JP6207385B2 - Electronics - Google Patents

Description

  The present invention relates to an electronic apparatus including a power supply unit that generates an operation power supply from an external power supply and a power supply control unit that controls supply of the operation power supply to a supply target.

  As this type of electronic device, an electronic device disclosed in Patent Document 1 below is known. This electronic device includes a switching power source that converts AC power supplied from a main power source into a DC voltage, a DC-DC converter that converts a DC voltage converted by the switching power source into a voltage suitable for a load, and an on / off state of the power source And a microcomputer for controlling the supply of power to the load by controlling the FET. In this electronic device, the microcomputer detects a pulse signal that is output when the switch is pressed, reads information on the power on / off state and mode recorded in the nonvolatile memory, and in accordance with the information, Perform on / off processing.

JP 2008-187871 A (page 4-5, FIG. 1)

  However, conventional electronic devices have the following problems to be improved. That is, in the electronic device described above, information on the power on / off state and mode is recorded in the nonvolatile memory, and the microcomputer reads the information and performs power on / off processing for the load according to the information. In this case, for example, when the supply of AC power to the switching power supply is started (when the power plug is inserted into the power outlet), the process of immediately starting the power supply to the load regardless of whether the switch is operated (first operation) Processing), and when the power plug is inserted into the power outlet, the load is immediately waited without starting the power supply, and the power supply is started when the switch is operated (second processing). Even in the case of performing relatively simple processing such as specifying and executing one of the above, information specifying whether to execute the first processing or the second processing is recorded in the nonvolatile memory, and the microcomputer That information is read out and one of the processes is executed. In this case, depending on the configuration of the nonvolatile memory, it may take time to read out information. For this reason, even when performing relatively simple processing as described above, this electronic device can supply power to the load in a short time due to the time required to read information from the nonvolatile memory. There is a problem that it is difficult to start.

  This invention is made | formed in view of this subject, and it aims at providing the electronic device which can shorten the start time of the power supply with respect to a supply object.

  In order to achieve the above object, an electronic device according to claim 1, wherein when an external power source is input, a power source unit that generates an operating power source from the external power source, and a start instruction to start supplying the operating power source to a supply target An operation unit capable of performing an operation and a stop operation instructing the supply power supply to be stopped, and the supply target regardless of whether or not the start operation is performed on the operation unit when the power supply unit inputs the external power supply The first power supply process for supplying the generated power supply for operation and the power supply for operation generated for the supply target when the power supply unit is inputting the external power supply and the start operation is performed. And a second power supply control unit that executes a second supply process for supplying the first power, and is always operated with an internal power supply, and a first mode for outputting a clock signal and a first mode for stopping the output of the clock signal. A real-time clock that can be set to any one of the modes, and the power control unit operates regardless of whether or not the start operation is performed, and the real-time clock is one of the first mode and the second mode. The first supply process is executed when the power supply unit is inputting the external power in the state set in the mode, and the real-time clock is one of the first mode and the second mode. The second supply process is executed when the power supply unit inputs the external power supply in the state set to the other mode.

  The electronic device according to claim 2 is the electronic device according to claim 1, wherein the power supply control unit is a CLR terminal for inputting a clear signal based on the power supply for operation, and an operation signal output at the time of a start operation. A PR terminal for inputting a D signal, a D terminal for inputting a D signal based on the operating power supply, a CK terminal for inputting the clock signal, and a Q signal for instructing the power supply unit to start supplying the operating power supply. A D-type flip-flop having a Q terminal for output is configured to output and stop the output of the Q signal according to whether the external power supply is input by the power supply unit and whether the clock signal is output. The first supply process and the second supply process are executed.

  According to a third aspect of the present invention, in the electronic device according to the first or second aspect, when the operating power supply is supplied to the supply target, the electronic device is operated by the operating power supply and the real-time clock is set. A clock controller configured to set the real-time clock to the other mode when the stop operation is performed in a state where the operation power is supplied to the supply target and set to one of the modes. I have.

