Abstract: According to an aspect of the present invention, there is provided a reference voltage generation circuit including: a first transistor having a first gate, a first source and a first drain; a second transistor having a second gate connected to the first gate, a second source connected to the first source and a second drain; a first diode connected between a ground and a V? node; a first resistor connected between the V? node and the first drain; a second diode and a second resistor connected between the ground and a V+ node; a third resistor connected between the V+ node and the first drain; an operational amplifier including input ports connected to the V+ node and the V? node and an output port connected to the first gate and the second gate; and a fourth resistor connected between the ground and the second drain.

Abstract: A level-shift circuit, comprising: an input, for receiving a first voltage; an output, for outputting a second voltage; a resistor array comprising one or more resistors connected in series to the input; a current sink for providing a current that is independent of the first voltage; a switch arrangement comprising a plurality of switch connections for establishing a selected one from a plurality of force paths between the current sink and the input, the selected force path comprising a selected number of the one or more resistors of said resistor array; and at least one connection between the output and the resistor array that provides a sense path between the resistor array and the output that does not comprise any of the switch connections used to establish each of the plurality of force paths.

Abstract: Disclosed is a signal output circuit comprising: a first transistor of an emitter follower configuration, which receives an input signal; a second transistor of an emitter follower configuration, which receives the input signal, and has an output connected to an external load (106); a comparator circuit which has an input pair connected via resistors to emitters of the first and the second transistors; a first current mirror circuit which has an input connected to an output of a first current source transistor and an output connected to an emitter of the first transistor; and a second current mirror circuit which has an input connected to a connection node of an output of a second current source transistor and an output of the comparator circuit, and has an output connected to an emitter of the second transistor.

Abstract: A method is disclosed for determining the intensity of ionizing radiation using a detector with a multiplicity of direct-conversion detector elements, in particular for use in a CT system. In at least one embodiment, the method includes supplying the signal pulses to a preamplifier/signal conditioner, supplying the amplified and conditioned signal pulses to two pulse-height discriminators connected in parallel or in series, registering by a combination logic, and transmitting the registered signal pulses to a counter. In at least one embodiment, provision is made for feedback, by which, firstly, the pulse shape of the signal pulses and, secondly, the clock rate of the clocked pulse-height discriminator are set as a function of the signal frequency.

Abstract: Method and device for adjusting or setting an electronic device (1) exhibiting at least one input for an external input signal and at least one output signal output, the value or the state of the output signal being a function of the values or of the state of the input signal. A memory circuit (9) for the value of an adjustment signal is linked to an adjustment input of the electronic device. A circuit (11) increments/decrements said adjustment value stored in said memory circuit. A switching circuit (12) switches said input of the electronic device to a predetermined state and links said output of the electronic device to said memory circuit via said incrementing/decrementing circuit. Said incrementing/decrementing circuit (11) is adapted for adjusting the value of said adjustment signal so that, when said input is switched to said predetermined state, the value or the state of said output signal tend to or attain a predetermined value or a predetermined state.

Abstract: Embodiments of methods and apparatus for receiving data are disclosed. More particularly, methods of receiving a current mode signal, which can improve a signal to noise ratio (SNR) according to a change in a power supply voltage, and current mode comparators and semiconductor devices that use the methods are provided. A method of receiving a current mode signal includes receiving a reference current signal and a data current signal through a channel and generating a sensing voltage based on a difference between the reference current signal and the data current signal, varying a transconductance to reduce an input resistance of the current mode comparator in inverse proportion to an increase in a power supply voltage supplied to the current mode comparator, and converting the sensing voltage into a CMOS level output signal using the current mode comparator.

Abstract: In one embodiment, an integrated device is disclosed. For example, in one embodiment of the present invention, a device comprises a logic control, and a combination differential driver coupled to the logic control, wherein the logic control receives a control signal for configuring the combination differential driver as a Low Voltage Differential Signaling (LVDS) driver or as a Transition Minimized Differential Signaling (TMDS) driver.

Abstract: A current mode comparator for a semiconductor device is disclosed. The current mode comparator may include a logic circuit coupled to a voltage sensing node, a first cascode coupled to the voltage sensing node and a first power node, and a second cascode coupled to the voltage sensing node and a second power node. The logic circuit may convert a voltage of the voltage sensing node to an output signal.

