JPWO2013190670A1 - Information processing apparatus and information processing apparatus control method - Google Patents

Abstract

An object of the present invention is to provide an information processing apparatus and an information processing apparatus control method for maintaining stable operation of the system. For this purpose, the information processing apparatus includes the following units. The power supply unit (102) supplies power to the load (21) in the device itself. The amplifier (105) reduces the voltage supplied from the power supply unit (102) when the current supplied by the power supply unit exceeds a first predetermined value. The overcurrent notification unit (113) notifies the overcurrent when the voltage supplied from the power supply unit (102) to the load (21) in the own apparatus exceeds a second predetermined value smaller than the first predetermined value. The control unit (22) receives the notification from the overcurrent notification unit (113) and reduces the load (21).

Description

  The present invention relates to an information processing apparatus and an information processing apparatus control method.

  Conventionally, a power supply unit (PSU) that is a power supply unit of an information processing apparatus such as a server is provided with an overvoltage protection circuit, a low voltage protection circuit, and a heating protection circuit. The overvoltage protection circuit is also called an over voltage protection (OVP) circuit, and has a function of preventing the output voltage from rising beyond a specified value. The low voltage protection circuit is also called an Under Voltage Protection (UVP) circuit, and has a function of preventing the output voltage from dropping below a specified value. The heat protection circuit is also called Thermal Heating Protect (THP), and has a function of preventing the ambient temperature of the power source from becoming high. When these protection functions are operated, the PSU notifies the apparatus side of an abnormality using the FAIL signal. Some PSUs perform processing such as stopping after notifying abnormality.

  The PSU also protects internal circuits from abnormalities caused by overcurrent when the load reaches 110% to 130% of the rating, so that the output voltage is reduced and the maximum rated power is not exceeded. Some have a function called overcurrent droop.

  Here, as a technique for dealing with an overcurrent, there is a conventional technique in which a current comparator determines whether a voltage supplied from a DC (Direct Current) -DC converter to a load is positive or negative and detects an abnormality of the DC-DC converter. (For example, refer to Patent Document 1). Further, there is a conventional technique for detecting an overcurrent by increasing the voltage value of the rising edge when the voltage value of the rising edge of the voltage signal exceeds a predetermined value, and comparing the increased voltage with a threshold value using a comparator. Yes (see, for example, Patent Document 2).

JP 2010-45947 A JP 2002-272098 A

  However, if the output voltage is lowered due to an overcurrent drooping state, the output voltage may be lowered too much and it may be difficult for the PSU to continue the operation. For this reason, it is difficult to maintain the stable operation of the entire system of the information processing apparatus if the overcurrent drooping state easily occurs.

  Further, when the conventional technique for detecting DC-DC abnormality using a current comparator is used, it is possible to quickly protect when an overcurrent occurs by using the comparator. However, since this is a technique for overcurrent and transition to overcurrent droop, it is difficult to avoid overcurrent droop, and it is difficult to maintain stable system operation. is there. The same applies to the conventional technique in which the voltage value at the rising edge of the voltage signal is increased and compared by a comparator.

  In one aspect, the disclosed technology aims to provide an information processing apparatus and an information processing apparatus control method that maintain stable operation of a system.

  In one aspect of the information processing apparatus and the information processing apparatus control method disclosed in the present application, the power supply unit supplies power to the load in the own apparatus. The output voltage adjustment unit reduces the voltage supplied from the power supply unit when the current supplied by the power supply unit exceeds a first predetermined value. The overcurrent notification unit notifies the overcurrent when the voltage supplied from the power supply unit to the load in the device exceeds a second predetermined value smaller than the first predetermined value. The control unit receives the notification from the overcurrent notification unit and reduces the load.

  According to one embodiment of the present invention, stable operation of the system can be maintained.

FIG. 1 is a block diagram of the information processing apparatus according to the first embodiment. FIG. 2 is a circuit diagram of the FAIL signal circuit. FIG. 3 is a diagram showing a truth table of the FAIL signal. FIG. 4 is a time chart of the power saving operation in the information processing apparatus according to the first embodiment. FIG. 5 is a flowchart of the power saving operation in the information processing apparatus according to the first embodiment. FIG. 6 is a circuit diagram of an OCA signal circuit according to the second embodiment. FIG. 7 is a time chart of the power saving operation in the information processing apparatus according to the second embodiment. FIG. 8 is a block diagram of the information processing apparatus according to the third embodiment. FIG. 9 is a circuit diagram of a FAIL signal circuit and an OCA signal circuit according to the third embodiment. FIG. 10 is a time chart of the power saving operation when the FAIL signal is transmitted by the overvoltage protection, the low voltage protection, or the heating protection function in the information processing apparatus according to the third embodiment. FIG. 11 is a time chart of the power saving operation when the FAIL signal indicating the OCA signal is transmitted in the information processing apparatus according to the third embodiment. FIG. 12 is a flowchart of the power saving operation in the information processing apparatus according to the third embodiment. FIG. 13 is a circuit diagram of a FAIL signal circuit and an OCA signal circuit according to the fourth embodiment. FIG. 14 is a time chart of the power saving operation when the FAIL signal indicating the OCA signal is transmitted in the information processing apparatus according to the fourth embodiment. FIG. 15 is a hardware configuration diagram of the information processing apparatus.

  Embodiments of an information processing apparatus and an information processing apparatus control method disclosed in the present application will be described below in detail with reference to the drawings. The information processing apparatus and the information processing apparatus control method disclosed in the present application are not limited by the following embodiments.

  FIG. 1 is a block diagram of the information processing apparatus according to the first embodiment. As shown in FIG. 1, the information processing apparatus according to the present embodiment includes a PSU 1 that is a power supply unit and a portion (hereinafter, referred to as a CPU (Central Processing Unit) other than PSU 1 and a mechanism that performs actual information processing such as a memory (hereinafter, referred to as a power processing unit). In the description, it is referred to as “main body 2” for convenience.

  A plurality of PSUs 1 may be provided, and the information processing apparatus according to the present embodiment includes n PSUs PSU # 1 to PSU # n. In FIG. 1, two PSUs 1 of PSU # 1 and PSU # n are illustrated as an example. Each PSU 1 is connected to a commercial power source 3. Each PSU 1 is supplied with AC power from the commercial power source 3. Hereinafter, the function and operation of PSU1 will be described using PSU # 1 as an example. Since the configuration and operation of PSU 1 other than PSU # 1 are the same as those of PSU # 1, description thereof will be omitted.

  The PSU 1 includes an AC / DC (Alternating Current / Direct Current) 101, a DC / DC (Direct Current / Direct Current) 102, a current sensing unit 103, a diode 104, an amplifier 105, a reference voltage unit 106, a resistor 107, a capacitor 108, and an amplifier. 109, a reference voltage unit 110, and a current balance circuit 111. Further, the PSU 1 includes a FAIL signal circuit 112 and an OCA (Over Current Alarm) signal circuit 113.

  The AC / DC 101 converts alternating current electricity input from the commercial power supply 3 into direct current. And AC / DC101 outputs the electricity converted into direct current to DC / DC102.

  The DC / DC 102 receives an electric input from the AC / DC 101. Then, the DC / DC 102 steps down the inputted electric voltage to a voltage that can be used by each circuit in the main body 2. Also, the DC / DC 102 receives the signal input from the amplifier 105 and changes the amount of voltage reduction according to the received signal. For example, the DC / DC 102 increases the amount of voltage reduction when the voltage of the input signal is high, and decreases the amount of voltage reduction when the voltage of the input signal is low. The DC / DC 102 supplies the reduced voltage to the load 21 of the main body 2 via the diode 104. In the case of an overcurrent, the DC / DC 102 receives a signal input from the amplifier 105 and lowers the voltage supplied to the load 21. As a result, the information processing apparatus enters an overcurrent drooping state. The DC / DC 102 corresponds to an example of a “power supply unit”.

  The current sensing unit 103 measures the voltage of electricity that the DC / DC 102 flows toward the diode 104. For example, the current sensing unit 103 may arrange a resistor and measure a voltage across the resistor, or may use DCR (Direct Current Resistance) current sensing. Then, the current sensing unit 103 outputs electricity having the measured voltage toward the amplifier 109 or the like.

