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Home > Products > Telescopes > CPC Series Computerized Telescopes > CPC 925 GPS (XLT) Computerized Telescope

CPC 925 GPS (XLT) Computerized Telescope
Item #11074-XLT

list price: $2,499.00 you save: $200.00 USD

SALE PRICE: $2,299.00 ^USD

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CPC 925 GPS (XLT) Computerized Telescope Photo

This product is proudly engineered in USA

Overview

CPC 925 GPS (XLT) - General Features

9.25" diffraction limited Schmidt-Cassegrain telescope
Celestron's premium StarBright XLT coatings
Fully computerized dual fork arm Altazimuth mount
8x50 finderscope to help accurately find objects
Newly designed heavy-duty tripod makes attaching the telescope so easy you can do it in the dark; also features sturdy 2" steel legs and accessory tray
Ergonomic design - Comfortably lift and move the telescope from location to location
Star diagonal provides more comfortable viewing position when observing objects that are high in the sky
Convenient remote hand control holder - Allows you to view information hands-free while using the scope

CPC 925 GPS (XLT) - Computerized Mount Features

Proven NexStar computer control technology
40,000 object database with over 100 user-definable objects and expanded information on over 200 objects
Custom database lists of all the most famous deep-sky objects by name and catalog number; the most beautiful double, triple and quadruple stars; variable star; solar systems; objects and asterisms
Re-designed drive base and drive mechanics - Quiet operation; large drive gears, quick release clutch
SkyAlign allows you to align on any three bright celestial objects, making for a fast and easy alignment process
Flash upgradeable hand control software and motor control units for downloading product updates over the Internet
Permanent PEC
Auxiliary port for additional accessories such as Autoguider, GPS accessory
NexRemote telescope control software and rs-232 cable included for advanced control of your telescope via computer

Manuals

CPC Series Manual
(2.77 MB)
NexStar Communication Protocol v 1.2
(0.08 MB)

Details

CPC 925 GPS — Unique design, advanced features, GOTO accuracy, and superb optics. You get the picture.

Celestron’s 9.25” optical system has enjoyed a loyal following since we first introduced it with our Ultima 9.25” in 1995. Now the 9.25” optical tube is coupled with Celestron's newest computerized telescope family — the CPC GPS series.

The 9.25” was already a favorite among astrophotographers and discerning visual observers and it offers 33% more light gathering than our 8" model. The CPC 925 GPS was specifically designed for visual infinity focus when using 2" eyepieces and has an optimized baffle system to benefit astrophotography by minimizing vignetting at the edge of the field of view. Its longer primary focal length and lower magnification secondary mirror contribute to a flatter field of view at the focal plane and helps to further reduce optical aberrations.

This feature packed model comes standard with Celestron's renowned StarBright multi-coatings. The CPC 925 GPS is compatible with the complete line of Celestron photographic and visual accessories.

What makes the CPC 925 GPS great for astrophotography?

Longer focal length primary and lower magnification secondary— Contributes to a flatter focal plane with less coma and off-axis astigmatism.
Baffle design —Optimized for astrophotography. Minimizes vignetting at the edge of the field of view. This reduces light drop off at the corners of your film plane.
Hand Figured Optics — Just like all other Celestron Schmidt-Cassegrain telescopes, the CPC 925 GPS optics are individually matched and hand figured to ensure the highest optical quality in every telescope.
Focus mechanism — At the heart of Celestron's Schmidt-Cassegrain focus mechanism are pre-loaded ball bearings, not bushings, minimizing focus shift.
Heavy-duty die cast aluminum fork arms —For maximum rigidity.
Unique roller bearing design bearing and shaft —The telescope base rotates around a wide 9.5” track for maximum stability; especially important when equatorially mounted for imaging.
Autoguider port — For interfacing an autoguider or a drive corrector for long exposure imaging or astrophotography.
StarBright coatings — High quality multi-layer coatings maximize transmission of light to the film plane.

Celestron's new CPC Series with revolutionary SkyAlign Alignment
Technology re-defines everything that amateur astronomers are looking for — quick and simple alignment, GPS, unsurpassed optical quality, ease of set-up and use, ergonomics, enhanced computerization and, most important, affordability.

Internal GPS
The CPC Series' internal GPS receiver automatically downloads the date and time from orbiting satellites and pinpoints its exact location on Earth. This eliminates the need for you to manually enter the date, time, longitude and latitude.

Celestron's Revolutionary SkyAlign
Once the CPC's internal GPS has established the telescope's position, aligning the telescope is as easy as 1-2-3! Simply locate and use hand control to manually point (slew) the telescope to three bright celestial objects. You do not need to know the names of the stars — you may even pick the moon or bright planets! Celestron's NexStar^® software technology will model the night sky to determine the position of every star, planet and celestial object above the horizon. Once aligned, the remote hand control allows direct access to each of the celestial catalogs in its user-friendly database.

Celestial Object Database
The CPC database contains over 40,000 celestial objects including Messier objects, the Caldwell Catalog, as well as NGC Galaxies, nebulae and planets. User-definable filter limits make navigating through this expansive database quicker and easier. Filter Limits let you filter out objects that are outside of your local horizon (ie, if trees or mountains were in the way).

Identify feature tells you what you're looking at, but it can also be a very fun way to tour around the sky. Just point the telescope up somewhere and ask it to identify Messier objects (for instance) and it will show you the 5 nearest Messier objects to your position and let you GOTO them. You can keep doing this for different parts of the sky or for different object types -- it is a lot of fun.

There's also "Solar Sys Align" that lets you align on the sun or moon for daytime observing -- it is easy to use this to see planets or bright stars in the day.

Innovative Features
The new CPC Series telescopes, like our acclaimed Advanced Series and premium CGE Series telescopes feature meticulously matched and hand-figured optical systems that are manufactured in our facilities in Torrance, California. In addition, all CPC models are available with StarBright and StarBright XLT High Performance Optical Coatings.

With the introduction of the CPC Series, Celestron has “gone back to the drawing board” and re-designed, re-engineered, and re-invented a telescope family that provides superior quality, unsurpassed ease of use, and incomparable value. All CPC models ship standard with our NexRemote telescope control software.