Abstract: In one embodiment, a zero crossing detector couples a plurality of comparators in parallel and operates at least a portion of the comparators at different time periods.

Abstract: The present disclosure relates to a differential signaling circuit including differential signaling circuitry having at least one output and one input, that can operate in multiple mode of operations while using a single, low voltage supply source. Two or more switches are included and configured to selectively couple a supply voltage to the output dependent on a mode of operation of the differential signaling circuitry. The circuit also includes a switch control biasing circuit operatively coupled to at least one of the switches and to the output of the differential signaling circuitry. The switch control biasing circuit provides a switch control biasing voltage to control a state of the switch based on a voltage level of the output. Further, a bulk biasing circuit is included and operatively coupled to the switch. The bulk biasing circuit selectively provides a bulk biasing voltage to the switch based on the voltage level of the output.

Abstract: A differential comparator is provided. The comparator receiving two differential signals and generating a comparison result represented by an output signal on one of two output terminals respectively on two current paths. The comparator comprises two pairs of latch transistors respectively disposed on the two current paths and two pairs of input transistors respectively disposed on the two current paths, wherein gates of the latch transistors on one of the current paths are commonly coupled to the output terminal between the latch transistors on the other current path, gates of the input transistors on one of the current paths respectively receives an input signal of one of the differential signals and a reference signal of the other differential signal and each of the input transistors is disposed between the output terminal and one of the latch transistors on the current path thereof.

Abstract: A motor speed control circuit which controls a rotational speed of a motor by controlling an amount of current flowing through a drive coil of the motor. The control circuit comprises a reference voltage circuit that generates a reference voltage corresponding to a speed-specifying signal inputted to specify the rotational speed of the motor; a clamp circuit that limits a level of the reference voltage generated by the reference voltage circuit; a comparator that has a speed voltage corresponding to an actual rotational speed of the motor and the reference voltage limited in level by the clamp circuit applied thereto and compares the two; and a control signal generator that generates and outputs a control signal for controlling the amount of current flowing through the drive coil based on the comparing result of the comparator.

Abstract: Circuits and methods may be improved by using ADCs that compensate for the effect of comparator input offset on comparator decisions. Offset compensation may be implemented in an ADC by using an amplifier section between the input of the ADC and a comparator section of the ADC to amplify the signals supplied to the comparator inputs and thereby reduce the effect of comparator offset on the comparator decision. The comparator section may be an autozeroing comparator section that is capable of performing an offset reduction operation to store offset compensation values at capacitors provided at its inputs. The amplifier section may be an autozeroing amplifier section having one or more amplifier stages that are capable of performing an offset reduction operation to store offset compensation values at capacitors provided at their inputs. Offset compensation may also be implemented using an autozeroing comparator section without a preceding amplifier section.

Abstract: A voltage level detection circuit is disclosed. The voltage level detection circuit comprises a pull-up unit including a plurality of pull-up devices, each for supplying an internal voltage in response to a signal resulting from a logic operation of a voltage up control signal and a voltage down control signal, a voltage division unit including a plurality of voltage dividers, each for dividing the internal voltage from a corresponding one of the pull-up device, a switching unit including a plurality of switching devices, each for switching and supplying an output voltage from a corresponding one of the voltage dividers to an output node in response to a signal resulting from a logic operation of the voltage up control signal and voltage down control signal, and a comparator for comparing the voltage at the output node with a predetermined reference voltage and outputting a voltage pumping enable signal according to a result of the comparison.

Abstract: A voltage (UE1, UE2), other than a supply voltage (UV1, UV2), is monitored and controlled to avoid damage to circuit components by maintaining a required voltage level. Dissipation power losses are reduced by switching off a monitoring circuit when monitoring is not required. For this purpose a stepped down voltage is derived from the voltage to be monitored at a tap (N1) of a voltage divider connected between ground potential and the voltage to be monitored. The derived voltage is then evaluated, for example by comparing with a reference voltage. A controllable switch is connected in series with two voltage divider elements. The switch is controlled to open for switching off the voltage divider when monitoring is not needed. The switch is closed to activate the voltage divider when monitoring is needed.

