Abstract: A design structure for a multimode circuit that is configured to operate in one of multiple operating modes is disclosed. In particular, a design structure for a exemplary multimode circuit may be configured to operating in one of a full-swing mode, a limited-swing mode, a full-swing to limited-swing converter mode, and a limited-swing to full-swing converter mode. The operating modes of the multimode circuit may be dynamically selectable. One or more multimode circuits may be part of a configurable distribution path for controlling the performance of a signal distribution path or tree of an integrated circuit.

Abstract: A multimode circuit that is configured to operate in one of multiple operating modes is disclosed. In particular, an exemplary multimode circuit may be configured to operating in one of a full-swing mode, a limited-swing mode, a full-swing to limited-swing converter mode, and a limited-swing to full-swing converter mode. The operating modes of the multimode circuit may be dynamically selectable. One or more multimode circuits may be part of a configurable distribution path for controlling the performance of a signal distribution path or tree of an integrated circuit.

Abstract: A static random access memory (SRAM) device a pair of cross-coupled, complementary metal oxide semiconductor (CMOS) inverters configured as a storage cell for a bit of data, a first pair of transfer gates configured to couple complementary internal nodes of the storage cell to a corresponding pair of bitlines during a read operation of the device; and a second pair of transfer gates configured to couple the storage cell nodes to the pair of bitlines during a write operation of the device, wherein impedance between the bitlines and the storage cell nodes during the write operation is less than that for the read operation, wherein impedance between the bitlines and the storage cell nodes during the write operation is less than that for the read operation.

Abstract: A method of balancing signal interconnect path delays between an analog domain and a digital domain of an integrated circuit includes applying a test signal to a selected one of a plurality of communication paths between the analog domain and the digital domain. A rising edge delay and a falling edge delay of the test signal is equalized by adjusting a body bias voltage of a delay element configured within the selected communication path. A rising edge delay and a falling edge delay for each of the remaining communication paths is compared with the equalized rising edge delay and falling edge delay of the selected communication path, and a body bias voltage for one or more of a plurality of delay elements configured within each of the remaining communication paths is adjusted until corresponding rising and falling edge delays thereof match the equalized rising edge delay and falling edge delay of the selected communication path.

Abstract: A multimode circuit that is configured to operate in one of multiple operating modes is disclosed. In particular, an exemplary multimode circuit may be configured to operating in one of a full-swing mode, a limited-swing mode, a full-swing to limited-swing converter mode, and a limited-swing to full-swing converter mode. The operating modes of the multimode circuit may be dynamically selectable. One or more multimode circuits may be part of a configurable distribution path for controlling the performance of a signal distribution path or tree of an integrated circuit.

Abstract: A design structure embodied in a machine readable medium used in a design process includes a voltage divider device, including a double gate field effect transistor (FET) having a first gate and a second gate disposed at opposite sides of a body region; the first and second gates configured to have an input voltage coupled thereacross; and at least one of a source of the FET and a drain of the FET configured to have an output voltage taken therefrom; wherein the output voltage represents a divided voltage with respect to the input voltage.

Abstract: A clock distribution network, structure, and method for providing balanced loading is disclosed. In particular, a clock distribution network may be formed of one or more clock fanout distribution levels. Each respective distribution level may include an equal number of buffer circuits and wiring routes that have substantially identical physical and electrical properties. Additionally, a final distribution level may include wiring routes that have substantially identical physical and electrical properties connecting buffer circuits to one or more logic leaf connection nodes.

Abstract: A clock distribution network, structure, and method for providing balanced loading is disclosed. In particular, a clock distribution network may be formed of one or more clock fanout distribution levels. Each respective distribution level may include an equal number of buffer circuits and wiring routes that have substantially identical physical and electrical properties. Additionally, a final distribution level may include wiring routes that have substantially identical physical and electrical properties connecting buffer circuits to one or more logic leaf connection nodes.

Abstract: Disclosed are embodiments of a transistor that operates as a capacitor and an associated method of tuning capacitance within such a capacitor. The embodiments of the capacitor comprise a field effect transistor with front and back gates above and below a semiconductor layer, respectively. The capacitance value exhibited by the capacitor can be selectively varied between two different values by changing the voltage condition in a source/drain region of the transistor, e.g., using a switch or resistor between the source/drain region and a voltage supply. Alternatively, the capacitance value exhibited by the capacitor can be selectively varied between multiple different values by changing voltage conditions in one or more of multiple channel regions that are flanked by multiple source/drain regions within the transistor. The capacitor will exhibit different capacitance values depending upon the conductivity in each of the channel regions.

