JP2015106958A - Electronic apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an electronic apparatus capable of suppressing rise of price and including a voltage monitoring part.SOLUTION: An electronic apparatus includes a second voltage conversion part 108 for outputting a second voltage and electronic components 101-104 to which a second voltage is supplied as an operation voltage. Further the electronic apparatus includes: a first voltage conversion part 109 for outputting a first voltage; a voltage switching part 106 connected to the first voltage conversion part and the second voltage conversion part; and a voltage monitoring part 105 to which a third voltage outputted from the voltage switching part is supplied as an operation voltage. The voltage switching part which, when a voltage value of at least one voltage out of the first voltage and the second voltage exceeds a predetermined voltage value, outputs a voltage according to a voltage having a voltage value exceeding the predetermined voltage value out of the first voltage and the second voltage as the third voltage.

Description

  The present invention relates to an electronic device, for example, a technique effective for an electronic device including a voltage monitoring unit.

  Patent Document 1 discloses a power supply device including a voltage monitoring unit. For example, as shown in FIG. 3, the voltage monitoring unit disclosed in Patent Document 1 includes an AD converter and a system monitoring processor, and the AD converter and the system monitoring processor are resident in the AD converter and the system monitoring processor. Each operating voltage is fed by a power source.

Republished patent WO2009 / 054059

  The voltage monitoring unit monitors a power supply voltage supplied to, for example, a plurality of electronic components built in the electronic device, and detects an abnormality such as a decrease in the power supply voltage. The power supply voltage is converted into a voltage value by, for example, a voltage converter (for example, a converter or a regulator) so as to have an appropriate voltage value as an operating voltage of each of the plurality of electronic components, and is supplied to each electronic component.

  Even in the voltage monitoring unit that performs such monitoring, the operation voltage needs to be supplied in order to perform the monitoring operation. In the technique described in Patent Document 1, power supply voltage is supplied to the voltage monitoring unit by a resident power supply. Thus, in Patent Document 1, it is possible to constantly monitor the power supply voltage. However, in order to be able to constantly monitor the power supply voltage, the resident power supply is required to always supply a stable voltage. Therefore, an electronic device having such a resident power supply is expensive.

  An object of the present invention is to provide an electronic device having a built-in voltage monitoring unit that can suppress an increase in price.

  The above and other objects and novel features of the present invention will be apparent from the description of this specification and the accompanying drawings.

  Of the inventions disclosed in the present application, the outline of typical ones will be briefly described as follows.

  That is, the electronic device converts the main power supply voltage into a first voltage having a voltage value different from the voltage value of the voltage, and outputs the first voltage conversion unit (second voltage conversion unit), 1 has an electronic component that is fed as an operating voltage. Further, the electronic device converts the main power supply voltage into a second voltage having a voltage value different from the voltage value of the voltage, and outputs the second voltage conversion unit (first voltage conversion unit), A voltage switching unit connected to the first voltage conversion unit and the second voltage conversion unit, and a voltage monitoring unit to which a third voltage output from the voltage switching unit is fed as an operating voltage. Here, when the voltage value of at least one of the first voltage and the second voltage exceeds a predetermined voltage value, the voltage switching unit includes the first voltage and the second voltage. A voltage according to a voltage having a voltage value exceeding a predetermined voltage value is output as the third voltage.

  When either the first voltage or the second voltage exceeds a predetermined voltage value, the voltage monitoring unit operates using a voltage corresponding to the voltage exceeding the predetermined voltage value as an operating voltage. As a result, it is possible to suppress an increase in the price of the electronic device including the voltage monitoring unit.

  In one embodiment, the voltage monitoring unit monitors the voltage value of the first voltage and the voltage value of the second voltage. Thereby, the voltage monitoring unit can record a temporal change in the first voltage and the second voltage as a log.

  In one embodiment, the voltage monitoring unit includes a control circuit that generates a reset signal for resetting the electronic component when the voltage value of the first voltage is lower than a predetermined voltage value. As a result, it is possible to prevent the electronic component having the first voltage as the operating voltage from malfunctioning.

  Further, in one embodiment, the voltage switching unit includes first and second diode elements each having a pair of terminals. Here, a first voltage is applied to one terminal of the first diode element, a second voltage is applied to one terminal of the second diode element, and the first and second diodes are applied. The other terminals of the elements are connected in common, and the third voltage is output from the other terminal. Each of the first and second diode elements is applied to one terminal when a voltage value exceeding the forward bias voltage value is applied to one terminal with respect to the voltage value at the other terminal. The voltage is output to the other terminal.

  Accordingly, the voltage switching unit is configured to output a voltage exceeding a predetermined voltage value when at least one of the first voltage and the second voltage exceeds a predetermined voltage value (forward bias voltage value). Is output as a third voltage. In addition, since the first and second diode elements are passive elements, the voltage switching unit does not require an operating voltage except for input voltages (first and second voltages). In other words, a resident power supply for operating the voltage switching unit is not required. This also makes it possible to prevent the electronic device from becoming expensive.

  Furthermore, in one embodiment, the electronic device is a relay device that has a plurality of ports that transmit or receive frames in the network and relays frames. An electronic component included in the electronic device is a switch device that relays a frame between a plurality of ports.

