All Courses

Computer Architecture
Course Objective:

They will study the basic organization and architecture of digital computers (CPU, memory, I/O, software). Discussions will include digital logic and microprogramming. Such knowledge leads to better understanding and utilization of digital computers and can be used in the design and application of computer systems or as the foundation for more advanced computer-related studies. The architectural overview of different instruction sets, registers, memory allocation can be studied on the emerging vision that helps furthermore research. Classify the pipelining, as a basic practice for cumulative CPU performance as well as a design factor, planning, and control of pipeline units. Also, improve critical thinking when assessing the presence of a computer system conferring to objective standards.

Learning outcomes

 Understand the operation of electronic logic elements
 Comprehend the organization of a computer system in terms of its main components
 Grasp the detailed operation of a simple microprocessor
 Usage the different processor architectures
 Understand input/output mechanisms
 Know the prospective of a hierarchical memory system
 Be able to use standard levels to perform evaluation studies, and understand the equivalent result reports
 Nurture design skills of Instruction Sets
 Realize the visualization of the architecture of RISC and CISC processor
Digital Systems Design
Course Objective:
Introduce the concept of digital and binary systems. Be able to design and analyze
combinational logic circuits. Be able to design and analyze sequential logic circuits.
Understand the basic software tools for the design and implementation of digital
circuits and systems. Reinforce theory and techniques taught in the classroom
through experiments and projects in the laboratory.

Learning outcomes
 Design and implement digital/computer circuits with modern design tools.
 Determine the behavior of a digital logic circuit (analysis).
 Translate descriptions of logical problems to efficient digital logic circuits
(synthesis).
 Integrate previously designed components into a large-scale system to meet
specified requirements.
 Participating as a member of a team-oriented design project.
Management Information System
Course Objective:
Students are able to utilize necessary skill, to successfully manage systems
development projects. Also can effectively use and administrating Information
Systems in different business settings. Acquiring and applying analytical skills
which will enable them to visualize a complex business problem and make
informed decisions based on available information and technology resources.
They can apply problem solving skills which will allow them to model
information systems solutions for business problems. Having a deep
understanding of the business and professional responsibilities related to the use
of information systems in organizations

Learning outcomes
 Explain complex software within the context of business user needs through
training presentations and written documentation.
 Distinguish relationships between programming languages and information
systems.
 Analyze existing systems and design technology solutions appropriate to the
goals of an organization.
 Determine factors influencing the strengths and weaknesses of the most
common computer operating systems and determine how one would be
preferred over others.
 Effectively utilize database and database management systems to organize,
store and retrieve data.
Microprocessor and Assembly Language
A microprocessor is a computer processor where the data processing logic and control is included on a single integrated circuit, or a small number of integrated circuits. The microprocessor contains the arithmetic, logic, and control circuitry required to perform the functions of a computer's central processing unit. The integrated circuit is capable of interpreting and executing program instructions and performing arithmetic operations.[1] The microprocessor is a multipurpose, clock-driven, register-based, digital integrated circuit that accepts binary data as input, processes it according to instructions stored in its memory, and provides results (also in binary form) as output. Microprocessors contain both combinational logic and sequential digital logic, and operate on numbers and symbols represented in the binary number system.