  The electronic device according to claim 1, further comprising a real-time clock that can be set to a first mode for outputting a clock signal and a second mode for stopping the output of the clock signal. The first supply process is executed when the power supply unit is inputting the external power in the state set to one of the mode and the second mode, and the real-time clock is set to the first mode and the second mode. The second supply process is executed when the power supply unit inputs an external power supply in the state set to the other of the two modes. For this reason, in this electronic device, the power supply unit is connected to the external power supply without recording in the memory information about which of the first supply process and the second supply process is executed when the power supply unit inputs the external power supply. Either the first supply process or the second supply process can be executed in accordance with the mode of the real-time clock when. Therefore, according to this electronic apparatus, when such information is recorded in the memory and the supply of the operating power supply is started, the time required for reading the information is not required as compared with the configuration in which the information is read from the memory. Therefore, the start time of power supply to the supply target can be sufficiently shortened.

  According to another aspect of the present invention, the power supply control unit is configured by including a D-type flip-flop. In this case, for example, when the second supply process is executed, in a configuration in which a main control unit such as a CPU monitors whether or not the operation unit is operated, it is necessary to constantly supply operating power to the main control unit for monitoring. There is. On the other hand, in this electronic device, the operation unit is not operated by the operation of the power supply control unit (D-type flip-flop) capable of reducing power consumption with a simple configuration without performing monitoring by the main control unit. When the operation is performed, the second supply process can be executed. For this reason, according to this electronic device, power consumption for monitoring by the main control unit can be reduced, and as a result, power consumption can be reduced.

  According to another aspect of the present invention, there is provided a clock controller that operates with the power supply for operation and controls the setting of the mode of the real-time clock, so that the clock that operates with a power supply different from the power supply for operation is provided. Since the setting of the real-time clock mode can be reliably controlled without providing a control unit, the configuration can be simplified because it is not necessary to provide another power source for such a clock control unit.

1 is a configuration diagram showing a configuration of a measuring device 1. FIG. FIG. 3 is a configuration diagram showing a configuration of a power supply control unit 14. FIG. 3 is a first explanatory view explaining the operation of the measuring apparatus 1. FIG. 6 is a second explanatory diagram for explaining the operation of the measuring apparatus 1. FIG. 6 is a third explanatory diagram for explaining the operation of the measuring apparatus 1. FIG. 6 is a fourth explanatory view for explaining the operation of the measuring apparatus 1.

  Hereinafter, embodiments of an electronic device will be described with reference to the accompanying drawings.

  First, the configuration of the measuring apparatus 1 as an example of an electronic device will be described with reference to the drawings. The measuring apparatus 1 shown in FIG. 1 is configured to be able to measure a measurement target to be measured (for example, physical quantities such as impedance, inductance, and capacitance). Specifically, as shown in the figure, the measuring apparatus 1 includes a power supply unit 11, a main switch 12, a power switch 13, a power supply control unit 14, a measurement unit 15, and a real time clock 16 (hereinafter also referred to as “RTC16”). , And a main control unit (CPU) 17.

  The power supply unit 11 includes an AC-DC converter as an example. As shown in FIG. 1, an operation power supply Po (for example, a DC power supply) is supplied from an external power supply Pe (for example, a commercial AC power supply) input from the outside. Generate. Further, the power supply unit 11 generates the generated power supply Po for the power input terminal and D terminal of a D-type flip-flop 21 to be described later in the power supply control unit 14 and the reset IC 22 and the resistor 23 in the power supply control unit 14. It is output continuously from the start (regardless of the presence or absence of a start operation by a power switch 13 described later) (see FIG. 2). Further, the power supply unit 11 supplies the operating power supply Po to the measurement unit 15 and the main control unit 17 as an example of the supply target under the control of the power supply control unit 14. Specifically, the power supply unit 11 operates a switch (not shown) according to the Q signal Sq output from the D-type flip-flop 21 of the power supply control unit 14 to supply the operating power supply Po to the measurement unit 15 and the main control unit 17. (See FIGS. 2 and 3).