  Each of the first voltage conversion unit and the second voltage conversion unit generates a voltage. From the viewpoint of generating a voltage, the first voltage converter and the second voltage converter correspond to the first voltage generator and the second voltage generator. When viewed from this viewpoint, in one embodiment, the electronic device includes a first voltage generation unit that forms a first voltage, a plurality of electronic components to which the first voltage is fed as an operating voltage, A second voltage generation unit configured to generate a second voltage; a voltage switching unit connected to the first voltage generation unit and the second voltage generation unit; and a voltage monitoring unit. Here, when the voltage value of at least one of the first voltage and the second voltage exceeds a predetermined voltage value, the voltage switching unit includes the first voltage and the second voltage. A voltage corresponding to a voltage having a voltage value exceeding a predetermined voltage value is output as the third voltage. The voltage monitoring unit performs an operation of monitoring the voltage value using the third voltage as an operating voltage.

  Further, when viewed from the viewpoint of the first voltage generation unit and the second voltage generation unit, in one embodiment, the voltage switching unit includes first and second diode elements each having a pair of terminals. It has. In the voltage switching unit, the first voltage is applied to one terminal of the first diode element, and the second voltage is applied to one terminal of the second diode element. The other terminals of the diode elements are connected in common, and the third voltage is output from the other terminal.

  According to one embodiment, it is possible to provide an electronic device with a built-in voltage monitoring unit that can suppress an increase in price.

It is a block diagram which shows the structure of the relay apparatus concerning one embodiment. It is a block diagram which shows the structure of the voltage monitoring part concerning one Embodiment. It is a circuit diagram which shows the structure of the voltage switching part concerning one Embodiment. (A)-(F) are the wave form diagrams of the operation | movement which monitors a voltage.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. Note that components having the same function are denoted by the same reference symbols throughout the drawings for describing the embodiment, and the repetitive description thereof will be omitted.

  In the following description, a relay device used in a network system will be described as an example of an electronic device. Needless to say, the electronic device is not limited to the relay device.

  FIG. 1 is a block diagram illustrating a configuration of the relay device 100. In the figure, each of P1 to Pn is a port, and each of PV and PG is a power supply port. Although not particularly limited, the power supply port PG is supplied with the ground voltage Vs, and the power supply port PV is supplied with a power supply voltage having a predetermined voltage value with respect to the ground voltage Vs. The relay device 100 operates with a power supply voltage supplied to the power supply port PV. In FIG. 1, signal flow is indicated by wiring with an arrow, and voltage wiring is indicated by wiring without an arrow.

  The power ports PV and PG are connected to a voltage converter (for example, a voltage converter) 107 by voltage wiring. The voltage converter 107 steps down the power supply voltage supplied to the power supply port PV, for example, and generates an internal main power supply voltage (main power supply voltage) Vd. Although not particularly limited, the voltage conversion unit 107 generates a voltage of about 5V by step-down and outputs the voltage of about 5V as the internal main power supply voltage Vd. The internal main power supply voltage Vd is supplied to the first voltage conversion unit (for example, voltage converter) 109 and the second voltage conversion unit (for example, voltage converter) 108 via the voltage wiring. The second voltage converter 108 steps down the supplied internal main power supply voltage Vd, although not particularly limited, to generate the internal power supply voltage Vd1. The first voltage converter 109 also steps down the supplied internal main power supply voltage Vd to generate the internal power supply voltage Vd1. In this embodiment, although not particularly limited, each of first voltage conversion unit 109 and second voltage conversion unit 108 converts the voltage value by stepping down internal main power supply voltage Vd, and has the same voltage value. A power supply voltage Vd1 is generated and output. The voltage value of the internal power supply voltage Vd1 is, for example, about 3.3V.

  The internal power supply voltage Vd1 generated by the second voltage converter 108 is supplied as a power supply voltage to each electronic component provided in the relay device 100 via the voltage wirings 115 and 111. Although there are a plurality of electronic components provided in the relay device 100, FIG. 1 shows a microprocessor (hereinafter referred to as a CPU) 101, a memory 102, a nonvolatile memory 103, and a switch device 104 as an example. . Each of the CPU 101, the memory 102, the nonvolatile memory 103, and the switch device 104 is connected to the voltage wiring 111 via the voltage wiring 121, and operates using the internal power supply voltage Vd <b> 1 fed through the voltage wiring 121 as the operating voltage.

  In the nonvolatile memory 103, for example, a program and data for determining processing executed by the CPU 101 are stored. The memory 102 is used when data is temporarily stored when the CPU 101 performs processing. The CPU 101 performs processing according to a program from the nonvolatile memory 103.

  The switch device 104 relays the frame received at any of the ports P1 to Pn to the ports P1 to Pn different from the received port. When relaying, processing such as analysis of the received frame is performed in the CPU 101, and ports for transmitting frames are selected from the ports P1 to Pn. The selected port and the port that received the frame are electrically connected by the switch device 104. In this way, the relay operation is performed by transmitting the received frame to the selected port. That is, the switch device 104 relays frames between a plurality of ports. Note that transmission and reception of signals among the CPU 101, the memory 102, the nonvolatile memory 103, and the switch device 104 are performed via the signal wiring 123.

