Agenda

  • STM32Cube ecosystem overview & STM32U5 MCU series overview
  • New features of STM32CubeIDE and STM32CubeMX for the STM32U5 MCU series

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Workshop agenda

Time

Content

8:00 - 9:00

Registration and system check for pre-installed tools

Morning session: Stepper motors with STSPIN820 / POWERSTEP01

9:00 - 10:00

Stepper motor fundaments

Theory: What makes a stepper turn?

Voltage and current mode drive

Limitations,speed/torque,ect

9:00 - 10:00

Stepper motor fundaments

Theory: What makes a stepper turn?

Voltage and current mode drive

Limitations,speed/torque,ect

11:30 - 12:30

Lunch

11:30 - 12:30

Lunch

11:30 - 12:30

Lunch

11:30 - 12:30

Lunch

10:00 - 11:30

STSPIN820 or POWERSTEP01

Using the GUI to evaluate motor operation

Configuring motor control parameters with the GUI

Implementing a drive based on the firmware pack

10:00 - 11:30

STSPIN820 or POWERSTEP01

Using the GUI to evaluate motor operation

Configuring motor control parameters with the GUI

Implementing a drive based on the firmware pack

9:00 - 10:00

Stepper motor fundaments

Theory: What makes a stepper turn?

Voltage and current mode drive

Limitations,speed/torque,ect

11:30 - 12:30

Lunch

Afternoon session: BLDC motors with STSPIN32F0

12:30 - 1:30

BLDC theory and fundamentals

# pole pairs

What makes FOC work (donkey and carrot example)

Sensoriess vs. Sensored feedback control

1:30 - 3:00

Implementing a 6-step drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

Afternoon session: BLDC motors with STSPIN32F0

12:30 - 1:30

BLDC theory and fundamentals

# pole pairs

What makes FOC work (donkey and carrot example)

Sensoriess vs. Sensored feedback control

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

Afternoon session: BLDC motors with STSPIN32F0

12:30 - 1:30

BLDC theory and fundamentals

# pole pairs

What makes FOC work (donkey and carrot example)

Sensoriess vs. Sensored feedback control

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

Afternoon session: BLDC motors with STSPIN32F0

12:30 - 1:30

BLDC theory and fundamentals

# pole pairs

What makes FOC work (donkey and carrot example)

Sensoriess vs. Sensored feedback control

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

Afternoon session: BLDC motors with STSPIN32F0

12:30 - 1:30

BLDC theory and fundamentals

# pole pairs

What makes FOC work (donkey and carrot example)

Sensoriess vs. Sensored feedback control

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

Afternoon session: BLDC motors with STSPIN32F0

12:30 - 1:30

BLDC theory and fundamentals

# pole pairs

What makes FOC work (donkey and carrot example)

Sensoriess vs. Sensored feedback control

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

Afternoon session: BLDC motors with STSPIN32F0

12:30 - 1:30

BLDC theory and fundamentals

# pole pairs

What makes FOC work (donkey and carrot example)

Sensoriess vs. Sensored feedback control

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

Afternoon session: BLDC motors with STSPIN32F0

12:30 - 1:30

BLDC theory and fundamentals

# pole pairs

What makes FOC work (donkey and carrot example)

Sensoriess vs. Sensored feedback control

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

Afternoon session: BLDC motors with STSPIN32F0

12:30 - 1:30

BLDC theory and fundamentals

# pole pairs

What makes FOC work (donkey and carrot example)

Sensoriess vs. Sensored feedback control

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

3:00 - 4:30

Implementing a FOC drive

Speakers

Product details

The VIPERGAN50 is a high voltage converter, designed for medium power quasi-resonant ZVS (Zero Voltage Switching at switch turn-on) flyback converters, capable to provide an output power up to 50 W in wide range.

It integrates a complete set of features that provide an extremely flexible and easy to use chip and helps to design a highly efficient offline power supply. The ZVS quasi-resonant operation with the dynamic blanking time feature and the valley synchronization function, that turns on the power switch always at the valley of the drain resonance, reduces the switching losses and maximizes the overall efficiency at any input line and load condition. The advanced power management with the low quiescent helps to achieve low stand-by consumptions. The feed-forward compensation minimizes the maximum output peak power variation over the entire input voltage range.