alabama, 22 October 1965. 45 pages. Technical Memorandum X- 53350. Available online:PDF
  • "Saturn IB/V Instrument Unit Instrumentation System Description". International Business Machines, Federal Systems Division, Huntsville, Alabama, 1 June 1966. 119 pages. IBM No. 65-966-0021, MSFC No. III-5-509-1. Available online:PDF Describes the transducers, measurement system, and telemetry function of the IU.

Instrument Unit Guidance

  • Herman E. Thomason. "General Description of the ST-124M Inertial Platform System." NASA TN D-2983, dated September 1965. 93 pages. This has clearer figures than most of the PDF documents about the IU, providing the best views of the insides of the gyros and gas bearings. Available on-line: PDF
  • Walter Haeussermann. "Description and Performance of the Saturn Launch Vehicle's Navigation, Guidance, and Control System." NASA TN D-5869, dated July 1970. 52 pages. Available online: PDF
  • Richard L. Moore and Herman E. Thomason. "Gimbal Geometry and Attitude Sensing of the ST-124 Stabilized Platform." NASA TN D-1118, dated May 1962. An early, and mathematical, rather than descriptive, account of the ST-124. At this date the ST-124 was a 4-gimbal concept, whereas the version that flew had only 3 gimbals. Available online:PDF
  • "Saturn V Launch Vehicle Digital Computer. Volume 1: General Description and Theory." IBM, 30 November 1964. Changed 4 January 1965. 256 pages. Available online: PDF
  • "Laboratory Maintenance Instructions for the Saturn V Launch Vehicle Digital Computer." Volume 1 of 2, dated 4 January 1965. 256 pages.
  • Decher, Rudolf. "The Astrionics System of Saturn Launch Vehicles". NASA MSFC Huntsville, Alabama, 1 February 1966. 180 pages. NASA TM X- 53384. Available online: PDF
  • Lyons, R.E. and Vanderkulk, W. "The Use of Triple-Modular Redundancy to Improve Computer Reliability". IBM Journal, April 1962, pp. 200–209. Available online: PDF Theory behind the LVDC.
  • Stumpf, David K. "Titan II. A History of a Cold War Missile Program.". University of Arkansas Press, Fayetteville, Arkansas, 2000. ISBN 1-55728-601-9. Picture of the ASC-15 computer used on the Titan II and on early Saturn flights. The ASC-15 was the predecessor of the LVDC, and was the guidance computer before the IU and on IU version 1, at least.

NASA computers

  • Tomayko, James E. "Computers in Spaceflight: The NASA Experience". NASA Contractor Report 182505, March 1988. Available online: HTML
  • "Spaceborne Digital Computer Systems". NASA, SP-8070, March 1971. Available online: PDF

Notes

  1. "Instrument Unit Fact Sheet, Saturn V News Reference." Changed December 1968. Page 2.
  2. Roger E. Bilstein. Stages to Saturn. The NASA History Series, 1996. Chapter 8. From Checkout to Launch: The Quintessential Computer. IBM is also identified as the Instrument Unit builder on the nameplate of IU-514 at Udvar-Hazy Center. This nameplate is at the top left of location 7.
  3. ‘’Stages To Saturn’’ Chapter 8.
  4. The Apollo "A"/Saturn C-1 Launch Vehicle System
  5. Saturn I Summary PDF p. 36
  6. ‘’Saturn Illustrated Chronology’’, Appendix H. Moonport, Appendix A. Apollo Program Summary Report, Appendix A.
  7. "Astrionics System Handbook", 1 November 1968, MSFC No. IV-4-401-1. IBM No. 68-966-0002. Section 1.3. Saturn V Mission Profile.
  8. " Instrument Unit Fact Sheet. Saturn V News Reference." Changed December 1968. Pp. 5-6.
  9. "Saturn V Flight Manual SA-507." MSFC-MAN-507. Changed 5 October 1969. P. 2-1 (PDF page 15). Section II. Performance. Flight Sequence.
  10. "Astrionics System Handbook", 1 November 1968, MSFC No. IV-4-401-1. IBM No. 68-966-0002. P. 1.2-1 (PDF p. 15): The old and new coordinate systems are described. The new standard became effective for vehicles 204 and 502 (and subsequent).
  11. "Saturn I Summary." 15 February 1966.

External links