Process Discrete Input (PDI)

This information applies to the CompactLogix 5380P and ControlLogix 5580P controllers.
The Process Discrete Input (PDI) instruction monitors a discrete (true or false) input, and checks for alarm conditions. Use the PDI instruction to process a signal from a channel of a discrete input module. Use the PDI instruction with any discrete (BOOL) signal.
The PDI instruction provides these capabilities:
  • De-bounce of the discrete input signal to filter out fast status changes by specifying a minimum time status must maintain state.
  • Display of the input state; the 0-state and 1-state names are configurable. The input state is also displayed independently, even when the input is substituted.
  • Target Disagree status based on comparing the input state against a target, or normal, state. The Target Disagree status is enabled by a gating input signal with a configurable gate delay. The Target Disagree status on and off delays are configurable. The Target Disagree status has an associated tag-based alarm.
  • Handle a process variable (PV) fault input by displaying the fault to the operator. The PV fault has an associated tag-based alarm.
  • The operator can select and manually enter a substitute PV. This manual override is made clearly visible to the operator. Optionally, the user can configure the substitute PV signal to track the Target input so that no Target Disagree status or alarm is generated.
  • Support for a virtual PV for use in instruction testing, demonstration, or operator training.
Available Languages
Ladder Diagram
PDI_avail_ladder_v33
Function Block Diagram
PDI_FBD_v33
Structured Text
PDI(PDI tag, BusObj);
Operands
IMPORTANT:
Unexpected operation may occur if:
  • Output tag operands are overwritten.
  • Members of a structure operand are overwritten.
  • Except when specified, structure operands are shared by multiple instructions.
There are data conversion rules for mixing numeric data types within an instruction. See Data conversions.
Configuration Operands
Operand
Type
Format
Description
PDI
P_DISCRETE_INPUT
tag
Data structure required for proper operation of instruction.
BusObj
BUS_OBJ
tag
Bus component. May be null.
P_DISCRETE_INPUT Structure
Public members are standard, visible tag members that are programmatically accessible. Private, or hidden, members are used in HMI faceplates and are not programmatically accessible. Private members are listed in separate tables after public members.
Public Input Members
Data Type
Description
EnableIn
BOOL
Enable input.
Ladder Diagram:
Corresponds to the rung condition.
Default is true.
Inp_InitializeReq
BOOL
1 = Request to initialize the instruction. The instruction is normally initialized in instruction first run. Use this request to re-initialize. The instruction clears this operand automatically.
Default is true.
Inp_PVData
BOOL
Input signal (process variable) from device.
When EnableIn is false the instruction executes and uses the inverse of the Inp_PVData signal for processing.
Default is true.
Inp_ModFault
BOOL
1 = I/O module failure or module communication status bad,
0 = OK.
Default is false.
Inp_ChanFault
BOOL
1 = I/O channel fault or failure,
0 = OK.
Default is false.
Inp_PVUncertain
BOOL
Indicates the channel data accuracy is undetermined.
1 = The channel data is uncertain.
This input sets Sts_PVUncertain if not in Virtual.
Default is false.
Inp_PVNotify
SINT
Related PV object alarm priority and acknowledgement status.
0 = Not in alarm, acknowledged,
1 = Not in alarm, unacknowledged or reset required,
2 = Low severity alarm, acknowledged,
3 = Low severity alarm, unacknowledged,
4 = Medium severity alarm, acknowledged,
5 = Medium severity alarm, unacknowledged,
6 = High severity alarm, acknowledged,
7 = High severity alarm, unacknowledged,
8 = Urgent severity alarm, acknowledged,
9 = Urgent severity alarm, unacknowledged.
Default = 0.
Inp_Target
BOOL
Target state of input. Input Inp_PVData is compared with the target state using Gate function. If not in target state, the Target Disagree status (Sts_TgtDisagree) is set to 1 and Target Disagree tag-based alarm is raised (if enabled).
Default is true.
Inp_Gate
BOOL
The gate input used for status detection.
1 = Target Disagree monitoring is enabled.
0 = Target Disagree detection is disabled and the Target Disagree status output is forced off.
Default is true.
Inp_Reset
BOOL
1 = Reset Shed Latches and Cleared Alarms.
Default is false.
Cfg_AllowDisable
BOOL
1 = Allow Maintenance to disable alarms.
Default is true.
