1,381 | 2 hours ago : | ||||
700 | 08-07-2024, 12:00 AM : | ||||
430 | 08-05-2024, 04:19 PM : | ||||
240 | 08-02-2024, 11:03 PM : | ||||
332 | 07-28-2024, 12:34 AM : | ||||
1,056 | 07-27-2024, 03:44 PM : | ||||
2,453 | 07-26-2024, 03:31 PM : | ||||
341 | 07-23-2024, 07:36 PM : | ||||
173 | 07-23-2024, 12:45 AM : | ||||
730 | 07-21-2024, 08:55 PM : |
By Dean Dad
You have / 5 articles left. Sign up for a free account or log in.
Although I've been doing this for some time, I still don't fully understand how course levels are determined. This is particularly true in the social sciences and humanities, where you don't have relatively hard and fast prerequisites to settle the question.
Is "Women in Film" properly a 200 level course or a 300 level course? What about "Psychology of Aging" or "Civil Liberties"? More interestingly, how do you know?
In my neck of the woods, this is becoming a high-stakes question.
By law, cc's here aren't allowed to offer classes above the 200 level. The idea is that 300 level classes are intended for juniors and seniors majoring in a given discipline, so they properly belong to the four-year colleges. (In return, we have a very strong claim on having credits for 100 and 200 level classes transfer.) If we overstep our curricular bounds, the four-year schools won't take our credits in transfer, and our graduates will have to repeat -- and pay for repeating -- courses they've already taken.
Worse, it's at least theoretically possible that continued, sustained curricular overreach could land us in serious trouble with the state, which would not be a happy outcome for us.
Over time, as one might expect, there have been border skirmishes. Northern Midtier State says Advanced Basketweaving is a 200 level class, and it accepts our credits in transfer; Southern Midtier State says it's a 300 level class and gives our grads a hard time. We defend ourselves by pointing out that NMS says it's a 200-level class, but you can imagine how much that means to the faculty at SMS.
Now that the state is pushing harder for regularized transfer of credits, the stakes are being raised. Now we aren't just talking about a course here and there; we're talking about the entire midsection of the curriculum. Some of the four-year schools have started renumbering some 200 level courses as 300 level, specifically to defeat the transfer initiative. (They'd rather have the students pay them for the course a second time.) Of course, others haven't, and there's a surprising level of disagreement among the four-year schools when you get down to specifics. And, to be fair, we'd love to run some of the classes that the four-year schools claim as their exclusive domain.
Both sides have an economic interest in the outcome of the squabbling, so nobody can credibly claim impartiality. In the absence of some sort of authoritative list of what goes where, it can be hard to know where intellectual arguments end and resource battles begin.
So I'll ask my wise and worldly readers, since y'all can afford a certain honesty.
How do you know a 300 level class when you see one? Is there a reasonable way to distinguish the 200 from the 300 level on a course-by-course basis? And if there is, how does one square "statewide transfer" with local faculty governance?
State Representative Randy Fine says that after he repeatedly called the state university chancellor about a “Muslim
More from confessions of a community college dean.
Implementation matters.
A review of Paved Paradise by Henry Grabar.
4 /5 Articles remaining this month.
Let your curiosity lead the way:
Apply Today
Chemistry major.
We provide you with the foundation to pursue a variety of careers in scientific research and discovery, education, medicine, engineering, or careers outside of chemistry.
Course Number | Course Title | Credit(s) |
---|---|---|
Chem 105* or Chem 111A | General Chemistry I | 3 |
Chem 106* or Chem 112A | General Chemistry II | 3 |
Chem 151 | General Chemistry Lab I | 2 |
Chem 152 | General Chemistry Lab II | 2 |
Chem 261 | Organic Chemistry with Lab I | 4 |
Chem 262 | Organic Chemistry with Lab II | 4 |
Math 131 | Calculus I | 3 |
Math 132 | Calculus II | 3 |
Math 233 | Calculus III | 3 |
Physics 197 or 191/191L | Physics I | 4 |
Physics 198 or 192/192L | Physics II | 4 |
Chem 401 | Physical Chemistry I | 3 |
Chem 402 | Physical Chemistry II | 3 |
Chem 461 | Inorganic Chemistry | 3 |
Students earning a Chemistry Major must take 9 additional units in chemistry at the 300 level or above (not including Chem 490 or Chem 495). At least 3 of these units must be an Advanced Lab (see below).
*Please note: In certain instances, students may substitute Chem 105/106 for Chem 111A/112A. Please consult Chemistry's Director of Undergraduate Studies (Prof. Richard Mabbs, [email protected] ) for details.
At least one advanced lab, selected from:
Course Number | Course Title | Credit(s) |
---|---|---|
Chem 358 | Organic Chemistry Laboratory II | 4 |
Chem 435 | Nuclear and Radiochemistry Laboratory | 3 |
Chem 445 | Instrumental Methods: Physical Chemistry Laboratory | 3 |
Chem 462 | Polymer Synthesis Laboratory | 3 |
Chem 470 | Inorganic Chemistry Laboratory | 3 |
Students have the advantage of planning their course program with their adviser in accordance with personal interests. Some graduate courses also are available to seniors. All chemistry coursework must be taken in residence at Washington University to be eligible to earn a chemistry major. A minimum grade of C- must be earned in each course to count toward the chemistry major.
Note: Per the College of Arts & Sciences guidelines, if a student has a major and a minor or has two minors, only introductory (100- and 200-level) courses may be counted, when relevant, toward the requirements of both programs. All advanced (300- and 400-level) courses must be unique to each program, i.e., no advanced course may "double-count" for the coursework needed to fulfill either program's minimal requirements. Should a student's major/minor programs require the same course, a departmentally-sanctioned elective must be chosen to replace the course in one of the programs.
