Abstract: A phase-detector circuit is disclosed. The phase-detector circuit comprises a plurality of phase comparators which detects a phase difference between receipt data and a clock signal of a plurality of clock signals having the same frequency and phase difference of a predetermined angle with each other, and generates and outputs signals for up/down signals for synchronizing a phase. The phase comparator generates and outputs a signal for the up/down signals having a pulse width including a detected phase-time difference and a predetermined delay time.

Abstract: A system for synchronizing a functional reset between first and second clock domains that operate on first and second clock signals, respectively. The system includes first, second and third synchronizer flip-flops that operate on the second clock signal. The first synchronizer flip-flop receives a functional reset signal generated by the first clock domain at its reset terminal and generates a low output signal. The low output signal causes the second synchronizer flip-flop and subsequently the third synchronizer flip-flop to generate low output signals at positive edges of the second clock signal. The low output signal generated by the third synchronizer flip-flop is used to reset the second clock domain.

Abstract: Methods, apparatus, and fabrication techniques relating to improved propagation of fuse data through an integrated circuit device during scan shift reset. In some embodiments, the methods comprise loading a first value of at least one fuse bit to an integrated circuit device, during a time period when a clock signal having a first frequency is provided to at least one component of the integrated circuit device; disabling a scan shift after the loading of the first value; inactivating the clock signal after the loading of the first value; propagating the first value of the at least one fuse bit to the at least one component of the integrated circuit device; and reactivating the clock signal after the propagation of the first value.

Abstract: A touch panel system includes a signal generator configured to generate a reference signal and one or more channels. Each of the channels comprises a sensing unit configured to sense a touch thereon to output a sensing signal indicative of the touch; and a delay unit configured to adjust the reference signal based on a delay compensation value to compensate delay of the reference signal caused by the difference of distance between the signal generator and the channel. Further, each of the channels comprises an operation unit configured to perform an operation on the sensing signal and the reference signal from the delay unit to produce an operation result representing difference between the sensing signal and the adjusted reference signal; and a controller configured to determine the delay compensation value of the delay unit in each channel based on the voltage signal from the operation unit.

Abstract: An electronic device has a power control module for causing selected functional blocks to run in a low power mode of operation, while leaving other functional blocks supplied continuously with power. A power mode control distribution network includes serially connected chains of buffers in a distribution tree for distributing power mode control signals received at a common input end to respective output ends which are connected to respective functional blocks. In the low power mode of operation the power control module causes power to be supplied continuously to output buffers at the output ends of the chains while causing power supplied to other buffers to be reduced or cut-off. The output buffers include feedback paths for causing the states of the output buffers prior to the low power mode of operation to latch during the low power mode of operation.

Abstract: Disclosed herein is a device comprising a first terminal for a first clock signal, a second terminal for a second clock signal substantially complementary to the first clock signal, a third terminal for a third clock signal, a fourth terminal for a fourth clock signal substantially complementary to the third clock signal, a first logic gate to produce a first intermediate signal, a second logic gate to produce a second intermediate signal, a first delay circuit to produce a third intermediate signal, and a second delay circuit to produce a fourth intermediate signal, and a first output circuit coupled to the first and second delay circuits to produce the third and fourth clock signals respectively at the third and fourth terminals.

Abstract: A signal generating apparatus, for generating a power-on-reset signal, including a bias circuit and a power-on-reset signal generating circuit is disclosed. The bias circuit is for generating an output bias voltage, and includes at least one bipolar junction transistor (BJT), wherein a base terminal of the BJT is coupled to a collector terminal of the BJT, and the output bias voltage is related to an emitter-to-base voltage of the BJT. The power-on-reset signal generating circuit is coupled to the bias circuit, and is for generating a duplicated voltage by duplicating the output bias voltage, wherein the power-on-reset signal is generated according to the duplicated voltage.

Abstract: A clock synchronization circuit includes a delay-locked loop (DLL) and a delay-locked control unit. The DLL is configured to generate an output clock signal by delaying an input clock signal by a delay time, and to execute a delay-locking operation in which the delay time is adjusted to a locked state according to a comparison between the output clock signal and the input clock signal.

