JP5854877B2 - Power monitoring circuit - Google Patents

Description

  The present invention relates to a power supply monitoring circuit that detects a decrease in power supply voltage and resets a microcomputer (hereinafter referred to as a microcomputer).

  An IC such as a photo IC (integrated circuit) in which a light receiving element used for a photoelectric switch and a signal processing circuit are housed in a package incorporates a power supply monitoring circuit (see, for example, Patent Document 1) for monitoring a power supply voltage. The power supply monitoring circuit outputs a signal for canceling the operation of the microcomputer when the power supply voltage of the microcomputer exceeds a reference voltage, and for resetting the power supply voltage when the power supply voltage drops below the reference voltage.

  FIG. 4 shows an example of a conventional power supply monitoring circuit. The power supply monitoring circuit 1 and the VREGD generation circuit 6 are built in the photo IC, and the photo IC operates at the VCC of the power supply E2. The VREGD generation circuit 6 converts the VCC voltage of the power supply E2 into a desired VREGD voltage and supplies it to a digital system such as a microcomputer. When the power supply E2 rises, VCC rises first, and then VREGD rises. On the other hand, when the power supply E2 falls, the capacitor C1 for stabilizing the voltage is normally connected to VREGD, so that it falls in the order of VREGD and VCC.

  In the power supply monitoring circuit 1, the reference current generation circuit 2 that uses VCC as a power supply outputs a reference current to the comparison circuit 4 when the VCC voltage exceeds a certain voltage. On the other hand, the reset release circuit 3 that uses VREGD as a power source outputs a reset release current (reset release current> reference current here) to the comparison circuit 4 when the VREGD voltage is higher than a predetermined detection voltage, When the VREGD voltage is equal to or lower than the detection voltage, the output of the reset release current is stopped. This detection voltage is a voltage value with a margin for the operating voltage of the microcomputer.

  The comparison circuit 4 compares the reset release current and the reference current, and turns on and off the reset signal output circuit 5. When the reset release current is equal to or lower than the reference current, that is, when VREGD is a low voltage, the reset signal output circuit 5 outputs a reset signal of 0V. When a 0V reset signal is input, the microcomputer resets the operation. On the other hand, when the reset release current is larger than the reference current, that is, when VREGD is a normal voltage, the reset signal output circuit 5 outputs the VREGD voltage. The microcomputer is in a reset release state while the VREGD voltage is input.

  As a result, the power supply monitoring circuit 1 outputs a reset signal up to the microcomputer operating voltage when the power supply rises, and the microcomputer starts operation from the initial state when the microcomputer operating voltage is reached.

Japanese Patent Laid-Open No. 5-189090

  However, when the power supply fall time is early, since the capacitor C1 is connected to VREGD, the power supply falls in the order of VCC and VREGD. For example, when VCC momentary power failure occurs, VREGD falls later than VCC depending on the load status and fall time of VREGD, so that the power supply monitoring circuit 1 does not operate normally and the microcomputer resets normally. There was a problem that it was not.

  Here, FIG. 5 (a) and FIG. 5 (b) show changes with time in voltage when a momentary power failure occurs in VCC. In each graph, the vertical axis represents VCC, VREGD, and reset signal voltage, and the horizontal axis represents time. In FIG. 5A, when the VCC voltage decreases after the occurrence of a momentary power failure, the reference current is not output from the reference current generation circuit 2, and therefore the comparison circuit 4 always determines that the reset release current is larger. Then, the output of the reset signal output circuit 5 remains at the VREGD voltage and does not drop to 0 V (that is, the reset signal), so that the operation of the microcomputer is not reset. As a result, the VREGD voltage drops below the microcomputer operating voltage, which may cause a stop, freeze, abnormal operation, or the like.

  Alternatively, as shown in FIG. 5B, a situation where VCC recovers first in the middle of the rise of VREGD is also conceivable. In this case, since the reference current is output from the VCC recovery time, the comparison circuit 4 determines that the reference current is larger than the reset release current, and outputs a reset signal of 0 V from the reset signal output circuit 5. However, a reset time (time for inputting a 0V reset signal) may be defined depending on the microcomputer. In such a case, a short reset signal as shown in FIG. 5B is insufficient.

