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This document is the property of CIAT and is delivered on the express condition that it is not to be disclosed, reproduced in whole or in part, or used for manufacture by anyone other than CIAT without its written consent, and that no right is granted to disclose or so use any information contained in said document.
CIAT reserves the right to change or modify the information or product described without prior notice and without incurring any liability.
© 2016, CIAT 808-335 Rev. 06/16
LonWorksCIAT Translator
Overview and ConfigurationManual
Introduction ................................................................. 1About this Manual .................................................. 1
Operating Characteristics ........................................... 3Templates ................................................................ 3Default Address and Baud Rate .............................. 5LonWorks CIAT Translator ConfigurationTables ...................................................................... 6
CIAT Translator Configuration Table ........... 6Chiller Mapping Tables .................................. 6Generic Mapping Tables ................................ 6Rooftop Mapping Tables .............................. 7CIAT Translator Device ConfigurationTable ............................................................... 7
CIAT Translator Maintenance Tables ................... 7 Chiller, Rooftop, Generic
Mapping Maintenance Tables ....................... 7Communication Status Maintenance Table .... 7Messages Maintenance Table ....................... 7
Configuration ............................................................... 9Configuration Process ............................................. 9
Select the LonWorks Profile ........................... 9Map CPP Points with LonWorks Variables ..10 Check for Mapping Errors and Confirm Valuesin Maintenance Tables ..................................11Commissioning the Device on the LonWorksNetwork .........................................................12
CIAT Translator Configuration (CONFIG) Table ..13 Chiller Mapping Configuration (CHLRMAP1)Table 1 ....................................................................16Chiller Mapping Configuration (CHLRMAP2)Table 2 ....................................................................21Rooftop Mapping Configuration (RTUMAP1)Table 1 ....................................................................25Rooftop Mapping Configuration (RTUMAP2)Table 2 ....................................................................31
Generic Mapping Configuration (GNRCMAP1)Table 1 ....................................................................36Generic Mapping Configuration (GNRCMAP2)Table 2 ....................................................................40
Maintenance ................................................................45 Chiller Maintenance (CHLRMNT1) Table 1 ....................................45
Chiller Maintenance(CHLRMNT2) Table 2 ....................................48Rooftop Maintenance(RTUMNT1) Table 1 ......................................50Rooftop Maintenance(RTUMNT2) Table 2 ......................................52Generic Maintenance(GNRCMNT1) Table 1 ...................................55Generic Maintenance(GNRCMNT2) Table 2 ...................................57Communication Status (COMMSTAT)Maintenance Table ........................................59Messages Maintenance (MESSAGES)Table ..............................................................61
Appendix ......................................................................63
Index ............................................................................77
ii
iii
ManualRevisions
The LonWorks CIAT Translator Overview and Configuration Manual is catalog number 808-335, Rev. 06/16.
ChangesSection/Chapter
N/A
iv
Introduction
1
This manual contains information about the functions of the LonWorks CIAT Translator module with LON FT-10A (free topology) communi-cation and how the user configures the LonWorks CIAT Translator to perform those functions.
The manual is divided into the following sections:
• Introduction• Operating Characteristics• Configuration• Maintenance
The Introduction consists of this description of the manual.
The Operating Characteristics section contains a description of the CIAT Translator hardware and a summary description of its configura-tion and maintenance tables.
The Configuration section contains detailed lists of the decisions for each CIAT Translator configuration table. Each list entry includes the decision’s purpose, the range of values that may be used, and the default values that will appear in the decision if it is not configured by the user. The mapping tables include an explanation of each decision, along with the LonWorks read/write access, LON Variable Type, and an example CPP point name.
The Maintenance section contains detailed lists of the decisions for each CIAT Translator maintenance table. Each list entry includes the decision’s purpose and the range of values that may be displayed.
The Appendix contains examples of actual configurations for a chiller, rooftop, and generic template, along with a list of LON SNVTs and corresponding CPP (Chiller Proprietary Protocol) point names and descriptions.
About thisManual
Introduction
2
OperatingCharacteristics
3
The LonWorks CIAT Translator with LON FT-10A (free topology) communication is a micro controller-based module that provides the ability to integrate CIAT CPP-based controllers into LonWorks-based networks.
The LonWorks CIAT Translator (33CNTRANLON) provides CPP to LON FT-10A ANSI/EIA-709.1 protocol conversion.
The CIAT Translator can be mounted in the controls section of any CPP equipment and converts the CPP-based controller data to LonWorks. The CIAT Translator is outdoor duty rated and contains a CPP RS-485 connector and a LON FT-10A communications connector.
The LonWorks CIAT Translator can convert CIAT equipment with CPP controls to LON and outputs the CPP data in standard LON Rooftop or Chiller profiles. CIAT rooftop units can be converted to the standard LonMark Rooftop Unit (RTU) Functional profile 8030 Version 1.1. CIAT chillers can be converted to the standard LonMark Chiller Functional profile 8040 Version 1.0. The chiller and rooftop profiles include additional LON SNVTs beyond those required by the LON standard profiles. These additional SNVTs allow for enhanced LON capability beyond the standard LON-defined profiles. In addition to the rooftop and chiller profiles, a generic LON profile is also supplied. This profile can be used to convert CIAT controllers that may not convert efficiently into the LonMark Rooftop or Chiller profiles.
When connected to a CPP controller, the LonWorks CIAT Translator allows a third party LON device to read and write to the CPP controller’s mapped status display, time schedule, and setpoint schedule data. Note that LON status display write access is subject to the CPP equipment controller’s defined read/write access for each status display item.
The LonWorks CIAT Translator contains chiller, rooftop, and generic LON templates that allow mapping of various CPP points to LON SNVTs. Tables 2-1 through 2-3 show the type and quantity of CPP points in each supplied template.
OperatingCharacteristics
Templates
4
Reads Writes
Space Temperature Space TemperatureOutdoor Air Temperature Outdoor Air TemperatureOutdoor Air Humidity Outdoor Air HumidityCO2 (PPM) Space HumidityCooling Coil % CO2 (PPM)Heating Coil % Supply Air Setpoint (VAV)Economizer Position % Setpoint OffsetFan Speed % 6 Setpoints (degF)Normal/Alarm Discrete 1 Setpoint (PPM)Controlling Setpoint Occupancy Schedule (>64E)4 Generic Temperature 1 Generic Temperature8 Generic Discrete 3 Generic Discrete2 Generic Pressure ("H2O) 3 Generic Discrete3 Generic Percentage 1 Generic Pressure ("H2O)2 Generic Delta Temp 2 Generic Percentage2 Generic (0 to 65535) 1 Generic (0 to 65535)2 Generic (-32767 to 32767)
Reads Writes
Percent Capacity Chiller Start/StopActive Demand Limit Percent Active Demand Limit PercentChilled Water Control Temp Chilled Water Control TempEntering Chilled Water Temp Hot Water Control TempLeaving Chilled Water Temp Occupancy Schedule (>64E)Entering Cond Water Temp 1 Generic TemperatureLeaving Cond Water Temp 2 Generic DiscreteChilled Water Flow Discrete 1 Generic Pressure (PSI)Cond Walter Flow Discrete 1 Generic (0 to 65535)6 Generic Temperature6 Generic Discrete4 Generic Pressure (PSI)2 Generic Percentage2 Generic Delta Temp2 Generic (0 to 65535)2 Generic (-32767 to 32767)
Table 2-1 Rooftop Template
Table 2-2Chiller Template
5
Reads Writes
Cooling Coil % 6 Setpoints (degF)Heating Coil % Occupancy Schedule (>64E)Second Heating Coil % 3 Generic TemperatureEconomizer Position % 3 Generic DiscreteFan Speed % 1 Generic Pressure ("H2O)Normal/Alarm Discrete 1 Generic Pressure (PSI)8 Generic Temperature 2 Generic Percentage8 Generic Discrete 1 Generic PPM2 Generic Pressure ("H2O) 1 Generic (0 to 65535)4 Generic Pressure (PSI)4 Generic Percentage2 Generic Delta Temp1 Generic PPM2 Generic (0 to 65535)2 Generic (-32767 to 32767)
The LonWorks CIAT Translator’s default CPP address is 0,200 (bus number, system element number). The default CPP baud rate is 9600 bps.
Each LonWorks CIAT Translator has a unique LON address. The LON address can be sent to LON configuration tools when the LON service pin is pressed.
The CIAT Translator has three LEDs that are used to indicate opera-tional status:
LED Color Indicates
Status Red Operating, initialization and configurationstatus. The LED blinks at a 2 Hz ratewhen initializing and at 1 Hz whenoperating correctly.
CPP Yellow The CIAT Translator is sending CPP communication messages to the connected CPP controller. If the connected CPP controller is responding, its CPP LED will blink when a message is sent back to the CIAT Translator.
(continued)
Table 2-3Generic Template
Default Addressand Baud Rate
Table 2-4CIAT Translator LEDs
6
LED Color Indicates
LON Green The CIAT Translator is sending LON communication messages to the third party LonWorks network.
The CIAT Translator contains the configuration tables listed below. For descriptions of the decisions in each table, refer to the Configuration section of this manual. The purpose of each table is summarized on the following pages.
CIAT Translator Device Configuration Table (CtlrID) Chiller Mapping Table 1 (CHLRMAP1)Chiller Mapping Table 2 (CHLRMAP2)CIAT Translator Configuration Table (CONFIG) Generic Mapping Tab le 1 (GNRCMAP1)Generic Mapping Table 2 (GNRCMAP2)Rooftop Unit Mapping Table 1 (RTUMAP1) Rooftop Unit Mapping Table 2 (RTUMAP2)
The CIAT Translator Configuration Table (CONFIG) contains deci-sions used to specify the following:
• LonWorks Profile (Rooftop, Chiller, Generic)• CPP Address• Auto-mapping• Reset Points Profile
The Chiller Mapping Tables (CHLRMAP1 and CHLRMAP2) are used to map or associate CPP points with the variables in the LonWorks Chiller profile, which is based on LonMark Functional Profile Chiller 8040 V 1.0. These tables are configured if the CIAT Translator CONFIG Table's Device Type decision is set to 2 (Chiller).
The CIAT Translator's Generic Mapping Tables (GNRCMAP1 and GNRCMAP2) are used to map or associate CPP points with the variables in the LonWorks generic controller profile. These tables are configured if the CIAT Translator CONFIG Table's Device Type decision is set to 3 (Generic). This table could be used, for example, to allow LON access to an air handler.
Table 2-4CIAT Translator LEDs (continued)
LonWorks CIAT Translator Configuration Tables
CIAT Translator Configuration Table
Chiller Mapping Tables
Generic MappingTables
7
Chiller, Rooftop,Generic MappingMaintenance Tables
The CIAT Translator's Rooftop Mapping Tables (RTUMAP1 and RTUMAP2) are used to map or associate CPP points with the variables in the LonWorks rooftop profile, which is based on LonMark Function Profile Rooftop Unit 8030 Version 1.1. The table is configured if the CIAT Translator CONFIG Table's Device Type decision is set to 1(Rooftop).
The CIAT Translator contains a Device Configuration Table (CtlrID). By changing the information that appears in this table, you can change the name, description, and location that appears for the CIAT Translator in the CPP front end's Controller List.
The CIAT Translator contains the following maintenance tables:
Chiller Mapping Table 1 (CHLRMNT1)Chiller Mapping Table 2 (CHLRMNT2)Communication Status Table (COMSTAT)Generic Mapping Table 1 (GNRCMNT1)Generic Mapping Table 2 (GNRCMNT2)LonWorks Messages Table (MESSAGES)Rooftop Unit Mapping Table 1 (RTUMNT1)Rooftop Unit Mapping Table 2 (RTUMNT2)
The maintenance values displayed in these tables are read-only values that show the current value of the CPP points that have been mapped to the Lonworks variables as the points exist in the CPP system element. These values are updated every 30 seconds. Note that if a LonWorks read (nvo) and write (nvi) variable have been mapped to the same CPP point, they will display the same value in the maintenance table display.
The maintenance values displayed in this table are read-only values that show diagnostic data about LonWorks-to-CPP system element com-munication.
The maintenance values displayed in this table are read-only values that show diagnostic data about LonWorks-to-CPP system element com-munication messages.
Rooftop MappingTables
CIAT Translator Device Configuration Table
CIAT Translator Maintenance Tables
Messages MaintenanceTable
Communication StatusMaintenance Table
8
Configuration
9
The LonWorks CIAT Translator's operation is controlled by decisions entered in a group of configuration tables. The CIAT Translator contains the following configuration tables:
CTLR_ID
CHLRMAP1CHLRMAP2CONFIGGNRCMAP1GNRCMAP2RTUMAP1RTUMAP2
CIAT Translator Controller Identification TableChiller Mapping Configuration Table 1 Chiller Mapping Configuration Table 2 CIAT Translator Configuration Table Generic Configuration Table 1Generic Configuration Table 2Rooftop Unit Configuration Table 1 Rooftop Unit Configuration Table 2
LonWorks CIAT Translator configuration and start-up consists of four main processes:
1. Physically connect the LonWorks CIAT Translator to the CPPsystem element.
2. Select the appropriate LonWorks profile. You do this in theCONFIG Table.
3. Map, or associate, CPP points with LonWorks points by config-uring the appropriate set of configuration tables (rooftop, chiller,or generic), depending on the device type that you selected in theCONFIG Table.
4. Commission the CIAT Translator on the LonWorks network.
Each of the above-listed processes is discussed below.
1. Connect the target CPP system element to the CIAT Translator's CPP connector. Confirm that the element is powered and communicating on the CPP Bus.
2. Using a CPP front end (such as Service Tool) access the CIAT Translator’s CONFIG Table and select the appropriate LonWorks profile (Rooftop, Chiller, or Generic) by entering a 1, 2, or a 3 into the CONFIG Table's Device Type decision.
Configuration
ConfigurationProcess
Select the LonWorksProfile
10
3. Enter appropriate values into all CONFIG Table decisions and download the CONFIG Table into the CIAT Translator.
If the CIAT Translator is on a CPP bus with elements other than the single CPP device with which it is communicating, you must:
• Set Bus and Element #s• Set the Reset Points Profile decision to Yes• Download.
This chapter's CIAT Translator Configuration (CONFIG) Tablesection contains explanations of and allowable entries and defaultvalues for each CONFIG Table decision.
After approximately 5 seconds, the CIAT Translator should identify the target CPP system element and begin to download its tables. This takes 10 to 40 seconds, depending on the number of tables in the target CPP system element. During this period, the Yellow LED will flash to indicate CPP bus activity. When the flashing stops, the download is complete.
Note: Do not cycle CIAT Translator power within 30 secondsof downloading the CONFIG Table or any of the map-ping tables. Be sure that the Yellow CPP LED is NOT flashing.
1. Using a CPP front end, access the appropriate set of configurationtables, depending on the value you specified in the CONFIG Table'sDevice Type decision :
Rooftop (Device Type 1) - RTUMAP1 and RTUMAP2Chiller (Device Type 2) - CHLRMAP1 and CHLRMAP2Generic (Device Type 3) - GNRCMAP1 and GNRCMAP2
2. You will now "map" or associate CPP point names with each LonWorks network variable name that is listed in the configuration tables. Note that those LonWorks network variables having read access begin with the characters nvo and LonWorks network variables with write access begin with the characters nvi.
Entries are case insensitive - upper or lower case characters may beused.
Map CPP Points with LonWorks Variables
11
In the Lon structure, there are different types of points for reading and writing purposes. If a CPP point is to be both read and written to by the Lon system, it is recommended that you use two Lon points to accomplish this. The reason for using a separate Lon point to read the CPP point is in case that CPP point is forced by a higher level function than the CIAT Translator itself, which uses Control forces.
Also in the Lon structure, there are dedicated types of points for different types of generic values, such as Temperature, Tempera-ture Difference, Pressure, Percent, and Discrete. You must associate a particular CPP point with the matching Lon point type or the CIAT Translator will not function properly.
In addition, for the CIAT Translator's chiller and rooftop map-ping tables, the identity of some Lon points have been pre-determined to conform to the LonMark functional profile for the particular device type. Using these points, where possible, allows the generic point types that appear later in the mapping table to be used for other CPP points. Example: In the Chiller tables there are dedicated Lon points for Entering and Leaving Chilled Water Temperature, and in the Rooftop tables there are dedicated points for Space and Outside Air Temperature.
Explanations of each table decision, along with example CPP point names, can be found later in this Configuration chapter. Examples of completed templates and lists of SNVTs and corresponding CPP points can be found in the Appendix.
1. Using a CPP front end, access the two configuration mappingtables (chiller, rooftop, or generic) that were used in Step 2 of theMap CPP Points with LonWorks Variables procedure, whichappears prior to this section of the Configuration chapter.
2. Download each table to the CIAT Translator and wait approxi-mately one minute.
During this time the CIAT Translator performs error checking toverify if you have entered any non-existent point names as well aschecks for correct point types (analog/discrete,etc.).
