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G. Boselli, V. Ciriani, V. Liberali G. Trucco Dept. of Information Technologies

Terza giornata nazionale di sintesi logica. A comparison between different logic synthesis techniques from the digital switching noise viewpoint. G. Boselli, V. Ciriani, V. Liberali G. Trucco Dept. of Information Technologies Verona, 21 June 2007. Introduction.

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G. Boselli, V. Ciriani, V. Liberali G. Trucco Dept. of Information Technologies

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  1. Terza giornata nazionale di sintesi logica A comparison between different logic synthesis techniques from the digital switching noise viewpoint G. Boselli, V. Ciriani, V. Liberali G. Trucco Dept. of Information Technologies Verona, 21 June 2007

  2. Introduction • Mixed-signal integrated systems • Careful modeling of crosstalk between analog and digital sections • Disturbances injected by digital circuits can degrade overall system performance • Digital switching • Deterministic process, depending on circuit parameters and input signals • Huge number of logic blocks  cognitively stochastic process • Digital switching currents as stationary shot noise process • Amplitude distribution • Power spectral density

  3. Digital switching current • Proposed model valid under some hypotheses: • Transition activity of a logic gate independent of the activity of other gates • In fact, gate inputs are driven by other gate outputs • A large system contains a huge number of gates  each gate depends on a small number of neighboring cells • Logic transitions uniformely distributed in time • Correct for asynchronous digital systems • Synchronous system: transistion activity correlated with clock  more complex analysis • All logic transitions require the same time  all current pulses have the same finite time duration

  4. Stochastic model of digital switching noise (1) • Consider: • Asynchronous digital network • Identical logic cells driving equal capacitive loads • Switching instants of input signals applied to gates independent and randomly distributed in uniform manner • Digital switching noise as shot noise process • Switching instants of input signals as Poisson points

  5. Stochastic model of digital switching noise (2) • Input transition of logic gates as Dirac impulses • Train of impulses, taken at random instants • X(t): stochastic process representing the input transition of logic gates • Logic gates all equal (same IDD and ISS current absorption)  convolution between train of impulses X(t) and current absorbed by single logic gate h(t) = total current absorbed by the entire circuit I(t)

  6. Amplitude distribution of switching noise • Represented by the Probability Density Function (pdf, f(x)) of the stochastic process I(t) • Calculated from the pdf of the single current pulse • Arbitrary time instant t1 • pdf of the total current at time t1 depends on the number of Poisson impulses falling in the interval and the pdf of the single current pulse fH(x) where

  7. where • is the psd of logic transition impulses X(t) • H(f) is the Fourier transform of the impulse response h(t) Power spectral density of switching noise • Power Spectral Density (psd) of switching current: • h(t): current pulse, approximated with a triangular pulse  the charge Q transferred during the complete switching of a logic gate is equal to the area under the curve

  8. As a result of few calculations, we obtain • Term : dc component of digital switching power • Term : ac component of the power • More general expression: • : “pulse shape” factor, depending on the single current pulse waveform in time domain. whose normalized power is Normalized power of switching current

  9. Model validation • clip.pla: digital combinatory circuit included in the IWLS’93 benchmarks • synthesized using equal-delay gates in a 180-nm CMOS technology: inverter, 2-input NAND and NOR gates. • network made of about 130 logic gates. • inputs are driven with random digital signals; at any time, only one bit can change its logic value. • Transistor-level simulation with SPECTRE • values of the iDD current, sampled at 1-ps intervals, were stored for post-processing. • Two different average values of input transition rates, giving a low-density and a high-density switching activity. • the number of logic transitions at high-density transition is approximately ten times larger than the low-density transition.

  10. Model validation: amplitude distribution • Current waveforms exhibit triangular pulses • Simulated circuit gates with different capacitive loads  different current peaks (generalized Poisson process). • Amplitude density constant for intermediate values of current • For low current values the amplitude density is larger to account for pulse tails. • Peak values of the single current pulse assumed to be uniformly distributed between i2 and i3. Amplitude density of the single switching current pulse. Digital switching currents (low density of logic transitions).

  11. Amplitude distribution: results Simulated pdf of the iDD switching current (low and high density of logic transitions) Theoretical pdf of the iDD switching current (low and high density of logic transitions)

  12. Model validation: power spectral density Simulated psd of the iDD switching current (low and high density of logic transitions) Theoretical psd of the iDD switching current (low and high density of logic transitions)

  13. IDEA • To analyze different logic synthesis techniques from digital switching noise viewpoint • To apply the developed methodology to the same logic function, synthesized with different techniques • CLIP benchmark circuit: • Sop: ~ 770 MOS transistors • Xor: ~ 400 MOS transistors 16 transistors 6 transistors

  14. SOP subcircuits INVERTER NOR NAND

  15. XOR circuit • XOR asymmetric circuit • just in one case the output is connected to a supply node • In the other three cases XOR works as transfer gate • Differences which depends on what input signal switches

  16. Power dissipation • fewer MOS transistor= lower digital switching noise? • MOS transistor: • Static power dissipation • Dynamic power dissipation • It is important the number and the distribution of input signal commutation • Input files • Switching at random instants • At any time just one input signal can commutate

  17. Currents XOR SOP

  18. PDF SOP XOR

  19. PSD XOR SOP

  20. Conclusion • Digital switching noise as stochastic process • Faster estimation of digital switching noise, described by few parameters • Digital switching current as shot noise process • Amplitude density and power spectral density of switching currents derived • Circuit synthesized with XOR gates exhibits lower switching activity • Future development • Analysis for pseudo-synchronous circuits • Methodology to optimize the number and distribution of the commutations of logic gates

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