I. Introduction

II. Procedures

Page History

I. Introduction

II. Procedures

III. Uploading Data to LIMS

IV. Appendix

Theory of Operation

Hardware

Getting Started

Detector Calibration

Starting Measurements

Page tree

Versions Compared

Key

Theory of Operation

Hardware

Getting Started

Detector Calibration

Starting Measurements

Cropping and Processing an X-Ray image

Turning the X-Rays OFF

Seasoning

Motion Control Setup

Cropping and Processing an X-Ray image

Turning the X-Rays OFF

Seasoning

File Formats and File Saving

File Uploading to LIMS

Displaying the images with LIVE

A.1. Health, Safety and Environment

A.2. Maintenance

B1. Troubleshooting

B2. NI Communication Ports

C1. Motion Control Setup

Shielding

Safety Systems

Thermal Management

Turning ON the XSCAN

Launching the IMS X-Ray Imager application

Initial Instrument Setup

X-Ray Power Settings

Calibrating the Detector

Positioning the section inside the XSCAN

Entering Sample Information

Entering Sample Information

Old Version 9

New Version Current

Shielding

Safety Systems

Thermal Management

Turning ON the XSCAN

Launching the IMS X-Ray Imager application

Initial Instrument Setup

X-Ray Power Settings

Calibrating the Detector

Positioning the section inside the XSCAN

Entering Sample Information

Entering Sample Information

Taking X-Ray Images

Positioning sections inside the XSCAN

Selecting the crop area

Processing the image

Saving the images

X-Ray Auto Off

ABORT a measurement sequence

Motor and Track Options Menu

Fixed Positions Menu

Retrieving Sections from inside the XSCAN

Entering Sample Information

Taking X-Ray Images

Selecting the crop area

Processing the image

Saving the images

X-Ray Auto Off

ABORT a measurement sequence

Seasoning

X-Ray Source Status

Cleaning tube

Computer memory full

Seasoning of the spare tube does not start

IMS frozes during X-Ray Auto off

Motor and Track Options Menu

Failsafe Circuitry

Visual Indicators

Door Switches

Emergency Stop Switch

A Quick Introduction to the IMS Program Structure

XSCAN Instrument General Setup

Imaging Method

Imaging Method

Sample Entry Tabs

Failsafe Circuitry

Visual Indicators

Door Switches

Emergency Stop Switch

A Quick Introduction to the IMS Program Structure

XSCAN Instrument General Setup

Imaging Method

Imaging Method

Sample Entry Tabs

Sample Entry Tabs

Scanned Interval Length

Imaging sections longer than 150 cm

Imaging Method

Sample Entry Tabs

Scanned Interval Length

Table of Contents

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XSCAN in the Core

lab

Lab

This guide describes the standard operating procedures for the X-Ray imager (XSCAN) located in the Core Lab. The system is capable of collecting linescan X-radiographs on whole round and section half cores. Furthermore, the source and detector can be rotated around the core material for linescans with different view angles. A specific region of interest (ROI) on a core section can be imaged separately using the ROI feature.

Users should review the X-Ray Methods and Theory Powerpoint from B. LeVay, 2019 for background on X-Ray radiograph acquisition before operating the system.

The IODP X-Ray scanner is composed of a 210W, 160 kV, 1.3 mA constant potential X-Ray source and a linescan detector. The source is a Spellman XRBD 160PN210 Monoblock X-Ray generator with a 0.5 mm focal spot. The beam fan angle is 90 x 12 degrees which is distanced approximately 36 cm from the source. The detector is a Hamamatsu C12300-321 composed of a CCD sensor with a ~22 cm field of view utilizing time-delayed integration (TDI) and a resolution of 48 microns per pixel. (Add the corresponding documentation on Confluence: Hamamatsu manual, Spellman XRB)

The shielding consists of several complimentary designs. The primary shield (Figure 1) houses the X-Ray source and detector. It is constructed of 3D-printed ABS plastic with hollow walls that are filled with Tungsten powder. The base of the primary shield (under the detector) is a solid piece of 1-cm thick Tungsten plate to block the primary X-Ray beam. X-Ray scatter is shielded by 2mm lead equivalent leaded vinyl or leaded acrylic panels on the sides, ends, top and bottom of the logger (Figure 2). The leaded acrylic provides a view of the inside of the logger while it operates. The hatches that allow insertion of core material on either end of the logger are also shielded with solid Tungsten plates.

Figure Figure 1: Primary shield top and bottom halves, the latter shows the tungsten powder filling and solid tungsten plate used in the first design of the XSCAN.

Figure 2: Leaded acrylic and leaded vinyl shielding panels

The XSCAN imager has multiple safety systems in place to ensure a user does not operate the system in a radiologically unsafe manner. Never attempt to operate the X-Ray source without the proper shielding in place! The safety subsystems include:

X-rays ON amber lights on two corners (Figure 3) Note an extra X-rays On amber light is mounted on the aft of the Xscan and indicates when the xrays are on for the spare source.
Colored light status indicators (AKA Patlite tower) (Figure 5)
X-rays ON amber lights on two corners (Figure 3)
Shutter position sensors
Door electronic locks (Figure 6)
X-ray source interlock
Emergency Stop Switch (motion and X-ray abort) (Figure 7)
X-rays auto-off after a user-selectable period

These components are wired into one fail safe system controlled by a National Instruments cRIO-9053 unit.

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Figure 3: X-Ray emitting lights (lit=ON) on two corners of the XSCAN

In order to generate X-Rays, a series of safety switches and shutter positions must be verified to enable the generation of X-Rays. Certain switches or sensors are operated electrically, others use pneumatics.

Figure 4 shows the failsafe circuit and the safety switches involved. All switches must be verified before the software command to generate X-Rays will be performed.

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Figure 4: Fail safe circuit schematic.

A multi-color tower light mounted horizontally on the top corner of the logger acts as a visual indicator of the safety system and X-Ray status. It has four segments that reflect specific safety subsystems of the logger plus one for the measurement phase at the time (Figure 5).

X-Ray source:
- Amber: source is in use, X-Rays are emitted
- Green: source is ON, but there is no X-ray emission
- Light OFF: source is OFF
Shutter light indicator:
- Amber: shutter is open
- Green: shutter is closed – safe to open doors
- Light OFF: shutter is disabled
Door light indicators:
- Amber: doors are latched and/or unsafe to open
- Green: doors are unlatched, safe to open
IMS measurement operations status colors:
- Purple – initialized
- Green – idle
- Blue – translational move of the camera
- Sky blue – rotational move of the camera
- Amber – image in progress
- Off – quit IMS software is not open

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Figure 5: Multi-section Patlite tower mounted horizontally at the top of the logger.

These lights act as visual indicators of measurement operations, door(s), and X-Ray status.

The Table 1 below illustrates the status combinations:

Scenario	X-Ray source	Shutter/E-stop	Forward (FWD) Door	Aft Door	IMS Status
Subsystems powered, doors unlatched, IMS off	Off	Green	Green	Green	Off
IMS at idle, doors unlatched, shutter closed	Green	Green	Green	Green	Purple
Latch doors via IMS menu	Green	Green	Amber	Amber	Purple
Open shutter via IMS menu	Off?	Amber	Green	Green	Purple
X-rays ON, shutter closed, doors unlatched	Amber	Green	Green	Green	Purple
During imaging	Amber	Amber	Amber	Amber	Purple, then Blue at end

Table 1. Different Patlite status indicator combinations

Electronically-controlled safety locks have been installed on both the forward and aft doors. If either of these doors are open at the beginning of imaging, calibration or seasoning the c-RIO will disallow the process and warn the user about it. There are also indicator lights on the door lock electronics (Figure 6). Note that a lit red indicator means that the door is unlocked and can be opened. These switches are always energized and therefore are usually warm to the touch, but this is not an issue.

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Figure 6: Electronic safety lock on the logger door

There are two main Emergency Stop switches installed on the XSCAN, one for each source.

Main (in use) source (name or reference number S/N: 135769488-A00001)

An emergency stop (e-stop) switch is located on the front port side of the XSCAN along the top rail (Figure 7). When activated, i.e., the user hits the button, the e-stop switch cuts two circuits. One circuit runs straight to the source power supply and one circuit runs through the cRIO with the safety circuit. The e-stop switch opens the interlock on the XRB and the X rays go OFF. It also kills the MDrive and will immediately stop all motion.picture here of Figure 7

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Figure 7: X-ray logger Emergency Shut Off Switch.

{replace with image of final XSCAN placement if different}

Spare source (name or reference numberS/N: 132614727-A00001)

The e-emergency stop for the spare source is located near the spare source at on aft end, starboard side near the bottom of the XSCAN Image Removedthe XSCAN. This switch cuts the power circuit to the spare source when pressed.

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Figure 8: Emergency Shut Off Switch of the spare source

The detector (camera) on the XSCAN logger can run warm when it is on. AdditionallyAdditionally, the X-Ray source adds heat while producing X-rays: due to the low efficiency of the X-ray tube, most of the power it uses will be expended as heat. Optimally the camera should be operated at temperatures less than 40°C. The IMS software continuously monitors the camera and X-ray source temperatures and displays them on the main acquisition screen (Figure 9). Cooling modifications such as two air conditioners on the cabinet portion of the logger as well as and directed fans on the camera itself help to keep things cool during operations. However, it may happen that the temperature increases because of fan failure for instance. If the camera temperature exceeds 40°C, the temperature diagram (Figure 9) will flash. The user must stop using the instrument to allow the camera to cool down before resuming scanning. Note the AC units are connected to a drain and container that must be emptied periodically.

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Figure 9: IMS temperature monitor sub-window for the source and the camera

Source temperature: A graphical temperature display is provided to monitor the temperature of the X-ray source. The source is usually at room temperature or below 30°C.
Camera temperature: A graphical temperature display is provided to monitor the temperature of the camera. The manufacturer recommends that the camera temperature should not exceed 40°C.

The cRIO switch is always on, unless troubleshooting the instrument requires the cRIO to be reset. All other switches are off when the XSCAN is off.

If the XSCAN is completely shut down, a series of switches must be activated for the instrument to operate properly. The switches are located on two surge protector panels below the shielded cabinet (Figure 10). The top panel involves equipment running through ship’s power, and the lower panel handles equipment connected to a UPS. They should be turned on in the following order:

Lower Switches (connected to a UPS):

cRIO and Excelsys power supply
X Ray Source & Camera: to turn on the main X-Ray source and the camera
Patlite safety status lights
cRIO and Excelsys power supply

Upper Switches (connected to ship’s power):

M-drive 23 and 34
Power switch for the spare X-ray source (optional)
Power for the spare source’s safety light
AFT A/C*: to turn on the aft piezo air conditioner
FWD A/C*: to turn on the forward piezo air conditioner
Cab lite = Cabinet light: to turn on the cabinet light (optional)

*Only one A/C is required to be on in most situations. If the lab is warmer or if the XSCAN seems to be heating up, the second unit can be turned on.

