Detailed Course Curriculum
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Welcome to the Course
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Software download
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How to use Discussions option
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Course access duration
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Piracy & infringement warning
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Aerodynamic forces modeling (3 cases)
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NEDC drive cycle
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Motor Data
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Sales
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Day 1: Intern onboarding
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Scilab Softwares download
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Day 2: Scilab introduction & Scilab Programing Part 1
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Day 2: Scilab introduction & Scilab Programing Part 2
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Day 2: Scilab introduction & Scilab Programing Part 3
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Day 3: Scilab Xcos introduction & Practice Part 1
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Day 3: Scilab Xcos introduction & Practice Part 2
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Day 3: Scilab Xcos introduction & Practice Part 3
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Day 3: Scilab Xcos introduction & Practice Part 4
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Day 4: Practice Scilab Xcos with real time problems Part 1
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Day 4: Practice Scilab Xcos with real time problems Part 2
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Day 4: Practice Scilab Xcos with real time problems Part 3
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Day 4: Practice Scilab Xcos with real time problems Part 4
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Day 5: Creating data visualization & analysis graphs in Scilab Part 1
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Day 5: Creating data visualization & analysis graphs in Scilab Part 2
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Day 5: Creating data visualization & analysis graphs in Scilab Part 3
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Day 5: Creating data visualization & analysis graphs in Scilab Part 4
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Day 5: Creating data visualization & analysis graphs in Scilab Part 5
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Day 5: Creating data visualization & analysis graphs in Scilab Part 6
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Day 5: Creating data visualization & analysis graphs in Scilab part 7 (Help video)
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Drive Cycle Data
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Program to define vehicle parameters
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Grade Data
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Model Images
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Water Tank Level Control
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Track Data
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Reference Document for report
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Comparison Documents for Vehicle Resistive Force Assignment
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Resistive Forces assignment submission
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Day 1: Modeling of Vehicle Resistive forces Part 1
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Day 1: Modeling of Vehicle Resistive forces Part 2
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Day 1: Modeling of Vehicle Resistive forces Part 3
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Day 1: Modeling of Vehicle Resistive forces Part 4
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Day 1: Modeling of Vehicle Resistive forces Part 5
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Day 2: Modeling of Vehicle Resistive forces continued Part 1
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Day 2: Modeling of Vehicle Resistive forces continued Part 2
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Day 2: Modeling of Vehicle Resistive forces continued Part 3
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Day 2: Modeling of Vehicle Resistive forces continued Part 4
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Day 2: Modeling of Vehicle Resistive forces continued Part 5
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Day 2: Modeling of Vehicle Resistive forces continued Part 6
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Day 2: Modeling of Vehicle Resistive forces continued Part 7
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Day 3: Modeling of Vehicle Resistive forces continued Part 8
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Day 3: Modeling & analysis of control system Part 1
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Day 3: Modeling & analysis of control system Part 2
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Day 3: Modeling & analysis of control system Part 3
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Day 4: Modeling & analysis on control systems Quiz
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Day 4: Modeling & analysis of control system continued Part 1
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Day 4: Modeling & analysis of control system continued Part 2
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Day 5: Problem solving with Xcos challenge Part 1
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Day 5: Problem solving with Xcos challenge Part 2
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Overtaking ADAS System - Theory Part 1
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Overtaking ADAS Systems - Theory part 2
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Overtaking ADAS System - Theory Part 3
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Overtaking ADAS System - Modelling and Simulation
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About this course
- 65 lessons
- 14 hours of video content
- 4.5 course rating & 1210+ learners
About the Course
Do you know? due to road accidents in our country, India loses 3% of its GDP? Which is over 435,000 Core INR/year. Specifically, overtaking during driving contributes to the highest number of fatal deaths. Can we build a technology solution? To reduce the fatal deaths.
Overtaking Driver Assistance System (ADAS) is the possible technology solution that can address the needful along with the adherence to traffic & driving rules.
Course Overview
For the driver, an overtaking maneuver is one of the toughest and most dangerous maneuvers among other maneuvers while driving a vehicle. Developing Overtaking Driver Assistance System helps the driver to overtake the vehicle in a smooth way, safely, and without collision. This in turn reduces the accidents caused due to overtaking of vehicles. In order to develop overtaking ADAS systems, an efficient controller is required; which is developed with various scenarios in this course for safe maneuver.
During this course, we will understand the complete system, functioning, logic, mathematics behind the system modeling, equations to create the Model-Based Design, build the model in simulation software, and analyze & tune the system to get the desirable results. 100% hands-on to build the numerical model using the Scilab-Xcos.
Course content
- Introduction
- Sensors needs
- Lidar
- Radar
- Velocity sensor
- Scenarios
- Without Surrounding Vehicle – only overtaking and to be overtaken vehicle
- With Surrounding Vehicle – Vehicle behind overtaking vehicle
- Control Algorithm
- High-Level Controller
- Low-Level Controller
- Modeling Vehicle Behaviour
- Time to collision
- Driver Steering Response
- Scilab-based Model Development
- XCos-based Model Development
- Simulation results analysis and discussion.
- Conclusion
- Future Scope of Work
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Overtaking Driver Assistance System Modeling & Simulation in Scilab
₹3,999.00
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Reach us for any queries - 7411019255 / [email protected]
Sample Certificate
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Frequently Asked Questions
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Should I have any prerequisite knowledge to learn this course?
The course will be taught from fundamentals with real-world examples & hands-on sessions. It should not be a concern if you do not have prior exposure to programming/software used.
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Should I need a computer?
Yes, you will need a computer to practice.
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How the teaching will happen?
You will get full access to the course upon the completion of payment.
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What should I do, if I get a doubt?
You need to report the doubts/issues over the Discussion box available in the course. The course coordinator will clarify your doubts by replying via the discussion box. If needed, we will arrange meetings with the mentor, to clarify your doubts via Zoom.
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How will I build projects?
Projects will be guided by the mentor with the help of recorded lectures.
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How much time do I have to spend everyday?
We suggest 2 hours per day, an average of 10 hours per week.