JP6558271B2 - Power supply control apparatus and information processing apparatus - Google Patents

Description

  The present invention relates to a power supply control device, an information processing device, and a power supply control method.

  In a large-scale circuit such as a controller module (CM) board mounted on a storage device capable of configuring RAID (Redundant Arrays of Inexpensive Disks), a plurality of devices operating with the same power supply voltage are often used. When supplying power to a plurality of devices operating at the same power supply voltage, a configuration in which a plurality of devices are connected to one power supply circuit is often employed. Examples of the power circuit include a DC (Direct Current) / DC converter.

  Here, when power is supplied from the power supply circuit to the device, a voltage drop occurs due to the pattern impedance in the surface pattern connecting the power supply circuit and the device. A difference in voltage drop may occur due to a difference in path length from the power supply circuit to the device, and the voltage supplied to each device may be different. For example, a difference in voltage drop occurs between a device closest to the power supply circuit and a device farthest from the conditions such as pattern impedance. In this case, when the difference in voltage drop occurs, the nearest device can be supplied with a voltage that satisfies the guaranteed operating voltage, but the farthest device can only be supplied with a voltage that is less than the guaranteed operating voltage. There is.

  The following methods have been proposed as a method for suppressing such a voltage drop difference and performing stable power supply from the power supply circuit to the load device.

  As one method, the surface pattern from the power supply circuit to the device is formed in the same length in each path, and the devices are arranged symmetrically, thereby reducing the difference in pattern impedance and aligning the voltage drop values. There is a way. By using this method, the input voltage to each device can be made substantially the same, and a relatively stable voltage supply can be achieved by tuning the power supply output side.

  As another method, there is a method using remote sensing which is a technique for correcting a voltage drop generated from the power supply output terminal to the load terminal. For example, the voltage at the power input pin of the device is measured and fed back to the power supply circuit to recognize the voltage drop and increase the output voltage to correct the voltage drop.

  In addition, there is a conventional technique in which the power supply voltage of each device is monitored, and when the power supply voltage of a certain device falls below the lower limit value, the power supply voltage is controlled to keep the voltage above the lower limit value. Further, there is a conventional technique in which the minimum voltage among the power supply voltages of each device is supplied to the power supply as a feedback voltage, and the output of the power supply voltage is controlled so that the feedback voltage becomes a target voltage.

Japanese Patent Laid-Open No. 2003-295979 JP 2006-174658 A

  However, in recent years, the arrangement and wiring of devices tend to increase in density. In particular, since high-speed wiring and the like have a large influence on signal quality due to line length and routing, their configuration is regarded as important, and pattern formation of power supply paths and device arrangement are often limited. For this reason, it is difficult to form the surface pattern from the power supply circuit to the device with the same length in each path, and to arrange the devices symmetrically. Also, if the power consumption of the load device is different, the voltage drop generated in the path will vary, the surface pattern from the power supply circuit to the device will be formed with the same length in each path, and the devices will be placed symmetrically. However, it is difficult to make the input voltage to each device almost the same.

  In addition, when remote sensing is used in a configuration in which power is supplied from the same power supply circuit to multiple devices, a voltage based on the voltage drop of the device that is the target of remote sensing is generated. There is a risk of applying an unexpected voltage.

  In addition, even when using the conventional technology that maintains the voltage above the lower limit by controlling the power supply voltage when the power supply voltage falls below the lower limit value, there is a risk of overvoltage in a device with a small voltage drop. It is difficult to adjust to an appropriate value. Also, in the conventional technology that controls the output of the power supply voltage so that the feedback voltage becomes the target voltage, the supply voltage of each device is set to an appropriate value because adjustment is performed based on the power supply voltage of the device with the minimum supply voltage. It is difficult to adjust.

  The disclosed technology has been made in view of the above, and an object thereof is to provide a power supply control device, an information processing device, and a power supply control method that adjust the supply voltage of each device to an appropriate value.

In one aspect of the power supply control device, the information processing apparatus, and the power supply control method disclosed in the present application, the voltage drop calculation unit supplies the output voltage from the power supply and a plurality of operation units that operate with the power supplied from the power supply. Get the input voltage and calculate the maximum voltage drop. Output voltage adjustment unit, said on the basis of the maximum value of the voltage drop calculated by voltage drop calculation unit, an input voltage of the voltage drop to the operating unit is a maximum Ri Do a predetermined voltage or more, and the other operation the output of the power supply to the first tuning input voltage is so that fit in the upper limit of the part, after the adjustment of the output of the power supply is over, the input voltage to the other operating unit to a predetermined value Secondly adjust the power supply output . The voltage drop adjustment unit adjusts a voltage drop between the power source and the operation unit on which the first adjustment and the second adjustment are performed by the output voltage adjustment unit.

  According to one aspect of the power supply control apparatus, the information processing apparatus, and the power supply control method disclosed in the present application, there is an effect that the supply voltage of each device can be adjusted to an appropriate value.

FIG. 1 is a hardware configuration diagram of the storage apparatus according to the first embodiment. FIG. 2 is a schematic diagram of a hardware configuration and a power supply system in the Controller Module. FIG. 3 is a block diagram showing details of the power supply control device. FIG. 4 is a block diagram illustrating details of the monitoring control unit. FIG. 5 is a schematic circuit diagram of the feedback voltage adjusting mechanism and the DC / DC converter. FIG. 6 is a flowchart of control of the input voltage to each device by the power supply control apparatus according to the first embodiment. FIG. 7 is a flowchart of control of the input voltage to each device by the power supply control device according to the second embodiment.

  Hereinafter, embodiments of a power control device, an information processing device, and a power control method disclosed in the present application will be described in detail with reference to the drawings. The power control device, the information processing device, and the power control method disclosed in the present application are not limited by the following embodiments.

  FIG. 1 is a hardware configuration diagram of the storage apparatus according to the first embodiment. In FIG. 1, the storage apparatus 1 is connected to a server 2 as an example.

