-
Notifications
You must be signed in to change notification settings - Fork 51
NI RFmx SpecAn Phasenoise Configuration Functions
- RFmxSpecAn_PhaseNoiseCfgRangeDefinition
- RFmxSpecAn_PhaseNoiseCfgAutoRange
- RFmxSpecAn_PhaseNoiseCfgNumberOfRanges
- RFmxSpecAn_PhaseNoiseCfgRangeArray
- RFmxSpecAn_PhaseNoiseCfgAveragingMultiplier
- RFmxSpecAn_PhaseNoiseCfgSmoothing
- RFmxSpecAn_PhaseNoiseCfgSpotNoiseFrequencyList
- RFmxSpecAn_PhaseNoiseCfgIntegratedNoise
- RFmxSpecAn_PhaseNoiseCfgSpurRemoval
- RFmxSpecAn_PhaseNoiseCfgCancellation
int32 __stdcall RFmxSpecAn_PhaseNoiseCfgRangeDefinition (niRFmxInstrHandle instrumentHandle, char selectorString[], int32 rangeDefinition);
Specifies how the measurement computes offset subranges.
Input | ||
---|---|---|
Name | Type | Description |
instrumentHandle | niRFmxInstrHandle | Identifies the RFmx session. You can obtain this parameter from the RFmxSpecAn_Initialize) function. |
selectorString | char[] | Comprises the signal name. If you do not specify the signal name, the default signal instance is used. Example: "" "signal::sig1" You can use the RFmxSpecAn_BuildSignalString) function to build the selector string). |
rangeDefinition | int32 | Specifies how the measurement computes offset subranges. |
RFMXSPECAN_VAL_PHASENOISE_RANGE_DEFINITION_MANUAL (0) | Specify the offset sub-ranges used for the measurement. Use the RFMXSPECAN_ATTR_PHASENOISE_RANGE_START_FREQUENCY attribute and the RFMXSPECAN_ATTR_PHASENOISE_RANGE_STOP_FREQUENCY attribute to configure single or multiple range start and range stop frequencies. |
---|---|
RFMXSPECAN_VAL_PHASENOISE_RANGE_DEFINITION_AUTO (1) | Measurement computes offset sub-ranges by dividing the user configured offset range into multiple decade sub-ranges. The range is specified by the RFMXSPECAN_ATTR_PHASENOISE_START_FREQUENCY and the RFMXSPECAN_ATTR_PHASENOISE_STOP_FREQUENCY attributes. |
Name | Type | Description |
---|---|---|
status | int32 | Returns the status code of this operation. The status code either indicates success or describes an error or warning condition. Examine the status code from each call to an RFmx function to determine if an error has occurred. To obtain a text description of the status code and additional information about the error condition, call the RFmxSpecAn_GetError) function. The general meaning of the status code is as follows: |
Value | Meaning |
---|---|
0 | Success |
Positive Values | Warnings |
Negative Values | Errors |
int32 __stdcall RFmxSpecAn_PhaseNoiseCfgAutoRange (niRFmxInstrHandle instrumentHandle, char selectorString[], float64 startFrequency, float64 stopFrequency, float64 RBWPercentage);
Configures the offset range and the RBW percentage when you set the RFMXSpecAn_ATTR_PHASENOISE_RANGE_DEFINITION) attribute to RFMXSPECAN_VAL_PHASENOISE_RANGE_DEFINITION_AUTO.