CPC 925 GPS (XLT) - General Features

9.25" diffraction limited Schmidt-Cassegrain telescope
Celestron's premium StarBright XLT coatings
Fully computerized dual fork arm Altazimuth mount
8x50 finderscope to help accurately find objects
Newly designed heavy-duty tripod makes attaching the telescope so easy you can do it in the dark; also features sturdy 2" steel legs and accessory tray
Ergonomic design - Comfortably lift and move the telescope from location to location
Star diagonal provides more comfortable viewing position when observing objects that are high in the sky
Convenient remote hand control holder - Allows you to view information hands-free while using the scope

CPC 925 GPS (XLT) - Computerized Mount Features

Proven NexStar computer control technology
40,000 object database with over 100 user-definable objects and expanded information on over 200 objects
Custom database lists of all the most famous deep-sky objects by name and catalog number; the most beautiful double, triple and quadruple stars; variable star; solar systems; objects and asterisms
Re-designed drive base and drive mechanics - Quiet operation; large drive gears, quick release clutch
SkyAlign allows you to align on any three bright celestial objects, making for a fast and easy alignment process
Flash upgradeable hand control software and motor control units for downloading product updates over the Internet
Permanent PEC
Auxiliary port for additional accessories such as Autoguider, GPS accessory
NexRemote telescope control software and rs-232 cable included for advanced control of your telescope via computer

Specs

Optical Design :

Schmidt-Cassegrain

Aperture :

235 mm (9.25 in)

Focal Length :

2350 mm (92.52 in)

Focal Ratio :

Finderscope :

8x50 Finderscope with quick release bracket

Mount :

Dual Fork Arm

Optical Tube :

Aluminum

Eyepiece 1 :

40 mm (1.57 in)

Magnification 1 :

59 x

Star Diagonal :

1.25

Accessory Tray :

Leg Brace / Eyepiece holder

Tripod :

Heavy Duty Steel Adjustable

CD ROM :

NexRemote control software with RS232 cable

Power Supply :

Car battery adapter

Highest Useful Magnification :

555 x

Lowest Useful Magnification :

34 x

Limiting Stellar Magnitude :

14.4

Resolution (Rayleigh) :

0.59 arcsec

Resolution (Dawes) :

0.49 arcsec

Photographic Resolution :

200 line/mm

Light Gathering Power :

1127 x

Angular Field of View :

0.7 °

Linear Field of View (@1000 yds) :

38 ft (11.58 m)

Optical Coatings :

Starbright XLT Coating

Secondary Mirror Obstruction :

3.35 in (85.09 mm)

Secondary Mirror Obstruction by Area :

13.1 %

Secondary Mirror Obstruction by Diameter :

36.2 %

Telescope Weight :

58 lb (26.31 kg)

Tripod and Mount Weight :

27 lb (12.25 kg)

Motor Drive :

DC Servo motors with encoders, both axes

Motor Resolution :

0.14 arc seconds

Computer Hand Control :

Double line, 16 character Liquid Crystal Display; 19 fiber optic backlit LED buttons

Tracking Rates :

Sidereal, Solar and Lunar

Tracking Modes :

Altazimuth, EQ North and EQ South

Alignment Procedures :

SkyAlign, Auto Two-Star Alignment, Two-star Align, SolarSystem Align, EQ North Align, EQ South Align, One-Star Align

Software Precision :

24bit, 0.08 calculations

Periodic Error Correction :

Permanently Programmable

Fork Arm :

Dual fork arm, cast Aluminum with detachable HC cradle

Gear :

5.625 hard anodized gear in both axes, 180 tooth

Bearings :

9.8 azimuth bearing

Communication Ports :

RS-232 communication port on hand control

Motor Ports :

Aux Port, Autoguide Ports

Database :

40,000+ objects, 100 user defined programmable objects. Enhanced information on over 200 objects

Power Requirements :

12VDC 1.5A

Power Requirements - Idle Current :

340 mA

Power Requirements - Slew one axis :

640 mA

Power Requirements - Slew both axes :

900 mA

Cord Management :

Cord Wrap Software

GPS :

Internal 16 channel

CPC 925 GPS (XLT) Computerized Telescope
Item #11074-XLT

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2-year Telescope Warranty

CELESTRON TWO YEAR LIMITED WARRANTY

A. Celestron warrants your telescope to be free from defects in materials and workmanship for two years. Celestron will repair or replace such product or part thereof which, upon inspection by Celestron, is found to be defective in materials or workmanship. As a condition to the obligation of Celestron to repair or replace such product, the product must be returned to Celestron together with proof-of-purchase satisfactory to Celestron.

B. The Proper Return Authorization Number must be obtained from Celestron in advance of return. Call Celestron at (310) 328-9560 to receive the number to be displayed on the outside of your shipping container.

All returns must be accompanied by a written statement setting forth the name, address, and daytime telephone number of the owner, together with a brief description of any claimed defects. Parts or product for which replacement is made shall become the property of Celestron.

The customer shall be responsible for all costs of transportation and insurance, both to and from the factory of Celestron, and shall be required to prepay such costs.

Celestron shall use reasonable efforts to repair or replace any telescope covered by this warranty within thirty days of receipt. In the event repair or replacement shall require more than thirty days, Celestron shall notify the customer accordingly. Celestron reserves the right to replace any product which has been discontinued from its product line with a new product of comparable value and function.

This warranty shall be void and of no force of effect in the event a covered product has been modified in design or function, or subjected to abuse, misuse, mishandling or unauthorized repair. Further, product malfunction or deterioration due to normal wear is not covered by this warranty.

CELESTRON DISCLAIMS ANY WARRANTIES, EXPRESS OR IMPLIED, WHETHER OF MERCHANTABILITY OF FITNESS FOR A PARTICULAR USE, EXCEPT AS EXPRESSLY SET FORTH HEREIN. THE SOLE OBLIGATION OF CELESTRON UNDER THIS LIMITED WARRANTY SHALL BE TO REPAIR OR REPLACE THE COVERED PRODUCT, IN ACCORDANCE WITH THE TERMS SET FORTH HEREIN. CELESTRON EXPRESSLY DISCLAIMS ANY LOST PROFITS, GENERAL, SPECIAL, INDIRECT OR CONSEQUENTIAL DAMAGES WHICH MAY RESULT FROM BREACH OF ANY WARRANTY, OR ARISING OUT OF THE USE OR INABILITY TO USE ANY CELESTRON PRODUCT. ANY WARRANTIES WHICH ARE IMPLIED AND WHICH CANNOT BE DISCLAIMED SHALL BE LIMITED IN DURATION TO A TERM OF TWO YEARS FROM THE DATE OF ORIGINAL RETAIL PURCHASE.