Abstract: A semiconductor device having a power tracking circuit configured for activating a power tracking signal for a period corresponding to a period during which an external voltage retains a level lower than a level of a low power mode reference voltage if the external voltage retains the level lower than the level of the low power mode reference voltage for at least a preselected time.

Abstract: Embodiments relate to fault detection comparator circuitry and methods that can operate in conjunction with a power-on-reset (POR) scheme to put a chip into a reliable power-down mode upon fault detection to avoid disrupting the communication bus link such that other connected chips and the host can continue to operate. Power-on of the affected chip can then be carried out when the connection with that chip is restored.

Abstract: Methods, apparatus, and fabrication techniques relating to improved propagation of fuse data through an integrated circuit device during scan shift reset. In some embodiments, the methods comprise loading a first value of at least one fuse bit to an integrated circuit device, during a time period when a clock signal having a first frequency is provided to at least one component of the integrated circuit device; disabling a scan shift after the loading of the first value; inactivating the clock signal after the loading of the first value; propagating the first value of the at least one fuse bit to the at least one component of the integrated circuit device; and reactivating the clock signal after the propagation of the first value.

Abstract: A multi-phase clock generation circuit includes a first clock buffer unit configured to invert and buffer a first internal clock and a second internal clock in response to an external clock, and to generate a third internal clock and a fourth internal clock, and a second clock buffer unit configured to invert and buffer the third internal clock and the fourth internal clock in response to the external clock, and to generate the first internal clock and the second internal clock.

Abstract: An electronic circuit comprises a reset input for receiving an input reset signal, a clock input for receiving a clock signal, and a reset output for providing an output reset signal. And it comprises a synchronous reset signal path comprising a synchronization unit, arranged to receive the input reset signal and provide the input reset signal synchronized with the clock signal to the reset output when the clock signal is available, and an asynchronous reset signal path arranged to provide the input reset signal to the reset output when a current clock availability information in a clock monitoring signal indicates that the clock signal is not available.

Abstract: A semiconductor device includes a division unit configured to divide an oscillation signal and to generate a plurality of divided signals having different division ratios each other, a delay amount determination unit configured to combine an source signal, the oscillation signal, and the plurality of divided signals and to generate a delay amount information signal with information on a given delay amount, and an edge-delayed signal output unit configured to generate at least one edge-delayed signal corresponding to the given delay amount in response to the source signal and the delay amount information signal.

Abstract: An apparatus includes a processor and a device. The processor generates an output signal and a control signal. The device consumes power while operating in first and second states. The device consumes less power while in the first state than while in the second state. The processor: accounts for a transition time for the device to transition among a powered off state, the first state, and the second state; and generates the control signal based on the transition time. The device: in response to the control signal, transitions to the second state at a speed of periodicity of a periodic signal of the processor; subsequent to the transitioning to the second state, performs a function based on the output signal; and subsequent to performing the function, transitions from the second state to either the first state or the powered off state.

Abstract: Embodiments of a logic path are disclosed that may allow for a reduction in switching power. The logic path may include a storage circuit, a comparison circuit, and a clock gating circuit. The storage circuit may be configured to store received data responsive to a local clock signal. The comparison circuit may be operable to compare the received data to data previously stored in the storage circuit. The clock gating circuit may be configured to generate the local clock signal dependent on a global clock signal, and de-activate the local clock signal dependent upon the results of the comparison performed by the comparison circuit.

Abstract: A clock generation system for an integrated circuit (IC) chip (e.g., a microcontroller) is disclosed that allows digital blocks and other components in the IC chip to start and stop internal clocks dynamically on demand to reduce power consumption.

Abstract: There is provided an integrated circuit having a plurality of circuit blocks. An acquisition unit acquires a request of a reset operation for at least one of the plurality of circuit blocks. A determination unit determines, based on constraining condition information indicating whether or not a reset target circuit block can perform the reset operation simultaneously with another circuit block in which the reset operation is underway, whether or not to instruct the reset target circuit block to perform the reset operation according to the request. An instruction unit instructs the reset target circuit block to start the reset operation according to the request when the determination unit determines to instruct the reset target circuit block to perform the reset operation.

