Abstract: Input circuits connected to an external input terminal PAD via resistor elements are activated in response to the level transition of the clock signals supplied thereto for accepting input signals. In order to input signals applied to the external input terminal PAD clock signals having different phases are supplied to the respective input circuits. The cycle time of each one input circuit can be made longer by sequentially assigning the serial data supplied to the external input terminals in response to the clock signals having different clock signals. Since the input circuits are isolated from each other by means of the resistor elements, the influence of the kick back signal which occurs at first stage of each the input circuit upon the other input circuit can be made very small.

Abstract: Provided is an amplifier circuit having a constant output swing range and a stable delay time, where the amplifier circuit includes a first bias unit, a second bias unit, a comparison unit, and an amplifier unit, and the first bias unit responds to an internal reference signal with a predetermined voltage level and maintains constant the amount of a first current, and the second bias unit receives an external reference signal, responds to a control voltage, and controls the amount of a second current to be the same as the amount of the first current, and the comparison unit compares a voltage level of a first node with a voltage level of a second node, and controls a voltage level of the control voltage according to the comparison result, and the amplifier unit compares a voltage level of an external input signal with a voltage level of the external reference signal, amplifies and outputs a voltage difference between the two compared signals, responds to the control voltage, and controls the amount of a third

Abstract: A level shifter circuit, which includes a Schmitt trigger function, shifts voltage of a high level signal into a low voltage and shifts a signal at an intermediate value of an input voltage. The level shifter circuit includes an input terminal connected to low and high voltage circuits. The low voltage circuit outputs a low drive voltage or ground voltage. The high voltage circuit outputs a high drive voltage or a high reference voltage, which is supplied to an RS latch circuit via a potential adjustment circuit at a level equal to an output potential at the low voltage circuit. The RS latch circuit uses the output of the potential adjustment circuit when the input voltage shifts to a high level and uses the output of the low voltage circuit when the input voltage shifts to a low level.

Abstract: In one embodiment, a fan out buffer has the inputs of a plurality of output followers connected to the output of a plurality of distribution gates.

Abstract: An input circuit commonly uses input ports of a microcomputer for a plurality of contact input terminals such as switches provided on the way to the ground. Transistors (Q1) to (Q8) whose bases are connected with contact input terminals (IN1) to (IN8) are provided. Groups of transistors, such as odd-numbered transistors and even-numbered transistors, are made selectable or non-selectable together by a selection output from an I/O port (P01) or (P02) of a microcomputer (12), and collector currents of a plurality of transistors (Q1, Q2; Q3, Q4; Q5, Q6; Q7, Q8) which are not simultaneously selected are converted into voltages using common resistors (R1) to (R4). These voltages then are fed to I/O ports (P1) to (P4). Accordingly, even upon a rise of a contact input from a ground potential due to the ON resistance of switches (SW1) to (SW8), the states of the contacts can be judged precisely.

Abstract: A clock signal generator includes a quartz crystal multivibrator circuit and a pulse-shaping circuit. The pulse-shaping circuit includes a D trigger. The D trigger includes a Q terminal, a Q? terminal, a CP terminal, and a D terminal. An output signal from the quartz crystal multivibrator is transferred to the CP terminal. The Q? terminal is connected to the D terminal. The Q terminal is an output end of the clock signal. A capacitor C4 is connected between the CP terminal and ground. A capacitor C5 is connected between the D terminal and ground. The capacitance of the capacitors C4 and C5 is adjusted to attain a clock signal of a predetermined frequency.

Abstract: A digital storage element comprising a master transparent latch that receives functional data from a data input port and scan data from a scan input port and comprises a master feedback loop with a first transistor coupled to the master feedback loop. The first transistor also is coupled to electrical ground. The digital storage element also comprises a slave transparent latch coupled to the master transparent latch, the slave transparent latch comprising dedicated functional data and scan data output ports, a slave feedback loop and a second transistor coupled to the slave feedback loop. The second transistor is coupled to electrical ground. When a clock signal is in a first state, the first single transistor is activated to preset the digital storage element. When the clock signal is in a second state, the second single transistor is activated to preset the digital storage element.

Abstract: A PLL apparatus and system for generating distributed clocks are disclosed. A synchronizing-edge detector is provided to the PLL apparatus in the PLL system to detect synchronizing edges of the input and output clock signals having gear relationship for the PLL apparatus. The synchronizing-edge detector detects a sample signal the frequency of which is the common divisor of the frequencies of the input and output signal. The PLL apparatus may be provided with a detection terminal connected with one of the input terminals of a pre-divider and loop divider for outputting the sample signal. Alternatively, the PLL system can comprise at least one additional divider coupled to the input and/or output signals of a PLL apparatus to generate the sample signal.

Abstract: A timing domain crossing apparatus and method of transferring signals between timing domains are disclosed. A receiver samples a data signal with a sample clock in a first timing domain. The sampled data signal is expanded to a plurality of expansion signals, which are held valid for a plurality of consecutive active clock cycles. A data order adjuster may re-order the plurality of expansion signals to a predetermined order. A timing generator samples a command signal with an internal clock in a second timing domain to generate a re-timing strobe. The re-timing strobe may be temporally positioned to be within the expansion data window and used to sample the plurality of expansion signals in the second timing domain. The timing domain crossing apparatus and method of signal sampling may be incorporated in a semiconductor device, which may be fabricated on a semiconductor wafer and included in an electronic system.

