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1 EECS 42005200 Term Project (10)
- 1. 1 EECS 4200/5200 Term Project (10%) sp21 Modeling of Soft Landing of Mars ‘Perseverance’ Rover Introduction On February 18, 2021 the Mars Perseverance Rover landed on Mars’s Jezero Crater. Sent to look for signs of ancient life and to collect rock samples, the process of landing on Mars safely required a team of scientists and researchers to derive a series of complex maneuvers. Over the course of this project, you will take on the role of these scientists and create models of the soft landing procedure. Objectives of the Term Project The term project's primary objective is to impart practical skills necessary to develop a real-world
- 2. system model. The student is expected to be able to do the following by the completion of this term project: 1. To generate a model of a practical system by the laws of the physical sciences governing the system’s behavior. In this case, it is Translational Motion Mechanical System. 2. Convert the model into a Free Body Diagram with all acting forces presented. 3. Create a Set of Differential Equations pertaining to the diagram. 4. Presentation of the equation in Matrix form with State variables and Output. 5. Develop Signal Flow Graph and defining the System Transfer function. 6. Identification of key design parameters from literatures and reference material and utilization/application to the modeling process. 7. Calculation of key parameters such as masses, velocities, gravity, etc. Any defined values from correlating literature (web, text, papers) must be specified regarding author(s), title, page, date, address (if Web).
- 3. 2 Background While performing the soft-landing on Mars, the Perseverance rover underwent a series of stages where numerous elements of the system would provide support ensuring a safe landing. As far as the soft-landing is concerned, at approximately 12 kilometers from the surface of Mars, the parachute of the Perseverance rover was deployed to slow its descent. After a reasonable amount of deacceleration, the heat shield was removed, allowing the cameras onboard the rover to obtain their first glimpse of the surface of Mars. Further into the descent, the engine of the hover unit was activated as the backshell containing the connection to the parachute was separated. At this stage of the descent, the rover’s landing was assisted by the hover unit providing upward thrust to decrease the velocity at which it fell. Finally, after a
- 4. predetermined height over the surface was reached, the hover unit took on the role of a helicopter and hovered in position. Then, the hover unit behaved like a “skycrane” where it gradually lowered the rover onto the surface. 3 Project Description The project you are assigned is concerned with the soft landing of the Perseverance rover; in other words, starting with the deployment of the parachute and onwards as it descends. For purposes of the project, we are to analyze the soft-landing system at the instant in which the parachute is deployed and the hover unit engines are activated providing upward thrust. In order words, the backshell is still attached while the heat shield has been removed. Furthermore, we assume the “skycrane” is already activated with its full length
- 5. and the rover has touched the surface. As a student, you are to model this landing system and derive a series of requirements based upon the description provided below: 1. The masses of the system considered are from the hover unit (M1) and the rover (M2). The backshell is assumed negligible and can be ignored as a mass (for simplicity). 2. As opposed to the backshell, we will assume the parachute is connected straight to the hover unit. It can be thought of as a spring (K1), while the “skycrane” the hover unit uses to lower the rover is also a spring (K2). 3. The parachute provides air resistance relating to the descent which can be thought of as friction (B1). Likewise, the “skycrane” between the hover and the rover has a friction of (B2). 4. The force the hover unit exerts to allow the system to hover is described as [ F(t)]. 5. Refer to the displacement of the hover unit as y1(t) and the displacement of the rover
- 6. as y2(t). 6. Hint: Read through the provided resources to help decrease any difficulties. 4 The Perseverance Rover Backshell, Hover and Rover 5 Details of Soft Landing Model As defined within the objectives, using the masses, friction, spring constants, displacement and force, you are to create a model illustrating how these components are correlated to one another (connections, placement, etc.). This diagram will serve as the basis you will use to create a free
- 7. body diagram of the system. The diagram must show all relevant forces and interactions. Using the free body diagram you created, you must derive their associated differential equations. You may assume all initial conditions to be equal to zero. Next, you are to present these equations in matrix format in addition to representing the output. You will then prepare a signal flow diagram of the system which will guide you in presenting a transfer function. In other words, you are to deliver the following in sequence: *Notes Per each of the deliverable below, specify the source of information, type of information you use, how you apply this information to yield each item of deliverable. If you miss this description, points will be deducted. 1. Draw a schematic to illustrate this Translational Motion Mechanical system. 2. Create a Free Body Diagram depicting the system (show all the parameters with directions).
