NASSP Masters 5003F - Computational Astronomy - 2009 Lecture 13 Further with interferometry – Resolution and the field of view; Binning in frequency and.

Slides:

Advertisements

Similar presentations

A Crash Course in Radio Astronomy and Interferometry: 4

Advertisements

A Crash Course in Radio Astronomy and Interferometry: 2

Computer Vision Lecture 7: The Fourier Transform

3-D Computational Vision CSc Image Processing II - Fourier Transform.

LECTURE Copyright  1998, Texas Instruments Incorporated All Rights Reserved Use of Frequency Domain Telecommunication Channel |A| f fcfc Frequency.

NASSP Masters 5003F - Computational Astronomy Lecture 5: source detection. Test the null hypothesis (NH). –The NH says: let’s suppose there is no.

DFT/FFT and Wavelets ● Additive Synthesis demonstration (wave addition) ● Standard Definitions ● Computing the DFT and FFT ● Sine and cosine wave multiplication.

Understanding interferometric visibility functions J. Meisner.

Techniques in Signal and Data Processing CSC 508 Fourier Analysis.

The Shapes Of Cross Correlation Interferometers Daniel Birman Boaz Chen

Radio `source’ Goals of telescope: maximize collection of energy (sensitivity or gain) isolate source emission from other sources… (directional gain… dynamic.

Gerald Leung.  Implementation Goal of Phase Vocoder  Spectral Analysis and Manipulation  Matlab Implementation  Result Discussion and Conclusion.

General Functions A non-periodic function can be represented as a sum of sin’s and cos’s of (possibly) all frequencies: F(  ) is the spectrum of the function.

CSCE 641 Computer Graphics: Image Sampling and Reconstruction Jinxiang Chai.

Sampling, Reconstruction, and Elementary Digital Filters R.C. Maher ECEN4002/5002 DSP Laboratory Spring 2002.

Image Enhancement in the Frequency Domain Part I Image Enhancement in the Frequency Domain Part I Dr. Samir H. Abdul-Jauwad Electrical Engineering Department.

1 Synthesis Imaging Workshop Error recognition R. D. Ekers Narrabri, 20 Sep 2006.

Back Projection Reconstruction for CT, MRI and Nuclear Medicine

1 Synthesis Imaging Workshop Error recognition R. D. Ekers Narrabri, 14 May 2003.

Ninth Synthesis Imaging Summer School Socorro, June 15-22, 2004 Cross Correlators Walter Brisken.

Interferometry Basics

Basics of Interferometry

Topic 7 - Fourier Transforms DIGITAL IMAGE PROCESSING Course 3624 Department of Physics and Astronomy Professor Bob Warwick.

GLOW Interferometry School, Bielefeld Fourier optics 2.Fourier theorems 3.Visibility function 4.Aperture synthesis 5.Coordinates 6.Correlation interferometer.

Diffraction from point scatterers Wave: cos(kx +  t)Wave: cos(kx +  t) + cos(kx’ +  t) max min.

Motivation Music as a combination of sounds at different frequencies

Random Media in Radio Astronomy Atmospherepath length ~ 6 Km Ionospherepath length ~100 Km Interstellar Plasma path length ~ pc (3 x Km)

: Chapter 14: The Frequency Domain 1 Montri Karnjanadecha ac.th/~montri Image Processing.

Controlling Field-of-View of Radio Arrays using Weighting Functions MIT Haystack FOV Group: Lynn D. Matthews,Colin Lonsdale, Roger Cappallo, Sheperd Doeleman,

NASSP Masters 5003F - Computational Astronomy Lecture 3 First, a bit more python. Then some noise statistics.

Radio Interferometry and ALMA T. L. Wilson ESO. A few basics: Wavelength and frequency  -1 temperature max (mm) ~ 3/T(K) (for blackbody) Hot gas radiates.

09/19/2002 (C) University of Wisconsin 2002, CS 559 Last Time Color Quantization Dithering.

Digital Image Processing Chapter 4 Image Enhancement in the Frequency Domain Part I.

Lecture 7: Sampling Review of 2D Fourier Theory We view f(x,y) as a linear combination of complex exponentials that represent plane waves. F(u,v) describes.

