Robotic Telepresence for the Terraformation of Mars
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Transcript of Robotic Telepresence for the Terraformation of Mars
The current frequency and strength of natural disasters, coupled with increasing temperature and global scarcity has startled humanity with the implications of overpopulation.
It is time to make humanity a multi-planetary species!
Rotation Period (Day)∫ 23.0 Hours 24.6 Hours
Revolution Period (Year) 365.2 Days 686.2 Days
Average Temperature 59 F -91 F
Atmospheric Pressure 1013 millibars 6 millibars
Average Distance From Sun 93 Million Miles 132 Million Miles
Tilt Of Axis 23.5 Degrees 25 Degrees
Gravity 1 G 0.4 G
HOW ABOUT MARS?
BUT...
The atmospheric conditions and temperature on Mars currently do not facilitate human survival
● Thin atmosphere ● Too Cold ● No Magnetosphere ● No Gravity.
TERRAFORMATION
Introduction of photosynthetic organisms, the melting of polar ice caps, and the introduction of greenhouse gases could all be used to create an ozone-rich atmosphere.
● Runaway Greenhouse Effect (Carl Sagan) ○ Chloroluorocarbons (CFCs) ○ Orbiting Mirrors
● Ecopiosies○ Inflatable Biodomes/Greenhouses ○ Drill Microbes
ROBOTIC TELEPRESENCERemote operation of a humanoid robot by a human operator to manipulate objects and carry out tasks in a remote environment by interacting with a virtual environment.
● Gestures can be recorded from Earth to carry out tasks on the Martian terrain to begin the terraforming process before humans arrive.
● Facilitated through immersive technology supported by multi-modal feedback.
IMMERSIVE TECHNOLOGYUsers feel more “present” in virtual environments that effectively leverage these technologies to provide the user with multi-modal feedback through multiple sources of sensory input.
● VR Head Mounted Device (Oculus, Hololens, HTC Vive, Sony Morpheus)● Motion Detection (Microsoft Kinect 2) ● Motion Interaction (Leap Motion)
HUMANOID ROBOTICSHumanoid Robots are frequently used in space to complete tasks in environments that are dangerous to humans.
NAO
ROBONAUT
ASIMO VALKYRIE
FUTURE TASKS
● Infrastructure - constructing orbiting mirrors and biodomes.● Agriculture - planting microbes into Martian surface. ● Maintenance & Repair - ensuring that all the equipment on the base is
running efficiently.● Regulation of Sensory Data - acting upon a variable that is not behaving
as intended.● MIning - robots will be able to identify and mine for resources to be used
both on Mars and possibly Earth as well.
TECHNICAL CONSIDERATIONS● Calibration - users must appear in front of the Kinect motion sensor to
calibrate the cartesian coordinates to degrees of freedom and robot dexterity.
● Natural Walking - visualize and facilitate walking with humanoid robot with Leap Motion or 3D mouse
● Object Recognition - humanoid robot can be trained to recognize objects in its environment.
● Obstacle Avoidance - allowing the robot to navigate around potentially dangerous objects it has identified.
● Force Controlled Manipulation - users can pick up, move, turn, push, and pull objects by utilizing force controlled manipulation.
DESIGN CONSIDERATIONS● Represent robot:
○ State, Sensors, Inferences, Plan● Re-calibrate plans and sensor data● Self-monitor plan enactment● Naturally express complex motion plans in terms of
high level objectives (Jet Propulsion Laboratory)
HUMAN FACTORS CONSIDERATIONS
Simulator Sickness● Persistent head tracking at all times● Avoid sharp changes in acceleration
Motion Fatigue● Avoid repetitive movements ● Ensure that gestures are comfortable
● Awareness● Embodied Navigation● Dashboard ● Task Manager ● Mailbox● Database
WHAT WILL THIS LOOK LIKE?
FUTURE● Humans:
○ AR/VR Arenas○ Exoskeletons
● Robots:○ Cooperation & Communication ○ Robotic Self-Replication & Repair
● Technology:○ Increased AI ○ Internet of Things (IoT)