Patent application number | Description | Published |
20080204100 | Logic circuit - For example, a gain control part and a common node control part are provided in a logic circuit including a data acquisition part that has a differential amplifier configuration and acquires a data input signal when a click signal is an “H” level and a latch part that latches a data output signal from the data acquisition part when the click signal is an “L” level. The gain control part is provided between common nodes of NMOS transistors in the differential amplifier and serves to make the gain of the differential amplifier higher in a high frequency band than in a low frequency band. When the clock signal is an “L” level, the common node control part serves to control an electrical charge so as to eliminate a potential difference between the common nodes. Thus, the transition time of the data output signal is speeded up and the setup margin is increased in the latch part. The above described technique can therefore speed up operations of various logic circuits such as a latch circuit. | 08-28-2008 |
20080265973 | Semiconductor Device Having Transmitter/Receiver Circuit Between Circuit Blocks - A receiver circuit includes first and second constant current sources respectively connected to a pair of first and second receiving terminals to receive complementary current signals, a first NMOS transistor connected at a source thereof to the first receiving terminal and the first constant current source and connected at a drain thereof to a first power supply via a first output terminal and first load means, and a second NMOS transistor connected at a source thereof to the second receiving terminal and the second constant current source and connected at a drain thereof to the first power supply via a second output terminal and second load means. | 10-30-2008 |
20090009240 | Amplifier Circuit - An amplifier circuit block and a compensation circuit block are provided. The amplifier circuit block includes an analog adder for subtracting an output signal of the compensation circuit block from an input signal and an amplifier circuit operating in a wide band. The compensation circuit block includes an amplifier circuit with a low offset voltage and a low noise in a low frequency region, an analog adder block for subtracting an output signal of the amplifier circuit from an output signal of the amplifier circuit and generating a differential signal thereof, and a feedback circuit block for negatively feeding back the differential signal to the analog adder. The amplifier circuit block can reduce the offset voltage and the low-band noise by the negative feedback of the differential signal, and at the same time, the operation band of the entire amplifier circuit can be decided by the characteristic of the amplifier circuit. | 01-08-2009 |
20090033431 | Oscillation Circuit - The present invention provides a highly accurate oscillation circuit. For example, the oscillation circuit includes plural ring oscillator units RO | 02-05-2009 |
20090085632 | LOW-OFFSET INPUT CIRCUIT - In a signal transmission system where an influence of the circuit characteristic variation of an input circuit on signal receiving operation cannot be ignored, there is provided a method of realizing a low-offset input circuit which is capable of conducting high-speed operation and always continuing signal receiving operation without increasing the number of terminals of a semiconductor integrated circuit and without the necessity of providing additional signal observing means and variation adjustment amount calculating means to the external of the semiconductor integrated circuit. In a signal receiver circuit having an input circuit, an automatic zero amplifier, an analog/digital converter circuit, an encoder circuit, and a signal holding circuit, an output error signal of the input circuit is amplified by the automatic zero amplifier, and the signal is digitalized or the digitalized signal is encoded as the occasion demands, and held by the holding circuit, and the circuit characteristic variation of the input circuit is adjusted by the held signal. | 04-02-2009 |
20090207957 | Clock recovery circuit - A clock recovery circuit capable of simultaneously satisfying all of a bit synchronization period, a clock wander tracking performance, and a high high-frequency jitter tolerance. The clock recovery circuit includes: a phase difference detecting circuit that detects a phase difference between an input data signal and a recovery clock; an averaging circuit that averages the output of the phase difference detecting circuit; a sampling and holding circuit with resetting that samples and holds the output of the phase difference detecting circuit; and a recovery clock generating circuit that generates a recovery clock having a phase corresponding to the sum of the integral value of the output of the averaging circuit and the output of the sampling and holding circuit with resetting. The sampling and holding circuit with resetting receives a burst transmission start signal and samples and holds the output of the phase difference detecting. In addition, the sampling and holding circuit with resetting receives a burst transmission end signal and resets the held value to an initial value. | 08-20-2009 |
20090296851 | Pre-emphasis circuit - A pre-emphasis circuit which can improve a communication quality of a data transmission at low cost is provided. A current switch circuit, a current adder circuit, and transition detection circuits are provided in a transmitter of a data transmission system. The transition detection circuits detect transitions of transmission data signals which are a differential pair. The current switch circuit receives the transmission data signals, carries driving currents in accordance with the transmission data signals, and outputs output data signals which are a differential pair. The current adder circuit receives detection signals from the transition detection circuits, and adds driving currents in accordance with the detection signals to load resistors. By this means, output data signals in which the transitions are emphasized are inputted to a transmission line. | 12-03-2009 |