  The present invention has been made to solve the above-described problems, and an object of the present invention is to provide a power supply monitoring circuit that normally outputs a reset signal regardless of the order of the power supply voltage fall and the fall time. To do.

  A power supply monitoring circuit according to claim 1 of the present invention operates at a power supply switching unit that switches to a power source having a higher voltage of the first power supply and the second power supply, and a power supply voltage that is switched by the power supply switching unit. A reference current generation unit that outputs a predetermined reference current, a reset release unit that outputs a reset release current higher than the reference current when the voltage of the second power supply is higher than the detection voltage, a reset release current, and a reference A comparison unit that compares currents and a reset signal output unit that outputs a reset signal when a reset release current is lower than a reference current based on a comparison result of the comparison unit.

  A power supply monitoring circuit according to a second aspect of the present invention includes a first diode connected to a first power supply, and a second diode connected to a second power supply, the first diode and the second diode The reference current generator is connected to the connection end between them.

  According to the present invention, since the first power supply and the second power supply are switched to the power supply having the higher voltage, the power supply voltage is normally reset regardless of the rising order and the falling time of the power supply voltage. A power supply monitoring circuit that outputs a signal can be provided.

  According to the present invention, since the power supply switching unit is constituted by two diodes, the circuit area is not increased and the cost is hardly increased.

It is a circuit diagram which shows the structure of the power supply monitoring circuit which concerns on Embodiment 1 of this invention. 1 is a block diagram showing a power circuit configuration of a photoelectric switch to which a power monitoring circuit according to a first embodiment is applied. 4 is a graph showing a change with time in voltage when an instantaneous power failure occurs in VCC in the power supply monitoring circuit according to the first embodiment. It is a circuit diagram which shows an example of the conventional power supply monitoring circuit. In the conventional power supply monitoring circuit, it is a graph which shows the time-dependent change of the voltage when a momentary power failure occurs in VCC.

Embodiment 1 FIG.
FIG. 1 is a circuit diagram showing a configuration of a power supply monitoring circuit 1a according to the first embodiment, and the same or corresponding parts as those of the conventional power supply monitoring circuit 1 (FIG. 4) described above are denoted by the same reference numerals. Attached.

  FIG. 2 is a block diagram showing a power supply circuit configuration of the photoelectric switch 10 to which the power supply monitoring circuit 1a is applied. The power supply circuit 11 steps down the power supply E1 to the power supply E2 (VCC; first power supply) of the photo IC 12. A photo IC 12 that uses VCC as a power source includes a power monitoring circuit 1a and a VREGD generation circuit 6 shown in FIG. 1 in addition to a light receiving element and a signal processing circuit. The VREGD generation circuit 6 converts VCC into a power source (VREGD; second power source) for the microcomputer 13 and the display circuit 15 which are electronic devices. In addition, a reset signal for resetting the operation of the microcomputer 13 is output from the power supply monitoring circuit 1 a to the microcomputer 13. The light projecting circuit 14 normally uses VCC, which is the output voltage of the power supply E1 or the power supply circuit 11, as a power supply.

As shown in FIG. 1, both the VCC and VREGD are connected to the input terminal of the reference current generating circuit 2a via diodes D1 and D2, respectively. A power supply switching circuit composed of these diodes D1 and D2 is provided to apply a higher voltage of VCC or VREGD to the reference current generating circuit 2a.
When VCC and VREGD are normal voltages, (VCC voltage−forward voltage of diode D1)> (VREGD voltage−forward voltage of diode D2), current flows from VCC to the reference current generation circuit 2a to generate a reference current. The circuit 2a operates with the VCC voltage.
On the other hand, when the VCC voltage decreases (VCC voltage−forward voltage of diode D1) <(VREGD voltage−forward voltage of diode D2), a current flows from VREGD to the reference current generation circuit 2a, and the reference current generation circuit 2a operates with the VREGD voltage.

  In the illustrated example, power supply switching between VCC and VREGD is performed using the diodes D1 and D2, but power supply switching between VCC and VREGD may be performed using other power supply switching circuits. However, in the case of the illustrated example, since it is a simple circuit in which only two diodes D1 and D2 are added, there is an advantage that the circuit area is not increased and the cost is hardly increased.

