1 / 33

Electromigration Analysis for MTTF Calculations

Electromigration Analysis for MTTF Calculations. Mahesh N. Jagadeesan Analog IC Research Group The University of Texas, Arlington jmaheshn@yahoo.com. Electromigration. Current induced transport of the conducting material Electromigration is caused by high current density stress

lyre
Télécharger la présentation

Electromigration Analysis for MTTF Calculations

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Electromigration Analysis for MTTF Calculations Mahesh N. Jagadeesan Analog IC Research Group The University of Texas, Arlington jmaheshn@yahoo.com

  2. Electromigration • Current induced transport of the conducting material • Electromigration is caused by high current density stress • Major source of breakdown in electronic devices • Electromigration and Joule Heating (JH) • Peak current density is calculated with the help of layout parameters • Peak current density solutions used to generate adequately safe current density design guidelines

  3. Electromigration estimation • Electromigration Analysis – Checks for violations of the current density limits • MTTF Calculation - Assess the mean-time-to-failure (MTTF) for all wire segments

  4. Electromigration Analysis • Computation of peak current densities for power, ground and other metal lines in a circuit • Extraction of RC parameters from layout designed, using circuit netlist • Verification of the estimated peak values with the values extracted from the layout parameters

  5. Computation of peak current densities • Jpeak comprehends simultaneously both of the relevant temperature dependent mechanisms-electromigration (EM) and joule heating (JH) • Parametric dependence of Jpeak on lead width, underlying oxide thickness, and EM current density are given

  6. Joule Heating effect on current densities • For JH, the steady state equation for quasi one dimensional (1-D) heat transport equation is given by where Tm - mean metal lead temperature Tref - maximum allowed junction reference temperature (100 C) Kox - underlying oxide thermal conductivity tox - underlying oxide thickness tm - metal thickness wm - metal width ρm - temperature dependent metal resistivity.

  7. Computation of peak current densities • Figure shows three single level metal systems From Hunter et al, “Self -consistent solutions for allowed interconnect current density” • 1-D solutions are considered the worst-case “thermally-wide” case • Quasi-two-dimensional (2-D) solution as found analytically by Bilotti et al, for weff accurate to 3% weff= wm + 0.88 tox

  8. EM lifetime on current density • Black’s equation for dependence of EM lifetime on current density and temperature ; where JEM - dc current density at temperature Tm Em - activation energy for the EM mechanism JEM, dc, ref - dc EM current density specification at the temperature Tref.

  9. Peak Current density • For a unipolar (and rectangular) pulsed dc waveform with duty cycle r and peak current density Jpeak, the standard definition of Jrms results • Reason for unipolar pulsed dc is that, maximum allowed Jpeak for a symmetrical pure ac is greater than for the pulsed dc case, making the latter a worst-case Where

  10. Parameter Values used Values of material parameters used

  11. Extraction of interconnect Area from layout • Interconnect with an insufficient width may be subject to electromigration • Crucial to address the problems of current densities and electromigration during layout generation • Capacitance of each net has two components: - area and perimeter

  12. Capacitance Extraction for Area estimation • There are three capacitance components at any node Overlap capacitance (Cover) Lateral capacitance (Clat) Fringing capacitance (Cfr) From Arora et al, “Modeling and Extraction of Interconnect Capacitances for Multilayer VLSI Circuits”

  13. Area from Capacitance • Intrinsic capacitance two components: - overlap and fringing capacitances • overlap capacitance Where Carea is capacitance per unit area (fF/µm2), and W.L is the area (..m2). • fringing capacitance • Intrinsic capacitance is the sum of these two components Cover = Carea W. L Cfr=2.Clength.L Cint = (Carea W+2.Clength).L

  14. Interconnect Area Extraction • Modelling approach is not restricted to the structure • Structures such as vias are not modelled using this approach • Overlap capacitance is observed using Spectre simulator from Cadence tools • Capacitance per unit area, Carea is estimated using the Advanced Design Systems (ADS)