3. Upload the tables and check the displayed tables.
Look for any decisions that may have the message error**1 orerror**2 displayed in their Value column. These messagesindicate that the entry that was made for this decision is invalid:
Check for MappingErrors and ConfirmValues in MaintenanceTables
12
error**1 Indicates that the point name was not found in thetarget CPP system element.
error**2 The point name was found on the target CPP devicebut the data type is not valid to this LonWorks net-work variable.
The errors should be corrected and the tables downloaded.
Example: If, in the CHILLERMAP1 Table, the nvoTEMP1decision has been configured with the point nameDP_A, which is a pressure, the message error**2 willbe displayed because this decision requires a tempera-ture point.
After verifying that there are no error messages in either Configuration mapping Table, cycle power to the CIAT Translator and observe the yellow LED. This is the CPP communication indicator.
Approximately one minute after the yellow LED stops blinking, check theappropriate Maintenance Tables to confirm that the correct data isdisplayed for each configured point.
Note: The CIAT Translator polls the CPP system element every 30 seconds to both Read and Write CPP points.
The CIAT Translator is now fully commissioned on the CIAT/CPP side and is ready for the Lon systems integrator to commission the Lon side using a Lon software tool such as LonMaker.
A list of the actual CPP points configured in the appropriate MAP1 and MAP2 templates should be supplied to the systems integrator to assist him/her with the commissioning process. A blank copy of these templates can be found in the Appendix of this manual. Additionally, the NeuronID of the Echelon Lon processor chip should also be supplied to the systems integrator. This is a 12 character alphanumeric code that can be found on a white label located along the upper edge of the control board, opposite the Lon connector.
After the LonWorks CIAT Translator is added to the LonWorks network, the LonWorks network variables that were mapped in this chapter's Map CPP Points with LonWorks Variables procedure can be used to read/write data points on the target CPP system element.
Commissioning theDevice on theLonWorks Network
13
CIAT Translator Configuration(CONFIG) Table
The CIAT Translator's CONFIG Table is shown below. An explanation of each decision, including allowable entries and default values follows.
Note: When starting up the CIAT Translator this is the first tableyou must configure.
Device Type1=Rftp, 2=Chillr,3=Gnrc
Use this decision to select the desired LonWorks Profile. After entering this value and downloading this table to the CIAT Translator, the appropriate LonWorks variable names will be loaded into the CIAT Translator.
Allowable Entries 1 = Rooftop2 = Chiller3 = Generic
Default Value 0
Figure 3-1CIAT Translator Configuration (CONFIG) Table
14
Use this decision to specify the bus number of the CPP system element to which the CIAT Translator is connected.
Note: If you do not enter a value for this decision or if the value isincorrect, the CIAT Translator will attempt to find the element address itself. You will then have to upload this table to check if the correct address has been found.
Allowable Entries 0-239
Default Value 0
Use this decision to specify the number of the CPP system element to which the CIAT Translator is connected.
Note: If you do not enter a value for this decision or if the value is incorrect, the CIAT Translator will attempt to find the element address itself. You will then have to upload this table to check if the correct address has been found.
Allowable Entries 0-239
Default Value 0
Use this decision to disable or enable the CIAT Translator's automatic mapping feature. Setting this decision to No will cause the CIAT Trans-lator to upload mapping tables that may exist in the target CPP system element. Setting this decision to Yes will disable automatic mapping and will cause the CIAT Translator to use the mapping tables from the CIAT Translator.
Note: No current CPP system element contains automatic mappingtables.
Allowable Entries 0 = No1 = Yes
Default Value 0
Target Bus No.
Target Address
Disable Auto-mapping
15
Reset Points Profile Use this decision to clear the contents of all of the CIAT Translator's CPP points to LonWorks variable mapping tables. This decision resets to No on completion of the operation. The following tables will be cleared:
RTUMAP1 and RTUMAP2CHLRMAP1 and CHLRMAP2GNRCMAP1 and GNRCMAP2
Note: Do not save this decision set to Yes. Do not cycle CIAT Translator power for at least 30 seconds after downloading this decision set to Yes. If you do cycle power within 30 seconds of downloading this decision as Yes, the CIAT Translator will return to its default address of 0,200 at a baud rate of 9600 baud.
Allowable Entries 0 = No1 = Yes
Default Value 0
Use this decision to clear the COMMSTAT Maintenance Table's NumSuccessful Messages and Num Failed Messages counters. This decisionresets to No on completion of the operation.
Note: Do not save this decision set to Yes.
Allowable Entries 0 = No1 = Yes
Default Value 0
Use this decision to specify whether the CIAT Translator should act as a CPP alarm acknowledger for all alarm messages received from the CPP Bus. There must be only one CPP alarm acknowledger per CPP.
Note that alarms from the CIAT Translator's target system element are placed into the CIAT Translator's buffer.
Allowable Entries 0 = No1 = Yes
Default Value 1
Reset Comm. Counters
Alarm Acknowledger
16
Chiller MappingConfiguration(CHLRMAP1)Table 1
The CIAT Translator's CHLRMAP1 Table is used to map or associate CPP points with the variables in the LonWorks chiller profile (which is based on LonMark Functional Profile: Chiller 8040 V 1.0). This table should be configured if the CIAT Translator CONFIG Table's Device Type decision was set to 2 (Chiller). A sample CHLRMAP1 Table is shown below. An explanation of each decision, including LonWorks read/write access, LON Variable Type, along with an example CPP point name follows.
CPP point names can consist of up to 8 characters. The default for each decision is blank.
Figure 3-2Chiller Mapping 1Configuration (CHLRMAP1)Table
Allowable Entries andDefault Value
17
Use this decision to specify the name of the discrete CPP point that the LON system can write to in order to start or stop the chiller.
LON Variable Type SNVT_switch
Read/Write Access Write
Example CHIL_S_SChiller Start/Stop
Use this decision to specify the name of the analog CPP point that the LON system can write to in order to set the leaving chilled water tem-perature setpoint when the chiller is operating in cooling mode.
LON Variable Type SNVT_temp_p
Read/Write Access Write
Example CTRL_PNTControl Point
Use this decision to specify the name of the discrete CPP point that the LON system can read in order to indicate the chiller's current status (on/off ).
Note: Most CPP chillers do not contain this point.
LON Variable Type SNVT_switch
Read/Write Access Read
Use this decision to specify the name of the analog CPP point that the LON system can read in order to obtain the current value of the chiller's cooling or heating setpoint. The setpoint to be used (cooling or heating) depends on the chiller's current operating mode.
LON Variable Type SNVT_temp_p
Read/Write Access Read
Example CTRL_PNTControl Point
Use this decision to specify the name of the analog CPP point that the LON system can write to in order to set the capacity limit of the chiller.
LON Variable Type SNVT_lev_percent
Read/Write Access Write
Example DEM_LIMActive Demand Limit
nviCoolSetpt
nvoOnOff
nvoActiveSetpt
nviCapacityLim
nviChillerEnable
18
Use this decision to specify the name of the analog CPP point that the LON system can write to in order to set the heating setpoint.
LON Variable Type SNVT_temp_p
Read/Write Access Write
Example CTRL_PNTControl Point
Use this decision to specify the name of the analog CPP point that the LON system can read in order to obtain the current running capacity of the chiller.
LON Variable Type SNVT_lev_percent
Read/Write Access Read
Example CAP_TPercent Total Capacity
Use this decision to specify the name of the analog CPP point that the LON system can read in order to obtain the chiller's current capacity limit setpoint.
LON Variable Type SNVT_lev_percent
Read/Write Access Read
Example DEM_LIMActive Demand Limit
Use this decision to specify the name of the analog CPP point that the LON system can read in order to obtain the leaving chilled water tem-perature.
LON Variable Type SNVT_temp_p
Read/Write Access Read
Example LWTLeaving Fluid Temp
Use this decision to specify the name of the analog CPP point that the LON system can read in order to obtain the entering chilled water temperature.
LON Variable Type SNVT_temp_p
Read/Write Access Read
Example EWTEntering Fluid Temp
nviHeatSetpt
nvoActualCapacity
nvoCapacityLim
nvoEntCHWTemp
nvoLvgCHWTemp
19
nvoLvgCNDWTemp
Use this decision to specify the name of the analog CPP point that the LON system can read in order to obtain the entering condenser water temperature.
LON Variable Type SNVT_temp_p
Read/Write Access Read
Example COND_EWTCondenser Entering Fluid
Use this decision to specify the name of the analog CPP point that the LON system can read in order to obtain the leaving condenser water temperature.
LON Variable Type SNVT_temp_p
Read/Write Access Read
Example COND_LWTCondenser Leaving Fluid
Use this decision to provide the name of the discrete CPP point that the LON system can read in order to obtain the main running mode of the chiller.
Note: Most CPP chillers do not contain this point.
LON Variable Type SNVT_chlr_status
Read/Write Access Read
Use this decision to provide the name of the discrete CPP point that the LON system can read in order to obtain the main operating status of the chiller.
Note: Most CPP chillers do not contain this point.
LON Variable Type SNVT_chlr_status
Read/Write Access Read
Use this decision to provide the name of the discrete CPP point the LON system can read in order to obtain the alarm status of the chiller.
Note: Most CPP chillers do not contain this point.
LON Variable Type SNVT_chlr_status
Read/Write Access Read
nvoChillerStat.run_mode
nvoEntCNDWTemp
nvoChillerStat.in_alarm
nvoChillerStat.op_mode
20
Use this decision to specify the name of the discrete CPP point that the LON system can read in order to obtain the status of the chiller (start/stop).
LON Variable Type SNVT_chlr_status
Read/Write Access Read
Example CHIL_S_SChiller Start/Stop
Use this decision to specify the name of the discrete CPP point that the LON system can read in order to obtain the chiller's local or network control status.
Note: Most CPP chillers do not contain this point.
LON Variable Type SNVT_chlr_status
Read/Write Access Read
Use this decision to specify the name of the discrete CPP point that the LON system can read in order to indicate that the chiller cannot reach setpoint.
Note: Most CPP chillers do not contain this point.
LON Variable Type SNVT_chlr_status
Read/Write Access Read
Use this decision to specify the name of the discrete CPP point that the LON system can read in order to indicate if chilled water flow is present.
LON Variable Type SNVT_chlr_status
Read/Write Access Read
Example COOLFLOWCooler Flow Switch
Use this decision to specify the name of the discrete CPP point that the LON system can read in order to indicate if condenser water flow is present.
LON Variable Type SNVT_chlr_status
Read/Write Access Read
Example CONDFLOWCondenser Flow Switch
nvoChillerStat.run_enabl
nvoChillerStat.Local
nvoChillerStat.Limited
nvoChillerStat.cndw_flow
nvoChillerStat.chw_flow
21
nviOccSchedule Use this decision to specify the name of the CPP occupancy schedule that the LON system can write to in order to set occupancy times.
Note: The chiller unit must be configured to use a global occupancyschedule (Allowable entries: OCCPC65E to OCCPC99E).Refer to the chiller documentation for additional information onthe setup of the global occupancy schedule.
LON Variable Type SNVT_tod_event
Read/Write Access Write
Example OCCPC66EOccupancy Equipment
The CIAT Translator's CHLRMAP2 Table is used to map or associate CPP points with the variables in the LonWorks chiller profile. This table, in addition to the CHLRMAP1 Table, should be configured if the CIAT Translator CONFIG Table's Device Type decision was set to 2 (Chiller). A sample CHLRMAP2 Table is shown below. An explanation of each decision, including LonWorks read/write access, LON Variable Type, along with an example CPP point name follows.
CPP point names can consist of up to 8 characters. The default for each decision is blank.
Use this decision to specify the name of the analog CPP point that the LON system can write to in order to set an additional chiller operating temperature.
LON Variable Type SNVT_temp_p
Read/Write Access Write
Example OATOutdoor Air Temperature
Use these 6 decisions to specify the names of the analog CPP points that the LON system can read in order to obtain additional chiller operating temperatures.
LON Variable Type SNVT_temp_p
Read/Write Access Read
Example TMP_SCTASaturated Condensing Temp
Chiller MappingConfiguration(CHLRMAP2)Table 2
Allowable Entries andDefault Value
nviTEMP1
nvoTEMP1 - 6
22
Figure 3-3Chiller Mapping 2Configuration (CHLRMAP2)Table
23
Use this decision to specify the name of the analog CPP point that the LON system can write to in order to set an additional chiller operating pressure.
Note: 1. Most CPP chillers do not allow write access to this point.2. For use with points having units of psi (kPa).
LON Variable Type SNVT_press
Read/Write Access Write
Use these 4 decisions to specify the names of the analog CPP points that the LON system can read in order to obtain additional chiller operating pressures.
Note: 1. For use with points having units of psi (kPa).
LON Variable Type SNVT_press
Read/Write Access Read
Example SP_ASuction Pressure Circuit A
Use these 2 decisions to specify the names of the analog CPP points the LON system can read in order to obtain additional chiller operating parameters in percentage.
LON Variable Type SNVT_lev_percent
Read/Write Access Read
Example CAPA_APercentage Operating Capacity
Use these 2 decisions to specify the names of the analog CPP points that the LON system can read in order to obtain additional chiller differential temperatures.
LON Variable Type SNVT_temp_diff
Read/Write Access Read
Example SH_ASuction Superheat
Use these 2 decisions to specify the names of the discrete CPP points that the LON system can write to in order to set additional discrete operating parameters.
LON Variable Type SNVT_switch
Read/Write Access Write
Example EMSTOPEmergency Stop
nvoPRESS1 - 4
nviPRESS1
nvoPCT1 - 2
nvoTEMPDIFF1 - 2
nviDISCRETE1 - 2
24
Use these 6 decisions to specify the names of the discrete CPP points that the LON system can read in order to obtain additional discrete operating parameters.
LON Variable Type SNVT_switch
Read/Write Access Read
Example FANS_1Fan 1 Relay
Use this decision to specify the name of the analog or multi-state CPP point that the LON system will write to in order to set additional analog or multi-state operating parameters.
LON Variable Type SNVT_count
Read/Write Access Write
Example S_HRSService Ontime Hours
Use these decisions to specify the names of the analog or multi-state CPP points that the LON system will read in order to obtain additional analog or multi-state values.
LON Variable Type SNVT_count
Read/Write Access Read
Example STATRun Status
Use these decisions to specify the names of the analog or multi-state CPP points that the LON system will read in order to obtain additional analog or multi-state values.
LON Variable Type SNVT_count_inc
Read/Write Access Read
Example STATRun Status
nvoDISCRETE1 - 6
nviCOUNT1
nvoCOUNT1 - 2
nvoCOUNTinc1 - 2
25
The CIAT Translator's RTUMAP1 Table is used to map or associate CPP points with the variables in the LonWorks rooftop profile (which is based on LonMark Functional Profile: Rooftop Unit (RTU) 8030 Version 1.1). This table should be configured if the CIAT Translator CONFIG Table's Device Type decision was set to 1 (Rooftop). A sample RTUMAP1 Table is shown on the page which follows. An explanation of each decision, including LonWorks read/write access, LON Variable Type, along with an example CPP point name follows.
CPP point names can consist of up to 8 characters. The default for each decision is blank.
Use this decision to specify the name of the analog CPP point that the LON system can write to in order to set the space temperature.
LON Variable Type SNVT_temp_p
Read/Write Access Write
Example SPTSpace Temperature
Use this decision to specify the name of the analog CPP point that the LON system can write to in order to set the temperature setpoint.
LON Variable Type SNVT_temp_p
Read/Write Access Write
Example CTRL_PNTControl Point
Use this decision to specify the name of the analog CPP point that the LON system can read in order to indicate the space temperature.
LON Variable Type SNVT_temp_p
Read/Write Access Read
Example SPTSpace Temperature
Use this decision to specify the name of the discrete CPP point that the LON system can read in order to indicate the rooftop's operating mode.
Note: CPP rooftops do not contain this point.
LON Variable Type SNVT_hvac_status
Read/Write Access Read
nviSpaceTemp
nvoUnitStatus.mode
nvoSpaceTemp
nviSetPoint
Allowable Entries andDefault Value
Rooftop MappingConfiguration(RTUMAP1)Table 1
26
Figure 3-4Rooftop Mapping 1Configuration (RTUMAP1)Table
27
Use this decision to specify the name of the analog CPP point that the LON system can read in order to indicate the current primary heat capacity in percent full scale.
LON Variable Type SNVT_hvac_status
Read/Write Access Read
Example HCAPHeating % Total Capacity
Use this decision to specify the name of the analog CPP point that the LON system can read in order to indicate the current secondary heat capacity in percent full scale.
LON Variable Type SNVT_hvac_status
Read/Write Access Read
Example HCAPHeating % Total Capacity
Use this decision to specify the name of the analog CPP point that the LON system can read in order to indicate the current secondary cooling capacity in percent full scale.
LON Variable Type SNVT_hvac_status
Read/Write Access Read
Example CCAPCooling % Total Capacity
Use this decision to specify the name of the analog CPP point that the LON system can read in order to indicate the current economizer position in percent full scale.
LON Variable Type SNVT_hvac_status
Read/Write Access Read
Example ECONOPOSEconomizer Position %
Use this decision to specify the name of the analog CPP point that the LON system can read in order to indicate the current fan speed in percent full scale.
