Orion PARSEC 10100C User Manual

InStruCtIOn MAnuAl  
®
Orion Parsec Series  
Astronomical Imaging Cameras  
Parsec 8300C (Color) #52075  
Parsec 8300M (Monochrome) #52077  
Parsec 10100C (Color) #52078  
#52078  
Providing Exceptional Consumer Optical Products Since 1975  
Oriontelescopes.com  
Customer Support (800) 676-1343  
Corporate Offices (831) 763-7000  
89 Hangar Way, Watsonville, CA 95076  
© 2008-2011 Orion Telescopes & Binoculars  
IN 383 Rev. B 11/11  
table of Contents  
1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . 4  
1.1. The Parsec 8300 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4  
1.2. The Parsec 10100C. . . . . . . . . . . . . . . . . . . . . . . . . . . . 4  
1.3. Feature Highlights . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5  
6. Multiple Camera Control for Autoguiding. . . 34  
6.1. Autoguider Calibration . . . . . . . . . . . . . . . . . . . . . . . . . 34  
7. Other Features Of MaxIm Dl . . . . . . . . . . . . 37  
7.1. Information Window. . . . . . . . . . . . . . . . . . . . . . . . . . . 37  
7.2. Night Vision . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 37  
7.3. Observatory Control Window. . . . . . . . . . . . . . . . . . . . 38  
2. Getting Started . . . . . . . . . . . . . . . . . . . . . . . . 6  
2.1. Parts List. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6  
2.2. System Requirements . . . . . . . . . . . . . . . . . . . . . . . . . . 7  
2.3. Software and Driver Installation. . . . . . . . . . . . . . . . . . . 9  
8. tips . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 38  
8.1. Polar Alignment . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 38  
8.2. Choosing a Site for Astro-Imaging. . . . . . . . . . . . . . . . 39  
8.3. Using Focal Reducers and Barlow Lenses . . . . . . . . . 40  
8.4. Filters. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 40  
8.5. USB Extension Cable . . . . . . . . . . . . . . . . . . . . . . . . . 40  
8.6. Care and Maintenance . . . . . . . . . . . . . . . . . . . . . . . . 40  
3. Software Walk-through . . . . . . . . . . . . . . . . . 10  
3.1. The Camera Control Window . . . . . . . . . . . . . . . . . . . 11  
3.2. The Screen Stretch Window . . . . . . . . . . . . . . . . . . . . 14  
4. Astronomical Imaging . . . . . . . . . . . . . . . . . . 16  
4.1. Focusing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17  
4.2. Setting the Cooler . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19  
4.3. Imaging Deep Sky Objects . . . . . . . . . . . . . . . . . . . . . 20  
9. Specifications . . . . . . . . . . . . . . . . . . . . . . . . 42  
5. Image Processing . . . . . . . . . . . . . . . . . . . . . 26  
5.1. Image Calibration. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26  
5.2. Convert Raw to Color (For Parsec 8300C and 10100) 27  
5.3. Stacking – Combining Images. . . . . . . . . . . . . . . . . . . 28  
5.4. Filter. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32  
5.5. Color Balance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32  
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1. Introduction  
Welcome to the exciting world of astro-imaging. Your new  
Parsec Astronomical Imaging Camera is capable of captur-  
Tripod adapter  
ing professional quality astro-images of your favorite celestial  
objects. You can showcase spectacular images on your com-  
puter, share them on the internet, or print them. The camera’s  
large 8.3 mega-pixel array provides very high resolution imag-  
es which are great for publishing in large prints.  
LED 2  
LED 1  
Power port  
USB port  
Please read this instruction manual before attempting to use the camera or install  
the needed software. For the most detailed information on specific camera and  
software functions, consult the Maxim DL Help Topics included with the CD; the  
tutorials found there are especially useful for familiarizing yourself with the soft-  
ware and camera.  
Figure 1. Parsec ports and LEDs.  
1.3. Feature Highlights  
1.1. the Parsec 8300  
Simple interface: A USB port and power port are all that’s needed to  
The Parsec 8300 is a high resolution, 8.3 megapixel CCD with a dual-stage,  
regulated thermoelectric cooler to enable maximum imaging performance. Both  
the 8300M and 8300C are very sensitive and capable of detecting faint deep sky  
objects in a short exposure; and longer exposures can reveal extremely deep  
fields with subtle nebulosity and galaxies in the background.  
power and connect to the Parsec (Figure 1).  
Dual-stage thermoelectric cooler: Dramatically reduces thermal noise in  
all images.  
Regulated cooling: Enables you to set the exact temperature within the  
cooling range of the camera. This allows you to take calibration images like  
dark frames at the exact same temperature as your light frames, making for  
the cleanest images possible. Additionally, since you can match the CCD  
temperature at any time (within the range of the cooler), you have the freedom  
to take dark frames when it’s most convenient for you, so you don’t have to use  
up valuable imaging time to take dark frames.  
The unique versatility of the Kodak KAF8300 full frame CCD lets you take advan-  
tage of the densely-packed pixel array. 1x1 mode (3326 x 2504) utilizes the full  
resolution of the camera, providing the most detailed images and largest possible  
prints. Binning in 2x2 mode (1663 x 1252) increases the camera’s sensitivity and  
full well capacity (meaning it can collect more light) at the expense of resolution.  
Binning in 2x2 mode can be especially useful for longer focal length and higher  
focal ratio telescopes. Note that the Parsec 8300C model will not have any color  
in 2x2 mode.  
Regulated cooling fan speed: Three fan speed settings allow you to set  
the speed to your liking. High is the loudest but most effective setting.  
Shutter: A shutter is necessary for Kodak CCD chips, but it also enables  
you to automatically take dark frames without having to cap the front of  
your telescope. This is especially useful when taking autosave image  
sequences.  
1.2. the Parsec 10100C  
The 10.7 megapixel Parsec 10100C uses Kodak’s KAI10100 interline CCD. It has  
the same cooling system and architecture as the Parsec 8300, but with slightly  
faster data transfer to accommodate the higher number of pixels (3760 x 2840 in  
1x1, 1880 x 1420 in 2x2). Additionally the number of binning modes includes 1x1  
(full resolution), 2x2, 3x3, and 4x4.  
High speed USB 2.0 interface and internal memory buffer: The full  
frame 32 megabyte SDRAM on-board memory ensures a clean image  
download each time, even if the system resources of your PC are  
temporarily compromised. The high-speed USB 2.0 downloads the full  
frame within 15 seconds depending on your computer speed.  
This CCD chip offers the unique ability to image in color at 1x1 mode, as well  
as 2x2 mode. This is advantageous when imaging with different focal lengths. In  
general, the longer focal length telescopes (like RCs and SCTs) are more suited  
to image with in 2x2 for this particular CCD sensor, because the pixels are small.  
Imaging in 2x2 mode makes each pixel size the equivalent of 10.8 microns instead  
of 5.4 in 1x1 mode. Binning 2x2 with color cameras is normally captured in mono-  
chrome only. But the Parsec 10100C can bin 2x2 in color.  
Compact design: With a footprint of just 4" x 4" with 3" of depth, the  
Parsec easily fits into your imaging setup. The Parsec’s compact size also  
®
makes the camera suitable for Celestron Hyperstar or Fastar systems.  
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Parsec lED Status Indicators  
Hard carrying case  
lED 1  
lED 2  
Blink  
On/Idle  
Solid  
Off  
Exposing  
Reading  
Blink  
Solid  
Solid  
Solid  
Blink  
Parsec 8300  
Downloading  
Figure 2. The Parsec’s LED status indicators  
USB cable  
CD-ROM  
DC power cable  
with lighter plug  
2" nosepiece  
(camera ships with  
nosepiece attached)  
Figure 4. Parts list  
Figure 3.1. The shutter is free to move  
when the Parsec is off.  
Figure 3.2. The shutter resets its  
position and holds firmly in place when the  
Parsec is powered on.  
LED Status Indicator: Two LEDs on the Parsec indicate the camera  
power, exposure, image readout, and download (Figure 2)  
A note about the Shutter  
The Parsec’s leaf shutter moves freely when the camera is off.You may notice the  
shutter in an arbitrary position when removing the dust cap from the nosepiece  
(Figure 3.1). This is normal and does not affect operation in any way. Once the  
Parsec is powered on, current is applied to the shutter’s motor and the shutter  
position resets and firmly holds its place. (Figure 3.2)  
Figure 5.1. The Parsec fits into a 2"  
focuser, just like a standard 2" eyepiece.  
Firmly tighten the thumbscrew that secures  
the Parsec in the focuser.  
