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lronaccal

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Radiometrically calibrates a LROC NAC image

Overview Parameters

Description

lronaccal performs radiometric corrections to images acquired by the Narrow Angle Camera aboard the Lunar Reconnaissance Orbiter spacecraft.

The LRO NAC detector has a total of 5064 pixels, divided among an A channel and a B channel. The pixels alternate between the two channels: ABABABAB, etc. Images from LROC NAC may or may not include all pixels in the acquired image. There are special summing modes that are utilized on-board the spacecraft to average detector pixels to combine them into a single output pixel value. The value of the ISIS label keyord, SpatialSumming, indicates the number of samples that were summed and averaged to result in the pixel values stored in the file. Note that this will reduce the number of samples in the output image by a factor of at most the SpatialSumming mode value.

The LROC NAC camera has the ability to acquire images of differing sizes in both line and sample. The starting hardware detector pixel for the acquired image is specified by the ISIS label keyword, SampleFirstPixel. The first pixel in the detector is indicated by a value of 0.

Dark current pixels are taken for each line from the masked pixels that lie along each edge of the image.

If SpatialSumming is 1 the dark current pixels are averaged together then this average is subtracted from all image pixels. If SpatialSumming is 2, the dark current pixels for the A and B channel are averaged separately, then the A channel dark average is subtracted from the A channel image pixels and the B channel dark average is subtracted from the B channel image pixels.

The DN level in an uncalibrated image is the sum of the true signal from the scene, the bias, the dark current, and random noise in all 3 components. The random noise in the true signal and dark current is called shot noise and the random noise in the bias is called read noise. The true signal, bias, and dark current are defined as mean values so that if the random noise were averaged down to insignificance by taking a very large number of images and averaging them, the resulting image would be the true scene, bias, and dark current with no systematic error. That implies the statistical distribution of the random noise has an average of zero, and therefore the random noise has both positive and negative values, except for the trivial case of zero random noise.

The calibration equation is:

        reportedDN = ObservedDN - MeanBias - DarkCurrent 
      
Where:
        ObservedDN = TrueDN + E
        E is a randomly sampled value from (mu, sigma^2) and mu=0
        TrueDN is the signal that would be reported in an idealized case of an instrument with zero noise.
      

The dark average produced is dependant on which options are selected. There are three options for dark calibration/correction. If the image has exposure code of zero, the nearest dark files with exposure code of zero will be used. Nearest pair of darks (Default): This option selects the two closest dark files (before and after the observation) and computes a time-weighted average. In the ideal case, this average product should characterize the dynamic dark response the best. Note: Each dark file is an average of a month’s worth of dark observations under given settings (i.e., exposure code, summing mode, etc.). The maximum time range between pairs of dark files is 45 days. If a suitable pair is not found, the latest dark file taken before the image will be used. pixel_dark_average = avgDarkLine1_pixel * |darkfile1_time - time| + avgDarkLine2_pixel * |darkfile2_time - time| / (1.0 * ( |darkFile1_time - time| + |darkFile2_time - time| ) ) Nearest dark file: This option selects the nearest dark file (before or after the observations). This option is typically only used when a pair of darks do not surround the observation. For example, during the mission, new NACs may not have a dark file in the dark catalog for times after the observation being calibrated. In this case, lronaccal will use only the previous NAC dark in the calibration steps. However, suppose the image is calibrated again after new darks have been added to the catalog. In that case, the default options for lronaccal will use a pair of dark observations, and the resulting calibrated image may have slightly different intensities than the NAC processed with only a single dark file. Note: While this is not a default option, if only one dark is available, lronaccal will automatically apply the nearest dark file. The user can see which dark(s) were applied in the cube header. Custom dark: This option uses a single custom dark file that the user must supply with the DarkFile parameter. This option is typically only used in special cases, such as calibrating very long exposure NAC images.

Let's look at the case of a calibrated image for which the true signal is zero, a dark image. In calibration the mean bias and dark current are subtracted. The random noise term is then randomly sampled from a known distribution with a mean of zero. Since the distribution has a mean of zero, values for the random noise can be positive or negative. Therefore, the addition of random noise to a pixel with true signal near zero can result in negative DN values.

Negative reported DNs are possible when E < -1 * TrueDN. These are pixels in a very dark image that happen to have a strongly negative random noise value.

Note: ObservedDN and TrueDN both must be greater than or equal to zero. For ObservedDN, it's because the hardware is not able to report negative DN values . For TrueDN, it's because radiance and reflectivity cannot be negative. The dimmest target is one that is completely dark, and for that target TrueDN = 0.

