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BACnet PIC Statement for Quantum Subsystem Physical Devices
using Quantum Version 3.2
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Quantum
3691058a 1 06.06.17
BACnet Protocol Implementation Conformance Statement (PICS)
Date: May 2, 2017
Vendor Name: Lutron Electronics Co., Inc.
Product Name: Quantum BACnet Integration
Applications Software Version: 2.0
Firmware Revision: 3.2
BACnet Protocol Revision: 4
Vendor ID: 176
Product Description
BACnet IP is embedded in the Quantum processor. There are two types of BACnet devices available in Quantum
subsystem devices and area devices:
• The subsystem devices are physical BACnet devices; typically, one per floor of the building.
• The area devices are virtual BACnet devices, typically one per area of the floor. It is typical to have multiple
subsystem devices and area devices in a Quantum system. Areas devices are routed through the subsystem
device which is also a BACnet router.
BACnet Interoperability Building Blocks Supported (Annex K):
K.1.2 BIB B Data Sharing ReadProperty-B (DS-RP-B)
K.1.4 B IB B Data Sharing ReadPropertyMultiple-B (DS-RPM-B)
K.1.8 B I B B Data Sharing WriteProperty-B (DS-WP-B)
K.1.10 B I B B Data Sharing WritePropertyMultiple-B (DS-WPM-B)
K.1.12 B IB B Data Sharing COV-B (DS-COV-B)
K.5.2 BIBB Device Management DynamicDeviceBinding-B (DM-DDB-B)
K.5.4 BIBB Device Management DynamicObjectBinding-B (DM-DOB-B)
K.5.6 BIBB Device Management DeviceCommunicationControl-B (DM-DCC-B)
BACnet Standardized Device Profile (Annex L):
BACnet Application Specific Controller (B-ASC)
Segmentation Capability:
Segmented requests supported? No. Window Size: n/a
Segmented responses supported? No
. Window Size: n/a
Non-Standard Application Services:
Non-standard application services are not supported.
BACnet is a registered trademark of ASHRAE. ASHRAE does not endorse, approve or test
products for compliance with ASHRAE standards. Compliance of listed products to the
requirements of ASHRAE Standard 135 is the responsibility of BACnet International (BI).
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Standard Object Types Supported:
Device
1. Dynamically creatable using BACnet CreateObject service? No.
2. Dynamically deletable using BACnet DeleteObject service? No.
3. List of optional properties supported: Active COV_Subscriptions, Description, Location, Profile_Name.
4. List of all properties that are writable where not otherwise required by this standard: None.
5. List of proprietary properties: None.
6. List of any property value range restrictions: None.
Analog Value
1. Dynamically creatable using BACnet CreateObject service? No.
2. Dynamically deletable using BACnet DeleteObject service? No.
3. List of optional properties supported: COV_Increment. (See Table for objects that support this property)
4. List of all properties that are writable where not otherwise required by this standard: None.
5. List of proprietary properties: None.
6. List of any property value range restrictions: See Table.
Binary Value
1. Dynamically creatable using BACnet CreateObject service? No.
2. Dynamically deletable using BACnet DeleteObject service? No.
3. List of optional properties supported: Active_Text, Inactive_Text.
4. List of all properties that are writable where not otherwise required by this standard: None.
5. List of proprietary properties: None.
6. List of any property value range restrictions: See Table.
Multi-State Value
1. Dynamically creatable using BACnet CreateObject service? No.
2. Dynamically deletable using BACnet DeleteObject service? No.
3. List of optional properties supported: State_Text.
4. List of all properties that are writable where not otherwise required by this standard: None.
5. List of proprietary properties: None.
6. List of any property value range restrictions: See Table.
Data Link Layer Options:
BACnet IP
Device Address Binding:
Is static device binding supported? No.
Networking Options:
BACnet / IP Annex J non-BBMD functionality; the Quantum processor is able to register as a foreign device.
The Quantum processor is able to initiate original-broadcast-NPDU.
Character Sets Supported:
Indicating support for multiple character sets does not imply that they can all be supported simultaneously.
• ANSIX3.4
BACnet Routing:
Routes between the connected physical BACnet network and a virtual BACnet network.
Router_Busy flag is supported to indicate when router is operational but currently cannot respond.
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BACnet PIC Statement for Quantum Subsystem Physical Devices
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Object Name Type Instance Read Write COV Units Min
PV
Max
PV
Inactive
Text (0)
Active
Text (1)
State Text (Multi-State)
{Subsystem Name}
{Device Instance
Number}
DEVICE Same as
device
instance
number
X
Notes: The System Name is the logical name of one of the Quantum system’s subsystems that typically corresponds to a physical
portion of the building, such as a floor. The Instance is the same as the unique Device ID assigned to each subsystem.
