CIP Axis Status Attributes

These are the device status attributes associated with a Motion Control Axis. Any status bits that are not applicable are set to 0.
Axis State
Usage
Access
T
Data Type
Default
Min
Max
Semantics of Values
Required - All
Get
T
USINT
-
-
-
Enumeration:
0 = Initializing
1 = Pre-Charge
2 = Stopped
3 = Starting
4 = Running
5 = Testing
6 = Stopping
7 = Aborting
8 = Major Faulted
9 = Start Inhibited
10 = Shutdown
11-255: Reserved
Enumerated value indicating the state of the axis.
Axis Status
Usage
Access
T
Data Type
Default
Min
Max
Semantics of Values
Required - All
Get
T
DWORD
-
-
-
See Semantics
The Axis Status attribute is a collection of standard bits indicating the internal status of the axis.
Axis Status 2
Usage
Access
T
Data Type
Default
Min
Max
Semantics of Values
Required - XG Opt - NED
Get
T
DWORD
-
-
-
See Semantics
The Axis Status 2 attribute is a collection of standard bits that indicate the internal status of the axis. The attribute provides a 32-bit extension to the CIP Axis Status attribute.
Axis Status 2 - Mfg
Usage
Access
T
Data Type
Default
Min
Max
Semantics of Values
Required - All
Get
T
DWORD
-
-
-
Bitmap:
0-31: Vendor Specific
(Published in Product Manual)
The Axis Status 2 - Mfg attribute is a collection of vendor-specific bits indicating the internal status of the axis. This attribute provides a 32-bit extension to the Axis Status Mfg attribute.
CIP Status Bit Descriptions
Bit
Usage
Status Condition
Description
0
Required
Local Control
This bit is set if the axis is taking command reference and services from the local interface instead of the remote (CIP Motion) interface. This bit is based on the current state of the Remote Mode bit of the Node Status attribute.
1
Required
Alarm
This bit is set if the axis has detected one or more exception conditions configured to generate an alarm. This bit is clear if there are no current axis alarm conditions.
2
Required/ XBD
DC Bus Up
For a drive axis, this bit is set if the DC Bus has charged up to an operational voltage level based on direct measurement and, if applicable, the Converter Bus Up Status bit associated with the external CIP Motion converter) supplying DC Bus power to this device is also set. If the Bus Configuration attribute is set to
Shared DC - Non CIP Converte
r the drive might also check the status of its associated external Non-CIP Motion converter. When a drive axis is in the Pre-Charge state, the transition of the DC Bus Up status bit from 0 to 1 initiates a state transition to the Stopped State. Once set, the DC Bus Up bit is cleared when the DC Bus voltage has dropped below an operational voltage level, or the Converter Bus Up Status bit associated with external CIP Motion converters supplying DC Bus power to this device is cleared.
For an AC/DC converter axis, this bit is set if the DC Bus has charged up to an operational voltage level based on direct measurement alone. When a converter axis is in the Pre-Charge state, the transition of the DC Bus Up status bit from 0 to 1 initiates a state transition to the Running state for a Passive converter, or to the Stopped state for an Active converter. Once set, the DC Bus Up bit is cleared when the DC Bus voltage has dropped below an operational voltage level, independent of the state of the Converter Bus Up Status bit.
For a DC/DC converter axis, this bit is set when the primary DC Bus has charged up to an operational voltage level based on direct measurement, the Converter Bus Up Status bit associated with external CIP Motion converters supplying DC Bus power to this device has been set, and the DC/DC converter has established all the secondary DC Bus voltage levels. While the DC/DC converter axis is in the Pre-Charge state, the transition of the DC Bus Up status bit from 0 to 1 initiates a state transition to the Running state.
3
Required/
XGD O/N
Power Structure Enabled
This bit is set if the axis power structure is energized and capable of generating motor flux and torque for a drive axis, or regenerating power to the AC line for a converter axis. The value of the Power Structure Enabled bit is determined by the Axis State, and for the drive axis, the configured Stopping Action attribute value.
4
Required/
D
Motor Flux Up
This bit is set if the motor flux for an induction motor has reached an operational level. Transition of the Motor Flux Up bit is initiated in the Starting State according to the configured Flux Up Control attribute value. This bit is only applicable to Induction Motor types.
