The domes at Moore and Mt. Kent observatories have their own control systems designed to interface with the electromechanical hardware supplied by the dome manufacturer. The esstential design elements shared by all domes are
Additionally, some domes have environmental and shutter status monitors.
This page is a description of the dome control hardware and software highlighting similarities and differences between the systems for the various telescope enclosures at Moore and Mt. Kent observatories.
We use an RFID tag encoder that senses tags attached to the inside perimeter of a dome. On the CDK20 Sirius domes, the tags are attached to the gear drive rail as shown here:
The tags on CDK20N are 4 degrees apart. Each tag has a unique identifying code. When the dome rotates and brings a tag into the sensing space of a tag reader, software traps the tag event and identifies the dome azimuth angle based on a map of tags to angle that is saved for each dome.
The tag readers are from Phidgets, a company that makes USB-interfaced hardware for electronics hobbiest. They supply an OpenSource library that enables us to include the tag reader in the dome control software.
Dome rotation software has been written to use the INDI protocol and communicate with the telescope control software in an observatory operations package.
More information is available on the Shared Skies software page.
The original Sirius electronics control dome rotation and the opening and closure of the upper and lower shutters. The control board is proprietary, but its operation is determined by wiring to screw terminals that we have modified to connect to external systems.
This schematic shows a how a switch will apply 12 VDC power to one of two lines that select the direction of rotation, or similarly open or close the two shutters. In computer controlled operation there is a relay system in parallel with the manual switch, such as shown here:
with the power for the relays provided by the "COM" 12 VDC power of the dome electronics. Note that "COM" is not ground, but the common 12VDC from the battery power of the system. Fuses and circuit breakers protect the motors from overload, and the control board is designed so that most operations are safe. In this respect, there are limit switches on the shutter motion that turn off power to the motors when the shutters are fully open or closed. There is no hard-wired logic to insure that the lower shutter is closed before the upper shutter drops down over it, however.
At the CDK20N we have a relay box mounted on the dome wall containing 6 socketed industrial relays with 12 VDC coils. The relays are wired such that the application of the "COM" voltage to a control line causes the relay to close with the same effect as the corresponding switch.
There is a dropline from the dome electronics to the relay box to allow the connection of the static relay system to the rotating dome. The line falls at the perimeter of the dome. When the line is in use, software prohibits rotating the dome through azimuth 0 (shutter opening to the north) to lessen the chance of the cable snagging. The dropline is connected through an 8-pin Phoenix Contact connector that will pull apart if the cable is caught.
The relay box may be controlled by logic level electronics or by a web switch. In the first generation of this system a National Instruments PCI-6518 digital logic controller with open collector logic was intalled in the telescope computer. With the replacement of the computer in the fall of 2011 we changed operation to use a Digital-Loggers Web Din Relay shown here:
The device provides a robust configurable interface that enables web-based control of the dome shutters and rotation. Since it runs its own internal server. interfacing with it is simple through TCP/IP over port 80.
Each labelled relay controls a single normally open line, and connects to the dome 12 VDC system to switch on that function. The lines are color coded, and connected by a 9-wire cable that is terminated with a Phoenix Contact connector close to the DIN controller:
This relay order leaves a safe gap on the user interface between shutter and dome rotation. It also avoids relay 3 which, on the module in the CDK20N dome, may have a high resistance contact.