Abstract: The present disclosure relates to a differential signaling circuit including differential signaling circuitry having at least one output and one input, that can operate in multiple mode of operations while using a single, low voltage supply source. Two or more switches are included and configured to selectively couple a supply voltage to the output dependent on a mode of operation of the differential signaling circuitry. The circuit also includes a switch control biasing circuit operatively coupled to at least one of the switches and to the output of the differential signaling circuitry. The switch control biasing circuit provides a switch control biasing voltage to control a state of the switch based on a voltage level of the output. Further, a bulk biasing circuit is included and operatively coupled to the switch. The bulk biasing circuit selectively provides a bulk biasing voltage to the switch based on the voltage level of the output.

Abstract: Disclosed is an internal voltage generator, which includes a detecting means for detecting a level of an internal voltage, an oscillator for generating a driving pulse signal in response to an output signal of the detecting means, a first driving unit for outputting a first pulse signal after receiving the driving pulse signal, a second driving unit for outputting a second pulse signal after receiving the driving pulse signal, and a pumping unit for changing a potential level of the internal voltage after selectively receiving one of the first pulse signal and the second pulse signal.

Abstract: A DC level wandering cancellation circuit is provided. The DC level wandering cancellation circuit comprises a low pass filter, for receiving an input voltage; a high pass filter coupled to the low pass filter; an amplifier coupled to the high pass filter for receiving a reference voltage and an output signal of the high pass filter; a comparator coupled to the amplifier for receiving an output signal of the amplifier to compare the reference voltage with the output signal of the amplifier; a resistor coupled between outputs of the high pass filter and the amplifier; a control logic coupled to the comparator for receiving a compared result from the comparator; and a switching means coupled between the high pass filter and the output of the amplifier. The switching means is turned on for a predetermined interval by the control logic according to the compared result.

Abstract: Disclosed herein is a method and system for calibrating line drive currents in systems that generate data signals by varying line drive currents and that interpret the data signals by comparing them to one or more reference voltages. The calibration includes varying the line drive current at a transmitting component. At different line drive currents, a receiver reference voltage is varied while the transmitting component transmits data to a receiving component. At each line drive current, the system records the highest and lowest receiver reference voltages at which data errors do not occur. The system then examines the recorded high and low receiver reference voltages to determine a desirable line drive current.

Abstract: A feedback control system and method thereof are provided. The feedback control method includes (a) comparing the level of a reference signal with the levels of first and second signals, (b) if the levels of the first and second signals are lower than the level of the reference signal, generating a first control signal, if the levels of the first and second signals are higher than the level of the reference signal, generating a second control signal, and if the level of the reference signal is between the level of the first signal and the level of the second signal, generating a third control signal, (c) controlling the level of an output signal in response to the first through third control signals, and (d) outputting the controlled output signal and generating the first signal and the second signal.

Abstract: The conventional chopper comparator circuit has had high power consumption because the gain thereof used to be set high, so that there has been the need for cutting down on power consumption.

Abstract: The present invention is related to a device comprising a capacitive feedback transimpedance operational amplifier, that comprises a main operational amplifier (with a first input, a second input and an output) and an integrating capacitor, connected between the second input and the output, and a first switch connected in parallel to the integrating capacitor. The device further comprises an auto-zero operational amplifier having a third input and a fourth input, whereby to the third input and the first input signals at virtual ground potential are applied. The fourth input is connected to the output by a circuit comprising two offset error capacitors, a second switch and a third switch.

Abstract: An input circuit has a differential amplification circuit which converts a differential signal to a single end signal to output the single end signal, an attenuation circuit which attenuates a first input signal to output the attenuated signal to the differential amplification circuit, a capacitor in which one end thereof is connected to a first input terminal to which the first input signal is inputted, and another end thereof is connected to an output side of the differential amplification circuit, a buffer to which the single end signal outputted from the differential amplification circuit and a signal transmitted through the capacitor are inputted, and which outputs the output signal, and a feedback circuit which outputs a signal based on an output signal outputted from the buffer and the second input signal to the differential amplification circuit.

Abstract: A voltage comparator with comparing means that are energized upon the occurrence of a clock-edge and that are de-energized when the comparison operation is completed. The comparing means are preceded by a voltage divider (D) for dividing the voltage to be compared and a switch (S8) in series with the voltage divider for preventing current flow through the voltage divider when the comparing means are de-energized.

