XTM Configurator. Introduction Page 3. Theory of Operation *3. Configuration Procedures 7

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1 FANs 636.4, XTM/XPx Section Technical Bulletin Issue Date 0400 XTM Configurator Introduction Page 3 Theory of Operation *3 Configuration Procedures 7 Design Considerations 8 Start XTM Configurator *9 Set Program Language Files *9 Hardware Sets *12 XTM-105 Item Settings 15 XTM-105 Type Settings 18 Analog Input (AI) 20 Binary Input 26 Analog Output Configuration 33 Binary Output Configuration *34 Downloading Procedures 41 Operator Workstation *41 Standalone Mode 42 Through an N30 Supervisory Controller *45 Appendix A: Configuration Items Reference Table 47 Appendix B: Module Panel Labels 49 XTM Label Template Access 50 Printer Requirements 51 *Indicates those sections where changes have occurred since the last printing Johnson Controls, Inc. 1 Code No. LIT

2 Appendix C: Ordering Information 53 Model Codes *53 *Indicates those sections where changes have occurred since the last printing. 2 XTM/XPx XTM Configurator

3 Introduction Theory of Operation Hardware Sets and Files Items The XTM Configurator software tool creates configuration files for the XTM-105 Extension and XPx-xxx Expansion Modules. XTM Extension Modules store configuration data and handle N2 Bus communications. There are several types of XPx Expansion Modules that provide various combinations of inputs and outputs (analog, binary, and multistate) to the supervisory system, Metasys Operator Workstation (OWS) or Companion /Facilitator via the N2 Bus. For more information on the XTM/XPx hardware, refer to the XTM-105 Extension Module, XPx-xxx Expansion Modules Technical Bulletin (LIT ). The XTM Configurator is a standalone Windows -based program included with the M-Tool software package. The XTM Configurator, the standard Download Controller feature of the Metasys Operator Workstation (OWS) software, or the Loader User Interface (UI) can be used to directly download configuration files. Defining an XTM configuration involves: defining a hardware set using the number and types of expansion modules connected to the XTM-105 setting configuration item parameters in the XTM-105 A hardware set describes the number and types of expansion modules connected to an XTM-105. A maximum of six XPx modules can be connected to a single XTM-105. Two configuration files are created when a hardware set is saved: hardware file (extension.hmc) software file (extension.dbf) A configuration consists of a parameter set that is stored in XTM-105 memory. Mnemonic names called Items are used to address and reference these memory locations. Each Item represents a specific memory location. Dynamic (changing) data, such as analog values, are stored in Random Access Memory (RAM). XTM/XPx XTM Configurator 3

4 The three categories of Items are: Input values and status Items. These Items can be read but not changed by a supervisory system. Variables. These Items can be read and modified using the XTM Configurator or supervisory systems. Other Items, which contain analog ranges, output type, etc., can only be changed using the XTM Configurator. For example, XTM-105 configuration Items contain specific parameters (e.g., analog and binary input types, etc.) for the extension and expansion module configurations. After defining a hardware set, use the XTM Configurator to enter values for the configuration Items. The.DBF configuration file is automatically updated. For details, refer to Appendix A: Configuration Items Reference Table later in this document. Item Format The information stored in Items has one of several formats: Floating Point Numerical Items Floating Point Numerical Items are real numbers, with a ± sign and decimal point. They refer to input or output values, limit values, etc. Integer Items Integer Items are positive whole numbers used as scale factors. Totalized Numerical Items Totalized Numerical Items are positive whole numbers without a sign or decimal point. They refer to totalized values of pulse counters. Note: When entering real numbers, the XTM Configurator software accepts any value between and Numbers with a modulus greater than 2048 may be rounded up or down by up to 0.1 percent as shown in Table 1. The rounding is due to the external communications bus protocol and could affect accuracy when analog values are read at a supervisory system. This rounding does not affect the precision of the internal control process. Table 1: Rounding Factors Range Rounding (+/-) XTM/XPx XTM Configurator

5 Status Items Status Items give information on the current binary status or configuration of the inputs, outputs, and modules. Item Tag Each Item has a unique, 3- or 4-character name or tag, which is a mnemonic for the type and usage of the data stored at that memory location in the XTM-105. XTM/XPx XTM Configurator 5

6 6 XTM/XPx XTM Configurator

7 Configuration Procedures This section describes how to use the XTM Configurator to configure an XTM-105 Extension Module device set. Figure 1 outlines the configuration procedure. Design Considerations Determine types of expansion modules: Number of Analog Inputs Number of Analog Outputs Number of Binary Inputs Number of Binary Inputs as Counters Number of Binary and Multistate Outputs Define XTM Hardware Set Set Configuration Items Download Configuration File to XTM Hardware Set Figure 1: XTM Configuration Procedure XTM/XPx XTM Configurator 7

8 Design Considerations Table 2 lists the expansion modules available and the number and types of inputs and outputs for each module: Table 2: XPx-xxx Expansion Modules Expansion Modules for Number and Types of Inputs and Outputs XTM-105 Analog Modules XPA-821 Binary and Multistate Modules XPB-821 XPE/L-401 XPE/L-402 XPE/L-403 Binary Modules Note: XPE-404 XPT-401 XPT analog inputs 2 analog outputs 8 binary inputs 4 binary inputs 3 binary outputs (latching or electrically maintained relays) 4 binary inputs 1 binary output (latching or electrically maintained relays) 1 2-stage output (latching or electrically maintained relays) 4 binary inputs 1 3-stage output (latching or electrically maintained relays) 4 binary inputs 4 binary outputs (electrically maintained relays) 4 binary inputs 4 binary outputs (triacs rated at 24 VAC) 8 binary outputs (triacs rated at 24 VAC) The E/L stand for XPE (electrically maintained relays) or XPL (Latching relays). For example, the XTM Configurator shows XPx-4x2, selecting this allows either XPE-402 or XPL-402 to be connected. 8 XTM/XPx XTM Configurator

9 Start XTM Configurator The XTM Configurator can be launched from several locations. To start the XTM Configurator: Select Start > Programs > Configuration Tools > XTM Configurator. XTM Configurator appears (Figure 2). From the Project Builder Tools menu, select N2 Controller Editors > XTM. XTM Configurator appears (Figure 2). From an OWS select Accessories > Custom Applications > XTM Configurator. XTM Configurator appears (Figure 2). Figure 2: XTM Configurator Set Program Language Files English is the installation language. The dialog box and message language can be changed. There are separate language files for each language (i.e., English and German) in the XTM Configurator program directory. These language files are translatable into any language using Windows Notepad. For details, refer to the Translate and Install Language Files section of this document. To set the language: 1. From the About menu, select the Select Language option. The Select Language dialog box appears (Figure 3). XTM/XPx XTM Configurator 9

