Section Half Imaging Logger: User Guide

Manual Information

Contents

Introduction

The section half image logger (SHIL) takes digital images of the flat face of split cores using a line scan camera and generates RGB data. All 'Archive' section halves are imaged on the SHIL. Sediment cores are imaged as soon as possible after splitting and scraping to minimize color changes that occur through oxidation and drying. The SHIL can also be used to image the outside of a whole round hard rock section (see <<section>> for details).

Theory of Operation

The track system is composed of two slaved linear actuators and a linear encoder that provides precise triggering pulses to a gantry-mounted JAI color line scan camera. The line scan interval is 20 lines/mm (50 microns) and the camera height is adjusted so that image pixels will be square. Light is provided by a number of Advanced Illumination high-current focused light emitting diode (LED) line lights adjusted to precise angles relative to the lens axis in order to evenly illuminate an uneven surface. Motion control is performed using Galil software and hardware coupled to the linear actuators.

Line Scan Camera

Unlike a "normal" distal photo sensor with a square sensor array, similar to a postage stamp, a line scan camera's array consists of a single line of pixels. Whereas a normal camera captures frames, the line scan camera sees only a single line at a time and sends this line image to a capture card on a dedicated computer. Line by line, the computer compiles the final image.
In some applications, the photographic subject may move in front of the camera on a conveyor belt at a specific combination of object speed and shutter speed. In the case of the SHIL, the camera moves across the sample via a motorized gantry. The combination of gantry travel speed and camera shutter speed is critical and is explained in the Camera Configuration Advanced User Guide.
The line scan camera images only one line of pixels rather than an area and therefore what happens outside the line of view is of no consequence. The line scan camera effectively masks everything other than the single line of pixels being imaged. This fact is key to the effectiveness of the line lights in providing even illumination at different distances from the lens.
The camera lens on the imaging track, Nikon 60 mm macro, does not have 1/2 or 1/3 stops, only whole F/stops: 5.6, 6.3, 8, 11, 16, 22, and 32. F/16 is the minimum aperture needed to achieve the required depth of field to image the subject at varying heights.

System Operation

SHIL system operation involves a number of processes, some performed only once upon initial installation, some only when lighting or camera equipment is replaced, and some on a routine basis at the beginning of each expedition or at the beginning of each batch of samples. The following procedures are covered in this manual:

• Installing and calibrating light array (see Light Installation).
• Setting black and white saturation gain levels (see Maximum Dynamic Sensor Range).
• Setting color balance Author: Where is this covered?
• Making camera corrections (see Routine Camera Adjustments).
• Setting track velocity (see Track Speed Example).
• Adjusting knee slope, if needed (see Procedure: Iterative Adjustment).
• Performing QA/QC to confirm camera settings (see Quality Assurance/Quality Control).

Apparatus

Hardware

The core imaging track system includes the following hardware components:

• Camera
  • 3CCD (charge-coupled device) line scan camera: JAI model CV107CL
  • Macro lens: AF micro Nikkor 60 mm (1:2.8)
• Light system
  • High-current line lights: Advanced Illumination model LL068
  • Power supply: 24 V/6 A
  • Current source: model CS420-0103 constant (modified)
• Linear encoder: Newall 2 µm/72 in. model SHG-TT
• Motor system
  • Motors: Galil model BLM-N23-50-100
  • PCI controller card: model DMC-1846
  • Motor amplifier: model AMP-19520
  • Breakout board: ICB-90044-M 44-pin
  • Power supply: CPS 56V/12A
  • Connectors for motor extension cords: AMP 4-pin connectors (172167-1 male, 172159-1 female)
• Robot modules: NSK 2-meter model XY-HRS200-F06246
• PC Workstation
  • NI frame grabber card model PCIe-1429
  • NI camera link I/O extension board

Software

Data are collected using the LabVIEW 10.0 application.

Sample Preparation & Analysis

Core imaging takes place in the Core Description Laboratory on board the ship. The workflow is as follows:

1. Preparing samples (Sample Preparation).
2. Preparing track system (Instrument Preparation).
3. Calibrating the system (Calibration).
4. Running samples (Running Samples).
5. Analyzing data and uploading to LIMS (LIMS Integration).

