INSTRUCTION MANUAL Meade 114ST EQ-D 4.5" Equatorial Reflecting Telescope
Meade Instruments Corporation
WARNING! NEVER USE A MEADE 114ST EQ-D
TELESCOPE TO LOOK AT THE SUN! LOOKING AT OR NEAR THE SUN WILL CAUSE INSTANT AND IRREVERSIBLE DAMAGE TO YOUR EYE. EYE DAMAGE IS OFTEN PAINLESS, SO THERE IS NO WARNING TO THE OBSERVER THAT DAMAGE HAS OCCURRED UNTIL IT IS TOO LATE. DO NOT POINT THE TELESCOPE OR ITS VIEWFINDER AT OR NEAR THE SUN. DO NOT LOOK THROUGH THE TELESCOPE OR ITS VIEWFINDER AS IT IS MOVING. CHILDREN SHOULD ALWAYS HAVE ADULT SUPERVISION WHILE OBSERVING.

Meade Limited Warranty

Every Meade telescope, spotting scope, and binocular is warranted by Meade Instruments Corp. (MIC) to be free of defects in materials and workmanship for a period of ONE YEAR from date of original retail purchase in the U.S.A. MIC will repair or replace the product, or part thereof, found upon inspection by MIC to be defective, provided the defective part or product is returned to MIC, freight prepaid, with proof of purchase. This warranty applies to the original purchaser only and is non-transferable. Meade products purchased outside North America are not included in this warranty, but are covered under separate warranties issued by Meade International Distributors. RGA Number Required: Prior to the return of any product or part, a Return Goods Authorization (RGA) number must be obtained by writing to MIC or calling 949-451-1450. Each returned part or product must include a written statement detailing the nature of the claimed defect, as well as the owners name, address, phone number, and a copy of the original sales invoice. This warranty is not valid in cases where the product has been abused or mishandled, where unauthorized repairs have been attempted or performed, or where depreciation of the product is due to normal wear-and tear. MIC specifically disclaims special, indirect, or consequential damages or lost profit, which may result from a breach of this warranty. Any implied warranties which can not be disclaimed are hereby limited to a term of one year from the date of purchase by the original retail purchaser. This warranty gives you specific rights. You may have other rights which vary from state to state. MIC reserves the right to change product specifications or to discontinue products without prior notice. This warranty supersedes all previous Meade product warranties.
TABLE OF CONTENTS Telescope Features. 4 Introduction. 6 Unpacking and Assembly. 6 1. Balancing the Telescope. 7 2. Alignment of the Viewfinder. 7 Understanding Celestial Movements and Coordinates. 8 Lining Up with the Celestial Pole. 9 Using the Telescope. 9 Using Setting Circles. 10 Calculating Power. 11 Maintenance. 11 Cleaning. 11 Mount and Tripod Adjustments. 11 Collimation. 12 a. Correct Collimation. 12 b. Diagonal Holder Adjustments. 12 c. Primary Mirror Adjustments. 12 d. Star Testing the Collimation. 13 Specifications: Model 114ST EQ-D. 15 Optional Accessories. 15
Key to Figs. 1a - 1g 1. Eyepiece 2. Equatorial mount 3. Right Ascension (R.A.) flexible cable control 4. Declination (Dec.) flexible cable control 5. Counterweights 6. Counterweight shaft 7. Counterweight lock 8. Safety washer/thumbscrew 9. Viewfinder Dustcover 10. Polar axis 11. Latitude lock knob 12. Optical tube assembly 13. Optical tube saddle plate 14. Optical tube mounting thumbscrews 15. Equatorial mount base 16. Viewfinder bracket mounting bolts 17. Focuser drawtube and eyepiece holder 18. Eyepiece holder thumbscrew 19. Focuser 20. Viewfinder bracket 21. Focus knobs 22. R.A. lock 23. Dec. lock 24. 5 x 24 viewfinder 25. Viewfinder focuser 26. Viewfinder adjustment thumbscrews 27. R.A. setting circle 28. Dec. setting circle 29. Latitude dial 30. Azimuth lock 31. Declination axis 32. Tripod leg brace 33. Tripod leg brace support 34. Tripod legs 35. Tripod-to-mount wingnuts 36. Accessory tray 37. Eyepiece holder slots 38. Mounting bolt hole 39. Telescope front dust cover 40. Collimating Screws 41. Counterweight shaft attachment location

Fig. 1a: Model 114ST EQ-D: Optical tube assembly.
Fig. 1b: Bolt hole for tray assembly. Fig. 1c: Mount features.
Fig. 1d: Optical tube attachment (underside view).
Fig. 1e: More mount features. Fig. 1f: Leg brace and tray assembly.
Fig. 1g: Attaching tripod leg to mount.

