RFmxLteMXPropertyId Enumeration

Specifies the instrument port to be configured to acquire a signal. Use RFmxInstr_GetAvailablePorts function to get the valid port names.

For a single carrier, this method specifies the center frequency of the acquired RF signal.

Specifies the reference level which represents the maximum expected power of the RF input signal. This value is configured in dBm for RF devices and as Vpk-pk for baseband devices.

Specifies the attenuation of a switch or cable connected to the RF IN connector of the signal analyzer. This value is expressed in dB. Refer to the RF Attenuation and Signal Levels topic for your device in the NI RF Vector Signal Analyzers Help for more information about attenuation.

Specifies the margin RFmx driver adds to the SetReferenceLevel(string, double) method. The margin avoids clipping and overflow warnings if the input signal exceeds the configured reference level.

Specifies the trigger type.

Specifies the source terminal for the digital edge trigger. This method is used only when you set the SetTriggerType(string, RFmxLteMXTriggerType) method to DigitalEdge.

Specifies the active edge for the trigger. This method is used only when you set the SetTriggerType(string, RFmxLteMXTriggerType) method to DigitalEdge.

Specifies the channel from which the device monitors the trigger. This method is used only when you set the SetTriggerType(string, RFmxLteMXTriggerType) method to IQPowerEdge.

Specifies the power level at which the device triggers. This value is expressed in dB when you set the SetIQPowerEdgeTriggerLevelType(string, RFmxLteMXIQPowerEdgeTriggerLevelType) method to Relative and in dBm when you set the IQ Power Edge Level Type method to Absolute. The device asserts the trigger when the signal exceeds the level specified by the value of this method, taking into consideration the specified slope. This method is used only when you set the SetTriggerType(string, RFmxLteMXTriggerType) method to IQPowerEdge.

Specifies the reference for the SetIQPowerEdgeTriggerLevel(string, double) method. The IQ Power Edge Level Type method is used only when you set the SetTriggerType(string, RFmxLteMXTriggerType) method to IQPowerEdge.

Specifies whether the device asserts the trigger when the signal power is rising or when it is falling. The device asserts the trigger when the signal power exceeds the specified level with the slope you specify. This method is used only when you set the SetTriggerType(string, RFmxLteMXTriggerType) method to IQPowerEdge.

Specifies the trigger delay time. This value is expressed in seconds. If the delay is negative, the measurement acquires pre trigger samples. If the delay is positive, the measurement acquires post trigger samples.

Specifies whether the measurement computes the minimum quiet time used for triggering.

Specifies the time duration for which the signal must be quiet before the signal analyzer arms the I/Q power edge trigger. This value is expressed in seconds.

Specifies the link direction of the received signal.

Specifies the duplexing technique of the signal being measured.

Specifies the configuration of the LTE frame structure in the time division duplex (TDD) mode. Refer to table 4.2-2 of the 3GPP TS 36.211 specification to configure the LTE frame.

Specifies the downlink eNodeB (Base station) category. Refer to the 3GPP 36.141 specification for more details.

Specifies the special subframe configuration index. It defines the length of DwPTS, GP, and UpPTS for TDD transmission as defined in the section 4.2 of 3GPP 36.211 specification.

Specifies the number of physical antennas available at the DUT for transmission in a MIMO setup.

Specifies the physical antenna connected to the analyzer.

Specifies the number of subblocks that are configured in intra-band non-contiguous carrier aggregation.

Specifies the offset of the subblock from the center frequency. This value is expressed in Hz.

Specifies the evolved universal terrestrial radio access (E-UTRA) operating frequency band of a subblock, as defined in section 5.2 of the 3GPP TS 36.521 specification.

Specifies the spacing between two adjacent component carriers within a subblock.

Specifies the index of the component carrier having its center at the user-configured center frequency. RFmxLTE uses this method along with ComponentCarrierSpacingType method to calculate the value of the SetFrequency(string, double).

Specifies the number of component carriers configured within a subblock.

Specifies the channel bandwidth of the signal being measured. This value is expressed in Hz.

Specifies the offset of the component carrier from the subblock center frequency that you configure in the Center Frequency method. This value is expressed in Hz. This method is applicable only if you set the ComponentCarrierSpacingType method to User.

Specifies a physical layer cell identity.

Specifies the cyclic prefix (CP) duration and the number of symbols in a slot for the signal being measured.

Specifies whether to enable autodetection of the cell ID. If the signal being measured does not contain primary and secondary sync signal (PSS/SSS), autodetection of cell ID is not possible. Detected cell ID can be fetched using GetDownlinkDetectedCellID(string, out int) method.

Specifies the channel configuration mode.

Specifies whether the values of the SetPdschResourceBlockAllocation(string, string) method, the corresponding PDSCH CW0 Modulation Type method, and the PDSCH Power method are auto-detected by the measurement or user-specified.

Specifies whether the value of PSS Power, SSS Power, PBCH Power, PDCCH Power, and PCFICH Power properties are auto-detected by the measurement or user-specified. Currently, auto-detection of PHICH Power method is not supported.

Specifies whether the value of SetPcfichCfi(string, int) method is auto-detected by the measurement or user-specified.

Specifies whether the Mi parameter is specified by section 6.1.2.6 of 3GPP TS 36.141 specification for testing E-TMs or in the Table 6.9-1 of 3GPP TS 36.211 specification. The Mi parameter determines the number of PHICH groups in each downlink subframe, when you set the SetDuplexScheme(string, RFmxLteMXDuplexScheme) method to Tdd.

Specifies the ratio Rhob/Rhoa for the cell-specific ratio of one, two, or four cell-specific antenna ports as described in Table 5.2-1 in section 5.2 of the 3GPP TS 36.213 specification. This method determines the power of the channel resource element (RE) in the symbols that do not contain the reference symbols.

Specifies the power of primary synchronization signal (PSS) relative to the power of cell-specific reference signal. This value is expressed in dB.

Specifies the power of secondary synchronization signal (SSS) relative to the power of cell-specific reference signal. This value is expressed in dB.

Specifies the power of physical broadcast channel (PBCH) relative to the power of cell-specific reference signal. This value is expressed in dB.

Specifies the power of physical downlink control channel (PDCCH) relative to the power of cell-specific reference signal. This value is expressed in dB.

Specifies the number of unique subframes transmitted by the DUT. If you set the SetDownlinkChannelConfigurationMode(string, RFmxLteMXDownlinkChannelConfigurationMode) method to TestModel, this method will be set to 10 for FDD and 20 for TDD by default.

Specifies the control format indicator (CFI) carried by physical control format indicator channel (PCFICH). CFI is used to compute the number of OFDM symbols which will determine the size of physical downlink control channel (PDCCH) within a subframe.

Specifies the power of physical control format indicator channel (PCFICH) relative to the power of cell-specific reference signal. This value is expressed in dB.

Specifies the physical channel hybridARQ indicator channel (PHICH) resource value. This value is expressed in Ng. This method is used to calculate number of PHICH resource groups. Refer to section 6.9 of the 3GPP 36.211 specification for more information about PHICH.

Specifies the physical hybrid-ARQ indicator channel (PHICH) duration.

Specifies the power of all BPSK symbols in a physical hybrid-ARQ indicator channel (PHICH) sequence. This value is expressed in dB.

Specifies the number of physical downlink shared channel (PDSCH) allocations in a subframe.

Specifies the modulation type of codeword0 PDSCH allocation.

Specifies the resource blocks of the physical downlink shared channel (PDSCH) allocation.

Specifies the physical downlink shared channel (PDSCH) power level (Ra) relative to the power of the cell-specific reference signal. This value is expressed in dB. Measurement uses the SetDownlinkUserDefinedCellSpecificRatio(string, RFmxLteMXDownlinkUserDefinedRatio) method to calculate the Rb. Refer to section 3.3 of the 3GPP 36.521 specification for more information about Ra.

Specifies the E-UTRA Test Model type when you set the SetDownlinkChannelConfigurationMode(string, RFmxLteMXDownlinkChannelConfigurationMode) method to TestModel. Refer to section 6.1.1 of the 3GPP 36.141 specification for more information regarding test model configurations.

Specifies whether the values of the SetPuschModulationType(string, RFmxLteMXPuschModulationType), SetPuschNumberOfResourceBlockClusters(string, int), SetPuschResourceBlockOffset(string, int), and SetPuschNumberOfResourceBlocks(string, int) properties are auto-detected by the measurement or if you specify the values of these properties.