In an effort to develop an annual program evaluation in cooperation with the Higher Learning Commission, the Chemistry Department offers an exit interview and an exit exam to all graduating seniors. All graduating majors are required to sit for the exam, the ACS Diagnostic of Undergraduate Knowledge in Chemistry exam. It takes one hour and includes questions with multiple choice answers. The performance on this exam does not affect the student’s transcript of GPA. The exam is tentatively scheduled for the week of Commencement each Spring.
Course Number | Course Title | Credit(s) |
---|---|---|
Chem 105* or Chem 111A | General Chemistry I | 3 |
Chem 106* or Chem 112A | General Chemistry II | 3 |
Chem 151 | General Chemistry Lab I | 2 |
Chem 152 | General Chemistry Lab II | 2 |
Chem 261 | Organic Chemistry with Lab I | 4 |
Chem 262 | Organic Chemistry with Lab II | 4 |
Chem 401 | Physical Chemistry I | 3 |
Chem 402 | Physical Chemistry II | 3 |
Chem 461 | Inorganic Chemistry | 3 |
Chem 481 | General Biochemistry I | 3 |
Chem 482 | General Biochemistry II | 3 |
Math 131 | Calculus I | 3 |
Math 132 | Calculus II | 3 |
Math 233 | Calculus III | 3 |
Physics 197 or 191/191L | Physics I | 4 |
Physics 198 or 192/192L | Physics II | 4 |
Biol 2960 | Principles of Biology I | 4 |
Biol 2970 | Principles of Biology II | 4 |
Students must select at least one advanced lab from:
Course Number | Course Title | Credit(s) |
---|---|---|
Chem 358 | Organic Chemistry Laboratory II | 4 |
Chem 435 | Nuclear and Radiochemistry Lab | 3 |
Chem 445 | Instrumental Methods: Physical Chemistry | 3 |
Chem 462 | Polymer Synthesis Laboratory | 3 |
Chem 470 | Inorganic Chemistry Laboratory | 3 |
Biol 4522 | Laboratory in Protein Analysis, Proteomics and Protein Structure | 3 |
Biol 4523 | Molecular Methods in Enzyme Analysis | 4 |
All chemistry course work must be taken in residence at Washington University to be eligible to earn a chemistry major. A minimum grade of C- must be earned in each course to count toward the chemistry major.
Minor requirements.
A student planning to complete a minor in Chemistry must complete the following pre-requisite courses:
Course Number | Course Title | Credit(s) |
---|---|---|
Chem 105* or Chem 111A | General Chemistry I | 3 |
Chem 106* or Chem 112A | General Chemistry II | 3 |
Chem 151 | General Chemistry Lab I | 2 |
Chem 152 | General Chemistry Lab II | 2 |
Chem 261 | Organic Chemistry with Lab I | 4 |
Chem 262 | Organic Chemistry with Lab II | 4 |
Math 131 | Calculus I | 3 |
Math 132 | Calculus II | 3 |
Math 233 | Calculus III | 3 |
Physics 197 or 191/191L | Physics I | 4 |
Physics 198 or 192/192L | Physics II | 4 |
In addition, nine units of Chemistry encompassing at least two sub-disciplines are required at the advanced (300+ level). Chem 490 and Chem 495 are specifically excluded from the minor. *Please note: In certain instances, students may substitute Chem 105/106 for Chem 111A/112A. Please consult Chemistry's Director of Undergraduate Studies (Prof. Richard Mabbs, [email protected] ) for details.
Latin Honors are determined on the basis of a student’s performance through eight semesters in college. To be eligible for Latin Honors, the student must have maintained a 3.65 GPA and must complete the Latin Honors curriculum in Chemistry.
The Latin Honors Curriculum for Chemistry majors requires the completion of a second advanced chemistry lab. One of the advanced labs must be a Physical Chemistry Lab (Chem 435 or Chem 445). The other advanced lab must be a Synthetic Chemistry Lab (Chem 358, Chem 462, or Chem 470).
The Latin Honors Curriculum for Chemistry: Biochemistry Concentration majors requires the completion of an additional 3 units of advanced biochemistry or biological chemistry course credit. Courses may be chosen from the following list: Biol 334, Biol 349, Chem 453, Chem 464, Chem 483, Chem 485, Chem 510, Chem 358, Chem 435, Chem 445, Chem 462, Chem 470, Biol 4522, or Biol 4523.
Departmental or “English” honors are awarded by the Chemistry Department for the successful completion of a rigorous program of study in Chemistry, which emphasizes research as an important part of Chemistry education.
To earn Chemistry Department honors, a student must first complete the Latin Honors Curriculum and must also achieve the following:
Department Honor | Chemistry GPA Requirement | Research Requirement |
---|---|---|
With distinction | 3.50 | At least one semester of Chem 490 research* |
With high distinction | 3.65 | At least two semesters of Chemistry research, one of which is Chem 495 |
With highest distinction | 3.80 | At least two semesters of Chemistry research, one of which is Chem 495 |
*for students with alternate research experiences, petitions will be considered Chemistry research is defined as a research project performed under the direction of a Chemistry faculty member or a research project approved by the Chemistry Undergraduate Work Committee. The Chemistry GPA is calculated from the grades received in Chemistry courses and Chemistry prerequisites (including lower-level Chemistry courses, Math, Physics, and Biology (if pursuing the Biochemistry Focused major). The level of Department Honors a student achieves will appear on the student’s final transcript.
Consult WashU's catalog of programs and degree requirements
News + events, get involved, search metrostate.edu.
About the program.
The computer science major provides a firm foundation in computing principles, the development of effective problem-solving and mathematical skills, and the systematic application of theory to the design and development of software. Metropolitan State’s computer science program, available on campus in Minnesota, also provides preparation for graduate school in computer science. A minimum of 16 semester credits of major requirements must be completed at Metro State to earn a Bachelor of Science in Computer Science.
