JP5581993B2 - Reset circuit - Google Patents

Description

  The present invention relates to a reset circuit, and more particularly to a reset circuit capable of resetting a first control circuit and a second control circuit in synchronization with rising of an output of a power supply circuit.

  Generally, in a reset IC, a predetermined power supply line is used as an input voltage, a low level signal is output until the input voltage exceeds a predetermined threshold, and a high level signal is output when the input voltage exceeds a predetermined threshold (Patent Document). 1 paragraph 0011 etc.).

  However, a malfunction may occur when the input voltage is equal to or lower than the operating voltage of the reset IC (paragraph 0011 of Patent Document 2). For example, in Patent Document 2, the reset IC is operated when the input voltage is equal to or lower than the operating voltage of the reset IC. A circuit configuration is disclosed in which the output is maintained and the output is maintained at a low level. Patent Document 3 discloses a reset device that can arbitrarily change the reset operation voltage without using a dedicated reset IC. Further, in Patent Document 4, it is ensured by resetting the CPU with a CPU initialization reset signal composed of a first variation including a rising edge and a second variation including a subsequent trailing edge. A technique for stably initializing a CPU is disclosed.

JP 2005-285041 A JP 2003-330574 A Utility Model Registration No. 3019111 JP 2003-052996 A

Here, the configuration of the conventional power supply circuit and reset circuit will be described with reference to FIG. In FIG. 3, the reset circuit 5 is supplied with a power supply voltage from the power supply circuit 1. The power supply circuit 1 is supplied with an external power supply voltage (for example, a commercial AC voltage) by connecting a plug to an outlet for supplying power, and generates a plurality of power supply voltages using the external power supply voltage. -Output is possible. In addition, the power supply circuit 1 has a rise time that varies from the start of the supply of the power supply voltage to the specified output due to the rating of the elements used inside, variations in element characteristics, temperature, etc. To do. In FIG. 3 , the power supply circuit 1 is illustrated as a self-excited switching power supply circuit.

In FIG. 3 , the reset IC 5 outputs a reset signal to the first control circuit 4a and the second control circuit 4b to reset it. The first control circuit 4a and the second control circuit 4b are initialized by the reset.

  The regulator IC 2 regulates the first voltage supplied from the power supply circuit 1 and outputs a second voltage (first voltage ≧ second voltage). The regulator IC 2 regulates the first voltage input from the power supply circuit 1 to the operating voltage Vd1 (for example, 3.3 V) of the first control circuit 4a, and supplies the first voltage to the first control circuit 4a as the second voltage. When the second voltage output from the regulator IC2 becomes equal to or higher than the operating voltage Vd1 of the first control circuit 4a, the first control circuit 4a is activated.

  The regulator IC 3 regulates the third voltage (first voltage> third voltage) supplied from the power supply circuit 1 and outputs the fourth voltage (third voltage ≧ fourth voltage). The regulator IC3 regulates the third voltage input from the power supply circuit 1 to the operating voltage Vd2 (for example, 3.3 V) of the second control circuit 4b and supplies the regulated voltage to the second control circuit 4b. When the fourth voltage output from the regulator IC3 becomes equal to or higher than the operating voltage Vd2 of the second control circuit 4b, the second control circuit 4b is activated.

  The reset IC 5 includes an input terminal and an output terminal. When the second voltage is input to the input terminal and this voltage is less than a predetermined threshold, and for a predetermined time ( For example, a reset signal (for example, a low level signal) is output from the output terminal until 150 ms) elapses. Thereafter, when a predetermined time has elapsed, the output of the reset signal is stopped (for example, a high level signal is output).

  The operation in the configuration of FIG. 3 described above will be described with reference to the timing chart of FIG. FIG. 2 is a timing chart showing changes in signals input to and output from a conventional reset circuit.

  First, when a device plug is connected to an outlet, supply of AC power to the power supply circuit 1 is started. Then, the power supply circuit 1 applies the power supply voltage converted into a direct current by a noise removal circuit, a rectifier circuit, or the like to the primary winding of the switching transformer with a predetermined switching period by the self-excited oscillation circuit. At this time, since the first control circuit 4a is not activated, a predetermined control signal (P-ON signal) is not output, and the power supply circuit 1 switches the FET on and off at a switching cycle for supplying a standby voltage. The output is raised to output the standby voltage. For example, as shown in parentheses in FIG. 4, the power supply circuit 1 gradually increases the first voltage toward 7V and gradually increases the third voltage toward about 1.5V.