  As shown in FIG. 1, the main switch 12 is disposed between a power supply plug (not shown) and a power supply unit 11 that are plugged into a power outlet to which an external power supply Pe is supplied. In response to the disconnection operation, the external power source Pe is input to the power source unit 11 and input is stopped (connection and disconnection between the power outlet and the power source unit 11).

  The power switch 13 corresponds to an operation unit, and a start operation for instructing start of supply of the operation power source Po to the measurement unit 15 and the main control unit 17 as supply targets, and a stop operation for instructing stop of supply of the operation power source Po. It is possible to do. Specifically, as an example, the power switch 13 is formed of a push switch that functions as a momentary switch, and is connected between a resistor 23 (described later) and a low potential (ground potential) as shown in FIGS. ing. In this case, low level and high level PR signals Spr (see FIG. 3) are output to the PR terminal of the D-type flip-flop 21 of the power supply control unit 14 and the main control unit 17 in accordance with the push operation on the power switch 13. The Further, as will be described later, supply of the operation power supply Po to the supply target is started and stopped by a change in the level of the PR signal Spr. That is, the push operation on the power switch 13 corresponds to a start operation and a stop operation.

  The power supply control unit 14 operates by inputting the operation power supply Po output from the power supply unit 11 regardless of the start operation by the power switch 13 and operates on the measurement unit 15 and the main control unit 17 as supply targets. Controls the supply and stop of the power supply Po. Specifically, the power supply control unit 14 first supplies the operation power Po to the supply target regardless of whether or not the power switch 13 is started when the power supply unit 11 inputs the external power supply Pe. And a second supply process for supplying the operating power Po to the supply target when the power supply unit 11 is inputting the external power supply Pe and the power switch 13 is started.

  Here, in this measuring apparatus 1, the power supply control unit 14 is in a state where the RTC 16 is set to a first mode (an example of one of the first mode and the second mode) described later. , The first supply process is executed when the power supply unit 11 is inputting the external power supply Pe, and the RTC 16 performs a second mode (an example of the other one of the first mode and the second mode) described later. When the power supply unit 11 inputs the external power supply Pe in the state set to, the second supply process is executed. That is, in this measuring apparatus 1, when the power supply unit 11 inputs the external power supply Pe, the power supply control unit 14 performs either the first supply process or the second supply process according to the set mode of the RTC 16. Run.

  As an example, the power supply control unit 14 includes a D-type flip-flop 21 (hereinafter also referred to as “FF21”) having a PR terminal, a CLR terminal, a CK terminal, a D terminal, and a Q terminal, as shown in FIG. A reset IC 22 and a resistor 23 are provided. In this case, the CLR terminal receives a CLR signal Scrr (see FIG. 3) that is generated based on the operating power supply Po, and the PR terminal is an operation signal that is generated when a push operation on the power switch 13 is performed. As a PR signal Spr (see the same figure). Further, the D terminal inputs the operating power supply Po as a D signal Sd (see the same figure), and the CK terminal inputs a CK signal (clock signal) Sck (see the same figure) output from the RTC 16 to be described later. Further, the Q terminal outputs a Q signal Sq to the power supply unit 11 as a Q signal instructing supply of the operation power supply Po to the supply target. In the FF21, the CLR terminal and the PR terminal are respectively defined as low active.

  In this measuring apparatus 1, as shown in FIGS. 3 to 6, the FF 21 has the presence or absence of input of the external power supply Pe by the power supply unit 11, the level of the PR signal Spr or CLR signal Scrr, and the presence or absence of output of the CK signal Sck, etc. The first supply process and the second supply process are executed by outputting the Q signal Sq in response to the above.

  The measurement unit 15 is operated by the operation power supply Po supplied from the power supply unit 11, and executes a measurement process for measuring a measured amount of a measurement target (not shown) under the control of the main control unit 17.

