Abstract: A dedicated logic cell in a programmable logic structure is described that comprises the following primary components: a configurable logic function or look-up table (LL), a dedicated logic function (DL), a sequential logic function (LS), and a control logic function (LC). In this illustration, the dedicated logic cell comprises two configurable logic functions, two sequential logic functions, a dedicate logic function, and a control logic function. In a first embodiment, the dedicated logic cell is constructed with a combination of configurable logic functions that are coupled to a dedicated logic function in order to perform a four 2-input function, an AND function, an OR function, or an XOR function. In a second embodiment, the dedicated logic cell is constructed with a combination of configurable logic functions that are coupled to a dedicated logic function in order to perform a four 2-to-1 multiplexer function.

Abstract: One or more configurable transceivers can be fabricated on an integrated circuit. The transceivers contain various components having options that can be configured by turning configuration memory cells on or off. The integrated circuit may also contain programmable fabric. Other components in the transceivers can have options that are controlled by the programmable fabric. The integrated circuit may also contain one or more processor cores. The processor core and the transceivers can be connected by a plurality of signal paths that pass through the programmable fabric.

Abstract: A programmable logic structure is disclosed that has a set of dedicated lines which extend internally throughout different dedicated logic cells within a logic and routing block (LRB), extend from a previous logic routing block to the present logic and routing block, or extend from the present logic and routing block to the next logic and routing block. One set of dedicated lines from a first logic and routing block can be stitched to another set of dedicated lines of a second logic and routing block for extending the reach as well as bypassing a logic and routing block, or bypassing a dedicated logic cell in the same logic and routing block. The dedicated lines between logic and routing blocks allow a logic and routing block to receive more inputs from its own switch box or to drive more outputs than provided by the logic and routing block as specified by a given function.

Abstract: Disclosed are methods and structures for preparing data for transmission over a network. In an embodiment consistent with the OSI network model, transmit and receive CRC generators are moved from the link layer to the physical layer, which frees up valuable programmable logic resources when a programmable logic device is employed to perform the functions of the link layer. The CRC generators of the physical layer comply with a plurality of network communication standards.

Abstract: A programmable logic device has a plurality of levels of programmable logic modules with fixed interconnections. The outputs of a level connect to inputs of the next level of programmable logic modules. The first level is fed from a bank of memory elements and the inputs to this bank of memory elements are derived from the last level. Crossbar switches are optionally inserted between a carefully chosen pairs of levels.

Abstract: A transmit variable-width interface can be programmed to convert an electronic digital data path that is either 1N, 2N, 4N, or 8N bits wide into a data path that is 2N bits wide, either by serializing bits (4N- or 8N-bit cases), re-clocking bits (2N-bit case), or grouping bits (1N-bit case). A receive variable-width interface can be programmed to convert a data path 2N bits wide into a data path that is 1N, 2N, 4N, or 8N bits wide. The widths of the two variable-width data paths are controlled independently. The variable-width interfaces are coupled between a multi-gigabit transceiver and core logic of a programmable logic device. The incoming and outgoing data paths of the variable-width interfaces have separate clocks signals that are synchronized such that small amounts of skew in these clock signals do not disrupt the operation of the variable-width interfaces.

Abstract: A programmable logic device (PLD) is provided that supports multi-gigabit transceivers (MGTs). The PLD includes one or more pairs of shared clock pads for receiving one or more high-quality differential clock signals. Dedicated clock traces couple each pair of shared clock pads to one or more MGTs on the PLD. Each MGT includes a clock multiplexer circuit, which allows one of the high-quality differential clock signals to be routed as a reference clock signal for the MGT. The clock multiplexer circuits are designed such that no significant jitter is added to the high-quality clock signals. The clock multiplexer circuits can also route general-purpose clock signals received by the PLD as lower quality reference clock signals for the MGTs. The reference clock signal routed by the clock multiplexer circuit can be stepped down to provide a reference clock for a physical coding sublayer of the MGT.

Abstract: A system and method are disclosed for providing highly parallel, FFT calculations in a circuit including a plurality of RADIX-2 elements. Partitioned RAM resources allow RADIXes at all stages to have optimal bandwidth memory access. Preferably more memory is made available for early RADIX stages and a “critical” stage. RADIXes within stages beyond the critical stage preferably each need only a single RAM partition, and can therefore simultaneously operate without fighting for memory resources. In a preferred configuration having P RAM partitions and P RADIX stages, the critical stage is stage number log2 P, and until the critical stage, only P/2 RADIX elements can simultaneously operate within each stage. After the critical stage, all RADIXes within each stage can simultaneously operate.

Abstract: A transmit variable-width interface can be programmed to convert an electronic digital data path that is either 1N, 2N, 4N, or 8N bits wide into a data path that is 2N bits wide, either by serializing bits (4N- or 8N-bit cases), re-clocking bits (2N-bit case), or grouping bits (1N-bit case). A receive variable-width interface can be programmed to convert a data path 2N bits wide into a data path that is 1N, 2N, 4N, or 8N bits wide. The widths of the two variable-width data paths are controlled independently. The variable-width interfaces are coupled between a multi-gigabit transceiver and core logic of a programmable logic device. The incoming and outgoing data paths of the variable-width interfaces have separate clocks signals that are synchronized such that small amounts of skew in these clock signals do not disrupt the operation of the variable-width interfaces.

Abstract: A system and method are disclosed for providing highly parallel, FFT calculations in a circuit including a plurality of RADIX-2 elements. Partitioned RAM resources allow RADIXes at all stages to have optimal bandwidth memory access. Preferably more memory is made available for early RADIX stages and a “critical” stage. RADIXes within stages beyond the critical stage preferably each need only a single RAM partition, and can therefore simultaneously operate without fighting for memory resources. In a preferred configuration having P RAM partitions and P RADIX stages, the critical stage is stage number log2P, and until the critical stage, only P/2 RADIX elements can simultaneously operate within each stage. After the critical stage, all RADIXes within each stage can simultaneously operate.

Abstract: A system and method are disclosed for providing highly parallel, FFT calculations in a circuit including a plurality of RADIX-2 elements. Partitioned RAM resources allow RADIXes at all stages to have optimal bandwidth memory access. Preferably more memory is made available for early RADIX stages and a “critical” stage. RADIXes within stages beyond the critical stage preferably each need only a single RAM partition, and can therefore simultaneously operate without fighting for memory resources. In a preferred configuration having P RAM partitions and P RADIX stages, the critical stage is stage number log2P, and until the critical stage, only P/2 RADIX elements can simultaneously operate within each stage. After the critical stage, all RADIXes within each stage can simultaneously operate.

Abstract: A system and method are disclosed for providing highly parallel, FFT calculations in a circuit including a plurality of RADIX-2 elements. Partitioned RAM resources allow RADIXes at all stages to have optimal bandwidth memory access. Preferably more memory is made available for early RADIX stages and a "critical" stage. RADIXes within stages beyond the critical stage preferably each need only a single RAM partition, and can therefore simultaneously operate without fighting for memory resources. In a preferred configuration having P RAM partitions and P RADIX stages, the critical stage is stage number log.sub.2 P, and until the critical stage, only P/2 RADIX elements can simultaneously operate within each stage. After the critical stage, all RADIXes within each stage can simultaneously operate.

Abstract: A method using replication of distributed arithmetic logic circuits and recursive interpolation of reduced angular increments of sine and cosine sum constants in logic look-up tables permits the computation of vector rotation and large FFTs in an efficient-parallel fashion within a unitary field programmable gate array chip, without off-chip memory for storing constants.