KR19990026504A - Micom stabilization device in DPM off mode - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a microcomputer stabilization apparatus in a DCMS off mode that can supply stable microcomputer power even in a power saving mode of DPMS (Display Power Management Signaling) off mode.

In the conventional SMPS power circuit, when the DPMS mode in the power saving mode is turned off, an abnormal oscillation of the primary side of the SMPS transformer occurs, so that the noise of the SMPS transformer is generated, and since the stable power is not supplied to the microcomputer, the operation of the microcomputer becomes unstable. There is a problem.

Therefore, in the present invention, in order to solve such a conventional problem, the horizontal pulse is input from the high-voltage output circuit, and the DPMS on / off mode is determined according to the input of the horizontal pulse. Stop the oscillator of the control means to prevent noise of the SMPS transformer due to the primary side abnormal oscillation, and also generate a negative power supply so that the generated negative power supply is supplied to a circuit such as a microcomputer instead of the voltage induced from the SMPS transformer. Thus, stable power can always be supplied to a circuit such as a microcomputer regardless of DPMS on / off.

Description

MICOM stabilization device in DCS off mode.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a microcomputer stabilization apparatus in a DCMS off mode that can supply stable microcomputer power even in a power saving mode of DPMS (Display Power Management Signaling) off mode.

FIG. 1 is a circuit diagram illustrating a configuration of a conventional switching mode power supply (SMPS) power circuit. Referring to FIG. 1, the configuration and operation thereof will be described below.

The bridge diode BD1 rectifies the supplied AC power, the capacitor C1 smoothing the DC power rectified through the bridge diode BD1, and the rectified and smoothed DC voltage is inputted to the primary side and induced to the secondary side. The SMPS transformer T1 for supplying a constant voltage to a circuit such as the microcomputer M, the SMPS control unit 1 for controlling the operation of the SMPS transformer T1 by controlling the switching operation of the transistor Q1, and the SMPS The second output voltage of the SMPS transformer 1 is fed back to the feedback voltage terminal V _FB of the SMPS controller 1 and the comparator CMP by operating the voltage output through the transformer T1. A photo coupler (PC1) for controlling the operation of T1) and a secondary horizontal pulse (HP; Horizontal Pulse) of the feedback flyback transformer are received and induced to the secondary side, and the induced pulse is SMPS. Transmitter T2 to the oscillator (OSC) of the control unit 1 It is composed of

Reference numeral Isense denotes an overcurrent applied to the SMPS transformer (T1), Ref is a reference voltage, R1 to R8 are resistors, D1 to D4 are diodes, C1 to C5 are capacitors, and VR1 is a variable resistor.

The supplied AC power is rectified through the bridge diode BD1, and the rectified power is outputted with a constant pulse voltage to the secondary side of the SMPS transformer T1 which is switched under the control of the SMPS controller 1.

As described above, the output voltage is smoothed by the diode D3 and the capacitor C5 and supplied to a circuit such as the microcomputer M.

At this time, the output voltage is to operate the diode of the optical coupler (PC1), thereby operating a transistor connected to the reference voltage terminal (Ref) and the collector terminal is operated by the comparator (CMP) of the SMPS control unit 1 SMPS transformer ( The secondary output feedback voltage of T1) is delivered.

As described above, the SMPS controller 1 controls the switching of the transistor Q1 to control the operation of the SMPS transformer T1 in comparison with the reference voltage.

In addition, the secondary side horizontal pulse (HP) of the high-voltage generating flyback transformer is applied to the oscillator (OSC) of the SMPS control unit (1) through the diode (D2) through the transformer (T2) to the SMPS transformer (1) To operate stably.

However, in such a conventional SMPS power supply circuit, when the DPMS mode of the power saving mode is turned off, the VCC voltage of the SMPS controller 1 is lowered, so that the primary side abnormal oscillation of the SMPS transformer T1 occurs, whereby the SMPS transformer ( The noise of 1) is generated, and since the stable power is not supplied to the microcomputer M, there is a problem that the operation of the microcomputer M becomes unstable.

Therefore, in the present invention, in order to solve such a conventional problem, when the DPMS mode is turned off, the oscillator of the SMPS control means is stopped to stop the operation of the SMPS transformer, and the microcomputer generates at least a sub-power required for the operation to save power. It is possible to supply low voltage at, so as to prevent the noise of SMPS transformer in DPMS mode off state and to always supply stable power to microcomputer.

1 is a circuit diagram showing the configuration of a conventional SPMS power supply circuit.

Figure 2 is a circuit diagram showing the configuration of the microcomputer stabilization device in the present invention DMPS off mode.

