OPTIMAL ELECTRONIC CIRCUITS and MICROSYSTEMS NETWORKED DESIGNER

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OPTIMAL ELECTRONIC CIRCUITS and
MICROSYSTEMS NETWORKED DESIGNER

• Prof. ANATOLY PETRENKO
• National Technical University of Ukraine
• Kiev Polytechnic Institute,
  
• Tel./FAX 380 44 280 90 46,
• e-mail petrenko_at_cad.kiev.ua

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Outline

• Networked CAD tools
• International co-operation Experience
• ALLTED All Technology Designer
• Novel numerical methods
• Results of solving the benchmark circuits
• Optimization example
• AND Logical Circuit on OET
• Possible co-operation

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Networked CAD tools

• Remote access to CAD tools and collectively
  execution the joint Projects
• Meeting different requirements to hardware of a
  server and a client
• New level of functional cooperation via GRID
  infrastructure
• Possibilities for Small and Middle enterprises
  to take a part in international work force
  distribution developing competitive products.

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ALLTED All Technology Designer

• Previous versions of this system (named
  SPARS, PRAM-01, PRAM-PK, PRANS for EC and SM
  computers) were used in the former Soviet Union
  as the branch Ministry of the Defense industry
  standard OST V3-4776-80 for circuit design
  automation and similar standards for the
  Ministries of General and Average Machinobuilding
  and Radio industry.
• ALLTED is especially useful in the
  development of new products which combine various
  physical phenomena in one device

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International co-operation Experience

• Digital (Alpha Processor simulation)
• Intel (Parallel computation, Formal
  verification, Layout extraction, VLSI
  Interconnects Model-Order Reduction ,ALOE to
  Cadence / Cadence to ALOE converters )
• General Electric (MEMS Model design)
• Motorola ( Signal Processors implementation)
• Sun ( Layout verification)
• Panasonic (Remote Access to Networked Appliances
  )
• Melexes (VLSI design with 0.25 u)
• HPC Germany ( RF circuits design)
• EC Projects ( Tempus, Inco- Copernicus)
• STCU Projects ( Remote Simulation, MEMS Design)

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Layout visualization
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PostGL-3D Open GL Viewer
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ALLTED All Technology Designer

• ALLTED is an acronym for ALL TEchnology
  Designer. It was developed not only for
  simulation and analysis, but for processing
  project procedures such as
• parametric optimization tasks
• optimal tolerance assignments
• centering availability regions
• yield maximization
• design of Nonlinear Dynamic Systems composed of
  either/and electronic, hydraulic, pneumatic,
  mechanical, electromagnetic, and other elements.

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ALLTED All Technology Designer
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ALLTED Shematic editor
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ALLTED in distributed Web environment
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ALLTED usage examples
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ALLTED usage examples
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ALLTED usage examples
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ALLTED usage examples
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ALLTED usage examples
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ALLTED usage examples
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System on a Chip
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System on a Chip
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ALLTED offers

• Faster simulation speed and improved numerical
• convergence
• Sensitivity analysis for frequency and
  transient analyses
• Comprehensive optimization procedure and optimal
  tolerances assignment
• Alternative approach to the secondary response
  parameters determination (delays, rise and fall
  times, etc.)
• Powerful user-defined modeling capability .
• Original way of generating a system-level model
  of MEMS from FEM component equations.

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Novel numerical methods

• The new solution curve-search method for Steady
• State (DC) Analysis which provides the quick
  descent to the solution point region from any
  starting point
• The Diagonal Modification Method which helps
  considerably preserve convergence of linearized
  equations solution without re-ordering when
  matrix element values change from one iteration
  to another iteration .
• The Optimization Variable-order Methods which is
  equivalent to taking into consideration five
  terms of Tailors series for the Goal function
  which considerably improve determination of a
  direction to the optimal point

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Novel numerical methods

• The Implicit Linear Multi-step Variable-order
  Integration Method for Transient Analysis(TR)
  which uses high order back differences that
  allows to select the proper one resulting in
  minimization of solution time for prescribed
  accuracy .
• The Optimal Tolerances Assignment Method which is
  based on applying Optimization procedures and
  takes into account the prescribed deviations of
  Controlled Output Parameters
• Statistical Yield Maximization Method which
  provides centering the solution point in the
  region of acceptable solutions

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DC Method Example 1
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Diagonal modification method
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TR solution approach
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Optimization Variable order method
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INTEL AWARD
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Results of solving the benchmark circuits of the
Microelectronics Center in North Carolina

• Circuit ALLTED PSPICE
  Gain
• Iteration
  Iteration
• INPUT 358 755
  2.11
• CHARGE 4682 7625 1.63
• FADD32 873 2280 2.61

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CHARGE Circuit with BISIM 49 Models
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ALLTED and PSPICE v.9.2 outputs
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FADD32 Circuit (288 transistors)
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ALLTED and PSPICE v.9.2 outputs
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Simulation results obtained by ALLTED and HSPICE
Circuit DC Iteration number, ALLTED DC Iteration number, HSPICE TR Iteration number, ALLTED TR Iteration number, HPSPICE
Bjtinv 95 96 1340 3239
Gm3 80 185 149 219
Make2 12 10 527 but 256 steps 327 outputs are distorted
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MIKE2 Circuit with bsim13 models
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ALLTED and HSPICE outputs for Mike2_bisim13
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ALLTED statistics of the transient analysis of
Mike 2

• S t a t i s t i c s
• Number of steps
  256
• Number of iterations
  528
• Number of steps per order
• order - 0 -
  26
• order - 1 -
  46
• order - 2 -
  90
• order - 3 -
  71
• order - 4 -
  19
• order - 5 -
  4
• order - 6 -
  0
• Number of rejected steps
  23
• HSPICE uses only 2-d order integration formula

