Embedded Systems and Design & Development - Feb 20, 2026 | Afternoon | VisionAstraa EV Academy

Name: Embedded Systems and Design & Development - Feb 20, 2026 | Afternoon | VisionAstraa EV Academy
Uploaded: 2026-02-20T03:39:59.000Z
Duration: 1 h 40 min 34 s
Description: At VisionAstraa EV Academy, we are committed to shaping the future of the Electric Vehicle (EV) Industry. Our institution serves as a bridge between Academia and Industry, empowering students with the skills and knowledge needed to thrive in the EV sector.

Understanding Motor Load and Performance

Introduction to Motor Components

The discussion begins with an overview of essential components such as the main MCB, ignition switch, and key for starting the motor.

A component is introduced that helps in adjusting the load on the motor from zero to 100%, allowing for a practical demonstration of how load affects performance.

Load Impact on Motor Performance

The speaker explains how applying different loads (zero, 50%, and 100%) impacts current, voltage, and speed of the motor.

At 50% load, the speed reaches approximately 61 km/h with a DC current reading of about 23.97 amps; this indicates an increase in current draw as load increases.

Observations at Full Load

When increasing to a full load (100%), there is a noticeable spike in both current and speed; current can exceed 18 amps under maximum load conditions.

The speaker emphasizes that while voltage remains stable, significant variations in current are observed as loads change.

Fault Conditions in Electric Vehicles

Types of Fault Conditions

Discussion shifts to potential fault conditions in electric vehicles (EV), including ignition failure and emergency braking issues.

An explanation is provided regarding how these faults affect power supply; if ignition fails, acceleration will not function due to loss of supply between pedal input and main power.

Emergency Systems Overview

The conversation transitions into emergency systems like stop buttons and their importance during critical failures.

Communication Systems within EV Components

Communication Between Control Units

The roles of VCU (Vehicle Control Unit), ECU (Electronic Control Unit), and MCU (Motor Control Unit) are discussed concerning communication needs for effective vehicle operation.

Wiring for Communication

A two-wire twisted pair system is mentioned as crucial for communication among various EV components like ECUs and VCUs.

Three-phase Inverter Functionality

Conversion Process Explained

Explanation on how three-phase currents are derived from a three-phase inverter which converts DC voltage into usable AC for motors.

Clark Transformation Insight

Introduction to Clark transformation as part of Field-Oriented Control (FOC); it’s used to manage motor control effectively by converting three-phase currents into manageable forms.

Three-Phase Inverter and Control Techniques

Overview of Three-Phase Inverter Operation

The discussion begins with the operation of a three-phase inverter, where three currents (IU, IV, IW) are taken as inputs.

These currents undergo a CL transformation to convert them into two-phase parameters (Iα and Iβ), simplifying the analysis.

Transformation Process

The conversion from two-phase to direct axis (D) and quadrature axis (Q) is explained; these axes represent independent current components in motor control.

A PI controller is employed to set ID (direct axis current) to zero, optimizing efficiency by minimizing losses.

Control Mechanism

The IQ value is processed further through PWM generation, converting it back into alpha and beta voltages before being sent to the inverter for motor operation.

Emphasis on understanding the Field Oriented Control (FOC) method as crucial for effective motor control.

Detailed Explanation of Transformations

A reiteration of the transformation process: starting from three-phase currents to two-phase using CL transformation, then moving to D and Q axes via Park transformation.

Clarification that setting ID to zero allows only torque-producing components in the system.

Final Output Generation

After processing through various transformations including inverse Clark and Park transformations, three-phase voltages (VAB and VC) are generated for driving the BLDC motor.

Battery Management System Setup

Introduction to BMS Technology Kit

Transitioning from inverter discussion, a Battery Management System (BMS) setup is introduced with connected cells arranged in series.

Cell Configuration Details

Eight lithium-ion cells are used in series; participants are encouraged to count them for clarity on configuration.

Internal Resistance Testing

An internal resistance tester is presented as part of the setup; it measures how well each cell performs under load conditions.

Voltage Specifications

Discussion on nominal voltage reveals that while full charge voltage may be 3.7V, nominal voltage per lithium cell is actually 3.2V.

Total Voltage Calculation

Participants calculate total output voltage based on eight cells connected in series; expected reading should reflect cumulative nominal voltages.

Battery Voltage Measurement and BMS Technology

Connecting Cells and Measuring Voltage

The first cell shows a voltage of 3.7V, indicating it is fully charged.

As the second cell is connected, the voltage increases to 6.6V, then to 9.7V for the third cell.

The fourth cell measures at 13.5V, while the fifth reaches 16.3V; the sixth cell shows 19.1V.

The seventh cell's connection results in a total voltage of 25.4V, aligning closely with the DC meter reading of 25.3V.

Smart BMS Technology Overview

Introduction of smart Battery Management System (BMS) technology that monitors total voltage across cells.

Active balancer connections allow real-time monitoring of battery pack voltage and current values.

Components Demonstration

A setup is shown where individual cell voltages can be calculated using specific components.

Discussion on various components used in real-time applications, including temperature sensors and voltage indicators.

Battery Pack Structure

Explanation of motor control units (MCUs), Vehicle Control Units (VCUs), and their relevance in electric vehicles like Ola.

Description of an Ola battery pack structure featuring cylindrical lithium-ion cells interconnected with thin sheets.

Motor Control Unit Insights

Overview of a motor control unit designed for Permanent Magnet Synchronous Motors (PMSM), highlighting its three-phase wiring system.

Discussion on communication links between battery supply and motor controllers via CAN communication protocols.

DCDC Converter and EV Charging Overview

Understanding DCDC Conversion

The discussion begins with an introduction to a DCDC converter that transforms 36V and 72V inputs into a 12V output, highlighting its function in voltage conversion.

Participants are prompted to identify the type of conversion occurring, leading to the conclusion that it is a buck converter, which steps down voltage effectively.

Home EV Charging Solutions

The speaker mentions a specific charger used for home applications, particularly for electric vehicle (EV) charging, noting that it takes longer than public chargers due to AC to DC conversion processes.

A brief overview of the session's objectives is provided, indicating an intention to explain how components are connected within vehicles.

Vehicle Battery Configuration

The conversation shifts to a specific EV model (BNM 1200), detailing its dual battery pack setup—one located at the rear and another at the front—emphasizing swappable technology.

Motor Controller and Hub Motor Insights

An explanation of the motor controller's placement within the vehicle is given, along with details about three-phase power transfer to the hub motor connected directly to the wheel.

The speaker notes that using a battery pack exceeding 60 volts allows operation of this assembled vehicle model (Ather 450), concluding with hopes that attendees found the session informative.