The microcomputer stabilization device in the present invention DPM off mode,

An SMPS power supply circuit comprising an SMPS control means having an oscillator for receiving and oscillating a secondary output horizontal pulse of a high voltage output transformer to control an operation of an SMPS transformer,

Horizontal pulse detection means for detecting the secondary horizontal pulse of the high-voltage output transformer to determine the on / off of the DPMS mode, and the DPMS mode on / off depending on whether or not the horizontal pulse detection means When the DPMS mode is turned off, the oscillation control means for controlling the oscillator of the SMPS control means so that the SMPS transformer is not operated and the DPMS mode on / off are judged according to the presence or absence of the horizontal pulse detection of the horizontal pulse detection means. It is characterized by consisting of a low voltage generating means for generating a low voltage corresponding to the power saving mode from the AC power input at the time to supply to a circuit such as a microcomputer.

FIG. 2 is a circuit diagram showing the configuration of a microcomputer stabilization apparatus in the present invention in the DPMs (DPMS) off mode. Referring to FIG. 2, the same components as in the prior art will be described with the same reference numerals. same.

The bridge diode BD1 rectifies the supplied AC power, the capacitor C1 smoothing the DC power rectified through the bridge diode BD1, and the rectified and smoothed DC voltage is inputted to the primary side and induced to the secondary side. The SMPS transformer T1 for supplying a constant voltage to a circuit such as the microcomputer M, the SMPS control unit 1 for controlling the operation of the SMPS transformer T1 by controlling the switching operation of the transistor Q1, and the SMPS Operated by the voltage output through the transformer T1, the secondary voltage of the SMPS transformer 1 is fed back to the feedback voltage terminal V _FB of the SMPS controller 1 and the comparator CMP, thereby supplying the SMPS transformer T1. Optical coupler (PC1) to control the operation of the, and receives the secondary horizontal pulse (HP) of the feedback flyback transformer is fed to the secondary side, and the induced pulse oscillator (OSC) of the SMPS controller 1 In the SMPS power circuit consisting of a transformer (T2) for transmitting to

A horizontal pulse detector (2) and a signal input from the horizontal pulse detector (2) to detect the horizontal pulse (HP) induced to the secondary side of the transformer (T2) to determine the on / off of the DPMS mode The OSC controller 3 and the horizontal pulse detector 2 for determining the DPMS mode on / off and controlling the oscillator OSC of the SMPS controller 1 so that the SMPS transformer is not operated when the DPMS mode is off. The low voltage generator (4) determines the DPMS mode on / off according to the signal input from the controller, and generates a low voltage corresponding to the power saving mode from the AC power input when the DPMS mode is off and supplies it to a circuit such as a microcomputer (M). It is characterized by including the configuration,

The horizontal pulse detector 2 is a transistor Q2 that receives the secondary output voltage pulse of the transformer T2 as a base and is a signal input to the base according to the on / off switching operation of the transistor Q2. And a transistor (Q4) for switching operation.

The OSC control unit 3 is a signal input to the base according to the switching operation of the transistor Q2, and is composed of a transistor Q6 which stops the operation of the oscillator OSC of the SMPS control unit 1 by the switching operation. ,

The low voltage generator 4 receives a transistor Q3 which is turned on when the transistor Q4 of the horizontal pulse detector 2 is turned on and a voltage applied from a collector terminal of the transistor Q3 as a base. Transistor Q5 for controlling the operation of the transformer T3 by switching operation and AC power input through the transistor Q3 are induced to the secondary side with a constant voltage conversion ratio, and the induced voltage is transferred to the diode D9. And a transformer T3 supplied to a circuit such as a microcomputer M and a transformer T4 for synchronizing with the SMPS transformer T1.

Reference numerals R9 to R16 denote resistors, C6 to C8 denote capacitors, D5 to D9 diodes, and L1 denote coils.

In the DPMS off mode of the present invention having such a configuration, the microcomputer stabilization apparatus stops the operation of the SMPS transformer from the SMPS control means in the DPMS off mode operating in the power saving mode, and generates power to be supplied to the microcomputer as a negative power supply. To make it available.

In the DPMS off mode, in order to operate in the power saving mode without supplying full power, the potential of the VCC of the SMPS controller 1 is set to about half lower than that in the on mode. The primary side abnormal oscillation of (1) occurs.

In the present invention, it is possible to prevent this to be able to supply a stable power supply to the microcomputer (M) even in the DPMS off mode,

First, the secondary horizontal pulse of the flyback transformer is induced to the resistor R8 through the transformer T2, and the thus induced pulse voltage is supplied to the oscillator OSC of the SMPS controller 1.

