" This course covers topics on the engineering of computer software and hardware systems: techniques for controlling complexity; strong modularity using client-server design, virtual memory, and threads; networks; atomicity and coordination of parallel activities; recovery and reliability; privacy, security, and encryption; and impact of computer systems on society. Case studies of working systems and readings from the current literature provide comparisons and contrasts. Two design projects are required, and students engage in extensive written communication exercises."
Focus on the key role that information technology plays in enabling organizational change and integration, especially in manufacturing. Topics include: trends in core technologies, including computer hardware, software, communications, and networks; the development and evolution of the internet and web; business models for electronic commerce; reinventing business processes and supply chain management; evaluating and managing the use of advanced information technologies in manufacturing; and new technology-enabled forms of working and organizing. In virtually every industry and every firm, information technology is driving change, creating opportunities and challenges. Leaders who don't understand at least the fundamentals of information systems will be at a strategic disadvantage. This course provides broad coverage of technology concepts and trends underlying current and future developments in information technology, and fundamental principles for the effective use of computer-based information systems. There will be a special emphasis on manufacturing. Information Systems topics that will be covered include networks and distributed computing, including the World Wide Web, hardware and operating systems, software development tools and processes, relational databases, security and cryptography, enterprise applications, B2B, the semantic web and electronic commerce. Sloan LFM students with an interest in Information Systems are encouraged to register for this course.
Teaches the fundamentals of engineering operating systems. The following topics are studied in detail: virtual memory, kernel and user mode, system calls, threads, context switches, interrupts, interprocess communication, coordination of concurrent activities, and the interface between software and hardware. Most importantly, the interactions between these concepts are examined. The course is divided into two blocks; the first block introduces one operating system, UNIX® v6, in detail. The second block of lectures covers important operating systems concepts invented after UNIX® v6, which was introduced in 1976.
This course teaches the fundamentals of engineering operating systems. The following topics are studied in detail: virtual memory, kernel and user mode, system calls, threads, context switches, interrupts, interprocess communication, coordination of concurrent activities, and the interface between software and hardware. Most importantly, the interactions between these concepts are examined. The course is divided into two blocks; the first block introduces one operating system, UNIX® v6, in detail. The second block of lectures covers important operating systems concepts invented after UNIX® v6, which was introduced in 1976.
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