Abstract: Data are transmitted from a control device through an interface cable to a set of driver devices in synchronization with an external clock signal, or a complementary pair of external clock signals. The signal line or lines carrying the external clock signal or signals are terminated at both ends by resistors with resistance values matching the characteristic impedance of the interface cable. Each driver device has a comparator that compares the external clock signal with a regulated reference voltage, or compares the two complementary external clock signals with each other, and thereby generates an internal clock signal. The driver devices receive the data in synchronization with these internal clock signals.

Abstract: A final stage clock buffer for use in a clock distribution network in a circuit with scan design includes a demultiplexer circuit and a control circuit. The buffer receives an input clock signal and outputs a clock signal and a scan clock signal. The buffer can operate in a functional mode, a scan mode and a hold mode. The demultiplexer circuit receives the input clock signal and a scan enable signal. The scan enable signal, when asserted, causes the buffer to enter the scan mode. In the scan mode, the demultiplexer circuit propagates the input clock signal to a scan clock terminal and a constant logic level to a clock terminal. When the scan enable signal is deasserted, the demultiplexer circuit propagates the input clock signal to the clock terminal and a constant logic level to the scan clock terminal. The control circuit receives a chip-enable signal. When the chip-enable signal is asserted while the scan signal is deasserted, the buffer enters the functional mode.

Abstract: A microelectronic circuit includes a plurality of circuitry blocks and sub-blocks, a clock driver, an electrical interconnect that directly connects the clock driver to the sub-blocks, and balanced clock-tree distribution systems provided between the electrical interconnect and circuitry in the sub-blocks respectively. A method of producing a hierarchial clock distribution system for the circuit includes determining clock skews between the clock driver and the sub-blocks respectively. Delay buffers are selected from a predetermined set of delay buffers having the same physical size and different delays, with the delay buffers being selected to provide equal clock skews between the clock driver and the distribution systems respectively. Each delay buffer includes a delay line, and a number of loading elements that are connected to the delay line, with the number of loading elements being selected to provide the required clock delay for the respective sub-block.

Abstract: A clock distribution network for distributing a clock signal across a VLSI chip. A H-tree is combined with an x-y grid to allow buffering of the clock signal, while minimizing clock skew across the chip. The H-tree distributes a plurality of repower buffer levels above a final repower buffering level. The output of the final level are coupled by the x-y grid to minimizes clock skew caused by the chip and by local loading variations in the circuits.

Abstract: A system in which line reflections in a clock distribution network are cancelled by providing the clock distribution network with a branching point and suitably arranging recipient devices with respect to the branching point to provide for clock pulse reflection cancellation and attenuation. Moreover, the system can be arranged so that clock pulse reflections are not received as pulses which are discrete from legitimate clock pulses. The system also provides capability for reducing electromagnetic interference.

Abstract: A microelectronic circuit includes a plurality of circuitry blocks and sub-blocks, a clock driver, an electrical interconnect that directly connects the clock driver to the sub-blocks, and balanced clock-tree distribution systems provided between the electrical interconnect and circuitry in the sub-blocks respectively. A method of producing a hierarchial clock distribution system for the circuit includes determining clock skews between the clock driver and the sub-blocks respectively. Delay buffers are selected from a predetermined set of delay buffers having the same physical size and different delays, with the delay buffers being selected to provide equal clock skews between the clock driver and the distribution systems respectively. Each delay buffer includes a delay line, and a number of loading elements that are connected to the delay line, with the number of loading elements being selected to provide the required clock delay for the respective sub-block.

Abstract: A clock distribution network for synchronously coupled electronic communication systems that includes a clock distribution device having a phase locked loop for synchronizing the external clock signals provided to each semiconductive device with each other. The clock distribution device distributes a low speed clock to a large number of clocked semiconductor devices where those devices then internally generate high speed clocks in phase with the low speed clock. The low speed clocks are phase shifted with respect to each other to reduce radiated energy. The ratio of internal to external clock speed is also communicated to each chip so that the chips can be programmed to operate with a variety of external clock speeds. The phase shifting of the external clock to different chips is provided so that the chips can still communicate synchronously at the high speed internal clock.

Abstract: A microprocessor circuit is provided that allows the internal microprocessor clock speed to vary depending upon a register that can be programmed by software. In addition, the drive strength of the internal clock generator may similarly be varied by software programming. The programmer or user of the microprocessor may change the internal clock speed such that the microprocessor operates at a first frequency or at a second frequency depending upon the performance requirements. A lower frequency of operation may be selected for low power consumption and low EMI, while a higher frequency of operation may be selected for computational intensive and high performance applications.

Abstract: A daisy chained clock distribution scheme for distributing a clock signal from a central communications clock driver to the nodes of a massively parallel multi-processor computer or supercomputer. The daisy chained clocking scheme is implemented using point-to-point clock distribution of a differential clock signal to the communication nodes of a plurality of processors in a multicomputer system or to components connected to a common bus in a high speed microprocessor system. Differential signaling is employed wherein the differentiality is maintained including through silicon. In an alternate embodiment, the clock pulse is also regenerated in each node component.

Abstract: In a semiconductor device including a clock driver which provides clock signals, a plurality of electronic elements which are operable in timed relation to the clock signals, are provided a plurality of circumferentially-wired, lattice-shaped wiring blocks to which the electronic elements are connected and each of which has a center portion, and an interconnecting wiring pattern connected to the center portion. The interconnecting wiring pattern connects the clock driver with the center portion of each circumferentially-wired, lattice-shaped wiring block so that a distance between the clock driver and each center portion is substantially equal to one another in the center portions.

Abstract: Circuitry for producing a transition detection signal of adequate and optimized duration is disclosed. A transition detection circuit is associated with each of the input terminals from which transitions are to initiate an operating cycle, such as precharge and equilibration in a memory access cycle. Each transition detection circuit produces, responsive to a logic transition at its associated terminal, a transition detection pulse. Those transition detection circuits which produce only brief transition detection pulses are coupled to a centralized summing circuit. The summing circuit generates the transition detection circuit from the logical combination of the transition detection circuits, and includes a delay circuit to lengthen the brief incoming transition detection pulse to the desired duration. In this way, a single placement of the summing circuit can be used to optimize the transition detection pulse duration for initiation of the operating cycle of the integrated circuit.

Abstract: An intra-LSI clock distribution circuit which includes a main distribution circuit, a plurality of intra-block clock distribution circuitries, feedback wires provided in association with each of blocks and each connected to one of plural block-based clock signal wires within the associated block and the intra-block distribution circuitry of the associated block for feeding back the intra-block clock signal distributed to a given one of circuit elements connected to the intra-block clock signal wires to the intra-block clock distribution circuitry of that block.