Class / Patent application number | Description | Number of patent applications / Date published |
327293000 | With plural paths in network | 39 |
20080204104 | Clocking architecture in stacked and bonded dice - A method and apparatus for distributing clock signals throughout an integrated circuit is provided. An embodiment comprises a distribution die which contains either the clock signal distribution network by itself, or the clock signal distribution network in tandem with a clock signal generator. The distribution die is electrically connected through an interface technology, such as microbumps, to route the clock signals to the functional circuits on a separate functional die. Alternatively, the distribution die could be electrically connected to more than one die at a time, using vias through the distribution die to route the clock signals to the different die. This separate distribution die reduces the coupling between lines and also helps to prevent signal skew as the signal moves through the distribution network. | 08-28-2008 |
20080284483 | Clock distribution circuit and test method - A clock distribution circuit having plural stages of buffers disposed along branch paths for dividing up a clock signal and configured in a manner that outputs of a plurality of buffers in a final stage and/or a middle stage are short-circuited, includes in relation to at least one buffer of a plurality of buffers in the same stage on a branch path, a selector for receiving an output of an adjacent buffer located upstream in terms of chain-connection along which the plurality of buffers are connected in testing, and a signal at a branch node corresponding to the at least one buffer by a first input and a second input respectively, selecting one of the first input and the second input based on a select control signal, and supplying the selected input to the one buffer. | 11-20-2008 |
20090033398 | Clock Distribution Network Wiring Structure - A wiring structure for clock signals has two or more parallel clock signal wires disposed in adjacent power wire bays that span the distance between the sinks to which the clock signal wires are to be coupled. The parallel clock signal wires are shorted one to another by stubs placed at locations in order to time the clock wiring structure. The delay tuning of the structure is obtained by the discrete movement of wiring stubs between the wiring bays of the pre-defined power grid. | 02-05-2009 |
20110068845 | SERIALIZER CIRCUITRY FOR HIGH-SPEED SERIAL DATA TRANSMITTERS ON PROGRAMMABLE LOGIC DEVICE INTEGRATED CIRCUITS - Serializer circuitry for high-speed serial data transmitter circuitry on a programmable logic device (“PLD”) or the like includes circuitry for converting parallel data having any of several data widths to serial data. The circuitry can also operate at any frequency in a wide range of frequencies, and can make use of reference clock signals having any of several relationships to the parallel data rate and/or the serial data rate. The circuitry is configurable/re-configurable in various respects, at least some of which configuration/re-configuration can be dynamically controlled (i.e., during user-mode operation of the PLD). | 03-24-2011 |
20110102044 | Clocking Architecture in Stacked and Bonded Dice - A method and apparatus for distributing clock signals throughout an integrated circuit is provided. An embodiment comprises a distribution die which contains either the clock signal distribution network by itself, or the clock signal distribution network in tandem with a clock signal generator. The distribution die is electrically connected through an interface technology, such as microbumps, to route the clock signals to the functional circuits on a separate functional die. Alternatively, the distribution die could be electrically connected to more than one die at a time, using vias through the distribution die to route the clock signals to the different die. This separate distribution die reduces the coupling between lines and also helps to prevent signal skew as the signal moves through the distribution network. | 05-05-2011 |
20110248762 | Clock generator - To provide a clock generator capable of suppressing a peak power, the circuit includes a counter receiving a reference clock signal to generate a timing signal based on the reference clock signal; and a plurality of intermittent clock generating units each coupled to a storage unit thereof storing a bit strings data, each of the intermittent clock generating units receiving the reference clock signal and the timing signal. Each of the intermittent clock generating units masks a clock pulse of the reference clock signal based on the bit string data stored in the storage unit thereof to output an intermittent clock signal in response to the timing signal. | 10-13-2011 |
