Accurate, field-ready timing and motion capture are essential for assessing agility beyond the limits of manual stopwatches. We present a modular measurement system that fuses infrared (IR) optical gates for robust event detection with a trunk-worn inertial measurement unit (IMU) for kinematic profiling. Each sensing node is built on an Adafruit Feather M0 Wi-Fi microcontroller and communicates via UDP to a laptop server. Time alignment is accomplished without internet connectivity: the server establishes a relative epoch and executes a triple-handshake broadcast protocol, while timestamps are generated at the edge to avoid latency bias from transport or processing. Module- and device-level characterization shows that IR-receiver processing combined with interrupt service routine latency yields a per-event timestamp error of 0.54 ms ± 0.14 ms (latency ± uncertainty), and local clocks remain stable over the durations relevant to agility trials. In wireless operation, accepted synchronization attempts form tight response clusters in favorable RF conditions, whereas congested environments may require retries; for section times across different gates, we therefore report a conservative inter-node uncertainty. End-to-end validation across laboratory, entry-hall, and gym venues using the Agility T-test confirms that total test time measured on the same start/finish gate remains below 1 ms error over 10–20 s trials. Synchronized IMU waveforms add explanatory value beyond total and split times by revealing braking, change-of-direction, and re-acceleration phases. The system provides a deployable workflow with substantially improved precision over manual timing. Future work will target more robust synchronization and expanded analytics, including automated phase detection, asymmetry indices, and optional integration with indoor positioning.

infrared gates; IMU; embedded systems; wearable sensor device; wireless synchronization; agility testing

K. Pauole, K. Madole, J. Garhammer, M. Lacourse, and R. Rozenek, “Reliability and validity of the T-test as a measure of agility, leg power, and leg speed in college-aged men and women,” Journal of Strength and Conditioning Research, vol. 14, no. 4, pp. 443–450, Nov. 2000, doi: 10.1519/00124278-200011000-00012.

R. K. Hetzler, C. D. Stickley, K. M. Lundquist, and I. F. Kimura, “Reliability and accuracy of handheld stopwatches compared with electronic timing in measuring sprint performance,” Journal of Strength and Conditioning Research, vol. 22, no. 6, pp. 1969–1976, Nov. 2008, doi: 10.1519/JSC.0b013e318185f36c.

L. Villalón-Gasch, J. M. Jiménez-Olmedo, A. Penichet-Tomas, and S. Sebastia-Amat, “Concurrent validity and reliability of Chronojump photocell in the acceleration phase of linear speed test,” Applied Sciences*, vol. 15, no. 16, Art. no. 8852, Aug. 2025.

A.-M. Alanen, A.-M. Räisänen, L. C. Benson, and K. Pasanen, “The use of inertial measurement units for analyzing change of direction movement in sports: A scoping review,” International Journal of Sports Science & Coaching, 2021, doi: 10.1177/17479541211003064.

S. Apte, H. Karami, C. Vallat, V. Gremeaux, and K. Aminian, “In-field assessment of change-of-direction ability with a single wearable sensor,” Scientific Reports, vol. 13, Art. no. 4518, Mar. 2023, doi: 10.1038/s41598-023-30773-y.

L. Wolski, M. Halaki, C. E. Hiller, E. Pappas, and A. Fong Yan, “Validity of an Inertial Measurement Unit System to Measure Lower Limb Kinematics at Point of Contact during Incremental High-Speed Running,” Sensors, vol. 24, no. 17, 5718, Sept. 2024, doi: 10.3390/s24175718.

E. M. Nijmeijer, P. H. Heuvelmans, et al., “Concurrent validation of the Xsens IMU system of lower-body kinematics in jump-landing and change-of-direction tasks,” Journal of Biomechanics, vol. 154, 2023.

N. Myhill, D. Weaving, M. Robinson, S. Barrett, and S. Emmonds, “Concurrent validity and between-unit reliability of a foot-mounted inertial measurement unit to measure velocity during team sport activity,” Science and Medicine in Football, vol. 8, no. 4, pp. 308–316, 2024, doi: 10.1080/24733938.2023.2237493.