Cfg_AllowShelve
BOOL
1 = Allow Operator to shelve alarms.
Default is true.
Cfg_NoSubstPV
BOOL
Disables the maintenance substitution feature.
0 = The Substitute PV Maintenance function is enabled,
1 = The Substitute PV Maintenance function is disabled.
When Cfg_NoSubstPV is 0, the commands MCmd_SubstPV and MCmd_InpPV are used to select the input PV or the substitute PV. Sts_SubstPV is set to 1 when the substitute PV is selected.
Default is false.
Cfg_SubstTracksTarget
BOOL
1 = The substitute PV tracks Inp_Target, 0 = The substitute PV is set by MSet_SubstPV.
Default is false.
Cfg_NormTextVis
BOOL
1 = The state text is displayed in Normal state,
0 = The state text is hidden in Normal state.
Default is true.
Cfg_HasMoreObj
BOOL
1 = Tells HMI an object with more info is available.
Default is false.
Cfg_Debounce
REAL
Minimum time status must maintain state (seconds). Debounces the input PV, ensuring that the status stays in each state a minimum time.
Valid = 0.0 to 2147483.0 seconds.
Default = 0.0.
Cfg_GateDly
REAL
Target Disagree Gate delay (seconds). Time Inp_Gate must be 1 before Target Disagree condition is checked.
Valid = 0.0 to 2147483.0 seconds.
Default = 0.0.
Cfg_TgtDisagreeOffDly
REAL
Minimum time for input to agree with target to clear status (seconds).
Valid = 0.0 to 2147483.0 seconds.
Default is 0.0.
Cfg_TgtDisagreeOnDly
REAL
Minimum time for input to disagree with target to raise status (seconds).
Valid = 0.0 to 2147483.0 seconds.
Default is 0.0.
Cfg_CnfrmReqd
SINT
Operator command confirmation required. Represents the type of command confirmation required.
0 = None,
1 = Command confirmation required,
2 = Performer e-signature required,
3 = Performer and approver e-signature required.
Default is 0.
Set_VirtualPV
BOOL
PV used in Virtual (Sts_Virtual is 1). If the instruction is not in Virtual (Inp_Virtual is 0), the Set_VirtualPV input tracks the input PV (Inp_PVData) for bumpless transfer into Virtual.
Default is false.
PCmd_Virtual
BOOL
Program command to select Virtual (simulated) device operation. The instruction clears this operand automatically.
Default is false.
PCmd_Physical
BOOL
Program command to select Physical device operation (not simulated). The instruction clears this operand automatically.
Default is false.
PCmd_Reset
BOOL
Program command to reset all alarms and latched shed conditions requiring reset. The instruction clears this operand automatically.
Default is false.
XCmd_Reset
BOOL
External command to reset all alarms and latched shed conditions. The instruction clears this operand automatically.
Default is false.
XCmd_ResetAckAll
BOOL
External command to acknowledge and reset all alarms and latched shed conditions. The instruction clears this operand automatically.
Default is false.
Public Output Members
Data Type
Description
EnableOut
BOOL
Enable output. This output state always reflects EnableIn input state.
Out
BOOL
Discrete input status (including de-bounce and manual override, if used).
0 = The discrete input is Off,
1 = The discrete input is On.
Out_InpPV
BOOL
Echo of Inp_PVData (actual raw or virtual input).
Out_Reset
BOOL
1 = Reset command has been received and accepted.
Sts_Initialized
BOOL
1 = Instruction is initialized. Use Inp_InitializeReq to reinitialize.
Sts_PVUncertain
BOOL
Indicates the channel data accuracy is undetermined. 1 = The channel data is uncertain. This output is set by Inp_PVUncertain (if not in Virtual).
Sts_SubstPV
BOOL
1 = Using substitute PV (Override).
Sts_InpPV
BOOL
1 = Using input PV (Normal).
Sts_Virtual
BOOL
1 = Using virtual PV instead of the input from the device (Inp_PVData) to calculate output.
0 = The instruction uses input operand Inp_PVData to calculate output.