Some states do not allow the exclusion or limitation of incidental or consequential damages or limitation on how long an implied warranty lasts, so the above limitations and exclusions may not apply to you.

This warranty gives you specific legal rights, and you may also have other rights which vary from state to state.

Celestron reserves the right to modify or discontinue, without prior notice to you, any model or style telescope.

If warranty problems arise, or if you need assistance in using your telescope contact:

Celestron
Customer Service Department
2835 Columbia Street
Torrance, CA 90503
Tel. (310) 328-9560
Fax. (310) 212-5835

Monday-Friday 8AM-4PM PST

NOTE: This warranty is valid to U.S.A. and Canadian customers who have purchased this product from an authorized Celestron dealer in the U.S.A. or Canada. Warranty outside the U.S.A. and Canada is valid only to customers who purchased from a Celestron's International Distributor or Authorized Celestron Dealer in the specific country. Please contact them for any warranty service.

CPC 925 GPS (XLT) Computerized Telescope Thumbnail

CPC 925 GPS (XLT) Computerized Telescope
Item #11074-XLT

Accessories

Programming Cable
Item #93922

$24.95 ^USD

Diagonal, Erect Image - 1.25 in - 45°
Item #94112-A

$39.95 ^USD

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Reducer - Corrector
Item #94175

$144.95 ^USD

AC Adapter
Item #18778

$23.95 ^USD

PowerTank 17
Item #18777

$129.95 ^USD

VSP (Vibration Suppression Pads)
Item #93503

$49.95 ^USD

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Solar Filter (CPC 925, CGE 925)
Item #94237

$84.95 ^USD

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Lens Shade, C 9.25
Item #94013

$34.95 ^USD

NexImage
Item #93712

$119.95 ^USD

2-inch XLT Diagonal (SCT)
Item #93527

$144.95 ^USD

UHC/LPR Filter - 1.25 in
Item #94123

$74.95 ^USD

Flashlight, Night Vision
Item #93588

$15.95 ^USD

Axiom LX 15mm Eyepiece
Item #93396

$179.95 ^USD

Axiom LX 19mm Eyepiece
Item #93397

$249.95 ^USD

Axiom LX 23mm Eyepiece
Item #93398

$299.95 ^USD

Ultima LX 32mm Eyepiece
Item #93376

$199.95 ^USD

Ultima 1.25 in - 2x
Item #93506

$84.95 ^USD

Moon Filter - 1.25 in
Item #94119-A

$13.95 ^USD

Oxygen III Narrowband Filter - 1.25 in
Item #93623

$79.95 ^USD

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Binocular Viewer, Stereo
Item #93691

$209.95 ^USD

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Anniversary Pins

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Digital Camera Adapter - Universal

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SkyScout Connect

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CPC 925 GPS (XLT) Computerized Telescope
Item #11074-XLT

Support

Knowledge Base

Manuals

CPC Series Manual
(2.77 MB)
NexStar Communication Protocol v 1.2
(0.08 MB)

Software

Motor Control Firmware Updates v.2.2.5
(3.57 MB) release notes
Hand Control Firmware Updates v.1.1.14
(3.75 MB) release notes
PEC Tool v.1.0.18
(3.35 MB) release notes
NexRemote v. 1.7.15 (30 day trial)
(18.61 MB) release notes

CPC 925 GPS (XLT) Computerized Telescope
Item #11074-XLT

News

Celestron News

10/13/2009 - Celestron Applauds The White House And President Barack Obama For Their Support Of Astronomy And Science Education
12/09/2005 - Sky & Telescope Magazine Names SkyAlign as Hot Product for 2006!

Tour

CPC 925 GPS (XLT) Computerized Telescope
Item #11074-XLT

Specials

For a limited time, receive $200 off Celestron's CPC GPS Series Computerized Telescopes

Offer valid through participating dealers only.

Hurry, offer ends 07/31/10.

Offer excludes Anniversary Edition CPC 800 GPS.

Dealers

CPC 925 GPS (XLT) Computerized Telescope
Item #11074-XLT

Images

Sirsalis Rille - Lunar HWY

Rima Sirsalis is a long dead-straight rille that unusually cuts through lunar highland near the Western limb of the Moon. Most rilles are in maria or flooded craters. It looks like a highway! It extends outside this image in both directions. Apparently the lunar magnetic field (which is very weak) is unusually strong in the vicinity of the Rima Sirsalis. The prominent crater in the bottom of the image is Sirsalis (42 km); it partly obliterates the older Sirsalis A (49 km). Crater Sirsalis J (12 km) bisects the rille. A less prominent rille wraps around Sirsalis A, and towards the bottom left of the image a faint rille is just apparent. South is up. It was raining half an hour after I captured this one!

submitted by Andrew Bray

Rimae Triesnecker

Crater Triesnecker (26 km) lies next to a complex rille system Rimae Triesnecker making this an interesting field. The larger rilles are relatively easy to observe though some are quite difficult. The rilles are shallow & the Northern structures are complex & disrupted by what looks like tectonic activity. Hyginus crater & rille sit just North of this field. The crater on the RHS is Chiadni (13.6 km). Resolution ~1 km. South is up.

submitted by Andrew Bray

Autolycus and Luna 2 crash site

This image is dominated by crater Autolycus (39 km). The little crater on the rim is Autolycus A (4 km). The rille system Rimae Fresnel can be seen to the left - it is at the foot of the mountain range Montes Apenninus, which is just out of the frame to the left. Though not visible (!), the Luna 2 �crash site� is just 30 km to the right of Autolycus (at 2 o�clock). The Soviet Luna 2 was the first spaceship to �land� on the Moon. South is up. This is one of several AVIs captured during a short spell of good seeing on 19 July. Resolution: ~1 km.

