Sentences with phrase «compare box plots»

I then went on to compare box plots.

For information about these resources and an index for the whole collection please visit http://www.mrbartonmaths.com/CIMT.htm Keywords: Statistics, Data, Grouped, Cumulative Frequency, Box Plot, Box and Whisker Diagram, Curve, Median, Quartile, Upper, Lower, Percentile, Distribution, Inter quartile Range, Semi Inter quartile, Frequency Polygon, Total, Percentage, Mean, Mode, Frequency Table, Class Width, Standard Deviation, Variance, Range, Spread, Distribution, Compare, Calculation, Justify, Evidence.

Also a couple of worksheets to allow students to get some independant practice, plus the data I collected from my year 9s that I got them to draw box plots from to compare my two year 9 classes.

(Mean, median, mode, comparing charts and graphs, probability, equally likely outcomes, pie charts, box and whisker plots, scatter diagrams, correlation.)

Pupils shuffle avenger cards and create a tem of 11 heroes and draw a box plot of thier power and cunning, comparing the two and comparing with a friend to see who has the best team.

## COMPARE TO GAVIN PLOT par (mar = c (3,3,2,1)-RRB- plot (c (time (hansen88)-RRB-, hansen88 -LSB-,» Scenario.A»], col = 2, ylim = c -LRB--.25, 1.5), xlim = c (1958,2010), xlab =»», ylab =»», tcl =.25, axes = FALSE) box -LRB--RRB-; axis (side = 1, tcl =.25); axis (side = 2, las = 1, font = 2) lines (c (time (hansen88)-RRB-, hansen88 -LSB-,» Scenario.A»], col = 2, lwd = 2) lines (c (time (hansen88)-RRB-, hansen88 -LSB-,» Scenario.B»], col =» green4 ″, lwd = 2) points (c (time (hansen88)-RRB-, hansen88 -LSB-,» Scenario.B»], col =» green4 ″, pch = 1) lines (c (time (hansen88)-RRB-, hansen88 -LSB-,» Scenario.C»], col = 4, lwd = 2) points (c (time (hansen88)-RRB-, hansen88 -LSB-,» Scenario.C»], col = 4, pch = 1) lines (c (time (giss.glb)-RRB-, giss.glb, col =» grey60 ″, lwd = 2) points (c (time (giss.glb)-RRB-, giss.glb, col =» grey60 ″, pch = 19) lines (c (time (spaghetti)-RRB-, spaghetti -LSB-,» tlt3.glb»], col = 1, lwd = 3) points (c (time (spaghetti)-RRB-, spaghetti -LSB-,» tlt3.glb»], col = 1, pch = 19) abline (v = 1987, lty = 3, col =» grey80 ″) abline (h = seq (0,1.5,.5), col =» grey80 ″, lty = 2) legend (1958,1.6, fill = c (2,3,4,» grey60 ″, 1), legend = c («Hansen A»,» Hansen B»,» Hansen C»,» GISS Surf»,» RSS Sat»)-RRB- title (main =» Hansen et al 1988 Projections&raqPLOT par (mar = c (3,3,2,1)-RRB- plot (c (time (hansen88)-RRB-, hansen88 -LSB-,» Scenario.A»], col = 2, ylim = c -LRB--.25, 1.5), xlim = c (1958,2010), xlab =»», ylab =»», tcl =.25, axes = FALSE) box -LRB--RRB-; axis (side = 1, tcl =.25); axis (side = 2, las = 1, font = 2) lines (c (time (hansen88)-RRB-, hansen88 -LSB-,» Scenario.A»], col = 2, lwd = 2) lines (c (time (hansen88)-RRB-, hansen88 -LSB-,» Scenario.B»], col =» green4 ″, lwd = 2) points (c (time (hansen88)-RRB-, hansen88 -LSB-,» Scenario.B»], col =» green4 ″, pch = 1) lines (c (time (hansen88)-RRB-, hansen88 -LSB-,» Scenario.C»], col = 4, lwd = 2) points (c (time (hansen88)-RRB-, hansen88 -LSB-,» Scenario.C»], col = 4, pch = 1) lines (c (time (giss.glb)-RRB-, giss.glb, col =» grey60 ″, lwd = 2) points (c (time (giss.glb)-RRB-, giss.glb, col =» grey60 ″, pch = 19) lines (c (time (spaghetti)-RRB-, spaghetti -LSB-,» tlt3.glb»], col = 1, lwd = 3) points (c (time (spaghetti)-RRB-, spaghetti -LSB-,» tlt3.glb»], col = 1, pch = 19) abline (v = 1987, lty = 3, col =» grey80 ″) abline (h = seq (0,1.5,.5), col =» grey80 ″, lty = 2) legend (1958,1.6, fill = c (2,3,4,» grey60 ″, 1), legend = c («Hansen A»,» Hansen B»,» Hansen C»,» GISS Surf»,» RSS Sat»)-RRB- title (main =» Hansen et al 1988 Projections&raqplot (c (time (hansen88)-RRB-, hansen88 -LSB-,» Scenario.A»], col = 2, ylim = c -LRB--.25, 1.5), xlim = c (1958,2010), xlab =»», ylab =»», tcl =.25, axes = FALSE) box -LRB--RRB-; axis (side = 1, tcl =.25); axis (side = 2, las = 1, font = 2) lines (c (time (hansen88)-RRB-, hansen88 -LSB-,» Scenario.A»], col = 2, lwd = 2) lines (c (time (hansen88)-RRB-, hansen88 -LSB-,» Scenario.B»], col =» green4 ″, lwd = 2) points (c (time (hansen88)-RRB-, hansen88 -LSB-,» Scenario.B»], col =» green4 ″, pch = 1) lines (c (time (hansen88)-RRB-, hansen88 -LSB-,» Scenario.C»], col = 4, lwd = 2) points (c (time (hansen88)-RRB-, hansen88 -LSB-,» Scenario.C»], col = 4, pch = 1) lines (c (time (giss.glb)-RRB-, giss.glb, col =» grey60 ″, lwd = 2) points (c (time (giss.glb)-RRB-, giss.glb, col =» grey60 ″, pch = 19) lines (c (time (spaghetti)-RRB-, spaghetti -LSB-,» tlt3.glb»], col = 1, lwd = 3) points (c (time (spaghetti)-RRB-, spaghetti -LSB-,» tlt3.glb»], col = 1, pch = 19) abline (v = 1987, lty = 3, col =» grey80 ″) abline (h = seq (0,1.5,.5), col =» grey80 ″, lty = 2) legend (1958,1.6, fill = c (2,3,4,» grey60 ″, 1), legend = c («Hansen A»,» Hansen B»,» Hansen C»,» GISS Surf»,» RSS Sat»)-RRB- title (main =» Hansen et al 1988 Projections»)