Note: The computer and its monitors are plugged directly into the UPS. The computer must be Note: The computer and its monitors are plugged directly into the UPS. The computer must be powered down via Windows or the computer’s power button.

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Figure 10: Switch

board

board

The IMS XSCAN software can be launched from the desktop icon (Figure 11). Before launching the IMS software, make sure that all Patlite sectors (except the one for IMS) are green. If IMS is launched before the instrument is fully on, it may generate communication issues between the IMS software and the cRIO safety system.put new icon here

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Figure 11: XSCAN Desktop Icon

At launch, the program begins the following initialization process:

Testing instrument communications (camera, X-ray source)
Homing the rotational actuator
Homing the linear actuator
Verify connectivity with the c-RIO safety system

After successful initialization, the main IMS-XSCAN window will appear (Figure 12).

If the computer has been restarted, the software will typically give a W-axis error when first opened. Close IMS and reopen the program and this error will clear itself.

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Figure 12: XSCAN IMS Main Window

IMS is a modular program. Individual modules are as follows:

INST plug-in: code for each of the instruments (source and detector)
MOTION plug-in: code for the motion control system
DAQ Engine: code that organizes INST and MOTION plug-ins into a track system

The XSCAN system, specifically, is built with one INST module (I_PI_Hama), one MOTION module (M_PI_M-Drive), and one DAQ Engine module (DAQ_PI_XSCAN).

The IMS Main User Interface (IMS-UI) calls these modules, instructs them to initialize, and provides a user interface to their functionality.

Each module manages a configuration file that opens the IMS program at the same state it was when previously closed and provides utilities for the user to edit or modify the configuration data and calibration routines.

The four buttons on the IMS-UI window provide access to utilities/editors via dropdown menus as shown in Figure in Figure 13.

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Figure 13: IMS Control Panel Drop down Menus

XSCAN Configuration

Configuration values should be set during initial setup and configuration by the technician or scientist(s). There should be no need to change these values unless the configuration file is corrupted or the hardware setup is changed. The logger will provide some default values automatically if the configuration file is missing or unreadable at startup.

To open the XSCAN instrument setup window (Figure 14), select Instruments > Camera: General Setup from the IMS panel menu (Figure 13). This window displays information about the source and camera hardware, primarily for metadata recording. The Table 2 below gives a description of the different settings. These settings are hard coded and cannot be changed by the user.

Name	Description	Meaning
True Pixel Pitch (μ)	Pixel pitch on the detector	48 µm for C12300-321
SID mm	Distance in mm from the focal spot on the source to the detector’s surface	Used to calculate magnification and blur
SOD mm	Distance in mm from the focal spot to the average height of a SHLF surface or the midplane of a WRND core	Used to calculate magnification and blur
OID mm	Distance in mm from the section half plane or WRND midplane to the detector surface	= SID - SOD
Magnification	Calculated magnification factor	= SID/SOD
Apparent Pixel Pitch (µ)	Pixel pitch corrected for magnification	= SOD/SID x true pixel pitch
Focal Spot Diameter mm	Diameter of the X-ray source’s focal spot in mm	0.5 mm for Spellman XRB
Unsharp Blur mm	Blurring in images are a result of focal spot size and system geometry	= OID/SOD x focal spot diameter
Scale Across px/cm	Across-core scaling	222.2 px/cm on split-core plane
Scale Along px/cm	Down-core scaling	254.1 px/cm on split-core plane

Table 2. XSCAN camera parameters

The shutter should be enabled and the air pressure should be selected for safety reasons: both buttons should be YES (Figure 14).

The user can set the time limit for the X-ray Auto off, i.e., the number of minutes when the X-rays will automatically be ramped down after the instrument is in the idle state with no action from the user. It is recommended to set a time of 15 min.

Click Accept to save the changes and write them to the configuration file. Click Cancel to revert to previous values.

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Figure 14: XSCAN Parameters Window

Prior to collecting X-Ray radiographs on whole rounds or section halves in the XSCAN, the user must set the imaging X-ray power (voltage and current). These are set during the calibration process.

kV: X-ray tube voltage. Maximum voltage for the source is 160 kV, minimum voltage is 35 kV. Lowering the voltage while maintaining the number of X-rays penetrating the core (longer exposure or higher current) will increase image contrast.
mA: X-ray tube current. The maximum allowable current is 2.1 mA. Maximum power for the source is 210 watts. Therefore, the source is either voltage limited or current limited as seen in Table 3 below. Increasing the current will increase contrast if voltage is kept constant.

Voltage (

kV

kVp)	Max Current (mA)	Wattage (calculated)	Power State
160	1.31	210	Voltage-limited
150	1.40	210
140	1.50	210
130	1.62	210
120	1.75	210
110	1.91	210
100	2.10	210	Current-limited
90	2.10	189
80	2.10	168
70	2.10	147
60	2.10	126
50	2.10	105
40	2.10	84

Table 3. X-ray source power ranges

Detector calibration should be done at the beginning of the expedition or whenever the power settings are changed. It is a quick and easy process to do.

To calibrate the detector, select Instruments> Camera: Calibrate from the main IMS menu (Figure 13). The calibration utility window will open(Figure 15). The purpose of this utility is to collect White and Dark images that will be used to perform offset and gain corrections for all images acquired with the camera at given power settings.

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Figure 15: Detector Calibration user interface window. From this utility a user takes the Dark and White correction measurements after setting the track speed, which dictates the camera’s exposure.

Step 0: Make sure the bore is empty and clean before starting a calibration.

Step 1: Dark Image Correction

The DARK image is normally made with the X-rays off to capture the electrical background noise of the detector (Figure 16, A). Click

To capture the dark image:

Click the Grab button (Figure 16, B) to take twenty Dark grabs, numbered 0 to 19. The “Current Grab Stacked” sub window will display the resulting dark grabs with its characteristic striping (Figure 16, C-1). When it is done, the “DARK Measured” indicator becomes green (Figure 16, C-2).

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Figure 16: Taking the Dark correction image. Note the small DARK Measured LED is lit in the lower right corner.

Step 2: White Image Calibration

The WHITE image is taken with the X-rays on and the shutter open. We simulate motion by using the exposure of the camera since everything is stationary (this detector has no internal shutter). You can change Changing the track speed which then updates will also update the exposure settings (Figure 17, A). The number of scans is automatically calculated from the chosen speed and exposure.

The WHITE image is used for the gain correction after the offset correction from the dark image is completed.

To capture the WHITE image:

Click “Update X-Ray” (Figure 17, B). A window will open (Figure 18).
Enter the desired power settings (Figure 18, A), and click “Apply Values” (Figure 18, B).

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Figure 17: Taking the White Image Calibration. Note the small WHITE Measured LED is lit in the lower right corner.

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Figure 18: Modifying X-ray power settings

2. Turn on the X-rays by toggling the X-rays ON button (Figure 17, C-1). The source will ramp up to power (Figure 19).

3. Open the shutter (toggle the Shutter button, Figure 17, C-2), then again click the Grab toggle as you did for the dark image

4. Click the Grab button (Figure 17, D). The WHITE Measured LED will light up (Figure 17, E-2) when the grabs finish. The “Current Grab Stacked” sub window will display the resulting white grabs with its characteristic white to grey pattern (Figure 17, E-1). The grey outside edges are the tube.

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Figure 19: X-Rays ramping up for white calibration

5. Once acquisition is completed (Figure 17, E-1), check the saturation value (Figure 17, F) and confirm that it saturation percentage is in the target range of 94-98%. To get more exposure within the image, the saturation values can be higher (100%). This will clip the data, but can produce a better image in denser materials. Adjust the exposure values (Figure 17, A) and repeat until user is satisfied.

6. Adjust the If not, adjust the exposure values (Figure 17, A) and repeat. Adjust the position of the blue left-hand mask bar if needed; this will be rare. XSCAN uses masking to eliminate the bore walls from our images. By default the mask width is set to 1600 pixels.

7. When you are satisfied with everything then click the Accept Changes button (Figure 17, G). This saves the calibration information to memory and to the configuration file.

Prior to imaging cores, especially at the start of an expedition, the user must perform a detector white-dark calibration at the chosen power settings (see Detector Calibration Section). Once this step is complete, the user may begin imaging.

To take images, the user selects the Start button on the IMS main panel (Figure 13) to open the sample information window Slide the bottom of the section fully into the bore of the logger (Figure 20). The top of a section should face This is where the user . If imaging section halves, ensure that the surface of the core is level, i.e., horizontal while inserting the section.

If imaging whole round sections, ensure that the double lines are facing up. This ensures that the XSCAN rotation angle matches that of the IODP orientation frame.

Proper insertion depth is attained by pushing with the base of the core extraction tool until the shoulder of the stop hits the side of the bore.

The tool can also be used to rotate the section half to be normal to the X-ray beam.

The fork end of the tool is used to retrieve sections. Insert the fork until you feel it touch the end of the section. A brisk short motion will pop the tines of the fork over the end cap and allow you to pull the section back towards you. If repeated attempts are not successful, rotate the fork 180° and try again.

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Figure 20: Positioning a section inside the XSCAN

Click START on the IMS main panel (Figure 13) to open the sample information window (Figure 21). This is where the user enters the imaging method and the sample ID for a section and initiates the measurement.

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Figure 21: Section Information Window (default display)

It is possible to measure either section halves or whole round sections. Select “SHLF-A” or “SHLF-W” in the Section Type box for sections halves, and “SECTION” for WRND measurements. The available presets for the selected sample type on the left are highlighted/activated in light grey. The preset selected for the scan is highlighted in green (Figure 21, A).

Definition of the presets:

For Archive and Working halves

enters the imaging method and the sample ID for a section and initiates the measurement.

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Figure 20: Section Information Window (default display)

It is possible to measure either section halves or whole round sections. Select “SHLF-A” or “SHLF-W” in the Section Type box for sections halves, and “SECT” for WRND measurements. The selection will determine which imaging method presets are active. The available presets for the selected sample type on the left are highlighted/activated in light grey. The preset selected for the scan is highlighted in green (Figure 20, A). Note that this selection will affect how the sample id information is parsed and displayed when the user scans or selects a sample from LIMS.

Definition of the presets:

For Archive and Working halves

-Section half: only: Basic X-ray imaging of a full or partial section (angle is 0 degrees, camera is perpendicular to the section’s split surface)

-Section half: thickness: X-ray imaging of a full or partial section at 0 and 90 degrees to estimate the thickness of a section half.

-Section half: CT: the user can do multiple consecutive scans of a section at different evenly spaced angles without cropping the image between scans. It is possible to do CT-like imaging at angles from 0 to 180 degrees, with an angle step as low as 1 degree.