10 Select Language X Old Language: ENGLISH New Language: DEUTSCH OK Cancel Figure 3: Select Language Dialog Box 2. Choose the new language in the combo box. 3. Click OK in the Select Language dialog box. The message XTM Configurator will be closed, please restart appears. 4. Click OK. The program terminates. The XTM Configurator uses the new language on restart. Translate and Install Language Files The four files for each language are: DATATEXT.xxx MAINTEXT.xxx XTM.xxx XTMTEXT.xxx The extension.xxx is an abbreviation of the language, for example: MAINTEXT.ENG = the English version MAINTEXT.DEU = the German (Deutsch) version For the XTM Configurator to recognize a new language, it is necessary to translate copies of the four language files and modify the XTMCFG.INI file in the Windows directory. 10 XTM/XPx XTM Configurator

11 To do this: 1. Copy the four files for the existing language using a copy utility (e.g., Windows Explorer). The extensions of the new language files are the first three characters of the name of the new language. For example, copy MAINTEXT.ENG to: MAINTEXT.DUT for the DUTch language, or MAINTEXT.FRE for the FREnch language. 2. Edit and translate the new language files using a editor or word processor that stores files in the ANSI character set (e.g., Windows Notepad). Each line of a language file is the in one static field, menu option, button, or one option of a drop-down combo box. In a menu option or button, the ampersand character (&) placed before the underlined character indicates the Alt + character key combination that can be used to select the item. 3. Copy the XTMCFG.INI file (located in the Windows directory) into the same editor used previously. 4. Locate a section in the file similar to the following: [STANDALONE] LANGUAGE=ENGLISH LANGUAGE_0=ENGLISH LANGUAGE_1=DEUTSCH LANGUAGE_2= LANGUAGE_3= LANGUAGE_4= LANGUAGE_5= LANGUAGE_6= LANGUAGE_7= LANGUAGE_8= LANGUAGE_9= 5. Modify the next free language entry to add the new language. For example: LANGUAGE_2=FRENCH When the XTM Configurator restarts, the new language appears in the Select Language dialog box. XTM/XPx XTM Configurator 11

12 Hardware Sets A hardware set contains a description of the number and types of expansion modules connected to an XTM-105. When starting the XTM Configurator, the Hardware Set dialog box appears as the program s main window (Figure 4). Use this dialog box to: create a new hardware set copy a hardware set that has the same XTM and expansion module configuration as the existing set but requires different configuration item settings display an existing hardware set delete a hardware set access the Configuration Items dialog box download configuration files to XTMs set the dialog box language XTM-105 Button. Provides access to the Configurations Items dialog box. Before the XTM file type is saved, the button appears as XTM-xxx. File About XTM Configurator - Hardware Set X XTM-105 XPA-8x1 XPB-8x1 XPE-4x4 XPT-4x1 Analog Modules Module 1 (XP0 / XP0A) XPA-8x1 Module 2 (XP0B) NONE I/O Points AI: 6 AO: 2 BI: 16 BO: 8 MSO: 0 Binary Modules Module 1 (XP1 / XP1A) XPB-8x1 Module 2 (XP1B) NONE Module 3 (XP2 / XP2A) XPE-4x4 Module 4 (XP2B) XPT-4x1 Download New Open Save Exit Figure 4: XTM Configurator Hardware Set Dialog Box The buttons to the right of the XTM-105 button update to show the positions and types of modules currently defined in the set. The I/O Points fields also reflect how many points of each type are included in the configuration. 12 XTM/XPx XTM Configurator

13 Before a hardware set is saved, the XTM-105 button appears gray. After the set is saved the button appears black and provides access to the Configuration Items dialog box. Create a New Hardware Set To create a new hardware set: 1. From the File menu, select New or click the New button. All dialog box options for defining the new hardware set are reset. 2. Starting with the analog modules and working from top to bottom, choose the analog, binary, and multistate expansion modules that are connected to the XTM (Figure 4). Notes: Always choose Module 1 before choosing Module 2 (and Module 3 before 4 for the binary modules) because the software verifies the allowable module positions, which depend on the modules in the previous positions. When physically connecting the expansion modules to the XTM-105 make certain that they are in the order shown by the buttons at the top of the dialog box. The XTM will not communicate to the supervisory systems if the modules are in the wrong order. If there are no analog modules connected to the XTM, the binary inputs of one 8-input or one or two 4-input modules can be used as pulse counters. Set the XTS configuration item to identify the module positions where inputs are used as counters. Refer to the XTM-105 Extension Module, XPx-xxx Expansion Modules Technical Bulletin (LIT ) for details. 3. From the File menu, select Save, or click the Save button, to save the hardware set. The File Open/Save dialog box appears. 4. Select a file name and location. Typically, a name indicates the device s use (e.g., fan3spd) or address on the N2 Bus (e.g., xtm012). 5. Click OK. After saving the hardware set, the program automatically creates and saves a hardware configuration file (.HMC file) and a software configuration file (.DBF file). The software configuration file downloads to the XTM. XTM/XPx XTM Configurator 13

14 6. Click the XTM-105 button, to change the configuration item settings associated with the hardware set. For details, refer to the Set Configuration Items section of this document. Note: Once saved, the hardware set remains loaded in the dialog box and cannot be changed. However, the configuration items associated with the hardware set are modifiable after saving the set. If the XTM type or the expansion module configuration is incorrect, delete the hardware set and create a new hardware set with the correct configuration. For details on deleting hardware sets, refer to the Delete Hardware Set section of this document. Copy Hardware Set Display Existing Hardware Set To create a new hardware set with the same expansion module configuration but different configuration item settings, use a copy of the existing hardware set. The expansion module configuration of the new set is not modifiable. To copy a hardware set: 1. From the File menu, select Open or click the Open button. The File Open/Save dialog box appears. 2. Select the hardware set to copy. 3. Click OK. The Hardware Set dialog box appears (Figure 4). 4. From the File menu, select Save As. 5. Enter a file name and location. The hardware and software configuration files associated with a hardware set copy are saved in the same directory. The.HMC and.dbf file extensions are added automatically to the file names. The hardware configuration appears in the Hardware Set dialog box. 6. Click XTM-105 to change the configuration item settings. For details, refer to Set Configuration Items later in this document. To display an existing hardware set: 1. From the File menu, select Open or click the Open button. The File Open/Save dialog box appears. 2. Select a hardware set. 3. Click OK. The hardware configuration appears in the Hardware Set dialog box. Click XTM-105 to change the associated configuration item settings. 14 XTM/XPx XTM Configurator