October 29, 2013Computer Vision Lecture 13: Fourier Transform II 1 The Fourier Transform In the previous lecture, we discussed the Hough transform. There.

1 ATNF Synthesis Workshop 2001 Basic Interferometry - II David McConnell.

NASSP Masters 5003F - Computational Astronomy Lecture 12: The beautiful theory of interferometry. First, some movies to illustrate the problem.

NASSP Masters 5003F - Computational Astronomy Lecture 14 Reprise: dirty beam, dirty image. Sensitivity Wide-band imaging Weighting –Uniform vs Natural.

The Australia Telescope National Facility Ray Norris CSIRO ATNF.

Tenth Synthesis Imaging Summer School UNM, June 13-20, 2006 Cross Correlators Walter Brisken.

Lecture#10 Spectrum Estimation

NASSP Masters 5003F - Computational Astronomy Lecture 12 Complex numbers – an alternate view The Fourier transform Convolution, correlation, filtering.

Lecture 7 Transformations in frequency domain 1.Basic steps in frequency domain transformation 2.Fourier transformation theory in 1-D.

2D Sampling Goal: Represent a 2D function by a finite set of points.

Geology 5600/6600 Signal Analysis 16 Sep 2015 © A.R. Lowry 2015 Last time: A process is ergodic if time averages equal ensemble averages. Properties of.

NASSP Masters 5003F - Computational Astronomy Lecture 16 Further with interferometry – Digital correlation Earth-rotation synthesis and non-planar.

Lecture 8 Source detection NASSP Masters 5003S - Computational Astronomy

Lecture 14. Radio Interferometry Talk at Nagoya University IMS Oct /43.

Lens to interferometer Suppose the small boxes are very small, then the phase shift Introduced by the lens is constant across the box and the same on both.

1 ATNF Synthesis Workshop 2003 Basics of Interferometry David McConnell.

NASSP Masters 5003F - Computational Astronomy Lecture 11 Single-dish spectra: baselines. Complex numbers refresher Fourier refresher Correlation.

1 Combining Single Dish and Interferometer Data Naomi McClure-Griffiths ATNF ATNF Astronomical Synthesis Imaging Workshop September 24-28, 2001 or Seeing.

Single Dish Summer School, Green Bank 2007 Things to do with Single Dish: VLBI Tapasi Ghosh NAIC/Arecibo Observatory Outline: Interferometry Basic.

M.P. Rupen, Synthesis Imaging Summer School, 18 June Cross Correlators Michael P. Rupen NRAO/Socorro.

Atacama Large Millimeter/submillimeter Array Karl G. Jansky Very Large Array Robert C. Byrd Green Bank Telescope Very Long Baseline Array Short Spacing.

The Fourier Transform.

ATNF Synthesis Workshop - September Single-dish spectral-line observing Lister Staveley-Smith, ATNF  Why use a single-dish?  Analogy with interferometer.

Details: Gridding, Weight Functions, the W-term

Linear Filters and Edges Chapters 7 and 8

Linear Filters and Edges Chapters 7 and 8

CLEAN: Iterative Deconvolution

FFT-based filtering and the

Telescopes and Images.

(C) 2002 University of Wisconsin, CS 559

van Cittert-Zernike Theorem

General Functions A non-periodic function can be represented as a sum of sin’s and cos’s of (possibly) all frequencies: F() is the spectrum of the function.

All about convolution.

Lecture 35 Wave spectrum Fourier series Fourier analysis

Deconvolution and Multi frequency synthesis

Goals of telescope: Radio `source’

Presentation transcript:

NASSP Masters 5003F - Computational Astronomy Lecture 13 Further with interferometry – Resolution and the field of view; Binning in frequency and time, and its effects on the image; Noise in cross-correlation; Gridding and its pros and cons.

NASSP Masters 5003F - Computational Astronomy Earth-rotation synthesis Apply appropriate delays: like measuring V with ‘virtual antennas’ in a plane normal to the direction of the phase centre.

NASSP Masters 5003F - Computational Astronomy Earth-rotation synthesis Apply appropriate delays: like measuring V with ‘virtual antennas’ in a plane normal to the direction of the phase centre.

NASSP Masters 5003F - Computational Astronomy Earth-rotation synthesis Apply appropriate delays: like measuring V with ‘virtual antennas’ in a plane normal to the direction of the phase centre.

