Preface

The Global Interlock System (GIS) Design represents a challenge in that its design is in parallel with (and in some cases before) the designs of the systems it is meant to safeguard. Without completed designs and hazard analyses, the safety functions that the GIS are to implement cannot be completely defined.

The design of the Global Interlock System has been separated into two main portions. There is the hardware design, the GIS Architecture, which is the subject of SPEC-0112. The second portion is the software design, the GIS Functional Description, which is handled in this document.

The reason for this separation is that the hardware design has been developed and is well understood. The GIS Functional Design requires the completion of subsystem designs, hazard analyses, and risk assessments.

In order to not delay development and construction of the GIS Architecture, the two portions have been separated.

The hardware architecture has been designed with the premise of flexibility, expandability, and programmability as basic considerations. This lends itself well to being adaptable to any safety function that may need to be implemented.

Introduction

Purpose

This document provides the basis of design for the architecture of the DKIST Global Interlock System (GIS). The design of the GIS is provide in two main sections, the architecture which describes the hardware and interfaces of the system; and the functional design which covers design and implementation of the safety-related control functions.

The diagrams and descriptions of safety function presented below are meant to convey the general flow of the safety function and the interactions between the various subsystems. They are not intended to cover the implementation details. For example, almost all safety inputs and outputs are redundant and usually employ negative logic, meaning that for a single item such as “Door 501A locked” there are two signals that indicate the door is not closed plus two more signals that indicate the solenoid controlling the door is not unlocked. Including this level of detail would add complexity and not aid in understanding how the various safety functions control safety.

Scope

This document, GIS Functional Design, is intended to cover safety-related control functions (SRCFs) that are handled by the GIS. Some safety-related control functions are handled by individual subsystems. The distinction of which are covered by the GIS is based on a hazard analysis, generally only those SRCFs that require SIL 3 mitigation, mitigation above the SIL rating of the subsystem controller, or those SRCFs that span multiple subsystems are GIS safety functions.

Revision Control

To aid in tracking and control of various revisions to the application code the Project Vault (Solidworks Enterprise PDM) shall be used. Because the code is being developed in a single developer environment the need for a more advanced and robust solution is not necessary and would add complexity with little value. Also the ladder logic is stored in proprietary binary format that does not lend itself well to the use of standard versioning control software.

The Project Vault allows for the control of changes and edits in a single user environment as well as the ability to roll back changes if needed. It is centrally located and can be accessed remotely as needed.

The Project Vault shall be used continuously from development into operations.

Ladder Logic Example

Inputs from each LIC are consumed, and evaluated; subsequent outputs are produced to other LICs as necessary.

Figure 2‑1 shows a short example of the ladder logic of the safety task that would be used with a typical emergency stop circuit. The program uses application instructions that not only monitor the condition of the emergency stop switch, but compares the two channels for consistency and also monitors the status of the remote I/O module to detect a hardware failure. In the event of a hardware failure, the system defaults to a safe state.

Figure 2‑1

The program combines inputs from local emergency stop switches with a tag received from the GIC which indicates the status of the Emergency Stop System. If both are in the active safe state then two outputs are asserted that energize the drive and enable the pulse output of the drive.

When an emergency stop switch is pushed (or a hardware fault is detected), the two outputs are removed. First the output to the drive pulse suppression is removed and 200mS later (configurable) the power is removed from the drive’s power contactor removing all hazardous energy. If either feedback from the outputs does not indicate that the drive was properly shutdown a fault will be detected that can warn personnel that a potential hazard still exists.

GIS Operation

Status Monitoring and Fault Handling

In addition to the various safety functions implemented by the GIS, the GIS must also recognize and react to any fault that is detected.

The distributed I/O modules perform self-diagnostics on power-up and periodically during operation. In addition these modules also monitor I/O circuit health.

Embedded Control Operation

Each LIC is the safety controller for one or more subsystems. The application program for each LIC functions as an independent system. The safety controller is capable of startup and control of its safety functions regardless of connectivity to the GIC or other outside service.

Change of Network Status

Failure of the network does not result in a loss of safety function. Failure of the network which causes loss of communications with distributed I/O or a remote controller causes each such component of the GIS that relies on such communications to default to a safe state.

Restoration of the network function does not automatically restore operation of the GIS without intervention from the operator.

Operation following a rebooting or restarting

Rebooting or restarting causes the portion of the GIS that was rebooted or restarted to enter a safe state. Rebooting or restarting does not result in a loss of safety function.

Modes of operation

Automatic

Automatic operation is control handled by a computer interface in the control room (or other authorized location). Typically this is control by the Observatory Control System (OCS). Normal operations of the facility by the OCS are considered “automatic.”

Manual

Manual operation is controlled via a local hand-held device, such as a pendant, or by a remote push button panel or remote HMI. Typically manual operation is with the operator with sight of the equipment being controlled.

Safety-Related Control Functions

This section lists and summarizes the current list of planned safety functions.

Safety-related control functions (SRCFs) are the result of a detailed hazard analysis of the equipment under control. After a hazard has been identified that is to be mitigated by functional safety, the specification for each safety-related control function will be developed. Each SRCF comprises the functional requirements and the safety integrity requirements.

The functional requirements detail the description of the SRCF, the conditions in which the SRCF shall be active or disabled, the required responses to trips and faults, the timing and priority of responses of the SRCF.

The safety integrity requirement details the necessary risk reduction for each SRCF.

It is imperative that the subsystem’s hazard analysis be detailed, thorough, and complete. These hazard analyses are used to develop the various safety functions. If a hazard analysis does not identify a hazard, that hazard will not be safeguarded, presenting a serious potential risk to personnel and infrastructure.

It is foreseen that this list will need to be expanded and altered as additional hazards are identified during design, construction, integration, and testing. Additional hazard will require additional safety functions to be developed and likely will result in added hardware to detect the hazard and/or implement the safeguard.

Example of Development of Safety-Related Control Functions

To look at how the various Safety-Related Control Functions have been developed, we will follow an example of the how the related functions of the sun sensor we developed.

Early in the project it was recognized that the concentrated sunlight near the focus could provide a thermal hazard to personnel and equipment. The Hazard Analysis Team then met to analyze the hazards created.

The first was to define the extent of the hazard. Due to the fast focus of the telescope design the concentrated sunlight is limited to a relatively small area near the prime focus. For example the rapidly diverging beam spreads its energy over a fairly large area by the time the beam reaches the interior walls of the enclosure. While potentially a problem for thermal effects of seeing it does not represent a safety hazard.

The hazard to personnel is relatively easy to mitigate as it would require personnel to be near the prime focus which is inherently difficult in normal operations.

The hazard is mostly to the equipment itself. Due to its very nature the heat stop is designed to withstand this energy (given normal operation of the heat stop—failure of the heatstop thermal control has its own safety functions). This leaves damage to equipment near the heatstop. There are various cables and pipes in this area that could potentially be damaged/destroyed by sufficiently concentrated energy.

The solution was to design and implement a sun sensor that determines if the sun was within 1.5 solar radii (R_☉) of on-axis pointing. If the sun is within 1.5 R_☉) the excess energy is absorbed by the heatstop as designed. (See 4.4.3 On-Sun Pointing)

However, it was clarified that the telescope also needed to be able to view objects at elongations of greater than 1.5 R_☉. This leaves a complex problem of understanding where excess energy may focus depending on the relative angles of the sun, telescope, and entrance aperture, something that does not lend itself well to robust safety function.