INTRODUCTION

The Meade 114ST EQ-D is an easy-to-operate, high performance 4.5" (114mm) reflecting telescope, intended for astronomical observing. Equipped with a deluxe equatorial mount and aluminum tripod, the telescopes motion is continuously adjustable for tracking celestial objects. Your telescope comes to you ready for adventure; it will be your companion in a universe of planets, galaxies, and stars. Please note that the Meade 114ST EQ-D is a Newtonian reflecting telescope optimized for astronomical observing performance, and is not intended for terrestrial observing. We recommend that you take a few minutes to read all of this manual before making first observations through the telescope. As you read this manual, the technical terms associated with telescopes will be made clear.

Standard Equipment

Complete optical tube assembly with a 4.5" (114mm) diameter primary mirror, viewfinder mounting bolts with mounting nuts and rack-and-pinion focuser. Mirror focal length = 1000mm; f/8.8 Equatorial mount with aluminum tripod and leg braces. Accessories: MA 25mm (40x) eyepiece (1.25"O.D.), MA 12mm (83x) eyepiece (1.25"O.D.) 2x Barlow lens 5 x 24 viewfinder and bracket Counterweight with counterweight shaft Flexible cable controls for both telescope axes Accessory tray with mounting knob Astronomy software (separate instructions supplied in software package
UNPACKING AND ASSEMBLY (Numbers in brackets below refer to Fig. 1)
1. Remove and identify the telescopes components, using the listing above. 2. Attach the 3 aluminum tripod legs (6, Fig. 1f) to the base of the equatorial mount (15, Fig. 1g) with the 3 leg braces supports (32, Fig. 1f) facing inward. Three bolts each about 32 2.5"" long, with washers and wing nuts (35, Fig. 1g), are provided for this purpose in a hardware package. Stand the telescope upright, spreading the tripod legs evenly apart so that the accessory tray can be positioned to attach to the 3 leg braces. 3. Use the provided 3 short screws, washers and bolts to attach the accessory tray (36, Fig. 1f) to the tripod. Line up one of the leg braces (32, Fig. 1f) between the opening of one of the tripod leg brace supports 33 (33, Fig. 1f) on the tripod so that one of the short screws will be able to pass through the holes of the leg brace support and the leg brace. Using Fig. 2: Tripod leg brace support a Phillips-head screwdriver, thread one of the short screws through the assembly. hole. Place a washer on the other end, followed by the matching nut. Tighten to a firm feel. Repeat this procedure until all 3 leg braces are mounted on the 3 leg brace supports. See Fig. 2. 4. To attach the accessory tray (36, Fig. 1f) to the leg braces (32, Fig. 1f), place the round accessory tray over the over mounting bolt hole (38, Fig. 1b). Threading the attachment knob into the the mounting hole on top of the tray and turning the knob clockwise. Tighten to a firm feel, but do not overtightenyou will need to Leg lock remove the tray if you wish to collapse the tripod. To remove the tray, just knob rotate the knob counterclockwise and remove the knob. You can then lift Sliding and remove the tray. 5. Extend the sliding center portion of the adjustable height tripod leg to the desired length for all 3 legs. Lock the tripod legs by tightening the leg lock thumbscrew to a firm feel. See Fig. 3.

inner leg extension

6. Holding the counterweight (5, Fig. 1a) firmly in one hand, slip the counterweight onto the counterweight shaft (6, Fig. 1a). Attach the Fig. 3: Adjust the height of the counterweight and counterweight shaft, by supporting the unlocked tripod. counterweight firmly in one hand while threading the counterweight shaft into the base of the Declination axis of the telescopes equatorial mount (41, Fig. 1a). Once firmly attached, slide the counterweight about 2 inches from the bottom of the counterweight shaft and secure it in place with
7 the counterweight lock (7, Fig. 1a) of the counterweight. Note: If the counterweight ever slips, the secured threaded safety washer/screw (8, Fig. 1a) will not let the weight slide entirely off the counterweight shaft. Be certain that this safety washer/screw is always in place. 7. Attach the flexible cables (4, Fig. 1a) and (3, Fig. 1a and 1e), as shown. These cables are secured in place with a firm tightening of the thumbscrews located at the attachment ends of each cable. 8. Tilt the polar axis (10, Fig. 1c) of the telescope to roughly a 45 angle with the horizon. This tilt is accomplished by first loosening the latitude adjustment lock (11, Fig. 1a and 1e), adjusting the mount and firmly re-tightening the latitude control lock. 9. Remove the optical tube attachment thumbscrews (14, Fig. 1d) from the optical tube mounting bolts that are on the underside of the main optical tube (12, Fig. 1a). Then lay the telescope optical tube assembly onto the saddle plate (13, Fig. 1a) passing the mounting bolts through the holes in the saddle of the mount. Re-attach the attachment thumbscrews to the mounting bolts, and tighten to a firm feel. See Fig. 1d. 10. Attach the viewfinder bracket (20, Fig. 1a) to the telescope using the 2 thumbscrews provided (16, Fig. 1a). The bracket fits over the two small bolts. Thread the thumbscrews over the bolts and tighten to a firm feel. Slide the Viewfinder tube (24, Fig. 1a) into the bracket and loosely tighten the tube using the Viewfinder adjustment screws. Remove the Viewfinder dustcover (9, Fig. 1a). See Aligning the Viewfinder below. 11. Insert the 25mm eyepiece (13, Fig. 1) into the eyepiece holder (17, Fig. 1a). Secure the eyepiece in place by tightening the eyepiece holder thumbscrews (18, Fig. 1a) to a firm feel. The telescope is now completely assembled. Before it can be affectively used, however, the viewfinder (24, Fig. 1a) must be aligned with the main telescope.