{SubsystemName} is a text string defined in the Lutron Quantum system configuration software. {DeviceInstanceNumber} is a
number defined in the Lutron Quantum system configuration software that is equal to the {Base} number + {System} number +1.
{Base} is a 22-bit value set in the Lutron Quantum system configuration software (default 1760000). {System} is an 8-bit value
set in the Lutron Quantum system configuration software (0 to 127).
Master Loadshed
Enabled
BV 2 X X X 0 1 Disabled Enabled
Notes: This value determines whether all of the areas in the Quantum subsystem are being controlled via load shedding. When this value
is set to Enabled, for all areas in the subsystem that have loadshed allowed, any dimmable lights in each area that are turned On
will have their light level reduced by the percentage specified in the loadshed goal value. When Disabled, the lights will dim to
their commanded level.
Master Hyperion
Enabled
BV 3 X X X 0 1 Disabled Enabled
Notes: When the Master Hyperion Enabled feature is set to Enabled, for all areas in the Quantum subsystem that have Hyperion
configured, the Hyperion feature will control the Lutron Sivoia QS roller shades and set their level automatically depending on the
position of the sun. When the Master Hyperion feature is set to Disabled, in all areas of the subsystem, the shades will not be
controlled automatically by the Hyperion feature and will not respond to radio window sensors.
Roof-Mount Cloudy
Day Sensor:
Subsystem Status
BV 4 X X X 0 1 Dark Sunny
Notes: A Lutron roof-mounted, wired Cloudy Day sensor or a BMS system sensor is used to override all Hyperion controlled shades in
the subsystem. Sunny indicates that the Hyperion feature is in control of the shades; Dark indicates that the shades are
overridden to open. This feature is independent of the radio window sensor feature.
(continued on next page)
BV = Binary-Value
PV = Present-Value
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Object Name Type Instance Read Write COV Units Min
PV
Max
PV
Inactive Text
(0)
Active Text (1) State Text (Multi-State)
{TimeclockName}
Enabled
BV 1000 to
1999
X X X 0 1 Disabled Enabled
Notes: For each timeclock in the Quantum system, there will be one instance number in the range from 1000 to 1999, that can either Enable or
Disable that timeclock in the subsystem, or query its current enable state.
Please note that for each such instance, there will be a corresponding instance at the same offset but within the range from 2000 to
2999, a {TimeclockName} Enable Command object, similar but with more functionality.
Please note that if there are multiple subsystems, the instance number representing an individual timeclock appears in each
subsystem’s BACnet system device. To enable or disable the timeclock for all subsystems, write to the same instance number in each
subsystem’s BACnet system device.
Write with 0 to Disable Permanently. The timeclock will no longer affect objects in the subsystem.
Write with 1 to Enable Without Catch Up. The timeclock will affect objects in the subsystem as programmed, but only starting with
future events.
Read {TimeclockName} Enabled will return 0 (Disabled) if the last {TimeclockName} Enable Command was any of the following:
Disable Permanently
Disable Until End of Day Without Catch Up
Disable Until End of Day With Catch Up
Read {TimeclockName} Enabled will return 1 (Enabled) if the last {TimeclockName} Enable Command was any of
Enable Without Catch Up
Enable With Catch Up
Enable and Run Previous Event Only
{TimeclockName} is a text string defined in the Lutron Quantum system configuration software
BV = Binary-Value
PV = Present-Value
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Object Name Type Instance Read Write COV Units Min
PV
Max
PV
Inactive
Text (0)
Active
Text (1)
State Text (Multi-State)
{TimeclockName}
Enable Command
MSV 2000 to
2999
X X X 1 6
1 = Disable Permanently
2 = Disable Until End of Day Without Catch Up
3 = Disable Until End of Day With Catch Up
4 = Enable Without Catch Up
5 = Enable With Catch Up
6 = Enable and Run Previous Event Only
Notes: For each timeclock in the Quantum system, there will be one instance number in the range from 2000 to 2999, that can either Enable
or Disable that timeclock in the subsystem, or query its current enable state.
Please note that for each such instance, there will be a corresponding instance at the same offset but within the range from 1000 to
1999, a {TimeclockName} Enabled object, similar but with less functionality.
Please note that if there are multiple subsystems, the instance number representing an individual timeclock appears in each
subsystem’s BACnet system device. To enable or disable the timeclock for all subsystems, write to the same instance number in each
subsystem’s BACnet system device.
WRITING:
Write with 1 to Disable Permanently. The timeclock will no longer affect objects in the subsystem.
