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Stacking Signal TSV for Thermal Dissipation in Global Routing for 3D IC. National Tsing Hua University Po-Yang Hsu,Hsien-Te Chen, TingTing Hwang. ASPDAC’13. Outline. Introduction Motivation Signal TSV Assignment and Relocation for Thermal Dissipation Experimental Result Conclusion.
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Stacking Signal TSV for Thermal Dissipation in Global Routingfor 3D IC National Tsing Hua University Po-Yang Hsu,Hsien-Te Chen, TingTing Hwang ASPDAC’13
Outline • Introduction • Motivation • Signal TSV Assignment and Relocation for Thermal Dissipation • Experimental Result • Conclusion
Introduction • Three dimensional (3D) chip stacking by Through-Silicon-Via (TSV) has been identified as an effective way to achieve better performance in speed and power [2, 3]. • However, such solution inevitably encounters challenges in thermal dissipation since stacked dies generate significant amount of heat per unit volume.
Introduction • Temperature aware 3D global routing algorithm by inserting ”thermal vias” and ”thermal wires” to lower the thermal resistance[4] • Reduces the temperature at the cost of extra area of ”thermal vias”[1,6-10] • Performance and thermalaware Steiner routing algorithm to place signal TSVs to reduce temperature.[11] • Does not fully utilize the outstanding thermal conductance of TSV in thermal dissipation. • [12] proposed a stacked-TSV power network structure to improve thermal dissipation by fully utilizing TSVs in power network. • only employs stacked-TSV structure in power network.
Motivation- Thermal model • The lateral thermal resistors Rlateral are determined by heat conductance of device material
Motivation 20um
Motivation • Relationship between temperature and distance of stacked signal TSV to heat source
Signal TSV Assignment and Relocation for Thermal Dissipation • Overall flow of placing signal TSVs in global routing
Initial TSV Assignment • PowDensityi,j,k: power density in grid (i,j,k) where i, j, k denotes coordinates of the grid node in x, y, z axis direction • high lumped power density grid needs more signal TSVs to dissipate its heat. • n : number of tiers in the design. • TSVNumi,j,k: number of signal TSVs in grid (i,j,k).
Initial TSV Assignment • SDi,jis defined as the stacking degree in grid (i,j), which is computed as the number of TSV stacking at grid position (i,j). • Larger Gain value means higher power density, less TSVs, and more stacking signal TSVs.
Hotspot grids Identification • Hotspot grid is identified by the top 10% highest thermal criticality grids. • define a circle region to find its saver net.
Hotspot grids Identification • Use a matching algorithm to find the overall best solution. • GridDistis the summation of distance from hotspot grid to the nearest TSV of the saver net n in all tiers. • wiring overhead if we stack the TSVs of saver net n close to the grid g. H S Weighted graph G = ( H∪S, E)
Hotspot grids Identification • Use a matching algorithm to find the overall best solution. • StackingDegreeis the number of tiers that a saver net crosses. • heat dissipation ability H S Weighted graph G = ( H∪S, E)
Determination of Stacking Grid • Based on the matching solution, TSV of a saver net will be relocated near the hotspot grid. • However, there are other factors to determine if a grid location is the best choice. • Define candidate target grids which are hotspot grids and the adjacent grids nearby themto determine the best target grid location for moving signal TSV.
Determination of Stacking Grid • Gain function to select our target grid to place stacked signal TSV at grid (i, j) is defined as • Consider • Distance between candidate target grid and hotspot grid • Power density • Number of TSVs • Whitespace • Wirelength
Determination of Stacking Grid • Gain function to select our target grid to place stacked signal TSV at grid (i, j) is defined as • Consider • Distance between candidate target grid and hotspot grid • The larger DSST the closer the distance between stacking location to the hotspot grid.
Determination of Stacking Grid • Gain function to select our target grid to place stacked signal TSV at grid (i, j) is defined as • Consider • Power density • High power density grid needs more stacked signal TSV to dissipate its heat.
Determination of Stacking Grid • Gain function to select our target grid to place stacked signal TSV at grid (i, j) is defined as • Consider • Number of TSVs • When TSVi,j,kis larger, fewer number of TSVs is in grid (i,j,k).
Determination of Stacking Grid • Gain function to select our target grid to place stacked signal TSV at grid (i, j) is defined as • Consider • Whitespace
Determination of Stacking Grid • Gain function to select our target grid to place stacked signal TSV at grid (i, j) is defined as • Consider • Wirelength • Wirelengthi,j,kis the wirelengthoverhead in tier k if stacking location is at grid (i,j). • smaller value of WL denotes higher wiring overhead. Move signal TSVs to the same 2D location across all tiers will change the routing topology and increase wiring overhead.
Experimental Result • 2005 IWLS benchmarks [20] and industrial circuits. • 3D placement results are produced by a partitioning driven placement for 3D ICs [5]. • minimize the total wirelengthand signal-TSV count
Experimental Result Extra hardware overhead !!! S.TSV : Total # of Stacked TSV
Conclusion • A new integrated architecture, stacked signal TSV, was developed to dissipate heat. • Based on this structure, a two-stage TSV locating algorithm has been proposed to construct the stacked signal TSVs and fully utilize the TSV thermal conductance to optimize the chip temperature. • Compared to previous thermal-TSV insertion method, our proposed algorithm has zero hardware overhead incurred by thermal-TSV.