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Mission Background
The human endeavor to explore Mars has been in progress for decades. The first artificially made object reached the Martian surface in 1971. Since then, a number of robotic missions have successfully operated on the Martian surface, and many others have found homes in orbit around the Red Planet.
Despite the increasing complexity and capability of landers and rovers, NASA maintains its dedication to send people to Mars. The expectation of an eventual human mission to Mars has become a hallmark of the public vision of space exploration. Sending people to Mars has proven to be a much more challenging undertaking than sending humans to the moon; nevertheless, NASA plans to land humans on Mars in the early 2030s (though precisely when is still a matter of contention). Numerous ideas have been proposed by a multitude of organizations about how future Mars missions may be accomplished; NASA, however, has chosen a strikingly Apollo-like architecture. The preliminary mission architecture is also extremely similar to that portrayed in the popular novel The Martian by Andy Weir. First, humans would depart Earth orbit on an Orion capsule and travel to the lunar Gateway, a station orbiting the moon. From there they would board the Deep Space Transport, which would ferry the astronauts to Mars orbit. The astronauts would spend 438 days at Mars before returning to the Gateway and then back to Earth.
The Apollo Program and the International Space Station operations have demonstrated the indispensability of constant telemetry data being provided to Mission Control. All of the Apollo missions had problems in flight, and Mission Control’s quick actions prevented disaster on several occasions. One of the new challenges with Mars missions is the signal delay, which varies between three and twenty-one minutes. Therefore, Mars missions will likely need to be more self-reliant than Apollo or ISS missions. However, a constant feed of telemetry will still probably remain a critical safety component of Mars missions. One of the challenges associated with obtaining this telemetry data, however, will maintain communication during the portion of the Martian solar day when the surface base does not face Earth. In other words, if the base isn’t pointed at Earth, it can’t talk to Earth because Mars is in the way.
Recently, the burgeoning smallsat revolution found allies even in Mars orbit – in the two 6U cubesats sent as an accompaniment to the InSight mission. These cubesats, called the MarCO mission, demonstrated that small satellites have the capability to communicate from Mars to Earth. Furthermore, the MarCO mission suggested that series of small spacecraft may contribute in unexpected ways to larger Mars missions.
Mission Statement
The mission of the Monarch System is to provide a continuous, reliable communication link from Earth to a low-power ground communication system anywhere on the portion of the Martian surface that does not have line-of-sight communication with Earth. The Monarch System will provide functionality that will not be compromised in the case of single-point failures.
Andrew Wagner - Project Manager & Command and Data Handling
Andrew is from Dubuque, Iowa, and is currently studying Aerospace Engineering, with a minor in Computer Science. Heis currently enrolled in the Accelerated BS/MS Program here at SLU, and after finishing his Master’s Degree he hopes to
work in Spacecraft Systems Engineering or Operations.
Meet The Space Bois
Jeffrey Kelley - Recorder and Communications System
Jeffrey is from Prairieville, Louisiana, and is currently studying toward a degree in Aerospace Engineering. His nominal trajectory is to pursue a Master's degree at Saint Louis University, where he can develop his skills in his primary interest areas of space systems engineering and integration.
Connor Highlander - Archivist, Structures, and Power
Connor is from Maryville Illinois and is at SLU pursuing a major in Aerospace Engineering. He has an interest in Integration, Testing and systems engineering and is looking forward to starting his career as a systems engineer with Northrop Grumman Innovation Systems when he graduates.
Sergio Bernabeu Peñalba - Webmaster and Orbital Mechanics
Born and raised in Madrid, Spain, Sergio studied at SLU Madrid for 1.5 years prior to transferring to the St. Louis campus. He is passionate about orbital mechanics (and, overall, space) and after graduation he will be pursuing a Master's degree in Sweden. He wants to work on space environmentalism and/or become an astronaut.
Previous projects: Argus-02
The team has previously worked together to design, assemble, test and control a small satellite. Argus-02’s mission was twofold: to characterize the effects of radiation on data storage components in Low Earth Orbit, and to train an Artificial Intelligence to recognize patterns and unknown objects from pictures taken by the spacecraft. Argus-02 was launched on board of NG-12 NET November 2nd, 2019 and deployed from the International Space Station on February 2020. Learn more about Argus-02 here.
Poster for (what would have been) the Parks & Senior Legacy Symposiums
Note: maximize poster window for greater detail; this poster is intended to be large in dimensions.
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