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We have optimized our team structure over time; this is our understanding of a better team structure. All the leads have worked closely for at least the last two months and can support the team in meeting the URC 2025 deadline.
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University Rover Challenge is a difficult competition due to its competitive nature. Our team experienced much disappointment when applying to the competition and trying to pass the System Acceptance Review(SAR). However, after carefully reading the competition guidelines and seeing reviewing some other teams invited' qualifications, the UWRT executive team has made the following changes to secure our invitation for SAR 2025.
Define the Key Selling point the key selling points the competition requires
Ensure the selling point covers all the main systems required by the competition guidelines
Setup Milestones aim to finish the selling point step by step
Not trying to accomplish all the missions, focus on the high-priority ones.
Not to push delay the SAR review component video until the last minute
Record the section of the SAR video after each milestone is completed
Develop an integration knowledge base
Ensure the team’s ability to prototype things and iterate to meet the competition requirement.
Constantly testing the rover to ensure all system functionality.
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Equipment max height: 1.5 meter
Insert Deliver a max 5kg Cache container and deliver insert it to into a drawer
Tighten 5/16” Allen(hex) head
undo the latch and open a panel
Type the keyboard and follow the directions on a computer display
Observe a Gauge and operate a Joystick
Insert USB A stick
Push buttons and , flip the switch, and turn the knob
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Take three photo
Wide angle panorama with scale
high-resolution picture with scale
Stratigraphic profile for depositional environment and analysis for history of water
Record GPS Coordinate of each site
Camera or other life-detection mechanism
Collect sub-surface samples (at least 10cm deep) from 2 sites at least 5g
Seal sample and return cache to command station
Require a science plan
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Working drivetrain to deliver the product
Pick up a max 5kg container and insert the container into a drawer
use a normal end effector to push the button
use a normal end effector to flip the switch
Use a normal end effector to undo the latch and open a panel
end effector camera for situational awareness
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5/16” Allen(hex) head end effector module
Small end effector module that can type keyboard
normal End effector and module to operate the joystick
Special motion for turning the knob
Special motion to insert USB and reverse the polarity retry if needed
Autonomy Mission:
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Our team has divided the Rover into six main systems. Each system focuses on accomplishing one aspect of the mission. This section illustrates the functionality of each subsystem; during the actual mission, the multiple systems need to interact to complete the mission objective.
Drivetrain
The current drivetrain system has almost reached the end of its design cycle. The only thing left is to clean up the current system to create a better foundation interfacing with the rest of the system since the drivetrain is considerably the most critical system in the whole rover. The figure illustrates a rendering of the current drivetrain system.
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The Drivetrain system is designed with the following requirements:
Rocker Bogie system to traverse through rough terrain
Minimum drivetrain ground clearance 1 meter
Max drivetrain system weight less than 20kg (ebox included)
Custom airless tire with enough grip on dirt and sand
Ability to climb a curve within a 15-degree elevation
Able to overcome obstacles with height within 20 cm
Independent control on each wheel
Arcade controller for easier operator control
Input interface to interact with command-based operation
Arm
The mechanical design of the arms project is completed. However, this project is undergoing validation and testing to study the system's capability before entering the full manufacturing stage.
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The arm system is designed with the following requirements:
At a minimum, the arm has 4 degrees of freedom
Max weight: 15kg.
The arm can pick up a 5kg object and hold the object
Able to adjust rover center of mass after picking up heavy object
Able to reach at least a workspace and pick up the end effect module
Able to grab a handle, flip a switch, and push a button
Science
The full design of the science module will wait until F24, when the competition guideline is released, since science missions change the most every year. However, a lesson learned from the past is that rapid prototyping and iterating are the best ways to develop the science module, and they usually help the team accomplish the most objectives and score the highest. The team also has the past design and prototype of the science module.
The science system is designed with the following requirements:
Max weight 15kg
Able to dig the hole and extract soil
Able to perform onboard analysis (software analysis or chemical analysis)
Able to seal the sample and transport the sample back
Autonomy
Autonomy is a complete system itself but requires communication with the drivetrain system to control the rover. Note: The drivetrain control is abstracted away from the autonomy system and only exposes certain APIs for motion control.
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The autonomy system is designed with the following requirements:
Able to navigate through the area based on the given GPS coordinate
Accurate GPS Coordinate information(VN300 is capable of providing the accuracy)
Camera ability to detect AR tags and objects
Camera ability to avoid large obstacles.
Power
The power system is available to protect the other electrical components onboard when one fails and still deliver the required power to all the components. The system will expands as the rover develops.
The power system is designed with the following requirements:
The power system takes 48v from the battery
The power system monitors all the rails before delivering the power to the rest of the system
The power system is able to detect faulty rails and disable them to ensure the safety of other components
Safety switch to kill the rover under emergency
Communication
The current rover communication system is equipped with a 27dbm telemetry radio operating at 900 MHz.
The communication system is designed with the following requirements:
Able to reach beyond the line of sight for a 1 km
Support enough bandwidth for live video feed
Switch over to a backup link in cases of main link failure
Reliable gimbal system and relay the video feed directly back to the ground station
Radio links need to be available for at least rover three orientations:
Two sides facing the ground station
the back side facing the ground station
Rover Vehicle Design:
When our team tried to attend URC for the last two seasons, most parts of the rover, especially mechanical, had already been designed. Therefore, this year's Rover Vehicle Design focuses not on recreating the whole rover but on validating the current design, making necessary improvements, and integrating the system to make it work. The following is the breakdown of the detailed vehicle design architecture decisions our Our team will make continue discussing to ensure the final productvehicle design matches the competition's successrequirements.
Team Management:
Risk analysis:
Project Name | Risks | alternative solution? | ||||||
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Drivetrain |
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Arm |
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Science |
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Communication |
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Power |
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Autonomy |
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Project Timeline:
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Note: the timeline is subject to change. As highlighted in the diagram, the team's goal is to complete the whole rover system as soon as possible, test it, and optimize it for the competition, which aligns with the iterative design process.
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