ALIGNING THE VIEWFINDER

The wide field of view provided by the 5 x 24mm viewfinder permits easy object sighting prior to observation in the higher-power main telescope. The 5 x 24 Viewfinder (24, Fig. 1a) and viewfinder bracket (20, Fig. 1a) attaches to the telescope tube assembly as described above. In order for the viewfinder to be functional, however, it must be aligned to the main telescope, so that both the viewfinder and main telescope point at the same position in the sky. With this simple alignment performed, finding objects is greatly facilitated, since you will first locate an object in the wide-field viewfinder, then you will look in the eyepiece of the main telescope for a detailed view. To align the viewfinder follow these steps: 1. Remove the telescope front dust cover (39, Fig. 1), and the dust cover of the viewfinder (9, Fig. 1a). 2. Place the low- power (MA 25mm) eyepiece into the focuser of the main telescope. 3. Unlock the Right Ascension (R.A.) lock (22, Fig. 1c) and the Declination (Dec.) lock (23, Fig. 1c) so that the telescope turns freely on both axes. Then point the main telescope at some well-defined land object (e.g. the top of a telephone pole) at least 200 yards distant, and re-lock the R.A and Dec. axes. Turn the flexible cable controls, (4, Fig. 1a) and (3, Fig. 1a and 1e), to center the object in the telescopic field. 4. With the front of the viewfinder already centered in the front bracket ring, look through the viewfinder and loosen or tighten, as appropriate, one or more of the rear viewfinder bracket ring thumbscrews (26, Fig. 1a) until the viewfinders crosshairs are likewise centered on the object previously centered in the main telescope. 5. Check this alignment on a celestial object, such as a bright star or the Moon, and make any refinements necessary, using the method outlined above. With this alignment performed, objects first located in the wide-field viewfinder will also be centered in the main telescopes field of view. (Note: The viewfinder presents an image which is upside-down.)

BALANCING THE TELESCOPE

In order for the telescope to move smoothly on its mechanical axes, it must first be balanced as follows: 1. Loosen the R.A. lock (22, Fig. 1a). With the R.A. lock loosened, the telescope mount will turn freely about the polar axis (10, Fig. 1c). Rotate the telescope about the polar axis so that the counterweight shaft (6, Fig. 1a) is parallel to the ground (horizontal).