  The internal power supply voltage Vd1 generated by the first voltage conversion unit 109 is supplied (output) to the voltage switching unit 106 via the voltage wiring 119. The voltage switching unit 106 is supplied (output) with the internal power supply voltage Vd1 from the second voltage conversion unit 108 via the voltage wiring 116. As will be described later with reference to FIG. 3, the voltage switching unit 106 includes an internal power supply voltage Vd1 fed from the first voltage conversion unit 109 and an internal power supply voltage Vd1 fed from the second voltage conversion unit 108. When at least one of the voltages exceeds a predetermined voltage value, a voltage having a voltage value corresponding to the internal power supply voltage Vd1 exceeding the predetermined voltage value is output as the operating voltage of the voltage monitoring unit.

  In FIG. 1, reference numeral 105 denotes a voltage monitoring unit. The voltage monitoring unit 105 receives the internal main power supply voltage Vd generated by the voltage conversion unit 107 via the signal wiring 114, and the internal power supply voltage generated by the second voltage conversion unit 108 via the signal wiring 117. Vd1 is received, and the internal power supply voltage Vd1 generated by the first voltage converter 109 is received via the signal wiring 118. The signal received via the signal wirings 114, 117 and 118 is the same as the internal main power supply voltage Vd and the internal power supply voltage Vd1 which are the operating voltages, but in order to monitor the respective voltage values, the voltage monitoring unit 105 is monitored. Has been sent. The voltage monitoring unit 105 monitors the voltage value of the power supply voltage received via the signal wirings 114, 117 and 118, and the voltage value of the power supply voltage is an abnormal value (for example, a voltage value lower than a predetermined voltage value). Are output, a plurality of alarm signals 126 are output. This alarm signal 126 includes a reset signal 126-1.

  As will be described in detail later, when the internal power supply voltage Vd1 generated by the second voltage converter 108 is lower than a predetermined voltage value, a reset operation is instructed to the electronic components 101 to 104. Such a reset signal 126-1 is generated by the voltage monitoring unit 105. When each of the electronic components 101 to 104 receives a reset signal 126-1 for instructing the reset operation, the reset operation is performed, and it is possible to prevent a malfunction from occurring due to a decrease in the internal power supply voltage.

  In FIG. 1, two voltage converters 108 and 109 are shown as voltage converters for generating the internal power supply voltage Vd1. Among these, the first voltage conversion unit 109 is provided to generate the internal power supply voltage Vd1 that is the operating voltage of the voltage monitoring unit 105. Therefore, in this embodiment, the internal power supply voltage Vd1 generated by the second voltage converter 108 is supplied as an operating voltage for each of the electronic components 101 to 104. A plurality of voltage converters that supply the internal power supply voltage Vd1 that is an operating voltage to each electronic component may be provided instead of one. In this case, the number of voltage conversion units may be increased in accordance with the current consumed by each electronic component.

  Moreover, a known voltage converter can be used for each configuration of the voltage converter 107, the first voltage converter 109, and the second voltage converter 108. For example, the voltage converter can be configured by a coil, a plurality of transistors that periodically drive the coil, and a control circuit that controls the plurality of transistors. In this embodiment, an example is shown in which each voltage conversion unit steps down an input voltage and outputs a voltage having a stepped down voltage value. However, any voltage converter that converts an input voltage and outputs a voltage having a voltage value different from the voltage value of the input voltage may be used.

  In the figure, reference numerals 113, 110, 122 and 125 are voltage wirings for transmitting the ground voltage Vs. Although not particularly limited, the ground voltage Vs is supplied from the voltage conversion unit 107 to these other portions except for the voltage switching unit 106 through these voltage wirings. In FIG. 1, reference numeral 124 denotes a signal line through which frames are transmitted and received between the switch device 104 and the ports P1 to Pn.

  Although not particularly limited, each of the CPU 101, the memory 102, the nonvolatile memory 103, the switch device 104, the voltage switching unit 106, and the voltage monitoring unit 105 is configured by, for example, a plurality of semiconductor integrated circuit devices (not shown). .

  FIG. 2 is a block diagram illustrating a configuration of the voltage monitoring unit 105. In the figure, 203-1 to 203-3 are comparison circuits. The comparison circuits 203-1 to 203-3 have the same configuration. In this specification, when a common matter is described with respect to the comparison circuits 203-1 to 203-3, the comparison circuit 203 is hereinafter described. The comparison circuit 203 has a pair of power supply terminals (voltage terminal Vd1 and ground terminal Vs), a pair of input terminals I1 and I2, and an output terminal (not shown). The comparison circuit 203 operates when a predetermined voltage is applied to the voltage terminal Vd1. That is, by applying a voltage having a predetermined potential difference between the ground terminal Vs and the voltage terminal Vd1, the comparison circuit 203 operates using this voltage as an operating voltage. In this case, the voltage terminals Vd1 of the comparison circuits 203-1 to 203-3 are connected to the voltage wiring 120, and the ground terminals Vs are connected to the voltage wiring 125. Accordingly, the comparison circuits 203-1 to 203-3 operate using the voltage supplied (output) from the voltage switching unit 106 via the voltage wiring 120 as the operating voltage.