Figure 5.2. If your telescope has  
T-threads, remove the nosepiece from the  
Parsec and thread the camera directly  
onto the telescope. This provides the most  
secure connection.  
2. Getting Started  
2.2. System requirements  
telescope  
The Parsec can be used with most telescopes compatible with 2" format eyepiec-  
es. The camera is simply inserted into a focuser in the same way as a standard  
eyepiece (Figure 5.1). The camera is also compatible with 1.25" focusers that  
include camera T-threads, although some vignetting (edge darkening) may occur.  
2.1. Parts list (Figure 4)  
Parsec Astronomical Imaging Camera  
2" nosepiece (camera ships with nosepiece attached)  
USB cable  
Caution: Be sure to always firmly tighten the thumbscrew(s) that secure the  
Parsec in the telescope focuser, or it could fall out and onto the ground!  
DC power cable with lighter plug  
CD-ROM  
If your telescope has T-threads for direct camera attachment, a more secure con-  
nection can be made. First, unthread the nosepiece from the Parsec camera body.  
This exposes the camera’s T-threads. Then, simply thread the camera onto your  
telescope (Figure 5.2).  
Hard carrying case  
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The camera’s pixel size and sensitivity make the Parsec suitable for most tele-  
scopes. For telescopes with very long focal lengths (2000mm and greater), you  
can optionally bin 2x2 (see section 2. Astronomical Imaging) to utilize greater  
sensitivity and obtain sharper images at the expense of resolution. Note that the  
Parsec 8300C (color) camera will lose its color information if binning in 2x2.  
Imaging in the field usually requires the  
use of a portable field battery to sup-  
ply power, or you can use a 110VAC  
to 12VDC power converter if you have  
access to an AC outlet. Make sure  
the power supply provides at least 2  
amperes of current. This allows the  
Parsec TEC to use 100% of its potential  
cooling power.  
Because the Parsec uses a larger format CCD chip, a telescope with a 2"  
focuser is recommended to for full field illumination. You can still use the  
camera with a 1.25" focuser if it has optional T-threads; however, some vignetting  
(edge-darkening) may occur in the images.  
Backfocus requirement  
The Parsec requires 29.24mm (1.151") of backfocus. This is the distance from the  
front of the T-threads to the CCD sensor.  
2.3. Software and Driver  
Installation  
Before the camera can be used, the  
software and camera drivers must be  
installed onto your computer. Turn on  
your computer and allow the Windows operating system to load as normal. Insert  
the included CD-ROM into your computer’s CD-ROM drive, and the Launcher  
will appear. This allows you to install the Maxim DL software. After the software is  
installed, the drivers will install automatically once the Parsec is initially connected  
to the computer. Do not connect the camera to your computer before you have  
installed the software.  
Figure 6. The Launcher provides an  
easy menu for software installation.  
Mount  
Deep sky imaging with the Parsec requires an equatorial mount with a right ascen-  
sion (R.A.) motor drive. The goal for your mount is to seamlessly track the appar-  
ent movement of the sky as the Earth rotates. The tracking must be very accurate,  
or the object you want to image will drift and blur across the camera’s field of view  
while the exposure is taken. Even a small amount of drift will cause a star to look  
oblong instead of a round point. We recommend using a high-quality equatorial  
mount which utilizes periodic error correction (PEC) or has the ability to interface  
with an autoguider.  
Software and  
Driver Installation  
To install Maxim DL:  
Computer  
The Parsec requires a PC to operate the camera. For astro-imaging in the field at  
night, a laptop computer is highly recommended. The included software is Maxim  
DL which requires Windows XP, or Windows Vista operating systems.  
1. Insert the CD-ROM into the drive. The Launcher will appear (Figure 6). (For  
Windows 7 and Vista computers, the AutoPlay window will appear first.  
Select Run Launcher.exe, then the Launcher will appear.)  
The following hardware is also required:  
Processor – 700 MHz speed or higher, Pentium III equivalent or higher  
2. Click Install MaxIm DL  
Recommended minimum memory size is 512 MB.  
3. The Install Shield Wizard will start. Click Next.  
Disk Space – 380 MB for software installation, 1GB or more to store  
images is recommended.  
4. Read the Maxim DL License Agreement. If you agree with the terms, then  
select I accept the terms in this license agreement and click Next.  
Video Display – 1024 X 768 or higher, 16-bit color or higher.  
Mouse  
5. Click Install. The installation will proceed.  
6. The installation is now complete. Click the Finish button. Do not open MaxIm  
Internet Explorer 4 or higher required to display on-line help  
High-speed USB 2.0 port  
DL yet.  
Camera Driver  
Installation  
Power  
Now that the software is installed, the camera driver must also be installed. You  
must connect power to the camera and connect the USB cable from your camera  
to the computer before starting MaxIm DL, or the software and computer will not  
recognize the camera.  
The Parsec requires 12 volts DC (12VDC) with approximately 2 amperes of cur-  
rent. Power to the entire camera, including the thermo-electric cooler (TEC), and  
fan is supplied by the included power cable when plugged into a 12VDC power  
source.  
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For the most detail regarding all of the  
features in MaxIm DL, please con-  
sult the comprehensive help tutorial  
in MaxIm’s Help Topics. The following  
section of the manual will walk you  
through the basic features mostly found  
in the Camera Control Window.  
The Parsec includes a free 60-day trial  
of MaxIm DL 5 Pro. Start by opening  
MaxIm DL, and you will be prompted  
with the User Registration window  
which requires your license informa-  
tion (Figure 8). Refer to the registration  
label on the envalope of your software  
CD and enter the information exactly  
as it is shown on the label. Once your  
information is entered correctly, the OK  
button will become available, click OK  
to proceed. You will only have to enter  
your software license once.  
Figure 7. Access the Camera Control Window from the View menu, or pressing Ctrl +  
Figure 9.1. The Setup tab in the  
Camera Control Window.  
W, or selecting the icon.  
to install the camera driver:  
1. Insert the CD-ROM into the  
computer. The Launcher will  
appear (Figure 6). (For Windows 7  
and Vista computers, the AutoPlay  
window will appear first. Select  
Run Launcher.exe, then the  
Launcher will appear.)  
Figure 8. User Registration Window.  
2. In Launcher screen, select Install  
FTDI. This installs the driver files  
for the Parsec camera.  
3.1. the Camera Control  
3. Connect the Orion Parsec to a USB port on the computer with the supplied  
USB cable.  
Window  
Figure 9.2. The More/Less button  
reveals more detailed information about  
the camera status, such as the cooler  
temperature, exposure progress, and more.  
The Camera Control Window con-  
trols your Parsec camera, as well as  
your autoguider if you are using one.  
The window has three tabs, Expose,  
Guide, and Setup.  
4. Plug the supplied power cable into a 12VDC power source and connect the  
cable to the Parsec. LED status indicator and cooling fan will automatically  
power on. Windows will automatically detect the camera and install it  
onto your computer. Wait for the message to appear, Device Installed  
Successfully.  
To access the Camera Control Window, Open MaxIm DL and go to View, then  
select Camera Control Window, or you may click on the icon found in MaxIm  
(Figure 7) or press Control + W.  
Note: Your computer must have a high-speed USB 2.0 port available. If your  
computer has multiple USB ports, you will need to install the driver again if the  
Parsec is connected to a different USB port.  
the Setup tab and Connecting the Parsec (Figure 9.1)  
We recommend selecting More on the bottom right of the Setup (Figure 9.2) tab  
which will reveal more information such as the cooler status, exposure progress,  
and more.  
The Parsec uses FTDI drivers which are WHQL certified by Microsoft for both  
32-bit and 64-bit Windows operating systems including Windows XP, Vista and  
Windows 7. We recommend regularly checking www.ftdichip.com/Drivers/  
D2XX.htm for updates.  
Camera 1 should be used for your Parsec. Camera 2 should be used for your  
autoguider if you are using one.  
3. Software Walk-through  
To connect your Parsec camera to MaxIm DL.  
MaxIm DL 5 is a powerful imaging program which offers complete control for your  
Parsec camera, autoguider, telescope, and imaging accessories such as a motor-  
ized filter wheel and focuser. In addition to controlling your camera and accesso-  
ries for image capture, MaxIm DL also provides all the necessary processing tools  
to assemble your astro-image.  
1. Plug the Parsec into your computer’s USB port.  
2. Plug the power cable into the Parsec, with your 12VDC power source already  
connected. The cooling fan and LED status indicators will automatically  
power on.  
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Figure 11. The Expose tab using the Exposure Preset default settings in Find Star.  