5
Required/
XGD
Tracking Command
This bit is set if the axis control structure is actively tracking the command reference from the motion planner associated with a drive axis, or the bus voltage setpoint of a converter axis, or the current references of a track section axis applying force to resident movers. The Tracking Command bit is directly associated with the Running state of the Axis State Model.
6
Required/
P
Position Lock
This bit is set if the actual position is within the Position Lock Tolerance of the command position.
7
Optional/
PV
Velocity Lock
This bit is set if the velocity feedback signal is within the Velocity Lock Tolerance of the unlimited velocity reference.
8
Required/
ED
Velocity Standstill
This bit is set if the velocity feedback signal is within the Velocity Standstill Window of 0. For a Frequency Control drive, this bit is set if the velocity reference signal is within the Velocity Standstill Window of 0.
9
Optional/
ED
Velocity Threshold
This bit is set if the absolute velocity feedback signal is below Velocity Threshold. For a Frequency Control drive, this bit is set if the absolute velocity reference signal is below the Velocity Threshold.
10
Optional/
FPV
Velocity Limit
This bit is set if the velocity reference signal is limited by the Velocity Limiter.
11
Optional/
C
Acceleration Limit
This bit is set if the acceleration reference signal is limited by the Acceleration Limiter.
12
Optional/
C
Deceleration Limit
This bit is set if the acceleration reference signal is limited by the Deceleration Limiter.
13
Optional/
C
Torque Threshold
This bit is set if the absolute filtered torque reference is above the Torque Threshold.
14
Required/
C
Torque Limit
This bit is set if the filtered torque reference is limited by the Torque Limiter.
15
Optional/
XD
Current Limit
This bit is set if the command current, Iq, is limited by the Current Vector Limiter.
16
Optional/
XD
Thermal Limit
This bit is set if the Current Vector Limit condition of the axis is limited by any of the axis's Thermal Models or I
2
T Thermal Protection functions.
17
Required/
RE
Feedback Integrity
This bit, when set, indicates that the feedback device is accurately reflecting changes to axis position, and there have been no conditions detected that would compromise the quality of the feedback position value. The bit is set at power-up assuming that the feedback device passes any power-up self-test required. If during operation a feedback exception occurs that could impact the fidelity of axis position, the bit is immediately cleared. The bit remains clear until either a fault reset is executed by the drive or the drive is power cycled. The Feedback Integrity bit behavior applies to both absolute and incremental feedback device operation.
18
Required/
XBD
Shutdown
This bit is set when the axis is in the shutdown state or in the faulted state but would transition to the shutdown state if the faults were cleared. Therefore, the Shutdown bit is closely associated with the Shutdown State of the Axis State Model.
19
Required
In Process
This bit is set for the duration of an active process. An example of an active process would be an operation initiated by a Run Motor Test, Run Hookup Test, or Run Inertia Test to request service. An active process that requires the enabling of the axis power structure results in a transition to the Testing State of the Axis State Model.
20
Optional/
XBD
DC Bus Unload
This bit is set by a CIP Motion converter, or a CIP Motion drive containing an integral converter, or a CIP Motion drive connected to an external non-CIP converter, to indicate that the converter cannot continue supplying DC Bus power to other drives and converters on a shared DC Bus. This is usually the result of a shutdown fault action initiated by the drive or converter, or a shutdown request from the controller. When the DC Bus Unload bit is set, the Shutdown bit (bit 18) in this case is also set. A start inhibit condition can also set the DC Bus Unload bit.
When there is no AC Contactor Enable output to drop the DC Bus, a method is needed to unload the converter from all other drives and converters sharing the DC Bus. By monitoring the DC Bus Unload status bit, the control system uses the Converter Bus Unload bit of Control Status to initiate Bus Power Sharing exceptions on all enabled drives on the shared DC Bus that are configured for Shared AC/DC or Shared DC operation. This Bus Power Sharing exception invokes the configured Exception Action that, by default, disables the device’s power structure and unloads the bus. Upon receiving a Converter Bus Unload, all disabled drives sharing the DC Bus shall indicate a Converter Bus Unload start inhibit.