Computer science is the study of systematic approaches for the design and development of application systems that support the functioning of core industries and services and the theory that underpins these techniques. The theoretical issues range from algorithms and data structures that can be readily applied to far more abstract questions such as what is computable and the fundamental questions regarding computing efficiency. The field also studies the software and hardware approaches for the design of computer systems.
According to the U.S. Department of Labor, the computer science field is expected to experience exceptional growth, with rates that are projected to exceed all other occupational categories. Most graduates of the program are successfully employed in the industry, and some Metro State computer science program undergraduates have gone on to master's and PhD programs at well-known graduate schools in the country.
The computer science program is designed to help graduates achieve the following career and professional objectives. Graduates will:
Current students: declare this program.
Once you’re admitted as an undergraduate student and have met any further admission requirements your chosen program may have, you may declare a major or declare an optional minor .
Apply to Metropolitan State: Start the journey toward your Computer Science BS now. Learn about the steps to enroll or, if you have questions about what Metropolitan State can offer you, request information, visit campus or chat with an admissions counselor .
Get started on your Computer Science BS
More ways to earn your degree: Metropolitan State offers the flexibility you need to finish your degree. Through programs at our partner institutions, you can find a path to getting your Computer Science BS that works best for you.
About your enrollment options
Students interested in the Computer Science Bachelor of Science degree will be given premajor status when admitted to the university. They will be assigned an academic advisor in the College of Sciences.
For acceptance into the Computer Science major, students must submit an Undergraduate Program Declaration Form when the following conditions are met:
Students in premajor status are unable to take any 400-level major courses. Official acceptance into this major program and the review of transfer coursework equivalency and qualifications are done through the Computer Science and Cybersecurity (CSC) Department.
Requirements for completing the Computer Science major
+ premajor foundation (28 credits).
To declare the Computer Science major, students are required to complete the following premajor foundation courses with a grade of C- or higher and a minimum GPA of 2.5 for ICS 141, ICS 240 and MATH 215 or transfer equivalents. For further details, reference the General Guidelines section below.
Choose one of the following two courses.
This course introduces fundamental concepts in computer programming and the development of computer programs to solve problems across various application domains. Topics include number systems, Boolean algebra, variables, decision-making and iterative structures, lists, file manipulation, and problem deconstruction via modular design approaches. Lab work and homework assignments involving programming using a language such as Python form an integral part of the course.
Full course description for Computational Thinking with Programming
This course is designed to provide a fast-paced exposure to the C programming language for students majoring in a computer-related discipline. The following topics are briefly reviewed using C syntax: looping, selection, variables, scope rules, functions and pass-by-value arguments. New topics include pass-by-address arguments, formatted and unformatted I/O, user defined types (enum, struct, union), preprocessing directives, file handling, pointers, pointer arithmetic, string manipulation and selected library functions.
Full course description for C Programming
Complete all of the following five courses.
This course is designed to prepare students for calculus. Topics include polynomial, rational, exponential, logarithmic, and trigonometric functions; the algebra of functions; multiple function representations; and an introduction to analytic geometry.
Full course description for Precalculus
This course covers a variety of important topics in math and computer science. Topics include: logic and proof, sets and functions, induction and recursion, elementary number theory, counting and probability, and basic theory of directed graphs.
Full course description for Discrete Mathematics
Structure, design, and implementation of object-oriented computer programs. Topics include sequential structures, selection structures, repetition structures, recursion, quadratic sorting algorithms, exceptions, objects, and classes. Emphasis on methods, parameter passing, arrays, and arrays of objects. Exploration of problem-solving and algorithm-design techniques using pseudocode and Unified Modeling Language (UML). Design of good test cases and debugging techniques are highlighted. Programming projects involving multiple classes.
Full course description for Problem Solving with Programming
Introduces machine language, digital logic and circuit design, data representation, conventional von Neumann architecture, instruction sets and formats, addressing, the fetch/execute cycle, memory architectures, I/O architectures, as well as hardware components, such as gates and integrated chips.
Full course description for Computer Organization and Architecture
This course provides basic introduction to data structures and algorithms and emphasizes the relationship between algorithms and programming. Students will learn intermediate object-oriented design, programming, testing and debugging. Topics include inheritance, polymorphism, algorithm complexity, generic programming, linked list, stack, queue, recursion, trees, hashing, searching, and sorting.
Full course description for Introduction to Data Structures
Calculus requirement: choose one of the following two courses.
This course provides an overview of the differential calculus for single and multivariable functions and an introduction to the integral calculus and differential equations, with an emphasis on applications to the natural and physical sciences. Particular topics covered in the course include limits, ordinary and partial derivatives, applications of derivatives, definite integrals, fundamental theorem of calculus, applications of definite integrals, models involving differential equations, Eulers method, equilibrium solutions.
Full course description for Applied Calculus
Since its beginnings, calculus has demonstrated itself to be one of humankind's greatest intellectual achievements. This versatile subject has proven useful in solving problems ranging from physics and astronomy to biology and social science. Through a conceptual and theoretical framework this course covers topics in differential calculus including limits, derivatives, derivatives of transcendental functions, applications of differentiation, L'Hopital's rule, implicit differentiation, and related rates.
Full course description for Calculus I
Once the premajor foundation are complete, students must complete all of the following courses with a grade of C- or higher.
The Capstone course, ICS 499, should be taken in the final semester of your program, or at least during the semester you complete the last of the other required major courses.
Students who have not declared their major or have not been accepted into the major will not be allowed to take any 400-level major courses. For further details on prerequisites, reference the General Guidelines section below.