If run on a non-spiceinited cube, this program requires access to local mission-specific SPICE kernels, in order to find the distance between the sun and the target body. When run on a spiceinited cube, this can be determined using the camera model. Using a spiceinited cube as input has the advantage of not requiring that local mission-specific kernels be available. (See spiceinit web=true.)


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History

Jacob Danton2008-11-02 Original version
Adam Licht2013-02-28 No longer treat negative DNs differently in the Non-linearity correction.
Victor Silva2020-01-06 Added option for base calibration directory
Victor Silva2020-06-19 Updated dark calibration to use nearest pair of dark images to calibrate
Victor Silva2020-10-04 Updated dark calibration documentation to provide more clarity to dark file options

Parameter Groups

Files

Name Description
FROM Level 0 LROC NAC image
TO Level 1 LROC NAC image

Masked Pixels Options

Name Description
Masked Calibrate using the masked pixels.
MaskedFile

Dark File Options

Name Description
Dark Calibrate using average dark pixels.
DarkFileType Calibrate using average dark pixels from Nearest Single, Pair, or Custom dark file(s).
DarkFile

Nonlinearity Options

Name Description
Nonlinearity Calibrate using nonlinearity.
OffsetFile The Nonlinearity offset values.
NonlinearityFile Calibrate using the average dark pixels.

Flatfield Options

Name Description
Flatfield Calibrate using the flatfield.
FlatfieldFile Calibrate using the average dark pixels.

Radiometric Options

Name Description
Radiometric Calibrate using radiometric calibration.
RadiometricType Which radiance correction?
RadiometricFile
X

Files: FROM


Description

An uncalibrated LROC NAC image.

Type cube
File Mode input
Filter *.cub
Close Window
X

Files: TO


Description

The resultant radiometrically calibrated cube

Type cube
File Mode output
Pixel Type real
Close Window
X

Masked Pixels Options: Masked


Description

Type boolean
Default True
Inclusions
  • MaskedFile
Close Window
X

Masked Pixels Options: MaskedFile


Description

Type filename
Default Default
Close Window
X

Dark File Options: Dark


Description

Calibrate using average dark pixels. This is also referred to as dark correction. These dark calibration/correction files are included in the data directory (lro/calibration/nac_darks).

Type boolean
Default True
Inclusions
  • DarkFileType
Close Window
X

Dark File Options: DarkFileType


Description

There are three options for dark calibration/correction. If the image has exposure code of zero, the nearest dark files with exposure code of zero will be used. PAIR (Nearest pair of darks) [Default]: This option selects the two closest dark files (before and after the observation) and computes a time-weighted average. The maximum time range between pairs of dark files is 45 days. If a suitable pair is not found, the latest dark file taken before the image will be used. NEAREST (Nearest dark file): This option selects the nearest dark file (before or after the observations). Note: While this is not a default option, if only one dark is available, lronaccal will automatically apply the nearest dark file. CUSTOM (Custom dark): This option uses a single custom dark file that the user must supply with the DarkFile parameter. This option is typically only used in special cases, such as calibrating very long exposure NAC images.

Type string
Default Pair
Option List:
Option Brief Description
PAIRPair Pair of dark calibration files that the image time lies between

Exclusions

  • DarkFile
NEARESTNearest Single dark calibration file that is nearest the image time

Exclusions

  • DarkFile
CUSTOMCustom Dark File User provided dark calibration file

Inclusions

  • DarkFile
Close Window
X

Dark File Options: DarkFile


Description

Type filename
Default
Close Window
X

Nonlinearity Options: Nonlinearity


Description

Type boolean
Default True
Inclusions
  • OffsetFile
  • NonlinearityFile
Close Window
X

Nonlinearity Options: OffsetFile


Description

Type filename
Default Default
Close Window
X

Nonlinearity Options: NonlinearityFile


Description

Type filename
Default Default
Close Window
X

Flatfield Options: Flatfield


Description

Type boolean
Default True
Inclusions
  • FlatfieldFile
Close Window
X

Flatfield Options: FlatfieldFile


Description

Type filename
Default Default
Close Window
X

Radiometric Options: Radiometric


Description

Type boolean
Default True
Inclusions
  • RadiometricType
  • RadiometricFile
Close Window
X

Radiometric Options: RadiometricType


Description

Type string
Default IOF
Option List:
Option Brief Description
IOFI/F
RADIANCERadiance
Close Window
X

Radiometric Options: RadiometricFile


Description

Type filename
Default Default
Close Window