Abstract: An imaging system 1 includes an imaging control device 10, an imaging device 20, and a light emitting device 30. The imaging control device 10 is provided for controlling the imaging device 20 and the light emitting device 30, and includes an evaluation unit 13, a light reception adjustment unit 14, and a light emission adjustment unit 15. The evaluation unit 13 evaluates respective brightnesses of the first image data and the second image data that are output from the imaging device 20. The light reception adjustment unit 14 adjusts any of an exposure time, a diaphragm value, and a gain that are to be used when the imaging device 20 captures an image, based on a brightness evaluation result. The light emission adjustment unit 15 causes the light emitting device 30 to emit light of either wavelength band of the first wavelength band and the second wavelength band, and adjusts a light emission intensity of the light, based on an evaluation result.

Abstract: A receiving device 20 includes a voltage controlled oscillator 22, a sampling unit 23, a control voltage generating unit 24, an error detecting unit 25, and a control voltage holding unit 26. The control voltage holding unit 26 holds a value of a control voltage Vc output from the control voltage generating unit 24. When the error detecting unit 25 detects an error of a digital signal, a control voltage held before error detection is provided to the voltage controlled oscillator 22.

Abstract: This embodiment relates to a transmitter that has a structure to suppress an increase in device occupancy area on a semiconductor substrate. The transmitter includes an output driver, a duplication driver, a reference voltage generation unit, a first selection unit, a second selection unit, a comparison unit, and a control unit. The first selection unit selects a first or second test voltage outputted from a duplication driver in which a resistance value is set in cooperation with the output driver. The second selection unit selects a first or second reference voltage outputted from the reference voltage generation unit. The comparison unit compares magnitudes of the first test voltage and the first reference voltage during a first operation period and compares magnitudes of the second test voltage and the second reference voltage during a second operation period different from the first operation period.

Abstract: A serializer device (1) includes a first latch unit (11), a second latch unit (12), a conversion unit (13), a frequency division unit (14), a load signal generation unit (15), a phase difference detection unit (16), and a reset instruction unit (17), and has a simple configuration and can reduce a bit error rate at an early stage. The phase difference detection unit (16) detects a phase difference between a first clock (CLK1) applied to the first latch unit (11) and a third clock (CLK3) applied to the second latch unit (12). The reset instruction unit (17) outputs a reset instruction signal (RSTn) to the frequency division unit (14) when the phase difference is not within a target range.

Abstract: A mode switching notification in a first mode is transmitted from a transmission device 10 to a reception device 20 according to a first protocol. In a second mode, training data is transmitted from the transmission device 10 to the reception device 20, clock training is performed in the reception device 20, and a mode switching notification for the first mode is transmitted from the transmission device 10 to the reception device 20 according to a second protocol simpler and faster than the first protocol.

Abstract: A transmission/reception system 1 includes a transmission apparatus 10A, and a reception apparatus 20A. The transmission apparatus 10A includes a first switch 101, a second switch 102, a first transistor 111, a second transistor 112, a first differential amplifier 121, and a second differential amplifier 122. The reception apparatus 20A includes a first transistor 211, a second transistor 212, a first differential amplifier 221, a second differential amplifier 222, a first resistor 231, a second resistor 232, and a reception unit 240.

Abstract: A transmitter includes: an output driver that outputs differential signals to differential signal lines; first termination resistors and a first switch which are provided in series between a first reference voltage input terminal to which a reference voltage is inputted and the differential signal lines; a pulse generator that outputs a common-mode pulse to the differential signal lines; a second switch provided between the differential signal lines and the pulse generator; a detector that detects, after generation of the common-mode pulse starts, timing at which a voltage level of the common-mode pulse exceeds a threshold; and a controller that places the second switch in an on state to connect the pulse generator to the differential signal lines, and powers down the output driver and then places the first switch in an off state to allow the pulse generator to output the common-mode pulse to the differential signal lines.

Abstract: The invention relates to a reception device, etc., applied to a transmission/reception system capable of performing high-speed transmission, having a structure to enable to adjust an offset without increasing a circuit area and power consumption. The reception device includes a signal input unit including an offset adjusting circuit, and an adjustment unit. When a pair of adjusting signals of which a voltage between signals is fixed to zero V is outputted from a transmission device to the reception device connected to each other via a differential signal line including at least a pair of signal lines, the signal input unit that has received the pair of adjusting signals outputs logical value data corresponding to the voltage between signals. The adjustment unit determines adjustment value data to adjust the offset of a threshold to obtain the logical value data based on the logical value data inputted in a certain period.

Abstract: A first communication unit 21 of a host-side transceiver device 20 performs communication based on an I2C communication scheme with a host device 10 and receives an access request signal sent from the host device 10. A second communication unit 22 performs communication based on a communication scheme different from the I2C communication scheme with a remote-side transceiver device 30 and sends the access request signal received by the first communication unit 21 to the remote-side transceiver device 30. The first communication unit 21 notifies the host device 10 that the first communication unit 21 has received the access request signal sent from the host device 10 before the access to the remote device 40 based on the access request signal sent from the second communication unit 22 ends.

Abstract: A transmitting device has a transmission data generating part and an output buffer part. The transmission data generating part transmits a data and a clock, which are to be transmitted to a receiving device, and outputs them to the output buffer part. The output buffer part includes a data transmitting part and a clock transmitting part. The clock transmitting part generates and transmits a clock intermittently phase-shifted. The data transmitting part transmits the data in sync with the clock transmitted from the clock transmitting part.