-Section half: custom: The user can do multiple consecutive scans of a section at evenly spaced angles. The user must crop the scanned imaged between each scan.

For Whole Round sections

-Whole Round-Section half: only: Basic X-ray imaging of a full or partial section (angle is 0 degrees, camera is perpendicular to the section’s split surface)

-Section half: thicknessWhole Round: 0-90: X-ray imaging of a full or partial section at 0 and 90 degrees to estimate the thickness of a section half.

- Section halfWhole Round: CT: the the user can do multiple consecutive scans of a same section at different angles evenly spaced angles without cropping the image between scans. It is possible to do CT-like imaging at angles from 0 to 180 degrees, with an angle step as low as 1 degree.

- Section halfWhole Round: custom. : The user can do multiple consecutive scans of a same section at evenly spaced desired angles and crops the scanned imaged between scans.

For Whole Round sections

- Whole Round: only. Basic X-ray imaging of a full or partial section (angle is 0 degrees)

-Whole Round: 0-90. X-ray imaging of a full or partial section at 0 and 90 degrees.

- Whole Round: CT. the user can do multiple consecutive scans of a same section at different angles evenly spaced without cropping the image between scans. It is possible to do CT-like imaging at angles from 0 to 180 degrees, with an angle step as low as 1 degree.

- Whole Round: custom. The user can do multiple consecutive scans of a same section at evenly spaced desired angles and crops the scanned imaged between scans.

There are three tabs available on the sample information screen
Sample Entry Tabs
There are three tabs available on the sample information screen (Figure 20, B). Each provides a different method for entering the sample ID information (Figure 21).
Scanner: Scan the IODP barcode to enter the sample’s Text ID and Label ID values, using either a barcode gun or the barcode camera by the loading door (Figure 21, A).
LIMS: Select expedition, site, hole, core, and section values from a series of list boxes that are populated with data from the LIMS database (Figure 21, B).
Each provides a different method for entering the sample ID information (Figure 22).
Manual: Manually Scanner: Scan the IODP barcode to enter the sample’s Text ID and Label ID values , using either a barcode gun or the barcode camera by the loading door (Figure 22, A).
LIMS: Select expedition, site, hole, core, and section values from a series of list boxes that are populated with data from the LIMS database (Figure 22, B).
Manual: Manually enter the sample’s Text ID and Label ID values and a length (Figure 22, C). The name fields will accept any name, but that does not guarantee the and a length (Figure 21, C). The name fields will accept any name, but that does not guarantee the data will upload. The user must be careful to enter the name properly. If the name is incorrect files will be created, but it may not upload properly. The Text ID information must match an actual section in order for the data to upload. Click USE ME to update and validate the entries and enable the SCAN button.
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Figure
22
21: Sample Information Window – A. Scanner (barcode gun or barcode camera) entry, B. LIMS entry, and C. Manual Entry
Scanned Interval Length
It is possible to scan either a full section or a portion of it.
The user can select the desired scan length by clicking on the ROI/FULL SECTION button on the right (Figure 2120, C). Full Select full section will be used to scan a section over its entire length (i.e., LIMS length). A user can scan a specific region of interest (ROI, which stands for Region of Interest, will be selected to set an interval (top/start and bottom/), by selecting the ROI option and setting the measurement interval in centimeters (start and end) to scan.
Taking X-Ray Images
Select START on the IMS panel (Figure 13) to open the sample information window (Figure 21).
Insert the section in the XSCAN (Figure 20)
Enter the Sample ID Information and Imaging method as described above (Figure 21)
Select SCAN (Figure 21, D)
The track reverses 0.5 cm from its home position. For the first scan after launching IMS the X-ray source will ramp up and a window with the X-ray source status will appear (Figure 23).
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Figure 23: Status window displays the progress of the X-ray source ramping up to the requested kV and mA settings.
Once the mA and kV are stable, the window will close, the shutter will open, and image acquisition will begin. The user may abort at any time by clicking the STOP/CANCEL button (Figure 24).
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Figure 24: Stop/cancel button during image acquisition.
The system will scan down the section until it reaches the end of the section or 150.0 cm*, whichever is greatest, at which time the shutter will close and the scanner will return to the home position. Then the loading door will unlock in preparation for removing and replacing the core for the next scan. Note that the X-ray source is still ON.
Positioning sections inside the XSCAN
Section position is important within the XSCAN unit. The unit is intended to only image sections up to 150 cm long.
Sections are loaded into the XSCAN by sliding the section into the aft door, bottom of the section first (Figure 22a). The top of a section should face the user, this is typically a blue end cap and where the label for the section will be. If imaging section halves, ensure that the surface of the core is level, i.e., horizontal while inserting the section. If imaging whole round sections, ensure that the double lines are facing up. This ensures that the XSCAN rotation angle matches that of the IODP orientation frame.
To position the section properly in the XSCAN imager, use the double ended core extraction tool (Figure 22a). Use the round flat end to push the section into the acrylic tube until the round stop contacts the outside edge of the XSCAN unit. The user must also be careful not to push sections to quickly into the XSCAN or they may slide further along the track than intended. The forked end of the extraction tool can also be used to rotate the section half to be normal to the X-ray beam if the section twists while being loaded.
Imaging sections longer than 150 cm
Sections longer than 150 cm require multiple images and adjustments to the sample positioning to capture the entire section. The user must first position the section as they would for sections under 150 cm and take an image. After the first image*Note: Logger design decisions dictated that the maximum length of core that can be imaged on this logger is 150.5 cm, to minimize the overall size of the instrument. If it is imperative that every centimeter of a section that is longer that this be imaged, the user must pull the section out back until the end cap top of the section is flush with the end of the bore and scan again to get the very bottom imaged. The images can be spliced together manually later if a single composite core image is desired.
Cropping and Processing an X-Ray image
When the imaging is complete, the image will flip around the +z downcore axis in the background to mimic the SHIL image. The user must then process and crop the image (Figure 25). Note that processing and cropping is not performed by the user when the imaging is done in CT mode.
Processing an X-ray image involves three steps:
Cropping the image to eliminate non core-material elements, e.g. core liner and white areas at the edges of the image
Selecting a method and degree of image manipulation to enhance features
Saving the image which produces its file for uploading to the database
The IMAGE Process & Crop window can be separated into 3 areas: on the left the X-ray histograms of the image acquisition, in the middle, the raw and processed images, and on the right the different options for processing and cropping (Figure 25).
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Figure 25. Utility window to crop, process and save an X-Ray image
Left (Figure 25, A):
Original Histogram: This histogram represents the X-Ray penetration for a section with the X-Ray counts (Y-axis) as a function of the number of X-ray transmitted (X-axis).
DIFF Histogram: This is the DIFFERENCE histogram. Each column of pixel values is averaged down the entire length of the image, and this average value is then subtracted from each pixel down the same column of the raw image, continued for every pixel column across the image. The yellow line indicates the Maximum or mean value of the resulting histogram depending on user selection.
Processed Histogram: this displays the effects of the user-selected level of histogram expansion on the slider to the right. Adjust the slider while observing both the changes to the processed histogram and the image itself in the Processed tab in the center of the screen.
When you are satisfied with the quality of the image then click the Save Image button.
Details are provided in the Processing the image section below.
Middle: four tabs showing different images (Figure 25, B and Figure 26)
Raw tab: This is the raw, dark and white corrected image after flip.
Processed tab: This is the resulting image after the processing performed by the user.
Mask tab: this is the mask of the image where all scanned material is shown in white.
Edges tab: Profile of the section edges detected using weighted intensities.
The green box represents the crop area and can be adjusted by the user using the settings on the right.
Image Removed
Figure 26. Raw and processed images, mask and calculated edges
Right: Options to process, crop and save (Figure 25, C)
The red asterisks are important options to consider for a good, processed crop. IMS will automatically process the raw image based on the parameters set by the user.
In this window, the user can choose an appropriate imaging process, crop, and save the images.
Selecting the crop area
To select a good crop area, the user can:
Adjust the Mask Threshold by moving the red line up/down within the graph. The shape of this curve is effectively an across-core profile of a WRND or section half. Thinner areas on the edges produce brighter pixels with higher values while the thick centers are darker. Many images will have “shoulders” that represent the core liner. We recommend keeping the threshold below these shoulders.
Choose the crop width by sliding the cursor: this defines the width of the green box in pixel. Recommended setting is between 1600 (default) and 1700 px.
The full image can be seen by sliding the bar on the right and by using the arrows for the top and bottom of the section. That way, the user can make sure that the full section is comprised within the green crop box.
When a crop is good, the crop status appears as “GOOD CROP”. If the crop is not good, the status appears as “TOO SHORT”, and the Crop button will become unavailable. The user must check the crop area and correct as necessary. If the crop area is good and the message is still there, the user needs to check the box “Override Crop Restrictions” to enable the Crop button.
If there is a void or missing part at the top of the scanned section, the user can force the crop area to be tight to the top of the section liner (endcap) by ticking the “Lock to top” box, so that the zero cm offset of the virtual ruler starts at the endcap and not at the top of the section material. Similarly, the user can force the crop area to be tight to the bottom of the liner by ticking the “Lock to bottom” box.
The “Un-crop & Init ROI” button is used to set the green box back to its original position. This can be repeated until the user is happy with the selected crop area.
Processing the image
The user can choose between four process methods: (i) by full core profile (most commonly used and recommended method), (ii) by smoothing, (iii) by synthetic half profile, and (iv) by synthetic whole-round profile.
Other processing options
Histogram expansion: The expansion of the processed histogram (displayed on the bottom left of the window) is adjusted by sliding the cursor on the bar between 1 for a sharp (narrow) histogram and 9 for a smooth (wide) histogram. This feature changes the shape of the processed on the right – a blue curve with an S-shape is preferred.
More details about the processing methodology are found in the Appendix.
Saving the images
When a user is satisfied with the crop area and the processed image, the user clicks “Crop”, and then “Save”. After saving the image, IMS will output a processed image with virtual ruler and label (file name_P.jpg), a processed cropped image (file name_C.jpg) without ruler and label, and a white-dark corrected raw TIF image with embedded metadata (file name_R.tiff) to the C:\data\in folder sorted by site and hole.
Turning the X-Rays OFF
For safety and to save the X-ray source from emitting when not in use, the user can turn off the X-ray source from the IMS main menu by sending the CAMERA: X-ray | Ramp Down command to the source, via the Instruments menu on the IMS main window (Figure 13). The X-rays will ramp down and eventually turn off.
Image Removed
Figure 27. X-ray status window (ramp down)
NOTE: During imaging, the user can use the software STOP/CANCEL button (Figure 24) to end the imaging process and ramp down the source.
In case of emergency, the X-Ray source can be immediately turn off by selecting Instruments > CAMERA: Off now ! If the software is unresponsive, then activate the hardware abort button to stop X-rays and motion (Figure 7).
X-Ray Auto Off
When the XSCAN is not in use for a certain time, the X-ray source will automatically shutdown after a time chosen by the user. Three options are available: 5, 10 or 15 min of inactivity. This can be selected in Instruments > CAMERA: General Setup (Figure 14).
ABORT a measurement sequence
At any time during a measurement (imaging, calibration, or seasoning), the user can stop/abort the sequence by using either IMS or the emergency hardware abort button.
The hard Abort button (emergency switch) is located near the loading door (Figure 7) {write here where the button(s) will be located, and refer to pictures at the beginning of the UG}. If itis used, the X-Rays will automatically shut down. During imaging, the camera will stop moving, the imaging will end, and the user will need to start imaging the section from the beginning.
After releasing the hard “Abort” button, it is not necessary to restart IMS. Starting a new scan or any other work will reset the error and move the camera to the Load/Home position.
Seasoning
Seasoning is to ensure a longer life for the X-Ray tube. The X-Ray sources, both main and spare, must be seasoned every week with the recommended daily seasoning type (1 to 7 days). Seasoning procedure can be activated in the IMS main menu Instruments > Camera: Season Tube.
More details about the Seasoning is found in the Appendix.
Motion Control Setup
Motion control should be set during initial setup and further changes should not be necessary. Motion control setup can be accessed by selecting Motion > Setup from the IMS panel menu (Figure 28). The M-Drive Motion Setup control panel will open (Figure 28).
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Figure 28. Motion Setup Menu from the IMS panel menu
The user may select between four setup panels from this window.
Motor and Track Options
Fixed Positions
Limit and Home Switches
Motion Profiles
Motor and Track Options Menu
Once these values have been properly set, they should not change. This panel is only for initial setup.
Make sure to use the values shown for the XSCAN (Figure 29).
The relationship between motor revolutions and linear motion of the track is defined in this window and is critical to both safe and accurate operation. User should be familiar with the M-Drive motor system prior to adjusting these settings.
X-axis (Figure 29A)
Select Axis: Select X for translational motion of the camera.
Encoder Pulses/rev: Defined by the manufacturer of the M-Drive as 2048.
Screw Pitch: Set to 4.0 (the ratio of 2048 steps per revolution and chain displacement (cm) as a function of the drive gears diameter).
Gear Ratio: Set to 2.0.
Direction: Clockwise rotation moves the tray in a positive direction (from home to end of track).
W-axis (Figure 29B)