  The storage device 1 includes an FRT (Front End Router) 11, CMs (Controller Module) 121 to 124, and storage medium storage devices 131 to 132. In this embodiment, the storage apparatus 1 has a plurality of FRTs 11. In addition, the storage device 1 includes a plurality of storage medium storage devices 131 and 132 corresponding to the CMs 121 to 124.

  The FRT 11 is a PCIe (Peripheral Component Interconnect express) switch. Each FRT 11 is connected to the server 2. Each FRT 11 is connected to each of CMs 121 to 124. The FRT 11 receives a read command and a write command from the server 2. Then, the FRT 11 determines the destination of the received command and outputs it to the CMs 121 to 124 that are the destination. Further, the FRT 11 acquires data from the CMs 121 to 124 as a response to the read command or the like. Then, the FRT 11 transmits the acquired data to the server 2.

  In FIG. 1, CMs 121 to 125 are duplexed. Specifically, CM 121 and CM 122 form a pair, and CM 123 and CM 124 form a pair, and each realizes a duplex configuration. The CMs 121 to 124 all have the same function. Therefore, in the following, when the CMs 121 to 124 are not distinguished from each other, they are referred to as “CM 120”.

  Each CM 120 is connected to a plurality of FRTs 11. The CMs 121 and 122 are connected to a plurality of storage medium storage devices 131. The CMs 123 and 124 are connected to a plurality of storage medium storage devices 132. For communication between the CM 120 and the FRT 111, high-speed serial communication such as PCIe is used.

  The CM 120 is equipped with a CPU (Central Processing Unit) and the like. The CM 120 executes an I / O (Input / Output) process for a storage medium such as a hard disk installed in the storage medium storage devices 131 and 132. For example, the CM 120 receives a read command and a write command from the server 2 via the FRT 11. In the case of a read command, the CM 120 accesses the storage medium storage device 131 or 132 that mounts the storage medium storing the specified data, and reads the specified data from the storage medium. Then, the CM 120 transmits the read data to the server 2 via the FRT 11. Further, in the case of a write command, the CM 120 specifies a storage medium that is a write destination of designated data. Then, the CM 120 accesses the storage medium storage device 131 or 132 on which the specified storage medium is mounted, and stores the data in the specified storage medium.

  The storage medium storage devices 131 and 132 each include a plurality of storage media such as hard disks and SSDs (Solid State Drives). Data transmitted from the CM 120 is stored in each storage medium mounted on the storage medium 131.

  FIG. 2 is a schematic diagram of a hardware configuration and a power supply system in the Controller Module. However, FIG. 2 shows a power supply source and a power supply destination, and a power supply control device and the like are omitted.

  As illustrated in FIG. 2, the CM 120 includes a CPU 221, a SAS (Serial Attached Small Computer System Interface) controller 222, a PCIe switch 223, PCIe connectors 231 to 233, and SAS connectors 234 to 236. Further, the CM 120 includes an AC (Alternating Current) / DC converter 201 and DC / DC converters 211 to 218. The lines connecting the components shown in FIG. 2 indicate power supply paths. Here, the device mounted on the CM 120 illustrated in FIG. 2 is an example, and another device may be mounted.

  The CPU 221 executes I / O processing. Further, the CPU 221 instructs the SAS controller 222 to read out or write the RAID configuration or data in accordance with the received command. Further, the CPU 221 communicates with other CMs 120 via the PCIe connectors 231 to 233 according to the received command.

  The SAS controller 222 communicates with the storage medium storage device 131 or 132 via the SAS connectors 234 to 236. The SAS controller 222 configures a RAID using a plurality of storage media stored in the storage medium storage device 131 or 132. Further, the SAS controller 222 reads and writes data to and from a plurality of storage media stored in the storage medium storage device 131 or 132 in accordance with an instruction from the CPU 221.

  The PCIe switch 223 selects the PCIe connectors 231 to 233 designated by the instruction and switches the connection in accordance with an instruction from the CPU 221.

  The PCIe connectors 231 to 233 are connected with cables for communicating with other CMs 120. The SAS connectors 234 to 236 are connected to cables for communicating with the storage medium storage device 131.

  Next, power supply to the CPU 221, the SAS controller 222, the PCIe 223, the PCIe connectors 231 to 233, and the SAS connectors 234 to 236 will be described.

  The AC / DC converter 201 is connected to the commercial power source 3. The AC / DC converter 201 is connected to the DC / DC converters 211 to 218.

  The AC / DC converter 201 receives supply of AC electricity from the commercial power source 3. The AC / DC converter 201 converts the supplied AC electricity into DC and adjusts the voltage. For example, the AC / DC converter 201 converts input DC electricity into 12V AC electricity. Thereafter, the AC / DC converter 201 supplies alternating-current electricity whose voltage is adjusted to the DC / DC converters 211 to 218.

  DC / DC converters 211 to 218 are connected to AC / DC converter 201. The DC / DC converters 211 to 213 are connected to the CPU 221. The DC / DC converters 214 and 215 are connected to the SAS controller 222. The DC / DC converters 216 and 217 are connected to the PCIe switch 223. Further, the DC / DC converter 218 is connected to the PCIe connectors 231 to 233 and the SAS connectors 234 to 236. DC / DC converters 211 to 218 receive power supply from AC / DC converter 201. Then, the DC / DC converters 211 to 218 adjust the voltage to the drive voltage of each connected device and supply power to the connected device.

  Specifically, the DC / DC converters 211 to 213 receive a 12 V AC electricity supply from the AC / DC converter 201. Then, the DC / DC converters 211 to 213 convert the supplied 12 V AC electricity to 1.0 V and supply it to the CPU 221.

  The DC / DC converters 214 and 215 receive a 12V AC electricity supply from the AC / DC converter 201. The DC / DC converter 214 converts the supplied 12-V AC electricity to 1.0 V and supplies the converted voltage to the SAS controller 222. The DC / DC converter 215 converts the supplied 12-V AC electricity to 1.5 V and supplies it to the SAS controller 222.

  The DC / DC converters 216 and 217 receive 12V AC electricity from the AC / DC converter 201. Then, the DC / DC converter 216 converts the supplied 12-V AC electricity to 1.8 V and supplies it to the PCIe switch 223. The DC / DC converter 217 converts the supplied 12-V AC electricity to 0.9 V and supplies it to the PCIe switch 223.

