Explorer 35

Explorer 35
Spacecraft properties


Mission type	Space physics
Operator	NASA
COSPAR ID	1967-070A
SATCAT №	2884
Mission duration	2,167 days

Manufacturer	Langley Research Center
Launch mass	104.3 kilograms (230 lb)

Start of mission
Launch date	July 19, 1967, 14:19:02 (1967-07-19UTC14:19:02Z) UTC
Rocket	Delta E1
Launch site	Cape Canaveral LC-17B

End of mission
Disposal	Deactivated
Deactivated	June 24, 1973 (1973-06-25)
Decay date	Mid-late 1970s

Orbital parameters
Reference system	Selenocentric
Semi-major axis	7,886 kilometers (4,900 mi)
Eccentricity	0.0136973
Periselene	764 kilometers (475 mi)
Aposelene	7,886 kilometers (4,900 mi)
Inclination	147.3 degrees
Period	710 minutes
RAAN	90.2825 degrees
Argument of periselene	39.3155 degrees
Mean anomaly	321.7298 degrees
Mean motion	14.95777010
Epoch	03 March 1969 11:06:06 UTC
Revolution number	16777

Lunar orbiter
Orbital insertion	July 21, 1967

Explorer 35 was a spin-stabilized spacecraft instrumented for interplanetary studies, at lunar distances, of the interplanetary plasma, magnetic field, energetic particles, and solar X rays. It was launched into an elliptical lunar orbit. The spin axis direction was nearly perpendicular to the ecliptic plane, and the spin rate was 25.6 rpm. Mission objectives were achieved. After successful operation for 6 years, the spacecraft was turned off on June 24, 1973.

Science instruments

Magnetometers

The Ames magnetometer experiment consisted of a boom-mounted triaxial fluxgate magnetometer and an electronics package. The sensors were orthogonally mounted, with one sensor oriented along the spin axis of the spacecraft. A motor interchanged a sensor in the spin plane with the sensor along the spin axis every 24 hours, allowing inflight calibration. The instrument package included a circuit for demodulating the outputs from the sensors in the spin plane. The noise threshold was about 0.2 nT . The instrument had three ranges covering plus or minus 20, 60, and 200 nT full scale for each vector component. The digitization accuracy for each range was 1% of the entire range covered. The magnetic field vector was measured instantaneously, and the instrument range was changed after each measurement. A period of 2.05 seconds elapsed between adjacent measurements and a period of 6.14 s elapsed between measurements using the same range. The instrument performance was normal.

The experiment consisted of a boom-mounted triaxial fluxgate magnetometer. Each sensor had dual ranges of minus to plus 24 nT and 64 nT, with digitization resolutions of minus to plus 0.094 nT and 0.25 nT, respectively. Zero level drift was checked by periodic reorientation of the sensors until May 20, 1969, when the flipper mechanism failed. Past this point, data analysis was more difficult as the zero level drift of the sensor parallel to the spacecraft spin axis was not readily determined. Spacecraft interference was less than 0.125 nT. One vector measurement was obtained each 5.12 s. The bandpass of the magnetometer was 0 to 5 Hz, with a 20-dB per decade decrease for higher frequencies. Except for the flipper failure, the experiment functioned normally from launch to spacecraft turnoff (June 24, 1973).

Bistatic Radar Observations

The purpose of this experiment was to study the electromagnetic reflective properties of the lunar surface. The 136.10-MHz (2.2 m) telemetry transmissions from the spacecraft were scattered from the lunar surface and then recorded by use of the 150-ft Stanford dish antenna. The reflected signal intensity depended upon the lunar reflectivity, the spacecraft altitude above the lunar surface, and the mean curvature of the Moon. The returned signal bandwidth was proportional to RMS lunar surface slopes. Occultation phenomena permitted a determination of the scattering properties of the lunar limb. The dielectric constant of the lunar subsurface in the scattering region below a depth of about 25 cm was then determined from a profile of reflectivity values vs the angle of incidence on the Moon. The mean lunar slope over each area from which signals were reflected has also been inferred. The observations were located within about 10 degrees of the lunar equator. Experiment operation was normal as of March 1971.

Ion chambers and Geiger tubes

This experiment consisted of a 12-cm Neher-type ionization chamber and two Lionel type 205 HT Geiger-Müller (GM) tubes. The ion chamber responded omnidirectionally to electrons above 0.7 MeV and protons above 12 MeV. Both GM tubes were mounted parallel to the spacecraft spin axis. GM tube 1 detected electrons above 45 keV that were scattered off a gold foil. The acceptance cone for these electrons had a 70-deg full-angle and an axis of symmetry that was 20 deg off the spacecraft spin axis. GM tube 2 responded to electrons and protons above 22 and 300 keV, respectively, in an acceptance cone of 70-deg full-angle centered at the spacecraft spin axis. Both GM tubes responded omnidirectionally to electrons and protons of energies above 2.5 and 50 MeV, respectively. Pulses from the ion chamber and counts from each GM tube were accumulated for 39.72 s and read out every 40.96 s. In addition, the time between the first ion chamber pulses in an accumulation period was also telemetered. This experiment performed well initially.