The decision was made to restrict observations to elongations greater than 25° as the geometry is such that no sunlight should strike the primary mirror if the entrance aperture is more than 25° from the telescope’s line-of-sight.

Also if the sun is below the horizon it is also considered safe.

The last two items revealed the need to introduce an additional safety function (see 4.4.2 Off Sun Pointing) to calculate the sun’s position and determine if the sun is in a safe position relative to the telescope.

Requirements for Safety Functions

Stop Functions

The categories of stop functions are defined in NFPA 79.

Category 0

Category 0 is an uncontrolled stop by immediately removing power the machine actuators.

This is essentially pulling the plug. Stopping distance/time is determined by inertia, friction, and mechanical braking (if present).

Category 1

Category 1 is a controlled stop with power to the machine actuators available to achieve the stop then remove power when the stop is achieved.

This is a more graceful stop, powered deceleration under control, followed by pulling the plug. Stopping distance/time is determined by control system parameters for deceleration.

Category 2

Category 2 is a controlled stop with power left available to the machine actuators.

This is controlled stop without removal of power. Essentially this commands velocity to zero and leaves the actuators powered. Category 2 is not used by the GIS.

The choice of Category 0 or Category 1 is based on a hazard analysis.

Control Reliability

In order to ensure a safety system safety functions require that hardware needed in each safety function have a fault tolerance of at least 1 (i.e. loss of any single component shall not cause the loss of the safety function). Secondly, diagnostics shall be included to detect a failure of any component that could cause a loss of a safety function at or before the next demand on that component.

Response Time

Each safety function must have a response time of less than 200 milliseconds as measured from the time an input changes until the output changes to a safe state. The safety function must either respond to an input change or default to the safe state within that time. The safety function may not necessarily complete its action by that time but must initiate a change to the safe state

The safety function must complete any action required to reach a safe state before any hazard can cause damage.

For example the M1 Mirror Cover must begin closing with 200 milliseconds of an over temperature fault but may take as long as 15 seconds to completely close. The upper limit is imposed by the duration of the heat stop shutter ability to withstand damage.

Safe State

The safe state of the system is defined as:

Telescope Azimuth motion stopped, drives disabled and brakes applied
Telescope Azimuth Cable Wrap motion stopped and drives disabled
Telescope Altitude motion stopped, drives disabled and brakes applied
Coudé Rotator motion stopped, drives disabled and brakes applied
Enclosure Azimuth motion stopped, drives disabled and brakes applied
Enclosure Azimuth Cable Wrap motion stopped, drives disabled
Enclosure Altitude motion stopped, drives disabled and brakes applied
Aperture Cover closed, motion stopped, and drives disabled
M1 Mirror Cover closed, motion stopped and drives disabled
Heat Stop Safety Shutter closed
Enclosure Jib Crane motion stopped, drives disabled and brakes applied
Enclosure Bridge Crane motion stopped, drives disabled, and brakes applied
GOS PA&C hazardous motion stopped, drives disabled and brakes applied
VBI-Blue hazardous motion stopped, drives disabled and brakes applied
VBI-Red hazardous motion stopped, drives disabled and brakes applied
VISP hazardous motion stopped, drives disabled and brakes applied.

Global Safety Functions

There are several safety functions that span multiple systems. These safety functions are controlled by the Global Interlock Controller and are referred to as Global Safety Functions.

Emergency Stop Safety Function

Safety Function	Emergency Stop
Hazard	avert potential hazards or reduce existing hazards that may arise from malfunctioning of the facility, human error or normal operation
Triggering Event	human-operated control device
Priority	Emergency Stop shall take priority over all other control functions.
Modes	always active
Reaction	Halt all hazardous motion Block light path
Safe State	Telescope Azimuth motion stopped Telescope Altitude motion stopped Coudé Rotator motion stopped Enclosure Azimuth motion stopped Enclosure Shutter closed M1 Mirror Cover closed Enclosure Jib Crane motion stopped Enclosure Bridge Crane motion stopped GOS PA&C motion stopped VBI-Blue motion stopped VBI-Red motion stopped VISP motion stopped
Required Integrity	PLc SIL2

All subsystems’ emergency stop devices are combined in logic at the GIC, so that activating any emergency stop device shall cause all GIS-connected subsystems to go to their safe state. In most cases they perform an immediate stop (category 0 or 1 stop as determined by subsystem analysis). The exception is that M1 Mirror Cover and Enclosure Entrance Aperture close (their safe state) in a predetermined sequence.

Hazardous Access

Because of the many large moving elements of the facility there exist numerous hazards associated with personnel exposed to these mechanisms. In order to limit exposure a trapped key plan will be implemented to inhibit access to hazardous areas during motion. See SPEC-0133 Hazardous Zones Fully Automated Control Access for details.

Because of the design of the GIS being distributed, the safety functions that implement hazardous access control bridge the GIC and LICs. The Facility LIC typically handles the input from the trapped keys and controls the locking of various doors and access points. The GIC controls the various permissive signals to individual LICs to inhibit hazardous motion.

Specific procedures must be followed when securing hazardous zones to ensure no personnel remain in the hazardous zone when the system is restarted. This is especially important in cases when the system has detected an entry through a locked/monitored door.

Ground Floor Inner Pier

The moving cable wrap presents a hazard. Access via door 110A is limited requiring a trapped key that disables the Coudé Rotator.

Coudé Inner Pier

The moving cable wrap and other mechanisms present a hazard. Access via door 209A and 210A is limited requiring a trapped key that disables the Coudé Rotator. Furthermore access via doors and hatches is monitored from the area under the Coudé Lab floor.

Coudé Lab

The moving floor of the Coudé Lab could present a hazard because of non-rotating equipment on the periphery of the room. Therefore when the Coudé Lab is accessed by personnel the speed of rotation of the Coudé Lab is limited to 1.75°/sec.

External Catwalk

The moving Enclosure Azimuth presents hazards. Access to the external enclosure catwalks and ladders is limited requiring a trapped key that disables Enclosure Rotation.

Lifting Platform

The moving Enclosure Azimuth presents hazards. Access to the external enclosure catwalks and ladders is limited requiring a trapped key that disables Enclosure Rotation

Enclosure Cable Wrap

The moving cable wrap present a hazard. Access floor hatches are limited requiring a trapped key that disables the Enclosure Azimuth.

Upper Enclosure Platforms

Access to the Upper Enclosure Platform is restricted by gates requiring a trapped key that disables Enclosure Azimuth and Aperture motion.

Enclosure Floor

The moving floor of the Enclosure could present a hazard because of non-rotating equipment on the periphery of the area. Therefore when the Enclosure Floor is accessed by personnel the speed of rotation of the Enclosure Azimuth is limited to 1.5°/sec.

Telescope Cable Wrap

The moving cable wrap and other mechanisms present a hazard. Access via doors 501A and 502A are limited requiring a trapped key that disables the Telescope Azimuth rotation.

