AEKD-BLINDSPOTA1

AEKD-BLINDSPOTA1 Data brief Blind-spot detection simulation kit Features • • • • • • • Conveyor belt with DC gearbox motor Hall sensor for magnetic field detection 1 car model 1:43 fixed 1 car model 1:43 with internal magnets to be placed on the conveyor belt High brightness LED turns on when two cars are near each other Part of the AutoDevKit™ initiative RoHS and WEEE compliant Description Product summary Blind-spot detection simulation kit AEKDBLINDSPOTA1 Firmware for AEKDBLINDSPOTB1 STSWBLINDSPOT Development environment SPC5-Studio community.st.com/ autodevkit AutoDevKit AutoDevKit library plugin for SPC5STUDIO STSWAUTODEVKIT SPC5-UDESTK Debugging Software for Windows SPC5-UDESTKSW MCU discovery board for SPC5 Chorus 4M automotive microcontroller with CAN transceivers AEK-MCUC4MLIT1 Digitally controlled LED driver board for automotive lighting applications AEKLED-21DISM1 VN7050AS evaluation board based on VIPower M0-7 technology EV-VN7050AS Applications Chassis and Safety The AEKD-BLINDSPOTA1 blind-spot kit simulates the detection of motor a vehicle in the regions around a car that drivers typically cannot see directly or with mirrors. It works by interpreting magnetic field variations through a Hall sensor mounted on one car model that remains stationary and magnets mounted on another car model that moves on the conveyor belt driven by a 12 VDC gearbox motor with 40 RPM and high torque. The AEKD-BLINDSPOTA1 hardware assembly system is used with the AEKDBLINDSPOTB1 kit of boards to drive the blind-spot demo loads. The goal of the training kit is to help developers build effective firmware for blind-spot systems using the SPC5-Studio integrated development environment with the AutoDevKit plugin extension. DB4117 - Rev 2 - March 2020 For further information contact your local STMicroelectronics sales office. www.st.com AEKD-BLINDSPOTA1 Overview 1 Overview Blind-spot detection is implemented in modern transportation vehicles to prevent accidents in common overtaking scenarios and other dangerous circumstances involving vehicles occupying areas that cannot seen directly by the drivers of other vehicles. These warning systems detect the presence of vehicles in blind-spot zones and alert the driver. In this simulation kit, the system consists of a plexiglass structure to simulate the loads and a set of boards to drive the application (AEKD-BLINDSPOTB1). Two cars are placed on the demo: one is stationary, while another car with embedded magnets moves on the conveyor belt driven by a gear-DC motor. A Hall sensor under the belt measures the magnetic field around it and a LED near the stationary car indicates when the blind-spot warning signal is triggered. The application is controlled by: • a 32-bit automotive microcontroller (SPC58EC80E5) • a VIPower actuator board (EV-VN7050AS) with a high side driver used to drive the conveyor belt geared DC motor • a LED driver board (AEK-LED-21DISM1) drives the warning LED Figure 1. AEKD-BLINDSPOTA1 hardware assembly DB4117 - Rev 2 1. Side for board connection 2. LED 3. DC motor 4. Hall sensor 5. Car with magnets page 2/6 AEKD-BLINDSPOTA1 Block diagram 1.1 Block diagram Figure 2. AEKD-BLINDSPOTA1 plus AEKD-BLINDSPOTB1 blind-spot detection kit component block diagram DB4117 - Rev 2 page 3/6 AEKD-BLINDSPOTA1 How to create a blind-spot detection application using AutoDevKit 1.2 How to create a blind-spot detection application using AutoDevKit Step 1. Create a new project and select the MCU platform to use, i.e. SPC58 Chorus 4 Mb Step 2. Add SPC5 Init Component for clock configurator, interrupt management and an operating system abstraction layer together with bootstrap files Step 3. Add AutoDevKit Init Component for Board View Editor Step 4. Add low-level drivers for MCU peripherals management Step 5. Pick AutoDevKit components according to the blind-spot warning system to build: LED driver, DC motor driver for the conveyor belt and the Hall sensor capture component Step 6. Configure the added AutoDevKit components Step 7. Run automatic pin allocation Step 8. Verify the assigned pins in the PinMap Editor Step 9. Connect your boards using the Board View Step 10. Write the main() function using AutoDevKit with high-level APIs Figure 3. main() function operation block diagram Step 11. Compile the code Step 12. Download the code using PLS UDE Step 13. Debug your application DB4117 - Rev 2 page 4/6 AEKD-BLINDSPOTA1 Revision history Table 1. Document revision history DB4117 - Rev 2 Date Version Changes 13-Feb-2020 1 Initial release. 04-Mar-2020 2 Minor text changes. page 5/6 AEKD-BLINDSPOTA1 IMPORTANT NOTICE – PLEASE READ CAREFULLY STMicroelectronics NV and its subsidiaries (“ST”) reserve the right to make changes, corrections, enhancements, modifications, and improvements to ST products and/or to this document at any time without notice. Purchasers should obtain the latest relevant information on ST products before placing orders. ST products are sold pursuant to ST’s terms and conditions of sale in place at the time of order acknowledgement. Purchasers are solely responsible for the choice, selection, and use of ST products and ST assumes no liability for application assistance or the design of Purchasers’ products. No license, express or implied, to any intellectual property right is granted by ST herein. Resale of ST products with provisions different from the information set forth herein shall void any warranty granted by ST for such product. ST and the ST logo are trademarks of ST. For additional information about ST trademarks, please refer to www.st.com/trademarks. All other product or service names are the property of their respective owners. Information in this document supersedes and replaces information previously supplied in any prior versions of this document. © 2020 STMicroelectronics – All rights reserved DB4117 - Rev 2 page 6/6