NEW: Automotive E-Mobility Software Developer
Description
E-Learning package for Automotive Electromobility Software Developer
Welcome to our cutting-edge e-learning package tailored specifically for Automotive Electromobility Software Developers. Dive into a comprehensive range of courses designed to elevate your skills and knowledge in this rapidly evolving field.
Our package covers a multitude of essential topics, including ASPICE, providing insights into its purpose and detailed information on engineering and management processes. You'll also explore automotive cybersecurity, understanding its significance, regulatory frameworks, and practical implementation strategies. Additionally, delve into encryption methods, electric vehicles, electri…
Frequently asked questions
There are no frequently asked questions yet. If you have any more questions or need help, contact our customer service.
E-Learning package for Automotive Electromobility Software Developer
Welcome to our cutting-edge e-learning package tailored specifically for Automotive Electromobility Software Developers. Dive into a comprehensive range of courses designed to elevate your skills and knowledge in this rapidly evolving field.
Our package covers a multitude of essential topics, including ASPICE, providing insights into its purpose and detailed information on engineering and management processes. You'll also explore automotive cybersecurity, understanding its significance, regulatory frameworks, and practical implementation strategies. Additionally, delve into encryption methods, electric vehicles, electrified powertrains, electrical machines, serial bus systems, operating systems, real-time operating systems, and vector control.
Through these meticulously crafted courses, developers will master ASPICE implementation, software development related to AUTOSAR™, battery systems, cybersecurity protocols, control of electrical machines, encryption techniques, electric vehicle charging infrastructure, serial bus systems, as well as operating and real-time operating systems.
Equip yourself with the indispensable skills and knowledge required to thrive in the Automotive Electromobility Software Development landscape. Stay ahead of the curve, tackle complex challenges with confidence, and drive innovation forward in automotive e-mobility.
The following courses are included in this package:
Embedded Software Basics
Content: 1 hour and 15 minutes, study time: 14 hours and 10 minutes
Fixed Point Arithmetic
- Storage of Numbers in Memory
- Value Range and Accuracy
- Error Possibilities
- Mathematical Representation and Conversion
- Arithmetic Operations
- Advantages and Disadvantages
Floating Point Arithmetic
- Exponential Representation
- Single and Double
- Storage of Numbers in Memory
- Value Range
- Error Possibilities and Exceptions
- Advantages and Disadvantages
Introduction to Serial Bus Systems
Content: 2 hours and 50 minutes, study time: 6 hours and 15 minutes
Basic Terms
- Motivation (the term bus, typical applications, real time, serial vs. parallel transmission).
- Transmission path (simplex/duplex, bit rate, baud rate, clock
signal, communication models, latency, payload and control
data)
protocol (structure, principles, protocol stack) - System components (router, gateway, switch and repeater)
OSI Model
- Motivation, mode of operation and basic model structure
- Transport-oriented layers and their tasks
- Application-oriented layers and their tasks
Physical Layer
- Different types of transmission media
- Basic structure and examples of connectors
- Binary representation (endianness, bit significance and different codings)
Data Link Layer
- Communication Process: synchronous and asynchronous serial communication, routing schemes, topologies
- Possibilities for secure data transmission, e.g. parity bit
- Different access control methods
CRC Basics
- Usage and definition
- Explanation of the generator polynomial
- Calculation of the CRC using two examples
Operating System
Content: 55 minutes, study time: 4 hours and 35 minutes
- General Introduction
- Kernel
- Multitasking
- Safety and other Advanced Aspects
- Embedded OS
Real-Time Operating System
Content: 1 hour and 5 minutes, study time: 5 hours and 25 minutes
- General Introduction
- Revision
- Characteristics
- Tasks
- Scheduling
- Typical Problems
Cryptography
Content: 4 hours, study time: 20 hours
Classical Cryptography
- Cryptography Basics
- Scytale
- Caesar Cipher
- Vigenère Cipher
- One-Time Pad
- Enigma
Modern Cryptography
- Who are Alice and Bob?
