How many glyphs are there 4.3

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RDF feed. The resulting plot is shown in Figure Symmetric error bars have been drawn for the temperature measurements. These errors were calculated as the average of the upper and lower error bars for the data and so are only for illustrative purposes. We can therefore plot the asymmetric temperature errors using the following where we re-use the index array j to exclude points with no error data. The error-bar style is changed from the default value of bar - as used in Figure 11 - to cap , and the colors of the error bars and symbols are also changed.

The plot title is changed to be aligned to the left of the plot - by setting both title. Asymmetric error bars have been drawn for the temperature measurements. The properties of the curve error bar style, color, and symbol color have been changed from their default values. Similarly, the plot title has been adjusted so that it is left-aligned with the plot and uses a different font than normal times rather than helvetica.

The ChIPS state file z-tx-error2. The following show the settings of some of the elements of the figure - the symbol and error settings of the curve and the title settings of the plot.

We set up the a , da , b , and db arrays with these values:. Now we can plot the data. We first create two plots, arranged vertically, using split , and then change the currency so that both plots are current. Note that although the two curves were created by a single call, they are independent objects once they have been created, as shown by the fact you can change the err. The only difference in the two plots is that the err.

We finish this section with a brief discussion for the preliminary support of limits in ChIPS. Limits are indicated by supplying, along with the error values, a vector with values of 1 for an upper limit, -1 for a lower limit, and 0 to indicate that the value from the error array should be used instead.

We create such an array and set the third and last-but-one elements to indicate upper and lower limits respectively for the a,b arrays we used to create Figure When plotted see Figure 14 the third and last-but-one points are drawn as limits rather than errors. Although not shown here, the limits array can be replaced by a list of vectors - the same number as used for the error values - if limits along different axes are needed.

The same data as shown in Figure 13 has been plotted, but this time limits are indicated for the third and last-but-one points. Note: the limits start - rather than end - at the data point here the a,b values.

Currently there are only two attributes that control the appearance and behavior of limits:. The limit. In this section we show some of the customizations that can be applied to axes, in particular: adjusting the position of the labels, changing the format used to draw the numeric labels, adding an extra axis to a plot, and changing the labeling of the axis.

The plot will be of the X-ray luminosity versus redshift of the clusters in the BAX database. With the new label format, the label for the Y axis overlaps the ticklabels.

We can, and will, increase the separation between the axis label and the axis, but first we increase the left plot margin - from 0. There are many attributes that change the appearance of axes; here we concentrate on those that control the appearance of the labels that appear at the positions of the major tick marks on the Y axis:.

To stop the axis label from overlapping the ticklabels we increase the offset. We now want to add an X axis to the top of the plot that indicates the luminosity distance to the clusters. The pad attribute is set to 0 to make sure that these limits are not automatically expanded when the axis is created since the default value for the attribute is 0.

The current state of the plot is shown in Figure An extra X axis has been added to the top of the plot. At the moment it has the same range, scaling, and labels as the bottom X axis although the size of the ticklabels is smaller. We now want to label the luminosity distances along this axis. The new axis is explicitly identified in this call - i.

Since the minor tick marks have no meaning for this axis as the scaling is neither linear or logarithmic , we turn them off by setting the minortick. As the new X axis is still current we can easily add a label to it and decrease the separation between the label and the new axis. To make the most use of the space we decrease the right margin of the plot from 0.

Finally we print out the plot after changing the symbol to the smallest sized circle provided by ChIPS. The postscript and PDF versions are scaled up to fit a US letter page whilst keeping the aspect ratio of the plot fixed. The final plot shows customizations applied to both axes. The Y axis has been changed to use scientific notation i. Both the Y axis and the bottom original X axis have had the size of the ticklabels increased.

The second X axis, added at the top of the plot, has been adjusted so that it shows representative luminosity distance values. Since the scaling between redshift and luminosity distance is not linear or logarithmic, the minor tick marks have been hidden for this axis. The plot margins have been adjusted so that the plot makes full use of the space it occupies, and to allow the labels on the Y axis to be moved so they do not overlap.

The ChIPS state file axes. Error bars can be symmetric or asymmetric and drawn for one or both axes. There is also rudimentary support for drawing upper or lower limits. There are nine symbol styles that can be used not counting the none value which turns off the symbol support for the curve.

All the styles, except for the point type, can be drawn either open or filled, and at a range of sizes 1 to , where the default value is 5. Annotations such as lines, labels, points, and regions, can be added to plots Figure 6. The size and position of plots within a frame can be adjusted by changing the margin attributes of a plot - e. Regions can be filled with a color of adjustable transparency, as shown in Figure 8.

In CIAO 4. If a solid fill is not required, a pattern can be used to fill regions or histograms , as shown in Figure The order that items are drawn is determined by the order they were created and the value of their depth attributes. This value can be adjusted, as shown when creating Figure 9 , to ensure certain features are not covered up in this case it was to avoid the filled region from blocking out the data point.

The currency settings can be used to create multiple copies of an object. Axes contain a large number of attributes to control their appearance. Some highlights are:. Email: cxchelp head. All rights reserved. Skip to the navigation links. ChIPS - using symbols to draw sets of x,y points. Overview Synopsis: This thread is intended to give a simple demonstration of the support for symbols and error bars in ChIPS. Symbol support for curves In this section we are going to plot up the flux versus redshift values from the file bax.

Figure 1: Flux versus redshift using the default symbol style. Figure 2: Flux versus redshift: open square.