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

Speaker

Jeff Halio

Product Marketing Engineer

Jeff Halio is a Product Marketing Engineer at STMicroelectronics, supporting the general purpose analog portfolio. Based in the Burlington, MA office, he joined ST in 2018 and has supported a wide variety of products at ST customers in the eastern US and Canada. Jeff graduated from Tufts University in 1994 with a BSEE.

Product details:

The 6 V to 75 V wide input voltage range L3751 synchronous buck controller features extreme voltage conversion ratio over switching frequency range (100 kHz - 1 MHz) thanks to 40 nsec minimum conduction time. The diode emulation (DEM) implements pulse skipping mode that maximizes the efficiency at light-load while providing controlled output voltage ripple. The forced PWM (FPWM) over the load range makes the switching frequency constant and minimizes the output voltage ripple. The L3751 supports a Power Good open collector output, embedded gate driver, output overcurrent protection, input voltage UVLO, internal voltage monitoring, and thermal shutdown.