Telescope Access

The moving telescope, cable wraps and other mechanisms present a hazard. Access to the telescope mount is limited by gates requiring a trapped key that disables Telescope Azimuth and Altitude motion.

Optical Support System LIC

The Optical Support System LIC is responsible for interlocks, limits, and emergency stop functions for the Top End Optical Assembly; M1 Active and Thermal Controller; and Feed Optics.

This LIC is also the connection point for emergency stop devices located at:

M2 assembly
OSS platform

Top End Optical Assembly

Heat Stop Over-Temperature

Temperatures above a predetermined level of the heat stop indicate a failure of the cooling system. The reaction of the GIS is to close the safety shutter, close the M1 mirror cover, and close the entrance aperture.

Safety Function	Heat Stop Over Temperature
Hazard	Damage to Heatstop, possible resultant leak of coolant
Triggering Event	Heat Stop temperature above TBD°C
Priority
Modes	Always active
Reaction	Close safety shutter, aperture cover, and M1 Cover
Safe State	Safety Shutter, Aperture Cover, and M1 Cover closed
Required Integrity	SIL 2

Because the Safety Shutter has limited survivability in the focused beam, the Aperture Cover and/or M1 Cover must also close to protect the Safety Shutter.

TEOA Removed

If the TEOA has been removed from the Telescope it may imbalance the telescope. The reaction of the GIS is to disable the Telescope altitude axis.

Safety Function	TEOA Removed
Hazard	Unexpected motion due to imbalance of telescope
Triggering Event	Removal of the TEOA
Priority	Cannot be overridden
Modes	All modes
Reaction
Safe State	Manual pin in place
Required Integrity	SIL 2

Heat Stop Removed

If the heat stop has been removed from the Telescope it may imbalance the telescope. The reaction of the GIS is to disable the Telescope altitude axis.

Safety Function	Unexpected motion due to imbalance of telescope
Hazard	Removal of the heat stop
Triggering Event	Cannot be overridden
Priority	All modes
Modes
Reaction
Safe State	Manual pin in place
Required Integrity	SIL 2

M1 Active Controller & Thermal Controller

To be determined

Off Sun Pointing

The design of the telescope is such that during normal operation most of the reflected solar energy from the M1 is directed into the heat stop. There are dangers associated with the reflected solar energy near the prime focus. It is required to restrict where this reflected energy may fall. The light path is blocked by redundantly using the Aperture Cover and the M1 Cover, either of which are individually effective but both are used to avoid a potential single point failure.

Obviously, when the Sun is below the horizon the telescope should be able to point safely at any location in the sky. To determine the location of the Sun relative to horizon, a relatively simple ephemeris calculation is needed. This calculation relies on two different time sources (NTP and PTP). These two sources are compared for agreement. If they agree and the Sun is below the horizon, the light path may be opened.

Additionally, when the Sun is more than 25° away from where the telescope and/or enclosure is pointing, no sunlight reaches the primary mirror, thus there is no reflected solar radiation to be concerned with. In this case the light path may also be opened.

Safety Function	Off Sun
Hazard	Concentrated solar radiation
Triggering Event	Telescope pointing off axis of Sun within 25°
Priority
Modes	Automatic
Reaction	Block the light path
Safe State	Aperture Cover closed M1 Cover closed
Required Integrity	SIL 2

On-Sun Pointing

Related to the off Sun pointing are on-axis solar observations. When the sun is within 1.5 solar radii (R_☉), the reflected solar energy is trapped in the heat stop. This is the normal operating condition of the telescope. Due to the accuracy required to ensure that the reflected energy is contained within the heat stop, the above ephemeris calculation is unlikely to be sufficiently accurate.

In this case, two small sun position sensors are required. These sensors usea two-dimensional position sensitive device (PSD) to determine if the sun is on-axis. A small lens is used to focus the image on the PSD with a focal length of 100mm. Neutral density filters (nd=2.7) are added to reduce the intensity to acceptable limits.

It should be noted that the Safety Shutter in front of the heat stop is not used in this safety function. If the telescope is sufficiently off-axis, the Safety Shutter cannot block the light path. If the telescope is on-axis, the heat stop should absorb the solar energy as designed. Failure of the heat stop is covered elsewhere.

Aperture Cover Interlock

The Enclosure Aperture Cover is allowed to open under specific circumstances.

If the M1 cover is closed or no sunlight striking the M1 there is no reflected solar energy. Typical operation requires that in order to acquire the sun, the telescope points at the sun with the M1 cover closed. Once the sun sensor described in 4.4.3 detects the sun is within 1.5R_☉the M1 cover is permitted to open and the aperture is permitted to stay open.

M1 Cover Interlock

The M1 cover is allowed to open under specific circumstances.

Similar to the Entrance Aperture below, the M1 cover may open when there is no sunlight on the mirror. Additionally if the telescope is pointed directly at the sun and the safety shutter is open and the heat stop is not in an over-temperature condition the M1 Cover may open.

Mount Base LIC

The Mount Base LIC is responsible for interlocks, limits, and emergency stop functions for the Telescope Mount Azimuth and Altitude Axes, Cable Wraps; M1 Mirror Cover; and M5/M6 Access Platform.

For details of implementation see LIC design requirements document.

Telescope Mount Azimuth Axis

Telescope Azimuth Drive Over-Speed

Abnormally high velocities indicate a failure of Azimuth Axis Bogie Drive. The reaction of the GIS is to bring the axis to a stop as quickly as possible, remove power from all Azimuth Drive Controllers and apply the brakes (category 1 stop).

Safety Function	Telescope Azimuth Over Speed
Hazard	Damage to motor, exceeding travel limits
Triggering Event	Telescope motion exceeding normal operating speeds
Priority
Modes	All modes
Reaction	Telescope drives disabled, brakes applied
Safe State	Telescope drives disabled, motion stopped
Required Integrity	SIL 2

Telescope Positive Azimuth Final Travel Limit

When a Positive Final Limit is detected by using combinational logic of the End Stop position and the limit switches, the reaction of the GIS to bring the axis to a stop as quickly as possible, remove power from all Azimuth Drive Controllers (category 1 stop) and apply the brakes.

Safety Function	Telescope Positive Azimuth Final Travel Limit
Hazard	Damage to cable chain
Triggering Event	Telescope rotation exceeding positive limit
Priority
Modes	Automatic modes, can be overridden in manual mode
Reaction	Telescope drives disabled, brakes applied
Safe State	Telescope drives disabled, motion stopped
Required Integrity	SIL 2

Telescope Negative Azimuth Final Travel Limit

When a Negative Azimuth Final Limit is detected by using combinational logic of the End Stop position and the limit switches, the reaction of the GIS is to bring the axis to a stop as quickly as possible, remove power from all Azimuth Drive Controllers (category 1 stop) and apply the brakes.

Safety Function	Telescope Negative Azimuth Final Travel Limit
Hazard	Damage to cable chain
Triggering Event	Telescope rotation exceeding negative azimuth limit
Priority
Modes	All automatic modes, can be overridden in manual mode
Reaction	Telescope drives disabled, brakes applied
Safe State	Telescope drives disabled, motion stopped
Required Integrity	SIL 2

Telescope Azimuth Cable Wrap Over-Te

The GIS shall inhibit motion and remove power to the Telescope Drives if the tension of the Azimuth Cable Wrap exceeds predetermined limits.