20120249207 | CLOCK SIGNAL GENERATION CIRCUIT - A clock signal generation circuit includes a first oscillation circuit for generating a first oscillation clock signal having a first frequency; a second oscillation circuit for generating a second oscillation clock signal having a second frequency; a frequency division circuit for generating a frequency division clock signal obtained through dividing the first oscillation clock signal; and a clock selection circuit for outputting the first oscillation clock signal as a high speed clock signal. The clock selection circuit is configured to output the second oscillation clock signal as the low speed clock signal when the second oscillation circuit transmits the second oscillation clock signal, and to output the frequency division clock signal as the low speed clock signal when the second oscillation circuit does not transmit the second oscillation clock signal. | 10-04-2012 |
20130033298 | DOUBLE-SWING CLOCK GENERATOR AND CHARGE PUMP - A double-swing clock generator includes a first double-swing clock generation circuit and a second double-swing clock generation circuit. The first double-swing clock generation circuit is used for receiving a first voltage, a second voltage, a first clock, an inverse first clock, and a third voltage, and outputting a first double-swing clock. The second double-swing clock generation circuit is used for receiving a fourth voltage, the second voltage, the first clock, the inverse first clock, and the third voltage, and outputting a second double-swing clock. | 02-07-2013 |
20130057330 | ENHANCED COMPLEMENTARY WAVEFORM GENERATOR - An enhanced complementary waveform generator (ECWG) generates two complementary pulse width modulation (PWM) outputs determined by rising and falling event sources. In a simple configuration of the ECWG, the rising and falling event sources are the same signal which is a PWM signal having the desired period and duty cycle. The ECWG converts this single PWM input into dual complementary PWM outputs. The frequency and duty cycle of the dual PWM outputs substantially match those of the single input PWM signal. Blanking and deadband times may be introduced between the dual complementary PWM outputs, and the dual complementary PWM outputs may also be phase delayed. | 03-07-2013 |
20130099843 | CLOCK SIGNAL GENERATING APPARATUS CAPABLE OF REDUCING OR AVOIDING CROSSTALK AND GLITCH SIGNALS, AND METHOD USED IN CLOCK SIGNAL GENERATING APPARATUS - A clock signal generating apparatus includes a first frequency generating circuit, a second frequency generating circuit, and an output circuit. The first frequency generating circuit is arranged to generate a first clock signal having a first oscillation frequency. The second frequency generating circuit is arranged to generate a second clock signal having a second oscillation frequency. The output circuit is arranged to receive the first and second clock signals. The output circuit is able to output one of the first and second clock signals as an output clock signal according to an oscillation frequency control setting provided by an external bounding pad included within the clock signal generating apparatus. | 04-25-2013 |
20130099844 | CLOCK DISTRIBUTION CIRCUIT AND METHOD OF FORMING CLOCK DISTRIBUTION CIRCUIT - This invention includes a clock tree to which clock signals are distributed, and a phase comparison circuit configured to detect the phase difference between a plurality of feedback clock signals upon receiving the plurality of feedback clock signals output from different branching points of the clock tree. The invention includes a feedback clock signal generation circuit configured to generate a variation-corrected feedback clock signal for correcting a manufacture variation in the semiconductor integrated circuit based on the phase difference detected by the phase comparison circuit. The invention includes a phase regulation circuit configured to delay the clock signal so as to reduce the phase difference between a reference clock signal and the variation-corrected feedback clock signal generated by the feedback clock signal generation circuit. | 04-25-2013 |
20130342257 | Multi-Point Analog to Single-Line Input for a PLC System - A hardware/PLC logic combination which enables measurement of a plurality of analog voltage points (e.g., multiples of 8 points) on a single high speed PLC input without separate synchronization inputs or outputs. This is accomplished through the use of a multiplexer circuit [clock, binary counter, analog multiplexer, voltage to frequency converter], and a high speed counter function at the PLC. Synchronization between the PLC and circuit is through the detection of a fixed voltage on channel “one” of the circuit, which is set well above the typical range (e.g., 0-10V) of the remaining analog inputs. | 12-26-2013 |