Sample Preparation and Loading

Sediment

If the surface of the archive half is not even use a flat spatula to provide a "clean" surface for imaging. Sediment cores should be imaged as soon as possible after splitting and scraping are completed to minimize color change through oxidation and drying.

Hard Rock

Rock pieces should be dry and individually rotated such that the split face is approximately perpendicular to the axis of the camera. The lights and lens aperture are configured to give consistent illumination and focus to effectively image rubble bins.
For 360 Imaging of hard rock cores refer to Appendix X, 360 Imaging of Hard Rock.

Loading Section

1. Pick up section half and place in the track loading area with the blue end cap forward against the color block. Make sure the section the section is pushed all the way against the block so the end cap is lined up with 0cm on the ruler.
2. Bring the endcap for the section to the SHIL workstation for entering sample information.
3. If the section has a whole round sample taken, denoted by a yellow bottom endcap, place a  split styrofoam spacer at the end of the section. Cut the styrofoam to same length of the sample taken and write letters on the styrofoam to indicate the type of the sample taken. For example a 5cm Interstitial Water whole round sample taken. A 5cm styrofoam spacer with 'IW' written on it would be placed at the bottom. Once a spacer has been made it can be used over the course of the expedition for applicable section halves.

Launch IMS Application

First open the IMS Application 'SHIL' on the desktop.(Figure X)

IMS will open and test communication with the  instruments, reads configuration files, and homes the instrument . After successful initialization the main IMS

Two windows will appear: The 'IMS Control Panel on the left and the measurement window along the top of the screen. FIGURE (XX)

Start A Measurement

1. Click the green 'Start' Button in the 'IMS Control' panel.
2. The 'Sample Information' Window will pop up (FIGURE XX).
   
   
   
   
3. The area on the left has four fields to define the condition of the sample measurement:
   1. Image Type: 'Section Imaging' or '360 Imaging'. For instructions on the 360 imaging refer to XXXXXX
   2. Wet/Dry: Indicates the type of the material being imaged
   3. Condition: 'Pristine' or 'Sampled/Altered'. Sampled/altered could include imaging the working half or a highly disturbed section. Most instances should be pristine.
   4. 360 Imaging: This area is grayed out unless '360 Imaging' Image Type is selected. For instructions on the 360 imaging refer to XXXXXX

        Select the conditions appropriate for the section half.

       4. There are three ways to enter sample information into IMS:

                  Barcode (most common): Put cursor in the 'Scan' box. Use the bar-code scanner to scan the label on the end-cap. The sample information will parse into the 'Sample ID', 'LIMS ID', and Length fields.

                  LIMS Entry: Select the 'LIMS' tab at the top of the window. Navigate through the hierarchy to select the correct, expedition, site, hole, core, and section. Length information will automatically populate when the section is selected. 

                  Manual Entry: Select the 'Manual' tab at the top of the window. Click in the box and manually type sample information into the box.

       5. Click 'Take a Picture'. The lights will turn on and start moving down the length of the core. In the IMS interface the sample information will go away revealing the measurement windows. The image and RGB data is displayed and updates as the measurement progresses. 

       6. When the measurement is complete, the camera lights will turn off and move back to the home position on the track.

       7. An 'Image Crop' window pops up. An image should be cropped to include all material and the inner edge of the end-cap. RGB data will exclude data outside of the Crop area. The green box is the IMS estimation of the crop area. Click and drag the green lines to adjust the cropped area              at the top, bottom, and sides of the image. Tools in this window include:

                   Show Bottom of Image: Takes image down to illustrate the bottom of the image and crop box.

                   Show Top of Image: Brings image up to show the top of the image and crop box.

                   Crop Image: Crops the image to show only image inside of the green box.                   

                   Uncrop Image: Will undo a crop and allow user to re-adjust the green crop box.

         The Image crop restricts users to limit adjustments to 2cm or less. If the image needs to cropped by more than 2cm check the correct section/end cap is being uses, a styrofoam spacer is not missing, and the curated length. Cores can expand so if the curated length is incorrect, talk to    the curator on shift to correct the length. Note this will also create a need for the curator to re-calcuate depth of the hole. If the error is in the curated length of the core a user can check the 'override crop restriction' button to crop the image and upload the data.

      8. Click 'Crop Image' when satisfied the green box will capture the entire image.

      9. If satisfied with the image click 'Save Image'. If the image needs to be re-imaged click 'Discard Image' and re-start the measuring process.