8 2. Loosen the counterweights lock (7, Fig. 1a) and slide the counterweight (5, Fig. 1a) along the shaft until the telescope remains in any given position without tending to drift up or down the polar axis. Then retighten the counterweight lock. The telescope is now balanced.
UNDERSTANDING CELESTIAL MOVEMENTS AND COORDINATES
Understanding where to locate celestial objects, and how those objects move across the sky is fundamental to enjoying the hobby of astronomy. Most amateur astronomers adopt the simple practice of star-hopping to locate celestial objects by using star charts or astronomical software which identify bright stars and star patterns (constellations) that serve as road maps and landmarks in the sky. These visual reference points guide amateur astronomers in their search for astronomical objects. And while starhopping is the preferred technique, a discussion of using setting circles for locating objects is desirable since your telescope is provided with this feature. However, be advised, compared to star-hopping, object location by use of setting circles requires a greater investment in time and patience to achieve a more precise alignment of the telescopes polar axis to the celestial pole. For this reason, in part, star-hopping is popular because it is the faster, easier way to become initiated in the hobby. Understanding how astronomical objects move: Due to the Earths rotation, celestial bodies appear to move from East to West in a curved path through the skies. The path they follow is known as their line of Right Ascension (R.A.). The angle of this path they follow is known as their line of Declination (Dec.). A celestial coordinate system was created that maps an imaginary sphere surrounding the Earth upon which all stars appear to be placed. This mapping system is similar to the system of latitude and longitude on Earth surface maps. In mapping the surface of the Earth, lines of longitude are drawn between the North and South Poles and lines of latitude are drawn in an East-West direction, parallel to the Earths equator. Similarly, imaginary lines have been drawn to form a latitude and longitude grid for the celestial sphere. These lines are known as Right Ascension and Declination. The celestial map also contains two poles and an equator just like a map of the Earth. The poles of this coordinate system are defined as those two points where the Earths North and South poles (i.e., the Earth's axis), if extended to infinity, would cross the celestial sphere. Thus, the North Celestial Pole (see Fig. 4) is that point in the sky where an extension of the North Pole intersects the celestial sphere. The North Star, Polaris, is located very near the North Celestial Pole. The celestial equator is a projection of the Earths equator onto the celestial sphere. So just as an object's position on the Earths surface can be located by its latitude and longitude, celestial objects may also be located using Right Ascension and Declination. For example: You could locate Los Angeles, California, by its latitude (+34) and longitude (118). Similarly, you could locate the Ring Nebula (also known as M57) by its Right Ascension (18hr) and its Declination (+33). I Right Ascension (R.A.): This celestial version of longitude is measured in units of hours (hr), minutes (min), and seconds (sec) on a 24-hour "clock" (similar to how Earth's time zones are determined by longitude lines). The "zero" line was arbitrarily chosen to pass through the constellation Pegasus, a sort of cosmic Greenwich meridian. R.A. coordinates range from 0hr 0min 0sec to 23hr 59min 59sec. There are 24 primary lines of R.A., North Celestial Pole +90 Dc. +90 Dec. located at 15-degree intervals along Ple nord cleste (Vicinity of Polaris) Etoile Star the celestial equator. Objects located further and further East of the zero R.A. grid line (0hr 0min 0sec) carry higher R.A. coordinates. Declination (Dec.): This celestial Earths rotation Rotation de la Terre version of latitude is measured in degrees, arc-minutes, and arcCelestialcleste Equateur Ascension droite Right Ascension Equator seconds (e.g., 15 27' 33"). Dec. locations North of the celestial equator are indicated with a plus (+) sign (e.g., the Dec. of the North South Ple cleste Sud. Dc.-90 Dc. -90 Dec. Celestial celestial pole is +90). Dec. Pole locations South of the celestial equator are indicated with a minus Fig. 4: Celestial Sphere.

ison clina D

9 () sign (e.g., the Dec. of the South celestial pole is 90). Any point on the celestial equator (such as the the constellations of Orion, Virgo, and Aquarius) is said to have a Declination of zero, shown as 0 0' 0." With all celestial objects therefore capable of being specified in position by their celestial coordinates of Right Ascension and Declination, the task of finding objects (in particular, faint objects) in the telescope can be simplified. The setting circles, R.A. (27, Fig. 1c) and Dec. (28, Fig. 1c) of the Meade 114ST EQ-D telescope may be dialed, in effect, to read the objects coordinates, positioning the object in the vicinity of the telescopes telescopic field of view. However, these setting circles may be used to advantage only if the telescope is first properly aligned with the North Celestial Pole.
LINING UP WITH THE CELESTIAL POLE
Objects in the sky appear to revolve around the celestial pole. (Actually, celestial objects are essentially fixed, and their apparent motion is caused by the Earths axial rotation). During any 24 hour period, stars make one complete revolution about the pole, making concentric circles with the pole at the center. By lining up the telescopes polar axis with the North Celestial Pole (or for observers located in Earths Southern Hemisphere with the South Celestial Pole), astronomical objects may be followed, or tracked, by moving the telescope about one axis, the polar axis. If the telescope is reasonably well aligned with the pole, therefore, very little use of the telescopes Declination flexible cable control is necessary and virtually all of the required telescope tracking will be in Right Ascension. (If the telescope were perfectly aligned with the pole, no Declination tracking of stellar objects would be required). For the purposes of casual visual telescopic observations, lining up the telescopes polar axis to within a degree or two of the pole is more than sufficient: with this level of pointing accuracy, the telescope can track accurately by slowly turning the telescopes R.A. flexible cable control and keep objects in the telescopic field of view for perhaps 20 to 30 minutes. 1. Release the Azimuth lock (30, Fig. 1a and 1e) of the Azimuth base, so that the entire telescopewith-mounting may be rotated in a horizontal direction. Rotate the telescope until the polar axis (10, Fig. 1c) points due North. Use a compass or locate Polaris, the North Star (see Fig. 5), as an accurate reference for due North. 2. Level the mount, if necessary, by adjusting the heights of the three tripod legs.

Little Dipper Little Dipper

Polaris Polaris

Big Dipper Big Dipper

Cassiopeia Cassiopeia

3. Determine the latitude of your observing location Fig. 5: Locating Polaris. by checking a road map or atlas. Release the latitude lock (11, Fig. 1a and 1e) and tilt the telescope mount so that the star Polaris is centered in the telescopes viewfinder eyepiece, then re-tighten the latitude lock. 4. If steps (1) - (3) above were performed with reasonable accuracy, your telescope is now sufficiently well-aligned to the North Celestial Pole for visual observations. Once the mount has been polar-aligned as described above, the latitude angle need not be adjusted again, unless you move to a different geographical location (i.e. a different latitude). The only polar alignment procedure that you need to perform each time you use the telescope is to point the polar axis due North, as described in step 1 above.