SrcQ_IO
SINT
Source and quality of primary input or output (enumerated):
0 = Good, live, confirmed good,
1 = Good, live, assumed good,
2 = Good, no feedback, assumed good,
8 = Test, virtualized,
9 = Test, loopback,
10 = Test, manually entered,
16 = Uncertain, live, off-spec,
17 = Uncertain, substituted at device or bus,
18 = Uncertain, substituted at instruction,
19 = Uncertain, using last known good,
20 = Uncertain, using replacement value,
32 = Bad, signal failure,
33 = Bad, channel fault,
34 = Bad, module or communication fault,
35 = Bad, invalid configuration.
SrcQ
SINT
Source and quality of primary value or status (enumerated):
0 = Good, live, confirmed good,
1 = Good, live, assumed good,
2 = Good, no feedback, assumed good,
8 = Test, virtualized,
9 = Test, loopback,
10 = Test, manually entered,
16 = Uncertain, live, off-spec,
17 = Uncertain, substituted at device or bus,
18 = Uncertain, substituted at instruction,
19 = Uncertain, using last known good,
20 = Uncertain, using replacement value,
32 = Bad, signal failure,
33 = Bad, channel fault,
34 = Bad, module or communication fault,
35 = Bad, invalid configuration.
Sts_eSts
SINT
Device confirmed status values:
0 = PV Good,
1 = PV uncertain,
2 = PV bad,
3 = PV substituted.
Sts_eFault
SINT
Device fault status values:
0 = None,
1 = Target disagree,
2 = Configuration error.
Sts_eNotify
SINT
All alarm status enumerated values:
0 = Not in alarm, acknowledged,
1 = Not in alarm, unacknowledged or reset required,
2 = Low severity alarm, acknowledged,
3 = Low severity alarm, unacknowledged,
4 = Medium severity alarm, acknowledged,
5 = Medium severity alarm, unacknowledged,
6 = High severity alarm, acknowledged,
7 = High severity alarm, unacknowledged,
8 = Urgent severity alarm, acknowledged,
9 = Urgent severity alarm, unacknowledged.
Sts_eNotifyAll
SINT
All alarm status enumerated values including related objects:
0 = Not in alarm, acknowledged,
1 = Not in alarm, unacknowledged or reset required,
2 = Low severity alarm, acknowledged,
3 = Low severity alarm, unacknowledged,
4 = Medium severity alarm, acknowledged,
5 = Medium severity alarm, unacknowledged,
6 = High severity alarm, acknowledged,
7 = High severity alarm, unacknowledged,
8 = Urgent severity alarm, acknowledged,
9 = Urgent severity alarm, unacknowledged.
Sts_eNotifyIOFault
SINT
IOFault alarm status enumerated values.
0 = Not in alarm, acknowledged,
1 = Not in alarm, unacknowledged or reset required,
2 = Low severity alarm, acknowledged,
3 = Low severity alarm, unacknowledged,
4 = Medium severity alarm, acknowledged,
5 = Medium severity alarm, unacknowledged,
6 = High severity alarm, acknowledged,
7 = High severity alarm, unacknowledged,
8 = Urgent severity alarm, acknowledged,
9 = Urgent severity alarm, unacknowledged.
Sts_eNotifyTgtDisagree
SINT
TgtDisagree alarm status enumerated values.
0 = Not in alarm, acknowledged,
1 = Not in alarm, unacknowledged or reset required,
2 = Low severity alarm, acknowledged,
3 = Low severity alarm, unacknowledged,
4 = Medium severity alarm, acknowledged,
5 = Medium severity alarm, unacknowledged,
6 = High severity alarm, acknowledged,
7 = High severity alarm, unacknowledged,
8 = Urgent severity alarm, acknowledged,
9 = Urgent severity alarm, unacknowledged.
Sts_UnackAlmCount
DINT
Count of unacknowledged alarms.
Sts_MaintByp
BOOL
1 = The device has a Maintenance Bypass function active.
Sts_Err
BOOL
1 = Error in configuration: See detail bits (Sts_Errxxx) for reason.
Sts_ErrGateDly
BOOL
1 = Error in configuration: Cfg_GateDly value is invalid.
Sts_ErrTgtDisagreeOffDly
BOOL
1 = Error in configuration: Cfg_TgtDisagreeOffDly value is invalid.
Sts_ErrTgtDisagreeOnDly
BOOL
1 = Error in configuration: Cfg_TgtDisagreeOnDly value is invalid.
Sts_ErrDebounce
BOOL
1 = Error in configuration: Cfg_Debounce value is invalid.
Sts_ErrAlm
BOOL
1 = Error in tag-based alarm settings.
