Aspects of the present disclosure involve systems, methods, computer program products, and the like, for utilizing a CIC value field in signaling information of a communication to provide an identification of the ingress network to an egress or receiving network of a long distance telecommunications network. The system and method provides for the provisioning of a signaling CIC for an ingress trunkgroup or network to a telecommunications network for downstream signaling purposes by overriding a received CIC value with a provisioned CIC value specific to the ingress network. This provisioned CIC value identifies the ingress network to the long distance network to the egress network for use by the egress network.

The present disclosure relates to a reception apparatus and method, a transmission apparatus and method, and a program, capable of obtaining desired communication quality. Under the control of a central control unit, a tactile signal generation unit generates a tactile signal of a necessary number. Under the control of the central control unit, a header generation unit generates header information including the presence or absence of the tactile signal (that is, information indicating whether or not the tactile signal is to be used for each of vibration units as information associated with the vibration unit that uses the tactile signal), the delay amount, and the magnitude. A signal coupling unit adds header information to each of the tactile signals from the tactile signal generation unit, and performs time-division multiplexing on each of the tactile signals to which the header information has been added. The present disclosure can be applied to a tactile presentation system that vibrates a wearable reception apparatus including the vibration unit, for example.

The present disclosure relates to a reception apparatus and method, a transmission apparatus and method, and a program, capable of obtaining desired communication quality. Under the control of a central control unit, a tactile signal generation unit generates a tactile signal of a necessary number. Under the control of the central control unit, a header generation unit generates header information including the presence or absence of the tactile signal (that is, information indicating whether or not the tactile signal is to be used for each of vibration units as information associated with the vibration unit that uses the tactile signal), the delay amount, and the magnitude. A signal coupling unit adds header information to each of the tactile signals from the tactile signal generation unit, and performs time-division multiplexing on each of the tactile signals to which the header information has been added. The present disclosure can be applied to a tactile presentation system that vibrates a wearable reception apparatus including the vibration unit, for example.

An endoscope includes: an imager; a transmission path configured to connect a controller and the imager with each other; a superimposed signal generating circuit configured to generate, as a superimposed signal, a signal obtained by associating High and Low of a pulsed data signal with a change in a pulse width of a pulsed reference clock signal; a parallel-serial converter circuit configured to perform parallel-serial conversion on the imaging signal; a PLL circuit configured to generate a multiplied clock signal; a restoring circuit configured to restore, based on the superimposed signal and the multiplied clock signal, the reference clock signal and the data signal contained in the superimposed signal; and a timing generating circuit configured to generate, based on the reference clock signal and the data signal, a drive signal for driving the imager.

The present disclosure provides an acknowledgment message resource allocation method applicable to an NB-IoT TDD cell, and a corresponding base station and corresponding user equipment for performing the method. The user equipment according to an embodiment of the present invention includes: a receiving unit, configured to receive allocation information of acknowledgment message transmission resources, the allocation information including offset indication information instructing an offset j.sub.0 of a start time of the acknowledgment message transmission resources with respect to a reference time, and the offset j.sub.0 instructing an offset expressed by a number of NB-IoT uplink slots; and a transmitting unit, configured to perform acknowledgment message transmission based on the allocation information.

Methods and apparatuses are provided in which a user equipment (UE) receives a system information block (SIB) from a network. The UE identifies at least one downlink (DL) period based on a first uplink (UL)/DL configuration included in the SIB. The UE monitors a physical downlink control channel (PDCCH) during the at least one DL period using a discontinuous reception (DRX) operation. The UE obtains downlink control information (DCI) for indicating at least one second UL/DL configuration as a format for one or more time intervals from the monitored PDCCH. The UE determines the format for the one or more time intervals based on the obtained DCI. The monitoring of the PDCCH includes monitoring the PDCCH in an active time of a DRX cycle. The active time includes a time when the UE performs continuous reception.

Certain aspects of the present disclosure generally relate to wireless communications and more specifically to transmission resource management for ordered physical random access channel (PRACH) signals. An example method performed by a base station generally includes providing an indication of a set of transmission resources, within a narrowband region of a wider system bandwidth, for transmitting scheduled physical random access channel (PRACH) signals by a first user equipment (UE) and transmitting a command to the first UE to transmit a scheduled PRACH.

A method and a device are provided for deriving audio parameter values from an AES67-compatible audio information signal, which AES67-compatible audio information signal is generated from a serial data stream of successive IP packets (IP(i)), the IP packets containing an IP header (IP HDR), a UDP header (UDP HDR), an RTP header (RTP HDR) and a data field (DATA), and wherein audio parameter values such as sampling frequency and number of channels are derived from information stored in the headers.

Various example embodiments for supporting generation of addresses for network entities in communication systems are presented. Various example embodiments for supporting generation of addresses for network entities may be configured to support generation of a new address for a network entity based on an existing address of the network entity. Various example embodiments for supporting generation of addresses for network entities may be configured to support generation of a new address for a network entity based on manipulation of at least a portion of an existing address of the network entity. Various example embodiments for supporting generation of addresses for network entities may be configured to support generation of a transport layer address (e.g., an Internet Protocol (IP) address or the like) for a network entity based on a data link layer address (e.g., a Media Access Control (MAC) address or the like) of the network entity.

The present invention relates to a power fetching system for a no neutral switch and a control method thereof, and a no neutral switch, wherein the power fetching system is connected to an electrical device and a wireless controller, and the wireless controller controls a switch module for changing an operating state of the electrical device. The power fetching system includes: a power fetching module, connected between a power source and the wireless controller, the power source supplying power to the wireless controller and the electrical device, where the power fetching module is configured to obtain power from the power source and supply the obtained power to the wireless controller during energization of the electrical device; and a control module, connected to the power fetching module, and configured to detect power consumption of the wireless controller and provide a control signal to the power fetching module according to a change in power consumption of the wireless controller to adjust the power obtained by the power fetching module from the power source.