  The RTC 16 is always operated by an independent internal power source (for example, a DC power source of a battery disposed in the measuring apparatus 1) different from the external power source Pe and the operating power source Po, and calculates the time, and the main control unit 17 Time data is output in response to the request. The RTC 16 also has a first mode for outputting a CK signal Sck (for example, a pulse signal of 32768 Hz) used for time calculation, and a second mode (second mode) for stopping the output of the CK signal Sck. The time calculation is continued without stopping). In this case, the RTC 16 switches between the first mode and the second mode according to the mode instruction signal Sm output from the main control unit 17.

  The main control unit 17 operates with the operating power supply Po supplied from the power supply unit 11 (that is, the supply target) and controls the measurement unit 15. The main control unit 17 functions as a clock control unit, and outputs the mode instruction signal Sm to the RTC 16, thereby setting the RTC 16 to one of the first mode and the second mode. .

  Specifically, the main control unit 17 sets the RTC 16 to the first mode when supply of the operating power supply Po to the supply target (the measurement unit 15 and the main control unit 17 itself) is started, and sets the supply target as the supply target. On the other hand, the RTC 16 is set to the second mode when a stop operation is performed by the power switch 13 while the operating power supply Po is supplied. Further, when the power supply unit 11 stops the input of the external power supply Pe while the operation power supply Po is supplied to the supply target (when the disconnection operation is performed on the main switch 12), the main control unit 17 Therefore, the RTC 16 maintains the mode set immediately before the main controller 17 stops operating.

  In addition, the main control unit 17 outputs a stop instruction signal Sc to the power supply unit 11 when the operation is stopped by the power switch 13 in a state where the operation power supply Po is supplied to the supply target. The supply of the operating power supply Po to the object is stopped.

  Next, operation | movement of the measuring apparatus 1 is demonstrated with reference to drawings. In the initial state, it is assumed that the RTC 16 is set to the first mode (a mode for outputting the CK signal Sck).

  In this measuring apparatus 1, when a connection operation is performed on the main switch 12 in a state where the power plug is inserted into a power outlet (none of which is shown), the power supply unit 11 inputs the external power supply Pe. . Next, the power supply unit 11 generates an operation power supply Po from the external power supply Pe. At this time, the generated power supply Po for operation is output to the power supply control unit 14, and the power supply control unit 14 operates.

  On the other hand, since the RTC 16 is set to the first mode in the initial state (that is, the power supply unit 11 inputs the external power supply Pe in the state where the RTC 16 is set to the first mode), the power control unit 14 The first supply process is executed. In this first supply process, when the power supply unit 11 inputs the external power supply Pe, the power supply control unit 14 measures the supply unit 15 and the main control unit 17 regardless of whether or not the power switch 13 is started. The supply of the operating power supply Po to is started.

  The first supply process will be described in detail with reference to FIGS. First, when the power supply unit 11 generates the operation power supply Po, the operation power supply Po is input to the power supply terminal in the FF 21 of the power supply control unit 14 and input to the D terminal (see FIG. 2) as the D signal Sd. (See FIG. 3). In addition, the operating power supply Po generated by the power supply unit 11 is supplied to the resistor 23 (see FIG. 2) of the power supply control unit 14, and is supplied to the PR terminal (see FIG. 2) of the FF 21 as a PR signal Spr (see FIG. 3). input.

  Further, the reset IC 22 (see FIG. 2) of the power supply control unit 14 inputs the operation power supply Po generated by the power supply unit 11. In this case, since the reset IC 22 has an input capacity inside, the voltage level of the input capacity charged by the operating power supply Po gradually increases immediately after the input of the operating power supply Po starts. Therefore, as shown in FIG. 3, when the level of the operating power supply Po reaches a predetermined level, the reset IC 22 converts the CLR signal Scrr (see FIG. 3) of the H signal (high level signal) into the FF 21. Output to the CLR terminal (see FIG. 2).

  On the other hand, in the initial state, since the RTC 16 set in the first mode outputs the CK signal Sck, the CK signal Sck is output to the CK terminal (see FIG. 2) of the FF 21 (see FIG. 3). . In this case, as shown in FIG. 3, the Q signal Sq of the H signal is output from the Q terminal in synchronization with the rise of the CK signal Sck immediately after the CLR signal Scrr of the H signal is input to the CLR terminal.