LON Variable Type SNVT_hvac_status
Read/Write Access Read
Example VFDVariable Frequency Drive Speed %
nvoUnitStatus.heat_out_s
nvoUnitStatus.cool_out
nvoUnitStatus.econ_out
nvoUnitStatus.fan_out
nvoUnitStatus.heat_out_p
28
nvoUnitStatus.in_alarm Use this decision to provide the name of the discrete CPP point that theLON system can read in order to indicate the alarm status of the rooftop.
Note: Most CPP rooftops do not contain this point.
LON Variable Type SNVT_hvac_status
Read/Write Access Read
Use this decision to specify the name of the CPP occupancy schedule that the LON system can write to in order to set occupancy times.
Note: The rooftop unit must be configured to use a global occupancyschedule (Allowable entries: OCCPC65E to OCCPC99E).Refer to the rooftop documentation for additional informationon the setup of the global occupancy schedule.
LON Variable Type SNVT_tod_event
Read/Write Access Write
Example OCCPC66EOccupancy Equipment
Use this decision to specify the name of the analog CPP point that the LON system will write to in order to set the active temperature setpoint.
Note: Most CPP rooftops do not contain this point.
LON Variable Type SNVT_temp_p
Read/Write Access Write
Use this decision to specify the name of the analog CPP point that the LON system will write to in order to set the outside air temperature.
LON Variable Type SNVT_temp_p
Read/Write Access Write
Example OATOutside Air Temperature
Use this decision to specify the name of the analog CPP point that the LON system will write to in order to set the outside air relative humidity.
LON Variable Type SNVT_lev_percent
Read/Write Access Write
Example OARHOutside Air Relative Humidity
nviOccSchedule
nviSetptOffset
nviOutsideRH
nviOutsideTemp
29
Use this decision to specify the name of the analog CPP point that the LON system can read in order to indicate the temperature setpoint.
LON Variable Type SNVT_temp_p
Read/Write Access Read
Example CTRL_PNTControl Point
Use this decision to specify the name of the analog CPP point that the LON system can read in order to indicate the outside air temperature.
LON Variable Type SNVT_temp_p
Read/Write Access Read
Example OATOutside Air Temperature
Use this decision to specify the name of the analog CPP point that the LON system can read in order to indicate the outside air relative humidity.
LON Variable Type SNVT_lev_percent
Read/Write Access Read
Example OARHOutside Air Relative Humidity
Use this decision to specify the name of the analog CPP point that the LON system will write to in order to set the relative humidity.
LON Variable Type SNVT_lev_percent
Read/Write Access Write
Example RHRelative Humidity
Use this decision to specify the name of the analog CPP point that the LON system will write to in order to set the CO2 level in ppm.
LON Variable Type SNVT_ppm
Read/Write Access Write
Example IAQIndoor air quality
nvoEffectSetpt
nvoOutsideTemp
nvoOutsideRH
nviSpaceRH
nviCO2
30
Use this decision to specify the name of the analog CPP point that the LON system will read to indicate the CO2 level in ppm.
LON Variable Type SNVT_ppm
Read/Write Access Read
Example IAQIndoor air quality
Use this decision to specify the name of the analog CPP point that the LON system will write to in order to set an additional rooftop operating temperature.
LON Variable Type SNVT_temp_p
Read/Write Access Write
Example OATOutdoor Air Temperature
Use these 4 decisions to specify the analog CPP point names that the LON system will read to indicate additional rooftop operating temperatures.
LON Variable Type SNVT_temp_p
Read/Write Access Read
Example TMP_SCTASaturated Condensing Temp
Use this decision to specify the name of the analog CPP point that the LON system will write to in order to set an additional rooftop operating pressure.
Note: For use with points having units of "H2O (Pa).
LON Variable Type SNVT_press_p
Read/Write Access Write
Example SPStatic Pressure
nvoCO2
nviTEMP1
nvoTEMP1-4
nviPRESS1
31
Use these 2 decisions to specify the names of the analog CPP point that the LON system will read to indicate additional rooftop operating pres-sures.
Note: For use with points having units of "H2O (Pa).
LON Variable Type SNVT_press_p
Read/Write Access Read
Example SPStatic Pressure
The CIAT Translator's RTUMAP2 Table is used to map or associateCPP points with the variables in the LonWorks rooftop profile. This table should be configured if the CIAT Translator CONFIG Table's Device Type decision was set to 1 (Rooftop). A sample RTUMAP2Table is shown on the page which follows. An explanation of each decision, including LonWorks read/write access, LON Variable Type, along with an example CPP point name follows.
CPP point names can consist of up to 8 characters. The default for each decision is blank.
Use these 2 decisions to specify the names of the analog CPP points that the LON system will write to in order to set additional rooftop operating parameters in percentage.
LON Variable Type SNVT_lev_percent
Read/Write Access Write
Example ECONPOSEconomizer Position
Use these 3 decisions to specify the names of the analog CPP point that the LON system will read to indicate additional rooftop operating parameters in percentage.
LON Variable Type SNVT_lev_percent
Read/Write Access Read
Example CAPA_APercentage Operating Capacity
Allowable Entries andDefault Value
Rooftop MappingConfiguration(RTUMAP2)Table 2
nvoPRESS1 - 2
nvoPCT1-3
nviPCT1-2
32
Figure 3-5Rooftop Mapping 2Configuration (RTUMAP2)Table
33
Use these 2 decisions to specify the names of the analog CPP points that the LON system will read to indicate additional rooftop differential temperatures.
LON Variable Type SNVT_temp_diff
Read/Write Access Read
Example SH_ASuction Superheat
Use these 3 decisions to specify the names of the discrete CPP points that the LON system will write to in order to set additional discrete operating parameters.
LON Variable Type SNVT_switch
Read/Write Access Write
Example EMSTOPEmergency Stop
Use these 8 decisions to specify the names of the discrete CPP points that the LON system will read to indicate additional discrete operating parameters.
LON Variable Type SNVT_switch
Read/Write Access Read
Example FANS_1Fan 1 Relay
Use this decision to provide the name of the analog CPP point that the LON system will write to in order to set the CO2 threshold value.
LON Variable Type SNVT_ppm
Read/Write Access Write
Example IAQSIndoor Air Quality Setpoint
Use this decision to provide the name of the analog CPP point that the LON system will write to in order to set the occupied cooling setpoint.
LON Variable Type SNVT_temp_setpt
Read/Write Access Write
Example OCSPOccupied Cool Setpoint
nviDISCRETE1 - 3
nvoDISCRETE1 - 8
nciCO2Limit
nciSetpnts.occupied_cool
nvoTEMPDIFF1 - 2
34
nciSetpnts.occupied_heat
nciSetpnts.standby_heat
nciSetpnts.unocc_heat
nciSetpnts.unocc_cool
Use this decision to provide the name of the analog CPP point that the LON system will write to in order to set the cooling setpoint in standby mode.
Note: Most CPP rooftops do not use this mode.
LON Variable Type SNVT_temp_setpt
Read/Write Access Write
Use this decision to provide the name of the analog CPP point that the LON system will write to in order to set the unoccupied cooling setpoint.
LON Variable Type SNVT_temp_setpt
Read/Write Access Write
Example UCSPUnoccupied Cool Setpoint
Use this decision to provide the name of the analog CPP point that the LON system will write to in order to set the occupied heating setpoint.
LON Variable Type SNVT_temp_setpt
Read/Write Access Write
Example OHSPOccupied Heat Setpoint
Use this decision to provide the name of the analog CPP point that the LON system will write to in order to set the heating setpoint in standby mode.
Note: Most CPP rooftops do not use this mode.
LON Variable Type SNVT_temp_setpt
Read/Write Access Write
Use this decision to provide the name of the analog CPP point that the LON system will write to in order to set the unoccupied heating setpoint.
LON Variable Type SNVT_temp_setpt
Read/Write Access Write
Example UHSPUnoccupied Heat Setpoint
nciSetpnts.standby_cool
35
Use this decision to specify the name of the analog or multi-state CPP point that the LON system will write to in order to set additional analog or multi-state operating parameters.
LON Variable Type SNVT_count
Read/Write Access Write
Example OASPOA cfm Setpoint
Use these 2 decisions to specify the names of the analog or multi-state CPP points that the LON system will read in order to obtain additional analog or multi-state values.
LON Variable Type SNVT_count
Read/Write Access Read
Example OACFMOA Airflow
Use these 2 decisions to specify the names of the analog or multi-state CPP points that the LON system will read in order to obtain additional analog or multi-state values.
LON Variable Type SNVT_count_inc
Read/Write Access Read
Example OACFMOA Airflow
nviCOUNT1
nvoCOUNT1 - 2
nvoCOUNTinc1 - 2
36
The CIAT Translator's GNRCMAP1 Table is used to map or associate CPP points with the variables in the LonWorks generic controller profile. This table should be configured if the CIAT Translator CONFIG Table's Device Type decision was set to 3 (Generic). This table could be used, for example, to allow LON access to an air handler. A sample GNRCMAP1 Table is shown on the page which follows. An explanation of each decision, including LonWorks read/write access, LON Variable Type, along with an example CPP point name follows. The decision explanations and example point names below are taken from a CPP air handler. Keep in mind, however, that the generic controller profile can also be used with other types of CPP controllers.
CPP point names can consist of up to 8 characters. The default for each decision is blank.
Use this decision to specify the name of the discrete CPP point that the LON system can read in order to indicate the air handler's operating mode.
Note: Most CPP air handlers do not contain this point.
LON Variable Type SNVT_hvac_status
Read/Write Access Read
Use this decision to specify the name of the analog CPP point that the LON system can read in order to indicate the current primary heat capacity in percent full scale.
LON Variable Type SNVT_hvac_status
Read/Write Access Read
Example HCVHeating Coil Valve %
Use this decision to specify the name of the analog CPP point that the LON system can read in order to indicate the current secondary heat capacity in percent full scale.
LON Variable Type SNVT_hvac_status
Read/Write Access Read
Example HCVHeating Coil Valve %
Allowable Entries andDefault Value
Generic MappingConfiguration(GNRCMAP1)Table 1
nvoUnitStatus.mode
nvoUnitStatus.heat_out_p
nvoUnitStatus.heat_out_s
37
Figure 3-6Generic Mapping 1Configuration (GNRCMAP1)Table
38
Use this decision to specify the name of the analog CPP point that that the LON system can read in order to indicate the current cooling capacity in percent full scale.
LON Variable Type SNVT_hvac_status
Read/Write Access Read
Example CCVCooling Coil Valve
Use this decision to specify the name of the analog CPP point that the LON system can read in order to indicate the current economizer posi-tion in percent full scale.
LON Variable Type SNVT_hvac_status
Read/Write Access Read
Use this decision to specify the name of the analog CPP point that the LON system can read in order to indicate the current fan speed in percent full scale.
LON Variable Type SNVT_hvac_status
Read/Write Access Read
Example VFDVariable Frequency Drive Speed %
Use this decision to provide the name of the discrete CPP point that the LON system can read in order to indicate the alarm status of the air handler.
Note: Most CPP air handlers do not contain this point.
LON Variable Type SNVT_hvac_status
Read/Write Access Read
nvoUnitStatus.cool_out
nvoUnitStatus.econ_out
nvoUnitStatus.fan_out
nvoUnitStatus.in_alarm
39
Use this decision to specify the name of the CPP occupancy schedule that the LON system can write to in order to set occupancy times.
Note: The CPP unit must be configured to use a global occupancyschedule (Allowable entries: OCCPC65E to OCCPC99E). Refer to the CPP documentation for additional information on the setup of the global occupancy schedule.
LON Variable Type SNVT_tod_event
Read/Write Access Write
Example OCCPC66EOccupancy Equipment
Use these 3 decisions to specify the name of the analog CPP point that the LON system can write to in order to set an additional air handler operating temperature.
LON Variable Type SNVT_temp_p
Read/Write Access Write
Example OATOutdoor Air Temperature
Use these 8 decisions to specify the analog CPP point names that the LON system can read in order to indicate additional air handler operating temperatures.
LON Variable Type SNVT_temp_p
Read/Write Access Read
Example SATSupply Air Temperature
Use these 2 decisions to specify the name of the analog CPP point that the LON system can write to in order to set an additional air handler operating pressure.
Note: 1. Most CPP air handlers do not allow write access to thispoint.
2. PRESS1 is for use with points having units of "H20 (Pa).3. PRESS2 is for use with points having uints of psi (kPa).
LON Variable Type PRESS1: SNVT_press_pPRESS2: SNVT_press
Read/Write Access Write
nviOccSchedule
nviTEMP1 - 3
nvoTEMP1 - 8
nviPRESS1 - 2
40
Use these 6 decisions to specify the names of the analog CPP point that that the LON system can read in order to indicate additional air handler operating pressures.
Note: 1. PRESS1-2 are for use with points having units of "H20 (Pa).2. PRESS3-6 are for use with points having units of psi (kPa).
LON Variable Type PRESS1-2: SNVT_press_pPRESS3-6: SNVT_press
Read/Write Access Read
Example SPStatic Pressure
Use these 2 decisions to specify the names of the analog CPP points that the LON system can read in order to indicate additional air handler differential temperatures.
Note: Most CPP air handlers do no contain these points.
LON Variable Type SNVT_temp_diff
Read/Write Access Read
The CIAT Translator's GNRCMAP2 Table is used to map or associate CPP points with the variables in the LonWorks generic profile. This table, in addition to the GNRCMAP1 Table, should be configured if the CIAT Translator CONFIG Table's Device Type decision was set to 3 (Generic). A sample GNRCMAP2 Table is shown below. An explana-tion of each decision, including LonWorks read/write access, LON Variable Type, along with an example CPP point name follows. The decision explanations and example point names below are taken from a CPP air handler. Keep in mind, however, that the generic controller profile can also be used with other types of CPP controllers.
CPP point names can consist of up to 8 characters. The default for each decision is blank.
Use these 2 decisions to specify the names of the analog CPP points that the LON system will write to in order to set additional operating parameters in percentage.
LON Variable Type SNVT_lev_percent
Read/Write Access Write
Example MIXDMixed Air Damper
nvoTEMPDIFF1 - 2
Generic MappingConfiguration(GNRCMAP2)Table 2
nviPCT1 - 2
nvoPRESS1 - 6
41
Figure 3-7Generic Mapping 2Configuration (GNRCMAP2)Table
42
Use these 4 decisions to specify the names of the analog CPP points that the LON system can read in order to indicate additional air handler operating parameters in percentage.
LON Variable Type SNVT_lev_percent
Read/Write Access Read
Example RFVCReturn Fan Volume Control
Use these 3 decisions to specify the names of the discrete CPP points that the LON system can write to in order to set additional discrete operating parameters.
LON Variable Type SNVT_switch
Read/Write Access Write
Example FLTSFilter Status
Use these 8 decisions to specify the names of the discrete CPP points that the LON system can read in order to indicate additional discrete operating parameters.
LON Variable Type SNVT_switch
Read/Write Access Read
Example FANS_1Fan 1 Relay
Use this decision to provide the name of the analog CPP point that the LON system can write to in order to set the occupied cooling setpoint.
LON Variable Type SNVT_temp_setpt
Read/Write Access Write
Example OCSPOccupied Cool Setpoint
Use this decision to provide the name of the analog CPP point that the LON system can write to in order to set the cooling setpoint in standby mode.
Note: Most CPP air handlers do not use this mode.
LON Variable Type SNVT_temp_setpt
Read/Write Access Write
nvoDISCRETE1 - 8
nciSetpnts.occupied_cool
nciSetpnts.standby_cool
nviDISCRETE1 - 3
nvoPCT1 - 4
43
Use this decision to provide the name of the analog CPP point that the LON system can write to in order to set the unoccupied cooling setpoint.
LON Variable Type SNVT_temp_setpt
Read/Write Access Write
Example UCSPUnoccupied Cool Setpoint
Use this decision to provide the name of the analog CPP point that the LON system can write to in order to set the occupied heating setpoint.
LON Variable Type SNVT_temp_setpt
Read/Write Access Write
Example OHSPOccupied Heat Setpoint
Use this decision to provide the name of the analog CPP point that the LON system can write to in order to set the heating setpoint in standby mode.
Most CPP air handlers do not contain this point.
LON Variable Type SNVT_temp_setpt
Read/Write Access Write
Use this decision to specify the name of the analog CPP point that the LON system will write to in order to set an additional operating param-eter in PPM.
LON Variable Type SNVT_ppm
Read/Write Access Write
Example AQ1Air Quality 1 (ppm)
Use this decision to specify the name of the analog CPP point that the LON system will read in order to obtain an additional analog values in PPM.
LON Variable Type SNVT_ppm
Read/Write Access Read
Example AQ1Air Quality 1 (ppm)
nciSetpnts.standby_heat
nciSetpnts.occupied_heat
nviPPM1
nvoPPM1
nciSetpnts.unocc_cool
44
Use this decision to specify the name of the analog or multi-state CPP point that the LON system will write to in order to set additional analog or multi-state operating parameters.
LON Variable Type SNVT_count
Read/Write Access Write
Example OASPOA cfm Setpoint
Use these 2 decisions to specify the names of the analog or multi-state CPP points that the LON system will read in order to obtain additional analog or multi-state values.