- Symmetric Encryption
- Asymmetric Encryption
- Hybrid Encryption
- DES (Data Encryption Standard)
- AES (Advanced Encryption Standard)
- Diffie-Hellman Key Exchange
- RSA
Electronics and Electrical Fundamentals
Content: 3 hours and 10 minutes, study time: 15 hours and 50 minutes
- Electronics and Magnetism
- Important Components and Principles
- Circuits
- Alternating Current Circuits
- Basics of Power Electronics
Power Electronics Fundamentals
Content: 2 hours and 10 minutes, study time: 10 hours and 50 minutes
Basics of Power Electronics
- Definition, application fields and basic functions
- Electronic switch and switching in general
- Example of an electronic circuit
- The basic components resistor, inductor, capacitor and diode
Components of Power Electronics
- Semiconductor Basics (doped semiconductor, p-n-junction, biased p-n-junction)
- Semiconductor Components (non-controllable and only switch-on)
- Functionality and characteristic line of a diode
- Switchable power semiconductors
- MOSFET (4 types, functionality, characteristic line)
Vector Control
Content: 45 minutes, study time: 4 hours and 45 minutes
- Edith Clarke and Robert H. Park
- The Clarke Transformation
- The Park Transformation
Battery and Battery Systems
Content: 1 hour and 30 minutes, study time: 7 hours and 30 minutes
E-Learning Basics of Power Electronics
- Definition, application fields and basic functions
- Electronic switch and switching in general
- Example of an electronic circuit
- The basic components resistor, inductor, capacitor and diode
E-Learning Components of Power Electronics
- Semiconductor Basics (doped semiconductor, p-n-junction, biased p-n-junction)
- Semiconductor Components (non-controllable and only switch-on)
- Functionality and characteristic line of a diode
- Switchable power semiconductors
- MOSFET (4 types, functionality, characteristic line)
Electrical Machines
Content: 1 hours and 45 minutes, study time: 8 hours and 45 minutes
Basics of Electrical Machines
- Subcomponents of an Electrical Machine
- Rotating Field Machines
- Concentrated vs Distributed Windings
- Different Rotor Types
- Reluctance Machines
- General Development Targets
- Requirements Management
Permanent Magnet Synchronous Machines
- Permanent Magnet Synchronous Machine
- E-Machine Simulation Procedure
- Torque Characteristics
- Single Losses
Synchronous Machines
- Synchronous Machine
- Torque Characteristics
- Single Losses
Induction Machines
- Induction Machine
- Torque Characteristics
- Single Losses
- Comparison IM Types
DC & Brushless DC Machines
- DC & Brushless DC Machine
- Connection Variants
- DC Machine with PM Excitation
- Brushless DC Machine
Control of Electrical Machines
Content: 3 hours, study time: 15 hours
Field-Oriented Control
- DC Motor
- Derivation of Field Orientation
- Electrical Machine as a Controlled System
- Inverter as Control Actuator
- Other Machine Types
Control Design
- Procedure of Control Parameterization
- Cascaded Control for Powertrain
E-Mobility
Content: 2 hours and 20 minutes, study time: 11 hours and 40 minutes
Introduction
- Mega Trends
- Use Cases and TCO
- Disruptive Market
EV Charging Basics
- Charging Basics
- Charging Dependency and Bidirectional Charging
Electric Vehicle System
- System Powertrain
- Electric Drive System Design
- Functional Safety
- System Energy Management
EV Charging
Content: 2 hours and 30 minutes, study time: 10 hours and 50 minutes
EV Charging Basics
- System approaches on charging
- Charging standards
- Charging modes according to IEC 61851-1
- Charging Plugs
- Charging Dependency on the State-of-Charge (SOC)
- Bidirectional Charging
Automated Charging
- Nikola Tesla & Inductive Charging
- Types of Inductive Charging
- Inductive Charging Layout & Efficiency
- Auxiliary Functions
- Automative Conductive Charging, System Requirements and Process
Charging Use Cases
- Charging Use Cases: At Home
- Charging Use Cases: At Work
- Charging Use Cases: At A Shop
- Charging Use Cases: At Travels
- Charging Use Cases: Vehicle to Device
Grid Interaction
- Electric Vehicles & Renewable Energies
- Energy Production, Consumption and Pricing
- Regional Power Generation
Communication in EV Charging: Pilot Signal & Duty Cycle
- Pilot Signal
- Frequency
- Duty Cycle
- Relation Duty Cycle – Current
- Inside the EV
Communication in EV Charging: High Level Communication
- OSI Model
- Physical Layer
- Data Link Layer
Electrified Powertrain
Content: 4 hours and 45 minutes, study time: 23 hours and 45 minutes
Power Electronics
- Basics of Power Electronics
- Components of Power Electronics
- Principle of Half Bridge
- Thermal Design and Assembly
Electrical Machines – Basics
- Basics of Electrical Machines
- Permanent Magnet Synchronous Machine
- Synchronous Machine
Control of Electrical Machines – An Introduction
- Basics of Control Systems
- Field Orientation as the Principal Tool of Control
- Control Design
- Strategy of Control
Battery and BMS
- Battery System
- Battery Cell
- Battery Management System (BMS)
Noise, Vibration and Harshness (NVH)
Content: 30 minutes, study time: 2 hours and 30 minutes
- Physical Description of Sound
- Psychoacoustics
- Noise Contribution and Propagation
- Sound Design
Automotive SPICE PAM V3.1 - An Overview
Content: 1 hour and 35 minutes, study time: 7 hours and 55 minutes
- Reasons for the introduction of Automotive SPICE
- Relation to other standards
- How does Automotive SPICE work?
- Example: MAN.3 project management
Automotive SPICE PAM V3.1 - Engineering
Content: 2 hours and 50 minutes, study time: 14 hours and 10 minutes
System Engineering Processes
- SYS.1: Requirements Elicitation
- SYS.2: System Requirements Analysis
- SYS.3: System Architectural Design
- SYS.4: System Integration and Integration Test
- SYS.5: System Qualification Test
Software Engineering Processes
- SWE.1: Software Requirements Analysis
- SWE.2: Software Architectural Design
- SWE.3: Software Detailed Design and Unit Construction
- SWE.4: Software Unit Verification
- SWE.5: Software Integration and Integration Test
- SWE.6: Software Qualification Test
Automotive SPICE PAM V3.1 - Supporting Processes
Content: 1 hour and 45 minutes, study time: 8 hours and 45 minutes
- SUP.1: Quality Assurance
- SUP.8: Configuration Management
- SUP.9: Problem Resolution Management
- SUP.10: Change Request Management
Automotive Cybersecurity
Content: 45 minutes, study time: 4 hours and 45 minutes
- Why Automotive Cybersecurity matters
- Regulations and Standards
- Cybersecurity in the Product Life Cycle
- Cybersecurity Threat Analysis, Risk Assessment and Treatment
- Cybersecurity Controls and Requirements
- Cybersecurity Verification and Validation Testing
By booking this package you have access to this courses for 📅 12
months.
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