Abstract: The subject matter described herein includes methods, systems, and computer readable media for testing radio access network nodes by emulating band-limited RF and numerology-capable UEs in wideband networks. One method includes storing, in a database, UE bandwidth and numerology capability profiles for modeling UEs with different bandwidth and numerology capabilities. The method further includes emulating UEs with different bandwidth and numerology capabilities by communicating, over an uplink interface, the bandwidth and numerology capability profiles to a radio access network node under test. The method further includes receiving, over a downlink interface and from the radio access network node under test, bandwidth part and numerology assignments for emulated UEs. The method further includes validating the UE bandwidth part and numerology assignments.

Abstract: The subject matter described herein includes methods, systems, and computer readable media for testing radio access network nodes by emulating band-limited RF and numerology-capable UEs in wideband networks. One method includes storing, in a database, UE bandwidth and numerology capability profiles for modeling UEs with different bandwidth and numerology capabilities. The method further includes emulating UEs with different bandwidth and numerology capabilities by communicating, over an uplink interface, the bandwidth and numerology capability profiles to a radio access network node under test. The method further includes receiving, over a downlink interface and from the radio access network node under test, bandwidth part and numerology assignments for emulated UEs. The method further includes validating the UE bandwidth part and numerology assignments.

Abstract: Methods, systems, and computer readable media for testing and modeling the beamforming capabilities of a device under test (DUT) are disclosed. The method includes receiving, from a DUT, system information that correlates a plurality of resources to a plurality of synchronization system (SS) blocks transmitted by the DUT and receiving, from the DUT, the plurality of SS blocks. In response to receiving the plurality of SS blocks, the method further includes sending a random access procedure (RACH) message from an emulated user equipment to the DUT via a resource that is correlated per the system information to a predefined SS block that is specified in a beam model. The method also includes analyzing a beam switch indication message sent by the DUT to confirm that the DUT has restricted communication to the emulated user equipment via a beam signal corresponding to the predefined SS block.

Abstract: Methods, systems, and computer readable media for testing and modeling the beamforming capabilities of a device under test (DUT) are disclosed. The method includes receiving, from a DUT, system information that correlates a plurality of resources to a plurality of synchronization system (SS) blocks transmitted by the DUT and receiving, from the DUT, the plurality of SS blocks. In response to receiving the plurality of SS blocks, the method further includes sending a random access procedure (RACH) message from an emulated user equipment to the DUT via a resource that is correlated per the system information to a predefined SS block that is specified in a beam model. The method also includes analyzing a beam switch indication message sent by the DUT to confirm that the DUT has restricted communication to the emulated user equipment via a beam signal corresponding to the predefined SS block.

Abstract: A method for testing an air interface device using emulated noise in unassigned uplink resource blocks (RBs) includes, in a network equipment test device including at least one processor, receiving a first downlink signal transmission from an air interface device under test. The method further includes identifying unassigned uplink resource blocks. The method further includes transmitting an uplink signal to the air interface device under test with emulated channel noise in at least one of the unassigned uplink resource blocks. The method further includes receiving, after transmission of the uplink signal to the air interface device under test, a subsequent downlink signal transmission from the air interface device under test. The method further includes determining an effect of the emulated channel noise on resource block assignments.

Abstract: A method for testing an air interface device using emulated noise in unassigned uplink resource blocks (RBs) includes, in a network equipment test device including at least one processor, receiving a first downlink signal transmission from an air interface device under test. The method further includes identifying unassigned uplink resource blocks. The method further includes transmitting an uplink signal to the air interface device under test with emulated channel noise in at least one of the unassigned uplink resource blocks. The method further includes receiving, after transmission of the uplink signal to the air interface device under test, a subsequent downlink signal transmission from the air interface device under test. The method further includes determining an effect of the emulated channel noise on resource block assignments.

Abstract: A network equipment test device includes per-UE uplink signal generation processing chains for generating per-UE time domain uplink signals. Per-UE signal faders simulate per-UE signal fading for the per-UE time domain uplink signals. Different phases and amplitudes are used over time to simulate different signal fading. Fourier transformation units perform Fourier transformation of each of the time domain uplink signals to produce per-UE frequency domain uplink signals with simulated per-UE signal fading. A subcarrier mapping unit performs subcarrier mapping of the per-UE frequency domain uplink signals to produce a frequency domain multi-UE uplink signal with simulated per-UE signal fading. An inverse Fourier transformation unit performs inverse Fourier transformation of the frequency domain multi-UE uplink signal to produce a multi-UE time domain uplink signal with simulated per-UE signal fading.

Abstract: A network equipment test device includes per-UE uplink signal generation processing chains for generating per-UE time domain uplink signals. Per-UE signal faders simulate per-UE signal fading for the per-UE time domain uplink signals. Different phases and amplitudes are used over time to simulate different signal fading. Fourier transformation units perform Fourier transformation of each of the time domain uplink signals to produce per-UE frequency domain uplink signals with simulated per-UE signal fading. A subcarrier mapping unit performs subcarrier mapping of the per-UE frequency domain uplink signals to produce a frequency domain multi-UE uplink signal with simulated per-UE signal fading. An inverse Fourier transformation unit performs inverse Fourier transformation of the frequency domain multi-UE uplink signal to produce a multi-UE time domain uplink signal with simulated per-UE signal fading.