Abstract: A switching circuit includes a semiconductor switching element having a control electrode and a source-drain current path, the source-drain current path being connected between a voltage source and a load circuit, a parallel circuit formed by first and second transistors having respective collector-emitter paths connected between the control electrode of the semiconductor switching element and a reference potential point, a first resistor connected to the second transistor in series, a differential circuit connected between a control signal terminal and the base of the first transistor and a second resistor connected between the control signal terminal and the base of the second transistor. The first transistor is made conductive by a signal obtained by differentiating a control signal and subsequently the second transistor is made conductive to control the semiconductor switching element for ON/OFF.

Abstract: Hysteresis circuit 10 is composed of three inverters 40, 42, 44. Node NB in hysteresis circuit 10 is connected to the input terminal of transition-detecting part 14 of transmission control part 12. Transition-detecting part 14 detects the timing of the start of the output inversion operation and the timing of the completion of the transition in hysteresis circuit 10 corresponding to potential VB of node NB, and it controls activation/deactivation of inverter 50 on the signal transmission path.

Abstract: A phase adjustment circuit generates multiple clock signals by, for example, successively delaying a first clock signal. One of the generated clock signals is selected and output. A phase difference detector determines whether the phase of the selected clock signal and the phase of a second clock signal satisfy a given condition. The clock signal selection can changed until the condition is satisfied, either by external control by a device that monitors a signal output by the phase difference detector, or by a built-in selection signal generator. This scheme assures that two clock signals with phases satisfying the given condition are obtained, regardless of environmental factors or fabrication variations.

Abstract: A method and circuitry for a Delay Locked Loop (DLL) or a phase Locked Loop (PLL) is disclosed, which improves the loop stability at high frequencies and allows maximum tracking bandwidth, regardless of process, voltage, or temperature variations. Central to the technique is to effectively operate the loop at a lower frequency close to its own intrinsic bandwidth (1/tLoop) instead of at the higher frequency of the clock signal (1/tCK). To do so, in one embodiment, the loop delay, tLoop, is measured or estimated prior to operation of the loop. The phase detector is then enabled to operate close to the loop frequency, 1/tLoop. In short, the phase detector is made not to see activity during useless delay times, which prevents the loop from overreacting and becoming unstable.

Abstract: A duty cycle corrector including a restore circuit configured to receive a differential input clock and a differential feedback clock each having crossings of a first type and a second type and to provide a differential output clock having crossing of the first type based on differential input clock crossings of the first type and crossings of the second type based on differential feedback clock crossings of the first type. A delay element configured to delay the differential output clock by a delay time to provide the differential feedback clock. An adjuster circuit configured to receive the differential input and feedback clocks and to adjust the delay time so as to maintain a duty cycle of the differential output clock substantially at a desired duty cycle.

Abstract: Systems and techniques for producing a signal with a known phase relationship to a source clock at an output of an indeterminate circuit element such as a clock divider. The systems and techniques may be used to allow circuit test data to be accurately compared with simulation data.

Abstract: A digital storage element comprises a master transparent latch that receives functional data from a data input port and scan data from a scan input port and a slave transparent latch coupled to the master transparent latch. The slave transparent latch comprises dedicated functional data and scan data output ports. The master and slave transparent latches have opposite transparent polarities when in a functional mode and have the same polarities (e.g., positive level sense) when in a scan mode. The transparent polarity of a transparent latch defines the state of a clock to that latch for which the transparent latch is transparent.

Abstract: A method and system for providing startup delay is disclosed. The system includes a startup delay circuit. The startup delay circuit includes a signal generating sub-circuit that generates an output signal. The signal generating sub-circuit generates the output signal after a period of time that is related to an input offset of a component of the signal generating sub-circuit.

Abstract: First and second analog switches are connected in series between first and second nodes. One terminal of a third analog switch is connected to a series connection node of the first and second analog switches. The other terminal of the third analog switch is supplied with a second voltage different from a first voltage applied to the first node. The third analog switch drives on when the first and second analog switches drive off, and outputs the second voltage to the series connection node of the first and second analog switches.

Abstract: A circuit arrangement for bidirectional current limiting comprises a first transistor, a second transistor, a first resistor, a first zener diode and a second zener diode. The first transistor comprises a first controllable path and a first control terminal and the second transistor comprises a second controllable path and a second control terminal. The first and the second control terminals are connected to a first current source and the first resistor is connected between the first and the second controllable paths. The first zener diode is connected between the first current source and a first line node which is located between the first controllable path of the first transistor and the first resistor. The second zener diode is connected between the first current source and a second line node which is located between the second controllable path of the second transistor and the first resistor.

Abstract: A differential sense amplifier is described that can be configured as a preamplifier or a latch circuit as triggered by a clock signal connected to a switch circuit. When the clock signal is set at a first signal level, the switch circuit in the differential sense amplifier is activated so that the differential sense amplifier is configured as a preamplifier with a positive feedback circuit. When the clock signal is set at a second signal level, the switch circuit in the differential sense amplifier is deactivated so that the differential sense amplifier is configured as the latch circuit. For one read cycle, the differential sense amplifier operates first as the preamplifier and then as the latch circuit.