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The Development of High-Resolution Imaging in Radio Astronomy

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1 The Development of High-Resolution Imaging in Radio Astronomy
Jim Moran Harvard-Smithsonian Center for Astrophysics 7th IRAM Interferometry School, Grenoble, October 4–7, 2010 It is an honor to give this lecture in the city where Joseph Fourier did the work that is so fundamental to our craft.

2 Outline of Talk I. Origins of Interferometry II. Fundamental Theorem of Interferometry (Van Cittert-Zernike Theorem) III. Limits to Resolution (uv plane coverage) IV. Quest for High Resolution in the 1950s V. Key Ideas in Image Calibration and Restoration VI. Back to Basics – Imaging Sgr A* in 2010 and beyond

3 I. Origins of Interferometry
A. Young’s Two-Slit Experiment B. Michelson’s Stellar Interferometer C. Basic Radio Implementation D. Ryle’s Correlator E. Sea Cliff Interferometer F. Earth Rotation Synthesis Albert Michelson (1852–1931) Martin Ryle (1918–1984) John Bolton (1922–1993) Thomas Young (1773–1829)

4 Young’s Two-Slit Experiment (1805)
Source plane Aperture plane (screen with 2 small holes) Pupil or Image plane quasi-monochromatic light source Fringes Bright Dark I X I = (E1 + E2 )2 =  E12 +  E22 + 2(E1E2 ) interference term Imax– Imin Imax+ Imin V =  t  1 bandwidth effect Imax Imin 1. Move source  shift pattern (phase) 2. Change aperture hole spacing  change period of fringes 3. Enlarge source plane hole  reduce visibility

5 Michelson-Pease Stellar Interferometer (1890-1920)
Two outrigger mirrors on the Mount Wilson 100 inch telescope Paths for on axis ray and slightly offset ray Image plane fringe pattern. Solid line: unresolved star Dotted line: resolved star

6 Simple Radio Interferometer
R = I cos   = d s = cos  2 2 d = e sin d dt = sin d  = 2 =  2 d sin  d sin   = projected baseline d sin  d s R “fringes”

7 Simple Adding Interferometer (Ryle, 1952)
R = (a + b)2 = a 2 +b 2 +2ab Cassiopeia A Cygnus A

8 Phase Switching Interferometer (Ryle, 1952)
R = (a + b)2 – (a – b)2 = 4ab

9 Sea Cliff Interferometer (Bolton and Stanley, 1948)
Time in hours Response to Cygnus A at 100 MHz (Nature, 161, 313, 1948)

10 II. Fundamental Theorem
A. Van Cittert-Zernike Theorem B. Projection Slice Theorem C. Some Fourier Transforms

11 Van Cittert–Zernike Theorem (1934)
E1 = e i r 2 r1 1 E1 E2  = e i (r – r )   2 r1 r2 2 * E2 = e i r r2 Huygen’s principle  2 = I(,) r1r2  z 2 Integrate over source V(u,v) = I(,) e i2 ( u +  v) d d E1 E2 z r2 r1 x ′ y ′ ( = x ′/z) ( = y ′/z) x =u y = v source distribution I (, ) Ground Plane Sky Plane Assumptions Incoherent source Far field z >d 2 / ; d = 104 km,  = 1 mm, z > 3 pc ! Small field of view Narrow bandwidth  field = max ( ) dmax 

12 Projection-Slice Theorem (Bracewell, 1956)
F (u,v) =  f(x,y) e–i 2 (ux + vy) dx dy F(u,0) =  [  f(x,y) dy ] e–i 2 ux dx F(u,0)  fs (x) “strip” integral Works for any arbitrary angle Strip integrals, also called back projections, are the common link between radio interferometry and medical tomography.

13 Visibility (Fringe) Amplitude Functions for Various Source Models
Moran, PhD thesis, 1968

14 III. Limits to Resolution (uv plane coverage)
A. Lunar Occultation B. uv Plane Coverage of a Single Aperture

15 Lunar Occultation Geometric optics  one-dimension integration
Moon as a knife edge Geometric optics  one-dimension integration of source intensity Im( ) = I( )  H( ) Im(u) = I(u) H(u) where H(u) = 1/u H  u F.T. MacMahon (1909)

16 Criticized by Eddington (1909)
H u F = 2R   (wiggles) (R = earth-moon distance) 2 H = e –iF u sign(u) 1 Same amplitude as response in geometric optics, but scrambled phase F = 5 0.5 wavelength F = 2´ @ 10 m wavelength