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Optimization example 1

Circuit Operational Amplifier RCA 3040 with
11 transistors Task calculate the resistances
R1, R3 and R4 values in such a way, that the
output impulse amplitude on resistor R11 would
be equal to 8 V. 0.1      
lt        R1       lt        10
0.1K    lt        R3       lt         10
0.1K    lt        R4       lt         10K

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Optimization example 1

• Task file
• tr
• optim
• const DCERR1.e-6
• const tmax90, MINSTEP1e-4, ERR0.01, LERR0.1,
  REVAL3
• TR OUTPUT parameters
• fix T3MINF(UR11)
• fix T4MAXF(UR11)
• INT DURFT4-T3
• const method120
• varpar R1(0.01,10), R3(1,100), R4(1,100)
• of DIF1 F1(8/DURF)
• plot Ur11

• Objective function
• DIF1 .3146487870E-07
• R E S U L T S O F O P T I M I Z A T I O N
• Variable parameters
• R1 .1000000000E01
• R3 .6778549874E01
• R4 .6778549874E01
  Directive F I X output characteristics
• T3 2.47580528
• T4 10.4756279
• Directive I N T output characteristics
  
• DURF 7.99982262

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Optimization example 2

• Circuit Active RC filter RAD
• Task
• dc
• ac
• optim
• const lfreq0.0025, ufreq0.005,METHOD152
• TF K1V6/UE1
• plot MA.K1
• fix f1MAXA(MA.K1)
• fix f2MAXF(MA.K1)
• func f5F7(1/f2)
• of errorf5(1/f5)
• varpar Alpha.OP1(3E1,4E3), Alpha.OP2(0.6E1,1E3)
• limit Lim2F2(0.003734/f1)

ALPHA.OP1 ALPHA.OP2 0.3709765013D04 0.1000000000D04
Constraints
LIM2
RESULTS OF OPTIMIZATION ERROR
0.1786038652D-01 Variable parameters
ALPHA.OP1 0.3709765013D04 ALPHA.OP2
0.1000000000D04
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Interactive Tasks formation
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Optimal tolerance assignment example Circuit
Operational Amplifier RCA 3040 with 11
transistors Task calculate the resistances R2,
R3 and voltage source E2 tolerances values for
which the output minimal voltage UR11 changes
/- 5 of its value.

task dc tr tolas const tmax90 ,ERR0.01,
LERR0.1, REVAL3 FIX UMminf(UR11) const
TOLERR0.001 control UM(5,5) varpar
E2(10),R2,R3(10)
O P T I M A L T O L E R A N C E S
Parameter
Nominal
Tolerance value
abs E2
.1200000000E02 - 19.682 -
-.2361829758E01 R2 .1000000015E00 -
4.614 - .4613934550E-02 R3
.1000000000E01 - 3.697 -
.3696829081E-01
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Mixed Analyses example

Macromodel 2-input AND Cell (0,1,2,3)
j1(1,0)f300(ut,rbx/uj1) j2(2,0)f300(ut,rbx/uj2
) e1(3,0)f310(u1,u0,f1,d1,f0,d0,r1,r0,-1/ue1,ie
1) list m1.icand rbx50 ut1 u00.3
u12.4 f1-1 d110 f0-1 d010
r10.1 r00.02
Now we are going to provide possibilities for
users to access NetALLTED resources through the
Internet for optimal Microsystems design.
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The example of Micro-machined Ultrasonic
Transducer simulation


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AND Logical Circuit on OET
One-electron transistor model
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Microwave Devices in ALLTED

• Model of transmission line with a negative
  inductance

Fig. 8 The
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ALLTED adaptation to a new application

• New components mathematical models incorporating
  ( in equations form)
• New graphical symbols for components, if any
• New sections in library with components
  parameters
• OF, LIMIT and FUNC libraries upgrading
• if any
• Numerical procedures constants adjusting for new
  types of tasks

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MEMS Simulation level
System level
Circuit level
Components level
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Model Order reduction

(Krylov- Arnoldi Method)
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Circuit model reduction method
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Y/? transformation
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Y/? transformation

• ??? ???????? 2-? ? 3-? ???????? ???????????
  ?????? ?????? ?????? ???? ???? ??????
  ???????????, ???? ?? ????????? ??? ?????
  ???????????

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Y/? transformation

• ??? ???????? 2-? ? 3-? ???????? ???????????
  ?????? ?????? ?????? ???? ???? ??????
  ???????????, ???? ?? ????????? ??? ?????
  ???????????

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Microaccelerometer
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The finite element model of the accelerometer
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Eigenfrequencies of Microaccelerometer
n 2 f 1018,1 kHz
n 1 f 181,36 kHz
n 3 f 1018,1 kHz
n 4 f 3427,8 kHz
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Electrical Circuit Reduction Results
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Possible Project Tasks

• ALLTED facilities Testing on Samsung Examples
  (optimization, tolerance assignment, yield
  maximization, DC conversion, RF design etc.)
• Adaptation and enrichment of ALLTED component
  models Library (including new ones, say, for CCD
  , MEMS and IP Solutions), using semantic formats
• Developing parallel numerical simulation
  algorithms for a supercomputer
• Implementation of parallel ALLTED version in Grid
  environment and providing possibilities of
  remote its executing through Internet
• Development of the methodology of IC energy
  consumption minimization based on ALLTED
  optimization procedures (say, by varying W and L
  of transistors and keeping the given frequency
  value).

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Thanks you very much !