Abstract: A method of minimizing power consumption in an integrated device is disclosed. The method comprises providing a plurality of circuit blocks having circuits for performing logic functions, wherein each circuit block consumes power in a static state; coupling one of a plurality of operating voltages to each circuit block of the plurality of circuit blocks; enabling a reduction of power consumed by a first set of circuit blocks by way of a first power reduction signal; and enabling a reduction of power consumed by a second set of circuit blocks by way of a second power reduction signal. A circuit for minimizing power consumption in a device is also disclosed.

Abstract: A method and apparatus to implement clock signal adaptation is provided to characterize an input clock signal that is to be adapted and in response, generate adaptation updates at each subsequent clock cycle of the input clock signal. In a first embodiment, clock signal adaptation occurs through duty cycle correction (DCC) to substantially achieve a 50% duty cycle. In an alternate embodiment, clock signal adaptation occurs through a multiplication operation that is applied to the clock signal to be adapted, whereby the multiplication operation is parameterizable to allow odd/even multiplication. In an alternate embodiment, clock signal adaptation occurs through a phase-shift operation that is applied to the clock signal to be adapted, whereby the phase-shift operation is parameterizable to allow all possible fractions and percentages of phase shifts.

Abstract: A method and apparatus to implement clock signal adaptation is provided to characterize an input clock signal that is to be adapted and in response, generate adaptation updates at each subsequent clock cycle of the input clock signal. In a first embodiment, clock signal adaptation occurs through duty cycle correction (DCC) to substantially achieve a 50% duty cycle. In an alternate embodiment, clock signal adaptation occurs through a multiplication operation that is applied to the clock signal to be adapted, whereby the multiplication operation is parameterizable to allow odd/even multiplication. In an alternate embodiment, clock signal adaptation occurs through a phase-shift operation that is applied to the clock signal to be adapted, whereby the phase-shift operation is parameterizable to allow all possible fractions and percentages of phase shifts.

Abstract: A PLD is configurable to efficiently implement a wide variety of user functions. The PLD includes a programmable interconnect circuit, programmable logic circuits, one-bit registers, selector circuits, and input/output blocks. The programmable interconnect circuit is configurable to connect the signal lines of its output ports to the signal lines of its input ports. The programmable logic circuits are configurable to implement a programmable function generating one-bit signal values from a respective output port of the programmable interconnect circuit. The one-bit registers store a respective one of these one-bit signal values. The programmable selector circuits are each coupled to output ports of a plurality of the one-bit registers, with each of these one-bit registers coupled to a respective one of the programmable logic circuits.

Abstract: A method of minimizing power consumption in an integrated device is disclosed. The method comprises providing a plurality of circuit blocks having circuits for performing logic functions, wherein each circuit block consumes power in a static state; coupling one of a plurality of operating voltages to each circuit block of the plurality of circuit blocks; enabling a reduction of power consumed by a first set of circuit blocks by way of a first power reduction signal; and enabling a reduction of power consumed by a second set of circuit blocks by way of a second power reduction signal. A circuit for minimizing power consumption in a device is also disclosed.

Abstract: A method and apparatus for a CPLD-structured ASIC. Circuit blocks associated with a programmed portion of a CPLD are configured to preserve timing associated with instantiation of a circuit design in the programmed portion of the CPLD. The circuit blocks have predetermined placement information obtained from the CPLD, and the placement information is used to locate CPLD-structured ASIC cells associated with the circuit blocks.

Abstract: Voltage level translation for open-drain circuitry is described. A logic isolation circuit includes a first buffer circuit configured for being switched between a first voltage transferable state and a first voltage non-transferable state. A first latch circuit is configured for being switched between a first reset state and a first non-reset state, the first reset state for setting the first latch circuit to a first reset condition. A second buffer circuit and second latch circuit are configured like the first buffer circuit and the first latch circuit. First and second input/output nodes are coupled to receive first and second logic level voltages, respectively. The first logic level voltage and the second logic level voltage are both for a same logic state, but the second logic level voltage is significantly greater than the first logic level voltage.

Abstract: A PLD is configurable to efficiently implement a wide variety of user functions. The PLD includes a programmable interconnect circuit, programmable logic circuits, one-bit registers, selector circuits, and input/output blocks. The programmable interconnect circuit is configurable to connect the signal lines of its output ports to the signal lines of its input ports. The programmable logic circuits are configurable to implement a programmable function generating one-bit signal values from a respective output port of the programmable interconnect circuit. The one-bit registers store a respective one of these one-bit signal values. The programmable selector circuits are each coupled to output ports of a plurality of the one-bit registers, with each of these one-bit registers coupled to a respective one of the programmable logic circuits.

Abstract: Fast logic sharing is created using a feedback path from the output logic macrocell of one functional block to the product term inputs of another function block without going through an advanced interconnect matrix (AIM). The fast feedback path may be provided from the macrocell after the product terms XOR gate without registering, and/or after the register in the macrocell. The fast logic sharing avoids the slow AIM for feedback logic, and allows additional resources to be borrowed from other function blocks with a limited delay penalty. In particular, delay penalties resulting from dividing wide operations requiring multiple product terms between the product terms of multiple functional blocks are significantly reduced.

Abstract: Methods of implementing routing matrices for programmable logic devices (PLDs). Each method includes generating a seed matrix, a distribution matrix, adjustment values for the distribution matrix, and a routing matrix pattern. The seed matrix and distribution matrix are implemented according to a set of rules that define valid matrices. The routing matrix is then implemented by applying the routing matrix pattern to provide programmable interconnections between input and output terminals of the routing matrix. Each signal value in the routing matrix pattern corresponds to one of the input terminals, and each row of signal values in the routing matrix pattern corresponds to a set of the input terminals programmably coupled to a different one of the output terminals. By adding additional columns of sub-matrices to an existing distribution matrix, an existing routing matrix can also be expanded to accommodate a larger number of input signals.

Abstract: An application specific processor for an application program is provided. First a software description, for example, a HDL description, of a processor is created. A user program is written using the processor's instruction set and compiled and/or assembled into object code. The software description of the processor and the object code are combined and synthesized into a logic gate circuit description, which may be implemented in a Field Programmable Gate Array (FPGA), a Complex Programmable Logic Device (CPLD) or any other Integrated Circuit (IC) having programmable logic modules. Typically, the logic gate circuit description is optimized, hence reducing the number of logic gates and the resources needed.