CASSIOPE

CASSIOPE

CASSIOPE launches on a Falcon 9 v1.1
Mission type	Technology Communications Research
Operator	University of Calgary
COSPAR ID	2013-055A
SATCAT no.	39265
Website	http://www.asc-csa.gc.ca/eng/satellites/cassiope.asp
Mission duration	Primary mission: 18 months [1] Design life: 2 years [2] [3] Elapsed: 12 years, 3 months, 16 days
Orbits completed	53807 [4]
Spacecraft properties
Bus	MAC-200
Manufacturer	MDA (prime) Magellan Aerospace (subcontractor) Com Dev (subcontractor)
Launch mass	481 kg (1,060 lb) [5]
Dimensions	180×125 cm (71×49 in) [3]
Power	5 solar panels generating up to 600 W [3]
Start of mission
Launch date	September 29, 2013, 16:00 (2013-09-29UTC16Z) UTC
Rocket	Falcon 9 v1.1
Launch site	Vandenberg SLC-4E
Contractor	SpaceX
Orbital parameters
Reference system	Geocentric
Regime	Low Earth
Semi-major axis	7,063 km (4,389 mi) [4]
Eccentricity	0.0526838 [4]
Perigee altitude	320 km (200 mi) [4]
Apogee altitude	1,064.2 km (661.3 mi) [4]
Inclination	80.9604 degrees [4]
Period	98.46 minutes [4]
RAAN	349.3323 degrees [4]
Argument of perigee	335.9358 degrees [4]
Mean anomaly	21.8 degrees [4]
Mean motion	14.6254 [4]
Epoch	January 30, 2024, 12:46:11 UTC [4]

Cascade, Smallsat and Ionospheric Polar Explorer (CASSIOPE), is a Canadian Space Agency (CSA) multi-mission satellite operated by the University of Calgary. The mission development and operations from launch to February 2018 was funded through CSA and the Technology Partnerships Canada program. In February 2018 CASSIOPE became part of the European Space Agency's Swarm constellation through the Third-Party Mission Program, known as Swarm Echo, or Swarm-E. It was launched September 29, 2013, on the first flight of the SpaceX Falcon 9 v1.1 launch vehicle. CASSIOPE is the first Canadian hybrid satellite to carry a dual mission in the fields of telecommunications and scientific research. The main objectives are to gather information to better understand the science of space weather, while verifying high-speed communications concepts through the use of advanced space technologies.

The satellite was deployed in an elliptical polar orbit and carries a commercial communications system called Cascade as well as a scientific experiment package called e-POP (enhanced Polar Outflow Probe) Following staging, the Falcon 9's first stage was used by SpaceX for a controlled descent and landing test. While the first stage was destroyed on impact with the ocean, significant data was acquired and the test was considered a success.

History

The satellite that became CASSIOPE began with a 1996 concept for a small (70 kg/150 lb), inexpensive microsatellite called Polar Outflow Probe, or POP. The Canadian Space Agency funded a 1997 feasibility study that led to a modified mission concept that was designed during 2000-2005. ^[6] The revised concept was to combine an enhanced version of POP, called e-POP, with a MacDonald, Dettwiler and Associates (MDA) commercial satellite called Cascade, into a single satellite, and to design and build a generic, low-cost small satellite bus that would be useful for other Canadian satellite missions in the future. ^[7] The eight e-POP scientific instruments were built, calibrated, and tested in 2005-2007, with integration onto the satellite bus for spacecraft-level testing in 2008-2009. ^[6]

Spacecraft

CASSIOPE is a 481 kg (1,060 lb) small satellite that is 180 cm (71 in) long and 125 cm (49 in) high. ^{[5] [8]} It combines the function of two distinct missions in order to be more cost-effective and reduce risk. ^[9] The spacecraft carries a primary payload of two instrument suites: the Cascade commercial communications system and a scientific payload named e-POP.

Cascade

The commercial payload, named Cascade, is a technology demonstrator courier in the sky, aimed at providing a proof of concept for a digital broadband courier service for commercial use. ^[10] Built by MDA, the operational concept is to receive very large data files as the satellite orbits the globe, store them onboard temporarily, then deliver them at a later time to nearly any destination worldwide. ^[9]

e-POP

The e-POP portion of CASSIOPE is a suite of eight scientific instruments. The University of Calgary's Institute for Space Research leads the science project, while MDA is the prime contractor for the mission including launch and operation of the spacecraft. The orbital science mission is scheduled for a 21-month duration. ^[6] e-POP will gather data on Solar storms in the upper atmosphere. These storms give rise to the polar aurora or northern lights seen in the skies in northern latitudes. While these atmospheric glows may offer a thrilling nighttime spectacle, the inducing radiation can interfere with radio communications, GPS navigation, and other space-based systems. ^[11] The eight scientific instruments aboard CASSIOPE will help scientists understand solar weather and eventually plan for measures to mitigate its deleterious effects. ^[12]

