Abstract: Circuits, apparatuses, and methods are disclosed for delay models. In one such example circuit, a first delay model circuit is configured to provide a first output signal by modeling a delay of a signal through a path. A second delay model circuit is configured to provide a second output signal by modeling the delay of the signal through the path. A compare circuit is coupled to the first and second delay model circuits. The compare circuit is configured to compare a third signal from the first delay model circuit and a fourth signal from the second delay model circuit, and, in response provide an adjustment signal to adjust the delay of the second delay model circuit.

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: Apparatus, systems, and methods are disclosed that operate to generate a clock signal in a die in a stack and to receive the clock signal in another die in the stack. Additional apparatus, systems, and methods are disclosed.

Abstract: A method and apparatus is provided for controlling a delay line for achieving power reduction. The device comprises a delay lock loop to provide an output signal based upon a phase difference between a reference signal and a feedback signal, said delay lock loop comprising at least one delay circuit comprising a plurality of logic gates configured to provide for substantially uniform degradation of a plurality of NAND gates in a static state.

Abstract: Circuits, apparatuses, and methods are disclosed for delay models. In one such example circuit, a first delay model circuit is configured to provide a first output signal by modeling a delay of a signal through a path. A second delay model circuit is configured to provide a second output signal by modeling the delay of the signal through the path. A compare circuit is coupled to the first and second delay model circuits. The compare circuit is configured to compare a third signal from the first delay model circuit and a fourth signal from the second delay model circuit, and, in response provide an adjustment signal to adjust the delay of the second delay model circuit.

Abstract: Locked loops, delay lines, delay circuits, and methods for delaying signals are disclosed. An example delay circuit includes a delay line including a plurality of delay stages, each delay stage having an input and further having a single inverting delay device, and also includes a two-phase exit tree coupled to the delay line and configured to provide first and second output clock signals responsive to clock signals from inputs of the delay stages of the plurality of delay stages. Another example delay circuit includes a delay line configured to provide a plurality of delayed clock signals, each of the delayed clock signals having a delay relative to a previous delayed clock signal equal to a delay of a single inverting delay device. The example delay circuit also includes a two-phase exit tree configured to provide first and second output clock signals responsive to the delayed clock signals.

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: Apparatus, systems, and methods are disclosed that operate to generate a clock signal in a die in a stack and to receive the clock signal in another die in the stack. Additional apparatus, systems, and methods are disclosed.

Abstract: Locked loops, delay lines, delay circuits, and methods for delaying signals are disclosed. An example delay circuit includes a delay line including a plurality of delay stages, each delay stage having an input and further having a single inverting delay device, and also includes a two-phase exit tree coupled to the delay line and configured to provide first and second output clock signals responsive to clock signals from inputs of the delay stages of the plurality of delay stages. Another example delay circuit includes a delay line configured to provide a plurality of delayed clock signals, each of the delayed clock signals having a delay relative to a previous delayed clock signal equal to a delay of a single inverting delay device. The example delay circuit also includes a two-phase exit tree configured to provide first and second output clock signals responsive to the delayed clock signals.

Abstract: A method and apparatus is provided for controlling a delay line for achieving power reduction. The device comprises a delay lock loop to provide an output signal based upon a phase difference between a reference signal and a feedback signal, said delay lock loop comprising at least one delay circuit comprising a plurality of logic gates configured to provide for substantially uniform degradation of a plurality of NAND gates in a static state.

Abstract: Circuits, apparatuses, and methods are disclosed for frequency division. In one such example circuit, a frequency divider is configured to alternate between providing a common frequency clock signal as an output clock signal through a first circuit responsive to a reference clock signal and providing a reduced frequency clock signal as the output clock signal through a second circuit responsive to the reference clock signal. The first and second circuits share a shared circuit through which the output clock signal is provided. An enable circuit is configured to cause the frequency divider to alternate between providing the common frequency clock signal as the output clock signal through the first circuit and the reduced frequency clock signal as the output clock signal through the second circuit.