Abstract: Methods, systems, and computer readable media for enhanced channel control element (CCE) decoding are disclosed. According to one method that occurs in a multi-UE simulator, the method includes receiving physical downlink control channel (PDCCH) data from an evolved node B (eNode B) under test and decoding, using CCE avoidance information for avoiding at least a first CCE successfully identified as being associated with at least a first UE simulated by the multi-UE simulator, a second CCE associated with a second UE simulated by the multi-UE simulator.

Abstract: Methods, systems, and computer readable media for enhanced channel control element (CCE) decoding are disclosed. According to one method that occurs in a multi-UE simulator, the method includes receiving physical downlink control channel (PDCCH) data from an evolved node B (eNode B) under test and decoding, using CCE avoidance information for avoiding at least a first CCE successfully identified as being associated with at least a first UE simulated by the multi-UE simulator, a second CCE associated with a second UE simulated by the multi-UE simulator.

Abstract: The subject matter described herein includes methods, systems, and computer readable media for simulating per-UE Doppler shifts. One exemplary method includes generating uplink signals to be transmitted from a plurality of different simulated UEs to an air interface device under test. The method further includes applying per-UE Doppler shifts to the signals, wherein applying per-UE Doppler shifts includes applying different Doppler shifts to at least some of the signals. The method further includes transmitting the signals to the air interface device under test.

Abstract: Methods, systems, and computer readable media for testing an air interface device using per user equipment (UE) channel noise are disclosed. One method includes, generating uplink signals at a network equipment test device to be transmitted from plural simulated UEs to an air interface device under test. The method further includes generating and applying per-UE channel noise to the signals, where applying per-UE channel noise includes applying different channel noise to at least some of the uplink signals. The method further includes transmitting the uplink signals with the per-UE channel noise to the air interface device under test.

Abstract: Methods, systems, and computer readable media for determining a metric of radio frequency channel quality for idle channels are disclosed. One method includes receiving a plurality of reference symbols transmitted by a transmitter for an idle channel state when user data and control channel data are not transmitted over the radio frequency channel. The method further includes computing a metric of channel quality using at least one of the reference symbols.

Abstract: The subject matter described herein includes methods, systems, and computer readable media for frequency selective channel modeling. One exemplary system includes a network equipment test device including at least one processor. The network equipment test device includes the UE emulator implemented by the at least one processor and configured to emulate a plurality of UEs that attach to and communicate with a device under test. The system further includes a frequency selective channel modeler configured to receive resource scheduling information for the UEs from the device under test, to determine channel performance categories for the UEs using the resource scheduling information and to determine values for channel quality parameters using the channel performance categories assigned to the resource blocks, which represent selected frequencies in the total channel bandwidth.

Abstract: Methods, systems, and computer readable media for determining a metric of radio frequency channel quality for idle channels are disclosed. One method includes receiving a plurality of reference symbols transmitted by a transmitter for an idle channel state when user data and control channel data are not transmitted over the radio frequency channel. The method further includes computing a metric of channel quality using at least one of the reference symbols.

Abstract: Methods, systems, and computer readable media for simulating channel conditions are disclosed. According to one method, the method includes storing a plurality of system level metrics associated with various channel conditions. The method also includes receiving data from a device under test (DUT). The method further includes for each of a plurality of user devices or simulated user devices during a test period: identifying, using information about the received data and a precomputed channel type configuration, a first system level metric from the plurality of system level metrics, and providing the first system level metric to the DUT.

Abstract: Methods, systems, and computer readable media for determining a radio frame synchronization position are disclosed. According to one method, the method includes receiving a radio frame having an ascertainable physical channel or ascertainable data intended for providing non-synchronization related information. The method also includes determining, using the ascertainable physical channel or ascertainable data, a frame synchronization position.

Abstract: Methods, systems, and computer readable media for testing an air interface device using per user equipment (UE) channel noise are disclosed. One method includes, generating uplink signals at a network equipment test device to be transmitted from plural simulated UEs to an air interface device under test. The method further includes generating and applying per-UE channel noise to the signals, where applying per-UE channel noise includes applying different channel noise to at least some of the uplink signals. The method further includes transmitting the uplink signals with the per-UE channel noise to the air interface device under test.

Abstract: The subject matter described herein relates to methods, systems, and computer readable media for smart decoding of downlink signals in the presence of interference caused by reference signals of different generation air interface equipment. One method includes receiving, at a decoder, a downlink signal including interference caused by different generation network equipment. The method further includes providing information regarding reference signal locations to the decoder. The method further includes, at the decoder, weighting decoding error metrics resulting from received bits corresponding to the reference signal locations relative to decoding error metrics resulting from received bits corresponding to other locations to account for the presence of the interference caused by the reference signals. The method further includes decoding the received bits based on the relative weights and outputting a sequence of likely transmitted bits.

Abstract: The subject matter described herein includes methods, systems, and computer readable media for simulating per-UE Doppler shifts. One exemplary method includes generating uplink signals to be transmitted from a plurality of different simulated UEs to an air interface device under test. The method further includes applying per-UE Doppler shifts to the signals, wherein applying per-UE Doppler shifts includes applying different Doppler shifts to at least some of the signals. The method further includes transmitting the signals to the air interface device under test.