submitted by Andrew Bray

Ptolemaeus and its ghost craters

When the illumination is sufficiently low, the walled plain Ptolemaeus (153 km) shows its flooded �ghost� craters. Several are apparent in this image. The lone prominent crater is Ammonius (9 km). Many of the craterlets across the floor are 1-3 km in diameter, though the floor is not as smooth as you may think. Check out the Apollo 16 image recorded on 5� film: http://www.lpi.usra.edu/resources/apollo/images/print/AS16/M/0990.jpg

submitted by Andrew Bray

Hyginus Crater and Rille

Rima Hyginus is an unusual formation with an average width of 3 km. It is bisected by crater Hyginus (10.6 km), which is believed to be of volcanic origin. This is a relatively "young" feature on the Moon. The Northern end of the complex rille system Rimae Triesnecker is visible in the top of the image. Additional processing can pull out many smaller craters in the surrounding field, but the image starts to look unnatural. Seeing was good for a short time and so I recorded several AVIs. South is up.

submitted by Andrew Bray

Cassini Crater and Prom. Agassiz

This interesting field shows crater Cassini (57 km) in the centre. The largest craters in the flooded floor, Cassini A (17 km) & B (9 km), give Cassini a distinctive appearance. Several rilles are apparent to the left of Cassini. To the right casting a nice jagged shadow is Promontorium Agassiz, the most southern mountain of the Montes Alps. The seeing was quite steady in the evening for about half an hour. Resolution is to ~1 km. South is up. 200 of 3000 frames stacked.

submitted by Andrew Bray

M2 (NGC7089) in Aquarius

M2 is a bright, concentrated (class II) globular cluster. Through the eyepiece the brighter stars tend to yellow-orange and it is very concentrated in the centre though nicely resolved. 33 of 50 frames stacked. The 9.25" does a nice job on this type of target. South is up.

submitted by Andrew Bray

Omega Centauri Core (NGC 5139)

This is a 370" x 370" image of the core of Omega Centauri captured with the 9.25" CPC. In most images the core stars are saturated or burnt out in order to show the outliers. Here you can see discrete stars with a range of colours. There are a few very red stars - similar to the view through a larger telescope. It is now believed that a black hole lurks here in the centre.

submitted by Andrew Bray

NGC5286 Globular Cluster in Centaurus

NGC5286 is the "other" bright globular cluster in Centaurus - it is of medium concentration (V) and well resolved in the 9.25" telescope. The nearby bright yellow star, M Cen (mag 4.7, type G5) outshines the cluster.

submitted by Andrew Bray

M68 (NGC4590) Globular Cluster in Hydra

M68 in Hydra is an example of a less condensed (Type X) globular cluster. Diameter ~11'. At mag 7.8 it is not particularly bright. I caught it early in the evening before it set. Visually easily resolved in the 9.25". I took 100 frames and selected the best 47 for stacking.

submitted by Andrew Bray

Technologies

Celestron Premier Select Dealers:

For a complete list of Celestron dealers, please visit our Dealer Locater

StarBright XLT

Celestron is proud to introduce a revolutionary coating system that outperforms any other coating in the commercial telescope market. Our most popular Schmidt-Cassegrain telescopes are now available with this high quality optical coating at an incredible value.

Navigate through this section to get detailed information on how XLT is designed, and how XLT measures up against our current StarBright coatings. We have also used this site as a resource to provide information on our testing methods and we offer a section detailing which models this new coating will be available with and the cost breakdown for each model.

OVERVIEW
COATINGS OVERVIEW
STARBRIGHT XLT SYSTEM
CURRENT STARBRIGHT
OUR MEASUREMENTS

To find a Celestron Dealer near you who carries telescopes with StarBright XLT, please click here for our Dealer Locater.

StarBright XLT & Our Commitment to Quality TOP

We strive to design and engineer products with quality components using a state of the art manufacturing process that is followed up with uncompromising quality assurance. You can see it in the design and quality of our entire product line. And our new StarBright XLT coating system is no exception.

Design - We design and test our optical coatings with the aid of thin film design software in wide use throughout the optical, semiconductor, aerospace, and telecommunications industries. Using this software we have improved on our multi-layer enhanced mirror coatings, shifting the peak reflectance to the center of the visible spectrum. We have designed a completely new multi-layer anti-reflective coating and have introduced a new low absorption, high transmission glass for our corrector lens. This unequaled combination is standard with every StarBright XLT system.

Quality Components and Process - Our coating process uses state-of-the-art thin film vacuum deposition technology. To ensure consistent optical coatings of the highest quality the process is tightly monitored and controlled by highly trained coating technicians. Prior to coating, each optical element is thoroughly cleaned and inspected to ensure proper adhesion of the films during the coating process. The materials used in our reflective and anti-reflective coatings including Aluminum, Hafnium Oxide, Titanium Dioxide, Silicon Dioxide, and Magnesium Fluoride are the purest available, exceeding 99.99%.

Quality Assurance - Our QA process is designed to prevent any optical element from passing if it does not meet our strict standards of optical quality. Witness plates are included in each coating run, and are subjected to spectrophotometric analysis to determine if the minimum acceptable transmission or reflectance has been achieved.

Optical Elements of the Schmidt-Cassegrain Telescope TOP

A telescope is a group of optical elements that collects light and focuses it for observation by an eyepiece or some other imaging device. There are two types of optical elements: mirrors and lenses. Mirrors reflect light and lenses refract, or bend light. The Schmidt-Cassegrain telescope uses both mirrors and lenses. The diagram below shows a cross-section of a Schmidt-Cassegrain. In this telescope, light first passes through the corrector lens, and then reflects off the primary mirror. Finally, it reflects off the secondary mirror and comes to a focus at the focal plane.

Optical Coatings

The purpose of a telescope is to collect as much light as possible. The amount of light collected affects the brightness of the resulting image. Unfortunately, there are sources of light loss at each optical surface, and within each lens. Fortunately, we can design optical coatings and choose lens materials that minimize the amount of light lost to these sources.