Input | ||
---|---|---|
Name | Type | Description |
instrumentHandle | niRFmxInstrHandle | Identifies the RFmx session. You can obtain this parameter from the RFmxSpecAn_Initialize) function. |
selectorString | char[] | Comprises the signal name. If you do not specify the signal name, the default signal instance is used. Example: "" "signal::sig1" You can use the RFmxSpecAn_BuildSignalString) function to build the selector string). |
startFrequency | float64 | Specifies the start frequency of the offset frequency when you set the RFMXSPECAN_ATTR_PHASENOISE_RANGE_DEFINITION attribute to RFMXSPECAN_VAL_PHASENOISE_RANGE_DEFINITION_AUTO. This value is expressed in Hz. |
stopFrequency | float64 | Specifies the stop frequency of the offset frequency range when you set the RFMXSPECAN_ATTR_PHASENOISE_RANGE_DEFINITION attribute to RFMXSPECAN_VAL_PHASENOISE_RANGE_DEFINITION_AUTO. This value is expressed in Hz. |
RBWPercentage | float64 | Specifies the RBW as a percentage of the start frequencyof each sub-range when you set the RFMXSPECAN_ATTR_PHASENOISE_RANGE_DEFINITION attribute to RFMXSPECAN_VAL_PHASENOISE_RANGE_DEFINITION_AUTO. This value is expressed as a percentage. |
Name | Type | Description |
---|---|---|
status | int32 | Returns the status code of this operation. The status code either indicates success or describes an error or warning condition. Examine the status code from each call to an RFmx function to determine if an error has occurred. To obtain a text description of the status code and additional information about the error condition, call the RFmxSpecAn_GetError) function. The general meaning of the status code is as follows: |
Value | Meaning |
---|---|
0 | Success |
Positive Values | Warnings |
Negative Values | Errors |
int32 __stdcall RFmxSpecAn_PhaseNoiseCfgNumberOfRanges (niRFmxInstrHandle instrumentHandle, char selectorString[], int32 numberOfRanges);
Configures the number of offset ranges when you set the RFMXSpecAn_ATTR_PHASENOISE_RANGE_DEFINITION) attribute to Manual.
Input | ||
---|---|---|
Name | Type | Description |
instrumentHandle | niRFmxInstrHandle | Identifies the RFmx session. You can obtain this parameter from the RFmxSpecAn_Initialize) function. |
selectorString | char[] | Comprises the signal name. If you do not specify the signal name, the default signal instance is used. Example: "" "signal::sig1" You can use the RFmxSpecAn_BuildSignalString) function to build the selector string). |
numberOfRanges | int32 | Specifies the number of manual ranges. |
Name | Type | Description |
---|---|---|
status | int32 | Returns the status code of this operation. The status code either indicates success or describes an error or warning condition. Examine the status code from each call to an RFmx function to determine if an error has occurred. To obtain a text description of the status code and additional information about the error condition, call the RFmxSpecAn_GetError) function. The general meaning of the status code is as follows: |
Value | Meaning |
---|---|
0 | Success |
Positive Values | Warnings |
Negative Values | Errors |
int32 __stdcall RFmxSpecAn_PhaseNoiseCfgRangeArray (niRFmxInstrHandle instrumentHandle, char selectorString[], float64 rangeStartFrequency[], float64 rangeStopFrequency[], float64 rangeRBWPercentage[], int32 rangeAveragingCount[], int32 numberOfElements);
Configures an array of the offset range, RBW percentage and averaging count when you set the RFMXSpecAn_ATTR_PHASENOISE_RANGE_DEFINITION) attribute to RFMXSPECAN_VAL_PHASENOISE_RANGE_DEFINITION_MANUAL.
Input | ||
---|---|---|
Name | Type | Description |
instrumentHandle | niRFmxInstrHandle | Identifies the RFmx session. You can obtain this parameter from the RFmxSpecAn_Initialize) function. |
selectorString | char[] | Comprises the signal name. If you do not specify the signal name, the default signal instance is used. Example: "" "signal::sig1" You can use the RFmxSpecAn_BuildSignalString) function to build the selector string). |
rangeStartFrequency | float64[] | Specifies the start frequency for the specified subrange when you set the RFMXSPECAN_ATTR_PHASENOISE_RANGE_DEFINITION attribute to RFMXSPECAN_VAL_PHASENOISE_RANGE_DEFINITION_MANUAL. |
rangeStopFrequency | float64[] | Specifies the stop frequency for the specified subrange when you set the RFMXSPECAN_ATTR_PHASENOISE_RANGE_DEFINITION attribute to RFMXSPECAN_VAL_PHASENOISE_RANGE_DEFINITION_MANUAL. This value is expressed in Hz. |
rangeRBWPercentage | float64[] | Specifies the RBW of the start offset of each sub-range. This value is expressed as a percentage. |
rangeAveragingCount | int32[] | Specifies the averaging count for the specified range. |
numberOfElements | int32 | Specifies the number of elements in each array. |
Name | Type | Description |
---|---|---|
status | int32 | Returns the status code of this operation. The status code either indicates success or describes an error or warning condition. Examine the status code from each call to an RFmx function to determine if an error has occurred. To obtain a text description of the status code and additional information about the error condition, call the RFmxSpecAn_GetError) function. The general meaning of the status code is as follows: |
Value | Meaning |
---|---|
0 | Success |
Positive Values | Warnings |
Negative Values | Errors |
int32 __stdcall RFmxSpecAn_PhaseNoiseCfgAveragingMultiplier (niRFmxInstrHandle instrumentHandle, char selectorString[], int32 averagingMultiplier);
Configures the averaging multiplier.