  15. Interconnect width extraction • Two different ways researched • From parasitic capacitances, - using metal interconnect area - width calculated with some assumptions for a constant length • Metal width from Virtuoso Custom Router (VCR) - from the design rules file as documented by the VCR when creating a route between devices in a circuit

  16. From parasitic capacitances • For overlap capacitance, Cover - Schematic and layout created - DRC, LVS checks performed - extraction with DIVA RCX cadence tool • For Carea from the Advanced Design systems (ADS) - microstrip line is considered with unit values for width and length - S-parameters generated - SPICE model generator creates R and C values for unit area • WxL obtained using the expressions shown before

  17. Schematic of a comparator circuit Schematic of a comparator circuit from Virtuoso Schematic viewer

  18. Layout of the comparator circuit Layout of the comparator circuit, from Virtuoso XL, layout editor

  19. Layout with parasitics Layout with parasitics extracted using the DIVA tool for RCX

  20. Extracted netlist with capacitance values

  21. Microstrip line for capacitance estimation Microstrip line for capacitance per area estimation in ADS

  22. S-parameters generated S-parameters generated for the microstrip line in ADS

  23. SPICE model generated

  24. Metal width from VCR • With the procedure described before the width of the metal line is difficult to obtain if the length is not known • Virtuoso Custom Router (VCR) from Cadence • VCR allows automatic and manual routing between the devices on a circuit • Routing done after the devices are placed using a placement tool

  25. Metal width from VCR • Placement tool works to place the devices in the circuit at the optimum places from schematic • Routing tool then draws metal and poly lines between them • The lines are drawn depending on the dimension requirements from the user, and these values are documented in the device rules file in VCR

  26. Layout as created by VCR Layout as created by Virtuoso Custom Router

  27. Rules file from VCR devicelib.rules file from Virtuoso Custom Router

  28. Calculated Current density values Current density values calculated

  29. Verification of Current Densities • Account for temperature, characteristics of the process, and materials parameters and relate it with the current density that has been measured • Relation between an acceptable current density Jcir(T) at an actual tempereature T and a material-dependent maximum current density Jpeak (Tref) at a given reference temperature Tref, with Q denoting experimentally determined activation energy, k denoting the Boltzmann’s constant, Tref usually 100 C for silicon, and T the working temperature | Jcir(T)| ≤ | Jpeak (Tref)|.exp ( - (Q/nk Tref)(1-( Tref /T)))

  30. MTTF Calculations • Mean Time To Failure, MTTF, of a system is the expected time a system will operate before the first failure occurs • The MTTF of a conductor under a constant current stress is expressed by MTTF = AJ-n exp {Ea/ kT} Where Ea - Activation Energy, J - Current density, T - Temperature in degrees Kelvin A - constant depending on geometry and material parameters – scaling factor K - Boltzmann constant, n - constant ranging from 1 to 7

  31. MTTF Calculations • Three associated problems in electromigration - Joule Heating (JH) - Current crowding - Material reactions • If the reliability of a system can be expressed in terms of a failure parameter, then it should be possible to express it as a numerical index which could be seen as a fitness of the design created

  32. Conclusion and future works • A simple method for electomigration analysis was devised and the current density violations were checked for MTTF calculations • Once these analysis confirms that current densities do not exceed the limits, the mean time to failure (MTTF) calculations are done for the interconnects • The future works for this project include, - Design and simulation of some basic test circuits for the electomigration analysis and MTTF calculations. - Extraction of interconnect width at the layout level for variable width interconnect circuits, using metal line parasitic either from Cadence tools.

  33. Conclusion and future works - Formulating a capacitance extraction technique for VLSI circuits which have the overlap, fringing and other intrinsic capacitance values, which might be used for the interconnect width estimations - Developing a PERL script for incorporating the electromigration analysis – current density and temperature violation checks, and the MTTF calculations. - Determination of current crowding and hot spots at different places in a circuit for estimating the failure time. By this way the MTTF estimations can be done for a specific number of metal lines surrounding the hot spots. - Extending this work for circuits from industry and performing analysis and calculations for specified interconnects alone for processing time optimization.

More Related