  The comparison circuit 203 compares the voltage of the signal at the input terminal I1 with the voltage of the signal at the input terminal I2 when an operating voltage is applied, and outputs a signal corresponding to the comparison result to an output terminal (not shown). The comparison operation output from is performed. For example, when the voltage of the signal at the input terminal I1 is higher than the voltage of the signal at the input terminal I2, a high level signal is output from the output terminal by the comparison operation. On the other hand, when the voltage of the signal at the input terminal I1 is lower than the voltage of the signal at the input terminal I2, a low level signal is output from the output terminal by the comparison operation.

  In FIG. 2, 202 is a reference voltage generating circuit. The reference voltage generation circuit 202 is connected to the voltage wirings 120 and 125, and generates reference voltages Vref1 and Vref2 corresponding to voltages supplied through the voltage wiring 120. In the figure, although shown by one wiring, the generated reference voltage Vref1 is applied to the input terminal I2 of the comparison circuit 203-1. The generated reference voltage Vref2 is applied to each input terminal I2 of the comparison circuits 203-2 to 203-3. The reference voltage generation circuit 202 generates the reference voltages Vref <b> 1 and Vref <b> 2 by, for example, dividing a voltage supplied via the voltage wiring 120 with a plurality of resistance elements. In this case, the voltages obtained by the voltage division by the resistance elements are set as the reference voltages Vref1 and Vref2, and are set to predetermined voltage values. That is, the reference voltage Vref1 is a predetermined voltage value corresponding to the internal main power supply voltage Vd, and the reference voltage Vref2 is a predetermined voltage value corresponding to the internal power supply voltage Vd1. Although not particularly limited, in this embodiment, the voltage value of the internal main power supply voltage Vd is about 5V, and the voltage value of the internal power supply voltage Vd1 is about 3.3V. Therefore, the reference voltage Vref1 is set to a voltage value higher than the reference voltage Vref2.

  The comparison circuit 203-1 receives the internal main power supply voltage Vd applied via the signal wiring 114 at the input terminal I1, and compares the voltage between the internal main power supply voltage Vd and the reference voltage Vref1. Similarly, the comparison circuit 203-2 receives the internal power supply voltage Vd1 applied via the signal wiring 117 at the input terminal I1, and compares the voltage between the internal power supply voltage Vd1 and the reference voltage Vref2. The comparison circuit 203-3 receives the internal power supply voltage Vd1 applied via the signal wiring 118 at the input terminal I1, and compares the voltage between the internal power supply voltage Vd1 and the reference voltage Vref2.

  Thus, the comparison circuit 203-1 outputs a high-level output signal when the internal main power supply voltage Vd exceeds the voltage value (predetermined voltage value) of the reference voltage Vref1, and the internal main power supply voltage Vd is the reference voltage. When it is lower than the voltage value (predetermined voltage value) of the voltage Vref1, a low level output signal is output. Each of comparison circuits 203-2 and 203-3 outputs a high-level output signal when internal power supply voltage Vd1 exceeds the voltage value (predetermined voltage value) of reference voltage Vref2, and internal main power supply When the voltage Vd is lower than the voltage value (predetermined voltage value) of the reference voltage Vref2, a low level output signal is output.

  The output signals of the comparison circuits 203-1 to 203-3 are transmitted to the control unit 200. The control unit 200 has a voltage terminal Vd1 and a ground terminal Vs, and operates using a voltage supplied to the voltage terminal Vd1 as an operating voltage. In this embodiment, the voltage terminal Vd 1 is connected to the voltage wiring 120, and the ground terminal Vs is connected to the voltage wiring 125. As a result, the voltage is output from the voltage switching unit 106 to the voltage monitoring unit 105 via the voltage wiring 120, so that each circuit in the voltage monitoring unit 105 operates using this voltage as an operating voltage. When the operating voltage is applied, the control unit 200 forms and outputs an alarm signal 126 corresponding to the output signals from the comparison circuits 203-1 to 203-3. The alarm signal 126 includes a reset signal 126-1. The control unit 200 includes a control circuit 201 that generates a reset signal 126-1 based on a combination of output signals from the comparison circuits 203-1 to 203-3.

  The control circuit 201 can be configured by combining a plurality of logic circuits and a holding circuit, for example. Although described later with reference to FIG. 4, in this embodiment, although not particularly limited, the reset signal 126-1 instructs the reset operation when the voltage becomes high level. On the other hand, the reset signal 126-1 changes to a low level to instruct the release of the reset operation.

  As shown in FIG. 1, the CPU 101, the memory 102, the nonvolatile memory 103, and the switch device 104 receive the reset signal 126-1. These electronic components change to an initial state when a reset operation is instructed by a reset signal 126-1, and are in an initial state until an instruction to cancel the reset operation is instructed by a reset signal 126-1. When cancellation of the reset operation is instructed by the reset signal 126-1, each electronic component starts operation.

