Course Details

Description

This course introduces students to principles, methodologies, and procedures for embedded systems. The goal is to learn how to bring hardware (microprocessors, Arduino, Raspberry PI, sensors, displays, etcâ€¦) and software (programming language, operating system (windows 10, Linux, etcâ€¦)) together to specify, design, and implement system solutions to the production of whole and complete products.

Program

Computer Science Program.

Objectives

1. Identify and appreciate the meaning of embedded systems applications.
2. Use Microcontroller software with high level programming to develop task oriented applications in real time.
3. Understand and use real time operating system s and tools for multi-tasking, inter-networking, memory limitations, hardware resource allocation, etcâ€¦

Textbook

Daniel W. Lewis. Fundamentals of Embedded Software with the ARM Cortex-M3, Pearson

Course Content

content serial

Description

1	Introduction
2	Understanding embedded systems using modular design and abstraction
3	How to build and test circuits with switches, diodes, LEDs, resistors, potentiometers, transistors, op-amps, opto-couplers, and Liquid Crystal Displays (LCDs)
4	How to read data sheets of analogue and digital ICs, microprocessors (Arduino, Raspberry PI, etc...) a. C programming: considering both functions and styles.
5	Hardware/Software architectures of Arduino
6	Digital input/output for interfacing and synchronization of hardware and software inputs/outputs with switches, lights, sounds, LCDs, sensors, and actuators
7	7th Week Exam
8	Timers/Counters Applications for Pulse Width Modulation (PWM) and DC and stepper motor control applications
9	Analogue Input/Output using Analogue to Digital Converters (ADCs) and Digital to Analogue Converters (DACs)
10	Implementation of an I/O driver and multi-threaded programming using interrupts.
11	Digital Signal Processors (DSPs) characteristics and applications in embedded systems
12	12th Week Exam
13	Real Time Operating System (RTOS) applications in embedded systems
14	Raspberry-Pi and ARM processor hardware/software models, programming, and applications (image processing, video processing, etc…)
15	Application Project (How to construct a smart object and create a system as part of the Internet of Things)
16	Final Exam
1	Introduction
2	Understanding embedded systems using modular design and abstraction
3	How to build and test circuits with switches, diodes, LEDs, resistors, potentiometers, transistors, op-amps, opto-couplers, and Liquid Crystal Displays (LCDs)
4	How to read data sheets of analogue and digital ICs, microprocessors (Arduino, Raspberry PI, etc...) a. C programming: considering both functions and styles.
5	Hardware/Software architectures of Arduino
6	Digital input/output for interfacing and synchronization of hardware and software inputs/outputs with switches, lights, sounds, LCDs, sensors, and actuators
7	7th Week Exam
8	Timers/Counters Applications for Pulse Width Modulation (PWM) and DC and stepper motor control applications
9	Analogue Input/Output using Analogue to Digital Converters (ADCs) and Digital to Analogue Converters (DACs)
10	Implementation of an I/O driver and multi-threaded programming using interrupts.
11	Digital Signal Processors (DSPs) characteristics and applications in embedded systems
12	12th Week Exam
13	Real Time Operating System (RTOS) applications in embedded systems
14	Raspberry-Pi and ARM processor hardware/software models, programming, and applications (image processing, video processing, etc…)
15	Application Project (How to construct a smart object and create a system as part of the Internet of Things)
16	Final Exam
1	Introduction
2	Understanding embedded systems using modular design and abstraction
3	How to build and test circuits with switches, diodes, LEDs, resistors, potentiometers, transistors, op-amps, opto-couplers, and Liquid Crystal Displays (LCDs)
4	How to read data sheets of analogue and digital ICs, microprocessors (Arduino, Raspberry PI, etc...) a. C programming: considering both functions and styles.
5	Hardware/Software architectures of Arduino
6	Digital input/output for interfacing and synchronization of hardware and software inputs/outputs with switches, lights, sounds, LCDs, sensors, and actuators
7	7th Week Exam
8	Timers/Counters Applications for Pulse Width Modulation (PWM) and DC and stepper motor control applications
9	Analogue Input/Output using Analogue to Digital Converters (ADCs) and Digital to Analogue Converters (DACs)
10	Implementation of an I/O driver and multi-threaded programming using interrupts.
11	Digital Signal Processors (DSPs) characteristics and applications in embedded systems
12	12th Week Exam
13	Real Time Operating System (RTOS) applications in embedded systems
14	Raspberry-Pi and ARM processor hardware/software models, programming, and applications (image processing, video processing, etc…)
15	Application Project (How to construct a smart object and create a system as part of the Internet of Things)
16	Final Exam
1	Introduction
2	Understanding embedded systems using modular design and abstraction
3	How to build and test circuits with switches, diodes, LEDs, resistors, potentiometers, transistors, op-amps, opto-couplers, and Liquid Crystal Displays (LCDs)
4	How to read data sheets of analogue and digital ICs, microprocessors (Arduino, Raspberry PI, etc...) a. C programming: considering both functions and styles.
5	Hardware/Software architectures of Arduino
6	Digital input/output for interfacing and synchronization of hardware and software inputs/outputs with switches, lights, sounds, LCDs, sensors, and actuators
7	7th Week Exam
8	Timers/Counters Applications for Pulse Width Modulation (PWM) and DC and stepper motor control applications
9	Analogue Input/Output using Analogue to Digital Converters (ADCs) and Digital to Analogue Converters (DACs)
10	Implementation of an I/O driver and multi-threaded programming using interrupts.
11	Digital Signal Processors (DSPs) characteristics and applications in embedded systems
12	12th Week Exam
13	Real Time Operating System (RTOS) applications in embedded systems
14	Raspberry-Pi and ARM processor hardware/software models, programming, and applications (image processing, video processing, etc…)
15	Application Project (How to construct a smart object and create a system as part of the Internet of Things)
16	Final Exam

Markets and Career

Generation, transmission, distribution and utilization of electrical power for public and private sectors to secure both continuous and emergency demands.
Electrical power feeding for civil and military marine and aviation utilities.
Electrical works in construction engineering.

Degree Bachelor
Code: CS427
Credit hrs: 3
Prequisites:

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Computing & Information Technology Cairo

Embedded Systems Programming

Description

Program

Objectives

Textbook

Course Content

Markets and Career

19838

Computing & Information Technology Cairo

Embedded Systems Programming

Description

Program

Objectives

Textbook

Course Content

Markets and Career

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