Real-Time Operating Systems Design And Implementation

[xodynu]

Real-Time Operating Systems: Design And Implementation
Published 10/2024
Created by Dr. R. Anto Arockia Rosaline,Nancy p,Vinod D
MP4 | Video: h264, 1280x720 | Audio: AAC, 44.1 KHz, 2 Ch
Genre: eLearning | Language: English | Duration: 41 Lectures ( 5h 36m ) | Size: 4.14 GB
Process Synchronization, Process Scheduling, Deadlocks, Memory Management, Disk Scheduling​

What you'll learn
Choose the relevant process and thread concepts for solving synchronization problems.
Implement different types of scheduling algorithms.
Exemplify various deadlock mechanisms.
Apply paging and segmentation in memory management and incorporate page fault handling, demand paging.
Demonstrate the storage management techniques through various File Management techniques.
Requirements
No Programming experience required.
Description
This course offers a comprehensive introduction to fundamental operating system concepts, focusing on key areas like process synchronization, scheduling, memory management, and disk handling. You will gain an in-depth understanding of synchronization techniques such as the Bounded Buffer Problem, Peterson's Solution, Mutex Locks, Semaphores, and the Reader-Writer Problem, which are critical for managing the coordination between multiple processes. The course also covers a wide range of scheduling approaches, including thread scheduling, real-time CPU scheduling, and multi-processor scheduling, all aimed at optimizing CPU resource allocation for better performance.In addition to process management, you'll dive into deadlock handling, learning methods to detect, prevent, and recover from deadlocks, ensuring system stability and efficiency. The course covers essential memory management techniques like swapping, segmentation, paging, and virtual memory, which are critical for efficient data handling. Practical strategies for implementing page replacement policies and avoiding thrashing are explored, giving you the tools to manage memory allocation effectively in high-demand situations.Disk management is another major focus of the course, where you'll learn about disk scheduling algorithms, RAID structures, and file system organization. The course emphasizes important aspects of file sharing and protection mechanisms to ensure secure and efficient file access and management.By the end of the course, you will have developed the skills and knowledge needed to tackle real-world operating system challenges. Whether you are a professional, developer, or a tech enthusiast, this course is ideal for those seeking to deepen their understanding of operating systems.
Who this course is for
This course is tailored for undergraduate students pursuing degrees in computer science, information technology, or related disciplines. It is ideal for learners seeking to gain a solid foundation in the core principles and functions of modern operating systems.
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[0dayddl]

Real-Time Operating Systems: Design And Implementation
Published 10/2024
MP4 | Video: h264, 1920x1080 | Audio: AAC, 44.1 KHz
Language: English | Size: 2.83 GB | Duration: 5h 36m​

Process Synchronization, Process Scheduling, Deadlocks, Memory Management, Disk Scheduling

What you'll learn

Choose the relevant process and thread concepts for solving synchronization problems.

Implement different types of scheduling algorithms.

Exemplify various deadlock mechanisms.

Apply paging and segmentation in memory management and incorporate page fault handling, demand paging.

Demonstrate the storage management techniques through various File Management techniques.

Requirements

No Programming experience required.

Description

This course offers a comprehensive introduction to fundamental operating system concepts, focusing on key areas like process synchronization, scheduling, memory management, and disk handling. You will gain an in-depth understanding of synchronization techniques such as the Bounded Buffer Problem, Peterson's Solution, Mutex Locks, Semaphores, and the Reader-Writer Problem, which are critical for managing the coordination between multiple processes. The course also covers a wide range of scheduling approaches, including thread scheduling, real-time CPU scheduling, and multi-processor scheduling, all aimed at optimizing CPU resource allocation for better performance.In addition to process management, you'll dive into deadlock handling, learning methods to detect, prevent, and recover from deadlocks, ensuring system stability and efficiency. The course covers essential memory management techniques like swapping, segmentation, paging, and virtual memory, which are critical for efficient data handling. Practical strategies for implementing page replacement policies and avoiding thrashing are explored, giving you the tools to manage memory allocation effectively in high-demand situations.Disk management is another major focus of the course, where you'll learn about disk scheduling algorithms, RAID structures, and file system organization. The course emphasizes important aspects of file sharing and protection mechanisms to ensure secure and efficient file access and management.By the end of the course, you will have developed the skills and knowledge needed to tackle real-world operating system challenges. Whether you are a professional, developer, or a tech enthusiast, this course is ideal for those seeking to deepen their understanding of operating systems.

Overview

Section 1: Process Synchronization

Lecture 1 Introduction to Process Synchronization

Lecture 2 Bounded Buffer Problem

Lecture 3 Peterson Solution

Lecture 4 Test and Set Process

Lecture 5 Compare and Swap Instruction

Lecture 6 Mutex Locks

Lecture 7 Introduction to Critical section Problem

Lecture 8 Semaphores

Lecture 9 Reader Writer Problem

Lecture 10 Dining Philosopher Problem

Lecture 11 Dining Philosopher Problem using Monitors

Section 2: Process scheduling

Lecture 12 Basic Concepts, Scheduling Criteria

Lecture 13 FCFS Scheduling Algorithm

Lecture 14 Shortest Job First Scheduling algorithm

Lecture 15 Priority Scheduling algorithm

Lecture 16 Round robin scheduling algorithm

Lecture 17 Multilevel Queue Scheduling

Lecture 18 Multilevel Feedback Queue Scheduling

Section 3: Deadlocks

Lecture 19 Introduction to Deadlocks

Lecture 20 Deadlock Prevention

Lecture 21 Deadlock Avoidance

Lecture 22 Problems-Deadlock Avoidance

Lecture 23 Deadlock Detection

Lecture 24 Recovery from Deadlock

Section 4: Memory Management

Lecture 25 Swapping

Lecture 26 Paging, Structure of the Page Table

Lecture 27 Segmentation

Lecture 28 Page Fault and Steps in handling Page Fault

Lecture 29 Virtual Memory :Introduction

Lecture 30 Demand Paging

Lecture 31 Page Replacement Algorithms - FIFO

Lecture 32 Page Replacement Algorithms - Optimal Page Replacement

Lecture 33 Page Replacement Algorithms - LRU

Lecture 34 Allocation of Frames

Section 5: Disk Scheduling

Lecture 35 Introduction to Disk Scheduling

Lecture 36 FCFS-Disk scheduling

Lecture 37 SSTF-Disk scheduling

Lecture 38 SCAN-Disk scheduling

Lecture 39 LOOK-Disk scheduling

Lecture 40 CSCAN-Disk scheduling

Lecture 41 CLOOK-Disk scheduling

This course is tailored for undergraduate students pursuing degrees in computer science, information technology, or related disciplines. It is ideal for learners seeking to gain a solid foundation in the core principles and functions of modern operating systems.

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