Safety Function	Telescope Azimuth Cable Wrap Over Tension
Hazard	Damage to cable chain
Triggering Event	Tension on cable in cable chain excessive
Priority
Modes	Automatic mode
Reaction	Telescope drives disabled, brakes applied
Safe State	Telescope drives disabled, motion stopped
Required Integrity	SIL 2

Trapped Key Interlock

This is actually a group of trapped keys which when one or more are removed will inhibit Telescope motion by removing power. This key is required to enter the Azimuth Cable Wrap or Azimuth Mechanical areas.

Safety Function	Telescope Azimuth Trapped Key Interlock
Hazard	Pinch/crush hazard from moving parts
Triggering Event	Trapped key removed
Priority
Modes	All modes
Reaction	Telescope drives disabled, brakes applied
Safe State	Telescope drives disabled, motion stopped
Required Integrity	SIL 3

Telescope Azimuth Axis Interlock

This safety function is the result of combinational logic in the GIS that determines another subsystem poses a hazard to Telescope Azimuth Axis motion.

This interlock is asserted unless all the following are true:

Enclosure Bridge Crane stowed
Enclosure Jib Crane stowed
TEOA Platform stowed (see section 4.9.5)
Boom lift stowed

The reaction of the GIS is to remove power from the Telescope Azimuth Axis drives.

Telescope Altitude Axis

Telescope Altitude Drive Over-Speed

Velocities above a predetermined level indicate a failure of an Altitude Axis Drive. The reaction of the GIS is to remove power from the Altitude Drive Controllers and apply the brakes (category 0 stop).

Safety Function	Telescope Altitude Over Speed
Hazard	Damage to motor, exceeding travel limits
Triggering Event	Telescope motion exceeding normal operating speeds
Priority
Modes	All modes
Reaction	Telescope drives disabled, brakes applied
Safe State	Telescope drives disabled, motion stopped
Required Integrity	SIL 2

Telescope Positive Altitude Final Travel Limit

When a Positive Altitude Final Limit is detected, the reaction of the GIS is to remove Telescope drive power (category 0 stop) and apply the brakes.

Safety Function	Telescope Positive Altitude Final Travel Limit
Hazard	Damage to cable chain
Triggering Event	Telescope motion exceeding positive altitude limit
Priority
Modes	Automatic modes, can be overridden in manual mode
Reaction	Telescope drives disabled, brakes applied
Safe State	Telescope drives disabled, motion stopped
Required Integrity	SIL 2

Telescope Negative Altitude Final Travel Limit

When a Negative Altitude Final Limit is detected, the reaction of the GIS is to remove Telescope drive power (category 0 stop) and apply the brakes.

Safety Function	Telescope Negative Altitude Final Travel Limit
Hazard	Damage to cable chain
Triggering Event	Telescope motion exceeding negative altitude limit
Priority
Modes	Automatic modes, can be overridden in manual mode
Reaction	Telescope drives disabled, brakes applied
Safe State	Telescope drives disabled, motion stopped
Required Integrity	SIL 2

Telescope Altitude Cable Wrap Over-Tension

The GIS shall inhibit motion and remove power to the Telescope Drives (category 0 stop) if the tension of the Altitude Cable Wrap exceeds predetermined limits.

Safety Function	Telescope Altitude Cable Wrap Over-Tension
Hazard	Damage to cable chain
Triggering Event	Tension on cable in cable chain excessive
Priority
Modes	Automatic mode
Reaction	Telescope drives disabled, brakes applied
Safe State	Telescope drives disabled, motion stopped
Required Integrity	SIL 2

Manual Lockout Pin

The manual lockout pin is a physical means by which the motion of the Telescope can be prevented. If this pin is not fully removed the GIS shall remove Telescope drive power.

Trapped Key Interlock

This is actually a group of trapped keys which when one or more are removed inhibits Enclosure and/or Telescope motion by removing power.

Safety Function	Telescope Altitude Trapped Key Interlock
Hazard	Pinch/crush hazard from moving parts
Triggering Event	Trapped key removed
Priority
Modes	All modes
Reaction	Telescope drives disabled, brakes applied
Safe State	Telescope drives disabled, motion stopped
Required Integrity	SIL 3

Telescope Altitude Axis Interlock

This safety function is the result of combinational logic in the GIS that determines another subsystem poses a hazard to Telescope Altitude Axis motion.

This interlock is asserted unless all the following are true:

Enclosure Bridge Crane stowed
Enclosure Jib Crane stowed
TEOA Platform stowed or fully deployed (see section 4.9.5)
Boom Lift Stowed

The reaction of the GIS is to disable power to the Telescope Altitude Axis Drives.

M1 Cover Interlock

The M1 cover is allowed to open under specific circumstances.

Similar to the Entrance Aperture below, the M1 cover may open when no sunlight can strike the mirror (see 4.4.2 Off Sun Pointing). Additionally if the telescope is pointed directly at the sun and the safety shutter is open and the heat stop is not in an over-temperature condition the M1 Cover may open.

Telescope Floor Access Panels Not Closed

Telescope Drive Power is disabled unless are Telescope Floor Access Panels are closed.

Safety Function	Telescope Floor Access Panels Not Closed
Hazard	Impact, crush/pinch
Triggering Event	Any telescope floor access panel not fully closed
Priority
Modes	Always active
Reaction	Inhibit Telescope azimuth rotation
Safe State	Telescope motion stopped
Required Integrity	SIL 1

M5/M6 Access Platform Not Stowed

Telescope Altitude Drive Power is disabled unless the M5/M6 is fully stowed.

Safety Function	M5/M6 Access Platform Not Stowed
Hazard	Damage to telescope mount
Triggering Event	M5/M6 Bridge not stowed
Priority
Modes	All modes
Reaction	Telescope elevation drives disabled, brakes applied
Safe State	Telescope elevation drives disabled, motion stopped
Required Integrity	SIL 2

OSS Access Platform Not Stowed

Telescope Altitude Drive Power is disabled unless the M5/M6 is fully stowed.

Safety Function	OSS Access Platform Not Stowed
Hazard	Damage to telescope mount
Triggering Event	M5/M6 Bridge not stowed
Priority
Modes	All modes
Reaction	Telescope elevation drives disabled, brakes applied
Safe State	Telescope elevation drives disabled, motion stopped
Required Integrity	SIL 2

Access Doors Not Closed

Telescope Elevation Drive Power is disabled unless the Access Door is closed.

Safety Function	Access Doors Not Closed
Hazard	Damage to telescope mount
Triggering Event	Access Doors not closed
Priority
Modes	All modes
Reaction	Telescope elevation drives disabled, brakes applied
Safe State	Telescope elevation drives disabled, motion stopped
Required Integrity	SIL 2

Telescope Azimuth Cable Wrap Access

This area requires a trapped key to access. Inserting the trapped key allows removal of one or more secondary personnel safety keys. All personnel who enter are required to carry a personnel safety key.