LON Variable Type SNVT_count
Read/Write Access Read
Example OACFMOA Airflow
Use these 2 decisions to specify the names of the analog or multi-state CPP points that the LON system will read in order to obtain additional analog or multi-state values.
LON Variable Type SNVT_count_inc
Read/Write Access Read
Example OACFMOA Airflow
nvoCOUNT1 - 2
nvoCOUNTinc1 - 2
nviCOUNT1
Maintenance
45
The CIAT Translator contains the maintenance tables listed below.
CHLRMNT1 Chiller Maintenance Table 1CHLRMNT2 Chiller Maintenance Table 2COMMSTAT Communication Status Maintenance TableGNRCMNT1 Generic Maintenance Table 1GNRCMNT2 Generic Maintnenance Table 2MESSAGES Messages Maintenance TableRTUMNT1 Rooftop Maintenance Table 1RTUMNT2 Rooftop Mainten ance Table 2
The maintenance values displayed in these tables are read-only values that show the current value of the CPP points that have been mapped to the Lonworks variables as the points exist in the CPP system element. These values are updated every 30 seconds. Note that if a LonWorks read (nvo) and write (nvi) variable have been mapped to the same CPP point, they will display the same value in the maintenance table display.
Figure 4-1 on the page which follows illustrates the Chiller Maintenance(CHLRMNT1) Table. An explanation of each value in the table follows.Note that the valid display ranges are dependent on the point.
Indicates the commanded state of the chiller (on or off).
Indicates the commanded value for the leaving chilled water temperaturesetpoint when the chiller is operating in cooling mode.
Indicates the chiller's current status (on/off ).
Note: Most CPP chillers do not contain this point.
Indicates the current value of the chiller's cooling or heating setpoint. Thesetpoint to be displayed (cooling or heating) depends on the chiller'scurrent operating mode.
Indicates the commanded value for the capacity limit of the chiller.
nviChillerEnable
ChillerMaintenance(CHLRMNT1)Table 1
nviCoolSetpt
nvoOnOff
nvoActiveSetpt
Maintenance
nviCapacityLim
46
Figure 4-1Chiller Maintenance(CHLRMNT1)Table 1
47
Indicates the commanded heating setpoint.
Indicates the current running capacity of the chiller.
Indicates the chiller's current capacity limit setpoint.
Indicates the leaving chilled water temperature.
Indicates the entering chilled water temperature.
Indicates the entering condenser water temperature.
Indicates the leaving condenser water temperature.
Indicates the main running mode of the chiller.
Note: Most CPP chillers do not contain this point.
Indicates the main operating status of the chiller.
Note: Most CPP chillers do not contain this point.
Indicates the alarm status of the chiller.
Note: Most CPP chillers do not contain this point.
Indicates the start or stop status of the chiller.
Indicates the chiller's local or network control status.
Note: Most CPP chillers do not contain this point.
Indicates if the chiller cannot reach setpoint.
Note: Most CPP chillers do not contain this point.
Indicates the presence of chilled water flow.
Indicates the presence of condenser water flow.
Indicates the next commanded occupancy state, as determined by the CPP global occupancy equipment table.
nviHeatSetpt
nvoActualCapacity
nvoCapacityLim
nvoLvgCNDWTemp
nvoEntCNDWTemp
nvoEntCHWTemp
nvoLvgCHWTemp
nvoChillerStat.run_mode
nvoChillerStat.op_mode
nvoChillerStat.in_alarm
nvoChillerStat.run_enabl
nvoChillerStat.Local
nvoChillerStat.Limited
nvoChillerStat.cndw_flow
nvoChillerStat.chw_flow
nviOccSchedule
48
Figure 4-2 shown below illustrates the Chiller Maintenance(CHLRMNT2) Table. An explanation of each value in the table follows.Note that the valid display ranges are dependent on the point.
Chiller Maintenance(CHLMNT2) Table 2
Figure 4-2Chiller Maintenance(CHLRMNT2)Table 2
49
nviTEMP1
nvoPRESS1 - 4
nvoTEMP1 - 6
nviPRESS1
Indicates an additional chiller commanded operating temperature.
Indicates additional chiller operating temperatures.
Indicates an additional chiller commanded operating pressure.
Indicates additional chiller operating pressures.
Indicates additional chiller operating parameters in percentage.
Indicates additional chiller differential temperatures.
Indicates additional commanded discrete operating parameters.
Indicates additional discrete operating parameters.
Indicates chiller commanded analog or multi-state parameter.
Note: This point will always display in customary US units.
Indicate chiller analog or multi-state values.
Note: These points will always display in customary US units.
Indicate chiller analog or multi-state values.
Note: These points will always display in customary US units.
nvoPCT1 - 2
nvoTEMPDIFF1 - 2
nviDISCRETE1 - 2
nvoDISCRETE1 - 6
nviCOUNT1
nvoCOUNT1 - 2
nvoCOUNTinc1 - 2
50
Figure 4-3 on the page which follows illustrates the Rooftop Maintenance (RTUMNT1) Table. The maintenance values displayed in this table are read-only values that show the current value of the CPP points that have been mapped to the Lonworks variables as the points exist in the CPP system element. These values are updated every 30 seconds. An expla-nation of each value in the table follows. Note that the valid display ranges are dependent on the point.
Indicates the commanded space temperature.
Indicates the commanded temperature setpoint.
Indicates the space temperature.
Indicates the rooftop's operating mode.
Note: Most CPP rooftops do not contain this point.
Indicates the current primary heat capacity in percent full scale.
Indicates the current secondary heat capacity in percent full scale.
Indicates the current cooling capacity in percent full scale.
Indicates the current economizer position in percent full scale.
Indicates the current fan speed in percent full scale.Note: Most CPP rooftops do not contain this point.
Indicates the alarm status of the chiller.
Notes: Most CPP rooftops do not contain this point.
Indicates the next commanded occupancy state, as determined by the CPP global occupancy equipment table.
Indicates the commanded temperature setpoint offset.
Notes: Most CPP rooftops do not contain this point.Metric points will always assume ^T, even if the point ismapped to a temperature.
RooftopMaintenance(RTUMNT1)Table 1
nviSpaceTemp
nvoUnitStatus.mode
nvoSpaceTemp
nviSetPoint
nvoUnitStatus.heat_out_s
nvoUnitStatus.cool_out
nvoUnitStatus.econ_out
nvoUnitStatus.heat_out_p
nvoUnitStatus.fan_out
nvoUnitStatus.in_alarm
nviOccSchedule
nviSetptOffset
51
Figure 4-3Rooftop Maintenance(RTUMNT1)Table 1
52
Indicates the commanded outside air temperature.
Indicates the commanded outside air relative humidity.
Indicates the setpoint temperature.
Indicates the outside air temperature.
Indicates the outside air relative humidity.
Indicates the commanded space relative humidity.
Indicates the commanded CO2 level in ppm.
Indicates the commanded CO2 level in ppm.
Indicates an additional rooftop commanded operating temperature.
Indicate additional rooftop operating temperatures.
Indicates an additional rooftop commanded operating pressure.
Indicate additional rooftop operating pressures.
Figure 4-4 illustrates the Rooftop Maintenance (RTUMNT2) Table. The maintenance values displayed in this table are read-only values that show the current value of the CPP points that have been mapped to the Lonworks variables as the points exist in the CPP system element. These values are updated every 30 seconds. An explanation of each value in the table follows. Note that the valid display ranges are dependent on the point.
Indicate rooftop commanded parameters in percentage.
Indicate additional rooftop operating parameters in percentage.
Indicate additional rooftop differential temperatures.
Indicate additional discrete commanded operating parameters.
nvoEffectSetpt
nvoOutsideTemp
nvoOutsideRH
nviSpaceRH
nviCO2
nvoCO2
nviTEMP1
nvoTEMP1-4
RooftopMaintenance(RTUMNT2)Table 2
nviPRESS1
nvoPRESS1 - 2
nvoPCT1-3
nvoTEMPDIFF1 - 2
nviDISCRETE1 - 3
nviPCT1-2
nviOutsideTemp
nviOutsideRH
53
Indicate additional discrete commanded operating parameters.
Indicates the commanded CO2 threshold value.
Indicates the commanded occupied cooling setpoint.
Indicates the commanded cooling setpoint in standby mode.
Note: Most CPP rooftops do not use this mode.
Indicates the commanded unoccupied cooling setpoint.
Indicates the commanded occupied heating setpoint.
Indicates the commanded heating setpoint in standby mode.
Note: Most CPP rooftops do not use this mode.
Indicates the commanded unoccupied heating setpoint.
Indicates a rooftop commanded analog or multi-state parameter.
Note: This point will always display in customary US units.
Indicate rooftop analog or multi-state values.
Note: These points will always display in customary US units.
Indicates rooftop analog or multi-state values.
Note: These points will always display in customary US units.
nciSetpnts.occupied_cool
nciSetpnts.standby_cool
nciSetpnts.unocc_cool
nciSetpnts.occupied_heat
nciSetpnts.standby_heat
nciSetpnts.unocc_heat
nviCOUNT1
nvoCOUNT1 - 2
nvoCOUNTinc1 - 2
nvoDISCRETE1 - 8
nciCO2Limit
54
Figure 4-4Rooftop Maintenance(RTUMNT 2)Table 2
55
Figure 4-5 on the page which follows illustrates the Generic Maintenance (GNRCMNT1) Table. The maintenance values displayed in this table are read-only values that show the current value of the CPP points that have been mapped to the Lonworks variables as the points exist in the CPP system element. These values are updated every 30 seconds. An expla-nation of each value in the table follows. Note that the valid display ranges are dependent on the point.
Indicates the controller's operating mode.
Note: Most CPP controllers do not contain this point.
Indicates the current primary heat capacity in percent full scale.
Indicates the current secondary heat capacity in percent full scale.
Indicates the current cooling capacity in percent full scale.
Indicates the current economizer position in percent full scale.
Indicates the current fan speed in percent full scale.
Indicates the alarm status of the controller.
Note: Most CPP air handlers do not contain this point.
Indicates the next commanded occupancy state, as determined by the CPP global occupancy equipment table.
Indicates an additional controller commanded operating temperature.
Indicate additional controller operating temperatures.
Indicate additional controller commanded operating pressures.
Note: Most CPP controllers do not allow write access to this point.
Use these 6 decisions to specify the names of the analog CPP point that will indicate additional controller operating pressures.
Indicate additional controller differential temperatures.
Note: Most CPP air handlers do not contain this point.
GenericMaintenance(GNRCMNT1)Table 1
nvoUnitStatus.mode
nvoUnitStatus.heat_out_p
nvoUnitStatus.heat_out_s
nvoUnitStatus.cool_out
nvoUnitStatus.econ_out
nvoUnitStatus.fan_out
nvoUnitStatus.in_alarm
nviOccSchedule
nviTEMP1 - 3
nvoTEMP1 - 8
nviPRESS1 - 2
nvoTEMPDIFF1 - 2
nvoPRESS1 - 6
56
Figure 4-3Generic Maintenance(GNRCMNT1)Table 1
57
Figure 4-6 on the page which follows illustrates the Generic Maintenance (GNRCMNT2) Table. The maintenance values displayed in this table are read-only values that show the current value of the CPP points that have been mapped to the Lonworks variables as the points exist in the CPP system element. These values are updated every 30 seconds. An expla-nation of each value in the table follows. Note that the valid display ranges are dependent on the point.
Indicate additional controller commanded parameters in percentage.
Indicate additional controller operating parameters in percentage.
Indicate additional commanded discrete operating parameters.
Indicate additional discrete operating parameters.
Indicates the commanded occupied cooling setpoint.
Indicates the commanded cooling setpoint in standby mode.
Note: Most CPP controllers do not use this mode.
Indicates the commanded unoccupied cooling setpoint.
Indicates the commanded occupied heating setpoint.
Indicates the commanded heating setpoint in standby mode.
Note: Most CPP controllers do not contain this point.
Indicates a commanded parameter in PPM.
Indicates an analog value in PPM.
Indicates a commanded analog or multi-state parameter.
Note: This point will always display in customary US units.
Indicate analog or multi-state values.
Note: These points will always display in customary US units.
Indicate analog or multi-state values.
Note: These points will always display in customary US units.
Generic MappingMaintenance(GNRCMNT2)Table 2
nvoPCT1 - 4
nviDISCRETE1 - 3
nvoDISCRETE1 - 8
nciSetpnts.occupied_cool
nciSetpnts.standby_cool
nciSetpnts.unocc_cool
nciSetpnts.occupied_heat
nciSetpnts.standby_heat
nviPCT1 - 2
nviPPM
nvoPPM
nviCOUNT1
nvoCOUNT1 - 2
nvoCOUNTinc1 - 2
58
Figure 4-6Generic Mapping 2Maintenance (GNRCMNT2)Table
59
Figure 4-7 below illustrates the Communication Status Maintenance(COMMSTAT) Table. The maintenance values displayed in this table are read-only values that show diagnostic data about LonWorks-to-CPP system element communication. These values are updated every 30 seconds. An explanation of each value in the table follows.
Note: This information is primarily intended to be used by the Lonsystems integrator for troubleshooting.
CommunicationStatusMaintenance(COMMSTAT)TableFigure 4-7Communications StatusMaintenance (COMMSTAT)Table
60
Num SuccessfulMessages
Num Failed Messages
Communication History1 - 4
CommunicationType
Successful?
Indicates the number of successful read, write, and other communication messages sent from LonWorks to the CPP system element. This value is a running total of the number of successful messages detected since the last communication reset. It is not reset on cycling CIAT TRANS-LATOR power. It can be reset, however, using the CONFIG Table's Reset Comm. Counters decision.
Valid Display 0 - 65,000
Indicates the number of unsuccessful read, write, and other communica-tion messages sent from LonWorks to the CPP system element. This value is a running total of the number of unsuccessful messages detected since the last communication reset. It is not reset on cycling power to the CIAT Translator. It can be reset, however, using the CONFIG Table's Reset Comm. Counters decision.
Valid Display 0 - 65,000
These 4 decisions display the below-listed data about the four most recent LonWorks-to-CPP communication messages.
Indicates the type of communication message.
Valid Display 1 = Read Network Variable2 = Write Network Variable3 = Other
Indicates whether or not this communication was successful.
Valid Display Yes/No
61
Figure 4-8 below illustrates the Messages Maintenance (MESSAGES) Table. The maintenance values displayed in this table are read-only values that show diagnostic data about LonWorks-to-CPP system element communication messages. These values are updated every 30 seconds. An explanation of each value in the table follows.
Note: This information is primarily intended to be used by the Lonsystems integrator for troubleshooting.
MessagesMaintenance(MESSAGES)Table
Figure 4-8Messages Maintenance(MESSAGES)Table
62
LON Message 1 - 10 These 10 decisions display diagnostic information about the 10 most recent LonWorks-to-CPP communication messages.
Valid Display Self configurationRead all NVsPropagate NV#Set NV#Read NV#
where: NV = Network Variable# = Number of the NetworkVariable
The Propagate and Set commands both refer to writes to CPP points. Propagate indicates that the value has not changed, but the CIAT Translator's 30 second refresh has caused Lonworks to write to the CPP point again. Set indicates that Lonworks has written a new value to the CPP point.
Appendix
63
This section contains examples of actual configurations for a chiller, rooftop, and generic template, along with a list of LON SNVTs and corresponding CPP point names and descriptions.
Appendix
64
Figure A-2Sample Configuration forCHLRMAP1 Table
Job
Site
:LE
I Add
ress
:0,
211
Atta
ched
Dev
ice:
19XR
IIIA
ttach
ed D
evic
e Add
ress
:0,
1LO
N P
rofil
e:C
hille
r Pro
file
CHLR
MAP
1SN
VT T
ype
R
ead
CPP
Poi
ntC
PP P
oint
or
Writ
e?
D
escr
iptio
nN
ame
nviC
hille
rEna
ble
......
......
......
....S
NVT
_sw
itch
POIN
T01.
.....
W...
......
......
......
...C
hille
r Sta
rt/St
op...
......
......
......
......
......
CH
IL_S
_Snv
iCoo
lSet
pt...
......
......
......
......
SNVT
_tem
p_p
POIN
T02.
.....
W...
......
......
......
...Le
avin
g C
hille
d W
ater
Con
trol P
oint
.....
LCW
_STP
Tnv
oOnO
ff...
......
......
......
......
.....
SNVT
_sw
itch
POIN
T03.
.....
R...
......
......
......
......
......
......
......
......
......
......
......
......
......
.....
nvoA
ctive
Setp
t....
......
......
......
.SN
VT_t
emp_
pPO
INT0
4....
..R
......
......
......
......
.Lea
ving
Chi
lled
Wat
er C
ontro
l Poi
nt...
..LC
W_S
TPT
nviC
apac
ityLi
m...
......
......
......
..SN
VT_l
ev_p
erce
ntPO
INT0
5....
..W
......
......
......
......
Activ
e D
eman
d Li
mit
......
......
......
......
...D
EM_L
IMnv
iHea
tSet
pt...
......
......
......
......
SNVT
_tem
p_p
POIN
T06.
.....
W...
......
......
......
......
......
......
......
......
......
