MIKROE-957 mikroElektronika, MIKROE-957 Datasheet - Page 84

MIKROE-957

Manufacturer Part Number

MIKROE-957

Description

Other Development Tools ASLK PRO ANALOG DEVELOPMENT SYSTEM

Manufacturer

mikroElektronika

Datasheet

1.MIKROE-957.pdf (104 pages)

Specifications of MIKROE-957

Rohs

yes

Product

Analog System Lab Kit PRO

Tool Is For Evaluation Of

TL082, MPY634

Operating Supply Voltage

2.5 V to 5.5 V

Description/function

Analog Lab Kit for Undergraduate Engineering

Maximum Operating Temperature

+ 125 C

Minimum Operating Temperature

- 40 C

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Simulation models are very useful in the design phase of an electronic system.

Before a system is actually built using real components, it is necessary to perform

a ‘software breadboarding’ exercise through simulation to verify the functionality

of the system and to measure its performance. If the system consists of several

building blocks B1, B2, ..., Bn, the simulator requires a mathematical representation

of each of these building blocks in order to predict the system performance. Let us

consider a very simple example of a passive component such as a resistor. Ohm’s law

can be used to model the resistor if we intend to use the resistor in a DC circuit. But

if the resistor is used in a high frequency application, we may have to think about

the parasitic inductances and capacitances associated with the resistor. Similarly,

the voltage and current may not have a strict linear relation due to the dependence

of the resistivity on temperature of operation, skin effect, and so on. This example

illustrates that there is no single model for an electronic component. Depending

on the application and the accuracy desired, we may have to use simpler or more

complex mathematical models.

We will use another example to illustrate the above point. The MOS transistor,

which is the building block of most integrated circuits today, is introduced at the

beginning of the course on VLSI design. In a digital circuit, the transistor may be

simply modeled as an ideal switch that can be turned on or off by controlling the

gate voltage. This model is sufficient if we are only interested in understanding

the functionality of the circuit. If we wish to analyze the speed of operation of the

circuit or the power dissipation in the circuit, we will need to model the parasitics

associated with the transistors. If the same transistor is used in an analog circuit,

the model that we use in the analysis would depend on the accuracy which we want

in the analysis. We may perform different kinds of analysis for an analog circuit -

DC analysis, transient analysis, and steady-state analysis. Simulators such as SPICE

require the user to specify the model for the transistor. There are many different

models available today for the MOS transistor, depending on the desired accuracy.

The level-1 model captures the dependence of the drain-to-source current on the

gate-to-source and drain-to-source voltages, the mobility of the majority carrier,

the width and length of the channel, and the gate oxide thickness. It also considers

non-idealities such as channel length modulation in the saturation region, and the

dependence of the threshold voltage on the source-to-bulk voltage. More complex

models for the transistor are available, which have more than 50 parameters.

B.1 Micromodels

If you have built an operational amplifier using transistors, a straight-forward way

to analyze the performance of the OP-Amp is to come up with the micromodel of the

OPAMAP, where each transistor is simply replaced with its corresponding simulation

model. Micromodels will lead to accurate simulation, but will prove computationally

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intensive. As the number of nodes in the circuit increases, the memory requirement

will be higher and the convergence of the simulation can take longer.

A macromodel is a way to address the problem of space-time complexity mentioned

above. In today’s electronic systems we make use of analog circuits such as

are categorized into 17 different bins to make the selection simpler. However,

you will notice that 240 varieties are available in the category of Standard Linear

amplifers! How does a system designer select from this large collection? To

understand this, you must look at the characteristics of a standard linear amplifier

- these include the number of operational amplifiers in a single package, the

Gain Bandwidth Product of the amplifier, the CMRR, Vs (min), Vs (max), and so

on. See http://tinyurl.com/ti-std-linear. The website allows you to specify these

parameters and narrow your choices.

But how does one specify the parameters for the components? The overall

system performance will depend on the way the parameters for the individual

components have been selected. For example, the gain-bandwidth product of an

operational amplifier B1 will influence a system-level parameter such as the noise

immunity or stability. If one has n components in the system, and there are m

choices for each component, there are m·n possible system configurations. Even

if we are able to narrow the choices through some other considerations, we may

still have to evaluate several system configurations. Performing simulations using

micromodels will be a painstaking and non-productive way of selecting system

configurations.

B.2 Macromodels

A macromodel is a mathematical convenience that helps to reduce simulation

complexity. The idea is to replace the actual circuit by something that is simpler,

but is nearly equivalent in terms of input characteristics, output characteristics, and

feedforward characteristics. Simulation of a complete system becomes much more

simple when we use macromodels for the blocks. Manufacturers of semiconductors

provide macromodels for their products to help system designers in the process of

system configuration selection. The macromodels can be loaded into a simulator.

operational amplifiers, data converters, PLL, VCO, voltage regulators, and so on.

The goal of the system designer is not only to get a functionally correct design,

but also to optimize the cost and performance of the system. The system-level

cost and performance depend on the way the building blocks B1, B2,..., Bn have

been implemented. For example, if B1 is an OP-Amp, we may have several choices

of operational amplifiers. Texas Instruments offers a large number of operational

amplifiers that a system designer can choose from. Refer to Table B.1. As you

will see, there are close to 2000 types of operational amplifiers available! These

Analog System Lab Kit PRO

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MIKROE-957

Specifications of MIKROE-957

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