Safety Function	Telescope Azimuth Trapped Key Interlock
Hazard	Pinch/crush hazard from moving parts
Triggering Event	Trapped key removed
Priority
Modes	All modes
Reaction	Telescope drives disabled, brakes applied
Safe State	Telescope drives disabled, motion stopped
Required Integrity	SIL 3

Telescope Azimuth Mechanical Level

Access to the Mechanical Level requires a trapped key. Inserting the trapped key allows removal of one or more secondary personnel safety keys. All personnel who enter are required to carry a personnel safety key.

Safety Function	Telescope Azimuth Trapped Key Interlock
Hazard	Pinch/crush hazard from moving parts
Triggering Event	Trapped key removed
Priority
Modes	All modes
Reaction	Telescope drives disabled, brakes applied
Safe State	Telescope drives disabled, motion stopped
Required Integrity	SIL 3

Coudé Rotator LIC

The Coudé Rotator LIC is responsible for interlocks, limits, and emergency stop functions of the Telescope Coudé Rotator Azimuth Axis and Cable Wrap.

Coudé Drive Controller

Coudé Rotator Azimuth Drive Over-Speed

Velocities above a predetermined level indicate a failure of Coudé Axis Drive. The reaction of the GIS is to remove power from the Coudé Drive Controllers and apply the brakes (category 0 stop).

Safety Function	Coudé Rotator Azimuth Over Speed
Hazard	Damage to motor, exceeding travel limits
Triggering Event	Telescope motion exceeding normal operating speeds
Priority
Modes	All modes
Reaction	Rotator drives disabled, brakes applied
Safe State	Rotator drives disabled, motion stopped
Required Integrity	SIL 2

Coudé Rotator Positive Azimuth Final Travel Limit

When a Coudé Rotator Positive Final Limit is detected by using combinational logic of the End Stop position and the final limit switches, the reaction of the GIS is to remove Coudé Rotator drive power (category 0 stop) and apply the brakes.

Safety Function	Coudé Rotator Positive Azimuth Final Travel Limit
Hazard	Damage to cable chain
Triggering Event	Rotator motion exceeding positive azimuth limit
Priority
Modes	Automatic modes, can be overridden in manual mode
Reaction	Rotator drives disabled, brakes applied
Safe State	Rotator drives disabled, motion stopped
Required Integrity	SIL 2

Coudé Rotator Negative Azimuth Final Travel Limit

When a Coudé Rotator Negative Azimuth Final limit is detected by using combinational logic of the End Stop position and the final limit switches, the reaction of the GIS is to remove Coudé Rotator drive power (category 0 stop) and apply the brakes.

Safety Function	Coudé Rotator Negative Azimuth Final Travel Limit
Hazard	Damage to cable chain
Triggering Event	Rotator motion exceeding negative azimuth limit
Priority
Modes	Automatic modes, can be overridden in manual mode
Reaction	Rotator drives disabled, brakes applied
Safe State	Rotator drives disabled, motion stopped
Required Integrity	SIL 2

Coudé Rotator Azimuth Cable Wrap Over-Tension

The GIS shall inhibit motion and remove power to the Coudé Rotator Drives if the tension of the Azimuth Cable Wrap exceeds predetermined limits.

Safety Function	Coudé Rotator Azimuth Cable Wrap Over Tension
Hazard	Damage to cable chain
Triggering Event	Tension on cable in cable chain excessive
Priority
Modes	Automatic mode
Reaction	Telescope drives disabled, brakes applied
Safe State	Telescope drives disabled, motion stopped
Required Integrity	SIL 2

Trapped Key Interlock

This is actually a group of trapped keys which when one or more are removed inhibit Coudé Rotator motion by removing power. This key is required to unlock and enter the Coudé Rotator area.

Safety Function	Coudé Rotator Trapped Key Interlock
Hazard	Pinch/crush hazard from moving parts
Triggering Event	Trapped key removed
Priority
Modes	All modes
Reaction	Rotator drives disabled, brakes applied
Safe State	Rotator drives disabled, motion stopped
Required Integrity	SIL 3

Coudé Lab Crane Not Stowed

Use of the Coudé Lab Crane requires that hazardous motion be inhibited.

Safety Function	Coudé Lab Crane Interlock
Hazard	Pinch/crush hazards.
Triggering Event	Coudé Lab Crane not stowed
Priority
Modes	Automatic (can be overridden with enabling pendent in manual control)
Reaction	inhibit Coudé Azimuth rotation
Safe State	Coudé Azimuth rotation stopped AND Coudé Azimuth drives de-energized.
Required Integrity	SIL 2

Electronic Rack Door Open

The GIS shall inhibit motion and remove power to the Coudé Rotator Drives if any electronic rack door is not closed.

Safety Function	Electronic Rack Door Open
Hazard	Pinch/crush hazards
Triggering Event	Any electronic rack door not closed
Priority
Modes	All
Reaction	inhibit Coudé Azimuth rotation
Safe State	Coudé Azimuth rotation stopped AND Coudé Azimuth drives de-energized.
Required Integrity	SIL 1

Instrumentation Systems LIC

Coudé Adaptive Optics (AO-C)

None currently identified.

Coudé Active Optics (aO-C)

None currently identified.

Visible Light Broadband Imager (VLBI)

None currently identified.

Visible Spectropolarimeter (ViSP)

None currently identified.

Near-IR Spectropolarimeter (NIRSP)

None currently identified.

Visible Tunable Filter (VTF)

None currently identified.

Enclosure Motion Control LIC

The Enclosure Motion Control LIC is responsible for interlocks, limits, and emergency stop functions for the Enclosure Azimuth, Shutters, Cable Wraps, Entrance Aperture; Bridge Crane, Jib Cranes, Rear Access Doors, and TEOA Platform.

This LIC is also the connection point for emergency stop devices located at or near the above items.

Enclosure Azimuth Axis

Enclosure Azimuth Positive Final Travel Limit

When an Enclosure Azimuth Positive Final Limit is detected by using combinational logic of the End Stop position and the final limit switches, the reaction of the GIS is to remove Enclosure Azimuth drive power (category 0 stop) and apply the brakes.

Safety Function	Enclosure Positive Azimuth Final Travel Limit
Hazard	Damage to cable chain
Triggering Event	Enclosure motion exceeding positive azimuth limit
Priority
Modes	Automatic modes, can be overridden in manual mode
Reaction	Enclosure drives disabled, brakes applied
Safe State	Enclosure drives disabled, motion stopped
Required Integrity	SIL 2

Enclosure Azimuth Negative Final Travel Limit

When an Enclosure Azimuth Negative Final limit is detected by using combinational logic of the End Stop position and the final limit switches, the reaction of the GIS is to remove Enclosure Azimuth drive power (category 0 stop) and apply the brakes.

Safety Function	Enclosure Negative Azimuth Final Travel Limit
Hazard	Damage to cable chain
Triggering Event	Enclosure motion exceeding negative azimuth limit
Priority
Modes	Automatic modes, can be overridden in manual mode
Reaction	Enclosure drives disabled, brakes applied
Safe State	Enclosure drives disabled, motion stopped
Required Integrity	SIL 2

Enclosure Azimuth Cable Wrap Over Tension

The GIS shall inhibit motion and remove power to the Enclosure Azimuth Drives if the tension of the Azimuth Cable Wrap exceeds predetermined limits.