Specifies whether you configure the values of the demodulation reference signal (DMRS) parameters, such as SetUplinkGroupHoppingEnabled(string, RFmxLteMXUplinkGroupHoppingEnabled), SetUplinkSequenceHoppingEnabled(string, RFmxLteMXUplinkSequenceHoppingEnabled), SetCellId(string, int), SetPuschNDmrs1(string, int), SetPuschNDmrs2(string, int), and SetPuschDeltaSequenceShift(string, int) properties, or if the values of these properties are auto-detected by the measurement.

Specifies whether the sequence group number hopping for demodulation reference signal (DMRS) is enabled, as defined in section 5.5.1.3 of the 3GPP TS 36.211 specification.

Specifies whether the base sequence number hopping for the demodulation reference signal (DMRS) is enabled, as defined in section 5.5.1.3 of the 3GPP TS 36.211 specification. This method is only applicable only when you set the SetPuschNumberOfResourceBlocks(string, int) method to a value greater than 5.

Specifies whether orthogonal cover codes (OCCs) need to be used on the demodulation reference signal (DMRS) signal. The measurement internally sets this method to TRUE for multi antenna cases.

Specifies the n_DMRS_1 value, which is used to calculate the cyclic shift of the demodulation reference signal (DMRS) in a frame. The valid values for this method are defined in table 5.5.2.1.1-2 of the 3GPP TS 36.211 specification.

Specifies the physical uplink shared channel (PUSCH) delta sequence shift, which is used to calculate cyclic shift of the demodulation reference signal (DMRS). Refer to section 5.5.2.1.1 of the 3GPP TS 36.211 specification for more information about the PUSCH delta sequence shift.

Specifies the modulation scheme used in the physical uplink shared channel (PUSCH) of the signal being measured. Use "carrier(k)" or "subblock(n)/carrier(k)" as the selector string to configure or read this method.

Specifies the number of resource allocation clusters, with each cluster including one or more consecutive resource blocks. Refer to 5.5.2.1.1 of the 3GPP TS 36.213 specification for more information about the number of channels in the physical uplink shared channel (PUSCH).Use "carrier(k)" or "subblock(n)/carrier(k)" as the selector string to configure or read this method.

Specifies the starting resource block number of a physical uplink shared channel (PUSCH) cluster. Use "cluster(l)" or "carrier(k)" or "subblock(n)/carrier(k)"/cluster(l)" as the selector string to configure or read this method.

Specifies the number of consecutive resource blocks in a physical uplink shared channel (PUSCH) cluster. Use "cluster(l)" or "carrier(k)" or "subblock(n)/carrier(k)"/cluster(l)" as the selector string to configure or read this method.

Specifies the n_DMRS_2 value, which is used to calculate the cyclic shift of the demodulation reference signal (DMRS) in a slot. The valid values for this method are, as defined in table 5.5.2.1.1-1 of the 3GPP TS 36.211 specification. Use "carrier(k)" or "subblock(n)/carrier(k)" as the selector string to configure or read this method.

Specifies the cyclic shift field in uplink-related DCI format. When the SetDmrsOccEnabled(string, RFmxLteMXDmrsOccEnabled) method is set to True, the measurement uses the table 5.5.2.1.1-1 of 3GPP 36.211 specification to decide the valued of n(2)DMRS and [w(0) w(1)] for DMRS signal based on Cyclic Shift Field along with SetTransmitAntennaToAnalyze(string, int).

Specifies the power of the physical uplink shared channel (PUSCH) data relative to PUSCH DMRS for a component carrier. This value is expressed in dB.

Specifies whether the LTE signal getting measured contains SRS transmission.

Specifies the SRS subframe configuration specified in the Table 5.5.3.3-1 of 3GPP 36.211 specification. It is a cell-specific method. This method defines the subframes that are reserved for SRS transmission in a given cell.

Specifies the cell-specific SRS bandwidth configuration CSRS. Refer to section 5.5.3.2 of 3GPP 36.211 specification for more details.

Specifies the UE specific SRS bandwidth configuration BSRS. Refer to section 5.5.3.2 of 3GPP 36.211 specification for more details.

Specifies the SRS configuration index ISRS. It is used to determine the SRS periodicity and SRS subframe offset. It is a UE specific method which defines whether the SRS is transmitted in the subframe reserved for SRS by SRS subframe configuration. Refer to 3GPP 36.213 specification for more details.

Specifies the SRS frequency domain position nRRC. Refer to section 5.5.3.2 of 3GPP 36.211 specification for more details.

Specifies the cyclic shift value nSRSCS used for generating SRS base sequence. Refer to section 5.5.3.2 of 3GPP 36.211 specification for more details.

Specifies the SRS hopping bandwidth bhop. Frequency hopping for SRS signal is enabled when the value of SRS b_hop method is less than the value of SetSrsBSrs(string, int) method.

Specifies the transmission comb index. If you set this method to 0, SRS is transmitted on the even subcarriers in the allocated region. If you set this method to 1, SRS is transmitted on the odd subcarriers in the allocated region.

Specifies SRS MaxUpPTS parameter which determines whether SRS is transmitted in all possible RBs of UpPTS symbols in LTE TDD. Refer to section 5.5.3.2 of 3GPP 36.211 specification for more details.

Specifies the number of format 4 PRACH allocations in UpPTS for Subframe 1, first special subframe, in LTE TDD.

Specifies the number of format 4 PRACH allocations in UpPTS for Subframe 6, second special subframe, in LTE TDD. It is ignored for UL/DL Configuration 3, 4, and 5.

Specifies the average power of SRS transmission with respect to PUSCH DMRS power. This value is expressed in dB.

Specifies the modulation scheme used in physical sidelink shared channel (PSSCH) of the signal being measured.

Specifies the starting resource block number of a physical sidelink shared channel (PSSCH) allocation.

Specifies the number of consecutive resource blocks in a physical sidelink shared channel (PSSCH) allocation.

Specifies the power of the physical sidelink shared channel (PSSCH) data relative to PSSCH DMRS for a component carrier. This value is expressed in dB.

Specifies the starting subframe of an LAA burst.

Specifies the number of subframes in an LAA burst including the starting subframe.

Specifies the starting position of symbol 0 in the first subframe of an LAA uplink burst. Refer to section 5.6 of the 3GPP 36.211 specification for more information regarding LAA uplink start position.

Specifies the ending symbol number in the last subframe of an LAA uplink burst. Refer to section 5.3.3.1.1A of the 3GPP 36.212 specification for more information regarding LAA uplink ending symbol.

Specifies the starting symbol number in the first subframe of an LAA downlink burst. Refer to section 13A of the 3GPP 36.213 specification for more information regarding LAA downlink starting symbol.

Specifies the number of ending symbols in the last subframe of an LAA downlink burst. Refer to section 4.3 of the 3GPP 36.211 specification for more information regarding LAA downlink number of ending symbols.

Specifies the narrowband physical layer cell identity.

Specifies the subcarrier bandwidth of an NB-IoT signal. This method specifies the spacing between adjacent subcarriers.

Specifies whether the values of the SetNPuschToneOffset(string, int), NPUSCH Number of Tones, and SetNPuschModulationType(string, RFmxLteMXNPuschModulationType) properties are auto-detected by the measurement or specified by you.

Specifies the NPUSCH format. A value of 1 indicates that narrowband physical uplink shared channel (NPUSCH) carries user data (UL-SCH) and a value of 2 indicates that NPUSCH carries uplink control information.

Specifies the starting slot number of the NPUSCH burst.

Specifies the location of the starting subcarrier (tone) within the 200 kHz bandwidth that is allocated to the narrowband physical uplink shared channel (NPUSCH).

Specifies the number of subcarriers (tones) within the 200 kHz bandwidth that is allocated to the narrowband physical uplink shared channel (NPUSCH).

Specifies the modulation type that is used by the narrowband physical uplink shared channel (NPUSCH).

Specifies whether the SetNPuschDmrsBaseSequenceIndex(string, int) method is computed by the measurement or specified by you.

Specifies the base sequence index of the Narrowband Physical Uplink Shared Channel (NPUSCH) DMRS as defined in section 10.1.4.1.2 of the 3GPP TS 36.211 specification.

Specifies the cyclic shift of the narrowband physical uplink shared channel (NPUSCH) DMRS as defined in Table 10.1.4.1.2-3 of the 3GPP TS 36.211 specification.

Specifies whether the group hopping is enabled for narrowband physical uplink shared channel (NPUSCH) DMRS. This method is valid only when the SetNPuschFormat(string, int) is 1.

Specifies the delta sequence shift of the narrowband physical uplink shared channel (NPUSCH) DMRS, which is used to calculate the sequence shift pattern. This value is used to compute the sequence group number as defined in section 10.1.4.1.3 of the 3GPP TS 36.211 specification. This method is valid when you set the SetNPuschDmrsGroupHoppingEnabled(string, RFmxLteMXNPuschDmrsGroupHoppingEnabled) method to True.