Optical coatings are very thin layers of material that are applied to the glass in a process called 'vacuum deposition '. The physical properties and thickness of each layer in the coating, as well as their orientation with each other and the glass to which they are applied, determine how well they will do their job.

Since the function of a mirror is to collect light by way of reflection, we use highly reflective metallic coatings on these optical elements. A mirror without coatings reflects about 4% of the light that hits its surface. A mirror coated with standard Aluminum coatings reflects about 86 - 88%, and a mirror coated with StarBright XLT reflects 95%.

Light traveling through a lens is a little more complicated. In this case, light is lost to both reflection and absorption. When light first strikes an uncoated lens, about 4% is reflected back and never has the chance to make it through. Some of the remaining 96% will be absorbed on its way through the glass, and then the second lens surface reflects another 4%. To minimize unwanted reflection, dielectric materials are used in pairs of alternating high and low refractive index. A good anti-reflection (A/R) coating for telescope lenses is one that will deliver very low, very 'flat ' reflectance across the entire visible spectrum.

Although A/R coatings can dramatically reduce the amount of light lost to reflection, no optical coating can reduce the amount of light lost to absorption within the glass. To reduce this source of light loss, it is important to choose a glass that absorbs as little light as possible.

For many A/R coating applications, it is standard to measure the reflection of the coated surface and to ignore the amount of light that is being absorbed by the glass. But for a telescope lens, stating how well an A/R coating suppresses reflection without also revealing how much light is lost to absorption within the glass can be quite misleading. For this application, actual transmission, which accounts for light lost to both sources, should be measured directly. You can learn more about how we did these measurements in the section titled Our Measurements.

Telescope System Transmission

System transmission is the percentage of light that arrives at the focal plane compared to the light that enters the telescope, and is calculated by taking the product of the corrector lens transmission, the primary mirror reflectance, and the secondary mirror reflectance. Here is an example; if the corrector lens transmits 92% of the light, and the primary and secondary each reflect 89% of the light, then:

Total System Transmission = .92 * .89 * .89 = .73 (73%)

StarBright XLT - An Optical System Breakthrough! TOP

Celestron has brought its renowned StarBright technology to an even higher level of light transmission with the introduction of our new optional StarBright XLT High Performance Optical Coating System.

StarBright XLT Optical System Design - You'll See The Light.

One of the most important factors in the evaluation of a Schmidt-Cassegrain telescope's optical system performance is its transmission - the percentage of incoming light that reaches the focal plane. The design of the XLT System accomplishes two crucial objectives: Develop a coating system that is optimized for visual use and for CCD/Photographic imaging.

The StarBright XLT System - What Makes It Different Makes It Better

There are three major components that make up our StarBright XLT high transmission optical system design:

1. Unique enhanced multi-layer mirror coatings
Our mirror coatings are made from precise layers of Aluminum (Al), SiO2 (quartz), TiO2 (Titanium Dioxide), and Si02. Reflectivity is fairly flat across the spectrum, optimizing it for both CCD imaging and visual use. Click here to see a plot of the reflectivity of XLT's Mirror Coatings.

2. Multi-layer anti-reflective coatings
Made from precise layers of MgF2 (Magnesium Fluoride), and HfO2 (Hafnium Dioxide) A rare element costing nearly $2000 per kilogram, Hafnium gives us a wider band pass than Titanium, used in competing coatings. Click here to see a plot of XLT's corrector transmission.

3. High Transmission Water White glass
Celestron Schmidt-Cassegrain optical systems with optional StarBright XLT coatings use Water White glass instead of Soda Lime glass for the corrector lens. Water White glass transmits about 90.5% without anti-reflective coatings. That is 3.5% better transmission than uncoated Soda Lime glass. When Water White glass is used in conjunction with StarBright XLT 's anti-reflective coatings, the average transmission reaches 97.4% - an 8% improvement! Click here to see a plot of water white glass versus soda lime.*

These three components of our StarBright XLT coatings result in one of the finest coatings available. The peak transmission for the systems is 89% at 520 nm. The overall system transmission is 83.5% averaged over the spectrum from 400 to 750 nm. The plot below shows the entire system transmission over the spectrum.

This plot is obtained by measuring the reflectivity of the secondary mirror and the primary mirror and measuring the amount of light transmitted through the coated corrector lens. Each of those values are multiplied together calculate the system transmission. The overall system transmission peaks at 88.9% while the average transmission is 83.5% over the spectrum from 400 to 750nm.

*Percent differences are calculated by taking the comparison data percentage divided by the baseline data. Example: Measured average system transmission for current StarBright is 72%. XLT average system transmission is 83.5%. 83.5% divided by 72% = 1.16 or 16% improvement. Measurement results are rounded to the nearest whole percentage.

StarBright XLT vs. Current StarBright Coatings TOP

StarBright XLT system transmission gives a 16% improvement compared to the current StarBright coatings. The average system transmission for the current StarBright coatings is 72% where the average system transmission StarBright XLT is 83.5%. Current StarBright uses soda lime glass correctors where StarBright XLT uses water white glass, which improves the corrector throughput dramatically.

The average system transmission of StarBright XLT 83.5% compared to current StarBright at 72%. StarBright XLT is a 16% improvement over current StarBright .* The peak transmissions of each being 89% and 80% respectively.

StarBright Mirror Reflectivity Comparison
StarBright XLT mirror reflectivity peaks at 95% and has an average reflectance across the spectrum of 93%. Click on the link above to show how XLT compares to current StarBright and UHTC.

Mirror Reflectivity for StarBright XLT and current StarBright. StarBright XLT reflectivity peaks at 95% and has an average reflectance across the spectrum of 93%. Current StarBright peaks at 94% with an average reflection of 91% across the spectrum.

StarBright Corrector Transmission Comparison
XLT's corrector transmission is 97.4% versus current StarBright with 87% and UHTC with 91% across the spectrum from 450 to 750 nm.

Average XLT transmission of 97.4% versus current StarBright with 87% across the spectrum from 450 to 750 nm. StarBright XLT is a 12% improvement over current StarBright transmission.* StarBright XLT has peak transmission at 99%, while current StarBright peaks at 91%.

