Abstract: An apparatus for placement between a package and an integrated circuit board includes: an insert having: a substrate having a top side and a bottom side; a first set of pads at the top side of the substrate; a second set of pads at the bottom side of the substrate; and a plurality of vias in the substrate, the vias connecting respective pads in the first set to respective pads in the second set; wherein the insert has a thickness that is less than a spacing between the package and the integrated circuit board.

Abstract: An apparatus for placement between a package and an integrated circuit board includes: an insert having: a substrate having a top side and a bottom side; a first set of pads at the top side of the substrate; a second set of pads at the bottom side of the substrate; and a plurality of vias in the substrate, the vias connecting respective pads in the first set to respective pads in the second set; wherein the insert has a thickness that is less than a spacing between the package and the integrated circuit board.

Abstract: A simulation model is provided for flip-chip BGAs to help engineers determine the effects of IC package components. The simulation model includes a bump model, a package planes model, a package bypass capacitor model, a ball model and a PCB model. The simulation model in particular includes resistors, inductors, capacitors and transmission lines to simulate the electrical interaction between signal conductors, power/ground planes, vias and balls that exist in a flip-chip ball grid array (BGA) package. The simulation model helps engineers understand actual physical effects of flip-chip and IC package interactions, as well as the impact of the effects of power supply droop, ground bounce and crosstalk between adjacent signals, not only on the IC package level, but at the computer system level.

Abstract: A system and method for determining the desired decoupling components for a power distribution system having a voltage regulator module. The system may employ a mathematical model of a voltage regulator circuit, such as a switching voltage regulator. The mathematical model may be a SPICE model, or a circuit model in another format. The method may include simulating the operation of the power distribution system to obtain a estimate of the bulk capacitance required for effective decoupling. For digital systems, the method may include a cycle-by-cycle simulation of the power distribution system, wherein the simulation occurs over a number of clock cycles. The performance of the power distribution system may then be analyzed for each simulated clock cycle. The simulation may also include analyzing the transient responses and loop stability of the power distribution.

Abstract: A methodology for determining the placement of decoupling capacitors in a power distribution system and system therefor is disclosed. In one embodiment, a method for determining the placement of decoupling capacitors in a power distribution system includes determining target impedance, creating a power distribution system model, performing an LC (inductive-capacitive) resonance analysis, and performing a cavity resonance analysis. During the performance of the LC resonance analysis, capacitors may be selected in order to suppress impedance peaks resulting from LC resonances. Following the LC resonance analysis, the method may place the capacitors in the power distribution system at evenly spaced intervals. During the performance of the cavity resonance analysis, the capacitors may be repositioned in the power distribution system so as to suppress cavity resonances.

Abstract: A methodology for determining the placement of decoupling capacitors in a power distribution system and system therefor is disclosed. In one embodiment, a method for determining the placement of decoupling capacitors in a power distribution system includes determining target impedance, creating a power distribution system model, performing an LC (inductive-capacitive) resonance analysis, and performing a cavity resonance analysis. During the performance of the LC resonance analysis, capacitors may be selected in order to suppress impedance peaks resulting from LC resonances. Following the LC resonance analysis, the method may place the capacitors in the power distribution system at evenly spaced intervals. During the performance of the cavity resonance analysis, the capacitors may be repositioned in the power distribution system so as to suppress cavity resonances.

Abstract: A system and method for determining the desired decoupling capacitors for power distribution systems having frequency dependent target impedance. In one embodiment, the target impedance may be a function of frequency, and thus may vary in value over a frequency range from 0 Hz to a corner frequency. A specific quantity of decoupling capacitors may be selected to provide decoupling for the power distribution for a given frequency within the frequency range. A total impedance provided by the specific quantity of selected decoupling capacitors may be calculated and compared to the calculated target impedance for the given frequency. If the total impedance provided by the specific quantity of selected decoupling capacitors is greater than the target impedance for the given frequency, the impedance may be adjusted by changing the quantity of capacitors. Capacitors may continue to be added until the total impedance is less than the target impedance.