Covers concepts and methods in the definition, creation and management of databases. Emphasis is placed on usage of appropriate methods and tools to design and implement databases to meet identified business needs. Topics include conceptual, logical and physical database design theories and techniques, such as use of Entity Relationship diagrams, query tools and SQL; responsibilities of data and database administrators; database integrity, security and privacy; and current and emerging trends. Use of database management systems such as MySQL. Coverage of HCI (Human Computer Interaction) topics and development of front ends to databases with application of HCI principles to provide a high level usability experience. Overlap: ICS 311T Database Management Systems.
Full course description for Database Management Systems
Exploration of the design and implementation of data structures and algorithms fundamental to computer systems and applications and to software engineering. Topics include trees, graphs, basic analysis of algorithmic complexity, fundamental questions of computability, and introduction to the algorithmic basis of intelligent systems. Programming projects.
Full course description for Algorithm Design and Analysis
This course is a comprehensive introduction to the principal features and design of programming languages. It provides a comparative study of programming paradigms including structured programming, object-oriented programming, functional programming and logic programming. This course is a survey of programming concepts and constructs including data types, control structures, subprograms and parameter passing, nesting and scope, derived data types, input and output, and dynamically varying structures. Also covered are the principles of lexical and semantics analysis.
Full course description for Organization of Programming Languages
System development using the object-oriented paradigm. Programming topics include: inheritance, polymorphism, dynamic linking, generics, Graphical User Interfaces, and data serialization. Use-case and state-based approaches for the discovery of conceptual classes. Design principles including the Liskov Substitution Principle, Open Closed Principle, and Stable Dependencies Principle. Design patterns such as Factory, Iterator, Adapter, Facade, Bridge, Observer, Command, State, Composite, Singleton, and Mediator. Employment of design principles, design patterns, and the Model View Controller in the design of object-oriented systems. System implementation. Refactoring. Group projects.
Full course description for Object-Oriented Design and Implementation
Covers design and development of parallel and distributed algorithms and their implementation. Topics include multiprocessor and multicore architectures, parallel algorithm design patterns and performance issues, threads, shared objects and shared memory, forms of synchronization, concurrency on data structures, parallel sorting, distributed system models, fundamental distributed problems and algorithms such as mutual exclusion, consensus, and elections, and distributed programming paradigms. Programming intensive.
Full course description for Parallel and Distributed Algorithms
Principles and practices of the OSI and TCP/IP models of computer networks, with special emphasis on the security of these networks. Coverage of general issues of computer and data security. Introduction to the various layers of network protocols, including physical, data link, network, and transport layers, flow control, error checking, and congestion control. Computer system strengths and vulnerabilities, and protection techniques: Topics include applied cryptography, security threats, security management, operating systems, network firewall and security measures. Focus on secure programming techniques. Programming projects.
Full course description for Networks and Security
Principles, techniques, and algorithms for the design and implementation of modern operating systems. Topics include operating system structures, process and thread scheduling, memory management including virtual memory, file system implementation, input output systems, mass storage structures, protection, and security. Students will implement process, memory, and file management algorithms.
Full course description for Operating Systems
This course focuses on the theory and practice of effectively and efficiently building software systems that satisfy the requirements placed upon them by customers. This course gives an overview of the software lifecycle and introduces various process models used to develop software.
Full course description for Software Engineering and Capstone Project
Either eight upper-division credits, or a minor in a field approved by the academic advisor, are required for the Computer Science major.
Complete a minimum of eight upper-division credits (i.e, 300-level, or higher) of elective courses. Consult with academic advisor on acceptable electives.
Note the following:
-At least 4 credits of electives must come from upper-division (i.e., 300-level, or higher) ICS courses, not already required for the major, with the following exceptions: ICS 350I, ICS 370, ICS 38*, and ICS 48*.
-The contents of ICS 490 Special Topics in Information and Computer Sciences and ICS 492 Seminar on Emerging Technologies vary from semester to semester and may be taken more than once for elective credits (with permission of the CSC department) as long as they cover different topics.
-Any 300-level or higher CFS, CYBR, ICS, MATH or STAT course may be used as an elective except for the following courses: CFS 350I, CFS 499, CYBR 350I, CYBR 362, CYBR 498, CYBR 499, ICS 370, MATH 350I, MATH 499 and STAT 350I.
-A maximum of 4 credits in ICS 350I Individualized Internship spread over 1-3 semesters may be used as elective credits.
Work with your academic advisor to assess if the minor option is appropriate for your degree and career plan. Students with a previous bachelor's degree should talk to their advisor about whether that degree can be used in lieu of a minor. Recommended fields for a minor include (but are not limited to): Industrial and Applied Mathematics, Applied Statistics, Biology, Chemistry, Computer Forensics, Cybersecurity, Design of User Experience, Game Studies, Physics, Project Management, and Technical Communication.
Transfer courses.
Transfer coursework equivalency is determined by the Computer Science and Cybersecurity (CSC) department and is initially evaluated upon admission with updates documented on the Degree Audit Report (DARS). When transferring coursework, please be aware that many universities, community, and technical colleges offer courses equivalent to some of our pre-major courses. Sometimes a course at the lower division at another university or college is equivalent to one of our upper-division courses, or an upper-division course at another institution is equivalent to one of our lower-division courses. To calculate upper-division credits for the major electives or for university graduation requirements, the status of the course at the institution where the student took the course is what matters.
Students must be aware of and abide by prerequisites for all courses for which they are enrolled. No student may be enrolled in a course unless they have completed all course prerequisites with a grade of C- or higher. Students will be administratively dropped from a course if they have not met the required prerequisites. For some courses, prerequisites are enforced automatically by the registration system. If your DARS report shows you have met the prerequisites for a course, and the registration system will not let you register, please contact your academic advisor.