Specifies the downlink channel configuration mode for NB-IoT.

Specifies the power of the NB-IoT primary synchronization signal (NPSS) relative to the power of the NB-IoT downlink reference signal (NRS). This value is expressed in dB.

Specifies the power of the NB-IoT secondary synchronization signal (NSSS) relative to the power of the NB-IoT downlink reference signal (NRS). This value is expressed in dB.

Specifies the NB-IoT physical downlink shared channel (NPDSCH) power level relative to the power of the NB-IoT downlink reference signal (NRS). This value is expressed in dB.

Specifies whether NPDSCH is active in a particular subframe. Note that subframes 0, 5, and 9 are reserved for NPBCH, NPSS, and NSSS. The measurement will return an error if you try to configure NPDSCH for those subframes.

Specifies whether the component carrier contains enhanced machine type communications (Cat-M1 or Cat-M2) transmission.

Specifies the number of active steps in the list.

Specifies the units in which SetListStepTimerDuration(string, double) and SetListStepTimerOffset(string, double) are specified.

Specifies the duration of a given list step in units specified by SetListStepTimerUnit(string, RFmxLteMXListStepTimerUnit).

Specifies the offset from the start of the step for which the measurements are computed. The unit for this method is specified by SetListStepTimerUnit(string, RFmxLteMXListStepTimerUnit). This method is valid only when you set the SetDigitalEdgeTriggerSource(string, string) method to NationalInstruments.RFmx.LteMX.RFmxLteMXConstants.TimerEvent.

Specifies whether to enable the ModAcc measurement.

Specifies whether to use a filter to suppress the interference from out of band emissions into the carriers being measured.

Specifies the time synchronization mode used in uplink in the case of carrier aggregation.

Specifies whether the measurement is performed from the frame or the slot boundary.

Specifies the measurement offset to skip from the synchronization boundary. The synchronization boundary is specified by the SetSynchronizationMode(string, RFmxLteMXModAccSynchronizationMode) method. This value is expressed in slots.

Specifies the number of slots to be measured. This value is expressed in slots.

Specifies the operation mode of frequency error estimation.

Specifies whether to estimate IQ origin offset.

Specifies whether to enable IQ gain imbalance correction.

Specifies whether to enable IQ quadrature error correction. The default value is False.

Specifies whether to enable IQ timing skew correction.

Specifies whether the spectrum of the measured signal is inverted. The inversion happens when the I and the Q components of the baseband complex signal are swapped.

Specifies the method used for the channel estimation for the ModAcc measurement.

Specifies the units of the EVM results.

Specifies the FFT window type used for the EVM calculation for the ModAcc measurement.

Specifies the position of the FFT window used to calculate the EVM. The offset is expressed as a percentage of the cyclic prefix length. If you set this method to 0, the EVM window starts at the end of cyclic prefix. If you set this method to 100, the EVM window starts at the beginning of cyclic prefix. The default value is 50. Valid values are 0 to 100, inclusive.

Specifies the FFT window length (W). This value is expressed as a percentage of the cyclic prefix length. This method is used when you set the SetFftWindowType(string, RFmxLteMXModAccFftWindowType) method to Type3GPP, where it is needed to calculate the EVM using two different FFT window positions, Delta_C-W/2, and Delta_C+W/2. Refer to the Annexe E.3.2 of 3GPP 36.521 specification for more information.

Specifies whether the same Reference Clock is used for the local oscillator and the digital-to-analog converter in the transmitter. When the same Reference Clock is used, the carrier frequency offset is proportional to Sample Clock error.

Specifies whether to exclude some portion of the slots when calculating the EVM. This method is applicable only when there is a power change at the slot boundary. Refer to section 6.5.2.1A of the 3GPP TS 36.521-1 specification for more information about exclusion.

Specifies the frequency ranges at which to measure spectral flatness.

Specifies the in-band emissions mask type to be used for measuring in-band emission margin (dB) and subblock in-Band emission margin (dB) results.

Specifies whether to enable averaging for the ModAcc measurement.

Specifies the number of acquisitions used for averaging when you set the SetAveragingEnabled(string, RFmxLteMXModAccAveragingEnabled) method to True.

Specifies whether to enable the traces to be stored and retrieved after performing the ModAcc measurement.

Specifies the maximum number of threads used for parallelism for the ModAcc measurement. The number of threads can range from 1 to the number of physical cores. The number of threads you set may not be used in calculations. The actual number of threads used depends on the problem size, system resources, data availability, and other considerations.

Specifies the interval used for Pre-FFT Error Estimation.

Specifies whether to estimate symbol clock error.

Specifies whether timing tracking is enabled.

Specifies whether phase tracking is enabled.

Returns the mean value of the RMS EVMs calculated on all the configured channels, over the slots specified by the SetMeasurementLength(string, int) method.

Returns the maximum value of the peak EVMs calculated on all the configured channels over the slots specified by the SetMeasurementLength(string, int) method.

Returns the RMS mean value of the composite magnitude error calculated over the slots specified by the SetMeasurementLength(string, int) method on all the configured channels.

Returns the peak value of the composite magnitude error calculated over the slots specified by the SetMeasurementLength(string, int) method on all the configured channels.

Returns the RMS mean value of the composite phase error calculated over the slots specified by the SetMeasurementLength(string, int) method on all the configured channels. This value is expressed in degrees.

Returns the peak value of phase error calculated over the slots specified by the SetMeasurementLength(string, int) method on all thee configured channels. This value is expressed in degrees.

Returns the slot index where the ModAcc maximum peak composite EVM occurs. Use "carrier(k)" or "subblock(n)/carrier(k)" as the selector string to read this result.

Returns the symbol index of the GetMaximumPeakCompositeEvm(string, out double) method. Use "carrier(k)" or "subblock(n)/carrier(k)" as the selector string to read this result.

Returns the subcarrier index where the maximum peak composite EVM for ModAcc occurs. Use "carrier(k)" or "subblock(n)/carrier(k)" as the selector string to read this result.

Returns the mean value of RMS EVMs calculated on PDSCH data symbols over the slots specified by the SetMeasurementLength(string, int) method.

Returns the mean value of RMS EVMs calculated on all QPSK modulated PDSCH resource blocks over the slots specified by the SetMeasurementLength(string, int) method.

Returns the mean value of RMS EVMs calculated on all 16QAM modulated PDSCH resource blocks over the slots specified by the SetMeasurementLength(string, int) method.

Returns the mean value of RMS EVMs calculated on all 64 QAM modulated PDSCH resource blocks over the slots specified by the SetMeasurementLength(string, int) method.

Returns the mean value of RMS EVMs calculated on all 256 QAM modulated PDSCH resource blocks over the slots specified by the SetMeasurementLength(string, int) method.

Returns the mean value of RMS EVMs calculated on all 1024 QAM modulated PDSCH resource blocks over the slots specified by the SetMeasurementLength(string, int) method.

Returns the mean value of RMS EVMs calculated on RS resource elements over the slots specified by the SetMeasurementLength(string, int) method.

Returns the mean value of RMS EVMs calculated on primary synchronization signal (PSS) channel over the slots specified by the SetMeasurementLength(string, int) method.

Returns the mean value of RMS EVMs calculated on secondary synchronization signal (SSS) channel over the slots specified by the SetMeasurementLength(string, int) method.

Returns the mean value of RMS EVMs calculated on PBCH channel over the slots specified by the SetMeasurementLength(string, int) method.

Returns the mean value of RMS EVMs calculated on PCFICH channel over the slots specified by the SetMeasurementLength(string, int) method.

Returns the mean value of RMS EVMs calculated on PDCCH channel over the slots specified by the SetMeasurementLength(string, int) method.

Returns the mean value of RMS EVMs calculated on PHICH channel over the slots specified by the SetMeasurementLength(string, int) method.

Returns the mean value of power calculated on cell-specific reference signal (CSRS) resource elements over the slots specified by the SetMeasurementLength(string, int) method. This value is expressed in dBm.

Returns the mean value of power calculated in one OFDM symbol over the slots specified by the SetMeasurementLength(string, int) method. This value is expressed in dBm.

Returns the detected cell ID value.

Returns the mean value of RMS EVMs calculated on NB-IoT primary synchronization signal (NPSS) channel over the slots specified by the ModAccMeasurementLength method.

Returns the mean value of RMS EVMs calculated on NB-IoT secondary synchronization signal (NSSS) channel over the slots specified by the ModAccMeasurementLength method.

Returns the mean value of RMS EVMs calculated on the NB-IoT downlink shared channel (NPDSCH) data symbols over the slots specified by the ModAccMeasurementLength method.