17 Occultation of Beta Capricorni with Mt. Wilson 100 Inch Telescope and
Fast Photoelectric Detector Whitford, Ap.J., 89, 472, 1939

18 Radio Occultation Curves (Hazard et al., 1963)

19 Single Aperture Single Pixel Airy Pattern D  = 1.2  / D F.T.
v D Restore high spatial frequencies up to u = D/  no super resolution Chinese Hat Function

20 IV. Quest for High Resolution in the 1950s
A. Hanbury Brown’s Three Ideas B. The Cygnus A Story

21 Hanbury Brown’s Three Ideas for High Angular Resolution
In about 1950, when sources were called “radio stars,” Hanbury Brown had several ideas of how to dramatically increase angular resolution to resolve them. 1. Let the Earth Move (250 km/s, but beware the radiometer formula!) 2. Reflection off Moon (resolution too high) 3. Intensity Interferometer (inspired the field of quantum optics)

22 Intensity Interferometry
v2 v1 Normal Interferometer  = v1v2  V Intensity Interferometer  = v12v22 Fourth-order moment theorem for Gaussian processes v1v2v3v4 = v1v2 v3v4 + v1v3 v2v4 + v1v4 v2v3  = v12v22 = v12 v22 + v1v2  2  = P1P2 + V 2 constant square of visibility

23 Observations of Cygnus A with Jodrell Bank Intensity Interferometer
Square of Visibility at 125 MHz Jennison and Das Gupta, 1952, see Sullivan 2010

24 Cygnus A with Cambridge 1-mile Telescope at 1.4 GHz
3 telescopes 20 arcsec resolution Ryle, Elsmore, and Neville, Nature, 205, 1259, 1965

25 Cygnus A with Cambridge 5 km Interferometer at 5 GHz
16 element E-W Array, 3 arcsec resolution Hargrave and Ryle, MNRAS, 166, 305, 1974

26 V. Key Ideas in Image Calibration and Restoration
A. CLEAN B. Phase and Amplitude Closure C. Self Calibration D. Mosaicking E. The Cygnus A Story Continued Jan Högbom (1930–) Roger Jennison (1922–2006) Alan Rogers (1942–) several Ron Eker (~1944–) Arnold Rots (1946–)

27 First Illustration of Clean Algorithm on 3C224.1
at 2.7 GHz with Green Bank Interferometer Zero, 1, 2 and 6 iterations J. Högbom, Astron. Astrophys. Suppl., 15, 417, 1974

28 Closure Phase “Necessity is the Mother of Invention”
to source 1 3 3 2 2 d12 “cloud” with phase shift 1 = 2 t d12 + d23 + d31 = 0 Observe a Point Source 12 = d12 s + 1 – 2 2  C =  12 +  23 +  31 = [d12 + d23 + d31] s 2  Arbitrary Source Distribution m = v + (i – j) + ij ij noise C = m + m + m = v + v + v + noise 12 23 31 N stations  baselines, (N – 1)(N – 2) closure conditions N(N – 1) 2 1 fraction of phases f = 1 – 2 N N = 27, f  0.9 R. Jennison, 1952 (thesis): MNRAS, 118, 276, 1956; A. Rogers et al., Ap.J., 193, 293, 1974

29 Unknown voltage gain factors for each antenna gi (i = 1–4)
Closure Amplitude N ≥ 4 Unknown voltage gain factors for each antenna gi (i = 1–4)

30 A Half Century of Improvements
in Imaging of Cygnus A Kellermann and Moran, Ann. Rev. Astron., 39, 457, 2001

31 Imaging Sgr A* in 2010 and beyond
VI. Back to Basics Imaging Sgr A* in 2010 and beyond

32 230 GHz Observations of SgrA*
4030 km 908 km 4630 km VLBI program led by large consortium led by Shep Doeleman, MIT/Haystack

33 Visibility Amplitude on SgrA* at 230 GHz, March 2010
Days 96 and 97 (2010) Model fits: (solid) Gaussian, 37 uas FWHM; (dotted) Annular ring, 105/48  as diameter – both with 25  as of interstellar scattering Doeleman et al., private communication

34 New (sub)mm VLBI Sites Phase 1: 7 Telescopes (+ IRAM, PdB, LMT, Chile)
Phase 2: 10 Telescopes (+ Spole, SEST, Haystack) Phase 3: 13 Telescopes (+ NZ, Africa)

35 Progression to an Image
GR Model 7 Stations 13 Stations Doeleman et al., “The Event Horizon Telescope,” Astro2010: The Astronomy and Astrophysics Decadal Survey, Science White Papers, no. 68


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