JP2007102687A - Power controller, power control method and electronic equipment - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To shorten starting time about a power source part of electronic equipment. <P>SOLUTION: The power source part has a first power supply unit 101 and a second power supply unit to be serially connected to its rear stage. First, when a starting detection signal to be output according to completion of the starting from the first power supply unit 101 is detected after starting the first power supply unit 101, the second power supply unit 102 is started. Thus, it becomes possible to start the second power supply unit 102 just after the starting the first power supply unit 101 and the starting time is sharply made shorter than it is in warming up the second power supply unit 102 by setting fixed standby time. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a power supply control device and a method for controlling activation of a power supply device. The present invention also relates to an electronic device including such a power supply control device.

  For example, a power supply unit that is provided in various electronic devices and supplies power as an operation power supply to an electric circuit unit serving as an internal load is configured by connecting two types of power supply devices in series. It has been. FIG. 6 shows an example of the configuration of an electronic apparatus mainly composed of such a power supply unit.

In FIG. 6, as a power supply device, a first power supply device 101 that operates by receiving supply of input power, a second power supply device that operates by inputting the output of the first power supply device 101, and outputs power to the load circuit 103. A power supply 102 is shown.
The controller 104 in this case is configured as a microcomputer or the like, for example, and controls the electronic device. As one of the controls, the first power supply device 101 and the second power supply device 102 are used as power activation. Control for starting is also executed. In this figure, a control function given to the controller 104 by executing the program for starting the power supply is shown as a power supply start control unit 105.

The activation control for the first power supply apparatus 101 and the second power supply apparatus 102 by the controller 104 is performed as follows.
In this case, in the case where the first power supply device 101 and the second power supply device 102 are connected in series, the start of the first power supply device 101 in the previous stage is completed and then the subsequent power supply apparatus 101 is connected. It is necessary to start activation of the second power supply apparatus 102. For this reason, for example, it is assumed that the activation of the second power supply apparatus 102 is started before the activation of the first power supply apparatus 101 in the previous stage is completed without considering the timing of the activation control as described above. In this case, when the second power supply device 102 starts to start, the amount of power supplied from the first power supply device 101 has yet reached a state sufficient to normally start the second power supply device 102. There may not be. In such a situation, the second power supply device 102 cannot be started normally, and as a result, a malfunction that the power supply unit does not start normally is caused, and the reliability of the electronic device is impaired.

Therefore, as the start control by the power start control unit 105 of the controller 104, the start control of the first power supply device 101 and the second power supply device 102 is executed by using the procedure and algorithm shown in FIG.
When starting the power supply, the power supply startup control unit 105 outputs a first startup control signal to the first power supply apparatus 101 as shown in step S201. Based on the output of the first activation control signal, for example, the first power supply apparatus 101 can obtain an operation such as connecting a line for supplying input power to the internal circuit. In response to this, input of input power is started, and the first power supply apparatus 101 starts to be started accordingly.

  As is well known, it takes a certain amount of time from when the power supply circuit starts to start until the output voltage reaches the specified value and the start-up is completed. Here, such a time width is also referred to as “start-up required time”. In view of this, in step S202, a fixed standby time is set in consideration of the time required for starting the first power supply device, and the standby time is determined from the time when the startup is started in accordance with step S201. Wait for it to elapse. If it is determined that the waiting time has elapsed, the process proceeds to step S203.

  At the stage where a positive determination result is obtained in step S202, the first power supply apparatus 101 has already been started up and is in a state of shifting to a steady operation. Step S203 outputs a second activation control signal to the second power supply apparatus 102 under this state. In response to the second activation control signal, the second power supply device starts an operation by obtaining an operation such as connecting a line for inputting the output of the first power supply device 101 therein. In other words, the second power supply device 102 starts to be started in a state where the first power supply device 101 has been started, and a normal start-up operation as a power supply unit can be obtained. Become.

Here, mention is made of how to set the standby time as a determination factor in step S202.
As described above, the standby time is set based on the startup time of the first power supply apparatus 101. Generally, the startup time of the power supply circuit is, for example, in the temperature, the smoothing capacitor of the input stage, or the like. It is known that various conditions such as the residual charge amount and the input voltage change due to factors. Then, the above-described standby time is set in consideration of the longest required startup time corresponding to the worst condition, assuming that the condition is worst. In practice, the standby time is set by adding a certain time as a margin to the required startup time determined as the longest.