Sts_Alm
BOOL
1 = An alarm is active.
Sts_AlmInh
BOOL
1 = An alarm is shelved or disabled.
Sts_IOFault
BOOL
IO Fault Status (0 = OK, 1 = Bad). 1 = Channel data is inaccurate. This output is set by Inp_IOFault if not in Virtual.
There is a predefined default discrete tag-based alarm for the status. Set standard configuration members of the discrete tag-based alarm. Access alarm elements using this format:
PDITag.@Alarms.Alm_IOFault.AlarmElement
Sts_TgtDisagreeCmp
BOOL
Input versus Target comparison result before gating. 1 = The input does not match its target.
Sts_TgtDisagreeGate
BOOL
Target Disagree Gate Delay Status. 1 = The target disagree gate is open.
Sts_TgtDisagree
BOOL
Gated input versus target comparison result. 1 = Input is not in target state.
There is a predefined default discrete tag-based alarm for the status. Set standard configuration members of the discrete tag-based alarm. Access alarm elements using this format:
PDITag.@Alarms.Alm_TgtDisagree.AlarmElement
Sts_RdyAck
BOOL
1 = An alarm is ready to be acknowledged.
Sts_RdyReset
BOOL
1 = A latched alarm or shed condition is ready to be reset.
XRdy_Reset
BOOL
1 = Ready for XCmd_Reset, enable HMI button.
XRdy_ResetAckAll
BOOL
1 = Ready for XCmd_ResetAckAll, enable HMI button.
Private Input Members
Data Type
Description
MSet_SubstPV
BOOL
Maintenance-entered substitute PV that overrides input PV when Sts_SubstPV is 1. If not using the substitute (Sts_SubstPV is false), the MSet_SubstPV setting tracks the Out value for bumpless transfer from input PV to substitute PV.
Default is false.
MCmd_SubstPV
BOOL
Maintenance command to use Substitute PV (Override input). The instruction clears this operand automatically.
Default is false.
MCmd_InpPV
BOOL
Maintenance command to use Input PV (Normal). The instruction clears this operand automatically.
Default is false.
MCmd_Physical
BOOL
Maintenance command to select Physical device operation (not simulated). The instruction clears this operand automatically.
Default is false.
MCmd_Virtual
BOOL
Maintenance command to select Virtual (simulated) device operation. The instruction clears this operand automatically.
Default is false.
OCmd_Reset
BOOL
Operator command to reset all alarms and latched shed conditions. The instruction clears this operand automatically.
Default is false.
OCmd_ResetAckAll
BOOL
Operator command to acknowledge and reset all alarms and latched shed conditions. The use of OCmd_ResetAckAll is restricted to HMI. The instruction clears this operand automatically.
Default is false.
Private Output Members
Data Type
Description
HMI_BusObjIndex
DINT
This object's index in the bus array, for use by HMI display.
Default is 0.
MRdy_SubstPV
BOOL
1 = The instruction is ready for SubstPV command.
MRdy_InpPV
BOOL
1 = The instruction is ready for InpPV command.
MRdy_Physical
BOOL
1 = Ready for MCmd_Physical, enable HMI button.
MRdy_Virtual
BOOL
1 = Ready for MCmd_Virtual, enable HMI button.
ORdy_Reset
BOOL
1 = A latched alarm or shed condition is ready to be reset.
ORdy_ResetAckAll
BOOL
1 = A latched alarm or shed condition is ready to be reset or acknowledged.
Public InOut Members
Data Type
Description
BusObj
BUS_OBJ
Bus component
BUS_OBJ Structure
The BUS_OBJ structure links the discrete input instruction to other devices and instructions in a complex control strategy, typically into a hierarchy. A Bus Object rolls up status and alarm information from lower level devices to higher level control and fans out commands from higher level control to lower level devices. Items link to the bus by referencing a single member of the BUS_OBJ array associated with the bus.
This parameter links the instruction to an external tag that contains necessary data for the instruction to operate. The external tag must be of the data type shown, or may be NULL. If NULL, the Bus functions of this instruction are not available.