- 8. 3. Develop a set of differential equations based on this system. Assume all initial conditions are zero. 4. Convert your differential equation into a state equation formatting. 5. Depict your state equation in matrix format. Also include the output equation as a matrix too. 6. Draw a Signal Flow Graph (Observable form) using the states you created earlier as a guide. (mark the state variables on the graph) 7. Prepare a Transfer Function given input F and output y1. Hint: Use Mason’s Rule based off the signal flow graph you drew previously. 8. Given the provided literature and any other sources you find online (cite your references as per the instructions in the objectives section), Provide a Table of Key Parameters 6 which present a numerical values for M1, M2, K1, K2, B1, B2,
- 9. Y1 and Y2. Note that you may not find values for all of them. Present whatever you can find and suggest reasonable values per each parameter with source of information (title, author, page, date, web address if from web) if not possible, with justification. Further Requirements 1) You are to prepare a discussion detailing the procedure you followed to create your diagrams and how you went about solving them. Furthermore, all necessary calculations must be shown within your work. A scan representing your illustrations and calculations is accepted. 2) Present a section titled “Self-Assessment on the Use of Collected Information” where you collectively include answers to the following: a. Where do you get the information needed for modeling per each stage? b. What information you collected? c. How do you use the information for modeling project and
- 10. which stage? d. By including the values you got from the literature, what benefit did you receive from this project? 3) Finally, provide a short conclusion summarizing the project. Resources Here are resources to help you get started. Feel free to resort to anything else you can find. https://mars.nasa.gov/mars2020/ https://www.nasa.gov/perseverance https://mars.nasa.gov/resources/25529/mars-2020-perseverance- landing-press-kit/ (It is highly suggested you view the above press kit) https://www.youtube.com/watch?v=4czjS9h4Fpg&ab_channel= NASA (This video shows the soft-landing along with each of the steps detailed in the project) https://openoregon.pressbooks.pub/bodyphysics/chapter/lunar - lander/ https://mars.nasa.gov/mars2020/
- 11. https://www.nasa.gov/perseverance https://mars.nasa.gov/resources/25529/mars-2020-perseverance- landing-press-kit/ https://www.youtube.com/watch?v=4czjS9h4Fpg&ab_channel= NASA https://openoregon.pressbooks.pub/bodyphysics/chapter/lunar - lander/ 7 Midterm Project Report Your project report should be written in a professional manner including the following items in sequence: 1.Cover page: Course name, Project name, Your name, Date, Pledge (include the paragraph Below ass you did for Test) Pledge and Acknowledgement By writing my name, I pledge that: this is my own work and I do not give or receive any help in completing this term project. In addition, I acknowledge that there will be a penalty for late submission. Name____________________________ Date
- 12. ___________________ 2. Table of Contents 3. Schematic Diagram of Translational Mechanical Motion-Mars Soft Landing Rover 4. Free Body Diagram 5. Set of Differential Equations 6. State Equations with state variables and Output Equation 7. Matrix format of item 6 above 8. Signal Flow Graph marked with all state variables and parameter values 9. Key Parameter Value Table (per each parameter, specify the source as described in “item 8 of Details of Soft Landing Model”) 10. Signal Flow Graph (Observable Form) 11. Transfer function T(s) for input F and output Y1 12. Discussions 13.Self-Assessment on the use of Collected Information 14. Conclusions 15. List of References (include all references used to identify parameter values and modeling)
- 13. *Formatting and Submission Typed document submitted as a PDF. Scanned pages showing work are accepted. File name: 4200Projyourname.pdf Upload to Project link in BB Due: 5 PM April 27 (Tu), 2021. No Late Submission Accepted !