Ahmad H Atriss

Bio: Ahmad H Atriss is an academic researcher from Motorola. The author has contributed to research in topics: Phase-locked loop & Synchronous circuit. The author has an hindex of 9, co-authored 15 publications receiving 405 citations. Previous affiliations of Ahmad H Atriss include Codex Corporation & Freescale Semiconductor.

Circuit and method of switching between redundant clocks for a phase lock loop

Abstract: A phase lock loop monitors the frequency of redundant input clock signals (REFCLK₁AND REFCLK₂) and switches back and forth therebetween should one or the other become invalid. Thus, the PLL may continue normal operation even with a failure of one input clock signal. If both the input clock signals fail, an internal reference signal (RC_CLK) maintains the PLL at a nominal operating frequency until one of the input clock signals is restored whereby the loop can quickly re-establish phase lock. To determined validity, the input clock signals are sampled and stored by the reference signal in a predetermined manner. The input clock signal is valid if the samples of the input clock signal each have the same logic state after the sampling period; otherwise, the input clock signal is invalid if the samples of the input clock signal have at least one different logic state after the sampling period.

Optimized reference voltage generation using switched capacitor scaling for data converters

Abstract: An algorithmic or cyclic data converter uses an RSD stage having a switched capacitor network for efficiently scaling at least one externally supplied reference voltage. A reference voltage is scaled by using capacitor ratios that also function to provide an output voltage used as a residue output of the RSD A/D converter. The residue is used to generate a bit value corresponding to the magnitude of the residue. Two RSD stages cycle back and forth generating a logic value each half clock cycle until the desired bit resolution is achieved. In one form, the RSD stage scales the externally supplied reference voltage only by factors of less than one. In another form, the RSD stage scales the reference voltage by any scaling factor. A reference voltage scaling circuit separate from the RSD stage is avoided.

Lock detection for a phase lock loop

Abstract: A phase lock loop monitors a first digital signal and generates a second digital signal operating substantially at frequency and in-phase with the first digital signal. The first and second digital signal are applied to a lock detection circuit for generating a first digital output signal having a first logic state from a mutually exclusive combination of the first and second digital signals. The first logic state of the first digital output signal is compared with a time slot window formed by a control signal for generating a true lock detection signal when the first logic state of the first digital output signal occurs within the time slot window and a false lock detection signal when the first logic state of the first digital output signal occurs outside the time slot window.

Phase lock detection in a phase lock loop

Abstract: A phase lock loop monitors a first digital signal and generates a second digital signal operating substantially at frequency and in-phase with the first digital signal. The first and second digital signals are applied to a lock detection circuit for providing a lock detection signal when the first and second digital input signals have a first logic state at a first transition of a control signal and a second logic state at a second transition of the control signal. One false lock triggers an out-of-phase status indicator. The lock detection signal must return to a valid state for a predetermined number of periods before the phase lock status indicates a valid lock condition. The first and second digital input signals may operate with a non-50% duty cycle.

Phase-lock-loop lock indicator circuit

Abstract: A PLL lock indicator circuit for indicating when a phase-lock-loop circuit is in lock includes a gate circuit coupled to the phase/frequency detector of the phase-lock-loop circuit for providing an output logic signal that is responsive to output logic signals from the phase/frequency detector being in a predetermined state. A counter circuit is enabled by the output logic signal of the gate circuit for providing an output logic signal when the counter circuit has reached a predetermined count. A latch circuit is responsive to the output logic signal of the counter circuit for providing a lock signal at an output terminal of the circuit, the lock signal being indicative of when the PLL circuit is in phase lock.