Members
Data Type
Description
Inp_Cmd
DINT
Input to assert commands
Out_Cmd
DINT
Resultant commands
Inp_CmdLLH
DINT
Input for level normally high commands
Out_CmdLLH
DINT
Resultant line level high commands
Inp_Sts
DINT
Input to assert status
Out_Sts
DINT
Resultant status
Inp_CmdAck
DINT
Input to assert a command acknowledgement
Out_CmdAck
DINT
Resultant command acknowledgements
Inp_SeverityMax
DINT
Input: maximum alarm severity
Out_SeverityMax
DINT
Resultant of maximum alarm severity
Cfg_CmdMask
DINT
Propagation mask for commands
Cfg_CmdLLHMask
DINT
Propagation mask for line level high commands
Cfg_StsMask
DINT
Propagation mask for status
Ref_Index
DINT
Bus array index
Alarms
Discrete tag-based alarms are defined for these members.
Member
Alarm Name
Description
Sts_TgtDisagree
Alm_TgtDisagree
Target Disagree status.
Sts_IOFault
Alm_IOFault
I/O Fault status (not generated when PV Substitution is active).
Mark the alarm as used or unused and set standard configuration members of the discrete Logix Tag based alarm. Access alarm elements using this format:
PDITag.@Alarms.AlarmName.AlarmElement
There are Program, Operator, and External commands that enable the Reset and Reset & Acknowledge of all alarms of the instruction (Alarm Set) at the same time. This diagram shows how the commands interact with the instruction.
PDI_alarmoperation_v33
Operation
The Gate function provides the ability to raise an abnormal condition (alarm condition) when another condition is true. For example, a high vibration switch should only generate an alarm when the associated motor is running long enough to stabilize. The Inp_Gate input must be set to 1 (its default value) and the tag-based alarm for Sts_TgtDisagree enabled for alarm to occur. The alarm will not occur until the Inp_Gate input has been set for the Gate Delay (Cfg_GateDly) time.
The alarm is generated when the Inp_PVData (process variable) input is different from the Inp_Target (target) input. The Target indicates the normal condition. For example, a flow switch should indicate flow when a pump is running and should not indicate flow when a pump is stopped. The pump run status is used as the Target input, and when the switch does not match the target (within the allotted time), the Alarm (Flow Loss / Switch Failure) is generated.
TIP:
In Ladder Diagram if the rung-condition-in is false, the instruction uses the inverse of the Inp_PVData signal for processing. This allows the input to be a condition on the rung with PDI rather than mapped into Inp_PVData. To use the rung-condition-in mapping method, set Inp_PVData to 1, its default value.
This instruction includes a substitute PV capability for a manually-entered state. This is useful when a sensor is out of order or for simulation and testing.
The Discrete Input instruction and its input, target and gate signals handle alarm conditions described by these use cases:
  • Raises an alarm when the input is in a given alarm state for a configurable amount of time, such as a low level alarm from a float level switch.
  • Raises an alarm when the input does not follow another given signal within a configurable amount of time, such as a flow switch which should indicate flow when an associated pump has been running for a period of time and which should indicate NO flow when the associated pump has been stopped for a period of time.
  • Raises an alarm when the input is in a given alarm state for a configurable amount of time after enabled by a gating signal, such as a vibration switch on a motor, which should only alarm when the motor has been running long enough for startup vibration to have settled out.
This diagram illustrates the functionality of the PDI instruction:
PDI_Operation1_v34
PDI_operation2_v33
Debouncing
A bounce is a reversal of state that occurs immediately after a deliberate transition. When filtering bounces you should acknowledge the very first transition as early as possible and ignore subsequent changes until the end of a hold-off period. Use Cfg_Debouncing to specify the hold-off period in seconds.
For example, as soon as the Input PV changes state from 0 to 1, the output changes to 1 and will not then follow the Input PV back to 0 until the Cfg_Debounce time has expired. If Cfg_Debounce is set to 1 second, the output remains at 1 for at least 1 second. After 1 second, if the Input PV was then 0, the output would change to 0 and would remain at 0 for at least 1 second.
This illustration shows the Debounce operation.
DebounceDetail_v34
Virtualization
Virtualization in PDI provides a virtual 0-state or 1-state input (Set_VirtualPV) that processes like an input. Use virtualization for instruction testing and operator training. Use PCmd_Virtual or MCmd_Virtual to enable virtualization. After finishing virtualization, use PCmd_Physical or MCmd_Physical to return to normal (physical device) operation.