  Here, if the operating voltage Vd1 of the first control circuit 4a is 3.3V, the first control circuit 4a is activated when the first voltage exceeds 3.3V and the second voltage also exceeds 3.3V. Also, 3.3V is input to the input terminal of the reset IC 5, and the reset IC 5 starts counting for a predetermined time (for example, 150 ms). At this time, since the count of the reset IC 5 has just started, a reset signal is output from the reset IC 5 to the first control circuit 4a, and the first control circuit 4a is activated after being initialized before being activated.

  Next, when activated, the first control circuit 4a starts outputting a predetermined control signal (P-ON signal). The predetermined control signal is input to the primary side via the photocoupler of the power supply circuit 1. When a predetermined control signal is input, the power supply circuit 1 raises the switching period and raises the output to output an on-voltage compared to when the predetermined control signal is not input. The on-voltage is higher than the standby voltage. For example, the on-voltage is 24V when the first voltage sufficiently rises and 5V when the third voltage sufficiently rises.

  Further, a predetermined control signal (P-ON signal) output by the first control circuit 4a at the time of activation is also input to the enable terminal of the regulator IC3. The regulator IC 3 starts regulation when a predetermined control signal is input to the enable terminal.

  In this way, the power supply circuit 1 increases the output, but the rise time of the output of the power supply circuit 1 varies due to various factors. Therefore, before the fourth voltage output from the regulator IC3 reaches the operating voltage of the second control circuit 4b and the second control circuit 4b is started, the count of the predetermined time of the reset IC5 is completed, and the reset IC5 There is a possibility of stopping the output. Then, the second control circuit 4b is started without being initialized, and there is a possibility that a malfunction occurs in the operation.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide a reset circuit that can be reliably reset when the control circuit is activated.

  In order to solve the above-mentioned problem, in the invention according to claim 1 of the present invention, in the reset circuit including the reset signal output circuit that outputs the reset signal to the first control circuit and the second control circuit, the output timing of the reset signal Is provided with an output timing control circuit for controlling.

In the above configuration, the first regulator circuit receives a first voltage from a power supply circuit that generates and outputs a plurality of power supply voltages, and a first voltage generated by regulating the first voltage is a first voltage. Supply to the control circuit. The second regulator circuit receives a third voltage lower than the first voltage from the power supply circuit, and supplies a fourth voltage generated by regulating the third voltage to the second control circuit. The first control circuit starts after initialization if the reset signal is input when the second voltage reaches the operating voltage, and the second control circuit starts up after the fourth voltage reaches the operating voltage. If the reset signal is input at this time, it starts after initialization. Therefore, before Symbol reset signal output circuit by outputting a reset signal at the right time and the first control circuit and the second control circuit, and the first control circuit and said second control circuit, starting It can be initialized before.

  Therefore, the output timing control circuit causes the reset signal output circuit to continue outputting the reset signal until the first voltage exceeds a fifth voltage higher than the second voltage and until a predetermined time elapses thereafter. When the predetermined time elapses after one voltage exceeds the fifth voltage, the reset signal output circuit stops the output of the reset signal. According to this configuration, by appropriately setting the fifth voltage, it is possible for the reset circuit to continue outputting the reset signal until after the second control circuit is activated, and the first control circuit And the second control circuit can be surely initialized before starting. Therefore, the first control circuit and the second control circuit can be safely and reliably reset and started normally.

  As a selective aspect of the present invention, the fifth voltage is a power source supplied from the second regulator circuit to the second control circuit after a lapse of the predetermined time after the first voltage exceeds the fifth voltage. The voltage is set so as to exceed the operating voltage of the second control circuit. According to this configuration, the fifth voltage can be set specifically and easily.

  As a selective aspect of the present invention, the power supply circuit is a self-excited switching power supply circuit, and is configured such that the rise time of the output voltage varies depending on the change in the rating of the starting resistor. According to this configuration, even if the rise time of the power supply circuit varies by changing the rating of the starting resistance of the power supply circuit, the first control circuit and the second control circuit can be adjusted by appropriately adjusting the fifth voltage. The control circuit can be reliably and easily initialized before starting.

