TL783_12 Datasheet, PDF(8/20 Page) Texas Instruments – HIGH-VOLTAGE ADJUSTABLE REGULATOR

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TL783

SLVS036M â SEPTEMBER 1981 â REVISED APRIL 2008 ............................................................................................................................................... www.ti.com

DESIGN CONSIDERATIONS

The internal reference (see functional block diagram) generates 1.25 V nominal (Vref) between OUT and ADJ.

This voltage is developed across R1 and causes a constant current to flow through R1 and the programming

resistor R2, giving an output voltage of:

VO = Vref (1 + R2/R1) + lI(ADJ) (R2)

VO â Vref (1 + R2/R1)

The TL783 was designed to minimize the input current at ADJ and maintain consistency over line and load

variations, thereby minimizing the associated (R2) error term.

To maintain II(ADJ) at a low level, all quiescent operating current is returned to the output terminal. This quiescent

current must be sunk by the external load and is the minimum load current necessary to prevent the output from

rising. The recommended R1 value of 82 â¦ provides a minimum load current of 15 mA. Larger values can be

used when the input-to-output differential voltage is less than 125 V (see the output-current curve in Figure 12) or

when the load sinks some portion of the minimum current.

Bypass Capacitors

The TL783 regulator is stable without bypass capacitors; however, any regulator becomes unstable with certain

values of output capacitance if an input capacitor is not used. Therefore, the use of input bypassing is

recommended whenever the regulator is located more than four inches from the power-supply filter capacitor. A

1-ÂµF tantalum or aluminum electrolytic capacitor usually is sufficient.

Adjustment-terminal capacitors are not recommended for use on the TL783 because they can seriously degrade

load transient response, as well as create a need for extra protection circuitry. Excellent ripple rejection presently

is achieved without this added capacitor.

Due to the relatively low gain of the MOS output stage, output voltage dropout may occur under large-load

transient conditions. The addition of an output bypass capacitor greatly enhances load transient response and

prevents dropout. For most applications, it is recommended that an output bypass capacitor be used, with a

minimum value of:

Co (ÂµF) = 15/VO

Larger values provide proportionally better transient-response characteristics.

Protection Circuitry

The TL783 regulator includes built-in protection circuits capable of guarding the device against most overload

conditions encountered in normal operation. These protective features are current limiting, safe-operating-area

protection, and thermal shutdown. These circuits protect the device under occasional fault conditions only.

Continuous operation in the current limit or thermal shutdown mode is not recommended.

The internal protection circuits of the TL783 protect the device up to maximum-rated VI as long as certain

precautions are taken. If Vl is switched on instantaneously, transients exceeding maximum input ratings may

occur, which can destroy the regulator. Usually, these are caused by lead inductance and bypass capacitors

causing a ringing voltage on the input. In addition, when rise times in excess of 10 V/ns are applied to the input,

a parasitic npn transistor in parallel with the DMOS output can be turned on, causing the device to fail. If the

device is operated over 50 V and the input is switched on, rather than ramped on, a low-Q capacitor, such as

tantalum or aluminum electrolytic, should be used, rather than ceramic, paper, or plastic bypass capacitors. A Q

factor of 0.015, or greater, usually provides adequate damping to suppress ringing. Normally, no problems occur

if the input voltage is allowed to ramp upward through the action of an ac line rectifier and filter network.

Similarly, when an instantaneous short circuit is applied to the output, both ringing and excessive fall times can

result. A tantalum or aluminum electrolytic bypass capacitor is recommended to eliminate this problem. However,

if a large output capacitor is used, and the input is shorted, addition of a protection diode may be necessary to

prevent capacitor discharge through the regulator. The amount of discharge current delivered is dependent on

output voltage, size of capacitor, and fall time of Vl. A protective diode (see Figure 15) is required only for

capacitance values greater than:

Co (ÂµF) = 3 Ã 104/(VO)2

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