20090304092 | Low offset input circuit and transmission system with the input circuit - A low offset input circuit and a signal transmission system which can accommodate a high-speed interface and achieve reduction of an offset voltage are provided. An offset voltage compensating circuit block | 12-10-2009 |
20110001588 | WAVEFORM EQUALIZATION CIRCUIT WITH PULSE WIDTH MODULATION - There is provided a waveform equalization circuit with pulse width modulation that includes pulse-width adjust-level generation circuits PWCLC | 01-06-2011 |
20110193595 | OUTPUT DRIVER CIRCUIT - Disclosed is an output driver circuit capable of realizing reduction in power consumption, and/or enhancement in transmission waveform quality in addition to an increase in transmission speed. The output driver circuit is provided with, for example, a voltage-signal generation circuit block VSG_BK for driving positive negative output-nodes (TXP, TXN) by voltage, -pulse-signal generation circuits PGEN | 08-11-2011 |
20110249980 | OPTICAL COMMUNICATION MODULE AND OPTICAL COMMUNICATION DEVICE - An optical communication module and an optical communication device including the same are provided. For example, a first semiconductor chip on which a laser diode is formed and a second semiconductor chip on which a laser diode driver circuit, etc. for subjecting the laser diode to drive by current are formed are mounted on a package printed circuit board to be close to each other. Temperature detecting means is further formed on the second semiconductor chip (laser diode driver circuit, etc.). The temperature detecting means detects a temperature variation ΔT of the first semiconductor chip (laser diode) transmitted via a wiring in the package printed circuit board and controls the magnitude of the driving current of the laser diode driver circuit based on a detection result. | 10-13-2011 |
20110316632 | OPTICAL COMMUNICATION DEVICE - An optical communication device which can be operated at high speed is provided. For example, the optical communication device includes: a pre-amplifier circuit PREAMP | 12-29-2011 |
20120133394 | DATA JUDGMENT/PHASE COMPARISON CIRCUIT - The invention relates to a clock generation circuit and a signal reproduction circuit including the clock generation circuit, and, more particularly, the invention provides a data judgment/phase comparison circuit capable of performing both of data judgment and phase comparison by a single-phase clock, and provides a CDR (Clock Data Recovery) circuit including the data judgment/phase comparison circuit. The same data and clock are inputted to two data judging units C GOOD and C BAD each having a different data determination period (setup/hold time) required for correctly judging a data, and an output of the data judging unit C GOOD having a shorter required data determination period is taken as a data output of the data judgment/phase comparison circuit. When the outputs of both of the data judging units are different from each other, a signal Early indicating that a clock phase is too early or a signal Late indicating that the clock phase is too late is outputted. Depending on a relation among data outputs of total three symbols obtained by combining a symbol and symbols previous and subsequent thereto, it is selected that either the Early or the Late is to be outputted by a decision logic EL_LOGIC. | 05-31-2012 |
20120187980 | TRANSMITTER CIRCUIT - A transmitter circuit in which a driver circuit includes MOS transistors for bias voltage application, in which a driving current flows, cascode-connected to MOS transistors for differential signal input controlled by a voltage value of transmitted data signals, controlled by a voltage value of a bias voltage, and driver circuits include MOS transistors for bias voltage application, in which a driving current flows, cascode-connected to MOS transistors for differential signal input that is controlled by a voltage value of signals obtained by the transmitted data signals, connected to a load portion, and controlled by a voltage value of a bias voltage. | 07-26-2012 |
20120249217 | SEMICONDUCTOR INTEGRATED CIRCUIT DEVICE - A high-speed semiconductor integrated circuit device is achieved by adjusting an offset voltage. For example, dummy NMOS transistors MND | 10-04-2012 |
20130016748 | TRANSIMPEDANCE AMPLIFIER, SEMICONDUCTOR DEVICE, AND OPTICAL MODULEAANM TAKEMOTO; TakashiAACI FuchuAACO JPAAGP TAKEMOTO; Takashi Fuchu JPAANM YAMASHITA; HirokiAACI HachiojiAACO JPAAGP YAMASHITA; Hiroki Hachioji JPAANM TSUJI; ShinjiAACI HidakaAACO JPAAGP TSUJI; Shinji Hidaka JP - An optical module including a transimpedance amplifier capable of realizing a high-speed and high-quality receiving operation is provided. A transimpedance amplifier includes: a pre-amplifier using a single-end current signal as an input and converting the single-end current signal to a single-end voltage signal; an automatic decision threshold control detecting a center electric potential of the single-end voltage signal serving as an output of the pre-amplifier; a post-amplifier differentiating and amplifying the single-end voltage signal of the output of the pre-amplifier; and a power circuit supplying power to the pre-amplifier. Particularly, in accordance with an input voltage signal or an output voltage signal of the pre-amplifier, the power circuit outputs a varied current that flows to a supply terminal of the pre-amplifier and a varied current having a phase opposite to that of the varied current. Thus, the power supply current change is cancelled out. | 01-17-2013 |