1. Single Wire Heating and Hands-off Detection (HoD)

Hands-off Detection is a new use case for automotive steering wheels as well as handle bars of motor bikes. Our demo shows Microchip’s breakthrough cost-down solution to combine Heating and HoD sensing into one sensor – the slimmest implementation at the lowest cost.

2. Radiant Heating

EV’s are all about energy efficiency. Radiant Heating addresses that by enabling to heat your car up with 30% less energy. In addition, it is also faster, so your customers will feel faster and more comfortable in winter times. A cozy ride, while preserving energy and extending EV range.

3. Functional Safety Touch – Drive Mode Selector

Functional Safety is of crucial importance for safety relevant aspects of the user interface. Please see a full implementation of a ISO26262, ASIL-B Drive Mode selector using touch buttons. Our flexible solution will speed up any of your safety touch application.

4. New Touch Turnkey Solutions

Safe time, enables a sleek touch interface in your product without spending crucial software engineering resources – sounds too good to be true? Not anymore! Our new lineup of touch turnkey devices provides all the flexibility and design in supporting you expectation – without the need to touch firmware.

5. On-Cell Foldable OLED with maXTouch^® Knob-on-Display™ Technology

Demonstrate high-performance maXTouch^® Technology using new M1-generation product family in flexible OLED panel, with innovative Knob-on-Display™ (KoD™) technology. Primary target for automotive market and can extend to industrial market. Learn more here.

6. Robust Touchscreen Solution for Two-Wheelers

Adding a touchscreen as a user interface on two-wheelers like E-bikes, motorcycles and scooters has become a popular feature. Because two-wheelers are used outdoors, they are exposed to a variety of harsh outdoor conditions including rain, snow, dust, exposure to sunlight and vandalism. Demonstrate robust touchscreen solutions using maXTouch^® Technology. Learn more here.

7. Tactile Twist on Modern Touch Display Using maXTouch^® Knob-on-Display™ Technology

Microchip's innovative maXTouch^® Knob-on-Display™ (KoD™) technology and its use in the kitchen and the car for cutting edge user interfaces. See the convergence of tactile feedback from a traditional knob with a modern interactive display enabling local control of smart home appliances and reduced driver distraction in cars. Learn more here.

8. maXTouch^® Rugged Outdoor Touchscreen Solution with Fountain

maXTouch^® touchscreen controllers use unique and patented sensing algorithms for robust and reliable touch operation in the most challenging environments. With excellent immunity to water and electromagnetic noise and the ability to detect touch through thick gloves or front panels, these touchscreen controllers are well suited for outdoor applications including 2-wheelers, EV Charger Piles, Ruggedized Tablets, Marine, etc. Demonstrate a maXTouch^®-based rugged touchscreen solution that is resistant to water drops and running water. Learn more here.

9. Motor Control with Time Sensitive Networking (TSN)

From robots to rockets – witness the future of connectivity! We are showcasing Time-Sensitive Networking (TSN) on PolarFire^® SoC FPGAs to demonstrate precise, time-critical communication for industrial automation, robotics and space applications.

10. 10BASE-T1S for Industrial and Automotive Applications

This demonstration is a collaborative effort with ASRock Industrial, a subsidiary of Pegatron Corporation. The demo features an Industrial PC (IPC) equipped with T1S Ethernet and multiple T1S Edge Nodes (4-5 nodes). The IPC, designed by ASRock, incorporates Microchip's T1S product. The Edge Nodes are based on Microchip's new T1S EP products. The demonstration showcases potential applications such as the industry IoT controlling, robotics and automotive zone architecture.

11. Smart Stepper Motor Driver

The AVR EB MCU-based Smart Stepper Motor Driver simplifies precision motion control by eliminating the need for external controllers, reducing cost and complexity. With built-in signal generation and real-time fault detection, it ensures reliable performance for robotics, automation and e-mobility applications. Learn more here.

12. I3C Display – Reimagining Display Connectivity

Microchip’s I3C-based display solution simplifies HUB75 LED panel connectivity by reducing wiring and enabling hot-swappable integration. With high-speed communication and enhanced flexibility, it’s ideal for data centers, automotive, industrial and consumer applications.

13. PCI12000 AI Demo

PC12000 PCIe^® fanout switch enables the AI coprocessor and allow to highlight objects from the camera and bounding with green boxes around anything interesting.

14. AIoT for Industry 4.0

15. Two-Phase Smart Metering

The PIC32CXMTC series is our next-generation smart metering platform built around two high-performance 32-bit ARM(R) Cortex(R)-M4F processors. This dual-core architecture integrates the application and metrology functions in a single device. The demonstration board includes a polyphase energy metering analog front-end with three voltage and four current sense channels. Current channels are designed to interface with Current Transformers (CTs), Rogowski coils and shunt current resistors. Radio and PLC communication capabilities based on industry-leading communications protocols like G3, PRIME and IEEE(R) 802.15.4g are possible by means of plugged-in modules at the available expansion ports. Learn more here.

16. Truck Loading Bay Monitoring Augmented by AI

Discover a parking lot/truck loading bay monitoring application running on our single-core Arm^® Cortex^®-A7 Microprocessor, the SAMA7G54. This demo is augmented by AI leverages Edge Impulse model creation and training capabilities. Learn more here.

17. Smart Door Lock Based on Facial Recognition

Experience the cutting-edge SAMA7G54 32-bit microprocessor, featuring an Arm^® Cortex^®-A7 core running at 1 GHz in our smart door lock demo. Witness lightning-fast facial recognition and quick enrollment, ensuring secure and seamless access control.

