Abstract: Imaging devices and ranging devices are disclosed. In one example, an imaging device includes a semiconductor substrate, a first pixel array, a second pixel array, and a control unit. In the first pixel array, a first light receiving pixel on the semiconductor substrate has a stacked structure of a first electrode, a photoelectric conversion layer, and a second electrode (80). It photoelectrically converts light in a first wavelength region including the visible light region. In the second pixel array, a second light receiving pixel is provided at a position overlapping the first light receiving pixel in a thickness direction of the semiconductor substrate. It photoelectrically converts light in a second wavelength region including the infrared light region. The control unit drives and controls the second pixel array based on a signal photoelectrically converted by the first pixel array.

Abstract: A display panel includes a display region defined by a plurality of pixels P and a peripheral region other than the display region. The display panel includes a gate drive circuit and a dummy capacitance portion in the peripheral region. The gate drive circuit includes a shift register. The dummy capacitance portion includes a plurality of capacitance elements connected in parallel and connected to a dummy stage. Each of the plurality of capacitance elements includes a first capacitance electrode, a second capacitance electrode, and a dielectric layer positioned between the first capacitance electrode and the second capacitance electrode. The dummy capacitance portion further includes at least one first connection portion with two ends respectively connected to the first capacitance electrode of any one of the plurality of capacitance elements and to the first capacitance electrode of any other one of the plurality of capacitance elements.

Abstract: A display panel includes a display region and a peripheral region other than the display region. The display panel includes, in the peripheral region, a gate drive circuit and a first trunk line extending in a column direction. The first trunk line includes a first edge on a first side corresponding to the display region side in the row direction and a second edge on a second side corresponding to a side opposite to the display region in the row direction. The first trunk line includes a first portion and a second portion, each including the first edge and the second edge, and the first edge of the second portion is closer to the second side in the row direction than the first edge of the first portion. The first portion is not provided with an element, and the second portion includes a region provided with an element.

Abstract: The accuracy of an offset value is improved by correcting an error in time synchronization caused by link asymmetry. PTP packets are exchanged between a master node 3 and a slave node 4 vis a first transmission device 1 connected to the master node 3 and a second transmission device 2 corresponding to the first transmission device 1 and connected to the slave node 4.

Abstract: A time synchronization mechanism is provided. A second transmission device includes: a transmission section configured to transmit packets for delay calculation for a plurality of wavelengths to the corresponding time transmission device simultaneously; and a reception section configured to calculate a propagation delay Dms on a path from the corresponding time transmission device to the second transmission device based on a difference between the arrival times of the packets for delay calculation for the plurality of wavelengths received, receive a propagation delay Dsm on a path from the second transmission device to the corresponding time transmission device calculated, and calculate a propagation delay Dmax that is larger than any of the propagation delay Dms and the propagation delay Dsm. The reception section transmits a received PTP packet to a slave node after a waiting delay Wms calculated by subtracting the propagation delay Dms from the propagation delay Dmax.

Abstract: Device cost and electric power consumption are reduced. Nodes 11a to 11d as optical add/drop multiplexers each include AWGs 24a and 24b connected between light transmission paths as optical fibers 12 and 13 and transponders 25a to 25n and configured to output optical signals from the light transmission paths to the transponders 25a to 25n through ports and transmit optical signals from the transponders 25a to 25n to the light transmission paths through ports, and an optical coupler 24c configured to connect ports of the AWGs 24a and 24b to the transponders 25a to 25n through coupling or bifurcation. The channel interval of ports of the AWGs 24a and 24b is multiple times larger than the channel interval of ports of the transponders 25a to 25n, and transponder signals of a plurality of different wavelengths to and from one or a plurality of the transponders 25a to 25n can pass through ports of the AWGs 24a and 24b.

Abstract: An optical transmission device of each node simultaneously sends a plurality of signals having different wavelengths as delay measurement signals to a transmission path. The optical transmission device determines a delay value that reflects a propagation delay calculated based on an arrival time difference between a plurality of wavelengths in a signal received from another node, and determines a waiting time amount based on the delay value and the propagation delay. The optical transmission device notifies the other node of the delay value. Each optical transmission device outputs the received signal from the other node with a delay of the waiting time amount. The optical transmission device generates an optical intermittent signal obtained by selecting and multiplexing any of time information, the delay measurement signal, and communication information. A reception side extracts a desired multiplexed signal from the received optical intermittent signals.