Select Axis: Select W-axis for the rotational system of the XSCAN
Encoder Pulses/rev: Defined by the manufacturer of the M-Drive as 2048.
Screw Pitch: Set to 125
Gear Ratio: Set to 2.0.
Direction: Counter clockwise rotation moves the tray in a positive direction (from home to end of track).
Click Accept to save the values or Cancel to return to previous values.
Image Removed
Figure 29. XSCAN Motor and Track Options Setup Window for (A) the X-axis and (B) the W-axis
Fixed Positions Menu
Once these values have been properly set, they should not change. This panel is only for initial setup.
In this window the user may define fixed track locations used by IMS motion control. For the XSCAN, make sure to use these values unless there has been a physical change to the system (Figure 30).
X-axis (Figure 30A)
Select Axis: Select X for translational motion of the camera.
Max Section Length: Maximum length of section that can be placed in the track. This value is set to 150 cm.
Allowable Track Move: Distance in cm between the limit switches. Currently the value is set at 0 cm.
Load and Unload positions: For the XSCAN, these values are set to 0. This will always bring the tray back to the sample load end after a measurement sequence.
Top-of-SectionSwitch?: OFF
Top-of-Section Switch Offset: 0
Push Past: 0
Fast Past: 0
Run Out Switch?: OFF
W-axis (Figure 30B)
Select Axis:Select W-axis for the rotational system of the XSCAN
Load and Unload positions: For the XSCAN, these values are set to 0.
acrylic tube and take a second image.
Retrieving Sections from inside the XSCAN
The fork end of the double ended extraction tool is used to retrieve sections. Insert the fork until you feel it touch the end of the section. A brisk short motion will pop the tines of the fork over the end cap and allow you to pull the section back towards you. If repeated attempts are not successful, rotate the fork 180° and try again. When retrieving section halves, the fork often needs to be rotated from horizontal to properly connect the tines to the end cap.
Short sections can be easily loaded into the XSCAN unit, but can be difficult to retrieve using the typical extraction tool. It can also be difficult to retrieve cores with extender caps. The user may use the U-shaped extractor tool to scoop under or over the top of a section and pull it out (Figure 22b). A string tied to the section can also work well on small sections such as core catchers. Loop the string around the top of the core, tighten the loop, and put the knot under the core so the weight is on the string. When pulling the core out, gently pull the string. If none of these methods work, the user may push the section out from the forward end of the XSCAN.
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Figure 22a: Positioning a section inside the XSCAN
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Figure 22b: Using the U-shaped extractor

Entering Sample Information
Click START on the IMS main panel (Figure 13) to open the sample information window (Figure 23). This is where the user enters the imaging method and the sample ID for a section and initiates the measurement.
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Figure 23: Section Information Window (default display)
Imaging Method
It is possible to measure either section halves or whole round sections. Select “SHLF-A” or “SHLF-W” in the Section Type box for sections halves, and “SECTION” for WRND measurements. The available presets for the selected sample type on the left are highlighted/activated in light grey. The preset selected for the scan is highlighted in green (Figure 23, A).
Definition of the presets:
For Archive and Working halves
-Section half: only: Basic X-ray imaging of a full or partial section (angle is 0 degrees, camera is perpendicular to the section’s split surface)
-Section half: thickness: X-ray imaging of a full or partial section at 0 and 90 degrees to estimate the thickness of a section half.
- Section half: CT: the user can do multiple consecutive scans of a same section at different evenly spaced angles without cropping the image between scans. It is possible to do CT-like imaging at angles from 0 to 180 degrees, with an angle step as low as 1 degree.
- Section half: custom. The user can do multiple consecutive scans of a same section at evenly spaced desired angles and crops the scanned imaged between scans.
For Whole Round sections
- Whole Round: only. Basic X-ray imaging of a full or partial section (angle is 0 degrees)
-Whole Round: 0-90. X-ray imaging of a full or partial section at 0 and 90 degrees.
- Whole Round: CT. the user can do multiple consecutive scans of a same section at different angles evenly spaced without cropping the image between scans. It is possible to do CT-like imaging at angles from 0 to 180 degrees, with an angle step as low as 1 degree.
- Whole Round: custom. The user can do multiple consecutive scans of a same section at evenly spaced desired angles and crops the scanned imaged between scans.
Sample Entry Tabs
There are three tabs available on the sample information screen (Figure 23, B). Each provides a different method for entering the sample ID information (Figure 24).
Scanner: Scan the IODP barcode to enter the sample’s Text ID and Label ID values, using either a barcode gun or the barcode camera by the loading door (Figure 24).
LIMS: Select expedition, site, hole, core, and section values from a series of list boxes that are populated with data from the LIMS database (Figure 24, B).
Manual: Manually enter the sample’s Text ID and Label ID values and a length (Figure 24,C). The name fields will accept any name, but that does not guarantee the data will upload. The user must be careful to enter the name properly. If the name is incorrect files will be created, but it may not upload properly. The Text ID information must match an actual section in order for the data to upload. Click USE ME to update and validate the entries and enable the SCAN button.
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Figure 24: Sample Information Window – A. Scanner (barcode gun or barcode camera) entry, B. LIMS entry, and C. Manual Entry
Scanned Interval Length
It is possible to scan either a full section or a portion of a section using the ROI feature.
The user can select the desired scan length by clicking on the ROI/FULL SECTION button on the right (Figure 23, C). Full section will be used to scan a section over its entire length (i.e., LIMS length). ROI, which stands for Region of Interest, will be selected to set an interval (top/start and bottom/end) to scan.
Taking X-Ray Images
Select START on the IMS panel (Figure 13) to open the sample information window (Figure 23).
Insert the section in the XSCAN (Figure 22)
Enter the Sample ID Information and Imaging method as described above (Figure 24)
Select SCAN (Figure 23, D)
The track reverses 0.5 cm from its home position. For the first scan after launching IMS the X-ray source will ramp up and a window with the X-ray source status will appear (Figure 25).
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Figure 25: Status window displays the progress of the X-ray source ramping up to the requested kV and mA settings.
Once the mA and kV are stable, the window will close, the shutter will open, and image acquisition will begin. The user may abort at any time by clicking the STOP/CANCEL button (Figure 26).
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Figure 26: Stop/cancel button during image acquisition.
The system will scan down the section until it reaches the end of the section or 150.0 cm*, whichever is greatest, at which time the shutter will close and the scanner will return to the home position. Then the loading door will unlock in preparation for removing and replacing the core for the next scan. Note that the X-ray source is still ON.
*Note: Logger design decisions dictated that the maximum length of core that can be imaged on this logger is 150.5 cm, to minimize the overall size of the instrument. If it is imperative that every centimeter of a section that is longer that this be imaged, the user must pull the section out until the end cap is flush with the end of the bore and scan again to get the very bottom imaged. The images can be spliced together manually later if a single composite core image is desired.
Cropping and Processing an X-Ray image
When the imaging is complete, the image will flip around the +z downcore axis in the background to mimic the SHIL image. The user must then process and crop the image (Figure 27). Note that processing and cropping is not performed by the user when the imaging is done in CT mode.
Processing an X-ray image involves three steps:
Cropping the image to eliminate non core-material elements, e.g. core liner and white areas at the edges of the image
Selecting a method and degree of image manipulation to enhance features
Saving the image which produces its file for uploading to the database
The IMAGE Process & Crop window can be separated into 3 areas: on the left the X-ray histograms of the image acquisition, in the middle, the raw and processed images, and on the right the different options for processing and cropping (Figure 27).
Image AddedFigure 27: Utility window to crop, process and save an X-Ray image

