MSK1933 Datasheet, PDF(3/6 Page) M.S. Kennedy Corporation – ULTRA HIGH SPEED/VOLTAGE NEGATIVE OUTPUT VIDEO AMPLIFIER

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MSK1933 Datasheet, PDF (3/6 Pages) M.S. Kennedy Corporation – ULTRA HIGH SPEED/VOLTAGE NEGATIVE OUTPUT VIDEO AMPLIFIER

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APPLICATION NOTES

POWER SUPPLIES

The input stage of the MSK 1933 requires power supplies of

+20V and -10.5V for optimum operation. The negative power

supply can be increased to -12V if -10.5V is not available, but

additional power dissipation will cause the internal temperature

to rise. Both low voltage power supplies should be effectively

decoupled with tantalum capacitors (at least 4.7ÂµF) connected

as close to the amplifier's pins as possible. The MSK 1933 has

internal 0.01ÂµF capacitors that also improve high frequency

performance. It is also recommended to put 0.1ÂµF decoupling

capacitors on the +20V and -10.5V supplies as well. Since

the output stage is returned to +20V internally, all of the out-

put current will flow through this supply pin.

The high voltage power supply (-VHV) is connected to the

amplifier's output stage and must be kept as stable as possible.

The internal or external Rp is connected to -VHV and as such,

the amplifier's DC output is directly related to the high voltage

value. The -VHV pins of the hybrid should be decoupled to

ground with as large a capacitor as possible to improve output

stability.

SUPPLY SEQUENCING

The power supply sequence is VHV, VCC, VEE followed by the

other DC control inputs. If power supply sequencing is not

possible, the time difference between each supply should be

less than five milliseconds. If the DC control signals are being

generated from a low impedance source other than the VREF

output, reverse biased diodes should be connected from each

input (VGAIN, VOFF) to the VCC pin. This will protect the inputs

until VCC is turned on.

VIDEO OUTPUT

When power is first applied and VIN=VGAIN=VOFF=0V, the

output will be practically at the -VHV rail voltage. The output

voltage is a function of the value of Rp and also the VGAIN and

VOFF DC inputs. The maximum output voltage swing for any of

the MSK 1933 variants is determined by Vpp = (250mA) x

(Rp). The bandwidth of the amplifier largely depends on both

Rp and Lp.

VIDEO INPUTS

The video input signals should be kept below Â±2VMAX total,

including both common mode offset and signal levels. The

input structure of the MSK 1933 was designed for Â±0.714Vpp

RS343 signals. If either input is not used it should be con-

nected directly to the analog ground or through a 25â¦ resistor

to ground if input offset currents are to be minimized.

OUTPUT PROTECTION

The output pin of the MSK 1933 should be protected from

transients by connecting reversed biased ultra-low capacitance

diodes from the output pin to both -VHV and ground. The out-

put can also be protected from arc voltages by inserting a small

value (25-50â¦) resistor in series with the amplifier. This resis-

tor will reduce system bandwidth along with the load capaci-

tance, but a series inductor can reduce the problem substan-

tially.

VGAIN CONTROL INPUT

The VGAIN control (contrast) input is designed to allow the

user to vary the video gain. By simply applying a DC voltage

from 0V to VREF, the video gain can be linearly adjusted from 0

to 195V/V (MSK 1933-2). The VGAIN input should be connected

to the VREF pin through a 5Kâ¦ pot to ground. For convenient

stable gain adjustment, a 0.1ÂµF bypass capacitor should be con-

nected near the VGAIN input pin to prevent output instability due

to noisy sources. Digital gain control can be accomplished by

connecting a D/A converter to the VGAIN pin. However, some

temperature tracking performance may be lost when using an

external DC voltage source other than VREF for gain adjustment.

The bandwidth of the VGAIN input is approximately 1MHz.

The overall video output of the MSK 1933 can be character-

ized using the following expression:

Vpp=VHV-VOUT

VHV-VOUT=(VIN)(VGAIN)(Rp)(0.09)

(or)

Voltage Gain=VOUT/VIN=(VGAIN)(Rp)(0.09)

Here is a sample calculation for the MSK 1932-2:

Given information

Hybrid pins 12 and 13 are directly connected to Rp. Addi-

tional external resistance can be added to reduce power dissi-

pation, but slower transition times will result. If an additional

resistor is used, it must be low capacitive and the layout should

minimize capacitive coupling to ground (ie: no ground plane

under Rp).

VIN=0.7V

VGAIN=1VDC

Rp=400â¦ (internal)

VHV=-80VDC

VHV-VOUT=(0.7V)(1V)(400â¦)(0.09)

VHV-VOUT=25.2V Nominal

The MSK 1933 Series is conservatively specified with low

values for Lp which yield about 5% overshoot. Additional peak-

ing can be obtained by using a high self-resonant frequency

inductor in series with pins 12 & 13. Since this value of induc-

tance can be very dependent on circuit layout, it is best to

determine its value by experimentation. A good starting point

is typically 0.47ÂµH for the MSK 1933-0 and 0.0047ÂµH for the

remaining devices.

If external resistors or inductors are not used, be sure to

connect high frequency bypass capacitors directly from pins

12 and 13 to ground for the devices that contain an internal

Rp.

The expected video output would swing from approximately

-80V to -54.8V assuming that VOFF=0V. This calculation should

be used as a nominal result because the overall gain may vary as

much as Â±20% due to internal high speed device variations.

Changing ambient conditions can also effect the video gain of

the amplifier by as much as 150 PPM/Â°C. It is wise to connect

all video amplifiers to a common heat sink to maximize thermal

tracking when multiple amplifiers are used in applications such

as RGB systems. Additionally, only one of the VREF outputs

should be shared by all three amplifiers. This voltage should be

buffered with a suitable low drift op-amp for best tracking per-

formance.

Rev. A 8/00

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