Initialization
The instruction is normally initialized in the instruction first run. Re-initialization can be requested any time by setting Inp_InitializeReq = 1. For proper initialization, when adding the instruction while performing an online edit of the code, make sure that Inp_InitializeReq = 1, the default value.
Configuration of Strings for HMI
Configure strings for HMI faceplates, as seen in
FactoryTalk View
FactoryTalk View
, and for the
Logix Designer
configuration dialog box. The strings are set to extended properties of tag items. Configure the strings in the Logix Designer application only.
  • Description
  • State name strings for 0-state and 1-state
  • Label for graphic symbol
  • Display Library for HMI Faceplate call-up
  • Instruction name
  • Area name
  • URL link
  • More Information
Implementation
This illustration shows normal implementation with the input condition mapped to Inp_PVData on a separate branch.
PDI_implementation_1_v33
This illustration shows the implementation with the input condition mapped to the PDI instruction using the rung-condition-in.
PDI_implementation_2_v33
Monitor the PDI Instruction
Use the operator faceplate from the PlantPAx library of Process objects for monitoring.
Affects Math Status Flags
No.
Major/Minor Faults
None specific to this instruction. See Index Through Arrays for array-indexing faults.
Execution
Ladder Diagram
Condition/State
Action Taken
Prescan
Rung-condition-out is cleared to false.
The state of using raw input or maintenance substitute PV is not modified and persists through a controller powerup or PROG-to-RUN transition.
The state of the physical/virtual selection persists through a control power or PROG-to-Run transition.
Instruction first run
All commands that are automatically cleared each execution are cleared and ignored.
The instruction executes normally.
Rung-condition-in is false
Rung-condition-out is cleared to false.
The instruction executes normally, except it uses the inverse of the Inp_PVData signal for processing.
Rung-condition-in is true
Set rung-condition-out to rung-condition-in.
The instruction executes.
Postscan
Rung-condition-out is cleared to false.
Function Block Diagram
Condition/State
Action Taken
Prescan
EnableOut is cleared to false.
The state of using raw input or maintenance substitute PV is not modified and persists through a controller powerup or PROG-to-RUN transition.
The state of the physical/virtual selection persists through a control power or PROG-to-Run transition.
Instruction first run
All commands that are automatically cleared on each execution are cleared and ignored.
The instruction executes normally.
Instruction first scan
See Instruction first run in the Function Block Diagram table.
EnableIn is false
EnableOut is cleared to false.
The instruction executes normally, except it uses the inverse of the Inp_PVData signal for processing.
EnableIn is true
EnableOut is set to true.
The instruction executes.
Postscan
EnableIn and EnableOut bits are cleared to false.
Structured Text
In Structured Text, EnableIn is always true during normal scan. The instruction executes when it is in the control path activated by the logic.
Condition/State
Action Taken
Prescan
See Prescan in the Function Block Diagram table.
Instruction first run
See Instruction first run in the Function Block Diagram table.
EnableIn is true
See EnableIn is true in the Function Block Diagram table.
Postscan
See Postscan in the Function Block Diagram table.
Example
In this example, tag I_VSH_P50 is the digital process value monitored by the PDI instruction. This tag provides a Boolean indication of High Vibration. The bad quality indication for the value of the process variable (Inp_ChanFault) comes from the connection status indication on the input module.
Inp_Target is defaulted to 1 indicating that the normal condition for I_VSH_P50 is also 1, and tag comments confirm that 1=OK for this process value. Inp_Gate is connected to the Motor Running status tag (P50_Running) that comes from the Sts_Running output of the P_Motor instruction instance for this motor (P50_Motor). The gate delay is configured to give the motor sufficient time after starting to settle into full normal speed run before enabling the high vibration indication (Sts_TgtDisagree) and alarm. The tag-based alarm for Target Disagree status (Sts_TgtDisagree) applies On Delay timing so the alarm will not raise until after delay time has expired.
Finally, P50_HighVibr is the output tag that indicates the status of I_VSH_P50 with appropriate gate delays based on whether the motor is running.
Ladder Diagram
PDI_LadderExample_v33
Function Block Diagram
PDI_FBDExample_v33
Structured Text
VAH_50.Inp_PV_Data := I_VSH_P50;
VAH_50.Inp_ChanFault := CAF_117[5];
VAH_50.Inp_Gate := P50_Running;
PDI(VAH_50);
P50_HighVibr := VAH_P50.Sts_TgtDisagree;
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