Abstract: Transmitters and receivers for use in hybrid networks capable of supporting time-reversal division multi-access communication protocols are described. Wireless access points include a wireless receiver for receiving a wireless channel probe signal from a device and a wireless transmitter capable of supporting a time-reversal division multi-access (TRDMA) protocol and at least one other wireless communication protocol. A controller is used to control the operation of the wireless transmitter. Wireless terminal devices include a wireless transmitter for transmitting a wireless channel probe signal and a wireless receiver capable of supporting a TRDMA protocol and at least one other wireless communication protocol. A controller is used to control the operation of the wireless receiver. An example of the at least one other wireless communication protocol that may be supported is OFDMA.

Abstract: Method, apparatus and systems for object tracking are disclosed. In one example, a disclosed method includes obtaining at least one time series of channel information (CI) of a wireless multipath channel using: a processor, a memory communicatively coupled with the processor and a set of instructions stored in the memory. The at least one time series of channel information is extracted from a wireless signal transmitted between a Type 1 heterogeneous wireless device at a first position in a venue and a Type 2 heterogeneous wireless device at a second position in the venue through the wireless multipath channel. The wireless multipath channel is impacted by a current movement of an object in the venue. The method also includes determining a spatial-temporal information of the object based on at least one of: the at least one time series of channel information, a time parameter associated with the current movement, and a past spatial-temporal information of the object.

Abstract: Transmitters and receivers for use in hybrid networks capable of supporting time-reversal division multi-access communication protocols are described. Wireless access points include a wireless receiver for receiving a wireless channel probe signal from a device and a wireless transmitter capable of supporting a time-reversal division multi-access (TRDMA) protocol and at least one other wireless communication protocol. A controller is used to control the operation of the wireless transmitter. Wireless terminal devices include a wireless transmitter for transmitting a wireless channel probe signal and a wireless receiver capable of supporting a TRDMA protocol and at least one other wireless communication protocol. A controller is used to control the operation of the wireless receiver. An example of the at least one other wireless communication protocol that may be supported is OFDMA.

Abstract: The present teaching relates to collecting and processing location-specific wireless waveforms for use in wireless communication, components, methods, apparatuses, servers, and systems. In one embodiment, a disclosed system comprises a first wireless transceiver of a first device, and at least one second wireless transceiver of at least one second device. The first wireless transceiver of the first device is wirelessly coupled to the at least one second wireless transceiver through a wireless multipath channel associated with a space. The first device with the first wireless transceiver comprises a processor and a memory, which are configured to obtain a set of channel information (CI) and perform a task associated with the space based on the set of channel information.

Abstract: The present teaching relates to wireless power transmission based on power waveforming. In one example, an apparatus for wireless power transmission is disclosed. The apparatus comprises: at least one antenna configured for receiving at least one wireless signal from a receiver, via a multipath channel between the apparatus and the receiver; and at least one processor configured for estimating at least one channel state information (CSI) of the multipath channel based on the at least one wireless signal, determining a power transmission waveform based on the at least one CSI, and calculating a power transfer signal based on the power transmission waveform and a reference signal. The at least one antenna is further configured for wirelessly transmitting the power transfer signal to the receiver.

Abstract: A method of connecting devices to a network is provided. The method includes providing base stations connected to a network, and at each of the base stations, receiving probe signals from terminal devices. For each of the terminal devices, the base station calculates a signature waveform based on a time-reversed waveform of a channel response signal derived from the corresponding probe signal. For each of the terminal devices, the base station determines a downlink transmit signal for the terminal device based on the downlink data and the corresponding signature waveform, and transmits the downlink signals to the terminal devices. Several base stations have overlapping broadcast regions, several terminal devices are located within the overlapped broadcast regions, the base stations transmit the downlink signals using a same frequency band, and some downlink signals transmitted by base stations having overlapping broadcast regions also overlap in time.

Abstract: A time-reversal positioning system includes a storage storing first data representing channel impulse responses derived from probe signals sent from a plurality of positions and second data representing coordinates of the positions. A data processor determines a position of a terminal device based on the stored channel impulse responses and a time-reversed signal determined based on a time-reversed version of a channel impulse response that is estimated based on a channel probing signal sent from the terminal device.