  For example, the control circuit 200 changes the reset signal 126-1 to the low level when all the output signals from the comparison circuits 203-1 to 203-3 are at the high level. Further, after the reset signal 126-1 changes to the low level, the output signal from the comparison circuit 203-1 and the output signal from the comparison circuit 203-2 are at the high level, and the output signal from the comparison circuit 203-3 is The control circuit 200 generates the low level reset signal 126-1 even when the level is changed to the low level. On the other hand, when the output signal from the comparison circuit 203-2 changes to the low level, the control circuit 201 changes the reset signal 126-1 from the low level to the high level.

  The comparison circuit 203-2 compares the internal power supply voltage Vd1 supplied to the electronic components 101 to 104 with the reference voltage Vref2. That is, the internal power supply voltage Vd1 generated by the second voltage converter 108 is compared with the reference voltage Vref2 serving as the reference. Therefore, the change of the comparison circuit 203-2 to the low level means that the internal power supply voltage Vd1 supplied to each of the electronic components 101 to 104 is lowered. In this case, as described above, the reset signal 126-1 that instructs the reset operation is transmitted from the voltage monitoring unit 105 to each electronic component. Each of the electronic components 101 to 104 may malfunction due to a decrease in the internal power supply voltage Vd1 that is its operating voltage. However, since the reset signal 126-1 causes a reset operation, an abnormality due to the malfunction occurs. Can be prevented.

  On the other hand, the comparison circuit 203-3 compares the internal power supply voltage Vd1 fed to the voltage monitoring unit 105 with the reference voltage Vref2. That is, the internal power supply voltage Vd1 generated by the first voltage conversion unit 109 is compared with the reference voltage Vref2 serving as the reference. Therefore, when the output signal of the comparison circuit 203-2 does not change to a low level and only the output signal of the comparison circuit 203-3 changes to a low level, the internal power supply voltage supplied to each of the electronic components 101 to 104 It is determined that Vd1 has not decreased and the internal power supply voltage Vd1 supplied to the voltage monitoring unit 105 has decreased. Therefore, in this case, the reset signal 126-1 that instructs the reset operation is not transmitted from the voltage monitoring unit 105 to each electronic component.

  As described above, in this embodiment, in order to supply the operating voltage to the voltage monitoring unit 105 even when the internal power supply voltage Vd1 generated by the first voltage conversion unit 109 is reduced, A switching unit 106 is provided. Next, the voltage switching unit 106 will be described.

  FIG. 3 is a circuit diagram showing a configuration of the voltage switching unit 106. In the figure, each of D1 and D2 is a diode element. Each of the diode elements D1 and D2 has a pair of terminals, one terminal being an anode terminal AN and the other terminal being a cathode terminal KN. Each of the diode elements D1 and D2 is a so-called passive element, and is forward-biased by applying a positive voltage to the anode terminal AN with respect to the cathode terminal KN. In this case, when a voltage having a voltage value exceeding a predetermined voltage value is applied to the cathode terminal KN with a forward bias, a forward current flows. Here, the predetermined voltage value corresponds to the threshold voltage of the diode element (forward voltage of the PN junction).

  The anode terminal AN of the diode element D1 is connected to the voltage wiring 119, the anode terminal AN of the diode element D2 is connected to the voltage wiring 116, the cathode terminals KN of the diode elements D1 and D2 are connected in common, and the cathode terminal KN is It is connected to the voltage wiring 120. As a result, when the voltage value of the internal power supply voltage Vd1 in at least one of the voltage wirings 116 and 119 is higher than the voltage in the voltage wiring 120, the diode elements D1 and D2 have a voltage value exceeding a predetermined voltage value. A voltage corresponding to the internal power supply voltage Vd1 having a voltage value exceeding a predetermined voltage value is supplied (output) to the voltage wiring 120.

  For example, when the voltage value of the internal power supply voltage Vd1 (second voltage) in the voltage wiring 119 exceeds the predetermined voltage value (forward voltage of the PN junction) with respect to the voltage in the voltage wiring 120 The voltage corresponding to the internal power supply voltage Vd1 in the voltage wiring 119 (that is, the internal power supply voltage Vd1−predetermined voltage value) is output from the voltage switching unit 106 to the voltage wiring 120 as the operating voltage (third voltage). . Similarly, the voltage value of the internal power supply voltage Vd1 (first voltage) in the voltage wiring 116 is a voltage value that exceeds a predetermined voltage value (forward voltage of the PN junction) with respect to the voltage in the voltage wiring 120. Sometimes, the voltage corresponding to the internal power supply voltage Vd1 in the voltage wiring 116 (that is, the internal power supply voltage Vd1−predetermined voltage value) is output from the voltage switching unit 106 to the voltage wiring 120 as the operating voltage (third voltage). The That is, even if the voltage value of the internal power supply voltage Vd1 generated by the first voltage conversion unit 109 or the second voltage conversion unit 108 decreases, the second voltage generates the internal power supply voltage Vd1 that does not decrease. A voltage corresponding to the internal power supply voltage Vd1 generated by the conversion unit 108 or the first voltage conversion unit 109 is output from the voltage switching unit 106 to the voltage monitoring unit 105.

  In this case, the voltage switching unit 106 can be regarded as an OR circuit including a plurality of diode elements D1 and D2. Further, since it is composed of passive elements, the voltage switching unit 106 does not require an operating voltage to operate, unlike a circuit such as the comparison circuit described in FIG. Therefore, a resident power supply that constantly supplies an operating voltage to the voltage switching unit 106 is not required.