  The DC / DC converter 218 receives a 12 V AC electricity supply from the AC / DC converter 201. Then, the DC / DC converter 218 converts the supplied 12V AC electricity to 3.3V and supplies it to the PCIe connectors 231 to 233 and the SAS connectors 234 to 236. As described above, the DC / DC converter 218 supplies power to a plurality of devices. The DC / DC converter 218 corresponds to an example of “power supply”. The PCIe connectors 231 to 233 and the SAS connectors 234 to 236 that receive power supply from the DC / DC converter 218 are examples of the “operation unit”.

  Next, the power supply from the DC / DC converter 218 will be described in detail with reference to FIG. Here, FIG. 3 is a block diagram showing details of the power supply control device.

  Here, the DC / DC converter 218 is actually connected to the PCIe connectors 231 to 233 and the SAS connectors 234 to 236 as shown in FIG. 2, but here the DC / DC converter 218 is connected to the three devices 301 to 302. It will be described as being connected. That is, the devices 301 to 302 correspond to an example of “operation unit”.

  However, even when the number of devices connected to the DC / DC converter 218 is different, the same function can be realized by adopting the same configuration. In this embodiment, a plurality of devices are connected only to the DC / DC converter 218, but the CM 120 may include a DC / DC converter to which a plurality of other devices are connected. In that case, a power system from a DC / DC converter to which a plurality of devices are connected to a power supply target device has the same configuration as the power system from the DC / DC converter 218 to the devices 301 to 302.

  Load adjusting units 311 to 313 are arranged on the power supply path connecting the DC / DC converter 218 and each of the devices 301 to 303. A feedback voltage adjustment mechanism 320 is disposed on the electrical feedback path output from the DC / DC converter 218. Further, a monitoring control unit 400 that monitors the voltage and adjusts the feedback voltage and controls the load adjustment units 311 to 313 is arranged. The load adjustment units 311 to 313, the feedback voltage adjustment mechanism 320, and the monitoring control unit 400 are power supply control devices 240 that control the output voltage of the DC / DC converter 218.

  The DC / DC converter 218 converts the electricity provided from the AC / DC converter 201 into alternating current, and further adjusts and outputs the voltage. Electricity output from the DC / DC converter 218 is supplied to the load adjusting units 311 to 313. Electricity output from the DC / DC converter 218 is fed back to the DC / DC converter 218 via the feedback voltage adjustment mechanism 320.

  The load adjustment unit 311 is a mechanism for controlling a voltage drop arranged on the power supply path connecting the DC / DC converter 218 and the device 301. The load adjustment unit 311 controls the voltage drop by changing the load impedance by adjusting the pattern impedance or the load current, and lowers the input voltage of the device 301. Here, the load adjustment unit 311 may have another configuration as long as the voltage drop can be controlled.

  For example, the load adjustment unit 311 increases the voltage drop in response to an instruction from the monitoring control unit 400. The load adjustment unit 311 has, for example, a predetermined voltage drop amount for each step. When receiving an instruction from the monitoring control unit 400, the load adjustment unit 311 decreases the input voltage of the device 301 by one step.

  The load adjustment units 312 and 313 also have the same mechanism as the load adjustment unit 311. Then, the load adjustment units 312 and 313 receive the instruction from the monitoring control unit 400 and reduce the input voltages of the devices 302 and 303, respectively.

  The monitoring control unit 400 monitors the output voltage of the DC / DC converter 218 and the input voltages of the devices 301 to 303, and adjusts the input voltages of the devices 301 to 303. Therefore, the monitoring control unit 400 will be described with reference to FIG. FIG. 4 is a block diagram illustrating details of the monitoring control unit.

  As shown in FIG. 4, the monitoring control unit 400 includes an output voltage monitoring unit 401, input voltage monitoring units 411 to 413, a voltage drop difference comparison unit 421, an output voltage adjustment unit 422, a storage unit 423, and an operation guarantee value comparison unit 424. And input voltage adjustment units 431 to 433. The voltage drop difference comparison unit 421, the output voltage adjustment unit 422, and the operation guarantee value comparison unit 424 are realized by a CPU, an FPGA (Field Programmable Gate Array), or the like. The storage unit 423 is realized by a memory or the like.

  The storage unit 423 is a storage medium such as a memory. The storage unit 423 holds the operation guarantee appropriate values of the devices 301 to 303. Here, the operation guarantee appropriate value is the most appropriate voltage value for each of the devices 301 to 303 to operate.

  The output voltage monitoring unit 401 measures the electrical voltage output from the DC / DC converter 218. Hereinafter, the electric voltage output from the DC / DC converter 218 is referred to as “power supply output voltage”. Then, the output voltage monitoring unit 401 outputs the measured voltage value of the power supply output voltage to the voltage drop difference comparison unit 421.

  The input voltage monitoring unit 411 measures the voltage at the input terminal of the device 301 and acquires the input voltage of the device 301. Then, the input voltage monitoring unit 411 outputs the acquired voltage value of the input voltage of the device 301 to the voltage drop difference comparison unit 421 and the operation guarantee value comparison unit 424.

  The input voltage monitoring unit 412 measures the voltage at the input terminal of the device 302 and acquires the input voltage of the device 302. Then, the input voltage monitoring unit 412 outputs the acquired voltage value of the input voltage of the device 302 to the voltage drop difference comparison unit 421 and the operation guarantee value comparison unit 424.

  The input voltage monitoring unit 413 measures the voltage at the input terminal of the device 301 and acquires the input voltage of the device 303. Then, the input voltage monitoring unit 413 outputs the acquired voltage value of the input voltage of the device 303 to the voltage drop difference comparison unit 421 and the guaranteed operation value comparison unit 424.

  The voltage drop difference comparison unit 421 receives an input of the voltage value of the power supply output voltage from the output voltage monitoring unit 401. Further, the voltage drop difference comparison unit 421 receives input of voltage values of the input voltages of the devices 301 to 303 from the input voltage monitoring units 411 to 413, respectively. Then, the voltage drop difference comparison unit 421 calculates a difference between the power supply output voltage and each of the input voltages of the devices 301 to 303.

