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Computer Science [clear]
Title | Offering | Standing | Credits | Credits | When | F | W | S | Su | Description | Preparatory | Faculty | Days | Multiple Standings | Start Quarters | Open Quarters |
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Sheryl Shulman
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Program | SO–SRSophomore–Senior | 8 | 08 | Day | Su 16 Summer | This class will focus on developing programming techniques in a variety of programming languages. Possible languages include C, C++, Java, Haskell, ML, and OCAML. This is an opportunity to explore languages in more depth, increase you expertise in programming, prepare for more advanced work, and increase the depth and breadth of your programming background. In connection with the practical programming component we will also read papers on programming language design, emphasizing recent language innovations such as generics, multi-paradigm languages, the introduction of lambda terms and their role, and higher-order programming. | Computer Science | Sheryl Shulman | Tue Thu | Sophomore SO Junior JR Senior SR | Summer | Summer | |||
Neal Nelson, Adam King, Sheryl Shulman and Richard Weiss
Signature Required:
Winter Spring
|
Program | FR–SRFreshmen–Senior | 16 | 16 | Day | F 15 Fall | W 16Winter | S 16Spring | The goal of this program is for students to learn the intellectual concepts and skills that are essential for advanced work in computer science and beneficial for computing work in support of other disciplines. Students will have the opportunity to achieve a deeper understanding of increasingly complex computing systems by acquiring knowledge and skills in mathematical abstraction, problem solving, and the organization and analysis of hardware and software systems. The program covers material such as algorithms, data structures, computer organization and architecture, logic, discrete mathematics, and programming in the context of the liberal arts and compatible with the model curriculum developed by the Association for Computing Machinery's Liberal Arts Computer Science Consortium.The program content will be organized around four interwoven themes. The computational organization theme covers concepts and structures of computing systems from digital logic to the computer architecture and assembly language supporting high-level languages and operating systems. The programming theme concentrates on learning how to design and code programs to solve problems. The mathematical theme helps develop mathematical reasoning, theoretical abstractions, and problem-solving skills needed for computer scientists. A technology and society theme explores social, historical, or philosophical topics related to science and technology.We will explore these themes throughout the year through lectures, programming labs, workshops, and seminars. | Neal Nelson Adam King Sheryl Shulman Richard Weiss | Mon Tue Wed Thu | Freshmen FR Sophomore SO Junior JR Senior SR | Fall | Fall Winter Spring | ||
Ab Van Etten
|
Program | FR–SRFreshmen–Senior | 8 | 08 | Evening | S 16Spring | Ab Van Etten | Mon Wed | Freshmen FR Sophomore SO Junior JR Senior SR | Spring | Spring | |||||
Brian Walter
Signature Required:
Winter
|
Contract | SO–SRSophomore–Senior | 0, 4 | 0 04 | Day | W 16Winter | S 16Spring | Individual study offers students the opportunity to study subjects or do projects not typically available through the regular curriculum. It also offers opportunities to learn learning: the opportunity to develop self-direction, to learn how to manage a personal project, and/or to learn how to learn technical material outside of the classroom. Students interested in a self-directed project, research, or course of study in Mathematics or theoretical Computer Science are invited to present a proposal to Brian Walter. Students with a lively sense of self-direction, discipline, and intellectual curiosity are strongly encouraged to apply, as are groups of students interested in studying a subject together. | mathematics, computer science | Brian Walter | Sophomore SO Junior JR Senior SR | Winter | Winter Spring | |||
Brandon Sackmann
|
Course | FR–SRFreshmen–Senior | 4 | 04 | Evening | Su 16 Summer | Geographic Information Systems (GIS) are computer-based systems for management, display, and analysis of geographic data. This is an introductory course designed to provide the student with an overview of the development and basic principles of GIS, practical experience in the use of ArcGIS 10.x (one of the most popular commercial GIS packages), and, finally, an understanding of the development of a GIS project. By the end of the course, students will be able to create GIS maps, explore and analyze the data behind the maps, and apply methods to easily communicate GIS-based information to others. | Brandon Sackmann | Tue Wed Thu | Freshmen FR Sophomore SO Junior JR Senior SR | Summer | Summer | ||||
Arun Chandra
Signature Required:
Winter
|