Returns the mean value of RMS EVMs calculated on all QPSK modulated NPDSCH subframes/slots specified by the ModAccMeasurementLength method.

Returns the mean value of RMS EVMs calculated on NRS resource elements over the slots specified by the ModAccMeasurementLength method.

Returns the mean value of power calculated on NB-IoT downlink reference signal (NRS) resource elements over the slots specified by the ModAccMeasurementLength method. This value is expressed in dBm.

Returns the in-band emission margin. This value is expressed in dB.

Returns the peak-to-peak ripple of the EVM equalizer coefficients within the frequency Range1. This value is expressed in dB.

Returns the peak-to-peak ripple of the EVM equalizer coefficients within the frequency Measurement Offset parameter. This value is expressed in dB.

Returns the peak-to-peak ripple of the EVM equalizer coefficients from the frequency Range1 to the frequency Measurement Offset parameter. The frequency Range1 and frequency Measurement Offset parameter are defined in the section 6.5.2.4.5 of the 3GPP TS 36.521 specification. This value is expressed in dB. Use "carrier(k)" or "subblock(n)/carrier(k)" as the selector string to read this result.

Returns the mean value of the RMS EVMs calculated on the physical uplink shared channel (PUSCH) data symbols over the slots specified by the SetMeasurementLength(string, int) method. Use "carrier(k)" or "subblock(n)/carrier(k)" as the selector string to read this result.

Returns the maximum value of the peak EVMs calculated on the physical uplink shared channel (PUSCH) data symbols over the slots specified by the SetMeasurementLength(string, int) method. Use "carrier(k)" or "subblock(n)/carrier(k)" as the selector string to read this result.

Returns the mean value of the RMS EVMs calculated on the PUSCH DMRS over the slots specified by the SetMeasurementLength(string, int) method. Use "carrier(k)" or "subblock(n)/carrier(k)" as the selector string to read this result.

Returns the maximum value of the peak EVMs calculated on PUSCH DMRS over the slots specified by the SetMeasurementLength(string, int) method. Use "carrier(k)" or "subblock(n)/carrier(k)" as the selector string to read this result.

Returns the mean value of the power calculated on the physical uplink shared channel (PUSCH) data symbols over the slots specified by the SetMeasurementLength(string, int) method. This value is expressed in dBm. Use "carrier(k)" or "subblock(n)/carrier(k)" as the selector string to read this result.

Returns the mean value of the power calculated on the PUSCH DMRS over the slots specified by the SetMeasurementLength(string, int) method. This value is expressed in dBm.

Returns the mean value of RMS EVMs calculated on the SRS symbols over the slots specified by the SetMeasurementLength(string, int) method.

Returns the mean value of power calculated on SRS over the slots specified by the SetMeasurementLength(string, int) method. This values is expressed in dBm.

Returns the mean value of RMS EVMs calculated on the narrowband physical uplink shared channel (NPUSCH) data symbols over the slots specified by the SetMeasurementLength(string, int) method.

Returns the maximum value of peak EVMs calculated on the narrowband physical uplink shared channel (NPUSCH) data symbols over the slots specified by the SetMeasurementLength(string, int) method.

Returns the mean value of RMS EVMs calculated on the narrowband physical uplink shared channel (NPUSCH) DMRS over the slots specified by the SetMeasurementLength(string, int) method.

Returns the maximum value of peak EVMs calculated on NPUSCH DMRS over the slots specified by the SetMeasurementLength(string, int) method.

Returns the mean value of the power calculated on the narrowband physical uplink shared channel (NPUSCH) data symbols over the slots specified by the SetMeasurementLength(string, int) method. This value is expressed in dBm.

Returns the mean value of the power calculated on the narrowband physical uplink shared channel (NPUSCH) DMRS over the slots specified by the SetMeasurementLength(string, int) method. This value is expressed in dBm.

Returns the peak-to-peak ripple of the EVM equalizer coefficients from frequency Measurement Offset parameter to frequency Range1. This value is expressed in dB.

Returns the in-band emission margin of a subblock aggregated bandwidth. This value is expressed in dB.

Returns the mean value of the RMS EVMs calculated on the physical sidelink shared channel (PSSCH) data symbols over the slots specified by the SetMeasurementLength(string, int) method. Use "carrier(k)" or "subblock(n)/carrier(k)" as the selector string to read this result.

Returns the maximum value of the peak EVMs calculated on the physical sidelink shared channel (PSSCH) data symbols over the slots specified by the SetMeasurementLength(string, int) method. Use "carrier(k)" or "subblock(n)/carrier(k)" as the selector string to read this result.

Returns the mean value of the RMS EVMs calculated on the PSSCH DMRS symbols over the slots specified by the SetMeasurementLength(string, int) method. Use "carrier(k)" or "subblock(n)/carrier(k)" as the selector string to read this result.

Returns the maximum value of the peak EVMs calculated on PSSCH DMRS symbols over the slots specified by the SetMeasurementLength(string, int) method. Use "carrier(k)" or "subblock(n)/carrier(k)" as the selector string to read this result.

Returns the mean value of the power calculated on the physical sidelink shared channel (PSSCH) data symbols over the slots specified by the SetMeasurementLength(string, int) method. This value is expressed in dBm. Use "carrier(k)" or "subblock(n)/carrier(k)" as the selector string to read this result.

Returns the mean value of the power calculated on the PSSCH DMRS symbols over the slots specified by the SetMeasurementLength(string, int) method. This value is expressed in dBm. Use "carrier(k)" or "subblock(n)/carrier(k)" as the selector string to read this result.

Returns the estimated carrier frequency offset averaged over the slots specified by the SetMeasurementLength(string, int) method. This value is expressed in Hz. Use "carrier(k)" or "subblock(n)/carrier(k)" as the selector string to read this result.

Returns the estimated maximum carrier frequency offset per slot in case of Uplink and per subframe in case of Downlink over the slots specified by the SetMeasurementLength(string, int) method. This value is expressed in Hz.

Returns the estimated I/Q origin offset averaged over the slots specified by the SetMeasurementLength(string, int) method. This value is expressed in dBc.

Returns the estimated maximum IQ origin offset over the slots specified by the SetMeasurementLength(string, int) method. This value is expressed in dBc.

Returns the estimated I/Q gain imbalance averaged over the measurement length. The I/Q gain imbalance is the ratio of the amplitude of the I component to the Q component of the I/Q signal being measured. This value is expressed in dB.

Returns the estimated quadrature error averaged over the slots specified by the SetMeasurementLength(string, int) method. This value is expressed in degrees.

Returns the estimated IQ timing skew averaged over measured length. IQ timing skew is the difference between the group delay of the in-phase (I) and quadrature (Q) components of the signal. This value is expressed in seconds.

Returns the time difference between the detected slot or frame boundary and the reference trigger location depending on the value of ModAccSynchronizationMode method. This value is expressed in seconds.

Returns the estimated symbol clock error averaged over the slots specified by the SetMeasurementLength(string, int) method. This value is expressed in ppm. Use "carrier(k)" or "subblock(n)/carrier(k)" as the selector string to read this result.

Returns the estimated I/Q origin offset averaged over the slots specified by the SetMeasurementLength(string, int) method in the subblock. This value is expressed in dBc.

Returns the estimated I/Q gain imbalance averaged over the slots specified by the SetMeasurementLength(string, int) method. This value is expressed in dB. The I/Q gain imbalance is the ratio of the amplitude of the I component to the Q component of the I/Q signal being measured in the subblock. This result is valid only when you set the SetLinkDirection(string, RFmxLteMXLinkDirection) method to Uplink and the SetTransmitterArchitecture(string, RFmxLteMXTransmitterArchitecture) method to LOPerSubblock. Otherwise, this parameter returns NaN, as measurement of this result is currently not supported.

Returns the estimated quadrature error averaged over the slots specified by the SetMeasurementLength(string, int) method. This value is expressed in degrees. Quadrature error is a measure of the skewness of the I component with respect to the Q component of the I/Q signal being measured in the subblock.

Specifies whether to enable the ACP measurement.

Specifies the integration bandwidth of a subblock. This value is expressed in Hz. Integration bandwidth is the span from the left edge of the leftmost carrier to the right edge of the rightmost carrier within the subblock.

Specifies the integration bandwidth of the component carrier (CC). This value is expressed in Hz.

Specifies whether the number of offsets is computed by measurement or configured by you.

Specifies the number of universal terrestrial radio access (UTRA) adjacent channel offsets to be configured at offset positions, when you set the ACP Configurable Number of Offset Enabled method to True.

