Super-resolution imaging with Sparse Modeling Mareki Honma (NAOJ) Kazu Akiyama(U. Tokyo) Makoto Uemura (Hiroshima U.) Shiro Ikeda (Institute of Statistical.

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Presentation transcript:

Super-resolution imaging with Sparse Modeling Mareki Honma (NAOJ) Kazu Akiyama(U. Tokyo) Makoto Uemura (Hiroshima U.) Shiro Ikeda (Institute of Statistical Mathematics)

Motivation For BH study, we need high resolution. Higher is better. (the main motivation for going to mm/sub-mm) If there is an imaging technique to obtain resolution better than the beam size (Θ ～ λ/D), this would significantly boost the imaging capability of EHT. Super-resolution technique is equivalent to buildinga larger array !!

Interferometry imaging Discrete Fourier transform of 2-D grid data Limited (u, v) coverage needs 0 padding of grids As a result, there will be finite-size beam and side lobes beam size Θ ～ λ / B (λ ： wavelength, B ： baseline length) Visibility S(u,v) Image I (x,y) N 2 points 2-D FT

Standard imaging: FFT with 0-filling V 1 I 1 V 2 I 2 V 3 = x I 3… V M … 0… 0I N Observed data A 0-fill 0-filling is done to equalize the number of equations and solutions

Imaging with sparse modeling V 1 I 1 V 2 I 2 V 3 = x I 3… V M … … I N Observed data A Sparse modeling can solve such an under-determined problem, only if the solution is sparse. i.e., select most sparse solution among infinite number of possible solutions (with l1-norm penalty) Free from side-lobes, free from the synthesized beam (in theory)

Simulation Simulated 6-station EHT observations of M87 (with noise) Initial model Standard image Sparse modeling Honma et al.(2014), PASJ in press, arXiv

Application to real data: M87 Not EHT, but VLBA at 22G/43G (Hada et al.11) Sparse modeling 43GHz 4x4 mas Sparse modeling 24GHz 4x4 mas Jet’s limb structure is clearly seen toward the core. Counter-jet is also resolved ! Preliminary Results ! Preliminary Results ! Standard imaging (Hada )

Concluding remarks Introduction of sparse modeling allow us to obtain super- resolution images and to boost imaging capability Application to the M87 data seems that the technique is promising, and hopefully make significant contribution to understand the event-horizon-scale structure in the AGNs. Great if we can apply this to high-sensitive data such as EATING VLBI Noto SRT Yebes