......
......
......
......
....
nvoA
ctua
lCap
acity
......
......
.....
SNVT
_lev
_per
cent
POIN
T07.
.....
R...
......
......
......
....M
otor
Per
cent
Kilo
wat
ts...
......
......
......
.KW
_Pnv
oCap
acity
Lim
......
......
......
....S
NVT
_lev
_per
cent
POIN
T08.
.....
R...
......
......
......
....A
ctiv
e D
eman
d Li
mit
......
......
......
......
...D
EM_L
IMnv
oLvg
CHW
Tem
p...
......
......
....S
NVT
_tem
p_p
POIN
T09.
.....
R...
......
......
......
....L
eavi
ng C
hille
d Wat
er...
......
......
......
.....
LCW
nvoE
ntC
HW
Tem
p...
......
......
....S
NVT
_tem
p_p
POIN
T10.
.....
R...
......
......
......
....E
nter
ing
Chi
lled
Wat
er...
......
......
......
....E
CW
nvoE
ntC
ND
WTe
mp
......
......
....S
NVT
_tem
p_p
POIN
T11.
.....
R...
......
......
......
....E
nter
ing
Con
dens
er W
ater
......
......
......
ECD
Wnv
oLvg
CNDW
Tem
p...
......
......
..SN
VT_t
emp_
pPO
INT1
2....
..R
......
......
......
......
.Lea
ving
Con
dens
er W
ater
......
......
......
..LC
DW
nvoC
hille
rSta
t.run
_mod
e...
......
SNVT
_chl
r_st
atus
POIN
T13.
.....
R...
......
......
......
......
......
......
......
......
......
......
......
......
......
.....
nvoC
hille
rSta
t.op_
mod
e...
......
.SN
VT_c
hlr_
stat
usPO
INT1
4....
..R
......
......
......
......
......
......
......
......
......
......
......
......
......
......
..nv
oChi
llerS
tat.i
n_al
arm
......
.....
SNVT
_chl
r_st
atus
POIN
T15.
.....
R...
......
......
......
......
......
......
......
......
......
......
......
......
......
.....
nvoC
hille
rSta
t.run
_ena
bl...
......
SNVT
_chl
r_st
atus
POIN
T16.
.....
R...
......
......
......
......
......
......
......
......
......
......
......
......
......
.....
nvoC
hille
rSta
t.Loc
al...
......
......
.SN
VT_c
hlr_
stat
usPO
INT1
7....
..R
......
......
......
......
......
......
......
......
......
......
......
......
......
......
..nv
oChi
llerS
tat.L
imite
d...
......
....S
NVT
_chl
r_st
atus
POIN
T18.
.....
R...
......
......
......
......
......
......
......
......
......
......
......
......
......
.....
nvoC
hille
rSta
t.chw
_flo
w...
......
.SN
VT_c
hlr_
stat
usPO
INT1
9....
..R
......
......
......
......
......
......
......
......
......
......
......
......
......
......
..nv
oChi
llerS
tat.c
ndw
_flo
w...
.....
SNVT
_chl
r_st
atus
POIN
T20.
.....
R...
......
......
......
......
......
......
......
......
......
......
......
......
......
.....
nviO
ccSc
hedu
le...
......
......
......
SNVT
_occ
upan
cyPO
INT2
1....
..W
......
......
......
......
......
......
......
......
......
......
......
......
......
......
.
65
Figure A-2Sample Configuration forCHLRMAP2 Table
CHLR
MAP
2SN
VT T
ype
Rea
d or
Writ
e?
CPP
Poi
nt D
escr
iptio
nC
PP P
oint
Nam
env
iTEM
P1...
......
......
......
......
....S
NVT
_tem
p_p
POIN
T22
......
W...
......
......
......
......
......
......
......
......
......
......
......
......
......
....
nvoT
EMP1
......
......
......
......
......
SNVT
_tem
p_p
POIN
T23
......
R...
......
......
......
......
......
......
......
......
......
......
......
......
......
.....
nvoT
EMP2
......
......
......
......
......
SNVT
_tem
p_p
POIN
T24
......
R...
......
......
......
......
......
......
......
......
......
......
......
......
......
.....
nvoT
EMP3
......
......
......
......
......
SNVT
_tem
p_p
POIN
T25
......
R...
......
......
......
......
......
......
......
......
......
......
......
......
......
.....
nvoT
EMP4
......
......
......
......
......
SNVT
_tem
p_p
POIN
T26
......
R...
......
......
......
......
......
......
......
......
......
......
......
......
......
.....
nvoT
EMP5
......
......
......
......
......
SNVT
_tem
p_p
POIN
T27
......
R...
......
......
......
......
......
......
......
......
......
......
......
......
......
.....
nvoT
EMP6
......
......
......
......
......
SNVT
_tem
p_p
POIN
T28
......
R...
......
......
......
......
......
......
......
......
......
......
......
......
......
.....
nviP
RES
S1...
......
......
......
......
.SN
VT_p
ress
POIN
T29
......
W...
......
......
......
......
......
......
......
......
......
......
......
......
......
....
nvoP
RES
S1...
......
......
......
......
SNVT
_pre
ssPO
INT3
0...
...R
......
......
......
......
.Eva
pora
tor R
efrig
Pre
ssur
e...
......
......
...ER
Pnv
oPR
ESS2
......
......
......
......
...SN
VT_p
ress
POIN
T31
......
R...
......
......
......
....C
onde
nser
Ref
rig P
ress
ure
......
......
......
CRP
nvoP
RES
S3...
......
......
......
......
SNVT
_pre
ssPO
INT3
2...
...R
......
......
......
......
.Oil
Pum
p D
elta
P...
......
......
......
......
.....
OIL
PDnv
oPR
ESS4
......
......
......
......
...SN
VT_p
ress
POIN
T33
......
R...
......
......
......
......
......
......
......
......
......
......
......
......
......
.....
nvoP
CT1
......
......
......
......
......
..SN
VT_l
ev_p
erce
ntPO
INT3
4...
...R
......
......
......
......
.Ave
rage
Line
Cur
rent
......
......
......
......
...AM
PS_%
nvoP
CT2
......
......
......
......
......
..SN
VT_l
ev_p
erce
ntPO
INT3
5...
...R
......
......
......
......
......
......
......
......
......
......
......
......
......
......
..nv
oTEM
PDIF
F1...
......
......
......
.SN
VT_t
emp_
diff_
pPO
INT3
6...
...R
......
......
......
......
......
......
......
......
......
......
......
......
......
......
..nv
oTEM
PDIF
F2...
......
......
......
.SN
VT_t
emp_
diff_
pPO
INT3
7...
...R
......
......
......
......
......
......
......
......
......
......
......
......
......
......
..nv
iDIS
CR
ETE1
......
......
......
.....S
NVT
_sw
itch
POIN
T38
......
W...
......
......
......
......
......
......
......
......
......
......
......
......
......
....
nviD
ISC
RET
E2...
......
......
......
..SN
VT_s
witc
hPO
INT3
9...
...W
......
......
......
......
......
......
......
......
......
......
......
......
......
......
.nv
oDIS
CRET
E1...
......
......
......
.SN
VT_s
witc
hPO
INT4
0...
...R
......
......
......
......
.Chi
ller S
tart/
Stop
......
......
......
......
......
...C
HIL
_S_S
nvoD
ISCR
ETE2
......
......
......
....S
NVT
_sw
itch
POIN
T41
......
R...
......
......
......
....C
hille
d W
ater
Flo
w S
tatu
s...
......
......
....C
HW
_FLO
Wnv
oDIS
CRET
E3...
......
......
......
.SN
VT_s
witc
hPO
INT4
2...
...R
......
......
......
......
.Con
dens
er W
ater
Flo
w S
tatu
s....
......
...C
DW
_FLO
Wnv
oDIS
CRET
E4...
......
......
......
.SN
VT_s
witc
hPO
INT4
3...
...R
......
......
......
......
......
......
......
......
......
......
......
......
......
......
..nv
oDIS
CRET
E5...
......
......
......
.SN
VT_s
witc
hPO
INT4
4...
...R
......
......
......
......
......
......
......
......
......
......
......
......
......
......
..nv
oDIS
CRET
E6...
......
......
......
.SN
VT_s
witc
hPO
INT4
5...
...R
......
......
......
......
......
......
......
......
......
......
......
......
......
......
..nv
iCO
UNT1
......
......
......
......
....S
NVT
_cou
ntPO
INT4
6...
...W
......
......
......
......
......
......
......
......
......
......
......
......
......
......
.nv
oCO
UNT1
......
......
......
......
...SN
VT_c
ount
POIN
T47
......
R...
......
......
......
....C
ontro
l Mod
e...
......
......
......
......
......
......
MO
DE
nvoC
OUN
T2...
......
......
......
......
SNVT
_cou
ntPO
INT4
8...
...R
......
......
......
......
.Run
Sta
tus
......
......
......
......
......
......
......
STAT
US
nvoC
OUN
Tinc
1...
......
......
......
..SN
VT_c
ount
_inc
POIN
T49
......
R...
......
......
......
....S
yste
m A
larm
/Ale
rt...
......
......
......
......
..SY
S_AL
Mnv
oCO
UNTi
nc2
......
......
......
.....S
NVT
_cou
nt_i
ncPO
INT5
0...
...R
......
......
......
......
......
......
......
......
......
......
......
......
......
......
..
66
Figure A-3 CHLRMAP1 Table SNVTs and CPP Points
LEI A
ddre
ss:
Atta
ched
Dev
ice:
Atta
ched
Dev
ice A
ddre
ss:
LON
Pro
file:
(NA)
Mea
ns n
ot g
ener
ally
app
licab
le to
CP
P
CHLR
MAP
1...
......
......
......
......
SNVT
Typ
eR
ead
or W
rite?
.. C
PP P
oint
Des
crip
tion
nviC
hille
rEna
ble
......
......
......
....S
NVT
_sw
itch
POIN
T01
W...
......
......
......
...C
hille
r Sta
rt/St
op (1
/0)
nviC
oolS
etpt
......
......
......
......
...SN
VT_t
emp_
pPO
INT0
2W
......
......
......
......
Chi
lled
Wat
er C
ontro
l Tem
p (d
egF)
nvoO
nOff
......
......
......
......
......
..SN
VT_s
witc
hPO
INT0
3R
......
......
......
......
.Chi
ller O
n/O
ff (1
/0) (
NA)
nvoA
ctive
Setp
t....
......
......
......
.SN
VT_t
emp_
pPO
INT0
4R
......
......
......
......
.Chi
lled
Wat
er C
ontro
l Tem
p (d
egF)
nviC
apac
ityLi
m...
......
......
......
..SN
VT_l
ev_p
erce
ntPO
INT0
5W
......
......
......
......
Activ
e D
eman
d Li
mit
(%)
nviH
eatS
etpt
......
......
......
......
...SN
VT_t
emp_
pPO
INT0
6W
......
......
......
......
Hot
Wat
er C
ontro
l Tem
p (d
egF)
nvoA
ctua
lCap
acity
......
......
.....
SNVT
_lev
_per
cent
POIN
T07
R...
......
......
......
....P
ecen
t Cap
acity
(%)
nvoC
apac
ityLi
m...
......
......
......
.SN
VT_l
ev_p
erce
ntPO
INT0
8R
......
......
......
......
.Act
ive
Dem
and
Lim
it (%
)nv
oLvg
CHW
Tem
p...
......
......
....S
NVT
_tem
p_p
POIN
T09
R...
......
......
......
....L
eavi
ng C
hille
d W
ater
Tem
p (d
egF)
nvoE
ntC
HW
Tem
p...
......
......
....S
NVT
_tem
p_p
POIN
T10
R...
......
......
......
....E
nter
ing
Chi
lled
Wat
er T
emp
(deg
F)nv
oEnt
CN
DW
Tem
p...
......
......
.SN
VT_t
emp_
pPO
INT1
1R
......
......
......
......
.Lea
ving
Con
d W
ater
Tem
p (d
egF)
nvoL
vgCN
DWTe
mp
......
......
.....
SNVT
_tem
p_p
POIN
T12
R...
......
......
......
....E
nter
ing
Con
d W
ater
Tem
p (d
egF)
nvoC
hille
rSta
t.run
_mod
e...
......
SNVT
_chl
r_st
atus
POIN
T13
R...
......
......
......
....(
NA)
nvoC
hille
rSta
t.op_
mod
e...
......
.SN
VT_c
hlr_
stat
usPO
INT1
4R
......
......
......
......
.(N
A)nv
oChi
llerS
tat.i
n_al
arm
......
.....
SNVT
_chl
r_st
atus
POIN
T15
R...
......
......
......
....C
hille
r In
Alar
m (1
/0) (
NA)
nvoC
hille
rSta
t.run
_ena
bl...
......
SNVT
_chl
r_st
atus
POIN
T16
R...
......
......
......
....C
hille
r Run
Ena
bled
(1/0
) (N
A)nv
oChi
llerS
tat.L
ocal
......
......
....S
NVT
_chl
r_st
atus
POIN
T17
R...
......
......
......
....C
hille
r Loc
al E
nabl
ed (1
/0) (
NA)
nvoC
hille
rSta
t.Lim
ited
......
......
.SN
VT_c
hlr_
stat
usPO
INT1
8R
......
......
......
......
.Chi
ller D
eman
d Li
mite
d (1
/0) (
NA)
nvoC
hille
rSta
t.chw
_flo
w...
......
.SN
VT_c
hlr_
stat
usPO
INT1
9R
......
......
......
......
.Chi
lled
Wat
er F
low
Det
ecte
d (1
/0)
nvoC
hille
rSta
t.cnd
w_f
low
......
..SN
VT_c
hlr_
stat
usPO
INT2
0R
......
......
......
......
.Con
d W
ater
Flo
w D
etec
ted
(1/0
)nv
iOcc
Sche
dule
......
......
......
...SN
VT_o
ccup
ancy
POIN
T21
W ..
......
......
......
.... G
loba
l CP
P O
ccup
ancy
(>64
)
67
Figure A-4 CHLRMAP2 Table SNVTs and CPP Points
CHLR
MAP
2SN
VT T
ype
Rea
d or
Writ
e?
CPP
Poi
nt D
escr
iptio
nnv
iTEM
P1...
......
......
......
......
....S
NVT
_tem
p_p
POIN
T22
......
W...
......
......
......
....T
empe
ratu
re (d
egF)
nvoT
EMP1
......
......
......
......
......
SNVT
_tem
p_p
POIN
T23
......
R...
......
......
......
.....
Tem
pera
ture
(deg
F)nv
oTEM
P2...
......
......
......
......
...SN
VT_t
emp_
pPO
INT2
4...
...R
......
......
......
......
..Te
mpe
ratu
re (d
egF)
nvoT
EMP3
......
......
......
......
......
SNVT
_tem
p_p
POIN
T25
......
R...
......
......
......
.....
Tem
pera
ture
(deg
F)nv
oTEM
P4...
......
......
......
......
...SN
VT_t
emp_
pPO
INT2
6...
...R
......
......
......
......
..Te
mpe
ratu
re (d
egF)
nvoT
EMP5
......
......
......
......
......
SNVT
_tem
p_p
POIN
T27
......
R...
......
......
......
.....
Tem
pera
ture
(deg
F)nv
oTEM
P6...
......
......
......
......
...SN
VT_t
emp_
pPO
INT2
8...
...R
......
......
......
......
..Te
mpe
ratu
re (d
egF)
nviP
RES
S1...
......
......
......
......
.SN
VT_p
ress
POIN
T29
......
W...
......
......
......
....P
ress
ure
(PSI
)nv
oPR
ESS1
......
......
......
......
...SN
VT_p
ress
POIN
T30
......
R...
......
......
......
.....
Pres
sure
(PSI
)nv
oPR
ESS2
......
......
......
......
...SN
VT_p
ress
POIN
T31
......
R...
......
......
......
.....
Pres
sure
(PSI
)nv
oPR
ESS3
......
......
......
......
...SN
VT_p
ress
POIN
T32
......
R...
......
......
......
.....
Pres
sure
(PSI
)nv
oPR
ESS4
......
......
......
......
...SN
VT_p
ress
POIN
T33
......
R...
......
......
......
.....
Pres
sure
(PSI
)nv
oPCT
1...
......
......
......
......
.....S
NVT
_lev
_per
cent
POIN
T34
......
R...
......
......
......
.....
Perc
ent (
%)
nvoP
CT2
......
......
......
......
......
..SN
VT_l
ev_p
erce
ntPO
INT3
5...
...R
......
......
......
......
..Pe
rcen
t (%
)nv
oTEM
PDIF
F1...
......
......
......
.SN
VT_t
emp_
diff_
pPO
INT3
6...
...R
......
......
......
......
..D
elta
Tem
pera
ture
(^F)
nvoT
EMPD
IFF2
......
......
......
....S
NVT
_tem
p_di
ff_p
POIN
T37
......
R...
......
......
......
.....
Del
ta T
empe
ratu
re (^
F)nv
iDIS
CR
ETE1
......
......
......
.....S
NVT
_sw
itch
POIN
T38
......
W...
......
......
......
....D
iscr
ete
(1/0
)nv
iDIS
CR
ETE2
......
