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NI RFmx SpecAn Marker Functions
- RFmxSpecAn_MarkerCfgNumberOfMarkers
- RFmxSpecAn_MarkerCfgType
- RFmxSpecAn_MarkerCfgReferenceMarker
- RFmxSpecAn_MarkerCfgXLocation
- RFmxSpecAn_MarkerCfgThreshold
- RFmxSpecAn_MarkerCfgTrace
- RFmxSpecAn_MarkerCfgPeakExcursion
- RFmxSpecAn_MarkerPeakSearch
- RFmxSpecAn_MarkerNextPeak
- RFmxSpecAn_MarkerFetchXY
int32 __stdcall RFmxSpecAn_MarkerCfgNumberOfMarkers (niRFmxInstrHandle instrumentHandle, char selectorString[], int32 numberOfMarkers);
Configures the number of markers.
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). |
numberOfMarkers | int32 | Specifies the number of markers. |
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_MarkerCfgType (niRFmxInstrHandle instrumentHandle, char selectorString[], int32 markerType);
Configures the marker type.
Use "marker<n>" as the selector string to configure this function.
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 and marker number. If you do not specify the signal name, the default signal instance is used. Example: "marker0" "signal::sig1/marker0" You can use the RFmxSpecAn_BuildMarkerString2 )function to build the selector string). |
markerType | int32 | Specifies whether the marker is disabled (Off) or is enabled (On) either as a normal marker or a delta marker. |
RFMXSPECAN_VAL_MARKER_MARKER_TYPE_OFF (0) | The marker is disabled. |
---|---|
RFMXSPECAN_VAL_MARKER_MARKER_TYPE_NORMAL (1) | The marker is enabled as a normal marker. |
RFMXSPECAN_VAL_MARKER_MARKER_TYPE_DELTA (3) | The marker is enabled as a delta marker. |
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_MarkerCfgReferenceMarker (niRFmxInstrHandle instrumentHandle, char selectorString[], int32 referenceMarker);
Configures the reference marker to a delta marker.
Use "marker<n>" as the selector string to configure this function.
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 and marker number. If you do not specify the signal name, the default signal instance is used. Example: "marker0" "signal::sig1/marker0" You can use the RFmxSpecAn_BuildMarkerString2 )function to build the selector string). |
referenceMarker | int32 | Specifies the marker to be used as reference marker when you set the RFMXSPECAN_ATTR_MARKER_TYPE attribute to RFMXSPECAN_VAL_MARKER_MARKER_TYPE_DELTA. This parameter is not used when you set the RFMXSPECAN_ATTR_MARKER_TYPE attribute to RFMXSPECAN_VAL_MARKER_MARKER_TYPE_NORMAL. |
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_MarkerCfgXLocation (niRFmxInstrHandle instrumentHandle, char selectorString[], float64 markerXLocation);
Configures the X location of the marker. Ensure that you configure the reference marker X location or perform peak search on the reference marker before configuring the X location for the Delta marker.
Use "marker<n>" as the selector string to configure this function.
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 and marker number. If you do not specify the signal name, the default signal instance is used. Example: "marker0" "signal::sig1/marker0" You can use the RFmxSpecAn_BuildMarkerString2 )function to build the selector string). |
markerXLocation | float64 | Specifies the X location of the marker on the trace when you set the marker type to Normal. The X location is relative to the value of the reference marker when you set the marker type to Delta. |
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_MarkerCfgThreshold (niRFmxInstrHandle instrumentHandle, char selectorString[], int32 thresholdEnabled, float64 threshold);
Configures the threshold to use for peak search.
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). |
thresholdEnabled | int32 | Specifies whether to enable the threshold for the trace while finding the peaks. |
RFMXSPECAN_VAL_MARKER_THRESHOLD_ENABLED_FALSE (0) | Disables the threshold for the trace while finding the peaks. |
---|---|
RFMXSPECAN_VAL_MARKER_THRESHOLD_ENABLED_TRUE (1) | Enables the threshold for the trace while finding the peaks. |
threshold | float64 | Specifies the threshold for finding the peaks on the trace. |
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_MarkerCfgTrace (niRFmxInstrHandle instrumentHandle, char selectorString[], int32 trace);
Configures the measurement trace to be used by the marker.
Use "marker<n>" as the selector string to configure this function.