Abstract: A system and method for analyzing simultaneous switching noise. In one embodiment, a model may be provided for the electronic circuit to be analyzed. The electronic circuit may be an integrated circuit, a multi-chip module, a printed circuit assembly, or other type, and may in some embodiments include combinations of these types. The electronic circuit may include a plurality of drivers, each of which may be coupled to a power plane, a ground plane, and a transmission line. The connection of the driver may be accurately modeled in this manner. Each driver may be configured to switch between a logic high voltage and a logic low voltage. The modeled electronic circuit may also include a voltage source coupled to the power plane and the ground plane, a voltage regulator module, and a plurality of decoupling capacitors. The simultaneous switching of a plurality of drivers, from a logic high to a logic low, or vice versa, may be simulated.

Abstract: A method for determining the desired decoupling components for stabilizing the electrical impedance in the power distribution system of an electrical interconnecting apparatus, including a method for measuring the ESR for an electrical device, a method for determining a number of desired decoupling components for a power distribution system, and a method for placing the desired decoupling components in the power distribution system. The method creates a model of the power distribution system based upon an M×N grid for both the power plane and the ground plane. The model receives input from a user and from a database of various characteristics for a plurality of decoupling components. The method determines a target impedance over a desired frequency range. The method selects decoupling components. The method determines a number for each of the decoupling components chosen. The method places current sources in the model at spatial locations corresponding to physical locations of active components.

Abstract: A system and method for determining the desired decoupling capacitors for power distribution systems having frequency dependent target impedance. In one embodiment, the target impedance may be a function of frequency, and thus may vary in value over a frequency range from 0 Hz to a corner frequency. A specific quantity of decoupling capacitors may be selected to provide decoupling for the power distribution for a given frequency within the frequency range. A total impedance provided by the specific quantity of selected decoupling capacitors may be calculated and compared to the calculated target impedance for the given frequency. If the total impedance provided by the specific quantity of selected decoupling capacitors is greater than the target impedance for the given frequency, the impedance may be adjusted by changing the quantity of capacitors. Capacitors may continue to be added until the total impedance is less than the target impedance.

Abstract: A system and method for using a computer system to determine the desired decoupling components for stabilizing the electrical impedance in the power distribution system of an electrical interconnecting apparatus, including a method for measuring the ESR for an electrical device, a method for determining a number of desired decoupling components for a power distribution system, and a method for placing the desired decoupling components in the power distribution system. The method creates a model of the power distribution system based upon an M×N grid for both the power plane and the ground plane. The model receives input from a user and from a database of various characteristics for a plurality of decoupling components. The method determines a target impedance over a desired frequency range. The method selects decoupling components. The method determines a number for each of the decoupling components chosen.

Abstract: A method for determining the desired decoupling components for stabilizing the electrical impedance in the power distribution system of an electrical interconnecting apparatus, including a method for measuring the ESR for an electrical device, a method for determining a number of desired decoupling components for a power distribution system, and a method for placing the desired decoupling components in the power distribution system. The method creates a model of the power distribution system based upon an M×N grid for both the power plane and the ground plane. The model receives input from a user and from a database of various characteristics for a plurality of decoupling components. The method determines a target impedance over a desired frequency range. The method selects decoupling components. The method determines a number for each of the decoupling components chosen. The method places current sources in the model at spatial locations corresponding to physical locations of active components.

Abstract: A system and method for measuring the equivalent series resistance (ESR) of one or more capacitors using an impedance analyzer, whereby the capacitors are joined to the impedance analyzer with a conductive adhesive. The conductive adhesive may advantageously provide for an electrically and mechanically stable connection between the capacitor and the remainder of the electrical circuit used to measure the ESR of the capacitor. The conductive adhesive may include heat activated or cold solder, or conductive putty. The system comprises a measuring unit for sweeping a frequency range to find the minimum impedance for the capacitor and a connector assembly for holding the capacitor in an electrically and mechanically stable connection using the conductive adhesive. The connector assembly includes a mating portion adapted for electrically connecting the connector assembly to an I/O port of the measuring unit and a terminal portion that accommodates a connection to the capacitor using the conductive adhesive.