MC33072PG ON Semiconductor, MC33072PG Datasheet - Page 11

MC33072PG

Manufacturer Part Number

MC33072PG

Description

IC OPAMP DUAL 4.5MHZ 8DIP

Manufacturer

ON Semiconductor

Datasheets

1.MC33072DR2G.pdf (25 pages)

2.MC33072PG.pdf (7 pages)

Specifications of MC33072PG

Amplifier Type

General Purpose

Number Of Circuits

Slew Rate

13 V/µs

Gain Bandwidth Product

4.5MHz

Current - Input Bias

100nA

Voltage - Input Offset

1000µV

Current - Supply

1.9mA

Current - Output / Channel

30mA

Voltage - Supply, Single/dual (±)

3 V ~ 44 V, ±1.5 V ~ 22 V

Operating Temperature

-40°C ~ 85°C

Mounting Type

Through Hole

Package / Case

8-DIP (0.300", 7.62mm)

Number Of Channels

Common Mode Rejection Ratio (min)

70 dB

Input Voltage Range (max)

Positive Rail - 1.8 V

Input Voltage Range (min)

Negative Rail

Input Offset Voltage

5 mV

Input Bias Current (max)

500 nA

Operating Supply Voltage

44 V

Supply Current

3.8 mA

Maximum Operating Temperature

+ 85 C

Minimum Operating Temperature

- 40 C

Dual Supply Voltage

+/- 3 V, +/- 5 V, +/- 9 V

Maximum Dual Supply Voltage

+/- 22 V

Minimum Dual Supply Voltage

+/- 1.5 V

Mounting Style

Through Hole

Shutdown

Supply Voltage (max)

44 V

Supply Voltage (min)

3 V

Technology

Bipolar

Voltage Gain Db

100 dB

Bandwidth

4.5 MHz

Channel Separation

120

Common Mode Rejection Ratio

Current, Input Bias

700 nA

Current, Input Offset

300 nA

Current, Output

30 mA

Current, Supply

2.8 mA

Harmonic Distortion

0.02 %

Number Of Amplifiers

Dual

Package Type

PDIP-8

Resistance, Input

150 Megohms

Temperature, Operating, Range

-40 to +85 °C

Voltage, Gain

20 V/mV

Voltage, Input

±15 V

Voltage, Noise

32 nV/sqrt Hz

Voltage, Offset

7 mV

Voltage, Output, High

13.4 V

Voltage, Output, Low

-13.5 V

Voltage, Supply

3 to 44 V

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Output Type

-3db Bandwidth

Lead Free Status / Rohs Status

Lead free / RoHS Compliant

Other names

MC33072PGOS

Available stocks

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Part Number

Manufacturer

Quantity

Price

Company:

Bonase Electronics (HK) Co., Limited

Part Number:

MC33072PG

Manufacturer:

Quantity:

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values of feedback resistances (lower current DACs). This

input pole can be compensated for by creating a feedback

zero with a capacitance across the feedback resistance, if

necessary, to reduce overshoot. For 2.0 kW of feedback

resistance, the MC34071 series can settle to within 1/2 LSB

of 8−bits in 1.0 ms, and within 1/2 LSB of 12−bits in 2.2 ms

for a 10 V step. In a inverting unity gain fast settling

configuration, the symmetrical slew rate is ±13 V/ms. In the

classic noninverting unity gain configuration, the output

positive slew rate is +10 V/ms, and the corresponding

negative slew rate will exceed the positive slew rate as a

function of the fall time of the input waveform.

are superior to that of JFETs, a low untrimmed maximum

offset voltage of 3.0 mV prime and 5.0 mV downgrade can

be economically offered with high frequency performance

characteristics. This combination is ideal for low cost

precision, high speed quad op amp applications.

equivalent circuit schematic, offers unique advantages over

the more conventional NPN/PNP transistor Class AB output

stage. A 10 kW load resistance can swing within 1.0 V of the

positive rail (V

This large output swing becomes most noticeable at lower

supply voltages.