  Subsequently, as shown in FIG. 3, in response to the output of the Q signal Sq of the H signal, the power supply unit 11 operates a switch (not shown) to an ON state, and the measurement unit 15 and the main control unit as supply targets The supply of the operating power supply Po to 17 is started. Thereby, the main control part 17 starts and each process is started. Thus, when the power supply unit 11 inputs the external power supply Pe in a state where the RTC 16 is set to the first mode (when the connection operation to the main switch 12 is performed), Regardless of whether or not a start operation is performed on the power switch 13, a first supply process for immediately starting the supply of the operating power supply Po to the supply target is executed.

  Next, as shown in FIG. 3, the main control unit 17 outputs a mode instruction signal Sm for setting the mode of the RTC 16 to the first mode to the RTC 16. In this case, since the RTC 16 is already set to the first mode at this time, the RTC 16 maintains the state set to the first mode.

  Subsequently, when causing the measurement unit 15 to execute the measurement process, an operation unit (not shown) is operated to instruct the execution of the measurement process. In response to this, the main control unit 17 controls the measurement unit 15 to execute measurement processing.

  Next, when the measurement is completed, the supply of the operating power supply Po to the measurement unit 15 and the main control unit 17 as supply targets is stopped. Specifically, a push operation is performed on the power switch 13. In this case, as shown in FIG. 4, the resistor 23 is connected to a low potential (ground potential) only while the power switch 13 is being pushed, and the PR signal Spr of the L signal (low level signal) is Output to the PR terminal. At this time, the main control unit 17 outputs to the RTC 16 a mode instruction signal Sm for setting the mode of the RTC 16 to the second mode in synchronization with the falling of the PR signal Spr, as shown in FIG.

  Subsequently, the RTC 16 sets the second mode according to the mode instruction signal Sm, and stops the output of the CK signal Sck as shown in FIG. Next, as shown in the figure, the main control unit 17 outputs an H signal stop instruction signal Sc for stopping the supply of the operating power supply Po to the power supply unit 11. In this case, the power supply unit 11 stops the supply of the operating power supply Po to the measurement unit 15 and the main control unit 17 as the supply target in synchronization with the rise of the stop instruction signal Sc.

  Subsequently, the main switch 12 is disconnected. Thereby, as shown in FIG. 4, the power supply part 11 stops the input of the external power supply Pe, and stops the production | generation of the working power supply Po. As a result, the input of the PR signal Spr, the CLR signal Scrr and the D signal Sd and the output of the Q signal Sq are stopped. As described above, when the disconnection operation is performed on the main switch 12 after the push operation is performed on the power switch 13 to stop the supply of the operating power supply Po to the supply target, the RTC 16 is set to the second mode. After becoming the state, the generation of the operating power supply Po by the power supply unit 11 is stopped.

  Next, in the state where the RTC 16 is set to the second mode, when a connection operation to the main switch 12 is performed, the power supply unit 11 inputs the external power supply Pe, and the operation power supply Po from the external power supply Pe. Is generated.

  At this time, since the RTC 16 is set to the second mode, the power control unit 14 executes the second supply process. In this second supply process, the power supply control unit 14 is a measurement unit as a supply target when the power supply unit 11 is inputting the external power supply Pe and a push operation (start operation) is performed on the power switch 13. 15 and the supply of the operating power supply Po to the main control unit 17 are started.

  The second supply process will be described in detail with reference to FIGS. First, when the power supply unit 11 generates the operation power supply Po, the operation power supply Po is input to the power supply terminal and to the D terminal of the FF 21 (see FIG. 2). Further, the operating power supply Po is supplied to the resistor 23 (see FIG. 2) of the power supply control unit 14, and is input to the PR terminal (see FIG. 2) of the FF 21 as the PR signal Spr (see FIG. 5).

  Further, when the reset IC 22 (see FIG. 2) inputs the operation power supply Po and the level of the operation power supply Po reaches a predetermined level (a certain amount of time from the input time point of the operation power supply Po). When the time elapses, as shown in FIG. 5, the CLR signal Sclr of the H signal is output to the CLR terminal of the FF 21 (see FIG. 2).