Program | JR–SRJunior–Senior | 16 | 16 | Day | F 15 Fall | W 16Winter | S 16Spring | Western European music has had a long development of simultaneous complexity, from the introduction during Medieval times of independent voice leading, to the multi-voiced complexity of Gyorgi Ligeti's in the 1960s. is the presence of multiple, independent musical voices, where the differences of each voice emphasize the differences of the others. It is the opposite of , in which musical lines are hierarchically bound to one another, harmonically and metrically, as in a barbershop quartet. From the 1920s through the 1940s, the anthropologists Gregory Bateson and Margaret Mead studied the cultures of the South Pacific, as well as those of North America and Europe. They traced and articulated the differences between cultures, while noting the simultaneous shared properties held between them. In the 1940s, Bateson and Mead (along with Heinz von Foerster, W. Ross Ashby, and others) began what was later called cybernetics. In our program, we will be reading papers by Bateson, Mead, von Foerester, and others. We will study the mathematical theory of information and create compositions in sound that mirror and address the complexities that these scientists wrote about, by means of the musical techniques of polyphony and voice-misleading.We will also investigate and learn how to program in the C programming language under the Linux operating system, in an attempt to create acoustic events that might begin to match the complexity of our own times, using polyphony, and study the ideas of counterpoint as shown in the compositions of J. S. Bach, Arnold Schoenberg, Gyorgi Ligeti, and contemporary composers. During the first quarter, we'll study the basics of C programming, getting familiar with the fundamentals of digital synthesis and the Linux operating system. Projects will include the creation of single-channel sound files and learning about the fundamental waveforms, additive synthesis, mixing, and frequency modulation. By the second quarter, we'll expand the work to include two-channel sounds, algorithms for equal-power panning, filtering and granular synthesis. In the third quarter, students will create 8-channel compositions, study direct waveform synthesis, and utilize all the algorithms that we studied through the year. Throughout the year, students will also be expected to write and perform vocal exercises in musical counterpoint, which they will perform in groups.There will be regular listening sessions, musical projects, and writing assignments using the writings of cyberneticians as models. The program will attend concerts of music in Seattle and Portland and give a public concert of our final compositions. | Arun Chandra | Tue Tue Wed Thu Thu | Junior JR Senior SR | Fall | Fall Winter | ||
Arlen Speights and Richard Weiss
|
Program | FR–SRFreshmen–Senior | 8 | 08 | Day | Su 16 Session II Summer | Physical computing is computing that interacts with the physical world. We will explore this in multiple forms, emphasizing the interconnections among 3D printing, robotics, interactivity, and microcontrollers. This program can be an introduction to programming, integrating the arts, engineering and computing. It is also open to students who want to explore more advanced work in computing and robotics.Students will learn how to program and connect Arduino microcontrollers, connecting programming with sensors, motors and displays, e.g., to build interactive devices. For Robotics, we will explore programming, image processing, and AI. One of the robots we will use is the Scribbler by Parallax. Students will work on a project in groups after learning the basics about the robot. They will also learn the fundamentals of programming in Python, which is a powerful scripting language. This is ideal for students who have programmed in another language. Students will develop an understanding of the object-oriented programming paradigm, program design, and problem solving. Students can also find parts for their work at thrift stores, then integrate them using 3D printed interconnections. Students will develop final projects that use the systems above, with the option to explore other areas such as the Raspberry Pi computer or wireless mobile devices. | Arlen Speights Richard Weiss | Mon Tue Wed Thu | Freshmen FR Sophomore SO Junior JR Senior SR | Summer | Summer | ||||
Peter Randlette
|
Program | FR–SRFreshmen–Senior | 8 | 08 | Day | Su 16 Session I Summer | Computers are now the basic sketchpad for creating music. From recording instruments into them to using software instruments that sound like nearly anything, software allows extremely complex production. This five-week class will familiarize members with the use of computer-based MIDI soft and hardware, synthesizers, and will cover some of the technical ‘mysteries’ which are critical to comprehending their use. Studio production, recording with mics, and basics of audio will be covered. This class is mostly about exploring the musical production process. The only prerequisites are interest in music, some keyboard and/or guitar skill, and curiosity. The class structure will consist of three separate elements. Lecture/Workshop sessions will cover operation of the systems, demonstrating different techniques in a group setting. This will be the time for reviewing readings, presenting questions, and troubleshooting. Students will play back their pieces for feedback and so others can see how different people compose. Individual studio times will be assigned to each student, for trying the different functions of the software, creating short musical ideas to apply learned skills, and experimenting with new techniques. Members will be expected to spend a minimum of two 4 hour blocks in the studio per week. Consulting times will be scheduled to permit students to meet for individual or small group assistance in the studio. | Peter Randlette | Tue Wed Thu Fri | Freshmen FR Sophomore SO Junior JR Senior SR | Summer | Summer | ||||