Testing Methods: TOP

Total telescope light throughput can be measured in two different ways; either by measurement of the assembled optical system, or by measurement of the reflectance of each mirror (or reflective element), and the transmission of each refractive element in the optical path. In the case of a Schmidt Cassegrain telescope, there are two reflective elements (the primary and secondary mirrors), and one refractive element (the corrector plate, or Schmidt Corrector). See diagram below:

Assembled Telescope vs. Individual Optical Element Analysis:

To measure the throughput of the assembled telescope, a beam of light is passed through the telescope and compared to a beam of equal intensity light passing through air only. Total telescope throughput is then the ratio of light intensity measured through the telescope divided by the light intensity measured through air. This is easily said, but very challenging to execute correctly. Great care must be taken to ensure that the reference beam is of constant intensity, and that its light is collected in a manner which does not bias the results. Errors introduced by beam geometry (f ratio) at the entrance to the detector, less than perfect alignment of the optical elements, including placement and dimensions of internal light baffles, will tend to reduce the intensity of light measured through the telescope.

The second method of measuring total telescope throughput, by spectrophotometric analysis of each element in the optical path, is not susceptible to these sources of error. Furthermore, individual element analysis provides specific information about each optical element, while measuring the throughput of the assembled optical tube does not. Results obtained in this manner represent an upper limit to the actual throughput of the assembled telescope. Total Telescope Throughput (%TT) is less than or equal to Corrector Plate Transmission (%TC) times Primary Mirror Reflectance (%RP) times Secondary Mirror Reflectance (%RS).

Corrector Plate Transmission (%TC):

We use a Shimadzu UV1601 spectrophotometer for analysis of corrector plate transmission. This is a double beam instrument with a spectral range of 190 to 1100nm. Transmission data is typically collected in the visible region from 400 to 750 nm. Small samples of corrector material called witness plates are included in each corrector coating run. In order to minimize handling and the possibility of scratching a full size corrector plate, we use these witness plates to represent the transmission characteristics of our correctors.

Our instrument is capable, however, of measuring the transmission of correctors up to 8" diameter. If this is necessary, the corrector plate is measured at 4 points roughly 90� apart, and the results are averaged. Before and after each measurement, baseline (100%) measurements are made to ensure light source and/or detector drift is negligible.

Primary and Secondary Reflectance (%RP, %RS):

The preferred method of measuring reflectance of primary and secondary mirrors involves the use of witness plates as well. These are small (1" to 2" diameter) flat polished glass substrates, which are coated along with the primary and secondary mirrors. Since the coating process is the same, and the surfaces are equally well polished, the reflectance of the witness plate is the same as that for the primary and secondary mirror. The reasons for using flat witness plates are 1) the primary and secondary mirrors are not themselves subjected to a measurement process which can potentially cause scratches, and 2) very simple test methods and readily available reference standards can be used to measure the reflectance of flat surfaces.

Typically, the reflectance of a surface is measured against a standard reference of known reflectance. Our standard reference is an enhanced aluminum coated quartz flat, calibrated against a NIST (National Institute of Standards and Technology) specular reflectance standard. To measure the reflectance of a flat sample, the baseline measurement is made using this standard, and the reflectance of the sample is compared to this baseline. The sample reflectance factor (%RS) is equal to its reflectance relative to the reference standard (%RSR) times the reference standard's known reflectance (%RR):

However, if the sample to be measured has a curved surface like a secondary or a primary mirror, and there is no witness plate available, then special care must be taken to ensure that the method used to measure reflectance is insensitive to this curvature. If we compared the reflectance of a curved surface directly to that of a flat reflectance standard, our results would not be accurate, since the converging or diverging beam generated by a curved surface would direct either less light (in the case of a secondary mirror), or more light (in the case of a primary mirror) onto the detector than was directed by the flat reference standard.

The most widely used tool for measuring the reflectance of curved surfaces is called an integrating sphere. This device collects and then measures the intensity of light in a manner which is insensitive to beam geometry, hence, insensitive to surface curvature of a reflective sample being measured. However, integrating spheres can be quite expensive, and they are time-consuming to set up and calibrate. We developed a method which is equally insensitive to surface curvature, but much less costly and time consuming to perform. We made our own reference standards from secondary and primary mirrors with the same surface curvature as those we wished to test.

We obtained samples of the secondary and primary mirrors which we wished to test, stripped the existing coating, and replaced it with one for which we also obtained flat witness plates. These flat witness plates were calibrated against a NIST specular reflectance standard. Since the flat witness plates were coated along with the curved samples, and since we have adequate data to show that our coatings are very uniform from part to part in any given coating run, we can apply this reflectance data to our curved samples. Using these curved surface reflectance standards we are able to measure other mirrors of the same curvature just as we use our flat reflectance standard to measure the reflectance of flat samples.

To perform these measurements, we use an Ocean Optics USB2000 Spectrometer with an LS-1 Tungsten Halogen Light Source. This is a single-beam instrument with a 0.3nm resolution, a scanning range from 340nm to 1024nm, and is equipped with a fiber optic curved-surface reflectance measuring probe.

Reporting the Data:

Collecting the data and reducing it to yield total telescope throughput (%TT) (system transmission) is simply a matter of multiplication. We find the average of each data set (%TC, %RP, and %RS) for each wavelength measured, and multiply them together.

TOP

NexRemote

NexRemote Control Software
for Celestron Computerized Telescopes

OVERVIEW
SYSTEM REQUIREMENTS
NEXREMOTE KIT
DOWNLOADS

Celestron has been in the forefront of computerized telescope technology for over two decades. We have taken this expertise in telescope technology one step further by introducing the NexRemote™ Telescope Control Software. NexRemote allows the user to control their Celestron computerized telescope from their personal computer. Everything that is done using the telescope’s hand control can now be done remotely from a PC or laptop. This software was developed for Celestron’s high-end telescopes that use the NexStar control system including the NexStar "i" Series, Advanced Series, NexStar GPS Series and CGE Series.

