AD650BD Analog Devices Inc, AD650BD Datasheet - Page 13

Voltage / Frequency (V/F & F/V) Converter IC

AD650BD

Manufacturer Part Number

AD650BD

Description

Voltage / Frequency (V/F & F/V) Converter IC

Manufacturer

Analog Devices Inc

Type

Volt to Freq & Freq to Voltr

Datasheet

1.AD650KNZ.pdf (20 pages)

Specifications of AD650BD

Mounting Type

Through Hole

Package / Case

14-DIP

Frequency - Max

1MHz

Full Scale

±150ppm/°C

Linearity

±0.1%

Converter Function

VFC/FVC

Full Scale Frequency

1000

Power Supply Requirement

Dual

Single Supply Voltage (typ)

Not RequiredV

Single Supply Voltage (max)

Not RequiredV

Single Supply Voltage (min)

Not RequiredV

Dual Supply Voltage (min)

±9V

Dual Supply Voltage (max)

±18V

Operating Temperature (min)

-25C

Operating Temperature (max)

85C

Operating Temperature Classification

Commercial

Package Type

SBCDIP

Lead Free Status / RoHS Status

Contains lead / RoHS non-compliant

Lead Free Status / RoHS Status

Contains lead / RoHS non-compliant

Available stocks

Company

Part Number

Manufacturer

Quantity

Price

Company:

BOSTOCK HK LIMITED

Part Number:

AD650BD

Manufacturer:

ADI

Quantity:

549

Company:

Meier Automation Equipment Co., Limited

Part Number:

AD650BD

Manufacturer:

ADI/亚德诺

Quantity:

20 000

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Other circuit components do not directly influence the accuracy

of the VFC over temperature changes as long as their actual

values are not as different from the nominal value as to preclude

operation. This includes the integration capacitor C

in the capacitance value of C

voltage change across the capacitor. During the integration phase

(see Figure 8), the rate of voltage change across C

opposite effect that it does during the reset phase. The result is

that the conversion accuracy is unchanged by either drift or

tolerance of C

capacitor is simply to change the peak-to-peak amplitude of the

sawtooth waveform at the output of the integrator.

The gain temperature coefficient of the AD650 is not a constant

value. Rather, the gain TC is a function of both the full-scale

frequency and the ambient temperature. At a low full-scale

frequency, the gain TC is determined primarily by the stability of

the internal reference (a buried Zener reference). This low speed

gain TC can be quite effective; at 10 kHz full scale, the gain TC near

25°C is typically 0 ± 50 ppm/°C. Although the gain TC changes

with ambient temperature (tending to be more positive at higher

temperatures), the drift remains within a ±75 ppm/°C window over

the entire military temperature range. At full-scale frequencies

higher than 10 kHz, dynamic errors become much more important

than the static drift of the dc reference. At a full-scale frequency

of 100 kHz and above, these timing errors dominate the gain

TC. For example, at 100 kHz full-scale frequency (R

−80 ±50 ppm/°C, but at an ambient temperature near 125°C, the

gain TC tends to be more positive and is typically 15 ±50 ppm/°C.

This information is presented in a graphical form in Figure 15.

The gain TC always tends to become more positive at higher

temperatures. Therefore, it is possible to adjust the gain TC of

the AD650 by using a one-shot capacitor with an appropriate

TC to cancel the drift of the circuit. For example, consider the

100 kHz full-scale frequency. An average drift of −100 ppm/°C

means that as temperature is increased, the circuit produces a

lower frequency in response to a given input voltage. This means

that the one-shot capacitor must decrease in value as temperature

increases in order to compensate the gain TC of the AD650; that

is, the capacitor must have a TC of −100 ppm/°C. Now consider

the 1 MHz full-scale frequency.

= 330 pF) the gain TC near room temperature is typically

–100

–200

–300

–400

100

INT

100kHz

10kHz

1MHz

–50

. The net effect of a change in the integrator

Figure 15. Gain TC vs. Temperature

–25

TEMPERATURE (°C)

INT

simply results in a different rate of

100

INT

has the

= 40 kΩ and

. A change

125

Rev. D | Page 13 of 20

It is not possible to achieve much improvement in performance

unless the expected ambient temperature range is known. For

example, in a constant low temperature application such as

gathering data in an Arctic climate (approximately −20°C), a

the gain drift of the AD650. However, if that circuit should see

an ambient temperature of 75°C, then the C

change the gain TC from approximately 0 ppm to 310 ppm/°C.

The temperature effects of these components are the same when

the AD650 is configured for negative or bipolar input voltages,

and for F/V conversion as well.

NONLINEARITY SPECIFICATION

The linearity error of the AD650 is specified by the endpoint

method. That is, the error is expressed in terms of the deviation

from the ideal voltage to frequency transfer relation after

calibrating the converter at full scale and zero. The nonlinearity

varies with the choice of one-shot capacitor and input resistor

(see Figure 10). Verification of the linearity specification

requires the availability of a switchable voltage source (or a

DAC) having a linearity error below 20 ppm, and the use of

very long measurement intervals to minimize count

uncertainties. Every AD650 is automatically tested for linearity,

and it is not usually necessary to perform this verification,

which is both tedious and time consuming. If it is required to

perform a nonlinearity test either as part of an incoming quality

screening or as a final product evaluation, an automated bench-

top tester proves useful. Such a system based on Analog

Devices’ LTS-2010 is described in “V-F Converters Demand

Accurate Linearity Testing, ” by L. DeVito, (Electronic Design,

March 4, 1982).

The voltage-to-frequency transfer relation is shown in Figure 16

and Figure 17 with the nonlinearity exaggerated for clarity. The

first step in determining nonlinearity is to connect the endpoints of

the operating range (typically at 10 mV and 10 V) with a straight

line. This straight line is then the ideal relationship that is desired

from the circuit. The second step is to find the difference between

this line and the actual response of the circuit at a few points

between the endpoints—typically ten intermediate points

suffices. The difference between the actual and the ideal

response is a frequency error measured in hertz. Finally, these

frequency errors are normalized to the full-scale frequency and

expressed either as parts per million of full scale (ppm) or parts

per hundred of full scale (%). For example, on a 100 kHz full

scale, if the maximum frequency error is 5 Hz, the nonlinearity

is specified as 50 ppm or 0.005%. Typically on the 100 kHz

scale, the nonlinearity is positive and the maximum value

occurs at about midscale (Figure 16). At higher full-scale

frequencies, (500 kHz to 1 MHz), the nonlinearity becomes “S”

shaped and the maximum value can be either positive or negative.

Typically, on the 1 MHz scale (R

nonlinearity is positive below about 2/3 scale and is negative

above this point. This is shown graphically in Figure 17.

with a drift of −310 ppm/°C is called for in order to compensate

= 16.9 kΩ, C

capacitor would

= 51 pF) the

AD650

AD650BD Analog Devices Inc, AD650BD Datasheet - Page 13

AD650BD

Specifications of AD650BD

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