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MIPS Enhancer

MIPS Enhancer. MIPS_Enhancer Overview MIPS Data Processing and Calibration Workshop April 12, 2004. How to Run MIPS_ENHANCER. Command line options mips_enhancer –f filename.fits (40+ options) Namelist options mips_enhancer –n namelist.in. What have we learned since launch ?.

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MIPS Enhancer

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  1. MIPS Enhancer MIPS_Enhancer Overview MIPS Data Processing and Calibration Workshop April 12, 2004

  2. How to Run MIPS_ENHANCER • Command line options • mips_enhancer –f filename.fits (40+ options) • Namelist options • mips_enhancer –n namelist.in

  3. What have we learned since launch ? • Need to make MIPS_enhancer more efficient in terms of: • Memory • Speed • Improve method of combing surface bright nesses.

  4. Memory and Speed • Tiling • -x #, -y # • Only operating on tile sub-pixels • Do not hold mosaic in memory • -m • Memory limited to current tile • Write tiles out • Stitch mosaic from tiles • Necessary to change format of mosaic to limit memory needed. • Primary header (history, information from first DCE) • Extensions: surface brightness, uncertainty, pixel flag, overlap coverage)

  5. Conserving Surface Brightness • Improvements in: • Outlier rejection algorithm • Weighting overlapping pixels in mosaic

  6. Outlier Rejection Algorithm • For each sub-pixel there is a stack of overlapping BCD pixels.

  7. Sub-Pixel Outlier Rejection N BCD overlapping pixel values Start Iteration i = 1. • Find the median value: Medianorg • Find Standard Deviation: STDEVorg • Find N differences: |(Medianorg – fluxk)| • Sort differences • Withhold 10% largest differences (minimum 1) • Find new medianand standard deviation of remaining points: Mediani, STDEVi • Test Most deviant point: • (Fluxmost deviant point – Mediani)/STDEVi> Sigma Clipping (SC) • If reject – iterate

  8. Outlier Rejection cont. • Continue iterating until: • Remain points < Minimum Points (SP) • Iteration # > Maximum # iterations (SM) • ((STDEVorg – STDEVnew)/STDEVorg )*100 > Sigma Tolerance (ST)

  9. Variation on Outlier Rejection • Option: SK Test Most deviant point: (Fluxmost deviant point – Mediani)/STDEVi> Sigma Clipping (SC) • Option: SU Instead of using the standard deviation of stack: STDEVi Combine in quadrature: uncertainty of BCD pixel and standard deviation of Median

  10. Obsolete Outlier Rejection options • Quartiles • May retire thresholding (t) • (Fluxi/Median Flux) > t continue rejecting • (Fluxi/Median Flux) < t stop rejection

  11. Conserving Surface Brightness • For each sub-pixel we have N BCD pixels overlapping • Surface Brightness of BCD • Uncertainty associated with surface brightness • Overlap Area • How do we combine information to conserve surface brightness in mosaic ?

  12. Distortions

  13. Weighting Methods Most probable value is a weighted average of points: • = wixi/  wi • W1= overlap area, uncertainties • W2=overlap area • W3=overlap area, S/N (SB/uncertainty) • W4=overlap area, SQRT(S/N) • W5=overlap area, SQRT(S)

  14. Useful Options for MIPS_enhancer • -f filename (-i list of files) • -o output_name • -RR (remove rotation) • -s # (scale factor, recommended = 0.25) • dy (correct for distortion, default) • -x #, -y #, -m (memory & speed options) • -r # (70 microns, # BCDs to reject after stim, recommened 1) • -IB (ignore bias boost, 24 microns, default) • -W2 (W1,W3,W4,W5) Weight options • -SC #, ST #, SP #, SM # SK, SU (outlier rejection options Recommened:SC 4, ST 10, SP 3, SM 30, SK) • -FM (FD) sub-pixel flux weighted mean (median) • -D, -C, -FL (sets other appropriate options)

  15. Near Term Improvements • SED mode • Distortion (verify or tweak distortion coefficients produced from CODE-V) • Study on surface brightness conservation • Add weighting which only uses the number of reads that went into the slope determination. • Develop testing routine to see how well we have Use simulating routine (Emeric) to add sources to cal file. • Move on to 160 micron data • Start enhancing framework

  16. Suggestions ?

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