Figure 10. Select Orion Parsec in the pull down menu.  
telescope’s focus and adjust the  
exposure time as needed to get a  
focused image.  
3. In the Setup tab in MaxIm DLs Camera Control Window, select Setup  
Camera. Locate the Orion Parsec in the dropdown list and click OK  
(Figure 10).  
4. Look at the Pixel value in the  
Information window while the  
mouse cursor is over the image.  
The Pixel and Average value  
should be well below 50000  
4. Click Connect and your Parsec will connect to MaxIm DL.  
the Expose tab and taking your First Parsec Image  
We recommend becoming familiar with the Parsec during the day. Connect the  
camera to your telescope and focus on an object ¼ of a mile away. If you do not  
have enough outward focus travel to focus this closely, you may need an extension  
tube (available from Orion).  
or your image is overexposed  
(Figure 12). If you cannot get the  
Pixel value low enough during  
Figure 12. The Information window  
displays detailed information about the  
image, including the Pixel count which can  
indicate if the image is overexposed.  
the day, you will need to reduce  
the aperture of your telescope by  
creating an aperture mask.  
In the Expose tab:  
1. Select Find Star in Exposure Preset (Figure 11). Use the default settings  
and notice that X Binning/Y Binning is set to 2/Same. This cuts the  
resolution to 1/4 and speeds up the download time while making initial  
focusing easier to obtain.  
5. You may change the Binning X/  
Binning Y to 1x1. For the Parsec  
8300C, set the Frame Type to Color.  
2. Reduce the exposure Seconds to 0.1.  
Note: Any time a setting is changed in the Exposure Preset, a * will appear next  
to the preset name indicating the settings are different than the default. Click the  
3. Click Expose and you will hear the shutter. Wait a few seconds for the  
image to appear. It may be over exposed or grossly out of focus. Adjust the  
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13  
arrow button next to the preset name to  
manage your presets, including Update  
Current Preset, and Save As New  
Preset. See MaxIm DLs Help Topics  
for more detailed information.  
readout Mode  
In the Expose Tab, select Normal for  
the best image quality, and Fast for a  
quicker image download.  
Range of brightness levels  
Figure 13. The Screen Stretch  
Window is a histogram that allows you to  
adjust the apparent brightness levels of an  
image on your screen.  
Frame type  
Choose, Light (Raw or Color for the  
8300C), Bias, Dark, and Flat. Please  
read section 5, “Astronomical Imaging”  
to determine when and why to take a  
dark or flat.  
Fan Speed  
Select Camera Settings in the Expose tab (Figure 14.1) to access the fan speed,  
High, Medium, or Low (Figure 14.2). High is recommended for the best cooling  
performance.  
Figure 14.1. The Camera Settings is found in the Expose tab.  
Maximum and Minimum values is to  
move the slider arrows located directly  
under the histogram of the image in the  
Screen Stretch Window. The red slider  
arrow corresponds to the Minimum  
value and the green arrow corresponds  
to the Maximum value. Simply left-click  
and then drag each arrow to adjust it  
There are a large slew of settings in the Camera Control Window’s Expose tab.  
Please read MaxIm DLs HelpTopics which covers all the settings in greater detail.  
3.2. the Screen Stretch Window  
The function of the Screen Stretch Window (Figure 13) is to properly map the  
image brightness levels captured by the camera into corresponding image bright-  
ness levels on the computer screen. A typical camera image has each pixel (light  
detecting site, over eight million pixels form a single Parsec image) represented  
as a number (from 1 to 65535) depending on brightness. This has to be mapped  
into the video monitor’s brightness range (from 1 to 255). It is important to set the  
screen stretch appropriately, or a great image may look terrible!  
Figure 14.2. Adjust the Fan Speed in  
the Parsec Settings.  
to the desired level. The best results  
are obtained by adjusting the arrows  
(numbers) until the most pleasing dis-  
play appears.  
When an image is displayed, you will notice a graph in the Screen Stretch  
Window. This is called the “histogram” of the currently displayed image. A histo-  
gram is a simple bar graph that shows the range of brightness in an image. Each  
bar in the graph represents a level of brightness; the bar to the far left in the histo-  
gram represents the dimmest pixels, and the bar to the far right is for the brightest  
pixels. The height of the bar is the total number of pixels at that brightness level  
in the image. Every image has a different histogram depending on how much of  
the image is bright or dark. Directly viewing the histogram of your image in the  
Screen Stretch Window provides an easy interface for making decisions on how  
the screen stretch should be set.  
There are also seven automatic settings in the Screen Stretch Window. Typically,  
Medium will give good results for deep sky objects, so the default screen stretch  
setting is Medium.  
Instead of using the Screen Stretch Window, it is faster to use the Quick Stretch  
facility. This allows you to modify the image appearance instantly with small up/  
down and left/right movements of the mouse. To do this, hold down the Shift key,  
then left-click and drag the mouse on the image. You’ll find this feature to be a  
great convenience when fine adjusting the screen stretch to get an image to look  
its best.  
The trick with stretching is determining exactly how to stretch the image for best  
effect. Often there are several different possibilities for the same image. Trial-and-  
error will be the best way to judge what the best screen stretch setting is. Try  
In Maxim DL, the two parameters entered in the Screen Stretch Window are  
Minimum and Maximum.A pixel that is at the Minimum value is set to zero (black),  
and a pixel at the Maximum value is set to 255 (white). An easy way to adjust the  
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4.1. Focusing  
Focusing the CCD camera is one of the most critical parts of imaging. It can be  
challenging, but MaxIm DL has some helpful features which will assist you when  
focusing your Parsec. Before focusing, make sure your mount is polar aligned and  
tracking.  
For best results, we recommend focusing on a star at least 30° above the horizon  
(or higher). Follow these steps to achieve an accurate focus:  
1. Find and center a moderately bright star through your finder scope. Try to  
find a star around magnitude 4 or 5. If you are not using an optical finder  
or just using your unaided eye, the star should look relatively faint. This is  
important because brighter stars will easily over saturate the camera and  
compromise the focus accuracy.  
2. Center your telescope on the star using an eyepiece. Make sure the right  
ascension (R.A.) tracking motor is engaged on your mount.  
3. Replace the eyepiece with the Parsec.  
4. Set the Exposure Preset to in the Camera Control Window’s Expose tab  
to Focus.  
5. Click the Expose button. You should see the out of focus star in the image. If  
you do not see anything, you need to increase the exposure time.  
6. Check that the Subframe section has both the On and Mouse boxes  
Figure 15. Subframe around the star you want to focus on by drawing a box around it  
with your mouse.  
checked on.  
7. Draw a small box around the unfocused star with your mouse (hold-click and  
drag the mouse cursor around the star to draw the box, Figure 15).  
several different settings until you find one you think looks best. When the image  
is subsequently saved, the screen stretch setting information will be kept when  
the image is next opened. Feel free to adjust the Screen Stretch settings all you  
want; it will not effect the image data you captured and only effects how the image  
is displayed.You can always switch back to a preset setting, like Medium or Moon.  
8. In the Expose tab, towards the right, select Continuous. Click Expose. The  
camera will only download the area you previously selected, which makes  
each image download significantly faster than the whole frame.  
Note: If the Parsec is grossly out of focus, no object will appear in the image, not  
even a blur. Increase the exposure time if needed and patiently move through the  
focus range of your telescope until you see the centered star come into view.  
4. Astronomical Imaging  
Now that you’re familiar with basic camera and software operation, it’s time to take  
the Parsec out at night under the stars to capture some astronomical images. We  
recommend starting with the Moon, as it is easy to acquire into the camera’s field  
of view, and typically does not require stacking multiple exposures like planetary  
and deep sky images do.  
1. Gradually adjust the telescope’s focuser inward until the star visually comes  
to a small point on your computer screen. You have achieved a rough focus.  
Some small adjustments remain to get a perfect focus.  
2. Click the Stop button.  
3. Set Seconds somewhere between 0.1 and 3 seconds (or longer for fainter  
stars), depending on the brightness of your star.  
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a fainter star. Paying attention to  
these values will help you get a  
very accurate focus, far better than  
simply looking at the star image on  
your screen.  
7. Click Stop once you reach the  
best focus and click Reset in  
the Subframe section at the  
bottom of the Camera Control  
window. Before proceeding to take  
images, switch back to the desired  
Exposure Preset.  
Figure 17.1. Turn the Coolers on.  
Note: Due to atmospheric seeing condi-  
tions, you may notice significant fluctu-  
ation in the FWHM and Max Pixel val-  
ues while focusing. You typically have  
to take multiple exposures each time  
you adjust the focuser to determine the  
quality of your focus.  
