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Design Economics

Design Economics. Design Economics. IC designer should able to predict the cost and the time to design a particular IC. This guides the choice of implementation strategy. Selling price S total = C total / (1-m) Where m = profit margin and C total = total cost

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Design Economics

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  1. Design Economics

  2. Design Economics • IC designer should able to predict the cost and the time to design a particular IC. • This guides the choice of implementation strategy. • Selling price Stotal = Ctotal / (1-m) Where m = profit margin and Ctotal = total cost • Cost to produce an IC are divided into: • Nonrecurring engineering costs (NRE) • Recurring costs • Fixed costs

  3. Non-recurring Engineering Costs • Cost once spent during the design of an IC, they include: • Engineering design cost • Prototype manufacturing cost • i.e., Ftotal = Etotal + Ptotal • NRE can be viewed as an investment for which there is a required rate of return. • Engineering design costs, include: • Personnel costs • Support costs • Prototype manufacturing costs, include: • Mask cost • Test fixture costs • Package tooling

  4. The personnel cost include labor for: • Architectural design • Logic capture • Simulation for functionality • Layout of modules and chip • Timing verification • DRC and tapeout procedures • Test generation • The support costs are: • Computer costs • CAD software costs • Training

  5. Recurring Costs • The cost that recurs every time an IC is sold. • The total cost is Ct = Cprocess + Cpack + Ctest • Cprocess = W / (N.Yd.Ypack.) • Fabrication • Wafer cost / (Dice per wafer * Yield) • Wafer cost: $500 - $3000 • Dice per wafer: • Yield: Y = e-AD • For small A, Y  1, cost proportional to area • For large A, Y  0, cost increases exponentially • Packaging • Test

  6. Fixed Costs • Data sheets and application notes • Marketing and advertising

  7. Schedule • Estimate the design cost and design time for the system. • Selecting the strategy by which the ICs will be available in the right time and price. • Experienced person. • To estimate schedule some idea of the amount effort required to complete the design. • Schedule is a function of personpower. • Methods for improving the schedules: • Using a high productivity design method • Improving the productivity of a given technique • Decreasing the complexity of the design task by partitioning

  8. Personpower • Tasks required are: • Architectural design • HDL capture • Functional verification • PAR • Timing verification, signal integrity, reliability verification • DRC and tapeout procedures • Test generation

  9. Example • You want to start a company to build a wireless communications chip. • How much venture capital must you raise? • Because you are smarter than everyone else, you can get away with a small team in just two years: • Seven digital designers • Three analog designers • Five support personnel

  10. Digital designers: salary overhead computer CAD tools Total: Analog designers salary overhead computer CAD tools Total: Support staff salary overhead computer Total: Fabrication Back-end tools: Masks: Total: Summary Solution

  11. Digital designers: $70k salary $30k overhead $10k computer $10k CAD tools Total: $120k * 7 = $840k Analog designers $100k salary $30k overhead $10k computer $100k CAD tools Total: $240k * 3 = $720k Support staff $45k salary $20k overhead $5k computer Total: $70k * 5 = $350k Fabrication Back-end tools: $1M Masks: $1M Total: $2M / year Summary 2 years @ $3.91M / year $8M design & prototype

  12. Cost Breakdown • New chip design is fairly capital-intensive • Maybe you can do it for less?

  13. Special-purpose Subsystems

  14. Agenda • Packaging • Package options • Chip-to-package connections • Package parasitics • Heat dissipation • Power Distribution • On-chip power distribution network • Supply noise • I/O • Basic I/O pad circuits • Clock • Clock system architecture • Global clock generation & distribution • Local clock gaters

  15. Packaging • Package functions: • Electrical connection of signals and power from chip to board, with little delay or distortion • Mechanical connection of chip to board • Removes heat produced on chip • Protects chip from mechanical damage • Compatible with thermal expansion • Inexpensive to manufacture and test

  16. Package Options • Through-hole vs. surface mount

  17. Multichip Modules • Pentium Pro MCM • Fast connection of CPU to cache • Expensive, requires known good dice

  18. Chip-to-Package Bonding • Traditionally, chip is surrounded by pad frame: • Metal pads on 100 – 200 mm pitch • Gold bond wires attach pads to package • Lead frame distributes signals in package • Metal heat spreader helps with cooling

  19. Advanced Packages • Metal leads contribute parasitic inductance and coupling capacitors to their neighbors • Fancy packages have many signal, power layers • Like tiny printed circuit boards • Flip-chip places connections across surface of die rather than around periphery • Top level metal pads covered with solder balls • Chip flips upside down • Carefully aligned to package (done blind!) • Heated to melt balls • Introduces new testing problems

  20. Package Parasitics • Use many VDD, GND in parallel • Inductance, IDD

  21. Bond wires and lead frame contribute parasitic inductance to the signal traces. • They also have mutual inductance and capacitive coupling to nearby signal traces, causing crosstalk when multiple signal switch. • VDD & GND wires also have inductance from both bond wires and lead frame. • They have nonzero resistance, which becomes important for chips drawing large supply current • High performances packages often include bypass capacitors between VDD & GND.