Input | ||
---|---|---|
Name | Type | Description |
instrumentHandle | niRFmxInstrHandle | Identifies the RFmx session. You can obtain this parameter from the RFmxSpecAn_Initialize) function. |
selectorString | char[] | Comprises the signal name. If you do not specify the signal name, the default signal instance is used. Example: "" "signal::sig1" You can use the RFmxSpecAn_BuildSignalString) function to build the selector string). |
averagingMultiplier | int32 | Specifies the factor by which the averaging count for each sub-range to increase. |
Name | Type | Description |
---|---|---|
status | int32 | Returns the status code of this operation. The status code either indicates success or describes an error or warning condition. Examine the status code from each call to an RFmx function to determine if an error has occurred. To obtain a text description of the status code and additional information about the error condition, call the RFmxSpecAn_GetError) function. The general meaning of the status code is as follows: |
Value | Meaning |
---|---|
0 | Success |
Positive Values | Warnings |
Negative Values | Errors |
int32 __stdcall RFmxSpecAn_PhaseNoiseCfgSmoothing (niRFmxInstrHandle instrumentHandle, char selectorString[], int32 smoothingType, float64 smoothingPercentage);
Configures the smoothing type and smoothing percentage used to smoothen the measured log plot trace.
Input | ||
---|---|---|
Name | Type | Description |
instrumentHandle | niRFmxInstrHandle | Identifies the RFmx session. You can obtain this parameter from the RFmxSpecAn_Initialize) function. |
selectorString | char[] | Comprises the signal name. If you do not specify the signal name, the default signal instance is used. Example: "" "signal::sig1" You can use the RFmxSpecAn_BuildSignalString) function to build the selector string). |
smoothingType | int32 | Specifies the smoothing type used to smoothen a log plot trace. |
RFMXSPECAN_VAL_PHASENOISE_SMOOTHING_TYPE_NONE (0) | Smoothing is disabled. |
---|---|
RFMXSPECAN_VAL_PHASENOISE_SMOOTHING_TYPE_LINEAR (1) | Performs linear moving average filtering on the measured phase noise log plot trace. |
RFMXSPECAN_VAL_PHASENOISE_SMOOTHING_TYPE_LOGARITHMIC (2) | Performs logarithmic moving average filtering on the measured phase noise log plot trace. |
RFMXSPECAN_VAL_PHASENOISE_SMOOTHING_TYPE_MEDIAN (3) | Performs moving median filtering on the measured phase noise log plot trace. |
smoothingPercentage | float64 | Specifies the number of points to use in the moving average filter as a percentage of total number of points in the log plot trace. This value is expressed as a percentage. |
Name | Type | Description |
---|---|---|
status | int32 | Returns the status code of this operation. The status code either indicates success or describes an error or warning condition. Examine the status code from each call to an RFmx function to determine if an error has occurred. To obtain a text description of the status code and additional information about the error condition, call the RFmxSpecAn_GetError) function. The general meaning of the status code is as follows: |
Value | Meaning |
---|---|
0 | Success |
Positive Values | Warnings |
Negative Values | Errors |
int32 __stdcall RFmxSpecAn_PhaseNoiseCfgSpotNoiseFrequencyList (niRFmxInstrHandle instrumentHandle, char selectorString[], float64 frequencyList[], int32 arraySize);
Configures a list of frequencies at which the phase noise values are to be read using the smoothed log plot trace.