15 Delete Hardware Set Access Configuration Items Dialog Box To delete a hardware set file: 1. From the File menu, select Delete. The File Open/Save dialog box appears. 2. Select the hardware set to delete and click OK. 3. Click OK in the message box to delete the set and associated.hmc and.dbf configuration files. To access the Configuration Items dialog box: 1. For a newly defined hardware set (i.e., not saved), save the set by selecting Save from the File menu or clicking the Save button. In the File Open/Save dialog box, enter the file name and location for the new set. If the hardware set already exists, choose the set where the configuration Items are to be modified from the File Open/Save dialog box. 2. Click XTM-105 to bring up the Configuration Items dialog box. The XTM-105 button appears gray and is inactive when there is no configuration displayed in the Hardware Set dialog box or if the configuration has not been saved. The name of the set appears in parentheses in the title bar of the dialog box if it has been saved and/or re-opened. XTM-105 Item Settings I/O Type Map Each extension module configuration is defined by an I/O type map, which is contained in Item memory locations. The Items identify which inputs and outputs (in pairs) are used in each expansion module position (XP0, XP1, and XP2). Items must correspond with the actual expansion modules connected to the extension module or the XTM-105 does not communicate with the supervisory system. The database in the XTM-105 is designed to accept many configurations of inputs and outputs. All inputs and outputs that are physically connected through expansion modules must be configured. XTM/XPx XTM Configurator 15

16 When the XTM-105 is powered up, it automatically reads which XPx modules are connected and compares this data with the I/O type map. Configuration errors are indicated by flashing Light-Emitting Diodes (LEDs). Table 3 contains information about interpreting the LED status. Table 3: LED Signals for XTM-105 Communication and Status XTM-105 Communication and Error LED Indication Status Good communications with supervisory system. No configuration errors. Configuration error or power watchdog error. No communication with a supervisory system. Power LED lights up continuously. Power LED blinks at a frequency of about twice per second. Power LED blinks at a frequency of about once per second. Configuration Items Dialog Box After defining the hardware set, enter values for the device s configuration Items in the Configuration Items dialog box (Figure 5). The configuration item settings are stored in the.dbf configuration file associated with the hardware set. When creating the hardware set, a configuration file containing default settings for the configuration Items is also created. Note: The terms binary and digital are interchangeable. There are up to eight inputs and/or outputs for each module or module pair (XP0, XP1, XP2) as follows: AI1-AI8 AO1-AO8 DI1-DI8 DO1-DO8 Analog Inputs Analog Outputs Binary Inputs Binary Outputs Multistate outputs are always defined by the first binary output used, (i.e., DO1 or DO5). Clicking XTM-105 opens the Configuration Items dialog box (Figure 5). 16 XTM/XPx XTM Configurator

17 Configuration Items (xtm005) CNT1 CNT2 CNT3 CNT4 CNT5 CNT6 CNT7 CNT8 X PC1 DIT1 PC2 DIT2 PC3 PC4 PC5 PC6 PC7 PC8 DIPS NOC1 NOC2 XTS COL1 COL2 MOE1 MOE2 MOS1 MOS2 MTBC DOT1 AIT1 AIT2 AIT3 AIT4 AIT5 DOT2 HR1 HR2 HR3 HR4 HR5 DOPT DOR1 DOR2 AOT LR1 HIA1 LOA1 ADF1 FTC1 OFS1 LR2 HIA2 LOA2 ADF2 FTC2 OFS2 LR3 HIA3 LOA3 ADF3 FTC3 OFS3 LR4 HIA4 LOA4 ADF4 FTC4 OFS4 LR5 HIA5 LOA5 ADF5 FTC5 OFS5 CNT1 AIT6 CNT2 HR6 CNT3 LR6 CNT4 HIA6 LOA6 CNT5 CNT6 ADF6 CNT7 FTC6 CNT8 OFS6 AIT7 AIT8 AOR1 HR7 HR8 AOR2 LR7 HIA7 LOA7 ADF7 FTC7 OFS7 LR8 HIA8 LOA8 ADF8 FTC8 OFS8 AOR3 AOR4 AOR5 AOR6 AOR7 AOR8 Close Figure 5: Configuration Items Dialog Box Each button within the dialog box is labeled with the abbreviated name of a configuration item. Refer to Appendix A: Configuration Items Reference Table for a list of abbreviations. Configuration Items not required for the current hardware set appear gray. The gray Items associated with counters (CNT1-8, PC1-8, COL1-2) correspond to the entry under Counters in the XTM Type Settings dialog box. Set Configuration Items To set configuration Items: 1. In the Configuration Items dialog box, click the item to set. 2. Specify the Items settings. There are separate dialog boxes for each type of configuration item. 3. Click OK. The new settings are immediately stored in the.dbf configuration file. Note: No separate save operation is required when setting configuration Items. 4. Click Close in the Configuration Items dialog box. 5. Download the.dbf configuration file to the device. For details, refer to Downloading Procedures later in this document. XTM/XPx XTM Configurator 17

18 XTM-105 Type Settings XTS The following user-defined options are available through the XTS Item. To set the XTM type settings, click XTS. The XTM Type Settings dialog box appears (Figure 6). XTM Type Settings X Power Line Binary Outputs Counters 50 Hz 60 Hz OK Reset on comm. failure Hold on comm. failure Cancel NONE on XP1 or XP1A on XP1B on XP2 or XP2A on XP2B on XP1A and XP1B on XP2A and XP2B Figure 6: Dialog Box for XTM Type Settings Power Line To change the power line frequency, click the appropriate frequency button under Power Line. The default is 60 Hz. Binary Outputs There are two options for binary outputs: Reset on comm. failure and Hold on comm. failure. Reset on comm. failure switches off or resets the outputs upon a supervisory system communication failure. Use this setting, for example, to discontinue electric heat in the absence of airflow (i.e., when the GPL headend command is lost and the status of the fan is unknown). Hold on comm. failure is the default. Click it for the outputs to hold their current state upon a supervisory system communication failure. Use this setting for lighting control, for instance, so the lights would stay on in the event of communication loss. 18 XTM/XPx XTM Configurator