Abstract: A phase recombination circuit includes a first phase input and a first one-shot pulse generator adapted to receive the first phase input and produce a first signal to pull a signal to a first state. The phase recombination circuit also includes a second phase input in phase relationship with the first phase input, and a second one-shot pulse generator adapted to receive the second phase input and produce a second signal to pull a signal to a second state.

Abstract: Locked loops, delay lines, delay circuits, and methods for delaying signals are disclosed. An example delay circuit includes a delay line including a plurality of delay stages, each delay stage having an input and further having a single inverting delay device, and also includes a two-phase exit tree coupled to the delay line and configured to provide first and second output clock signals responsive to clock signals from inputs of the delay stages of the plurality of delay stages. Another example delay circuit includes a delay line configured to provide a plurality of delayed clock signals, each of the delayed clock signals having a delay relative to a previous delayed clock signal equal to a delay of a single inverting delay device. The example delay circuit also includes a two-phase exit tree configured to provide first and second output clock signals responsive to the delayed clock signals.

Abstract: A method and apparatus is provided for controlling a delay line for achieving power reduction. The device comprises a delay lock loop to provide an output signal based upon a phase difference between a reference signal and a feedback signal, said delay lock loop comprising at least one delay circuit comprising a plurality of logic gates configured to provide for substantially uniform degradation of a plurality of NAND gates in a static state.

Abstract: Apparatus, systems, and methods are disclosed that operate to generate a clock signal in a die in a stack and to receive the clock signal in another die in the stack. Additional apparatus, systems, and methods are disclosed.

Abstract: Electronic apparatus, systems, and methods to implement selective edge phase mixing are disclosed. A selective edge phase mixing system includes a processor and memory device configured to perform operations in synchronization with transitions of an externally provided clock signal. A selective edge phase mixing unit for the memory device may include a first logic gate that receives the clock signal at an input port and receives first control signals, and pull-up circuits in communication with an output of the first logic gate and first control signals. A second logic gate receives the clock signal at the input port and receives second control signals. Pull-down circuits are coupled to the second logic gate and the second control signals, wherein the pull-up circuits and the pull-down circuits are coupled to the output port to provide a duty cycle corrected clock signal to the memory device. Additional apparatus, systems, and methods are disclosed.

Abstract: Apparatus for synchronizing signals. For memory devices, such as SDRAMs, implementing a synchronization device to synchronize one signal, such as an external clock signal with a second signal, such as a data signal, tuning elements may be provided at various points in the signal path of the synchronization device. The tuning elements are designed to be identical, such that a single design may be used to a signal mismatch that is produced in either direction, using a single design. The tuning elements may be implemented to provide uniformity in the access time through a range of conditions, such as drain voltages and temperatures.

Abstract: A method and apparatus is provided for controlling a delay line for achieving power reduction. The device comprises a delay lock loop to provide an output signal based upon a phase difference between a reference signal and a feedback signal, said delay lock loop comprising at least one delay circuit comprising a plurality of logic gates configured to provide for substantially uniform degradation of a plurality of NAND gates in a static state.

Abstract: Electronic apparatus, systems, and methods to implement selective edge phase mixing are disclosed. A selective edge phase mixing system includes a processor and memory device configured to perform operations in synchronization with transitions of an externally provided clock signal. A selective edge phase mixing unit for the memory device may include a first logic gate that receives the clock signal at an input port and receives first control signals, and pull-up circuits in communication with an output of the first logic gate and first control signals. A second logic gate receives the clock signal at the input port and receives second control signals. Pull-down circuits are coupled to the second logic gate and the second control signals, wherein the pull-up circuits and the pull-down circuits are coupled to the output port to provide a duty cycle corrected clock signal to the memory device. Additional apparatus, systems, and methods are disclosed.

Abstract: Apparatus for synchronizing signals. For memory devices, such as SDRAMs, implementing a synchronization device to synchronize one signal, such as an external clock signal with a second signal, such as a data signal, tuning elements may be provided at various points in the signal path of the synchronization device. The tuning elements are designed to be identical, such that a single design may be used to a signal mismatch that is produced in either direction, using a single design. The tuning elements may be implemented to provide uniformity in the access time through a range of conditions, such as drain voltages and temperatures.