The e-POP payload contains eight scientific instruments: ^[13]

• Coherent EM Radio Tomography (CER), measuring radio propagation and ionospheric scintillation
• Fast Auroral Imager (FAI), measuring large-scale auroral emissions
• GPS Altitude and Profiling Experiment (GAP), high-precision position and attitude determination
• Imaging and Rapid Scanning Ion Mass Spectrometer (IRM), measuring the three-dimensional distribution of ions
• Fluxgate Magnetometer (MGF), high-precision magnetic field perturbation measurement
• Neutral Mass Spectrometer (NMS), measuring the mass, composition and velocity of neutral particles
• Radio Receiver Instrument (RRI), measuring radio wave propagation
• Suprathermal Electron Imager (SEI), measuring low-energy electron distribution

Launch

SpaceX Falcon 9 launch from Vandenberg with CASSIOPE

At the time the launch services were contracted in 2006, the SpaceX Falcon 9 launch vehicle had yet to be developed, but MDA signed on to have CASSIOPE on one of its first flights anyway. ^[14] The launch was originally scheduled for second quarter in 2008. ^[15] The launch date slipped several times, and the launch vehicle shifted from the Falcon 9 v1.0 to the Falcon 9 v1.1 in June 2010. ^[12]

MDA agreed to put CASSIOPE on the first flight of an essentially new launch vehicle. ^[16] The Falcon 9 v1.1, upgraded from the original Falcon 9, was a much larger and heavier rocket with 60 percent more thrust. ^[16] The payload mass, at approximately 500 kg (1,100 lb), was very light relative to the rocket's capability. ^[17] MDA received a discounted rate, at approximately 20 percent off from the normal published price for a SpaceX Falcon 9 low-Earth orbit (LEO) mission, because the launch was a technology demonstration mission for SpaceX. ^[18]

Since this was the first flight of a new launch vehicle, the US Air Force had estimated the overall probability of failure on the mission was nearly fifty percent. ^[19] As it turned out, the mission was successful, as was each of the next 13 Falcon 9 v1.1 missions before a launch vehicle failure and loss of mission occurred on the SpaceX CRS-7 International Space Station resupply mission in June 2015. ^[20]

The satellite was launched on September 29, 2013. ^[21] This was SpaceX's first-ever launch of a Falcon 9 from Vandenberg Air Force Base in California. It was also SpaceX's first Falcon 9 launch into a polar orbit and the first time that a Falcon 9 launched with payload fairings instead of a Dragon spacecraft on top. ^[22] The Falcon 9 upper stage used to launch CASSIOPE was left derelict in a decaying elliptical low-Earth orbit that entered the atmosphere on February 8, 2025 with its final perigee of 135 km (84 mi) and an apogee of 161 km (100 mi). ^[23]

Post-mission launch vehicle testing

Main article: SpaceX reusable launch system development program

After the second stage separated from the booster stage, SpaceX tested the booster in an attempt to re-enter the lower atmosphere in a controlled manner and decelerate to a simulated over-water landing. ^[24] Three minutes into the launch, the booster stage attitude was reversed, and three of the nine engines refired at high altitude, as planned, to initiate the deceleration and controlled descent trajectory to the surface of the ocean. The first phase of the test worked well and the first stage re-entered safely. ^[21] However, the first stage began to roll due to aerodynamic forces during the descent through the atmosphere, and the roll rate exceeded the capabilities of the booster attitude control system (ACS) to null it out. The fuel in the tanks centrifuged to the outside of the tank and the single engine involved in the low-altitude deceleration maneuver shut down. Debris from the first stage was subsequently retrieved from the ocean. ^[21]

SpaceX also ran a post-mission test on the second stage. While a number of the new capabilities were successfully tested on the CASSIOPE flight, there was an issue with the second stage restart test. The test to reignite the second stage Merlin 1D vacuum engine once the rocket had deployed its primary payload (CASSIOPE) and all of its nanosat secondary payloads was unsuccessful. The engine failed to restart while the second stage was coasting in low-Earth orbit. ^[25]

Secondary payloads

Five nanosatellite spacecraft that were also carried to orbit on the same launch vehicle that carried the CASSIOPE primary payload: ^[9]

• CUSat, Cornell University
• Drag and Atmospheric Neutral Density Explorer (DANDE), University of Colorado Boulder
• three Polar Orbiting Passive Atmospheric Calibration Spheres (POPACS), each a 10 cm (4 in) white aluminum sphere, joint project of Morehead State University, University of Arkansas, Montana State University, Drexel University, and Planetary Systems Corporation. ^[26]