the current source transistor Q

transistor Q

circuit resistance, R

saturation voltage of the pull−down transistor Q

voltage drop I

resistance R

valued sink currents, the above voltage drops are negligible,

allowing the negative swing voltage to approach within

millivolts of V

diode D3 clamps the voltage across R

negative swing to the saturation voltage of Q

forward diode drop of D3 (≈V

supply voltage, unprecedented peak−to−peak output voltage

swing is possible as indicated by the output swing

specifications.

ground for single supply applications, the maximum

possible output swing can be achieved for a given supply

voltage. For light load currents, the load resistance will pull

the output to V

will pull the load resistance near ground during the negative

swing. The load resistance value should be much less than

that of the feedback resistance to maximize pull up

capability.

Since the bipolar input device matching characteristics

The all NPN output stage, shown in its basic form on the

The positive swing is limited by the saturation voltage of

If the load resistance is referenced to V

), providing a 28.7 V

, where I

, and the voltage drop associated with the short

. For large valued sink currents (>5.0 mA),

), and within 0.3 V of the negative rail

during the positive swing and the output

, and the voltage drop associated with

. The negative swing is limited by the

is the sink load current. For small

swing from ±15 V supplies.

, and V

+1.0 V). Thus for a given

, thus limiting the

of the NPN pull up

instead of

, plus the

http://onsemi.com

, the

been eliminated, the MC34071 series offers a 20 mA

minimum current sink capability, typically to an output

voltage of (V

output can directly source or sink base current from a

common emitter NPN transistor for fast high current

switching applications.

inherently fast, contributing to the bipolar amplifier’s high

gain bandwidth product and fast settling capability. The

associated high frequency low output impedance (30 W typ

@ 1.0 MHz) allows capacitive drive capability from 0 pF to

10,000 pF without oscillation in the unity closed loop gain

configuration. The 60° phase margin and 12 dB gain margin

as well as the general gain and phase characteristics are

virtually independent of the source/sink output swing

conditions. This allows easier system phase compensation,

since output swing will not be a phase consideration. The

high frequency characteristics of the MC34071 series also

allow excellent high frequency active filter capability,

especially for low voltage single supply applications.

5.0 V, these amplifiers are functional to 3.0 V @ 25°C

although slight changes in parametrics such as bandwidth,

slew rate, and DC gain may occur.

polarity or if the IC is installed backwards in a socket, large

unlimited current surges will occur through the device that

may result in device destruction.

bipolar amplifiers since there are no MOS transistors on the

die.

dress, component placement, and PC board layout should be

exercised for optimum frequency performance. For

example, long unshielded input or output leads may result in

unwanted input−output coupling. In order to preserve the

relatively low input capacitance associated with these

amplifiers, resistors connected to the inputs should be

immediately adjacent to the input pin to minimize additional

stray input capacitance. This not only minimizes the input

pole for optimum frequency response, but also minimizes

extraneous “pick up” at this node. Supply decoupling with

adequate capacitance immediately adjacent to the supply pin

is also important, particularly over temperature, since many

types of decoupling capacitors exhibit great impedance

changes over temperature.

protected from a direct short to ground. However, under

such conditions, it is important not to allow the device to

exceed the maximum junction temperature rating. Typically

for ±15 V supplies, any one output can be shorted

continuously to ground without exceeding the maximum

temperature rating.

Because the PNP output emitter−follower transistor has

In addition, the all NPN transistor output stage is

Although the single supply specifications is defined at

If power to this integrated circuit is applied in reverse

Special static precautions are not necessary for these

As with most high frequency amplifiers, proper lead

The output of any one amplifier is current limited and thus

+1.8 V). In single supply applications the

MC33072PG ON Semiconductor, MC33072PG Datasheet - Page 11

MC33072PG

Specifications of MC33072PG

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