20140021998 | SKEW REDUCTION CIRCUIT - A circuit for skew reduction, includes: first signal lines configured to transmit first signals delayed by first paths respectively; second signal lines configured to transmit second signals delayed by second paths respectively; and a first swap circuit, wherein the first swap circuit is configured to swap and connect the at least one of the first signal lines to the at least one of the second signal lines, when a mutual delay time difference of the second signals in a state where the at least one of the first signal lines is swapped and connected to the at least one of the second signal lines is smaller than a mutual delay time difference of the second signal lines in a state where the first signal lines is connected to the second signal lines without being swapped. | 01-23-2014 |
20140253203 | PROGRAMMABLE CLOCK SPREADING - An integrated circuit having a programmable clock spreader configured to generate a plurality of controllably skewed clock signals, each applied to a corresponding region within the integrated circuit with circuitry configured to be triggered off the applied clock signal. The programmable clock spreader is designed to enable customization of the current-demand characteristics exhibited by the integrated circuit, e.g., based on the circuit's spectral impedance profile, to cause transient voltage droops in the power-supply network of the integrated circuit to be sufficiently small to ensure proper and reliable operation of the integrated circuit. | 09-11-2014 |
20140266376 | ACTIVE CLOCK TREE FOR DATA CONVERTERS - A multi-stage clock distribution circuit for an integrated circuit is provided. The clock distribution circuit may route a common clock signal to a plurality of clock receiver circuits. Each stage in the distribution circuit may include a plurality of buffers. Outputs of at least some, perhaps all, of the buffers may be connected to each other by an interconnect. The interconnect may align clock signals that are output by the interconnected buffers and thereby encourage synchronization of those clock signals. Other stages of the clock distribution signal may be connected as well. | 09-18-2014 |
20150048873 | Power Source for Clock Distribution Network - A clock distribution network having a separate power supply for top levels thereof is disclosed. In one embodiment, an integrated circuit includes a clock distribution network configured to distribute a clock signal to each of a number of clock consumers. The clock distribution network is arranged in a hierarchy of levels, with each of the levels including at least one buffer, and with the upper levels being closer to a source of the clock signal and the lower levels being closer to the clock consumers. The buffers of the upper levels are coupled to receive power from a first power source, via a first power grid. The buffers of the lower levels are coupled to receive power from a second power source, separate from the first, via a second power grid. | 02-19-2015 |
20150301556 | APPARATUS FOR COMMUNICATING ANOTHER DEVICE - A semiconductor chip comprising: an internal clock circuit for generating an internal clock signal; a first phase shift device for shifting the phase of an external clock signal and outputting a phase shifting clock signal; a multiplexer, for selectively outputting one of the internal clock signal and the phase shifting clock signal to be a first clock signal; a second phase shift device, for shifting the phase of the first clock signal and outputting a second clock signal; an first output pad, for outputting the first clock signal; and a controllable pad. The controllable pad is controlled to selectively act as an input pad for receiving the external signal and transmitting the external clock signal to the first phase shift device, or act as a second output pad for transmitting the second clock signal. | 10-22-2015 |
20150378388 | STITCHABLE GLOBAL CLOCK FOR 3D CHIPS - A stitchable clock mesh, a dual operation mode method, and a master clock stratum are provided for a 3D chip stack. The stitchable clock mesh includes at least one clock mesh, on each of the two or more strata, having a plurality of sectors for providing a global clock signal. The stitchable clock mesh further includes mesh data sensors, on each of the two or more strata, for collecting mesh data for the at least one mesh. The mesh data includes measured functional data and measured performance data for a current system configuration. The stitchable clock mesh further includes mesh segmentation and joining circuitry for selectively performing a segmentation operation or a joining operation on the least one mesh or one or more portions thereof responsive to the mesh data and the current system configuration selectable from a plurality of system target configurations. | 12-31-2015 |