Unlike other devices, DC/DC converters configured for Shared DC/DC operation on the shared primary DC Bus do not assert a Bus Power Sharing exception when receiving a Converter Bus Unload. Instead, DC/DC converters cascade the Converter Bus Unload, sent by the control system to devices on the primary bus, to devices on the secondary DC Bus by setting its DC Bus Unload status bit. The DC/DC converter remains operational in the Running state to allow Shared DC devices on the secondary DC bus to execute the configured Bus Power Sharing exception action. However, if the DC/DC converter itself experiences a fault condition or a shutdown request, it sets the Bus Unload bit, but all other devices in the Primary Shared DC Bus remain operational.
Only the originating drive or converter with the DC Bus Unload condition can cause Bus Power Sharing Faults on other drives and AC/DC converters on the associated shared bus. In other words, no device with a Bus Power Sharing Fault can cause a Bus Power Sharing exception on other devices on the shared bus by setting its DC Bus Unload bit. This qualification helps prevent DC Bus recovery deadlock. To recover full DC Bus operation, the originating drive or converter with the DC Bus Unload condition must first be reset via a Shutdown Reset Request. Once clear, the controller then clears the Converter Bus Unload bit to all the shared drives and converters. The Bus Power Sharing Faults on the shared drives and AC/DC converters can then be cleared successfully by either a Fault Reset Request, or a Shutdown Reset Request, allowing these devices to become operational.
21
Optional/
XBD
AC Power Loss
This bit is set when a CIP Motion converter, or a CIP Motion drive containing an integral converter, or a CIP Motion drive connected to an external non-CIP converter, has detected a loss of AC input power. This bit is cleared when AC input power is determined to be sufficient for converter operation.
When an AC Power Loss condition is detected by a converter supplying power to other devices over a shared DC Bus, a method is needed to generate a Converter AC Power Loss exception on any drive whose power structure is enabled. To accomplish this, the control system monitors the AC Power Loss status bits of converters supplying DC Bus power and propagates AC Power Loss status to all drives on the shared DC Bus, such as drives that are configured for Shared AC/DC or Shared DC operation. Upon notification of AC Power Loss, drives that have enabled power structures will assert a Converter AC Power Loss exception and invoke the programmed Axis Exception Action. Disabled drives will not generate an exception action on AC Power Loss. Thus, no drive faults will occur on removal of AC Power from a converter.
Unlike other devices, DC/DC converters configured for Shared DC/DC operation on the shared primary DC bus do not assert an AC Power Loss exception when receiving a Converter AC Power Loss. Instead, DC/DC converters cascade the Converter AC Power Loss, sent by the control system to devices on the primary bus, to devices on the secondary DC Bus by setting its AC Power Loss status bit and, thereby, initiating AC Power Loss exceptions on all enabled Shared DC devices assigned to the secondary Shared DC Bus. The DC/DC converter remains operational in the Running state to allow Shared DC devices on the secondary DC bus to execute the configured AC Power Loss exception action.
Only the originating drive or converter with the AC Power Loss condition can cause AC Power Loss Faults on other drives on the associated shared bus. In other words, no device with an AC Power Loss Fault can cause an AC Power Loss exception on other drives on the shared bus by setting its AC Power Loss bit. This qualification prevents DC Bus recovery deadlock. To recover full DC Bus operation, the originating drive or converter with the AC Power Loss condition must first be reset, typically via a Shutdown Reset Request. Once clear, the controller then clears the Converter AC Power Loss bit to all the shared drives. The AC Power Loss Faults on the shared drives can then be successfully cleared by either a Fault Reset Request, or a Shutdown Reset Request, allowing these drives to become operational.
22
Optional/
C
Position Control Mode
When set, this bit indicates that axis position is being actively controlled by the Position Loop. Position Control Mode is only applicable when the axis is enabled and using the PI Vector Control Method. The "Position Control Mode" status bit is cleared whenever the active Control Mode is changed from Position Control to Velocity Control or Torque Control. This status bit is clear if the drive axis is disabled.
23
Optional/
C
Velocity Control Mode
When set, this bit indicates that axis velocity is being actively controlled by the Velocity Loop. Velocity Control Mode is only applicable when the drive axis is enabled and using the PI Vector Control Method. The "Velocity Control Mode" status bit is cleared whenever the active Control Mode is changed from Velocity Control to Position Control or Torque Control. This status bit is clear if the drive axis is disabled.
