Abstract: A communications device includes a transmitter configured to transmit in one of plural segments of an available channel bandwidth signals representing data via a wireless access interface to a mobile communications network, a receiver configured to receive in one of the plural segments signals representing the data via the wireless access interface from the mobile communications network, and a controller configured to control the transmitter and the receiver. The controller is configured in combination with the transmitter and the receiver to measure a relative quality of signals received by the receiver in each of the plural segments, to transmit a measurement report to the mobile communications network, the measurement report including the measured relative quality of signals in each of the plural segments, and wherein, upon predetermined conditions being met, to skip the measuring of the relative quality of signals received in one or more of the plural segments.

Abstract: A method and system that allows authorized individuals access into controlled access locations and the ability to grant temporary and limited access to guests into these locations. The method and system allows for navigational services to be provided to members and guests, and real-time tracking and confirmation to members and administrators that guests have arrived at their destination and did not enter any unauthorized areas. The method preferably can work through a system of wireless radio, sound and/or light-based beacons communicating with member and guest's electronic devices. Members and administrators can send one or more temporary electronic access keys to a guest's smartphone or other electronic device. Wireless radio, sound and/or light-based beacons provide an access control and location tracking system with real-time data about the member and guest whereabouts, allowing for the confirmation and tracking.

Abstract: In retrodirective wireless power delivery environments wireless power receivers generate and send beacon signals that are received by multiple antennas of a wireless power transmission system. The beacon signals provide the charger with timing information for wireless power transfers and also indicate directionality of the incoming signal. As discussed herein, the directionality information is employed when transmitting in order to focus energy (e.g., power wave delivery) on individual wireless power receiver clients. Techniques are described herein for reducing the burden of sampling the beacon signals across the multiple antennas and determining the directionality of the incoming wave. In some embodiments, the techniques leverage previously calculated values to simplify the receiver sampling.

Abstract: The present invention relates to calibration of an electronic device. An operation method of an electronic device may comprise the operations of: setting a first path for a first calibration of a transmission path; performing the first calibration of the transmission path by using the first path; setting a second path for a second calibration of a transceiving path; performing the second calibration of the transceiving path by using the second path; and generating data indicating a result of calibration of a reception path, on the basis of a result obtained by the first calibration and the second calibration. Various other embodiments are possible.

Abstract: A testing enclosure can be used while testing telecommunications devices. In some examples, the testing enclosure includes at least one radio frequency (RF) shielded box configured to couple with a wireless telecommunications device and protect the telecommunications device from ambient RF signals while the telecommunications device is under test. The testing enclosure may include a panel, a switch, and an attenuator. In some examples, the testing enclosure may receive a radio signal from a radio source located outside of the testing enclosure and provide the radio signal to the telecommunications device under testing via the panel, the switch and/or the attenuator.

Abstract: Provided is a mobile terminal testing device capable of shortening a time required for extracting a test case of a conformance test and a time required for measuring the conformance test. A mobile terminal testing device includes an operation unit 4 that receives an operation input from a user, a display unit 5 that displays an image, and a control unit 6 that displays on the display unit 5, a list of test cases of a conformance test and a list of identification information of a mobile terminal 10 of which performance information is stored in advance, and collates, for each test case selected from the list of test cases, a requirement of the test case with the performance information of the mobile terminal 10 selected from the list of identification information of the mobile terminal to extract a test case to be measured.

Abstract: The technology relates to generating a wireless network access point model for determining locations within an area. In one example, a plurality of scan vectors, each scan vector representing a set of signal strengths for a set of wireless network access point identifiers and being associated with a location within the area at which a mobile device moving through the area measured the set of signal strengths are received. A set of clusters is generated by iterating through a split phase until the number of clusters in the set of clusters equals a maximum number of clusters or there are no bad scan vectors identified. A bad scan vector may include a vector having a vector difference from a center of a cluster to which that vector is assigned is less than a minimum similarity value. The set of cluster is then used to generate the model of the area.

Abstract: Device and method for testing wireless devices without a physical connection to the wireless device which has to be tested. Accordingly, the reception and transmission of the wireless device which has to be tested is controlled only by a test data sequence which is repeatedly sent from a test device to the wireless device which has to be tested. Accordingly, a measurement of the responses from the device which is to be tested can be performed in order to evaluate the operation of the respective device.