USING THE TELESCOPE

With the telescope assembled, balanced and polar aligned as described above, you are ready to begin observations. Decide on an easy-to-find object such as the Moon, if it is visible, or a bright star to become accustomed to the functions and operations of the telescope. For the best results during observations, follow the suggestions below: To center an object in the main telescope, loosen the telescopes R.A. lock (22, Fig. 1c) and Dec. lock (23, Fig. 1c). The telescope can now turn freely on its axes. Use the aligned viewfinder to first sight-in on the object you wish to observe; with the object centered on the viewfinders crosshairs, re-tighten the R.A. and Dec. locks.
10 Always start an observation with a low power eyepiece (the MA 25mm eyepiece); get the object wellcentered in the field of view and sharply focused. Next, insert the MA 12mm eyepiece to try the next step up in magnification. If the image starts to become fuzzy as you work into higher magnifications, then back down to a lower power; the atmospheric steadiness is not sufficient to support high powers at the time you are observing. Keep in mind that a bright, clearly resolved but smaller image will show far more detail than a dimmer, poorly resolved larger image. The MA 25mm eyepiece included with the Meade 114ST EQ-D presents a wide field of view, ideal for general astronomical observing of star fields, clusters of stars, nebulae, and galaxies; it is also probably the best eyepiece to use in the initial finding and centering of any object. Once centered, the object can be focused by turning one of the knobs of the focusing mechanism (21, Fig. 1). You will notice that the astronomical object in the field of view will begin to slowly move across the eyepiece field. This motion is caused by the rotation of the Earth on its axis. To keep astronomical objects centered in the field of the polar aligned telescope, simply turn the R.A. flexible cable control (3, Fig. 1e). These objects will appear to move through the field more rapidly at higher powers. Note that the Declination flexible cable control (4, Fig. 1e) is used only for centering purposes, and not for tracking. Avoid touching the eyepiece while observing through the telescope. Vibrations resulting from such contact will cause the image to move. Likewise, avoid observing sites where ground-based vibrations may resonate the tripod. Viewing from the upper floors of a building may also introduce vibration. You should allow a few minutes to allow your eyes to become dark adapted before attempting any serious astronomical observations. Use a red filtered flashlight to protect your night vision when reading star maps or inspecting the components of the telescope. Avoid setting up the telescope inside a room and observing through an open window (or worse yet, a closed window). Images viewed in such a manner may appear blurred or distorted due to temperature differences between inside and outside air. Also, it is a good idea to allow your telescope a chance to reach the ambient (surrounding) outside temperature before starting an observing session. Avoid viewing objects low on the horizonobjects will appear better resolved with far greater contrast when viewed higher in the sky. Also, if images appear to shimmer in the eyepiecereduce power until the image steadies. This condition is caused by air turbulence in the upper atmosphere. We repeat the warning stated at the outset of this manual: Never point the telescope directly at or near the Sun at any time! Observing the Sun, even for the smallest fraction of a second, will result in instant and irreversible eye damage, as well as physical damage to the telescope itself. Astronomical software, such as StarNavigator, or a good star atlas, will assist you in locating many interesting celestial objects. These objects include: Cloud belts across the surface of the planet Jupiter. The 4 major moons of Jupiter, with the moons positions changing each night. Saturn and its famous ring system, as well as several faint moons of Saturn. The Moon: A veritable treasury of craters, mountain ranges and fault lines. The best time to view the Moon is during its crescent phase. Image contrast during the full Moon phase is low and makes for poor viewing due to the angle of illumination. Deep-Space: Nebulae, galaxies, multiple star systems, star clustershundreds of such objects are visible through the Meade 114ST EQ-D.

USING SETTING CIRCLES

Setting circles of the polar aligned equatorial mount can facilitate the location of faint celestial objects not easily found by direct visual observation. To use the setting circles, follow this procedure: Use a star chart or star atlas, and look up the celestial coordinates, Right Ascension and Declination (R.A. and Dec.), of an easy-to-find bright star that is within the general vicinity of the faint object you wish to locate. Center the determined bright star in the telescopes field of view. Manually turn the R.A. setting circle (27, Fig. 1c) to read the R.A. of the object now in the telescopes eyepiece. The setting circles are now calibrated (the Dec. setting circle (28, Fig. 1c) is factory calibrated). To locate a nearby faint object using the setting circles determine the faint objects celestial coordinates
11 from a star chart, and move the telescope in R.A. and Declination until the setting circles read the R.A. and Dec. of the object you are attempting to locate. If the above procedure has been carefully performed, the faint object will now be in the field of a low power eyepiece. The R.A. Setting Circle must be manually re-calibrated on the current Right Ascension of a star every time the telescope is set up, and reset to the centered objects R.A. coordinate before moving to a new R.A. coordinate setting. The R.A. Setting Circle has two sets of numbers, the inner set is for Southern hemisphere use while the outer set of numbers (the set closest to the R.A. gear), is for use by observers located North of the Earths equator (e.g., in North America).