  As a selective aspect of the present invention, the power supply circuit is a self-excited switching power supply circuit, and the rise time of the output voltage varies due to variations in the resistance value of the starting resistor and the turn-on threshold value of the switching element. It is said. According to this configuration, even if the rise time of the power supply circuit varies due to variations in the resistance value of the starting resistance of the power supply circuit and the turn-on threshold value of the switching element, the fifth voltage can be adjusted by appropriately adjusting the fifth voltage. The first control circuit and the second control circuit can be reliably and easily initialized before starting.

  As a selective aspect of the present invention, the second regulator circuit generates a fourth voltage generated by regulating the third voltage when a predetermined control signal is input to a predetermined control terminal. The first control circuit is activated after initialization when the reset signal is input when the second voltage reaches the operating voltage, and the predetermined control terminal of the second regulator circuit A predetermined control signal is input to the. According to this configuration, the first control circuit and the first control circuit are adjusted by adjusting the fifth voltage in consideration of the time from when the predetermined control signal is input to when the output of the third voltage is started. The second control circuit can be reliably initialized before starting.

  As a selective aspect of the present invention, when the reset signal is input when the second voltage reaches the operating voltage, the first control circuit is started after initialization and predetermined to the power supply circuit. The power supply circuit is a switching power supply circuit, and when the predetermined control signal is input, the switching cycle is increased compared to when the predetermined control signal is not input. According to this configuration, when the rise of the output of the power supply voltage becomes faster due to an increase in the switching cycle of the power supply circuit, the first control circuit is adjusted by adjusting the fifth voltage in consideration of the rise speed. And the second control circuit can be surely initialized before starting.

  As an alternative aspect of the present invention, the output timing control circuit includes a Zener diode having a cathode connected to the first voltage supply line and an anode connected to the ground via a resistor, and the reset circuit connected to the reset circuit. A PNP transistor having an emitter connected to a line for inputting two voltages, a collector connected to the ground, and a base connected to the anode of the Zener diode through a resistor, wherein the first voltage is less than the fifth voltage In this case, the Zener diode does not breakdown and the PNP transistor is turned on, and when the first voltage becomes equal to or higher than the fifth voltage, the Zener diode breaks down and the PNP transistor is turned off. According to this configuration, the output timing control circuit can be specifically realized.

As an optional aspect of the present invention,
The power supply circuit is a self-excited switching power supply circuit, and the rise time of the output voltage fluctuates due to the change in the rating of the starting resistor and the variation of the resistance value of the starting resistor and the turn-on threshold of the switching element,
The reset signal output circuit is a reset IC including an input terminal, an output terminal, and a ground terminal, the input terminal is connected to the second voltage supply line, and the output terminals are the first control circuit and the second control circuit. Connected to the reset terminal, ground terminal connected to ground,
The first regulator circuit is a regulator IC having an input terminal, an output terminal, and a ground terminal, and the first voltage is input to the input terminal, and the second voltage is supplied from the output terminal to the first control circuit. , The ground terminal is connected to the ground,
The second regulator circuit is a regulator IC having an input terminal, an output terminal, a ground terminal, and an enable terminal. The third voltage is input to the input terminal, and the fourth voltage is output from the output terminal to the second control circuit. The output of the fourth voltage is stopped while the ground terminal is connected to the ground, and the predetermined control signal is not input to the enable terminal, and when the predetermined control signal is input to the enable terminal, Supplying a fourth voltage to the second control circuit;
The first control circuit is activated after initialization when the reset signal is input to the reset terminal when the second voltage reaches the operating voltage, and the first control circuit is activated after the enable terminal of the second regulator circuit and the power source A predetermined control signal is input to the circuit,
When the predetermined control signal is input, the power supply circuit increases the switching period compared to when the predetermined control signal is not input.
The output timing control circuit has a cathode connected to the first voltage supply line and an anode connected to the ground via a resistor, and an emitter connected to the reset voltage input line for the second voltage. And a PNP transistor having a collector connected to the ground and a base connected to the anode of the Zener diode through a resistor,
When the first voltage is less than the fifth voltage, the Zener diode does not breakdown, and the PNP transistor is turned on to supply the ground to the input terminal of the reset IC. Output a reset signal,
When the first voltage becomes equal to or higher than the fifth voltage, the Zener diode breaks down, turns off the PNP transistor, and inputs the voltage of the second voltage supply line to the input terminal of the reset IC, Thereafter, the reset IC may stop outputting the reset signal after the predetermined time has elapsed.