Abstract: A multimode circuit that is configured to operate in one of multiple operating modes is disclosed. In particular, an exemplary multimode circuit may be configured to operating in one of a full-swing mode, a limited-swing mode, a full-swing to limited-swing converter mode, and a limited-swing to full-swing converter mode. The operating modes of the multimode circuit may be dynamically selectable. One or more multimode circuits may be part of a configurable distribution path for controlling the performance of a signal distribution path or tree of an integrated circuit.

Abstract: A method, system and computer program product reducing clock noise generated by clock signals in an integrated circuit (IC) are disclosed. Conventional IC design attempts to ensure coincident clock active edge arrival times for all clocked elements. The coincident active clock edges generate coincident noise currents, which elevates the total noise current. The current invention assigns clock arrival times for clocked elements of an IC based on a desired clock arrival time distribution such that active clock edges are not coincident. As a consequence, the total noise would be spread over a large portion of the clock cycle, thus reducing the noise magnitude substantially.

Abstract: A method and system for reducing clock noises are disclosed. A clock signal includes active edges and inactive edges. Inactive edges produce clock noise but are not critical to the functionality of the clock signal. That is, only active edges are critical to proper timing of an integrated circuit (IC). As such, inactive edges of clock signals to clocked elements of an IC may be shifted to be misaligned to one another. As a consequence, peak noise produced by the inactive edges will be spread over a large area and therefore will be reduced in amplitude.

Abstract: A method for noise comprising synthesizing blocks of sequential latches, e.g., a pipeline circuit architecture or clocking domain, which comprises combinational logic, synthesizing a root or a master clock and at least one phase-shifted sub-domain clock for each block, assigning primary inputs and primary outputs of the block to the root clock, assigning non-primary inputs and non-primary outputs of the block to the sub-domain clock, splitting root clock inputs into root clock inputs and phase-shifted sub-domain clock inputs, assigning each of the blocks a different phase-shifted sub-domain clock phase offset, creating a clock generation circuitry for the root clocks and the phase-shifted sub-domain clocks.

Abstract: A system and method for eliminating step response power supply perturbation during voltage island power-up/power-down on an integrated circuit is disclosed. An IC chip communicates with a primary power supply and includes at least one voltage island. A primary header on the voltage island of the chip communicates with the primary power supply via a primary header power path. A secondary header on the voltage island of the chip communicates with a secondary power supply via a secondary header power path. A control decoder communicating with the IC chip and the voltage island regulates the state of the primary and secondary headers.

Abstract: A design structure for eliminating step response power supply perturbation during voltage island power-up/power-down on an integrated circuit is disclosed. An IC chip communicates with a primary power supply and includes at least one voltage island. A primary header on the voltage island of the chip communicates with the primary power supply via a primary header power path. A secondary header on the voltage island of the chip communicates with a secondary power supply via a secondary header power path. A control decoder communicating with the IC chip and the voltage island regulates the state of the primary and secondary headers.

Abstract: The present invention provides a transceiver for receiving and transmitting data over a network, and a method for testing the same. In particular, the present invention provides a physical layer transceiver having a built-in-self-test (BIST) device that allows for, among other things, pulse density/width variation and jitter control.

Abstract: A voltage divider device includes a double gate field effect transistor (FET) having a first gate and a second gate disposed at opposite sides of a body region. An input voltage is coupled between the first and second gates, and an output voltage is taken from at least one of a source of the FET and a drain of the FET, wherein the output voltage represents a divided voltage with respect to the input voltage.

Abstract: A voltage divider device includes a double gate field effect transistor (FET) having a first gate and a second gate disposed at opposite sides of a body region. An input voltage is coupled between the first and second gates, and an output voltage is taken from at least one of a source of the FET and a drain of the FET, wherein the output voltage represents a divided voltage with respect to the input voltage.

Abstract: A voltage divider device includes a double gate field effect transistor (FET) having a first gate and a second gate disposed at opposite sides of a body region. An input voltage is coupled between the first and second gates, and an output voltage is taken from at least one of a source of the FET and a drain of the FET, wherein the output voltage represents a divided voltage with respect to the input voltage.

Abstract: A method for converting globally clock-gated circuits to locally clock-gated circuits is disclosed. A timing analysis is initially performed on an integrated circuit (IC) design to generate a slack time report for all globally clock-gated circuits within the IC design. Based on their respective slack time indicated in the slack time report, all globally clock-gated circuits that should be connected to locally generated clocks are identified. After disconnecting from a global clock tree, each of the identified globally clock-gated circuits is subsequently connected to a locally generated clock having a clock delay comparable to its slack time indicated in the slack time report.