CALCULATING POWER

The power, or magnification of the telescope depends on two optical characteristics: the focal length of the main telescope and the focal length of the eyepiece used during a particular observation. For example, the focal length of the Meade 114ST EQ-D telescope is fixed at 1000mm. To calculate the power in use with a particular eyepiece, divide the focal length of the eyepiece into the focal length of the main telescope. For example, using the MA 25mm eyepiece supplied with the Meade 114ST EQ-D, the power is calculated as follows:
Power = 1000mm 25mm = 40X
The supplied 2X Barlow lens doubles the power of each eyepiece. Insert the 2X Barlow lens into the the diagonal prism, followed by the eyepiece, and secure by tightening the respective thumbscrews. For example, the 25mm (40X) eyepiece, when used with the 2X Barlow Lens, yields 80X. The letters MA refers to the Modified Achromatic optical design, which yields corrected images. The optical design has no bearing on the power of the eyepiece. Meade Instruments manufactures several types of eyepiece designs that are available for your telescope. The type of eyepiece (MA Modified Achromatic, SP Super Plssl, etc.) has no bearing on magnifying power but does affect such optical characteristics as field of view, flatness of field, eye relief, and color correction. The maximum practical magnification is determined by the nature of the object being observed and, most importantly, by the prevailing atmospheric conditions. Under very steady atmospheric seeing, the Meade 114ST EQ-D may be used at powers up to about 228x on astronomical objects. The maximum practical magnification is determined by the nature of the object being observed and, most importantly, by the prevailing atmospheric conditions. Under very steady atmospheric seeing, the Meade 114ST EQ-D may be used at powers up to about 228x on astronomical objects. Generally, however, lower powers of perhaps 75x to 175x will present the best images consistent with high image resolution. When unsteady air conditions prevail (as witnessed by rapid twinkling of the stars), extremely high-power eyepieces result in poor magnification, where the object detail observed is actually reduced by the excessive power. When unsteady air conditions prevail (as witnessed by rapid twinkling of the stars), extremely high-power eyepieces result in poor magnification, where the object detail observed is actually reduced by the excessive power.

MAINTENANCE Cleaning

As with any quality instrument, lens or mirror surfaces should be cleaned as infrequently as possible. Front surface aluminized mirrors, in particular, should be cleaned only when absolutely necessary. In all cases avoid touching any mirror surface. A little dust on the surface of a mirror or lens causes negligible loss of performance and should not be considered reason to clean the surface. When lens or mirror cleaning does become necessary, use a camels hair brush or compressed air gently to remove dust. If the telescopes dust cover is replaced after each observing session, cleaning of the optics will rarely be required.
Mount and Tripod Adjustments
Every Meade 114ST EQ-D equatorial mount and tripod is factory inspected for proper fit and function prior to shipment. The tripod legs have wingnuts (35, Fig. 1g). They may be tightened to a firm feel for a more sturdy performance of the telescope.
Collimation (Alignment) of the Optics
All Meade 114ST EQ-D telescopes are optically aligned at the factory prior to shipment. It is unlikely that you will need to align, or collimate, the optics after receipt of the instrument. However, if the telescope received unusually rough handling in shipment, it is possible that the optics must be re aligned for best optical performance. In any case this alignment procedure is simple, and requires only a few minutes the very first time the telescope is used. Take the time to familiarize yourself with the following collimation procedure, so that you will recognize a properly collimated instrument and can adjust the collimation yourself, if necessary.

a. Correct collimation

The properly collimated (aligned) mirror system in the Meade 114ST EQ-D assures the sharpest images possible. This occurs when the primary mirror and diagonal mirror are tilted so that the focused image (see Fig. 6) falls directly through the center of the focuser drawtube (17, Fig. 1a). These mirror tilt adjustments are made with the diagonal assembly (Fig. 7) and the primary mirror cell (Fig. 8), and will be discussed later. To inspect the view of the mirror collimation, look down the focuser drawtube with the eyepiece removed. The edge of the focuser drawtube (1, Fig. 9), will frame the reflections of the primary mirror with the 3 mirror clips (2, Fig. 9), the diagonal mirror (3, Fig. 9) , the spider vanes (4, Fig. 9), and your eye (5, Fig. 9). Properly aligned, all of these reflections will appear concentric (i.e., centered) as illustrated in Fig. 9. Any deviation from the concentric reflections will require adjustments to the diagonal assembly (Fig. 7), and/or the primary mirror cell (Fig. 8).

