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L
INEAR
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EVICES,
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INTRODUCTION
As today's analog systems become more sophisticated, complex
and precise, and as industrial, instrumentation, telecom and au-
tomoti ve electronic control systems need to perform more func-
tions, it becomes increasingly cost effecti ve to integrate compo-
nents such as op amps, comparators, digital logic, etc. into a
single Application Specific IC. While microelectronics tech-
nology have increased in capability, it is also increasingly com-
ple x, and expensi ve. It has become necessary to hav e better and
faster eng ineering tools to tackle these higher level design c hal-
lenges, while decreasing the time to market.
In examining a typical design process, the design task usually
starts conceptually with an outline of desired capabilities, speci-
fications and features of the system. After design concept has
been established, One of the critical steps in the design process,
namely the prototype functional implementation and e v aluation
requires that individual functional blocks be specified, and that
individual components specifications be evaluated as to their
effect upon overall system performance.
It is at this lev el of design that the designer needs to know quickly
what functions, components, and particular specifications are
suitable and how they effect the system performance, and be
able to determine whether or not these components will per-
form the function within required system specifica tions. Once
these selections are made, the circuit design can be synthesized
and developed further.
Finally, a prototype breadboard can be constructed to test the
design concept, and gather data that are unattainable otherwise
and facilitate further circuit evaluation. Changes, corrections,
and improvements can clearly be evaluated. In order to recon-
cile any dif ferences between the design goal and the breadboard
implementation, not only the functionality of the breadboard
has to be adequate, but any incompatibilities or inconsistencies
between the various components must be resolved.
The design task takes on an additional dimension w hen analog
components are used and especially when such parameters as
tempco, offset voltages, and offset currents, noise, gain, device
matching, tracking of voltages and currents, power supply re-
jection ratio, and common mode rejection ratio become impor-
tant to the proper operation of the system.
Integration of these analog components into a single custom
monolithic IC while addressing these issues can become a daunt-
MACROMODELS THAT SPEED SOFTWARE SIMULATION
BECOME A USEFUL PRE-BREADBOARDING TOOL
ing task. And yet to reduce space, simplify manufacturing, reduce
parts count, and to reduce time to market, the designer often must
look towards an ASIC implementation. The pressure to integrate
mounts especiall y when production v olumes are seen to increase. At
that point, if the or iginal prototype design was done without due con-
sideration for integration, a complete redesign is usually necessary.
ALD ASIC PROGRAM
To address the situation mentioned above, Advanced Linear Devices
(ALD) of Sunnyvale, California has embarked on a two prong ap-
proac h to provide the designer with inexpensive, common sensed tool
that provides a powerful mixed signal ASIC design en vironment while
still providing the component level design and prototype parts for an
off the shelf low to medium volume design. Essentially a prototype
and low volume solution with the ease of integration without a rede-
sign.
First, ALD provides a design kit consisting of predesigned and pre-
fabricated analog functional bloc ks that have been completely tested
and c haracterized, these parts are standard parts, complete with char-
acterization curves and specifications. These analog functions are
not only useful in breadboarding for functionality but also useful in
determining any potential second or der effects that ma y affect per-
formance of the final system.
The question arises: If these analog cell are so well designed and
engineered to be adequate for this purpose, then w hy not sell these
blocks as a standard pr oduct? Indeed that's exactly what ALD has
done. They have made their standard packaged parts available as
standard cell integrated components. These products are a v ailable as
packaged parts or as ASIC functional blocks. ALD guarantees that
all of their products are fully compatible with each other on the same
chip. These products, therefore are available for prototyping, vol-
ume manufacturing or as ASIC components.
Second, ALD has also developed a unique family of macromodels,
subcircuits, and components that are fitted to their processing param-
eters. They are designed to be compatible with PSPICE and most
other SPICE based circuit simulators. These macromodels have been
de veloped specifically to ease the burden of the system designer when
utilizing the ALD products for board level design or for designing
breadboard/prototype for ASI implementation.
With these models, it now has become practical to simulate an ana-
log board level system on a personal computer. In addition a bread-
board using the actual IC components can be constructed. Due to the
complexity of most applications, utilizing hundreds of transistors,
the macro-model approach allows a designer to simulate develop a
415 Tasman Drive Sunnyvale, CA 94089-1706 (T) 408.747.1155 (F) 408.747.1286 (E-mail) sales@aldinc.com (Website) www.aldinc.com
system-on-a-chip using both software and hardwar e tools, thus per-
forming trial and error experimentation on the personal worksta-
tion as well as on the lab bench. Of cour se, the final design will
only be as good as what the designer can measure or predict using
simulation and breadboar d measurements. With simulation added
to the design verification process, convergence upon a design so-
lution is rapid. In addition, this approach allo ws the manufacturer
the possibility to verify his system through actual field tests, lim-
ited production, and beta test sites, before committing to the ex-
pensive of custom IC production.