Specifies the number of evolved universal terrestrial radio access (E-UTRA) adjacent channel offsets to be configured at offset positions, when you set the ACP Configurable Number of Offset Enabled method to True.

Specifies the evolved universal terrestrial radio access (E-UTRA) offset channel definition.

Specifies the number of GSM adjacent channel offsets to be configured when you set the SetBandwidth(string, double) to 200.0 k and the ACP Configurable Number of Offset Enabled method to True.

Specifies the offset frequency of an offset channel. This value is expressed in Hz. When you set the SetLinkDirection(string, RFmxLteMXLinkDirection) method to Uplink, the offset frequency is computed from the center of a reference component carrier/subblock to the center of the nearest RBW filter of the offset channel. When you set the Link Direction method to Downlink, the offset frequency is computed from the center of the closest component carrier to the center of the nearest RBW filter of the offset channel.

Specifies the integration bandwidth of an offset carrier. This value is expressed in Hz.

Specifies whether the measurement computes the RBW.

Specifies the bandwidth of the RBW filter, used to sweep the acquired signal, when you set the SetRbwFilterAutoBandwidth(string, RFmxLteMXAcpRbwAutoBandwidth) method to False. This value is expressed in Hz.

Specifies the shape of the RBW filter.

Specifies whether the measurement computes the sweep time.

Specifies the sweep time when you set the SetSweepTimeAuto(string, RFmxLteMXAcpSweepTimeAuto) method to False. This value is expressed in seconds.

Specifies the units for absolute power.

Specifies the method for performing the ACP measurement.

Specifies whether the noise calibration and measurement is performed automatically by the measurement or by you. Refer to the measurement guidelines section in the Noise Compensation Algorithm topic for more information.

Specifies whether the RFmx driver automatically computes the averaging count used for instrument noise calibration.

Specifies the averaging count used for noise calibration when you set the SetNoiseCalibrationAveragingAuto(string, RFmxLteMXAcpNoiseCalibrationAveragingAuto) method to False.

Specifies whether RFmx driver compensates for the instrument noise while performing the measurement when you set the SetNoiseCalibrationMode(string, RFmxLteMXAcpNoiseCalibrationMode) method to Auto, or when you set the ACP Noise Cal Mode method to Manual and the SetMeasurementMode(string, RFmxLteMXAcpMeasurementMode) method to Measure. Refer to the measurement guidelines section in the Noise Compensation Algorithm topic for more information.

Specifies the noise compensation type. Refer to the measurement guidelines section in the Noise Compensation Algorithm topic for more information.

Specifies whether to enable averaging for the ACP measurement.

Specifies the number of acquisitions used for averaging when you set the SetAveragingEnabled(string, RFmxLteMXAcpAveragingEnabled) method to True.

Specifies the averaging type for averaging multiple spectrum acquisitions. The averaged spectrum is used for ACP measurement.

Specifies whether the measurement calibrates the noise floor of analyzer or performs the ACP measurement. Refer to the measurement guidelines section in the Noise Compensation Algorithm topic for more information.

Specifies how overlapping is applied when computing the FFT of the acquired samples.

Returns the number of samples to overlap between consecutive chunks while performing FFT. This value is expressed as a percentage of Sequential FFT Size when you set the SetMeasurementMethod(string, RFmxLteMXAcpMeasurementMethod) method to SequentialFft.

Specifies whether the measurement computes an appropriate IF output power level offset for the offset channels to improve the dynamic range of the ACP measurement. This method is applicable only when you set the SetMeasurementMethod(string, RFmxLteMXAcpMeasurementMethod) method to DynamicRange.

Specifies the offset that is needed to adjust the IF output power levels for the offset channels that are near the carrier channel to improve the dynamic range. This value is expressed in dB. This method is applicable only when you set the SetIFOutputPowerOffsetAuto(string, RFmxLteMXAcpIFOutputPowerOffsetAuto) method to False and SetMeasurementMethod(string, RFmxLteMXAcpMeasurementMethod) method to DynamicRange.

Specifies the offset that is needed to adjust the IF output power levels for the offset channels that are far from the carrier channel to improve the dynamic range. This value is expressed in dB. This method is applicable only when you set the SetIFOutputPowerOffsetAuto(string, RFmxLteMXAcpIFOutputPowerOffsetAuto) method to False and SetMeasurementMethod(string, RFmxLteMXAcpMeasurementMethod) method to DynamicRange.

Specifies the FFT size, when you set the SetMeasurementMethod(string, RFmxLteMXAcpMeasurementMethod) method to SequentialFft.

Specifies whether the amplitude of the frequency bins, used in measurements, is corrected for external attenuation at the RF center frequency, or at the individual frequency bins. Use the RFmxInstr_CfgExternalAttenuationTable function to configure the external attenuation table.

Specifies whether to enable the traces to be stored and retrieved after performing the ACP measurement.

Specifies the maximum number of threads used for parallelism for the ACP measurement. The number of threads can range from 1 to the number of physical cores. The number of threads you set may not be used in calculations. The actual number of threads used depends on the problem size, system resources, data availability, and other considerations.

Returns the sum of powers of all the frequency bins over the integration bandwidths of all subblocks. The sum includes the power in inter-carrier gaps within a subblock but it does not include the power in subblock gaps. When you set the RFmxLteMXAcpPowerUnits method to dBm, the method returns the total subblock power in dBm of all the active carriers measured over the subblock. When you set the RFmxLteMXAcpPowerUnits method to dBm/Hz, the method returns the power spectral density in dBm/Hz based on the power in all the active carriers measured over the subblock.

Returns the absolute center frequency of the subblock, which is the center of the subblock integration bandwidth. This value is expressed in Hz. Integration bandwidth is the span from the left edge of the leftmost carrier to the right edge of the rightmost carrier within the subblock.

Returns the integration bandwidth used in calculating the power of the subblock. This value is expressed in Hz. Integration bandwidth is the span from left edge of the leftmost carrier to the right edge of the rightmost carrier within the subblock. Use "subblock(n)" as the selector string to read this result.

Returns the sum of powers of all the frequency bins over the integration bandwidth of the subblock. When you set the RFmxLteMXAcpPowerUnits method to dBm, the method returns the total subblock power in dBm of all the active carriers measured over the subblock. When you set the RFmxLteMXAcpPowerUnits method to dBm/Hz, the method returns the power spectral density in dBm/Hz based on the power in all the active carriers measured over the subblock. Use "subblock(n)" as the selector string to read this result.

Returns the power measured over the integration bandwidth of the carrier. The carrier power is reported in dBm when you set the RFmxLteMXAcpPowerUnits method to dBm, and in dBm/Hz when you set the RFmxLteMXAcpPowerUnits method to dBm/Hz. Use "carrier(k)" or "subblock(n)/carrier(k)" as the selector string to read this result.

Returns the component carrier power relative to its subblock power. This value is expressed in dB. Use "carrier(k)" or "subblock(n)/carrier(k)" as the selector string to read this result.

Returns the lower (negative) offset channel power. If this offset is not applicable for the intra-band non-contiguous type of carrier aggregation, a NaN is returned. The carrier power is reported in dBm when you set the RFmxLteMXAcpPowerUnits method to dBm, and in dBm/Hz when you set the RFmxLteMXAcpPowerUnits method to dBm/Hz. Refer to the 3GPP TS 36.521 specification for more information about the applicability of an offset channel. Use "offset(k)" or "subblock(n)/offset(k)" as the selector string to read this result.

Returns the power in lower (negative) offset channel relative to the total aggregated power. This value is expressed in dB. For the intra-band non-contiguous type of carrier aggregation, if this offset is not applicable, a NaN is returned. Refer to the 3GPP TS 36.521 specification for more information about the applicability of the offset channel. Use "offset(k)" or "subblock(n)/offset(k)" as the selector string to read this result.

Returns the upper (positive) offset channel power. For the intra-band non-contiguous type of carrier aggregation, if this offset is not applicable, the method returns a NaN. The offset power is reported in dBm when you set the RFmxLteMXAcpPowerUnits method to dBm, and in dBm/Hz when you set the RFmxLteMXAcpPowerUnits method to dBm/Hz. Refer to the 3GPP TS 36.521 specification for more information about the applicability of offset channel. Use "offset(k)" or "subblock(n)/offset(k)" as the selector string to read this result.

Returns the power in the upper (positive) offset channel relative to the total aggregated power. This value is expressed in dB. For the intra-band non-contiguous type of carrier aggregation, if this offset is not applicable, a NaN is returned. Refer to the 3GPP TS 36.521 specification for more information about the applicability of the offset channel. Use "offset(k)" or "subblock(n)/offset(k)" as the selector string to read this result.