Caution: Once you have achieved  
focus, be sure to click the Reset but-  
ton in the Subframe box, otherwise the  
camera will crop all your images into a  
small square!  
Figure 17.2. Establish a Setpoint(C)  
you wish to set the CCD temperature to.  
Figure 16.1. Select Display Large Statistics in the Expose tab.  
4. Click Expose.  
5. Carefully watch the FWHM and  
Max Pixel values in the Camera  
Control Window. If you are stand-  
ing several feet from your laptop  
while focusing, check the Display  
Large Statistics option in the  
Expose tab (Figures 16.1 and  
16.2). The FWHM (Full-Width Half  
Maximum) indicates the diameter  
of the star. The Max Val is the  
brightness value for the bright-  
est pixel in the star. The smaller  
the FWHM, and the larger the  
4.2. Setting the Cooler  
The Parsec can cool the CCD to more than 35°C below the ambient tempera-  
ture. But remember that the ambient temperature changes and you want to have  
enough cooling capacity to take dark frames at the same temperature later.  
To set the cooler:  
1. Connect the Parsec camera with MaxIm DL in the Camera Control  
Window’s Setup tab.  
2. In the Camera Control Window’s Setup tab, click On under the Coolers  
box (Figure 17.1).  
3. Click Cooler under the Camera 1 box and enter the Setpoint(C) you wish  
to cool the CCD to (Figure 17.2). Keep in mind the cooling range of the  
camera which is MAX 30-40°C below ambient depending on fan speed. The  
Setpoint(C) is the absolute temperature, so this will be the actual target  
temperature of the CCD camera. If you set the temperature to -10°C, the  
CCD chip will literally cool to 10 degrees below zero Celsius.  
Figure 16.2. The Focus Statistics offer  
Max Pixel, the closer you are to  
focused.  
a convenient way to easily monitor your  
focusing while standing at the telescope  
several feel away from your laptop.  
6. Adjust the focus as needed to get  
the smallest FWHM and largest  
Max Pixel possible. The Max Pixel  
4. Click More/Less on the bottom right of the Camera Control Window to  
should stay well below 50000, as this approaches saturation. If the Max  
Pixel approaches 40000-50000, reduce the exposure time or try selecting  
monitor the cooling status. After a couple of minutes the Cooler Power  
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Figure 18.1. The Autosave Setup window sets all of your options to autosave your  
image in a sequence.  
sures of 60 seconds or more also require autoguiding with a separate camera.  
The Orion StarShoot AutoGuider can be operated with the Parsec in MaxIm DL.  
To start:  
1. Acquire and center the deep sky object into the field of view of your  
eyepiece. If you are using a mount with an accurate computerized go-to  
system, you can keep the camera installed in your telescope’s focuser  
without using the eyepiece.  
Figure 17.3. Monitor the Cooler Power, Sensor Temp, and Setpoint and make sure  
they reach your goals.  
2. Remove the eyepiece and replace it with the Parsec.  
3. Set the Exposure Preset to Focus and precisely focus the camera. If  
necessary, move the telescope to a nearby star to determine the best focus.  
For best results, when using the Parsec 8300C, select Light Raw for Frame  
Type so you can properly calibrate your astro-images later, see section  
5, “Image Processing”. For Parsec 8300M users, simply choose Light for  
Frame Type.  
should drop below 100% (Figure 17.3). If the Cooler Power does not drop  
below 100% after a couple of minutes, you will need to raise the Setpoint.  
5. Monitor the Sensor Temp and Setpoint and make sure they match. If the  
Senor Temp is higher than the Setpoint, you will need to raise the Setpoint.  
We recommend keeping the Cooler Power to about 80% (or less) for the best  
performance while still having the ability to match the temperature later if needed.  
Pushing the cooler to near 100% will hinder the accuracy if your dark frames if the  
dark frame temperature does not match your light frame.  
4. In the Expose tab, set Seconds to 10-20 and click Expose. After the image  
downloads check to see if the deep sky object is centered well in your  
camera. Adjust the camera orientation if needed, keeping in mind that you  
may have to refocus the camera after making the adjustment. Reposition the  
telescope if needed to center the deep sky object.  
4.3. Imaging Deep Sky Objects  
Capturing impressive images of deep sky objects, such as galaxies, nebulae, and  
star clusters, require relatively long exposures. You will take several individual  
images and stack them together to form one high-quality resultant image.  
5. Set the Exposure Preset to LRGB, even if you are using the Parsec 8300C.  
You can always rename the Exposure Preset with your custom settings.  
6. Click the Autosave button, and select your exposure times, and frame type  
Very accurate polar alignment is essential for deep sky imaging. Stars will streak  
across the field of view without precise polar alignment and tracking. Longer expo-  
(Figure 18.1).  
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Figure 18.2. Select Set Image Save Path.  
7. Select the file folder in which you  
would like to save the images with  
Select Image Save Path found by  
clicking the arrow in the Autosave  
Setup window (Figure 18.2)  
and set the name of the file in  
Autosave Filename. Typically the  
name of the object being imaged,  
such as “OrionNebula1”, will be  
entered here. If “OrionNebula1”  
is the Autosave Filename,  
and you choose to save five  
images, then the images will  
appear in the selected file  
Figure 20. Set the Type to Dark in the Autosave Setup window.  
(background noise level), read noise (noise introduced during camera readout and  
download) and hot pixels (bright dots in the image). All of this noise exists in your  
raw astro-image too, which distracts from the detail you want to see.  
To eliminate most of the camera noise, you can take several dark frames, average  
them, then subtract them from your astro-images, also called, “light” images.  
Note: Make sure the cooler set point and CCD temperature are the same as they  
were when you took your light frames.  
To take dark frames for subtraction from “light” images:  
1. Set the Frame Type in the Camera Control Window’s Expose tab to Dark.  
Or if you are taking a sequence of images, set the Type in the Autosave  
Setup window to Dark (Figure 20). Even though MaxIm DL will already know  
which of your images are dark frames, it’s a good idea to assign a preset,  
such as D to better organize your different images.  
Figure 19. A dark frame contains the  
thermal and background noise, as well as  
any read noise. The same noise appears  
in your “light” images. Dark frames isolate  
the noise so it can later be subtracted from  
your “light” images.  
folder as “OrionNebula1_0001.  
fit”, “OrionNebula1_0002.  
fit”, “OrionNebula1_0003.fit”,  
“OrionNebula1_0004.fit”, and  
“OrionNebula1_0005.fit”. Try  
exposures of 30-60 Seconds to  
start.  
Note to Parsec 8300C and 10100 users:You must take Raw Light frames in mono-  
chrome BEFORE converting to color in order to utilize dark frames.  
2. Use the same exposure time as the “light” images you have or will take. If  
your “light” image is 60 seconds, the dark frame must also be 60 seconds.  
8. Click Expose, and the camera will commence taking the images.  
3. Set the number of dark frames you would like the camera to take under (3 to  
10 will generally suffice, as these will be averaged together).  
Note: When the camera is taking long exposure images, it is critically important  
not to touch, shake, or otherwise disturb the telescope, or a blurred image will  
result. Also, make sure no surrounding light shines into the telescope during the  
exposure.  
4. Click OK, and proceed to click Expose in the Expose tab. Since the Parsec  
has a shutter, you to not need to be present when the dark frames are taken,  
it will occur automatically during the sequence!  
Dark Frames  
Dark frames are images taken with no light coming into the camera. A dark frame  
is typically taken with the telescope’s objective capped. The only data in the image  
is the inherent camera noise (Figure 19). The noise contains the dark current  
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2. Point the telescope at a uniform and featureless light source, like the sky  
at dusk or dawn, or a blank white sheet of paper. Make sure the camera  
orientation is exactly the same as it is or was for astro-imaging (Although the  
telescope is pointing at a featureless surface, the focus and orientation must  
be set as it normally would be for astro-images.)  
Flat Fields  
A flat field is an image taken with  
uniform featureless light entering the  
telescope, such as a blue sky in the  
early morning or after sunset. Flat fields  
solve a number of issues in your astro-  
images.  
3. Set the Frame Type in the Camera Control Window’s Setup tab to Flat.  
Or if you are taking a sequence of images, set the Type in the Autosave  
Setup window to Flat. Even though MaxIm DL will already know which of  
your images are flat frames, it’s a good idea to assign a preset, such as F to  
better organize your different images.  