The reference current generation circuit 2a operates at a higher voltage of VCC and VREGD, and causes the reference current to flow to the comparison circuit 4 when the higher voltage exceeds a certain voltage. The certain voltage is a predetermined voltage lower than the normal voltages of VCC and VREGD. Further, VCC and VREGD are also connected to the input terminal of the reset signal output circuit 5a via these diodes D1 and D2, and operate at the higher voltage of VCC or VREGD, and the higher voltage or 0V is operated. Output a reset signal.

  In the reset release circuit 3, a voltage value with a margin for the operating voltage of the microcomputer 13 is set as a detection voltage. The reset release circuit 3 supplies a reset release current to the comparison circuit 4 when the VREGD voltage is higher than the detection voltage. On the other hand, when the VREGD voltage is equal to or lower than the detection voltage, the output of the reset release current is stopped. This reset release current has a value higher than the reference current.

  The comparison circuit 4 compares the reset release current output from the reset release circuit 3 with the reference current output from the reference current generation circuit 2a, and turns on the reset signal output circuit 5a when the reset release current is larger than the reference current. When the reset release current is equal to or lower than the reference current, the reset signal output circuit 5a is turned off. When the reset signal output circuit 5a is turned on by the comparison circuit 4, it outputs the higher one of VCC and VREGD to put the microcomputer 13 in the reset release state. On the other hand, when OFF, a reset signal of 0V is output, and the operation of the microcomputer 13 is reset.

  If the capacitor C1 is connected to VREGD as in the prior art example described above (shown in FIG. 4), when the fall time of the power supply E2 is early, the power supply E2 falls in the order of VCC and VREGD. When the fall time is late, the fall occurs in the order of VREGD and VCC. For example, as shown in FIG. 3, when VCC instantaneously stops, VREGD falls later than VCC depending on the load status and fall time of VREGD.

In FIG. 3, during a period of VCC> VREGD before and after the occurrence of a momentary power failure, VCC, which is a higher voltage, is applied to the reference current generation circuit 2a and the reset signal output circuit 5a via the diode D1.
The reference current generation circuit 2 a causes the reference current to flow to the comparison circuit 4 using VCC as the power supply voltage. Since the VREGD voltage is higher than the detection voltage, the reset release circuit 3 supplies a reset release current to the comparison circuit 4. Since the reset release current is larger than the reference current, the comparison circuit 4 turns on the reset signal output circuit 5a. Then, the reset signal output circuit 5a outputs VCC voltage using VCC as the power supply voltage. For this reason, the microcomputer 13 continues the reset release state.

In the subsequent period (2), VCC starts to fall before VREGD, so VCC <VREGD, and VREGD is applied to the reference current generation circuit 2a and the reset signal output circuit 5a via the diode D2.
When only VCC is used as the power supply voltage as in the conventional example, when the VCC voltage decreases, the reference current cannot be output from the reference current generating circuit 2a. However, in the first embodiment, since VCC is switched to VREGD, VREGD The reference current can be output until the voltage drops below a certain voltage . While the VREGD voltage is higher than the detection voltage, the reset release current is output from the reset release circuit 3, and thus the VREGD voltage is output from the reset signal output circuit 5a. For this reason, the microcomputer 13 continues the reset release state.
Thereafter, when the VREGD voltage decreases and falls below the detection voltage, the reset release current stops outputting, so the comparison circuit 4 determines that the reference current is higher and turns off the reset signal output circuit 5a. Then, the output of the reset signal output circuit 5a becomes 0V, that is, a reset signal is output. For this reason, the microcomputer 13 resets the operation.

In the subsequent period (3), VCC starts to rise before VREGD, so VCC> VREGD, and VCC is applied to the reference current generation circuit 2a and the reset signal output circuit 5a via the diode D1.
Since the reset release circuit 3 stops outputting the reset release current until the VREG voltage rises in this period (3) and exceeds the detection voltage following the latter half of the previous period (2), the reset signal output circuit A reset signal of 0V is output from 5a.
Thereafter, when the VREGD voltage exceeds the detection voltage, a reset release current is output from the reset release circuit 3 to the comparison circuit 4, and the comparison circuit 4 determines that the reset release current is higher than the reference current and turns on the reset signal output circuit 5a. To do. Since the reset signal output circuit 5a uses VCC as the power supply voltage and outputs the VCC voltage, the microcomputer 13 enters the reset release state.

