Examples provide a network testing solution using a remote-controlled testing device. A test device includes a computing device for executing network performance testing logic and a cellular device. The test device controls the cellular device via a series of commands issued to the cellular device by the computing device. The test device is placed onto or inside a vehicle. As the vehicle moves through a geographical area, the test device automatically and autonomously performs network testing operations. The test data generated during the test is periodically uploaded to a central controller. The central controller aggregates test data received from a plurality of test devices assigned to a plurality of vehicles for a given campaign. The aggregated test data is analyzed and filtered to generate performance test results. A user can dynamically set up each campaign and assign test devices and vehicles to each campaign using a graphical user interface.

Examples provide a network testing solution using a remote-controlled testing device. A test device includes a computing device for executing network performance testing logic and a cellular device. The test device controls the cellular device via a series of commands issued to the cellular device by the computing device. The test device is placed onto or inside a vehicle. As the vehicle moves through a geographical area, the test device automatically and autonomously performs network testing operations. The test data generated during the test is periodically uploaded to a central controller. The central controller aggregates test data received from a plurality of test devices assigned to a plurality of vehicles for a given campaign. The aggregated test data is analyzed and filtered to generate performance test results. A user can dynamically set up each campaign and assign test devices and vehicles to each campaign using a graphical user interface.

A first mobile terminal testing device 1 including plurality of pseudo base station units 12-0, 12-1 operating as LTE base stations of NSA, and second mobile terminal testing device 2 operating as 5G NR base stations of NSA are provided. Each of the pseudo base station units 12-0, 12-1 is associated with the second mobile terminal testing devices 2, 2. The second mobile terminal testing device 2 generates a 5G NR control signal when testing a mobile terminal 3 which supports for NSA. The generated 5G NR control signal is transmitted to the first mobile terminal testing device 1. The first mobile terminal testing device 1 transmits the received 5G NR control signal to the mobile terminal 3 by the LTE control signal using the pseudo base station unit 12 corresponding to the second mobile terminal testing device 2 which transmits the control signal.

A system instantiates a unified interface for a telecommunications network including a Network Function Virtualization (NFV) architecture of an IP multimedia subsystem (IMS) with multiple Virtual Network Functions (VNFs) that each have multiple component VNFs. The system instantiates a tracing tool configured to evaluate performance of the IMS in response to execution of a test case, which includes a test script to test a computing product and where the performance of the IMS is based on packets captured concurrently from VNFs. The test script causes capture and analysis of parameters extracted from packets of the VNFs. In response to completing the test case, the system reports test results indicating the performance of the IMS relative to pass/fail criteria, where the test results are presented through the unified interface.

There is provided a communication apparatus that enables acquisition of data to be sent after a Secure Shell (SSH) connection between a wireless unit and a baseband unit is established. A communication apparatus (10) according to the present disclosure includes a communication unit (11) that establishes a first Secure Shell (SSH) connection with a wireless apparatus (20) that performs wireless communication with a communication terminal (40), and establishes a second SSH connection with a control apparatus (30) that performs a baseband process related to a signal used in the wireless communication, and a data recording unit (12) that records data of a management plane received from the wireless apparatus (20) through the first SSH connection or the data of the management plane received from the control apparatus (30) through the second SSH connection.

There is provided a communication apparatus that enables acquisition of data to be sent after a Secure Shell (SSH) connection between a wireless unit and a baseband unit is established. A communication apparatus (10) according to the present disclosure includes a communication unit (11) that establishes a first Secure Shell (SSH) connection with a wireless apparatus (20) that performs wireless communication with a communication terminal (40), and establishes a second SSH connection with a control apparatus (30) that performs a baseband process related to a signal used in the wireless communication, and a data recording unit (12) that records data of a management plane received from the wireless apparatus (20) through the first SSH connection or the data of the management plane received from the control apparatus (30) through the second SSH connection.

A system for load-testing a cloud radio access network (C-RAN) is provided. The system includes at least one radio point (RP), each being configured to exchange radio frequency (RF) signals with at least one user equipment (UE). The system also includes a baseband controller communicatively coupled to the at least one RP via a front-haul ETHERNET network. The front-haul ETHERNET network includes at least one switch; and a testing device that is time-synchronized to the baseband controller and the at least one RP. The testing device is configured to receive at least one packet from each of the at least one RP. The testing device is also configured to replicate each of at least some of the received packets to produce a respective replicated packet. The testing device is also configured to transmit at least one replicated packet to the baseband controller.

During operation, an electronic device may emulate client functionality associated with a virtual client in a wireless network, where emulating the client functionality includes generating a first frame that is compatible with a wireless communication protocol and is associated with fictious wireless communication with the virtual client. Then, the electronic device may provide, to a computer, a second frame that includes at least a portion of the first frame, where the second frame is compatible with a wired communication protocol. Next, the electronic device may receive, from the computer, a response message based at least in part on the first frame, where the response message includes information associated with a service provided by the computer. Moreover, the electronic device may assess the service based at least in part on the information and may selectively perform the remedial action based at least in part on the assessment.

During operation, an electronic device may emulate client functionality associated with a virtual client in a wireless network, where emulating the client functionality includes generating a first frame that is compatible with a wireless communication protocol and is associated with fictious wireless communication with the virtual client. Then, the electronic device may provide, to a computer, a second frame that includes at least a portion of the first frame, where the second frame is compatible with a wired communication protocol. Next, the electronic device may receive, from the computer, a response message based at least in part on the first frame, where the response message includes information associated with a service provided by the computer. Moreover, the electronic device may assess the service based at least in part on the information and may selectively perform the remedial action based at least in part on the assessment.

A radio for determining the occupancy of a variable width channel for secondary use, the variable width channel with a bandwidth equal to an integer multiple of the bandwidth of a plurality of narrowband channels in an RF frequency band. The radio decides whether the variable width channel in the RF band is occupied by whether classifying each of the narrowband channels corresponding to the variable width channel and each of a plurality of sub-bands with bandwidths of narrowband channels but center frequencies shifted by one-half of the bandwidth of the narrowband channel and overlap with the bandwidth of the variable width channel as containing signal or noise based on measured energy levels.