Vignetting  
Vignetting (Figure 21.1) in a telescope  
reveals edge-darkening in the astro-  
image. The large CCD chip in the  
Parsec can easily detect vignetting  
through almost any telescope, even  
specialized astrographs. Vignetting is  
more apparent when the telescope’s  
illuminated field is not large enough to  
illuminate the full area of the CCD chip.  
As a result, more light is detected in  
the center of the image compared to  
the edge.  
Figure 21.1. Larger format CCD  
cameras like the Parsec reveal vignetting  
through most telescopes. Vignetting occurs  
when the edge of the image plane has less  
illumination than the center.  
4. Set the Seconds to 0.1 for now and click OK, then Expose. You want the  
Max Pixel to read somewhere around 20000. Adjust the exposure time  
as needed until the Max Pixel is close to 20000. It’s a good idea to take  
several flat frames and try different exposure times until you find the correct  
exposure. If you are taking your flats near dusk or dawn, the sky brightness  
will changes rapidly.  
The flat fields also need dark frames.  
5. Add another Slot sequence in Autosave Setup and select Dark under Type.  
Select the same exposure time as your flat and assign a prefix such a FL.  
6. Click OK then Expose. Note that you can set all of your lights, darks, flats,  
and dark flats at the same time in the Autosave Setup window to make the  
sequence faster and more convenient. Once you get used to all of these  
features, you will be able to set all of the frames you want in Autosave  
Setup window without having to go back to add more frame types.  
Dust and Particles  
Dust and particles (Figure 21.2) will  
inevitably show up in your raw astro-  
images. Large particles on the CCD  
optical window sometimes look like  
unfocused circles or doughnuts in your  
images. It’s too late to clean your cam-  
Figure 21.2. Dust or other particles on  
the camera’s optical window can show up  
as distracting dark shapes in your images.  
light and Dark 2x2 Modes  
For added convenience and versatility, the Parsec’s individual pixels (light-  
detecting sites) can be “binned” into units of two-by-two pixels (i.e. four individual  
pixels create one binned 2x2 pixel). This creates larger and more sensitive pixels,  
but with decreased resolution. This can be useful for some types of astronomical  
imaging, such as capturing faint nebulae. It can also be useful for quickly check-  
ing the image centering and orientation before using the full resolution to actually  
capture images.  
era if you are already imaging in the field at night. And even when the camera is  
clean, dust usually finds a way to show up in your images.  
Telescope Artifacts  
Very large particles or other artifacts in your telescope can effect your astro  
images. Insufficient telescope baffling or poor collimation can also cause unsym-  
metrical field illumination in your images.  
To use in “2x2” mode, select X Binning/Y Binning to 2x2/Same.  
To take a flat field image:  
Note to Parsec 8300C users: By binning the images in 2x2, you will bypass the  
RGB filter built into the camera; so the resulting binned images will be black and  
white, without the ability to convert to color.  
1. Ensure that the telescope is focused and ready for astro-imaging.  
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Figure 22.1. Before your images are  
combined, an individual deep space image  
will have more noise and less detail.  
Figure 22.2. Combining multiple deep  
space images greatly increases the detail  
in the resulting combined image  
Each individual deep sky image is faint and has a noticeable amount of noise.  
Combining the individual deep sky images eliminates the noise and enhances the  
detail in the deep sky object by improving the signal to noise ratio.The more imag-  
es you combine, the better the resulting image will look. (Figures 22.1 and 22.2).  
Read section 5 “Image Processing” to utilize MaxIm DLs Stack function.  
5. Image Processing  
After you have captured and combined individual images (with or without dark  
frame subtraction) into a single resultant image, you may want to perform some  
additional image processing to bring out subtle details or to make the image  
appear more pleasing overall. MaxIm DL contains several image processing func-  
tions which will further enhance your image once your individual images have  
been calibrated and combined. The image processing functions are found in the  
Process menu.  
Figure 23. The Set Calibration window lets you automatically select all of your  
calibration images.  
5. Click OK.  
6. With your astro-image open in MaxIm DL, select Calibrate from the Process  
menu (or click the Calibrate icon in MaxIm DL) You should see a significant  
amount of noise disappear. This process can be automated for all of your  
light images, see “Stacking – Combining Images”.  
5.1. Image Calibration  
The darks and flats you previously saved will be subtracted from your “light”  
images.  
1. Select Setup Calibrate from the Process menu.  
5.2. Convert raw to Color (For Parsec 8300C and 10100)  
2. Click Clear All Groups if any filenames appear in the window.  
3. Select the Source Folder where you saved your dark frames (Figure 23)  
Once you have calibrated your images, you need to convert them to color:  
1. Open the raw images you wish to convert to color. If you need to convert  
more than 5 images or so, please refer to “Batch Processing” as this method  
allows you to combine an unlimited number of images without consuming  
more memory from your computer.  
4. Click Auto-Generate and MaxIm DL will automatically find all of your  
calibration images such as darks and flats. The selected dark frames will  
now appear in the pop-up window.  
2. Select Convert Color in the Process menu.  
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6. The Tree View on the left side of  
the Stack dialog will now show all  
the image files you have selected,  
arranged into groups according to  
their FITS header. You can open  
the groups to view the files by  
clicking on the + sign. If you would  
like to view an individual file, right-  
click it and select Display Image.  
Alternatively, using the right-click  
menu select Auto Display, and  
any image you click on will be  
automatically displayed.  
3. Select Orion Parsec High Quality  
in the Select Camera pull down  
menu (Figure 24).  
4. Click OK and the image should  
appear in color. You can make  
several adjustments to the Color  
Balance if needed (see “Color  
Balance”).  
5.3. Stacking –  
Figure 26. Filter Channels.  
Combining Images  
Combining individual deep sky images  
enhances the detail in the deep sky  
object by improving the signal to noise  
ratio.  
7. If necessary, you can move images  
or entire groups by dragging  
them. You can set properties for  
groups or individual files using the  
right-click menu.  
We will demonstrate stacking LRGB  
images; however, a similar process  
works for monochrome, one-shot color,  
and RGB image sets.  
Figure 24. The Convert Color window  
converts raw images taken from the Parsec  
8300C to color.  
8. Select the Quality tab (Figure  
27). If you would like to eliminate  
images with out-of-round stars  
caused by bad tracking, turn on  
the Roundness check box. The  
Threshold should be set to limit  
how far out of round the star can  
be; for example, 0.1 will throw out  
any image with stars that are more  
than 10% out of round. Click the  
Measure All button, and any bad  
images will automatically receive  
an X in the enable box. You can  
manually override this decision if  
you like, by changing the enable  
box.  
1. Select the Process menu Stack  
command (Figure 25)  
2. On the Select tab, turn on  
Classify by OBJECT and FILTER.  
Figure 27. The Stack window  
can measure the image quality and  
automatically reject the ones which are not  
good enough to combine.  
3. Click the FILTER button to set  
up the filter mapping. This will  
determine what filters are mapped  
into which LRGB color channels.  
To change a row, click once on  
the row, then click once on the  
Filter Color item, and enter a new  
value. This will make sure that your  
filters are automatically assigned  
to the correct group (Figure 26).  
Figure 25. The Stack window is a  
powerful feature which automatically  
calibrates, sorts LRGB filtered images, and  
combines your astroimages.  
9. Select the Align tab (Figure 28).  
If your images have been solved  
using PinPoint Astrometry you may  
wish to use the Astrometric align  
mode, which is extremely accurate.  
Alternatively, the Auto Star  
4. If your images have not yet been  
calibrated, turn on Mark added  
images as Auto Calibrate. Each  
image will automatically be calibrated as it is needed, using the settings from  
the Set Calibration command.  
5. Click the drop list on the multi-function button and select Add Folder.  
Browse to a folder on disk where your images are located. This folder may  
contain images of several different targets, as long as the OBJECT FITS  
keyword is set in each image (during imaging, this is automatically obtained  
from the Observatory Control window if a telescope is connected).  
Matching mode is fully automatic  
and quite accurate. There are a  
variety of other alignment modes  
available, including manual  
Figure 28. The Align tab can  
automatically align (register) your  
images by using Auto Star Matching or  
Astrometric functions.  
alignment.  
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29  
10. You can select one of the images  
to be the Reference Image,  
command before opening them with the Open command. Alternatively, you  
can simply drag and drop them from Windows Explorer onto the MaxIm DL  
window.  
using the right-click menu. This  
image will not be shifted during  
alignment; all other images will be  
aligned to it. If you do not select  
the reference image, the first  
image in the list will be used.  
Tip: Once you have all the settings the way you like them, you can simply dump  
in the images and click the Go button.  