As described above, according to the present invention, it is possible to provide a reset circuit capable of initializing the first control circuit and the second control circuit before starting.
According to the invention of claim 2, the fifth voltage can be specifically realized.
According to the third aspect of the present invention, even if the rise time of the power supply circuit varies by changing the rating of the starting resistance of the power supply circuit, the first control circuit and the second control circuit can be adjusted by appropriately adjusting the fifth voltage. The control circuit can be reliably initialized before starting.
According to the invention of claim 4, even if the rise time of the power supply circuit varies due to variations in the resistance value of the starting resistance of the power supply circuit and the turn-on threshold value of the switching element, the fifth voltage is appropriately adjusted. Thus, the first control circuit and the second control circuit can be reliably initialized before starting.
According to the fifth aspect of the present invention, the first control circuit and the first control circuit are adjusted by adjusting the fifth voltage in consideration of the time from when the predetermined control signal is input until the output of the third voltage is started. It is possible to reliably initialize the two control circuits before starting.
According to the sixth aspect of the present invention, when the rise of the output of the power supply voltage becomes faster due to an increase in the switching period of the power supply circuit, the first control is performed by adjusting the fifth voltage in consideration of this rise speed. The circuit and the second control circuit can be reliably initialized before starting.
According to the invention of claim 7, the output timing control circuit can be specifically realized.
Needless to say, in a more specific configuration as in the eighth aspect, the same effects as those of the first to seventh aspects of the invention described above can be achieved.

It is a circuit diagram which shows the structure of a reset circuit. It is a timing chart which shows the change of the signal inputted / outputted to a reset circuit. It is a circuit diagram which shows the structure of the conventional reset circuit. It is a timing chart which shows the change of the signal inputted / outputted to the conventional reset circuit.

Hereinafter, embodiments of the present invention will be described in the following order.
(1) Configuration of the present embodiment:
(2) Operation of this embodiment:
(3) Summary:

(1) Configuration of the present embodiment:
First, the configuration of a reset circuit that specifically implements the present invention will be described with reference to FIG. FIG. 3 is a circuit diagram in the case where the reset circuit according to the present embodiment is arranged between a power supply circuit and a control circuit included in an electric device or electronic device. Of course, the reset circuit according to the present embodiment can be realized as part of the power supply circuit, realized as part of the control circuit, or included in various other circuits.

  In FIG. 1, the reset circuit 100 is supplied with a power supply voltage from the power supply circuit 10. The power supply circuit 10 is supplied with an external power supply voltage (for example, commercial AC voltage) by connecting a plug to an outlet for supplying power, and generates a plurality of power supply voltages using the external power supply voltage. -Output is possible. In addition, the power supply circuit 10 has a rise time that varies from the start of the supply of the power supply voltage to the specified output due to the rating of the elements used internally, variations in element characteristics, temperature, etc. To do. Such a power supply circuit 10 is configured, for example, as a self-excited or separately-excited switching power supply circuit, and FIG. 1 illustrates a self-excited switching power supply circuit. The rating of the element that affects the rise time of the output voltage is, for example, the resistance value of the starting resistor, and the characteristic variation of the element that affects the rise time of the output voltage is, for example, the resistance value of the starting resistor or the turn-on threshold of the switching element. Variation.

  In FIG. 1, the reset circuit 100 outputs a reset signal to the reset terminals of the first control circuit 41 and the second control circuit 42 and resets them in synchronization with the rise of the power supply voltage supplied from the power supply circuit 10. The first control circuit 41 and the second control circuit 42 are initialized by the reset and can be normally started.

  The first control circuit 41 operates even during the standby of the device. For example, the first control circuit 41 monitors an operation signal input from an operation unit such as a remote controller or a tact switch, and activates the second control circuit 42 as necessary. Bear. The second control circuit 42 stops when the device is on standby, and starts when the device is turned on to execute main control of the device. Thus, by preparing two control subjects, power saving can be appropriately realized. Specifically, the first control circuit 41 and the second control circuit can be configured by a microcomputer or a CPU (Central Processing Unit).