Abstract: A novel solution to generate an optimal spatial placement map of Radio Frequency (RF) beacons, such as Bluetooth Low Energy (BLE) beacons, which can be used for indoor localization. A described embodiment solves for both generating optimal number of beacons required in a given environment and optimizing their location. The solution also incorporates behavior of RF signal due to various environmental factors such as signal reflection and absorption due to static and dynamic obstacles. In one embodiment, the framework is built upon Genetic Algorithm (GA) for optimization of beacon placement. The experimental results achieved using one implementation of the described method reduced the number of beacons by 50% as compared to beacons placed using expert knowledge. Furthermore, the overall localization error increased by ˜0.4 m when the results using the RF/BLE map generated by the described system were compared with the RF/BLE map generated using expert knowledge.

Abstract: Disclosed is an electronic device which includes an antenna array including a plurality of antenna elements and a wireless communication circuit configured to transmit and/or receive a signal having a frequency in a range of 3 GHz to 300 GHz. The wireless communication circuit includes a plurality of pairs of transmit and receive paths. The wireless communication circuit is configured to allow a first pair of the plurality of pairs to use the transmit path of the first pair and a second pair of the plurality of pairs to use the receive path of the second pair, to transmit a first signal using the transmit path of the first pair, to monitor the receive path of the second pair, and to determine whether the first signal is at least partially blocked, based at least in part on a result of monitoring the receive path.

Abstract: Unpowered switching module. A switching module can include a first input terminal, a second input terminal, and an output terminal. The output terminal can be configured to output a radio-frequency (RF) component of an input signal received on the first input terminal or the second input terminal in response to the input signal including a positive direct-current (DC) voltage.

Abstract: A computer program is stored in a computer-readable recording medium to implement a test group distribution method in a server device. The test group distribution method includes: generating identification information of a first test to be performed, differently from identification information of at least one test that is registered in advance, wherein the first test is performed by a plurality of user terminals classified into a plurality of groups; generating a unique identifier of each of users by using a first key comprising identification information of each user and a second key comprising the identification information of the first test; and determining test group information of each user based on the unique identifier of each user, the test group information corresponding to a group to which each user belongs.

Abstract: A measurement system comprising a device under test, at least a first antenna and a second antenna, a reflector device, a shielded space and a signal analysis module is disclosed. The first antenna is configured to at least one of generate electromagnetic waves directed to the reflector device and receive electromagnetic waves reflected by the reflector device. The reflector device is configured to reflect electromagnetic waves between the first antenna and the device under test. The second antenna is positioned in a near-field area of the device under test. At least the second antenna is connected to the signal analysis module, and the device under test, the first antenna, the second antenna and the reflector device are assigned to the shielded space. Moreover, a method for operating a measurement system is disclosed.

Abstract: A method and apparatus for notifying authors of a conflict in a report is described herein. During operation authors' devices will be dynamically added to a particular talkgroup if it is determined that a conflict in a report has been detected.

Abstract: A method and a device for pre-correction of a downlink signal are provided. The method comprises: on the basis of an obtained uplink frequency offset value of a first RRU and a second RRU corresponding to each client, determining a set of uplink frequency offset values corresponding to each RRU; when a downlink pre-correction period is reached, calculating an average uplink frequency offset value of the RRU; and on the basis of the average uplink frequency offset value of the RRU and a downlink pre-correction value in a previous pre-correction period, determining a downlink pre-correction value of the RRU in the current downlink pre-correction period.

Abstract: Certain aspects of the present disclosure generally relate to wireless communication. A wireless node may receive a first scheduling command identifying a first resource allocation via a first link, may determine a second resource allocation based at least in part on the first resource allocation and a resource allocation policy, may transmit a second scheduling command identifying the second resource allocation via a second link, and may communicate network traffic on the first link and the second link using the first resource allocation and the second resource allocation, respectively. Numerous other aspects are provided.

Abstract: A method, device and computer program for generating wireless signals for testing a network node for transmitting Narrow Band Internet of Things signals, for compliance with predetermined criteria, the network node being configured to support multiple carriers and to support operation within at least one radio frequency bandwidth. The method comprises: controlling a wireless signal generator to generate one test signal in a frequency band towards one edge of one of the at least one radio frequency bandwidth and one further test signal in a frequency band towards the other edge of the same one of the at least one radio frequency bandwidth, the one test signal comprising a Narrowband Internet of Things test signal.

