US 20040199882 A1 Abstract A method for estimating decoupling capacitance during an ASIC design flow is disclosed. The method includes precharacterizing a set of power grid structures to model their respective noise behaviors, and storing the respective noise behaviors as noise factors in a table. During the ASIC design flow for a current design that includes at least one of the precharacterized power grid structures, the corresponding noise factor from the table is used to calculate decoupling capacitance for the current design.
Claims(27) 1 A method for estimating decoupling capacitance during a design flow, the method comprising the steps of:
(a) precharacterizing a set of power grid structures to model their respective noise behaviors;
(b) storing the respective noise behaviors as noise factors in a table; and
(c) during the ASIC design flow for a current design that includes at least one of the power grid structures, using the corresponding noise factor from the table to calculate decoupling capacitance for the current design.
2 The method of 3 The method of 4 The method of 5 The method of 6 The method of 7 The method of 8 The method of 9 The method of 10 The method of 11 A method for estimating decoupling capacitance during a design flow, the method comprising the steps of:
(a) modeling a set of power grid structures to obtain respective noise factors for each;
(b) storing the noise factors in a first table;
(c) characterizing a set of memory, and logic structures to obtain respective sets of peak current parameters;
(d) storing the peak current parameters in a second table;
(e) for a design that includes any combination of the power, package, memory, and logic structures, looking up the corresponding noise factors and peak current parameters from the first and second tables; and
(f) using the noise factors and peak current parameters retrieved from the tables to calculate decoupling capacitance and a number of required decoupling capacitors for the design.
12 The method of 13 The method of 14 The method of 15 The method of 16 The method of 17 The method of 18 A computer readable medium containing program instructions for estimating decoupling capacitance during a design flow, the instructions for:
(a) precharacterizing a set of power grid structures to model their respective noise behaviors;
(b) storing the respective noise behaviors as noise factors in a table; and
(c) during the ASIC design flow for a current design that includes at least one of the power grid structures, using the corresponding noise factor from the table to calculate decoupling capacitance for the current design.
19 The computer readable medium of 20 The computer readable medium of 21 The computer readable medium of 22 The computer readable medium of 23 The computer readable medium of 24 The computer readable medium of 25 The computer readable medium of 26 The computer readable medium of 27 The computer readable medium of clam 26 wherein step (c) further includes the step of: calculating the decoupling capacitance by, Cdec=noise factor×Q/(ΔVlim).Description [0001] The present invention relates to estimating decoupling capacitance, and more particularly to a decoupling capacitance estimation and insertion flow for ASIC designs. [0002] In deep sub-micron ASIC design, with decreasing supply voltages and noise margin, and higher clock speeds, core noise is one of the most significant signal integrity problems facing a chip designer. Core noise, or instantaneous voltage drop, is due to a large demand for current across a chip in a short period of time. Instantaneous voltage drop has been linked to the following problems in integrated circuits; high performance clock jitter (cycle-to-cycle), clock skew balanced delay chain matching and clock balancing, tight hold time margin paths and scan shift chain, and jitter sensitive I/O interfaces, such as DDR and source synchronous. Instantaneous voltage drop (IVD) can also cause functional failures if not addressed properly in the design phase. [0003] One of the most effective ways to reduce power supply noise is to increase on-chip decoupling capacitance (dcap) by adding decoupling capacitors to the circuit layout. Decoupling capacitors can be designed into the layout before or after the design is complete. Although adding decoupling capacitors is an effective method for combating IVD, the current method for estimating and adding decoupling capacitors to a chip design has disadvantages. [0004] One disadvantage is that an integrated package level and chip level power bus model with switching and timing information is needed to accurately analyze such voltage variations over time. The current static analysis methodology relies on average power calculations to analyze and design the power distribution. There is a deficiency in the current voltage drop analysis flow in that it only takes into account the average voltage drop. Peak currents may occur between four and five times the average current estimated by conventional analysis, resulting in short duration peak voltage drops between four and five times on the chip over what was predicted, not including the package and board voltage drop. Therefore, the number of decoupling capacitors that will be placed on the chip may not be adequate to handle the underestimation of the peak voltage drops. [0005] Another disadvantage is that if the number of decoupling capacitors is initially underestimated by the voltage drop simulation, and more must be added after the chip design is complete, then the chip may no longer have an adequate amount of area to place the additional decoupling capacitors. [0006] A further deficiency with the current dynamic spice-like voltage drop simulation is that it is slow and time-consuming. Once a chip design nears completion, further testing and analysis are performed, followed by refinements to the design, including the decoupling capacitors. With each iteration, the voltage drop simulation increases the time for that cycle to complete. With some designs, use of the simulation is not feasible in the overall ASIC design flow because of the slow turn-around time of the simulation and a limited capacity to handle large designs. [0007] Accordingly, what is needed is an improved method for estimating the decoupling capacitance required for an ASIC design. The present invention addresses such a need. [0008] The present invention provides a method for estimating decoupling capacitance during an ASIC design flow. The method includes precharacterizing a set of power grid structures to model their respective noise behaviors, and storing the respective noise behaviors as noise factors in a table. During the design flow for a current design that includes at least one of the precharacterized power grid structures, the corresponding noise factor from the table is used to calculate decoupling capacitance for the current design. [0009] According to the present invention, components that are commonly used in ASIC designs are precharacterized for future use in a table look-up approach, thereby eliminating the need to perform these steps during the actual design flow, and