Academic requirements for master's degrees, academic requirements for the doctor of philosophy and doctor of musical arts degrees, course designations, grading system.
In recognition that the objectives of master’s degrees differ for various departments and for individual students, especially in the importance given to research, two general plans for master’s degrees may be followed. The Master's Thesis Option is for MA or MS degrees with a thesis based on individual research and a final oral examination. The Master's Non-Thesis Option is for MA, ME, MEM, MFA, MPH, or MS degrees without a thesis but requiring a comprehensive examination, major project or other culminating experience to be administered by the academic unit.
Within the framework of these general regulations, it is expected that a relevant program of study will be planned for each candidate for the master's degree by the student and the faculty advisor or advisory committee. If applicable, a Planned Program of Study (PPOS) must be submitted to the School of Graduate Studies by the end of the second semester. Check with your program to determine if a PPOS is required. Such a program should include appropriate courses, thesis, and/or project hours, and may also include, where relevant, such experiences as field work or practicum. Guides to submitting and updating the PPOS through the Student Information System (SIS) are available from the University Registrar . Some departments have the degree requirements coded in the Student Information System and do not require a PPOS. For these programs, the academic requirements report in the Student Information System replaces the PPOS.
Unless stated higher by the department, a minimum cumulative grade point average of 3.00 is required for the awarding of the graduate degrees from the School of Graduate Studies. The master's degree under the thesis option requires a minimum of 30 total semester hours, with 18-21 regular hours of course work, plus a thesis equivalent to at least 9-12 semester hours of registration. At least 18 hours of coursework must be at the 400 level or higher. Courses taken at the 300 level should only be allowed when no 400 level course is available, or under unusual circumstances, both of which must be approved in advance via a petition to Graduate Studies. At least 12 semester hours of course work must be graded. Once registered for thesis credit (Course 651), a student must continue 651 registration each succeeding regular semester until graduation. However, if a student is registered for course work or research toward the doctorate in the semester in which the thesis examination is expected to occur, concurrent registration for 651 is not required.
Each student must prepare an individual thesis. Joint theses are not permitted. The written thesis must conform to regulations concerning format, quality, digital accessibility, and time of submission as established by the School of Graduate Studies. Detailed instructions can be obtained from the School of Graduate Studies website.
For completion of master’s degrees under the thesis option, an oral examination (defense) of the master’s thesis is required. This examination is conducted by a committee of at least three members of the University faculty. The candidate’s thesis advisor customarily serves as the chair of the examining committee. The other members of the committee are appointed by the chair of the department or curricular program faculty supervising the candidate’s course of study. The examining committee must agree unanimously that the candidate has passed the thesis examination. When the research relates to proprietary material, the student and advisor are responsible for making preliminary disclosures to the sponsor sufficiently in advance to permit timely release of the thesis, and these plans should be disclosed when the thesis is submitted to the School of Graduate Studies. These arrangements, and any requests for delayed publication, must be disclosed to the School of Graduate Studies using the Electronic Thesis and Dissertation (ETD) Document Approval and Certification Form as part of the final graduation materials .
Unless stated higher by the department, a minimum cumulative grade point average of 3.00 is required for the awarding of the graduate degrees from the School of Graduate Studies. The minimum requirements for the master’s degree under the non-thesis option are 30 semester hours of course work with at least 12 semester hours of letter-graded course work, and a comprehensive examination, approved project or other culminating experience. At least 18 semester hours of course work must be at the 400 level or higher. Courses taken at the 300 level should only be allowed when no 400 level course is available or under unusual circumstances, both of which must be approved in advance via a petition to Graduate Studies.
The Case School of Engineering offers a non-thesis, course focused master's degree. The minimum requirements for the course only masters are 30 semester hours of coursework with at least 12 hours of letter-graded coursework and at least 24 hours at the 400 level or above.
Each candidate for the master’s degrees under the non-thesis option must pass satisfactorily a comprehensive examination, project or other culminating experience to be administered by the department or curricular program committee. The examination may be written or oral or both. A student must be registered during the semester in which any part of the comprehensive examination is taken. If not registered for other courses, the student will be required to register for one semester hour of EXAM 600 before taking the examination.
Case Western Reserve University awards University Certificates as a credential for completing a set of courses (possibly in combination with other learning experiences) that focus on a specific topic or theme. A graduate certificate program contains courses taught at the graduate or professional level. The program must include a minimum of 15 credit hours. The student must earn a minimum GPA of 3.00 in order for the graduate certificate to be awarded. Certificate programs may be embedded within degree programs and offered as an option for degree-seeking students, or can be stand-alone programs to which students apply and are granted admission. Courses taken as part of a certificate program may be double counted for degree programs. Certificates are recorded in the Student Information System and will appear as awarded on the student’s official University transcript upon final confirmation from the School of Graduate Studies.
The degrees of Doctor of Philosophy and Doctor of Musical Arts are awarded in recognition of in-depth knowledge in a major field and comprehensive understanding of related subjects together with a demonstration of ability to perform independent investigation and to communicate the results of such investigation in an acceptable dissertation.
Within the framework of these general regulations, it is expected that a relevant program of study will be planned for each candidate for the doctorate by the student and the faculty advisor or advisory committee. This Planned Program of Study (PPOS), if applicable, must be submitted to the School of Graduate Studies before the end of the second semester. Guides to submitting and updating the PPOS through the Student Information System (SIS) are available from the University Registrar. Some programs have the degree requirements built into the Student Information System and do not require a PPOS. For these programs, the Academic Requirements Report in the Student Information System replaces the PPOS.