You can also drag-and-drop images onto the Tree View from the Windows  
Explorer, or select files individually.  
When you use the Add Folder option calibration files are automatically ignored;  
the other methods for adding files will include them. Usually you don’t want to  
stack the calibration files automatically, since the Set Calibration command does  
that for you with proper normalization, etc.  
11. Select the Color tab (Figure 29).  
If you wish to customize the color  
balance settings you may do  
so; otherwise click the Defaults  
button, which assumes 1:1:1  
color balance. Also turn on Auto  
equalize background to remove  
any background color cast due to  
sky glow.  
There are several methods that will achieve slightly different results when stacking  
images, such as, Average, Sum, Median, and Sigma-Clip. Each of these meth-  
ods will improve your image buy stacking it, but each one combines the images  
in different ways.  
Figure 29. The Color tab.  
1. Average sums all the pixels and divides by the number of images chosen to  
12. Select the Combine tab and set  
the Combine Method (Figure  
30). For large numbers of images  
we recommend using Sigma  
Clip; a Sigma Factor of 3 is a  
good starting point. If you have a  
modest number of images the SD  
Mask mode will produce a better  
result (but will take more time); a  
good starting point for the settings  
is a Sigma Factor of 0.5 and a  
Number of Passes of 3.  
combine.  
2. Sum adds up all the pixels in the images. This will increase the Max Pixel  
value and the offset in the Screen Stretch window. If you Sum the image,  
the file should be saved as a fit in IEEEFloat (beyond 16 bits) to preserve all  
the data in the image.  
3. Median takes the middle pixel value from all of the images. The Median  
mode is useful when some pixels are extremely bright or dark (hot/dark  
pixels, cosmic ray hits). If Median mode is used, a Normalize option is  
available. Normalize will remove differences in the image scaling which  
could interfere with the median processing.  
Figure 30. The Combine tab lets you  
select the different combine methods such  
as SigmaClip or Average.  
4. Sigma-Clip combines the best features of Average and Median. Sigma-  
Clip is the best choice for removing unwanted noise, hot pixels and satellite  
trails. It works like Average but also calculates the standard deviation of the  
averaged pixel values. The Sigma Factor will determine how many pixels  
from the standard deviation are discarded. The lower the Sigma Factor, the  
more pixels are discarded. 3.0 is a good value to start with. A new average  
is calculated without the discarded pixel. This value is assigned to the  
corresponding pixel in the output image.  
13. Be sure to turn on Ignore Black  
Pixels. If there are any areas  
where the images do not completely overlap, this will ignore the contribution  
from the missing data. Otherwise you may get strips across the edges of the  
image that look dimmer.  
14. Set Normalization to Linear and set Area to 50%. This setting assumes that  
any changes in intensity between the images are due to extinction rather  
than changes in background level. If you have strong background level  
changes you may want to use Delta-Level instead.  
5. SD Mask is a custom variation on Sigma Clip contributed by Ray Gralak.  
This is an iterative algorithm that more effectively removes outlier pixels  
while preserving “good” pixels. It is most useful when the number of images  
available is too small for effective use of Sigma Clip.  
15. Select whether you want the results created as new images or written to a  
disk folder using the commands in the Options menu.  
6. Drizzle is a method intended for combining undersampled, dithered  
images developed by Andy Fruchter (Space Telescope Science Institute)  
and Richard Hook (Space Telescope European Coordinating Facility). This  
process, formally called Variable-Pixel Linear Reconstruction, can restore  
16. Click Go to start the stacking process. This may take some time; you can  
interrupt and restart the process if needed. If you have multiple image  
groups, they will be stacked separately. Color sets will automatically be  
color combined. To view results written to a folder, you must close the Stack  
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31  
detail finer than the pixel size of  
the frames being combined. The  
technique is described at http://  
xxx.lanl.gov/abs/astro-ph/9808087.  
the Preview Image to see how altering these parameters will affect your image  
(or click the Full Screen button to see the changes applied to your full image).  
Note for the Parsec 8300M: Before any color balance adjustment can be made,  
you must first Combine Color to each individual LRGB or RGB images.  
Color images from CCD cameras typically require a background level adjustment.  
This is accomplished by bringing the background level (or bias) in each color plane  
down to zero. Each of the Background Level values is subtracted from every  
image pixel in its color plane. Any pixel values that become negative are forced to  
zero. The Auto button automatically determines the settings necessary to equal-  
ize the image background in all three color planes. The Reset button resets the  
background level subtraction to zero on all planes.  
5.4. Filter  
Filtering an image is an operation that  
emphasizes certain characteristics of  
an image while suppressing others.  
MaxIm DL supports several kinds of  
Filters, such as:Unsharp Mask, Kernal  
Filters, and Digital Development,  
available from the Filter menu.  
Scaling adjustment (entered as a percentage) allows you to compensate for  
transmittance differences between the filters used to acquire the three color  
planes.Values of 100% result in no change.The scaling percentages can be typed  
in or adjusted using the “spin” controls (small up and down click arrows to the right  
of the scaling numbers). The Preview Image is particularly helpful in monitoring  
the results when using the spin controls.The Reset Scaling button resets to 100%  
on all three planes.  
Please read MaxIm DLs Help Topics  
for the most detailed information about  
the various image processing filters  
available. The following are just some  
of the many processing filters available  
in MaxIm DL.  
Figure 31. The Color Balance  
Window.  
The Click On White Area to Set Scaling check box enables the operation of the  
mouse to set the scaling. Set the Background Level first (you can use Auto), then  
click on a white object (e.g. a neutral-colored star) in the image (not the Preview  
Image) with the mouse. The Scaling settings will automatically be adjusted to  
make the selected point appear white. If an area of the image is known to be white  
(or gray), this is an easier way to determine the scaling factors, and can be used  
to instantly color balance the image.  
Unsharp Mask is a method of sharpening or high-pass filtering an image. It  
amounts to subtracting a low-pass filtered version of an image from itself. The  
low-pass filtered version is called the mask.  
Kernal, High-Pass Filter can be set to More or Less for different effect.The High-  
Pass Filter can be useful for accentuating fine details in an image.  
Kernal, Gaussian Blur is a method of blurring an image. It can be used to sup-  
press noise in an image at the expense of sharpness. The Radius setting controls  
the amount of blurring applied to the image. Increasing the radius increases the  
amount of blur applied.  
note on File Format  
When saving individual images that were not taking during a sequence (using  
Save or Save As in the File menu), you have a choice of file formats. The default  
produces .fit files, but .tif, .jpg, .png, and .bmp file formats can also be selected.  
Having a choice of output file formats is useful, especially if images will be  
exported to other software programs for additional image processing (like Adobe  
Photoshop, for instance).  
For best results, turn on the Auto Full Screen preview button, and adjust the set-  
tings. This allows you to rapidly adjust the settings until you are satisfied with the  
results. Then, click OK to actually apply the filter settings to the image.  
It is best to use a light touch with this command, to avoid over-processing the  
image. Over-processing can create artifacts; i.e. features in the image that are not  
real. It also amplifies the noise in the image.  
If you save to a file format other than .fit, you will need to check the Auto Stretch  
box, or otherwise Stretch the image to change the Output Range (in the Stretch  
command window) to match the Size Format (in the Save As window). Otherwise,  
the Output Range will likely exceed the Size Format, and the saved image will  
be ruined (will turn all white).  
5.5. Color Balance  
The sensitivity of most CCD cameras as a function of wavelength (color) is differ-  
ent from the response of the human eye. The filters used for creating color com-  
posites also have their own characteristics, as do the telescope optics. Although  
“perfect” color rendition is an elusive if not impossible goal (all individuals see col-  
ors slightly differently), it is straightforward to get “good” color balance with simple  
weightings. This is where the Color Balance command (in the Process menu,  
Figure 31) comes in handy to touch up the resultant colors in your images. Use  
For example, say the Output Range is set to create image brightness values in  
16-bit format, while the Size Format of a specific file format (.jpg, for example)  
may only support 8-bits. Since the 16-bit format sees 65535 brightness levels,  
and the 8-bit format can only support 255 levels, all of the levels above 255 in the  
16-bit image (i.e. the vast majority of the 16-bit brightness levels) will be saved at  
the maximum 8-bit value of 255. So the saved .jpg will have very little brightness  
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information from levels 1 to 254 and almost all the brightness information at level  
255. Thus a white image results.  
If you plan to do all image processing within MaxIm DL Edition (or the optional  
full version of MaxIm DL), saving images in the FITS (.fit) File Format using the  
IEEE Float Size Format is recommended. This ensures that all saved data will  
be kept intact. If another Size Format is utilized, there may be some loss of data,  
especially when saving combined images.  