Micrometeoroid detector

This experiment was designed to measure the ionization, momentum, speed, and direction of micrometeorites, using thin film charged detectors, induction devices, and microphones.

Faraday cup

A multigrid, split-collector Faraday cup mounted on the equator of the spacecraft was used to study the directional intensity of solar wind positive ions and electrons with particular emphasis on the interaction of the solar wind with the Moon. Twenty-seven integral current samples (requiring about 4.3 s) were taken in an energy-per-charge window from 80 to 2850 eV. Then the current was sampled in eight differential energy-per-charge windows between 50 and 5400 eV at the azimuth where the peak current appeared in the previous series of integral measurements. These measurements (integral and differential) took about 25 s. Both the sum and difference of collector currents were obtained for positive ions. Only the sum was obtained for electrons. A complete set of measurements (two collector plate sums and one difference for protons, and one collector plate sum for electrons) required 328 s. The experiment worked well from launch until its failure in July 1968.

External links

National Space Science Data Center Page on AIMP 2 (Explorer 35)

Explorers program

Explorer	Explorer 1 2 3 4 5 6 (S-2) 7 (S-1a) 8 S-56 9 (S-56A) 10 11 (S-15) 14 (EPE-B) 17 (AE-A) 19 30 (Solrad 8) 32 (AE-B) 33 (IMP-D) 34 35 (IMP-E) 37 (Solrad 9) 39 42 (Uhuru) 44 (Solrad 10) 48 (SAS B) 49 (RAE-B) 52 (Hawkeye 1) 53 (SAS C) 56 (ISEE-1) 57 (IUE) 58 (HCMM) 59 (ICE) 61 (Magsat) 62 (DE-1) 63 (DE-2) 64 (SME) 66 (COBE) 67 (EUVE) 68 (SAMPEX)

MIDEX	50 (IMP-8) 69 (RXTE) 71 (ACE) 77 (FUSE) 78 (IMAGE) 80 (WMAP) 84 (Swift) 85 thru 89 (THEMIS) 92 (WISE) ICON^‡ TESS^‡

SMEX	68 (SAMPEX) 70 (FAST) 73 (TRACE) 74 (SWAS) 75 (WIRE) 81 (RHESSI) 83 (GALEX) 90 (AIM) 91 (IBEX) 93 (NuSTAR) 94 (IRIS)

UNEX	72 (SNOE) 82 (CHIPSat)

MO	79 (HETE-2) CINDI Suzaku TWINS Hitomi GOLD^‡ NICER^‡

International	INTEGRAL

Italics indicates probes that failed to deploy or otherwise malfunctioned · ^‡ indicate missions yet to launch.