  The amplifier 109 is an operational amplifier, for example. The amplifier 109 receives the voltage output from the current sense unit 103 and the voltage output from the reference voltage unit 110. The amplifier 109 amplifies and outputs the potential difference between the voltage output from the current sense unit 103 and the voltage output from the reference voltage unit 110. Here, the amplification factor of the amplifier 109 is determined by the resistor 107 and the capacitor 108. The voltage output from the amplifier 109 is input to the current balance circuit 111.

  The reference voltage unit 110 outputs a predetermined voltage to the amplifier 109. Here, the voltage output from the reference voltage unit 110 may be determined such that the voltage output from the amplifier 109 is easily compared with the voltage of the parallel operation signal in the current balance circuit 111. preferable.

  The current balance circuit 111 receives a voltage input from the amplifier 109. Further, the current balance circuit 111 extracts an input signal having the highest voltage among the signals input from the other PSUs 1 using a diode, and receives the input as a parallel operation signal. The current balance circuit 111 compares the voltage input from the amplifier 109 with the parallel operation signal and controls the amplification factor of the amplifier 105. Thereby, the control signal with respect to DC / DC102 changes, and the output voltage of DC / DC102 can be adjusted. For example, the current balance circuit 111 reduces the amplification factor when the voltage input from the amplifier 109 is lower than the voltage of the parallel operation signal. The current balance circuit 111 increases the amplification factor when the voltage input from the amplifier 109 is higher than the voltage of the parallel operation signal.

  The reference voltage unit 106 outputs a predetermined voltage to the amplifier 105. Here, the voltage output from the reference voltage unit 106 is, for example, a voltage having a value between 110% and 130% of the rating. The voltage rating in the reference voltage unit 106 is a voltage serving as a reference for the voltage output from the DC / DC 102 to the load 21 of the main body 2.

  The amplifier 105 is an operational amplifier, for example. The amplifier 105 receives the voltage output from the DC / DC 102. In addition, the amplifier 105 receives a voltage input from the reference voltage unit 106. The amplifier 105 amplifies and outputs the potential difference between the voltage output from the DC / DC 102 and the voltage output from the reference voltage unit 106. For example, assuming that the reference voltage output from the reference voltage unit 106 is 130% of the rating, the amplifier 105 outputs a signal having a high voltage to the DC / DC when the voltage output from the DC / DC 102 is higher than 130% of the rating. It outputs to the DC 102 and instructs to lower the voltage. As a result, the voltage output from the DC / DC 102 is lowered, resulting in an overcurrent droop. Here, the voltage from the DC / DC 102 is proportional to the current flowing through the load 21 if the load is constant. Therefore, in the amplifier 105, when the voltage output from the DC / DC 102 exceeds a predetermined value, the overcurrent drooping means that the load current is equal to or greater than a threshold value determined according to the predetermined voltage. This is the same as overcurrent drooping. That is, it can be said that when the load current flowing through the load 21 exceeds the threshold value, an overcurrent droop is caused by an instruction to reduce the voltage from the amplifier 105. The amplifier 105 and the reference voltage unit 106 are an example of an “output voltage adjustment unit”. The voltage output from the reference voltage unit 106 is an example of “first predetermined value”.

  The FAIL signal circuit 112 receives the voltage output from the DC / DC 102. The FAL signal circuit 112 detects an overvoltage or a low voltage from the input voltage, and outputs a FAIL signal notifying the overcurrent or the low voltage to the control unit 22 of the main body 2. FIG. 2 is a circuit diagram of the FAIL signal circuit. Here, the details of the FAIL signal circuit will be described with reference to FIG.

  As shown in FIG. 2, the FAIL signal circuit 112 includes an OVP (Over Voltage Protect) comparator 201, an OVP reference voltage unit 202, a UVP (Under Voltage Protect) comparator 203, a UVP reference voltage unit 204, a power supply voltage 205, and a THP. (Thermal Heating Protect) It has a temperature sensor 206, an OR circuit 207, an on / off unit 208, an output control circuit 209, and an amplifier 210.

  As the power supply voltage 205, the output voltage (Vo) output from the DC / DC 102 is input. Hereinafter, the output voltage (Vo) output from the DC / DC 102 may be simply referred to as “output voltage”. In FIG. 2, for convenience of explanation, the power supply voltage 205 is described. However, the power supply voltage 205 is actually connected to the output path from the DC / DC 102.

  The OVP reference voltage unit 202 outputs a predetermined overvoltage determination voltage for determining an overvoltage if the voltage is higher than that. For example, the OVP reference voltage unit 202 outputs a predetermined voltage that takes a value between 110% and 130% of the rating as the overvoltage determination voltage.

  The OVP comparator 201 receives an output voltage. The OVP comparator 201 receives an overvoltage determination voltage from the OVP reference voltage unit 202. Then, the OVP comparator 201 compares the output voltage with the overvoltage determination voltage. When the output voltage is less than the overvoltage determination voltage, the OVP comparator 201 outputs a High signal. On the other hand, when the output voltage is equal to or higher than the overvoltage determination voltage, the OVP comparator 201 outputs a Low signal.

  The UVP reference voltage unit 204 outputs a predetermined low voltage determination voltage for determining a low voltage if the voltage is lower than that. For example, the UVP reference voltage unit 204 outputs a predetermined voltage that takes a value between 70% and 80% of the rating as the low voltage determination voltage.

  The UVP comparator 203 receives an output voltage. Further, the UVP comparator 203 receives an input of a low voltage determination voltage from the UVP reference voltage unit 204. Then, the UVP comparator 203 compares the output voltage with the low voltage determination voltage. When the output voltage is equal to or higher than the overvoltage determination voltage, the UVP comparator 203 outputs a High signal. On the other hand, when the output voltage is less than the overvoltage determination voltage, the UVP comparator 203 outputs a Low signal.

  The THP temperature sensor 206 is installed in a place where the PSU 1 is likely to become hot. The THP temperature sensor 206 measures the temperature around the installed location. The THP temperature sensor 206 outputs a Low signal when the measured temperature is lower than a predetermined temperature. In contrast, if the measured temperature is equal to or higher than a predetermined temperature, the THP temperature sensor 206 outputs a High signal.

  The OR circuit 207 receives signal inputs from the OVP comparator 201, the UVP comparator 203, and the THP temperature sensor 206. The OR circuit 207 outputs a High signal if the signals input from the OVP comparator 201, the UVP comparator 203, and the THP temperature sensor 206 are all high. On the other hand, if any one of the signals input from the OVP comparator 201, the UVP comparator 203, and the THP temperature sensor 206 is a Low signal, a Low signal is output.

  The on / off unit 208 turns on / off the output control circuit 209 in response to an instruction from the operator. For example, when receiving an on instruction from the operator, the on / off unit 208 turns on the output control circuit 209. When receiving an off instruction from the operator, the on / off unit 208 turns off the output control circuit 209.

  The output control circuit 209 receives a signal input from the OR circuit 207. The output control circuit 209 does not output the signal input from the OR circuit 207 in the case of off. On the other hand, when ON, the output control circuit 209 outputs the signal input from the OR circuit 207 to the amplifier 210.

  The amplifier 210 receives a signal input from the output control circuit 209. The amplifier 210 amplifies the input signal and outputs it to the control unit 22 of the main body 2 as a FAIL signal.

  The FAIL signal output from the FAIL signal circuit 112 will be described together. FIG. 3 is a diagram showing a truth table of the FAIL signal. OVP in truth table 200 represents an output from OVP comparator 201. UVP in truth table 200 represents the output from UVP comparator 203. THP in the truth table 200 represents an output from the THP temperature sensor 206. In the truth table 200, “0” in the columns of OVP, UVP, and THP indicates normality, and “1” in the columns of OVP, UVP, and THP indicates that an abnormality has occurred. Represents. Further, “0” in the column of the FAIL signal in the truth table 200 indicates that the signal indicates an abnormality, and “1” in the column of the FAIL signal indicates that the signal indicates normality.