24
Optional/
C
Torque Control Mode
When set, this bit indicates that axis velocity is being actively controlled by the Torque (Current) Loop. Torque Control Mode is only applicable when the drive axis is enabled and using the PI Vector Control Method. The "Torque Control Mode" status bit is cleared whenever the active Control Mode is changed from Torque Control to Position Control or Velocity Control. This status bit is clear if the drive axis is disabled.
25-31
-
Reserved
-
The naming convention for individual bits within the CIP Axis Status attributes is to append a 'Status' suffix to the CIP Axis Status condition. This table lists the resulting CIP Axis Status tags associated with the above status conditions.
Bit
Tag
0
LocalControlStatus
1
AlarmStatus
2
DCBusUpStatus
3
PowerStructureEnabledStatus
4
MotorFluxUpStatus
5
TrackingCommandStatus
6
PositionLockStatus
7
VelocityLockStatus
8
VelocityStandstillStatus
9
VelocityThresholdStatus
10
VelocityLimitStatus
11
AccelerationLimitStatus
12
DecelerationLimitStatus
13
TorqueThresholdStatus
14
TorqueLimitStatus
15
CurrentLimitStatus
16
ThermalLimitStatus
17
FeedbackIntegrityStatus
18
ShutdownStatus
19
InProcessStatus
20
DCBusUnloadStatus
21
ACPowerLossStatus
22
PositionControlMode
23
VelocityControlMode
24
TorqueControlMode
Axis Test Mode
Axes with the Test Mode attribute that is set to Enabled and that are configured for Controller Loop Back simulate these CIP Axis Status bits.
Bit
Tag
Axis Test Mode Support
(Test Mode Configuration)
1
AlarmStatus
Controller Loop Back: v35
2
DCBusUpStatus
Controller Loop Back: v35
3
PowerStructureEnabledStatus
Controller Loop Back: v35
5
TrackingCommandStatus
Controller Loop Back: v35
6
PositionLockStatus
Controller Loop Back: v35
7
VelocityLockStatus
Controller Loop Back: v35
8
VelocityStandstillStatus
*Controller Loop Back: v35
9
VelocityThresholdStatus
Controller Loop Back: v35
17
FeedbackIntegrityStatus
Controller Loop Back: v35
18
ShutdownStatus
Controller Loop Back: v35
20
DCBusUnloadStatus
Controller Loop Back: v35
21
ACPowerLossStatus
Controller Loop Back: v35
22
PositionControlMode
Controller Loop Back: v35
* Value is set to 1 by default. Value does not accurately reflect the axis’s move status.
CIP Axis Status 2
Usage
Access
T
Data Type
Default
Min
Max
Semantics of Values
Required - G
Optional - NED
All
Get/GSV
T
DWORD
-
-
-
Enumeration:
0 = Monitoring
1 = Regenerating
2 = Ride Thru
3 = AC Line Sync
4 = Bus Voltage Lock
5 = Reactive Power Only Mode
6 = Voltage Control Mode
7 = Power Loss
8 = AC Line Voltage Sag
9 = AC Line Phase Loss
10 = AC Line Frequency Change
11 = AC Line Sync Loss
12 = Single Phase
13 = Bus Voltage Limit
14 = Bus Voltage Rate Limit
15 = Active Current Rate Limit
16 = Reactive Current Rate Limit
17 = Reactive Power Limit
18 = Reactive Power Rate Limit
19 = Active Current Limit
20 = Reactive Current Limit
21 = Motoring Power Limit
22 = Regenerative Power Limit
23 = Converter Thermal Limit
24-31 = Reserved
The CIP Axis Status 2 attribute is a collection of standard bits indicating the internal status conditions of the axis. This attribute provides a 32-bit extension to the CIP Axis Status attribute.
CIP Axis Status 2 Bit Descriptions
Bit
Usage
Status Condition
Description
0
Optional/
G
Motoring
This bit is set when the regenerative converter is consuming power from the AC Line.
1
Optional/
G
Regenerating
This bit is set when the regenerative converter is regenerating power to the AC Line.
2
Optional/
GD
Ride Thru
This bit is set when the device has initiated a Ride Thru action, temporarily suspending PWM modulation, as a result of detecting a problem with the power source.
3
Optional/
G
AC Line Sync
This bit is set when regenerative converter is phase locked to the AC Line voltage.
