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This article explores the design and uses of auxiliary rovers for Mars exploration, including search and rescue operations, short excursions, and general labor assistance. It also discusses communication methods, non-interactive science payloads, and future directions for rover development.
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A&AE 450 – Senior Design Team ERV Science and communication January 23, 2000 Christopher Burnside
Science & Communication Areas of current research • Auxiliary rover design • Auxiliary rover uses • Wagon concept vehicle • Communication with rover • Non-interactive science payloads • Weight estimates • Cost estimates • Failure estimates
Auxiliary Rover Uses • Search and rescue operations (hopefully never) • Carried by main rover on extended missions for higher effectiveness science • Short excursions from the main base • General labor assistance • Used in place of the main rover during scheduled rover preventive maintenance times • “Hazardous missions” – no mission will put the crew in excess danger, but the rovers might be placed in danger.
Rover Design • 4-wheel vs. 3-wheel rover vs. Treads • Stability and safety issues • Maneuverability • Higher speed (treads generally are slower) • “Dune buggy” type design • More inclined to a 4 wheel design • Unpressurized • Shorter range than main rover • Reliability on the order of road cars (if built and maintained properly) • A “good” earth buggy from a dealer costs $9215 US • ~ 150 kg (330 earth lbs.) • Pictures from www.dune-buggy.com (authors are unknown)
Mars Wagon • Used to carry: • Raw material • Science equipment • Samples • Just about anything else • This is triton trailer found at www.tritontrailer.Com • Can be used on extended missions with the rovers • General labor around the base • Design similar to a flatbed trailer on earth • Range in cost from $100 to $10,000 depending on quality • ~40 kg (90 lbs.) • Reliability on the order of trailers on earth (~.95)
Rover Communication • 3 levels of communication redundancy • Satellite • Allows direct communication with earth and mars base • Easy with a good satellite infrastructure • NASA has already started with global surveyor – it has a navigation beacon on it • Initial navigation • Quality initial navigation units cost around than $14,000 • www.systron.com • Short-wave radio • Lightweight, cheap and easy to use • Low-band width is a con • $40 to $1500 is a typical cost BEI multi-axis inertial sensing system Radioshack short-wave receiver NASA’s Mars Global Surveyor
Non-interactive Science • Science packages can be flown which require little human interaction • SPADUS – space dust and energetic particle experiment • Taylor university – www.Taylor.Edu • Dr. Voss, head of space science research • Currently flying and projecting orbits of micrometeorites • ~25 lbs • Meteorological experiments • Find the weather for 2 years at the landing site prior to landing as well as during the mission • Others, but since they are not mission critical a total weight will be determined for all non-interactive science • ~100 lbs possibly
Future Directions • Sizing code for auxiliary rover • Explore more uses for an auxiliary rover • Demonstrate actual need of the wagon • Size the wagon • Communication frequencies of satellite, short-wave radio • Compute the accuracy vs. Drift of rate gyros. (How close can you get to the base starting from 400 km away) • Cost, failure, weight analysis of communication equipment • Determine best total weight for non-critical science packages
Experience Science & com EE 201 Hobby electronics C/MATLAB programming Taylor connections Lots of interest AutoCAD, Surfcam, CNC, model airplanes Science is of prime importance and is a broad subject. Ideas for science can be expressed and will be considered. Comments