We present a detailed analysis of archival Hubble Space Telescope data that we use to measure the proper motion of the Crab pulsar, with the primary goal of comparing the direction of its proper motion with the projected axis of its pulsar wind nebula (the projected spin axis of the pulsar). We demonstrate that our measurement, using 47 observations spanning > 10 yr, is robust and has an uncertainty of only +/- 0.4 mas yr(-1) on each component of the proper motion. However, we then consider the various uncertainties that arise from the need to correct the proper motion that we measure to the local standard of rest at the position of the pulsar and find mu(alpha) = 11.8 +/- 0.4 +/- 0.5 mas yr(-1) and mu(alpha) = +4.4 +/- 0.4 +/- 0.5 mas yr(-1) relative to the pulsar's standard of rest, where the two uncertainties are from the measurement and the reference frame, respectively. Comparing this proper motion to the symmetry axis of the pulsar wind nebula, we must consider the unknown velocity of the pulsar's progenitor (assumed to be similar to 10 km s(-1)), and hence add an additional uncertainty of +/- 2 mas yr(-1) to each component of the proper motion. This implies a projected misalignment with the nebular axis of 14 degrees +/- 2 degrees +/- 9 degrees, consistent with a broad range of values including perfect alignment. We use our proper motion to derive an independent estimate for the site of the supernova explosion with an accuracy that is 2-3 times better than previous estimates. We conclude that the precision of individual measurements which compare the direction of motion of a neutron star to a fixed axis will often be limited by fundamental uncertainties regarding reference frames and progenitor properties.

• 出版日期2008-4-20