675.613.81 - The Bold Science Motivating and Enabled by our Engineering

Expanded Course Description

Topics in the course will include a mix of engineering and science on

• Lessons learned and development of early and modern telescopes,
• Landing and exploring diversity on ocean worlds,
• Multi-point and distributed measurements of the sun-earth system,
• Technologies to protect our planet against space hazards,
• Engineering and technology frameworks for lunar surface and cis-lunar space,
• NASA as one of many customers in the space industry,
• Special topics on foundational questions that can be uniquely addressed through space exploration,
• Engineering challenges created by bold science mission concepts.

By the end of this course, you will be able to:

1. Describe the major scientific discoveries in the history of space exploration.
2. Categorize the major scientific discoveries to the engineering and technologies that enabled them.
3. Develop engineering strategies to tackle the big science questions facing the future of space exploration.
4. Analyze a proposed scientific investigation from the perspective of the engineer tasked with assessing requirements for the spacecraft and instruments, and deriving engineering solutions.

Effectively present complex space engineering projects to a wide range of audiences.

Course Structure

The course materials are divided into modules which can be accessed by clicking Modules on the course menu. A module will have several sections including the overview, advanced reading, content (recording and powerpoint file), quiz questions, and an introduction to best practices for communicating technical content effectively. You are encouraged to preview all sections of the module before starting. Most modules run for a period of seven (7) days, exceptions are noted in the Course Outline. You should regularly check the Calendar and Announcements for assignment due dates.

Course Topics

Week 1 -- Aug 26 - Sep 01, 2024 -- Module 1 -- Our Place in the Universe
Week 2 -- Sep 02 - Sep 08, 2024 -- Module 2 -- Ocean Worlds
Week 3 -- Sep 09 - Sep 15, 2024 -- Module 3 -- Golden Eye and Webb Projects Start
Week 4 -- Sep 16 - Sep 22, 2024 -- Module 4 -- Space Hazards
Week 5 -- Sep 23 - Sep 29, 2024 -- Module 5 -- Engineering Team Projects - Start
Week 6 -- Sep 30 - Oct 06, 2024 -- Module 6 -- Living with our Star
Week 7 -- Oct 07 - Oct 13, 2024 -- Module 7 -- Webb Projects Finalize and Report Out
Week 8 -- Oct 14 - Oct 20, 2024 -- Module 8 -- Hubbble
Week 9 -- Oct 21 - Oct 27, 2024 -- Module 9 -- Roman
Week 10 -- Oct 28 - Nov 03, 2024 -- Module 10 -- Engineering Team Projects - Interim Update
Week 11 -- Nov 04 - Nov 10, 2024 -- Module 11 -- Lunar
Week 12 -- Nov 11 - Nov 17, 2024 -- Module 12 -- Communications Challenge Pitches Report Out
Week 13 -- Nov 18 - Nov 24, 2024 -- Module 13 -- Exotic Universe
Thanksgiving Week -- Off Nov 25 - Dec 01 2024
Week 14 -- Dec 02 - Dec 08, 2024 -- Module 14 -- Engineering Team Projects - Final Report Out

Course Goals

To introduce students to the connection between innovative space engineering and the most significant scientific breakthroughs that have resulted from it.

Course Learning Outcomes (CLOs)

• Describe the major scientific discoveries in the history of space exploration.
• Categorize the major scientific discoveries to the engineering and technologies that enabled them.
• Develop engineering strategies to tackle the big science questions facing the future of space exploration.
• Analyze a proposed scientific investigation from the perspective of the engineer tasked with assessing requirements for the spacecraft and instruments, and deriving engineering solutions
• Effectively present complex space engineering projects to a wide range of audiences.

Textbooks

No required textbooks.  Reading material and other resources are provided on canvas for each module.  This includes papers, documents, videos, and websites.

Other Materials & Online Resources

Reading Material

Module 1: Our Place in the Universe

Module 2: Exploration of Ocean Worlds 

Module 3: Golden Eye

Module 4: Space Hazards

Module 5: Initiate Engineering Team Challenge Projects ​

Previous SSE course materials 

Module 6: Living with our Star 

Website: https://www.esa.int/Science_Exploration/Space_Science/Solar_Orbiter


Module 7: Webb Project Reports ​

Previous SSE course materials

Jovian System

https://jwstgiantplanets.github.io/web/

https://github.com/JWSTGiantPlanets/

 

Exoplanets

https://ers-transit.github.io/

 

Stellar Populations

https://ers-stars.github.io/

 

Cosmic Evolution

https://ceers.github.io/

 

Module 8: Hubble!