  Thus, since the power supply monitoring circuit 1a uses the higher voltage of VCC and VREGD, a normal reset signal can be output when the VREGD voltage falls below the detection voltage. Therefore, it is possible to cause the microcomputer 13 to perform a normal reset operation and to prevent the microcomputer 13 from operating at a voltage lower than the microcomputer operating voltage. In addition, when the VREGD voltage falls below the detection voltage, a stable reset signal is output at a constant 0V. Therefore, even for the microcomputer 13 in which the reset time (the time when the 0V reset signal is input) is specified, it is normal. A reset operation can be performed.

  In addition, when the power supply falls slowly, it may fall in the order of VREGD and VCC, but even if the turnover order is switched, it will switch to the higher power supply voltage, so a normal reset signal should be output. Can do.

  As described above, according to the first embodiment, the power supply monitoring circuit 1a operates by outputting a 0V reset signal to the microcomputer 13 operating with VREGD generated from VCC when the VREGD voltage is lower than the predetermined detection voltage. The power supply switching circuit (diodes D1 and D2) that switches to the higher power supply of VCC and VREGD, and the reference current that operates with the power supply voltage that is switched by the power supply switching circuit. The reference current generation circuit 2a to output, the reset release circuit 3 to output the reset release current when the VREGD voltage is higher than the detection voltage, the reset release current of the reset release circuit 3 and the reference current of the reference current generation circuit 2a are compared. Based on the comparison result of the comparison circuit 4 and the comparison voltage of the comparison circuit 4 and the power supply voltage switched by the power supply switching circuit. When the reset release current is lower than the reference current, a reset signal of 0V is output to reset the operation of the microcomputer 13. Conversely, when the reset release current is higher than the reference current, the power supply voltage is output to release the microcomputer 13 from the reset state. And a reset signal output circuit 5a. For this reason, since the power supply monitoring circuit 1a can be operated by switching to the power supply having the higher voltage of VCC and VREGD, the reset signal is normally output regardless of the rising order and the falling time of the power supply voltage. Can be output.

  Further, according to the first embodiment, the power supply switching circuit has the diode D1 connected to VCC and the diode D2 connected to VREGD, and the reference current generating circuit 2a and the reset signal are connected to the connection ends of the diodes D1 and D2. The output circuit 5a is connected. Therefore, it can be configured with a simple circuit, the circuit area is not increased, and the cost is hardly increased.

  In the above description, an example in which the power monitoring circuit 1a is configured in the photo IC 12 of the photoelectric switch 10 is shown, but the present invention is not limited to this, and an IC for other purposes may be used.

  The embodiment of the present invention has been described in detail with reference to the drawings. However, the specific configuration is not limited to the configuration of the above-described embodiment, and the design does not depart from the gist of the present invention. Needless to say, changes and the like are included in the present invention.

1, 1a Power supply monitoring circuit 2, 2a Reference current generator (reference current generator)
3 Reset release circuit (Reset release unit)
4 comparison circuit (comparison part)
5,5a Reset signal output circuit (reset signal output unit)
6 VREGD generation circuit 10 Photoelectric switch 11 Power supply circuit 12 Photo IC
13 Microcomputer (electronic equipment)
14 Light Emitting Circuit 15 Display Circuit C1 Capacitor D1, D2 Diode (Power Supply Switching Unit)
E1, E2 power supply

Claims (1)

A power source that outputs a reset signal to an electronic device that operates from a first power source and that operates with a second power source when the voltage of the second power source is lower than a predetermined detection voltage, thereby resetting the operation of the electronic device A monitoring circuit,
A power supply switching unit that switches to a power supply having a higher voltage of the first power supply and the second power supply;
A reference current generator that operates with the power supply voltage switched by the power supply switching unit and outputs a predetermined reference current;
A reset release unit that outputs a reset release current higher than the reference current when the voltage of the second power supply is higher than the detection voltage;
A comparison unit for comparing the reset release current and the reference current;
A reset signal output unit that outputs the reset signal when the reset release current is lower than the reference current based on a comparison result of the comparison unit ;
The power supply switching unit includes a first diode connected to the first power supply and a second diode connected to the second power supply, and the connection between the first diode and the second diode A power supply monitoring circuit , wherein the reference current generating unit is connected to an end .

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