Datasheet MSK167B, MSK166, MSK166B, MSK167 Datasheet (MSK)

ULTRA HIGH VOLTAGE

ISO-9001 CERTIFIED BY DSCC

OPERATIONAL AMPLIFIER

166/167

M.S.KENNEDY CORP.

4707 Dey Road Liverpool, N.Y. 13088

(315) 701-6751

FEATURES:

Low Cost Surface Mount Package

Monolithic MOS Technology

High Voltage Operation - 350V

Low Quiescent Current - 2mA Max.

High Output Current - 60mA Min.

No Second Breakdown

High Speed - 40V/µS Typ.

External Compensation And Null Capability

DESCRIPTION:

MSK166

The MSK 166 and 167 ultra high voltage monolithic MOSFET operational amplifier ideally suited for electrostatic

transducer and electrostatic deflection applications. With a total supply voltage rating of 350 volts and 60mA of

available output current, the MSK 166 and 167 are also an excellent low cost choice for high voltage piezo drive

circuits. The MOSFET output frees the MSK 166 and 167 from secondary breakdown limitations and power dissipa-

tion is kept to a minimum with a quiescent current rating of only 2mA. The MSK 166 is packaged in a hermetically

sealed 40 pin leadless chip carrier which has two external compensation pins. The output of the MSK 166 and 167

can be externally nulled using the two null pins. The MSK 167 is packaged in a 24 pin ceramic flatpack and is

otherwise identical to the MSK 166. (see mechanical specifications).

EQUIVALENT SCHEMATIC

PIN-OUT INFORMATION

MIL-PRF-38534 QUALIFIED

MSK167

The pin numbers shown in the above

schematic are for the MSK 166.

TYPICAL APPLICATIONS

Piezo Electric Positioning

Electrostatic Deflection

Computer to Vacuum Tube Interface

Ultra High Voltage Op-Amp Applications

+Vcc

1

N/C

2

Output Drive

3

N/C

4

N/C

5

N/C

6

Compensation 1

7

N/C

8

Compensation 2

9

N/C

10

Current Sense

11

N/C

12

N/C

13

N/C

14

N/C

15

N/C

16

N/C

17

N/C

18

N/C

19

N/C

20

N/C

1

Balance 1

2

Balance 2

3

N/C

4

-Vcc

5

N/C

6

+Vcc

7

Output Drive

8

N/C

9

Compensation 1

10

Compensation 2

11

N/C

12

MSK 166 PINOUT

MSK 167 PINOUT

N/C

40

-Vcc

39

N/C

38

N/C

37

N/C

36

Balance 2

35

N/C

34

Balance 1

33

N/C

32

Non Inverting Input

31

N/C

30

Inverting Input

29

N/C

28

N/C

27

N/C

26

N/C

25

N/C

24

N/C

23

N/C

22

N/C

21

N/C

24

Non Inverting Input

23

Inverting Input

22

N/C

21

N/C

20

N/C

19

N/C

18

N/C

17

N/C

16

N/C

15

Current Sense

14

N/C

13

1

Rev. B 8/00

ABSOLUTE MAXIMUM RATINGS

2

VCC

±IOUT

±IOUTP

VIND

VIN

TJ

Total Supply Voltage

○○○○○○○○○○○

Output Current (within S.O.A.)

Output Current Peak

Input Voltage (Differential)

○○○○○○○○○○

○○○○○○○

Input Voltage (Common Mode)

Junction Temperature

○○○○○○○○○

ELECTRICAL SPECIFICATIONS

○○○○○

120mA

±16V

○○○○○

150°C

350V

60mA

±Vcc

TST

Storage Temperature

TLD

Lead Temperature

TC

Case Operating Temperature

(MSK166B/167B)

(MSK166/167)

RTH

Thermal Resistance (DC)