  In the truth table 200, when the outputs from the OVP comparator 201, the UVP comparator 203, and the THP temperature sensor 206 are all normal, that is, all the columns are “0”, the FAIL signal is a signal indicating normal. " On the other hand, if any one of the outputs from the OVP comparator 201, the UVP comparator 203, and the THP temperature sensor 206 is abnormal, that is, if any column is “1”, in the truth table 200, the FAIL signal is It is “0” which is a signal representing an abnormality. The FAIL signal is High in the case of a signal representing normality, and is Low in the case of a signal representing abnormality.

  The OCA signal circuit 113 includes an OCA comparator 301 and an OCA reference voltage unit 302.

  The OCA reference voltage unit 302 outputs a predetermined overcurrent determination voltage for determining an overcurrent if the voltage is higher than that. The overcurrent determination voltage is a value lower than the overvoltage determination voltage. When the overcurrent determination voltage is a value between 110% and 130% of the rating, for example, the OCA reference voltage unit 302 outputs a voltage having a value between 100% of the rating as the overcurrent determination voltage. Here, the voltage rating in the OCA reference voltage unit 302 is, for example, when a voltage serving as a reference for the voltage output from the DC / DC 102 to the load 21 of the main body 2 is output from the DC / DC 102. For example, the voltage output from 103.

  The OCA comparator 301 receives a voltage input from the current sense unit 103. The OCA comparator 301 receives an input of an overcurrent determination voltage from the OCA reference voltage unit 302. The OCA comparator 301 compares the voltage input from the current sense unit 103 with the overcurrent determination voltage. When the voltage input from the current sense unit 103 is less than the overcurrent determination voltage, the OCA comparator 301 outputs an OCA signal indicating normality to the control unit 22. For example, in this embodiment, the OCA comparator 301 outputs a Low signal as a signal indicating normality. On the other hand, when the voltage input from the current sense unit 103 is equal to or higher than the overcurrent determination voltage, the OCA comparator 301 outputs an OCA signal indicating an abnormality to the control unit 22. For example, in this embodiment, the OCA comparator 301 outputs a High signal as a signal indicating abnormality. Here, the voltage from the current sensing unit 103 is proportional to the current flowing through the load 21 if the load is constant. Therefore, in the OCA comparator 301, the voltage from the current sensing unit 103 being equal to or higher than the overcurrent determination voltage is the same as the load current flowing through the load 21 being equal to or higher than a threshold determined according to the overcurrent determination voltage. is there. That is, it can be said that when the load current flowing through the load 21 exceeds the threshold, the OCA comparator 301 outputs an OCA signal indicating abnormality. This overcurrent determination voltage corresponds to an example of “second predetermined value”.

  For example, when a voltage that takes a value of 100% of the rating is used as the overcurrent determination voltage, the OCA comparator 301 determines that if the voltage input from the current sense unit 103 is less than 100% of the rating, a Low signal, That is, an OCA signal indicating normality is output. On the other hand, when the voltage input from the current sense unit 103 becomes 100% or more of the rating, the OCA comparator 301 outputs a High signal, that is, an OCA signal representing an abnormality.

  Since the overcurrent determination voltage is set to a value lower than the overvoltage determination voltage, before the overcurrent droop occurs in the amplifier 105, the OCA comparator 301 outputs an OCA signal indicating an abnormality. The OCA signal circuit 113 is an example of an “overcurrent detection unit”.

  The main body 2 includes a load 21 and a control unit 22.

  As shown in FIG. 1, the load 21 includes a CPU, a memory, a PCI (Peripheral Component Interconnect) card, an HDD (Hard Disk Drive), a fan, and the like. Here, in FIG. 1, a CPU, a memory, and the like are described as examples of the load 21, but the load 21 is not limited to those described here, and any component that operates using the power supplied from the PSU 1 can be used as the load 21. Become. The load 21 receives control from the control unit 22 to limit power consumption. The load 21 reduces power consumption by reducing the load according to the received control. The load 21 uses a large current if the consumed power is large, that is, if the load is large, and uses a small current if the consumed power is small, that is, if the load is small.

  The control unit 22 controls the operation of each component included in the load 21. For example, the control unit 22 controls ON / OFF of the hard disk. For example, the control unit 22 controls the number of rotations of the fan.

  The control unit 22 receives an input of the FAIL signal from the FAIL signal circuit 112. When all of the overvoltage protection, the low voltage protection, and the overheat protection are normal, the control unit 22 receives a high signal indicating normality from the FAIL signal circuit 112. On the other hand, when an abnormality has occurred in any of the overvoltage protection, the low voltage protection, and the overheat protection, the control unit 22 receives an input of a Low signal indicating the abnormality from the FAIL signal circuit 112.

  When receiving the input of the FAIL signal indicating the abnormality, the control unit 22 performs a predetermined process. For example, processing such as notifying the CPU of the occurrence of an abnormality and stopping the operation of the information processing apparatus is performed.

  The control unit 22 receives an OCA signal from the OCA comparator 301 of the OCA signal circuit 113. When the received OCA signal is a signal indicating normality, that is, a Low signal, the control unit 22 performs normal control on the load 21. On the other hand, when the received OCA signal is a signal indicating abnormality, that is, a High signal, the control unit 22 reduces the power consumed by the load 21. For example, the control unit 22 may reduce the CPU and memory clocks, reduce the number of fan rotations, stop unused HDDs, or limit the number of operating CPUs when there are multiple CPUs. By doing so, power consumption is reduced. Hereinafter, the state in which the power consumed by the control unit 22 at the load 21 is reduced may be referred to as “power save mode”. Further, the process of reducing power consumption performed in the power save mode may be referred to as “power save”. By shifting to the power save mode, the power consumed by the load 21 decreases, and the current flowing to the load 21 decreases.

  Here, as described above, before the overcurrent drooping by the amplifier 105 occurs, the OCA comparator 301 outputs an OCA signal indicating an abnormality. Therefore, the control unit 22 can receive the OCA signal and cause the load 21 to shift to the power save mode before the overcurrent droop occurs.

  The control unit 22 stores a predetermined period (here, this period is referred to as “period Ta”) as a period from when the OCA signal returns to normal to when the power save is canceled. For example, the period Ta can be 1 minute or the like. Here, if the period Ta is made too short, the voltage output from the current sense 103 may exceed the overcurrent determination voltage as soon as the power save is canceled. In this case, power saving is frequently repeated, and the system becomes unstable. On the other hand, if the period Ta is too long, the power saving time becomes too long and the processing is delayed. Therefore, it is preferable that the period Ta is set appropriately according to the operation status.

  After the control unit 22 receives the OCA signal indicating abnormality and then receives the OCA signal indicating normality, when the period Ta elapses, the control unit 22 cancels the power save mode. When the power save mode is canceled, the load 21 returns to normal operation and the load increases, so that the current flowing through the load 21 increases.

  Here, the control unit 22 shifts the load 21 to the power save mode when an OCA signal indicating abnormality is input even in one of the PSUs 1. However, since each PSU 1 is adjusted by the current balance circuit 111 so that each PSU 1 outputs substantially the same current, in most cases, the OCA signal is input from most PSUs 1. For this reason, even if there is a PSU 1 that inputs even one OCA signal indicating an abnormality, even if the load 21 is shifted to the power save mode, appropriate power consumption can be reduced.

  Next, the flow of the power saving operation according to the present embodiment will be described with reference to FIG. FIG. 4 is a time chart of the power saving operation in the information processing apparatus according to the first embodiment.

  A graph 401 represents the OCA signal output from the OCA signal circuit 113. The high portion of the graph 401 represents a high signal, and the low portion represents a low signal. A graph 402 represents a power saving operation. In the portion where the graph 402 is high, power saving is performed at the load 21, and in the portion where the graph 402 is low, power saving is not performed. A graph 403 represents a change in voltage output from the current sense unit 103. A graph 403 represents voltage on the vertical axis. Since the voltage output from the DC / DC 102 is proportional to the current flowing through the load 21, the graph 403 may be considered to represent a change in the load current flowing through the load 21. Each of the graphs 401 to 403 represents the passage of time on the horizontal axis.