  Next, the voltage drop difference comparison unit 421 specifies the largest difference among the calculated differences. Furthermore, the voltage drop difference comparison unit 421 identifies the maximum difference device that is the device having the largest difference from the devices 301 to 303. Here, a case where the maximum difference device is the device 303 will be described.

  Next, the voltage drop difference comparison unit 421 acquires the operation guarantee appropriate value of the device 303 that is the maximum difference device from the storage unit 423. Then, the voltage drop difference comparison unit 421 determines whether or not the input voltage of the device 303 which is the maximum difference device is an operation guarantee appropriate value of the device 303. When the input voltage of the device 303 is an operation guarantee appropriate value, the voltage drop difference comparison unit 421 ends the adjustment of the input voltage of the devices 301 to 303.

  On the other hand, when the input voltage of the device 303 is equal to or lower than the operation guarantee appropriate value, the voltage drop difference comparison unit 421 instructs the output voltage adjustment unit 422 to increase the power supply output voltage. Further, the voltage drop difference comparison unit 421 transmits information on the device 303 that is the maximum difference device and a notification of execution of the power supply output voltage increase to the operation guarantee value comparison unit 424.

  Thereafter, upon receiving notification of the end of the adjustment of the input voltage from the voltage drop difference comparison unit 421, the voltage drop difference comparison unit 421 acquires again the voltage value of the input voltage of the device 303 that is the maximum difference device. Then, the voltage drop difference comparison unit 421 determines whether or not the input voltage of the device 303 which is the maximum difference device is an operation guarantee appropriate value of the device 303. When the input voltage of the device 303 is equal to or lower than the operation guarantee appropriate value, the voltage drop difference comparison unit 421 repeats the instruction to the output voltage adjustment unit 422 and the notification to the operation guarantee value comparison unit 424 of the rise of the power supply output voltage.

  When the input voltage of the device 303 becomes an operation guarantee appropriate value, the voltage drop difference comparison unit 421 ends the adjustment of the input voltage of the devices 301 to 303. The voltage drop difference comparison unit 421 corresponds to an example of a “voltage drop calculation unit”.

  The output voltage adjustment unit 422 receives a feedback current that is an electric current fed back to the DC / DC converter 218. Here, the output voltage adjustment unit 422 has a predetermined value as a value for increasing the power supply output voltage for each step.

  The output voltage adjustment unit 422 receives an instruction to increase the power supply output voltage from the voltage drop difference comparison unit 421. When the resistor 321 receives an instruction to increase the power supply output voltage, the feedback current is used to increase the current power supply output voltage by one step, that is, the power supply output voltage is increased by a predetermined value. The control amount is calculated as follows. Thereafter, the output voltage adjustment unit 422 adjusts the feedback voltage adjustment mechanism 320 with the calculated control amount. The output voltage adjustment unit 422 repeatedly increases the power supply output voltage step by step in accordance with an instruction from the voltage drop difference comparison unit 421 to adjust the power supply output voltage to an operation guarantee appropriate value. This operation guarantee appropriate value is an example of the “predetermined voltage”.

  For example, as will be described later, when the feedback voltage is changed by changing the resistance value of the resistor included in the feedback voltage adjustment mechanism 320, the following processing is performed. The output voltage adjustment unit 422 calculates a resistance value for increasing the power supply output voltage by a predetermined value. Then, the output voltage adjustment unit 422 changes the resistance value of the resistor included in the feedback voltage adjustment mechanism 320 so that the calculated resistance value is obtained.

  The guaranteed operation value comparison unit 424 receives input of the voltage value of the input voltage of each device from the input voltage monitoring units 411 to 413. Next, the guaranteed operation value comparison unit 424 receives from the voltage drop difference comparison unit 421 information on the device 303 that is the maximum difference device and a notification of execution of an increase in power supply output voltage.

  The guaranteed operation value comparison unit 424 selects one device from devices other than the device 303 that is the maximum difference device among the devices 301 to 303. For example, the guaranteed operation value comparison unit 424 selects the device 301.

  Then, the operation guarantee value comparison unit 424 acquires the operation guarantee appropriate value of the selected device 301 from the storage unit 423. Then, the operation guarantee value comparison unit 424 determines whether or not the input voltage of the selected device 301 is an operation guarantee appropriate value of the device 301.

  When the input voltage of the device 301 exceeds the operation guarantee appropriate value, the operation guarantee value comparison unit 424 instructs the input voltage adjustment unit 431 to increase the voltage drop. The operation guarantee value comparison unit 424 repeats the instruction to increase the voltage drop to the input voltage adjustment unit 431 until the input voltage of the device 301 reaches the operation guarantee appropriate value.

  When the input voltage of the device 301 reaches the operation guarantee appropriate value, the operation guarantee value comparison unit 424 selects a device for which the adjustment of the input voltage is not completed from the devices 301 and 302 other than the device 303 that is the maximum drop device. Select one. In this case, the guaranteed operation value comparison unit 424 selects the device 302. Then, as in the case of the device 301, the operation guarantee value comparison unit 424 instructs the input voltage adjustment unit 432 to increase the voltage drop, and sets the input voltage of the device 302 to an operation guarantee appropriate value.

  Here, the case where three devices 301 to 303 are connected to the DC / DC converter 218 has been described, but more devices may be connected. The operation guarantee value comparison unit 424 sequentially selects devices and repeats the process of adjusting the input voltage of the selected device to the operation guarantee appropriate value for all devices except the maximum drop device. When the adjustment of the input voltage of all devices except the maximum drop device is completed, the operation guarantee value comparison unit 424 notifies the voltage drop difference comparison unit 421 of the completion of the adjustment of the input voltage. The operation guarantee value comparison unit 424 corresponds to an example of a “voltage drop adjustment unit”.