Safety Function	Enclosure Azimuth Cable Wrap Over Tension
Hazard	Damage to cable chain
Triggering Event	Tension on cable in cable chain excessive
Priority
Modes	Automatic mode
Reaction	Enclosure drives disabled, brakes applied
Safe State	Enclosure drives disabled, motion stopped
Required Integrity	SIL 2

Enclosure Azimuth Personnel Trapped Key Interlock

This is actually a group of trapped keys which when one or more are removed inhibit Enclosure Azimuth motion by removing power. This key is required to enter the Azimuth Cable Wrap or Azimuth Mechanical areas. In manual mode (Enclosure Pendant installed and enabling grip held) it may be muted to allow Enclosure Azimuth rotation. It is also be required to enable the exterior boom lift.

Safety Function	Enclosure Trapped Key Interlock
Hazard	Pinch/crush hazard from moving parts
Triggering Event	Trapped key removed
Priority
Modes	Automatic mode, may be overridden in manual mode
Reaction	Enclosure drives disabled, brakes applied
Safe State	Enclosure drives disabled, motion stopped
Required Integrity	SIL 3

Altitude Axis

Shutter Personnel Trapped Key Interlock

This is actually a group of trapped keys which when one or more are removed inhibits Enclosure Shutter motion by removing power.

Safety Function	Enclosure Trapped Key Interlock
Hazard	Pinch/crush hazard from moving parts
Triggering Event	Trapped key removed
Priority
Modes	All modes
Reaction	Enclosure drives disabled, brakes applied
Safe State	Enclosure drives disabled, motion stopped
Required Integrity	SIL 3

Cranes

Bridge Crane Not Stowed

When in automatic mode, if the Bridge Crane is not stowed (i.e. hook not fully up, trolley at end-of-travel, and bridge fully towards the rear of the enclosure) the GIS removes drive power from the both the Altitude and Azimuth telescope drive controllers (category 0 stop).

If the enclosure has the pendant connected, Enclosure Azimuth motion may be enabled for safe-limited speed.

Safety Function	Bridge Crane Not Stowed
Hazard	Collison between Telescope and crane
Triggering Event	Bridge Crane not in stowed position
Priority
Modes	Automatic (may be overridden in manual mode)
Reaction	Inhibit Enclosure rotation
Safe State	Bridge Crane in Stowed Position (hook up, bridge at rear of enclosure)
Required Integrity	SIL 2

Bridge Crane Interlock

The GIS shall inhibit (category 0 stop) the Bridge Crane unless the following conditions are true:

The telescope is parked.
The telescope azimuth and altitude drives are disabled.
The telescope brakes are engaged.

Safety Function	Bridge Crane Interlock
Hazard	Collison between Telescope and crane
Triggering Event	Telescope not parked
Priority
Modes	Automatic (may be overridden in manual mode)
Reaction	Disable Motion of Bridge Crane
Safe State	Telescope Mount stopped
Required Integrity	SIL 2

Jib Crane Not Stowed

If the GIS detects that the Jib Crane is not stowed (i.e. hook not fully up, jib fully towards the wall of the enclosure) the GIS removes drive power from the both the Altitude and Azimuth telescope drive controllers (category 0 stop).

Safety Function	Jib Crane Not Stowed
Hazard	Collison between Telescope and crane
Triggering Event	Jib Crane not in stowed position
Priority
Modes	Automatic (may be overridden in manual mode)
Reaction	Inhibit Enclosure rotation
Safe State	Jib Crane in Stowed Position (hook up, jib against side of enclosure)
Required Integrity	SIL 2

Jib Crane Interlock

The GIS shall inhibit (category 0 stop) the Jib Crane unless the following conditions are true:

The telescope azimuth and altitude drives are disabled.
The telescope brakes are engaged.

Safety Function	Jib Crane Interlock
Hazard	Collison between Telescope and crane
Triggering Event	Telescope not parked
Priority
Modes	Automatic (may be overridden in manual mode)
Reaction	Disable Motion of Jib Crane
Safe State	Telescope Mount stopped
Required Integrity	SIL 2

Entrance Aperture Cover Interlock

The enclosure entrance aperture cover is allowed to open under specific circumstances.

If the M1 cover is closed or there is no sunlight on the M1 the Entrance Aperture Cover may open. Additionally if the telescope is pointed at the sun and the heat stop shutter is open and heat stop is not in an over-temperature condition the Entrance Aperture Cover may open.

TEOA Access Platform

The TEOA Access Platform may only be deployed when the telescope mount is aligned in azimuth with the platform and the telescope altitude is at least 25° (this measurement needs to be verified). This allows the platform and then the guard rails to be deployed. The TEOA Platform may only be raised once the telescope altitude is above 25° and the guard rails have been stowed.

Operating Sequence

To deploy the TEOA Access Platform:

With telescope altitude above 25°, align telescope azimuth with TEOA maintenance position.
Lower TEOA platform fully.
Deploy TEOA guardrails.
Lower telescope altitude to TEOA maintenance position.

To retract the TEOA Access Platform:

With the telescope parked at the TEOA maintenance position, raise telescope altitude to above 25°.
Retract the TEOA guardrails.
Raise the TEOA platform fully.

Safety Function	TEOA Access Platform Permissive
Hazard	Pinch/crush hazard from moving components
Triggering Event	Enclosure Azimuth at TEOA maintenance position AND Telescope Azimuth at TEOA maintenance position AND Telescope Altitude above 25°.
Priority
Modes	All modes
Reaction	Enable TEOA maintenance platform drives
Safe State	TEOA maintenance platform disabled
Required Integrity	SIL 2

Additionally, when the TEOA Access Platform is not stowed, Enclosure Azimuth motion and Telescope Azimuth motion is inhibited.

Safety Function	TEOA Access Platform Not Stowed
Hazard	Pinch/crush hazard from moving components
Triggering Event	TEOA Access Platform not stowed
Priority
Modes	All modes
Reaction	Disable Telescope Azimuth and Enclosure Azimuth drives
Safe State	Enclosure Azimuth drives disabled AND Enclosure Azimuth brakes set AND Telescope Azimuth Drives disabled AND Telescope Azimuth brakes set
Required Integrity	SIL 2
Remarks	See section 4.6.1

However, the Telescope Altitude axis is required to lower into position when the TEOA Access Platform in not stowed. Telescope Altitude motion shall be permitted only when the TEOA Access Platform is fully deployed or fully retracted.

Safety Function	TEOA Access Platform Not In Position
Hazard	Pinch/crush hazard from moving components
Triggering Event	TEOA Access Platform not stowed AND TEOA Access Platform not fully deployed
Priority
Modes	All modes
Reaction	Disable Telescope Altitude drives
Safe State	Telescope Altitude Drives disabled AND Telescope Altitude brakes set
Required Integrity	SIL 2
Remarks	See section 4.6.2

Facility Thermal System LIC

Vent Gates

None currently identified

Enclosure Cooling

Enclosure Coolant Leak

This safety function monitors supply and return flow rates. If the delta of supply and return rates exceeds a predetermined threshold the GIS commands a controlled stop of the pumps and then disables power (category 1 stop).

