ANALYSIS OF PHYSICAL COMPONENTS IN WRESTLING FREESTYLE

The purpose of this study was to determine the effect of arm power, agility and eye-hand and foot coordination in performing arm slamming skills in wrestling athletes in West Java Province. The population that was reached in this study were all wrestling athletes in the West Java area, which consisted of 30 freestyle wrestling athletes. Determination of the sample using a saturated sample, meaning that the entire affordable population is used as a research sample. The data analysis technique used is descriptive analysis and path analysis with the help of SPSS version 21 computer program with a significant level of 95% or = 0.05. The results showed that: The direct effect given by the arm power variable (X1) on the eye, hand and foot coordination variable (X3) was -0.414. Then the direct effect given by the agility variable (X2) on the eye, hand and foot coordination variable (X3) is -0.357. Then the direct effect given by the arm power variable (X1) on the arm swing skill variable (Y) is 0.546. Then the direct effect given by the agility variable (X2) on the arm swing skill variable (Y) is 0.638. And lastly, the direct effect given by the eye, hand and foot coordination variable (X3) on the arm slamming skill variable (Y) is 0.351. Sobel test calculations (Sobel Test) obtained that the value of one-tailed probability (One-tailed probability) of 0.029 <0.05. So it can be concluded that the arm power variable (X1) has an indirect effect through eye coordination, hands and feet (X3) against arm slam skills (Y). Then the results of the Sobel test calculation (Sobel Test) obtained that the one-tailed probability value is 0.0730 > 0.05. So it can be concluded that the agility variable (X2) has no indirect effect through eye, hand and foot coordination (X3) on arm slamming skills (Y). Keywords: Arm Power, Agility, Eye, Hand and Foot Coordination, Arm Kick Skills, Wrestling

Mechanical role of Arm Swing on Vertical Jump Performance

Introduction: Advanced technology has allowed biomechanists to gather very accurate measurements of many of the parameters associated with human movement. In sports, vertical jump is very important factors. It is an effective exercise for building both endurance and explosive power and through the vertical jump performance the players take advantage in sports. So here, the present study was to analyze the Mechanical role of arm swing on vertical jump performance. Objective: 1. To know the mechanical role of arm swing and without arm swing on vertical jump performance of university level players of Jadavpur University, West Bengal, India. 2. To know the effect of power on arm swing and without arm swing of vertical jump performance of the university level players of Jadavpur University, West Bengal, India. 3. To find out the relationship between power and arm swing of vertical jump performance of the university level players of Jadavpur University, West Bengal, India. Methodology: 4 Volleyball (20.29±1.38 years, 179±4.54cm and 67±4.34kg), 4 Basketball (23.43±2.57years, 170.57±3.15cm and 62.13±7.58kg) and 4 High Jump (21.75±.95 years, 170.37±3.15cm and 64.75±2.21kg) university (Jadavpur university) level players were selected randomly as the subjects. Results: The result of study revealed that there were significant differences (t-4.17*) between arm swing (56.67±4.86cm) and without arm swing (43.21±4.23) vertical jump performance of high jump players and vertical jump performance of the volleyball and basketball players were found no significant difference but positive effect showed. Also the results showed that in power (ground reaction force) there were no significant differences found between arm swing and without arm swing of the university level players. There were also positive relationship found in Volleyball (r-0.61), Basketball (r- 0.89) and High jump (r- 0.84) University level players between power and arm swing vertical jump performance. Conclusion: Arm swing positively effect on the vertical jump performance for Volleyball, Basketball and High Jump players. Arm swing also positively effect on increased the power which in turn help to increased the jumping height of Volleyball, Basketball and High Jump players. It also concluded that there is positive relationship between power and with arm swing in vertical jump performance.

Increased Arm Swing and Rocky Surfaces Reduces Postural Control in Healthy Young Adults

Fall-induced injuries can stem from a disruption in the postural control system and place a financial burden on the healthcare system. Most gait research focused on lower extremities and neglected the contribution of arm swing, which have been shown to affect the movement of the center of mass when walking. This study evaluated the effect of arm swing on postural control and stability during regular and rocky surface walking. Fifteen healthy young adults (age = 23.4 ± 2.8) walked on these two surfaces with three arm motions (normal, held, and active) using the CAREN Extended-System (Motek Medical, Amsterdam, NL). Mean, standard deviation and maximal values of trunk linear and angular velocity were calculated in all three axes. Moreover, step length, time and width mean and coefficient of variation as well as margin of stability mean and standard deviation were calculated. Active arm swing increased trunk linear and angular velocity variability and peak values compared to normal and held arm conditions. Active arm swing also increased participants’ step length and step time, as well as the variability of margin of stability. Similarly, rocky surface walking increased trunk kinematics variability and peak values compared to regular surface walking. Furthermore, rocky surface increased the average step width while reducing the average step time. Though this surface type increased the coefficient of variation of all spatiotemporal parameters, rocky surface also led to increased margin of stability mean and variation. The spatiotemporal adaptations showed the use of “cautious” gait to mitigate the destabilizing effects of both the active arm swing and rocky surface walking and, ultimately, maintain dynamic stability.

Mechanical Design and Control System Development of a Rehabilitation Robotic System for Walking With Arm Swing

Background: Interlimb neural coupling implies that arm swing should be included during gait training to improve rehabilitation outcomes. We previously developed several systems for production of walking with arm swing, but the reaction forces on the foot sole during usage of the systems were not satisfactory and there was potential to improve control system performance. This work aimed to design and technically evaluate a novel system for producing walking with synchronised arm and leg movement and with dynamic force loading on the foot soles.Methods: The robotic system included a passive curved treadmill and a trunk frame, upon which the rigs for the upper and lower limbs were mounted. Ten actuators and servocontrollers with EtherCAT communication protocol controlled the bilateral shoulder, elbow, hip, knee and ankle joints. Impedance control algorithms were developed and ran in an industrial PC. Flexible pressure sensors recorded the plantar forces on the foot soles. The criteria of implementation and responsiveness were used to formally evaluate the technical feasibility of the system.Results: Using impedance algorithms, the system produced synchronous walking with arm swing on the curved treadmill, with mean RMS angular tracking error &lt;2° in the 10 joint profiles. The foot trajectories relative to the hip presented similar shapes to those during normal gait, with mean RMS displacement error &lt;1.5 cm. A force pattern that started at the heel and finished at the forefoot was observed during walking using the system, which was similar to the pattern from overground walking.Conclusion: The robotic system produced walking-like kinematics in the 10 joints and in the foot trajectories. Integrated with the curved treadmill, the system also produced walking-like force patterns on the foot soles. The system is considered feasible as far as implementation and responsiveness are concerned. Future work will focus on improvement of the mechanical system for future clinical application.

Reliability and Differences of Jump Kinetics Related to Different Load in College Male Athletes

The purpose of this study was to explore reliability and differences of jump kinetics related to different training load in college male athletes. The subjects were required to perform countermovement jump (CMJ) and loaded countermovement jump (LCMJ-0%, LCMJ-20% and LCMJ-80% of one-repetition maximum squat) three times for each load which were recorded by a force plate. One-way repeated measures ANOVA and the LSD post hoc method were employed to evaluate the results. The results reveled that jump kinetics-related parameters increased/decreased by the load. Compared with the loading jumps, the CMJ incorporate with an arm swing directly led to an increase in eccentric contraction duration during jumping. Most of the jump mechanical parameters under substantially different load conditions fall within the good to excellent reliability. It appears that the CMJ and CMJ with extra load were reliable in explore the kinetics related parameters. Keywords: countermovement jump, one-repetition maximum, arm swing, eccentric contraction