......
......
.....S
NVT
_sw
itch
POIN
T39
......
W...
......
......
......
....D
iscr
ete
(1/0
)nv
oDIS
CRET
E1...
......
......
......
.SN
VT_s
witc
hPO
INT4
0...
...R
......
......
......
......
..D
iscr
ete
(1/0
)nv
oDIS
CRET
E2...
......
......
......
.SN
VT_s
witc
hPO
INT4
1...
...R
......
......
......
......
..D
iscr
ete
(1/0
)nv
oDIS
CRET
E3...
......
......
......
.SN
VT_s
witc
hPO
INT4
2...
...R
......
......
......
......
..D
iscr
ete
(1/0
)nv
oDIS
CRET
E4...
......
......
......
.SN
VT_s
witc
hPO
INT4
3...
...R
......
......
......
......
..D
iscr
ete
(1/0
)nv
oDIS
CRET
E5...
......
......
......
.SN
VT_s
witc
hPO
INT4
4...
...R
......
......
......
......
..D
iscr
ete
(1/0
)nv
oDIS
CRET
E6...
......
......
......
.SN
VT_s
witc
hPO
INT4
5...
...R
......
......
......
......
..D
iscr
ete
(1/0
)nv
iCO
UNT1
......
......
......
......
....S
NVT
_cou
ntPO
INT4
6...
...W
......
......
......
......
.Gen
eric
ana
log
or d
iscr
ete
(0-6
5535
)nv
oCO
UNT1
......
......
......
......
...SN
VT_c
ount
POIN
T47
......
R...
......
......
......
.....
Gen
eric
ana
log
or d
iscr
ete
(0-6
5535
)nv
oCO
UNT2
......
......
......
......
...SN
VT_c
ount
POIN
T48
......
R...
......
......
......
.....
Gen
eric
ana
log
or d
iscr
ete
(0-6
5535
)nv
oCO
UNTi
nc1
......
......
......
.....S
NVT
_cou
nt_i
ncPO
INT4
9...
...R
......
......
......
......
..G
ener
ic a
nalo
g or
dis
cret
e (-3
2767
- 327
67)
nvoC
OUN
Tinc
2...
......
......
......
..SN
VT_c
ount
_inc
POIN
T50
......
R...
......
......
......
.....
Gen
eric
ana
log
or d
iscr
ete
(-327
67 - 3
2767
)
68
Figure A-5Sample Configuration forRTUMAP1 Table
Job
Site
:LE
I Add
ress
:0,
204
Atta
ched
Dev
ice:
48H
G C
entu
rian
Atta
ched
Dev
ice A
ddre
ss:
0, 1
LON
Pro
file:
Roo
ftop
RTUM
AP1
SNVT
Typ
eR
ead
or W
rite?
C
PP P
oint
Des
crip
tion
CPP
Poi
nt N
ame
nviS
pace
Tem
p...
......
......
......
...SN
VT_t
emp_
pPO
INT0
1...
..W
......
......
......
......
......
......
......
......
......
......
......
......
......
......
.nv
iSet
Poin
t....
......
......
......
......
.SN
VT_t
emp_
pPO
INT0
2...
..W
......
......
......
......
......
......
......
......
......
......
......
......
......
......
.nv
oSpa
ceTe
mp.
......
......
......
....S
NVT
_tem
p_p
POIN
T03
.....
R...
......
......
......
....S
pace
Tem
pera
ture
......
......
......
......
.....
SPT
nvoU
nitS
tatu
s.m
ode
......
......
...SN
VT_h
vac_
stat
usPO
INT0
4...
..R
......
......
......
......
......
......
......
......
......
......
......
......
......
......
..nv
oUni
tSta
tus.
heat
_out
_p...
...SN
VT_h
vac_
stat
usPO
INT0
5...
..R
......
......
......
......
......
......
......
......
......
......
......
......
......
......
..nv
oUni
tSta
tus.
heat
_out
_s...
...SN
VT_h
vac_
stat
usPO
INT0
6...
..R
......
......
......
......
......
......
......
......
......
......
......
......
......
......
..nv
oUni
tSta
tus.
cool
_out
......
.....
SNVT
_hva
c_st
atus
POIN
T07
.....
R...
......
......
......
......
......
......
......
......
......
......
......
......
......
.....
nvoU
nitS
tatu
s.ec
on_o
ut...
......
SNVT
_hva
c_st
atus
POIN
T08
.....
R...
......
......
......
......
......
......
......
......
......
......
......
......
......
.....
nvoU
nitS
tatu
s.fa
n_ou
t....
......
..SN
VT_h
vac_
stat
usPO
INT0
9...
..R
......
......
......
......
......
......
......
......
......
......
......
......
......
......
..nv
oUni
tSta
tus.
in_a
larm
......
.....
SNVT
_hva
c_st
atus
POIN
T10
.....
R...
......
......
......
......
......
......
......
......
......
......
......
......
......
.....
nviO
ccSc
hedu
le...
......
......
......
SNVT
_occ
upan
cyPO
INT1
1...
..W
......
......
......
......
Occ
upan
cy S
ched
ule
......
......
......
......
..O
CC
PC65
Env
iSet
PtO
ffset
......
......
......
......
SNVT
_tem
p_p
POIN
T12
.....
W...
......
......
......
......
......
......
......
......
......
......
......
......
......
....
nviO
utsid
eTem
p...
......
......
......
SNVT
_tem
p_p
POIN
T13
.....
W...
......
......
......
......
......
......
......
......
......
......
......
......
......
....
nviO
utsid
eRH
......
......
......
......
.SN
VT_l
ev_p
erce
ntPO
INT1
4...
..W
......
......
......
......
......
......
......
......
......
......
......
......
......
......
.nv
oEffe
ctSe
tpt.
......
......
......
.....
SNVT
_tem
p_p
POIN
T15
.....
R...
......
......
......
......
......
......
......
......
......
......
......
......
......
.....
nvoO
utsid
eTem
p...
......
......
.....
SNVT
_tem
p_p
POIN
T16
.....
R...
......
......
......
....O
utdo
or A
ir Tem
pera
ture
......
......
......
...O
ATnv
oOut
sideR
H...
......
......
......
...SN
VT_l
ev_p
erce
ntPO
INT1
7...
..R
......
......
......
......
......
......
......
......
......
......
......
......
......
......
..nv
iSpa
ceR
H...
......
......
......
......
SNVT
_lev
_per
cent
POIN
T18
.....
W...
......
......
......
......
......
......
......
......
......
......
......
......
......
....
nviC
O2
......
......
......
......
......
.....
SNVT
_ppm
POIN
T19
.....
W...
......
......
......
......
......
......
......
......
......
......
......
......
......
....
nvoC
O2
......
......
......
......
......
....S
NVT
_ppm
POIN
T20
.....
R...
......
......
......
....I
ndoo
r Air
CO
2 Le
vel.
......
......
......
......
...IA
Qnv
iTEM
P1...
......
......
......
......
....S
NVT
_tem
p_p
POIN
T21
.....
W...
......
......
......
......
......
......
......
......
......
......
......
......
......
....
nvoT
EMP1
......
......
......
......
......
SNVT
_tem
p_p
POIN
T22
.....
R...
......
......
......
....S
uppl
y Air
Tem
pera
ture
......
......
......
.....
SAT
nvoT
EMP2
......
......
......
......
......
SNVT
_tem
p_p
POIN
T23
.....
R...
......
......
......
......
......
......
......
......
......
......
......
......
......
.....
nvoT
EMP3
......
......
......
......
......
SNVT
_tem
p_p
POIN
T24
.....
R...
......
......
......
......
......
......
......
......
......
......
......
......
......
.....
nvoT
EMP4
......
......
......
......
......
SNVT
_tem
p_p
POIN
T25
.....
R...
......
......
......
......
......
......
......
......
......
......
......
......
......
.....
nviP
RES
S1...
......
......
......
......
.SN
VT_p
ress
_pPO
INT2
6...
..W
......
......
......
......
......
......
......
......
......
......
......
......
......
......
.nv
oPR
ESS1
......
......
......
......
...SN
VT_p
ress
_pPO
INT2
7...
..R
......
......
......
......
......
......
......
......
......
......
......
......
......
......
..nv
oPR
ESS2
......
......
......
......
...SN
VT_p
ress
_pPO
INT2
8...
..R
......
......
......
......
......
......
......
......
......
......
......
......
......
......
..
69
Figure A-6Sample Configurationfor RTUMAP2 Table
RTUM
AP2
SNVT
Typ
eR
ead
or W
rite?
C
PP P
oint
Des
crip
tion
CPP
Poi
nt N
ame
nviP
CT1
SNVT
_lev
_per
cent
POIN
T29
Wnv
iPCT
2....
......
......
......
......
......
SNVT
_lev
_per
cent
POIN
T30
.....
W...
......
......
......
......
......
......
......
......
......
......
......
......
......
....
nvoP
CT1
......
......
......
......
......
..SN
VT_l
ev_p
erce
ntPO
INT3
1...
..R
......
......
......
......
.Eco
nom
izer
Pos
ition
......
......
......
......
...EC
ON
OPO
Snv
oPCT
2...
......
......
......
......
.....S
NVT
_lev
_per
cent
POIN
T32
.....
R...
......
......
......
....E
cono
miz
er M
in. P
ositi
on in
Effe
ct...
...M
IN_P
OS
nvoP
CT3
......
......
......
......
......
..SN
VT_l
ev_p
erce
ntPO
INT3
3...
..R
......
......
......
......
......
......
......
......
......
......
......
......
......
......
..nv
oTEM
PDIF
F1...
......
......
......
.SN
VT_t
emp_
diff_
pPO
INT3
4...
..R
......
......
......
......
......
......
......
......
......
......
......
......
......
......
..nv
oTEM
PDIF
F2...
......
......
......
.SN
VT_t
emp_
diff_
pPO
INT3
5...
..R
......
......
......
......
......
......
......
......
......
......
......
......
......
......
..nv
iDIS
CR
ETE1
......
......
......
.....S
NVT
_sw
itch
POIN
T36
.....
W...
......
......
......
...C
urre
ntly
Occ
upie
d...
......
......
......
......
...O
CC
UPI
EDnv
iDIS
CR
ETE2
......
......
......
.....S
NVT
_sw
itch
POIN
T37
.....
W...
......
......
......
...U
nit S
hutd
own
Inpu
t....
......
......
......
...FI
REDO
WN
nviD
ISC
RET
E3...
......
......
......
..SN
VT_s
witc
hPO
INT3
8...
..W
......
......
......
......
......
......
......
......
......
......
......
......
......
......
.nv
oDIS
CRET
E1...
......
......
......
.SN
VT_s
witc
hPO
INT3
9...
..R
......
......
......
......
.Cur
rent
ly O
ccup
ied
......
......
......
......
......
OC
CU
PIED
nvoD
ISCR
ETE2
......
......
......
....S
NVT
_sw
itch
POIN
T40
.....
R...
......
......
......
....S
uppl
y Fa
n St
atus
......
......
......
......
......
FAN
_STA
Tnv
oDIS
CRET
E3...
......
......
......
.SN
VT_s
witc
hPO
INT4
1...
..R
......
......
......
......
.Hea
ting
Stag
e 1
......
......
......
......
......
....H
EAT_
1nv
oDIS
CRET
E4...
......
......
......
.SN
VT_s
witc
hPO
INT4
2...
..R
......
......
......
......
.Hea
ting
Stag
e 2
......
......
......
......
......
....H
EAT_
2nv
oDIS
CRET
E5...
......
......
......
.SN
VT_s
witc
hPO
INT4
3...
..R
......
......
......
......
.Com
pres
sor A
1...
......
......
......
......
......
..C
OM
P_A1
nvoD
ISCR
ETE6
......
......
......
....S
NVT
_sw
itch
POIN
T44
.....
R...
......
......
......
....C
ompr
esso
r B1
......
......
......
......
......
.....
CO
MP_
B1nv
oDIS
CRET
E7...
......
......
......
.SN
VT_s
witc
hPO
INT4
5...
..R
......
......
......
......
.Com
pres
sor C
1...
......
......
......
......
......
..C
OM
P_C
1nv
oDIS
CRET
E8...
......
......
......
.SN
VT_s
witc
hPO
INT4
6...
..R
......
......
......
......
......
......
......
......
......
......
......
......
......
......
..nc
iCO
2Lim
it...
......
......
......
......
SNVT
_ppm
POIN
T47
.....
W...
......
......
......
......
......
......
......
......
......
......
......
......
......
....
nciS
etPn
ts.o
ccup
ied_
cool
......
SNVT
_tem
p_se
tpt
POIN
T48
.....
W...
......
......
......
...O
ccup
ied
Coo
ling
Setp
oint
......
......
......
OC
SPnc
iSet
Pnts
.sta
ndby
_coo
l....
...SN
VT_t
emp_
setp
tPO
INT4
9...
..W
......
......
......
......
......
......
......
......
......
......
......
......
......
......
.nc
iSet
Pnts
.uno
cc_c
ool.
......
...SN
VT_t
emp_
setp
tPO
INT5
0...
..W
......
......
......
......
Uno
ccup
ied
Coo
ling
Setp
oint
......
......
...U
CSP
nciS
etPn
ts.o
ccup
ied_
heat
.....S
NVT
_tem
p_se
tpt
POIN
T51
.....
W...
......
......
......
...O
ccup
ied
Hea
ting
Setp
oint
......
......
......
OH
SPnc
iSet
Pnts
.sta
ndby
_hea
t....
...SN
VT_t
emp_
setp
tPO
INT5
2...
..W
......
......
......
......
......
......
......
......
......
......
......
......
......
......
.nc
iSet
Pnts
.uno
cc_h
eat.
......
...SN
VT_t
emp_
setp
tPO
INT5
3...
..W
......
......
......
......
Uno
ccup
ied
Hea
ting
Setp
oint
......
......
..U
HSP
nviC
OUN
T1...
......
......
......
......
.SN
VT_c
ount
POIN
T54
.....
W...
......
......
......
......
......
......
......
......
......
......
......
......
......
....
nvoC
OUN
T1...
......
......
......
......
SNVT
_cou
ntPO
INT5
5...
..R
......
......
......
......
......
......
......
......
......
......
......
......
......
......
..nv
oCO
UNT2
......
......
......
......
...SN
VT_c
ount
POIN
T56
.....
R...
......
......
......
......
......
......
......
......
......
......
......
......
......
.....
nvoC
OUN
Tinc
1...
......
......
......
..SN
VT_c
ount
_inc
POIN
T57
.....
R...
......
......
......
......
......
......
......
......
......
......
......
......
......
.....
nvoC
OUN
Tinc
2...
......
......
......
..SN
VT_c
ount
_inc
POIN
T58
.....
R...
......
......
......
......
......
......
......
......
......
......
......
......
......
.....
70
Figure A-7RTUMAP1 Table SNVTs and CPP Points
Job
Site
:LE
I Add
ress
:A
ttach
ed D
evic
e:A
ttach
ed D
evic
e Add
ress
:LO
N P
rofil
e:(N
A) M
eans
not
gen
eral
ly a
pplic
able
to C
PP
RTUM
AP1
SNVT
Typ
eR
ead
or W
rite?
C
PP P
oint
Des
crip
tion
nviS
pace
Tem
p...
......
......
......
..SN
VT_t
emp_
pPO
INT0
1...
....W
......
......
......
......
Spac
e Tem
pera
ture
(deg
F)nv
iSet
Poin
t....
......
......
......
......
SNVT
_tem
p_p
POIN
T02
......
.W...
......
......
......
...Su
pply
Air
Setp
oint
on
VAV
units
(deg
F)nv
oSpa
ceTe
mp.
......
......
......
...SN
VT_t
emp_
pPO
INT0
3...
....R
......
......
......
......
.Spa
ce T
empe
ratu
re (d
egF)
nvoU
nitS
tatu
s.m
ode
......
......
..SN
VT_h
vac_
stat
usPO
INT0
4...
....R
......
......
......
......
.(N
A)nv
oUni
tSta
tus.
heat
_out
_p...
..SN
VT_h
vac_
stat
usPO
INT0
5...
....R
......
......
......
......
.Hea
ting
Coi
l Val
ve (%
)nv
oUni
tSta
tus.
heat
_out
_s...
..SN
VT_h
vac_
stat
usPO
INT0
6...
....R
......
......
......
......
.Sec
onda
ry H
eatin
g C
oil V
alve
(%) (
NA)
nvoU
nitS
tatu
s.co
ol_o
ut...
......
.SN
VT_h
vac_
stat
usPO
INT0
7...
....R
......
......
......
......
.Coo
ling
Coi
l Val
ve (%
)nv
oUni
tSta
tus.
econ
_out
......
..SN
VT_h
vac_
stat
usPO
INT0
8...
....R
......
......
......
......
.Eco
nom
izer
(%)
nvoU
nitS
tatu
s.fa
n_ou
t....
......
.SN
VT_h
vac_
stat
usPO
INT0
9...
....R
......
......
......
......
.Fan
Spe
ed (%
)nv
oUni
tSta
tus.
in_a
larm
......
....S
NVT
_hva
c_st
atus
POIN
T10
......