Unless stated higher by the department, a minimum cumulative grade point average of 3.00 is required for the awarding of the graduate degrees from the School of Graduate Studies. Although specific requirements vary among departments, students entering with a bachelor’s degree will satisfactorily complete a minimum of 36 semester hours of courses (which may include independent study/research), tutorials, and seminars. All course work must be at the 400 level or higher, and at least 24 semester hours of course work must be graded. For students entering with an approved master’s degree, completion of at least 18 semester hours of 400 level or higher course work and at least 12 semester hours of this course work must be graded. A minimum of 18 semester hours of dissertation research (Course 701) is required for all PhD students.
Unless stated higher by the department, a minimum cumulative grade point average of 3.00 is required for the awarding of the graduate degrees from the School of Graduate Studies. A minimum of 36 credit hours of course work (at least 24 hours must be graded work and at the 400 level or above) is required for the DMA, together with a minimum of 18 hours of applied music and 6 hours of lecture-recital/document preparation. Students are also required to give a recital, to pass a jury and qualifying examinations, and to demonstrate proficiency in two foreign languages relevant to their field of study. Students should contact the Department of Music for additional details.
For students matriculating in Summer 2019 and later, in order to accurately reflect the time and effort accrued in completing the dissertation, 36 hours of advanced dissertation research will be posted to the PhD/DMA student's record upon successful completion of the dissertation defense and submission of final certification paperwork.
In order to meet the requirements for the doctorate, a student must pass a general examination (or a series of examinations covering different fields) specified and administered by the student’s department or supervising committee. The examination generally precedes Advancement to Candidacy. A student must be registered during the semester in which any part of the general or qualifying examination is taken. If not registered for other courses, the student will be required to register for one semester hour of EXAM 700 , before taking the examination. A student who fails the examination on the first attempt may be permitted to take the examination a second time within one year at the discretion of the department. Except in unusual circumstances, a student who fails the examination a second time will be separated from further graduate study within the same department or program.
The formal acceptance of a student as a candidate for the doctoral degree is the responsibility of the student’s department or the committee supervising the doctoral program in accordance with the written procedures of the academic unit. Once a student has advanced to candidacy, notification to the School of Graduate Studies should be submitted using the Advancement to Candidacy form . Generally, advancement to candidacy allows the student to enter the dissertation research phase of the degree program, and occurs after all course work and exam requirements are satisfied. At its discretion the supervising unit may require a student to pass qualifying examinations before candidacy is granted. Students are expected to make regular and continuous progress toward the degree. Advancement to candidacy in a PhD program should occur within a maximum of 6 years post-matriculation with a bachelor’s degree (no later than at the completion of 36 semester hours of graduate study) and 4 years post-matriculation with a master’s degree (no later than at the completion of 18 semester hours of graduate study). Students may continue in pre-candidacy status beyond this time on a limited basis by means of a petition to the School of Graduate Studies by the student and program director, based on evidence of student progress toward the degree. Individual programs can require Advancement to Candidacy before the time limit set in this policy.
The School of Graduate Studies must be notified promptly in writing of the decision concerning a student’s advancement to candidacy, and a copy of the notification must be sent to the student concerned. A student who is refused candidacy status may not undertake further study for credit toward the doctoral degree within the same department or supervising unit. With the approval of both the department concerned and the School of Graduate Studies, such a student may:
When a student has been advanced to candidacy, they may begin dissertation research by formally registering for course 701 credits. At the point at which students begin registering for course 701, the department must identify a University faculty member who will serve as the doctoral student’s principal research advisor and formally notify the School of Graduate Studies. Students who have been advanced to candidacy may register for 1-9 credits of course 701 each fall and spring semester (or up to 6 credits for the summer when needed).
In certain cases, students who have not advanced to candidacy may be given predoctoral standing status at the discretion of the department and upon submission of the Predoctoral Standing form to the School of Graduate Studies. These students may register for up to a total of 6 credit hours of course 701 over a maximum of two regular semesters. Pre-Candidacy 701 hour(s) may be taken concurrently with coursework.
Once a student begins registration of 701 hours, they must register for at least one credit hour of 701 each semester until graduation. Doctoral students have five consecutive academic years from the semester of the first credited 701 registration, including leaves of absence, to complete all requirements for the doctorate.
All candidates for the PhD degree must electronically submit a dissertation as evidence of their ability to conduct independent research at an advanced level. The dissertation must represent a significant contribution to existing knowledge in the student’s field, and at least a portion of the content must be suitable for publication in a reputable professional journal or as a book or monograph. Students must prepare their own dissertations. Joint dissertations are not permitted. The dissertation must conform to regulations concerning format, quality, digital accessibility, and time of submission as established by the School of Graduate Studies in the Electronic Theses and Dissertation Guidelines . Research work connected with a dissertation is to be carried out under the direct supervision of a member of the University faculty.
When the research relates to proprietary material, the student and advisor are responsible for making preliminary disclosures to the sponsor in advance to permit timely release of the dissertation. These arrangements, and any requests for delayed publication, must be disclosed when the dissertation is submitted to the School of Graduate Studies on the Electronic Thesis and Dissertation (ETD) Document Approval and Certification Form as part of the final graduation materials . Once approved by the School of Graduate Studies, dissertations are to be uploaded to OhioLINK before certification of the doctorate. Because dissertations are made public immediately upon acceptance, they should not contain unauthorized, proprietary, or classified material.
Each doctoral student is responsible for becoming sufficiently familiar with the research interests of the department or program faculty to choose in a timely manner a faculty member who will serve as the student’s research advisor. The research advisor is expected to provide mentorship in research conception, methods, performance, and ethics, as well as focus on development of the student’s professional communication skills, building professional contacts in the field, and fostering the professional behavior standard of the field and research in general. The research advisor also assists with the selection of the other faculty to serve as members of the dissertation advisory and defense committee.
