Abstract: System and method for reducing voltage fluctuations in an integrated circuit with multiple power domains and sub-domains. A preferred embodiment comprises a plurality of voltage sources and a switching network (such as switching network 320) wherein outputs from the plurality of voltage sources are inputs. The switching network can couple the outputs of voltage sources (based on a mapping) with the same output voltage levels to reduce voltage fluctuation amongst power domains coupled to the coupled outputs. The coupling may be performed by a switching structure (such as the switching structure 215) that can controllably electrically couple two outputs.

Abstract: In a method and system for data retention, a data input is latched by a first latch. A second latch coupled to the first latch receives the data input for retention while the first latch is inoperative in a standby power mode. The first latch receives power from a first power line that is switched off during the standby power mode. The second latch receives power from a second power line. A controller receives a clock input and a retention signal and provides a clock output to the first latch and the second latch. A change in the retention signal is indicative of a transition to the standby power mode. The controller continues to hold the clock output at a predefined voltage level and the second latch continues to receive power from the second power line in the standby power mode, thereby retaining the data input.

Abstract: State retention registers for use in low-power standby modes of digital IC operation are provided, wherein: a differential circuit (M1?M3; M1?M4) is used to load the shadow latch from the normal functional latch; the signal (REST, RESTZ) used to restore data from the shadow latch to the normal functional latch is a “don't care” signal while the shadow latch is retaining the data during low-power standby mode; retained data from the shadow latch is restored to the normal functional latch via a transistor gate connected to a node (N10) of the shadow latch where the retained data is provided; a power supply (VDD) other than the shadow latch's power supply (VRETAIN) powers the data restore operation; and the normal functional latch is operable independently of the operational states of the high Vt transistors (M1, M2, M5 and M6; M3, M4, M5 and M6) used to implement the state retention functionality.

Abstract: System and method for detecting transistor failure in large-scale integrated circuits by measuring IDDQ. A preferred embodiment comprises a switch structure for an integrated circuit made up of a plurality of main switches (such as main switch 410) selectively coupling a power sub-domain to a power source pin, a plurality of pi-switches (such as pi-switch 415) selectively coupling pairs of power sub-domains, and a plurality of IDDQ switches (such as IDDQ switch 425) selectively coupling the power sub-domains to a VIDDQ pin. The pi-switches can decouple the power sub-domains while the IDDQ switches can enable the measurement of the quiescent current in the power sub-domains. The use of pi-switches and IDDQ switches can permit the measurement of the quiescent current in the power sub-domains without requiring the use of isolation buffers and needed to powering on and off the integrated circuit between current measurements in the different power sub-domains.

Abstract: determining piece-wise polynomials which together would represent large data sets having multi-dimensional input vectors and corresponding output element. In an embodiment, a function/procedure/routine is recursively called/invoked to determine piece-wise polynomial is a data set cannot be entirely modeled by one polynomial. Another aspect of the present invention reduces the number of combinations (of orders for sub-polynomials forming the polynomials) to be tried in determining polynomials, meeting various accuracy requirements. Such a reduction is obtained based on a recognition that when the order in one dimension alone is increased and the result does not lead to acceptable accuracy of the polynomial, the combinations with a lesser number for the order (of the dimension) can be ruled out.

Abstract: An electronic system. The system comprises a plurality of circuit paths. Each path in the plurality of circuit paths is coupled to receive a system voltage from a voltage supply. The system further comprises a first circuit for providing a first value indicating a potential capability of operational speed of at least one path in the plurality of paths and a second circuit for providing a second value for indicating a potential capability of operational speed of the at least one path in the plurality of paths. The system further comprises circuitry for adjusting the system voltage, as provided by the voltage supply, in response to a relation between the first value and the second value.

Abstract: Methods and apparatus to bias a backgate of a power switch while preventing latchup are disclosed. A disclosed method of biasing a backgate of a power switch comprises: if a voltage of a first power supply rises before a voltage of a second power supply, initially biasing the backgate with a voltage based on the first power supply; and if the voltage of the first power supply rises after the voltage of the second power supply, biasing the backgate with a voltage based on the second power supply.

Abstract: System and method for reducing power-on transient current magnitude on distributed header switches. A preferred embodiment comprises a distributed header switch coupling a circuit to a power supply, the distributed header switch comprising a linear sequence of combination switches, each combination switches containing a pre-charge switch and a header switch. A first-pass involves sequentially turning on each of the pre-charge switches, which enables a voltage level at the distributed header switch to approach that of a final voltage level and a second-pass involves sequentially turning on each of the header switches. Since the voltage level at the distributed header switches is close to the final voltage level, a resulting transient current is small in magnitude.

Abstract: System and method for providing power with a large on-current and small off-current to circuitry in an integrated circuit. A preferred embodiment comprises a switch for providing power to circuits in an integrated circuit made from a PMOS transistor and an NMOS transistor coupled in parallel. Each transistor's gate terminal is coupled to a separate control signal line. The PMOS transistor provides current to the circuits at high voltage supply levels while the NMOS transistor provides current to the circuits at low voltage supply levels, wherein the size of the PMOS and NMOS transistor can be changed during design to meet power requirements. Depending upon power requirements, multiple PMOS and NMOS transistors may be used. The combination of PMOS and NMOS transistors permit the use of limited fabrication processes wherein transistor widths can be limited.