In this case, the induced pulse is current limited through the bias resistor R9 of the horizontal pulse detector 2, rectified and smoothed by the diode D5 and the capacitor C6, and input to the base of the transistor Q2.

When such a voltage is input to the base of the transistor Q2, the transistor Q2 is turned on, so that the collector terminal of the transistor Q2 becomes low.

Accordingly, since the base potential of the transistor Q6 connected to the collector terminal of the transistor Q2 is also low, the transistor Q6 is maintained in the off state, so that the SMPS transformer T1 operates normally.

In addition, since the transistor Q2 is turned on, the base potential of the transistor Q4 is turned low, and since the transistor Q4 is turned off, the base of the transistor Q3 is opened to operate the transistor Q3. You will not.

Therefore, since the transistor Q5 is turned off and the transformer T3 does not operate, only the secondary voltage of the SMPS transformer T1 is supplied to a circuit such as the microcomputer M.

However, since the horizontal pulse is not input in the DPMS off mode, the base of the transistor Q2 goes low, so the transistor Q2 is turned off.

When the transistor Q2 is turned off, since the base potential of the transistor Q6 becomes high, the transistor Q6 is turned on, and thus the oscillator OSC of the SMPS controller 1 stops operating.

Therefore, the secondary voltage is not induced by the SMPS transformer T1.

When the transistor Q2 is turned off, the base potential of the transistor Q4 becomes high, so that the transistor Q2 is turned on to operate the transistor Q3.

Accordingly, the voltage induced by the transistor Q5 is turned on from the supplied AC power supply to the secondary side of the transformer T3 and rectified and smoothed through the diode D8 and the capacitor C8 to a circuit such as a microcomputer M. Will be supplied.

That is, in the DPMS off mode, the secondary induced voltage of the SMPS transformer T1 is not generated, and the voltage generated by the transformer T3 is supplied to a circuit such as the microcomputer M.

At this time, the voltage generated by the transformer T3 is the minimum voltage at which a circuit such as the microcomputer M can be stably operated in the power saving mode.

As described above, the horizontal pulse is input from the high-voltage output circuit, the DPMS on / off mode is judged according to the input of the horizontal pulse, and when the DPMS off mode is in the power saving mode, the oscillator of the SMPS control unit is stopped. The noise of SMPS transformer by abnormal side oscillation is prevented and the negative power is generated so that the generated negative power is supplied to a circuit such as a microcomputer instead of the voltage induced from the SMPS transformer, thereby correlating with DPMS on / off. Since it is possible to always supply a stable power supply to a circuit such as a microcomputer, there is an effect that can provide a reliable device.

Claims (2)

An SMPS power supply circuit comprising an SMPS control means having an oscillator for receiving and oscillating a secondary output horizontal pulse of a high voltage output transformer to control an operation of an SMPS transformer, Horizontal pulse detection means for detecting the secondary horizontal pulse of the high-voltage output transformer to determine the on / off of the DPMS mode, and the DPMS mode on / off depending on whether or not the horizontal pulse detection means When the DPMS mode is turned off, the oscillation control means for controlling the oscillator of the SMPS control means so that the SMPS transformer is not operated and the DPMS mode on / off are judged according to the presence or absence of the horizontal pulse detection of the horizontal pulse detection means. A microcomputer stabilization device in a DCS off mode, characterized in that the low-voltage generating means for generating a low voltage corresponding to the power saving mode from the AC power input at the time to supply to a circuit such as a microcomputer. 2. The transistor of claim 1, wherein the horizontal pulse detecting means (2) is adapted to switch between the transistor (Q2) and the on / off switching operation of the transistor (Q2) by receiving a secondary output voltage pulse of the transformer (T2) as a base. According to the signal input to the base, it comprises a transistor (Q4) for switching operation, The OSC control unit 3 is a signal input to the base according to the switching operation of the transistor Q2, and is composed of a transistor Q6 which stops the operation of the oscillator OSC of the SMPS control unit 1 by the switching operation. , The low voltage generator 4 receives a transistor Q3 which is turned on when the transistor Q4 of the horizontal pulse detector 2 is turned on and a voltage applied from a collector terminal of the transistor Q3 as a base. Transistor Q5 for controlling the operation of the transformer T3 by switching operation and AC power input through the transistor Q3 are induced to the secondary side with a constant voltage conversion ratio, and the induced voltage is transferred to the diode D9. The microcomputer stabilizes the microcomputer in the DMPS off mode, characterized in that it comprises a transformer T3 supplied to a circuit such as the microcomputer M, and a transformer T4 for synchronizing with the SMPS transformer T1. Device.