JP2008226065A - Power supply control device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a power supply control device, capable of preventing a system from going down at the occurrence of a failure in a power source on a mother board by performing switching to a spare power source before the power source on the mother board goes down. <P>SOLUTION: The device comprises voltage sensors 400 and 401 for detecting output voltages generated in onboard power sources 300 and 301 on the mother board. A control microcomputer 100 monitors the onboard power sources 300 and 301, and switches, when abnormality is detected, the power supply source from the onboard power source for which the abnormality is detected to a spare power source 202 disposed on the mother board. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a power supply control device, and more particularly to a power supply control device in a system having a plurality of on-board power supplies on a mother board when a spare power supply is provided on the mother board.

  As a conventional example, a common standby power source is provided outside each package having an on-board power source, and a power failure detection unit that detects a failure state of the on-board power source is provided in each package. There is a technique in which a power supply switching unit that switches from an on-board power supply to the standby power supply is provided (see Patent Document 1).

Japanese Patent Laid-Open No. 5-197252

  The technique described in Patent Document 1 is not effective when there are a plurality of power supplies on the motherboard. In addition, when switching from the onboard power supply to the standby power supply, it is difficult to prevent a voltage drop from the standby power supply to each chip set.

  An object of the present invention is to provide an information processing apparatus that does not cause a system down by detecting a precursor of a power supply failure even when the power supply on the motherboard fails, and switching to a standby power supply before the power supply on the motherboard goes down. is there.

  In order to achieve the above object, the present invention detects a voltage of an on-board power supply that supplies power to the chipset by the detection means, and when the output voltage of the on-board power supply is outside a predetermined range as a result of the detection. A switch that switches power supply between the onboard power supply and the standby power supply to the chipset, and the control means sets the output voltage of the standby power supply and the standby power supply supplies power to the chipset. A configuration for controlling is adopted.

  According to the present invention, when the power supply on the motherboard fails, power supply control can be performed without bringing down the system.

  FIG. 1 is a block diagram of an information processing system having two on-board power supplies according to an embodiment of the present invention.

  The onboard power supply 300 and the onboard power supply 301 are supplied with power from an external power supply (not shown). The onboard power supply 300 and the onboard power supply 301 generate a voltage to be supplied to the chipset 500 and the chipset 501 from the supplied voltage, and the onboard power supply 300 supplies a voltage to the chipset 500. 301 supplies a voltage to the chip set 501. The on-board power supply 300 is connected to the sensor 400, and the on-board power supply 301 is also connected to the sensor 401.

  The on-board power supply 300 and the on-board power supply 301 are connected to the control microcomputer 100 through a signal line for supplying an on-board power supply Disable signal that can turn off the on-board power supply. Specifically, an on-board power supply disable signal 220 is connected to the on-board power supply 300, and an on-board power supply disable signal 221 is connected to the control microcomputer 100, respectively.

  A switch 600 and a switch 601 are provided between the standby power source 700 and the chip set 500 and the chip set 501, respectively, and the presence / absence of electrical connection between the control microcomputer 100 and each chip set is controlled by opening and closing the switches. Yes. The switch is opened and closed for the switch 600 through the switch signal 210 from the control microcomputer 100, and for the switch 601 through the switch signal 211 from the control microcomputer 100.

  The standby power supply 700 is connected to the sensor 402. The sensor 400, the sensor 401, the sensor 402, and the EEPROM 110 are connected to the control microcomputer 100 by an I2C bus 200, an I2C bus 201, an I2C bus 202, and an I2C bus 230, respectively.

  Further, the standby power source 700, the EEPROM 110, the control microcomputer 100, the sensor 400, the sensor and the sensor 402 are supplied with power from an external power source not shown in FIG.

  The mounting position of the standby power supply 700 on the motherboard 800 is arranged at the center of the motherboard 800 as shown in FIG. Further, as shown in FIG. 3, a dedicated standby power supply 700 plane for preventing a voltage drop is provided in the inner layer of the printed circuit board, and each of the backup power supply plane 700 and the power supply plane 801 and the power supply plane 802 is provided between the power supply plane 801 and the power supply plane 802. A switch 600 and a switch 601 in which planes are connected by through holes are installed.

  FIG. 4 shows a data configuration diagram of the EEPROM 110. The EEPROM 110 stores an upper limit value, a standard value, and a lower limit value of the voltage supplied by the on-board power supply for each chip set.

  Hereinafter, an example of the operation of the present embodiment will be described with reference to the flowchart of FIG.

  In the system illustrated in FIG. 1, when power supply to the control microcomputer 100 is started from an external power source (not shown in FIG. 1) (step 900), the control microcomputer 100 displays the data table and chipset 1 shown in FIG. Of the chipset 1, the lower limit 123 of the chipset 1, the upper limit 124 of the chipset 2, the reference value 125 of the chipset 2 and the lower limit 126 of the chipset 2 are read from the EEPROM 110 through the I2C bus 230 ( Step 901).