Write with 2 to Disable Until End of Day Without Catch Up. The timeclock will not affect objects in the subsystem until midnight, at
which time it will affect objects in the subsystem as programmed, but only starting with future events.
Write with 3 to Disable Until End of Day With Catch Up. The timeclock will not affect objects in the subsystem until midnight, at which
time it will “catch up”, or set objects in the subsystem to the net state that would have occurred had the timeclock been enabled the
whole time. Thereafter, it will affect objects in the subsystem as programmed.
Write with 4 to Enable Without Catch Up. The timeclock will affect objects in the subsystem as programmed, but only starting with
future events.
Write with 5 to Enable With Catch Up. The timeclock will “catch up”, or set objects in the subsystem to the net state that would have
obtained had the timeclock never been disabled (accounting for missed events for up to the last seven days). Thereafter, it will affect
objects in the subsystem as programmed.
Write with 6 to Enable and Run Previous Event Only. The timeclock will run only the single last scheduled event. Thereafter, it will affect
objects in the subsystem as programmed.
READING:
If timeclock state was last changed by writing to {TimeclockName} Enable Command any of:
Disable Permanently
Disable Until End of Day Without Catch Up
Disable Until End of Day With Catch Up
Read thereof will return the same (1, 2, or 3). If timeclock state was last changed by writing to {TimeclockName} Enable Command was
any of:
Enable Without Catch Up
Enable With Catch Up
Enable and Run Previous Event Only
Read thereof will return the same (4, 5, or 6).
If timeclock state was last changed by writing 0 to the {TimeclockName} Enabled instance, then read of {TimeclockName} Enable
Command will return 1 (Disable Permanently).
If timeclock state was last changed by writing 1 to the {TimeclockName} Enabled instance, then read of {TimeclockName} Enable
Command will return 4 (Enable Without Catch Up).
{TimeclockName} is a text string defined in the Lutron Quantum system configuration software
{VariableName}
Current Variable
State
MSV 4000 to
4999
X X X 1 {Variable
State
Count}
{StateName}
Notes: The current value of a “State Variable”. The State Variable can be used during the evaluation of conditional logic on button
programming as configured in the Quantum system configuration software. The number of states, as well as the state names, must be
configured inside the Quantum system configuration software. {VariableName} is a text string defined in the Lutron Quantum system
configuration software. {VariableStateCount} is the number of states defined for this variable in the Lutron Quantum system
configuration software. {StateName} is a text string defined in the Lutron Quantum system configuration software.
BV = Binary-Value, MSV = Multi-State-Value
PV = Present-Value
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Object Name Type Instance Read Write COV Units Min
PV
Max
PV
Inactive
Text (0)
Active
Text (1)
State Text (Multi-State)
{Timeclock Name} /
{Timeclock Event}
Enabled
BV 5000 to 5999 X X X 0 1 Disabled Enabled
Notes: For each timeclock event in the Quantum subsystem, there will be one instance in the range of 5000 to 5999 that can be used to
enable or disable the individual events in the timeclock. Note that each timeclock may contain more than one event. Also note that
the timeclock Event Enabled, Hour, and Minute Instances are all correlated to each other by the last 3 digits of the instance
number. {TimeclockName} is a text string defined in the Lutron Quantum system configuration software.
{Timeclock Name} /
{Timeclock Event}
Hour
AV 6000 to 6999 X X X Hours 0 23 N/A N/A
Notes: For each timeclock event in the Quantum subsystem, there will be one instance in the range of 6000 to 6999 that can be used to
set the hour at which each timeclock event will occur. The hour is set in the 24 hour format (0 = 12 midnight). Note that each
timeclock may contain more than one event. Note that each timeclock may contain more than one event. Also note that the
timeclock Event Enabled, Hour, and Minute Instances are all correlated to each other by the last 3 digits of the instance number.
{TimeclockName} is a text string defined in the Lutron Quantum system configuration software.
{Timeclock Name} /
{Timeclock Event}
Minute
AV 7000 to 7999 X X X Minutes 0 59 N/A N/A
Notes: For each timeclock event in the Quantum subsystem, there will be one instance in the range of 7000 to 7999 that can be used to
set the minute at which each timeclock event will occur. The minute of the event can be set from 0 to 59. Note that each timeclock
may contain more than one event. Also note that the timeclock Event Enabled, Hour, and Minute Instances are all correlated to
each other by the last 3 digits of the instance number. {TimeclockName} is a text string defined in the Lutron Quantum system
configuration software.
BV = Binary-Value, AV = Analog-Value
PV = Present-Value
)Lutron, Lutron, Quantum, and Sivoia are trademarks of Lutron Electronics Co., Inc., registered in the U.S. and other countries.
Hyperion is a trademark of Lutron Electronics Co., Inc.
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