.R...
......
......
......
....D
iscr
ete
Alar
m p
oint
(1/0
)nv
iOcc
Sche
dule
.....
......
......
... S
NVT
_occ
upan
cy
POIN
T11
......
. W ..
......
......
......
.... G
loba
l CP
P O
ccup
ancy
(>64
)nv
iSet
PtO
ffset
......
......
......
.....
SNVT
_tem
p_p
POIN
T12
......
.W...
......
......
......
...Te
mpe
ratu
re (d
egF)
nviO
utsid
eTem
p...
......
......
.....
SNVT
_tem
p_p
POIN
T13
......
.W...
......
......
......
...O
utdo
or A
ir Tem
pera
ture
(deg
F)nv
iOut
sideR
H...
......
......
......
...SN
VT_l
ev_p
erce
ntPO
INT1
4...
....W
......
......
......
......
Out
door
Air
RH
(%)
nvoE
ffect
Setp
t....
......
......
......
.SN
VT_t
emp_
pPO
INT1
5...
....R
......
......
......
......
.Con
trollin
g Se
tpoi
nt (d
egF)
nvoO
utsid
eTem
p...
......
......
....S
NVT
_tem
p_p
POIN
T16
......
.R...
......
......
......
....O
utdo
or A
ir Tem
pera
ture
(deg
F)nv
oOut
sideR
H...
......
......
......
..SN
VT_l
ev_p
erce
ntPO
INT1
7...
....R
......
......
......
......
.Out
door
Air
RH
(%)
nviS
pace
RH
......
......
......
......
..SN
VT_l
ev_p
erce
ntPO
INT1
8...
....W
......
......
......
......
Spac
e R
H (%
)nv
iCO
2...
......
......
......
......
......
.SN
VT_p
pmPO
INT1
9...
....W
......
......
......
......
IAQ
(PPM
)nv
oCO
2...
......
......
......
......
......
SNVT
_ppm
POIN
T20
......
.R...
......
......
......
....I
AQ (P
PM)
nviT
EMP1
......
......
......
......
......
SNVT
_tem
p_p
POIN
T21
......
.W...
......
......
......
...Te
mpe
ratu
re (d
egF)
nvoT
EMP1
......
......
......
......
.....
SNVT
_tem
p_p
POIN
T22
......
.R...
......
......
......
....T
empe
ratu
re (d
egF)
nvoT
EMP2
......
......
......
......
.....
SNVT
_tem
p_p
POIN
T23
......
.R...
......
......
......
....T
empe
ratu
re (d
egF)
nvoT
EMP3
......
......
......
......
.....
SNVT
_tem
p_p
POIN
T24
......
.R...
......
......
......
....T
empe
ratu
re (d
egF)
nvoT
EMP4
......
......
......
......
.....
SNVT
_tem
p_p
POIN
T25
......
.R...
......
......
......
....T
empe
ratu
re (d
egF)
nviP
RES
S1...
......
......
......
......
SNVT
_pre
ss_p
POIN
T26
......
.W...
......
......
......
...Pr
essu
re (“
H2O
)nv
oPR
ESS1
......
......
......
......
..SN
VT_p
ress
_pPO
INT2
7...
....R
......
......
......
......
.Pre
ssur
e (“H
2O)
nvoP
RES
S2...
......
......
......
.....
SNVT
_pre
ss_p
POIN
T28
......
.R...
......
......
......
....P
ress
ure (
“H2O
)
71
Figure A-8RTUMAP2 Table SNVTs and CPP Points
RTUM
AP2
SNVT
Typ
eR
ead
or W
rite?
C
PP P
oint
Des
crip
tion
nviP
CT1.
......
......
......
......
......
..SN
VT_l
ev_p
erce
ntPO
INT2
9...
....W
......
......
......
......
Perc
ent (
%)
nviP
CT2.
......
......
......
......
......
..SN
VT_l
ev_p
erce
ntPO
INT3
0...
....W
......
......
......
......
Perc
ent (
%)
nvoP
CT1
......
......
......
......
......
.SN
VT_l
ev_p
erce
ntPO
INT3
1...
....R
......
......
......
......
.Per
cent
(%)
nvoP
CT2
......
......
......
......
......
.SN
VT_l
ev_p
erce
ntPO
INT3
2...
....R
......
......
......
......
.Per
cent
(%)
nvoP
CT3
......
......
......
......
......
.SN
VT_l
ev_p
erce
ntPO
INT3
3...
....R
......
......
......
......
.Per
cent
(%)
nvoT
EMPD
IFF1
......
......
......
...SN
VT_t
emp_
diff_
pPO
INT3
4...
....R
......
......
......
......
.Del
ta T
empe
ratu
re (^
F)nv
oTEM
PDIF
F2...
......
......
......
SNVT
_tem
p_di
ff_p
POIN
T35
......
.R...
......
......
......
....D
elta
Tem
pera
ture
(^F)
nviD
ISC
RET
E1...
......
......
......
.SN
VT_s
witc
hPO
INT3
6...
....W
......
......
......
......
Dis
cret
e (1
/0)
nviD
ISC
RET
E2...
......
......
......
.SN
VT_s
witc
hPO
INT3
7...
....W
......
......
......
......
Dis
cret
e (1
/0)
nviD
ISC
RET
E3...
......
......
......
.SN
VT_s
witc
hPO
INT3
8...
....W
......
......
......
......
Dis
cret
e (1
/0)
nvoD
ISCR
ETE1
......
......
......
...SN
VT_s
witc
hPO
INT3
9...
....R
......
......
......
......
.Dis
cret
e (1
/0)
nvoD
ISCR
ETE2
......
......
......
...SN
VT_s
witc
hPO
INT4
0...
....R
......
......
......
......
.Dis
cret
e (1
/0)
nvoD
ISCR
ETE3
......
......
......
...SN
VT_s
witc
hPO
INT4
1...
....R
......
......
......
......
.Dis
cret
e (1
/0)
nvoD
ISCR
ETE4
......
......
......
...SN
VT_s
witc
hPO
INT4
2...
....R
......
......
......
......
.Dis
cret
e (1
/0)
nvoD
ISCR
ETE5
......
......
......
...SN
VT_s
witc
hPO
INT4
3...
....R
......
......
......
......
.Dis
cret
e (1
/0)
nvoD
ISCR
ETE6
......
......
......
...SN
VT_s
witc
hPO
INT4
4...
....R
......
......
......
......
.Dis
cret
e (1
/0)
nvoD
ISCR
ETE7
......
......
......
...SN
VT_s
witc
hPO
INT4
5...
....R
......
......
......
......
.Dis
cret
e (1
/0)
nvoD
ISCR
ETE8
......
......
......
...SN
VT_s
witc
hPO
INT4
6...
....R
......
......
......
......
.Dis
cret
e (1
/0)
nciC
O2L
imit
......
......
......
......
..SN
VT_p
pmPO
INT4
7...
....W
......
......
......
......
IAQ
Set
poin
t (PP
M)
nciS
etPn
ts.o
ccup
ied_
cool
.....
SNVT
_tem
p_se
tpt
POIN
T48
......
.W...
......
......
......
...Te
mpe
ratu
re S
etpo
int (
degF
)nc
iSet
Pnts
.sta
ndby
_coo
l....
..SN
VT_t
emp_
setp
tPO
INT4
9...
....W
......
......
......
......
(NA)
nciS
etPn
ts.u
nocc
_coo
l....
.....
SNVT
_tem
p_se
tpt
POIN
T50
......
.W...
......
......
......
...Te
mpe
ratu
re S
etpo
int (
degF
)nc
iSet
Pnts
.occ
upie
d_he
at...
.SN
VT_t
emp_
setp
tPO
INT5
1...
....W
......
......
......
......
Tem
pera
ture
Set
poin
t (de
gF)
nciS
etPn
ts.s
tand
by_h
eat.
.....
SNVT
_tem
p_se
tpt
POIN
T52
......
.W...
......
......
......
...(N
A)nc
iSet
Pnts
.uno
cc_h
eat.
......
..SN
VT_t
emp_
setp
tPO
INT5
3...
....W
......
......
......
......
Tem
pera
ture
Set
poin
t (de
gF)
nviC
OUN
T1...
......
......
......
......
SNVT
_cou
ntPO
INT5
4...
....W
......
......
......
......
Gen
eric
ana
log
or d
iscr
ete
(0-6
5535
)nv
oCO
UNT1
......
......
......
......
..SN
VT_c
ount
POIN
T55
......
.R...
......
......
......
....G
ener
ic a
nalo
g or
dis
cret
e (0
-655
35)
nvoC
OUN
T2...
......
......
......
.....
SNVT
_cou
ntPO
INT5
6...
....R
......
......
......
......
.Gen
eric
ana
log
or d
iscr
ete
(0-6
5535
)nv
oCO
UNTi
nc1
......
......
......
....S
NVT
_cou
nt_i
ncPO
INT5
7...
....R
......
......
......
......
.Gen
eric
ana
log
or d
iscr
ete
(-327
67 - 3
2767
)nv
oCO
UNTi
nc2
......
......
......
....S
NVT
_cou
nt_i
ncPO
INT5
8...
....R
......
......
......
......
.Gen
eric
ana
log
or d
iscr
ete
(-327
67 - 3
2767
)
72
Figure A-9Sample Configuration forGNRCMAP1 Table
Job
Site
:LE
I Add
ress
:0,
182
Atta
ched
Dev
ice:
Prem
ierL
ink
Atta
ched
Dev
ice A
ddre
ss:
0, 3
1LO
N P
rofil
e:G
ener
ic
GNR
CMAP
1SN
VT T
ype
CPP
Poi
nt N
ame
nvoU
nitS
tatu
s.m
ode
SNVT
_hva
c_st
atus
POIN
T01
Rea
d or
Writ
e?
CPP
Poi
nt D
escr
iptio
n R
nvoU
nitS
tatu
s.he
at_o
ut_p
.....
SNVT
_hva
c_st
atus
POIN
T02
......
.R...
......
......
......
......
......
......
......
......
......
......
......
......
......
.....
nvoU
nitS
tatu
s.he
at_o
ut_s
.....
SNVT
_hva
c_st
atus
POIN
T03
......
.R...
......
......
......
......
......
......
......
......
......
......
......
......
......
.....
nvoU
nitS
tatu
s.co
ol_o
ut...
......
.SN
VT_h
vac_
stat
usPO
INT0
4...
....R
......
......
......
......
......
......
......
......
......
......
......
......
......
......
..nv
oUni
tSta
tus.
econ
_out
......
..SN
VT_h
vac_
stat
usPO
INT0
5...
....R
......
......
......
......
......
......
......
......
......
......
......
......
......
......
..nv
oUni
tSta
tus.
fan_
out.
......
....S
NVT
_hva
c_st
atus
POIN
T06
......
.R...
......
......
......
......
......
......
......
......
......
......
......
......
......
.....
nvoU
nitS
tatu
s.in
_ala
rm...
......
.SN
VT_h
vac_
stat
usPO
INT0
7...
....R
......
......
......
......
......
......
......
......
......
......
......
......
......
......
..nv
iOcc
Sche
dule
......
......
......
..SN
VT_o
ccup
ancy
POIN
T08
......
.W...
......
......
......
......
......
......
......
......
......
......
......
......
......
....
nviT
EMP1
......
......
......
......
......
SNVT
_tem
p_p
POIN
T09
......
.W...
......
......
......
......
......
......
......
......
......
......
......
......
......
....
nviT
EMP2
......
......
......
......
......
SNVT
_tem
p_p
POIN
T10
......
.W...
......
......
......
......
......
......
......
......
......
......
......
......
......
....
nviT
EMP3
......
......
......
......
......
SNVT
_tem
p_p
POIN
T11
......
.W...
......
......
......
......
......
......
......
......
......
......
......
......
......
....
nvoT
EMP1
......
......
......
......
.....
SNVT
_tem
p_p
POIN
T12
......
.R...
......
......
......
....S
uppl
y Air
Tem
pera
ture
......
......
......
.....
SAT
nvoT
EMP2
......
......
......
......
.....
SNVT
_tem
p_p
POIN
T13
......
.R...
......
......
......
....O
utdo
or A
ir Tem
pera
ture
......
......
......
...O
ATnv
oTEM
P3...
......
......
......
......
..SN
VT_t
emp_
pPO
INT1
4...
....R
......
......
......
......
.Spa
ce T
empe
ratu
re...
......
......
......
......
..SP
Tnv
oTEM
P4...
......
......
......
......
..SN
VT_t
emp_
pPO
INT1
5...
....R
......
......
......
......
......
......
......
......
......
......
......
......
......
......
..nv
oTEM
P5...
......
......
......
......
..SN
VT_t
emp_
pPO
INT1
6...
....R
......
......
......
......
......
......
......
......
......
......
......
......
......
......
..nv
oTEM
P6...
......
......
......
......
..SN
VT_t
emp_
pPO
INT1
7...
....R
......
......
......
......
......
......
......
......
......
......
......
......
......
......
..nv
oTEM
P7...
......
......
......
......
..SN
VT_t
emp_
pPO
INT1
8...
....R
......
......
......
......
......
......
......
......
......
......
......
......
......
......
..nv
oTEM
P8...
......
......
......
......
..SN
VT_t
emp_
pPO
INT1
9...
....R
......
......
......
......
......
......
......
......
......
......
......
......
......
......
..nv
iPR
ESS1
......
......
......
......
...SN
VT_p
ress
_pPO
INT2
0...
....W
......
......
......
......
......
......
......
......
......
......
......
......
......
......
.nv
iPR
ESS2
......
......
......
......
...SN
VT_p
ress
POIN
T21
......
.W...
......
......
......
......
......
......
......
......
......
......
......
......
......
....
nvoP
RES
S1...
......
......
......
.....
SNVT
_pre
ss_p
POIN
T22
......
.R...
......
......
......
......
......
......
......
......
......
......
......
......
......
.....
nvoP
RES
S2...
......
......
......
.....
SNVT
_pre
ss_p
POIN
T23
......
.R...
......
......
......
......
......
......
......
......
......
......
......
......
......
.....
nvoP
RES
S3...
......
......
......
.....
SNVT
_pre
ssPO
INT2
4...
....R
......
......
......
......
......
......
......
......
......
......
......
......
......
......
..nv
oPR
ESS4
......
......
......
......
..SN
VT_p
ress
POIN
T25
......
.R...
......
......
......
......
......
......
......
......
......
......
......
......
......
.....
nvoP
RES
S5...
......
......
......
.....
SNVT
_pre
ssPO
INT2
6...
....R
......
......
......
......
......
......
......
......
......
......
......
......
......
......
..nv
oPR
ESS6
......
......
......
......
..SN
VT_p
ress
POIN
T27
......
.R...
......
......
......
......
......
......
......
......
......
......
......
......
......
.....
nvoT
EMPD
IFF1
......
......
......
...SN
VT_t
emp_
diff_
pPO
INT2
8...
....R
......
......
......
......
......
......
......
......
......
......
......
......
......
......
..nv
oTEM
PDIF
F2...
......
......
......
SNVT
_tem
p_di
ff_p
POIN
T29
......
.R...
......
......
......
......
......
......
......
......
......
......
......
......
......
.....
73
Figure A-10Sample Configurationfor GNRCMAP2 Table
GNR
CMAP
2SN
VT T
ype
Rea
d or
Writ
e?
CPP
Poi
nt D
escr
iptio
nC
PP P
oint
Nam
env
iPCT
1SN
VT_l
ev_p
erce
ntPO
INT3
0W
nviP
CT2.
......
......
......
......
......
..SN
VT_l
ev_p
erce
ntPO
INT3
1...
..W
......
......
......
......
......
......
......
......
......
......
......
......
......
......
.nv
oPCT
1...
......
......
......
......
....S
NVT
_lev
_per
cent
POIN
T32
.....
R...
......
......
......
....C
oolin
g %
Tot
al C
apac
ity...
......
......
.....
CC
APnv
oPCT
2...
......
......
......
......
....S
NVT
_lev
_per
cent
POIN
T33
.....
R...
......
......
......
....H
eatin
g %
Tot
al C
apac
ity...
......
......
.....
HC
APnv
oPCT
3...
......
......
......
......
....S
NVT
_lev
_per
cent
POIN
T34
.....
R...
......
......
......
....E
cono
miz
er P
ositi
on...
......
......
......
......
ECO
NPO
Snv
oPCT
4...
......
......
......
......
....S
NVT
_lev
_per
cent
POIN
T35
.....
R...
......
......
......
......
......
......
......
......
......
......
......
......
......
.....
nviD
ISC
RET
E1...
......
......
......
.SN
VT_s
witc
hPO
INT3
6...
..W
......
......
......
......
Rem
ote
Occ
upie
d M
ode
......
......
......
....R
MTO
CCnv
iDIS
CR
ETE2
......
......
......
....S
NVT
_sw
itch
POIN
T37
.....
W...
......
......
......
......
......
......
......
......
......
......
......
......
......
....
nviD
ISC
RET
E3...
......
......
......
.SN
VT_s
witc
hPO
INT3
8...
..W
......
......
......
......
......
......
......
......
......
......
......
......
......
......