20160020759 | SYSTEMS AND METHODS FOR CLOCK DISTRIBUTION IN A DIE-TO-DIE INTERFACE - Circuits for die-to-die clock distribution are provided. A system includes a transmit clock tree on a first die and a receive clock tree on a second die. The transmit clock tree and the receive clock tree are the same, or very nearly the same, so that the insertion delay for a given bit on the transmit clock tree is the same as an insertion delay for a bit corresponding to the given bit on the receive clock tree. While there may be clock skew from bit-to-bit within the same clock tree, corresponding bits on the different die experience the same clock insertion delays. | 01-21-2016 |
20160028385 | SYSTEM AND METHOD FOR CLOCKING INTEGRATED CIRCUIT - A system and method of clocking an integrated circuit (IC) includes determining operating characteristics of the IC. The IC has multiple domains and each domain receives a respective domain clock signal. A skew value is determined for each of the domain clock signals, where each skew value is associated with a respective domain of the IC. The domain clock signals are generated from a reference clock signal and each domain clock signal is skewed from the reference clock according to the respective skew value. | 01-28-2016 |
20160085261 | LOW VOLTAGE SWING BUFFER - An apparatus includes a first circuit of a first type that couples an output node to a first power supply node in response to a first value of a control signal. The apparatus includes a second circuit of a second type to couple the output node to the first power supply node in response to a first value of a first signal having a first voltage swing. The apparatus includes a third circuit of the second type to couple the output node to a second power supply node in response to a second value of the first signal. The apparatus includes a control circuit that generates the control signal based on the first signal and an output signal on the output node. The first, second, and third circuits generate an output signal on the output node. The output signal has a second voltage swing less than the first voltage swing. | 03-24-2016 |
20160109898 | Peripheral Clock Management - A clock generator for use in an electronic system comprising an integrated circuit such as a microcontroller. A plurality of oscillators are selectively enabled to produce a respective plurality of oscillator signals. For each of a plurality of clock outputs, a mux selects a respective one of the oscillator signals in response to a respective select signal provided by a clocked facility. The selected oscillator signal is gated out as the respective clock signal in response to a respective gate signal also provided by the clocked facility. | 04-21-2016 |
20160173071 | CLOCK-DISTRIBUTION DEVICE AND CLOCK-DISTRIBUTION METHOD | 06-16-2016 |
327294000 | With common output | 16 |
20090072876 | ULTRA-WIDE BAND PULSE SIGNAL GENERATOR - There is provided an ultra-wide band pulse signal generator that can vary a waveform and bandwidth of a pulse signal by delaying transmitted data according to a clock signal without using a delay line to generate the pulse signal. An ultra-wide band pulse signal generator according to an aspect of the invention may include: a signal generating unit sequentially delaying transmitted data according to a predetermined clock signal to generate a plurality of pulse signals; an amplification unit amplifying the plurality of pulse signals from the signal generating unit according to predetermined amplification ratios; and a combination unit combining the plurality of pulse signals amplified by the amplification unit. | 03-19-2009 |
20100052761 | DUAL POWER SOURCE PULSE GENERATOR FOR A TRIGGERING SYSTEM - A dual power source pulse generator in power connection with a pair of electrodes having a first electrode, a second electrode and an air gap therebetween. The dual power source pulse generator includes a first pulse source producing a high voltage low current pulse across the pair of electrodes to allow dielectric breakdown, and a second pulse source electrically connected in parallel with an output of the first pulse source, and producing a low voltage high current pulse to thereby produce a current flow of high-density plasma between the same electrodes of the pair of electrodes in response to the high voltage low current pulse. | 03-04-2010 |
20100109737 | Clock pulse generating circuit - A clock pulse generating circuit includes a pulse generator, a clock regulator, and a pre-driver. The pulse generator is configured to vary pulse widths of a rising clock signal and a falling clock signal. The clock regulator is configured to regulate output signals of the pulse generator to prevent an overlap and a duty drop of the output signals of the pulse generator. The pre-driver is configured to output data driving signals according to output signals of the clock regulator. | 05-06-2010 |