Specifies whether to enable the channel power measurement.

Specifies the integration bandwidth (IBW) type used to measure the power of the acquired signal. Integration bandwidth is the frequency interval over which the power in each frequency bin is added to measure the total power in that interval.

Specifies the integration bandwidth of a subblock. This value is expressed in Hz. Integration bandwidth is the span from the left edge of the leftmost carrier to the right edge of the rightmost carrier within the subblock.

Specifies the integration bandwidth of a component carrier (CC). This value is expressed in Hz.

Specifies whether the CHP measurement computes the RBW.

Specifies the bandwidth of the RBW filter, used to sweep the acquired signal, when you set the SetRbwFilterAutoBandwidth(string, RFmxLteMXChpRbwAutoBandwidth) method to False. This value is expressed in Hz.

Specifies the shape of the digital RBW filter.

Specifies whether the measurement computes the sweep time.

Specifies the sweep time when you set the SetSweepTimeAuto(string, RFmxLteMXChpSweepTimeAuto) method to False. This value is expressed in seconds.

Specifies whether the noise calibration and measurement is performed automatically by the measurement or initiated by you. Refer to the measurement guidelines section in the Noise Compensation Algorithm topic for more information.

Specifies whether the RFmx driver automatically computes the averaging count used for instrument noise calibration.

Specifies the averaging count used for noise calibration when you set the SetNoiseCalibrationAveragingAuto(string, RFmxLteMXChpNoiseCalibrationAveragingAuto) method to False.

Specifies whether the RFmx driver compensates for the instrument noise when performing the measurement. To compensate for instrument noise when performing a CHP measurement, set the SetNoiseCalibrationMode(string, RFmxLteMXChpNoiseCalibrationMode) method to Auto, or set the CHP Noise Cal Mode method to Manual and the SetMeasurementMode(string, RFmxLteMXChpMeasurementMode) method to Measure. Refer to the measurement guidelines section in the Noise Compensation Algorithm topic for more information.

Specifies the noise compensation type. Refer to the measurement guidelines section in the Noise Compensation Algorithm topic for more information.

Specifies whether to enable averaging for the CHP measurement.

Specifies the number of acquisitions used for averaging when you set the SetAveragingEnabled(string, RFmxLteMXChpAveragingEnabled) method to True.

Specifies the averaging type for averaging multiple spectrum acquisitions. The averaged spectrum is used for CHP measurement.

Specifies whether the measurement calibrates the noise floor of analyzer or performs the CHP measurement. Refer to the measurement guidelines section in the Noise Compensation Algorithm topic for more information.

Specifies whether the amplitude of the frequency bins, used in measurements, is corrected for external attenuation at the RF center frequency, or at the individual frequency bins. Use the RFmxInstr_CfgExternalAttenuationTable function to configure the external attenuation table.

Specifies whether to enable the traces to be stored and retrieved after performing the CHP measurement.

Specifies the maximum number of threads used for parallelism for the CHP measurement. The number of threads can range from 1 to the number of physical cores. The number of threads you set may not be used in calculations. The actual number of threads used depends on the problem size, system resources, data availability, and other considerations.

Returns the total power of all the subblocks. This value is expressed in dBm. The power in each subblock is the sum of powers of all the frequency bins over the integration bandwidth of the subblocks. This value includes the power in the inter-carrier gaps within a subblock, but it does not include the power within the subblock gaps.

Returns the absolute center frequency of the subblock. This value is the center of the subblock integration bandwidth. Integration bandwidth is the span from left edge of the leftmost carrier to the right edge of the rightmost carrier within the subblock. This value is expressed in Hz. Use "subblock(n)" as the selector string to read this result.

Returns the integration bandwidth used in calculating the power of the subblock. Integration bandwidth is the span from left edge of the leftmost carrier to the right edge of the rightmost carrier within the subblock. This value is expressed in Hz. Use "subblock(n)" as the selector string to read this result.

Returns the sum of total power of all the frequency bins over the integration bandwidth of the subblock. This value includes the power in inter-carrier gaps within a subblock. This value is expressed in dBm. Use "subblock(n)" as the selector string to read this result.

Returns the power measured over the integration bandwidth of the component carrier. This value is expressed in dBm. Use "carrier(k)" or "subblock(n)/carrier(k)" as the selector string to read this result.

Returns the component carrier power relative to its subblock power. This value is expressed in dB. Use "carrier(k)" or "subblock(n)/carrier(k)" as the selector string to read this result.

Specifies whether to enable the OBW measurement.

Returns the frequency search space to find the OBW. This value is expressed in Hz.

Specifies whether the measurement computes the RBW.

Specifies the bandwidth of the RBW filter used to sweep the acquired signal, when you set the SetRbwFilterAutoBandwidth(string, RFmxLteMXObwRbwAutoBandwidth) method to False. This value is expressed in Hz.

Specifies the shape of the digital RBW filter.

Specifies whether the measurement computes the sweep time.

Specifies the sweep time when you set the SetSweepTimeAuto(string, RFmxLteMXObwSweepTimeAuto) method to False. This value is expressed in seconds.

Specifies whether to enable averaging for the OBW measurement.

Specifies the number of acquisitions used for averaging when you set the SetAveragingEnabled(string, RFmxLteMXObwAveragingEnabled) method to True.

Specifies the averaging type for averaging multiple spectrum acquisitions. The averaged spectrum is used for the OBW measurement.

Specifies whether the amplitude of the frequency bins, used in measurements, is corrected for external attenuation at the RF center frequency, or at the individual frequency bins. Use the RFmxInstr_CfgExternalAttenuationTable function to configure the external attenuation table.

Specifies whether to enable the traces to be stored and retrieved after performing the OBW measurement.

Specifies the maximum number of threads used for parallelism for the OBW measurement. The number of threads can range from 1 to the number of physical cores. The number of threads you set may not be used in calculations. The actual number of threads used depends on the problem size, system resources, data availability, and other considerations.

Returns the bandwidth that occupies 99 percentage of the total power of the signal within a carrier/subblock. This value is expressed in Hz. Use "subblock(n)" as the selector string to read this result.

Returns the total power measured in the carrier/subblock. This value is expressed in dBm. Use "subblock(n)" as the selector string to read this result.

Returns the start frequency of the carrier/subblock. This value is expressed in Hz. The occupied bandwidth is calculated using the following equation:Stop frequency - Start frequency = Occupied bandwidthUse "subblock(n)" as the selector string to read this result.

Returns the stop frequency of the carrier/subblock. This value is expressed in Hz. Occupied bandwidth is calculated using the following equation:Occupied bandwidth = Stop frequency - Start frequencyUse "subblock(n)" as the selector string to read this result.

Specifies whether to enable the SEM measurement.

Specifies the spectrum emission mask used in the measurement for uplink. Each mask type refers to a different Network Signalled (NS) value. General_CAClassB, CANS04, and CANCNS01 refers to carrier aggregation case. You must set the mask type to Custom to configure the custom offset masks. Refer to section 6.6.2.1 of the 3GPP 36.521 specification for more information about standard-defined mask types.

Specifies the limits to be used in the measurement for downlink. Refer to section 6.6.3 of the 3GPP 36.141 specification for more information about standard-defined mask types.

Specifies the spectrum emission mask used in the measurement for sidelink. Each mask type refers to a different Network Signalled (NS) value. You must set the mask type to Custom to configure the custom offset masks. Refer to section 6.6.2 of the 3GPP 36.521 specification for more information about standard-defined mask types.

Specifies the stop frequency for the last offset segment to be used in the measurement. This value is expressed in Hz.

Specifies the aggregated maximum output power of all transmit antenna connectors. This value is expressed in dBm. Refer to the Section 6.6.3 of 3GPP 36.141 specification for more details.

Returns the integration bandwidth of a subblock. This value is expressed in Hz. Integration bandwidth is the span from the left edge of the leftmost carrier to the right edge of the rightmost carrier within the subblock.

Returns the aggregated channel bandwidth of a configured subblock. This value is expressed in Hz. The aggregated channel bandwidth is the sum of the subblock integration bandwidth and the guard bands on either side of the subblock integration bandwidth.

Returns the integration bandwidth of a component carrier. This value is expressed in Hz.

Specifies the maximum output power, Pmax,c, per carrier that is used only to choose the limit table for Medium Range Base Station. For more details please refer to the section 6.6.3 of 3GPP 36.141 specification.

Specifies the number of SEM offset segments.

Specifies the start frequency of an offset segment relative to the SetBandwidth(string, double) edge (single carrier) or GetSubblockAggregatedChannelBandwidth(string, out double) edge (multi-carrier). This value is expressed in Hz.