  A threshold value 404 represents an overcurrent determination voltage output from the OCA reference voltage unit 302. Here, the case where the voltage of 100% of the rating is used as the overcurrent determination voltage will be described.

  At timing 411, the voltage output from the current sensing unit 103 increases and exceeds the threshold value 404, which is 100% of the rated voltage.

  The OCA comparator 301 detects that the voltage input from the current sense unit 103 has exceeded the overcurrent determination voltage. At timing 412, the signal output from the OCA signal circuit 113 changes from Low indicating normality to High indicating abnormality.

  When a High signal is input from the OCA signal circuit 113 to the control unit 22, at timing 413, the control unit 22 shifts the load 21 to the power save mode.

  When the load 21 shifts to the power save mode, the load current flowing to the load 21 decreases, and the voltage output from the current sensing unit 103 decreases at the timing 414 and becomes the threshold 404 or less. As a result, the voltage input to the OCA comparator 301 becomes less than the overcurrent determination voltage, and at timing 415, the signal output from the OCA signal circuit 113 changes from High indicating abnormality to Low indicating normal.

  After the input from the OCA signal circuit 113 changes to Low, the control unit 22 measures a period Ta represented by a period 417. During the period Ta, for example, the load of the CPU 21 is finished in the state of shifting to the power saving mode, and the load is reduced, and the load current flowing to the load 21 is reduced. As a result, at timing 416, the voltage output from the current sense unit 103 further decreases.

  Then, at timing 418 when the period Ta has elapsed, the control unit 22 cancels the power save mode of the load 21.

  When the power save is canceled, the load 21 returns to the normal operation, and the load current increases. As a result, at timing 419, the voltage output from the current sensing unit 103 increases. However, since the load current is reduced at timing 416 due to the completion of processing by the CPU, the voltage output from the current sense unit 103 does not exceed the threshold value 404 even when the power save mode is canceled, indicating an abnormality. The OCA signal is not output.

  Next, the flow of the power saving operation in the information processing apparatus according to the present embodiment will be described with reference to FIG. FIG. 5 is a flowchart of the power saving operation in the information processing apparatus according to the first embodiment.

  When the load current flowing through the load 21 increases and the voltage output from the current sensing unit 103 exceeds the overcurrent determination voltage, the OCA comparator 301 outputs an OCA signal indicating an abnormality. And the control part 22 receives the OCA signal which shows abnormality (step S101).

  The controller 22 shifts the load 21 to the power save mode (step S102).

  The OCA comparator 301 determines whether or not the voltage from the current sensing unit 103 is less than a threshold that is an overcurrent determination voltage (step S103). When the voltage is equal to or higher than the threshold (No at Step S103), the OCA comparator 301 waits until the voltage becomes lower than the threshold. On the other hand, when the voltage is less than the threshold (step S103: positive), the OCA comparator 301 returns the OCA signal to normal (step S104).

  In response to the return of the OCA signal to normal, the control unit 22 determines whether or not the period Ta has elapsed (step S105). When the period Ta has not elapsed (No at Step S105), the control unit 22 waits until the period Ta has elapsed. On the other hand, when the period Ta has elapsed (step S105: affirmative), the control unit 22 cancels the power save mode of the load 21 (step S106).

  As the power save mode is canceled, the load 21 performs a normal operation (step S107).

  As described above, the information processing apparatus according to the present embodiment limits the load and reduces power consumption when the load current flowing through the load exceeds a predetermined value before the overcurrent droops. When the load current flowing through the load decreases, the restriction on the load is released. As a result, the current can be reduced before the overcurrent droops, and the output drops due to the overcurrent droop, and the transition to a state outside the output accuracy of the PSU can be reduced. Therefore, the system can be kept operating stably.

  FIG. 6 is a circuit diagram of an OCA signal circuit according to the second embodiment. When the voltage output from the current sense exceeds the overcurrent determination voltage and the OCA signal indicating abnormality is output, the information processing apparatus according to the present embodiment falls below a predetermined threshold lower than the overcurrent determination voltage. Canceling the power save mode is different from the first embodiment. The information processing apparatus according to the present embodiment is also represented by the block diagram of FIG. In the following, description of each part having the same function as in the first embodiment will be omitted.

  The OCA signal circuit 113 according to this embodiment includes a resistor 303, a resistor 304, and a transistor 305 in addition to the OCA comparator 301 and the OCA reference voltage unit 302.

  The input path from the current sense unit 103 is branched and connected to the resistor 303 and the transistor 305. Further, the resistor 303 and the resistor 304 are connected in series. An input path to the OCA comparator 301 extends from a point between the resistors 303 and 304. The resistor 304 is connected to the ground. Further, a signal from the OCA comparator 301 is output to the control unit 22 and is branched in the middle and applied to the transistor 305. Here, the resistance of the resistor 303 is R1, and the resistance of the resistor 304 is R2.

  The transistor 305 is turned off when the signal output from the OCA comparator 301 is Low. The transistor 305 is turned on when the signal output from the OCA comparator 301 is High. That is, the transistor 305 is turned off when the OCA signal indicating normality is output from the OCA comparator 301, and is turned on when the OCA signal indicating abnormality is output from the OCA comparator 301.

  When the transistor 305 is OFF, that is, when the OCA signal indicates normal, the electricity input by the current sense unit 103 flows through the resistor 303. Further, when the transistor 305 is ON, that is, when the OCA signal indicates an abnormality, the electricity input by the current sense unit 103 flows to the transistor 305.

  Here, when it is determined that an overcurrent occurs when the voltage output from the current sense unit 103 reaches a predetermined voltage, the OCA reference voltage unit 302 uses a voltage obtained by multiplying the predetermined voltage by R2 / (R2 + R1). Output as overcurrent judgment voltage. For example, when it is determined that an overcurrent occurs when the voltage output from the current sense unit 103 reaches 100% or more of the rating, the OCA reference voltage unit 302 sets R2 / (R2 + R1) to the voltage of 100% of the rating. The multiplied voltage is output as an overcurrent determination voltage. R2 / (R2 + R1) is a voltage division ratio when electricity is input to the OCA comparator 301 via the resistor 303, as will be described later. Here, assuming that 100% of the rated voltage is Va, the overcurrent determination voltage output by the OCA reference voltage unit 302 is expressed as Va × {R2 / (R2 + R1)}.

  When the OCA comparator 301 outputs an OCA signal indicating normality, the transistor 305 is OFF, so that the OCA comparator 301 receives an electric input having a voltage divided by the resistor 303 and the resistor 304 from the resistor 303. Here, assuming that the voltage of electricity input from the current sensing unit 103 is V, electricity having a voltage of V × {R2 / (R2 + R1)} flows through the OCA comparator 301. Then, the OCA comparator 301 compares the voltage V × {R2 / (R2 + R1)} with the overcurrent determination voltage Va × {R2 / (R2 + R1)} from the OCA reference voltage unit 302. When the voltage V × {R2 / (R2 + R1)} is lower than the overcurrent determination voltage, that is, when V <Va, the OCA comparator 301 outputs an OCA signal indicating normality, that is, a Low signal. On the other hand, when the voltage V × {R2 / (R2 + R1)} is equal to or higher than the overcurrent determination voltage, that is, V ≧ Va, the OCA comparator 301 outputs an OCA signal indicating abnormality, that is, a High signal.

  When the OCA comparator 301 outputs an OCA signal indicating an abnormality, the transistor 305 is ON, so that the OCA comparator 301 receives an electric input having the voltage input by the current sense unit 103 from the transistor 305. Here, if the voltage of electricity input from the current sensing unit 103 is V, electricity having a voltage of V flows through the OCA comparator 301. Then, the OCA comparator 301 compares the voltage of V with the Va × {R2 / (R2 + R1)} overcurrent determination voltage from the OCA reference voltage unit 302. The OCA comparator 301 outputs an OCA signal indicating normality, that is, a Low signal, when the voltage of V is less than the overcurrent determination voltage, that is, when V <Va × {R2 / (R2 + R1)}. On the other hand, when the voltage V is equal to or higher than the overcurrent determination voltage, that is, when V ≧ Va × {R2 / (R2 + R1)}, the OCA comparator 301 displays an OCA signal indicating abnormality, that is, a high signal. Is output.