19 Counters Click one of the following buttons under Counters to select the expansion modules from which the inputs are to be taken. Note: When configuring an XTM, counters are definable for the binary inputs of one or two XPx modules. Counters can only be configured in the XTM if there are no modules installed in the XP0 (analog) position. For configuration details, refer to Counters under the Binary Input section of this document. Maximum Time Between Communications (MTBC) To set the maximum time between communications, click MTBC. The Maximum Time Between Communications dialog box appears (Figure 7). Maximum Time Between Communications X MTBC 60 Sec. OK Cancel Figure 7: Maximum Time Between Communications Dialog Box The default and suggested value is 60 seconds. The valid range is 0 to 65,535 seconds. When communication fails, the XTM-105 goes into a communication failure state, indicated by a blinking power LED (at a frequency of about once per second) on the front of the module. If there is a configuration error or power watchdog error, the power LED blinks at a frequency of about twice per second. In addition, outputs reset or maintain the last commanded condition, depending upon the setting in Item XTS. XTM/XPx XTM Configurator 19

20 Analog Input (AI) Input Type Range High/Low Alarm Limits A maximum of eight AIs can be connected to an XTM-105 depending on the configuration. Each analog input is defined and configured by the following parameters: input type range high and low limits differential filter time constant offset (inactive on the XPA-821) The input type for each of the eight possible inputs are configured in Items AITn (n represents 1 to 8). For active inputs, a numeric value expressed in engineering units is obtained using the input s high range at Items HRn and the input s low range at Items LRn. The high range value is required only for active and potentiometer sensor inputs. The high range gives the physical value that corresponds to the highest input (10V or 20 ma). The low range value is required only for active and potentiometer sensor inputs. It also gives the physical value, corresponding to the lowest input (0 or 2V, 0 or 4 ma). When selecting the Enable Square Root of Input in Item AIT, the low range default value of 0 must not be changed. For RTD inputs, the range of the temperature value is fixed according to the type of sensor and the units of measurement. The high alarm limits at Items HIAn and the low alarm limits at Items LOAn, define at which levels the analog input reading generates an alarm for remote monitoring. These Items may also be set by a supervisory system online. However, they can only be written approximately 10,000 times. The supervisory system writes new limits whenever the XTM comes online or when the AI point is added or modified. The supervisory system overwrites any limits entered by the XTM Configurator. The low limit value defines the level at which the corresponding analog input reading generates a low limit alarm for remote monitoring. 20 XTM/XPx XTM Configurator

21 Differential Filter Time Constant Square Root Offset The differentials on alarm limits are adjustable with Items ADFn. These Items are set by a supervisory system online. However, they can only be written approximately 10,000 times. When the XTM comes online to the supervisory system or the AI point is added or modified, these values are written to the Item locations. The alarm limit differential determines the change required (in the analog input value below the high alarm limit or above the low alarm limit) for the input to return to the normal state. The filter time constants, T s (in seconds), are defined in Items FTCn. The filter time constant is defined in seconds. A value of zero disables the filter. A configurable filter is incorporated for the reduction of signal instability. The filter function is: FV t 1 = FVt + + t 1 T ( AI FV ) 1 t 1 s where: FV t = Filtered Analog Value at current time FV t-1 = Filtered Analog Value at previous poll AI t T s = Actual Analog Value at current time = Filter Time Constant (seconds) Voltage and current inputs from a differential pressure sensor can be linearized by a square root function, which operates over the complete range of the input according to the following equation: % PR AI = ( HR LR ) + LR 100 where %PR = the analog value in percentage of the physical range (0-10V, 0-20 ma, 4-20 ma). An offset in the units of the analog input are defined in Items OFSn. This option is valid for the XPA-421 only, which is currently unavailable in the Americas. The offset is used to compensate for analog transmitters, which do not have a true zero output or for wiring resistance to RTD sensors. The offset value is added to the analog value calculated from the range parameters. XTM/XPx XTM Configurator 21

22 AIT1-AIT8 To set the parameters for the corresponding analog input, click AITn. The Input Type of Analog Input 1 dialog box appears (Figure 8). Input Type of Analog Input 1 X Linearization and Sensor Type: Linear (active sensor) Input Type: 0-10V or Potentiometer Enable Square Root of Input 20% Suppression Alarm on Unfiltered Value Measurement Units: None OK RTD Connection: 2- or 4-wire XPA-4x1 Cancel Figure 8: Input Type of Analog Input 1 Dialog Box The dialog box contains four drop-down menus. 1. From the Linearization and Sensor Type menu, select one of the following: For XPA-821: Linear (active sensor) Nickel 1000 Sensor (JCI) Nickel 1000 Extended Range (JCI), A99 Sensor (JCI) PT 1000 Sensor (DIN) 2. If the Linear (active sensor) was chosen, select the Input Type as 0-10V for a voltage input, or 0-20 ma or RTD for a current input. If one of the passive inputs was selected, the Input Type automatically defaults to 0-20 ma or RTD. 3. If one of the passive sensor types was chosen, select the Measurement Units as Degrees Celsius (RTD) or Degrees Fahrenheit (RTD). 4. Select the type of RTD Connection as 2-or 4-wire XPA-4x1 or 3-wire XPA-4x1. Make certain that these selections correspond with the physical installation. 5. To apply a square root function to a Linear (active sensor) input, select Enable Square Root of Input. 22 XTM/XPx XTM Configurator

23 6. To convert a 0-10V input into a 2-10V input or a 0-20 ma input into a 4-20 ma input, select 20% Suppression. 7. Select Alarm on Unfiltered Value for all input types for the alarm detection to remain on the raw analog input value when a filter time constant has been defined for this input in Item FTC. HR1-HR8 To set the high range value for the corresponding analog input, click HR1-HR8. The High Range Analog Input 1 dialog box appears (Figure 9). High Range Analog Input 1 X HR1 100 OK Cancel Figure 9: High Range Analog Input Dialog Box The default value is 100. The valid range is +/-32,750.nnn. LR1-LR8 To set the low range value for the corresponding analog input, click LRn. The Low Range Analog Input 1 dialog box appears (Figure 10). Low Range Analog Input 1 X LR1 0 OK Cancel Figure 10: Low Range Analog Input 1 Dialog Box When selecting the Enable Square Root of Input in Item AIT, the default value of 0 must not be changed. The range is +/ nnn. XTM/XPx XTM Configurator 23