  In this embodiment, even when an abnormality occurs in the first voltage conversion unit 109 that supplies the operating voltage to the voltage monitoring unit 105 or when it is stopped, the voltage switching unit 106 operates the voltage monitoring unit 105. The voltage can be continuously supplied. Further, it is not necessary to provide a resident power source for the voltage switching unit 106. Therefore, it is possible to suppress an increase in the price of the electronic device (for example, a relay device).

  The alarm signal 126 output from the control unit 200 includes information indicating temporal changes in the power supply voltage generated by each of the first voltage conversion unit 109, the second voltage conversion unit 108, and the voltage conversion unit 107. The alarm signal 126 including this information is transmitted to a log storage unit (not shown) that stores a log. For example, even if the first voltage conversion unit 109 is abnormal or stopped, the voltage monitoring unit 105 is supplied with power by the voltage switching unit 106, so that the control unit 200 can control the internal main power supply voltage Vd and the internal power supply voltage Vd1. Information indicating the change can be generated. The generated information can be used for analysis of an abnormality or the like by storing it as a log. The log storage unit may be configured by the CPU 101 and the nonvolatile memory 103, for example. In this case, the alarm signal 126 including the above information is written as a log in the nonvolatile memory 103 by the CPU 101. Of course, the log storage unit may be provided in the electronic apparatus 100 separately from the CPU 101 and the nonvolatile memory 103.

  4A to 4F are waveform diagrams showing the operation according to this embodiment. In the figure, the horizontal axis indicates time. 4A to 4C show the voltage waveform of the internal main power supply voltage Vd generated by the voltage conversion unit 107 and the voltage of the internal power supply voltage Vd1 generated by the first voltage conversion unit 109 in this order. The waveform shows the voltage waveform of the internal power supply voltage Vd1 generated by the second voltage converter 108. 4D to 4F show, in this order, the voltage waveform of the voltage output from the voltage switching unit 106, the voltage waveform of the reset signal 126-1 transmitted from the voltage monitoring unit 105, and the log storage unit. A log stored in (not shown) is shown. In FIG. 4D, the voltage value of the voltage output from the voltage switching unit 106 is shown as Vd1 for easy understanding of the drawing. However, as understood from the above description, the voltage switching is performed. The voltage value of the voltage output from the unit 106 is a voltage value lower than the internal power supply voltage Vd1. Next, the operation will be described with reference to FIGS. 1 to 3 and FIG.

  In FIG. 4, before the time t0, as shown in FIG. 4E, the reset signal 126-1 is at a high level, and the CPU 101, the memory 102, the nonvolatile memory 103, and the switch device 104 Assume that the reset operation is instructed for each of them. In the control circuit 201, the voltage value of the internal main power supply voltage Vd exceeds a predetermined voltage (Vref1), and the voltage value of the internal power supply voltage Vd1 generated by the first voltage conversion unit 109 and the second voltage conversion unit 108 is When the period exceeding the predetermined voltage (Vref2) continues for a predetermined time, the reset signal 126-1 is set to the low level. This can be achieved by the control circuit 201 determining the level of the output signal transmitted from the comparison circuits 203-1 to 203-3. When the reset signal 126-1 becomes low level, the reset operation for each of the CPU 101, the memory 102, the nonvolatile memory 103, and the switch device 104 is released (time t0). As described above, when the internal main power supply voltage Vd and the internal power supply voltage Vd1 are maintained at the predetermined voltage values (about 5 V and about 3.3 V) for a predetermined time, the reset operation is canceled, which is undesirable. It is possible to prevent the reset operation and the release thereof from being repeated.

  From time t0 to time t1, the internal main power supply voltage Vd generated by the voltage converter 107 is, for example, a voltage (Vd) of about 5V. At this time, each of the first voltage conversion unit 109 and the second voltage conversion unit 108 converts the voltage value of the internal main power supply voltage Vd to generate the internal power supply voltage Vd1. Since each of the first voltage conversion unit 109 and the second voltage conversion unit 108 has no abnormality, the internal power supply voltage Vd1 is about 3.3V. Since each of the CPU 101, the memory 102, the nonvolatile memory 103, and the switch device 104 is released from the reset operation, the CPU 101, the memory 102, the nonvolatile memory 103, and the switch device 104 operate using the internal power supply voltage Vd1 as the operating voltage. That is, the relay device 100 performs a frame relay operation.

  Further, from time t0 to time t1, the internal power supply voltage Vd1 of 3.3 V is applied to the respective anode terminals AN of the diode elements D1 and D2. Therefore, the diode element D1 or D2 is forward-biased. Thus, voltage switching unit 106 outputs a voltage corresponding to internal power supply voltage Vd1 of about 3.3 V to voltage monitoring unit 105 (FIG. 4D). With this voltage as the operating voltage, each circuit (reference voltage generation circuit 202, comparison circuits 203-1 to 203-3, control unit 200) in the voltage monitoring unit 105 operates. That is, the voltage monitoring unit 105 monitors the voltage values of the internal main power supply voltage Vd and the internal power supply voltage Vd1.

