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: 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 operate to receive the clock signal and control signals. An output port of the selective edge phase mixing unit may be used 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 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: One delay locked loop circuit embodiment includes a delay line system configured to generate a clock output signal by adding a delay line system time delay to a clock reference signal, a phase detector, a shift register, and a control unit. The delay line system includes a coarse delay line to adjust the delay line system time delay by remote coarse-shifting, a phase selector configured to adjust the delay line system time delay by local coarse-shifting output signals from a series of local coarse delay units, and a phase mixer to adjust a particular time delay of the clock output signal by fine-shifting. The phase mixer does not receive the clock reference signal. The phase detector detects a phase difference between the clock reference signal and the clock output signal. The shift register controls the remote coarse-shifting, and the control unit controls the local coarse-shifting, based on the phase difference.

Abstract: The disclosed embodiments of the present invention include a semiconductor memory apparatus having a selectable memory capacity. In one embodiment, a system includes input, output, and data storage devices, a processor coupled to the devices, a memory device coupled to the processor, and a configuration circuit interposed between the processor and the memory device to selectively couple lines in the address, control and data busses of the processor to lines in the address, control and data busses of the memory device. In another embodiment, a memory device includes an array coupleable to one or more busses of an external device and a configuration circuit between the array and the busses of the external device to selectively couple the busses to the memory cell array. In a particular embodiment, the configuration circuit includes one or more bi-stable relays, such as Micro-Electrical-Mechanical System (MEMS) relays.

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, 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: 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: 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: 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: One delay locked loop circuit embodiment includes a delay line system configured to generate a clock output signal by adding a delay line system time delay to a clock reference signal, a phase detector, a shift register, and a control unit. The delay line system includes a coarse delay line to adjust the delay line system time delay by remote coarse-shifting, a phase selector configured to adjust the delay line system time delay by local coarse-shifting output signals from a series of local coarse delay units, and a phase mixer to adjust a particular time delay of the clock output signal by fine-shifting. The phase mixer does not receive the clock reference signal. The phase detector detects a phase difference between the clock reference signal and the clock output signal. The shift register controls the remote coarse-shifting, and the control unit controls the local coarse-shifting, based on the phase difference.

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: Methods, circuits, devices, and systems are provided, including embodiments with local coarse delay units. One embodiment includes generating a first delayed signal, a second delayed signal, and a third delayed signal by delaying a clock reference signal with various time delays of a coarse delay line and local coarse delay units. This method embodiment also includes generating a clock output signal based on the first delayed signal, the second delayed signal, or the third delayed signal, depending on a phase difference between the clock reference signal and the clock output signal.

Abstract: Clock capturing synchronization circuitry first generates a synchronized clock signal from a reference clock signal, then captures the synchronized clock signal, and continues to output a synchronized clock signal after the reference clock signal is removed. The clock capturing synchronization circuitry also reduces input referred jitter in the synchronized clock signal.

Abstract: Clock capturing synchronization circuitry first generates a synchronized clock signal from a reference clock signal, then captures the synchronized clock signal, and continues to output a synchronized clock signal after the reference clock signal is removed. The clock capturing synchronization circuitry also reduces input referred jitter in the synchronized clock signal.

Abstract: Clock capturing synchronization circuitry first generates a synchronized clock signal from a reference clock signal, then captures the synchronized clock signal, and continues to output a synchronized clock signal after the reference clock signal is removed. The clock capturing synchronization circuitry also reduces input referred jitter in the synchronized clock signal.

Abstract: Methods and apparatuses for testing image sensors are disclosed. Desirable apparatuses of the present invention include image sensor testing devices comprising a digital light projection system capable of projecting static or dynamic images onto an image sensing device under test and an image sensor signal detection means for analyzing the output of said image sensing device under test. The digital light projection system comprises a light source, collimating optics, a digital micromirror device, and focusing optics. Other desirable methods and apparatuses of the present invention include image sensor testing devices employing a digital light projection system capable of simultaneously testing a plurality of image sensors. According to the present invention, the light source is calibrated and converted to a desired test image by the digital micromirror device. The test image is then focused onto an image sensor, the output of which is read by a detector and correlated with the input digital test image.

Abstract: The disclosed embodiments relate to circuits that produce synchronized output signals. More specifically, there is provided a synchronization circuit adapted to receive an input signal, the synchronization circuit comprising a delay monitor adapted to produce a delayed input signal, a counter adapted to determine a difference between the input signal and the delayed input signal and produce a coarse timing signal in response thereto, a circuit adapted to produce a fine timing signal based on the input signal, and a circuit adapted to combine the coarse timing signal and the fine timing signal to produce an output signal.