Abstract: The present disclosure provides a circuit delay self-measurement method, device and system. The device includes: a first communication interface, configured to receive a first analog signal; a receiving circuit module, configured to perform a first processing on the first analog signal to generate a first digital signal; a main control chip, configured to generate a second analog signal; a first switch module, configured to turn off a path between the first stationary end and the first connection end and turn on a path between the first stationary end and the second connection end; the main control chip is configured to send the second analog signal to the receiving circuit module; the receiving circuit module is configured to perform the first processing on the second analog signal to generate a second digital signal; the main control chip is configured to determine the circuit delay of the receiving circuit module.

Abstract: In one embodiment, a method is provided. The method comprises: transmitting, from a RADAR system, a frequency-modulated continuous wave (FMCW) RADAR signal in an anechoic chamber; receiving the FMCW RADAR signal at a test antenna in the anechoic chamber; generating a mixing signal; generating a simulated RADAR return signal from the mixing signal and the received FMCW RADAR signal; radiating the simulated RADAR return signal; and receiving the simulated RADAR return signal.

Abstract: A method is provided for performing over-the-air (OTA) testing of a device under test (DUT). The method includes establishing an OTA connection with the DUT, while the DUT is in signaling mode, the OTA connection including advertising channels and data channels; sending universally unique identifier (UUID) requests at different transmit powers to the DUT over the data channels of the OTA connection; receiving UUID responses from the DUT over the data channels of the OTA connection in response to at least some of the UIDD requests; and determining a packet error rate (PER) for the received UUID responses from the DUT based on a ratio of a number of received responses and a number of sent connect requests. The determined PER indicates sensitivity of a receiver in the DUT.

Abstract: One exemplary embodiment of the present invention relates to a circuit that includes at least one RF signal path for an RF signal and at least one power sensor, which is coupled to the RF signal path and configured to generate a sensor signal representing the power of the RF signal during normal operation of the circuit. The circuit further includes a circuit node for receiving an RF test signal during calibration operation of the circuit. The circuit node is coupled to the at least one power sensor, so that the at least one power sensor receives the RF test signal additionally or alternatively to the RF signal and generates the sensor signal as representing the power of the RF test signal.

Abstract: A waveform generator includes circuitry configured to: generate a digital representation of a pulse and apply the digital representation of the pulse to a digital interface of a radio system configured to propagate the pulse and convert the digital representation of the pulse to a radio frequency signal transmitted at the antenna; and mark the digital representation of the pulse with respect to a frame of digital data with a marker. Measurement of when the pulse occurs in the radio frequency signal based on the marker occurs by a spectrum analyzer. Determination occurs of a downlink propagation delay for the radio system between application of the digital representation of the pulse at the digital interface and transmission of the radio frequency signal at the antenna.

Abstract: An environmental surveillance system includes at least one status sensor, a control device, and at least one portable information capturing device. The control device is coupled to the status sensors to send a broadcast packet in accordance with sensing signals generated from the status sensors. The broadcast packet includes a broadcast data. The broadcast data includes an actuation command. The at least one portable information capturing device receives the broadcast packet and compares a match data with the broadcast data in the broadcast packet. When the match data matches the broadcast data, the at least one portable information capturing device starts a media capturing procedure in accordance with the actuation command.

Abstract: Apparatuses, methods, and systems of a hybrid node are disclosed. One embodiment of the hybrid node includes a first sector and a second sector. The first sector is operative to transmit a signal through a predetermined transmission channel at each of a first plurality of transmit beam forming settings. The second sector is operative to receive the signal through the predetermined channel at a second plurality of receive beam forming settings for each of more than one of the first plurality of transmit beam forming settings. Further, the node is operative to measure a received signal quality of the received signal at each of the second plurality of receive beam forming settings of the second plurality of antenna elements, for each of the more than one of the first plurality of transmit beam forming settings of the first plurality of antenna elements.