Arun Chandra
|
Course | FR–SRFreshmen–Senior | 4 | 04 | Day | S 16Spring | This class will meet once a week to discuss a series of readings that address art, cybernetics, and their interrelationship. The quarter will end with participation in the conference of the (in Olympia) during week 10. The reading list will contain: Students will be asked to write a short paper making connections between the readings. | Arun Chandra | Wed | Freshmen FR Sophomore SO Junior JR Senior SR | Spring | Spring | ||||
Neal Nelson, Richard Weiss and Sheryl Shulman
Signature Required:
Fall Winter
|
Program | SO–SRSophomore–Senior | 16 | 16 | Day | F 15 Fall | W 16Winter | S 16Spring | Large software systems have proven to be notoriously difficult to build, modify, and maintain despite the best efforts of many very capable people over the last 50 years. This is an upper-division program intended to help students gain the technical knowledge required to understand, analyze, modify, and build complex software systems.We will concentrate on learning the organization and complexity of large software systems that we do understand, and gaining practical experience in order to achieve a deeper understanding of the art, science, collaboration, and multidisciplinary skills required to work on computing solutions in real-world application domains. The technical topics will be selected from data structures, algorithm analysis, operating systems, networks, information security, object-oriented design, and analysis. The program seminar will focus on various technical topics in the software industry. Students will have an opportunity to engage in a substantial computing project through all the development phases of proposal, requirements, specification, design, and implementation.This program is for advanced computer science students who satisfy the prerequisites. We also expect students to have the discipline, intellectual maturity, and self motivation to complete homework at an advanced level, identify project topics, organize project teams and resources, and complete advanced project work independently. | Neal Nelson Richard Weiss Sheryl Shulman | Mon Tue Wed Thu | Sophomore SO Junior JR Senior SR | Fall | Fall Winter | ||
Douglas Schuler
Signature Required:
Fall Winter Spring
|
Research | SO–SRSophomore–Senior | 8 | 08 | Evening and Weekend | F 15 Fall | W 16Winter | S 16Spring | Civic intelligence attempts to understand how "smart" a society is in addressing the issues it faces and to think about – and initiate – practices that improve this capacity. It is an interdisciplinary area of inquiry that includes the sciences – social and otherwise – as well as the humanities. Visual art, music, and stories, are as critical to the enterprise as the ability to analyze and theorize about social and environmental issues.This learning opportunity is designed to allow students of various knowledge and skill levels to work with a high level of autonomy on the design and implementation of real-world research and action projects. Students will collaborate via issue-oriented "clusters" with students, faculty, and others inside and beyond Evergreen. The program will help students develop important skills in organizational and workshop design, collaboration, analysis and interpretation, written and oral communication, critical thinking skills, and interpersonal skills. We also expect to focus on the development of online services, information, and tools, including civic engagement games and online deliberation.Although there are many ways to engage in this research, all work will directly or indirectly support the work of the Civic Intelligence Research and Action Laboratory (CIRAL). These opportunities will include working with the "Home Office." The home office work will focus on developing the capacities of the lab, including engaging in research, media work, or tech development that will support the community partnerships. Other work can include direct collaboration outside the classroom, often on an ongoing basis. We are also hoping to support students who are interested in the development of online support for civic intelligence, particularly CIRAL. This includes the development of ongoing projects such as e-Liberate, a web-based tool that supports online meetings using Roberts Rules of Order, and Activist Mirror, a civic engagement game, as well as the requirements gathering and development of new capabilities for information interchange and collaboration. | Douglas Schuler | Wed | Sophomore SO Junior JR Senior SR | Fall | Fall Winter Spring | ||
Paula Schofield, Richard Weiss, Andrew Brabban, Neil Switz, Brian Walter, Abir Biswas, Michael Paros, Dharshi Bopegedera, Rebecca Sunderman, EJ Zita, Donald Morisato, Clarissa Dirks, James Neitzel, Sheryl Shulman, Neal Nelson and Lydia McKinstry
Signature Required:
Fall Winter Spring
|
