 Hello, good morning. So thanks for joining us for this brief presentation on how to overcome the key challenges of high-end MCU application based on SCM32F7, based on your core Cortex M7, the newest core. So you could take a sit. So first of all, we have to remember the key challenges of the high-end MCU real-time applications. High-end MCU application requires more performance. It requires more real-time determinism, rich connectivity, more integration in one microcontroller, and finally, power efficiency. So low-power conceptions is one of the key challenges for high-end MCU applications. One of the examples is smartwatches or AOC applications, all of wearable devices or applications. And to reach the key challenges and to fulfill the key challenges over these applications, we need a high-end MCU answering all these key challenges and offering rich connectivity. And the example of smartwatches is needing rich connectivity, it's like connecting Wi-Fi model, LCD display to be connected through either LCD TFT interface or just parallel interface, audio interface, and as well as any connectivity to have Bluetooth model and the connect sensor. And all of this to be powered by a battery. So the SCM32-F7 is overcoming all these challenges. So today, it is the smartest SCM32 delivering the highest performance thanks to the core Tex-M7. And it brings smart architecture and also offering a rich connectivity of new brand of setup peripherals and keeping the same power consumption as the SCM32-F4, reaching down to 1 micro-amps in V-BAT remote. And the great investment is that SCM32-F7 is designed to be pin-to-pin compatible with the SCM32-F4, starting from 144 pin packages. So the SCM32-F7 is the first worst MCU based on Cortex-M7. And it is not only integrating the highest core, but it also taking advantage of all the new features of the core and with the smart architectures and connecting a rich set of peripherals. So if you remember the key challenges of high-end and serial time application is the performance, determinism, power efficiency, and the rich connectivity. So the SCM32-F7 has the smartest architecture today while combining real-time determinism and performance. So thanks to the unique RT accelerator for Flash, so we reached zero weight state execution from Flash through ITC and BAS. This is a new BAS of the Cortex-M7. Also, you have the ITCM RAM and DTCM RAM. So this is advantages for real-time deterministic executions. And for more performance, the core integrates a cache. So there is an instruction cache and data cache. Allows to accelerate CPU access to external memories as well as internal memories, either internal SRAM or internal Flash through the ICSI bus or external memory. And to reach zero weight state execution from external memory. So you have parallel data transfer, for example, from internal memory to external memory through the GP DMAs. And to take advantage of the BAS matrix, the interconnection on the BAS matrix. And you can have benefits from ITC and BAS for real-time execution from Flash and reach higher performance through the external memory through the cache, using the online cache. So the SM32-F7 is running up to 200 megahertz. So it's delivering up to 1,000 score mark today, or 428 DMIPS. So it's reaching more performance. That means better responsiveness. And at the same time, it skips power efficiency. In addition to the smart architecture, the SM32-F7 it embeds smart peripherals, a new set of smart peripherals. We have all peripherals for graphics, like LCD, DFT, the Chrome Art Accelerator, camera interface, all the connectivity around the audio, serial audio interface, I2S, and the SPG receiver. And then all of set of communication peripherals like Qzart, I2C, ZMMC for SD card, or connect to Wi-Fi module, and all external memories. And for external memories, you are extending the interface to support quad-SPI, that is more useful for graphical applications. And the most important is that any application on STM32-F4 is fully compatible. It will be fully compatible to be migrated on STM32-F7. This is to optimize, develop on time, and reaching higher performance with a new core. OK, in addition to doubling performance, but the power consumption is kept the same for low power mode versus the STM32-F4. And for dynamic conceptions, we are reaching the same performance while running at the same frequency, like delivering 7.4 mark per middle watt while running at 1.8 volt. And this is quite beneficial for the wearable application or a smartwatch to keep very low power conceptions in low power mode while switching to low power mode. You can build yours. This was one example on how to build a smartwatch applications based on high-performance MCU while not consuming, so with low power conceptions. And here we do have a prototype. So build around the ecosystem of the STM32, or like nuclear board, NFT expansion board. So this is basically on the F4-11 device. But just one example, you can build the same. The hardware is not smart, but this is just a prototype. You can build your own applications. And it is easy to move from one F4 device to F7 to reach for sure a high performance and easy migration between F4 and F7. So F7 will respond to any needs for wearable applications, industrial home automation, home appliance applications. And today, we already have running applications like home automations, control, and wearable applications. We do have on our booth one application gateway where we connected three different ecosystems, system alarm, watcher breaker, and home control. And I invite you to have a look on this gateway application, as well as we have three different demonstrations around the graphic HMI. And you'll see the advantage of the F7 while comparing to F4, how you reach a higher performance today. So that's it. Thank you.