Abstract: A time-reversal wireless system comprising a first wireless transceiver of a time-reversal client, one or more second wireless transceiver and/or a time-reversal client with the first wireless transceiver. The first wireless transceiver of the time-reversal client is wirelessly coupled to the one or more second wireless transceiver through a wireless broadband multipath channel associated with a space. The time-reversal client contains the first wireless transceiver. The time-reversal client also contains a processor and a memory configured to obtain a set of channel state information (CSI) in a channel probing phase, and/or to obtain a set of location-specific signatures based on the set of CSI and/or a time reversal operation in a channel probing phase.

Abstract: An ATE system performs RA over NAND flash memory DUTs. A first UBM captures fresh failure related data from a DUT. A second UBM transmits existing failure related data. A fail engine accesses the stored existing failure related data and generates a failure list based thereon. The storing and the accessing the existing failure related data, and/or the generating the failure list, are performed in parallel contemporaneously in relation to the capturing the fresh data. The generated failure list is queued. A failure processor, which may be operable for controlling the capturing, computes a redundancy analysis based on the queued failure list. The first and second UBMs then ping-pong operably.

Abstract: In one embodiment, an automated test equipment (ATE) system includes a tester having a tester electronics module, an application specific electronics module, and a tester-to-device under test (DUT) interface mount. The tester electronics module has a first electronics interface configured to electrically connect to a tester-to-DUT interface when the tester-to-DUT interface is coupled to the tester-to-DUT interface mount. The application specific electronics module has a second electronics interface and a third electronics interface. The second and third electronics interfaces are configured to electrically connect to the tester-to-DUT interface when the tester-to-DUT interface is coupled to the tester-to-DUT interface mount. The application specific electronics module is configured to communicate with the tester electronics module via the second electronics interface, and with at least one DUT via the third electronics interface.

Abstract: A method of connecting devices to a network is provided. The method includes providing base stations connected to a network, and at each of the base stations, receiving probe signals from terminal devices. For each of the terminal devices, the base station calculates a signature waveform based on a time-reversed waveform of a channel response signal derived from the corresponding probe signal. For each of the terminal devices, the base station determines a downlink transmit signal for the terminal device based on the downlink data and the corresponding signature waveform, and transmits the downlink signals to the terminal devices. Several base stations have overlapping broadcast regions, several terminal devices are located within the overlapped broadcast regions, the base stations transmit the downlink signals using a same frequency band, and some downlink signals transmitted by base stations having overlapping broadcast regions also overlap in time.

Abstract: A method of connecting devices to a network is provided. The method includes providing base stations connected to a network, and at each of the base stations, receiving probe signals from terminal devices. For each of the terminal devices, the base station calculates a signature waveform based on a time-reversed waveform of a channel response signal derived from the corresponding probe signal. For each of the terminal devices, the base station determines a downlink transmit signal for the terminal device based on the downlink data and the corresponding signature waveform, and transmits the downlink signals to the terminal devices. Several base stations have overlapping broadcast regions, several terminal devices are located within the overlapped broadcast regions, the base stations transmit the downlink signals using a same frequency band, and some downlink signals transmitted by base stations having overlapping broadcast regions also overlap in time.

Abstract: Automated testing system and method of testing memory devices with distributed processing operations. A redundancy analysis system includes multiple test site processors (TSPs) respectively coupled to multiple devices under test (DUTs). Each TSP is installed with a redundancy analyzer configured to analyzing redundancy data returned from a respective (DUT). Each TSP may be coupled with a respective fail engine for returning the redundancy data from the corresponding DUT. A main TSP of the multiple TSPs is configured to control testing routine over the multiple DUTs and process failure related data from the DUTs. The main TSP may direct the RAs distributed in the multiple TSPs to execute the redundancy analyzers in parallel.

