KR19980019993A - Feedback circuit for protection - Google Patents

Abstract

The present invention discloses a feedback circuit for performing a protective operation. The circuit includes a soft start capacitor for charging a voltage through a reference voltage signal and a current source set with an initial operation, and a first comparison for generating a comparison signal in a first state when the voltage charged in the capacitor is greater than a delay voltage. Means, a first latch means for inputting the reference voltage signal as an enable signal and a set signal and for inputting and latching an output signal of the first comparison means as a reset signal, a second comparison means for detecting an overload occurrence, Second latch means for disabling during an initial blanking period and being enabled after the blanking period in response to a logical multiplication of the output signals of the first latching means and the second comparing means; And drive means driven in response to the output signal. Therefore, it is possible to prevent the protection circuit from operating due to the pseudo overload condition during the initial operation.

Description

Feedback circuit for protection

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a feedback circuit, and more particularly, to a feedback circuit that performs a protective operation in the event of a transient event or system failure.

In the conventional feedback circuit, the capacitor load must be charged during the initial operation, so the feedback circuit is recognized as an overload until the rated voltage is charged, and the latch protection circuit is operated so that the entire system cannot be started. To eliminate this unwanted condition, one can either increase the pole capacitor value of the feedback loop or remove the capacitive load component of the load.

However, this method has a disadvantage in that the response speed of the entire feedback loop becomes slow and the ripple capacity of the filter capacitor on the load side becomes large.

SUMMARY OF THE INVENTION An object of the present invention is to provide a feedback circuit that performs a protective operation in the event of a transient event or a system failure.

The feedback circuit for the protection operation of the present invention for achieving the above object is a soft start capacitor for charging the voltage through the reference voltage signal and the current source set with the initial operation, when the voltage charged in the capacitor is greater than the delay voltage First comparing means for generating a comparison signal in a first state, a first signal for inputting the reference voltage signal as an enable signal and a set signal, and inputting and outputting an output signal of the first comparing means as a reset signal; The operation is disabled during the initial blanking period in response to the logical multiplication of the latch means, the second comparing means for detecting the overload occurrence, and the output signal of the first latching means and the second comparing means and after the blanking period Having second latch means enabled and driving means driven in response to an output signal of said second latch means It is characterized by.

1 is a circuit diagram of a feedback circuit for performing a protective operation of the present invention.

FIG. 2 is an operation truth table of the latch shown in FIG. 1.

FIG. 3 is a diagram of each sub output waveform of the circuit shown in FIG. 1. FIG.

Hereinafter, with reference to the accompanying drawings will be described a feedback circuit for the protective operation of the present invention.

1 is a circuit diagram of a feedback circuit for the protection operation of the present invention, a feedback current source (Isink), current sources (Is1, Is2), a feedback capacitor (C _FB ), a soft star art capacitor (Cs / s), resistors ( R1, R2, R3), soft star art resistor (Rs / s), diodes (D1, D2, D3), comparators (10, 20, 30, 40), triangle wave generator circuit (50), S / R latch (60), AND gate (70), protective latch circuit (80), oscillator (90), and gate drive circuit (100).

FIG. 2 is an operation truth table of the S / R latch 60 shown in FIG. 1. When the enable signal, the set signal, and the reset signal Reset are all 1, the output signal Q is represented by FIG. At this time, the protective latch circuit 80 is disabled. When the enable signal (Set) and the set signal (Set) are all 1 and the reset signal (Reset) is all 0, the output signal (Q) becomes 1, and at this time, the protection latch circuit (80) can operate. Done. When the enable signal (Enable) and the set signal (Set) are 1, and the reset signal (Reset) is both 0 or 1, the output signal (Q) becomes 1, and at this time, the protection latch circuit even during the sink operation. Operation 80 is made possible. Finally, when the enable signal Enable and the set signal Set are 0 and the reset signal Reset is both 0 or 1, the output signal Q becomes 0.

3 is a diagram illustrating output waveforms of respective parts of the circuit illustrated in FIG. 1. The operation of the circuit illustrated in FIG. 1 will be described with reference to FIG. 3.

The reference voltage Vref is set with the initial operation. The soft star art capacitor Cs / s starts charging by the current source Is2, the reference voltage Vref, and the resistor R3. When the voltage V _B is smaller than the specific comparison voltage V _Delay , the output signal of the S / R latch 60 is kept at an initial low level because the reset input of the S / R latch 60 is maintained at a high level. Is keeping. During this period (initial blanking period shown in Fig. 3), the protective latch circuit 80 becomes inoperable, thereby preventing unwanted latch operation.

When the voltage V _B becomes larger than the voltage V _Delay , the reset input signal of the S / R latch 60 goes low and the output signal Q of the S / R latch 60 goes high. . From this point onwards, the protective latch circuit 80 can be operated so that the latch circuit 80 is freed by the comparator 40 to stop the operation of the gate driving circuit 100 in the event of an overload. The operable section of the circuit 80 is shown.

When the reset input signal of the S / R latch 60 is at the low level, the output signal Q of the S / R latch 60 is maintained at the high level regardless of the change in the voltage V _B. That is, even though the voltage V _B is greater or less than the threshold voltage V _Delay by the external sync signal, the output signal of the latch circuit 80 is fixed, so the latch circuit 80 is independent of whether the sync signal is input or not. Will always be enabled.

The present invention stops the operation of the latch protection circuit for an initial period of time, and then enables the latch operation according to the occurrence of the overload protection operation. Application of the present invention to integrated circuits requires the use of conventional soft StarArt capacitor voltages, thereby eliminating the need for additional external pins. In addition, the feedback loop constant and the filter capacitor value can be freely designed according to the design environment without a malfunction latch at the beginning of operation.

The feedback circuit for the protective operation of the present invention can prevent the protective circuit from operating due to a similar overload condition during the initial operation.

Claims (1)

A soft start capacitor for charging a voltage through a reference voltage signal and a current source set together with an initial operation; First comparing means for generating a comparison signal in a first state when the voltage charged in the capacitor is greater than a delay voltage; First latch means for inputting the reference voltage signal as an enable signal and a set signal, and inputting and latching an output signal of the first comparison means as a reset signal; Second comparing means for detecting an overload occurrence; Second latch means for disabling during an initial blanking period and enabling after the blanking period in response to a logical multiplication of the output signal of the first latching means and the second comparing means; And a driving means driven in response to the output signal of the second latching means.