Abstract: A system having a system backend having a backend processor configured to define a patient clinical team associated with a patient clinical process comprising of a series of patient clinical tasks effected within the healthcare facility, each patient clinical task with an associated patient clinical task location within the healthcare facility, a group of mobile devices communicably connected via a network to the system backend, each mobile device being associated with and configured for use by at least one care member of the patient clinical team, a low energy (LE) beacon array arranged in a predetermined relationship with and differentiating between different patient clinical task locations, and communicably connected to each of the mobile devices that is configured to resolve its proximity, from the beacon array, relative to the at least one patient clinical task location.

Abstract: A receiver configured to receive a frequency-modulated transmission having a preamble and a corresponding method are provided, the receiver having a buffer coupled to an input terminal for receiving the transmission, a time-to-frequency transformer coupled to the buffer, an energy aggregator coupled to the transformer, a preamble detector coupled to the aggregator, and a symbol synchronizer coupled to the detector; the method including receiving a sequence of time-domain frequency-modulated samples, transforming the sequence of time-domain samples into a spectrum of frequency-domain data, and matching an actual energy distribution over a plurality of discrete frequencies in the frequency-domain data with an expected energy distribution of the preamble to determine frequency error.

Abstract: Systems and methods for processing radiofrequency signals using modulation duty cycle scaling. One system includes a first receive path configured to directly sample a first signal in a first frequency range. The system includes a second receive path configured to convert a second signal in a second frequency range. The second receive path includes a receive modulator operating over a duty cycle. The receive modulator is configured to adjust the duty cycle by a predetermined scaling factor.

Abstract: The embodiments herein relate to a method performed by a testing device (101) for enabling testing of a communication node (103). The testing device (101) measures a test parameter associated with RF characteristics of the communication node (103) when it is located at a test location (105) during a first condition. The communication node (103) is configured with a node setting during the measurement in the first condition. The testing device (101) measures the test parameter associated with the RF characteristics of the communication node (103) when it is located at the test location (105) during a second condition. The communication node (103) is configured with the same node setting in the second condition as in the first condition. The testing device (101) checks whether a result parameter associated with the test parameter measured during the first and second condition fulfills a requirement.

Abstract: Systems, methods, apparatuses, and computer program products for enhancing the setup of carrier aggregation (or dual connectivity or multi connectivity or stand-alone LTE/LTE-like on unlicensed band or LAA or LTE-WLAN aggregation) from IDLE mode (or semi-idle or semi-connected or suspended state) are provided. One method includes providing an indication, to at least one UE, of (or configuring the UE with) potential inter-frequency carriers that the UE should measure during IDLE mode (or during semi-idle or semi-connected or suspended state) for potential SCells. The method may further include during or after RRC connection establishment, receiving an indication from the at least one UE that it has inter-frequency carrier(s) and/or SCell measurement results available, and based on the received measurement results, configuring carrier aggregation (or dual connectivity or multi connectivity or LAA or LTE-WLAN aggregation) without further measurements and activating the SCell.

Abstract: System and method for executing integration tests for testing software code are disclosed. The system comprises multi-user integrated test framework to simulate a multi-user test environment for executing integration tests concurrently. Multi-user integrated test framework receives ‘N’ as number of concurrent users for integration test project comprising integration tests associated with software code. The multi-user integrated test framework simulates multi-user test environment comprising locating a target assembly associated with the integration test project and generating executing assembly by using the integration tests from the target assembly. Simulating the multi-user test environment further comprises dissociating target assembly from executing assembly such that target assembly is prevented from locking and concurrently executing the integration tests, N number of times, by using executing assembly and parallel task library to obtain outcome of each of the plurality of the integration tests.

Abstract: A signal is transmitted and received between a base station device and a communication terminal device that are included in a communication system, through a multi-element antenna including a plurality of antenna elements. At least one of the base station device and the communication terminal device includes a PHY processing unit that is a calibration unit that performs calibration of phases and amplitudes of beams formed by the antenna elements when the signal is transmitted and received. The PHY processing unit obtains a correction value for the phases and the amplitudes of the beams in the respective antenna elements so that the phases and the amplitudes of the beams are identical among the antenna elements, and performs the calibration based on the obtained correction value.

Abstract: Disclosed is a method of multiuser uplink power control comprising receiving a multiuser uplink calibration transmission from a plurality of stations; grouping the plurality of stations into a plurality of subsets based on a subset characteristic; receiving a subset optimization transmission from a first subset according to a subset rule; and calculating a first calibrated coding data rate and a first calibrated target uplink transmit power for a station in the first subset based on the subset optimization transmission.

