LM7705MM NSC [National Semiconductor], LM7705MM Datasheet - Page 12

LM7705MM

Manufacturer Part Number

LM7705MM

Description

Low Noise Negative Bias Generator

Manufacturer

NSC [National Semiconductor]

Datasheet

1.LM7705MM.pdf (16 pages)

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The sensor generates a DC output signal. In this case, a DC

coupled, 2-stage amplifier is used. The output voltage swing

of the second op amp should me matched to the input voltage

range of the Analog to Digital Converter (ADC). For the high

side of the range this can be done by adjusting the gain of the

op amp. However, the low side of the range can’t be adjusted

and is affected by the output drive of the op amp.

Example:

Assume; the output voltage range of the sensor is 0 to 90 mV.

The available op amp is a LMP7702 (Dual LMP7701 op amp)

that can be used for A

supply voltage, having an output drive of 50mV from both

rails. This results in an output range of 50 mV to 4.95V for

each individual amplifier.

Let choose two resistors values for R

a gain of 10x for the first stage (A

second stage (A

swing from 0V to 4.5 Volt. This swing is limited by the 2 dif-

ferent factors:

When using a 12 bit ADC, and a reference voltage of 5 Volt

(having an ADC step size of approximate 1.2 mV), the output

saturation results in a loss of the lower 400 quantization levels

of the ADCs dynamic range. This will cause a major non-lin-

earity in the sensor reading.

Dual Supply, True Zero Amplifiers

The limitations of the output stage of the op amp, as indicated

in both examples, can be omitted by using a dual supply op

amp. The output stage of the used op amp can then still swing

from 50 mV of the supply rails. However, the functional output

range of the op amp is now from ground level to a value near

the positive supply rail. Figure 10 shows the output drive of

an amplifier in a true zero output voltage application.

Disadvantages of this solution are:

•

A better solution is to use the LM7705. This low noise negative

bias generator has some major advantages with respect to a

dual supply solution:

FIGURE 10. Amplifier output drive with a dual supply

The usage of a dual supply instead of a simple single

supply is more expensive.

A dual supply voltage for the op amps requires parts that

can handle a larger operating range for the supply voltage.

If the op amps used in the current solution can’t handle

this, a redesign can be required.

The high voltage swing is no problem; however the low

voltage swing is limited by the output saturation voltage

of A

of the desired 0V.

Another effect has more impact. The output saturation

voltage of the first stage will cause an offset for the input

of the second stage. This offset of A

gain of the second stage (10x in this example), resulting

in an output offset voltage of 500mV. This is significantly

more that the 50 mV (V

from the LM7702 and won’t go below 50mV instead

) The output of the A

and A

DSAT

. The op amp is using a 0/+5V

) of A

) and a gain of 5x for the

in the LMP7702 should

and R

is amplified by the

20173042

that result in

•

In the next section a typical amplifier application will be eval-

uated. The performance of an amplifier will be measured in a

single supply configuration. The results will be compared with

an amplifier using a LM7705 supplying a negative voltage to

the bias pin.

TYPICAL AMPLIFIER APPLICATION

This section shows the measurement results of a true zero

output amplifier application with an analog to digital converter

(ADC) used as back-end. The biasing of the op amp can be

done in two ways:

•

Basic Setup

The basic setup of this true zero output amplifier is given in

Figure 11. The LMP7701 op amp is configured as a voltage

follower to demonstrate the output limitation, due to the sat-

uration of the output stage. The negative power supply pin of

the op amp can be connected to ground level or to the output

of the negative bias generator, to demonstrate the V

fect at the output voltage range.

FIGURE 11. Typical True Zero Output Voltage Application

The output voltage of the LMP7701 is converted to the digital

domain using an ADC122S021. This is an 12 bit analog to

digital converter with a serial data output. Data processing

and graphical displaying is done with a computer. The nega-

tive power supply pin of the op amp can be connected to

ground level or to the output of the negative bias generator,

to demonstrate the effect at the output voltage range of the

op amp.

Operates with only a single positive supply, and is

therefore a much cheaper solution.

The LM7705 generates a negative supply voltage of only

−0.23V. This is more than enough to create a True-zero

output for most op amps.

In many applications, this “small” extension of the supply

voltage range can be within the abs max rating for many

op amps, so an expensive redesign is not necessary.

A single supply configuration

A single supply in combination with the LM7705, extending

the negative supply from ground level to a fixed -0.23

Voltage.

with/without LM7705

20173043

DSAT

ef-

LM7705MM NSC [National Semiconductor], LM7705MM Datasheet - Page 12

LM7705MM

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