  That is, when the OCA comparator 301 changes from a state in which an OCA signal indicating normality is output to a state in which an OCA signal indicating abnormality is output, the output voltage from the current sense unit 103 and a voltage of 100% of the rated value are Will be compared. Further, when the state changes from the state of outputting the OCA signal indicating abnormality to the state of outputting the OCA signal indicating normality, the OCA comparator 301 reduces the output voltage from the current sensing unit 103 to 100% of the rating {R2 / (R2 + R1)} is compared with the voltage multiplied by the value. As described above, when the OCA comparator 301 returns to the state of outputting the OCA signal indicating normality, after the output voltage from the current sense unit 103 becomes less than a voltage having a value smaller than 100% of the rating, An OCA signal is output. The voltage of 100% of the rating described here is an example of “second predetermined value”, and the voltage of 100% voltage multiplied by {R2 / (R2 + R1)} is an example of “third predetermined value”. It hits.

  Next, the flow of the power saving operation according to the present embodiment will be described with reference to FIG. FIG. 7 is a time chart of the power saving operation in the information processing apparatus according to the second embodiment.

  A graph 501 represents the OCA signal output from the OCA signal circuit 113. The high portion of the graph 501 represents a high signal, and the low portion represents a low signal. A graph 502 represents a power saving operation. In the portion where the graph 502 is high, power saving is performed at the load 21, and in the portion where the graph 502 is low, power saving is not performed. A graph 503 represents a change in voltage output from the current sense unit 103. A graph 503 represents voltage on the vertical axis. Since the voltage output from the DC / DC 102 is proportional to the current flowing through the load 21, the graph 403 may be considered to represent a change in the load current flowing through the load 21. Each of the graphs 401 to 403 represents the passage of time on the horizontal axis.

  A threshold 504 represents an overcurrent determination voltage when the voltage input from the current sensing unit 103 to the OCA comparator 301 is considered constant.

  When the OCA signal indicating normality is output from the OCA comparator 301, the transistor 305 is OFF, and the threshold value 504 is 100% of the rated voltage (hereinafter referred to as “Va”).

  At a timing 511, the voltage output from the current sensing unit 103 increases and exceeds the threshold value 504, Va.

  The OCA comparator 301 detects that the voltage input from the current sense unit 103 has exceeded the overcurrent determination voltage. At timing 512, the signal output from the OCA comparator 301 changes from Low indicating normal to High indicating abnormality.

  When the signal output from the OCA comparator 301 becomes High, the transistor 305 is turned on, and at the timing 513, the threshold 504 becomes Va × {R2 / (R2 + R1)}.

  When a High signal is input from the OCA comparator 301 to the control unit 22, at a timing 514, the control unit 22 shifts the load 21 to the power save mode.

  When the load 21 shifts to the power save mode, the load current flowing to the load 21 decreases, and the voltage input to the OCA comparator 301 decreases at timing 515. At this time, the voltage input to the OCA comparator 301 is lower than Va but is Va × {R2 / (R2 + R1)} or more. Therefore, at this timing, the signal output from the OCA signal circuit 113 does not change from Low indicating normality to High indicating abnormality.

  Thereafter, for example, the CPU process ends in the state of shifting to the power saving mode, and the load is reduced, and the load current flowing to the load 21 is reduced. As a result, the voltage output from the current sensing unit 103 further decreases at timing 516. As a result, the voltage input to the OCA comparator 301 becomes Va × {R2 / (R2 + R1)} or less.

  Therefore, at the timing 517, the OCA signal output from the OCA comparator 301 changes from High indicating abnormality to Low indicating normal. When the Low signal is output from the OCA comparator 301, the transistor 305 is turned off. Therefore, at timing 518, the threshold value 504 returns to Va.

  Thereafter, at timing 519, the control unit 22 releases the power save mode of the load 21.

  When the power save mode is canceled, the load 21 returns to normal operation, and the load current increases. Thereby, at timing 520, the voltage output from the current sensing unit 103 increases. However, since the load current is reduced at timing 516 or the like due to the completion of processing by the CPU, the voltage output from the current sense unit 103 does not exceed the threshold value 504 even if the power save mode is canceled, indicating an abnormality. The OCA signal is not output.

  As described above, when the voltage output from the current sense unit falls below a threshold value that is lower than the threshold value for determining overcurrent, the information processing apparatus according to the present embodiment returns the OCA signal to normal and returns power. Save mode is canceled. In other words, the information processing apparatus according to the present embodiment shifts to the power save mode when the load current becomes equal to or higher than the first threshold value, and then cancels the power save mode when the load current falls below the second threshold value lower than the first threshold value. For this reason, the information processing apparatus according to the present embodiment can cancel the power save mode after the current has surely decreased, can perform more appropriate power saving control, and can stably operate the system more appropriately. it can.

  FIG. 8 is a block diagram of the information processing apparatus according to the third embodiment. The information processing apparatus according to the present embodiment is different from the first embodiment in that an OCA signal is output as a FAIL signal. In the following, description of each part having the same function as in the first embodiment will be omitted.

  When the voltage input from the current sense unit 103 is less than the overcurrent determination voltage, the OCA comparator 301 according to this embodiment outputs a Low signal that is an OCA signal indicating normality to the FAIL signal circuit 112. Further, the OCA comparator 301 according to the present embodiment outputs a High signal, which is an OCA signal indicating an abnormality, to the FAIL signal circuit 112 when the voltage input from the current sensing unit 103 is equal to or higher than the overcurrent determination voltage.

  FIG. 9 is a circuit diagram of a FAIL signal circuit and an OCA signal circuit according to the third embodiment. The FAIL signal circuit 112 according to the present embodiment further includes a NOR circuit 211 in addition to the FAIL signal circuit according to the first embodiment. The signal output from the OCA comparator 301 is input to the NOR circuit 211.

  When the NOR circuit 211 receives a signal indicating an abnormality from one or both of the output control circuit 209 and the OCA comparator 301, the NOR circuit 211 outputs a High signal that is a FAIL signal indicating the abnormality to the control unit 22. The FAIL signal circuit 112 is an example of an “error notification unit”.

  The control unit 22 receives an input of a FAIL signal indicating normality from the NOR circuit 211 when no abnormality has occurred. Further, when an abnormality has occurred, the control unit 22 receives an input of a FAIL signal indicating the abnormality from the NOR circuit 211. Here, when a FAIL signal indicating an abnormality is received, the control unit 22 outputs a FAIL signal indicating an abnormality in overvoltage protection, undervoltage protection or overheat protection at that stage, or output from the OCA signal circuit 113. A distinction cannot be made between FAIL signal conversion indicating the OCA signal. Therefore, it is determined whether or not the FAIL signal received by the following method is a signal indicating the OCA signal.

  After receiving the FAIL signal indicating the abnormality, the control unit 22 stores a period Tb until it is determined whether or not the FAIL signal indicating the abnormality is a FAIL signal indicating the OCA signal. Further, the control unit 22 stores a period Tc from when the FAIL signal indicating abnormality is received until the power save mode is canceled. The period Tc is a period longer than the period Tb. For example, the period Tb can be within 1 minute, and the period Tc can be 2 minutes or 3 minutes. However, if the period Tb is too long, the determination whether or not the FAIL signal indicating the abnormality is a FAIL signal indicating the OCA signal is delayed, and the separation is delayed. Therefore, the overcurrent protection function and the low current protection function worked. It will be late to detect this. Therefore, the period Tb is preferably a period that is sufficient for the current to fall to an appropriate value by performing power saving, and that can be separated early.

  When receiving the FAIL signal indicating abnormality, the control unit 22 shifts the load 21 to the power save mode. Thereafter, the control unit 22 stands by for a period Tb. Then, the control unit 22 determines whether the FAIL signal is High or Low after a period Tb after receiving the FAIL signal.