Abstract: A semiconductor device includes a voltage detection circuit suitable for detecting an external power supply voltage and for sequentially activating first and second power-up signals in a power-up period of the external power supply voltage, and a control circuit suitable for activating at least one first control signal for controlling an internal voltage to be generated based on the first power-up signal, and for activating at least one second control signal for controlling an operation of an internal circuit using the internal voltage when a predetermined time lapses after the first control signal is activated, based on the second power-up signal.

Abstract: A semiconductor device includes a clock supply circuit configured to generate an internal clock by using an external clock, an internal circuit configured to operate in synchronization with the internal clock and enter a power-down mode in response to a power-down signal, and a controller configured to control an entry of the clock supply circuit into the power-down mode in response to a locking signal, which represents that the clock supply circuit has been locked, and the power-down signal.

Abstract: A power-on-detection (POD) circuit includes first and second comparators, a voltage divider, a detection circuit coupled to a first voltage source node and the voltage divider, and logic circuitry coupled to outputs of the first and second comparators. The detection circuit outputs a control signal identifying if a first voltage source node has a voltage potential that is higher than ground. The control signal turns on and off the first and second comparators, which are respectively coupled to first and second nodes of the voltage divider and to a reference voltage node. The logic circuitry outputs a power identification signal based on the signals received from the outputs of the first and second comparators.

Abstract: Apparatuses, circuits, methods, and other embodiments associated with digital power on reset are described. In one embodiment, an apparatus includes a digital electronic component configured to produce a clock signal. A first counter is configured to output a first count signal based on the clock signal and a second counter is configured to output a second count signal based on the clock signal. A power on reset logic is configured to provide a power on reset signal based on the first count signal and the second count signal, where the power on reset logic is configured to disable the digital electronic component after providing the power on reset signal to prevent the digital electronic component from drawing power.

Abstract: One embodiment relates to an integrated circuit having a plurality of four-channel serial interface modules. Each of the plurality of four-channel serial interface modules includes a first physical medium attachment (PMA) channel circuit, a second PMA channel circuit adjacent to the first PMA channel circuit, a third PMA channel circuit adjacent to the second PMA channel circuit, a fourth PMA channel circuit adjacent to the third PMA channel circuit, and at least one phase-locked loop (PLL) circuit which is programmably coupled to each of the first, second, third and fourth PMA channel circuits. Other embodiments and features are also disclosed.

Abstract: A delay locked loop includes initialization circuitry that ensures that a DLL is initialized to an operating point that is not to close to either end of a delay vs. control voltage characteristic. The initialization circuitry forces the DLL to initially search for a lock point starting from an initial delay, the delay is varied in one direction, forcing the DLL to skip the first lock point. The initialization circuitry only allows the DLL to vary the delay of the voltage controlled delay loop in the one direction from the initial delay until the operating point is reached.

Abstract: A motherboard includes a motherboard power supply connector and a time delay circuit. The motherboard power supply connector connects a power supply unit. The motherboard power supply connector has a power supply on pin and a power good pin. The power good pin is configured for receiving a power good signal from the power supply unit. The time delay circuit has an input terminal and an output terminal. The input terminal is configured for receiving a power supply on signal. The output terminal is connected to the power supply on pin and is configured for sending the power supply on signal to the power supply on pin after a time delay determined by the time delay circuit.

Abstract: Some of the embodiments of the present disclosure provide a integrated circuit comprising a plurality of components, wherein each of the plurality of components is configured to receive a clock signal and a reset signal; a clock module configured to selectively suppress the clock signal; and a reset module configured to assert the reset signal while the clock signal is suppressed. Other embodiments are also described and claimed.