Abstract: A method of connecting devices to a network is provided. The method includes providing base stations connected to a network, and at each of the base stations, receiving probe signals from terminal devices. For each of the terminal devices, the base station calculates a signature waveform based on a time-reversed waveform of a channel response signal derived from the corresponding probe signal. For each of the terminal devices, the base station determines a downlink transmit signal for the terminal device based on the downlink data and the corresponding signature waveform, and transmits the downlink signals to the terminal devices. Several base stations have overlapping broadcast regions, several terminal devices are located within the overlapped broadcast regions, the base stations transmit the downlink signals using a same frequency band, and some downlink signals transmitted by base stations having overlapping broadcast regions also overlap in time.

Abstract: A method according to one embodiment of the present invention for evaluating test results for a memory module. The method comprises reviewing contents of a test data stream for one or more sections of the memory module. A first counter is incremented when a defective portion is encountered in the test data stream for a first section of the one or more sections of the memory module. Each defective portion of the first section is marked as good in the test data stream so long as a first counter value is equal to or below a first threshold value. Data from the test data stream identifying defective portions of the first section are stored in an error cache for each remaining defective portion of the first section identified after the first counter passes a first threshold value.

Abstract: A method for evaluating test results for a memory module. Contents of a data stream are reviewed for one or more sections of the memory module. A plurality of counters is incremented when a defective portion is encountered in the data stream for a first section of the memory module. Values of the plurality of counters are compared to corresponding threshold values. Provided two or more counter values are at or above their threshold values, the first section is marked as bad, all defective portions of the first section are removed from the test data stream, and a failure header indicating that the first section is bad is stored and because of which counters in an error cache, otherwise each defective portion of the first section is marked as good in the data stream provided an error correction counter value of the plurality of counter values is equal to or below a first threshold value.

Abstract: An ATE system performs RA over NAND flash memory DUTs. A first UBM captures fresh failure related data from a DUT. A second UBM transmits existing failure related data. A fail engine accesses the stored existing failure related data and generates a failure list based thereon. The storing and the accessing the existing failure related data, and/or the generating the failure list, are performed in parallel contemporaneously in relation to the capturing the fresh data. The generated failure list is queued. A failure processor, which may be operable for controlling the capturing, computes a redundancy analysis based on the queued failure list. The first and second UBMs then ping-pong operably.

Abstract: ATE performs testing of memory devices with distributed processing operations. A redundancy analysis (RA) system has a first test site processor (TSP), operable for controlling a testing routine over multiple DUTs and analyzing redundancy data returned from a first of the DUTs. The RA has at least a second TSP, operable for analyzing redundancy data returned from a second of the DUTs. The RA may have one or more additional TSPs, each operable for analyzing redundancy data returned from an additional DUT. Controlling the testing routine includes directing the RA in each of the first and second (and any of the additional) TSPs.

Abstract: In one embodiment, an automated test equipment (ATE) system includes a tester having a tester electronics module, an application specific electronics module, and a tester-to-device under test (DUT) interface mount. The tester electronics module has a first electronics interface configured to electrically connect to a tester-to-DUT interface when the tester-to-DUT interface is coupled to the tester-to-DUT interface mount. The application specific electronics module has a second electronics interface and a third electronics interface. The second and third electronics interfaces are configured to electrically connect to the tester-to-DUT interface when the tester-to-DUT interface is coupled to the tester-to-DUT interface mount. The application specific electronics module is configured to communicate with the tester electronics module via the second electronics interface, and with at least one DUT via the third electronics interface.

Abstract: A method and computer-readable medium for performing predictive name completion, categorizing call lists and accessing dispatch ID numbers in a database for dispatch dialers is provided. The method for performing predictive name completion includes recognizing a portion of a dispatch ID input by a user; determining a name associated with a dispatch ID, based on the portion of the dispatch ID input by the user, and displaying the name. The method for categorizing call lists includes determining a type of each of a plurality of the dispatch calls; and placing each of the plurality of dispatch calls in one of a plurality of categorized lists, based on the type of each of the plurality of dispatch calls. The method for accessing dispatch ID numbers in a database includes establishing a mirror database including the dispatch ID numbers; and searching the mirror database for particular dispatch ID numbers.