  If the FAIL signal is Low, the FAIL signal indicating an abnormality continues to be output even if power saving is performed, so the control unit 22 determines that the FAIL signal indicates an abnormality in overvoltage protection, undervoltage protection, or overheat protection. . In this case, the control unit 22 performs a predetermined process when a FAIL signal is received. For example, the control unit 22 shuts down the information processing apparatus.

  When the FAIL signal is High, since the power signal is changed to the FAIL signal indicating normality, the control unit 22 determines that the FAIL signal indicating the abnormality received earlier is the FAIL signal indicating the OCA signal. In this case, the control unit 22 waits until the period Tc elapses after receiving the FAIL signal indicating abnormality, and cancels the power save mode of the load 21 when the period Tc elapses. Here, by making a time difference between the period Tb and the period Tc, frequent transition to and release from the power save mode can be avoided. Further, when a FAIL signal is transmitted due to power saving, it is possible to prevent erroneous detection as an alarm from the PSU due to a low voltage protection function or the like.

  Next, the operation of the control unit when a FAIL signal is transmitted by the function of overvoltage protection, low voltage protection, or heating protection will be described with reference to FIG. FIG. 10 is a time chart of the power saving operation when the FAIL signal is transmitted by the overvoltage protection, the low voltage protection, or the heating protection function in the information processing apparatus according to the third embodiment.

  A graph 601 represents a FAIL signal output from the FAIL signal circuit 112. A high portion of the graph 601 represents a high signal, and a low portion represents a low signal. A graph 602 represents the OCA signal output from the OCA signal circuit 113. The high portion of the graph 602 represents a high signal, and the low portion represents a low signal. A graph 603 represents a transition to the power save mode. In the portion where the graph 602 is high, power saving is performed at the load 21, and in the portion where the graph 602 is low, power saving is not performed. Each of graphs 601 to 603 represents the passage of time on the horizontal axis.

  At timing 611, the FAIL signal changes from High to Low, and a FAIL signal indicating an abnormality starts to be transmitted to the control unit 22. When receiving the FAIL signal indicating abnormality, the control unit 22 waits until the period Tb represented by the period 614 elapses.

  At this time, the control unit 22 cannot determine whether or not an OCA signal indicating abnormality is output from the OCA signal circuit 113. Therefore, as shown by the signal 612, it is unknown whether the OCA signal is High or Low during this period.

  Then, the control unit 22 shifts the load 21 to the power save mode at timing 613.

  Then, the control unit 22 determines whether the FAIL signal is High or Low at the timing 615 after the period Tb has elapsed. If the FAIL signal is also low at timing 615, that is, if the FAIL signal indicates an abnormality, the control unit 22 determines that the FAIL signal indicating the abnormality is transmitted by the function of overvoltage protection, low voltage protection, or heating protection. To do. Thereafter, the control unit 22 performs processing such as shutdown. However, when the overvoltage protection function operates, the OCA signal may also change to a state indicating an abnormality. Therefore, even after the timing 615, it is difficult to specify whether the OCA signal is High or Low.

  Next, the flow of the power saving operation according to the present embodiment will be described with reference to FIG. FIG. 11 is a time chart of the power saving operation when the FAIL signal indicating the OCA signal is transmitted in the information processing apparatus according to the third embodiment.

  A graph 701 represents a FAIL signal output from the FAIL signal circuit 112. A high portion of the graph 701 represents a high signal, and a low portion represents a low signal. A graph 702 represents the OCA signal output from the OCA signal circuit 113. A high portion of the graph 702 represents a high signal, and a low portion represents a low signal. A graph 703 represents a transition to the power save mode. In the portion where the graph 703 is high, power saving is performed at the load 21, and in the portion where it is low, power saving is not performed. A graph 704 represents a change in voltage output from the current sensing unit 103. Graph 704 represents voltage on the vertical axis. Each of the graphs 701 to 704 represents the passage of time on the horizontal axis.

  A threshold 705 represents an overcurrent determination voltage output from the OCA reference voltage unit 302. Here, the case where the voltage of 100% of the rating is used as the overcurrent determination voltage will be described.

  At timing 711, the voltage output from the current sensing unit 103 increases and exceeds the threshold value 705, which is 100% of the rated voltage.

  The OCA comparator 301 detects that the voltage input from the current sense unit 103 has exceeded the overcurrent determination voltage. At timing 712, the signal output from the OCA comparator 301 changes from Low indicating normal to High indicating abnormality.

  When a High signal is input from the OCA comparator 301 to the FAIL signal circuit 112, at a timing 713, the FAIL signal output from the FAIL signal circuit 112 changes from High to Low.

  When a Low signal is input from the FAIL signal circuit 114 to the control unit 22, at timing 714, the control unit 22 shifts the load 21 to the power save mode.

  When the load 21 shifts to the power save mode, the load current flowing to the load 21 decreases, and the voltage output from the current sensing unit 103 decreases at the timing 715 and becomes the threshold value 705 or less. As a result, since the voltage input to the OCA comparator 301 becomes less than the overcurrent determination voltage, at timing 716, the signal output from the OCA comparator 301 changes from High indicating abnormality to Low indicating normal. When the OCA signal input from the OCA signal circuit 113 to the FAIL signal circuit 112 changes from High to Low, at a timing 717, the FAIL signal output from the FAIL signal circuit 112 changes from Low to High. Here, although the input from the FAIL signal circuit 112 has changed to High indicating normality, the control unit 22 does not immediately release the power save mode.

  The control unit 22 measures a period Tb represented by a period 718 after receiving a High FAIL signal indicating abnormality. Then, when the period Tb has elapsed, the control unit 22 determines whether the FAIL signal is High or Low. In this embodiment, since the FAIL signal indicating abnormality is a FAIL signal indicating the OCA signal, the control unit 22 detects that the FAIL signal is High. Thereafter, the control unit 22 waits until a period Tc represented by a period 719 elapses after receiving a High FAIL signal indicating abnormality.

  During the period Tc, for example, the load of the CPU 21 is finished in the state of shifting to the power saving mode, and the load is reduced. As a result, at timing 720, the voltage output from the current sensing unit 103 further decreases.

  Then, at timing 721 when the period Tc has elapsed, the control unit 22 cancels the power save mode of the load 21.

  When the power save is canceled, the load 21 returns to the normal operation, and the load current increases. As a result, the voltage output from the current sensing unit 103 increases at timing 722. However, since the load current is reduced at timing 720 due to the completion of processing by the CPU, the voltage output from the current sense unit 103 does not exceed the threshold 404 even when the power save mode is canceled, indicating an abnormality. The OCA signal is not output.

  Next, the flow of the power saving operation in the information processing apparatus according to the present embodiment will be described with reference to FIG. FIG. 12 is a flowchart of the power saving operation in the information processing apparatus according to the third embodiment.

  When the OCA comparator 301 outputs an OCA signal indicating an abnormality or when a FAIL signal indicating an abnormality is transmitted by the function of overvoltage protection, undervoltage protection or heating protection, the FAIL signal circuit 112 outputs a FAIL signal indicating an abnormality. The data is sent to the control unit 22. And the control part 22 receives the FAIL signal which shows abnormality (step S201).

  The control unit 22 shifts the load 21 to the power save mode (step S202).

  The OCA comparator 301 determines whether or not the voltage from the current sensing unit 103 is less than a threshold that is an overcurrent determination voltage (step S203). When the voltage is equal to or higher than the threshold (No at Step S203), the OCA comparator 301 waits until the voltage becomes less than the threshold. On the other hand, when the voltage is less than the threshold value (step S203: affirmative), the OCA comparator 301 returns the OCA signal to normal (step S204).

  The control unit 22 determines whether or not the period Tb has elapsed after receiving the FAIL signal indicating abnormality (step S205). When the period Ta has not elapsed (No at Step S205), the control unit 22 waits until the period Ta has elapsed. On the other hand, when the period Ta has elapsed (step S205: affirmative), the control unit 22 determines whether or not a FAIL signal indicating abnormality has been received (step S206). When the FAIL signal indicating abnormality has not been received (No at Step S206), the control unit 22 determines whether or not the period Tc has elapsed since the reception of the FAIL signal indicating abnormality (Step S207). When the period Tc has not elapsed (No at Step S207), the control unit 22 waits until the period Tc has elapsed.

