A transceiver system includes a transmitter including a first driving signal output unit and a second driving signal output unit and a receiver including a first sensing signal input unit and a second sensing signal input unit. A first channel includes a first input/output line and a second input/output line that connect the first driving signal output unit and the first sensing signal input unit, and are configured to transfer signals having different phases; a second channel including a third input/output line and a fourth input/output line that connect the second driving signal output unit and the second sensing signal input unit, and are configured to transfer signals having different phases; and a first compensation capacitor including a first electrode electrically connected to the second input/output line and a second electrode electrically connected to the third input/output line.

A transceiver system includes a transmitter including a first driving signal output unit and a second driving signal output unit and a receiver including a first sensing signal input unit and a second sensing signal input unit. A first channel includes a first input/output line and a second input/output line that connect the first driving signal output unit and the first sensing signal input unit, and are configured to transfer signals having different phases; a second channel including a third input/output line and a fourth input/output line that connect the second driving signal output unit and the second sensing signal input unit, and are configured to transfer signals having different phases; and a first compensation capacitor including a first electrode electrically connected to the second input/output line and a second electrode electrically connected to the third input/output line.

A vehicle-mounted relay device includes a hardware unit implementing functions of first to third layer of OSI model, and a software unit implementing functions of fourth and upper layers of OSI model. The hardware unit includes a first abnormality recording section in which an abnormal frame detected during data relay is recorded, and a first abnormality recording processing section storing, in response to detection of the abnormal frame, the abnormal frame in the first abnormality recording section. The software unit includes a second vehicle information recording section in which vehicle information sequentially transmitted from an end ECU is stored, and a first diagnostic recording processing section, which reads out the abnormal frame from the first abnormality recording section and reads out the vehicle information from the second vehicle information recording section, and stores the readout abnormal frame and vehicle information in a diagnostic information recording section as diagnostic information.

A center server corresponding to a communication management device manages communication between a vehicle and an outside thereof. The center server includes: a request acquisition unit corresponding to an acquisition unit that acquires a requested bandwidth, which is a communication bandwidth requested for execution of a specific process in the vehicle, a radio resource arbitration unit corresponding to an identification unit that identifies a frequency band to which the requested bandwidth is allocated, according to a communication capacity of the vehicle, and a request response unit corresponding to a transmission unit that transmits, to the vehicle, an allocation result of allocating the requested bandwidth to the identified frequency band.

A communication ECU corresponding to a communication control device controls communication between a vehicle and an outside thereof. The communication ECU includes a requested bandwidth calculation unit corresponding to a calculation unit that calculates a requested bandwidth, which is a communication bandwidth requested for execution of a specific process in the vehicle, based on at least one of a computing power and a sensing capability of the vehicle. The communication ECU includes a bandwidth request unit corresponding to a request unit that requests a communication management device to secure the requested bandwidth; and a cooperation condition notification unit corresponding to a defining unit that defines a utilization bandwidth, which is a communication bandwidth used by the vehicle, based on a response to a request to secure the requested bandwidth.

A work machine includes a body, a work implement attached to the body, and a controller that executes a transmission process of transmitting data to an external apparatus installed outside the body. The controller measures a speed of communication with the external apparatus, places a functional restriction on the transmission process when the speed of communication is lower than a predetermined required speed, reinforces the functional restriction on the transmission process as the speed of communication lowers, and reinforces the functional restriction on the transmission process when a state of the work machine is an operation state, as compared to a case where the state of the work machine is not the operation state.

A wireless communication method includes determining a length of a ZC sequence based on a resource block quantity or a subcarrier quantity corresponding to a system bandwidth and determining a reference signal sequence included in an uplink reference signal based on the length of the ZC sequence and a resource block quantity or a subcarrier quantity corresponding to an allocated user bandwidth that is a part of the system bandwidth. When different communications devices use the same system bandwidth for communication, reference signal sequences used by the different communications devices correspond to the same ZC sequence length. The ZC sequence length is exclusively designed for a resource block quantity or a carrier quantity of the system bandwidth. Generation of the reference signal sequences is related to mapped locations of the reference signal sequences. Therefore, reference signal sequences used by different communications devices have a relatively high cross correlation.

A transceiver system includes a transmitter including a first driving signal output unit and a second driving signal output unit and a receiver including a first sensing signal input unit and a second sensing signal input unit. A first channel includes a first input/output line and a second input/output line that connect the first driving signal output unit and the first sensing signal input unit, and are configured to transfer signals having different phases; a second channel including a third input/output line and a fourth input/output line that connect the second driving signal output unit and the second sensing signal input unit, and are configured to transfer signals having different phases; and a first compensation capacitor including a first electrode electrically connected to the second input/output line and a second electrode electrically connected to the third input/output line.

A transceiver system includes a transmitter including a first driving signal output unit and a second driving signal output unit and a receiver including a first sensing signal input unit and a second sensing signal input unit. A first channel includes a first input/output line and a second input/output line that connect the first driving signal output unit and the first sensing signal input unit, and are configured to transfer signals having different phases; a second channel including a third input/output line and a fourth input/output line that connect the second driving signal output unit and the second sensing signal input unit, and are configured to transfer signals having different phases; and a first compensation capacitor including a first electrode electrically connected to the second input/output line and a second electrode electrically connected to the third input/output line.

In one embodiment, an apparatus includes a switch core that has a multi-stage switch fabric. A first set of peripheral processing devices coupled to the multi-stage switch fabric by a set of connections that have a protocol. Each peripheral processing device from the first set of peripheral processing devices is a storage node that has virtualized resources. The virtualized resources of the first set of peripheral processing devices collectively define a virtual storage resource interconnected by the switch core. A second set of peripheral processing devices coupled to the multi-stage switch fabric by a set of connections that have the protocol. Each peripheral processing device from the first set of peripheral processing devices is a compute node that has virtualized resources. The virtualized resources of the second set of peripheral processing devices collectively define a virtual compute resource interconnected by the switch core.