Program | SO–SRSophomore–Senior | V | V | Day | F 15 Fall | W 16Winter | S 16Spring | Rigorous quantitative and qualitative research is an important component of academic learning in Scientific Inquiry. Research opportunities allow science students to work on specific projects associated with faculty members’ expertise. Students typically begin by working in an apprenticeship model with faculty or laboratory staff and gradually take on more independent projects within the context of the specific research program as they gain experience. Students can develop vital skills in research design, data acquisition and interpretation, modeling and theoretical analysis, written and oral communication, collaboration and critical thinking. These are valuable skills for students pursuing a graduate degree or entering the job market. Faculty offering undergraduate research opportunities are listed below. Contact them directly if you are interested. (geology, earth science) studies nutrient and toxic trace-metal cycles in terrestrial and coastal ecosystems. Potential projects could include studies of mineral weathering, wildfires, and mercury cycling in ecosystems. Students could pursue these interests at the laboratory scale or through field-scale biogeochemistry studies, taking advantage of the Evergreen Ecological Observation Network (EEON), a long-term ecological study area. Students with backgrounds in a combination of geology, biology, or chemistry can gain skills in soil, vegetation, and water collection and learn methods of sample preparation and analysis for major and trace elements. (biotechnology) studies the physiology and biochemistry of prokaryotes of industrial and agricultural importance. Students who commit at least a full year to a research project, enrolling for 4 to 16 credits each quarter, will learn a broad range of microbiology (both aerobic and anaerobic techniques), molecular (DNA analysis and cloning), and biochemical techniques (chemical and pathway analysis, protein isolation). Students will also have opportunities for internships at the USDA and elsewhere, and to present data at national and international conferences. (chemistry) would like to engage students in two projects: (1) There is concern that toxic metals are found in unsafe quantities in children’s toys and cosmetics. She would like to engage a student in the quantitative determination of these metals, using the AA and the ICP-MS. Students who are interested in learning to use these instruments and quantitative analysis techniques will find this project interesting. (2) Science and education. With Dharshi, students will work with local teachers to develop lab activities that enhance the science curriculum in local schools. Students with an interest in teaching science who have completed general chemistry with laboratory would be ideal for this project. (3) Dharshi is also interested in looking at chemicals present in e-cigarettes. A student interested in this project could work on the organic or inorganic chemicals. (biology) conducts research in many areas of microbiology and ecology. Her recent work in microbiology has focused on the biodiversity and distribution of tardigrades in different ecosystems. She also aims to better understand the evolutionary principles that underlie the emergence, spread, and containment of infectious disease by studying the co-evolution of retroviruses and their hosts. Lastly, she is conducting snail surveys in Washington state to better characterize the species in the state, something that hasn’t been done in many decades. Depending on the project, students will gain experience in molecular biology technique, microbiology, field ecology, genetics, bioinformatics, and tissue culture. (organic chemistry) is interested in organic synthesis research, including asymmetric synthesis methodology, chemical reaction dynamics, and small molecule synthesis. One specific study involves the design and synthesis of enzyme inhibitor molecules to be used as effective laboratory tools with which to study the mechanistic steps of programmed cell death (e.g., in cancer cells). Students with a background in organic chemistry and biology will gain experience with the laboratory techniques of organic synthesis,as well as the techniques of spectroscopy. (biology) is interested in the developmental biology of the embryo, a model system for analyzing how patterning occurs. Maternally encoded signaling pathways establish the anterior-posterior and dorsal-ventral axes. Individual student projects will use a combination of genetic, molecular biological, and biochemical approaches to investigate the spatial regulation of this complex process. (biochemistry) uses methods from organic and analytical chemistry to study biologically interesting molecules. A major focus of his current work is on fatty acids; in particular, finding spectroscopic and chromatographic methods to identify fatty acids in complex mixtures and to detect changes that occur in fats during processing or storage. This has relevance both for foods and in biodiesel production. The other major area of interest is in plant natural products, such as salicylates. Work is in process screening local plants for the presence of these molecules, which are important plant defense signals. Work is also supported in determining the nutritional value of indigenous plants. Students with a background and interest in organic or analytical biochemistry will contribute to this work. (computer science) is interested in working with advanced computer topics and current problems in the application of computing to the sciences. His areas of interest include simulations of advanced architectures for distributed computing, advanced programming languages and compilers, and programming languages for concurrent and parallel computing. (physiology, microbiology, veterinary medicine) is interested in animal health, diseases