  The input voltage adjustment unit 431 receives an instruction to increase the voltage drop from the operation guarantee value comparison unit 424. Here, the input voltage adjustment unit 431 has a control amount for each step of the load adjustment unit 311 for increasing the voltage drop by a predetermined amount. In response to the instruction to increase the voltage drop, the input voltage adjustment unit 431 controls the load adjustment unit 311 for one step. As a result, the input voltage of the device 301 decreases by a predetermined amount.

  Further, the input voltage adjustment unit 432 receives an instruction to increase the voltage drop from the operation guarantee value comparison unit 424. Here, the input voltage adjustment unit 432 has a control amount for each step of the load adjustment unit 312 for increasing the voltage drop by a predetermined amount. In response to the instruction to increase the voltage drop, the input voltage adjustment unit 432 controls the load adjustment unit 312 for one step. As a result, the input voltage of the device 302 decreases by a predetermined amount.

  In the description here, since the device 303 is the maximum drop device, the adjustment by the input voltage adjustment unit 433 is not performed. However, if the other device 301 or 302 is the maximum drop device, the input voltage adjustment unit 433 adjusts the input voltage of the device 303.

  Feedback voltage adjustment mechanism 320 receives a power supply output voltage that is an output of DC / DC converter 218. Then, feedback voltage adjustment mechanism 320 performs a predetermined process on the input power supply output voltage, and outputs the processed voltage feedback voltage to DC / DC converter 218 as a feedback voltage.

  Further, feedback voltage adjustment mechanism 320 receives control for one step from output voltage adjustment unit 422 for increasing the power supply output voltage by a predetermined value. Feedback voltage adjustment mechanism 320 then outputs to DC / DC converter 218 a feedback voltage that generates a power supply output voltage that is higher than the power supply output voltage generated from the feedback voltage before being controlled by a predetermined value.

  Here, a specific example of adjustment of the output voltage of the DC / DC converter 218 by the feedback voltage adjustment mechanism 320 will be described with reference to FIG. FIG. 5 is a schematic circuit diagram of the feedback voltage adjusting mechanism and the DC / DC converter. In FIG. 5, each of the devices 301 to 303 is simply indicated as “device 300” without being distinguished from each other.

  For example, as illustrated in FIG. 5, the DC / DC converter 218 includes a comparator 501, a reference voltage output unit 502, a PWM (Pulse Width Modulation) controller 503, and FET (Field Effect Transistor) switches 504 and 505. The FET switches 504 and 505 are represented as “FET” in FIG.

  The output voltage of the AC / DC converter 201 is supplied to the FET switch 504. The FET switch 504 is connected to the FET switch 505. The FET switch 505 is connected to the ground. Further, a path connecting the FET switch 504 and the FET switch 505 is connected to the inductor 510. The inductor 510 is represented as “L” in FIG.

  The FET switches 504 and 505 receive switching timing input from the PWM controller 503. When the FET switch 504 is on and the FET switch 505 is off, the voltage of the AC / DC converter 201 is applied to the inductor 501. When the FET switch 504 is off and the FET switch 505 is on, the inductor 501 is connected to the ground. As a result, the device 300 receives a voltage applied according to the switching timing of the FET switches 504 and 505.

  The PWM controller 503 receives an input of the difference between the feedback voltage and the reference voltage from the comparator 501. The PWM controller 503 controls the switching timing of the FET switches 504 and 505 so as to add the input difference to the output voltage. Specifically, when increasing the output voltage, the PWM controller 503 lengthens the ON time of the FET switch 504 and shortens the ON time of the FET switch 505. On the contrary, when the output voltage is decreased, the PWM controller 503 shortens the ON time of the FET switch 504 and lengthens the ON time of the FET switch 505.

  The comparator 501 receives a reference voltage input from the reference voltage output unit 502. Further, the comparator 501 receives an input of a feedback voltage determined by resistance values of resistors 321 and 322 described later. Then, the comparator 501 calculates the difference between the feedback voltage and the reference voltage. Thereafter, the comparator 501 outputs the difference between the calculated feedback voltage and the reference voltage to the PWM controller 503.

  The inductor 510 is connected at the input end to a path connecting the output terminal of the FET switch 504 and the input terminal of the FET switch 505. Further, the output terminal of the inductor 510 is connected to the device 300.

  The inductor 510 repeats the application of the power supply output voltage, which is the voltage output from the DC / DC converter 218, and the connection to the ground, thereby generating AC electricity having a voltage corresponding to the timing of the voltage application and the connection to the ground. Output. The electricity output from the inductor 501 is supplied to the device 300 and is output to the feedback voltage adjustment mechanism 320. The device 300 is driven by electricity input from the inductor 510.

  The feedback voltage adjustment mechanism 320 includes resistors 321 and 322 as shown in FIG. The resistors 321 and 322 are represented by “R” in FIG.

  The resistor 321 is a variable resistor. One end of the resistor 321 is connected to the output end of the inductor 510. The other end of the resistor 321 is connected to one end of the resistor 322. Furthermore, the other end of the resistor 322 is connected to the ground. A connection point between the resistor 321 and the resistor 322 is connected to a resting terminal of the comparator 501. Further, the connection point between the resistor 321 and the resistor 322 is connected to the output voltage adjustment unit 422.

  The resistor 321 receives the input of electricity output from the inductor 510. Then, electricity having a voltage divided by the resistors 321 and 322 with respect to the output voltage of the inductor 510 is input to the comparator 501. That is, the divided voltage by the resistors 321 and 322 with respect to the output voltage of the inductor 510 becomes the feedback voltage.

  In addition, a feedback current that is a current output from the resistor 321 is input to the output voltage adjustment unit 422. After that, the resistor 321 receives control from the output voltage adjustment unit 422 and adjusts the resistance value to increase the current power supply output voltage by one step, that is, the resistance value by which the power supply output voltage increases by a predetermined value. Is done. As a result, the feedback voltage input to the comparator 501 decreases, and the power supply output voltage output from the DC / DC converter 218 increases by a predetermined electric value.

  Here, in this embodiment, the feedback voltage adjustment mechanism 320 having the resistors 321 and 322 is used to change the feedback voltage by changing the resistance value of the resistor 321. However, the configuration of the feedback voltage adjustment mechanism 320 is not limited. Is not limited to this. The feedback voltage adjustment mechanism 320 may have another configuration as long as the feedback voltage can be adjusted to a predetermined value.