Input | ||
---|---|---|
Name | Type | Description |
instrumentHandle | niRFmxInstrHandle | Identifies the RFmx session. You can obtain this parameter from the RFmxSpecAn_Initialize) function. |
selectorString | char[] | Comprises the signal name. If you do not specify the signal name, the default signal instance is used. Example: "" "signal::sig1" You can use the RFmxSpecAn_BuildSignalString) function to build the selector string). |
frequencyList | float64[] | Specifies an array of offset frequencies at which the corresponding phase noise is measured using the smoothed log plot trace. This value is expressed in Hz. |
arraySize | int32 | Specifies the size of the array. |
Name | Type | Description |
---|---|---|
status | int32 | Returns the status code of this operation. The status code either indicates success or describes an error or warning condition. Examine the status code from each call to an RFmx function to determine if an error has occurred. To obtain a text description of the status code and additional information about the error condition, call the RFmxSpecAn_GetError) function. The general meaning of the status code is as follows: |
Value | Meaning |
---|---|
0 | Success |
Positive Values | Warnings |
Negative Values | Errors |
int32 __stdcall RFmxSpecAn_PhaseNoiseCfgIntegratedNoise (niRFmxInstrHandle instrumentHandle, char selectorString[], int32 integratedNoiseRangeDefinition, float64 integratedNoiseStartFrequency[], float64 integratedNoiseStopFrequency[], int32 arraySize);
Configures the integrated noise ranges. The smoothed log plot trace is used when computing integrated measurements.
Input | ||
---|---|---|
Name | Type | Description |
instrumentHandle | niRFmxInstrHandle | Identifies the RFmx session. You can obtain this parameter from the RFmxSpecAn_Initialize) function. |
selectorString | char[] | Comprises the signal name. If you do not specify the signal name, the default signal instance is used. Example: "" "signal::sig1" You can use the RFmxSpecAn_BuildSignalString) function to build the selector string). |
integratedNoiseRangeDefinition | int32 | Specifies whether to use the complete measurement range for computing integrated measurements, or to use the range that you specify. |
integratedNoiseStartFrequency | float64[] | Specifies an array of the start frequencies for integrated measurement. This value is expressed in Hz. |
integratedNoiseStopFrequency | float64[] | Specifies an array of the stop offset frequencies for integrated measurement. This value is expressed in Hz. |
arraySize | int32 | Specifies the size of the array. |
Name | Type | Description |
---|---|---|
status | int32 | Returns the status code of this operation. The status code either indicates success or describes an error or warning condition. Examine the status code from each call to an RFmx function to determine if an error has occurred. To obtain a text description of the status code and additional information about the error condition, call the RFmxSpecAn_GetError) function. The general meaning of the status code is as follows: |
Value | Meaning |
---|---|
0 | Success |
Positive Values | Warnings |
Negative Values | Errors |
int32 __stdcall RFmxSpecAn_PhaseNoiseCfgSpurRemoval (niRFmxInstrHandle instrumentHandle, char selectorString[], int32 spurRemovalEnabled, float64 peakExcursion);
Configures enabling or disabling of the spur removal and the peak excursion to use when spur removal is enabled.
Input | ||
---|---|---|
Name | Type | Description |
instrumentHandle | niRFmxInstrHandle | Identifies the RFmx session. You can obtain this parameter from the RFmxSpecAn_Initialize) function. |
selectorString | char[] | Comprises the signal name. If you do not specify the signal name, the default signal instance is used. Example: "" "signal::sig1" You can use the RFmxSpecAn_BuildSignalString) function to build the selector string). |
spurRemovalEnabled | int32 | Specifies whether the spur removal is enabled or disabled. |
RFMXSPECAN_VAL_PHASENOISE_SPUR_REMOVAL_ENABLED_FALSE (0) | Disables spur removal on the log plot trace. |
---|---|
RFMXSPECAN_VAL_PHASENOISE_SPUR_REMOVAL_ENABLED_TRUE (1) | Enables spur removal on the log plot trace. |
peakExcursion | float64 | Specifies the minimum amplitude variation required in a signal to be considered as a peak. The signal must rise and fall above the threshold level by at least the peak excursion value to be considered as an eligible peak. The threshold is a curve fit performed on the measured phase noise. |
Name | Type | Description |
---|---|---|
status | int32 | Returns the status code of this operation. The status code either indicates success or describes an error or warning condition. Examine the status code from each call to an RFmx function to determine if an error has occurred. To obtain a text description of the status code and additional information about the error condition, call the RFmxSpecAn_GetError) function. The general meaning of the status code is as follows: |
Value | Meaning |
---|---|
0 | Success |
Positive Values | Warnings |
Negative Values | Errors |
int32 __stdcall RFmxSpecAn_PhaseNoiseCfgCancellation (niRFmxInstrHandle instrumentHandle, char selectorString[], int32 cancellationEnabled, float64 cancellationThreshold, float32 frequency[], float32 referencePhaseNoise[], int32 arraySize);
Configures the enabling or disabling of the phase noise cancellation, threshold cancellation, and the reference phase noise used for cancellation.
