Determination of flexibility and mobility levels for female physical education students and motor asymmetry analysis

Background and Study Aim. The aim of the study is the determination of flexibility and mobility levels (norm values) for female physical education students and analyses of the motor asymmetry. Material and Methods. In the study, 10 female physical education and sport students whose mean body weight was 59.3 kg and body height were 167.7 centimeters were included. Flexibility and mobility performance was measured by using tests such as a Forward-Backward Split (FBS0), Leg Raise forward (LRF0), Leg Raise Sideward (LRS0), Side Spit (SS0), Arm-Trunk Angle (AT0), Seat and reach hip angle degree (SRHA0). Data analysis in the study was made by using the IBM SPSS statistics 26 program. To handle the results of the study, the Independent-samples T-test and percentile(s) statistics were used. Norm values were given in four categories (20th, 40th, 60th, 80th) and middle fifty (50th). Calculation of the angle degrees was made by using the Kinovea-0.9.4-x64.exe program. Results. The findings have shown that the forward-backward split and leg raise forward angle degree when the right leg was ahead is significantly higher (better flexibility) than the forward-backward split and leg raise forward angle degree when the left leg was ahead (p<0.05). However, differences in the leg raise sideward angle degree in the right and left leg were not statistically significant (p>0.05). Conclusions. The study determined the level (norm values) of flexibility and mobility of female physical education students. The right leg flexibility and mobility level resulted to be significantly higher in comparison to the left leg.

Design and Analysis of Posterior Semicircular Canal BPPV Diagnostic Test Based on Physical Simulation

To discusses and analyzes how to realize the design of posterior semicircular canal BPPV diagnostic maneuver. First, measure the spatial attitude of the human semicircular canal, establish a BPPV virtual simulation platform, then analyze the key positions of the maneuver, and finally design a new diagnostic maneuver according to the demand, and perform physical simulation verification. The average value of the unit normal vector of the right posterior semicircular plane is [ 0.660, 0.702, 0.266], after rotate -46.8 ° around Z axis and 15.4 ° around Y axis, it parallel to the X axis. After that, when the tilt back angle reaches 70 °, the free otoconia in the left utricle will fall into the common crus; when bend forward 53.3°, the unit normal vector of the crista ampullaris plane of the posterior semicircular canal to the XY plane; when bend forward angle reaches 30°, the otoconia slides to the opening of the ampulla; when bend forward angle reaches 70°, the otoconia slides to the bottom of the crista ampullaris. The shallow pitching Yang maneuver is designed as turn head 45° to the one side, bend forward 45°, tilt back 90°, and bend forward 90°. The deep pitching Yang maneuver is designed as bend forward 90°, turn head 45° to one side, tilt back 135°, and bend forward 90°. A new posterior semicircular BPPV diagnostic test is designed to make the induced nystagmus have the characteristics of long latency, reversal, and repeatability, will not cause the inhibitory stimulation of the contralateral superior semicircular canal, and has good operation fault tolerance, which is of great value for clinical and scientific research.

$$K^{+}\Lambda $$ photoproduction at forward angles and low momentum transfer

Abstract$$\gamma p \rightarrow K^{+} \Lambda $$ γ p → K + Λ differential cross sections and recoil polarisation data from threshold for extremely forward angles are presented. The measurements were performed at the BGOOD experiment at ELSA, utilising the high angular and momentum resolution forward spectrometer for charged particle identification. The high statistics and forward angle acceptance enables the extraction of the cross section as the minimum momentum transfer to the recoiling hyperon is approached.

Ring Imaging Cherenkov Detector Technologies for Particle Identification in the Electron-Ion Collider Experiments

In the proposed Electron-Ion Collider (EIC) experiments, particle identification (PID) of the final state hadrons in the semi-inclusive deep inelastic scattering allows the measurement of flavor-dependent gluon and quark distributions inside nucleons and nuclei. The EIC PID consortium (eRD14 Collaboration) has been formed for identifying and developing PID detectors using Ring Imaging Cherenkov (RICH) techniques for the EIC experiments. A modular Ring Imaging Cherenkov (mRICH) detector has been designed for particle identification in the momentum coverage from 3 GeV/c to 10 GeV/c. The mRICH detector consists of an aerogel radiator block, a Fresnel lens, a mirror-wall and a photosensor plane. The first prototype of this detector was successfully tested at Fermi National Accelerator Laboratory in April 2016 for verifying the detector working principles. This talk will highlight the mRICH beam test results and their comparison with GEANT4-based detector simulations. An implementation of the mRICH detector concept in the Forward Angle sPHENIX spectrometer at BNL will also be mentioned in this talk.