JP 2000-115998 A

When the standby time is set as described above and the startup control is performed according to the algorithm shown in FIG. 7, normal power supply startup can always be performed.
However, the worst condition corresponding to the required start time considered when setting the standby time as described above is assumed to be a severe condition that cannot occur even in actual use. Yes. Therefore, this standby time is considerably longer than the actual required start time under normal use conditions. From this, in normal use, the start-up time from when the entire power supply unit composed of the first power supply device 101 and the second power supply device 102 starts to start to end startup may be unnecessarily long. It means that it is almost.
As an electronic device, for example, the time required to perform normal operation by performing an operation according to a power-on instruction such as turning on the power (here, “device start-up time” is referred to as “device start-up time”). It is preferable that the “time” is shortened as much as possible in consideration of stress applied to the user. From this point of view, shortening the start-up time of the power supply unit mounted on the electronic device can contribute directly to shortening the device start-up time of the electronic device, and the request is also an important thing that cannot be ignored. I can say that.

In view of the above-described problems, the present invention is configured as a power supply control device as follows.
That is, the first starter for executing the start control for starting the start of the first power supply device and the information indicating the completion of the start of the first power supply device output from the first power supply device side are input. And an activation control for starting activation of the second power supply device that operates by inputting the output of the first power supply device in response to input of the information indicating the completion of activation to the input means. And a second starting means for executing the above.

  Further, the electronic device is provided to supply power to a circuit portion serving as a load in the electronic device, and operates at least by inputting the output of the first power supply unit and the first power supply unit. Output from the first power supply unit side, a power supply unit configured to include two power supply units, a first activation unit that performs activation control for starting activation of the first power supply unit Input means for inputting information indicating completion of activation of the first power supply unit, and input of the output of the first power supply unit in response to input of information indicating completion of activation to the input means. Thus, the electronic device is configured to include a second activation unit that performs activation control for starting activation of the second power supply unit that operates as described above.

  In each of the above-described configurations, the second power supply device (unit) is activated in response to input of information indicating completion of activation output from the first power supply device (unit) side. Thereby, first, the start timing of the second power supply apparatus is always after the completion of the actual start-up of the first power supply apparatus, so that the normal start-up of the second power supply apparatus is guaranteed. In addition, the activation timing of the second power supply device is varied according to the actual activation completion timing of the first power supply device. For this reason, although the time required for starting the first power supply device (the time from the start to the completion of the start) varies depending on the ambient conditions at that time, the second power supply device always has the first power supply. The activation starts after the completion of the activation of the apparatus. That is, the second power supply device starts to be started at a timing that can be regarded as the shortest time from the start of the start of the first power supply circuit, in accordance with the time required for starting the first power supply device.

  As described above, according to the present invention, the start-up of the second power supply device is always started at the timing that is the shortest from the start-up time of the first power supply circuit in accordance with the required start-up time of the first power supply device. The Thereby, for example, when compared with the case where the second power supply device is activated after waiting for a fixed waiting time determined in consideration of the required activation time corresponding to the worst condition, these first and second power supplies The actual startup time for the power supply site with the device will be greatly reduced. And since the start-up time of the power supply part is shortened in this way, the device start-up time of the electronic device equipped with this power supply part is also shortened. For example, the stress of waiting for the user to complete the start-up is reduced. Will be.

FIG. 1 shows a basic configuration for power activation control as an embodiment of the present invention, together with a power supply device that is subject to activation control. Each block shown in these drawings is actually provided in a certain electronic device.
In this figure, a first power supply device 101 and a second power supply device 102 are shown as power supply devices subject to activation control.
The first power supply device 101 is supplied with input power, operates an internal circuit, and its output is input to the second power supply device 102. The second power supply apparatus 102 receives the output of the first power supply apparatus 101 and operates an internal circuit. Then, the output is supplied to the load circuit 103. In this way, the first power supply device 101 and the second power supply device 102 are connected in series so that the first power supply device 101 is in the previous stage and the second power supply apparatus 102 is in the subsequent stage.
The load circuit 103 is actually provided in the electronic device, and collectively indicates circuit portions that operate by inputting the output of the second power supply apparatus 102 as a power source.

  The controller 104 executes various controls of the electronic device, and includes a microcomputer including, for example, a CPU (Central Processing Unit), ROM, RAM, and the like. The controller 104 can execute start-up control (power start-up control) of the power supply device as one of the controls in the electronic device. The power activation control executed by the controller 104 is realized by the internal CPU executing a program stored in the internal ROM, for example. In this figure, the power supply start control function obtained in this way in the controller 104 is shown as the power supply start control unit 106.