  On the other hand, when the period Tc has elapsed (step S207: affirmative), the control unit 22 cancels the power save mode of the load 21 (step S208). As the power save mode is canceled, the load 21 performs a normal operation (step S209).

  On the other hand, when the FAIL signal indicating abnormality is received (step S206: Yes), the control unit 22 determines that the PSU 1 outputting the FAIL signal has failed (step S210). In this case, the control unit 22 executes a predetermined process such as shutdown.

  As described above, the information processing apparatus according to the present embodiment notifies the control unit of the information on the OCA signal using the FAIL signal. As a result, even when there is no vacancy in the signal PIN for transmitting and receiving signals between the PSU and the apparatus body, the OCA signal information can be sent to the control unit, and the current can be reduced before the overcurrent droops. it can.

  FIG. 13 is a circuit diagram of a FAIL signal circuit and an OCA signal circuit according to the fourth embodiment. When the voltage output from the current sense exceeds the overcurrent determination voltage and the OCA signal indicating abnormality is output, the information processing apparatus according to the present embodiment falls below a predetermined threshold lower than the overcurrent determination voltage. Canceling the power save mode is different from the first embodiment. That is, the present embodiment is a configuration when the function of the second embodiment is incorporated in the third embodiment. The information processing apparatus according to the present embodiment is also represented by the block diagram of FIG. Below, description may be abbreviate | omitted about each part which has the same function as Examples 1-3.

  The OCA signal circuit 113 according to the present embodiment includes an OCA comparator 301, an OCA reference voltage unit 302, a resistor 303, a resistor 304, and a transistor 305 as in the second embodiment. Further, the OCA signal circuit 113 according to the present embodiment has an EXOR (exclusive-OR) circuit 307.

  Similarly to the second embodiment, when the OCA signal indicating normality is output from the OCA comparator 301, the OCA comparator 301 receives the divided voltage by the resistor 303 and the resistor 304. When the OCA signal indicating abnormality is output from the OCA comparator 301, the voltage output from the current sense unit 103 is input to the OCA comparator 301. That is, also in the present embodiment, the OCA comparator 301 makes a determination by comparing a low voltage with a threshold when determining the occurrence of an overcurrent, and high when determining the convergence of the occurrence of an overcurrent. A determination is made by comparing the voltage with a threshold value. As a result, the OCA comparator 301 continues to output an OCA signal indicating an abnormality until the voltage output from the current sensing unit 103 becomes less than a threshold value that is lower than a threshold value for determining that an overcurrent has occurred.

  The signal output from the OCA comparator 301 is branched, one is input to the EXOR circuit 307 and the other is input to the delay circuit 308.

  The delay circuit 308 gives a certain delay to the received signal, and then outputs the signal to the EXOR circuit 307. The delay circuit 308 includes a flip-flop and the like.

  For example, when an OCA signal indicating an abnormality is output from the OCA comparator 301, after the OCA signal indicating the abnormality is input to the EXOR circuit 307, after a certain period of time, the OCA signal indicating the same abnormality is transmitted to the delay circuit 308. Is input to the EXOR circuit 307.

  The EXOR circuit 307 outputs a Low signal to the NOR circuit 211 of the FAIL signal circuit 112 when both the OCA signal input from the OCA comparator 301 and the OCA signal input from the delay circuit 308 are High or Low. . The EXOR circuit 307 outputs a High signal to the NOR circuit 211 of the FAIL signal circuit 112 when one of the OCA signal input from the OCA comparator 301 and the OCA signal input from the delay circuit 308 is High and the other is Low. Output to.

  That is, when the OCA signal output from the OCA comparator 301 changes from a low signal indicating normality to a high signal indicating abnormality, the output from the EXOR circuit 307 changes from low to high. Thereafter, the EXOR circuit 307 outputs a high signal until the delay time elapses. When the delay time elapses, the output from the EXOR circuit 307 changes from High to Low. Thereafter, the EXOR circuit 307 outputs a Low signal until the OCA signal output from the OCA comparator 301 changes from a High signal indicating abnormality to a Low signal indicating normality. When the OCA signal output from the OCA comparator 301 changes from a high signal indicating abnormality to a low signal indicating normality, the output from the EXOR circuit 307 changes from low to high. Thereafter, the EXOR circuit 307 outputs a high signal until the delay time elapses. When the delay time elapses, the output from the EXOR circuit 307 changes from High to Low. In other words, the EXOR circuit 307 generates a pulse having a width corresponding to the delay time provided by the delay circuit 308 at the timing when the OCA signal changes from High to Low and at the timing when the OCA signal changes from Low to High.

  When the NOR circuit 211 receives an input of a signal indicating abnormality from one or both of the output control circuit 209 and the EXOR circuit 307, the NOR circuit 211 outputs a High signal that is a FAIL signal indicating abnormality to the control unit 22. For example, when the NOR circuit 211 receives a signal indicating normality from the output control circuit 209 and receives a pulsed signal from the EXOR circuit 307, the NOR circuit 211 outputs a similar pulsed FAIL signal to the control unit 22. .

  When receiving the pulse signal from the NOR circuit 211, the control unit 22 shifts the load 21 to the power save mode. Thereafter, when the pulse signal is received again from the NOR circuit 211, the control unit 22 cancels the power save mode of the load 21.

  Next, with reference to FIG. 14, the flow of the power saving operation according to the present embodiment will be described. FIG. 14 is a time chart of the power saving operation when the FAIL signal indicating the OCA signal is transmitted in the information processing apparatus according to the fourth embodiment.

  A graph 801 represents the OCA signal output from the OCA comparator 301. The high portion of the graph 801 represents a high signal, and the low portion represents a low signal. A graph 802 represents a signal output from the delay circuit 306. The high portion of the graph 802 represents a high signal, and the low portion represents a low signal. A graph 803 represents a signal output from the OCA signal circuit. A high portion of the graph 803 represents a high signal, and a low portion represents a low signal. A graph 804 represents a FAIL signal output from the FAIL signal circuit 112. The high portion of the graph 804 represents a high signal, and the low portion represents a low signal. A graph 805 represents a transition to the power save mode. In the portion where the graph 805 is high, power saving is performed at the load 21, and in the portion where the graph 805 is low, power saving is not performed. A graph 806 represents a change in voltage output from the current sense unit 103. A graph 806 represents voltage on the vertical axis. Each of the graphs 801 to 806 represents the passage of time on the horizontal axis.

  A threshold 807 represents an overcurrent determination voltage when the voltage input from the current sensing unit 103 to the OCA comparator 301 is considered constant.

  At timing 811, the voltage output from the current sense unit 103 increases and exceeds the threshold value 807 that is 100% of the rated voltage.

  The OCA comparator 301 detects that the voltage input from the current sense unit 103 has exceeded the overcurrent determination voltage. At timing 812, the signal output from the OCA comparator 301 changes from Low indicating normal to High indicating abnormality. When the signal output from the OCA comparator 301 becomes High, the transistor 305 is turned on, and the threshold value 504 decreases at timing 813.

  When a high signal is input from the OCA comparator 301 to the EXOR circuit 307, a low signal is input from the delay circuit 306 at this timing. Therefore, at timing 814, a signal output from the EXOR circuit 307 is output from low. Change to High. Thereafter, the EXOR circuit 307 outputs a High signal until the timing 817 at which the delay time elapses.

  The NOR circuit 211 of the FAIL signal circuit 112 transitions the output signal from High to Low at timing 815 in response to the transition of the signal input from the EXOR circuit 307 from Low to High.

  Thereafter, at the timing 816 when the delay time has elapsed, the signal output from the delay circuit 306 changes from Low indicating normality to High indicating abnormality. As a result, a High signal is input from both the OCA comparator 301 and the delay circuit 306 to the EXOR circuit 307, so that the signal output from the EXOR circuit 307 changes from High to Low at timing 817.

  The NOR circuit 211 of the FAIL signal circuit 112 transitions the output signal from Low to High at timing 818 in response to the transition of the signal input from the EXOR circuit 307 from High to Low.