  A voltage obtained by regulating the output of the power supply circuit 10 to a constant value via the regulator circuit is supplied to the above control circuit as an operating voltage. An operating voltage is supplied to the first control circuit 41 via the regulator IC 20, and an operating voltage is supplied to the second control circuit 42 via the regulator IC 30w. In the present embodiment, the regulator IC 20 constitutes a first regulator circuit, and the regulator IC 30 constitutes a second regulator circuit.

  The regulator IC 20 regulates the first voltage supplied from the power supply circuit 10 and outputs a second voltage (first voltage ≧ second voltage). Specifically, the regulator IC 20 includes an input terminal 21, an output terminal 22, and a ground terminal 23. The first voltage input from the input terminal 21 is used as the operating voltage Vd1 (for example, 3.. 3V) and output from the output terminal 22 as the second voltage. The ground terminal 23 is connected to the ground. The regulator IC 20 outputs the first voltage as it is as the second voltage when the first voltage is lower than the operating voltage Vd1 of the first control circuit 41. Thus, when the second voltage output from the regulator IC 20 becomes equal to or higher than the operating voltage Vd1 of the first control circuit 41, the first control circuit 41 is activated.

  The regulator IC 30 regulates the third voltage (first voltage> third voltage) supplied from the power supply circuit 10 and outputs the fourth voltage (third voltage ≧ fourth voltage). Specifically, the regulator IC 30 includes an input terminal 31, an output terminal 32, a ground terminal 33, and an enable terminal 34. The third voltage input from the input terminal 31 is used as the operating voltage Vd2 of the second control circuit 42. The voltage is regulated to (eg, 3.3 V) and output from the output terminal 32 as the fourth voltage. The ground terminal 33 is connected to the ground. The regulator IC 30 outputs the third voltage as it is as the fourth voltage when the third voltage is lower than the operating voltage Vd2 of the second control circuit 42. Thus, when the fourth voltage output from the regulator IC 30 becomes equal to or higher than the operating voltage Vd2 of the second control circuit 42, the second control circuit 42 is activated.

  However, the regulator IC 20 stops the regulation when a predetermined control signal (for example, a P-ON signal described later) is not input to the enable terminal 34. That is, when the predetermined control signal is not input to the enable terminal 34, the fourth voltage is not output from the output terminal 32, and when the predetermined control signal is input to the enable terminal 34, regulation is performed and output. A fourth voltage is output from the terminal 32. In the present embodiment, the enable terminal 34 constitutes a predetermined control terminal.

  Next, the reset circuit 100 will be described. The reset circuit 100 includes a reset IC 110 that outputs a reset signal to the first control circuit 41 and the second control circuit 42, and an output timing control circuit that synchronizes the output timing of the reset signal output from the reset IC 110 with the output rise of the power supply circuit 10. 120. In the present embodiment, the reset IC 110 constitutes a reset signal output circuit.

  The reset IC 110 includes an input terminal 111, an output terminal 112, and a ground terminal 113. When the voltage is input from the output timing control circuit 120 to the input terminal 111 and the voltage is less than a predetermined threshold value, this voltage is set. A reset signal (for example, a low level signal) is output from the output terminal 112 until a predetermined time (for example, 150 ms) elapses after the threshold value becomes equal to or greater than a predetermined threshold. Thereafter, when a predetermined time has elapsed, the output of the reset signal is stopped (for example, a high level signal is output). That is, the output of the reset signal is continued until a timing instructed from the output timing control circuit 120 (a predetermined time (for example, 150 ms) has elapsed after a voltage equal to or higher than a predetermined threshold is input from the output timing control circuit 120). The ground terminal 113 is connected to the ground.

  Specifically, the output timing control circuit 120 includes a Zener diode 121, a PNP transistor 122, and resistors 123 to 125. The Zener diode 121 has a cathode connected to the first voltage supply line and an anode connected to the ground via a resistor 125. The PNP transistor 122 has an emitter connected to the input terminal 111 of the reset IC 110, a collector connected to the ground, and a base connected to the anode of the Zener diode 121 via the resistor 124.

  The output timing control circuit 120 configured as described above controls the input timing of the second voltage input to the input terminal 111 of the reset IC 110 based on the first voltage input to the regulator IC 20, and thereby the reset IC 110. Controls the output timing of the reset signal to be output.