Input | ||
---|---|---|
Name | Type | Description |
instrumentHandle | niRFmxInstrHandle | Identifies the RFmx session. You can obtain this parameter from the RFmxSpecAn_Initialize) function. |
selectorString | char[] | Comprises the signal name. If you do not specify the signal name, the default signal instance is used. Example: "" "signal::sig1" You can use the RFmxSpecAn_BuildSignalString) function to build the selector string). |
cancellationEnabled | int32 | Specifies whether to enable or disable the phase noise cancellation. |
RFMXSPECAN_VAL_PHASENOISE_CANCELLATION_ENABLED_FALSE (0) | Disables phase noise cancellation. |
---|---|
RFMXSPECAN_VAL_PHASENOISE_CANCELLATION_ENABLED_TRUE (1) | Enables phase noise cancellation. Specify the value to be used for phase noise cancellation in the RFMXSPECAN_ATTR_PHASENOISE_CANCELLATION_REFERENCE_PHASE_NOISE attribute. |
cancellationThreshold | float64 | Specifies the minimum delta between the reference and pre-cancellation traces that must exist before any cancellation is performed. The delta is evaluated on a bin per bin basis. This value is expressed in dB. |
frequency | float32[] | Specifies an array of frequency offsets where the reference phase noise has been measured. This value is expressed in Hz. |
referencePhaseNoise | float32[] | Specifies an array of the reference phase noise at the frequency offsets. This value is expressed in dBc/Hz. |
arraySize | int32 | Specifies the size of the array. |
Name | Type | Description |
---|---|---|
status | int32 | Returns the status code of this operation. The status code either indicates success or describes an error or warning condition. Examine the status code from each call to an RFmx function to determine if an error has occurred. To obtain a text description of the status code and additional information about the error condition, call the RFmxSpecAn_GetError) function. The general meaning of the status code is as follows: |
Value | Meaning |
---|---|
0 | Success |
Positive Values | Warnings |
Negative Values | Errors |
Creating and Setting Up a gRPC Server
Session Utilities API Reference
gRPC API Differences From C API
Sharing Driver Sessions Between Clients
C API Docs
NI-DAQmx
- gRPC API Differences From C API
- Task Configuration And Control
- Channel Configuration And Creation
- Timing
- Triggering
- Read Functions
- Write Functions
- Export Hardware Signals
- Scale Configuration
- Internal Buffer Configuration
- Advanced Functions
- System Configuration
- Error Handling
- Buffer Attributes
- Calibration Info Attributes
- Channel Attributes
- Device Attributes
- Export Signal Attributes
- Persisted Channel Attributes
- Persisted Scale Attributes
- Persisted Task Attributes
- Physical Channel Attributes
- Read Attributes
- Scale Attributes
- System Attributes
- Task Attributes
- Timing Attributes
- Trigger Attributes
- Watchdog Attributes
- Write Attributes
NI-DCPOWER
- Setup Functions
- Configure Functions
- Measurement Functions
- Control Functions
- Trigger And Event
- Attribute Functions
- Query Functions
- Calibration Functions
- Utility Functions
- Supported Device
- Source Attributes
- Transient Attributes
- Voltage Attributes
- Current Attributes
- Pulse Voltage Attributes
- Pulse Current Attributes
- Cutoff Attributes
- Measurement Attributes
- Trigger Attributes Functions
- Event Attributes
- Advanced Attributes
- Inherent Ivi Attributes
- Supported Device Attributes
NI-DIGITAL PATTERN DRIVER
- Init And Close Functions
- Session Locking Functions
- Utility Functions
- Error Handling Functions
- Calibration Functions
- Attributes Functions