NexRemote provides full emulation of every aspect of the Celestron Computerized Hand Control including:

Alignment in any tracking mode
Database of objects
User objects
Hibernation
Connect to popular planetarium programs

NexRemote began shipping in March 2005 with select high-end computerized Celestron telescopes including NexStar i Series models, NexStar GPS models and CGE models. Contact your Celestron dealer to find out availability of upgraded models that include NexRemote. Software will also come with an RS-232 cable to connect your Celestron telescope to a PC. For those who already own a compatible Celestron computerized telescope and want to take it to the next level of convenience and enjoyment, the software can be purchased separately as a kit through an authorized Celestron dealer (item# 93710). Kit includes the NexRemote software & license, RS-232 cable and a Serial-to-USB adapter.

System Requirements

Compatible Telescopes:

NexStar SLT
NexStar 8i SE
Advanced Computerized Series
CPC GPS Series
CGE Series
Discontinued Celestron NexStar 8/9.25/11 GPS
Discontinued Celestron NexStar 5i/ 8i

Computer:

PC compatible (Note: 233MHz Pentium II or better is required)
Windows 98SE or better is required for basic operation
Windows NT, 2000, or XP is required for Virtual Port operation
NexRemote will not work with 64 bit version of Windows Vista
DirectX 7 or later must be installed. (DirectX can be obtained for free by clicking here.)
SAPI 5.1 or later is required for speech support. ( This is free to download and can be obtained here.)
MDAC 2.5 or later is required for tour editing. (If no database entries are displayed when you launch NexTour, you can download this update for free by clicking here.)

Port:

RS232 Serial Port (or USB-to-Serial / PCMCIA-to-Serial adapter)

Cable:

PC Port (programming) or HC Serial cable (Note: An additional device is required when using the GT telescopes. Please contact technical support for more details.)

Gamepad:

Logitech Wingman Cordless Rumblepad
Logitech Cordless Rumblepad 2
Logitech Wingman Rumblepad USB
Saitek P3000 Wireless Pad

NOTE: Virtually any gamepad can be configured to work with NexRemote. Read the help files for details.

NexRemote Kit

Now Celestron Advanced Series GT, NexStar “i” Series, GPS, and CGE Series telescopes can be set up and operated remotely from a PC or laptop! NexRemote duplicates all of the functions and features of our NexStar software on the standard NexStar Hand Control plus much more! See our section on NexRemote for more information.

Kit Includes:

NexRemote Software CD with license
RS-232 Cable to connect telescope to PC or Laptop
Serial-To-USB Adapter

Features include:

Use your favorite planetarium software at the same time as NexRemote
Custom tour creation
Use speech support to hear NexRemote say everything out loud
Wireless operation with compatible gamepad

*NexRemote is included with select NexStar "i" Series, GPS, and CGE Series telescopes beginning in March, 2005 (contact your Celestron Dealer for availability of models with NexRemote).

GPS

GPS Compatible
Our NexStar SLT, Advanced Series GT and the CGE Series computerized telescopes are all GPS compatible. With an optional GPS accessory, these telescopes can automatically download the date and time from orbiting GPS satellites and pinpoint their exact location on Earth. This eliminates the need for you to manually enter the date, time, longitude and latitude which not only saves time, but is also very helpful for providing the most accurate alignments.

Flash Upgradeable

For the telescopes that have this technology feature, users can upgrade their telescope's operating software via the Internet.

The following products have this feature:

Current upgrades can be found through our downloads section and on each telescope's product page. To receive an announcement when upgrades have been added, make sure you are subscribed to our mailing list.

SkyAlign Technology

With SkyAlign, setting up and using a computerized telescope is faster and easier than ever before.

US Patent No. 7,382,448

Point the telescope at three bright objects in the sky and the telescope tells YOU what the objects are. You do not need to know the names of the stars – you can even pick the moon or bright planets! SkyAlign is the easiest method to align a computerized telescope; it's perfect for beginners and provides the convenience and accuracy demanded by experienced users.

Input the date, time and your location (GPS models obtain all this information automatically) and then point the telescope at three bright stars of your choosing. There is no need to point the telescope north or to level the optical tube as in previous alignment methods. The initial position of the telescope is irrelevant. This makes for a fast and very easy method for aligning the telescope.

"We decided to test the alignment [SkyAlign] by having the telescope slew to Jupiter. It hit Jupiter DEAD center in the 40mm eyepiece. Not center third of the field of view, not close to center, DEAD center. We were all amazed."
Ben Hauck, Oceanside Photo & Telescope

What is Alignment?
You have to know where you are in order to find your destination – that is what aligning a computerized telescope is all about. The software for the telescope needs to know the exact orientation of the telescope in relation to the night sky in order to find the tens of thousands of celestial objects programmed in the hand control.

Taking the Guesswork out of Alignment
Other methods for aligning a computerized telescope require the user to confirm what star the telescope is pointing at in order to align. If you don't know where Arcturus or Sirius is, how can you confirm that information? The best you can do is guess. SkyAlign is the only alignment method where you truly do not have to know the night sky – and it's only available from Celestron.

How does it work?
Click on the box below to see a demonstration video of SkyAlign (requires Real Player)

The NexStar^® software with SkyAlign measures the distance in each axis between the objects you selected. Given the current time and location, the software then compares the data to the expected distances of objects in the hand control's internal database . Once matches are found, the hand control displays the names of the three objects you selected to help you learn the night sky.