that affect the animal agriculture industry, and basic ecology of bacteriophage in physiologic systems. Currently funded research includes the development of bacteriophage therapy for dairy cattle mastitis. A number of hands-on laboratory projects are available to students interested in pursuing careers in science, with a particular emphasis on microbiology. (organic, polymer, materials chemistry) is interested in the interdisciplinary fields of biodegradable plastics and biomedical polymers. Research in the field of biodegradable plastics is becoming increasingly important to replace current petroleum-derived materials and to reduce the environmental impact of plastic wastes. Modification of starch through copolymerization and use of bacterial polyesters show promise in this endeavor. Specific projects within biomedical polymers involve the synthesis of poly (lactic acid) copolymers that have potential for use in tissue engineering. Students with a background in chemistry and biology will gain experience in the synthesis and characterization of these novel polymer materials. Students will present their work at American Chemical Society (ACS) conferences. (computer science) is interested in working with advanced computer topics and current problems in the application of computing to the sciences. Her areas of interest include advanced programming languages and compilers, programming language design, programming languages for concurrent and parallel computing, and logic programming. (inorganic/materials chemistry, physical chemistry) is interested in the synthesis and property characterization of new bismuth-containing materials. These compounds have been characterized as electronic conductors, attractive activators for luminescent materials, second harmonic generators, and oxidation catalysts for several organic compounds. Traditional solid-state synthesis methods will be utilized to prepare new complex bismuth oxides. Once synthesized, powder x-ray diffraction patterns will be obtained and material properties such as conductivity, melting point, biocidal tendency, coherent light production, and magnetic behavior will be examined when appropriate. (physics) develops optical instruments for use in biophysical and biomedical applications, including low-cost diagnostics. Projects in the lab are suitable for motivated students with quantitative backgrounds in physics, biology, chemistry, mathematics, or computer science. (mathematics) is interested in problems relating to graphs, combinatorial games, and especially, combinatorial games played on graphs. He would like to work with students who have a strong background in mathematics and/or computer science and are interested in applying their skills to open-ended problems relating to graphs and/or games. (computer science, mathematics) has several ongoing projects in computer vision, robotics, and security. There are some opportunities for students to develop cybersecurity games for teaching network security concepts and skills. In robotics, he is looking for students to develop laboratory exercises for several different mobile robotic platforms, including Scribbler, LEGO NXT and iRobot Create. This would also involve writing tools for image processing and computer vision using sequences of still images, videos treams and 2.5-D images from the Kinect. In addition, he is open to working with students who have their own ideas for projects in these and related areas, such as machine learning, artificial intelligence, and analysis of processor performance. (marine science) studies the developmental physiology and ecology of marine invertebrates. She is interested in the biochemistry of the seawater-organism interface, developmental nutritional biochemistry and metabolic depression, invasive species, carbonate chemistry (ocean acidification), and cultural relationships with foods from the sea. Students have the opportunity to collaboratively develop lines of inquiry for lab and/or field studies in ecology, developmental biology, physiology, marine carbonate chemistry and mariculture. (physics), who has expertise in energy physics, modeling, and organic farming, is researching sustainability and climate change. Many students have done fine projects on sustainable energy and food production in her academic programs. Zita is working with Judy Cushing and Scott Morgan to establish a new research program at Evergreen. She and Cushing will model land use impacts on climate change; she and Morgan will plan and facilitate sustainability projects on campus. More information on Zita's research is available at . | Paula Schofield Richard Weiss Andrew Brabban Neil Switz Brian Walter Abir Biswas Michael Paros Dharshi Bopegedera Rebecca Sunderman EJ Zita Donald Morisato Clarissa Dirks James Neitzel Sheryl Shulman Neal Nelson Lydia McKinstry | Sophomore SO Junior JR Senior SR | Fall | Fall Winter Spring | |||
David McAvity
Signature Required:
Fall Winter Spring
|
