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Solar-powered space flight

5c. Creating ultra-lightweight solar power concentrators: Which rotationally symmetric aplanatic two mirror arrangements are best for our purposes?

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5c.          Which rotationally symmetric aplanatic two mirror arrangements are best for our purposes?

 

5.7          The most effective layouts from our perspective appear to arise if  is positive,  is negative (between –1 and 0) and  is negative, see Kemp (2003). Figure 8 shows such a layout, if iterated to its extremities, derived from ,  and . The solid lines are cross-sections of the mirrors themselves, and the dotted lines are the paths of light rays from the object to the image passing through extremities of the available iterative process. This layout has an effective aperture area factor of 96%, a mirror surface area factor of 1.03 and an aberration factor of 0.059. It avoids having any of the rays of sunlight crossing the positive x-axis. This is a desirable feature, as ideally propellant would be ejected along approximately this axis, see later.

 

Figure 8. Mirror layout arising from ,  and

 

 

5.8          A possible disadvantage of choosing the above values of  and  is that the larger mirror is some way away from the image point, which would increase the mass of wires joining this mirror to the main vehicle body.  If instead we use  and  then the mirror layout is as shown in Figure 9 and the main mirror would be nearer to the focal point (i.e. the origin) for a fixed collector area. Three-dimensional perspectives of this layout are shown in Figure 10. The average aberration factor improves to 0.020. However, the aperture area factor falls to 91% and the mirror surface area factor rises to 1.13.

 

Figure 9. Mirror layout arising from ,  and

 

 

Figure 10. Three-dimensional perspectives of mirror layout arising from ,  and

 

 

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