  When the data table from the EEPROM 110 is read into the control microcomputer 100, the control microcomputer 100 starts polling the sensor 400 and the sensor 401 (step 902), and polls the data table value read from the EEPROM 110. The obtained values of the sensor 400 and the sensor 401 are compared, and it is determined whether or not the value obtained by the sensor is within the threshold value of the data table (step 903). Specifically, (1) the value obtained from the sensor 400 is smaller than the upper limit 121 of the chipset 1 read into the control microcomputer 100 and larger than the lower limit 123 of the chipset 1, or (2 When the value obtained from the sensor 401 is smaller than the upper limit 124 of the chipset 2 read into the control microcomputer 100 and larger than the lower limit 126 of the chipset 2 (step 903: Yes), the control microcomputer 100 Polls the sensor 400 and the sensor 401 again through the I2C bus 200 (step 903: No).

  In step 903, when the value obtained from the sensor 400 is larger than the upper limit 121 of the chipset 1 or smaller than the lower limit 121 of the chipset 1 (step 903: No), the control microcomputer 100 When a value larger than the upper limit 121 of the chipset 1 is obtained or a value smaller than the lower limit 124 of the chipset 1 is obtained, the voltage of the reference value 122 of the chipset 1 is output from the standby power supply 700. The standby power supply 700 is set through the I2C bus 202 (step 904).

  In step 903, when the value obtained from the sensor 401 is larger than the upper limit 124 of the chipset 2 or smaller than the lower limit 126 of the chipset 2 (step 903: No), the control is performed. When the microcomputer 100 obtains a value larger than the upper limit 124 of the chip set 2 or obtains a value smaller than the lower limit 126 of the chip set 2, the voltage of the reference value 125 of the chip set 2 is output from the standby power supply 700. Thus, the standby power supply 700 is set through the I2C bus 202 (step 904).

  In step 904, after setting the reference voltage to be output to the standby power supply 700, the control microcomputer 100 starts polling the sensor 402 through the I2C bus 201 (step 905).

  In step 905, as a result of polling the voltage of the standby power source 700, it is determined whether or not a voltage within the threshold is set in the standby power source (step 906). Specifically, (1) the reference value 122 of the chip set 1 is set for the standby power source 700, and the value obtained by polling the sensor 402 is smaller than the upper limit 121 of the chip set 1, and the chip It is determined whether or not the value is larger than the lower limit 123 of set 1. Or (2) a value obtained by setting the reference value 125 of the chipset 2 for the standby power supply 700 and polling the sensor 402 is smaller than the upper limit 124 of the chipset 2 and the lower limit of the chipset 2 It is determined whether or not the value is greater than 126.

  In step 906, when a voltage within a predetermined threshold is set in the standby power supply (step 906: Yes), the control microcomputer 100 switches the switch 600 when the chipset reference value 1 is set in the standby power supply 700. When the chip set reference value 2 is set in the standby power source 700, the switch 601 is turned on (step 907). Thereafter, the control microcomputer 100 outputs the on-board power source disable signal 220 when the switch 600 is turned on, and outputs the on-board power source disable signal 221 when the switch 601 is turned on (step 908). Thereafter, the control microcomputer 100 notifies the abnormality notification of the on-board power supply by the abnormality notification signal 240 (step 909).

  In step 906, when the voltage within the predetermined threshold is not set in the standby power supply (step 906: No), the control microcomputer 100 notifies the standby power supply abnormality notification by the abnormality notification signal 240 (step 910), and then continues. Then, the abnormality notification signal 240 is notified of the abnormality notification of the on-board power supply (step 909).

It is a block diagram of the information processing system which has two on-board power supplies which are one Embodiment of this invention. It is the mounting layout figure on the motherboard in one Embodiment of this invention. It is a mother board sectional view in one embodiment of the present invention. FIG. 3 is a detailed view of an EEPROM according to an embodiment of the present invention. It is a flowchart which shows an example of an effect | action of the information processing system which is one Embodiment of this invention.

Explanation of symbols

  100: Control microcomputer, 110: EEPROM, 200: I2C bus 1, 201: I2C bus 2, 202: I2C bus 3, 210: Switch signal 1, 211: Switch signal 2, 220: On-board power supply disable signal 1, 221: On-board power source disable signal 2, 300: On-board power source 1, 301: On-board power source 2, 400: Sensor 1, 401: Sensor 2, 402: Sensor 3, 500: Chip set 1, 501: Chip set 2, 600: Switch 1, 601: Switch 2, 700: Standby power, 800: Motherboard, 801: Power plane 1, 802: Power plane 2, 803: Standby power plane

Claims (1)

In the power supply control device that controls the power supply to the chipset arranged on the motherboard,
An on-board power supply for supplying power to the chipset;
Detection means for detecting the voltage of the on-board power supply;
As a result of detection by the detection means, when the output voltage of the on-board power supply is outside a predetermined range, a standby power supply that supplies power to the chipset;
A switch for switching power supply to the chipset between the on-board power supply and the standby power supply;
And a control means for setting an output voltage of the standby power supply and performing switching control of the switch.

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