Research | SO–SRSophomore–Senior | V | V | Day | F 15 Fall | W 16Winter | S 16Spring | Rigorous quantitative and qualitative research is an important component of academic learning in Scientific Inquiry. This independent learning opportunity allows advanced students to delve into real-world research with faculty who are currently engaged in specific projects. Students typically begin by working in apprenticeship with faculty or laboratory staff and gradually take on more independent projects within the context of the specific research program as they gain experience. Students can develop vital skills in research design, data acquisition and interpretation, written and oral communication, collaboration, and critical thinking that are valuable for students pursuing a graduate degree or entering the job market. (mathematics) is interested in problems in mathematical biology associated with population and evolutionary dynamics. Students working with him will help create computer simulations using agent-based modeling and cellular automata and analyzing non-linear models for the evolution of cooperative behavior in strategic multiplayer evolutionary games. Students should have a strong mathematics or computer science background. | theoretical biology, computer science, mathematics. | David McAvity | Sophomore SO Junior JR Senior SR | Fall | Fall Winter Spring | ||
Neal Nelson
Signature Required:
Fall Winter Spring
|
Research | SO–SRSophomore–Senior | V | V | Day | F 15 Fall | W 16Winter | S 16Spring | Rigorous quantitative and qualitative research is an important component of academic learning in Scientific Inquiry. Research opportunities allow science students to work on specific projects associated with faculty members’ expertise. Students typically begin by working in an apprenticeship model with faculty or laboratory staff and gradually take on more independent projects within the context of the specific research program as they gain experience. Students can develop vital skills in research design, data acquisition and interpretation, modeling and theoretical analysis, written and oral communication, collaboration and critical thinking. These are valuable skills for students pursuing a graduate degree or entering the job market. (computer science)is interested in working with advanced computer topics and current problems in the application of computing to the sciences. His areas of interest include simulations of advanced architectures for distributed computing, advanced programming languages and compilers, programming languages for concurrent and parallel computing. | Neal Nelson | Sophomore SO Junior JR Senior SR | Fall | Fall Winter Spring | |||
Richard Weiss
Signature Required:
Fall Winter Spring
|
Research | SO–SRSophomore–Senior | V | V | Day | F 15 Fall | W 16Winter | S 16Spring | Rigorous quantitative and qualitative research is an important component of academic learning in Scientific Inquiry. Research opportunities allow science students to work on specific projects associated with faculty members’ expertise. Students typically begin by working in an apprenticeship model with faculty or laboratory staff and gradually take on more independent projects within the context of the specific research program as they gain experience. Students can develop vital skills in research design, data acquisition and interpretation, modeling and theoretical analysis, written and oral communication, collaboration and critical thinking. These are valuable skills for students pursuing a graduate degree or entering the job market. (computer science, mathematics) has several ongoing projects in computer vision, robotics and security. There are some opportunities for students to develop cybersecurity games for teaching network security concepts and skills. In robotics, he is looking for students to develop laboratory exercises for several different mobile robotic platforms, including Scribbler, LEGO NXT and iRobot Create. This would also involve writing tools for image processing and computer vision using sequences of still images, video streams and 2.5-D images from the Kinect. In addition, he is open to working with students who have their own ideas for projects in these and related areas, such as machine learning, artificial intelligence and analysis of processor performance. | Richard Weiss | Sophomore SO Junior JR Senior SR | Fall | Fall Winter Spring | |||
Sheryl Shulman
Signature Required:
Fall Winter Spring
|
Research | SO–SRSophomore–Senior | V | V | Day | F 15 Fall | W 16Winter | S 16Spring | Rigorous quantitative and qualitative research is an important component of academic learning in Scientific Inquiry. Research opportunities allow science students to work on specific projects associated with faculty members’ expertise. Students typically begin by working in an apprenticeship model with faculty or laboratory staff and gradually take on more independent projects within the context of the specific research program as they gain experience. Students can develop vital skills in research design, data acquisition and interpretation, modeling and theoretical analysis, written and oral communication, collaboration and critical thinking. These are valuable skills for students pursuing a graduate degree or entering the job market. (computer science) is interested in working with advanced computer topics and current problems in the application of computing to the sciences. Her areas of interest include advanced programming languages and compilers, programming language design, programming languages for concurrent and parallel computing, and logic programming. | Sheryl Shulman | Sophomore SO Junior JR Senior SR | Fall | Fall Winter Spring | |||
Arlen Speights and Richard Weiss
|
Course | FR–SRFreshmen–Senior | 4 | 04 | Evening | Su 16 Session II Summer | Arlen Speights Richard Weiss | Mon Tue Wed Thu | Freshmen FR Sophomore SO Junior JR Senior SR | Summer | Summer |