20100182065 | MULTI-PHASE ULTRA-WIDEBAND SIGNAL GENERATOR USING DIFFERENTIAL PULSE OSCILLATORS AND ARRAY THEREOF - The present invention relates to a multi-phase ultra-wideband signal generator using differential pulse oscillators and an array thereof. The multi-phase ultra-wideband signal generator using differential pulse oscillators and an array thereof includes N pulse oscillators for generating pulse signals based on supply of power. The multi-phase ultra-wideband signal generator further comprises N inverting amplification units for outputting inverted amplified signals of output signals of the N pulse oscillators when a number of pulse oscillators is at least two, wherein, when the number of pulse oscillators is an even or odd number, the pulse oscillators are arrayed such that they have a connection form in which output terminals OUT(+) and OUT(−) of a relevant pulse oscillator are connected to output terminals OUT(+) and OUT(−) of a next pulse oscillator through a relevant inverting amplification unit, and the connection form is consecutively applied to the pulse oscillators. | 07-22-2010 |
20100188129 | Method and Apparatus for Applying Clock Phase and Frequency Offset - Various apparatuses and methods for offsetting the phase and/or frequency of a clock signal are disclosed herein. For example, some embodiments provide an apparatus for generating a clock signal, including a quadrature delay circuit connected to an input clock signal. The quadrature delay circuit outputs components of the input clock signal with different phase shifts. A first amplitude modulator is connected to the first output of the quadrature delay circuit, and a second amplitude modulator is connected to the second output of the quadrature delay circuit. A summer combines the output of the first and second amplitude modulators. | 07-29-2010 |
20100308884 | CLOCK RECEIVER IN SEMICONDUCTOR INTEGRATED CIRCUIT AND METHOD OF CONTROLLING THE SAME - A clock receiver in a semiconductor integrated circuit includes a first clock buffer configured to buffer an external clock to generate a low frequency buffered clock in response to a first operation signal; a second clock buffer configured to buffer the external clock to generate a high frequency buffered clock in response to a second operation signal; and an internal clock generating unit configured to receive the low frequency buffered clock and the high frequency buffered clock, to control states of the first operation signal and the second operation signal and to generate an internal clock. | 12-09-2010 |
20140062562 | CONSTRAINING CLOCK SKEW IN A RESONANT CLOCKED SYSTEM - An integrated circuit includes a plurality of resonant clock domains of a resonant clock network. Each resonant clock domain has at least one clock driver that supplies a portion of clock signal to an associated resonant clock domain. The resonant clock network operates in a resonant mode with inductors connected to pairs of resonant clock domains at boundaries between the resonant clock domains. Each inductor forms an LC circuit with clock load capacitance in the pair of resonant clock domains to which the inductor is connected. | 03-06-2014 |
20140062563 | CONTROLLING IMPEDANCE OF A SWITCH USING HIGH IMPEDANCE VOLTAGE SOURCES TO PROVIDE MORE EFFICIENT CLOCKING - A clock system of an integrated circuit includes first and second transistors forming a switch that is used when switching the clock system between a resonant mode of operation and a non-resonant mode of operation. An inductor forms a resonant circuit with capacitance of the clock system in resonant mode. The switch receives a clock signal and supplies the clock signal to the inductor when the switch is closed and disconnects the inductor from the clock system when the switch is open. First and second high impedance voltage sources supply respective first and second voltages to the switch and a gate voltage of the first transistor transitions with the clock signal around the first voltage and a gate voltage of the second transistor transitions with the clock signal around the second voltage such that near constant overdrive voltages are maintained for the first and second transistors. | 03-06-2014 |
20140062564 | PROGRAMMABLE CLOCK DRIVER - A clock driver circuit supplies a clock signal with a drive strength determined according to one or more control signals supplied to the clock driver that vary during run-time. The clock driver is operated with a first drive strength in a non-resonant mode of operation of an associated clock network and with a second drive strength in a resonant mode of operation of the associated clock network, the first drive strength being higher than the second drive strength. | 03-06-2014 |