Left panel (Figure 27, A):
Original Histogram: This histogram represents the X-Ray penetration for a section with the X-Ray counts (Y-axis) as a function of the number of X-ray transmitted (X-axis).
DIFF Histogram: This is the DIFFERENCE histogram. Each column of pixel values is averaged down the entire length of the image, and this average value is then subtracted from each pixel down the same column of the raw image, continued for every pixel column across the image. The yellow line indicates the Maximum or mean value of the resulting histogram depending on user selection.
Processed Histogram: this displays the effects of the user-selected level of histogram expansion on the slider to the right. Adjust the slider while observing both the changes to the processed histogram and the image itself in the Processed tab in the center of the screen.
When you are satisfied with the quality of the image then click the Save Image button.
Details are provided in the Processing the image section below.
Middle panel: four tabs showing different images (Figure 27, B and Figure 28)
Raw tab: This is the raw, dark and white corrected image after flip.
Processed tab: This is the resulting image after the processing performed by the user.
Mask tab: this is the mask of the image where all scanned material is shown in white.
Edges tab: Profile of the section edges detected using weighted intensities.
The green box represents the crop area and can be adjusted by the user using the settings on the right.
Image Added
Figure 28: Raw and processed images, mask and calculated edges
Right panel: Options to process, crop and save (Figure 26, C)
The red asterisks are important options to consider for a good, processed crop. IMS will automatically process the raw image based on the parameters set by the user. In this window, the user can choose an appropriate imaging process, crop, and save the images.
It the user is not happy with the image, the user can redo the imaging by clicking Discard Image. A pop-up window will ask confirmation to the user.
Selecting the crop area
To select a good crop area, the user can:
Adjust the Mask Threshold by moving the red line up/down within the graph. The shape of this curve is effectively an across-core profile of a WRND or section half. Thinner areas on the edges produce brighter pixels with higher values while the thick centers are darker. Many images will have “shoulders” that represent the core liner. We recommend keeping the threshold below these shoulders.
It is equally important to select a good across-core profile through the section, as the default profile is the first one imaged by the camera. To find a good across-core profile, one might slide the Profile Line Position slide bar.
Choose the Crop Width by sliding the cursor: this defines the width of the green box in pixel. Recommended setting is between 1600 (default) and 1700 px.
The full image can be seen by sliding the bar on the right and by using the arrows for the top and bottom of the section. That way, the user can make sure that the full section is comprised within the green crop box. If the user does not want to verify the processed image or wants to save time in the cropping, it is possible to halt processing by ticking the Suspend Process box.
When a crop is good, the crop status appears as “GOOD CROP”. If the crop is not good, the status appears as “TOO SHORT”, and the Crop button will become unavailable. The user must check the crop area and correct as necessary. If the crop area is good and the message is still there, the user needs to check the box Override Crop Restrictions to enable the Crop button.
If there is a void or missing part at the top of the scanned section, the user can force the crop area to be tight to the top of the section liner (endcap) by ticking the Lock to top box, so that the zero cm offset of the virtual ruler starts at the endcap and not at the top of the section material. Similarly, the user can force the crop area to be tight to the bottom of the liner by ticking the Lock to bottom box.
The user can choose to save the mask parameters for the next images by ticking the Save Mask box.
The Un-crop & Init ROI button is used to set the green box back to its original position. This can be repeated until the user is happy with the selected crop area.
Processing the image
The user can either choose to process the image after acquisition or not. If the user wants to process the image and save it, the user has to tick the Save Process Image box (i.e., yes). If the box is not ticked (i.e., no), only the raw image (.tif) will be saved and uploaded to LIMS.
For processing an image, the user can choose between four process methods: (i) by full core profile (most commonly used and recommended method), (ii) by smoothing, (iii) by synthetic half profile (not fully ready at the time of X399), and (iv) by synthetic whole-round profile (not fully ready at the time of X399).
Other processing options
Histogram expansion: The expansion of the processed histogram (displayed on the bottom left of the window) is adjusted by sliding the cursor on the bar between 1 for a sharp (narrow) histogram and 9 for a smooth (wide) histogram. This feature changes the shape of the processed on the right – a blue curve with an S-shape is preferred.
More details about the processing methodology are found in the Appendix.
Saving the images
When a user is satisfied with the crop area and if the case, the processed image, the user clicks “Crop”, and then “Save Image”. "Save Image" is not available until cropping is made. After saving and processing the image, IMS will output three images: a processed image with virtual ruler and label (file name_P.jpg), a processed cropped image (file name_C.jpg) without ruler and label, and a white-dark corrected raw TIF image with embedded metadata (file name_R.tif) to the C:\DATA\IN folder sorted by site and hole. If the user has chosen to save the raw image only without processing, only the .tif image (file name_R.tif) will be uploaded to LIMS.
If sample information was added manually the images will appear in C:\DATA\IN\OTHER.
Turning the X-Rays OFF
For safety and to save the X-ray source from emitting when not in use, the user can turn off the X-ray source from the IMS main menu by sending the CAMERA: X-ray | Ramp Down command to the source, via the Instruments menu on the IMS main window (Figure 13). The X-rays will ramp down and eventually turn off.
Image Added
Figure 29: X-ray status window (ramp down)

NOTE: During imaging, the user can use the software STOP/CANCEL button (Figure 26) to end the imaging process and ramp down the source.
In case of emergency, the X-Ray source can be immediately turn off by selecting Instruments > CAMERA: Off now ! If the software is unresponsive, then activate the hardware abort button to stop X-rays and motion (Figure 7).
X-Ray Auto Off
When the XSCAN is not in use for a certain time, the X-ray source will automatically shutdown after a time chosen by the user. Three options are available: 5, 10 or 15 min of inactivity. This can be selected in Instruments > CAMERA: General Setup (Figure 14).
ABORT a measurement sequence
At any time during a measurement (imaging, calibration, or seasoning), the user can stop/abort the sequence by using either IMS or the emergency hardware abort button.
The hard Abort button (Emergency Switch) is located on the front panel of the XSCAN (Figure 7). If itis used, the X-Rays will automatically shut down. During imaging, the camera will stop moving, the imaging will end, and the user will need to start imaging the section from the beginning.
After releasing the hard Emergency Switch button, it is not necessary to restart IMS. Starting a new scan or any other work will reset the error and move the camera to the Load/Home position.
Seasoning
Seasoning is to ensure a longer life for the X-Ray tube. The X-Ray sources, both main and spare, must be seasoned every week with the recommended daily seasoning type (1 to 7 days). Seasoning procedure can be activated in the IMS main menu Instruments > Camera: Season Tube. Please fill in the Confluence logsheet XSCAN Sources Seasoning for a record of the seasoning conducted.
More details about the Seasoning is found in the Appendix below.

III. Uploading Data to LIMS
File Formats and File Saving
A text file with extension .XSCAN contains information regarding the settings used is generated and automatically saved in the C:\DATA\IN folder.
This file contains the paths to each image file (one or three paths) and the calibration file (Figure 30).
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Figure 30: Path directories for images and calibration file to be uploaded to LIMS
IMS automatically outputs the raw (one image) with, if the case, the two processed images. One or three images are saved: the two processed are .jpg (corrected, cropped and processed images, respectively) and a raw .tif image.
Examples of file names:
Raw file name (.tif):
385-U1545A-3H-4-A_SHLF10354871_0000_deg_20230124132738_R.tif
Cropped file name (.jpg):
385-U1545A-3H-4-A_SHLF10354871_0000_deg_20230110125632_C.jpg
Processed file name:
385-U1545A-3H-4-A_SHLF10354871_0000_deg_20230130154107_P.jpg
Image File location: C:\DATA\IN\SiteHole (e.g., C:\Data\In\U1601A) for regular scans. Scans performed at different view angles are found in C:\DATA\IN\SiteHole\Section Rotary (e.g., C:\DATA\IN\U1385F\2X-1 Rotary). CT-style scans are found inC:\DATA\IN\SiteHole\SiteHole CT(e.g., C:\DATA\IN\U1601A\U1601A CT)
Calibration Data (Dark and White): C:\IMS\CONFIG_XSCAN\I_PI_HAMA.ini
Note: this calibration data is also contained in every MUT load file.
A unique time stamp is appended to each image.
File Uploading to LIMS
Open the MUT2 application (Figure 30) and select "X-Ray Imaging" as analysis.
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Figure 31: MUT2 application icon
Load files are text files with the extension .XSCAN. In order to successfully upload data, all image and configuration files must be at path listed in the text file. The uploader, MegaUploadaTron2, parses the information from the .XSCAN file and links the images. They are used by the MUT2 application to load acquired data and images into LIMS. Correct files appear with a green tick on MUT2 (Figure 32) and MUT2 will process them and then move them to the C:\DATA\archive folder.
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Figure 32: Uploading files to LIMS with MUT2
The files uploaded by LIMS are found in C:\DATA\IN as Exp-SiteHole-Core-Section-Type-Timestamp.XSCAN (e.g., 399-U1601A-6R-1-W_20230421043105.XSCAN).
Any file that fails to upload is moved to the C:\DATA\error folder.
All XSCAN line scan images are saved as a single set of files and once uploaded can be found in the LORE report under Images > X-ray Images (XSCAN). CT images are not uploaded to the database at this time. Any CT images collected need to be transferred to Data1.

IMPORTANT NOTE: When the images are uploaded to LIMS AND saved on Data1, make sure to delete at the end of the expedition all the images acquired during the expedition from the XSCAN workstation. Keeping big images on this computer will cause a full memory and prevent future image saving.
Displaying the images with LIVE
XSCAN images can be viewed in LIVE templates as thumbnails. A couple of points need to be kept in mind:
For section with a WRND sample taken at the bottom, i.e., section with a yellow end cap, the user must select the "ROI" feature of IMS in the Sample Information Window and set the top and bottom offset of the section scanned. For instance, a section curated at 150 cm (LIMS length) with a WRND sample taken at the bottom (for instance a 5 cm long IW sample) must be entered in the Sample Information Window with "ROI-Custom", start at 0 cm and end at 145 cm. The XSCAN image will then match the SHIL image. Failure to do so will result in a stretched thumbnail image in LIVE (Figure 33). That happens when the default feature "full section" is selected in the Sample Information Window. This can be fixed by editing the .XSCAN file by changing the bottom offset and changing the position specified line to TRUE.
Image AddedFigure 33. Display of XSCAN image in LIVE for section with a WRND taken at the bottom - "full section" on the left and "ROI" on the right
If there are several images taken for one section (for instance, full core and ROI), the last image taken (i.e., the last image uploaded by MUT) will be displayed in LIVE. This is because whenever a second (or more) image is uploaded for a sample, the new image is set with the "display flag" set to true, and all others have it set to false. The display flag controls what will be shown in LIVE and some other apps. LIME can be used to set the display flag to one of the older images. Scientists must ask a technician to change the display flag in LIME.
In LIME (Figure 34), select Test > Edit Display Image. Enter the TEXT ID in the box and select XSCAN - X-Ray images for the analysis. Select the section and click Display. In the pop-up window, all images taken for the selected section will be listed. Select the image to be shown in LIVE (based on the Test number) and click Update. In LIVE, refresh the page to display the desired image.
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Figure 34. How to modify a display flag in LIME
IV. Appendix
A.1. Health, Safety and Environment
Safety
Keep extraneous items and body parts away from the moving platform, belt, and motor.
The scanner has a well-marked emergency stop button to halt the system if needed.
Don't insert your hand between the source and the detector, and near the spare source when seasoning is ongoing.
Do not attempt to work on the system while a measurement is in progress.
Do not lean over the scanner.
Do not stack anything inside the scanner.
This analytical system does not require personal protective equipment.