b. Diagonal holder adjustments
If the diagonal mirror (1, Fig. 10) is centered in the drawtube (2, Fig. 10), but the primary mirror is only partially visible in the reflection (3, Fig. 10), the 3 Phillips-head diagonal tilt screws (1, Fig. 7). Note: To adjust these screws you must first remove an adhesive backing) must be unthreaded slightly to the point of where you can tilt the diagonal holder (3, Fig. 7) from side-to-side by grasping the diagonal holder with your hand and tilt until you see the primary mirror become as centered in the reflection of the diagonal mirror as possible. Once you are at the best position, thread in the 3 Phillips-head diagonal tilt screws to lock the rotational position. Then, if necessary, make adjustments to these 3 Phillips-head screws to refine the tilt-angle of the diagonal mirror until the entire primary mirror can be seen centered within the diagonal mirror reflection. When the diagonal mirror is correctly aligned, it will look like Fig. 10. (Note: The primary mirror is shown out of alignment.)
c. Primary mirror adjustments
If the diagonal mirror (1, Fig. 11) and the reflection of the primary mirror (2, Fig. 11) appear centered within the drawtube (3, Fig. 11), but the reflection of your eye and the reflection of the diagonal mirror (4, Fig. 11) appear off-center, you will need to adjust the primary mirror tilt Phillips-head screws of the primary mirror cell (3, Fig. 11). These primary tilt screws are located behind the primary mirror, at the lower end of the main tube. See Fig. 6. To adjust the primary mirror tilt screws, first unscrew several turns, the 3 hex-head primary mirror cell locking screws (2, Fig. 8) that are next to each primary mirror tilt Phillips-head screw. Then by trial-and-error, turn the primary mirror tilt Phillips-head screws (3, Fig. 8) until you develop a feel for which way to turn each screw to center the reflection of your eye. Once centered, as in Fig. 9, turn the 3 hex-head primary mirror cell locking screws (2, Fig. 8) to relock the tilt-angle adjustment.
Diagonal Monture Assembly Diagonale
Miroir Diagonal Diagonal Mirror
PrimaryPrimaire Miroir Mirror
Focused Image Image Focalise
Vis D'inclinaison Primary Mirror-Tilt Screws du Miroir Primaire
Fig. 6: The Newtonian Reflecting Telescope.
Remove With the collimation performed, you will want to test the accuracy of the adhesive alignment on a star. Use the MA 25mm eyepiece and point the telescope at backing a moderately bright (second or third magnitude) star, then center the star image in the telescopes field-of-view. With the star centered follow the 2 method below: 1 Bring the star image slowly out of focus until one or more rings are visible around the central disc. If the collimation was performed correctly, the central star disk and rings will be concentric circles, with a dark spot dead center within the out-of-focus star disk (this is the shadow of the Fig. 7: Diagonal Assembly. secondary mirror), as shown in Fig. 12C. (An improperly aligned telescope will reveal elongated circles (Fig. 12A), with an off-center dark shadow.) If the out-of-focus star disk appears elongated (Fig. 12A), you will need to adjust the primary mirror Phillips-head tilt screws of the primary mirror cell (3, Fig. 8). To adjust the primary mirror tilt screws (3, Fig. 8), first unscrew several turns the 3 hex-head primary mirror cell locking screws (2, Fig. 8), to allow free turning movement of the tilt knobs. Using the flexible cable controls (3, Fig. 1e and 4, Fig. 1a), move the telescope until the star image is at the edge of the field-of-view in the eyepiece, as in Fig. 12B. As you make adjustments to the primary mirror tilt screws (3, Fig. 8), you will notice that the out-offocus star disk image will move across the eyepiece field. Choose one of the 3 primary mirror tilt screws and slightly move the shadow to the center of the disk. Then slightly move the telescope using the flexible cable controls to center the star disk image in the center of the eyepiece.

d. Star testing the collimation
If any further adjustments are necessary, repeat this process as many times as needed until the outof-focus star disk appears as in Fig. 12C, when the star disk image is in the center of the eyepiece field. With the star testing of the collimation complete, tighten the 3 hex-head primary mirror locking screws (2, Fig. 8).
Fig. 8: Primary Mirror Cell.
Fig. 9: Correct Collimation.
Fig. 10: Diagonal Mirror Misalignment.
Fig. 11: Primary Mirror Misalignment.

Fig. 12: Collimation.

