NHSC HIFI DP workshop Caltech, 29 August 2013 - page 1 Sideband Deconvolution.

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Presentation transcript:

NHSC HIFI DP workshop Caltech, 29 August page 1 Sideband Deconvolution

- page 2 Outline What is sideband deconvolution and why it is necessary for HIFI data? General description of the algorithm Implementation within HIPE Workflow for spectral scans

- page 3 Heterodyne observations Detectors are not able to directly measure flux at the frequencies of interest. But by mixing the signal from the sky with a local oscillator, we `downconvert’ the frequency. cos(ω)cos(ν LO )=0.5[ cos(ω-ν LO ) + cos(ω+ν LO ) ] When ω is the entire, unfiltered sky frequency, you end up being sensitive to TWO bandpasses. (cos(ν) = cos(-ν))

- page 4 LSB USB ν LO Heterodyne observations What is being measured -> How it looks when collected-> IF Sky frequency

- page 5 LSB USB ν LO Heterodyne observations What is being measured -> How it looks when collected-> IF Sky frequency

- page 6 LSB USB ν LO Heterodyne observations What is being measured -> How it looks when collected-> IF Sky frequency

- page 7 LSB USB ν LO Heterodyne observations What is being measured -> How it looks when collected-> IF Sky frequency

- page 8 Heterodyne observations What is being measured -> How it looks when collected-> LSB USB ν LO IF Sky frequency

- page 9 LSB USB ν LO Heterodyne observations What is being measured -> How it looks when collected-> IF Sky frequency

- page 10 Heterodyne observations What is being measured -> How it looks when collected-> LSB USB ν LO IF Sky frequency

- page 11 LSB USB ν LO Heterodyne observations What is being measured -> How it looks when collected-> IF Sky frequency

- page 12 LSB USB ν LO Heterodyne observations What is being measured -> How it looks when collected-> IF Sky frequency

- page 13 LSB USB ν LO Heterodyne observations What is being measured -> How it looks when collected-> IF Sky frequency

- page 14 LSB USB ν LO Heterodyne observations What is being measured -> How it looks when collected-> IF Sky frequency

- page 15 LSB USB ν LO Heterodyne observations What is being measured -> How it looks when collected-> IF Sky frequency

- page 16 Heterodyne observations LSB + USB = DSB Lower sideband spectrum is reversed and added Two frequency scales result in the DSB result The lines may blend but they can be recovered (deconvolved) The continuum levels add (double) in the DSB The continuum slope is flattened but may be recovered (deconvolved) The noise adds in quadrature, increasing as sqrt(2) LO

- page 17 Sideband Deconvolution The problem is the following: Given a collection of double sideband data taken over several LO tunings, how do we recover the original ‘sky’ spectrum? Comito & Schilke (2002) provide an algorithm which has been successfully employed with ground based heterodynes. Has been implemented in CLASS + X-CLASS (Fortran based) but was converted to JAVA for use within HIPE. Upgrades to the algorithm have been almost exclusively within HIPE.

- page 18 Deconvolution Algorithm Start with a guess of the answer – a model with no assumptions for the SSB spectrum – flat "Observe it" – using knowledge of the instrument compare the observations of the model with the real observations compute a chi square and a delta (differential) chi-square each model "spectral channel" was in part responsible for some of the chi square change follow the slope of the chi square downward (it's partial derivitive w.r.t. the channel flux (and optionally the sideband gain) new downward steps always move at right angles to previous ones in the Conjugate Gradient Method Stop, when solution converges asymptotically, as defined by the "tolerance" It’s iterative

- page 19 Example: Iteration 0

- page 20 Example: Iteration 1

- page 21 Example: Iteration 2

- page 22 Example: Iteration 3

- page 23 Example: Iteration 4

- page 24 Example: Iteration 5

- page 25 Example: Iteration 6

- page 26 Example: Iteration 7

- page 27 Example: Iteration 8

- page 28 Example: Iteration 9

- page 29 doDeconvolution caveats Iteration requires that the data make sense. –Sufficient redundancy (~100% of the time) –No spurs –Compatible baselines –No (or well behaved) standing waves Most work is done before deconvolution

- page 30 Decon GUI Some features not recommended at all (may be deprecated in a later release) Some features not used very often

- page 31 Demos 1.Basic deconvolution 2.How unflagged spurs affect decon output 3.Carefully flagging bad data improves result 4.The diagnostic mode (advanced) 5.Ghosts and ‘Bright Lines’