therefore reducing the time to perform the decoupling capacitance estimation. [0010]FIG. 1 is a flow chart illustrating a decoupling capacitance estimation and insertion flow in ASIC design for core noise avoidance in accordance with one preferred embodiment of the present invention. [0011]FIG. 2 is a flow chart illustrating a power characterization process in further detail. [0012]FIG. 3 is a diagram illustrating post processing on a waveform output by the simulation to obtain the peak current parameters. [0013] The present invention relates to a decoupling capacitance estimation and insertion flow for ASIC designs. The following description is presented to enable one of ordinary skill in the art to make and use the invention and is provided in the context of a patent application and its requirements. Various modifications to the preferred embodiments and the generic principles and features described herein will be readily apparent to those skilled in the art. Thus, the present invention is not intended to be limited to the embodiments shown but is to be accorded the widest scope consistent with the principles and features described herein. [0014] The present invention provides a decoupling capacitance estimation and insertion flow during ASIC design for core noise avoidance. In a preferred embodiment, the decoupling capacitance estimation and insertion flow is implemented as a software tool, or set of tools, that is executed by a conventional PC, workstation, or server. One part of the tool is run prior to ASIC design flow in which a set of off-the-shelf power grid and package structures are precharacterized to model their noise behavior, which is represented as a noise factor and stored in noise factor table. When architecting a new ASIC design, a designer selects which of the off-the-shelf power grid and package structures will comprise the design. During the ASIC design flow for the new design, the decoupling capacitance tool is used to calculate decoupling capacitance for the design using the prestored noise factors corresponding to the selected structures in the design. Based on the estimated decoupling capacitance, an appropriate area in the design is reserved for insertion of the required decoupling capacitors. [0015] In accordance with one aspect of the present invention, the noise factor, on which the estimate of the decoupling capacitance for the current design is based, is calculated for each off-the-shelf power grid and package, such that a table lookup approach can be used to retrieve the corresponding noise factors during the decoupling capacitance calculation for a current design. By precharacterizing components of ASIC designs and using a table look-up approach, the present invention eliminates the need to perform these steps during the actual design flow using spice simulation, and therefore reduces the time to perform decoupling capacitance estimation. In addition, the decoupling capacitance estimation tool accounts for the decoupling capacitance area overhead upfront during chip size estimation and ensures that the chip always includes sufficient area required to place the decoupling capacitance cells. [0016]FIG. 1 is a flow chart illustrating a decoupling capacitance estimation and insertion flow in ASIC design for core noise avoidance in accordance with one preferred embodiment of the present invention. The process includes two stages, a precharacterization stage [0017] In a preferred embodiment, the noise factors [0018] The precharacterization stage [0019] The decoupling capacitance stage [0020] In step [0021] After bloating the memory, the normal ASIC process flow continues with floor-planning [0022] Referring now to FIG. 2, a flow chart illustrating the power characterization process corresponding to step [0023] Largest IVD: 1.26V, −40 C., SNSP. [0024] Lowest IVD: 1.08V, 115 C., WNWP. [0025] Normal IVD: 1.2V, 25 C., NOM. [0026] A ramp time of 0.20 ns, rail-to-rail, may be used for all stimuli, and a 32× standard load may be used for all output loads for this analysis. The output of the simulation is a waveform of the current flowing out of a power source. [0027]FIG. 3 is a diagram illustrating post processing on a waveform output by the simulation to obtain the peak current parameters. For a specific memory configuration that is being characterized, T is defined as a minimum cycle time of the memory. A time window of 0.5 T, (0.25 T on both left and right side of the maximum peak) may be used to find the total charge within the maximum peak of the current. The variable Tpk corresponds to the time-to-peak value, and the variable Ipeak corresponds to the peak current value. [0028] Referring again to FIG. 2, according to one aspect of the present invention, the output results of the power estimation tool are post-processed in step [0029] Note, the power estimation tool simulations include device and interconnect capacitance, but do not include the memory intrinsic capacitance (n-well, non-switching circuits capacitance, and power mesh capacitance). According to another aspect of the present invention, the post-processing step calculates the intrinsic capacitance as follows. [0030] The total intrinsic capacitance for a specific memory instance is expressed in pF. This parameter may include four main components: Nwell capacitance (Cnw), non-switching capacitance (Cns), metal grid capacitance, and internal decoupling capacitance. Cnw (n-well capacitance) is based on Nwell area. where Nwell area=N-well-parameter*memory-size [0031] The N-well-parameter is a number to denote the ratio of n-well area to the memory size. [0032] The Cns may be calculated as: [0033] where P=average power, A=internal memory switching activity, VDD=power supply voltage, and freq=operating frequency. A value for the total instrinsic capacitance can be obtained by extraction: [0034] where Cm is the metal grid capacitance and Cdcap is the internal decoupling capacitance. [0035] An alternative to calculating the intrinsic capacitance is to model the memory and determine these values directly through tables based on actual Hspice simulation results. [0036] Referring again to FIG. 1, step [0037] where delta_Vlim=may be 10% of vdd, and Q is the current peak charge. [0038] The number of decoupling capacitors that need to be added to the current design, Cdcap, may be calculated as: [0039] where Cn-well is the n-well capacitance characterized for each cells, Cns is the non-switching circuit capacitance, and Cpm is the power mesh capacitance. [0040] A fast-turn-around decoupling capacitance estimation and insertion flow in ASIC design for core noise avoidance has been disclosed. The present invention has been described in accordance with the embodiments shown, and one of ordinary skill in the art will readily recognize that there could be variations to the embodiments, and any variations would be within the spirit and scope of the present invention. Accordingly, many modifications may be made by one of ordinary skill in the art without departing from the spirit and scope of the appended claims. Referenced by
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