- Pin Map Functions
- Low Level Functions
- Low Level Action Functions
- Pin Control Functions
- Static IO Functions
- Clock Generator Functions
- Levels And Timing Functions
- TDR Functions
- PPMU Configuration Functions
- DC Voltage Functions
- DC Current Functions
- PPMU Action Functions
- Pattern Configuration Functions
- Pattern Action Functions
- History Ram Functions
- Source Memory Functions
- Capture Memory Functions
- Triggers And Events Functions
- Conditional Jump Trigger Functions
- Sequencer Flag Functions
- Sequencer Register Functions
- Match Fail Combination Functions
- Pattern Results Functions
- Sort Results Functions
- Frequency Measurement Functions
- IVI Inherent Attributes
- Specific Driver Information Attributes, Read Only
- Driver Setup Information Attributes
- Device Attributes
- Pin Control Attributes
- Level Configuration Attributes
- Trigger Configuration Attributes
- PPMU Attributes
- Patterns Attributes
- Pattern Opcode Event Attributes
- Timing Offset Attributes
- Keep Alive Attributes
- Frequency Measurement Attributes
- Clock Generator Attributes
- History RAM
- Synchronization Attributes
- TDR Endpoint Termination Attributes
NI-FGEN
- Setup Functions
- Configuration Functions
- Standard Output Functions
- Arbitrary Waveform Output Functions
- Arbitrary Sequence Output Functions
- Incremental Waveform Write Functions
- Configure Clock Functions
- Trigger And Syncronizations Functions
- 5404 Routing Functions
- Script Output Functions
- Configure Onboard Signal Processing Functions
- Configure Peer To Peer Functions
- Attribute Functions
- Waveform Control Functions
- Error Functions
- Output Attributes
- Arbitrary Waveform Attributes
- Data Transfer Attributes
- Onboard Signal Processing Attributes
- Peer To Peer Attributes
- Standard Function Attributes
- Clock Attributes
- Event Attributes
- Triggering Attributes
- Instrument Specific Attributes
- Inherent IVI Attributes
- 5401 5411 5431
NI-RFmx Bluetooth
- gRPC API Differences From C API
- General Functions
- Configuration Functions
- Set And Get Attribute Functions
- Fetch Results Functions
- Utility Functions
- Build String Functions
- Advanced Functions
- General Attributes
- Trigger Attributes
- Packet Attributes
- Auto Detect Signal Attributes
- Modacc Attributes
- ACP Attributes
- Twenty dB Attributes
- Frequency Range Attributes
- TXP Attributes
- Advanced Attributes
NI-RFmx NR
- gRPC API Differences From C API
- General Functions
- Configuration Functions
- Set And Get Attributes Functions
- Fetch Results Functions
- Utility Functions
- Build String Functions
- Advanced Functions
- General Attributes
- Trigger Attributes
- Signal Detection Attributes
- Component Carrier Attributes
- List Attributes
- Modacc Attributes
- ACP Attributes
- CHP Attributes
- OBW Attributes
- SEM Attributes
- TXP Attributes
- Pvt Attributes
- Advanced Attributes
NI-RFmx LTE
- gRPC API Differences From C API
- General Functions
- Configuration Functions
- Ch Configuration Functions
- NB IoT Configuration Functions
- ModAcc Configuration Functions
- ACP Configuration Functions
- CHP Configuration Functions
- OBW Configuration Functions
- SEM Configuration Functions
- PVT Configuration Functions
- SlotPhase Configuration Functions
- SlotPower Configuration Functions
- Set And Get Attribute Functions
- ModAcc Fetch Functions
- ACP Fetch Functions
- CHP Fetch Functions
- OBW Fetch Functions
- SEM Fetch Functions
- PVT Fetch Functions
- SlotPhase Fetch Functions
- SlotPower Fetch Functions
- Utility Functions
- Build String Functions
- Advanced Functions
- General Attributes