NASSP Masters 5003F - Computational Astronomy Field of view and resolution. Single dish: FOV and resolution are the same. FOV ~ λ /d (d = dish diameter) Resolution ~ λ /d

NASSP Masters 5003F - Computational Astronomy Field of view and resolution. Aperture synthesis array: FOV is much larger than resolution. FOV ~ λ /dResolution ~ λ /D (D = longest baseline) d D

NASSP Masters 5003F - Computational Astronomy Field of view and resolution. Phased array: Signals delayed then added. FOV again = resolution. FOV ~ λ /DResolution ~ λ /D d D Good for spectroscopy, VLBI.

NASSP Masters 5003F - Computational Astronomy LOFAR – can see the whole sky at once.

NASSP Masters 5003F - Computational Astronomy Reconstructing the image. The basic relation of aperture synthesis: where all the (l,m) functions have been bundled into I´. We can easily recover the true brightness distribution from this. The inverse relationship is: But, we have seen, we don’t know V everywhere.

NASSP Masters 5003F - Computational Astronomy Sampling function and dirty image Instead, we have samples of V. Ie V is multiplied by a sampling function S. Since the FT of a product is a convolution, where the ‘dirty beam’ B is the FT of the sampling function: I D is called the ‘dirty image’.

NASSP Masters 5003F - Computational Astronomy Painting in V as the Earth rotates

NASSP Masters 5003F - Computational Astronomy Painting in V as the Earth rotates

NASSP Masters 5003F - Computational Astronomy But we must ‘bin up’ in ν and t. This smears out the finer ripples. Fourier theory says: finer ripples come from distant sources. Therefore want small Δ ν, Δt for wide-field imaging. But:  huge files.

NASSP Masters 5003F - Computational Astronomy We further pretend that these samples are points.

NASSP Masters 5003F - Computational Astronomy What’s the noise in these measurements? Theory of noise in a cross-correlation is a little involved... but if we assume the source flux S is weak compared to sky+system noise, then If antennas the same, Root 2 smaller SNR from single-dish of combined area (lecture 9). –Because autocorrelations not done  information lost.

NASSP Masters 5003F - Computational Astronomy Resulting noise in the image: Spatially uniform – but not ‘white’. (Note: noise in real and imaginary parts of the visibility is uncorrelated.)

NASSP Masters 5003F - Computational Astronomy Transforming to the image plane: Can calculate the FT directly, by summing sine and cosine terms. –Computationally expensive - particularly with lots of samples. MeerKAT: a day’s observing will generate about 80*79*17000*500=5.4e10 samples. FFT: –quicker, but requires data to be on a regular grid.

NASSP Masters 5003F - Computational Astronomy How to regrid the samples? Could simply add samples in each box.

NASSP Masters 5003F - Computational Astronomy But this can be expressed as a convolution. Samples convolved with a square box.

NASSP Masters 5003F - Computational Astronomy Convolution  gridding. ‘Square box’ convolver is Gives But the benefit of this formulation is that we are not restricted to a ‘square box’ convolver. –Reasons for selecting the convolver carefully will be presented shortly.

NASSP Masters 5003F - Computational Astronomy What does this do to the image? Fourier theory: –Convolution  Multiplication. –Sampling onto a grid  ‘aliasing’.

NASSP Masters 5003F - Computational Astronomy A 1-dimensional example ‘dirty image’ I D : V  I via direct FT:

NASSP Masters 5003F - Computational Astronomy A 1-dimensional example ‘dirty image’ I D : Multiplied by the FT of the convolver:

NASSP Masters 5003F - Computational Astronomy A 1-dimensional example: The aliased result is in green: Image boundaries become cyclic.

NASSP Masters 5003F - Computational Astronomy A 1-dimensional example: Finally, dividing by the FT of the convolver:

NASSP Masters 5003F - Computational Astronomy Effect on image noise: Direct FT Gridded then FFT

NASSP Masters 5003F - Computational Astronomy Aliasing of sources – none in DT This is a direct transform. The green box indicates the limits of a gridded image.

NASSP Masters 5003F - Computational Astronomy Aliasing of sources – FFT suffers from this. The far 2 sources are now wrapped or ‘aliased’ into the field – and imperfectly suppressed by the gridding convolver.