Specifies the stop frequency of an offset segment relative to the SetBandwidth(string, double) edge (single carrier) or GetSubblockAggregatedChannelBandwidth(string, out double) edge (multi-carrier). This value is expressed in Hz.

Specifies whether the offset segment is present either on one side or on both sides of a carrier.

Specifies the bandwidth of an RBW filter used to sweep an acquired offset segment. This value is expressed in Hz.

Specifies the shape of a digital RBW filter.

Specifies the resolution of a spectrum to compare with the spectral mask limits as an integer multiple of the RBW.

Specifies the criteria to determine the measurement fail status.

Specifies the absolute power limit corresponding to the beginning of an offset segment. This value is expressed in dBm.

Specifies the absolute power limit corresponding to the end of an offset segment. This value is expressed in dBm.

Specifies the relative power limit corresponding to the beginning of the offset segment. This value is expressed in dB.

Specifies the relative power limit corresponding to the end of the offset segment. This value is expressed in dB.

Specifies whether the measurement computes the sweep time.

Specifies the sweep time when you set the SetSweepTimeAuto(string, RFmxLteMXSemSweepTimeAuto) method to False. This value is expressed in seconds.

Specifies whether to enable averaging for the SEM measurement.

Specifies the number of acquisitions used for averaging when you set the SetAveragingEnabled(string, RFmxLteMXSemAveragingEnabled) method to True.

Specifies the averaging type for averaging multiple spectrum acquisitions. The averaged spectrum is used for SEM measurement.

Specifies whether the amplitude of the frequency bins, used in measurements, is corrected for external attenuation at the RF center frequency, or at the individual frequency bins. Use the RFmxInstr_CfgExternalAttenuationTable function to configure the external attenuation table.

Specifies whether to enable the traces to be stored and retrieved after performing the SEM measurement.

Specifies the maximum number of threads used for parallelism for the SEM measurement. The number of threads can range from 1 to the number of physical cores. The number of threads you set may not be used in calculations. The actual number of threads used depends on the problem size, system resources, data availability, and other considerations.

Returns the sum of powers of all the subblocks. This value includes the power in the inter-carrier gap within a subblock, but it excludes power in the inter-subblock gaps. This value is expressed in dBm.

Returns the overall measurement status based on the standard mask type that you configure in the SEM Standard Mask Type method.

Returns the absolute center frequency of the subblock. This value is the center of the subblock integration bandwidth. Integration bandwidth is the span from the left edge of the leftmost carrier to the right edge of the rightmost carrier within the subblock. This value is expressed in Hz.

Returns the integration bandwidth of the subblock. Integration bandwidth is the span from left edge of the leftmost carrier to the right edge of the rightmost carrier within the subblock. This value is expressed in Hz.

Returns the power measured over the integration bandwidth of the subblock. This value is expressed in dBm. Use "subblock(n)" as the selector string to read this result.

Returns the sum of powers of all the frequency bins over the integration bandwidth of the carrier. This value is expressed in dBm. Use "carrier(k)" or "subblock(n)/carrier(k)" as the selector string to read this result.

Returns the sum of powers of all the frequency bins over the integration bandwidth of the component carrier power relative to its subblock power. This value is expressed in dB. Use "carrier(k)" or "subblock(n)/carrier(k)" as the selector string to read this result.

Returns the peak power in the component carrier. This value is expressed in dBm. Use "carrier(k)" or "subblock(n)/carrier(k)" as the selector string to read this result.

Returns the frequency at which the peak power occurs in the component carrier. This value is expressed in Hz. Use "carrier(k)" or "subblock(n)/carrier(k)" as the selector string to read this result.

Indicates the measurement status based on the spectrum emission limits defined by the standard mask type that you configure in the SEM Standard Mask Type method. Use "offset(k)" or "subblock(n)/offset(k)" as the selector string to read this result.

Returns the lower (negative) offset segment power. For the intra-band non-contiguous type of carrier aggregation, the offset segment may be truncated or discarded based on the offset overlap rules, as defined in the 3GPP TS 36.521 specification. If the offset segment is truncated, the measurement is performed on the updated offset segment. If the offset segment is discarded, a NaN is returned. This value is expressed in dBm. Use "offset(k)" or "subblock(n)/offset(k)" as the selector string to read this result.

Returns the power in the lower (negative) offset segment relative to the total aggregated power. For the intra-band non-contiguous type of carrier aggregation, the offset segment may be truncated or discarded based on the offset overlap rules, as defined in the 3GPP TS 36.521 specification. If the offset segment is truncated, the measurement is performed on the updated offset segment. If the offset segment is discarded, a NaN is returned. This value is expressed in dB. Use "offset(k)" or "subblock(n)/offset(k)" as the selector string to read this result.

Returns the peak power in the lower (negative) offset segment. For the intra-band non-contiguous type of carrier aggregation, the offset segment may be truncated or discarded based on the offset overlap rules, as defined in the 3GPP TS 36.521 specification. If the offset segment is truncated, the measurement is performed on the updated offset segment. If the offset segment is discarded, a NaN is returned. This value is expressed in dBm. Use "offset(k)" or "subblock(n)/offset(k)" as the selector string to read this result.

Returns the peak power in the lower (negative) offset segment relative to the total aggregated power. For the intra-band non-contiguous type of carrier aggregation, the offset segment may be truncated or discarded based on the offset overlap rules, as defined in the 3GPP TS 36.521 specification. If the offset segment is truncated, the measurement is performed on the updated offset segment. If the offset segment is discarded, a NaN is returned. This value is expressed in dB. Use "offset(k)" or "subblock(n)/offset(k)" as the selector string to read this result.

Returns the frequency at which the peak power occurs in the lower (negative) offset segment. For the intra-band non-contiguous type of carrier aggregation, the offset segment may be truncated or discarded based on the offset overlap rules, as defined in the 3GPP TS 36.521 specification. If the offset segment is truncated, the measurement is performed on the updated offset segment. If the offset segment is discarded, a NaN is returned. This value is expressed in Hz. Use "offset(k)" or "subblock(n)/offset(k)" as the selector string to read this result.

Returns the margin from the standard-defined absolute limit mask for the lower (negative) offset. Margin is defined as the minimum difference between the limit mask and the spectrum. For the intra-band non-contiguous type of carrier aggregation, the offset segment may be truncated or discarded based on the offset overlap rules, as defined in the 3GPP TS 36.521 specification. If the offset segment is truncated, the measurement is performed on the updated offset segment. If the offset segment is discarded, a NaN is returned. This value is expressed in dB. Use "offset(k)" or "subblock(n)/offset(k)" as the selector string to read this result.

Returns the power at which the margin occurs in the lower (negative) offset segment. For the intra-band non-contiguous type of carrier aggregation, the offset segment may be truncated or discarded based on the offset overlap rules, as defined in the 3GPP TS 36.521 specification. If the offset segment is truncated, the measurement is performed on the updated offset segment. If the offset segment is discarded, a NaN is returned. This value is expressed in dBm. Use "offset(k)" or "subblock(n)/offset(k)" as the selector string to read this result.

Returns the power at which the margin occurs in the lower (negative) offset segment relative to the total aggregated power. For the intra-band non-contiguous type of carrier aggregation, the offset segment may be truncated or discarded based on the offset overlap rules, as defined in the 3GPP TS 36.521 specification. If the offset segment is truncated, the measurement is performed on the updated offset segment. If the offset segment is discarded, a NaN is returned. This value is expressed in dB. Use "offset(k)" or "subblock(n)/offset(k)" as the selector string to read this result.

Returns the frequency at which the margin occurs in the lower (negative) offset. For the intra-band non-contiguous type of carrier aggregation, the offset segment may be truncated or discarded based on the offset overlap rules, as defined in the 3GPP TS 36.521 specification. If the offset segment is truncated, the measurement is performed on the updated offset segment. If the offset segment is discarded, a NaN is returned. This value is expressed in Hz. Use "offset(k)" or "subblock(n)/offset(k)" as the selector string to read this result.

Returns the measurement status based on the user-configured standard measurement limits and the failure criteria specified by Limit Fail Mask for the upper (positive) offset. For intra-band non-contiguous case, the offset segment may be truncated or discarded based on offset overlap rules defined in the 3GPP TS 36.521 specification. If the offset segment is truncated, the measurement is performed on the updated offset segment. If the offset segment is discarded, a NaN is returned. Use "offset(k)" or "subblock(n)/offset(k)" as the selector string to read this result.

Returns the upper (positive) offset segment power. For the intra-band non-contiguous type of carrier aggregation, the offset segment may be truncated or discarded based on the offset overlap rules, as defined in the 3GPP TS 36.521 specification. If the offset segment is truncated, the measurement is performed on the updated offset segment. If the offset segment is discarded, a NaN is returned. This value is expressed in dBm. Use "offset(k)" or "subblock(n)/offset(k)" as the selector string to read this result.

