s, the two large enclosures on the left and right are the
Nasmyth platforms, instruments at the
Cassegrain focus are visible at the base, and the three black boxes in the centre house the calibration lamps located at
folded Cassegrain.|alt=White metal truss frame inside white dome atop a circular base and flanked by two rectangular boxes on either side.
Optics The telescope consists of a
f/2.5 primary mirror made by
Owens-Illinois from
Cervit, a
zero-expansion glass-ceramic material, and ground by
Grubb Parsons. The
mirror blank was produced in 1969 as one of a set of four, along with those for the
AAT,
CFHT and
Blanco telescopes, and was purchased for the WHT in 1979, ten years after it was made. The primary is solid and un-thinned, so no
active optics system is required, despite its weight of . The
mirror support cell holds the main mirror on a set of 60
pneumatic cylinders. Even under the most extreme loading (with the telescope pointing at the horizon, so the mirror is vertical) the shape of the mirror changes by only ; during normal operation the deformation is much smaller. In its most usual configuration, a
hyperbolic secondary mirror made of
Zerodur is used to form a
Ritchey Chretien f/11 Cassegrain system with a 15
arcmin field of view. An additional
flat fold mirror allows the use of any one of two
Nasmyth platforms or two
folded Cassegrain stations, each with 5 arcmin fields of view. The telescope sometimes operates in a wide-field
prime focus configuration, in which case the secondary is removed and a three element
field-correcting lens inserted, which provides an effective
f/2.8 focus with a 60 arcmin field of view (40 arcmin
unvignetted). Changing between the Cassegrain and Nasmyth foci takes a matter of seconds and may be done during the night; switching to and from prime focus requires replacing the secondary mirror with a prime focus assembly during daytime (the two are mounted back-to-back) which takes around 30 minutes. A
Coudé focus was planned as a later addition, to feed an
optical interferometer with another telescope, but this was never built. A
chopping f/35 secondary mirror was planned for
infrared observations, but was placed on hold by the cost-saving re-design and never implemented.
Mount The optical system weighs and is manoeuvred on an
alt-azimuth mount, with a total moving mass of (plus instruments). The
BTA-6 and
Multi Mirror Telescope had demonstrated during the 1970s the significant weight (and therefore cost) savings which could be achieved by the alt-azimuth design compared to the traditional
equatorial mount for large telescopes. However, the alt-azimuth design requires continuous computer control, compensation for field rotation at each focus, and results in a 0.2 degree radius blind spot at the
zenith where the drive motors cannot keep up with
sidereal motion (the drives have a maximum speed of one degree per second in each axis). The mount is so smooth and finely balanced that before the drive motors were installed it was possible to move the then assembly by hand. During
closed loop guiding, the mount is capable of an absolute pointing accuracy of 0.03
arcseconds.
Dome The telescope is housed in an
onion-shaped steel dome with an internal diameter of , manufactured by
Brittain Steel. The telescope mount is located on a cylindrical concrete pier so that the centre of rotation is above ground level, which lifts the telescope above
ground-layer air
turbulence for better
seeing. A conventional up-down 6m-wide shutter with wind-blind, several large vents with
extractor fans for thermal control, and a capacity crane (used for moving the primary mirror e.g. for
aluminising) are all incorporated. The size and shape of the shutter allow observations down to 12° above the
horizon, which corresponds to an
airmass of 4.8. The total moving mass of the dome is , which is mounted on top of a three-
storey cylindrical building. The dome was designed to minimise wind stresses and can support up to its own weight again in ice during inclement weather. The dome and telescope rest on separate sets of
foundations (driven down into the volcanic basalt), to prevent vibrations caused by dome rotation or wind stresses on the building affecting the telescope pointing. Attached to the dome is a three-storey rectangular building which houses the telescope control room, computer room, kitchen etc. Almost no human presence is required inside the dome, which means the environmental conditions can be kept very stable. As a result, the WHT obtains perfect
dome seeing. This building also houses a
detector laboratory and a re
aluminising plant. Because the WHT has the largest single mirror at the
Roque de los Muchachos Observatory, its realuminising plant has a vacuum vessel large enough to accommodate the mirrors from any other telescope on the mountain. As a result, all of the other telescopes at the observatory contract to use the WHT plant for their realuminising (with the exception of the
Gran Telescopio Canarias, which has its own plant). ==Operations==