  It is assumed that, for example, an abnormality has occurred in the second voltage converter 108 at time t1. Due to this abnormality, as shown in FIG. 4C, the voltage value of the internal power supply voltage Vd1 generated by the second voltage converter 108 decreases. When the voltage value of the internal power supply voltage Vd1 generated by the second voltage conversion unit 108 decreases, the potential of the input terminal I1 of the comparison circuit 203-2 in the voltage monitoring unit 105 decreases from the reference voltage Vref2. As a result, the comparison circuit 203-2 forms a low-level output signal. The control unit 200 generates an alarm signal 126 in response to the low level output signal. Information included in the alarm signal 126 is stored as a log 1 in a log storage unit (not shown) (FIG. 4F). When the output signal from the comparison circuit 203-2 changes to the low level, the control circuit 201 changes the reset signal 126-1 to the high level as shown in FIG. 4E in response to this change. . As a result, each of the CPU 101, the memory 102, the nonvolatile memory 103, and the switch device 104 performs a reset operation.

  For example, even if the internal power supply voltage Vd1 generated by the second voltage conversion unit 108 has decreased from time t1 due to the occurrence of an abnormality, the voltage switching unit 106 changes the voltage corresponding to the internal power supply voltage Vd1 to the voltage monitoring unit. 105 can be output. That is, in this case, the voltage applied to the anode terminal AN of the diode element D1 in the voltage switching unit 106 becomes a voltage value exceeding a predetermined voltage value, and the diode element D1 is forward-biased. The voltage is output to the voltage monitoring unit 105 via the element D1. Thereby, the voltage monitoring unit 105 can continuously monitor the voltage.

  After time t1, the internal power supply voltage Vd1 generated by the second voltage conversion unit 108 returns to a normal voltage value, and the voltage conversion unit 107, the first voltage conversion unit 109, and the second voltage conversion unit 108 perform a predetermined time. When the internal main power supply voltage Vd and the internal power supply voltage Vd1 having normal voltage values are continuously transmitted to the voltage monitoring unit 105, the reset operation is canceled. That is, at time t2, the control circuit 201 changes the reset signal 126-1 from the high level to the low level. Thereby, the reset operation in each of the electronic components 101 to 104 is canceled, and the relay device 100 relays the frame.

  At time t3, when the voltage value of the internal power supply voltage Vd1 generated by the first voltage conversion unit 109 decreases due to, for example, occurrence of an abnormality (FIG. 4B), the input of the comparison circuit 203-3 in the voltage monitoring unit 105 is performed. The voltage value of the internal power supply voltage Vd1 at the terminal I1 is lower than the reference voltage Vref2. The comparison circuit 203-3 transmits a low-level output signal to the control unit 200 because the voltage value of the input terminal I1 is lower than the reference voltage Vref2. The control unit 200 receives the low-level output signal from the comparison circuit 203-3, thereby generating the alarm signal 126 including information indicating that the internal power supply voltage Vd1 generated by the first voltage conversion unit 109 has decreased. . This information is stored in a log storage unit (not shown) as log 2 (FIG. 4 (F)).

  On the other hand, the control circuit 201 in the control unit 200 maintains the reset signal 126-1 at the low level even when the output signal transmitted from the comparison circuit 203-3 changes to the low level. Accordingly, each of the electronic components 101 to 104 does not perform the reset operation and continues the frame relay operation. Further, in this case, in the voltage switching unit 106, the voltage value of the anode electrode AN of the diode element D1 decreases, but the internal power supply voltage Vd1 that has not decreased in voltage is applied to the anode terminal AN of the diode element D2. Power is supplied from the two-voltage converter 108. Since the voltage supplied from the second voltage conversion unit 108 exceeds a predetermined voltage value (forward voltage of the PN junction), the diode element D2 is forward-biased and supplied from the second voltage conversion unit 108. A voltage corresponding to the voltage value being output is output to the voltage monitoring unit 105.

  That is, even if the voltage value of the internal power supply voltage Vd1 generated by the first voltage conversion unit 109 provided corresponding to the voltage monitoring unit 105 decreases, the voltage monitoring unit 105 continues to have the internal power supply voltage Vd1. A voltage corresponding to the voltage is supplied (FIG. 4D). As a result, the voltage monitoring unit 105 is supplied with a voltage necessary for the operation even during a period (time t3 to time t4) in which the internal power supply voltage Vd1 generated by the first voltage conversion unit 109 is decreasing. Thus, the voltage value of the internal main power supply voltage Vd and the voltage value of the internal power supply voltage Vd1 generated by the second voltage conversion unit 108 during this period can be monitored. The monitoring result can be stored in the log storage unit as a log.

  When the voltage value of the internal power supply voltage Vd1 generated by the first voltage conversion unit 109 returns at time t4, for example, the log writing operation by the log storage unit is terminated.

  Thus, in this embodiment, even if the internal power supply voltage Vd1 generated by the first voltage conversion unit 109 or the second voltage conversion unit 108 decreases, the voltage monitoring unit 105 causes the internal main power supply voltage Vd and the internal power supply voltage Vd1 to be reduced. Each voltage value of the power supply voltage Vd1 can be monitored. Therefore, in FIG. 4A, the voltage change of the internal main power supply voltage Vd shown so that the voltage value does not change can be monitored from time t1 to time t4, and the result can be stored as a log. .