The composition of each student’s dissertation committee must have formal approval by the School of Graduate Studies on recommendation of the chair of the department, division, or curricular program committee.
The dissertation committee includes:
Throughout the development and completion of the dissertation, members of the dissertation advisory committee are expected to provide constructive criticism and helpful ideas generated by the research problem from the viewpoint of their particular expertise. Each member will make an assessment of the originality of the dissertation, its value, the contribution it makes, and the clarity with which concepts are communicated, especially to a person outside the field. The doctoral student is expected to arrange meetings and maintain periodic contact with each committee member. A meeting of the full committee for the purpose of assessing the student’s progress should occur at least once a year until the completion of the dissertation.
Each doctoral candidate is required to pass a final oral examination in defense of the dissertation. The examination may also include an inquiry into the candidate’s competence in the major and related fields.
The defense must be scheduled with the School of Graduate Studies no later than three weeks before the date of the examination. The chair of the examining committee should give approval to schedule the defense when the written dissertation is ready for public scrutiny. The candidate must provide to each member of the committee a copy of the completed dissertation at least ten days before the examination so that the committee members have an opportunity to read and discuss it in advance.
Scheduled defenses are publicized by the School of Graduate Studies, and any member of the University may be present at that portion of the examination pre-designated as public by the chair of the dissertation defense committee. Others may be present at the formal defense only by invitation of that chair.
It is expected that all members of the dissertation defense committee be present at the defense. Exceptions to this rule: a) must be approved by petition to the School of Graduate Studies and only under extraordinary circumstances; b) no more than one voting member can ever be absent; c) the absent member must participate through real-time video conferencing at the department’s expense; and d) the student must always be physically present. The petition should outline who will be attending the defense in person and who will be attending via video conferencing.
The dissertation defense committee is responsible for certifying that the quality and suitability of the material presented in the dissertation meet acceptable scholarly standards. A student will be certified as passing the final oral examination if no more than one of the voting members of the committee dissents.
The promotion of scholarship and the discovery of new knowledge through research are among the major functions of Case Western Reserve University. If this research is to be meaningful and beneficial to humanity, involvement of human subjects as experimental participants is necessary. It is imperative that investigators in all disciplines strive to protect human subjects. University policy and federal regulations demand compliance. Per federal regulations (45 CFR 46), all research involving human subjects requires submission of an IRB application prior to initiation of research to the Case Western Reserve IRB.
Each IRB application must have a faculty member noted as the Responsible Investigator. Applications that are not fully completed as instructed will not be accepted. See the University IRB Policies and Procedures on the involvement of human participants in research for guidelines under which investigations involving human subjects may be pursued.
Although there is no general foreign language requirement for the doctorate, each department or supervising committee may set such requirements as are appropriate to the student’s program of study. It is the student’s responsibility to ascertain the foreign language requirements approved by the supervising unit.
Courses numbered 100 to 399 are undergraduate-level courses. Courses numbered 400 and higher are graduate-level courses.
Graduate Students are expected to take courses at the 400 level or above. Some departments do allow courses at the 300 level to be used for master's programs, however, this should only occur when no graduate-level course is available or under unusual circumstances, both of which require a petition to Graduate Studies. Departments are strongly encouraged to create cross-listed graduate-level courses to accommodate this need. Graduate-level versions of courses must require additional work beyond that which is assigned to the undergraduate students in the course.
See the University Registrar section of this Bulletin for a list of valid grades for the School of Graduate Studies and their appropriate use in assigning to graduate students. The only grades that can be changed after they have been assigned by the instructor are Incompletes (I). All others will remain permanently on the student’s academic record. Additional work cannot be done to change an existing grade to a higher grade.
There are some grading schemes in the School of Graduate Studies that have important policy implications. They are:
Grades of I can only be assigned for letter-graded and Pass/No Pass courses for extenuating circumstances and only when a student who is passing the course fails to complete a small, evaluative segment of the course. Students may not sit in the same course in a later semester to complete the work required for the original course. All work for the incomplete grade must be made up and the change of grade recorded in the Student Information System (SIS) by the date specified by the instructor, but no later than the 11 th week of class in the semester following the one in which the I grade was received.
In exceptional circumstances, a student may petition for an extension of the incomplete deadline. The petition should be submitted by the original deadline date and must contain the reasons for the extension, a proposed new completion date, and a letter from the instructor supporting the extension.
When a student fails to submit the work required for removing the Incomplete by the date established, the instructor will enter a final grade that assumes a failing performance for the missing work. In the absence of the assignment of a grade by the instructor, the Registrar will convert the I to F when the deadline for making up Incomplete grades from a previous semester has passed.
Some graduate courses are graded on a Pass/No Pass basis, and students need to be aware of the regulations governing letter graded and Pass/No Pass credits. Of the minimum credit hours required beyond the bachelor’s degree to complete course work requirements, at least 12 credits must be letter graded for the master’s degree, and at least 24 credits must be letter graded for the PhD degree. For students with approved master’s degrees who are admitted to PhD programs, at least 12 credits of the required minimum of 18 credits of course work must be letter graded. Letter graded courses should be the courses most central to the student’s plan of study. Additional requirements of letter graded course work may be specified by departmental policy. Students in the School of Graduate Studies do not have the option to change a graded course to Pass/No Pass.
Grades of Satisfactory (S) and Unsatisfactory (U) are to be used exclusively for 651 thesis research and 701 dissertation research and the M.S. Project course (695) in the School of Engineering . Satisfactory indicates an acceptable level of progress towards completion of the research required for the degree, and Unsatisfactory indicates an unacceptable level of progress towards completion of the research for the degree. Any student who receives a grade of U will automatically be put on academic probation, and if a second U is received, the student will be separated from further study in their degree program. Students who receive a U must repeat the course for the same number of credits the following semester.