.nv
oDIS
CRET
E1...
......
......
......
SNVT
_sw
itch
POIN
T39
.....
R...
......
......
......
....S
uppl
y Fa
n R
elay
......
......
......
......
......
..SF
nvoD
ISCR
ETE2
......
......
......
...SN
VT_s
witc
hPO
INT4
0...
..R
......
......
......
......
.Eco
nom
izer
Act
ive
......
......
......
......
......
ECO
Snv
oDIS
CRET
E3...
......
......
......
SNVT
_sw
itch
POIN
T41
.....
R...
......
......
......
....R
emot
e O
ccup
ied
Mod
e...
......
......
......
.RM
TOCC
nvoD
ISCR
ETE4
......
......
......
...SN
VT_s
witc
hPO
INT4
2...
..R
......
......
......
......
......
......
......
......
......
......
......
......
......
......
..nv
oDIS
CRET
E5...
......
......
......
SNVT
_sw
itch
POIN
T43
.....
R...
......
......
......
......
......
......
......
......
......
......
......
......
......
.....
nvoD
ISCR
ETE6
......
......
......
...SN
VT_s
witc
hPO
INT4
4...
..R
......
......
......
......
......
......
......
......
......
......
......
......
......
......
..nv
oDIS
CRET
E7...
......
......
......
SNVT
_sw
itch
POIN
T45
.....
R...
......
......
......
......
......
......
......
......
......
......
......
......
......
.....
nvoD
ISCR
ETE8
......
......
......
...SN
VT_s
witc
hPO
INT4
6...
..R
......
......
......
......
......
......
......
......
......
......
......
......
......
......
..nc
iSet
Pnts
.occ
upie
d_co
ol...
..SN
VT_t
emp_
setp
tPO
INT4
7...
..W
......
......
......
......
Occ
upie
d C
oolin
g Se
tpoi
nt...
......
......
...O
CSP
nciS
etPn
ts.s
tand
by_c
ool.
.....
SNVT
_tem
p_se
tpt
POIN
T48
.....
W...
......
......
......
......
......
......
......
......
......
......
......
......
......
....
nciS
etPn
ts.u
nocc
_coo
l....
.....
SNVT
_tem
p_se
tpt
POIN
T49
.....
W...
......
......
......
...U
nocc
upie
d C
oolin
g Se
tpoi
nt...
......
......
UC
SPnc
iSet
Pnts
.occ
upie
d_he
at...
.SN
VT_t
emp_
setp
tPO
INT5
0...
..W
......
......
......
......
Occ
upie
d H
eatin
g Se
tpoi
nt...
......
......
...O
HSP
nciS
etPn
ts.s
tand
by_h
eat.
.....
SNVT
_tem
p_se
tpt
POIN
T51
.....
W...
......
......
......
......
......
......
......
......
......
......
......
......
......
....
nciS
etPn
ts.u
nocc
_hea
t....
.....
SNVT
_tem
p_se
tpt
POIN
T52
.....
W...
......
......
......
...U
nocc
upie
d H
eatin
g Se
tpoi
nt...
......
.....
UH
SPnv
iPPM
......
......
......
......
......
...SN
VT_p
pmPO
INT5
3...
..W
......
......
......
......
......
......
......
......
......
......
......
......
......
......
.nv
oPPM
......
......
......
......
......
..SN
VT_p
pmPO
INT5
4...
..R
......
......
......
......
......
......
......
......
......
......
......
......
......
......
..nv
iCO
UNT1
......
......
......
......
...SN
VT_c
ount
POIN
T55
.....
W...
......
......
......
......
......
......
......
......
......
......
......
......
......
....
nvoC
OUN
T1...
......
......
......
.....
SNVT
_cou
ntPO
INT5
6...
..R
......
......
......
......
......
......
......
......
......
......
......
......
......
......
..nv
oCO
UNT2
......
......
......
......
..SN
VT_c
ount
POIN
T57
.....
R...
......
......
......
......
......
......
......
......
......
......
......
......
......
.....
nvoC
OUN
Tinc
1...
......
......
......
.SN
VT_c
ount
_inc
POIN
T58
.....
R...
......
......
......
......
......
......
......
......
......
......
......
......
......
.....
nvoC
OUN
Tinc
2...
......
......
......
.SN
VT_c
ount
_inc
POIN
T59
.....
R...
......
......
......
......
......
......
......
......
......
......
......
......
......
.....
74
Figure A-11 GNRCMAP1 Table SNVTs and CPP Points
Job
Site
:LE
I Add
ress
:A
ttach
ed D
evic
e:A
ttach
ed D
evic
e Add
ress
:LO
N P
rofil
e:(N
A) M
eans
not
gen
eral
ly a
pplic
able
to C
PP
GNR
CMAP
1SN
VT T
ype
nvoU
nitS
tatu
s.m
ode
SNVT
_hva
c_st
atus
POIN
T01
Rea
d or
Writ
e?
CPP
Poi
nt D
escr
iptio
n R
(NA)
nvoU
nitS
tatu
s.he
at_o
ut_p
.....
SNVT
_hva
c_st
atus
POIN
T02
......
R...
......
......
......
....H
eatin
g C
oil V
alve
(%)
nvoU
nitS
tatu
s.he
at_o
ut_s
.....
SNVT
_hva
c_st
atus
POIN
T03
......
R...
......
......
......
....S
econ
dary
Hea
ting
Coi
l Val
ve (%
)nv
oUni
tSta
tus.
cool
_out
......
....S
NVT
_hva
c_st
atus
POIN
T04
......
R...
......
......
......
....C
oolin
g C
oil V
alve
(%)
nvoU
nitS
tatu
s.ec
on_o
ut...
.....
SNVT
_hva
c_st
atus
POIN
T05
......
R...
......
......
......
....E
cono
miz
er (%
)nv
oUni
tSta
tus.
fan_
out.
......
....S
NVT
_hva
c_st
atus
POIN
T06
......
R...
......
......
......
....F
an S
peed
(%)
nvoU
nitS
tatu
s.in
_ala
rm...
......
.SN
VT_h
vac_
stat
usPO
INT0
7...
...R
......
......
......
......
.Dis
cret
e Al
arm
poi
nt (1
/0)
nviO
ccSc
hedu
le ..
......
......
......
SN
VT_o
ccup
ancy
PO
INT0
8 ...
... W
.....
......
......
......
. Glo
bal C
PP
Occ
upan
cy (>
64)
nviT
EMP1
......
......
......
......
......
SNVT
_tem
p_p
POIN
T09
......
W...
......
......
......
...Te
mpe
ratu
re (d
egF)
nviT
EMP2
......
......
......
......
......
SNVT
_tem
p_p
POIN
T10
......
W...
......
......
......
...Te
mpe
ratu
re (d
egF)
nviT
EMP3
......
......
......
......
......
SNVT
_tem
p_p
POIN
T11
......
W...
......
......
......
...Te
mpe
ratu
re (d
egF)
nvoT
EMP1
......
......
......
......
.....
SNVT
_tem
p_p
POIN
T12
......
R...
......
......
......
....T
empe
ratu
re (d
egF)
nvoT
EMP2
......
......
......
......
.....
SNVT
_tem
p_p
POIN
T13
......
R...
......
......
......
....T
empe
ratu
re (d
egF)
nvoT
EMP3
......
......
......
......
.....
SNVT
_tem
p_p
POIN
T14
......
R...
......
......
......
....T
empe
ratu
re (d
egF)
nvoT
EMP4
......
......
......
......
.....
SNVT
_tem
p_p
POIN
T15
......
R...
......
......
......
....T
empe
ratu
re (d
egF)
nvoT
EMP5
......
......
......
......
.....
SNVT
_tem
p_p
POIN
T16
......
R...
......
......
......
....T
empe
ratu
re (d
egF)
nvoT
EMP6
......
......
......
......
.....
SNVT
_tem
p_p
POIN
T17
......
R...
......
......
......
....T
empe
ratu
re (d
egF)
nvoT
EMP7
......
......
......
......
.....
SNVT
_tem
p_p
POIN
T18
......
R...
......
......
......
....T
empe
ratu
re (d
egF)
nvoT
EMP8
......
......
......
......
.....
SNVT
_tem
p_p
POIN
T19
......
R...
......
......
......
....T
empe
ratu
re (d
egF)
nviP
RES
S1...
......
......
......
......
SNVT
_pre
ss_p
POIN
T20
......
W...
......
......
......
...Pr
essu
re (“
H2O
)nv
iPR
ESS2
......
......
......
......
...SN
VT_p
ress
POIN
T21
......
W...
......
......
......
...Pr
essu
re (P
SI)
nvoP
RES
S1...
......
......
......
.....
SNVT
_pre
ss_p
POIN
T22
......
R...
......
......
......
....P
ress
ure (
“H2O
)nv
oPR
ESS2
......
......
......
......
..SN
VT_p
ress
_pPO
INT2
3...
...R
......
......
......
......
.Pre
ssur
e (“H
2O)
nvoP
RES
S3...
......
......
......
.....
SNVT
_pre
ssPO
INT2
4...
...R
......
......
......
......
.Pre
ssur
e (P
SI)
nvoP
RES
S4...
......
......
......
.....
SNVT
_pre
ssPO
INT2
5...
...R
......
......
......
......
.Pre
ssur
e (P
SI)
nvoP
RES
S5...
......
......
......
.....
SNVT
_pre
ssPO
INT2
6...
...R
......
......
......
......
.Pre
ssur
e (P
SI)
nvoP
RES
S6...
......
......
......
.....
SNVT
_pre
ssPO
INT2
7...
...R
......
......
......
......
.Pre
ssur
e (P
SI)
nvoT
EMPD
IFF1
......
......
......
...SN
VT_t
emp_
diff_
pPO
INT2
8...
...R
......
......
......
......
.Del
ta T
empe
ratu
re (^
F)nv
oTEM
PDIF
F2...
......
......
......
SNVT
_tem
p_di
ff_p
POIN
T29
......
R...
......
......
......
....D
elta
Tem
pera
ture
(^F)
75
Figure A-12 GNRCMAP2 Table SNVTs and CPP Points
GNR
CMAP
2SN
VT T
ype
Rea
d or
Writ
e?
CPP
Poi
nt D
escr
iptio
nnv
iPCT
1....
......
......
......
......
......
SNVT
_lev
_per
cent
....P
OIN
T30
.....
W...
......
......
......
...Pe
rcen
t (%
)nv
iPCT
2....
......
......
......
......
......
SNVT
_lev
_per
cent
....P
OIN
T31
.....
W...
......
......
......
...Pe
rcen
t (%
)nv
oPCT
1...
......
......
......
......
.....
SNVT
_lev
_per
cent
....P
OIN
T32
.....
R...
......
......
......
....P
erce
nt (%
)nv
oPCT
2...
......
......
......
......
.....
SNVT
_lev
_per
cent
....P
OIN
T33
.....
R...
......
......
......
....P
erce
nt (%
)nv
oPCT
3...
......
......
......
......
.....
SNVT
_lev
_per
cent
....P
OIN
T34
.....
R...
......
......
......
....P
erce
nt (%
)nv
oPCT
4...
......
......
......
......
.....
SNVT
_lev
_per
cent
....P
OIN
T35
.....
R...
......
......
......
....P
erce
nt (%
)nv
iDIS
CR
ETE1
......
......
......
.....
SNVT
_sw
itch
......
.....
POIN
T36
.....
W...
......
......
......
...D
iscr
ete
(1/0
)nv
iDIS
CR
ETE2
......
......
......
.....
SNVT
_sw
itch
......
.....
POIN
T37
.....
W...
......
......
......
...D
iscr
ete
(1/0
)nv
iDIS
CR
ETE3
......
......
......
.....
SNVT
_sw
itch
......
.....
POIN
T38
.....
W...
......
......
......
...D
iscr
ete
(1/0
)nv
oDIS
CRET
E1...
......
......
......
.SN
VT_s
witc
h...
......
..PO
INT3
9...
..R
......
......
......
......
.Dis
cret
e (1
/0)
nvoD
ISCR
ETE2
......
......
......
....S
NVT
_sw
itch
......
.....
POIN
T40
.....
R...
......
......
......
....D
iscr
ete
(1/0
)nv
oDIS
CRET
E3...
......
......
......
.SN
VT_s
witc
h...
......
..PO
INT4
1...
..R
......
......
......
......
.Dis
cret
e (1
/0)
nvoD
ISCR
ETE4
......
......
......
....S
NVT
_sw
itch
......
.....
POIN
T42
.....
R...
......
......
......
....D
iscr
ete
(1/0
)nv
oDIS
CRET
E5...
......
......
......
.SN
VT_s
witc
h...
......
..PO
INT4
3...
..R
......
......
......
......
.Dis
cret
e (1
/0)
nvoD
ISCR
ETE6
......
......
......
....S
NVT
_sw
itch
......
.....
POIN
T44
.....
R...
......
......
......
....D
iscr
ete
(1/0
)nv
oDIS
CRET
E7...
......
......
......
.SN
VT_s
witc
h...
......
..PO
INT4
5...
..R
......
......
......
......
.Dis
cret
e (1
/0)
nvoD
ISCR
ETE8
......
......
......
....S
NVT
_sw
itch
......
.....
POIN
T46
.....
R...
......
......
......
....D
iscr
ete
(1/0
)nc
iSet
Pnts
.occ
upie
d_co
ol...
...SN
VT_t
emp_
setp
t....
POIN
T47
.....
W...
......
......
......
...Te
mpe
ratu
re S
etpo
int (
degF
)nc
iSet
Pnts
.sta
ndby
_coo
l....
...SN
VT_t
emp_
setp
t....
POIN
T48
.....
W...
......
......
......
...(N
A)nc
iSet
Pnts
.uno
cc_c
ool.
......
...SN
VT_t
emp_
setp
t....
POIN
T49
.....
W...
......
......
......
...Te
mpe
ratu
re S
etpo
int (
degF
)nc
iSet
Pnts
.occ
upie
d_he
at...
..SN
VT_t
emp_
setp
t....
POIN
T50
.....
W...
......
......
......
...Te
mpe
ratu
re S
etpo
int (
degF
)nc
iSet
Pnts
.sta
ndby
_hea
t....
...SN
VT_t
emp_
setp
t....
POIN
T51
.....
W...
......
......
......
...(N
A)nc
iSet
Pnts
.uno
cc_h
eat.
......
...SN
VT_t
emp_
setp
t....
POIN
T52
.....
W...
......
......
......
...Te
mpe
ratu
re S
etpo
int (
degF
)nv
iPPM
......
......
......
......
......
....S
NVT
_ppm
......
......
...PO
INT5
3...
..W
......
......
......
......
IAQ
(PPM
)nv
oPPM
......
......
......
......
......
...SN
VT_p
pm...
......
......
POIN
T54
.....
R...
......
......
......
....I
AQ (P
PM)
nviC
OUN
T1...
......
......
......
......
.SN
VT_c
ount
......
......
.PO
INT5
5...
..W
......
......
......
......
Gen
eric
ana
log
or d
iscr
ete
(0-6
5535
)nv
oCO
UNT1
......
......
......
......
...SN
VT_c
ount
......
......
.PO
INT5
6...
..R
......
......
......
......
.Gen
eric
ana
log
or d
iscr
ete
(0-6
5535
)nv
oCO
UNT2
......
......
......
......
...SN
VT_c
ount
......
......
.PO
INT5
7...
..R
......
......
......
......
.Gen
eric
ana
log
or d
iscr
ete
(0-6
5535
)nv
oCO
UNTi
nc1
......
......
......
.....
SNVT
_cou
nt_i
nc...
...PO
INT5
8...
..R
......
......
......
......
.Gen
eric
ana
log
or d
iscr
ete
(-327
67 - 3
2767
)nv
oCO
UNTi
nc2
......
......
......
.....
SNVT
_cou
nt_i
nc...
...PO
INT5
9...
..R
......
......
......
......
.Gen
eric
ana
log
or d
iscr
ete
(-327
67 - 3
2767
)
76
Index
77
Index
AAddress and Baud Rate 5
BBaud Rate and Address 5
CChiller Maintenance Table 1 45Chiller Maintenance Table 2 48Chiller Mapping Table 1 16Chiller Mapping Table 2 21Chiller Template
points in 4CHLRMAP1 Table 16CHLRMAP2 Table 21CHLRMNT1 Table 45CHLRMNT2 Table 48Commissioning
on the LonWorks Network 12COMMSTAT Table 59Communication Status Maintenance
Table 59CONFIG Table 13Configuration
procedure for 9Configuration Table 13Configuration Tables 9
EErrors
mapping 11
GGeneric Maintenance Table 1 55Generic Maintenance Table 2 57Generic Mapping Table 1 36Generic Mapping Table 2 40Generic Template
points in 5GNRCMAP1 Table 36GNRCMAP2 Table 40GNRCMNT1 Table 55GNRCMNT2 Table 57
LLED Indicators 5
MMaintenance Tables 45Mapping Errors 11Messages Maintenance Table 61MESSAGES Table 61
RRooftop Maintenance Table 2 52Rooftop Template
points in 4RTUMNT1 Table 50RTUMNT2 Table 52
78
808 - 335 Rev. 06/16