Operations

After a successful launch on September 29, 2013, CASSIOPE entered into a commissioning phase that lasted to January 1, 2014, with no faults detected on the spacecraft bus or payloads. Three ground stations were utilized, including Kiruna (Sweden), Inuvik (Canada), and the German Antarctic Receiving Station at the General Bernardo O'Higgins Base in Antarctica. Routine operations were scheduled to run to March, 2015. The mission was extended via funding from the Technology Partnerships Canada program through the Industrial Technologies Office that was part of the Canadian government at the time. In February 2018, the European Space Agency, through the Third Party Mission Program, integrated the mission into the Swarm constellation of satellites. ^[27] They renamed CASSIOPE as "Swarm-Echo", recognizing the synergy between the two missions in collecting space weather data in low-Earth orbit. ^[27] The partnership allowed for four ground station contacts per day, rather than one, greatly increasing the amount of data that could be downloaded from the e-POP suite of instruments.

On August 11, 2016, one of the four reaction wheels used for spacecraft attitude control failed. This did not affect spacecraft operations in a significant way since only three wheels are required for 3-axis stabilized pointing. A second reaction wheel failed on February 27, 2021, forcing the spacecraft into a slowly spinning, safe-hold attitude configuration. Three-axis stabilized control was restored in September 2021 by implementing a bias momentum configuration on the two remaining wheels (spinning the wheels in opposite directions), and using the magnetic torque rods for attitude control. Three months later, on December 17, 2021, a third reaction wheel failed, leaving the spacecraft with no viable methods for fixed attitude pointing. Although most of the e-POP instruments were fully operational, without stabilized pointing much of the science objectives could not be met, resulting in a conclusion of the operational portion of the mission on December 31, 2021. ^[28]