24 HIA1-HIA8 To set the high alarm limit for the corresponding analog input, click HIAn. The High Alarm Limit Analog Input 1 dialog box appears (Figure 11). High Alarm Limit Analog Input 1 X HIA1 100 OK Cancel Figure 11: High Alarm Limit Analog Input Dialog Box The high limit value defines the level at which the corresponding analog input reading generates a high limit alarm for remote monitoring. The valid range is +/ nnn. LOA1-LOA8 To set the low alarm limit for the corresponding analog input, click LOAn. The Low Alarm Limit Analog Input 1 dialog box appears (Figure 12). The range is +/ nnn. Low Alarm Limit Analog Input 1 X LOA1 0 OK Cancel Figure 12: Low Alarm Limit Analog Input Dialog Box Note: A supervisory system writes new limits to the controller whenever the XTM-105 comes online or when the AI object (point) is added or modified. IMPORTANT: The limits entered in the AI object overwrite the limits entered in the XTM Configurator. Writing these values in a cyclic process may damage the EEPROM. 24 XTM/XPx XTM Configurator

25 ADF1-ADF8 To set the alarm limit differential for the corresponding analog input, click ADFn. The Differential on Alarm Limit dialog box appears (Figure 13). The valid range is nnn. Differential on Alarm Limit X ADF1 1 OK Cancel Figure 13: Differential on Alarm Limits Dialog Box FTC1-FTC8 To set the filter time constant for the corresponding analog input, click FTCn. The Filter Constant Analog Input 1 dialog box appears (Figure 14). The valid range is Filter Constant Analog Input 1 X FTC1 0 OK Cancel Figure 14: Filter Constant Analog Input Dialog Box XTM/XPx XTM Configurator 25

26 OFS1-OFS8 To set the offset value for the corresponding analog input, click OFSn. This option is valid for XPA-421 only. The Offset Analog Input 1 dialog box appears (Figure 15). Offset Analog Input 1 X OFS1 0 OK Cancel Figure 15: Offset Analog Input Dialog Box The valid range is +/ nnn. Binary Input Input Types An XTM-105 can accept up to 16 binary inputs, depending on hardware configuration. The first eight binary inputs are connected in position XP1 and the next eight binary inputs in XP2. The input types for the 2 x 8 possible inputs are configured in Item DIT1 for XP1 (A and B), and in Item DIT2 for XP2 (A and B). Select Maintained or Pulse. Maintained or Pulse Contact Maintained contact types are configured in Item DITn. With maintained type contacts, the XTM-105 status follows the status of the contact. With pulse type contacts, the XTM-105 sets and resets the status at each pulse of the input contact. Pulse contacts are recommended only for functions, such as lighting control, where the user gets confirmation of the override request by a verifiable response (Figure 16). Contact XTM Status Contact XTM Status Maintained Pulse 1 0 Figure 16: Maintained and Pulse Type Contacts 26 XTM/XPx XTM Configurator

27 Maintained Contact Latch When set to Enabled, any state change of the input contact is latched until read by a supervisory system. When set to Disabled, the new binary input contact state must be present when read by the supervisory system for a Change-of-State (COS) to be detected. The XTM-105 module, by default, latches a COS in any binary input configured as maintained type until it is read by a supervisory system. The Maintained Contact Latch function is disabled in Item DIPS. Note: When this function is disabled, a COS of short duration (less than the supervisory system read/scan cycle) may not be reported to the supervisory system. Pulse Contact Buffer When the binary input is configured as a pulse contact type, the XTM-105 module can be configured to remember more than one COS between successive read commands from the supervisory system. The oldest COS stored in the buffer is reported and then deleted whenever a read command is received from the supervisory system. The Pulse Input Buffer size is set in Item DIPS. Entering 0 causes the XTM-105 to remember only one pulse input (or state change) until the supervisory systems reads the status of the binary input. The 0 entry ensures that the supervisory system receives an input state change before it resets locally. Entering 1 causes the XTM-105 to remember up to two pulses. If two pulses are registered before the supervisory system reads a binary input, the binary input changes state on the first subsequent read and returns to the previous state on the second subsequent read. An entry of 1 also enables an input state change to reset locally without waiting for a supervisory system read. However, both changes are reported at the supervisory system. Normally Open/Closed The normally open/normally closed contact type for each binary input is configured in Item NOC1 for XP1 (A and B) and in Item NOC2 for XP2 (A and B). For normally open contacts, the binary input is active when the contact is closed. For normally closed contacts, the binary input is active when the contact is open. XTM/XPx XTM Configurator 27

28 Counters DIT1-DIT2 Counters are defined for four or eight binary inputs in Item XTS as follows: XP1 (8 points) or XP1A (4 points) XP1B only (4 points) XP2 (8 points) or XP2A (4 points) XP2B only (4 points) XP1A and XP1B (8 points) XP2A and XP2B (8 points) If counters are defined for a 4-point module the counter Items are CNT1-CNT4 for an A-position module or CNT5-CNT8 for a B-position module. Note: Counters are only configurable in the XTM-105 if there are no modules installed in the XP0 (analog) position. To set the input type for DI1-DI8 on XP1 (A/B), click the DIT1 button. The Binary Input Type XP1 (A/B) dialog box appears (Figure 17). To set the input type for DI1-DI8 on XP2 (A/B), click the DIT2 button. The Binary Input Type XP2 (A/B) dialog box appears. Binary Input Type XP1 (A/B) X DI1: Maintained Contact DI5: Pulse Contact DI2: Maintained Contact DI6: Maintained Contact DI3: Maintained Contact DI7: Maintained Contact DI4: Maintained Contact DI8: Pulse Contact OK Cancel Figure 17: Binary Input Type XP1 Dialog Box Click the drop-down menu for each input and select Maintained Contact or Pulse Contact. 28 XTM/XPx XTM Configurator