4
Optional/
B
Bus Voltage Lock
This bit is set if the measured DC Bus Voltage is within a vendor-specific tolerance (that is 1%) of the Bus Voltage Reference.
5
Optional/
G
Reactive Power Only Mode
This bit is set when the regenerative converter is operating in Reactive Power Only Mode, supplying reactive power to the grid for Power Factor correction.
6
Optional/
G
Voltage Control Mode
When set, this bit indicates that the DC bus voltage is being actively controlled by the Bus Voltage Loop of the regenerative converter. The Voltage Control Mode status bit is cleared whenever the active Converter Control Mode is changed from Bus Voltage Control to AC Line Current Control. This status bit is clear if the converter is disabled.
7
Optional/
GD
Power Loss
This bit is set when a Power Loss condition has been detected. For a drive, this may have initiated a Ride Thru action, where the PWM output to the motor is temporarily suspended, or has initiated a Decel Regen action, where the drive attempts to hold up the DC Bus voltage by decelerating the motor. For a regenerative converter, this may have initiated a Ride Thru action where PWM Modulation is suspended to the AC Line.
8
Optional/
G
AC Line Voltage Sag
This bit is set when a regenerative converter detects a sag in AC line voltage. If configured to do so, this may have initiated a Ride Thru action, where PWM modulation to the AC line is temporarily suspended.
9
Optional/
G
AC Line Phase Loss
This bit is set when a regenerative converter detects an AC line phase loss. If configured to do so, this may have initiated a Ride Thru action, where PWM modulation to the AC line is temporarily suspended.
10
Optional/
G
AC Line Frequency Change
This bit is set when a regenerative converter detects a high rate of change of the AC line frequency. If configured to do so, this may have initiated a Ride Thru action, where PWM modulation to the AC line is temporarily suspended.
11
Optional/
G
AC Line Sync Loss
This bit is set when a regenerative converter detects it has lost synchronization to the AC line. If configured to do so, this may have initiated a Ride Thru action, where PWM modulation to the AC line is temporarily suspended.
12
Optional/
BD
Single Phase
This bit is set when the converter is operating on a single phase.
13
Optional/
G
Bus Voltage Limit
This bit is set if the bus voltage reference signal into the bus voltage control loop is limited by the Bus Voltage Limiter block.
14
Optional/
G
Bus Voltage Rate Limit
This bit is set if the bus voltage Rate Limiter block is limiting the rate of change of the bus voltage set point signal into the bus voltage control loop.
15
Optional/
G
Active Current Rate Limit
This bit is set if the Rate Limiter block is limiting the rate of change of the Active Current Command signal.
16
O/G
Reactive Current Rate Limit
This bit is set if the Rate Limiter block is limiting the rate of change of the Reactive Current Command signal.
17
Optional/
G
Reactive Power Limit
This bit is set if the Power Limiter block is limiting the Reactive Power Set Point signal.
18
Optional/
G
Reactive Power Rate Limit
This bit is set if the Rate Limiter block is limiting the rate of change of the Reactive Power Set Point signal.
19
Optional/
G
Active Current Limit
This bit is set if the active current reference signal is limited by the Current Limiter block.
20
Optional/
G
Reactive Current Limit
This bit is set if the reactive current reference signal is limited by the Current Limiter block.
21
Optional/
G
Motoring Power Limit
This bit is set if the current reference signals are limited by the Current Limiter block due to the Motoring Power Limit.
22
Optional/
G
Regenerative Power Limit
This bit is set if the current reference signals are limited by the Current Limiter block due to the Converter Regenerative Power Limit.
23
Optional/
G
Converter Thermal Limit
This bit is set if the current reference signals are limited by the Current Limiter block due to the Converter Thermal Current Limit.
24-31
-
Reserved
-
The naming convention for individual bits within the CIP Axis Status 2 attributes is to append a 'Status' suffix to the CIP Axis Status 2 condition. This table lists the resulting CIP Axis Status 2 tags associated with the above status conditions.