See also

• Spaceflight portal

• List of Falcon 9 and Falcon Heavy launches

References

1. Howell, Elizabeth (September 27, 2013). "SpaceX to Launch Space Weather Satellite for Canada Sunday". Space.com . Retrieved April 13, 2014.
2. Graham, William (September 29, 2013). "SpaceX successfully launches debut Falcon 9 v1.1". NASA Spaceflight. Retrieved April 13, 2014.
3. "CASSIOPE/e-POP Fact Sheet". University of Calgary. 2014. Archived from the original on October 31, 2013. Retrieved April 14, 2014.
4. "CASSIOPE Satellite details 2013-055A NORAD 39265". N2YO. January 30, 2024. Retrieved January 30, 2024.
5. Morris, Chris (September 16, 2013). "UNB scientists design space GPS unit". Times & Transcript . Moncton, New Brunswick: Brunswick News Inc. p. C2. ISSN   1912-1504 . Retrieved January 13, 2026– via Newspapers.com.
6. "e-POP Project Schedule". University of Calgary. 2013. Archived from the original on July 28, 2013. Retrieved September 6, 2013.
7. MDA Staff (2012). "Programs: CASSIOPE". MDA Corporation. Richmond, British Columbia: MacDonald, Dettwiler and Associates. Archived from the original on October 2, 2013. Retrieved January 13, 2026.
8. CSA Staff (February 22, 2018). "CASSIOPE: Observing space weather with a hybrid satellite". Canadian Space Agency. Archived from the original on August 8, 2018. Retrieved January 6, 2026.
9. Messier, Doug (September 10, 2013). "A Preview of Falcon 9′s Flight From Vandenberg". Parabolic Arc. Archived from the original on April 24, 2021. Retrieved September 11, 2013.
10. UofC Staff (2013). "Cascade Payload on CASSIOPE". Institute for Space Imaging Science. University of Calgary. Archived from the original on October 30, 2013. Retrieved January 13, 2026.
11. Semeniuk, Ivan (September 30, 2013). "Canadian satellite explores ionosphere". The Globe and Mail . Toronto: The Woodbridge Company. p. A5. ISSN   0319-0714 . Retrieved January 13, 2026– via Newspapers.com.
12. Boucher, Mark (June 26, 2012). "Canada's CASSIOPE Satellite Nearing Liftoff". SpaceRef Canada. Archived from the original on January 15, 2013. Retrieved September 7, 2013.
13. "e-POP Payload on CASSIOPE". University of Calgary. 2013. Archived from the original on October 31, 2013. Retrieved February 20, 2014.
14. Coppinger, Rob (April 10, 2006). "SpaceX wins Falcon 9 contract". Flight Global . London: DVV Media Group. ISSN   0015-3710. Archived from the original on December 7, 2024. Retrieved January 13, 2026.
15. Spaceref (May 31, 2006). "SpaceX Achieves Key Milestone of Tenth Launch Agreement". SpaceNews . Archived from the original on January 13, 2026. Retrieved January 13, 2026.
16. Clark, Stephen (September 28, 2013). "SpaceX to put Falcon 9 upgrades to the test Sunday". Spaceflight Now. Retrieved September 28, 2013.
17. Foust, Jeff (March 27, 2013). "After Dragon, SpaceX's focus returns to Falcon". NewSpace Journal. Archived from the original on May 18, 2013. Retrieved January 14, 2026.
18. Klotz, Irene (September 6, 2013). "Musk Says SpaceX Being "Extremely Paranoid" as It Readies for Falcon 9's California Debut". Space News. Archived from the original on September 13, 2013. Retrieved September 13, 2013.
19. "Waiver to Space Exploration Technologies Corporation of Acceptable Risk Limit for Launch". Federal Register . United States Government. Federal Aviation Administration. August 27, 2013. Retrieved January 21, 2016. The Falcon 9 v1.1 is a new launch vehicle. The U.S. Air Force has determined that its overall failure probability is nearly fifty percent for each of the first two launches.
20. Amos, Jonathan (June 28, 2015). "Unmanned SpaceX rocket explodes after Florida launch". BBC News . London: British Broadcasting Corporation. Archived from the original on June 30, 2015. Retrieved January 12, 2026.
21. Messier, Doug (September 29, 2013). "Falcon 9 Launches Payloads into Orbit From Vandenberg". Parabolic Arc. Archived from the original on September 30, 2013. Retrieved September 30, 2013.
22. Scully, Janine (September 30, 2013). "Falcon 9 blasts off from VAFB". Santa Maria Times . Santa Maria, California: Lee Enterprises. pp. A1, A10. ISSN   0745-6166 . Retrieved January 12, 2026– via Newspapers.com.
23. Peat, Chris (January 6, 2026). "Falcon 9 R/B - Orbit". Heavens Above. Retrieved January 6, 2026.
24. Lindsey, Clark (March 28, 2013). "SpaceX moving quickly towards fly-back first stage". NewSpace Watch. Archived from the original on April 16, 2013. Retrieved March 29, 2013.
25. Ferster, Warren (September 29, 2013). "Upgraded Falcon 9 Rocket Successfully Debuts from Vandenberg". Space News. Archived from the original on September 30, 2013. Retrieved September 30, 2013.
26. Holemans, Walter; Moore, R. Gilbert; Kang, Jin (2012). Counting Down to the Launch of POPACS (Polar Orbiting Passive Atmospheric Calibration Spheres). 26th Annual AIAA/USU Conference on Small Satellites. August 13–16, 2012. Utah State University. SSC12-X-3.
27. ESA Staff (February 22, 2018). "Swarm trio becomes a quartet" (Press release). European Space Agency. Archived from the original on October 10, 2022. Retrieved January 6, 2026.
28. "CASSIOPE science operations come to an end". 2022.

Further reading

• Yau, Andrew W.; James, H. Gordon (June 2009). "CASSIOPE Enhanced Polar Outflow Probe (e-POP) Small Satellite Mission: Space Plasma Observations and International Collaborations". AIP Conference Proceedings. 1144: 192–195. Bibcode:2009AIPC.1144..192Y. doi:10.1063/1.3169287.
• Fujikawa, Nobuko; Hayakawa, Hajime; Tsuruda, Koichiro; et al. (2005). Neutral mass and velocity spectrometer (NMS) on e-POP/CASSIOPE spacecraft (PDF). International Sessions of Japan Earth and Planetary Science Joint Meeting 2005.
• Yau, Andrew W.; James, H. Gordon (2011). "Scientific Objectives of the Canadian CASSIOPE Enhanced Polar Outflow Probe (e-POP) Small Satellite Mission". The Sun, the Solar Wind, and the Heliosphere. IAGA Special Sopron Book Series, Volume 4. Springer Netherlands. pp. 355–364. Bibcode:2011sswh.book..355Y. doi:10.1007/978-90-481-9787-3_26. ISBN   978-90-481-9786-6.
• Yau, A. W.; James, H. G.; Bernhardt, P. A.; et al. (April 2009). "The Canadian Enhanced Polar Outflow Probe (e-POP) Mission: Current Status and Planned Observations and Data Distribution". Data Science Journal. 8: S38 –S44. doi: 10.2481/dsj.8.S38 .

External links

• CASSIOPE at the Canadian Space Agency
• CASSIOPE at MacDonald, Dettwiler and Associates