Safety Function	Enclosure Coolant Leak
Hazard	Coolant on equipment
Triggering Event	Mismatch of supply and return rates
Priority	Low
Modes	All modes
Reaction	Stop affected pumps Close valves to isolate leak
Safe State	Pumps stopped Isolation valves closed
Required Integrity	n/a

Enclosure Dehumidification High High Humidity

In the event of a high wet bulb temperature in the Enclosure exceeds a predetermined level the GIS shall close the M1 cover, close the Aperture Cover, command a controlled stop of the Enclosure Altitude Axis, inflate the shutter seals, and command the Enclosure Dehumidification system to start.

Safety Function	High High Humidity
Hazard	Condensation on equipment
Triggering Event	Interior enclosure humidity above a predetermined level
Priority	Lowest
Modes	Automatic modes
Reaction	Close M1 Cover Close Aperture Cover Enclosure Altitude Axis stopped Inflate the shutter seals Start enclosure dehumidification system
Safe State	Aperture Cover closed Shutter seals inflated Dehumidification system running
Required Integrity	n/a

Enclosure Rear Door

None currently identified

Facilities LIC

The facilities LIC is responsible for interlocks, limits, and emergency stop functions located in the Support and Operations Building.

This LIC is also the connection point for emergency stop devices located at:

Control Room
Boom Lift

The facility LIC also plays a crucial role in controlling access to various hazardous zones of the facility.

Fire Alarm

The fire alarm system has detected a fire. All systems controlled by the GIS shall conduct a controlled stop and power off (category 1 stop).

Safety Function	Facility Fire Alarm
Hazard	Personnel hazard from smoke and flame
Triggering Event	Fire/smoke detected by building fire alarm
Priority
Modes	All
Reaction	All hazardous motion shall be stopped (Category 1 stop).
Safe State	Telescope Azimuth motion stopped Telescope Altitude motion stopped Coudé Rotator motion stopped Enclosure Azimuth motion stopped Aperture Cover closed Safety Shutter closed M1 Mirror Cover closed Enclosure Jib Crane motion stopped Enclosure Bridge Crane motion stopped
Required Integrity	n/a
Input	Dry contact from Fire Alarm Panel
Output	Tag FAC_FireAlarm_OK = 0

Seismic Alarm

Upon detection of a seismic event, all systems controlled by the GIS shall conduct a controlled stop and power off (category 1 stop).

Safety Function	Facility Seismic Alarm
Hazard	Personnel and equipment hazard during and following a seismic event
Triggering Event	Seismic event detected
Priority
Modes	All
Reaction	All hazardous motion shall be stopped (Category 1 stop).
Safe State	Telescope Azimuth motion stopped Telescope Altitude motion stopped Coudé Rotator motion stopped Enclosure Azimuth motion stopped Aperture Cover closed Safety Shutter closed M1 Mirror Cover closed Enclosure Jib Crane motion stopped Enclosure Bridge Crane motion stopped
Required Integrity	n/a
Input	Accelerometers
Output	Tag FAC_SeismicAlarm_OK = 0

Boom Lift

Boom Lift Not Stowed

This function is used by the GIS in combination logic to inhibit other subsystems.

Safety Function	Boom Lift Not Stowed
Hazard	Impact
Triggering Event	Boom lift not in stowed position
Priority
Modes	May be bypassed when lift is removed from observing chamber
Reaction	Inhibit enclosure motion AND inhibit telescope motion AND Inhibit M1 Cover motion
Safe State	Enclosure Azimuth Rotation stopped AND Enclosure Azimuth Rotation drives de-energized AND Telescope Azimuth rotation stopped AND Telescope Azimuth Drives de-energized AND Telescope Azimuth Brakes set AND Telescope Altitude rotation stopped AND Telescope Altitude Drives de-energized AND Telescope Altitude Brakes set.
Required Integrity	SIL 1

Boom Lift Permissive

Use of the Boom Lift shall require that hazardous motion be inhibited.

Safety Function	Boom Lift Permissive
Hazard	Impact
Triggering Event	Telescope and Enclosure not parked
Priority
Modes	May be bypassed when lift is removed from observing chamber
Reaction	Inhibit enclosure motion AND inhibit telescope motion AND Inhibit M1 Cover motion
Safe State	Telescope Azimuth motion stopped Telescope Altitude motion stopped Enclosure Azimuth motion stopped

Coudé Lab

Coudé Lab Crane Permissive

Use of the Coudé Lab Crane shall require that hazardous motion be inhibited.

Safety Function	Coudé Lab Crane Permissive
Hazard	Pinch/crush hazards
Triggering Event	Coudé Azimuth not parked.
Priority
Modes
Reaction	Inhibit Coudé Lab Crane motion
Safe State	Coudé Lab Crane de-energized
Required Integrity	SIL 2

Hazardous Area Access

Coudé Hazardous Zone

Access to hazardous areas is controlled via trapped keys and/or interlocked doors.

Safety Function	Coudé Pier Access
Hazard	Coudé cable wrap pinch/crush hazards Coudé azimuth rotator pinch/crush or impact hazards
Triggering Event	Door 110A opened OR Door 209A opened OR Door 210A opened
Priority
Modes	Automatic (can be overridden with enabling pendent in manual control)
Reaction	inhibit Coudé Azimuth rotation
Safe State	Coudé Azimuth rotation stopped. Coudé Azimuth drives de-energized.
Required Integrity	SIL 3

Coudé Lab Access

Safety Function	Coudé Lab Access
Hazard	Coudé Lab pinch/crush hazards
Triggering Event	Door 307A opened OR Door 308C opened
Priority	All stopping safety functions are higher priority
Modes
Reaction	Limit rotation speed of Coudé Lab to <1.75°/sec
Safe State	Coudé Azimuth rotation <1.75°/sec
Required Integrity	SIL 3

Telescope Pier Hazardous Zones

Safety Function	Utility Floor Access
Hazard	Telescope cable wrap pinch/crush hazards
Triggering Event	Door 403A opened OR Gate “21” opened
Priority
Modes	Automatic (can be overridden with enabling pendent in manual control)
Reaction	Inhibit telescope azimuth rotation
Safe State	Telescope Azimuth rotation stopped AND Telescope Azimuth Drives de-energized AND Telescope Azimuth Brakes set
Required Integrity	SIL 3

Telescope Cable Wrap Hazardous Access

Safety Function	Telescope Cable Wrap Access
Hazard	Telescope Cable Wrap crush/pinch hazards
Triggering Event	Door 501A opened OR Door 502A opened
Priority
Modes	Automatic (can be overridden with enabling pendent in manual control)
Reaction	Inhibit telescope azimuth rotation
Safe State	Telescope Azimuth rotation stopped AND Telescope Azimuth Drives de-energized AND Telescope Azimuth Brakes set
Required Integrity	SIL 3

Enclosure Hazardous Zones

Safety Function	Enclosure Cable Wrap Access
Hazard	Enclosure Cable Wrap crush/pinch hazards Enclosure Rotation crush/pinch hazards
Triggering Event	Floor Hatch FH-01 opened OR Floor Hatch FH-02 opened
Priority
Modes	Automatic (can be overridden with enabling pendent in manual control)
Reaction	Inhibit Enclosure Azimuth Rotation
Safe State	Enclosure Azimuth Rotation stopped AND Enclosure Azimuth Rotation drives de-energized.
Required Integrity	SIL 3