F. Bertozzi, C. Brunetti, P. Maver, M. Palombi, M. Santini, M. Galli, and M. Tarabini, “Concurrent validity of IMU and phone-based markerless systems for lower-limb kinematics during cognitively-challenging landing tasks,” Journal of Biomechanics, Aug. 2025, online ahead of print, doi: 10.1016/j.jbiomech.2025.112883.

S. Puckett and E. Jovanov, “ecoSync: An Energy-Efficient Clock Discipline Data Synchronization in Wi-Fi IoMT Systems,” Electronics, vol. 12, no. 20, 4226, Oct. 2023, doi: 10.3390/electronics12204226.

P. Chen and Z. Yang, “Understanding Precision Time Protocol in Today’s Wi-Fi Networks: A Measurement Study,” in Proc. USENIX ATC, Jul. 2021, pp. 597–610.

M. Altet et al., “UWB-Based Real-Time Indoor Positioning Systems: A Comprehensive Review,” Applied Sciences, vol. 14, no. 23, 11005, 2024, doi: 10.3390/app142311005.

D. L. Mills, J. Martin, J. Burbank, and W. Kasch, “Network Time Protocol Version 4: Protocol and Algorithms Specification,” RFC 5905, Jun. 2010, doi: 10.17487/RFC5905.

E. Keš, Senzorski sistem za ocenjevanje fizičnih sposobnosti v športu (magistrsko delo), Univerza v Ljubljani, Fakulteta za elektrotehniko, 2020. Online: https://repozitorij.uni-lj.si/IzpisGradiva.php?id=121709

Adafruit Industries, “Feather M0 Wi-Fi – ATSAMD21 + ATWINC1500 (Product 3010),” product page, accessed Aug. 22, 2025. Online: https://www.adafruit.com/product/3010

Microchip Technology Inc., “SAM D21/DA1 Family Data Sheet,” DS40001882 (latest rev.), accessed Aug. 22, 2025. Online: https://ww1.microchip.com/downloads/aemDocuments/documents/MCU32/ProductDocuments/DataSheets/SAM-D21-DA1-Family-Data-Sheet-DS40001882.pdf

Microchip Technology Inc., “ATWINC15x0-MR210xB IEEE® 802.11 b/g/n SmartConnect IoT Module,” DS70005304 (rev. F or latest), accessed Aug. 22, 2025. Online: https://ww1.microchip.com/downloads/aemDocuments/documents/WSG/ProductDocuments/DataSheets/ATWINC15x0-MR210xB-Wi-Fi-Module-Data-Sheet-DS70005304.pdf

Sharp Corporation, “IS471F: OPIC Light Detector with Built-in Signal Processing Circuit,” datasheet, accessed Aug. 22, 2025. Online: https://mm.digikey.com/Volume0/opasdata/d220001/medias/docus/987/IS471F.pdf

Vishay Semiconductors, “TSAL6200: High-Power Infrared Emitting Diode, 940 nm,” datasheet, accessed Aug. 22, 2025. Online: https://www.vishay.com/doc/81010/tsal6200.pdf

SICK AG, “P250 Reflector—Reflectors and Optics,” datasheet 5304812, accessed Aug. 22, 2025. Online: https://www.sick.com/media/pdf/4/94/694/dataSheet_P250_5304812_en.pdf

STMicroelectronics, “LSM6DS33: iNEMO inertial module—3D accelerometer and 3D gyroscope,” datasheet, accessed Aug. 22, 2025. Online: https://www.pololu.com/file/0J1087/LSM6DS33.pdf

Bosch Sensortec, “BNO055: Intelligent 9-axis absolute orientation sensor,” datasheet (rev. 1.2), accessed Aug. 22, 2025. Online: https://cdn-shop.adafruit.com/datasheets/BST_BNO055_DS000_12.pdf