Actual chip level experimentation and mask iteration are not only
costly, b ut as systems g et increasingl y complex, the probability of
a designer actually developing a w orking ASIC system under the
time and budget constraints diminishes. For complex analog or
mixed analog digital system development intended for ASIC imple-
mentation, the ability to inexpensively and quic kly do design it-
erations and measurements, whether on a computer station, or on a
breadboard, is vital to the ultimate success of the project.
Of course , the a bility to do both software and hardware iteration
produces a desirable combination for engineering analysis. For
certain situations, a quick run on a computer simulator can verify a
circuit conf iguration that performs an intended function. Unfortu-
nately , nice , idealized g raphs presented on a computer terminal do
not always represent actual circuit behavior and in many analog
systems full simulation with regard to all parametric behavior is
impractical if not impossible.
For other situations, such as to verify signal levels and timing of
interface between the ASIC and other board components such as
transducers, and to "feel" the adequac y of an analog signal, a bread-
board as an actual hardware simulator can prove superior as an
engineering tool. When all the pieces of individual subcircuits are
simulated or designed, the time comes to put them together and
verify that they perform as a system. This is a time when a de-
signer needs all the engineering tools at his disposal. As software
simulators and models may assist in spotting problems early on,
hardw are simulators and real hardware help other problems to show
up. This two prong approach to circuit development eliminates
redundant engineering effort when an ASIC needs to be imple-
mented later in a production cycle.
A design initially developed with this approach would not need
additional engineering effort when its time to integrate. More im-
portantly , this approach cut out most of the technical risks of ASIC
implementation because the designer has close feedback and abil-
ity to observe and measure the actual as well as the simulated sys-
tem. Thus the often sta ted goal of a quick implementa tion onto an
ASIC chip can be easily handled as the need and justification de-
velops.
EASY ASIC BREADBOARDING FOR AN ASIC
A vailable from ALD is a design kit that contains a box full of ana-
log IC par ts such as operational amplifiers, comparators, oscilla-
tors and transistors that allow a designer to develop custom cir-
cuitry. Also available from ALD is a proprietary library of
macromodels of these specific analog IC parts de veloped for a stan-
dard SPICE circuit simulator such as PSPICE, in addition a design
manual that contains complete information and useful hints is pro-
vided.
When working with the kit, one can design and sim ulate using the
ASIC library components or breadboard these circuits with Ad-
vanced Linear Devices' standard par ts. The designer can use any
number of analog cells fr om the design kit and in any configura-
tion desired, and later decide on the package or pinout for an ASIC
part. Since ALD's ASIC program is semicustom standard cell ap-
proach, ther e is no rigid limitation on how man y instances of any
of function block, pins, components or even the values used.
Furthermore, digital logic such as HC, 74C and CD4000 family
parts can also be used in the software simulator as well as the hard-
ware prototype . Many software circuit simulator suppliers already
supply dig ital parts by individual par t numbers in their digital li-
brary. These digital parts simulate the logic and performance of,
say, a CD4027 Dual JK Flip-Flop. ALD has developed functional
equiv alent digital cells in its computer libr ary that will perform the
identical logical functions.
A custom prototype system designed around using these generic
digital part types along with analo g parts supplied by ALD can be
readily implemented into an ASIC with virtually no performance
differences. With this complete libr ary of digital MSI functions
such as counters, encoders and decoders, no logic conversion is
necessary from standard part type to implementation of the ASIC.
All digital circuit blocks in ALD's digital library perfor m identical
functions to the generic part types in the simulation library.
Backgound on macromodels
An operational amplifier modeled with detailed transistor level
parameters and cir cuitry may run for five or six hours equivalent
CPU time based on a Pentium class personal computer for each
parametric iteration. W ith several amplifiers and tens or hundr eds
of simulations with perhaps dozens of parameters each requiring
multiple passes to run in order to completely analyze or optimize
an analog system design, analysis of these systems can readily
overwhelm available computer resources.
In addition, many simulation induced problems tend to creep up
using detailed transistor operational models. These problems in-
clude setting the correct internal node conditions, non-converg ence
of the circuit and simulation induced oscillation. In analog simu-
lation, where signal amplif ication, precision v oltages and feedback
are common circuit parameters, circuit behavior of a specific cir-
cuit block may depend not only on the transistor models and the
simulators used, but also on user specified iteration limits and tol-
erances. If these limits are set improperly, circuit may take hours
to converge, generate useless data, or terminate abruptly in the
middle of the simulation.