Enclosure Catwalk Hazardous Access

Safety Function	Catwalk Access
Hazard	Enclosure Rotation crush/pinch hazards
Triggering Event	Door 402D opened OR Door 210B opened OR Door 308D opened OR Door 402B opened OR Enclosure Door opened OR Outside Ladder Access opened
Priority
Modes	Automatic (can be overridden with enabling pendent in manual control)
Reaction	Inhibit Enclosure Azimuth Rotation
Safe State	Enclosure Azimuth Rotation stopped AND Enclosure Azimuth Rotation drives de-energized.
Required Integrity	SIL 3

Enclosure Upper Level Hazardous Access

Safety Function	Enclosure Upper Level Access
Hazard	Fall hazard, dropped item damage to equipment.
Triggering Event	Enclosure upper platform gate +X opened OR Enclosure upper platform gate –X opened.
Priority
Modes	All automatic modes
Reaction	Inhibit enclosure rotation motion
Safe State	Enclosure Rotation stopped AND Enclosure Drives de-energized AND Enclosure Brakes set
Required Integrity	SIL 3

Enclosure Lifting Platform Access

Safety Function	Lifting Platform Access
Hazard	Enclosure Rotation crush/pinch hazards
Triggering Event	Lifting platform access deployed
Priority
Modes	All automatic modes
Reaction	Inhibit Enclosure Azimuth Rotation
Safe State	Enclosure Azimuth Rotation stopped AND Enclosure Azimuth Rotation drives de-energized.
Required Integrity	SIL 3

Telescope Floor Hazardous Zones

Safety Function	Telescope Floor Access
Hazard	Enclosure azimuth pinch/crush Slip/trip hazard
Triggering Event	Enclosure Azimuth rotation exceed safe linear velocity threshold
Priority
Modes	Automatic (can be overridden with enabling pendent in manual control)
Reaction	Safe Limited Speed of Enclosure azimuth rotation
Safe State	Rotation speed less than 1.5°/sec
Required Integrity	SIL 3

Telescope Hazardous Zone

Safety Function	Telescope Access
Hazard	Pinch/crush hazard on Telescope Mount Assembly
Triggering Event	Telescope Gate opened
Priority
Modes	Automatic (can be overridden with enabling pendent in manual control)
Reaction	Inhibit telescope motion
Safe State	Telescope Azimuth rotation stopped AND Telescope Azimuth Drives de-energized AND Telescope Azimuth Brakes set AND Telescope Altitude rotation stopped AND Telescope Altitude Drives de-energized AND Telescope Altitude Brakes set
Required Integrity	SIL 3

PFlow Lift

PFlow Lift Permissive

Safety Function	PFlow Lift Permissive
Hazard	Pinch /crush hazard with Enclosure
Triggering Event	Rear door aligned with lift AND Enclosure drives disabled
Priority
Modes
Reaction	Inhibit PFlow lift movement above utility level
Safe State	PFlow lift below utility level
Required Integrity	SIL 1

PFLow Lift Interlock

Safety Function	PFlow Lift Interlock
Hazard	Pinch/crush hazard with Enclosure
Triggering Event	PFlow lift above utility level
Priority
Modes
Reaction	Inhibit Enclosure Azimuth rotation
Safe State	Enclosure Azimuth Rotation stopped AND Enclosure Azimuth Rotation drives de-energized.
Required Integrity	SIL 1

PFLow Lift Roof Closed

Safety Function	PFlow Lift Roof Not Closed
Hazard	Pinch/crush hazard with Enclosure
Triggering Event	PFlow Lift Roof not closed and locked
Priority
Modes
Reaction	Inhibit Enclosure Azimuth rotation
Safe State	Enclosure Azimuth Rotation stopped AND Enclosure Azimuth Rotation drives de-energized.
Required Integrity	SIL 1

HMI Functions

System Status

The HMI shall display the current status of hardware that comprises the GIS.

This display shall show any faulted or unconnected equipment to allow for rapid troubleshooting.

The results of component self-diagnostics shall also be displayed.

Part of the status display shall show whether there are any I/O forces and that all controllers have valid safety signatures.

General health information about the GIS shall also be provided this includes information such as network utilization.

Safety Function Status

The HMI shall also display the current status of all GIS safety functions.

The HMI shall display which systems are currently interlocked (tripped) or faulted.

Operator Control

The HMI also serves as a central point to acknowledge alarms and to reset trips and faults that occur anywhere in the system.

After the operator has verified that the cause of the trip or fault has been rectified the HMI allows password-controlled access to reset the system and restore operation.

Engineering Interface

The HMI shall be capable of displaying engineering screens that detail hardware status and configuration.

These screens shall be separate from the user screens and will require password-controlled access.

Logging

The HMI provides logging of trips and faults that occur within the system.

The logs shall be time-stamped to allow for correlation of GIS events with activities within the facility.

¹

^I

GIC	Global Interlock Controller
LIC	Local Interlock Controller
PAC	Programmable Automation Controller
PLC	Programmable Logic Controller
SIL	Safety Integrity Level
TÜV	Technischer Überwachungsverein (German)(English: Technical Inspection Association) An internationally accepted independent testing and certification organization.

SPEC-0140 GIS Functional Design

Preface

Introduction

Purpose

Scope

Related and Reference Documents

Related Documents

DKIST Specification Documents

DKIST Interface Control Documents

DKIST Reference Design Studies and Analyses

DKIST Drawings

Reference Documents

DKIST Documents

National Consensus Standards

International Standards

Industry Standards

Glossary

Control Software

Application Code

Revision Control

Ladder Logic Example

GIS Operation

Status Monitoring and Fault Handling

Embedded Control Operation

Change of Network Status

Operation following a rebooting or restarting

Modes of operation

Automatic

Manual

Safety-Related Control Functions

Example of Development of Safety-Related Control Functions

Requirements for Safety Functions

Stop Functions

Category 0

Category 1

Category 2

Control Reliability

Response Time

Safe State

Global Safety Functions

Emergency Stop Safety Function

Hazardous Access

Ground Floor Inner Pier

Coudé Inner Pier

Coudé Lab

External Catwalk

Lifting Platform

Enclosure Cable Wrap

Upper Enclosure Platforms

Enclosure Floor

Telescope Cable Wrap

Telescope Access

Optical Support System LIC

Top End Optical Assembly

Heat Stop Over-Temperature

TEOA Removed

Heat Stop Removed

M1 Active Controller & Thermal Controller

Off Sun Pointing

On-Sun Pointing

Aperture Cover Interlock

M1 Cover Interlock

Mount Base LIC

Telescope Mount Azimuth Axis

Telescope Azimuth Drive Over-Speed

Telescope Positive Azimuth Final Travel Limit

Telescope Negative Azimuth Final Travel Limit

Telescope Azimuth Cable Wrap Over-Te

Trapped Key Interlock

Telescope Azimuth Axis Interlock

Telescope Altitude Axis

Telescope Altitude Drive Over-Speed

Telescope Positive Altitude Final Travel Limit

Telescope Negative Altitude Final Travel Limit

Telescope Altitude Cable Wrap Over-Tension

Manual Lockout Pin

Trapped Key Interlock

Telescope Altitude Axis Interlock

M1 Cover Interlock

Telescope Floor Access Panels Not Closed