  Specifically, the Zener diode 121 does not breakdown when the first voltage is less than the breakdown voltage, and as a result, a potential difference that can turn on the PNP transistor 122 is generated between the emitter and base of the PNP transistor 122, The PNP transistor 122 is turned on. At this time, the input terminal 111 of the reset IC 110 is connected to the ground, the reset IC 110 outputs a reset signal from the output terminal 112, and the reset signal is input to the first control circuit 41.

  Further, the Zener diode 121 breaks down when the first voltage becomes equal to or higher than the breakdown voltage. As a result, the base voltage of the PNP transistor 122 becomes higher than the emitter voltage, and the PNP transistor 122 is turned off. That is, the second voltage is input to the input terminal 111 of the reset IC 110 via the resistor 123. If the second voltage input at this time is less than a predetermined threshold value, the reset IC 110 outputs a reset signal from the output terminal 112. If the second voltage input is equal to or higher than the predetermined threshold value, then the reset IC 110 outputs a predetermined time ( For example, the reset signal is output from the output terminal 112 until 150 ms), and when the predetermined time has elapsed, the output of the reset signal is stopped.

  In the present embodiment, the breakdown voltage of the Zener diode 121 constitutes the fifth voltage. The power supply voltage supplied from the regulator IC 20 to the second control circuit 42 after the elapse of a predetermined time (for example, 150 ms) after the first voltage exceeds the fifth voltage is determined by the operation of the second control circuit 42. It is set to exceed the voltage.

  Specifically, for example, the output rise of the first voltage and the output rise of the second voltage are measured, and the timing at which the output of the second voltage reaches the operating voltage Vd2 and the second control circuit 42 is activated is determined. The voltage value of the first voltage before 150 ms can be the fifth voltage. Of course, since the rise time of the power supply circuit 10 varies as described above, the rise measurement is performed a plurality of times, and the voltage value of the first voltage when the rise of the second control circuit is the slowest is used. It is preferable to determine the fifth voltage.

  The fifth voltage is set within a range not exceeding the first voltage (7 V in FIG. 2 described later) when the rising of the power supply circuit 10 is completed. By setting the fifth voltage in this manner, once the rising of the first voltage is completed, the first control circuit 41 as well as the second control circuit 42 can be reset as long as the plug is connected to the outlet. It will not take. Therefore, the second control circuit 42 can perform an operation reflecting the state before the transition to the standby when returning from the standby to the on state.

(2) Operation of this embodiment:
1 will be described with reference to the timing chart of FIG. In the figure, changes in signals input to and output from the reset circuit are shown in a timing chart.

  First, when a device plug is connected to an outlet, supply of AC power to the power supply circuit 10 is started. Then, the power supply circuit 10 applies the power supply voltage converted into a direct current by a noise removal circuit, a rectifier circuit, or the like to the primary winding of the switching transformer with a predetermined switching cycle by the self-excited oscillation circuit. At this time, since the first control circuit 41 is not activated, a predetermined control signal (P-ON signal) is not output, and the power supply circuit 10 switches the FET on and off at a switching cycle for supplying a standby voltage. The output is raised to output the standby voltage. For example, as shown in parentheses in FIG. 2, the power supply circuit 10 gradually increases the first voltage toward 7V and gradually increases the third voltage toward about 1.5V.

  Here, if the operating voltage Vd1 of the first control circuit 41 is 3.3V, the first control circuit 41 is activated when the first voltage exceeds 3.3V and the second voltage also exceeds 3.3V. At this time, since the output timing control circuit 120 drops the voltage input to the input terminal 111 of the reset IC 110 to the ground, the reset IC 110 inputs the reset signal to the first control circuit 41. Accordingly, the first control circuit 41 is activated after being initialized before being activated. Therefore, the first control circuit 41 starts up normally.

  Next, when activated, the first control circuit 41 starts outputting a predetermined control signal (P-ON signal). The predetermined control signal is input to the primary side via the photocoupler of the power supply circuit 10. When a predetermined control signal is input, the power supply circuit 10 increases the switching period compared to when the predetermined control signal is not input, and increases the output to output an on-voltage. The on-voltage is higher than the standby voltage. For example, when the first voltage is sufficiently increased, the on-voltage is 24V, and when the third voltage is sufficiently increased, the on-voltage is 5V.

  A predetermined control signal (P-ON signal) output from the first control circuit 41 at the time of activation is also input to the enable terminal 34 of the regulator IC 30. The regulator IC 30 starts regulation when a predetermined control signal is input to the enable terminal 34.