← 1966 · Orbital launches in 1967 · 1968 →

Intelsat II F-2 \| OPS 1664 \| OPS 9321 · OPS 9322 · OPS 9323 · OPS 9324 · OPS 9325 · OPS 9326 · OPS 9327 · OPS 9328 \| Kosmos 138 \| Kosmos 139 \| ESSA-4 \| OV3-5 \| OPS 4399 \| Lunar Orbiter 3 \| Kosmos 140 \| OPS 6073 \| Diadème 1 \| Kosmos 141 \| Kosmos 142 \| Diadème 2 \| OPS 4750 \| OPS 4204 \| Kosmos 143 \| Kosmos 144 \| Kosmos 145 \| OSO 3 \| Kosmos 146 \| Kosmos 147 \| Kosmos 148 \| Kosmos 149 \| Kosmos 150 · OGCh No.8 \| Intelsat II F-3 \| Kosmos 151 \| Kosmos 152 \| OPS 4779 \| Kosmos 153 \| ATS-2 · RPM-481 \| Kosmos 154 \| Kosmos 155 \| Unnamed \| OPS 0100 \| Surveyor 3 \| ESSA-5 \| Soyuz 1 \| San Marco 2 \| OPS 4243 \| Kosmos 156 \| OPS 6638 · OPS 6679 · ERS-18 · ERS-20 · ERS-27 \| Lunar Orbiter 4 \| Ariel 3 \| OPS 4696 · OPS 1967 \| Kosmos 157 \| Kosmos 158 \| Kosmos 159 \| Kosmos 160 \| OPS 7218 \| Kosmos 161 \| OPS 4321 · OPS 5557 \| Explorer 34 \| Molniya-1 No.8 \| ESRO-2A \| NRL PL-151 · NRL PL-152 · NRL PL-153 · NRL PL-154 · NRL-PL 159 · Timation 1 · Calsphere 3 · Calsphere 4 · OPS 5712 \| Kosmos 162 \| OPS 4360 \| Kosmos 163 \| Kosmos 164 \| Venera 4 \| Kosmos 165 \| Mariner 5 \| Kosmos 166 \| OPS 3559 · OPS 1873 \| Kosmos 167 \| Zenit-4 No.32 \| OPS 4286 \| Unnamed \| SECOR-9 · Aurora \| OPS 9331 · OPS 9332 · OPS 9333 · OPS 9334 · LES-5 · DODGE \| Kosmos 168 \| Surveyor 4 \| Kosmos 169 \| Explorer 35 \| Zenit-4 No.33 \| OPS 1879 \| OV1-11 · OV1-12 · OV1-86 \| OGO-4 \| Kosmos 170 \| Lunar Orbiter 5 \| OPS 4827 \| Kosmos 171 \| Kosmos 172 \| OPS 4886 \| OPS 7202 \| Kosmos 173 \| Kosmos 174 \| Zenit-2 No.51 \| Biosatellite 2 \| Surveyor 5 \| Kosmos 175 \| Kosmos 176 \| OPS 5089 \| Kosmos 177 \| Kosmos 178 \| OPS 4941 \| Kosmos 179 \| OPS 4947 \| Kosmos 180 \| Unnamed \| 7K-L1 No.4L \| Intelsat II F-4 \| Molniya-1 No.9 \| OPS 1264 \| Kosmos 181 \| Kosmos 182 \| Kosmos 183 \| OSO 4 \| Molniya-1 No.12 \| Kosmos 184 \| OPS 4995 \| Kosmos 185 \| Kosmos 186 \| Kosmos 187 \| Kosmos 188 \| Kosmos 189 \| OPS 0562 · OPS 1587 \| Kosmos 190 \| ATS-3 \| Surveyor 6 \| Apollo 4 \| ESSA-6 \| Kosmos 191 \| 7K-L1 No.5L \| Kosmos 192 \| Kosmos 193 \| WRESAT \| Kosmos 194 \| OV3-6 \| OPS 5000 \| OPS 1001 \| Pioneer 8 · ERS-30 \| Kosmos 195 \| Kosmos 196 \| Kosmos 197 \| Kosmos 198

Payloads are separated by bullets ( · ), launches by pipes ( \| ). Manned flights are indicated in bold text. Uncatalogued launch failures are listed in italics. Payloads deployed from other spacecraft are denoted in brackets.

Spacecraft missions to the Moon

Current

Orbiters	ARTEMIS Chang'e 5-T1 (Service Module) Lunar Reconnaissance Orbiter

Past

Programs	Apollo Chandrayaan Chinese Lunar Exploration Program Japanese Lunar Exploration Program Luna Lunar Orbiter Lunar Precursor Robotic Program Lunokhod Pioneer Ranger Surveyor Zond

Orbiters	Apollo 8 10 Apollo 15 Subsatellite (PFS-1) Apollo 16 Subsatellite (PFS-2) Chandrayaan-1 Chang'e 1 Chang'e 2 Clementine Explorer 35 Explorer 49 GRAIL Hiten LADEE Luna 10 11 12 14 19 22 Lunar Orbiter 1 2 3 4 5 Lunar Prospector SELENE (Kaguya, Okina & Ouna) SMART-1

Flybys	4M Apollo 13 AsiaSat-3 Cassini–Huygens Chang'e 5-T1 Galileo Geotail Luna 1 Luna 3 Mariner 10 Nozomi Pioneer 4 Pioneer 10 Ranger 5 Zond 3 5 6 7 8

Impactors	LCROSS Luna 2 MIP Ranger 4 6 7 8 9

Landers	Apollo Lunar Module x6 ALSEP (x5) and EASEP (x1) Chang'e 3 Luna 9 13 17 21 Surveyor 1 3 5 6 7

Rovers	Apollo 15 16 17 Lunokhod 1 Lunokhod 2 Yutu

Sample return	Apollo x6 Luna 16 20 24

Human landing	Apollo 11 12 14 15 16 17

Planned

Moon Express (2017)
SpaceIL (2017)
Chang'e 5 (2017)
Astrobotic / Hakuto / AngelicvM / Puli (2017)
Chandrayaan-2 (2018)
Chang'e 4 (2018)
EM-1 (Lunar Flashlight / Lunar IceCube / LunaH-Map / SkyFire) (2018)
SELENE-2 (2018)
SLIM (2019)
Chang'e 6 (2020)

Proposed

Cancelled