     10. The 'Image Crop' window will go away and the 'Sample Information' window will appear again.

Uploading Data

Three files are uploaded to LORE via MegaUploadaTron (MUT): a cropped JPEG file, full length TIFF file, and a RGB file. Files are written to C: > DATA > IN. MUT looks in this folder, uploads the files, and moves succesfully uploaded files to C: > DATA

Maintenance

Instrument Preparation

Preparing the track system for imaging cores requires adjusting the position of the lights and barcode imager for optimal quality and calibrating the system by adjusting camera settings. The position of the lights and barcode imager, once set, should be stable throughout an expedition. The technical staff will calibrate the camera settings (SHIL: Camera Configuration AUG) and light array (SHIL: Light Array AUG) whenever the camera or light sources have been repositioned or changed.

Setting up the Lights

Initial light installation and fine adjustment procedures are described in the SHIL: Light Array AUG. For routine operation, follow these steps:

1. Rotate the lights to the desired rough angle to the camera (usually ~30° to the camera axis for sediment cores). Fine-tune the light position by observing the camera output using MAX.
2. Manually turn on one line light at a time to full power by pressing the "+" button on the light controller until you reach 100%.
3. Loosen the brackets on both sides of the light mounts and make small position adjustments until the brightest image is achieved.
4. Turn off the light by pressing the "–" button and press Select to enable the other light.
5. Repeat Steps 2–4 for the second light.

Calibration

The laboratory technician calibrates the system when needed by adjusting camera settings and analyzing an imaged Kodak Q13 grayscale standard.
Calibration adjustments are performed using an iterative process of imaging a ruler placed crosswise on the track then counting the pixels between millimeter marks, moving the camera up or down, and repeating. See <LINK> [Author: Where is this procedure documented?] for details on this procedure.

LIMS Integration

Sample and Analysis Components

Troubleshooting

Common problems encountered when using the core imager and their possible causes and solutions:

Scheduled Maintenance

Standard Replacement Parts/Spares

Spares are available for the following parts:

• camera
• camera lens
• frame grabber card
• linear encoder head
• lights power supply

Non-camera-specific items are part of the shared spares pool for all the track systems. See a technician for the location of the shared spares.

Health, Safety, and Environment

Safety

• Avoid staring into the line lights, as they produce 90,000 lux each at full power. This is roughly equivalent to staring directly into the sun.
• Do not put your hands in or near the moving equipment. The actuators will torque out when impeded but injury could occur before that happens. Hardware abort buttons are located at both ends of the system for an emergency stop.
• Take care when working inside the electronics enclosure to avoid shocks from the power supply terminals.

Vendor Information

Galil Motion Control

270 Technology Way Rocklin, CA 95765 800-377-6329 galil@galilmc.com www.galilmc.com

JAI Inc., USA

625 River Oaks Parkway San Jose, CA 95134 800-445-5444 www.pulnix.com

Microscan

800-251-7711 helpdesk@microscan.com www.microscan.com/index.htm

Advanced Illumination, Inc.

24 Peavine Drive Rochester, VT 05767 800-767-3830 info@advancedillumination.com www.advancedillumination.com/

NSK Corporation

4200 Goss Road Ann Arbor, MI 48105 800-521-0605 www.npa.nsk.com/public/enu/1001_102.asp

Newall Electronics, Inc.

1778 Dividend Drive Columbus, OH 43228 800-229-4376 www.newall.com/LEDs/leds.htm

Digi-Key

www.digikey.com is a good source for small quantities of AMP hardware

Related Documentation/Links

The following documents contain more detailed information on the logger system components:

• LabVIEW: NI-IMAQ3_error_codes.xls
• JAI camera: CV-107CL manual.pdf
• Microscan barcode imager: MS4manual.pdf
• Advanced Illumination
  • Controller: AIcontroller.pdf
  • Lights: LL068.pdf
• Galil
• Motors: Blm_n23.pdf
• Software: wsdk.pdf
• Controllers: man19540.pdf
• Amplifiers: man18x-6.pdf
• Newall
  • Linear encoder: Newall_linear_encoder.pdf
  • Wiring diagram: Encoder_Connections.xls
  • ImCheck manual: Imcheck_Guide_V1.pdf