In this hands-on workshop, our STM32 experts will provide a complete overview of the performance, communication, and security features of the STM32H5 MCU, and explain how they can make a real difference in your design.
The STM32H5 MCU sets a new standard for mainstream microcontrollers, thanks to the most powerful implementation of the Arm Cortex-M33 core running as high as 250 MHz – a first in the MCU world. Reaching a 1017 CoreMark score, the STM32H5 comes with up to 2 Mbytes of flash memory and up to 640 Kbytes of RAM. It also features CORDIC and FMAC accelerators, and is the first STM32 to come with an I3C interface.
During the session we will walk you through an embedded application example based on the STM32H5 so you can see some of its features in action, such as GPIO states retention, I3C interface, and GPDMA, and try them out yourself*.
*An STM32H5 development board will be provided by STMicroelectronics for use during the workshop, and collected at the end of the training.
This workshop is part of the ST Technology Tour 2023 Santa Clara event and is free to attend. Separate registration is required due to a limited number of seats and development kits.
At 10:00 AM CET, the session will start with STMicroelectronics:
10:00 - 10:40 AM CET
- Overview of the power features of GaN that make it ideal to work at very high frequencies with low losses
- GaN in some power converters topologies (ACF, LLC, totem-pole PFC), with a focus on LLC resonant converters
At 10:40 AM CET, Würth Elektronik will explain:
10:40 - 11:20 AM CET
- How to select the correct transformer in power conversion application
- Transformers for LLC resonant converters with GaN
11:20 - 11:30 AM CET: Question & Answers
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
Greg has nearly 30 years in embedded design of hardware and software and has been at ST for over 10 years. In addition to general MCU/MPU technical marketing support in the Americas region, he also serves as an audio specialist for ST due to his background as a professional musician coupled with a DSP emphasis during his BSEE and design experience.
Anis joined ST in 2002 and has worked in firmware development, customer support, and training on STM32 products and software ecosystem, with focus on connectivity (USB and Ethernet). Today, he is an FAE supporting customers in the California Bay Area. He holds a masters in electrical engineering from the National School of Engineering of Monastir, Tunisia.
The STM32H5 development board (NUCLEO-H563ZI) provides an affordable and flexible way for users to try out new concepts and build prototypes by choosing from the various combinations of performance and power consumption features provided by the STM32 microcontroller. For compatible boards, the external SMPS significantly reduces power consumption in Run mode.
The ARDUINO® Uno V3 connectivity support and ST morpho headers allow easy expansion of the functionality of the STM32 Nucleo open development platform with a wide choice of specialized shields.
The STM32 Nucleo-64 board does not require a separate probe, as it integrates the ST-LINK debugger/programmer. It comes with STM32 comprehensive free software libraries and examples available with the STM32Cube MCU package.
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