Abstract: Circuits, integrated circuits, and methods are disclosed for bimodal disable circuits. In one such example method, a counter is maintained, with the counter indicating a logic level at which an output signal will be disabled during at least a portion of one of a plurality of disable cycles. The logic level indicated by the counter is transitioned. An input signal is provided as the output signal responsive to the enable signal indicating that the output signal is to be enabled, and the output signal is disabled at the logic level indicated by the counter responsive to the enable signal indicating that the output signal is to be disabled.

Abstract: A semiconductor device including a power-on-reset (POR) circuit. The semiconductor device includes a driving voltage generator configured to generate a first voltage that rises at a first slope and subsequently rises at a second slope greater than the first slope and a first POR signal generator configured to receive the first voltage and generate a first POR signal having a first ramp-up time.

Abstract: The power-on reset circuit includes: a NMOS transistor having a source connected to a second power supply terminal and a gate connected to a drain thereof; a depletion-type NMOS transistor having a source connected to the drain of the NMOS transistor, a drain connected to a first power supply terminal and a gate connected to the second power supply terminal; a PMOS transistor having a source connected to the first power supply terminal, a gate connected to the drain of the NMOS transistor and a drain; a capacitor having one end connected to the drain of the PMOS transistor and the other end connected to the second power supply terminal; and a waveform shaping circuit having an input terminal connected to the drain of the PMOS transistor and an output terminal from which a power-on reset signal is output.

Abstract: A reset circuit and a reset method of a portable terminal are provided. The reset circuit of a portable terminal includes an input unit for generating a certain input signal for reset according to a user input, a reset unit for generating a manual reset input signal according to an input of the certain input signal, for performing a control operation to cut-off power to be supplied to a Power Management IC (PMIC) using a signal generated during an operation maintenance time interval of the portable terminal and the manual reset input signal, and for performing a control operation to resupply the power to the PMIC according to an input signal from the input unit or completion of a preset timer, and a power supply unit for supplying the power.

Abstract: A clock divider may provide a lower speed clock to a logic block portion, but during reset, the clock divider may not operate properly, causing the logic block portion to be reset at a clock frequency greater than the frequency for which that logic was designed. However, an extended reset may be employed in which the clock divider is reset normally first before the logic block portion, allowing that logic to be reset according to the divided clock (e.g., rather than a higher speed clock). An asynchronous reset may also be employed in which one or more clock dividers first emerge from reset before being provided with a (synchronized) high speed clock signal, causing the clock dividers to be in phase with each other. This may enable communication between different areas of an IC that might not otherwise be in proper phase with each other.

Abstract: A clock divider may provide a lower speed clock to a logic block portion, but during reset, the clock divider may not operate properly, causing the logic block portion to be reset at a clock frequency greater than the frequency for which that logic was designed. However, an extended reset may be employed in which the clock divider is reset normally first before the logic block portion, allowing that logic to be reset according to the divided clock (e.g., rather than a higher speed clock). An asynchronous reset may also be employed in which one or more clock dividers first emerge from reset before being provided with a (synchronized) high speed clock signal, causing the clock dividers to be in phase with each other. This may enable communication between different areas of an IC that might not otherwise be in proper phase with each other.

Abstract: Disclosed herein is a device comprising a first terminal for a first clock signal, a second terminal for a second clock signal substantially complementary to the first clock signal, a third terminal for a third clock signal, a fourth terminal for a fourth clock signal substantially complementary to the third clock signal, a first logic gate to produce a first intermediate signal, a second logic gate to produce a second intermediate signal, a first delay circuit to produce a third intermediate signal, and a second delay circuit to produce a fourth intermediate signal, and a first output circuit coupled to the first and second delay circuits to produce the third and fourth clock signals respectively at the third and fourth terminals.

Abstract: A phase-frequency detector (PFD) circuit is disclosed. The PFD circuit includes a PFD portion adapted to detect frequency and phase difference of two input signals and to generate control signals according to the detected frequency and phase difference and a delay and reset portion adapted to delay the generated control signals, to generate reset signals for resetting the PFD portion based on a combination of the control signals and the delayed control signals, and to provide the generated reset signals to the PFD portion.