18. Stamford Connected to Multiple Orin Processors and ASA-ML SerDes Providing Camera Data

This demo demonstrates the power of our latest PCIe^® switch family and ASA-ML zonal aggregators, which leverages seamless multi-host communication, forming the foundation of a scalable central computer architecture for the automotive HPC.

19. Stream Analyze Predictive Maintenance Demo

This demo showcases the use of the Stream Analyze SA Studio application running in firmware on the SAME54 32-bit microcontroller. The on-chip real-time analysis is performed to determine unbalanced loading in a motor control system with statistical models and communicate via a Python-based script that communicates using TensorFlow. This allows the overall system to utilize cloud-based secondary processing for the model to both "learn" and be re-deployed across additional end nodes.

20. Motor Control AI/ML Predictive Maintenance Application

This demonstration application simulates predictive maintenance for motors using the MPLAB^® Machine Learning Development Suite with the dsPIC LVMC motor control board. This is based on classification model to determine the operational state of a motor – whether it is in normal condition or experiencing anomalies such as unbalanced load and a broken bearing – by monitoring the Iq current of the motor. Learn more here.

21. Solar Power Management HMI

This is a graphics demo to showcase the capabilities of the SAMA7D65.

22. Automotive Dashboard GUI with Screen Mirroring

This automotive dashboard GUI with screen mirroring of the map from the phone over Wi-Fi^® is a graphics demo to showcase the capabilities of the SAM9X75.

23. Smart Home Automation/Security Touchscreen Panel with Camera Feed

This demo showcases the image sensor on SAM9x75 connected via ethernet to SAMA7D65 curiosity with home automation 10-inch 1280x800 LVDS touchscreen.

24. MPU/BLE Map Navigation

25. Scalable Graphics and Touch Demo

This demo shows scalable HMI solutions with integrated graphics and touch libraries on microcontrollers. It features three demos including the low-end (PIC32CM LS+ OLED), mid-range (SAME51 + 3.5" LCD) and high-end (PIC32CZ CA80 + 4.3" LCD), highlighting various graphics and touch capabilities.

26. In-Flight Programming with RTPF Development Kit and SAMRH71 Kit

In the frame of a space flight application deployment, system partial or full reconfiguration/reprogramming after integration is becoming a stringent requirement.

Combining the flexibility of the radiation tolerant FPGA structure and the efficiency of the radiation hardened or radiation tolerant microcontrollers, Microchip can provide space applications with the highest level of in-flight reconfiguration.

The Microchip RT PolarFire^® FPGA offers an unrivaled space rated FPGA that can be reprogrammed during their flight. Reprogramming is done through a simple interface that can be managed by a processor/microcontroller. Combined with the SAMRH71F20 space rated microcontroller that is capable to operate up to 200 DMIPS/s, it becomes quite simple to provide a reconfigurable architecture to your space application. Interconnecting the FPGA and the microcontroller with only a few IOs allows us to manage the complete reprogramming process, emulating the JTAG interface and the configuration protocol directly in the microcontroller firmware.

The main principle of the RT FPGA reconfiguration is that the microcontroller manages the in-flight programming process of the RT FPGA thanks to the Direct C library that emulates both the JTAG interface of the FPGA and the configuration protocol.

Learn more here.

27. PolarFire^® Software-Defined Radio Demo with ADRV9002

A well-designed Software-Defined Radio (SDR) typically comprises various fixed components, such as an antenna, front-end RF hardware and an ADC or DAC. The remaining functionalities are implemented in a programmable medium, referred to as "soft" components. While general-purpose processors are commonly used for this purpose, they often lack the required I/O bandwidth and processing capabilities, except for the most basic SDR architectures. FPGA systems fulfill the demands of complex SDR implementations by offering both the necessary I/O bandwidth and processing capabilities.

This demonstration outlines an SDR application on the PolarFire^® SoC FPGA. Baseband processing is implemented on the FPGA and transmitted using a wideband RF transceiver, ADRV 9002. The transceiver is configured via RISC-V processor on the PolarFire SoC FPGA.

28. Rover Demo

This is a radiation hardened SAMRH71 IOT based rover demo. It can be controlled by any phone or tablet where you can control speed and direction.

29. High-Voltage Modular Battery Management System

Do you require a modular battery management system for your design?

Microchips stackable and customizable Battery Management System (BMS) offers scalability and flexibility for your design while supporting a wide range of voltage, whether you are powering a small device or a large-scale industrial system. Modular design allows for easy integration and could be tailored for a variety of applications and battery types. By utilizing Microchip’s 10BASE-T1S Ethernet, customers can simplify the architecture design for zonal BMS needs and in addition, Q100-qualified AFEs, high-precision voltage references and thermistor ICs provide the performance, flexibility and accuracy needed for variety of BMS applications. Learn more here.

30. Next-Generation Car Lighting

Check out this demo showcasing the next generation of vehicle lighting and explore our latest automotive lighting solutions, from the interior dynamic lighting to the exterior message display. Learn more here.

31. Car Door Handle Waterproof Touch

This demo showcases a touch-responsive exterior car door handle and a mini water fountain, which highlight the enhanced water rejection capability of the Impulse Touch Solution (ITS).

32. E-Kick Scooter

This demonstration application showcases Microchip’s comprehensive system solution for micro-mobility devices to help OEMs develop smaller, more efficient and higher performance of designs.