Abstract: A comparator circuit includes a reference generator connecting to a first source providing a first voltage. The reference generator is operative to generate a reference signal and includes a control circuit selectively operable in at least a first mode or a second mode in response to a first control signal, wherein in the first mode the reference signal is not generated, and in the second mode the reference generator is operative to generate the reference signal. The comparator circuit further includes a comparator connecting to a second source providing a second voltage, the second voltage being less than the first voltage. The comparator is operative to receive the reference signal and an input signal, and to generate an output signal which is a function of a comparison between the input signal and the reference signal.

Abstract: A DC level wandering cancellation circuit is provided. The DC level wandering cancellation circuit comprises a low pass filter, for receiving an input voltage; a high pass filter coupled to the low pass filter; an amplifier coupled to the high pass filter for receiving a reference voltage and an output signal of the high pass filter; a comparator coupled to the amplifier for receiving an output signal of the amplifier to compare the reference voltage with the output signal of the amplifier; a resistor coupled between outputs of the high pass filter and the amplifier; a control logic coupled to the comparator for receiving a compared result from the comparator; and a switching means coupled between the high pass filter and the output of the amplifier. The switching means is turned on for a predetermined interval by the control logic according to the compared result.

Abstract: Comparison circuits are provided, corresponding to a plurality of pull up transistors, each for comparing a voltage at an output node and each respective reference voltage different in voltage level from other, and for adjusting a drive current of a corresponding output pull up transistor, and further comparison circuits are provided, corresponding to a plurality of pull down transistors, each for comparing the voltage of the output node and each respective reference voltage different in voltage level from other, and each for adjusting an amount of a drive current of a corresponding pull down transistor in accordance with a result of comparison. The reference voltages each are set to a voltage level between a power supply voltage and a ground voltage. Without a dedicated power supply pin terminal, a signal of a small amplitude having the amplitude limited stably and precisely can be output at high speed.

Abstract: A high-speed signal level detector employs the high gain and high bandwidth of an inverter to perform a comparison. The high-speed signal level detector is capable of achieving the desired high-speed level detection without demanding the substantial power consumption required when using either the averaging technique or a high bandwidth op-amp type comparator.

Abstract: An input circuit in a DRAM includes a differential amplifier circuit amplifying a potential difference between a potential of an input signal and a reference potential, an inverter outputting an inversion signal of an output signal of the differential amplifier circuit, a latch circuit holding an output signal in a preceding cycle, and two resistive elements for switching the reference potential in accordance with an output signal of the latch circuit. Thus, the reference potential is switched in accordance with the logic level of the input signal in the preceding cycle, allowing accurate determination of the logic level of the input signal.

Abstract: The present invention concerns an apparatus comprising a first circuit and a second circuit. The first circuit may be configured to generate a reference output voltage in response to a plurality of reference voltages. The second circuit may be configured to generate an output voltage in response to the reference output voltage and an unknown voltage. The output voltage may comprise accurately controlled hysteresis.

Abstract: In one embodiment, a power switch device (33) includes a first MOSFET device 41 and a second MOSFET device (42). A split gate structure (84) including a first gate electrode (48,87) controls the first MOSFET device (41). A second gate electrode (49,92) controls the second MOSFET device (42). A current limit device (38) is coupled to the first gate electrode (48,97) to turn on the first MOSFET device during a current limit mode. A comparator device (36) is coupled to the second gate electrode (49,92) to turn on the second MOSFET device (42) when the power switch device (33) is no longer in current limit mode.

Abstract: A sensor signal output circuit includes a first differential amplifier, a first load resistor, a first transistor, a second transistor and a limiter section. The limiter section includes at least a second differential amplifier, which includes an input end coupled to output terminal and an other input end coupled to second reference voltage setting part, a second load resistor for a second differential amplifier, and a third transistor, which includes a gate connected to an output end of the second differential amplifier and a source connected to a gate of the second transistor.