Abstract: Device cost and electric power consumption are reduced. Nodes 11a to 11d as optical add/drop multiplexers each include cAWGs 24a and 24b that include a plurality of first side ports and a plurality of second side ports connected between light transmission paths as optical fibers 12 and 13 and transponders 25a to 25n and in which a first optical signal input-output channel interval of each port is a plurality of times larger than a second optical signal input-output channel interval of ports of the transponders 25a to 25n and optical signals of a plurality of different wavelengths from one or a plurality of transponders 25a to 25n or the light transmission paths can pass through a first channel. The cAWGs 24a and 24b cause the optical signals from the transponders 25a to 25n to pass through the first side ports, and then cyclically outputs and transmits the optical signals through the plurality of second side ports in a predetermined order to the light transmission paths.

Abstract: [Problem to be Solved] Optimizing a route of time synchronization in a network including apparatuses with different types of precision classes. [Solution to the Problem] A time transmission system includes BC nodes 200 with different types of apparatus performances, and multiple routes of PTP packets from GM nodes 101 and 102 to a BC node 220 via the BC node 200 are present. Each BC node 200 located upstream on a route performs notification of performance information indicating its apparatus performance to the BC node 200 located downstream with respect thereto. The BC node 220 includes a determination index calculation unit 11 that calculates a determination index for each route by referencing the performance information notified from the BC nodes 200 located upstream on each route, and a route selection unit 12 that selects a route for transmitting and receiving PTP packets from multiple routes of PTP packets to the BC node 220, based on the calculated determination index for each route.

Abstract: A connecter terminal structure includes: a male housing of a male connecter; a male terminal accommodated in the male housing and including a first electrical contact portion; a stepped shaft portion formed at a tip end of the first electrical contact portion; a hood portion surrounding the first electrical contact portion; an annular terminal spring externally fitted to the stepped shaft portion; and an insulating cap fixed to a tip end of the stepped shaft portion and configured to hold the annular terminal spring. The connecter terminal structure further includes: a female housing of a female connecter; a female terminal accommodating portion configured to be fitted into the hood portion; and a female terminal accommodated in the female terminal accommodating portion and including a second electrical contact portion having a tubular shape to allow the first electrical contact portion to be inserted therein.

Abstract: A relay device (39bA) includes an optical signal return unit (50a) and a detection unit (55b). When an optical signal input via one optical transmission line (41) of two optical transmission lines (41 and 42) with a double-ring configuration has not been detected for a predetermined time or longer, the detection unit (55b) outputs a disconnection signal of the optical transmission line. The optical signal return unit (50a) is configured to, only when there is an input of the disconnection signal, return to one of the optical transmission lines (41) only a clamp beam that has been sent from a representative node via the other optical transmission line (42) in the direction opposite to the optical signal input via the one of the optical transmission lines (41).

Abstract: An optical demultiplexer 40 includes: a plurality of optical gate switches 41a to 41n configured to transmit, when being turned on, and to block, when being turned off, a multiplexed optical signal obtained by multiplexing optical signals of a plurality of wavelengths by time-division multiplexing or wavelength-division multiplexing in addition to time-division multiplexing; and a cAWG 42 including a plurality of input ports and a plurality of output ports and configured to input the multiplexed optical signal transmitted through the optical gate switches 41a to 41n from the plurality of input ports, demultiplex the input multiplexed optical signal for each wavelength, and cycle and output the demultiplexed optical signals from the plurality of output ports in a predetermined order.

Abstract: [Problem] An object is to obtain a time quality of another GM with high accuracy on the basis of a GM a time quality of which is known already. [Solution] A first TC 20 includes a time comparison unit 23 that calculates time difference information by comparing first time information of a first PTP processing unit 12 and second time information of a second PTP processing unit 22 with each other. In addition, a quality calculation device 5 measures time difference information until time difference information obtained by a time comparison unit 23 of the first TC 20 and time difference information obtained by a time comparison unit 43 of a second TC 40 match each other, and obtains a GM time quality of a second GM 30 on the basis of a transmission time error of the time transmission network 2 at a timing when both of pieces of the time difference information match each other.

