24 research outputs found
Hubungan Kelincahan dengan Keterampilan Menggiring Bola pada Siswa Kelas V.e Sdn 006 Pangkalankerinci Kab. Pelalawan
Based on the researcher\u27s observation of students in class V,E of SDN 006 Pangkalan Kerinci Pelalawan District. Researcher found many student have deficiency of dribbling, visible when the student dribble imperfect, as the ball away from the feet, so that the ball easily captured opponent. It is influenced by physical conditions that agility. The purpose of this research is to see the correlation between agility with ball dribbling skills of Student class V.E of SDN 006 Pangkalan Kerinci Pelalawan District. Population in this research is all Student in class V of SDN 006 Pangkalan Kerinci Pelalawan District amount 22 people. Based on population that is not so large and within the limits the researchers set the whole population is used as a sample. The research sample as many as 22 people. Research instrument used suttle run test to agility and dribbling ball test. Data were analyzed by product moment correlation. Based on research results, it can be concluded as follows : that is result obtained from Student in class V.E of SDN 006 Pangkalan Kerinci Pelalawan District. Shows that there is correlation of the agility (X) with dribbling (Y) , which shows correlation rhitung = 0,462>rtabel = 0,43
Graphical representation of the statistical analysis (Wilcoxon signed-rank test) of differences in the amounts of collagen structures, i.e. apa.coll (%), in 10 proportional subunits of the CauF.
<p>The analyses were performed separately for each age group (‘young’ and ‘old’) and are displayed in three different diagrams. Note: Different designs (i.e. intensities of grey colour) indicate that the differences between the subunits, or groups of subunits, were <i>statistically significant</i>. The amounts of collagen structures (mean values) are recorded in the boxes arranged in each bar. In each age group, three procedures of comparison were performed, each displayed in one ‘Wilcoxon Bar’. Wilcoxon Bar 1: Comparison of one subunit with its preceding and succeeding neighbour. Wilcoxon Bar 2: Comparison of groups made up of 2 subunits each. Subunit 1 was not grouped with its neighbouring subunit 2 if its values were significantly higher than those of subunit 2. Wilcoxon Bar 3: Comparison of groups representing the hypothetical zones 1 to 4 (see Figs <a href="http://www.plosone.org/article/info:doi/10.1371/journal.pone.0128085#pone.0128085.g002" target="_blank">2</a> and <a href="http://www.plosone.org/article/info:doi/10.1371/journal.pone.0128085#pone.0128085.g004" target="_blank">4</a>). Bar 4 summarises bars 1–3; here, a <i>shaded</i> design indicates <i>continuous</i> transitions, because the distinct demarcation lines (representing statistically significant differences) were located differently in bars 1, 2, and 3, respectively.</p
Amounts of elastic fibres per area, apa.elast (%), in ‘young’ and ‘old’ minipigs.
<p>Eight hypothetical zones were assigned in the CraF: Zone 1 (Z1) was a narrow band underneath the epithelium (representing subunit 1), zones 2 to 7 (Z2–Z7) each comprised three subunits; zone 8 (Z8) represented the remaining subunit 20.</p
Elastic fibres in the CauF of ‘young’ and ‘old’ minipigs (all images in identical magnification).
<p>Four zones were defined as explained in <a href="http://www.plosone.org/article/info:doi/10.1371/journal.pone.0128085#pone.0128085.g003" target="_blank">Fig 3</a>. The images serve as examples to illustrate the distinct characteristics of each zone. Note that, according to statistical analysis, not all of them were clearly demarcated. Paraffin section, resorcin-fuchsin stain. Bar = 10 μm.</p
Graphical illustration of the proportional subunits and the zones of the cranial (CraF) and caudal (CauF) fold.
<p>Each examined connective tissue section of the CraF was separated into 20 subunits of equal thickness; the connective tissue component of the CauF was separated into 10 subunits due to its smaller thickness. Within the total thickness of the CraF, eight zones (Z1–Z8) were hypothetically defined; accordingly, the total thickness of the CauF was divided into four hypothetical zones (Z1–Z4).</p
Survey on the most prominent findings concerning collagen structures and elastic fibres in the cranial (CraF) and caudal (CauF) vocal fold of minipigs of different ages.
<p>Survey on the most prominent findings concerning collagen structures and elastic fibres in the cranial (CraF) and caudal (CauF) vocal fold of minipigs of different ages.</p
Graphical representation of the statistical analysis (Wilcoxon signed-rank test) of differences in elastic fibre amounts, i.e. apa.elast (%), in 20 proportional subunits of the CraF.
<p>The analyses were performed separately for each age group (‘young’ and ‘old’) and are displayed in three different diagrams. Note: Different designs (i.e. intensities of grey colour) indicate that the differences between the subunits, or groups of subunits, were <i>statistically significant</i>. The elastic fibre amounts (mean values) are recorded in the boxes arranged in each bar. Three procedures of comparison were performed (‘Wilcoxon Bars’ 1–3), and are summarised in bar 4 (Summary), as explained in <a href="http://www.plosone.org/article/info:doi/10.1371/journal.pone.0128085#pone.0128085.g005" target="_blank">Fig 5</a>.</p
Graphical representation of the statistical analysis (Wilcoxon signed-rank test) of differences in the amounts of collagen structures, i.e. apa.coll (%), in 20 proportional subunits of the CraF.
<p>The analyses were performed separately for each age group (‘young’ and ‘old’) and are displayed in three different diagrams. Note: Different designs (i.e. intensities of grey colour) of the boxes indicate that the differences between the subunits, or groups of subunits, were <i>statistically significant</i>. The amounts of collagen structures (mean values) are recorded in the boxes arranged in each bar. Three procedures of comparison were performed (‘Wilcoxon Bars’ 1–3), and are summarised in bar 4 (Summary), as explained in <a href="http://www.plosone.org/article/info:doi/10.1371/journal.pone.0128085#pone.0128085.g005" target="_blank">Fig 5</a>.</p
Graphical representation of the statistical analysis (Wilcoxon signed-rank test) of differences in elastic fibre amounts, i.e. apa.elast (%), in 10 proportional subunits of the CauF.
<p>The analyses were performed separately for each age group (‘young’ and ‘old’) and are displayed in three different diagrams. Note: Different designs (i.e. intensities of grey colour) of the boxes indicate that the differences between the subunits, or groups of subunits were <i>statistically significant</i>. The amounts of elastic fibres (mean values) are recorded in the boxes arranged in each bar. In each age group, three procedures of comparison were performed (‘Wilcoxon Bars’ 1–3), and are summarised in bar 4 (Summary), as explained in <a href="http://www.plosone.org/article/info:doi/10.1371/journal.pone.0128085#pone.0128085.g005" target="_blank">Fig 5</a>.</p
Graphical representation of the statistical analysis (Kruskal-Wallis test) of differences in elastic fibre amounts in the hypothetical zones 1 to 4 (Z1–Z4) between the two age groups (‘young’ versus ‘old’).
<p>These pairwise comparisons are displayed as two adjoining boxes. Note: Different designs (orientation of lines) indicate that the differences between the age groups were <i>statistically significant</i>.</p