Simulating Mars: Enabling Testing of the Perseverance Rover Sampling and Caching Subsystem on Earth

Abstract

The development of the Sampling and Caching Subsystem (SCS) on the JPL Perseverance Rover lies at the intersection of testing, robotics, and geology. The SCS team established three primary system test campaigns and venues to aid in the development of SCS through verification and validation testing – Qualification Model Dirty Testing (QMDT) to provide a venue for testing in a Martian environment, Vehicle System Testbed (VSTB) for testing while integrated with the mobility subsystem on Martian-like terrain, and the Flight Software Testbed (FSWTB) for conducting tests using the flight motor controllers and software system on a hexapod which had the ability to simulate rover tilt. Each venue contributed a vital piece to the SCS building blocks. However, the QMDT venue operating within a simulated Martian environment provided a sui generis opportunity to fine tune the entire sampling and caching process while building the team's knowledge base about rock drillability, system life, and target selection. On Earth, because Martian rocks are not readily available, the development team utilized geoanalogs to the rocks and regolith on Mars. With rock simulant drillability characteristics like density and compressibility defined, these geoanalog rocks are ready to be drilled into as on the Martian surface. A key aspect of interacting with Martian rocks is drilling target identification and selection. The Perseverance robotic system uses on-board cameras, instrumentation, and software to collect enough information to identify potential scientific targets. With the targets identified, SCS can place the Corer and abrade the surface or collect a sample. For a ground test activity like QMDT, the test team did not have all of the camera and instrumentation systems that the rover does, so the team developed ground test equivalents to process a rock, build a target map, and define the target. The team constructed a Rock Scanning Station to build a 3D point cloud of the rock which was then processed and evaluated in a Target Downselect Tool. Key outputs from the Target Downselect Tool can be uploaded directly to the robotic software system to simulate and build the robotic sequences used in tests. With these insights and programmatic definition of targets, the QMDT test team was able to make the same decisions that the Perseverance surface operations team does. In addition, valuable lessons learned from developing the target selection ground tools and using them in QMDT were implemented into the tools used for surface operations.