Junction to Case

○○○○○

○○○○○○○○○○○○○○

○○○○○○○

○○○○○○○○○

○○○○○○○○○○○○○

-65°C to +150°C

-55°C to +125°C

-40°C to +85°C

300°C

15°C/W

Parameter

STATIC

2

Supply Voltage Range

4

Quiescent Current

INPUT

Offset Voltage

Offset Voltage Drift

Offset Voltage vs ±Vcc

Input Bias Current

Input Impedance

Input Capacitance

4

4

4

4

4

Common Mode Rejection

Noise

OUTPUT

Output Voltage Swing

Output Current

Power Bandwidth

Resistance

Settling Time to 0.1%

Capacitive Load

4

4

3

4

TRANSFER CHARACTERISTICS

Slew Rate

Open Loop Voltage Gain

Test Conditions

9

VIN=0V

VIN=0V

VIN=0V

VIN=0V

VCM=0V

4

VCM=±90VDC

1Hz≤f≤10Hz

IOUT=±40mA Peak

VOUT=MAX

CC=10pF VOUT=280VPP

No Load, RCL=0Ω

4

CC=10pF 10V Step

AV=+1V/V

CC=Open

4

F=15Hz RL=5KΩ

(DC)

1

Group A

Subgroup

-

1

2

3

1

2,3

1

1,3

2

-

-

-

-

4

4

-

-

-

-

4

4

MSK166B/167B

Min.

±50

Typ.

±150

±1.4

-

±2.0

-

±1.0

-

±15

-

±40

-

±20

-

±5

-

-

10

-

-

84

-

±138

±60

-

-

-

5

94

50

±141

±120

26

150

12

10

20

94

40

106

Max.

±175

±2.0

±3.0

±2.1

±30

±65

±32

±50

-

±50

11

-

-

-

-

-

-

-

-

-

-

-

-

-

MSK166/167

Min.

±50

-

-

-

-

-

-

-

-

-

-

84

-

±138

±60

-

-

-

10

20

94

Typ.

±150

±1.4

-

-

±15

±40

±20

±5

-

10

5

94

50

±141

±120

26

150

12

-

40

106

11

Max.

±175

±2.0

-

-

±30

-

±32

±100

-

-

-

-

-

-

-

-

-

-

-

-

-

Units

V

mA

mA

mA

mV

µV/°C

µV/V

pA

nA

Ω

pF

dB

µVRMS

V

mA

KHz

Ω

µS

nF

V/µS

dB

NOTES:

1

Unless otherwise noted CC=18pF, RC=2.2KΩ, ±VCC= ±150VDC, null pins one and two are no connect.

2

Derate maximum supply voltage 0.5V/°C below TC=+25°C. No derating is needed above TC=25°C.

3

AV=-10V/V measured in false summing junction circuit.

4

Devices shall be capable of meeting the parameter, but need not be tested. Typical parameters are for reference only.

5

Industrial grade devices shall be tested to subgroups 1 and 4 unless otherwise requested.

6

Military grade devices ('B' suffix) shall be 100% tested to subgroups 1,2,3 and 4.

7

Subgroup 5 and 6 testing available upon request.

8

Subgroup 1,4 TC=+25°C

Subgroup 2,5 TC=+125°C

Subgroup 3,6 TA=-55°C

9

Electrical specifications are derated for power supply voltages less than ±50VDC.

Rev. B 8/002

APPLICATION NOTES

CURRENT LIMIT

Current limit resistor value can be calculated as follows:

CL=3/ILIM

R

It is recommended that the user set up the value of current limit

as close as possible to the maximum expected output current

to protect the amplifier. The minumum value of current limit

resistance is 33 ohms. The maximum practical value is 500

ohms. Current limit will vary with case temperature. Refer to

the typical performance graphs as a guide. Since load current

passes through the current limit resistor, a loss in output volt-

age swing will occur. The following formula approximates out-

put voltage swing reduction:

VR=IO RCL

*

When the device is in current limit, there will be spurious oscil-

lations present on the negative half cycle. The frequency of

the oscillation is application dependant and can not be pre-

dicted. Oscillation will cease when the device comes out of

current limit. If current limit is not required simply short pin 3

and pin 11.