As a configuration for power activation control, the controller 104 can output a first power activation control signal (Cnt1) to the first power supply device 101. In addition, the second power supply activation control signal (Cnt2) can be output to the second power supply apparatus 102.
Further, under the present embodiment, a start detection signal is output from the first power supply apparatus 101 to the controller 104. The activation detection signal is a signal that is output when the first power supply apparatus 101 detects that the activation is completed as its own state. The controller 104 inputs this activation detection signal from, for example, a predetermined port provided in the internal CPU.

  When the power supply circuit starts to start up, its output voltage rises to a specified level with a certain time constant. Then, when it reaches the specified level, the activation is completed. Based on this, the circuit configuration added to enable the output of the activation detection signal corresponds to the voltage value as the output of the first power supply device 101 being equal to or higher than a certain level corresponding to the specified level. Thus, a signal having a predetermined voltage value as the activation detection signal may be output. More specifically, for example, a voltage dividing circuit using a resistor that divides the voltage value of the output of the first power supply circuit into a predetermined ratio, and the voltage value of the output of the first power supply circuit divided by the voltage dividing circuit And a comparator for comparing with a predetermined value set corresponding to the prescribed level. That is, the circuit configuration for generating the activation detection signal according to the present embodiment can be realized with very simple components and circuit configuration. Further, in this figure, the activation detection signal generation circuit is shown as being provided in the first power supply apparatus 101. However, in actuality, for example, externally attached to the integrated circuit components constituting the first power supply apparatus 101, for example. It may be formed as a circuit.

Here, the necessity of the power supply start control, that is, the start start timing control for each of the plurality of power supply devices will be described.
As described above, the first power supply device 101 and the second power supply device 102 are connected in series. Under such a configuration, in order to always start the second power supply device stably and normally, a prescribed voltage level is stably obtained as the output of the first power supply device 101 as its input power. It is necessary to be in a state. Conversely, for example, even if the second power supply device 102 is activated in a state where the output voltage level of the first power supply device 101 is smaller than a specified value, the input power is insufficient and normal activation fails. There is a case. Therefore, at the time of power activation, it is necessary to start the second power supply device 102 after ensuring that the first power supply device 101 is completely activated and a specified output voltage level is obtained. is there. The power activation control controls the activation of the first power supply device 101 and the second power supply device 102 so that the power activation in this order is appropriately performed.

Therefore, FIG. 2 shows a procedure of power activation control executed by the power controller 106 of the controller 104 under the configuration shown in FIG.
For example, in an electronic device or the like that implements the configuration shown in FIG. 1, when the power-on operation is performed or the timer setting time is reached, the timing for starting the power is reached. First, as shown in step S101, the controller 104 outputs a first activation control signal (Cnt1) to the first power supply apparatus 101. In response to the input of the first activation control signal, the first power supply device supplies input power to the internal circuit, for example, by switching a line for supplying input power to the internal circuit from a disconnected state to a connected state. To start. As a result, the first power supply apparatus 101 starts to start.

In the next step S102, the process waits for the start detection signal (MON) output from the first power supply apparatus 101 to be input. Then, as described above, when the activation detection signal is output from the first power supply apparatus 101 in response to the first power supply apparatus 101 having been activated, the positive determination result in step S102 Thus, the process proceeds to step S103.
In step S103, a second activation control signal (Cnt1) is output to the second power supply apparatus 102. As a result, the second power supply apparatus 102 starts to start.

FIG. 3 schematically shows a change characteristic of the output voltage value of the first power supply device 101 as time elapses after the first power supply device 101 is started. From this figure, the timing of power activation control between the present embodiment and the prior art is compared as follows.
First, as shown in the figure, the change characteristic of the output voltage value of the first power supply device 101 is the specified output voltage level of the first power supply device 101 as time elapses from t0 which is the start point of activation. It rises as it reaches a certain Vout. The activation required time can be regarded as the time from the activation start time point t0 until reaching the specified output voltage level Vout.
As described above, the time required for starting the power supply circuit varies depending on conditions (starting conditions) including elements such as temperature, residual charge amount, and input voltage value. The same applies to the first power supply device 101 shown in FIG. In FIG. 3, the change characteristic of the output voltage value of the first power supply device 101 is shown by four curves according to the start conditions. As shown in this figure, the time required for starting the first power supply device 101 is the shortest in the period t0 to t1 when the best starting condition is met (at the best condition), and the worst starting condition (at the worst condition). Is the longest in the period t0 to t2.