FAQ: What telescopes feature SkyAlign? Will SkyAlign work with equatorial scopes or if my alt/az scope is on a wedge? Will SkyAlign work with my older Celestron computerized telescope? What steps can I take to ensure successful alignment with SkyAlign? What are the steps of the SkyAlign procedure? What telescopes feature SkyAlign? SkyAlign technology is standard in the CPC, NexStar SLT, NexStar 80 GTL and NexStar 8i Special Edition (available only with 11022-XLT-SE-SA models). Will SkyAlign work with equatorial scopes or if my alt/az scope is on a wedge? SkyAlign is not currently available for telescopes mounted equatorially (or on a wedge). Will SkyAlign work with my older Celestron computerized telescope? SkyAlign will work with alt/az Celestron telescopes that use the NexStar software (excluding the original NexStar 5 and NexStar 8 models). A new hand control will be required for this purpose. Please contact Celestron Technical Support for more information on obtaining an upgraded hand control. Upgraded hand controls that feature SkyAlign are also flash-upgradeable, allowing you to download software updates from the Celestron website. What steps can I take to ensure successful alignment with SkyAlign? Level the tripod Be sure to level the tripod before you start. Assumptions about the available bright stars and planets rely on a level tripod. Once the alignment is complete, GoTo and tracking are not dependent upon the accuracy with which you leveled the tripod, so do not spend time seeking perfect level - close is good enough. The CPC and NexStar SLT telescopes feature bubble levels on the tripod to assist with this. Set correct time If you do not have a GPS-equipped telescope, be accurate to within a couple of minutes when entering the time. Also, either select a city within 50 miles or enter your longitude and latitude to within one degree. Pick bright stars Only stars of magnitude 2.5 or brighter are included in the SkyAlign procedure, so it is best to take a look around and select three of the brightest stars in the sky. No need to worry about confusing planets for stars - SkyAlign works with the four brightest planets as well (Venus, Jupiter, Saturn and Mars). Also, you can even use the Moon as one of your alignment objects - though due to the speed with which it moves across the sky and the size, you would need to switch to a low power eyepiece to center it. Pick stars that are far apart from each other. It is helpful to select widely placed objects for alignment. When scanning the sky before you begin, keep this in mind. Only two of the objects (the two with widest separation) will actually be used for calculating the model of the sky. The third object is needed to provide a positive identification of the other two. So, be sure at least two of the three are widely spaced. What are the steps of the SkyAlign procedure? Level the tripod. Setup the scope in alt-az mode - mounted right on top of the tripod. SkyAlign is not currently available when mounted equatorially on a wedge. Power up the scope. Press ENTER to begin and then ENTER again when the display reads SkyAlign. The hand control will show either the current time or the time when you last used the scope. The top line of the display will cycle through the messages, "Enter if OK", and "UNDO to edit". * If your scope has a GPS module, the GPS receiver will shortly lock onto 3 GPS satellites and update the date, time, and location (skip to step 6). If you become impatient waiting for a GPS link, or if you don't have a GPS module in your scope, use the Up and Down buttons (6 and 9 on the keypad) to scroll through the date, time, and location settings. If they are all correct, press Enter to accept and proceed with the alignment. If they need to be adjusted, press Undo and make any necessary corrections. Then you will see a short message about what will happen next - press ENTER to continue. The display will now prompt to Center Object 1. Prior to beginning, you should scan across the sky looking for three bright points. Two of them should have wide separation, the third should not be close to the line connecting the other two. Use the arrow buttons to slew (move) to the first of your bright objects. Center the object in the finderscope and press ENTER. Then center the object in the eyepiece and press ALIGN. Repeat Step 7 for two additional objects and you are finished The hand control displays "Match Confirmed" and then asks you if you'd like to see the matches (hit Enter) or just carry on (hit Undo). If you hit Enter to see the matches, it brings up a list of the matches that you can scroll through. * entering the time will vary depending on the mount type

Celestron Applauds The White House And President Barack Obama For Their Support Of Astronomy And Science Education

TORRANCE, CA – (October 13, 2009) – Celestron® the world’s leading telescope maker and global sponsor of the International Year of Astronomy 2009, applauds the White House and President Barack Obama for their support of astronomy and science education. On Wednesday, October 8, 2009, President Barack Obama and the first lady Michelle Obama hosted what is believed to be the first star party ever to be held at the White House.

President Obama kicked-off the event with a brief address that was streamed live on the whitehouse.gov website. The program at the White House included more than 20 telescopes set up on the White House lawn focused on Jupiter, the Moon and select stars. President Obama, under the direction of his science advisor John Holdren, viewed a double-star in the constellation Lyra through a Celestron CPC 800 computerized telescope. “Celestron commends President Obama for his commitment to science education and support of astronomy. It is imperative that we all work together to bring awareness to our next generation about our place in the universe and the contributions that amateur astronomers can make to modern astronomy.” said Joseph A. Lupica Jr, President and CEO of Celestron.

This star party was held to mark the International Year of Astronomy (IYA2009), which celebrates the 400th anniversary of Galileo's first use of a telescope. "What will your great discovery be?" Obama asked the students before viewing through the telescope. "Galileo changed the world when he pointed his telescope to the sky. Now it's your turn. We need your restless curiosity," the president said. Obama, his wife Michelle, and a group of 150 local middle-school students attended. Also in attendance were two 15-year-old amateur astronomers, Caroline Moore, who at age 14 became the youngest person to discover a supernova, and Lucas Bolyard, who discovered a rare type of ultra-dense star known as a pulsar. Former astronauts Buzz Aldrin, Sally Ride and Mae Jemison, and current astronaut John Grunsfeld joined the historical event as well.

Visit the websites below for information on other notable IYA events happening in 2009:

October 9-23 -- Great World Wide Star Count www.starcount.org
October 19-25 -- Fall Astronomy Week, including Fall Astronomy Day on Saturday, October 24, with the Astronomical League www.astroleague.org
October 22-24 -- IYA Galilean Nights global star party www.galileannights.org
November 10-30 -- NASA’s Image Unveiling hubblesource.stsci.edu/events/iyafinale
IAU International Year of Astronomy website: www.astronomy2009.org

Sky & Telescope Magazine Names SkyAlign as Hot Product for 2006!

The editors at Sky & Telescope Magazine have named Celestron's SkyAlign alignment technology as a Hot Product for 2006 saying our revolutionary product has "redefined and simplified" the computerized telescope setup process.

SkyAlign comes standard on the following Celestron telescope families:

SLT Series
8i Special Edition
CPC Series

As the holiday season swings into high gear, there has never been a better time to consider purchasing a computerized telescope -- especially now that Celestron has pioneered a way to make them easier to use than ever! Contact your local Celestron dealer to find the SkyAlign telescope that is right for you.

For more information about SkyAlign click here.

Motor Control Firmware Updates v.2.2.5

Microsoft Windows - ALL 32 and 64bit versions

Hand Control Firmware Updates v.1.1.14

Microsoft Windows - ALL 32 and 64bit versions

PEC Tool v.1.0.18

Microsoft Windows - ALL 32 and 64bit versions

NexRemote v. 1.7.15 (30 day trial)

Microsoft Windows - ALL 32 and 64bit versions

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