6. Multiple Camera Control  
for Autoguiding  
One very nice feature of the MaxIm DL software is the ability to control two cam-  
eras simultaneously. This way, you only need one computer and software program  
to image and autoguide at the same time.This feature is also compatible with older  
SSDSI cameras.  
1. Plug both cameras, one at a time, into the USB ports on your computer.  
Install the drivers for each camera as detailed prior in this instruction manual.  
2. Open the MaxIm DL software. In the Camera Control Window’s Setup  
tab that appears, select the imager as Camera 1 and the autoguider as  
Camera 2, then click Connect.  
3. Click on the Guide tab, Camera 2 will be assigned here.  
Figure 32. The Guider Settings configure your autoguider in MaxIm DL.  
6.1. Autoguider Calibration  
each axis. The Calibration Time determines how long it activates the motors  
each time. The usual value is 5-10 seconds; start out with a value of 5.  
If you are using a second camera as an autoguider, you must calibrate the system.  
The exact orientation of the camera, the focal length of the guide telescope optics,  
and the speed of the motor drive all affect the calibration. To perform autoguider  
calibration:  
5. Make sure all of the Guider Enables boxes are checked.  
6. For Autoguider Output, set Control Via. If you are using the Orion  
1. Switch to the Guide tab.  
StarShoot AutoGuider for example, choose Guider Relays.  
2. Set the X and Y Aggr (aggressiveness) to 8 to start with. Set the Exposure  
7. Click Apply. You can leave this dialog box open, or Close it if you wish.  
to 1.0 second. Under Guide Star, make sure the Watch box is checked.  
8. Make sure that the telescope mount is set to move at 1X sidereal or slower.  
For some mounts, you must set the guide rate manually. The maximum  
usable rate is 1X sidereal. If your mount does not drift quickly, you can set  
the speed slower than 1X depending on your imaging configuration.  
Note: The X and YAggr (aggressiveness) controls on the Guide tab allows you  
to adjust how vigorously star motions are tracked out in each axis. An aggres-  
siveness setting of 10 means that the Parsec attempts to track out 100% of the  
motion, whereas a setting of 1 means that the Parsec only tracks out 10% of  
the motion. Usually a setting of around 8 or 9 provides the best tracking, since  
it reduces overshoot and helps ignore random motions due to atmospheric see-  
ing and wind loads. You should experiment to determine the best setting for your  
particular telescope.  
9. On the Guide tab, set to Expose, and click the Start button. A single image  
will be taken. Ensure that a well-focused bright star (near the actual object  
to be imaged) appears in the image. If not, adjust the guide scope and try  
again. Make sure the star is roughly centered.  
Note: The algorithm can be confused if another star appears in the frame; to mini-  
mize this risk, calibrate on an isolated bright star.  
3. Click the Settings button (Figure 32).  
4. Maxim DL needs to know how fast the telescope moves in right ascension  
(R.A.) and declination (Dec.) when the autoguider commands are issued. To  
do this, the software will Calibrate the mount by moving it back and forth on  
10. Now, set to Calibrate, and click the Start button. A series of five exposures  
will be taken; each time the telescope will be moved slightly. If the telescope  
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does not move, check the Settings. Remember, you have to set up a  
method for sending the autoguider commands to the telescope!  
On most telescopes, the Right Ascension drive likes to have some load  
pushing against sidereal tracking. If the mount is balanced such that it is  
pulling the mount forwards slightly, the gear teeth may bounce back and  
forth resulting in terrible guiding that cannot be corrected by an autoguider.  
Be sure to always balance the telescope such that it “lifting the weight”  
rather than “allowing it to fall”; i.e. heavier on the East side. Note that this  
may require balancing the telescope differently when it is pointed East  
versus West.  
11. The star should move in an L shape. If it does not move enough, a warning  
message will appear. The recorded positions will be displayed in the scrolling  
log, along with any error messages.  
Note: If the star does not move far enough, or moves too far (i.e. the star leaves the  
field), the duration of the calibration move commands can be adjusted by clicking  
the Settings command and changing the Calibration Time fields (measured in  
seconds). A longer calibration time will increase the motion of the star; a shorter  
time will decrease the motion. Typical values range from five to ten seconds,  
depending on the correction speed, focal length, and pixel size.  
7. Other Features Of MaxIm Dl  
This manual only covers a small fraction of all the capabilities and features of  
MaxIm DL. We strongly recommend reading through MaxIm DLs Help Topics for  
more detailed information about all of the features once you have become more  
familiar with setting up and using your Parsec camera.  
12. Once you have successfully calibrated, switch to the Track mode. Click  
Start, and watch the star. It should move to the center of the small track box,  
and whenever it drifts off it should be pulled back again. You can zoom in  
the window for a better look. Also the tracking errors will be displayed in the  
scrolling log.  
7.1. Information Window  
The Information window displays numerical information about selected areas of  
the image.The window can be switched on and off using the Information Window  
command on the View menu, or by using the cursor button on the Toolbar. The  
window can remain open as a floating toolbox without interfering with other com-  
mands.  
13. If the star bounces back and forth, reduce the aggressiveness for that  
axis. If it corrects too slowly, increase the aggressiveness. Changes to the  
aggressiveness settings take effect immediately.  
You are now ready to take a long-exposure image through the main telescope and  
imaging camera. The Parsec will continuously send small correction factors to the  
mount’s motor drive to insure steady and accurate tracking throughout the dura-  
tion of the exposure, however long that may be.  
The Information window has four modes of operation: Aperture, Region, Area,  
and Astrometric. There is also a Magnitude display that can be calibrated to show  
accurate stellar magnitudes. Except in Area mode, the mouse cursor will change to  
a crosshair and “bullseye” when the Information window is active and the mouse is  
over the selected image or preview.The sizes of the various elements of the circular  
cursor can be changed using the mouse with the right-click menu.  
Other Autoguiding notes:  
If you are using a German equatorial mount you must calibrate with the  
tube on the same side of the mount as it will be when actually imaging.  
The calibration settings need changing if you move the telescope in  
declination by more than about five degrees. Select another bright star,  
and Calibrate again.  
To lock the cursor at a specific position and freeze the information display,  
double-click on the image. When locked, the circular cursor can be moved using  
the arrow keys. You can then copy text from the status area of the Information  
window to the clipboard using the mouse and CTRL-C (or right-click the mouse  
in the status area and select Copy from the resulting context menu). To restore  
normal operation, click the mouse again on the image.  
If you experience bad guiding in declination and cannot resolve it through  
adjusting the calibration or aggressiveness, you may have a stiction  
problem with your declination drive. Watch which way the star drifts,  
and turn off the Guider Enable checkbox (in the Settings window) that  
pushes the star in that direction. That will prevent the stiction cycle from  
happening.  
Numbers exceeding one million are shown in scientific notation; a lower case e  
followed by an integer means the preceding quantity must be multiplied by that  
power of ten.  
Make sure that any backlash compensation in the mount is turned off.  
7.2. night Vision  
Selecting Night Vision toggles the night vision mode on and off. Three types of  
night vision display are available, selected by a dropdown on the General tab of  
the File Settings dialog:  
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Red helps maintain the human eye’s dark adaptation, Blue is the color to which  
most CCD cameras are least sensitive, and Dim maintains the color display but  
reduces the overall intensity to about one-eighth normal.  
over time must be observed. The basic idea is to let the telescope mount track  
while watching a star to see which way the star drifts. Note the direction of the drift,  
and correct by moving the mount in the appropriate direction.  
In red mode, all menus, dialog boxes, etc., are switched to red.  
Monochrome images are displayed red, but color images are displayed  
in their normal colors. This allows the user to inspect a color image  
without switching the entire screen back to normal colors. Red light helps  
maintain the human eye’s dark adaptation because it does not as readily  
destroy the “visual purple” photosensitive pigment of the scotopic vision  
system (“rod” cells).  
To perform the drift method of polar alignment:  
1. Do a rough polar alignment by pointing the R.A. axis of the mount at Polaris  
(the North Star).  
2. Find a bright star near the meridian (the imaginary line running north-  
to-south through zenith) and near the celestial equator (zero degrees  
declination). Point the telescope at this star, and center it in an illuminated  
reticle eyepiece (available from Orion). If you don’t have an illuminated reticle  
eyepiece, use your highest- magnification eyepiece.  
In blue mode, all menus, dialog boxes, and monochrome images are  
shown in blue. As before, color images are displayed in their normal colors.  