Assuming that the first power supply device 101 has such characteristics, if the power supply start-up configuration of the present embodiment described with reference to FIGS. 1 and 2 is used, the start-up start timing of the second power supply device 102 is the best condition. Correspondingly, the earliest is the timing that follows the time t1. Moreover, it becomes the slowest corresponding to the worst condition, and is the timing following time t2. That is, in the best condition, the activation detection signal is obtained at the timing corresponding to the time point t1, and in response to this, the second activation control signal is output and the activation of the second power supply apparatus 102 is started. Similarly, in the worst condition, an activation detection signal is obtained at a timing corresponding to the time point t2, and in response to this, a second activation control signal is output to start activation of the second power supply apparatus 102. It will be.
Thus, in the case of the present embodiment, activation of the second power supply device 102 is started following the timing immediately after the first power supply device 101 completes activation in accordance with the activation condition. The This means that the second power supply device 102 can be started up in the shortest time according to the start-up completion time of the first power supply device 101 corresponding to the start condition at that time.
On the other hand, for example, if the conventional power-on configuration described with reference to FIGS. 6 and 7 is applied, the standby time in step S102 in FIG. Is a fixed period (t0 to t3) from the time point t2 at which a certain margin period elapses until the time point t3. Therefore, the timing for starting to activate the second power supply apparatus 102 is always fixed after the time point t3.
As can be seen by comparing the start-up timing of the second power supply apparatus 102 in the present embodiment and the conventional one, first, in the present embodiment, the start-up start timing of the second power supply apparatus 102 is the latest. However, the timing is the same as or earlier than the conventional timing. In addition, as described above, in FIG. 3, the longest startup time indicated as the period t0 to t2 sets a severe condition that cannot be a normal use environment for the worst condition. It is assumed that it was obtained corresponding to the worst condition. Therefore, in normal use, the activation start timing of the second power supply apparatus 102 in the present embodiment is considerably earlier than the time point t2. If the start-up timing of the second power supply device is earlier, the timing at which the second power supply device 102 completes startup is earlier. Therefore, the power activation according to the present embodiment is completed much earlier than in the prior art when used under normal conditions. That is, the effect of greatly shortening the power-on time can be obtained.

  Conceptually, the activation start timing of the second power supply device in the present embodiment is the shortest time t1 and the longest time t2, but as described above, the output of the activation detection signal, Since the actual second power supply apparatus starts to be activated only when the second activation control signal is output in response to this, in practice, for example, a slight delay occurs with respect to time t1 and time t2. I can see it. However, even if such a delay element is taken into consideration, the power supply startup time of the present embodiment is greatly reduced as compared with the conventional case.

  As described above, the power-on configuration according to the present embodiment described so far is provided in some electronic device. In view of this, the configuration of the power activation according to the present embodiment will be described using a television receiver as an example applied to an actual electronic device.

FIG. 4 shows a configuration example of the television receiver 1 to which the power activation configuration of the present embodiment is applied.
In the television receiver 1 shown in this figure, the broadcast wave received by the antenna 10 is input to the tuner 11. The tuner 11 performs carrier demodulation on the input received wave, extracts and acquires a video signal and an audio signal (video / audio signal) of a specified channel, for example, under the control of the system controller 20, and AV Output to the (Audio Video) switch 13.

  In this case, the AV input terminal 12 is provided so that a video / audio signal output from an external video device or the like can be input. The video / audio signal input to the AV input terminal 12 is input to the AV switch 13.

  In the AV switch 13, the video / audio signal to be reproduced and output from the video / audio signals input from the tuner 11 and the AV input terminal 12 in accordance with the control of the system controller 20 as described above. To select. The video signal in the selected video / audio signal is output to the video signal processing unit 14, and the audio signal is input to the audio processor 17.

  The video signal processing unit 14 performs predetermined signal processing on the input video signal and outputs it to the video processor 15. The video processor 15 uses the input video signal to generate display data and signals corresponding to the display device, and supplies them to the display device unit 16. The display device unit 16 includes a predetermined type of display device, a drive circuit system corresponding to the display device type, and the like, and executes an operation for image display using a signal input from the video processor 15. As a result, an image obtained by reproducing the video signal is displayed on the display screen unit of the display device unit 16.

  In addition, the audio processor 17 performs predetermined signal processing on the input audio signal and outputs it to the amplifier 18. The amplifier 18 amplifies the input audio signal and drives the speaker 19. As a result, sound obtained by reproducing the audio signal is output from the speaker 19.

