 Hello, my name is Marco Defazio, I am a strategic marketing manager for the region of America, and we are here at CES 2019, where I will talk to you about our offering for educational platforms. This is the sensor tile, you might be familiar with this, this is our most popular development tool for wearable systems, it's a highly integrated system in very compact form, it embeds a microcontroller, a Bluetooth low energy and all sorts of sensors from a 6-axis IMU to a digital microphone and all the environmental sensors. We have used this tool to develop teaching material to allow students to learn everything that is to know into building embedded systems. We did that with Professor William Kaiser at UCLA, where we have a very strong collaboration in developing educational material. The educational material will teach students everything there is to know about developing an embedded systems from the very basics of installing an IDE on a computer, how to interface with the microcontrollers, and then how to connect with the sensors using a Bluetooth. The tutorials would go up to a very advanced system development. We have two tutorials developed at UCLA, one from freshman students and one more advanced for senior students. And this has proven to be a very effective system where the students just need to have a sensor tile and then they find online through our website all the teaching materials in tutorial formats. They will follow step-by-step instruction and learn everything there is to know about embedded systems. Beside embedded systems we decided to offer a solution to learn everything there is to know about motor control. We are building a prototype, this also was developed at UCLA. It's a rotary inverted pendulum and the system is built around our nuclear ecosystem and the STM32 open development environment. We have a white microcontroller board with an STM32F4 and a motor driver for a stepper motor. The students will learn how to interface with the microcontroller, how to install the firmware for motor control, how to attach the motor driver and how to drive the motor. And together with that to make this system more appealing they will have to solve the control system. The control system is very simple, it's a full rotor inverted pendulum where there is only one degree of freedom and the stick is completely free to move. There is an encoder also connected to the microcontroller and with simple PID loops freshman students will be able to solve this problem and develop firmware to keep the pendulum upright. So this is the way it works. So now the system is balancing but not only takes care of keeping the stick upright but it also controls the angle towards the system it's pointing to. Now this is done through a dual PID control loop and this is actually a very compelling problem for students to solve because the two PID control loop kind of fight each other. Teaching material will be also available for this system. We will start in June with a tutorial set base for freshman students but we will also offer later on next year more advanced tutorial that will focus on more advanced control systems. All the teaching material is available through our website at st.com-sensor-edu. It's an open source format. We have a lot of options through other universities also on the sensor type curriculum. Everybody can use the curriculum for free, the IDE also is free and everybody is welcome to contribute to the curriculum itself. In fact we also have built a community of professors that are exchanging ideas and they are contributing to our educational solution. Thank you very much.