Abstract: Systems, methods and apparatus are disclosed for automatic signal detection in an RF environment. An apparatus comprises at least one receiver and at least one processor coupled with at least one memory. The apparatus is at the edge of a communication network. The apparatus sweeps and learns the RF environment in a predetermined period based on statistical learning techniques, thereby creating learning data. The apparatus forms a knowledge map based on the learning data, scrubs a real-time spectral sweep against the knowledge map, and creates impressions on the RF environment based on a machine learning algorithm. The apparatus is operable to detect at least one signal in the RF environment.

Abstract: One embodiment of the present invention provides a system for correctly processing an interest in a content-centric network (CCN). During operation, a first node in the CCN receives an interest for a piece of content from a second node. The interest indicates a name of the piece of content and a hop count from the second node to a destination node advertising the piece of content. The system determines, based on forwarding information and information associated with pending interests stored on the first node, whether a distance-based forwarding condition is met; and in response to the distance-based forwarding condition being met, accepts the interest.

Abstract: An intelligent wireless access system for a vehicle comprises a non-transitory computer-readable storage medium having stored thereon a computer program for tracking a target and estimating distance, a position, or direction of the target to a vehicle. The computer program comprises a routine of set instructions for causing the machine to perform receiving a beacon packet from the target, determining signal strength information for the beacon packet, transmitting a message comprising the signal strength information and the beacon packet for the target, and estimating based on received message, at least one of distance, position, or direction of the target to the vehicle.

Abstract: In retrodirective wireless power delivery environments wireless power receivers generate and send beacon signals that are received by multiple antennas of a wireless power transmission system. The beacon signals provide the charger with timing information for wireless power transfers and also indicate directionality of the incoming signal. As discussed herein, the directionality information is employed when transmitting in order to focus energy (e.g., power wave delivery) on individual wireless power receiver clients. Techniques are described herein for reducing the burden of sampling the beacon signals across the multiple antennas and determining the directionality of the incoming wave. In some embodiments, the techniques leverage previously calculated values to simplify the receiver sampling.

Abstract: A vehicular radio communications system establishes a bi-directional digital radio communications link between a local wireless communication device inside a moving vehicle and a sequence of radio transceivers in a wireless network. The local device operates in a plurality of different device frequency bands and the external transceivers operate in a plurality of different network frequency bands. Some or all of the device frequency bands are the same as some or all of the network frequency bands. The system comprises a set of one or more external radio antennas operating in an external downlink and an external uplink using a network frequency band and a set of one or more local radio antennas operating in a local downlink and a local uplink using a local frequency band different from the network band.

Abstract: Methods and radio frequency (RF) Doppler emulator circuits for emulating Doppler spread in an RF domain. The RF Doppler emulator circuit includes a power splitter, a signature control circuit, a first variable attenuator, a second variable attenuator, and a power combiner. The power splitter is configured to receive an RF input signal and generate a first signal and a second signal using the RF input signal. The signature control circuit is configured to generate a third signal using the first signal. The signature control circuit is further configured to generate a fourth signal using the second signal. The first variable attenuator is configured to generate a fifth signal using the third signal. The second variable attenuator is configured to generate a sixth signal using the fourth signal. The power combiner is configured to generate an RF output signal by combining the fifth signal and the sixth signal.

Abstract: A mobile communication device comprises a communication interface for wireless communication of the mobile communication device with wireless devices over a wireless communication channel, and a channel simulation unit for simulating modified channel properties of the wireless communication channel.

Abstract: A system for estimating the location of a node in a mesh network and predicting future location of the same. Historical RSSI of nodes in a mesh network may be used to determine relative location amongst other nodes. The system may employ statistical approaches to predict future node locations.

Abstract: Methods, systems, and apparatuses are described for wireless communications. More particularly, an access point (AP) identifies a plurality of multi-user multiple-input multiple-output (MU-MIMO) groups associated with a wireless station (STA). The AP determines a communication metric associated with each of the plurality of MU-MIMO groups. The communication metric provides an indication of the compatibility of the STAs in the MU-MIMO group. The AP prioritizes at least one of the plurality of MU-MIMO groups based at least in part on the communication metric associated with the prioritized MU-MIMO group. The AP creates a preferred group list and/or a blacklisted group list and included the prioritized MU-MIMO group in the appropriate group list.