In the integration of a complex ASIC w here sev eral complex func-
tional blocks are used, a detailed tr ansistor lev el simulation is sim-
415 Tasman Drive Sunnyvale, CA 94089-1706 (T) 408.747.1155 (F) 408.747.1286 (E-mail) sales@aldinc.com (Website) www.aldinc.com
ply impractical. A macromodel that emulates the behavior of the
operational amplif ier, on the other hand , can be sim ulated in a few
seconds. Macromodels have been developed for the purpose of
simulation of a function block while using minimum computer
memory and CPU time and still provide adequate functional emu-
lation.
These are generally compositions of simple idealized elements, as
opposed to indi vidual transistor le vel models, this reduces the ma-
trix of variables that needs to be iterated on a computer station.
These macromodels ha ve been developed to perf orm the simulate
the function of indi vidual functional blocks. Ideal circuit elements
like ideal voltage controlled current sources are used to emulate
these amplifiers Also a set of equations in the simulator can emu-
late the behavior of an operational amplifier.
In many cases, the r eal difficulty in using this approach stems from
the fact tha t a real life operational amplifier may not be so "ideal"
in beha vior . As an y design engineer would attest, a r eal life circuit
can ha ve idiosyncrasies, behaviors and ca pabilities that can be dif-
ferent from the ideal, resulting in unintended behavior. The most
noteworthy of these differences can be incorporated into the
macromodel in order to better model the actual beha vior of a cir-
cuit. However, in the case of second or der effects like nonlinear
parametric changes, where a matrix of equations or even the best
macromodel may not accurately descr ibe actual circuit behavior,
the user would be w ell advised to check out his circuit with a bread-
board after simulation is completed.
Notwithstanding these limitations, in many applications a f irst or -
der macromodel can prov e adequate as a circuit analysis tool. These
macromodels, when carefully engineered and constructed, provide
the user with a convenient intermediate ste p where analysis com-
ple xity goes be yond paper and pencil, and the circuit function may
not yet be ready for breadboard construction in the laboratory.
Macromodels used in a simulators can and do give quick first or-
der tr ial analysis of the ability of a circuit conf iguration to perform
a given task. If a user also has working experience with an actual
part, and has developed intuition and feel to use it pr operly, then a
combination of the capabilities of computer simulation and bread-
boarding can be indeed a powerful engineering tool set indeed.
ALD-simulation model libraries
ALD models are designed to support board le vel macro simulation
such as PSPICE simulation where packaged circuit elements such
as transistors, operational amplifiers, MSI and SSI logic functions,
counters, latches, and gates are used. These are components tha t
one would normally put on a circuit board to prototype a system.
For ALD ASIC implementation, all chip macromodels and circuit
elements should be partitioned from other circuit elements. Parti-
tioning of the system involves no more than determining connec-
tion points between circuit elements that are intended on-chip and
those tha t are off-chip. ALD supplies a SPICE library designed for
ASIC integration that contains detailed SPICE circuit models of
analog integrated components like resistors, capacitors, diodes, tran-
sistors and of course all the major macro-models of functional
blocks of the standard integratible par ts. Once a partition of the
system is made, into on ASIC components, and off chip compo-
nents, then a sim ulation of the proposed ASIC can be done- in-
cluding the designers off chip components.
The circuit elements used in a simulator can be divided into four
major categories: ALD analog standard part macr omodels, ALD
ASIC element macromodels, digital function models and standard
vendor supplied PSPICE models.
ALD analog cell macromodels consists of a library of macromodels
of ALD standard parts including operational amplifiers, voltage
comparators, timers, oscillators, volta ge references and transistors.
These macromodels can also be used in applications where ASIC
implementation is not planned. ALD ASIC element macromodels
include diodes, transistors, zener diodes, input protection circuits,
and on-chip integrated resistors and capacitors. These element
models are only needed where an on-chip ASIC implementa tion
of these elements are planned.
Digital function models are specifically standard CMOS logic fam-
ily functions including, at present, HC logic family (5V only), 74C
logic family, and CD4000 logic family (5V to 12V). These com-
ponents and their models are widely available from a variety of
sources. Users can incorporate these functions into the their simu-
lator . ALD has these digital functions in its ASIC library r eady for
ASIC implementation.
Standard vendor supplied models are models of other circuit ele-
ments, such as a relay, microphone, piezoelectric crystal, or an
I.C. that is out of the scope of the ALD ASIC inte gratible library.
PSPICE provides a large selection of generic parts composed by
various vendors. These circuit elements can be used with the cir-
cuit simulator and the circuit breadboard but would not be included
in the ASIC chip.
