Polaroid ST-8E, ST-9E, ST-7E manual Accessories for your CCD Camera, Cooling Booster

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Section 6 - Accessories for your CCD Camera

6.Accessories for your CCD Camera

This section briefly describes the different accessories available for your CCD camera.

6.1.Cooling Booster

The cooling booster, which is included with the ST-9E and is an option for the ST-7E and ST-8E, is a small module that gets installed inside the back compartment of the camera. This section tells you how to best use the Cooling Booster.

SBIG understands that water-cooling is a major annoyance. We do not recommend using water cooling in the field due to the aggravation of dragging around buckets of water and finding more electrical power. For users that have fixed sites, or small observatories, the aggravation is more tolerable. The major problem one must deal with is routing the rather heavy water tubes off the mount to minimize perturbations to the mount during tracking. In general, try to route tubes (and wires) over the mount, rather than just let the tubes dangle from the end of a long tube. Water-cooling is probably not necessary for most users when the air temperature is below 10 degrees C (50 degrees F), since the dark current is fairly low already. Think of it as a summertime accessory! We do not recommend use of water cooling below freezing temperatures, where antifreeze must be added to the water. It is simply not necessary then. There is no problem with using the cooling booster with only air cooling in the winter, though.

The cooling booster can be used either without the flowing water or with it. Without flowing water the cooling improvement is about 6 degrees C. With it the cooling improvement is about 15 degrees C. If you plan to use it without the water then you should disconnect the hoses from the camera and shake out the water trapped in the heat sink. Disconnecting the hoses will reduce the potential perturbation to your telescope mount.

To operate the cooling booster without water cooling, mount the camera to the telescope as before and simply plug the auxiliary 12 volt supply jack into the connection on the camera back plate. Turn on the TE cooling to 100% by giving it a target temperature of –50 degrees. After 10 minutes examine the camera temperature, and reset the set point to 3 degrees C above the current temperature. This 3 degree temperature margin will enable the ST-7E/8E/9E to regulate the temperature accurately.

To operate the camera with water cooling, the procedure is the same except that the water flow must be established before mounting the camera to the telescope, since the water pumps have limited pressure capability. To do this, put the camera at the same level as the water reservoir. Connect all the hoses, and make sure the water return goes back into the reservoir. Push the ¼ inch internal diameter (ID) hoses onto the nipples on the back of the camera so they seal. Attach one hose to the nipple onto the reducing connector that adapts the ¼ inch ID hose to the ½inch diameter hose from the pump.

Turn on the pump, and let the flow establish itself through the hoses. Next, mount the camera to the telescope. If you always keep the return hose outlet near the reservoir level the pump will have no problem raising the water 2 meters (6 feet) off the floor. The limited pressure capacity of the pump is only a problem when you let the water fall back into the reservoir from a significant height above it, such a 0.3 meter (12 inches). Lastly, check for leaks!

When using water cooling, avoid the temptation to put ice in the water to get the camera even colder. As the cooling booster is designed, the camera will not be cooled below

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Contents Operating Manual Page Table of Contents Technique Road Map of the Documentation IntroductionQuick Tour Ccdops for Windows or Macintosh Ccdops SoftwareCCD Camera Page Cameras in General Introduction to CCD CamerasHow CCD Detectors Work Camera Hardware Architecture Full Frame and Frame Transfer CCDsCCD System Block Diagram Cooling CCD Special RequirementsDark Frames Double Correlated Sampling ReadoutPixels vs. Film Grains Flat Field ImagesGuiding Electronic Imaging Black and White vs. Color Page Step by Step with a CCD Camera At the Telescope with a CCD CameraAttaching the Camera to the Telescope Establishing a Communications Link Focusing the CCD CameraCamera Back Focus Processing the Image Finding and Centering the ObjectTaking an Image Displaying the ImageAdvanced Capabilities Crosshairs Mode Photometry and AstrometrySub-Frame Readout in Focus Autoguiding and Self Guiding Track and AccumulateColor Imaging Auto GrabAt the Telescope with a CCD Camera Camera Hardware Connecting the PowerConnecting to the Computer Connecting the Relay Port to the TelescopeUsing Mechanical Relays Push to Make Switch Modification Joystick Modification Modular Family of CCD CamerasSystem Features 20.6x sizeum Focal length cm Camera Hardware Connecting the older model CFW-6 filter wheel to the Camera Battery Operation Page Terrestrial Imaging Advanced Imaging TechniquesLunar and Planetary Imaging Deep Sky ImagingTaking a Good Flat Field Changing the Camera ResolutionBuilding a Library of Dark Frames Flat Fielding Track and Accumulate Images Tracking Functions Advanced Imaging Techniques Page Cooling Booster Accessories for your CCD CameraAO-7 and Lucy-Richardson Software Tri-color ImagingCamera Lens Adapters and Eyepiece Projection Focal ReducersImage Processing Software Third Party Products and ServicesSGS Self-Guided Spectrograph Windows SoftwareSbig Technical Support Common Problems Common Problems Common Problems Page Glossary STV Glossary Glossary Appendix a Connector Pinouts Appendix a Connector ad CablesSbig Tracking Interface Cable TIC-78 Figure A1 CCD Connector for TIC Mating Cleaning the CCD and the Window Appendix C MaintenanceRegenerating the Desiccant Page Technique Appendix C Capturing a Good Flat FieldPage Index IBM PC Separations
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