Bit
Tag
0
MotoringStatus
1
RegeneratingStatus
2
RideThruStatus
3
ACLineSyncStatus
4
BusVoltageLockStatus
5
ReactivePowerOnlyModeStatus
6
VoltageControlModeStatus
7
PowerLossStatus
8
ACLineVoltageSagStatus
9
ACLinePhaseLossStatus
10
ACLineFrequencyChangeStatus
11
ACLineSyncLossStatus
12
SinglePhaseStatus
13
BusVoltageLimit
14
BusVoltageRateLimit
15
ActiveCurrentRageLimit
16
ReactiveCurrentRateLimit
17
ReactivePowerLimit
18
ReactivePowerRateLimit
19
ActiveCurrentLimit
20
ReactiveCurrentLimit
21
MotoringPowerLimit
22
RegenerativePowerLimit
23
ConverterThermalLimit
Axis Test Mode
Axes with the Test Mode attribute set to Enabled and that are configured for Controller Loop Back simulate these CIP Axis Status 2 bits.
Bit
Tag
Axis Test Mode Support
(Test Mode Configuration)
3
PowerStructureEnabledStatus
Controller Loop Back: v35
4
TrackingCommandStatus
Controller Loop Back: v35
6
PositionLockStatus
Controller Loop Back: v35
13
VelocityLockStatus
Controller Loop Back: v35
CIP Axis Status 2 - Mfg
Usage
Access
T
Data Type
Default
Min
Max
Semantics of Values
Required - G
Optional - NED
All
Get/GSV
T
DWORD
-
-
-
Bitmap:
0-31: Vendor Specific
(Published in Product Manual)
The CIP Axis Status 2 - Mfg attribute is a collection of vendor-specific bits indicating the internal status of the axis.
CIP Axis Status - RA
Usage
Access
T
Data Type
Default
Min
Max
Semantics of Values
Required - All
Get/GSV
T
DWORD
-
-
-
Enumeration
0 = Torque Notch Filter Frequency Detected
1 = Torque Notch Filter Tuning Unsuccessful
2 = Torque Notch Filter Multiple Frequencies
3 = Torque Notch Filter Frequency Below Limit
4 = Torque Notch Filter Frequency Above Limit
5 = Adaptive Tune Gain Stabilization Active
6 - 31 = Reserved
The CIP Axis Status attribute is a 32-bit collection of
Rockwell Automation
specific bits indicating various internal status conditions of the device axis. Any status bits that are not applicable are set to 0.
CIP Axis Status- RA Status Bit Descriptions
Bit
Usage
Status Condition
Description
0
Optional/C
Torque Notch Filter Frequency Detected
This bit is set when the Adaptive Tuning function has detected a resonance frequency between the Torque Notch Filter Low Frequency Limit and the Torque Notch Filter High Frequency Limit with magnitude above the Toque Notch Filter Tuning Threshold.
Otherwise, the bit is clear.
This bit is cleared by the Adaptive Tuning function when the Axis state transitions to the Running state.
1
Optional/C
Torque Notch Filter Tuning Unsuccessful
  • When the Adaptive Tuning Configuration is set to Tracking Notch or Tracking Notch and Gain Stabilization, this bit is set when n+1 successive updates of the tunable Torque Notch Filters have failed to remove all resonances between the Torque Notch Filter Low Frequency Limit and the Torque Notch Filter High Frequency Limit with magnitude above the Toque Notch Filter Tuning
    T
    hreshold. Here “n” is defined as the configured Track Notch Filters attribute value. This condition can occur when there are more resonances in the system than there are tunable Torque Notch Filters. Otherwise, the bit is clear.
  • When this bit is set, and the Adaptive Tuning Configuration is set to Tracking Notch and Gain Stabilization, the Adaptive Tuning function decreases the Torque Low Pass Filter Bandwidth to attenuate the remaining resonances.
  • This bit is cleared by the Adaptive Tuning function when the Axis state transitions to the Running state or, when in the Running state, the Adaptive Tuning Configuration transitions from Disabled to one of the Torque Notch Filter Tuning enumerations.
2
Optional/C
Torque Notch Filter Multiple Frequencies
This bit is set when, the Adaptive Tuning function, identifies multiple resonant frequencies that are between the Torque Notch Filter Low Frequency Limit and the Torque Notch Filter High Frequency Limit whose magnitudes are above the Toque Notch Filter Tuning Threshold. Otherwise, the bit is clear.
This bit is cleared by the Adaptive Tuning function when the Axis state transitions to the Running state.
