LT1251CN Linear Technology, LT1251CN Datasheet - Page 14

LT1251CN

Manufacturer Part Number

LT1251CN

Description

IC AMP VIDEO FADE CONTRLD 14-DIP

Manufacturer

Linear Technology

Datasheet

1.LT1256CSPBF.pdf (24 pages)

Specifications of LT1251CN

Applications

Current Feedback

Number Of Circuits

-3db Bandwidth

40MHz

Slew Rate

300 V/µs

Current - Supply

14.5mA

Current - Output / Channel

40mA

Voltage - Supply, Single/dual (±)

5 V ~ 30 V, ±2.5 V ~ 15 V

Mounting Type

Through Hole

Package / Case

14-DIP (0.300", 7.62mm)

Lead Free Status / RoHS Status

Contains lead / RoHS non-compliant

Available stocks

Company

Part Number

Manufacturer

Quantity

Price

Company:

Meier Automation Equipment Co., Limited

Part Number:

LT1251CN#PBF

Manufacturer:

LINEAR/凌特

Quantity:

20 000

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LT1251/LT1256

APPLICATIONS

Control Circuit Description

The control section of the LT1251/LT1256 consists of two

identical voltage-to-current converters (V-to-I); each

V-to-I contains an op amp, an NPN transistor and a

resistor. The converter on the right generates a full-scale

current I

minimum of zero (when I

(when I

gain from each signal input to the output.

The op amp in each V-to-I drives the transistor until the

voltage at the inverting input is the same as the voltage at

the noninverting input. If the open end of the resistor (Pin

5 or 10) is grounded, the voltage across the resistor is the

same as the voltage at the noninverting input. The emitter

current is therefore equal to the input voltage V

the resistor value R

the same as the emitter current and it is the ratio of the two

collector currents that sets the gain.

The LT1251/LT1256 are tested with Pins 5 and 10 grounded

and a full-scale voltage of 2.5V applied to V

sets I

applied to Pin 3. When the control voltage is negative or

zero, I

channel one goes from 0% to 100% as V

to 2.5V. The gain of channel two goes the opposite way,

from 100% down to 0%. The worst-case error in K (the

is equal to or greater than I

at approximately 500 A; the control voltage V

is zero and K is zero. When V

CONTROL V TO I

is equal to, or greater than, I

–

. The ratio I

Figure 3. Control Circuit Block Diagram

and the one on the left generates a control

. The collector current is essentially

INFORMATION

is zero) to a maximum of one

is called K. K goes from a

and K is one. The gain of

FULL SCALE V TO I

). K determines the

is 2.5V or greater,

goes from zero

(Pin 12). This

–

divided by

1251/56 F03

gain) is 3% as detailed in the electrical tables. By using

a 2.5V full-scale voltage and the internal resistors, no

additional errors need be accounted for.

In the LT1256, K changes linearly with I

is zero, V

the worst-case control op amp offset. Similarly to insure

that K is 100%, V

the guaranteed gain accuracy.

To eliminate the overdrive requirement, the LT1251 has

internal circuitry that senses when the control current is at

about 5% and sets K to 0%. Similarly, at about 95% it sets

K to 100%. The LT1251 guarantees that a 2% (50mV)

input gives zero and 98% (2.45V) gives 100%.

The operating currents of the LT1251/LT1256 are derived

from I

of V

current for three values of V

mate formula for the supply current is:

where V

By reducing I

ever, the slew rate and bandwidth will also be reduced as

indicated in the characteristic curves. Using the internal

resistors (5k) with V

500 A; there is no reason to use a larger value of I

The inverting inputs of the V-to-I converters are available

so that external resistors can be used instead of the

internal ones. For example, if a 10V full-scale voltage is

desired, an external pair of 20k resistors should be used to

set I

greater than the maximum V

transistors from saturating. Do not use the internal resis-

tors with external resistors because the internal resistors

have a large positive temperature coefficient (0.2%/ C)

that will cause gain errors.

If the control voltage is applied to the free end of resistor

of the control voltage must be inverted. Therefore, K will

be 0% for zero input and 100% for – 2.5V input, assuming

ground; this is convenient for summing several negative

going control signals.

(Pin 5) and the V

equals 2.5V. With Pin 3 grounded, Pin 4 is a virtual

= 1mA + (24)(I

to 500 A. The positive supply voltage must be 2.5V

and R

and therefore the quiescent current is a function

is the total supply voltage between Pins 9 and 7.

must be negative 15mV or more to overcome

. The electrical tables show the supply

the supply current can be reduced, how-

must be 3% larger than V

input (Pin 3) is grounded, the polarity

) + (V

equal to 2.5V results in I

/20k)

including zero. An approxi-

and/or V

. To insure that K

to keep the

based on

equal to

LT1251CN Linear Technology, LT1251CN Datasheet - Page 14

LT1251CN

Specifications of LT1251CN

Available stocks

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