XSCAN Safety Systems and Logic
Power will be keyed locked
Primary Beam will be shuttered (failsafe)
Access Hatches will be latched during operations
Maintenance access panels will be interlocked
Shutter will close on loss of power, interlocks are open or emergency stop engaged
Shutter can be open only when access hatches are closed and latched
Hatches will be unlocked when shutter is closed

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Pollution Prevention
This procedure does not generate heat or gases and requires no containment equipment.
A.2. Maintenance
Seasoning
After initial installation and/or after periods of idle time (idle time is defined as X-ray production unused), the manufacturer of the X-ray source used in the XSCAN recommends warm-up schedules to ensure proper operation for the X-ray Tube. Disregarding this may cause irreversible damage to the X-ray tube and/or decrease its life expectancy.
{from Spellman website} Typically seasoning is done after initial installation and after periods of idle time. This would include a profile for daily seasoning and longer profiles for increased idle time. The seasoning procedure carefully raises the tube current and voltage to reduce any residual gas in the X-ray tube before the tube is operated at full output. Seasoning also minimizes un-even distribution of potential/electric field on the tube glass. Following the recommended seasoning schedule will help prolong the life of the X-ray tube and prevent tube arcing that can potentially cause irreversible damage to the X-ray tube.
The X-Ray sources, both main and spare, must be seasoned every week with the recommended daily seasoning type (1 to 7 days). Seasoning procedure can be activated in the IMS main menuInstruments > Camera: Season Tube. Please fill in the Confluence logsheet XSCAN Sources Seasoning for a record of the seasoning conducted.
Alternatively, the IMS software, when launched, will tell the user to proceed to seasoning whenever necessary by showing the window on Figure A1.
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Figure A1. IMS asking to perform the required weekly seasoning
X-Ray source can be seasoned in 5 different ways, whether it is a new tube installed (Figure A2) or based on the idle time (Figure A3).
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Figure A2. Seasoning window when a new tube is installed.
Image Added
Figure A3. Seasoning type based on idle time (from short to long break in time)
When a user clicks on “Use selected and Start”, the X-Ray tube seasoning window appears (Figure A4), the X-Rays ramp up, and the seasoning starts. The season table on the left is set with default values for the selected seasoning method. The seasoning can be stopped anytime by the user by clicking on “Stop seasoning” or “Abort”.
Image Added
Figure A4. X-Ray tube seasoning window with the season table of the weekly seasoning.

IMPORTANT: The seasoning is done for the main tube (in use) AND the spare tube.
To season the spare tube, turn on the switches for the spare source (Figure A5). Go to Instrument > Camera: Season Spare Tube to start the seasoning.
Image Added
Figure A5. Switches to turn on to season the spare X-Ray source
X-Ray Source Status
The Spellman X-ray source status and usage, for both main and spare sources, can be checked by using Monoblock X software provided by the vendor. This is a user-friendly GUI which indicates usage hours, faults, temperature, and allows seasoning (independently of IMS) amongst other features. The user is referred to the MonoblockX Manual for more information (MonoblockX_Manual_RevB.pdf).
Make sure that IMS is closed to allow the sources to communicate with MonoblockX. Open Monoblock X (Figure A6) and accept the terms of use.
Image Added
Figure A6. HR GUI MonoblockX software icon
In the Options tab, check that the serial settings are the same as in Figure A7. Click Connect to communicate with the Spellman XRB source. Change the communication port according to the source you want to check.
Image AddedFigure A7. Serial settings for the XRB sources
Once the communication is established (Figure A8), verify the source status in the Main tab and the number of hours in high voltage (HV on time) (Figure A9). Please report this information on the Confluence logsheet XSCAN Sources Seasoning for a record of the source usage.

Image AddedFigure A8. Connection with the source established - no faults detected
Image Added
Figure A9. High Voltage on Time displaying the total number of hours of use of the source
Cleaning tube
The bore inside the XSCAN needs to be cleaned when it is dirty. To remove the tube, the Working Half rack needs to be emptied so that the bore can be removed from this side. High pressure water (catwalk) is recommended to clean the inside. While doing that, a second bore can be put in place to keep running the measurement. Spare bores are available in the Upper Tween (above the gas bottles).
B1. Troubleshooting
Computer memory full
Images generated by the XSCAN are huge. A .tif image is usually around 180 MB. It is very likely that during the course of an exposition where the XSCAN is intensively used that the computer will reach its capacity to save images. It is very important that the user checks regularly if the image files are correct. When the computer reaches its full memory capacity, the images will be saved with a size of 0 kb !!! There is no warning from IMS. If the Xscan unit begins to stall on the way back to home, check the computer memory. If the computer is full the communications are interrupted and the track will freeze.
To avoid such a thing to happen, the user must ask a technician to save the files on Data1 in order to be able to delete those files from the computer.
Seasoning of the spare tube does not start
If the seasoning of the spare tube does not start, with the main source on, turn off the spare source, but not the main source. Close IMS. Leave the main source on, turn on the spare source, and re-open IMS. This should allow you to do the seasoning of the spare tube.
IMS frozes during X-Ray Auto off
It is very likely that this happens when a scan is about to start and the X-ray Auto-off is ongoing. Two contradictory commands may have been sent at the same time: one telling the source to ramp down, one telling it to ramp up. IMS needs to be killed and restarted. XSCAN switches must be turn off and on again to clear any potential residual error.
Image Added
X-Ray Auto-Off frozen window
B2. NI Communication Ports
The figures B2.1 and B2.2 below show the NI Max settings for the XSCAN to communicate with MonoblockX software and in case of communication loss.
Image Added
Figure B2.1. NI Max settings for the main source
Image Added
Figure B2.2. NI Max settings for the spare source
C1. Motion Control Setup
Motion control should be set during initial setup and further changes should not be necessary. Motion control setup can be accessed by selecting Motion > Setup from the IMS panel menu (Figure C1). The M-Drive Motion Setup control panel will open (Figure C1).
Image Added
Figure C1. Motion Setup Menu from the IMS panel menu
The user may select between four setup panels from this window.
Motor and Track Options
Fixed Positions
Limit and Home Switches
Motion Profiles
Motor and Track Options Menu
Once these values have been properly set, they should not change. This panel is only for initial setup.
Make sure to use the values shown for the XSCAN (Figure C2).
The relationship between motor revolutions and linear motion of the track is defined in this window and is critical to both safe and accurate operation. User should be familiar with the M-Drive motor system prior to adjusting these settings.
X-axis (Figure C2A)
Select Axis: Select X for translational motion of the camera.
Encoder Pulses/rev: Defined by the manufacturer of the M-Drive as 2048.
Screw Pitch: Set to 4.0 (the ratio of 2048 steps per revolution and chain displacement (cm) as a function of the drive gears diameter).
Gear Ratio: Set to 2.0.
Direction: Clockwise rotation moves the tray in a positive direction (from home to end of track).
W-axis (Figure C2B)
Select Axis: Select W-axis for the rotational system of the XSCAN
Encoder Pulses/rev: Defined by the manufacturer of the M-Drive as 2048.
Screw Pitch: Set to 125
Gear Ratio: Set to 2.0.
Direction: Counter clockwise rotation moves the tray in a positive direction (from home to end of track).
Click Accept to save the values or Cancel to return to previous values.
Image Added
Figure C2. XSCAN Motor and Track Options Setup Window for (A) the X-axis and (B) the W-axis
Fixed Positions Menu
Once these values have been properly set, they should not change. This panel is only for initial setup.
In this window the user may define fixed track locations used by IMS motion control. For the XSCAN, make sure to use these values unless there has been a physical change to the system (Figure C3).
X-axis (Figure C3A)
Select Axis: Select X for translational motion of the camera.
Max Section Length: Maximum length of section that can be placed in the track. This value is set to 150 cm.
Allowable Track Move: Distance in cm between the limit switches. Currently the value is set at 0 cm.
Load and Unload positions: For the XSCAN, these values are set to 0. This will always bring the tray back to the sample load end after a measurement sequence.
Top-of-SectionSwitch?: OFF
Top-of-Section Switch Offset: 0
Push Past: 0
Fast Past: 0
Run Out Switch?: OFF
W-axis (Figure C3B)
Select Axis:Select W-axis for the rotational system of the XSCAN
Load and Unload positions: For the XSCAN, these values are set to 0.
Note, these values along with the detector position set in the Camera: General Setup under instruments must be accurate for proper motion control. Take care in setting these values.
Image Added
Figure C3. XSCAN Fixed Positions Window for (A) the X-axis and (B) the W-axis
Limit and Home Switches Window
Once these values have been properly set, they should not change. This panel is only for initial setup.
This panel is used to define the orientation of the track system, limit switches, and the home switch (Figure C4). The MDrive can be used with either a dedicated Home switch or a limit switch as a home switch. In the case of the XSCAN track we use a home switch.
X-axis (Figure C4A)
Select Axis: Select X for translational motion of the camera.
Select Track and Home Geometry:For the XSCAN, select CCW look @ CW Edge
W-axis (Figure C4B)
Select Axis: Select W-axis for the rotational system of the XSCAN
Select Track and Home Geometry:For the XSCAN, select CW look @ CCW Edge
Image Added
Figure C4. XSCAN Limit and Home Switches Window for (A) the X-axis and (B) the W-axis
Motion Profiles
The motion profiles window can be used to adjust the speed, acceleration and deceleration profiles used by the track for various types of movements. In the case of the XSCAN, the motion profile is hard coded for both the X- and W-axis for safety reasons. It is NOT possible to adjust these values (Table 4).
DAQ Move: This profile controls moves between measurement positions.
Limit Seek: This profile finds the limit switch location.
Home Final: This profile finds the final location of the home switch.
Load/Unload: This profile is used for moving the actuator for general movements and moving out of the XSCAN to the final position prior to ending a measurement.

X-axis
W-axis

Speed
Acceleration
Deceleration
Speed
Acceleration
Deceleration
DAQ Move
5
50
50
5
5
30
Limit Seek
5
1
80
5
5
30
Home Final
1
2
80
1
5
20
Load/Unload
15
5
10
5
5
4
Table 4. Motion profile values for the X- and W- axes of the XSCAN
C.2. MDrive Motion Utility and Widget
The MDrive Motion Utility window (Figure C5), accessible in Motion>Utility, allows the user to move and rotate the camera as needed/necessary.
Image Added
Figure C5. MDrive Motion Utility Window
The Motion Widget window (Figure C6), accessible in Motion>Motion Widget, is a simpler interface and allows the user to move and rotate the camera as needed/necessary.
Image Added
Figure C6. Motion Widget Window

V. Credits
All improvements to the Quick Start Guides and User Guides are a communal effort, with honorable mention to the group of LOs, ALOs, and technicians who have helped.

