The table below gives all the details on the PS1 projection cells. The 000 skycell is in the bottom left corner of the projection cell, 010 is just above it, and 099 is in the upper right corner. Skycell images have names like skycell.nnnn.0yx where nnnn is the projection cell number (which ranges from 635 to 2643) and 0yx gives the skycell location in the image, with y and x ranging from 0 to 9 indicating the respective y and x section of the projection cell. Consequently, for objects and structures smaller than 2 arcmin it is generally not necessary to combine data from adjacent skycells. They can be pasted together to make a larger image.Īdjacent skycells within a projection cell overlap by 240 pixels (60 arcsec) at each edge with the neighboring skycells. The skycells are typically 0.4°x0.4° in size. These images are simple rectangular FITS images that share the same tangent world coordinate system with the original projection cell image (i.e., they have the same CRVAL1, CRVAL2, and pixel size). To make them easier to work with, each projection cell is divided into a grid of 10x10 skycells. The projection cell images would be large and inconvenient to download – they are typically about 63000圆3000 pixels and so would be about 8 GB each. In the future the data near the pole will be reprocessed to generate a larger image that has the necessary overlap.įigure 3: Closeup of PS1 projection cells near the north celestial pole showing regions where the overlap is small, or (in the case of the middle plot) has gaps between the images. The missing region is small (~1.6x10 -3 sq deg). The skycells that touch on the missing region are 2643.094 (from the polar image), 2638.093, and 2639.096. In that region there are no image pixels and no catalog coverage. In fact, the polar cell is currently slightly too small to create adequate overlap with the neighbors (Figure 3), so there is a gap in the PS1 sky coverage around RA=180 °, Dec=87.97 °. Note that the overlap regions between the projection cell centered on the north celestial pole and the neighboring cells are at some spots extremely small. The projection cells are 4°x4° in size and are on rings spaced by 4° in declination. The coverage extends from declination −30° to the north celestial pole.įigure 2: PS1 projection cells near the north celestial pole, where the image overlap is greatest due to convergence of the RA grid. The figures below display the projection cells for the entire PS1 sky north of −30° and for the region around the north celestial pole.įigure 1: Aitoff plot of all 2,009 PS1 projection cells for the 3PI survey. For the Medium Deep Surveys (which do not yet have image products), special projection cells are used that are centered on each medium deep field. Note that this tessellation applies to the PS1 3PI survey. (There are a few scattered images at more southern declinations, so there is a small amount of data – but no stack images – in projection cells smaller than 635.) The table at the bottom gives the details on the number of cells in each row, the exact sizes of the images, etc. The first PS1 projection cell above -30° is number 635 at RA=0°, δ = −30°, and the last one is 2643 at δ = +90°. Since the PS1 survey covers the sky only for δ > −30°, not all projection cells are used for PS1 images. Finally, the projection cells themselves are numbered consecutively (ordered by increasing RA) starting at 0 at the south pole, 1–9 at δ = −86°, etc. Within a given declination zone, the projection cells are centered at RA(n) = n Δα = n 360°/M where M is the number of RA cells in the zone. There are 46 declination zones numbered starting at 0 for an image at δ = −90°, 1 for a row of 9 images centered at δ = −86°, 2 at δ = −82°, and so on the images in zones 22 and 23 are at δ = −2° and +2°, and zones 44 and 45 are at δ = +86° and +90° respectively. The pattern is defined to cover the entire sky from δ = −90° to +90°. At a given declination, the pointing centers are equally spaced in right ascension around the sky, with the number of RA points changing to account for the convergence of RA lines in the spherical sky. The projection cell centers are located on lines of constant declination spaced 4° apart. The sizes of the large projection cells are approximately constant over the sky. It was defined by Tamas Budavari to meet the goals of defining a regular image pattern with nearly square cells that covers the sky while minimizing redundant image overlap. The PS1 image layout for the 3PI survey is called the RINGS.V3 tessellation. Projection cells in the RINGS.V3 tessellation
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