LM2453TA National Semiconductor, LM2453TA Datasheet - Page 8

LM2453TA

Manufacturer Part Number

LM2453TA

Description

IC DRIVER MONOLITHIC TO-220-15

Manufacturer

National Semiconductor

Datasheet

1.LM2453TA.pdf (14 pages)

Specifications of LM2453TA

Display Type

CRT

Current - Supply

35mA

Voltage - Supply

60 V ~ 85 V

Operating Temperature

-20°C ~ 100°C

Mounting Type

Through Hole

Package / Case

TO-220-15 (Bent and Staggered Leads)

Lead Free Status / RoHS Status

Contains lead / RoHS non-compliant

Interface

Configuration

Digits Or Characters

Other names

*LM2453TA

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Application Hints

Effect of Load Capacitance

Figure 10 shows the effect of increased load capacitance on

the speed of the device. This demonstrates the importance

of knowing the load capacitance in the application. It is im-

portant to note that the rise time of the series R in the test cir-

cuit in Figure 4 along with the load capacitance will increase

its contribution to the speed degradation as the load capaci-

tance is increased. The previous section discussed how to

optimize the transient response in the application with the

use of a series inductor.

Effect of Offset

Figure 9 shows the variation in rise and fall times when the

output offset of the device is varied from 40 VDC to 50 VDC.

The rise time shows a maximum variation relative to the cen-

ter data point (45 VDC) of less than 4%. The fall time shows

a variation of less than 10% relative to the center data point.

It is recommended that the video black level be set about

10V below the V

level at 70 with V

all performance while also minimizing the DC power dissipa-

tion.

DC CLAMP AMPLIFIERS

The portion of the multiplexed input signal that is below the

reference voltage controls the DC clamp amplifiers. The DC

transfer function of the amplifier is shown in Figure 12 . Fig-

ure 15 shows the application circuit for the clamp amplifier.

Clamp diode D1 is placed as close as possible to the video

node to minimize trace lengths and parasitic capacitance.

Pull-up resistor R1 is required to bias the PNP output stage

of the clamp circuit. Capacitor C2 provides a low impedance

at high frequencies and helps minimize clamp level variation

that could be caused by changes in the cathode current.

INTEGRATED BOOST SUPPLY AND G1 BLANK

CIRCUIT

Upon initial power up the G1 V

current until the boost capacitor is charged up to approxi-

mately 74V (V

the voltage across the boost capacitor will be replenished

during the vertical blank interval.

The charge cycle will be initiated by the V

(negative going, logic level pulse). Figure 16 shows the

boost application circuit. During the charge cycle the voltage

at pin 4 will be set to 6V and capacitor C28 will be charged

to 74V through diode D11. When the charge cycle is com-

pleted, the voltage at pin 4 will be set to 49V and the plus

side of the boost cap will be at 123 V

FIGURE 15. Clamp Application Circuit.

CC1

–V

power supply in the application (Black

G1-L

= 80 V

). After this initial charge up period,

(Continued)

). This will give the best over-

blank

/Cap Low input will sink

. Capacitor C29 will

blank

input signal

DS101302-21

then be charged to 122.3V (0.7V below 123) through D12.

Diode D12 is required to avoid turning on the ESD protection

diodes between the video clamp outputs and the 120V pin

during the charge cycle. C29 is required to maintain the

120V at pin 2 during the charge cycle.

The 43 Vp-p pulse at pin 4 can be ac-coupled to G1 of the

CRT to blank the CRT during vertical retrace. The recom-

mended application circuit for doing this is shown in Figure

18 .

THERMAL CONSIDERATIONS

Figure 6 shows the performance of the LM2453 video ampli-

fiers in the test circuit shown in Figure 4 as a function of case

temperature. The figure shows that the rise time of the

LM2453 decreases by approximately 6% as the case tem-

perature increases from 50˚C to 100˚C. This corresponds to

a speed degradation of 1.2% for every 10˚C rise in case tem-

perature. There is a negligible change in fall time versus

temperature in the test circuit.

Figure 8 shows the total power dissipation of the LM2453 vs.

frequency when all three video channels of the device are

driving an 8 pF or 12 pF load with a 40 V

assumes a 72% active time (device operating at the speci-

fied frequency) which is typical in a monitor application. The

other 28% of the time the device is assumed to be sitting at

the black level (65V in this case). This graph gives the de-

signer the information needed to determine the heat sink re-

quirement for his application. It is important to note that the

capacitive load dramatically effects the AC component of the

total power dissipation.

The LM2453 case temperature must be maintained below

100˚C. If the maximum expected ambient temperature is

50˚C and the maximum power dissipation is 8.5W, then a

maximum heat sink thermal resistance can be calculated:

This example assumes a capacitive load of 8 pF, no resistive

load and a maximum operating frequency of 50 MHz or

greater.

THE NSC REFERENCE DESIGN

Figures 17, 18, 19 show the schematic and layout for the

NSC Neck Board Reference Design. It contains a complete

video channel from monitor input to CRT cathode. Perfor-

mance is ideal for 1280 X 1024 resolution displays with pixel

clock frequencies up to 135 MHz. A sample of this design

along with all necessary support hardware and materials can

be obtained from your local sales office.

FIGURE 16. Boost Circuit Schematic

p-p

DS101302-20

signal. The graph

LM2453TA National Semiconductor, LM2453TA Datasheet - Page 8

LM2453TA

Specifications of LM2453TA

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