20140062565 | CLOCK DRIVER FOR FREQUENCY-SCALABLE SYSTEMS - A clock driver for a resonant clock network includes a delay circuit that receives and supplies a delayed clock signal. A first transistor is coupled to receive a first pulse control signal and supply an output clock node of the clock driver. An asserted edge of the first control signal is responsive to the falling edge of the delayed clock signal. A second transistor is coupled to receive a second control signal and to supply the output clock node of the clock driver. An asserted edge of the second control signal is responsive to a rising edge of the delayed clock signal. | 03-06-2014 |
20140176216 | INTEGRATED CIRCUIT COMPRISING A CLOCK TREE CELL - The invention relates to an integrated circuit comprising:
| 06-26-2014 |
20150333741 | SEMICONDUCTOR DEVICE WITH CLOCK-BASED SIGNAL INPUT CIRCUIT - A semiconductor device includes a signal input circuit suitable for synchronizing an input signal with a clock signal and receiving the clock signal as a power source when the input signal has a first phase, where the signal input circuit amplifies a swing width of the input signal based on a swing width of the clock. | 11-19-2015 |
20150338877 | INTEGRATED CIRCUIT - An integrated circuit includes a main clock tree, a reference clock trunk, a reference clock buffer and a calibration circuit. The main clock tree transmits a main operation clock to an internal node via serially-coupled buffers to form a local clock at an internal node. The reference clock buffer transmits a main reference clock via the reference clock trunk to form a reference clock at a terminal node. The calibration circuit compares phases of the local clock and the reference clock to accordingly generate a control signal, so the main clock tree can adjust phase of the local clock according to the control signal. | 11-26-2015 |
20160065187 | MULTI-LEVEL PULSE GENERATOR CIRCUITRY - During operation, a supply voltage and the reference voltage power a novel multi-level pulse generator circuit. The multi-level pulse generator circuit generates voltage pulses of varying magnitude from a respective output port. For example, the multi-level pulse generator circuit produces respective pulses to have magnitudes that fall inside and outside of a range defined by the supply voltage and the reference voltage. Expansion of the pulse magnitudes to be outside of the range as defined by the supply voltage and the reference voltage increases noise immunity and therefore enables a respective transmitter to transmit data at higher bandwidth. The multi-level pulse generator circuit can be fabricated using a set of multiple transistors of only a single type in which each of the multiple transistors in the set has a corresponding oxide breakdown voltage that is substantially less than the respective magnitude that falls outside of the range. | 03-03-2016 |
20160091918 | CONFIGURABLE LAST LEVEL CLOCK DRIVER FOR IMPROVED ENERGY EFFICIENCY OF A RESONANT CLOCK - Systems and methods are directed to a configurable last level driver coupled to a inductor-capacitor (LC) tank or resonant clock, for improving energy efficiency of the resonant clock. In a warm up stage, the last level clock driver can be enabled to store energy in the LC tank, and in a gating stage, the last level clock driver can be fully or partially disabled such that energy stored in the LC tank can be recirculated into a clock distribution network. In a refreshing stage, the last level clock driver can be enabled to replenish the energy lost by the LC tank in the recirculation of energy into the clock distribution network during the gating stage. Programmable counters can be used to control durations of the warm up, gating, and refreshing stages. | 03-31-2016 |
20160132070 | OSCILLATOR CIRCUIT AND METHOD OF GENERATING A CLOCK SIGNAL - An oscillator circuit of the type comprising a flip-flop for generating a clock signal and two comparators for comparing a reference voltage with the voltage across a first capacitor which is charged during a first cycle of the clock signal and the voltage across a second capacitor which is charged during a second cycle of a clock signal provides a means for removing the effects of any offset in either comparator. This is achieved by reversing the inputs of the comparators for each cycle of the output frequency. Thus an offset in a comparator which would increase the clock period on one cycle will reduce the period of the next cycle by the same amount. As a net result, the period of time over two clock periods will stay constant regardless of any offset drift in a comparator. | 05-12-2016 |