Abstract: An input receiver includes a first input receiving unit, a second input receiving unit, a delay unit, and a first logic unit. The first input receiving unit receives an inverse wake-up signal, an external clock enable signal, a first voltage, and a reference signal, and then generates a first enable signal according to the external clock enable signal and the reference signal. The second input receiving unit receives the external clock enable signal, the first voltage, and an inverse enable voltage, and then generates a second enable signal as its output according to the external clock enable signal. The delay unit generates a wake-up signal according to the second enable signal. The first logic unit receives the wake-up signal and the first enable signal, and then generates an internal clock enable signal according to the wake-up signal and the first enable signal.

Abstract: A reset signal generation apparatus includes a reset signal generation unit and a reset signal expansion unit. The reset signal generation unit enables a reset signal and an enable signal in response to a reset input signal, and disables the reset signal in response to a pulse width extension signal. The reset signal expansion unit generates the pulse width extension signal that is enabled for a predetermined time, in response to the enable signal.

Abstract: A method for synchronizing an output clock signal with an input clock signal in a delay locked loop. A first count values decreasing the number of bypassed elements in a differential delay line until an edge of the output clock signal is delayed relative to an edge of the input clock signal or the first count value reaches a first count final value if the first count value reaches the first count final value, a second count value is adjusting to decrease the number of bypassed elements in a single-ended delay line until the edge of the output clock signal is delayed relative to the edge of the input clock signal. A third count value is adjusted to decrease the delay of an interpolator until the edge of the output clock signal is no longer delayed with respect to the edge of the input clock signal.

Abstract: A time sequencing circuit for a power supply unit to ensure the correct sequencing of system voltages for a computer from a power supply unit includes first to ninth resistors, first to fifth electronic switches, and a capacitor. Each of the first to fifth electronic switches includes first to third terminals. When the power supply unit outputs all required voltages, the power supply unit outputs a high-voltage level indicating power good and the computer can start up. If any one of the required voltages is not being outputted, the power supply unit outputs a low-voltage level good signal until any non-output of voltage is cured.

Abstract: A semiconductor device includes a delay locked loop (DLL) configured to generate a DLL clock signal by delaying a reference clock signal in response to a second delay amount tracked using a first delay amount as an initial delay amount, and track the second delay amount again by adjusting the first delay amount in response to a reset signal, and a DLL controller configured to activate the reset signal when the second delay amount deviates from a given range.

Abstract: A signal input circuit and method and chip are disclosed. The signal input circuit includes a control signal input terminal configured for receiving a control signal; at least one common signal input terminal each configured for receiving a corresponding common signal; at least one first signal output terminal each configured for outputting a corresponding first signal; at least one first signal unit each configured for receiving said corresponding common signal and outputting said corresponding common signal as said corresponding first signal under control of said control signal; at least one second signal output terminal each configured for outputting a corresponding second signal; and at least one second signal unit each configured for receiving said corresponding common signal and outputting said corresponding common signal as said corresponding second signal under control of said control signal.

Abstract: A reset circuit is connected to a processor chip to reset the processor chip. The reset circuit includes a control unit, a standby power, and a voltage converting unit. The standby power provides power to the control unit. The control unit receives external control signals and outputs an enable signal in responds to the external control signal. The voltage converting unit converts an external voltage into a work voltage and generates a reset signal in responds to the enable signal. The voltage converting unit provides the work voltage to the processor chip and transmits the enable signal to control the processor chip to reset.

Abstract: Disclosed herein are a power on reset device capable of performing a precise brown out detection (BOD) function and a power on reset method using the same. The power on reset device may include a delay signal generating unit, a reference voltage generating unit, and a reset signal generating comparing a delay signal with a reference voltage to generate a reset signal.

Abstract: A multi-phase clock generation circuit includes a first clock buffer unit configured to invert and buffer a first internal clock and a second internal clock in response to an external clock, and to generate a third internal clock and a fourth internal clock, and a second clock buffer unit configured to invert and buffer the third internal clock and the fourth internal clock in response to the external clock, and to generate the first internal clock and the second internal clock.