Module 9: Roman

Module 10: Interim Update - Engineering Team Challenge Projects ​

Previous SSE course materials

Module 11: "New Space" in Lunar and Cislunar Space

Module 12: Communication Challenge Pitches

Module 13: The Exotic Universe

Module 14: Engineering Challenge Team Projects ​

Previous SSE course materials

Student Coursework Requirements

Assessment of student progress will be measured through several methods:

• In-Class Assignments and Quizzes – Brief, quiz questions will be given throughout each module.  Students should answer the questions on canvas.  Expectations are that the answer should be a short paragraph and it can be relatively qualitative in nature. Various points depending on the number of questions in each module; 10% of total grade

• Reflection Papers – Weekly white paper (1 page) reflecting on the course material, knowledge gained, and other relevant thoughts. These will be written documents submitted through canvas.  The papers will be assessed by the instructor per the rubric, and feedback will be provided. 15 points each (see rubric); 20% of total grade
  

Rubric
1.) Did the paper accurately describe the lesson content? (5 pts)
2.) Was the paper's length appropriate? (5 pts)
3.) Did the student identify a unique reflection from the lesson that was not explicitly covered in class? (5 pts)

• James Webb Space Telescope Project – The class will be split into ~3-6 person teams and each one assigned a newly released JWST Early Release Observation data set and/or new scientific result. The teams will be responsible for building a powerpoint report w/ voiceover (20 min length) that outlines their new scientific discovery and maps the science to the JWST engineering that enabled it This not only includes the instruments that took the data, but a full observatory engineering assessment (e.g., the thermal environment, point spread function, stability, detector sensitivity, etc.). A template will be provided and students will present the results of their analysis to the class so the instructor can assess their knowledge and understanding. The project will be introduced one quarter of the way through the class after a module on Webb, and will be due half way through the course. 100 points (see rubric); 25% of total grade

Rubric
1.) Science - Clear explanation of science goals of the ERS, including sufficient depth into research (20 pts)
2.) Link to Engineering - Ability to link science to JWST instrument/spacecraft engineering that is enabling (20 pts)
3.) Comparison to Current Capabilities - Delineation of why JWST is uniquely suited to answer the science, including comparison to current state of the art (20 pts)
4.) Future Investigations with Webb - Insight on forward looking future observations of the target that could push to new discovery (20 pts)
5.) Presentation Quality - Length, clarity and impact of the presentation (20 pts)

• Engineering Challenge – Team project: The Engineering Challenge Team Projects will kick off in module 5.  Students will learn what the objectives of this project are and background information will be given.  A template will be released to students and questions will be answered.  Students will discuss their initial ideas with one another and enter the "storming" phase.

  The instructor will act as a mission Principal Investigator and give each small team a unique and bold space science challenge.  Each of the teams will perform an engineering analysis and propose a focused engineering concept in response to the space science-oriented investigation. The focus will be on the engineering challenges and driving spacecraft performance requirements, mission design, and instrument requirements.  The students will derive and present concepts, backed up by engineering analysis, that could address those challenges.  The students must also identify the primary technical risks and populate a risk matrix for their concepts. The challenge will be initiated in module 5 with students presenting initial ideas to the instructor and their peers for constructive feedback in module 10 (rough powerpoint deck is fine).   The final class of the course will be based on out briefs of the final concepts.  These will be a single powerpoint file with an integrated voice over.  The length of the presentation should be no more than 20 min.  The instructor will provide the students with a database of unique mission concept study reports built off of National Academies Decadal Survey priorities.  These will serve as examples for them to study and understand what real-world ideas and concepts look like. 100 points each (see rubric); 30% of total grade

Rubric
1.) Clear explanation of science behind your mission? (20 pts)
2.) Ability to link science to instrument/spacecraft engineering that will enable it (30 pts)
3.) Discussion of Risks and Mitigations (10 pts)
4.) Schedule, Cost, Management, Trades presentation (20 pts)
5.) Length, clarity and impact of the presentation (20 pts)

• Communication Challenge – Students will each identify one topic of their choice from the course and prepare a 2 min pitch for their classmates to generate excitement and interest.  The intended target audience is a member of congress. These pitches will be posted on Canvas and all students will be expected to participate in a discussion board and to submit comments on at least 6 other projects of their choosing. 25 points each (see rubric); 15% of total grade 

Rubric
1.) Was the pitch on time and clearly communicated? (5 pts)
2.) Did the students successfully leverage 2 or more strategies that were discussed during the lessons? (5 pts)
3.) Was the pitch structured in a way that a key "punch line" was conveyed in a compelling manner to generate a "gasp", "jaw drop", or "ah ha" moment among the audience? (5 pts)
4.) How memorable was the key point? (5 pts)
5.) Student feedback on one another’s projects.  Each student should provide comments on at least 6 other communications pitches, of their choosing.  The comments will be received on each pitch will be a part of the grade (5 pts)

Grading Policy

Score Range	Letter Grade
100-97	= A+
96-93	= A
92-90	= A−
89-87	= B+
86-83	= B
82-80	= B−
79-77	= C+
76-73	= C
72-70	= C−
69-67	= D+
66-63	= D
<63	= F

Course Evaluation

The instructor will ask the students for feedback on the course and offer to meet with all students.
Students will be encouraged to complete a survey of the instructor and course.