3
Optional/C
Torque Notch Filter Frequency Below Limit
This bit is set when the Adaptive Tuning function identifies a frequency that is below the Torque Notch Filter Low Frequency Limit but whose magnitude is higher than the configured Toque Notch Filter Tuning Threshold. Otherwise, the bit is clear.
This bit is cleared by the Adaptive Tuning function when the Axis state transitions to the Running state.
4
Optional/C
Torque Notch Filter Frequency Above Limit
This bit is set when the Adaptive Tuning function identifies a frequency that is above the Torque Notch Filter High Frequency Limit but whose magnitude is higher than the configured Toque Notch Filter Tuning Threshold. Otherwise, the bit is clear.
This bit is cleared by the Adaptive Tuning function when the Axis state transitions from disabled to enabled operation.
5
Optional/C
Adaptive Tune Gain Stabilization Active
This bit is set when the Adaptive Tuning Gain Scaling Factor is not equal to one. This indicates that the Adaptive Tuning function is actively adjusting servo loop gain values and the Torque Low Pass Filter Bandwidth value to improve system stability.
This bit is cleared by the Adaptive Tuning function when the Axis state transitions to the Running state.
6-31
-
Reserved
-
The naming convention for individual bits within the CIP Axis Status RA attributes is to append a 'Status' suffix to the CIP Axis Status RA condition. This table lists the resulting CIP Axis Status RA tags associated with the above status conditions.
Bit
Tag
0
TorqueNotchFilterFreqDetectedStatus
1
TorqueNotchFilterTuneUnsuccessfulStatus
2
TorqueNotchFilterMultipleFreqStatus
3
TorqueNotchFilterFreqBelowLimitStatus
4
TorqueNotchFilterFreqAboveLimitStatus
5
AdaptiveTuneGainStabilizationStatus
CIP Axis Status 2 - RA
Usage
Access
T
Data Type
Default
Min
Max
Semantics of Values
Required - G
Optional - NED
All
Get/GSV
T
DWORD
-
-
-
-
The CIP Axis Status 2 attribute is a collection of
Rockwell Automation
specific bits indicating various internal status conditions of the axis. This attribute provides a 32-bit extension to the CIP Axis RA attribute. Any status bits that are not applicable are set to 0.
CIP Axis Status 2 - RA Status Bit Descriptions
Bit
Usage
Status Condition
Description
0-31
Reserved
-
The naming convention for individual bits within the CIP Axis Status 2 RA attributes is to append a 'Status' suffix to the CIP Axis Status 2 RA condition. This table lists the resulting CIP Axis Status 2 RA tags associated with the above status conditions.
Bit
Tag
0
-
Axis I/O Status
Usage
Access
T
Data Type
Default
Min
Max
Semantics of Values
Required - All
Get
T
DWORD
-
-
-
See Semantics
The Axis I/O Status attribute is a 32-bit collection of bits indicating the state of standard digital inputs and outputs associated with the operation of this axis. A value of zero for a given input bit indicates a logical 0 value, while a value of one indicates a logical one value.
Axis I/O Status - Mfg
Usage
Access
T
Data Type
Default
Min
Max
Semantics of Values
Required - All
Get
T
DWORD
-
-
-
Bitmap:
0-31: Vendor Specific
(Published in Product Manual)
The Axis I/O Status - Mfg attribute is a collection of bits indicating the state of vendor-specific digital inputs associated with the operation of this axis. A value of zero for a given input bit indicates a logical 0 value, while a value of one indicates a logical one value.
CIP Axis I/O Status Bit Descriptions
Bit
Usage
Status Condition
Description
0
Optional/
XBD
Enable Input
This bit represents the logical state of the Enable Input.
1
Optional/
ED
Home Input
This bit represents the logical state of the Home Input.
2
Optional/
ED
Registration 1 Input
This bit represents the logical state of the Registration 1 Input.
3
Optional/
ED
Registration 2 Input
This bit represents the logical state of the Registration 2 Input.
4
Optional/
P
Positive Overtravel OK Input
This bit represents the logical state of the Positive Overtravel OK Input.
5
Optional/
P
Negative Overtravel OK Input
This bit represents the logical state of the Negative Overtravel OK Input.
