CA3130AT INTERSIL [Intersil Corporation], CA3130AT Datasheet - Page 8

CA3130AT

Manufacturer Part Number

CA3130AT

Description

15MHz, BiMOS Operational Amplifier with MOSFET Input/CMOS Output

Manufacturer

INTERSIL [Intersil Corporation]

Datasheets

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factor in shunting the source resistance. It should be noted,

however, that for values of source resistance very much

greater than 1M , the total noise voltage generated can be

dominated by the thermal noise contributions of both the

feedback and source resistors.

Typical Applications

Voltage Followers

Operational ampliﬁers with very high input resistances, like

the CA3130, are particularly suited to service as voltage

followers. Figure 8 shows the circuit of a classical voltage

follower, together with pertinent waveforms using the

CA3130 in a split-supply conﬁguration.

A voltage follower, operated from a single supply, is shown in

Figure 9, together with related waveforms. This follower

circuit is linear over a wide dynamic range, as illustrated by

the reproduction of the output waveform in Figure 9A with

input-signal ramping. The waveforms in Figure 9B show that

the follower does not lose its input-to-output phase-sense,

even though the input is being swung 7.5V below ground

potential. This unique characteristic is an important attribute

in both operational ampliﬁer and comparator applications.

Figure 9B also shows the manner in which the CMOS output

stage permits the output signal to swing down to the

negative supply-rail potential (i.e., ground in the case

shown). The digital-to-analog converter (DAC) circuit,

described later, illustrates the practical use of the CA3130 in

a single-supply voltage-follower application.

9-Bit CMOS DAC

A typical circuit of a 9-bit Digital-to-Analog Converter (DAC)

is shown in Figure 10. This system combines the concepts of

multiple-switch CMOS lCs, a low-cost ladder network of

discrete metal-oxide-ﬁlm resistors, a CA3130 op amp

connected as a follower, and an inexpensive monolithic

regulator in a simple single power-supply arrangement. An

additional feature of the DAC is that it is readily interfaced

FIGURE 7. TEST-CIRCUIT AMPLIFIER (30-dB GAIN) USED

BW (-3dB) = 200kHz

TOTAL NOISE VOLTAGE (REFERRED

TO INPUT) = 23 V (TYP)

FOR WIDEBAND NOISE MEASUREMENTS

47pF -7.5V

+7.5V

0.01

0.01 F

30.1k

VOLTAGE

OUTPUT

NOISE

CA3130, CA3130A

with CMOS input logic, e.g., 10V logic levels are used in the

circuit of Figure 10.

The circuit uses an R/2R voltage-ladder network, with the

output potential obtained directly by terminating the ladder

arms at either the positive or the negative power-supply

terminal. Each CD4007A contains three “inverters”, each

“inverter” functioning as a single-pole double-throw switch to

terminate an arm of the R/2R network at either the positive

or negative power-supply terminal. The resistor ladder is an

assembly of 1% tolerance metal-oxide ﬁlm resistors. The ﬁve

arms requiring the highest accuracy are assembled with

series and parallel combinations of 806,000 resistors from

the same manufacturing lot.

A single 15V supply provides a positive bus for the CA3130

follower ampliﬁer and feeds the CA3085 voltage regulator. A

“scale-adjust” function is provided by the regulator output

control, set to a nominal 10V level in this system. The line-

voltage regulation (approximately 0.2%) permits a 9-bit

accuracy to be maintained with variations of several volts in

the supply. The ﬂexibility afforded by the CMOS building

blocks simpliﬁes the design of DAC systems tailored to

particular needs.

Single-Supply, Absolute-Value, Ideal Full-Wave

Rectiﬁer

The absolute-value circuit using the CA3130 is shown in

Figure 11. During positive excursions, the input signal is fed

through the feedback network directly to the output.

Simultaneously, the positive excursion of the input signal

also drives the output terminal (No. 6) of the inverting

ampliﬁer in a negative-going excursion such that the 1N914

diode effectively disconnects the ampliﬁer from the signal

path. During a negative-going excursion of the input signal,

the CA3130 functions as a normal inverting ampliﬁer with a

gain equal to -R

shown in Figure 11 is satisﬁed, the full-wave output is

symmetrical.

Peak Detectors

Peak-detector circuits are easily implemented with the

CA3130, as illustrated in Figure 12 for both the peak-positive

and the peak-negative circuit. It should be noted that with

large-signal inputs, the bandwidth of the peak-negative

circuit is much less than that of the peak-positive circuit. The

second stage of the CA3130 limits the bandwidth in this

case. Negative-going output-signal excursion requires a

positive-going signal excursion at the collector of transistor

associated circuitry in this mode. On the other hand, during

a negative-going signal excursion at the collector of Q

transistor functions in an active “pull-down” mode so that the

intrinsic capacitance can be discharged more expeditiously.

, which is loaded by the intrinsic capacitance of the

. When the equality of the two equations

, the

CA3130AT INTERSIL [Intersil Corporation], CA3130AT Datasheet - Page 8

CA3130AT

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