Abstract: A differential input receiver with hysteresis on both sides of the reference voltage may include a two-input, one-output differential amplifier including two input transistors having a common terminal connected together. The control terminal of each transistor may be connected to one of the inputs of the differential amplifier. The output of the differential amplifier may be connected to a set of cascaded digital inverters/buffers, and an output of each digital buffer may be connected to the control terminal of a feedback transistor. The feedback transistor may be connected in parallel across each of the input transistors so that when one input voltage increases above or decreases below the input voltage at the second input by a predetermined threshold value, the feedback transistors operate to provide positive feedback to facilitate a rapid switching action at the output.

Abstract: An output driver circuit includes an input stage to which an input voltage is applied, and an output stage to which an output voltage is applied, input stage and output stage being connected by at least one supply voltage terminal and/or at least one ground terminal to which at least one parasitic inductance is applied, and the input stage and output stage being configured so that when the difference amount between a potential as a function of the input voltage and a potential as a function of the supply voltage and/or ground voltage exceeds a predefined first threshold value or drops below a predefined second threshold value a flow of current is activated or deactivated respectively in the output stage via the supply voltage terminal(s) and/or the ground terminal(s) which also flows via the parasitic inductance(s).

Abstract: An edge sensitive detection circuit includes a filter module and a soft latch module. The filter module is operably coupled to receive an input logic signal that corresponds to the triggering of an event and produces a pulse signal in response to an edge of the input logic signal. The filter may include a capacitor operably coupled to a controlled impedance, an inverter and a driver transistor, wherein the capacitor senses an edge of the input logic signal and, in combination with the controlled impedance, produces the pulse signal. The soft latch module is operably coupled to receive the pulse signal and to latch a logic value in accordance with the pulse signal.

Abstract: System and methods are provided for monitoring circuit performance and correcting for variations in current reference signals to maintain a desired Voltage Output Differential (VOD) between the two differential output signals. A voltage signal associated with VOD is compared to a signal that is set to a desired voltage level based on a desired VOD. By determining whether the VOD level is higher or lower than the desired level, adjustments are made to at least one of an output current source level and an output current sink level. An increase in the source and sink currents at the output results in an increased VOD, while a balance decrease in the source and sink currents results in a decreased VOD.

Abstract: A system for measuring the stability of a power signal from a power supply includes a threshold violation detector. The threshold violation detector includes a comparator and an indicator. The comparator has a power signal input, a threshold signal input, and a comparison result output, and is configured to compare the power signal on the power signal input with a threshold on the threshold signal input to present a comparison result signal on the comparison result output. The indicator has a threshold violation output and a comparison input that receives the comparison result signal from the comparator. The indicator presents a threshold violation signal on the threshold violation output when the comparison result signal indicates that the power signal has violated the threshold.

Abstract: LVDS drivers and analog-to-digital (ADC) systems are provided which facilitate easy alteration (e.g., replacement of a selectable resistor Rsel) of differential current levels and differential voltages in response to altered loads. These drivers and systems maintain common-mode levels in the loads which are unaffected by alterations in the loads and their associated differential current and voltage levels.

Abstract: This invention relates to a method and apparatus for converting a current signal into a two-level output voltage depending on a reference current signal. In one embodiment, a first current, which is the reference current signal is applied to the apparatus. A negative feedback sets the output of the apparatus in a certain configuration. Any current signal to be compared to the reference current signal may be then applied. The output voltage level depends on whether the current signal is lower or higher than the reference current signal.

Abstract: An input buffer circuit for use with an analog-to-digital converter is provided. The input buffer circuit comprises a first amplifier configured with a second amplifier to improve the overall gain of the input buffer circuit. The first amplifier comprises a differential pair of transistors configured with a second pair of transistors comprising a current mirror arrangement, wherein one of the differential pair of transistors of the first amplifier is configured in a diode-connected arrangement to provide a first feedback loop, while the second amplifier comprises a differential pair of transistors configured with another pair of transistors also comprising a current mirror arrangement, with the second amplifier and the current mirror arrangement of the first amplifier comprising a second feedback loop.

Abstract: An amplifier circuit configuration includes a data line for transmitting a data signal. The data line is connected to a data signal input of an amplifier by way of a switching device. The amplifier includes a control circuit for controlling an input resistance of the amplifier with a terminal for a control signal. The terminal for the control signal of the control circuit is connected, parallel to the switching device, to the data line. As a consequence, a switching device, which is connected between the data line and the amplifier, has only little influence on the dynamic response when reading out a data signal.

