LM211DG ON Semiconductor, LM211DG Datasheet - Page 7

LM211DG

Manufacturer Part Number

LM211DG

Description

IC COMPARATOR SGL 36VDC 8-SOIC

Manufacturer

ON Semiconductor

Type

General Purposer

Datasheets

1.LM311DG.pdf (10 pages)

2.LM311DG.pdf (8 pages)

Specifications of LM211DG

Number Of Elements

Output Type

DTL, MOS, Open-Collector, Open-Emitter, RTL, TTL

Voltage - Supply

5 V ~ 30 V, ±2.5 V ~ 15 V

Mounting Type

Surface Mount

Package / Case

8-SOIC (0.154", 3.90mm Width)

Number Of Channels

1 Channel

Response Time

200 ns

Offset Voltage (max)

3 mV

Input Bias Current (max)

100 nA

Supply Voltage (max)

36 V

Supply Voltage (min)

5 V

Supply Current (max)

2.4 mA

Maximum Power Dissipation

625 mW

Maximum Operating Temperature

+ 85 C

Mounting Style

SMD/SMT

Minimum Operating Temperature

- 25 C

Comparator Type

High Speed

No. Of Comparators

Ic Output Type

DTL, MOS, RTL, TTL

Supply Current

2.4mA

Supply Voltage Range

5V To 30V

Amplifier Case Style

SOIC

Rohs Compliant

Yes

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Other names

LM211DG
LM211DGOS

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Manufacturer

Quantity

Price

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Part Number:

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with high speed input signals and low source impedances,

the output response will normally be fast and stable,

providing the power supplies have been bypassed (with

0.1 mF disc capacitors), and that the output signal is routed

well away from the inputs (Pins 2 and 3) and also away from

Pins 5 and 6.

sine wave, or if the signal source impedance is high (1.0 kW

to 100 kW), the comparator may burst into oscillation near

the crossing−point. This is due to the high gain and wide

bandwidth of comparators like the LM211 series. To avoid

oscillation or instability in such a usage, several precautions

are recommended, as shown in Figure 16.

inputs. If these pins are not connected to a trim−pot, they

should be shorted together. If they are connected to a

trim−pot, a 0.01 mF capacitor (C1) between Pins 5 and 6 will

minimize the susceptibility to AC coupling. A smaller

capacitor is used if Pin 5 is used for positive feedback as in

Figure 16. For the fastest response time, tie both balance pins

to V

waveform if a 100 pF to 1000 pF capacitor (C2) is connected

directly across the input pins. When the signal source is

applied through a resistive network, R1, it is usually

advantageous to choose R2 of the same value, both for DC

and for dynamic (AC) considerations. Carbon, tin−oxide,

and metal−film resistors have all been used with good results

in comparator input circuitry, but inductive wirewound

resistors should be avoided.

summing resistors), their value and placement are particularly

important. In all cases the body of the resistor should be close

to the device or socket. In other words, there should be a very

short lead length or printed−circuit foil run between

comparator and resistor to radiate or pick up signals. The

same applies to capacitors, pots, etc. For example, if R1 =

10 kW, as little as 5 inches of lead between the resistors and

the input pins can result in oscillations that are very hard to

dampen. Twisting these input leads tightly is the best

alternative to placing resistors close to the comparator.

When a high speed comparator such as the LM211 is used

However, when the input signal is a voltage ramp or a slow

The trim pins (Pins 5 and 6) act as unwanted auxiliary

Certain sources will produce a cleaner comparator output

When comparator circuits use input resistors (e.g.,

TECHNIQUES FOR AVOIDING OSCILLATIONS IN COMPARATOR APPLICATIONS

http://onsemi.com

LM211, LM311

result in oscillation, the printed−circuit layout should be

engineered thoughtfully. Preferably there should be a

groundplane under the LM211 circuitry (e.g., one side of a

double layer printed circuit board). Ground, positive supply

or negative supply foil should extend between the output and

the inputs to act as a guard. The foil connections for the

inputs should be as small and compact as possible, and

should be essentially surrounded by ground foil on all sides

to guard against capacitive coupling from any fast

high−level signals (such as the output). If Pins 5 and 6 are not

used, they should be shorted together. If they are connected

to a trim−pot, the trim−pot should be located no more than

a few inches away from the LM211, and a 0.01 mF capacitor

should be installed across Pins 5 and 6. If this capacitor

cannot be used, a shielding printed−circuit foil may be

advisable between Pins 6 and 7. The power supply bypass

capacitors should be located within a couple inches of the

LM211.

to prevent oscillation, and to avoid excessive noise on the

output. In the circuit of Figure 17, the feedback resistor of

510 kW from the output to the positive input will cause about

3.0 mV of hysteresis. However, if R2 is larger than 100 W,

such as 50 kW, it would not be practical to simply increase

the value of the positive feedback resistor proportionally

above 510 kW to maintain the same amount of hysteresis.

signals, or if a high−impedance signal is driving the positive

input of the LM211 so that positive feedback would be

disruptive, the circuit of Figure 16 is ideal. The positive

feedback is applied to Pin 5 (one of the offset adjustment

pins). This will be sufficient to cause 1.0 mV to 2.0 mV

hysteresis and sharp transitions with input triangle waves

from a few Hz to hundreds of kHz. The positive−feedback

signal across the 82 W resistor swings 240 mV below the

positive supply. This signal is centered around the nominal

voltage at Pin 5, so this feedback does not add to the offset

voltage of the comparator. As much as 8.0 mV of offset

voltage can be trimmed out, using the 5.0 kW pot and 3.0 kW

resistor as shown.

Since feedback to almost any pin of a comparator can

A standard procedure is to add hysteresis to a comparator

When both inputs of the LM211 are connected to active

LM211DG ON Semiconductor, LM211DG Datasheet - Page 7

LM211DG

Specifications of LM211DG

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