The blue mode is useful when imaging with CCD cameras because it is  
the band in which most CCD cameras are least sensitive.  
3. Determine which way is north and south in the eyepiece by moving the  
telescope tube slightly north and south.  
4. Now, let the mount’s motor drive run for about five minutes. The star will  
begin to drift north or south. Ignore any east-to-west movement.  
In dim mode, all menus, dialog boxes, and images (both monochrome  
and color) are displayed at approximately one-eighth normal brightness in  
order to reduce ambient light conditions in the observatory.  
5. If the star drifts north, the telescope mount is pointing too far west. If the star  
drifts south, the telescope mount is pointing too far east. Determine which  
way the star drifted and make the appropriate correction to the azimuth  
position of the mount. Rotate the entire mount (and tripod) slightly east or  
west as needed or use the azimuth adjustment knobs (if your mount has  
them) to make fine adjustments to the mount’s position.  
7.3. Observatory Control Window  
The Observatory Control Window provides comprehensive control and status for  
any other astro-imaging accessory you might be interfacing with your computer,  
including:  
Telescope mount control with auto-center  
Focuser control with autofocus  
6. Next, point the telescope at a bright star near the eastern horizon and near  
the celestial equator (Dec. = 0).  
7. Let the telescope track for at least five minutes, and the star should begin to  
drift north or south.  
Rotator control with FOV slaving  
Dome control with telescope slaving  
8. If the star drifts south, the telescope mount is pointed too low. If the star  
drifts north the telescope mount is pointed too high. Observe the drift and  
make the appropriate correction to the mount’s altitude (or latitude); most  
mounts have some sort of fine adjustment for this.  
A simple but powerful planetarium with image overlays, FOV overlays  
Extensive searchable catalogs  
The Observatory Control Window is resizable using the mouse.  
Repeat the entire procedure until the star does not drift significantly north or south  
in the eyepiece. When this is accomplished, you are very accurately polar aligned,  
and should be able to produce good (unguided) images of up to several minutes  
long, assuming the mount’s drives track well with little periodic error.  
8. tips  
8.1. Polar Alignment  
Good telescope mount polar alignment is of critical importance for long-exposure  
CCD imaging. Inaccurate polar alignment leads to image movement over time  
(even with motor drives running and engaged), which limits the amount of time an  
exposure can be taken before the stars begin to streak and blur.  
8.2. Choosing a Site for Astro-Imaging  
Once you have a focused image, you may find your image shifting and washed  
out. This can be caused by many environmental factors. Poor seeing (movement  
of molecules in the air, such as heat rising) and poor transparency (moisture,  
smoke, or other sky contaminants) will all serve to reduce image quality. That is  
why most major astronomical telescopes are on high mountains in thin air, to get  
above much of the transparency and seeing problems. Also, wind will move your  
telescope and affect images. Your eyes viewing through an eyepiece can change  
If your equatorial mount uses a polar axis finder scope, we highly recommend uti-  
lizing it for polar alignment. If not, a technique known as the “drift method” of polar  
alignment has been used for many years, and can achieve an extremely accurate  
polar alignment. Unfortunately it is very time consuming, since the drift of a star  
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slightly to compensate for disturbances like these, but the camera can not. Keep  
these factors in mind when choosing an observing site for astronomical imaging.  
Any quality optical lens cleaning tissue and optical lens cleaning fluid specifi-  
cally designed for multi-coated optics can be used to clean the glass surface of  
the Parsec’s optical window. Never use regular glass cleaner or cleaning fluid  
designed for eyeglasses.  
For the best astro-images, we recommend finding a location with dry air, some  
altitude, and away from city or streetlights. Even a nearby hilltop in the countryside  
can provide better viewing conditions than many convenient backyard locations.  
Before cleaning with fluid and tissue, blow any loose particles off the surface with  
a blower bulb or compressed air. Then apply some cleaning fluid to a tissue, never  
directly on the optics. Wipe the optical surface gently in a circular motion, then  
remove any excess fluid with a fresh lens tissue. Oily fingerprints and smudges  
may be removed using this method. Use caution; rubbing too hard may cause  
scratches.  
8.3. using Focal reducers and Barlow lenses  
Focal reducers and barlow lenses change the effective focal length of a telescope.  
These lenses are inserted between the camera and telescope when imaging to  
change image scale.  
Store the Parsec in the included hard carrying case. Keep the camera in a dry  
location away from direct sunlight.  
Focal reducers serve to decrease the focal length of your telescope. This increas-  
es the field of view seen by the camera (decreases camera magnification). This  
can be very useful for obtaining images of wide-field deep sky objects, such as the  
Andromeda Galaxy or the Pleadies star cluster. Focal reducers will usually thread  
onto the nosepiece of the Parsec.  
Barlow lenses increase the focal length of your telescope, which makes the cam-  
era’s field of view narrower (increases camera magnification). This is useful for  
planetary imaging. Keep in mind that when the focal length is doubled, the image  
will become four times dimmer, so a longer exposure may be necessary. Barlow  
lenses are generally inserted in the focuser’s drawtube and secured with the  
thumbscrew on the focuser’s drawtube, and the Parsec’s nosepiece is inserted  
into the barlow and secured with the thumbscrew on the barlow lens.  
8.4. Filters  
Any standard Orion 2" filter will thread into the 2" nosepiece of the Parsec. Light  
pollution filters, or special light pollution filters designed for imaging (such as the  
Orion SkyGlow Imaging Filter) improves image contrast from urban areas with  
severe light pollution.  
For the Parsec 8300M, we recommend using a motorized filter wheel, such as  
the Orion Nautilus to easily manage LRGB or narrowband filters to assemble a  
color image.  
8.5. uSB Extension Cable  
Most imaging setups may require extra distance to comfortably reach from Parsec  
to the computer. We recommend purchasing a 10’ USB extension cable if you  
need more cord length (available through Orion, check the catalog and/or www.  
OrionTelescopes.com). Do not exceed 20’ of cable length or you may start to  
experience connection problems.  
8.6. Care and Maintenance  
When the Parsec is not in use, the dust cap should be replaced on the end of the  
nosepiece. This prevents dust from accumulating on the Parsec’s optical window.  
If significant dust does accumulate on the optical window, or the optical surface is  
touched, then it should be cleaned.  
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9. Specifications  
Parsec 8300  
Parsec 10100C  
CCD Sensor (Parsec 8300C)  
Kodak KAF-8300CE  
Kodak KAF-8300-AXE  
17.96mm x 13.52mm  
22.5mm diagonal  
3326x2504 (8,328,304 total)  
5.4µm x 5.4µm  
CCD Sensor  
Kodak KAI-10100-CXC  
17.86mm x 13.49mm  
22.5mm diagonal  
CCD Sensor (Parsec 8300M)  
CCD detector size  
Sensor format  
CCD detector size  
Sensor format  
Pixel array  
3760x2840 (10,678,400 total)  
4.75µm x 4.75µm  
Pixel array  
Pixel size  
Pixel size  
Exposure range  
A/D conversion  
Binning  
0.002 seconds to infinity  
16 bit  
Exposure range  
0.002 seconds to infinity  
16 bit  
A/D conversion  
1x1, 2x2, 3x3 and 4x4  
25,000e-  
Binning  
1x1 and 2x2  
Full Well Capacity  
Read Noise (RMS)  
Dark Signal (at 0ºC)  
Thermoelectric cooling  
Operating Power Range  
Camera current draw  
USB connection  
IR-cut filter  
Full Well Capacity  
Read Noise (RMS)  
Dark Signal (at 0ºC)  
Thermoelectric cooling  
Operating Power Range  
Camera current draw  
USB connection  
25,500e-  
9e-  
8e-  
0.15e-/pixel/second  
40°C below ambient temperature  
10VDC to 13.8VDC  
Approximately 2A (at 12VDC)  
2.0 High speed  
0.15e-/pixel/second  
40°C below ambient temperature  
10VDC to 13.8VDC  
Approximately 2A (at 12VDC)  
2.0 High speed  
Yes  
IR-cut filter (Parsec 8300C)  
IR-cur filter (Parsec 8300M)  
Optical window  
Yes  
Optical window  
Fully coated with anti-reflection coatings  
No  
Backfocus Distance from T-threads 29.24mm (1.15")  
Fully coated with anti-reflection coatings  
Weight  
900g (32 oz)  
Yes  
Backfocus Distance from T-threads 29.24mm (1.15")  
Autoguider capability  
Mounting  
Weight  
900g (32 oz)  
Yes  
2" nosepiece or T-thread  
Autoguider capability  
Mounting  
2" nosepiece or T-thread  
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