Abstract: A multi-stage, low-offset, fast-recovery, comparator system and method for: reducing the input offset voltage of the zeroing amplifier by a factor essentially equal to gain of the zeroing amplifier; reducing the input offset voltage of the combined main and zeroing amplifiers by a factor essentially equal to the product of the gains of the main and zeroing amplifiers; and amplifying the input signal to the amplification stage in accordance with the gain of the main amplifier to generate an amplified high-resolution signal.

Abstract: In an isolator circuit, a first differential pair circuit compares voltages of two input signals with each other, and, in accordance with the ratio of the voltages, currents flow through two resistors respectively connected to two output terminals of the first differential pair circuit. A current comparison circuit compares the currents respectively flowing through the two resistors, and outputs a voltage corresponding to a result of the comparison. A second differential pair circuit compares the voltage output from the current comparison circuit with a reference voltage, and a negative feedback is conducted so that the currents flowing through the two resistors are equal to each other. Unlike the conventional art, an isolator circuit can be configured without disposing buffer circuits.

Abstract: A circuit receives data from a high frequency data line. The circuit determines the data value by employing a decision circuit and an over-sampling circuit. The over-sampling circuit captures the data levels on the data line at spaced apart time intervals. The decision circuit employs the data levels captured by the over-sampling circuit and a previously stored value to determine the data level that should be received from the data line.

Abstract: The present invention discloses a current comparator having simple, cheap and fast characteristics, especially discloses a current comparator having a small dead zone and excellent driving capability. The current comparator of the present invention comprises a first CMOS transistor, a second CMOS transistor, a diode-configured N-type transistor, a fourth CMOS transistor and a fifth CMOS transistor.

Abstract: A fast voltage differential signaling (LVDS) transceiver (50) having high repeater speeds up to 1.36 GBps, and also meeting the TIA/EIA-644 standard short-to-ground requirements. A mixed voltage-current mode differential driver has a respective control signal (A3) driving each of the drive transistors (Q3). The control signal (A3) is controlled by a transistor (M1) being a function of current through the respective drive transistor (Q3). A current mirror (Q4, Q5, Q6) is used to mirror current conducting through a transistor (Q4) in parallel with the drive transistor (Q3), which mirror current is compared against a current reference (Iref).

Abstract: An input buffer circuit for transforming pseudo differential input signals into full differential output signals wherein, the input buffer circuit includes a pull-up current source, two pull-down current sources, a differential input portion, and a positive feedback portion. The pull-up current source is formed of two PMOS transistors which are always in an “on” state, and provides an electric current. The two pull-down current sources are each formed of an NMOS transistor, which are always in an on state, and sink a pull-up electric current. The differential input portion is formed of two NMOS transistors, and receives an input signal and a reference signal, respectively. The positive feedback portion is formed of two NMOS transistors, and enlarges a voltage difference between two output terminals of the input circuit using positive feedback.

Abstract: A comparator circuit having a first state and a second state, a threshold potential for transition from the first state to the second state, another threshold potential for transition from the second state to the first state, and hysteresis characteristics that are independent of process, temperature, and supply voltage variations. Preferably, the threshold potentials and hysteresis characteristics depend only on a reference potential and on ratios of resistances of pairs of resistors.

Abstract: Current sense amplifiers with hysteresis are provided which conserve scarce chip surface area yet still provide fast response times in a low power CMOS environment. A first embodiment includes a first amplifier and a second amplifier which are electrically coupled. Each amplifier includes a first transistor of a first conductivity type and a second transistor of a second conductivity type, where the first and second transistors are coupled at a drain region. A signal input node is coupled to a source region of the first transistor in each amplifier. A signal output node is coupled to the drain region of the first and the second transistors in the second amplifier. The signal output node is further coupled to a gate of a third transistor in order to introduce hysteresis into the current sense amplifier. Integrated circuits, electrical systems, methods of operation and methods of forming the novel current sense amplifier are similarly included.

Abstract: The present invention discloses a method and apparatus for thresholding an input signal synchronous with a clock signal at a receiver. The input signal is compared with a threshold voltage to produce a difference signal. The difference signal is synchronized with the input signal to generate a feedback signal. The threshold voltage is adjusted based on the feedback signal.