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一个关于物理的翻译.把英文翻译成中文
then will give a feel for the properties of the scalar function. We show such a contour map in the xy-plane at z = 0 for Eq. (1.2.2), namely,
I(,xy,0) 1 1/ 3 (1.2.3)
x2 yd 2 x2 y 2
d
Various contour levels are shown in Figure 1.2.4, for d 1, labeled by the value of the function at that level.
Figure 1.2.4 A contour map in the xy-plane of the scalar field given by Eq. (1.2.3).
2. Color-Coding
Another way we can represent the values of the scalar field is by color-coding in two dimensions for a fixed value of the third. This was the scheme used for illustrating the temperature fields in Figures 1.2.1 and 1.2.2. In Figure 1.2.5 a similar map is shown for the scalar field I(,xy,0) . Different values of I(,xy,0) are characterized by different
colors in the map.
Figure 1.2.5 A color-coded map in the xy-plane of the scalar field given by Eq. (1.2.3).
then will give a feel for the properties of the scalar function. We show such a contour map in the xy-plane at z = 0 for Eq. (1.2.2), namely,
I(,xy,0) 1 1/ 3 (1.2.3)
x2 yd 2 x2 y 2
d
Various contour levels are shown in Figure 1.2.4, for d 1, labeled by the value of the function at that level.
Figure 1.2.4 A contour map in the xy-plane of the scalar field given by Eq. (1.2.3).
2. Color-Coding
Another way we can represent the values of the scalar field is by color-coding in two dimensions for a fixed value of the third. This was the scheme used for illustrating the temperature fields in Figures 1.2.1 and 1.2.2. In Figure 1.2.5 a similar map is shown for the scalar field I(,xy,0) . Different values of I(,xy,0) are characterized by different
colors in the map.
Figure 1.2.5 A color-coded map in the xy-plane of the scalar field given by Eq. (1.2.3).
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