| 5.0 DFM (Design For Manufacturability) Guidelines |
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| 1. Resolving common design rule violations in the pre-tapeout design review can minimize tapeout |
| cycletime. DRC runsets (YI-093-CC001, YI-093-HC001) are available from our |
| GLOBALFOUNDRIES EAM. Please read the disclaimers and notes in the runset specifications. |
| Should any discrepancy arise between this document and results from DRC runsets, the |
| specifications and rules in this document take precedence. |
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| 2. Relaxed designs with dimensions increased from baseline ground-rule minimums will generally |
| improve process and reliability yields. Minimum design dimensions should only be used to |
| decrease chip size or improve device performance. |
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| 3. Minimum lines and spaces increase circuit density. When circuit density is not limited by these |
| rules, increase the minimum line and space values by 10% to 20% as applicable during design |
| layout. This practice improves the product manufacturability, yields and performance by |
| reducing interconnect resistance and capacitance. |
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| 4. The minimum metal-overlap-of-contact and via rules are given to increase interconnect density. |
| Where interconnect is not limited by these rules, relax the metal-overlap-of-contact and via by |
| 10%-20% as applicable during design layout. This will improve both manufacturing margins |
| and reliability. |
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| 5. Narrow polysilicon and diffusion lines are particularly susceptible to localized increases in sheet |
| resistance in a salicide process. In applications where DC voltage drops are critical, avoid using |
| narrow poly or diffusion lines. |
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| 6. Since thin-gate-oxide integrity is driven by random process defects, avoid using large gate oxide |
| areas as decoupling capacitors. Follow the antenna ratio rules to ensure reliable gate oxides. |
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| 7. Avoid long parallel routing of intra-layer metal lines. This practice reduces coupling |
| capacitance, improves circuit performance and suppresses cross-talk. |
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| 8. Use top-metal as power supply, ground, bus signal and global interconnect since it has the |
| lowest resistivity. |
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| 9. Subject to space availability, use redundant contacts and vias to provide design robustness |
| against interconnect high resistance and opens. Avoid using single contact for interlevel |
| connection unless absolutely necessary. |
| Place “multiple (≥2) plug” redundant contact or via connections for extremely isolated |
| locations, defined as having 25µm spacing to the nearest neighbor via or contact in the same |
| layer. |
| It is recommended to choose the larger top via size option when using thick top metal |
| (≥8KA AlCu). In addition, refer to section 14.4 to verify electromigration susceptibility. |
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| 10. Implementing poly and metal dummy pattern fill by designer is highly recommended when GDS |
| densities are below the minimum rules specified. Control of dummy fill and minimized impact |
| to critical path circuitry are then assured in layout. Our DRC runsets implement GDS pattern |
| density checks. |
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| 11. If customers choose to use their algorithms rather than GLOBALFOUNDRIES’s generation |
| algorithms in section 4.2 to generate implant layers (TN, TP, HVN), drawn implant layer rules |
| in section 7.13 to 7.15 must be applied during DRC. |
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| 12. As product labels are placed in the chip area and not in the scribe line, labels and logos must |
| obey the design rules in this manual so as to prevent impact to circuit functionality. |
| GLOBALFOUNDRIES does not provide logo block marking layer to suppress DRC on logos. |