Abstract: System and method for providing power to circuitry while avoiding a large transient current. A preferred embodiment comprises a distributed switch (such as switch arrangement 400) with a plurality of switches (such as switch 405) coupling a power supply to the circuitry. Each switch is individually controlled by a control signal and is turned on sequentially. Also coupled to each switch is a pre-driver circuit (such as pre-driver circuit 410). The pre-driver circuit comprises a potential adjust circuit (such as potential adjust circuit 505) that rapidly adjusts a voltage potential at the switch and a rate adjust circuit (such as the rate adjust circuit 520) that accelerates the power ramp-up across the switch once transient currents are no longer a concern. Adjusting the voltage potential so that the switch operates in a saturation mode increases an effective capacitance across the switch and thereby retarding the power ramp-up across the switch.

Abstract: The method for powering down a circuit for a data retention mode includes: changing a supply voltage node from an active power voltage level to an inactive power level; coupling a source of a P channel device to the supply voltage node; providing a retaining power supply voltage level to a back gate of the P channel device; changing a drain voltage of the P channel device to a reference voltage level, wherein the reference voltage level is different from the retaining power supply voltage level; and changing a gate voltage of the P channel device to the reference voltage level.

Abstract: The method for powering down a circuit for a data retention mode includes: changing a supply voltage node from an active power voltage level to an inactive power level; coupling a source of a P channel device to the supply voltage node; providing a retaining power supply voltage level to a back gate of the P channel device; changing a drain voltage of the P channel device to a reference voltage level, wherein the reference voltage level is different from the retaining power supply voltage level; and changing a gate voltage of the P channel device to the reference voltage level.

Abstract: A device for adaptively controlling a voltage supplied to circuitry in substantially close proximity to the device, comprising a processing module, a first tracking element coupled to the processing module and producing a first value indicative of a first estimated speed associated with the circuitry, and a second tracking element coupled to the processing module and producing a second value indicative of a second estimated speed associated with the circuitry. The processing module compares each of the first and second values to a target value and causes a voltage output to be adjusted based on said comparison.

Abstract: A digital phase lock loop (DPLL) system and method employ digital loop control and a digital controller to drive the DPLL oscillator with fast re-lock capability. The DPLL optionally uses low power retention flops to implement low power and fast interrupt services.

Abstract: An SRAM device and a method of powering-down an SRAM device. In one embodiment, the SRAM device includes (1) an SRAM array coupled to an SRAM array low voltage source that provides a low SRAM array supply voltage VSB to the SRAM device and (2) main column peripheral circuitry having main pre-charge circuitry free of an SRAM header, coupled to the SRAM array by bit lines and coupled to a sleep mode controller through an associated main column peripheral driving circuitry that is configured to isolate the bit lines from a power supply during a sleep mode.

Abstract: System and method for reducing voltage fluctuations in an integrated circuit with multiple power domains and sub-domains. A preferred embodiment comprises a plurality of voltage sources and a switching network (such as switching network 320) wherein outputs from the plurality of voltage sources are inputs. The switching network can couple the outputs of voltage sources (based on a mapping) with the same output voltage levels to reduce voltage fluctuation amongst power domains coupled to the coupled outputs. The coupling may be performed by a switching structure (such as the switching structure 215) that can controllably electrically couple two outputs.

Abstract: A method of adding auxiliary data, e.g., audio data, to a high-speed serial video link in such a way that it is invisible to existing receiver and such that auxiliary data, e.g., audio, can be transmitted without any knowledge of the capabilities of the display to receive the auxiliary data. Some of the DC balancing bits are used to transport the auxiliary data information over the link in a manner that does not change the data recovered by a DVI-CE receiver, or a legacy receiver (installed base). DC balancing is also maintained, but with differences over known techniques. Since the auxiliary data bits (which are occupying the time slots of the DC balance bits) will be interpreted by legacy receivers as DC balance bits, the data must be optionally inverted to remain consistent with the value of the auxiliary data bit being transmitted.

Abstract: An SRAM device and a method of powering-down an SRAM device. In one embodiment, the SRAM device includes (1) an SRAM array coupled to an SRAM array low voltage source that provides a low SRAM array supply voltage VSB to the SRAM device and (2) main column peripheral circuitry having main pre-charge circuitry free of an SRAM header, coupled to the SRAM array by bit lines and coupled to a sleep mode controller through an associated main column peripheral driving circuitry that is configured to isolate the bit lines from a power supply during a sleep mode.

Abstract: A method of expanding data to a high-speed serial video link in such a way that it is invisible to existing receivers and such that auxiliary data, i.e. audio data, can be transmitted without any knowledge of the capabilities of the display to receive the auxiliary data.

Abstract: An encoding scheme simplifies the TMDS encoding algorithm described in the DVI 1.0 specification while retaining compatibility with most existing DVI receivers. The generation of the Transition Control bit has been removed; and although the INV bit has a similar function to the DC bit in the DVI 1.0 standard, the algorithm for deriving it is very different. No attempt is made to maintain a DC balance on the cable. Instead, the INV bit is set to a ‘1’ for the purpose of removing ‘rogue’ character sequences; otherwise it is always set to a ‘0’.