Hubble Optics Lightweight Sandwich Mirror
The 40" sandwich mirror delivered to NASA in 2014
- We have developed a revolutionary lightweight sandwich mirror, that is a cost effective and superior alternative to other lightweight and solid mirrors available on the market.
- Our sandwich mirrors have been used by NASA, US army, Princeton University, California State Polytechnic University, and numerous other organizations and individuals around the world. The Hubble sandwich mirrors are designed and built in a similar style to the Hubble Space Telescope, the most advanced telescope ever built.
- Currently, our lightweight sandwich mirrors are available from 12” to 40" in diameter.
- Thermal and Structural optimized open core, and dynamically stable closed back design.
- Rapid Thermal Response: cools down about 10 times faster than a solid mirror of equal thickness.
- Outperforms both conventional solid and closed cell lightweight mirrors in term of image quality in the real world observation.
- Simple Flotation Mounting.
- Lighter than the solid mirrors (with weight saving about 20% comparing with the solid mirrors of equal thickness) Cost competitive and unprecedented price/performance ratio.
Why would you select a Sandwich Mirror?
Telescope mirrors are manufactured in a strictly controlled temperature and humidity environment. Each mirror is carefully measured after it has reached equilibrium in our laboratory. While cooling, gradients in the mirror will cause deformation of the surface, and the aberrations induced by these gradients will be proportional to the CTE of the substrate. These gradient-induced aberrations die out as the mirror cools and equilibrates.
The main problem is not the aberrations due to deformation, but the layer of warm air in front of the primary mirror. This layer of warm air is the main cause of the image distortion called "mirror seeing", which is caused by the non-uniform index of diffraction in the cooler air over the warm mirror surface. No mirror, regardless of the type of glass used, will perform adequately until the mirror is close to the temperature of the ambient air. This occurs when the temperature difference between glass and air is less than one degree centigrade (°C), and best performance is achieved when this difference is less than 0.2 °C.
Therefore, the goal is to bring the temperature of the mirror to within 0.2 °C of the ambient air temperature as quickly as possible. This will greatly reduce image distortion due to mirror seeing. This is why all large professional mirrors, regardless of the type of glass used, employ complicated cooling systems to cool the primary mirror. For example, the Advanced Technology Solar Telescope (ATST) 4.24-meter primary mirror uses a jet cooling system.
Based on the extensive research, ASTS concluded that "thinner substrates dramatically reduce the thermal time lag", Technical Note #0028 by Nathan Dalrymple. For any mirror, cross sectional thickness of the glass is the primary factor in determining the thermal time temperatures during observing or imaging, your full thickness mirror may never reach equilibrium, and never reach its full optical potential. This is one of the major reasons why our lightweight-sandwich mirror has superior optical performance in real world situations, even without an active cooling system. (Active cooling systems, such as fans, introduce their own serious problems, such as micro vibration, which can seriously degrade the image quality if not done correctly.) Our mirrors reach equilibrium extremely fast, and without aid.
So, with our lightweight-sandwich mirror, what is measured in the laboratory is observed in the field.
Hubble 40" f/3.3 sandwich mirror in action (SDM telescope) at the Leon Mow Dark Sky Site near Heathcote, Melbourne
“It’s been 6 months now since we had first light on what is Australia’s largest privately owned telescope. Situated at the ASV’s Leon Mow Dark-Sky Site in a roll off roof observatory, 2 hours north of Melbourne, the views continue to get better and better since we have learned to manage temperature of the interior of the observatory prior to using the telescope. There are a lot of objects which have been transformed for me with this aperture, but the stand-out one to date has to be glimpsing the globular cluster in NGC253 which forms a loose triangle with the two bright 9th magnitude stars south of the galaxy core. Thanks Hubble Optics for the chance to experience the views that I and the ASV have seen and will see in the future".
20" f/4 Bino Scope made by Kunho Lee and his friend
16" f/4 Strock Style Travel Scope made by Cyrille Thieullet
Images taken with 16" f/5 Hubble Sandwich Mirrors by Emanuele De Giorgio
|OD||Thickness(mm)||Price(Plate glass)||Price(Pyrex glass)|
Strehl Ratio >= 0.95
For faster mirrors, there is 15% surcharge for each 1/2 stop of the speed.
The above prices include the standard Al + SiO2 overcoating.
The 92% Semi-enhacned, 96% Enhanced Aluminum and 97% Protected Silver coatings are available with additional charges:
|Diameter||Semi-enhanced Coating||Enhanced Coating|
All our stocked mirrors are the same high quality mirrors as our standard mirrors (1/10 or better in PV, about 1/50 in RMS, and 0.95 or better in Strehl ratio, with the 96% enhanced aluminum coating free of extra charge).
The mirrors will be shipped from Hong Kong. The air shipping will take about 10+ business days, while the surface will take about 10+ weeks.
|Optical Diameter, F/#||THK(mm)||WT(kg)||Reg.(US$)||Sales(US$)||Price with shipping|
|12"(304.8mm) f/3.0 Plate Glass Sandwich Mirror||~41||~5.8||$950|
|12"(304.8mm) f/3.5 Plate Glass Sandwich Mirror||~41||~5.8||$800|
|12"(304.8mm) f/4.0 Plate Glass Sandwich Mirror||~41||5.8||$700|
|12"(304.8mm) f/4.5 Pyrex Sandwich Mirror||~50||~5.4||1,585||Out of Stock|
|12"(304.8mm) f/4.5 Plate Glass Solid Mirror||~24||~4||$600|
|12"(304.8mm) f/5.0 Plate Glass Sandwich Mirror||~41||~5.8||$850||Out of Stock|
|14"(355.6mm) f/3.5 Plate Glass Sandwich Mirror||~39||~7.8||$1,095|
|14"(355.6mm) f/4.0 Plate Glass Sandwich Mirror||~39||~7.8||$995|
|14"(355.6mm) f/4.5 Plate Glass Sandwich Mirror||~39||~7.8||$850|
|14"(355.6mm) f/4.6 Plate Glass Sandwich Mirror||~39||~7.8||$850|
|14"(355.6mm) f/5.0 Plate Glass Sandwich Mirror||~39||~7.8||$750|
|16" (406.4mm) f/4.0 Plate Glass Sandwich Mirror||~42||~10.5||$1,350|
|16" f/4.5(406.4mm) Plate Glass Sandwich Mirror||~42||~10.5||$1150|
|16" f/5.0(406.4mm) Plate Glass Sandwich Mirror||~42||~10.5||$1050|
|18"(457.2mm) f/3.5 Plate Glass Sandwich Mirror||~42||~14.5||$1,925|
|18"(457.2mm) f/4.0 Plate Glass Sandwich Mirror||~42||~14.5||$1,725|
|18"(457.2mm) f/4.1 Plate Glass Sandwich Mirror||~47||~14.5||$2,125|
|18"(457.2mm) f/4.2 Plate Glass Sandwich Mirror||~47||~14.5||$1,600|
|18" (457.2mm) f/4.5 Plate Glass Sandwich Mirror||~47||~14.5||$1,500|
|20" (508mm) f/3.3 Plate Glass Sandwich Mirror||~49||~17||$3,000|
|20" (508mm) f/3.7 Plate Glass Sandwich Mirror||~49||~17||$2,750|
|20" (508mm) f/4.0 Plate Glass Sandwich Mirror||~49||~17||$2,500|
|20" (508mm) f/4.2 Plate Glass Sandwich Mirror||~49||~17||$2,200|