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 and marker number. If you do not specify the signal name, the default signal instance is used. Example: "marker0" "signal::sig1/marker0" You can use the RFmxSpecAn_BuildMarkerString2 )function to build the selector string). |
trace | int32 | Specifies the trace. |
RFMXSPECAN_VAL_MARKER_TRACE_ACP_SPECTRUM (0) | The marker uses the ACP spectrum trace. |
---|---|
RFMXSPECAN_VAL_MARKER_TRACE_CCDF_GAUSSIAN_PROBABILITIES_TRACE (1) | The marker uses the CCDF Gaussian probabilities trace. |
RFMXSPECAN_VAL_MARKER_TRACE_CCDF_PROBABILITIES_TRACE (2) | The marker uses the CCDF probabilities trace. |
RFMXSPECAN_VAL_MARKER_TRACE_CHP_SPECTRUM (3) | The marker uses the CHP spectrum trace. |
RFMXSPECAN_VAL_MARKER_TRACE_FCNT_POWER_TRACE (4) | The marker uses the FCnt power trace. |
RFMXSPECAN_VAL_MARKER_TRACE_OBW_SPECTRUM (5) | The marker uses the OBW spectrum trace. |
RFMXSPECAN_VAL_MARKER_TRACE_SEM_SPECTRUM (6) | The marker uses the SEM spectrum trace. |
RFMXSPECAN_VAL_MARKER_TRACE_SPECTRUM (7) | The marker uses the Spectrum trace. |
RFMXSPECAN_VAL_MARKER_TRACE_TXP_POWER_TRACE (8) | The marker uses the TXP power trace. |
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_MarkerCfgPeakExcursion (niRFmxInstrHandle instrumentHandle, char selectorString[], int32 peakExcursionEnabled, float64 peakExcursion);
Configures the peak excursion.
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). |
peakExcursionEnabled | int32 | Specifies whether to enable the peak excursion check for the trace while finding the peaks. |
RFMXSPECAN_VAL_MARKER_PEAK_EXCURSION_ENABLED_FALSE (0) | Disables the peak excursion check for the trace while finding the peaks. |
---|---|
RFMXSPECAN_VAL_MARKER_PEAK_EXCURSION_ENABLED_TRUE (1) | Enables the peak excursion check for the trace while finding the peaks. |
peakExcursion | float64 | Specifies the peak excursion value for finding the peaks on trace when you set the peakExcursionEnabled parameter to RFMXSPECAN_VAL_MARKER_PEAK_EXCURSION_ENABLED_TRUE. The signal should rise and fall by at least the peak excursion value, above the threshold, to be considered as a peak. |
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_MarkerPeakSearch (niRFmxInstrHandle instrumentHandle, char selectorString[], int32 *numberOfPeaks);
Moves the marker to the highest peak above the threshold on the configured trace.
Use "marker<n>" as the selector string to read results from this function.
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, result name, and marker number. If you do not specify the signal name, the default signal instance is used. Example: "marker0" "signal::sig1/marker0" "result::r1/marker0" "signal::sig1/result::r1/marker0" You can use the RFmxSpecAn_BuildMarkerString2 )function to build the selector string). |
Output | ||
Name | Type | Description |
numberOfPeaks | int32* | Returns the total number of peaks above the threshold, when you enable the marker threshold. |
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_MarkerNextPeak (niRFmxInstrHandle instrumentHandle, char selectorString[], int32 nextPeak, int32 *nextPeakFound);
Moves the marker to the next highest or next left or next right peak above the threshold on the configured trace.
Use "marker<n>" as the selector string to read results from this function.
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, result name, and marker number. If you do not specify the signal name, the default signal instance is used. Example: "marker0" "signal::sig1/marker0" "result::r1/marker0" "signal::sig1/result::r1/marker0" You can use the RFmxSpecAn_BuildMarkerString2 )function to build the selector string). |
nextPeak | int32 | Specifies the next peak on the trace. |
RFMXSPECAN_VAL_MARKER_NEXT_PEAK_NEXT_HIGHEST (0) | Moves the marker to the next highest peak above the threshold on the configured trace. |
---|---|
RFMXSPECAN_VAL_MARKER_NEXT_PEAK_NEXT_LEFT (1) | Moves the marker to the next peak to the left of the configured trace. |
RFMXSPECAN_VAL_MARKER_NEXT_PEAK_NEXT_RIGHT (2) | Moves the marker to the next peak to the right of the configured trace. |
Output | ||
Name | Type | Description |
nextPeakFound | int32* | Indicates whether the function has found the next peak on the trace. |
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_MarkerFetchXY (niRFmxInstrHandle instrumentHandle, char selectorString[], float64* markerXLocation, float64* markerYLocation);
Returns the X and Y locations of the marker.
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, result name, and marker number. If you do not specify the signal name, the default signal instance is used. Example: "marker0" "signal::sig1/marker0" "result::r1/marker0" "signal::sig1/result::r1/marker0" You can use the RFmxSpecAn_BuildMarkerString2 )function to build the selector string). |
Output | ||
Name | Type | Description |
markerXLocation | float64* | Returns the marker X location. |
markerYLocation | float64* | Returns the marker Y location. |
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 |
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