29 NOC1-NOC2 To set the normally open or normally closed contact type for DI1-DI8 on XP1 (A/B), click NOC1. The Normally Open/Closed Contact XP1 (A/B) dialog box appears (Figure 18). To set the normally open or normally closed type for DI1-DI8 on XP2 (A/B), click NOC2. The Normally Open/Closed Contact XP1 (A/B) dialog box appears. Normally Open/Closed Contact XP1 (A/B) X DI1: Normally Open DI5: Normally Closed DI2: Normally Open DI6: Normally Closed DI3: Normally Closed DI7: Normally Closed DI4: Normally Closed DI8: Normally Open OK Cancel Figure 18: Normally Open/Closed Contact XP1 (A/B) Dialog Box Click the drop-down menu for each input and select either Normally Open or Normally Closed. XTM/XPx XTM Configurator 29

30 DIPS Click DIPS in the Configuration Items dialog box to open the Binary Input Parameter Settings dialog box (Figure 19). Binary Input Parameter Settings X Pulse Contact Buffer: 0 0 = Allow only one state change (pulse) until BI status is read 1 = Allow up to two state changes (pulses) between successive BI status reads Maintained Contact Latch: Enabled Enabled = Latch input change until BI status is read OK Cancel Figure 19: Binary Input Parameter Settings 1. Set the Pulse Contact Buffer to 0 or Set the Maintained Contact Latch to Enabled or Disabled. The binary input transitions are counted as follows: Binary Input Prescaler PCn Count Transition Pulse Counter CNTn Figure 20: Binary Input Transitions Prescaler A count transition occurs when the number of positive transitions of the binary input equals the value of the Prescaler (PCn). The Pulse Counter Items (CNTn, n=1-8, 1-4 or 5-8) accumulate the count transitions. Counter Limit The counter limit (or rollover value) is set in Item COL1 for counters CNT1-4 and in Item COL2 for counter CNT 5-8. Select the maximum (4 bytes) counter limit only when the supervisory system can reset the counter to zero at its own rollover value or the counter is only used to determine a rate of change (where the counter increment is read regularly). For supervisory systems, the value of counters that have been configured are read and set at Items CNTn (n=1-8). 30 XTM/XPx XTM Configurator

31 PC1-PC8 To set the prescaler for the counter on binary inputs DI1-DI8: 1. Click PCn to open the Prescaler DI1 Counter dialog box (Figure 21). Prescaler DI1 Counter X PC1 255 OK C ancel Figure 21: Prescaler Dialog Box 2. Enter the prescaler value within the range CNT1-CNT8 To preset the pulse count for binary inputs DI1-DI8: 1. Click the CNTn button to open the DI1 Pulse Count dialog box (Figure 22). DI1 Pulse Count X CNT1 0,000,000 OK Cancel Figure 22: DI1 Pulse Count Dialog Box 2. Enter the pulse count value at which the counter starts after a download. XTM/XPx XTM Configurator 31

32 COL1-COL2 To set the counter limit for CNT1-CNT4, click COL. The Counter Limit CNT1-CNT4 dialog box appears (Figure 23). To set the counter limit for CNT5-CNT8, click COL2. The Counter Limit CNT5-CNT8 dialog box appears. Counter Limit CNT1-CNT4 X CNT1: Maximum (4 bytes) CNT3: 999,999 CNT2: 9,999 CNT4: 9,999,999 OK Cancel Figure 23: Counter Limit Dialog Box 1. For each counter, choose the value at which the counter (CNT1-CNT4) rolls over to zero. 2. Select the maximum rollover value (4 bytes) only when the supervisory system resets the counter to zero at its own rollover value or reads only the count increment on a regular basis. 32 XTM/XPx XTM Configurator

33 Analog Output Configuration Analog Output Ramp Time The output type is configured in Item AOT for Outputs 1-8, respectively. A maximum of eight AOs can be connected to an XTM-105 depending on configuration. For supervisory systems, the value of analog outputs that have been configured are read and set in percentages. The Analog Output Ramp Time is entered in Item AORn. The value entered determines the time required (increments of 5 milliseconds) for a 1% change in the analog output value in both manual and automatic modes. For example, to change the output 1% per second (0-100% in 100 seconds) enter 200 (200 x 5 milliseconds = 1%). A value of 0 disables the ramp function. AOT To set the type of analog outputs AO1-AO8, click AOT. The Analog Output Type dialog box appears (Figure 24). Analog Output Type X AO1: 0 to 10V AO5: Disabled AO2: 0 to 10V AO6: 0 to 20 ma AO3: 0 to 10V AO7: Disabled AO4: 0 to 10V AO8: 4 to 20 ma OK Cancel Figure 24: Analog Output Type Dialog Box 1. Click the drop-down menu for each output and select Disabled, 0 to 10V, 0 to 20 ma, or 4 to 20 ma depending on the requirements of the physical installation. 2. Make certain that the hardware jumper matches the software setting. Refer to the XTM-105 Extension Module, XPx-xxx Expansion Modules Technical Bulletin (LIT ) for jumper settings. XTM/XPx XTM Configurator 33

34 AOR1-AOR8 To set the ramp time for the corresponding analog output, click AOR1-AOR8. The Analog Output 5 Ramp Time dialog box appears (Figure 25). Analog Output 5 Ramp Time X AOR5 0 *5 msec for 1% change OK Cancel Figure 25: Analog Output Ramp Time Dialog Box The valid range is Binary Output Configuration A maximum of 16 binary outputs can be connected to an XTM-105 depending on configuration. The type of output is set in Item DOT1 for XP1 (A and B) and Item DOT2 for XP2 (A and B). Note: This setting is only required for binary outputs on XPE-404, XPT-401, and XPT-861 modules. For XPL and other XPE modules, the type of output is determined by the module. With an ON/OFF Type, the output relay or triac closes or opens alternately on each command with a maintained electric signal. With a Pulse Type, the output relay or triac closes and opens (pulses) on each command (Figure 26) with a momentary signal. 34 XTM/XPx XTM Configurator