  22. Heat Dissipation • 60 W light bulb has surface area of 120 cm2 • Itanium 2 die dissipates 130 W over 4 cm2 • Chips have enormous power densities • Cooling is a serious challenge • Advances in heat sinks, fans, packages have raised the practical limit for heat removal from about 8 W in 1985 to nearly 100 W today for affordable packaging. • Package spreads heat to larger surface area • Heat sinks may increase surface area further • Fans increase airflow rate over surface area • Liquid cooling used in extreme cases ($$$)

  23. Thermal Resistance • Temperature difference between transistor junctions and the ambient air is, DT = qjaP • DT: temperature rise on chip • qja: thermal resistance of chip junction to ambient • P: power dissipation on chip • Thermal resistances combine like resistors • Series and parallel • qja =qjp +qpa • Series combination

  24. Example • Your chip has a heat sink with a thermal resistance to the package of 4.0° C/W. • The resistance from chip to package is 1° C/W. • The system box ambient temperature may reach 55° C. • The chip temperature must not exceed 100° C. • What is the maximum chip power dissipation? • Solution is (100-55 C) / (4 + 1 C/W) = 9 W

  25. Power Distribution • Power Distribution Network functions: • Carry current from pads to transistors on chip • Maintain stable voltage with low noise • Provide average and peak power demands • Provide current return paths for signals • Avoid electromigration & self-heating wearout • Consume little chip area and wire • Easy to lay out

  26. Power Requirements • VDD = VDDnominal – Vdroop • Want Vdroop < +/- 10% of VDD • L di/dt of bond wire and IR drop across on-chip wires are often a major source of supply noise • Sources of Vdroop • IR drops • L di/dt noise • IDD changes on many time scales

  27. IR Drops: • Resistance of power supply network includes: • resistance of the on-chip wires and vias, • resistance of bond wires or solder bumps to the package, • resistance of the package planes, • resistance of the PCB planes • IR drops arise from both average and instantaneous current requirements. Ldi/dt Noise: • Inductance of power supply dominated by the inductance of the bond wires • Modern packages devote many of their pins to power and ground to minimize supply inductance • Two sources of current transients are switching I/O signals and changes between idle and active mode in the chip core

  28. On-chip Bypass Capacitance • The bypass capacitance is distributed across the chip so that a local spike in current can be supplied from nearby bypass capacitance rather than through the resistance of the overall power grid. • power distribution network doesn’t really need to carry all of the peak current. • Much of the difference between peak and average current may be supplied by local, on-chip bypass capacitors. • On-chip bypass capacitors can reduce the amount of metal needed for distribution. • It also greatly reduces the di/dt drawn from the package.

  29. Symbiotic Bypass Capacitors • Where are the bypass capacitors in this picture? • Gates that are not switching at a given instant in time act as symbiotic bypass capacitors • If only one gate in 60 switches at a given instant, the bypass capacitance is 30 times the switched capacitance

  30. Power System Model • Power comes from regulator on system board: • Board and package add parasitic R and L • Bypass capacitors help stabilize supply voltage • But capacitors also have parasitic R and L • Simulate system for time & frequency responses

  31. Input / Output • Input/Output System functions: • Communicate between chip and external world • Drive large capacitance off chip • Operate at compatible voltage levels • Provide adequate bandwidth • Limit slew rates to control di/dt noise • Protect chip against electrostatic discharge • Use small number of pins (low cost)

  32. I/O Pad Design • Pad Types: • VDD and GND • Output • Input • Bidirectional • Analog

  33. VDD and GND Pads • High-performance chips devote about half of their pins to power and ground. • This large number of pins is required to carry the high current and to provide low supply inductance. • Largest sources of noise in many chips is the ground bounce caused when the output pads switch. • The pads must rapidly charge the large external capacitive loads, causing a big current spike and high Ldi/dt noise. • The dirty power and ground lines serving the output pads are separated from the main power grid to reduce the coupling of I/O-related noise into the core.

  34. Output Pads • Drive large off-chip loads (2 – 50 pF) • With suitable rise/fall times • Requires chain of successively larger buffers • Output transistors have gates longer than normal to prevent avalanche breakdown damage and over voltage is applied to the drains. • Guard rings to protect against latchup • Noise below GND injects charge into substrate • Large nMOS output transistor • p+ inner guard ring • n+ outer guard ring • In n-well

  35. Input Pads • Level conversion • Higher or lower off-chip V • May need thick oxide gates • Noise filtering • Schmitt trigger • Hysteresis changes VIH, VIL • Protection against electrostatic discharge

  36. ESD Protection • Static electricity builds up on your body • Shock delivered to a chip can fry thin gates • Must dissipate this energy in protection circuits before it reaches the gates • ESD protection circuits • Current limiting resistor • Diode clamps • ESD testing • Human body model • Views human as charged capacitor

  37. Bidirectional Pads • Need tristate driver on output: • Use enable signal to set direction • Optimized tristate avoids huge series transistors • Improved tri-state • buffer

  38. Analog Pads • Pass analog voltages directly in or out of chip: • No buffering • Protection circuits must not distort voltages

  39. Clocking • Synchronous systems use a clock to keep operations in sequence • Distinguish this from previous or next • Determine speed at which machine operates • Clock must be distributed to all the sequencing elements • Flip-flops and latches • Also distribute clock to other elements • Domino circuits and memories

  40. Clock Distribution • On a small chip, the clock distribution network is just a wire • And possibly an inverter for clkb • On practical chips, the RC delay of the wire resistance and gate load is very long • Variations in this delay cause clock to get to different elements at different times • This is called clock skew • Most chips use repeaters to buffer the clock and equalize the delay • Reduces but doesn’t eliminate skew

  41. Review: Skew Impact • Ideally full cycle is available for work • Skew adds sequencing overhead • Increases hold time too

  42. Solutions • Reduce clock skew • Careful clock distribution network design • Plenty of metal wiring resources • Analyze clock skew • Only budget actual, not worst case skews • Local vs. global skew budgets • Tolerate clock skew • Choose circuit structures insensitive to skew

  43. Clock Skew Sources • Clock Skew Sources are: • systematic, • random, • drift, and • jitter • Note some engineers do not report jitter as part of the skew.

  44. Example • Skew comes from differences in gate and wire delay • With right buffer sizing, clk1 and clk2 could ideally arrive at the same time. • But power supply noise changes buffer delays • clk2 and clk3 will always see RC skew

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