Print this page.
The PDF will include all information unique to this page.
WGU subreddit specializing in degrees in the College of IT.
Hello can anyone explain this admission guideline or where I can find level 300 coursework
By continuing, you agree to our User Agreement and acknowledge that you understand the Privacy Policy .
You’ve set up two-factor authentication for this account.
Create your username and password.
Reddit is anonymous, so your username is what you’ll go by here. Choose wisely—because once you get a name, you can’t change it.
Enter your email address or username and we’ll send you a link to reset your password
An email with a link to reset your password was sent to the email address associated with your account
IMAGES
COMMENTS
To be considered for enrollment into a College of IT bachelor's degree program, you must possess a high school diploma or its equivalent AND demonstrate program readiness through one of the following: Option 1: Submit transcripts documenting completion of previous IT coursework. IT coursework must be 300 level or higher.
Option 3: Submit official record of completion of a transferable IT certification, some of which may provide transfer credit into various programs. Option 4: Submit high school transcripts with a minimum GPA of 3.0 Option 5: Submit transcripts documenting completion of previous IT coursework. IT coursework must be 300 level or higher.
In order to qualify for this program, you'll need a high school diploma (or its equivalent) AND demonstrate program readiness through one of the following: Option 1:Submit transcripts documenting completion of previous IT coursework. IT coursework must be 300-level or higher.
*Only advanced mathematics courses will satisfy this requirement Option 6: Submit transcripts documenting completion of previous IT coursework. IT coursework must be 300 level or higher. 3 Reply Extension_Spot_5372
To be considered for enrollment into this bachelor's degree program, students must possess a high school diploma or its equivalent AND demonstrate program readiness through one of the following: Option 1: Submit transcripts documenting completion of previous IT coursework. IT coursework must be 300-level or higher.
Option 3: Submit official record of completion of a transferable IT certification, some of which may provide transfer credit into various programs. Option 4: Submit high school transcripts with a minimum GPA of 3.0 Option 5: Submit transcripts documenting completion of previous IT coursework. IT coursework must be 300 level or higher.
Computer and Information Sciences Major. Forty-five to 48 semester hours are required for the bachelor of science in computer science, including 36 required core course hours and at least three additional elective courses chosen from any computer and information science courses at the 300 level or above.
The difference between 100, 200, and 300 level courses primarily lies in difficulty, depth of material, and the target audience of students. Here's a general breakdown: - 100 level courses: These are typically introductory courses designed for freshmen or students new to a subject area. They provide a foundation in the subject and often have ...
IT coursework must be 300 level or higher. Option 2: Possess a bachelor's or associate degree (A.A, A.S. or A.A.S. acceptable) from an accredited post-secondary institution. Option 3: Demonstrate at least two years of IT work experience through resume review.
The idea is that 300 level classes are intended for juniors and seniors majoring in a given discipline, so they properly belong to the four-year colleges. (In return, we have a very strong claim on having credits for 100 and 200 level classes transfer.) If we overstep our curricular bounds, the four-year schools won't take our credits in ...
All advanced (300- and 400-level) courses must be unique to each program, i.e., no advanced course may "double-count" for the coursework needed to fulfill either program's minimal requirements.
Currently I'm taking some classes @ Study.com to transfer in to BSIT WGU. What is IT coursework must be 300 level or higher meaning? can I get admitted with only Study.com transcript? Share Add a Comment Sort by: Confident_Natural_87 •
Metropolitan State's computer science program, available on campus in Minnesota, also provides preparation for graduate school in computer science. A minimum of 16 semester credits of major requirements must be completed at Metro State to earn a Bachelor of Science in Computer Science. Remote video URL.
Our 300-level courses are designed to meet the needs of the upper division undergraduate and they are not consequently designed to challenge the typical graduate student. To be sure, a 300-level course can and often do challenge both undergraduate and graduate students but perhaps our expectations as faculty for what a graduate student should ...
At least 18 hours of coursework must be at the 400 level or higher. Courses taken at the 300 level should only be allowed when no 400 level course is available, or under unusual circumstances, both of which must be approved in advance via a petition to Graduate Studies. At least 12 semester hours of course work must be graded.
Here's how it works: 1. Apply and get accepted to the program. 2. Complete your general education courses along with six bachelor's-level IT courses. 3. Move into graduate-level coursework with four master's-level bridge courses. 4. Earn your bachelor's degree and industry-relevant certifications.
To be considered for enrollment into this program, you must possess a high school diploma or its equivalent AND demonstrate program readiness through one of the following: Option 1: Submit transcripts documenting completion of college-level coursework with a minimum of 2.75 GPA or higher.
Re easy 300/400 level courses. | TexAgs. I need some help GB. Re easy 300/400 level courses. I need a few more hours of 300/400 level courses than what is left in my degree plan. What are some easy and interesting courses I could take. Just needs to be upper level, and I would prefer to enjoy it.
*Only advanced mathematics courses will satisfy this requirement Option 6: Submit transcripts documenting completion of previous IT coursework. IT coursework must be 300 level or higher. Would anyone have any insight to this kind of situation?
I am a Power Platform developer searching for fitting Certifications on Data Analysis (PowerBI). After Clearing the PL 300 Power BI Data Analyst Associate, I am having dificulties finding the next/better/further certifications that builds up from PL300. Could you help me find the differents paths available after the PL 300?
You could also take the 1 credit course at ASU which is the first course in the google cert. Easy to get an A and it only costs $25. That would be enough to qualify for the Pierpont AAS if you complete all the Sophia courses. You might want to take a few additional easy courses at Sophia to make sure you get the 60 total credits.
Level 300 coursework Hello can anyone explain this admission guideline or where I can find level 300 coursework 0 comments Best Add a Comment