35 Pulse Time The pulse length is set in Item DOPT. It determines how long an output relay or triac (configured as a pulse type) closes. Values are multiplied by 5 milliseconds (msec). For all other binary and multistate output modules, the setting has no influence on the operation of the binary outputs. The binary output pulse time applies to XPE-404, XPT-401, and XPT-861 modules configured with pulse type outputs to determine the output pulse width. On/Off Command Relay or Triac Pulse Command Realy or Triac t=dopt Figure 26: On/Off and Pulse Type Relay or Triac Restore Mode Manual Override The Restore mode for each output is defined in Item DOR1 for XP1 (A and B) and Item DOR2 for XP2 (A and B). Reset to 0 at power up, causes the output relay or triac to open when power is restored after a power failure. Restore at power up causes the output relay or triac to return to the condition it had before power failure. Note: The Restore mode only applies to XPE-401, XPE-402, and XPE-403 modules. The Manual Override Enable mode for each output on a module with the manual override feature is defined in Item MOE1 for XP1 (A/B) and Item MOE2 for XP2 (A/B). Select Standalone Only to disable the manual override function when the supervisory system is active. Override switches on the XPx-xxx are ignored. The manual override status display for each output on a module with the manual override feature is defined in Item MOS1 for XP1 (A/B) and Item MOS2 for XP2 (A/B). The Manual Override Command causes the LEDs to show the position of the manual override switches during manual override and non-manual override as well as the correct status when commanded from the supervisory system. Selecting Supervisory Command causes the LEDs to show the command from the supervisory system, regardless of the manual override setting. XTM/XPx XTM Configurator 35

36 DOT1-DOT2 To select the type of digital outputs DO1-8 on XP1, click DOT1. The Binary Output Type XP1 (A/B) dialog box appears (Figure 27). To select the type of digital outputs DO1-8 on XP2, click DOT2. The Binary Output Type XP2 (A/B) dialog box appears. Binary Output Type XP1 (A/B) X DO1: ON/OFF Type DO5: ON/OFF Type DO2: ON/OFF Type DO6: ON/OFF Type DO3: ON/OFF Type DO7: ON/OFF Type DO4: ON/OFF Type DO8: Pulse Type or XPM/L/E OK Cancel Figure 27: Binary Output Type Dialog Box Click the drop-down menu for each output and select ON/OFF Type or Pulse Type. XTM-101 This entry is not used by the XTM-101, and can be left at the default setting. The type of output is determined only by the connected multistate output module (XPM, XPL, or XPE). XTM-105 For XPM-4xx, XPL-4xx, XPE-4x1, XPE-4x2, and XPE-4x3 modules, select ON/OFF type to enable the restore mode of operation (refer to DOR1-DOR2). The digital output type of these modules is a function of the product code and not of the software configuration. Either selection option is valid for the binary modules XPE-4x4, XPT-4x1, and XPT-8x1, which may only be connected to the XTM-105. When an ON/OFF Type is selected, the output relay or triac closes following the ON command and opens following the OFF command. When a Pulse Type is selected, the output relay or triac closes and opens (pulses) on each command. The pulse length is set in Item DOPT (see below). 36 XTM/XPx XTM Configurator

37 DOPT To set the binary output pulse time, click DOPT. The Binary Output Pulse Time dialog box appears (Figure 28). Binary Output Pulse Time (*5 msec) X DOPT 4 *5 msec. OK Cancel Figure 28: Binary Output Pulse Time Dialog Box Enter a value that is a multiple of 5 msec. The default value is 4 (20 msec). The valid range is DOR1 Note: For the XTM-105, the restore mode function applies only to binary outputs set as ON/OFF Type in Items DOT1 or DOT2. Binary outputs set to Pulse Type do not respond to the Restore mode setting. To set the Restore mode for binary outputs DO1-DO8 on XP1, click DOR1. The Binary Output Restore XP1 (A/B) dialog box appears (Figure 29). Click the drop-down menu for each output and select either Reset to 0 at power up or Restore at power up. XTM/XPx XTM Configurator 37

38 To set the Restore mode for binary outputs DO1-DO8 on XP2, click DOR2. The Binary Output Restore XP2 (A/B) dialog box appears. Binary Output Restore XP1 (A/B) X DO1: Reset to 0 at power up DO5: Reset to 0 at power up DO2: Restore at power up DO6: Restore at power up DO3: Restore at power up DO7: Restore at power up DO4: Restore at power up DO8: Restore at power up OK Cancel Figure 29: Binary Output Restore XP1 (A/B) Dialog Box MOE1-MOE2 To enable manual override for DO1-DO8 on XP1 (A/B), click MOE1. The Manual Override Enable XP1 (A/B) dialog box appears (Figure 30). To enable manual override for DO1-DO8 on XP2 (A/B), click the MOE2. The Manual Override Enable XP2 (A/B) dialog box appears. Manual Override Enable XP1 (A/B) X DO1: Standalone Only DO5: Standalone Only DO2: Supervisory and Standalone DO6: Supervisory and Standalone DO3: Standalone Only DO7: Standalone Only DO4: Supervisory and Standalone DO8: Supervisory and Standalone OK Cancel Figure 30: Manual Override Enable XP1 (A/B) Dialog Box 38 XTM/XPx XTM Configurator

39 MOS1-MOS2 To set the manual override status display for DO1-DO8 on XP1 (A/B), click MOS1. The Manual Override Status Display XP1 (A/B) dialog box appears (Figure 31). To set the manual override status display for DO1-DO8 on XP2 (A/B), click MOS2. The Manual Override Status Display XP2 (A/B) dialog box appears. Manual Override Status Display XP1 (A/B) X DO1: Manual Override Command DO5: Manual Override Command DO2: Supervisory Command DO6: Supervisory Command DO3: Supervisory Command DO7: Manual Override Command DO4: Supervisory Command DO8: Supervisory Command OK Cancel Figure 31: Manual Override Status Display XP1 (A/B) Dialog Box Select either Supervisory Command or Manual Override Command. XTM/XPx XTM Configurator 39

40 40 XTM/XPx XTM Configurator

41 Downloading Procedures This section describes the procedures for downloading the XTM-105 configuration files to the hardware device using either the Metasys OWS (Supervisory mode) or the XTM Configurator (Standalone mode). Operator Workstation After creating a hardware set and entering the configuration Items for an XTM device, the configuration files are downloaded to the device online at the OWS. This requires the download to go through the Network Control Module (NCM). Therefore, it is necessary to install the device on the appropriate NCM N2 Bus and create a new hardware object for the device at the OWS. To do this: 1. Install and connect the expansion modules and XTM-105 module as defined in the hardware set. 2. Connect the XTM-105 module to the N2 Bus, making sure to set the correct address on the module s address DIP switches. 3. Verify that the configuration in the file and the hardware configuration are identical. 4. If the.dbf configuration file is not on the OWS PC, copy the file and save it in the C:\FMS\DATA\SYSTEM91 directory for easiest retrieval. When using the PREP-FOR tool to load the program, it is recommended to save the file in the C:\PROJECT\Contract#\SYSTEM91 directory. 5. Create a new hardware object for the XTM-105 at the OWS. For details on creating hardware objects, refer to Defining Objects in the Operator s Guide of the Operator Workstation User s Manual (FAN 634). 6. Display the Focus window for the new XTM-105 hardware object. 7. From the Metasys OWS Action menu, select the Download Controller option. 8. In the Download Controller dialog box, select the.dbf configuration file from the list box. 9. Click OK. The download begins. Configuration files are downloaded to only one XTM-105 device at a time. If an offline condition occurs after the download is complete, check all module connections and verify that the configuration files match the installed hardware. Repeat Steps 1-9 for each device that is to receive the same file. XTM/XPx XTM Configurator 41