Method and apparatus for adaptively adjusting the timing offset between a clock signal and digital signals transmitted coincident with that clock signal, and memory device and system using same

Abstract: A method and circuit adaptively adjust the timing offset of a digital signal relative to a clock signal output coincident with that digital signal to enable a latch receiving the digital signal to store the digital signal responsive to the clock signal. The digital signal is applied to the latch, and stored in the latch responsive to the clock signal. The digital signal stored in the latch is evaluated to determine if the stored digital signal has an expected value. The timing offset of the digital signal is thereafter adjusted relative to the clock signal. and the digital signal is once again stored in the latch responsive to the clock signal at the new timing offset. A number of digital signals at respective timing offsets relative to the clock signal are stored and evaluated, and a final timing offset of the digital signal is selected from the ones of the timing offsets that cause the latch to store the digital signal having the expected value. The timing offset of the digital signal is thereafter adjusted to the selected final timing offset. A read synchronization circuit may adaptively adjust the timing offset of digital signals in this manner, and such a read synchronization circuit may be utilized in many types of integrated circuits, including packetized dynamic random access memories, memory systems including a memory controller and one or more such packetized dynamic random access memories, and in computer systems including a plurality of such packetized dynamic random access memories.

Multistandard video decoder and decompression system for processing encoded bit streams including a video formatter and methods relating thereto

Abstract: A pipeline video decoder and decompression system handles a plurality of separately encoded bit streams arranged as a single serial bit stream of digital bits and having separately encoded pairs of control codes and corresponding data carried in the serial bit stream. The pipeline system employs a plurality of interconnected stages to decode and decompress the single bit stream, including a start code detector. When in a search mode, the start code detector searches for a specific start code corresponding to one of multiple compression standards. The start code detector responding to the single serial bit stream generates control tokens and data tokens. A respective one of the tokens includes a plurality of data words. Each data word has an extension bit which indicates a presence of additional words therein. The data words are thereby unlimited in number. A token decode circuit positioned in certain of the stages recognizes certain of the tokens as control tokens pertinent to that stage and passes unrecognized control tokens to a succeeding stage. A reconfigurable decode and parser processing means positioned in certain of the stages is responsive to a recognized control token and reconfigures a particular stage to handle an identified data token. Methods relating to the decoder and decompression system include processing steps relating thereto.

Clock vernier adjustment

Abstract: A integrated circuit, such as a memory integrated circuit, includes a vernier clock adjustment circuit receiving an input clock signal and providing a rising-edge clock signal representing the input clock signal delayed by a rising-edge delay and providing a falling-edge clock signal representing the input clock signal delayed by a falling-edge delay. An edge triggered circuit receives data and the rising-edge and falling-edge clock signals, and stores data at the rising-edge of the rising-edge clock signal and at the falling-edge of the falling-edge clock signal. One form of the invention is a memory system having a memory controller coupled to memory modules through data and command busses. Each memory module includes the vernier clock adjustment circuitry.

Data pipeline system and data encoding method

Abstract: A pipeline video decoder and decompression system handles a plurality of separately encoded bit streams arranged as a single serial bit stream of digital bits and having separately encoded pairs of control codes and corresponding data carried in the serial bit stream. The pipeline system employs a plurality of interconnected stages to decode and decompress the single bit stream, including a start code detector. When in a search mode, the start code detector searches for a specific start code corresponding to one of multiple compression standards. The start code detector responding to the single serial bit stream generates control tokens and data tokens. A respective one of the tokens includes a plurality of data words. Each data word has an extension bit which indicates a presence of additional words therein. The data words are thereby unlimited in number. A token decode circuit positioned in certain of the stages recognizes certain of the tokens as control tokens pertinent to that stage and passes unrecognized control tokens to a succeeding stage. A reconfigurable decode and parser processing means positioned in certain of the stages is responsive to a recognized control token and reconfigures a particular stage to handle an identified data token. Methods relating to the decoder and decompression system include processing steps relating thereto

Method and apparatus for adaptively adjusting the timing of a clock signal used to latch digital signals, and memory device using same

Abstract: A system for adjusting the phase of an internal clock signal relative to an external clock signal in a packetized dynamic random access memory device. The system applies a plurality of initialization packets to the memory device that are captured in a shift register responsive to a transition of the internal clock signal. However, the phase of the internal clock signal is sequentially incremented after each initialization packet has been captured in the shift register. After a plurality of initialization packets have been captured, an evalution circuit identifies which phases of the internal clock signal clocked the shift register at the proper time to accurately capture each initialization packet. A single phase of the internal clock signal is then selected from within the range of internal clock signal phases that successfully captured initialization packets. This selected phase of the internal clock signal is used during normal operation of the memory device.