VI. LIMS Component Table
ANALYSIS TABLE NAME ABOUT TEXT
XSCAN SAMPLE Exp Exp: expedition number
XSCAN SAMPLE Site Site: site number
XSCAN SAMPLE Hole Hole: hole number
XSCAN SAMPLE Core Core: core number
XSCAN SAMPLE Type Type: type indicates the coring tool used to recover the core (typical types are F, H, R, X).
XSCAN SAMPLE Sect Sect: section number
XSCAN SAMPLE A/W A/W: archive (A) or working (W) section half.
XSCAN CALCULATED Top Depth CSF-A (m) Depth CSF-A (m): position of observation (location of the upper edge of the section) expressed relative to the top of the hole.
XSCAN CALCULATED Bottom Depth CSF-A (m) Depth CSF-A (m): position of observation (location of the lower edge of the section) expressed relative to the top of the hole.
XSCAN CALCULATED Top Depth CSF-B (m) Depth [other] (m): position of observation (location of the upper edge of the section) expressed relative to the top of the hole. The location is presented in a scale selected by the science party or the report user.
XSCAN CALCULATED Bottom Depth CSF-B (m) Depth [other] (m): position of observation (location of the lower edge of the section) expressed relative to the top of the hole. The location is presented in a scale selected by the science party or the report user.
XSCAN SAMPLE Top offset (cm) Top offset (cm): top offset of observation from top of parent sample (i.e., location of the upper edge of the image relative to the top of the section), expressed in centimeters.
XSCAN SAMPLE Bottom offset (cm) Bottom offset (cm): bottom offset of observation from top of parent sample (i.e., location of the lower edge of the image relative to the top of the section), expressed in centimeters.
XSCAN RESULT Voltage (kV) Voltage (kV): the voltage, in kV, used for imaging the section
XSCAN RESULT Current (mA) Current (mA): the current, in mA, used for imaging the section
XSCAN RESULT Speed (cm/s) Speed (cm/s): Track speed (cm/s) during image acquisition.
XSCAN RESULT Exposure time (us) Exposure time (us): Time of exposure for a single stack of the TDI image, expressed in microseconds.
XSCAN RESULT Angle (degree) Angle (degree): rotational angle at acquisition of the image where 0 degrees is vertically down
XSCAN RESULT Bin size (px) Bin size (px): number of pixels binned horizontally and vertically on the detector (default is 1x1 [no binning])
XSCAN RESULT Apparent pixel pitch (um) Apparent pixel pitch (um): apparent pixel pitch at split-plane height of a section, expressed in microns, calculated as a function of true pixel pitch and inversely proportional to magnification
XSCAN RESULT Scale down core (px/cm) Scale down core (px/cm): pixels per centimeters down core
XSCAN RESULT Scale across core (px/cm) Scale across core (px/cm): pixels per centimeters across core
XSCAN RESULT Image calibration time Image calibration time: date and time the X-ray calibration images were collected (i.e., time of capture)
XSCAN RESULT Calibration left crop (px) Calibration left crop (px): number of pixels marking the left side crop of the calibration image
XSCAN RESULT Calibration right crop (px) Calibration right crop (px): number of pixels marking the right side crop of the calibration image (left +1600 px?)
XSCAN RESULT Image mode Image mode: selected preset for type of section imaged (e.g., SHLF-A, WRND)
XSCAN RESULT Start angle (degree) Start angle (degree): start rotational angle for acquisition of images at various angles where 0 degrees is vertically down.
XSCAN RESULT End angle (degree) End angle (degree): end rotational angle for acquisition of images at various angles where 0 degrees is vertically down.
XSCAN RESULT Step angle (degree) Step angle (degree): step angle used for acquisition of images at various angles.
XSCAN RESULT ROI left edge ROI left edge: pixel coordinate marking the left crop of the raw X-radiograph TIF image
XSCAN RESULT ROI upper edge ROI upper edge: pixel coordinate marking the top crop of the raw X-radiograph TIF image
XSCAN RESULT ROI right edge ROI right edge: pixel coordinate marking the right crop of the raw X-radiograph TIF image
XSCAN RESULT ROI lower edge ROI lower edge: pixel coordinate marking the bottom crop of the raw X-radiograph TIF image
XSCAN RESULT Sample length (cm) RESULT Sample length (cm): the length of the section as entered by the user; if scanning the label, the same as the length contained in the label barcode.
XSCAN RESULT Image mode Image mode: selected preset for type of section imaged (e.g., SHLF-A, WRND)
XSCAN RESULT Original image (tif) link Original image (tif) link: link to raw core image file. Raw core image is white and dark corrected
XSCAN RESULT Original image filename Original image filename: filename of the raw image. Raw core image is white and dark corrected
XSCAN RESULT Processed image (jpg) link Processed image (jpg) link: link to the processed image that includes the ruler and the label overlay
XSCAN RESULT Processed image filename Processed image filename: filename of the processed image that includes the ruler and the label overlay.
XSCAN RESULT Cropped image (jpg) link Cropped image (jpg) link: link to the processed image that does not include a ruler or label overlay
XSCAN RESULT Cropped image filename Cropped image filename: filename of the processed image that does not include a ruler or label overlay
XSCAN RESULT Positions specified? Positions specified?: a flag indicating if a region of interest (ROI) was selected
XSCAN SAMPLE Status (T/F) Status: single-character code for the current status of a sample (e.g., active, canceled)
XSCAN RESULT Processing method Processing method: processing method chosen by the user to process the raw image (e.g., Full Core Profile)
XSCAN RESULT Histogram expansion factor Histogram expansion factor: expansion factor of the histogram, chosen by the user to process the raw image. The factor is an integer from 0 to 10 (0 = sharp)
XSCAN RESULT Smoothing method Smoothing method: smoothing method chosen by the user and expressed as a boolean T/F; T=use histogram max value; F=use histogram expansion factor derived mean
XSCAN RESULT Run file link Run file link: serial number of the ASMAN link to the run file containing image metadata and calibration data.
XSCAN RESULT Run filename Run filename: name of run file containing image metadata and calilbration data
XSCAN RESULT Config file link Config file link: serial number of the link to the configuration .ini file
XSCAN RESULT Config filename Config filename: file name of the configuration file
XSCAN RESULT Timestamp (UTC) Timestamp (UTC): date and time the x-ray images were collected (i.e., time of capture)
XSCAN
TEST
Instrument Instrument: instrument entry from the TEST table. Detector name (e.g. Hamamatsu C123 ).
XSCAN TEST Instrument group Instrument group: field that describes the instrument group (most often this applies to loggers with multiple sensors); an abbreviation or mnemonic for the sensing device used to make this observation (XSCAN)
XSCAN SAMPLE Text ID Text ID: automatically generated unique database identifier for a sample, visible on printed labels
XSCAN SAMPLE Label ID Label identifier: automatically generated, human readable name for a sample that is printed on labels. This name is not guaranteed unique across all samples.
XSCAN SAMPLE Test No Sample Number: automatically generated database identifier for a sample. This is the primary key of the SAMPLE table.
XSCAN SAMPLE Sample Comments Sample comment: contents of the SAMPLE.description field (from Sample Master). Observations recorded about the sample itself.
XSCAN TEST Test Comments Test comment: contents of the TEST.comment field. Observations about a measurement or the measurement process, entered by the user; some measurement observations may be under Result comments.
XSCAN RESULT Result Comments Result comment: observations about a measurement or the measurement process; some measurement observations may be under Test Comments.
Note, these values along with the detector position set in the Camera: General Setup under instruments must be accurate for proper motion control. Take care in setting these values.
Image Removed
Figure 30. XSCAN Fixed Positions Window for (A) the X-axis and (B) the W-axis
Limit and Home Switches Window
Once these values have been properly set, they should not change. This panel is only for initial setup.
This panel is used to define the orientation of the track system, limit switches, and the home switch (Figure 31). The MDrive can be used with either a dedicated Home switch or a limit switch as a home switch. In the case of the XSCAN track we use a home switch.
X-axis (Figure 31A)
Select Axis: Select X for translational motion of the camera.
Select Track and Home Geometry:For the XSCAN, select CCW look @ CW Edge
W-axis (Figure 31B)
Select Axis: Select W-axis for the rotational system of the XSCAN
Select Track and Home Geometry:For the XSCAN, select CW look @ CCW Edge
Image Removed
Figure 31. XSCAN Limit and Home Switches Window for (A) the X-axis and (B) the W-axis
Motion Profiles
The motion profiles window can be used to adjust the speed, acceleration and deceleration profiles used by the track for various types of movements. In the case of the XSCAN, the motion profile is hard coded for both the X- and W-axis for safety reasons. It is NOT possible to adjust these values (Table 4).
DAQ Move: This profile controls moves between measurement positions.
Limit Seek: This profile finds the limit switch location.
Home Final: This profile finds the final location of the home switch.
Load/Unload: This profile is used for moving the actuator for general movements and moving out of the XSCAN to the final position prior to ending a measurement.
X-axis
W-axis
Speed
Acceleration
Deceleration
Speed
Acceleration
Deceleration
DAQ Move
5
50
50
5
5
30
Limit Seek
5
1
80
5
5
30
Home Final
1
2
80
1
5
20
Load/Unload
15
5
10
5
5
4
Table 4. Motion profile values for the X- and W- axes of the XSCAN
MDrive Motion Utility and Widget
The MDrive Motion Utility window (Figure 32), accessible in Motion>Utility, allows the user to move and rotate the camera as needed/necessary.
Image Removed
Figure 32. MDrive Motion Utility Window
The Motion Widget window (Figure 33), accessible in Motion>Motion Widget, is a simpler interface and allows the user to move and rotate the camera as needed/necessary.
Image Removed
Figure 33. Motion Widget Window
III. Uploading Data to LIMS
File Formats and File Uploading
IMS automatically outputs the raw and processed images. Three images are saved: two are .jpg (corrected. cropped and processed images, respectively) and a raw .tif image.
Examples of file names:
Raw file name (.tif):
385-U1545A-3H-4-A_SHLF10354871_0000_deg_20230124132738_R.tif
Cropped file name (.jpg):
385-U1545A-3H-4-A_SHLF10354871_0000_deg_20230110125632_C.jpg
Processed file name:
385-U1545A-3H-4-A_SHLF10354871_0000_deg_20230130154107_P.jpg
File location: C:\Data\In\SiteHole (e.g., XXX) for regular scans and CT-style scans will be found in a subfolder C:\Data\In\SiteHole\SiteHole-CT (e.g., XXX)
Calibration Data (Dark and White): C:\IMS-10\CONFIG_XSCAN\I_PI_HAMA.ini
Note: this calibration data is also contained in every MUT load file.
A unique time stamp is appended to each image.
IV. Appendix
A.1. Health, Safety and Environment
Safety
Keep extraneous items and body parts away from the moving platform, belt, and motor.
The scanner has a well-marked emergency stop button to halt the system if needed.
Don't insert your hand between the source and the detector, and near the spare source when seasoning is ongoing.
Do not attempt to work on the system while a measurement is in progress.
Do not lean over the scanner.
Do not stack anything inside the scanner.
This analytical system does not require personal protective equipment.
Pollution Prevention
This procedure does not generate heat or gases and requires no containment equipment.
A.2. Maintenance
Seasoning
After initial installation and/or after periods of idle time (idle time is defined as X-ray production
unused), the manufacturer of the X-ray source used in the XSCAN recommends warm-up schedules to ensure proper operation for the X-ray Tube. Disregarding this may cause irreversible damage to the X-ray tube and/or decrease its life expectancy.
{from Spellman website} Typically seasoning is done after initial installation and after periods of idle time. This would include a profile for daily seasoning and longer profiles for increased idle time. The seasoning procedure carefully raises the tube current and voltage to reduce any residual gas in the X-ray tube before the tube is operated at full output. Seasoning also minimizes un-even distribution of potential/electric field on the tube glass. Following the recommended seasoning schedule will help prolong the life of the X-ray tube and prevent tube arcing that can potentially cause irreversible damage to the X-ray tube.
The X-Ray sources, both main and spare, must be seasoned every week with the recommended daily seasoning type (1 to 7 days). Seasoning procedure can be activated in the IMS main menu Instruments > Camera: Season Tube.
Alternatively, the IMS software, when launched, will tell the user to proceed to seasoning whenever necessary by showing the window on Figure A1.
Image Removed
Figure A1. IMS asking to perform the required weekly seasoning
X-Ray source can be seasoned in 5 different ways, whether it is a new tube installed (Figure A2 new tube) or based on the idle time (Figure A3 – 4 different options).
Image Removed
Figure A2. Seasoning window when a new tube is installed.
Image Removed
Figure A3. Seasoning type based on idle time (from short to long break in time)
When a user clicks on “Use selected and Start”, the X-Ray tube seasoning window appears (Figure A4), the X-Rays ramp up, and the seasoning starts. The season table on the left is set with default values for the selected seasoning method. The seasoning can be stopped anytime by the user by clicking on “Stop seasoning” or “Abort”.
Image Removed
Figure A4. X-Ray tube seasoning window with the season table of the weekly seasoning.
IMPORTANT: The seasoning is done for the main tube (in use) AND the spare tube.
To season the spare tube, turn on the switches for the spare source (Figure A5). Go to Instrument>Camera: Season Spare Tube to start the seasoning.
put picture here of the switch board showing the switches of the spare source
Figure A5. Switches to turn on to season the spare X-Ray source
Cleaning tube
B1. Troubleshooting
V. Credits
All improvements to the Quick Start Guides and User Guides are a communal effort, with honorable mention to the group of LOs, ALOs, and technicians who have helped.
VI. LIMS Component Table