  When the power supply circuit 10 increases the output in this way, the first voltage exceeds the fifth voltage at any timing. Then, the Zener diode 121 of the output timing control circuit 120 breaks down, and the PNP transistor 122 is turned off. Then, a voltage corresponding to the second voltage is input to the input terminal 111 of the reset IC 110, and the reset IC 110 starts counting for a predetermined time (for example, 150 ms).

  When the operating voltage Vd2 of the second control circuit 42 is 3.3 V, the fourth voltage output from the regulator IC 30 exceeds 3.3 V while the reset IC 110 is counting for a predetermined time, so that the fourth voltage is increased. When the voltage also exceeds 3.3V, the second control circuit 42 is activated. Thereafter, when the counting for a predetermined time (for example, 150 ms) is completed, the reset IC 110 stops the reset signal output from the output terminal 112 (sets to a high level signal). As described above, when the output timing control circuit 120 appropriately controls the output timing of the reset signal of the reset IC 110, the reset signal is reliably input when the second control circuit 42 is activated. 42 starts after initialization before starting. Therefore, the second control circuit 42 starts up normally.

(3) Summary:
As described above, the reset circuit 100 according to this embodiment includes the first control circuit that is activated after initialization if the reset signal is input when the second voltage supplied from the regulator IC 20 reaches the operating voltage. 41, a second control circuit 42 that is activated after initialization if a reset signal is input when the fourth voltage supplied from the regulator IC 30 reaches the operating voltage, and a first voltage input from the power supply circuit 10 And a regulator IC 20 that supplies the second voltage that regulates the second voltage to the first control circuit 41. The fourth voltage that regulates the third voltage (<first voltage) input from the power supply circuit 10 is the first voltage. 2 regulator IC 30 supplied to the control circuit 42 and reset IC 110 until the first voltage exceeds the fifth voltage (> second voltage) and 150 ms elapses. Allowed to continue resetting comprises first voltage and an output timing control circuit 120 to stop outputting the reset signal when 150ms elapsed beyond the fifth voltage. Therefore, the microcomputer and the CPU can be safely and reliably reset and started normally.

Needless to say, the present invention is not limited to the above embodiments. It goes without saying for those skilled in the art,
・ Applying mutually interchangeable members and configurations disclosed in the above embodiments by appropriately changing the combination thereof.− Although not disclosed in the above embodiments, it is a publicly known technique and the above embodiments. The members and configurations that can be mutually replaced with the members and configurations disclosed in the above are appropriately replaced, and the combination is changed and applied. It is an embodiment of the present invention that a person skilled in the art can appropriately replace the members and configurations that can be assumed as substitutes for the members and configurations disclosed in the above-described embodiments, and change the combinations and apply them. It is disclosed as.

DESCRIPTION OF SYMBOLS 10 ... Power supply circuit, 20 ... Regulator IC, 21 ... Input terminal, 22 ... Output terminal, 23 ... Ground terminal, 30 ... Regulator IC, 31 ... Input terminal, 32 ... Output terminal, 33 ... Ground terminal, 34 ... Enable terminal, DESCRIPTION OF SYMBOLS 41 ... 1st control circuit, 42 ... 2nd control circuit, 100 ... Reset circuit, 111 ... Input terminal, 112 ... Output terminal, 113 ... Ground terminal, 120 ... Output timing control circuit, 121 ... Zener diode, 122 ... PNP type Transistor, 123 ... resistor, 124 ... resistor, 125 ... resistor

Claims (8)

