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STP-2 Mission

The Department of Defense (DoD) Space Test Program-2 (STP-2) mission, managed by the U.S. Air Force Space and Missile Systems Center (SMC), is targeting launch on June 24, 2019, with the launch window opening at 11:30 p.m. ET. Lifting off from Launch Complex 39A at the Kennedy Space Center in Florida, this mission will deliver 24 satellites to space on the DoD's first ever SpaceX Falcon Heavy launch vehicle. The STP-2 mission will be among the most challenging launches

in SpaceX history with four separate upper-stage engine burns, three separate deployment orbits, a final propulsive passivation maneuver and a total mission duration of over six hours. In addition, the U.S. Air Force plans to reuse side boosters from the Arabsat-6A Falcon Heavy launch, recovered after a return to launch site landing, making it the first reused Falcon Heavy ever flown for the U.S. Air Force.

The Mission

The STP-2 multi-manifest (rideshare) launch will demonstrate the capabilities of the SpaceX Falcon Heavy launch vehicle and provide critical data supporting certification for future National Security Space Launch (NSSL) missions. In addition, SMC will use this mission as a pathfinder for the development of mission assurance policies and procedures related to the reuse of launch vehicle boosters. The STP-2 payloads are assembled from a host of mission partners including the National Oceanic and Atmospheric Administration (NOAA), the National Aeronautics and Space Administration (NASA), DoD research laboratories, and university research projects. STP-2 provides a unique space access opportunity for DoD and inter-agency science and technology missions that directly enhance the space capabilities of the U.S. and its allies and partners.

Interested in learning more about the Air Force Space Command satellite launch program, including STP-2? Get an insider perspective from some of the wingmen who work on the program here.

DSX

The Air Force Research Laboratory’s Space Vehicle Directorate’s Demonstration and Science Experiments (DSX) spacecraft will conduct basic research on the harsh radiation environment of medium-Earth orbit (MEO). DSX will perform three primary experiments:

  • The Wave Particle Interaction Experiment (WPIx) will resolve critical feasibility issues for very-low frequency (VLF) wave-particle interaction.
  • The Space Weather Experiments (SWx) will measure and map the distributions of energetic protons, electrons and low-energy plasma in the inner magnetosphere to improve environment models for spacecraft design and operations.
  • The Space Environment Effects (SFx) will determine the MEO environmental effects on common electrical components, circuits and materials. This includes NASA’s Space Environment Testbeds (SET) experiments. SET will characterize how radiation driven by the Sun impacts hardware over time, paving the way for mitigating the effects of solar activity on spacecraft design and operations.

COSMIC-2

COSMIC-2 is a partnership between NOAA, the U.S. Air Force (USAF), NASA’s Jet Propulsion Lab (JPL), Taiwan’s National Space Organization (NSPO), the UK’s Surrey Satellite Technology Limited (SSTL), the Brazil Institute of Space Research (INPE), and the Australia Bureau of Meteorology (BoM). This six-satellite constellation will provide next-generation Global Navigational Satellite System Radio Occultation (GNSS-RO) data. Radio Occultation data is collected by measuring the changes in a radio signal as it is refracted in the atmosphere, allowing temperature and moisture to be determined.

  • International collaboration between Taiwan (NSPO) and the United States (NOAA)
  • Collects atmospheric data for weather prediction and for ionosphere, climate, and gravity research

GPIM

The Green Propellant Infusion Mission, or GPIM, is a NASA mission that develops a “green” alternative to conventional spacecraft propulsion systems. With the green propellant, launch vehicle and spacecraft fuel loading will be safer, faster, and much less costly. The “shirt sleeve” operational environment GPIM offers will reduce ground processing time from weeks to days.

  • Demonstrates a new form of safe propulsion
  • Improves propulsive efficiency while reducing handling concerns

Learn more about Ball Aerospace, Aerojet Rocketdyne and NASA's Green Propellant Infusion Mission.

Oculus

Oculus-ASR was developed by students at the Michigan Technological University in Houghton, MI through the Air Force Research Laboratory’s University Nanosatellite Program to provide calibration opportunities for ground-based observers attempting to determine spacecraft attitude and configuration using unresolved optical imagery.

  • Features spectrally distinct surfaces and shape profiles that can be observed from Earth’s surface
  • Records attitude time history for error correction in ground-based observations

OTB

General Atomics Electromagnetic Systems’ Orbital Test Bed (OTB) is a versatile, modular platform based on a flight-proven “hosting” model to test and qualify technologies. On STP-2, OTB hosts several payloads for technology demonstration, including the Deep Space Atomic Clock designed, built and operated by NASA’s Jet Propulsion Laboratory on behalf of the Space Technology Mission Directorate to revolutionize how spacecraft navigate.

  • Flexible technology demonstration platform
  • Hosts a miniaturized, high-stability atomic clock that will gain or lose less than a second of error in 3 million years

Learn more about General Atomics Electromagnetic Systems and NASA's Deep Space Atomic Clock.

NPSat

NPSat hosts two experiments built by the Naval Research Laboratory (NRL) to investigate space weather and support space situational awareness (SSA), including ionospheric electron density structures that cause radio scintillations impacting communications and navigation.

  • Monitors electron content and scintillations using radio frequency (RF) transmissions
  • Conducts Coherent Electromagnetic Radio Tomography (CERTO) experiment
  • NRL-built Langmuir probe takes in-situ measurements to improve ionospheric modeling

Prox-1

Prox-1 is a microsat developed by students at the Georgia Institute of Technology in Atlanta through the Air Force’s University Nanosat Program to demonstrate satellite close proximity operations and rendezvous.

  • Demonstrates small satellite close-encounter operations
  • Prox-1 deploys the LightSail 2 cubesat developed by the Planetary Society

Cubesats

E-TBEx: Measures distortion of radio signals traveling through the ionosphere using beacon tones transmitted from eight orbital locations: the six COSMIC-2 satellites and the twin E-TBEx CubeSats

Launch Environment Observer (LEO) & StangSat: Measures thermal and vibration environments during launch and demonstrates Wi-Fi data transmission between Cubesats (2 separate cubesats)

PSAT: Supports global amateur radio data relay capabilities to assist students and researchers around the world

TEPCE: Demonstrates the feasibility of using electrodynamic propulsion by deploying a 1 km electrically conductive tether, performing orbit-changing maneuvers without consuming any fuel

LightSail 2:The Planetary Society’s citizen-funded solar-sailing spacecraft propelled by the Sun

Falcon Heavy

Falcon Heavy’s first stage is composed of three Falcon 9 nine-engine cores whose 27 Merlin engines together generate more than 5 million pounds of thrust at liftoff, equal to approximately eighteen 747 aircraft. Falcon Heavy was designed from the outset to carry humans into space and restores the possibility of flying missions with crew to the Moon or Mars.

  • Width

    12.2m/39.9ft
  • Height

    70 m/229.6 ft
  • Mass

    1,420,788 kg/3,125,735 lb


PERFORMANCE

With the ability to lift into orbit nearly 64 metric tons (141,000 lb)---a mass greater than a 737 jetliner loaded with passengers, crew, luggage and fuel--Falcon Heavy can lift more than twice the payload of the next closest operational vehicle, the Delta IV Heavy, at one-third the cost.

  • Payload to Leo

    63,800 kg/140,660 lb
  • Payload to GTO

    26,700 kg/58,860 lb
  • Payload to Mars

    16,800 kg/37,040 lb
  • Payload to Pluto

    3,500 kg/7,720 lb

For more information on performance and other capabilities,
please see our user's guide.

Download User's Guide

Falcon Heavy Milestones