Abstract: The invention relates to a reception device, etc., applied to a transmission/reception system capable of performing high-speed transmission, having a structure to enable to adjust an offset without increasing a circuit area and power consumption. The reception device includes a signal input unit including an offset adjusting circuit, and an adjustment unit. When a pair of adjusting signals of which a voltage between signals is fixed to zero V is outputted from a transmission device to the reception device connected to each other via a differential signal line including at least a pair of signal lines, the signal input unit that has received the pair of adjusting signals outputs logical value data corresponding to the voltage between signals. The adjustment unit determines adjustment value data to adjust the offset of a threshold to obtain the logical value data based on the logical value data inputted in a certain period.

Abstract: The present embodiments relate to a reception device that enables accurate separation of video data and SYNC data sent out from a transmission device in accordance with a data enable (DE) signal, from among reception data even if the reception data deteriorates due to noise. The reception device separates the video data and the SYNC data from the reception data in accordance with the DE signal reproduced using a detection result of the BS data and the BE data representing a transition timing of a signal level of the DE signal and a prediction result of detection timings of the BS data and the BE data or a prediction result of the transition timing of the DE signal.

Abstract: This embodiment relates to a clock data recovering apparatus capable of improving consecutive identical digits (CID) resistance. The clock data recovering apparatus includes a clock generating apparatus. The clock generating apparatus includes a signal selection unit, a phase detection unit, a phase control unit, a selection unit, a phase delay unit, a time measurement unit, and a phase selection unit. The phase delay unit includes a plurality of delay elements. The phase selection unit selectively outputs an output signal of any one of the plurality of delay elements as a feedback clock. The phase detection unit detects a phase relation between an edge signal and the feedback clock. The phase control unit outputs a control signal to control a signal selection operation by the phase selection unit such that a phase difference detected by the phase detection unit decreases, to the phase selection unit.

Abstract: A transmitter includes: an output driver that outputs differential signals to differential signal lines; first termination resistors and a first switch which are provided in series between a first reference voltage input terminal to which a reference voltage is inputted and the differential signal lines; a pulse generator that outputs a common-mode pulse to the differential signal lines; a second switch provided between the differential signal lines and the pulse generator; a detector that detects, after generation of the common-mode pulse starts, timing at which a voltage level of the common-mode pulse exceeds a threshold; and a controller that places the second switch in an on state to connect the pulse generator to the differential signal lines, and powers down the output driver and then places the first switch in an off state to allow the pulse generator to output the common-mode pulse to the differential signal lines.

Abstract: A transmitter includes: an output driver that outputs differential signals to differential signal lines; first termination resistors and a first switch which are provided in series between a first reference voltage input terminal to which a reference voltage is inputted and the differential signal lines; a pulse generator that outputs a common-mode pulse to the differential signal lines during a period during which a pulse output instruction signal is at a significant level; and a detector that outputs a detection result signal indicating a magnitude relationship between a voltage level of the common-mode pulse and a threshold, during a period during which the pulse output instruction signal is at a significant level, and outputs a detection result signal indicating that the voltage level of the common-mode pulse does not exceed the threshold, during a period during which the pulse output instruction signal is at a non-significant level.

Abstract: The embodiment relates to an input device comprises first and second MOS transistors, first to fourth resistors, and a comparator circuit. The first MOS transistor has a drain connected to a first terminal having a first voltage, a gate connected to a signal input terminal, and a source connected to a second terminal having a second voltage via the first and third resistors. The second MOS transistor has a drain and a gate connected to the first terminal, and a source connected to the second terminal via the second and fourth resistors. The comparator circuit outputs a signal having a level corresponding to a state in which a voltage of a node between the first and third resistors is higher or lower than a voltage of a node between the second and fourth resistors.

Abstract: A transmission/reception system 1 includes a transmission device 10 configured to transmit image data and a reception device 20 configured to receive the image data transmitted from the transmission device 10. The transmission device 10 includes a serializer 11, an encoding unit 12, a data buffering unit 13, a data selection unit 14, a counter 15, and a synchronization signal generation unit 16. The data buffering unit 13 buffers data every n bits in synchronization with the clock. The data selection unit 14 outputs m-bit data selected from the data buffered by the data buffering unit 13 on the basis of a count value from the counter 15.

Abstract: The present embodiment relates to, for example, a transceiver system capable of notifying a transmission device of an asynchronous state of a reception device with a simple configuration. The reception device includes an input unit, a synchronous-state detector, a resistance-value controller, and a terminal resistor. When the synchronous-state detector detects the asynchronous state, the resistance-value controller sets a resistance value of the terminal resistor to a resistance value indicating the asynchronous state. The transmission device includes an output unit, an amplitude detector, an output controller, and a transmission resistor. The output controller causes the output unit to output a signal constituting normal data including clock information when the synchronous state of the reception device is detected, and causes the output unit to output a signal constituting training data including the clock information when the asynchronous state of the reception device is detected.

Abstract: A signal multiplexer according to the present embodiment has a configuration sufficiently capable of accelerating a data rate. The signal multiplexer includes M number of front units and a rear unit. An m-th front unit Am outputs an output signal corresponding to an m-th input signal Im when both the control signal Cm and the control signal Cn are significant levels, and outputs an output signal having a fixed level when at least either one of the control signal Cm or the control signal Cn is an non-significant level. A rear unit B receives signals from the front units, and outputs a signal having a different signal level in a case in which all the output signals from the front units are the same level or in the other case.

Abstract: A transmitting device has a transmission data generating part and an output buffer part. The transmission data generating part transmits a data and a clock, which are to be transmitted to a receiving device, and outputs them to the output buffer part. The output buffer part includes a data transmitting part and a clock transmitting part. The clock transmitting part generates and transmits a clock intermittently phase-shifted. The data transmitting part transmits the data in sync with the clock transmitted from the clock transmitting part.