Purpose: In recent years, with the popularity of the Internet of Things (IoT) and the rise of artificial intelligence (AI), the cross-disciplinary cooperation of related technologies combined with sports has become more and more popular, making it easier and more efficient to collect and analyze data. The purpose of this study is to do dynamics analysis of different types of crouch start by using starting blocks developed by IoT technology. Methods: The subjects were 8 short-distance male athletes from college track and field team (height: 173.16 ± 4.77 cm; weight: 65.55 ± 4.52 kg; age: 20.06 ± 1.09 years old). A set of data collecting and analyzing system developed by IoT systems, AI algorithm platform, Arduino, Raspberry Pi, and Deep Learning was used to collect data (patent number: I632939). Each of front and rear block was installed 20 pressure sensors (sampling frequency 1000Hz), and before installation, each sensor was calibrated, and multiple linear regression was used to calculate the voltage-force curve slope formula and then import it into the system. The experimental data were analyzed by repeated-measures one-way ANOVA to compare the differences between the different crouch starts. If a significant difference was reached, the LSD method was used for post-hoc comparison, and the significant level was α = .05. Results: In the starting phase, the rear foot of elongated staring mode was better than other modes in the time and force of maximal reaction force, and initial force and maximal rate of force development generated by the blocks were also larger. Also, it was also found that the distance from the starting line to front block was too long in subjects' habitual starting mode. Conclusions: The performance of dynamics analysis was better in the elongated and middle starting mode in the starting phase. It was suggested that athletes could adjust the front block 1.5-feet long from the staring line to improve starting performance.