42 For details on downloading configuration files to System 9100 devices, refer to Uploading and Downloading Databases in the Advanced User s Guide of the Operator Workstation User s Manual (FAN 634) or to the Uploading and Downloading Databases Technical Bulletin (LIT ). Standalone Mode When running the XTM Configurator in Standalone mode, configuration files are downloaded directly to one or more XTM-105 devices via the PC serial port. Since the PC serial port uses RS-232 signals and the N2 Bus uses RS-485 signals, it is necessary to connect a converter module the serial port and the XTM devices. The converter (MM-CVT101-0) is available from Johnson Controls Acquisition Services. The device can be disconnected from the converter for transport and installation. N2 Bus Connections The converter provides normal N2 Bus terminals for connecting one or more XTMs using the standard N2 Bus wiring scheme (daisy-chained). Table 4 compares the N2 Bus terminals labels for the converter module and the XTM. Table 4: Terminal Labels for N2 Bus RS-485 Signal MM-CVT101 XTM + N2 + RT + - N2 - RT - Reference REF COM (or C) MM-CVT101 Converter s RS-232 Connection The MM-CVT101 converter has a 25-pin female connector on the body of the converter that plugs-into a 25-pin serial port on the PC directly. PCs with only 9-pin serial ports require a 9-pin female to 25-pin male straight through cable (or converter plug) between the serial port and the MM-CVT101. For details, refer to the Metasys Companion Technical Manual (FAN 628.1). 42 XTM/XPx XTM Configurator

43 XTM Download Dialog Box To download in Standalone mode, click Download in the Hardware Set dialog box. The XTM Download dialog box appears (Figure 32). XTM Download X Use this dialog to download configuration files to XTMs. Choose a file and serial port, enter the XTM addresses, then press Download. XTM File: XTM012.DBF XTM001.DBF XTM002.DBF XTM007.DBF XTM008.DBF XTM012.DBF Directory: c:\fms\data c: fms data system91 hvacpro Serial Port COM 1 COM 2 Download XTM Address(es) (ex. 1,2,4-8) 2, 5, 6, 8-12 Drive: c: C ancel Figure 32: XTM Download Dialog Box To download a configuration file to one or more XTM-105 devices: 1. Set up the hardware at the Personal Computer (PC). a. Connect the converter module to the PC serial port (COM 1 or COM 2). b. Install and connect expansion modules to the XTM-105 (as defined in the hardware set) using the DIP switch of each XTM-105 module to set the hardware address on the N2 Bus. These addresses are the hardware addresses of the XTM-105s on the N2 Bus. Before starting the download, verify that the file configuration and the XTM-105 device set hardware configurations are identical. c. Connect the XTM-105 to the converter module s N2 Bus. d. Supply each XTM-105 with the proper voltage (24V). 2. Select the.dbf configuration file to download. 3. Type one or more addresses in the XTM address box. Note: To enter more than one address, use a comma to separate addresses (e.g., 2,4,8). To enter a range of addresses, use a dash to separate the first and last address of the range (e.g., 4-8). Combine both formats for multiple addresses (e.g., 1-5,8,10,12). The same configuration file is downloaded to each XTM-105 with a corresponding address. XTM/XPx XTM Configurator 43

44 4. Select the PC serial port (COM 1 or COM 2) to which the converter is connected. 5. To start the download operation, click Download. The RD (Receive Data) LED flashes as the device receives data (flashing occurs quickly because the transmission is very short). If the data does not transmit, verify all connections and addresses. For details on XTM-105 hardware connections and the address switches, refer to the XTM-105 Extension Module, XPx-xxx Expansion Modules Technical Bulletin (LIT ). Note: The configuration parameters are stored in the XTM-105 non-volatile Electrically Erasable Programmable Read-only Memory (EEPROM) memory. This can be written approximately 10,000 times. After downloading a configuration, if the device loses power, the configuration is saved. 44 XTM/XPx XTM Configurator

45 Through an N30 Supervisory Controller An XTM module on the N2 Bus of an N30 Supervisory Controller may be downloaded over the network if: XTM Configurator 3.03 or later is installed. M-Tool Loader User Interface (UI) is installed. PC is connected to a network of N30s. Note: The Loader UI is installed as part of System Tools. Refer to M-Tool Overview and Installation Technical Bulletin (LIT ) for details.! WARNING: You cannot upload an XTM. To download an XTM through an N30: 1. On the Windows Start menu, select Programs > Johnson Controls > M-Tool > System Tools > Loader User Interfaces. The Loader UI dialog box appears (Figure 33). Figure 33: Loader UI Dialog Box 2. Select XTM from the drop-down list. 3. Click Connect Site. The Site Manager appears minimized on the Windows taskbar and establishes a connection with the Site shown in the Site Name field. 4. Click Browse to select a *.DBF file to download. XTM/XPx XTM Configurator 45

46 5. In the Supervisory Controller field, select an N30 supervisory controller from the drop-down list. A list of the XTM modules connected to the selected supervisory controller will appear in the field below. 6. Select the XTM module to be downloaded. 7. Click Download. The following dialog box appears: Figure 34: XT/XTM Download Dialog Box Note: When Log File is checked, the program writes a series of messages to errorlog.txt file, recording download progress. The errorlog.txt file is in the C: root directory. 8. Click on OK to continue or Cancel to abort the download. Download progress is indicated by the progress bar in the Loader UI dialog box, and a message box displays the operational steps and commands of the Loader User Interface program. A dialog box appears with a download complete or a download failed message. 9. When the download is complete, return to Step 1 if you wish to download another XTM. Otherwise, click on the Close button to close the Loader UI dialog box and terminate the Site Manager and Loader User Interface programs. If the download is not successful, refer to the errorlog.txt file for the possible causes. 46 XTM/XPx XTM Configurator