  Next, the flow of control of the input voltage to each device by the power supply control device 240 according to the present embodiment will be described with reference to FIG. FIG. 6 is a flowchart of control of the input voltage to each device by the power supply control apparatus according to the first embodiment. Here, a case where the DC / DC converter 218 supplies power to the devices 301 to 303 will be described.

  The output voltage monitoring unit 401 measures a power supply output voltage that is an output voltage of the DC / DC converter 218. Further, the input voltage monitoring units 411 to 413 measure the input voltages of the devices 301 to 303 (step S1). The output voltage monitoring unit 401 outputs the power supply output voltage to the voltage drop difference comparison unit 421. Further, the input voltage monitoring units 411 to 413 output the input voltages of the devices 301 to 303 to the voltage drop difference comparison unit 421 and the operation guarantee value comparison unit 424, respectively.

  The voltage drop difference comparison unit 421 receives the input of the power supply output voltage from the output voltage monitoring unit 401. In addition, the voltage drop difference comparison unit 421 receives input of each input voltage of the devices 301 to 303 from the input voltage monitoring units 411 to 413. Next, the voltage drop difference comparison unit 421 obtains a difference between the power supply output voltage and each of the input voltages of the devices 301 to 303. And the voltage drop difference comparison part 421 compares the voltage difference between the DC / DC converter 218 which is a power supply, and each device 301-303 (step S2).

  Next, the voltage drop difference comparison unit 421 specifies the maximum drop device having the maximum voltage drop from the devices 301 to 303 (step S3).

  Next, the voltage drop difference comparison unit 421 uses the operation guarantee appropriate values of the devices 301 to 303 stored in the storage unit 423 to determine whether or not the input voltage of the maximum drop device is the operation guarantee appropriate value of the maximum drop device. Determine (step S4).

  When the input voltage of the maximum drop device is an operation guarantee appropriate value (step S4: affirmative), the voltage drop difference comparison unit 421 ends the control of the input voltage to each of the devices 301 to 303.

  On the other hand, when the input voltage of the maximum drop device is not the operation guarantee appropriate value (No at Step S4), the voltage drop difference comparison unit 421 instructs the output voltage adjustment unit 422 to increase the power supply output voltage. The output voltage adjustment unit 422 receives an instruction to increase the power supply output voltage from the voltage drop difference comparison unit 421, and controls the feedback voltage adjustment mechanism 320 to adjust the feedback voltage, thereby increasing the power supply voltage by one step. Is increased by a predetermined value (step S5). Then, the voltage drop difference comparison unit 421 transmits the maximum drop device information and the notification of execution of the power supply output voltage increase to the operation guarantee value comparison unit 424.

  The guaranteed operation value comparison unit 424 receives the information about the maximum drop device and the notification of execution of the rise of the power supply output voltage from the voltage drop difference comparison unit 421. Then, the operation comparison target unit 424 selects one device other than the maximum descending device from the devices 301 to 303 (step S6).

  Further, the guaranteed operation value comparison unit 424 receives input of the input voltages of the devices 301 to 303 from the input voltage monitoring units 411 to 413. Then, the operation guarantee value comparison unit 424 uses the operation guarantee appropriate values of the devices 301 to 303 stored in the storage unit 423 to determine whether the input voltage of the selected device is the operation guarantee appropriate value of the selected device. (Step S7).

  When the input voltage of the selected device is not an operation guarantee appropriate value (No at Step S7), the operation guarantee value comparison unit 424 controls the connection to the selected device in the input voltage adjustment units 431 to 433. As a result, the guaranteed operation value comparison unit 424 adjusts the load between the DC / DC converter 218 as the power source and the selected device, and drops the input voltage of the selected device by one step (step S8). Thereafter, the control of the input voltage of each of the devices 301 to 303 returns to step S7.

  On the other hand, if the input voltage of the selected device is an operation guarantee appropriate value (step S7: affirmative), the operation guarantee value comparison unit 424 has completed the adjustment of the input voltage of all devices other than the maximum drop device. It is determined whether or not (step S9).

  When there is a device whose input voltage adjustment has not been completed among devices other than the maximum drop device (No at Step S9), the guaranteed operation value comparison unit 424 returns to Step S6 and newly selects a device. .

  On the other hand, when adjustment of the input voltage of devices other than the maximum drop device is completed (step S9: affirmative), the power supply control device 240 returns to step S4.

  As described above, the power supply control apparatus according to the present embodiment adjusts the power supply output voltage so that the input voltage of the maximum drop device becomes an operation guarantee appropriate value. Furthermore, the power supply control apparatus according to the present embodiment adjusts the load between the power supply and the device so as to control the input voltage of devices other than the maximum drop device to an operation guarantee appropriate value. As a result, when power is supplied to a plurality of devices from one power source, the input voltage of each device can be adjusted with high accuracy, and the supply voltage to each device can be adjusted to an appropriate value. .

  Further, since the input voltage is adjusted for each device, the supply voltage to each device can be made constant even when the power consumption of a plurality of devices that receive power supply from one power source is different. Furthermore, since the device can be freely arranged with respect to the power supply, the power supply circuit can be arranged and wired flexibly, and the artwork becomes easy.

  In addition, the electrical stress on the device can be minimized and the power consumption can be reduced as compared with the technique of simply adjusting the power supply output voltage according to the maximum value of the voltage drop.

  Next, a power supply control apparatus according to the second embodiment will be described. The power supply control device 240 according to the present embodiment is also represented in FIGS. Below, with reference to FIG. 4, the monitoring control part 400 of the power supply control apparatus 240 which concerns on a present Example is demonstrated. In the following description, the description of the functions of the same parts as those in the first embodiment will be omitted.

  The storage unit 423 stores an operation guarantee upper limit value in addition to the operation guarantee appropriate values of the devices 301 to 302.

  The voltage drop difference comparison unit 421 identifies the maximum drop device. Here, the case where the maximum descending device is the device 303 will be described. Then, the voltage drop difference comparison unit 421 determines whether or not the input voltage of the device 303 is an operation guarantee appropriate value.