Returns the power in the upper (positive) offset segment relative to the total aggregated power.

Returns the power in the upper (positive) offset segment. For the intra-band non-contiguous type of carrier aggregation, the offset segment may be truncated or discarded based on the offset overlap rules, as defined in the 3GPP TS 36.521 specification. If the offset segment is truncated, the measurement is performed on the updated offset segment. If the offset segment is discarded, a NaN is returned. This value is expressed in dBm. Use "offset(k)" or "subblock(n)/offset(k)" as the selector string to read this result.

Returns the peak power in the upper (positive) offset segment relative to the total aggregated power. For the intra-band non-contiguous type of carrier aggregation, the offset segment may be truncated or discarded based on the offset overlap rules, as defined in the 3GPP TS 36.521 specification. If the offset segment is truncated, the measurement is performed on the updated offset segment. If the offset segment is discarded, a NaN is returned. This value is expressed in dB. Use "offset(k)" or "subblock(n)/offset(k)" as the selector string to read this result.

Returns the frequency at which the peak power occurs in the upper (positive) offset segment. For the intra-band non-contiguous type of carrier aggregation, the offset segment may be truncated or discarded based on the offset overlap rules, as defined in the 3GPP TS 36.521 specification. If the offset segment is truncated, the measurement is performed on the updated offset segment. If the offset segment is discarded, a NaN is returned. This value is expressed in Hz. Use "offset(k)" or "subblock(n)/offset(k)" as the selector string to read this result.

Returns the margin from the absolute limit mask for the upper (positive) offset. The Margin is defined as the minimum difference between the limit mask and the spectrum. For the intra-band non-contiguous type of carrier aggregation, the offset segment may be truncated or discarded based on the offset overlap rules, as defined in the 3GPP TS 36.521 specification. If the offset segment is truncated, the measurement is performed on the updated offset segment. If the offset segment is discarded, a NaN is returned. This value is expressed in Hz. Use "offset(k)" or "subblock(n)/offset(k)" as the selector string to read this result.

Returns the power at which the margin occurs in the upper (positive) offset segment. For the intra-band non-contiguous type of carrier aggregation, the offset segment may be truncated or discarded based on the offset overlap rules, as defined in the 3GPP TS 36.521 specification. If the offset segment is truncated, the measurement is performed on the updated offset segment. If the offset segment is discarded, a NaN is returned. This value is expressed in dBm. Use "offset(k)" or "subblock(n)/offset(k)" as the selector string to read this result.

Returns the power at which the margin occurs in the upper (positive) offset segment relative to the total aggregated power. For the intra-band non-contiguous type of carrier aggregation, the offset segment may be truncated or discarded based on the offset overlap rules, as defined in the 3GPP TS 36.521 specification. If the offset segment is truncated, the measurement is performed on the updated offset segment. If the offset segment is discarded, a NaN is returned. This value is expressed in dB. Use "offset(k)" or "subblock(n)/offset(k)" as the selector string to read this result.

Returns the frequency at which the margin occurs in the upper (positive) offset. For the intra-band non-contiguous type of carrier aggregation, the offset segment may be truncated or discarded based on the offset overlap rules, as defined in the 3GPP TS 36.521 specification. If the offset segment is truncated, the measurement is performed on the updated offset segment. If the offset segment is discarded, a NaN is returned. This value is expressed in Hz. Use "offset(k)" or "subblock(n)/offset(k)" as the selector string to read this result.

Specifies whether to enable the power versus time (PVT) measurement.

Specifies the method for performing the power versus time (PVT) measurement.

Specifies whether to enable averaging for the power versus time (PVT) measurement.

Specifies the number of acquisitions used for averaging when you set the SetAveragingEnabled(string, RFmxLteMXPvtAveragingEnabled) method to True.

Specifies the averaging type for averaging multiple spectrum acquisitions. The averaged spectrum is used for the power versus time (PVT) measurement.

Specifies the time excluded from the Off region before the burst. This value is expressed in seconds.

Specifies the time excluded from the Off region after the burst. This value is expressed in seconds.

Specifies whether to enable the traces to be stored and retrieved after performing the power versus time (PVT) measurement.

Specifies the maximum number of threads used for parallelism for the power versus time (PVT) measurement. The number of threads can range from 1 to the number of physical cores. The number of threads you set may not be used in calculations. The actual number of threads used depends on the problem size, system resources, data availability, and other considerations.

Returns the measurement status indicating whether the power before and after the burst is within the standard defined limit. Use "carrier(k)" or "subblock(n)/carrier(k)" as the selector string to read this result.

Returns the mean power in the segment before the captured burst. The segment is defined as one subframe prior to the burst for the FDD mode and 10 SC-FDMA symbols prior to the burst for the TDD mode. This value is expressed in dBm. Use "carrier(k)" or "subblock(n)/carrier(k)" as the selector string to read this result.

Returns the mean power in the segment after the captured burst. This value is expressed in dBm.

Returns the average power of the subframes within the captured burst.

Returns the width of the captured burst. This value is expressed in seconds. Use "carrier(k)" or "subblock(n)/carrier(k)" as the selector string to read this result.

Specifies whether to enable the SlotPhase measurement.

Specifies whether the measurement is performed from the frame or the slot boundary.

Specifies the measurement offset to skip from the synchronization boundary. This value is expressed in slots. The synchronization boundary is specified by the SetSynchronizationMode(string, RFmxLteMXSlotPhaseSynchronizationMode) method.

Specifies the number of slots to be measured. This value is expressed in slots.

Specifies whether to exclude some portions of the slots when calculating the phase. This method is applicable only when there is a power change at the slot boundary. Refer to section 6.5.2.1A of the 3GPP 36.521-1 specification for more information about the exclusion.

Specifies whether the same Reference Clock is used for local oscillator and the digital-to-analog converter. When the same Reference Clock is used, the carrier frequency offset is proportional to Sample Clock error.

Specifies whether the spectrum of the measured signal is inverted. The inversion happens when the I and the Q components of the baseband complex signal are swapped.

Specifies whether to enable the traces to be stored and retrieved after performing the SlotPhase measurement.

Returns the maximum value of phase difference at the slot boundaries within the SetMeasurementLength(string, int). This values is expressed in degrees.

Specifies whether to enable the SlotPower measurement.

Specifies the measurement offset to skip from the frame boundary or the marker (external trigger) location. This value is expressed in subframe.

Specifies the number of subframes to be measured. This value is expressed in subframe.

Specifies whether the same Reference Clock is used for the local oscillator and the digital-to-analog converter in the transmitter. When the same Reference Clock is used, the carrier frequency offset is proportional to Sample Clock error.

Specifies whether the spectrum of the measured signal is inverted. The inversion happens when the I and the Q components of the baseband complex signal are swapped.

Specifies whether to enable the traces to be stored and retrieved after performing the SlotPower measurement.

Specifies whether to enable the Transmit Power (TXP) measurement.

Specifies the measurement offset to skip from the start of acquired waveform for TXP measurement. This value is expressed in seconds.

Specifies the measurement interval. This value is expressed in seconds.

Specifies whether to enable averaging for TXP measurement.

Specifies the number of acquisitions used for averaging when Averaging Enabled is True.

Enables the traces to be stored and retrieved after the TXP measurement is performed.

Specifies the maximum number of threads used for parallelism inside TXP measurement.

Returns the average power of the acquired signal.

Returns the peak power of the acquired signal.

Specifies the initial reference level that the AutoLevel(string, double, out double) function uses to estimate the peak power of the input signal. This value is expressed in dBm.

Specifies whether RFmx driver optimizes the acquisition bandwidth. This may cause acquisition center frequency or local oscillator (LO) to be placed at different position than you configured.

Specifies the RF architecture at the transmitter in case of a multicarrier. 3GPP defines different options, each component carriers within a subblock can have separate LO or one common LO for an entire subblock. Based upon the selected option, the additional results are calculated.

Specifies the set of properties that are considered by RFmx driver in the locked signal configuration state.

Specifies the frequency that determines the SEM mask, IBE limits, and spectral flatness ranges. This value is expressed in Hz.

Specifies the time to wait before results are available in the RFmxLTE_PropertyNode. This value is expressed in seconds. Set this value to a time longer than expected for fetching the measurement. A value of -1 specifies that the RFmx Property Node waits until the measurement is complete.

This enum value has been deprecated.

This enum value has been deprecated.

Specifies whether to use a filter to suppress the interference from out of band emissions into the carriers being measured.