In a reset circuit including a reset signal output circuit that outputs a reset signal to the first control circuit and the second control circuit,
The first control circuit starts after initialization if the reset signal is input when the second voltage supplied from the first regulator circuit reaches the operating voltage.
The first regulator circuit receives a first voltage from a power supply circuit that generates and outputs a plurality of power supply voltages, and supplies the second voltage generated by regulating the first voltage to the first control circuit. And
The second control circuit is activated after initialization if the reset signal is input when the fourth voltage supplied from the second regulator circuit reaches the operating voltage.
The second regulator circuit is input the third voltage have lower than the first voltage from the power supply circuit to supply the fourth voltage generated by regulating the third voltage to the second control circuit,
The reset circuit further causes the reset signal output circuit to continue outputting the reset signal until the first voltage exceeds a fifth voltage higher than the second voltage and until a predetermined time elapses thereafter. A reset circuit comprising: an output timing control circuit that causes the reset signal output circuit to stop outputting the reset signal when the predetermined time elapses after the voltage exceeds the fifth voltage.   The power supply voltage supplied from the second regulator circuit to the second control circuit after the elapse of the predetermined time after the first voltage exceeds the fifth voltage is the operating voltage of the second control circuit. The reset circuit according to claim 1, wherein the reset circuit is set to exceed.   The reset circuit according to claim 1, wherein the power supply circuit is a self-excited switching power supply circuit, and a rise time of an output voltage varies depending on a change in a rating of a starting resistor.   4. The power supply circuit according to claim 1, wherein the power supply circuit is a self-excited switching power supply circuit, and the rise time of the output voltage varies due to variations in the resistance value of the starting resistor and the turn-on threshold value of the switching element. The reset circuit according to item. The second regulator circuit supplies a fourth voltage generated by regulating the third voltage to the second control circuit when a predetermined control signal is input to a predetermined control terminal.
The first control circuit is activated after initialization when the reset signal is input when the second voltage reaches the operating voltage, and a predetermined control signal is applied to a predetermined control terminal of the second regulator circuit. The reset circuit according to claim 1, wherein the reset circuit is input. The first control circuit is activated after initialization when the reset signal is input when the second voltage reaches an operating voltage, and inputs a predetermined control signal to the power supply circuit,
6. The power supply circuit according to claim 1, wherein the power supply circuit is a switching power supply circuit, and when the predetermined control signal is input, a switching cycle is increased as compared with a case where the predetermined control signal is not input. Reset circuit.   The output timing control circuit has a cathode connected to the first voltage supply line and an anode connected to the ground via a resistor, and an emitter connected to the reset voltage input line for the second voltage. And a PNP transistor having a collector connected to the ground and a base connected to the anode of the Zener diode via a resistor, and the Zener diode does not breakdown when the first voltage is less than the fifth voltage. 7. The reset according to claim 1, wherein when the PNP transistor is turned on and the first voltage becomes equal to or higher than the fifth voltage, the Zener diode breaks down and the PNP transistor is turned off. circuit. The power supply circuit is a self-excited switching power supply circuit, and the rise time of the output voltage fluctuates due to the change in the rating of the starting resistor and the variation of the resistance value of the starting resistor and the turn-on threshold of the switching element
The reset signal output circuit is a reset IC including an input terminal, an output terminal, and a ground terminal, the input terminal is connected to the second voltage supply line, and the output terminals are the first control circuit and the second control circuit. Connected to the reset terminal, ground terminal connected to ground,
The first regulator circuit is a regulator IC having an input terminal, an output terminal, and a ground terminal, and the first voltage is input to the input terminal, and the second voltage is supplied from the output terminal to the first control circuit. , The ground terminal is connected to the ground,
The second regulator circuit is a regulator IC having an input terminal, an output terminal, a ground terminal, and an enable terminal. The third voltage is input to the input terminal, and the fourth voltage is output from the output terminal to the second control circuit. The output of the fourth voltage is stopped while the ground terminal is connected to the ground, and the predetermined control signal is not input to the enable terminal, and when the predetermined control signal is input to the enable terminal, Supplying a fourth voltage to the second control circuit;
The first control circuit is activated after initialization when the reset signal is input to the reset terminal when the second voltage reaches the operating voltage, and the first control circuit is activated after the enable terminal of the second regulator circuit and the power source A predetermined control signal is input to the circuit,
When the predetermined control signal is input, the power supply circuit increases the switching period compared to when the predetermined control signal is not input.
The output timing control circuit has a cathode connected to the first voltage supply line and an anode connected to the ground via a resistor, and an emitter connected to the reset voltage input line for the second voltage. And a PNP transistor having a collector connected to the ground and a base connected to the anode of the Zener diode through a resistor,
When the first voltage is less than the fifth voltage, the Zener diode does not breakdown, and the PNP transistor is turned on to supply the ground to the input terminal of the reset IC. Output a reset signal,
When the first voltage becomes equal to or higher than the fifth voltage, the Zener diode breaks down, turns off the PNP transistor, and inputs the voltage of the second voltage supply line to the input terminal of the reset IC, The reset circuit according to claim 1, wherein the reset IC stops outputting the reset signal after the predetermined time has elapsed.

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