Abstract: An optical demultiplexer 40 includes: a plurality of optical gate switches 41a to 41n configured to transmit, when being turned on, and to block, when being turned off, a multiplexed optical signal obtained by multiplexing optical signals of a plurality of wavelengths by time-division multiplexing or wavelength-division multiplexing in addition to time-division multiplexing; and a cAWG 42 including a plurality of input ports and a plurality of output ports and configured to input the multiplexed optical signal transmitted through the optical gate switches 41a to 41n from the plurality of input ports, demultiplex the input multiplexed optical signal for each wavelength, and cycle and output the demultiplexed optical signals from the plurality of output ports in a predetermined order.

Abstract: A Pentas plant having a monogenic, incompletely dominant doubled-flower gene, a method for breeding the same, and a method for providing a Pentas variety with a doubled-flower or semi-double flower phenotype are provided for the purpose of creating a doubled-flower or semi-double flower Pentas plant with voluminous florets and a high ornamental value.

Abstract: The accuracy of an offset value is improved by correcting an error in time synchronization caused by link asymmetry. PTP packets are exchanged between a master node 3 and a slave node 4 vis a first transmission device 1 connected to the master node 3 and a second transmission device 2 corresponding to the first transmission device 1 and connected to the slave node 4.

Abstract: A SW used in the time transmission system in which a master node and a slave node perform transmission and reception of a precision time protocol (PTP) packet via the SW and the time of the master node is synchronized based on time information of the transmission and reception includes a delay calculator that measures an intra-device delay between input and output of the PTP packet to and from the SW, and a delay information writing unit that appends the intra-device delay measured by the delay calculator to a packet subsequent to the PTP packet, and outputs the appended packet to an output destination of the PTP packet.

Abstract: Device cost and electric power consumption are reduced. Nodes 11a to 11d as optical add/drop multiplexers each include AWGs 24a and 24b connected between light transmission paths as optical fibers 12 and 13 and transponders 25a to 25n and configured to output optical signals from the light transmission paths to the transponders 25a to 25n through ports and transmit optical signals from the transponders 25a to 25n to the light transmission paths through ports, and an optical coupler 24c configured to connect ports of the AWGs 24a and 24b to the transponders 25a to 25n through coupling or bifurcation. The channel interval of ports of the AWGs 24a and 24b is multiple times larger than the channel interval of ports of the transponders 25a to 25n, and transponder signals of a plurality of different wavelengths to and from one or a plurality of the transponders 25a to 25n can pass through ports of the AWGs 24a and 24b.

Abstract: A connecter terminal structure includes: a male housing of a male connecter; a male terminal accommodated in the male housing and including a first electrical contact portion; a stepped shaft portion formed at a tip end of the first electrical contact portion; a hood portion surrounding the first electrical contact portion; an annular terminal spring externally fitted to the stepped shaft portion; and an insulating cap fixed to a tip end of the stepped shaft portion and configured to hold the annular terminal spring. The connecter terminal structure further includes: a female housing of a female connecter; a female terminal accommodating portion configured to be fitted into the hood portion; and a female terminal accommodated in the female terminal accommodating portion and including a second electrical contact portion having a tubular shape to allow the first electrical contact portion to be inserted therein.

Abstract: Device cost and electric power consumption are reduced. Nodes 11a to 11d as optical add/drop multiplexers each include cAWGs 24a and 24b that include a plurality of first side ports and a plurality of second side ports connected between light transmission paths as optical fibers 12 and 13 and transponders 25a to 25n and in which a first optical signal input-output channel interval of each port is a plurality of times larger than a second optical signal input-output channel interval of ports of the transponders 25a to 25n and optical signals of a plurality of different wavelengths from one or a plurality of transponders 25a to 25n or the light transmission paths can pass through a first channel. The cAWGs 24a and 24b cause the optical signals from the transponders 25a to 25n to pass through the first side ports, and then cyclically outputs and transmits the optical signals through the plurality of second side ports in a predetermined order to the light transmission paths.