  When it is not the operation guarantee proper value, the voltage drop difference comparison unit 421 instructs the output voltage adjustment unit 422 to increase the power supply output voltage. In addition, the voltage drop difference comparison unit 421 transmits information on the maximum drop device and a notification of an increase in power supply output voltage to the operation guarantee value comparison unit 424.

  The voltage drop difference comparison unit 421 repeats the instruction to increase the power supply output voltage to the output voltage adjustment unit 422 until the input voltage of the device 303 becomes an operation guarantee appropriate value. When the input voltage of the device 303 reaches the operation guarantee proper value, the voltage drop difference comparison unit 421 notifies the operation guarantee value comparison unit 424 of the information about the maximum drop device and the notification of completion of adjustment of the power supply output voltage. To 424.

  The operation guarantee value comparison unit 424 receives the information about the maximum drop device and the notification of the rise of the power supply output voltage from the voltage drop difference comparison unit 421. Then, the operation guarantee value comparison unit 424 adjusts the input voltages of the devices 301 and 302 other than the device 303 which is the maximum descending device so as to be within the operation guarantee upper limit value.

  Thereafter, the guaranteed operation value comparison unit 424 receives from the voltage drop difference comparison unit 421 information on the maximum drop device and notification of completion of adjustment of the power supply output voltage. In response to the fact that the input voltage of the device 303 has reached the operation guarantee proper value, the operation guarantee value comparison unit 424 adjusts the input voltages of the devices 301 and 302 to the operation guarantee proper value. Here, the operation guarantee upper limit value is an upper limit value of a voltage at which the devices 301 to 303 can operate. The operation guarantee upper limit value is larger than the operation guarantee proper value.

  Next, the flow of control of the input voltage to each device by the power supply control device 240 according to the present embodiment will be described with reference to FIG. FIG. 7 is a flowchart of control of the input voltage to each device by the power supply control device according to the second embodiment. Here, a case where the DC / DC converter 218 supplies power to the devices 301 to 303 will be described.

  The output voltage monitoring unit 401 measures a power supply output voltage that is an output voltage of the DC / DC converter 218. Further, the input voltage monitoring units 411 to 413 measure the input voltages of the devices 301 to 303 (step S11). The output voltage monitoring unit 401 outputs the power supply output voltage to the voltage drop difference comparison unit 421. Further, the input voltage monitoring units 411 to 413 output the input voltages of the devices 301 to 303 to the voltage drop difference comparison unit 421 and the operation guarantee value comparison unit 424, respectively.

  The voltage drop difference comparison unit 421 receives the input of the power supply output voltage from the output voltage monitoring unit 401. In addition, the voltage drop difference comparison unit 421 receives input of each input voltage of the devices 301 to 303 from the input voltage monitoring units 411 to 413. Next, the voltage drop difference comparison unit 421 obtains a difference between the power supply output voltage and each of the input voltages of the devices 301 to 303. And the voltage drop difference comparison part 421 compares the voltage difference between the DC / DC converter 218 which is a power supply, and each device 301-303 (step S12).

  Next, the voltage drop difference comparison unit 421 specifies the maximum drop device having the maximum voltage drop from the devices 301 to 303 (step S13).

  Next, the voltage drop difference comparison unit 421 uses the operation guarantee appropriate values of the devices 301 to 303 stored in the storage unit 423 to determine whether or not the input voltage of the maximum drop device is the operation guarantee appropriate value of the maximum drop device. Determination is made (step S14).

  When the input voltage of the maximum drop device is not the operation guarantee proper value (No at Step S14), the voltage drop difference comparison unit 421 instructs the output voltage adjustment unit 422 to increase the power supply output voltage. The output voltage adjustment unit 422 receives an instruction to increase the power supply output voltage from the voltage drop difference comparison unit 421, and controls the feedback voltage adjustment mechanism 320 to adjust the feedback voltage, thereby increasing the power supply output voltage by one step. The value is increased by a predetermined value (step S15). Then, the voltage drop difference comparison unit 421 transmits the maximum drop device information and the notification of execution of the power supply output voltage increase to the operation guarantee value comparison unit 424.

  The guaranteed operation value comparison unit 424 receives the information about the maximum drop device and the notification of execution of the rise of the power supply output voltage from the voltage drop difference comparison unit 421. Then, the operation comparison target unit 424 selects one device other than the maximum descending device from the devices 301 to 303 (step S16).

  Further, the guaranteed operation value comparison unit 424 receives input of the input voltages of the devices 301 to 303 from the input voltage monitoring units 411 to 413. Then, the operation guarantee value comparison unit 424 uses the operation guarantee upper limit values of the devices 301 to 303 stored in the storage unit 423 to check whether the input voltage of the selected device is within the operation guarantee upper limit value of the selected device. It is determined whether or not (step S17).

  When the input voltage of the selected device is outside the operation guarantee upper limit value (step S17: No), the operation guarantee value comparison unit 424 controls what is connected to the selected device in the input voltage adjustment units 431 to 433. As a result, the guaranteed operation value comparison unit 424 adjusts the load between the DC / DC converter 218 as the power source and the selected device, and drops the input voltage of the selected device by one step (step S18). Thereafter, the control of the input voltage of each of the devices 301 to 303 returns to step S17.

  On the other hand, when the input voltage of the selected device is within the operation guarantee upper limit value (step S17: affirmative), the operation guarantee value comparison unit 424 has completed the adjustment of the input voltages of all devices other than the maximum drop device. It is determined whether or not (step S19).

  When there is a device whose input voltage adjustment has not been completed among devices other than the maximum drop device (No at Step S19), the guaranteed operation value comparison unit 424 returns to Step S16 and newly selects a device. .

  On the other hand, when the adjustment of the input voltage of the devices other than the maximum drop device is completed (step S19: Yes), the power supply control device 240 returns to step S14.