Abstract: A method and apparatus is disclosed herein for internal relative transceiver calibration.

Abstract: A method for measuring downlink delay in a radio system includes applying a digital representation of a Gaussian pulse to a digital interface of the radio system; marking the digital representation of the Gaussian pulse with respect to a frame of digital data with a marker; propagating the Gaussian pulse in the radio system to an antenna, the radio system configured to convert the digital representation of the Gaussian pulse to a radio frequency signal transmitted at the antenna; measuring when the Gaussian pulse occurs in the radio frequency signal based on the marker; and determining a downlink propagation delay for the radio system between application of the digital representation of the Gaussian pulse at the digital interface and transmission of the radio frequency signal at the antenna.

Abstract: A reception device receives a radio frequency (RF) signal and obtains a data signal from the RF signal in a desired reception channel. The reception device includes a bandpass filter, and first and second test signals are input to the bandpass filter in the test mode to obtain bandpass-filtered first and second test signals, respectively. Each of frequencies of the first and second test signals is lower and higher than a frequency of the desired reception channel, respectively. The reception device detects lower and higher frequency signal intensities from the bandpass-filtered first and second test signals, respectively, in the test mode, and adjusts a central frequency of the passband of the bandpass filter using a difference between the lower and higher frequency signal intensities so as to reduce a difference between the central frequency of the passband and the frequency of the desired reception channel.

Abstract: A test method for testing a device under test with a measurement unit comprises transmitting a number of test commands from the measurement unit to the device under test via a test interface of the device under test, generating in the device under test in response to the test commands respective communication signals, emitting by the device under test the generated communication signals via a wireless communication interface, receiving signals from the device under test in the measurement unit, and evaluating the received signals in the measurement unit.

Abstract: Apparatus, method and computer program for magnetic positioning management. A management apparatus assigns an identifier for a transmitting mobile apparatus, and commands the transmitting mobile apparatus to transmit a radio beacon including the identifier. The management apparatus receives reception information from a receiving mobile apparatus that received the radio beacon, the reception information including the identifier of the transmitting mobile apparatus. For at least one of the transmitting mobile apparatus or the receiving mobile apparatus, the management apparatus determines its estimated location for a magnetic positioning based on an association of the transmitting mobile apparatus with the receiving mobile apparatus.

Abstract: The method of routing for wireless ad hoc and sensor networks is a routing protocol that uses a greedy approach, selecting the best route having the maximum remaining energy above a pre-defined threshold limit. The method of routing for wireless ad hoc and sensor networks is an energy efficient routing protocol, in that the routing path is selected to maximize the lifetime of an individual source-destination pair by selecting a route between them that is based on the energy levels of neighboring nodes, without requiring an energy-intensive network flooding approach. The routing path between a source node and a destination node is selected by choosing, at each node, a neighboring node that has the greatest remaining energy level.

Abstract: The present invention relates to a reception apparatus. The reception apparatus includes a plurality of reception antennas; and a signal processing unit configured to use reception characteristic of the plurality of reception antennas, wherein the signal processing unit comprises a channel estimation unit configured to respectively estimate a channel response matrix of each signal received via the plurality of reception antennas, and a coding unit configured to define a coding matrix based on an inverse matrix of the estimated channel response matrix, and to obtain a final output signal corresponding to each reception antenna by applying the coding matrix to each received signal.

Abstract: In performing SVD-MIMO transmission, a set-up procedure is simplified while assuring a satisfactory decoding capability with a reduced number of antennas. A transmitter estimates channel information based on reference signals sent from a receiver, determines a transmit antenna weighting coefficient matrix based on the channel information, calculates a weight to be assigned to each of components of a multiplexed signal, and sends, to the receiver, training signals for respective signal components, the training signals being weighted by the calculated weights. On the other hand, the receiver determines a receive antenna weighting coefficient matrix based on the received training signals.

Abstract: A phone holder for a mobile phone testing apparatus which comprises at least a base plate, a rest structure on the base plate for supporting a mobile phone, at least one block for contacting a mobile phone's narrow side, wherein the at least one block is moveably attached to the base plate, thereby enabling adapting the position of the block to a mobile phone being supported by said rest, and clamping means for releasable fixing the at least one first block in said position can be configured for securely holding almost any mobile phone model.