Canda

This laboratory course focuses on practical applications of microprocessor and microcontroller systems. Students delve into assembly language programming, interfacing with input/output devices, and data transfer between microcontroller-based circuits and a PC via serial and parallel ports. Through hands-on exercises, students gain proficiency in programming languages and practical skills in interfacing electronic systems.

• Aligned with SDG 4, the laboratory provides a high-quality education by offering practical applications of theoretical concepts. Students gain hands-on experience in microprocessor and microcontroller programming, preparing them for roles in technological innovation.
• Emphasizing innovation in technology, the laboratory equips students with practical skills in interfacing and data transfer between electronic circuits and PCs. This aligns with SDG 9 by fostering advancements in technology and infrastructure reliant on embedded systems.
• Encouraging responsible consumption and production practices, the laboratory focuses on efficient data transfer methodologies between microcontroller-based circuits and PCs. Students learn to optimize interfaces, contributing to sustainable practices in electronic design and production.

• Assembly language programming for microprocessors and microcontrollers.
• Interfacing with various input/output devices.
• Data transfer between microcontroller-based circuits and PCs via serial and parallel ports

This course offers a comprehensive study of microprocessor and microcontroller systems, covering architecture, programming, interfacing techniques, memory systems, and bus standards. Students delve into the architecture and structure of microprocessor systems, exploring 8, 16, and 32-bit systems, memory systems, bus structures, and programming. Emphasis is placed on interrupts, exceptions, and basic input/output interfacing, including parallel communication. Additionally, the course covers microcontroller structure and programming using dedicated development systems.

• Aligned with SDG 9, the course emphasizes innovation in microprocessor and microcontroller systems. Students explore advanced architectures and programming techniques, contributing to technological innovation and fostering advancements in infrastructure reliant on embedded systems
• Committed to SDG 4, the course ensures a high-quality education by providing students with in-depth knowledge of microprocessor and microcontroller systems. Through hands-on programming and practical application, students acquire essential skills for future roles in technological development.
• Encouraging responsible consumption and production (SDG 12), the course addresses the design of efficient microprocessor and microcontroller systems. By studying memory systems, bus standards, and programming techniques, students learn to optimize systems, promoting sustainable practices in electronic design and production.

Course Coverage:

• Microprocessor and microcontroller systems architecture and organization.
• Programming methodologies for microprocessor and microcontroller systems.
• Interfacing techniques, memory system hierarchies, and bus standards.
• Overview of microcontroller structures and programming using specialized development systems

Electronic Circuits Analysis and Design is an advanced course that delves into the intricacies of electronic components and their applications. From frequency response characteristics to digital integrated circuits, this course provides students with a comprehensive understanding of electronic circuits and their design principles.

• Aligned with SDG 9, this course emphasizes innovation in electronic infrastructure. Students explore frequency response characteristics of transistors and digital integrated circuits, contributing to advancements in electronic infrastructure and fostering innovation in industries reliant on electronics.
• Committed to SDG 4, this course ensures a high-quality education by equipping students with in-depth knowledge of operational amplifiers, active filters, and pulsed waveforms. Through practical applications and theoretical learning, students gain essential skills for their academic growth and future roles in technological development.
• Encouraging responsible consumption and production (SDG 12), the course addresses the design of efficient electronic circuits. By studying low and high-frequency characteristics and implementing active filters, students learn techniques for optimizing circuits, contributing to sustainable practices in electronic design and production.

Course Coverage:

• Analysis of frequency response characteristics of transistors, covering both low and high frequencies. 
• In-depth study of operational amplifiers and their applications in various electronic circuits.
• Exploration of filter design, focusing on active filters and their significance in signal processing.
• Examination of pulsed waveforms and their use in electronic systems and communications
• Study of digital integrated circuits families and their applications in modern electronics.

Electronic Circuits Analysis and Design is an advanced course that delves into the intricacies of electronic components and their applications. From frequency response characteristics to digital integrated circuits, this course provides students with a comprehensive understanding of electronic circuits and their design principles.

• Aligned with SDG 9, this course emphasizes innovation in electronic infrastructure. Students explore frequency response characteristics of transistors and digital integrated circuits, contributing to advancements in electronic infrastructure and fostering innovation in industries reliant on electronics.
• Committed to SDG 4, this course ensures a high-quality education by equipping students with in-depth knowledge of operational amplifiers, active filters, and pulsed waveforms. Through practical applications and theoretical learning, students gain essential skills for their academic growth and future roles in technological development.
• Encouraging responsible consumption and production (SDG 12), the course addresses the design of efficient electronic circuits. By studying low and high-frequency characteristics and implementing active filters, students learn techniques for optimizing circuits, contributing to sustainable practices in electronic design and production.

Course Coverage:

• Analysis of frequency response characteristics of transistors, covering both low and high frequencies. 
• In-depth study of operational amplifiers and their applications in various electronic circuits.
• Exploration of filter design, focusing on active filters and their significance in signal processing.
• Examination of pulsed waveforms and their use in electronic systems and communications.
• Study of digital integrated circuits families and their applications in modern electronics.

This course provides a foundational understanding of electronic circuits by delving into the characteristics of diodes and transistors, essential for elementary analysis of circuits with discrete components. It extends to integrated circuits widely employed in electrical engineering applications. With a focus on sustainable development, the course introduces students to the design of electronic circuits for basic applications like filters, power supplies, and op-amp signal processors.

• The course contributes to SDG 7 by empowering students with the knowledge to design efficient power supply circuits, ensuring access to affordable and clean energy solutions. Understanding the characteristics of electronic components facilitates the creation of energy-efficient systems.
• Aligned with SDG 9, the course covers integrated circuits extensively used in electrical engineering. Students gain insights into cutting-edge technologies and innovation, preparing them for roles in advancing industrial infrastructure.
• Encouraging responsible consumption and production practices, the course emphasizes the design of electronic circuits with a focus on sustainability. Students learn to create efficient circuits for applications such as filters and power supplies, aligning with SDG 12's principles.

Course Coverage:

• Characteristics of diodes and transistors for elementary analysis of electronic circuits.
• In-depth study of integrated circuits commonly used in electrical engineering.
• Introduction to the design of electronic circuits for basic applications, including filters, power supplies, and op-amp signal processors.

This course provides a foundational understanding of electronic circuits by delving into the characteristics of diodes and transistors, essential for elementary analysis of circuits with discrete components. It extends to integrated circuits widely employed in electrical engineering applications. With a focus on sustainable development, the course introduces students to the design of electronic circuits for basic applications like filters, power supplies, and op-amp signal processors.

• The course contributes to SDG 7 by empowering students with the knowledge to design efficient power supply circuits, ensuring access to affordable and clean energy solutions. Understanding the characteristics of electronic components facilitates the creation of energy-efficient systems.
• Aligned with SDG 9, the course covers integrated circuits extensively used in electrical engineering. Students gain insights into cutting-edge technologies and innovation, preparing them for roles in advancing industrial infrastructure.
• Encouraging responsible consumption and production practices, the course emphasizes the design of electronic circuits with a focus on sustainability. Students learn to create efficient circuits for applications such as filters and power supplies, aligning with SDG 12's principles.

Course Coverage:

• Characteristics of diodes and transistors for elementary analysis of electronic circuits.
• In-depth study of integrated circuits commonly used in electrical engineering.
• Introduction to the design of electronic circuits for basic applications, including filters, power supplies, and op-amp signal processors.