Patent application number | Description | Published |
20080204460 | DEVICE HAVING MULTIPLE GRAPHICS SUBSYSTEMS AND REDUCED POWER CONSUMPTION MODE, SOFTWARE AND METHODS - Many computing device may now include two or more graphics subsystems. The multiple graphics subsystems may have different abilities, and may, for example, consume differing amount of electrical power, with one subsystem consuming more average power than the others. The higher power consuming graphics subsystem may be coupled to the device and used instead of, or in addition to, the lower power consuming graphics subsystem, resulting in higher performance or additional capabilities, but increased overall power consumption. By transitioning from the use of the higher power consuming graphics subsystem to the lower power consuming graphics subsystem, while placing the higher power consuming graphics subsystem in a lower power consumption mode, overall power consumption is reduced. | 08-28-2008 |
20100293402 | DEVICE HAVING MULTIPLE GRAPHICS SUBSYSTEMS AND REDUCED POWER CONSUMPTION MODE, SOFTWARE AND METHODS - Many computing device may now include two or more graphics subsystems. The multiple graphics subsystems may have different abilities, and may, for example, consume differing amount of electrical power, with one subsystem consuming more average power than the others. The higher power consuming graphics subsystem may be coupled to the device and used instead of, or in addition to, the lower power consuming graphics subsystem, resulting in higher performance or additional capabilities, but increased overall power consumption. By transitioning from the use of the higher power consuming graphics subsystem to the lower power consuming graphics subsystem, while placing the higher power consuming graphics subsystem in a lower power consumption mode, overall power consumption is reduced. | 11-18-2010 |
20140103971 | METHODS AND APPARATUS FOR SOURCE-SYNCHRONOUS CIRCUITS - Source-synchronization between a source module and a responder module generally includes providing, at the source module, an initial determinism reconciliation signal, propagating the initial determinism reconciliation signal from the source module to the responder module and back to the source module to produce a received determinism reconciliation signal, and compensating for an intrinsic delay of the circuit based on the initial determinism reconciliation signal and the received determinism reconciliation signal. | 04-17-2014 |
20140126612 | ADAPTIVE CLOCK MISMATCH COMPENSATION SYMBOL INSERTION IN SIGNAL TRANSMISSIONS - A transmitting interconnect interface inserts clock mismatch compensation symbols into a transmitted data stream so as to allow the receiving interconnect interface to compensate for clock frequency mismatch between transmit-side and receive-side clocks. The transmitting interconnect interface adjusts the rate of insertion of these symbols based on a determination of the clock frequency mismatch. The transmitting interconnect interface can incrementally adjust the insertion rate to change substantially proportionally with changes in the clock frequency mismatch. Alternatively, the transmitting interconnect interface can set the insertion rate to one of two levels. By adapting the insertion rate to the current measured clock frequency mismatch, the bandwidth penalty incurred by transmitting clock mismatch compensation symbols in excess of that necessary to permit receiver clock tolerance compensation can be reduced, thereby permitting more transmit bandwidth to be used for transmitting data. | 05-08-2014 |
Patent application number | Description | Published |
20120110529 | CLOCK DOMAIN CROSSING BUFFER - Techniques are disclosed relating to detecting and minimizing timing problems created by clock domain crossing (CDC) in integrated circuits. In various embodiments, one or more timing parameters are associated with a path that crosses between clock domains in an integrated circuit, where the one or more timing parameters specify a propagation delay for the path. In one embodiment, the timing parameters may be distributed to different design stages using a configuration file. In some embodiments, the one or more parameters may be used in conjunction with an RTL model to simulate propagation of a data signal along the path. In some embodiments, the one or more parameters may be used in conjunction with a netlist to create a physical design for the integrated circuit, where the physical design includes a representation of the path that has the specified propagation delay. | 05-03-2012 |
20140062555 | PROPAGATION SIMULATION BUFFER - Techniques are disclosed relating to detecting and minimizing timing problems created by clock domain crossing (CDC) in integrated circuits. In various embodiments, one or more timing parameters are associated with a path that crosses between clock domains in an integrated circuit, where the one or more timing parameters specify a propagation delay for the path. In one embodiment, the timing parameters may be distributed to different design stages using a configuration file. In some embodiments, the one or more parameters may be used in conjunction with an RTL model to simulate propagation of a data signal along the path. In some embodiments, the one or more parameters may be used in conjunction with a netlist to create a physical design for the integrated circuit, where the physical design includes a representation of the path that has the specified propagation delay. | 03-06-2014 |
20140089541 | BUS PROTOCOL COMPATIBLE DEVICE AND METHOD THEREFOR - A bus protocol compatible device, includes a transmitter having a first mode for providing a reference clock signal to an output, and a second mode for providing a training sequence to the output, and a power state controller for placing the transmitter in the first mode for a first period of time in response to a change in a link state, and in the second mode after an expiration of the first period of time. | 03-27-2014 |
20150324318 | BUS PROTOCOL COMPATIBLE DEVICE AND METHOD THEREFOR - A bus protocol compatible device includes an encoder having an input for receiving a local clock signal, and an output, a multiplexer having a first input for receiving a reference clock signal, a second input coupled to said output of said encoder, a control input for receiving a select signal, and an output, and a driver having an input coupled to said output of said multiplexer, and an output for coupling to a bus protocol link. | 11-12-2015 |