6
Optional/
ED
Feedback 1 Thermostat OK Input
This bit represents the logical state of the Thermostat OK input associated with the motor mounted Feedback 1device.
7
Optional/
D
Resistive Brake Release Output
This bit represents the logical state of the Resistive Brake Release Output.
8
Optional/
XD
Mechanical Brake Release Output
This bit represents the logical state of the Mechanical Brake Release Output.
9
Optional/
D
Motor Thermostat OK Input
This bit represents the logical state of the Motor Thermostat OK Input.
10-31
-
Reserved
-
The naming convention for individual bits within the CIP Axis I/O Status attributes is to append a 'Status' suffix to the CIP Axis Status condition. This table lists the resulting CIP Axis I/O Status tags associated with the above status conditions.
Bit
Tag
0
EnableInputStatus
1
HomeInputStatus
2
Registration1InputStatus
3
Registration2InputStatus
4
PositiveOvertravelInputStatus
5
NegativeOvertravelInputStatus
6
Feedback1ThermostatInputStatus
7
ResistiveBrakeOutputStatus
8
MechanicalBrakeOutputStatus
9
MotorThermostatInputStatus
CIP Axis I/O Status - RA
Usage
Access
T
Data Type
Default
Min
Max
Semantics of Values
Required - All
Get/GSV
T
DWORD
-
-
-
Enumeration:
0 = Regenerative Power OK Input
1 = Bus Capacitor Module OK Input
2 = Shunt Thermal Switch OK Input
3 = Contactor Enable Output
4 = Pre-Charge OK Input
5 = AC Line Contactor OK Input
6 = Regenerative Power OK Output
7 = Bus Conditioner Module OK Input
8 = Converter OK Input
9 = Converter OK Output
10 - 31 = Reserved
Collection of bits indicating the state of
Rockwell Automation
specific digital inputs associated with the operation of this axis. A value of zero for a given input bit indicates a logical 0 value, while a value of one indicates a logical one value.
CIP Axis I/O Status - RA Bit Descriptions
Bit
Usage
Name
Description
0
Optional/
D
Regenerative Power OK Input
This bit represents the logical state of the Regenerative Power Input. This input status bit indicates that the associated external regenerative converter is in the Running state and capable of transferring regenerative power.
1
Optional/
BD
Bus Capacitor Module OK Input
This bit represents the logical state of the Bus Capacitor Module Input.
2
Optional/
BD
Shunt Thermal Switch OK Input
This bit represents the logical state of the Shunt Thermal Switch Input.
3
Optional/
BD
Contactor Enable Output
This bit represents the logical state of the Contactor Enable Output.
4
Optional/
BD
Pre-Charge OK Input
This bit represents the logical state of the Pre-Charge Input.
5
Optional/
BD
AC Line Contactor OK Input
This bit represents the logical state of the AC Line Contactor OK Input
6
Optional/
G
Regenerative Power OK Output
This bit represents the logical state of the Regenerative Power Output. This output status bit indicates this regenerative converter is in the Running state and capable of transferring regenerative power.
7
Optional/
BD
Bus Conditioner Module OK Input
This bit represents the logical state of the Bus Conditioner Module Input.
8
Optional/
D
Converter OK Input
This bit represents the logical state of the Converter OK Input. This input status bit indicates that the associated external converter has determined that the DC bus has reached operational voltage level and that the converter is not faulted.
9
Optional/
B
Converter OK Output
This bit represents the logical state of the Converter OK Output. This output bit indicates that this converter has determined that the DC bus has reached operational voltage level and is not currently faulted.
10-31
-
Reserved
-
The naming convention for individual bits within the CIP Axis I/O Status - RA attributes is to append a 'Status' suffix to the CIP Axis Status - RA condition. This table lists the resulting CIP Axis I/O Status -RA tags associated with the above status conditions.
Bit
Tag
0
RegenerativePowerInputStatus
1
BusCapacitorModuleInputStatus
2
ShuntThermalSwitchInputStatus
3
ContactorEnableOutputStatus
4
PreChargeInputStatus
5
ACLineContactorInputStatus
6
RegenerativePowerOutputStatus
7
BusConditioneerModuleInputStatus
8
ConverterInputStatus
9
ConverterOutputStatus
Provide Feedback
Have questions or feedback about this documentation? Please submit your feedback here.