  Note that the output signal of the comparison circuit 203-1 is not digitally changed between the high level and the low level, but the potential difference between the reference voltage Vref 1 and the input terminal I 1 is transmitted to the control unit 200. You may make it do. In this way, it is possible to store a change in the voltage value of the internal main power supply voltage Vd generated by the voltage converter 107 as a log.

  According to this embodiment, even when the internal power supply voltage Vd1 generated by the first voltage conversion unit 109 provided corresponding to the voltage monitoring unit 105 decreases, the voltage monitoring unit 105 continues to operate, Log information can be left. This makes it possible to provide a relay device (electronic device) that suppresses an increase in price.

  In the embodiment, an example in which the voltage switching unit 106 is configured by two diode elements D1 and D2 has been described. However, by increasing the number of diode elements in accordance with the number of voltage conversion units, the voltage switching unit 106 is further increased. The voltage converter can also be used. Also in this case, an OR circuit is constituted by a plurality of diode elements. Moreover, although the step-down is shown as an example of the voltage conversion unit, it is needless to say that step-up is possible.

  Although the configurations of the voltage monitoring unit 105 and the voltage switching unit 106 have been shown using FIGS. 2 and 3, the configurations of the voltage monitoring unit and the voltage switching unit are not limited thereto.

  Further, each of the first voltage conversion unit 109 and the second voltage conversion unit 108 generates an internal power supply voltage Vd1. From the viewpoint of generating a voltage, the first voltage conversion unit 109 can be regarded as a first voltage generation unit, and the second voltage conversion unit 108 can be regarded as a second voltage generation unit. Needless to say, also from this viewpoint, the electronic apparatus includes the voltage switching unit 106, the voltage monitoring unit 105, and the electronic components 101 to 104 described above.

  Although the invention made by the present inventor has been specifically described based on the embodiments, the present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the scope of the invention. is there.

100 Electronic Device 101 Microprocessor 104 Switch Device 105 Voltage Monitoring Unit 106 Voltage Switching Unit 107 Voltage Conversion Unit 108 Second Voltage Conversion Unit 109 First Voltage Conversion Unit 200 Control Unit 201 Control Circuit 202 Reference Voltage Generation Circuits 203-1 to 203- 3 Comparison circuit D1, D2 Diode element

Claims (8)

A first voltage converter that converts the main power supply voltage into a first voltage having a voltage value different from the voltage value of the voltage and outputs the first voltage;
An electronic component to which the first voltage is fed as an operating voltage;
A second voltage converter that converts the main power supply voltage into a second voltage having a voltage value different from the voltage value of the voltage and outputs the second voltage;
The voltage value of at least one of the first voltage and the second voltage is connected to the first voltage conversion unit and the second voltage conversion unit, and exceeds a predetermined voltage value. A voltage switching unit that outputs, as a third voltage, a voltage according to a voltage having a voltage value exceeding the predetermined voltage value among the first voltage and the second voltage;
The third voltage is supplied as an operating voltage, and a voltage monitoring unit that monitors a voltage value;
An electronic device comprising:   The electronic device according to claim 1, wherein the voltage monitoring unit monitors a voltage value of the first voltage and a voltage value of the second voltage. A log storage unit for storing the alarm signal from the voltage monitoring unit as a log;
When the first voltage or the second voltage is lower than a predetermined voltage value, the voltage monitoring unit is configured to determine whether the first voltage or the second voltage is lower than a predetermined voltage value. The electronic device according to claim 1, which outputs an alarm.   The electronic device according to claim 3, wherein the voltage monitoring unit includes a control circuit that generates a reset signal for resetting the electronic component when a voltage value of the first voltage is lower than a predetermined voltage value. apparatus. The voltage switching unit includes first and second diode elements each having a pair of terminals,
The first voltage is applied to one terminal of the first diode element, the second voltage is applied to one terminal of the second diode element, and the first and second terminals 5. The electronic device according to claim 1, wherein the other terminals of the diode elements are connected in common, and the third voltage is output from the other terminal. 6. The electronic device is a relay device that has a plurality of ports for transmitting or receiving frames in a network and relays frames,
The electronic device according to claim 5, wherein the electronic component is a switch device that relays a frame between the plurality of ports. A first voltage generator for generating a first voltage;
A plurality of electronic components to which the first voltage is fed as an operating voltage;
A second voltage generator for generating a second voltage;
A voltage value of at least one of the first voltage and the second voltage is connected to the first voltage generation unit and the second voltage generation unit and exceeds a predetermined voltage value. A voltage switching unit that outputs, as a third voltage, a voltage according to a voltage having a voltage value exceeding the predetermined voltage value among the first voltage and the second voltage;
The third voltage is supplied as an operating voltage, and a voltage monitoring unit that monitors a voltage value;
An electronic device comprising: The voltage switching unit includes first and second diode elements each having a pair of terminals,
The first voltage is applied to one terminal of the first diode element, the second voltage is applied to one terminal of the second diode element, and the first and second terminals 8. The electronic device according to claim 7, wherein the other terminals of the diode elements are connected in common, and the third voltage is output from the other terminal.

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