The system controller 20 includes a microcomputer including, for example, a CPU, a ROM, a RAM, and the like, and executes various control processes for the television receiver 1. As one of the control processes, the activation control of the power supply unit 22 is executed.
The operation unit 21 collectively indicates various operators provided in the main body of the television receiver 1 and a part that generates a command according to an operation on the operator and outputs the command to the system controller 20. Further, even when a remote control device and a reception unit that receives a command transmitted from the remote control device and actually transfers the command to the system controller 20 are actually provided, the remote control device and the reception unit are operated by this operation. Part 21 can be included.

  The power supply unit 22 is provided to supply power to each circuit unit inside the television receiver 1. The actual circuits constituting the blocks described so far operate by receiving the supply of the power supply voltage supplied from the power supply unit 22.

FIG. 5 shows the configuration of the television receiver 1 shown in FIG.
The power supply unit 22 of the television receiver 1 in this case includes a power factor correction converter 201 and a primary / secondary converter 202 as shown in the figure. In this case, the power factor correction converter 201 inputs the commercial AC power supply 200 as input power and performs a switching operation, thereby sine the input current waveform input from the commercial AC power supply 200 for power factor improvement. Control is performed so that the voltage value of the DC output becomes constant at a specified value while approaching the wave.

  The primary-secondary converter 202 performs switching on the DC output output from the power factor correction converter 201 to convert it to AC, and then transmits power from the primary side to the secondary side via a converter transformer, for example. To be done. At this stage, the circuit in the television receiver 1 is subjected to DC insulation between the primary side and the secondary side of the commercial AC power supply 200. Then, the alternating current transmitted to the secondary side is converted again into direct current and output to the load circuit 203.

In the configuration of the power supply unit 22 described above, the power factor correction converter 201 at the front stage and the primary / secondary converter 202 at the rear stage are connected in a serial relationship. That is, in correspondence with FIG. 1, the power factor correction converter 201 corresponds to the first power supply device 101, and the primary-secondary converter 202 corresponds to the second power supply device 102.
The simplest configuration of the power supply unit 22 is, for example, a configuration in which the power factor correction converter 201 is omitted from the configuration of FIG. 5 and only the primary-secondary converter 202 is provided. In the case of such a configuration, the direct current generated from the commercial AC power supply 200 by a so-called capacitor input method is generally configured to be input to the primary-secondary converter 202. In the configuration in which the direct current input to the switching power supply (primary-secondary converter 202) is obtained by the capacitor input method based on the alternating current power supply in this manner, the direct current is input from the alternating current power supply as is well known. The AC input current waveform is pulsed, increasing the harmonic components and reducing the power factor. The power factor improving converter 201 is provided to improve the power factor that decreases in this way.

The load circuit 203 shown in FIG. 5 corresponds to the load circuit 103 of FIG. In this case, the load circuit 203 includes, for example, a switching power supply unit 203a and an operation circuit unit 203b. The switching power supply unit 203a receives the DC output of the primary-secondary converter 202, generates DC power supply voltages of a plurality of systems, and supplies them to a predetermined circuit unit that constitutes the operation circuit unit 203b.
The operation circuit unit 203b is a set of circuit units that operate by inputting the DC power supply voltage supplied from the switching power supply unit 203a. Here, the operation circuit unit 203b includes a video circuit system, an audio circuit system, and a display device system. It is supposed to be. As for the correspondence between these circuit systems and FIG. 4, for example, the video circuit system is a tuner 11, an AV switch 13, a video signal processing unit 14, a video processor 15, and the like, and the audio circuit system is an audio processor 17, an amplifier 18, and the like. Thus, the display device system is the display device unit 16. Although not shown here, the system controller 20 shown in FIG. 4 operates by a power supply voltage supplied from, for example, a standby power supply system.

  5 corresponds to the CPU constituting the microcomputer in the system controller 20 in correspondence with the television receiver 1 shown in FIG. 4, and corresponds to the controller 104 in correspondence with FIG. Therefore, the CPU 204 also has a function as the power supply start control unit 206 by executing a program for power supply start control stored in the ROM inside the system controller 20, for example.