Course Policies

Assignment deadlines will be generally set to be one week after each module ends (i.e., ~2 weeks after a module is released).  So, students can complete quizzes, reflection papers, discussions during the week of the module or a full week after the module.  Webb projects (released in Module 3) will be due at the end of the Module 7 week.  Communications Challenge projects (released in Module 12) will be due at the end of the Module 13 week.  Engineering Team Challenge projects (released in Module 5) will be due at the end of Module 14 week. 

If students submit a weekly quiz or reflection paper after 1 week past the deadline, they will lose 25%.
If students submit a weekly quiz or reflection paper after 2 weeks past the deadline, they will lose 50%.
If students submit a weekly quiz or reflection paper after 3 weeks past the deadline, they will lose 75%.
If students submit a weekly quiz or reflection paper after 4 weeks past the deadline, they will lose 100%.

Any quizzes or reflection papers not received by the end of the semester will receive a zero.  So, modules towards the end of the year will have less weeks applicable to extension since the semester runs out.

For the 3 larger projects with powerpoint and audio voiceover (Webb Projects, Engineering Team Challenge Projects, Module 12 Communication Challenge), the projects must be submitted on time to receive credt.

Academic Policies

Deadlines for Adding, Dropping and Withdrawing from Courses

Students may add a course up to one week after the start of the term for that particular course. Students may drop courses according to the drop deadlines outlined in the EP academic calendar (https://ep.jhu.edu/student-services/academic-calendar/). Between the 6th week of the class and prior to the final withdrawal deadline, a student may withdraw from a course with a W on their academic record. A record of the course will remain on the academic record with a W appearing in the grade column to indicate that the student registered and withdrew from the course.

Academic Misconduct Policy

All students are required to read, know, and comply with the Johns Hopkins University Krieger School of Arts and Sciences (KSAS) / Whiting School of Engineering (WSE) Procedures for Handling Allegations of Misconduct by Full-Time and Part-Time Graduate Students.

This policy prohibits academic misconduct, including but not limited to the following: cheating or facilitating cheating; plagiarism; reuse of assignments; unauthorized collaboration; alteration of graded assignments; and unfair competition. Course materials (old assignments, texts, or examinations, etc.) should not be shared unless authorized by the course instructor. Any questions related to this policy should be directed to EP’s academic integrity officer at ep-academic-integrity@jhu.edu.

Students with Disabilities - Accommodations and Accessibility

Johns Hopkins University values diversity and inclusion. We are committed to providing welcoming, equitable, and accessible educational experiences for all students. Students with disabilities (including those with psychological conditions, medical conditions and temporary disabilities) can request accommodations for this course by providing an Accommodation Letter issued by Student Disability Services (SDS). Please request accommodations for this course as early as possible to provide time for effective communication and arrangements.

For further information or to start the process of requesting accommodations, please contact Student Disability Services at Engineering for Professionals, ep-disability-svcs@jhu.edu.

Student Conduct Code

The fundamental purpose of the JHU regulation of student conduct is to promote and to protect the health, safety, welfare, property, and rights of all members of the University community as well as to promote the orderly operation of the University and to safeguard its property and facilities. As members of the University community, students accept certain responsibilities which support the educational mission and create an environment in which all students are afforded the same opportunity to succeed academically. 

For a full description of the code please visit the following website: https://studentaffairs.jhu.edu/policies-guidelines/student-code/

Classroom Climate

JHU is committed to creating a classroom environment that values the diversity of experiences and perspectives that all students bring. Everyone has the right to be treated with dignity and respect. Fostering an inclusive climate is important. Research and experience show that students who interact with peers who are different from themselves learn new things and experience tangible educational outcomes. At no time in this learning process should someone be singled out or treated unequally on the basis of any seen or unseen part of their identity. 
 
If you have concerns in this course about harassment, discrimination, or any unequal treatment, or if you seek accommodations or resources, please reach out to the course instructor directly. Reporting will never impact your course grade. You may also share concerns with your program chair, the Assistant Dean for Diversity and Inclusion, or the Office of Institutional Equity. In handling reports, people will protect your privacy as much as possible, but faculty and staff are required to officially report information for some cases (e.g. sexual harassment).

Course Auditing

When a student enrolls in an EP course with “audit” status, the student must reach an understanding with the instructor as to what is required to earn the “audit.” If the student does not meet those expectations, the instructor must notify the EP Registration Team [EP-Registration@exchange.johnshopkins.edu] in order for the student to be retroactively dropped or withdrawn from the course (depending on when the "audit" was requested and in accordance with EP registration deadlines). All lecture content will remain accessible to auditing students, but access to all other course material is left to the discretion of the instructor.