  On the other hand, when the input voltage of the maximum drop device is an operation guarantee appropriate value (step S14: Yes), the voltage drop difference comparison unit 421 notifies the operation guarantee value comparison unit 424 that the adjustment of the input voltage of the maximum drop device is completed. The guaranteed operation value comparison unit 424 receives notification of the completion of adjustment of the input voltage of the maximum drop device from the voltage drop difference comparison unit 421 and selects one device other than the maximum drop device from the devices 301 to 303 (step S20).

  Further, the guaranteed operation value comparison unit 424 receives input of the input voltages of the devices 301 to 303 from the input voltage monitoring units 411 to 413. Then, the operation guarantee value comparison unit 424 uses the operation guarantee appropriate values of the devices 301 to 303 stored in the storage unit 423 to determine whether the input voltage of the selected device is the operation guarantee appropriate value. Is determined (step S21).

  When the input voltage of the selected device is not an operation guarantee appropriate value (No at Step S21), the operation guarantee value comparison unit 424 controls the one connected to the selected device in the input voltage adjustment units 431 to 433. As a result, the guaranteed operation value comparison unit 424 adjusts the load between the DC / DC converter 218 as the power source and the selected device, and drops the input voltage of the selected device by one step (step S22). Thereafter, the control of the input voltage of each of the devices 301 to 303 returns to step S21.

  On the other hand, when the input voltage of the selected device is an operation guarantee appropriate value (step S21: affirmative), the operation guarantee value comparison unit 424 has completed the adjustment of the input voltage of all devices other than the maximum drop device. It is determined whether or not (step S23).

  When there is a device whose input voltage adjustment has not been completed among devices other than the maximum drop device (No at Step S23), the guaranteed operation value comparison unit 424 returns to Step S20 and newly selects a device. .

  On the other hand, when the adjustment of the input voltage of devices other than the maximum drop device is completed (step S23: Yes), the power supply control device 240 ends the control of the input voltage to each of the devices 301 to 303.

  As described above, in the first embodiment, the operation guarantee value comparison unit 424 adjusts the input voltages of the devices 301 and 302 other than the device 303 that is the maximum drop device to the operation guarantee appropriate values in accordance with the rise of the power supply output voltage. However, other procedures can be used for the adjustment procedure.

  Further, when the influence of the voltage rise on the device is small, the power supply control device 240 may adjust the input voltage in the following procedure. For example, the voltage drop difference comparison unit 421 adjusts the input voltage of the device 303 that is the maximum drop device to an appropriate operation value by adjusting the power supply output voltage. Thereafter, the operation guarantee value comparison unit 424 adjusts the input voltages of the devices 301 and 302 other than the device 303 to an operation guarantee appropriate value. In other words, if the input voltage of each device finally reaches an appropriate value that guarantees operation, the procedure for controlling the input voltage can be selected according to the operation of the information processing apparatus equipped with the power supply control device. .

  As described above, the power supply control apparatus according to the present embodiment has a configuration in which power is supplied from a single power supply to a plurality of devices even when the input voltage control procedure is different from that of the first embodiment. The supply voltage to each device can be adjusted to an appropriate value.

1 Storage device 2 Server 3 Commercial power supply 11 FRT
121-124 CM
131, 132 Storage medium storage device 201 AC / DC converter 211-218 DC / DC converter 221 CPU
222 SAS controller 223 PCIe switch 231 to 233 PCIe connector 234 to 236 SAS connector 240 power supply control device 301 to 303 device 311 to 313 load adjustment unit 320 feedback voltage adjustment mechanism 321 and 322 resistance 400 monitoring control unit 401 output voltage monitoring unit 411 to 413 Input voltage monitoring unit 421 Voltage drop difference comparison unit 422 Output voltage adjustment unit 423 Storage unit 424 Guaranteed operation value comparison unit 431-433 Input voltage adjustment unit 501 Comparator 502 Reference voltage output unit 503 PMW controller 504, 505 FET switch 510 Inductor

Claims (4)

A voltage drop calculation unit that obtains an output voltage from a power source and input voltages to a plurality of operation units that operate with power supplied from the power source, and calculates a maximum value of the voltage drop;
Based on the maximum value of the voltage drop calculated by the voltage drop calculation unit, wherein the input voltage of the voltage drop to the operation portion is the largest Ri Do a predetermined voltage, and an upper limit input voltage to other operating portion the output of the power supply so that fit in the value and the first adjustment, after the first adjustment is completed, to output a second adjustment of the power supply so that the input voltage to the other operating unit to a predetermined value An output voltage adjustment unit;
A voltage drop adjusting unit that adjusts a voltage drop between the power source and the operating unit in which the first adjustment and the second adjustment are performed by the output voltage adjusting unit;
A power supply control device comprising: The output voltage adjustment unit repeatedly performs the first adjustment and the second adjustment by repeating the step of increasing the output voltage of the power source by a predetermined amount,
The voltage drop adjustment unit adjusts the voltage drop so that a voltage drop between the power source and the operation unit becomes a predetermined guaranteed appropriate value for each step.
The power supply control device according to claim 1. Power supply,
A plurality of operating units that operate with power supplied from the power source;
A voltage drop calculation unit that obtains an output voltage from the power supply and an input voltage to the operation unit, and calculates a maximum value of the voltage drop;
Based on the maximum value of the voltage drop calculated by the voltage drop calculation unit, wherein the input voltage of the voltage drop to the operation portion is the largest Ri Do a predetermined voltage or more, and, the input voltage to the other operation portion the output of the power supply so that fit in the upper limit value and the first adjustment, after said first adjustment has been completed, outputs a second adjustment of the power supply the input voltage to the other operating unit to a predetermined value An output voltage adjustment unit to
A voltage drop adjusting unit that adjusts a voltage drop between the power source and the operating unit in which the first adjustment and the second adjustment are performed by the output voltage adjusting unit;
An information processing apparatus comprising: The output voltage adjustment unit repeatedly performs the first adjustment and the second adjustment by repeating the step of increasing the output voltage of the power source by a predetermined amount,
The voltage drop adjustment unit adjusts the voltage drop so that a voltage drop between the power source and the operation unit becomes a predetermined guaranteed appropriate value for each step.
The information processing apparatus according to claim 3.

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