- Trigger Attributes
- Component Carrier Attributes
- ModAcc Attributes
- ACP Attributes
- CHP Attributes
- OBW Attributes
- SEM Attributes
- PVT Attributes
- SlotPhase Attributes
- SlotPower Attributes
- Advanced Attributes
NI-RFmx SpecAn
- gRPC API Differences From C API
- General Functions
- Configuration Functions
- Set And Get Attribute Functions
- Read Functions
- Fetch Functions
- Utility Functions
- Marker Functions
- Build String Functions
- Advanced Functions
- General Attributes
- Trigger Attributes
- ACP Attributes
- Cdf Attributes
- CHP Attributes
- Fcnt Attributes
- Harm Attributes
- OBW Attributes
- SEM Attributes
- Spectrum Attributes
- Spur Attributes
- TXP Attributes
- AMPM Attributes
- Dpd Attributes
- IQ Attributes
- IM Attributes
- NF Attributes
- Phasenoise Attributes
- PAVT Attributes
- Advanced Attributes
NI-RFmx WLAN
- gRPC API Differences From C API
- General Functions
- Configuration Functions
- Set And Get Attribute Functions
- Fetch DSSS ModAcc Functions
- Fetch OFDM ModAcc Functions
- Fetch SEM Functions
- Fetch TXP Functions
- Fetch PowerRamp Functions
- Utility Functions
- Build String Functions
- Advanced Functions
- General Attributes
- Trigger Attributes
- OFDM Attributes
- Auto Detect Signal Attributes
- DSSS ModAcc Attributes
- OFDM ModAcc Attributes
- SEM Attributes
- TXP Attributes
- PowerRamp Attributes
- Advanced Attributes
NI-RFSA
- General Functions
- Configuration Functions
- Acquisition Functions
- Utility Functions
- Calibration Functions
- General Attributes
- Vertical Attributes
- Signal Path Attributes
- Acquisition Attributes
- Acquisition Attributes
- Triggers Attributes
- Events Attributes
- Device Characteristics Attributes
- Peer To Peer Streaming Attributes
- Configuration List Attributes
- Inherent IVI Properties Attributes
- De-embedding Attributes
- Self Calibration Attributes
- Factory Calibration Attributes
- External Alignment Attributes
- Device Specific Attributes
NI-RFSG
- General Functions
- Generation Configuration
- Utility Functions
- Calibration Functions
- Arb Attributes
- Clock Attributes
- Configuration List Attributes
- De-embedding Attributes
- Device Characteristics Attributes
- Device Specific Attributes
- Events Attributes
- External Calibration Attributes
- Inherent IVI Attributes Attributes
- IQ Impairment Attributes
- Load Configurations Attributes
- Modulation Attributes
- Obsolete Attributes
- Peer To Peer Attributes
- RF Attributes
- Self Calibration Attributes
- Triggers Attributes
NI-SCOPE
- Setup Functions
- Configure Functions
- Attribute Functions
- Acquisition Functions
- Measurement Functions
- Calibrate Functions
- Utility Funcitons
- Error Handling Functions
- IVI Compliance Or Obsolete Functions
- Vertical Attributes
- Horizontal Attributes
- Trigger Attributes
- Clocking Attributes
- Synchronization Attributes
- Acquisition Attributes
- Waveform Measurements Attributes
- Onboard Signal Processing Attributes
- Peer To Peer Streaming Attributes
- Device Attributes
- IVI Or Obsolete Attributes
- Instrument Capabilities Attributes
- If Digitizer Attributes
NI-XNET
- gRPC API differences from C APIs
- General Functions
- Cluster Properties
- Database Properties
- Device Properties
- ECU Properties
- Frame Properties
- Interface Properties
- LIN Schedule Entry Properties
- LIN Schedule Properties
- PDU Properties
- Session Ethernet Properties
- Session Frame Properties
- Session Interface Properties
- Session Properties
- Session SAE J1939 Properties
- Signal Properties
- Subframe Properties
- System Properties
- IP-Stack Functions
- Socket Options
- Socket Functions