In this case, the startup control procedure and algorithm for the power factor correction converter 201 of the power supply unit 22 and the primary-secondary converter 202 by the power supply startup control unit 206 of the CPU 204 are the same as those in FIG. That is, when the power source should be activated, the power source activation control unit 206 of the CPU 204 first outputs a first activation control signal to the power factor improvement converter 201 to start activation of the power factor improvement converter 201. Thereafter, when it is detected that the activation detection signal is output from the power factor correction converter 201, the second activation control signal is output to start activation of the primary-secondary converter 202.
The power factor improving converter 201 shown in FIG. 5 is also mainly composed of, for example, a switching converter, and its required start time varies depending on conditions such as temperature. Therefore, also for the television receiver 1 shown in FIG. 5, the start-up time of the power supply unit 22 is shortened as described with reference to FIG. According to the configuration shown in FIG. 5, in the television receiver 1, the start-up of the power supply unit 22 is completed and the specified DC voltage is supplied from the primary / secondary converter 202 to the switching power supply unit 203 a of the load circuit 203. The operation circuit unit 203b and the like can be operated by receiving power supply. From this, it can be understood that the shortening of the starting time of the power supply unit 22 can greatly contribute to the shortening of the starting time (device starting time) of the television receiver 1 which is an electronic device.

In addition, this invention is not limited to the structure as embodiment described so far.
For example, FIG. 5 shows a configuration in which the first power supply device is a power factor correction converter and the second power supply device is a primary-secondary converter. However, the first power supply device and the second power supply device are practical. Other functions and configurations are also conceivable.
In addition, here, a television receiver is cited as a specific example of an electronic device to which the power activation control of the present embodiment is applied, but if it is another electronic device other than this and includes a power supply device, Applicable in general.
Further, for example, in the description so far, the configuration for controlling the activation of the two power supply devices, the first power supply device and the second power supply device, is shown, but three or more power supply devices connected in a serial relationship. It can also be applied when controlling the activation of the. Regardless of the number of power supply devices connected in series, the activation of the power supply device in the subsequent stage may be started after detecting the output of the activation detection signal from the power supply device in the previous stage. In other words, the first power supply unit (unit) and the second power supply unit (unit) in the present invention are not conceptually limited to two power supply units in the power supply unit, but are simply connected in series. It refers to the power supply apparatus of the front | former stage and back | latter stage which are related.

It is a figure which shows the basic structural example of the power supply starting system as embodiment of this invention. It is a flowchart which shows the procedure of the power supply starting control performed by the controller of FIG. It is a figure which shows typically the change characteristic of the output voltage value at the time of starting of a 1st power supply device. It is a figure which shows the structural example of the television receiver which is one of the electronic devices with which the power supply starting system of embodiment is mounted. FIG. 5 is a diagram illustrating a configuration of a part mainly including a power supply unit in the television receiver illustrated in FIG. 4. It is a figure which shows the basic structural example of the conventional power supply starting system. It is a flowchart which shows the procedure of the power supply starting control performed by the controller of FIG.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 Television receiver, 10 Antenna, 12 AV input terminal, 13 AV switch, 14 Video signal processing part, 15 Video processor, 16 Display device part, 17 Audio processor, 18 Amplifier, 19 Speaker, 20 System controller, 21 Operation part , 22 power supply unit, 101 first power supply device, 102 second power supply device, 103 load circuit, 104 controller, 106 power supply start control unit, 200 commercial AC power supply, 201 power factor improvement converter, 202 primary-secondary converter, 203 Load circuit, 203a switching power supply unit, 203b operation circuit unit, 204 CPU, 206 power supply activation control unit

Claims (3)

First activation means for executing activation control for starting activation of the first power supply device;
Input means for inputting information indicating completion of activation of the first power supply device, which is output from the first power supply device side;
In response to the information indicating the completion of the activation being input to the input means, the activation control for starting the activation of the second power supply device that operates by inputting the output of the first power supply device is executed. A second activation means;
A power supply control device comprising: A first activation procedure for performing activation control for starting activation of the first power supply device;
An acquisition procedure for acquiring information indicating completion of activation of the first power supply device, which is output from the first power supply device side;
In response to the information indicating the completion of activation being acquired by the acquisition procedure, activation control for starting activation of the second power supply device that operates by inputting the output of the first power supply device is executed. A second startup procedure;
The power supply control method characterized by performing. Provided to supply electric power to a circuit part serving as a load in an electronic device. At least a first power supply unit and a second power supply that operates by inputting the output of the first power supply unit. A power supply unit configured to include a power supply unit unit;
First activation means for executing activation control for starting activation of the first power supply unit;
Input means for inputting information indicating completion of activation of the first power supply unit, which is output from the first power supply unit side;
In response to the information indicating the completion of activation being input to the input means, activation control for starting activation of the second power supply unit that operates by inputting the output of the first power supply unit. A second starting means to execute;
An electronic device comprising:

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