Initial weight values and correlation thresholds. by Qingnan Ji (22662198)

“…Integration efficiency increases by 18.7%, and computational complexity is significantly reduced, with average computation time decreased by 15.4%. …”

Ablation experiment results comparison. by Qingnan Ji (22662198)

“…Integration efficiency increases by 18.7%, and computational complexity is significantly reduced, with average computation time decreased by 15.4%. …”

Adjustment step size. by Qingnan Ji (22662198)

“…Integration efficiency increases by 18.7%, and computational complexity is significantly reduced, with average computation time decreased by 15.4%. …”

Curve of data size vs. running time. by Qingnan Ji (22662198)

“…Integration efficiency increases by 18.7%, and computational complexity is significantly reduced, with average computation time decreased by 15.4%. …”

Data (3). by Qingnan Ji (22662198)

“…Integration efficiency increases by 18.7%, and computational complexity is significantly reduced, with average computation time decreased by 15.4%. …”

Structure of the Kuhn-Munkres Algorithm. by Qingnan Ji (22662198)

“…Integration efficiency increases by 18.7%, and computational complexity is significantly reduced, with average computation time decreased by 15.4%. …”

Effect of the Surface Peak–Valley Features on Droplet Impact Dynamics under Leidenfrost Temperature by Yunlong Jiao (6672764)

“…The investigation focuses on two types of microtextured surfaces with totally different surface peak–valley features: a negatively skewed surface with micropit arrays (<i>Ssk</i> < 0) and a positively skewed surface with micropillar arrays (<i>Ssk</i> > 0). …”

Effect of the Surface Peak–Valley Features on Droplet Impact Dynamics under Leidenfrost Temperature by Yunlong Jiao (6672764)

“…The investigation focuses on two types of microtextured surfaces with totally different surface peak–valley features: a negatively skewed surface with micropit arrays (<i>Ssk</i> < 0) and a positively skewed surface with micropillar arrays (<i>Ssk</i> > 0). …”

S5 File - by Xiangling Li (2308666)

“…</p><p>Results</p><p>CY and DEX significantly reduced the immune function in DNFB-induced sensitized mice, as indicated by decreased thymus and spleen indices, MLN enlargement, intestinal sIgA content, and ear swelling degree. …”

S1 File - by Xiangling Li (2308666)

“…</p><p>Results</p><p>CY and DEX significantly reduced the immune function in DNFB-induced sensitized mice, as indicated by decreased thymus and spleen indices, MLN enlargement, intestinal sIgA content, and ear swelling degree. …”

S7 File - by Xiangling Li (2308666)

“…</p><p>Results</p><p>CY and DEX significantly reduced the immune function in DNFB-induced sensitized mice, as indicated by decreased thymus and spleen indices, MLN enlargement, intestinal sIgA content, and ear swelling degree. …”

S3 File - by Xiangling Li (2308666)

“…</p><p>Results</p><p>CY and DEX significantly reduced the immune function in DNFB-induced sensitized mice, as indicated by decreased thymus and spleen indices, MLN enlargement, intestinal sIgA content, and ear swelling degree. …”

Effect of the Surface Peak–Valley Features on Droplet Impact Dynamics under Leidenfrost Temperature by Yunlong Jiao (6672764)

“…The investigation focuses on two types of microtextured surfaces with totally different surface peak–valley features: a negatively skewed surface with micropit arrays (<i>Ssk</i> < 0) and a positively skewed surface with micropillar arrays (<i>Ssk</i> > 0). …”

S2 File - by Xiangling Li (2308666)

“…</p><p>Results</p><p>CY and DEX significantly reduced the immune function in DNFB-induced sensitized mice, as indicated by decreased thymus and spleen indices, MLN enlargement, intestinal sIgA content, and ear swelling degree. …”

S4 File - by Xiangling Li (2308666)

“…</p><p>Results</p><p>CY and DEX significantly reduced the immune function in DNFB-induced sensitized mice, as indicated by decreased thymus and spleen indices, MLN enlargement, intestinal sIgA content, and ear swelling degree. …”

Effect of the Surface Peak–Valley Features on Droplet Impact Dynamics under Leidenfrost Temperature by Yunlong Jiao (6672764)

“…The investigation focuses on two types of microtextured surfaces with totally different surface peak–valley features: a negatively skewed surface with micropit arrays (<i>Ssk</i> < 0) and a positively skewed surface with micropillar arrays (<i>Ssk</i> > 0). …”

Effect of the Surface Peak–Valley Features on Droplet Impact Dynamics under Leidenfrost Temperature by Yunlong Jiao (6672764)

“…The investigation focuses on two types of microtextured surfaces with totally different surface peak–valley features: a negatively skewed surface with micropit arrays (<i>Ssk</i> < 0) and a positively skewed surface with micropillar arrays (<i>Ssk</i> > 0). …”

Effect of the Surface Peak–Valley Features on Droplet Impact Dynamics under Leidenfrost Temperature by Yunlong Jiao (6672764)

“…The investigation focuses on two types of microtextured surfaces with totally different surface peak–valley features: a negatively skewed surface with micropit arrays (<i>Ssk</i> < 0) and a positively skewed surface with micropillar arrays (<i>Ssk</i> > 0). …”

Effect of the Surface Peak–Valley Features on Droplet Impact Dynamics under Leidenfrost Temperature by Yunlong Jiao (6672764)

“…The investigation focuses on two types of microtextured surfaces with totally different surface peak–valley features: a negatively skewed surface with micropit arrays (<i>Ssk</i> < 0) and a positively skewed surface with micropillar arrays (<i>Ssk</i> > 0). …”

Effect of the Surface Peak–Valley Features on Droplet Impact Dynamics under Leidenfrost Temperature by Yunlong Jiao (6672764)

“…The investigation focuses on two types of microtextured surfaces with totally different surface peak–valley features: a negatively skewed surface with micropit arrays (<i>Ssk</i> < 0) and a positively skewed surface with micropillar arrays (<i>Ssk</i> > 0). …”