INPUT PROTECTION

Input protection circuitry within the MSK 166/167 will clip

differential input voltages greater than 16 volts. The inputs are

also protected against common mode voltages up to the supply

rails as well as static discharge. There are 300 ohm current

limiting resistors in series with each input. These resistors may

become damaged in the event the input overload is capable of

driving currents above 1mA. If severe overload conditions are

expected, external input current limiting resistors are recom-

mended.

SAFE OPERATING AREA (SOA)

The MOSFET output stage of this ultra high voltage opera-

tional amplifier has two distinct limitations:

1. The current handling capability of the die metallization.

2. The junction temperature of the output MOSFET's.

NOTE: The output stage is protected against transient flyback.

However, for protection against sustained, high energy flyback,

external fast-recovery reverse biased diodes should be connected

from the output to ground.

OUTPUT SNUBBER NETWORK

A 100 ohm resistor and a 330pF capacitor connected in se-

ries from the output of the amplifier to ground is recommended

for applications where load capacitance is less than 330pF.

For larger values of load capacitance, the output snubber net-

work may be omitted. If loop stability becomes a problem due

to excessively high load capacitance, a 100 ohm resistor may

be added between the output of the amplifier and the load. A

small tradeoff with bandwidth must be made in this configura-

tion. The graph below illustrates the effect of capacitive load

on open loop gain. Note that the compensation capacitor must

have a voltage rating greater than or equal to the total rail to rail

power supply voltage.

STABILITY

The MSK 166/167 has sufficient phase margin when com-

pensated for unity gain to be stable with capacitive loads of at

least 10nF. However, it is recommended that the parallel sum

of the input and feedback resistor be 1000 ohms or less for

closed loop gains of ten or less to minimize phase shift caused

by the R-C network formed by the input resistor, feedback re-

sistor and input capacitance. The user can tailor the perfor-

mance of the MSK 166/167 to their application using the ex-

ternal compensation pins. The graphs of small signal gain and

phase as well as the graphs of slew rate and power response

demonstrate the effect of various forms of compensation. The

compensation capacitor must be rated at 350 volts working

voltage if maximum power supply voltages are used. The com-

pensation resistor and capacitor lead lengths must be kept as

short as possible to minimize spurious oscillations. A high quality

NPO capacitor rated for ±Vcc is recommended for the com-

pensation capacitor.

COMPENSATION AND OUTPUT NULL PINS

External compensation is only necessary at gains of 30v/v or

less. For larger gains, the compensation resistor and capacitor

may be omitted. When large closed loop voltage gains are

present, the designer may find it necessary to null the DC out-

put offset voltage. This can be accomplished by connecting a

null circuit to pins 33 and 35 (for the MSK 166) as shown in

the typical connection diagram above.

3

Rev. B 8/00

TYPICAL PERFORMANCE CURVES

Rev. B 8/004

MECHANICAL SPECIFICATIONS

MSK166

MSK167

ALL DIMENSIONS ARE ±0.010 INCHES UNLESS OTHERWISE LABELED.

ESD TRIANGLE INDICATES PIN 1.

ORDERING INFORMATION

Part

Number

MSK166

MSK166B

MSK167

MSK167B

M.S. Kennedy Corp.

4707 Dey Road, Liverpool, New York 13088

Phone (315) 701-6751

FAX (315) 701-6752

www.mskennedy.com

The information contained herein is believed to be accurate at the time of printing. MSK reserves the right to make

changes to its products or specifications without notice, however, and assumes no liability for the use of its products.

Screening Level

Industrial

Military-Mil-PRF-38534

Industrial

Military-Mil-PRF-38534

Rev. B 8/005