VII. Archived Versions
This User Guide is the first of its kind.

ANALYSIS	TABLE	NAME	ABOUT TEXT
XSCAN	SAMPLE	Exp	Exp: expedition number
XSCAN	SAMPLE	Site	Site: site number
XSCAN	SAMPLE	Hole	Hole: hole number
XSCAN	SAMPLE	Core	Core: core number
XSCAN	SAMPLE	Type	Type: type indicates the coring tool used to recover the core (typical types are F, H, R, X).
XSCAN	SAMPLE	Sect	Sect: section number
XSCAN	SAMPLE	A/W	A/W: archive (A) or working (W) section half.
XSCAN	CALCULATED	Top Depth CSF-A (m)	Depth CSF-A (m): position of observation (location of the upper edge of the section) expressed relative to the top of the hole.
XSCAN	CALCULATED	Bottom Depth CSF-A (m)	Depth CSF-A (m): position of observation (location of the lower edge of the section) expressed relative to the top of the hole.
XSCAN	CALCULATED	Top Depth CSF-B (m)	Depth [other] (m): position of observation (location of the upper edge of the section) expressed relative to the top of the hole. The location is presented in a scale selected by the science party or the report user.
XSCAN	CALCULATED	Bottom Depth CSF-B (m)	Depth [other] (m): position of observation (location of the lower edge of the section) expressed relative to the top of the hole. The location is presented in a scale selected by the science party or the report user.
XSCAN	SAMPLE	Top offset (cm)	Top offset (cm): top offset of observation from top of parent sample (i.e., location of the upper edge of the image relative to the top of the section), expressed in centimeters.
XSCAN	SAMPLE	Bottom offset (cm)	Bottom offset (cm): bottom offset of observation from top of parent sample (i.e., location of the lower edge of the image relative to the top of the section), expressed in centimeters.
XSCAN	RESULT	Voltage (kV)	Voltage (kV): the voltage, in kV, used for imaging the section
XSCAN	RESULT	Current (mA)	Current (mA): the current, in mA, used for imaging the section
XSCAN	RESULT	Speed (cm/s)	Speed (cm/s): Track speed (cm/s) during image acquisition.
XSCAN	RESULT	Exposure time (us)	Exposure time (us): Time of exposure for a single stack of the TDI image, expressed in microseconds.
XSCAN	RESULT	Angle (degree)	Angle (degree): rotational angle at acquisition of the image where 0 degrees is vertically down
XSCAN	RESULT	Bin size (px)	Bin size (px): number of pixels binned horizontally and vertically on the detector (default is 1x1 [no binning])
XSCAN	RESULT	Apparent pixel pitch (um)	Apparent pixel pitch (um): apparent pixel pitch at split-plane height of a section, expressed in microns, calculated as a function of true pixel pitch and inversely proportional to magnification
XSCAN	RESULT	Scale down core (px/cm)	Scale down core (px/cm): pixels per centimeters down core
XSCAN	RESULT	Scale across core (px/cm)	Scale across core (px/cm): pixels per centimeters across core
XSCAN	RESULT	Image calibration time	Image calibration time: date and time the X-ray calibration images were collected (i.e., time of capture)
XSCAN	RESULT	Calibration left crop (px)	Calibration left crop (px): number of pixels marking the left side crop of the calibration image
XSCAN	RESULT	Calibration right crop (px)	Calibration right crop (px): number of pixels marking the right side crop of the calibration image (left +1600 px?)
XSCAN	RESULT	Image mode	Image mode: selected preset for type of section imaged (e.g., SHLF-A, WRND)
XSCAN	RESULT	Start angle (degree)	Start angle (degree): start rotational angle for acquisition of images at various angles where 0 degrees is vertically down.
XSCAN	RESULT	End angle (degree)	End angle (degree): end rotational angle for acquisition of images at various angles where 0 degrees is vertically down.
XSCAN	RESULT	Step angle (degree)	Step angle (degree): step angle used for acquisition of images at various angles.
XSCAN	RESULT	ROI left edge	ROI left edge: pixel coordinate marking the left crop of the raw X-radiograph TIF image
XSCAN	RESULT	ROI upper edge	ROI upper edge: pixel coordinate marking the top crop of the raw X-radiograph TIF image
XSCAN	RESULT	ROI right edge	ROI right edge: pixel coordinate marking the right crop of the raw X-radiograph TIF image
XSCAN	RESULT	ROI lower edge	ROI lower edge: pixel coordinate marking the bottom crop of the raw X-radiograph TIF image
XSCAN	RESULT	Sample length (cm)	RESULT Sample length (cm): the length of the section as entered by the user; if scanning the label, the same as the length contained in the label barcode.
XSCAN	RESULT	Image mode	Image mode: selected preset for type of section imaged (e.g., SHLF-A, WRND)
XSCAN	RESULT	Original image (tif) link	Original image (tif) link: link to raw core image file. Raw core image is white and dark corrected
XSCAN	RESULT	Original image filename	Original image filename: filename of the raw image. Raw core image is white and dark corrected
XSCAN	RESULT	Processed image (jpg) link	Processed image (jpg) link: link to the processed image that includes the ruler and the label overlay
XSCAN	RESULT	Processed image filename	Processed image filename: filename of the processed image that includes the ruler and the label overlay.
XSCAN	RESULT	Cropped image (jpg) link	Cropped image (jpg) link: link to the processed image that does not include a ruler or label overlay
XSCAN	RESULT	Cropped image filename	Cropped image filename: filename of the processed image that does not include a ruler or label overlay
XSCAN	RESULT	Positions specified?	Positions specified?: a flag indicating if a region of interest (ROI) was selected
XSCAN	SAMPLE	Status (T/F)	Status: single-character code for the current status of a sample (e.g., active, canceled)
XSCAN	RESULT	Processing method	Processing method: processing method chosen by the user to process the raw image (e.g., Full Core Profile)
XSCAN	RESULT	Histogram expansion factor	Histogram expansion factor: expansion factor of the histogram, chosen by the user to process the raw image. The factor is an integer from 0 to 10 (0 = sharp)
XSCAN	RESULT	Smoothing method	Smoothing method: smoothing method chosen by the user and expressed as a boolean T/F; T=use histogram max value; F=use histogram expansion factor derived mean
XSCAN	RESULT	Run file link	Run file link: serial number of the ASMAN link to the run file containing image metadata and calibration data.
XSCAN	RESULT	Run filename	Run filename: name of run file containing image metadata and calilbration data
XSCAN	RESULT	Config file link	Config file link: serial number of the link to the configuration .ini file
XSCAN	RESULT	Config filename	Config filename: file name of the configuration file
XSCAN	RESULT	Timestamp (UTC)	Timestamp (UTC): date and time the x-ray images were collected (i.e., time of capture)
XSCAN	TEST	Instrument	Instrument: instrument entry from the TEST table. Detector name (e.g. Hamamatsu C123 ).
XSCAN	TEST	Instrument group	Instrument group: field that describes the instrument group (most often this applies to loggers with multiple sensors); an abbreviation or mnemonic for the sensing device used to make this observation (XSCAN)
XSCAN	SAMPLE	Text ID	Text ID: automatically generated unique database identifier for a sample, visible on printed labels
XSCAN	SAMPLE	Label ID	Label identifier: automatically generated, human readable name for a sample that is printed on labels. This name is not guaranteed unique across all samples.
XSCAN	SAMPLE	Test No	Sample Number: automatically generated database identifier for a sample. This is the primary key of the SAMPLE table.
XSCAN	SAMPLE	Sample Comments	Sample comment: contents of the SAMPLE.description field (from Sample Master). Observations recorded about the sample itself.
XSCAN	TEST	Test Comments	Test comment: contents of the TEST.comment field. Observations about a measurement or the measurement process, entered by the user; some measurement observations may be under Result comments.
XSCAN	RESULT	Result Comments	Result comment: observations about a measurement or the measurement process; some measurement observations may be under Test Comments.

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