  When receiving a pulsed FAIL signal from the FAIL signal circuit 114, the control unit 22 shifts the load 21 to the power save mode at timing 819.

  When the load 21 shifts to the power save mode, the load current flowing to the load 21 decreases, and the voltage input to the OCA comparator 301 decreases at timing 820. At this time, the voltage input to the OCA comparator 301 decreases, but is still above the threshold value 807 that has decreased. Therefore, at this timing, the signal output from the OCA signal circuit 113 does not change from Low indicating normality to High indicating abnormality.

  Thereafter, for example, the CPU process ends in the state of shifting to the power saving mode, and the load is reduced, and the load current flowing to the load 21 is reduced. As a result, at timing 821, the voltage output from the current sense unit 103 further decreases. As a result, the voltage input to the OCA comparator 301 falls below the threshold value 807.

  Therefore, at the timing 822, the OCA signal output from the OCA comparator 301 changes from High indicating abnormality to Low indicating normal. When the Low signal is output from the OCA comparator 301, the transistor 305 is turned off. Therefore, at the timing 823, the threshold value 807 is restored.

  When the Low signal is input from the OCA comparator 301 to the EXOR circuit 307, the High signal is input from the delay circuit 306 at the timing 824. Therefore, the signal output from the EXOR circuit 307 changes from Low to High. . Thereafter, the EXOR circuit 307 outputs a High signal until the timing 827 when the delay time elapses.

  The NOR circuit 211 of the FAIL signal circuit 112 transitions the output signal from High to Low at timing 825 in response to the transition of the signal input from the EXOR circuit 307 from Low to High.

  Thereafter, at a timing 826 when the delay time has elapsed, the signal output from the delay circuit 306 changes from High indicating abnormality to Low indicating abnormality. As a result, a Low signal is input to the EXOR circuit 307 from both the OCA comparator 301 and the delay circuit 306, so that the signal output from the EXOR circuit 307 changes from High to Low at timing 827.

  The NOR circuit 211 of the FAIL signal circuit 112 transitions the output signal from Low to High at timing 828 in response to the transition of the signal input from the EXOR circuit 307 from High to Low.

  When receiving a pulsed FAIL signal input from the FAIL signal circuit 114, the control unit 22 cancels the power save mode of the load 21 at timing 829.

  When the power save mode is canceled, the load 21 returns to normal operation, and the load current increases. Thereby, at timing 830, the voltage output from the current sensing unit 103 increases. However, since the load current is reduced at the timing 821, etc. after the processing by the CPU is finished, the voltage output from the current sense unit 103 does not exceed the threshold value 807 even when the power save mode is canceled, indicating an abnormality. The OCA signal is not output.

  As described above, in the information processing apparatus according to the present embodiment, the voltage output from the current sensing unit is higher than the threshold for determining overcurrent even when there is no PIN space connecting the PSU and the main body. The power save mode can be canceled when the value falls below the low threshold. For this reason, the information processing apparatus according to the present embodiment can cancel the power save mode after the current has been reliably reduced even when there is no PIN space between the PSU and the main body, and thus more appropriate power saving. Can be controlled and the system can be stably operated more appropriately.

(Hardware configuration)
FIG. 15 is a hardware configuration diagram of the information processing apparatus. The information processing apparatus according to each embodiment includes a PSU 1, a CPU 901, a memory 902, an HDD 903, a fan 904, and a PCI card 905.

  The CPU 901, the memory 902, the HDD 903, the fan 904, and the PCI card 905 correspond to an example of the load 21 illustrated in FIG.

  The PSU 1 supplies power to each unit of the CPU 901, the memory 902, the HDD 903, the fan 904, and the PCI card 905. The dotted line in FIG. 15 represents power supply.

  The memory 902, HDD 903, fan 904, and PCI card 905 are connected to the CPU 901 by a bus.

  The functions of the control unit 22 illustrated in FIG. 1 are realized by the CPU 901, the memory 902, the HDD 903, and the like. For example, the HDD 903 stores various programs such as a program for realizing the function of the control unit 22. The CPU 901 reads various programs stored in the HDD 903 and develops them as a process for realizing functions such as the control unit 22 on the memory 902.

1 PSU
2 Main body 3 Commercial power supply 21 Load 22 Control unit 101 AC / DC
102 DC / DC
DESCRIPTION OF SYMBOLS 103 Current sense part 104 Diode 105 Amplifier 106 Reference voltage part 107 Resistance 108 Capacitor 109 Amplifier 110 Reference voltage part 111 Power supply balance circuit 112 FAIL signal circuit 113 OCA signal circuit 301 OCA comparator 302 OCA reference voltage part

In one aspect of the information processing apparatus and the information processing apparatus control method disclosed in the present application, the power supply unit supplies power to the load in the own apparatus. The output voltage adjustment unit reduces the voltage supplied from the power supply unit when the current supplied by the power supply unit exceeds a first predetermined value. Overcurrent notification unit exceeds a voltage of a predetermined partial pressure of the voltage supplied from the power supply to a load within the device itself corresponds to a second predetermined value smaller than the first predetermined value, the power It is determined that the current supplied from the supply unit to the load has exceeded the second predetermined value and notification of overcurrent is started, and the voltage supplied from the power supply unit to the load corresponds to the second predetermined value When the voltage is equal to or lower than the predetermined voltage, it is determined that the current supplied from the power supply unit to the load is equal to or lower than a third predetermined value smaller than the second predetermined value, and the overcurrent notification is stopped . Controller receives the notification by the overcurrent notification unit, and reduce the load, the notification from the overcurrent notification unit releases the reduction of the load to stop.

Claims (7)

A power supply unit for supplying power to a load in the device;
An output voltage adjusting unit that reduces a voltage supplied from the power supply unit when a current supplied by the power supply unit exceeds a first predetermined value;
An overcurrent notification unit for notifying an overcurrent when a current supplied to the load by the power supply unit exceeds a second predetermined value smaller than the first predetermined value;
An information processing apparatus comprising: a control unit that receives the overcurrent notification from the overcurrent notification unit and reduces the load.   The overcurrent notification unit supplies the load to the load by the power supply unit by comparing a voltage supplied from the power supply unit to the load with a voltage corresponding to the second predetermined value using a comparator. 2. The information processing apparatus according to claim 1, wherein a determination is made as to whether or not a current to be exceeded has exceeded the second predetermined value. The overcurrent notification unit stops the overcurrent notification when the current supplied from the power supply unit to the load is equal to or less than a second predetermined value,
The information processing apparatus according to claim 1, wherein the control unit cancels the reduction of the load when a predetermined period elapses after the notification from the overcurrent notification unit is stopped. The overcurrent notification unit starts notification of an overcurrent when the current supplied from the power supply unit to the load exceeds the second predetermined value, and is supplied from the power supply unit to the load in the device itself. When the current that is less than the third predetermined value smaller than the second predetermined value, the overcurrent notification is stopped,
The information processing apparatus according to claim 1, wherein the control unit cancels the reduction of the load when the notification from the overcurrent notification unit stops. An error notification unit for notifying the control unit of other errors using an error notification signal;
The overcurrent notification unit transmits an overcurrent notification to the control unit using the error notification signal,
The control unit determines whether the received error notification signal is an overcurrent notification from the overcurrent notification unit, and reduces the load when the error notification signal is an overcurrent notification. The information processing apparatus according to claim 1.   The control unit determines whether or not the received error notification signal is an overcurrent notification from the overcurrent notification unit based on a period during which the error notification signal is received. The information processing apparatus according to claim 5. An information processing apparatus control method for an information processing apparatus having a power supply unit and a load control circuit,
Let the power supply unit supply power to the load in its own device,
When the current supplied by the power supply unit exceeds a first predetermined value, the voltage supplied to the power supply unit is decreased,
When the current supplied by the power supply unit exceeds a second predetermined value smaller than the first predetermined value, the power supply unit is notified of an overcurrent to the load control circuit,
When the load control circuit receives notification of an overcurrent from the power supply unit, the load control circuit causes the load to be reduced.

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