Abstract: The disclosed power-on reset circuit provides an indication of when and whether a supply voltage Vdd has reached a trigger voltage level Vtrig. The disclosed circuit includes a flip-flop circuit and a first comparator circuit. The circuit according to the invention has a D input node of the flip-flop circuit coupled to the supply voltage. The first comparator circuit outputs a clock signal, where the flip-flop circuit is clocked by the clock signal. A Q output node of the flip-flop circuit provides the power-on reset signal, where the power-on reset signal is in a LO state when the supply voltage is at a voltage level that is less than the trigger voltage level Vtrig. The power-on reset signal is in a HI state when the supply voltage is at a voltage level that is greater than the trigger voltage level Vtrig.

Abstract: A circuit receives a parameter signal at a set or reset input, a clock signal at a clock input and a constant digital value at a data input. A synchronous signal is output from the circuit: wherein when the parameter signal is in a first state, then the output synchronous signal has the digital value; wherein when the parameter signal transitions to a second state, then the output synchronous signal transitions to an inverse of the digital value at substantially the same time; and wherein when the parameter signal transitions back to the first state, then the output synchronous signal transitions to the digital value on a next clock edge.

Abstract: A power switch module for an electronic device includes a flip-flop circuit, a first current path for coupling a voltage source to the flip-flop circuit, and a second current path for coupling the voltage source to the flip-flop circuit. In response to a user power-on event, an output of the flip-flop circuit is at a first logic state for normally powering on the electronic device. In response to a user power-off event, the output of the flip-flop circuit is at a second logic state for normally powering off the electronic device. When the voltage source is suddenly interrupted, the output of the flip-flop circuit is kept at the first logic state but the electronic device is abnormally powered off. After the voltage source is resumed, the output of the flip-flop circuit kept at the first logic state reboots the abnormally powered-off electronic device.

Abstract: In an embodiment, the present invention includes a latch circuit having a first input to receive a data signal and a second input to receive a clock signal. This latch circuit may have a first pair of transistors including a first transistor gated by the data signal and a second transistor gated by an inverted data signal and a second pair of transistors including third and fourth transistors gated by the clock signal. The first transistor may be coupled to the third transistor at a first inter-latch node and the second transistor coupled to the fourth transistor at a second inter-latch node. A reset circuit may be coupled to the latch circuit to maintain the first and second inter-latch nodes at a predetermined voltage level when the clock signal is inactive.

Abstract: One or more techniques and systems for starting an output driver and an associated start-up circuit are provided herein. In some embodiments, a voltage provider is configured to charge a charge store to a pre-turn-on voltage. In some embodiments, an output driver is configured to control a connection between the charge store and the output driver. For example, the connection enables the charge store to discharge a voltage to the output driver, thus starting the output driver. Accordingly, a response time associated with starting the output driver is mitigated at least because the charge store is charged to the pre-turn-on voltage and connected to the output driver such that a gate of the driver is biased in a sudden fashion. In this manner, the driver is turned on more quickly. Additionally, effects associated with process, voltage, and temperature variations are mitigated, for example.

Abstract: An electronic circuit of the present disclosure includes a noise eliminating circuit configured to eliminate noise in a reset signal and output a signal obtained by eliminating the noise in the reset signal; a digital circuit configured to be reset by the signal outputted from the noise eliminating circuit; and an early-initialization circuit configured to fix an output signal of the digital circuit at a predetermined value until a reset status due to the reset signal is released.

Abstract: An integrated circuit including a degradation monitoring circuit. The degradation monitoring circuit includes a comparison circuit having a delay element including an input coupled to a data node of a timing path and having an output to provide a delayed signal of a data signal of the data node. The comparison circuit includes a logic comparator that provides a logic comparison between a data signal of the data node and the output of the delay element. The monitoring circuit includes a sampling circuit that provides a sampled signal of the output of the logic comparator that is a sampled with respect to a clock signal of the clock signal line. The monitoring circuit includes a hold circuit that provides a signal indicative of a data signal of the data node transitioning within a predetermined time of an edge transition of a clock signal of the clock signal line.