SPECIFICATIONS
Primary (main) mirror focal length:.1000mm Primary mirror diameter:.4.5" (114mm) Focal ratio:.f/8.8 Mounting:.German equatorial

OPTIONAL ACCESSORIES

See your Meade 114ST EQ-D dealer for further details on any of these accessories. See your Meade 80 EQ1-b dealer for further details on any of these accessories. Additional Eyepieces (1.25" barrel diameter): For higher or lower magnifications with the telescopes that accommodate 1.25" eyepieces, Meade 3-element Modified Achromatic eyepieces, available in focal lengths of 9 and 40mm, provide a high level of image resolution and color correction at an economical price. Also, at slightly higher prices, Meade 4-element Series 3000 Plssl eyepieces yield wider fields of view with excellent edge-of-field corrections and are available in a range of focal lengths including 5, 6.7, 9.5, 16, 25, and 40mm. Basic Camera Adapter: Permits direct attachment of 35mm SLR cameras to the telescope. (Requires T-Mount for your specific brand of camera). Suitable for lunar disk and land photography.

ADVANCED

PRODUCTS

DIVISION

Worlds Leading Manufacturer of Astronomical Telescopes for the Serious Amateur
6001 Oak Canyon, Irvine, California 92618 I (949) 451-1450 FAX: (949) 451-1460 I www.meade.com

ver 7/03

COPST COPSTCP CO0.5PST COSM40T COSM40T10 COSM60T
620.95 685.18 1,777.20 2,212.57 2,569.44 4,517.93
539.64 595.47 1,544.49 1,922.86 2,233.00 3,926.36

9 / 26

CO0.5SM60T COSM70T CO0.05SM70T COSM90T15 COSM90T30 CO0.5SM90T15 CO0.5SM90T30 COCaK70T CO40OTA

CO60OTA

CO90OTA
SolarMax 60 Package <0.5 Angstrom SolarMax 70 <0.7 Angstrom SolarMax 70 <0.5 Angstrom SolarMax 90 Package with BF15 <0.7 angstrom SolarMax 90 Package with BF30 <0.7 angstrom SolarMax 90 Package with BF15 <0.5 Angstrom SolarMax 90 Package with BF30 <0.5 Angstrom Ca-K 70mm Telescope OTA para SM40 - Tubo ptico optimizado para SolarMax40. Incluye anillos de montaje. No incluye filtro. Para quien tiene en SM40. OTA para SM60 - Tubo ptimo optimizado para SolarMax60. Incluye anillos de montaje. No incluye filtro. Para quien tiene un SM60. OTA para SM90 - Telescopio optimizado para SolarMax90. OTA con anillos de montaje & un juego de oculares Cemax. No incluye filtro. Para quien tiene un SM90. BINOCULARES
6,280.85 3,854.16 6,280.85 12,845.77 13,673.70 15,273.89 16,101.82 3,854.16 1,141.97
5,458.45 3,349.50 5,458.45 11,163.77 11,883.29 13,273.95 13,993.47 3,349.50 992.44

1,377.51

1,197.14

4,710.64

4,093.84
COBINO1 COBINO2 COBBM COBF5 COBFETX COBF10 COBF15 COBF30 COTmax 40 COTmax 60 COTmax 90 COCE12 COCE18 COCE25 COBAR COCEP COSOL COSOLC COPSTC COMalta COHAT COZO COAP180 COAP141 COAP175 COAP132 COAP151 COAP106 COAP163 COAP152 COAP187 COAP110 COAP178 COAP107 COAP131 COAP128 COAP153 COAP142 COAP113 COAP149
Binomite 10x25 Binomite II 12x60 BinoMax Canon ACCESORIOS 5mm Blocking Filter ETX BF Pennywhistle 10mm Blocking Filter 15mm Blocking Filter 30mm Blocking Filter Doppler Tuning Unit for SM40 Doppler Tuning Unit for SM60 Doppler Tuning Unit for SM90 Cemax 12mm Eyepiece Cemax 18mm Eyepiece Cemax 25mm Eyepiece 2x Barlow 12,18,25, 2x Barlow (4pc Package) SolRanger Sol Rranger & Clamshell Rings for SM40T PST Case Malta Tripod Mount UV Protection Material Hat Zero Length Adapter Adapter Plate - 5" Meade/127ED SM60 Adapter Plate - AP130/4"SM90 Adapter Plate - AP152 for 145ERF Adapter Plate - Astro Physics 155 SM90 Adapter Plate - Astro Physics 90 SM90 Adapter Plate - Astro Physics EDL-92 SM60 Adapter Plate - Astro Physics Starfire 7 SM90 Adapter Plate - Astro Physics Stowaway SM60 Adapter Plate - Astro Physics Stowaway SM90 Adapter Plate - Astro Physics Traveler SM90 Adapter Plate - Astro Physcis 130 SM60 Adapter Plate - Borg 50 SM40 Adapter Plate - Borg 76 SM60 Adapter Plate - Brandon 4 SM60 Adapter Plate - Brandon 94 SM90 Adapter Plate - BW Optic 100 SM90 Adapter Plate - Cel ST90/Orion ST-90/VX90 SM40 Adapter Plate - Celestron 102/Vixen SM90