  On the other hand, as shown in FIG. 5, since the RTC 16 is set to the second mode and does not output the CK signal Sck, the state where the Q signal Sq of the H signal is not output from the Q terminal continues.

  Subsequently, when a push operation is performed on the power switch 13, the resistor 23 is connected to a low potential (ground potential) only while the push operation is performed on the power switch 13, and the PR signal Spr is shown in FIG. As shown in FIG. At this time, since the L signal is input to the PR terminal and the H signal is input to the CLR terminal, the Q signal Sq of the H signal is output from the Q terminal as shown in FIG.

  In this case, when the Q signal Sq of the H signal is output from the Q terminal, the power supply unit 11 supplies the operating power supply Po to the measurement unit 15 and the main control unit 17 as supply targets, as shown in FIG. The main control unit 17 is activated to start each process. As described above, when the power supply unit 11 inputs the external power supply Pe in the state where the RTC 16 is set to the second mode (when the connection operation to the main switch 12 is performed), When supply of the operating power supply Po to the measuring unit 15 and the main control unit 17 as the supply target is not started immediately, but a standby operation is performed until a start operation (push operation) is performed on the power switch 13, and a start operation is performed The supply of the operating power supply Po to the supply target is started.

  Subsequently, as shown in FIG. 5, the main control unit 17 outputs a mode instruction signal Sm for setting the mode of the RTC 16 to the first mode to the RTC 16. Next, the RTC 16 is set to the first mode in synchronization with the rising of the mode instruction signal Sm, and starts outputting the CK signal Sck as shown in FIG.

  Subsequently, when causing the measurement unit 15 to execute the measurement process, an operation unit (not shown) is operated to instruct the execution of the measurement process. In response to this, the main control unit 17 controls the measurement unit 15 to execute measurement processing.

  On the other hand, when the measurement is finished, for example, when the disconnection operation is performed on the main switch 12 without performing the push operation on the power switch 13, the main control unit 17 connects the RTC 16 to the second switch as shown in FIG. Before the mode instruction signal Sm for setting the mode is output, the supply of the operating power supply Po to the main control unit 17 is stopped. Therefore, at this time, the RTC 16 is maintained in the state of the first mode (the mode immediately before the supply of the operating power supply Po to the main control unit 17 is stopped). When the connection operation to the main switch 12 is performed in this state (when the power supply unit 11 inputs the external power supply Pe), as described above, the power supply control unit 14 executes the first supply process, and the power switch Regardless of the presence or absence of the start operation for 13, the supply of the operating power supply Po to the supply target is immediately started.

  That is, in this measuring apparatus 1, the mode (disconnection method) when the power supply Po for operation is stopped is not recorded in the memory, and the mode of the RTC 16 when the connection operation is performed to the main switch 12 is performed. Thus, either the first supply process or the second supply process can be executed.

  As described above, the measurement apparatus 1 includes the RTC 16 that can be set to the first mode for outputting the CK signal Sck and the second mode for stopping the output of the CK signal Sck. The first supply process is executed when the power supply unit 11 is inputting the external power supply Pe in the state set to the mode 1, and the power supply unit 11 is externally connected in the state where the RTC 16 is set to the second mode. When the power supply Pe is input, the second supply process is executed. For this reason, in this measuring apparatus 1, the power supply unit 11 does not record information on which of the first supply process and the second supply process is executed in the memory when the power supply unit 11 inputs the external power supply Pe. Either the first supply process or the second supply process can be executed in accordance with the mode of the RTC 16 when the external power supply Pe is input to the apparatus 11. Therefore, according to the measurement apparatus 1, it is unnecessary to read information as compared with the configuration in which such information is recorded in the memory and the information is read from the memory when the supply of the operating power supply Po is started. Therefore, the start time of power supply to the supply target can be sufficiently shortened.

  Further, the measuring apparatus 1 includes a D-type flip-flop 21 to configure the power supply control unit 14. In this case, for example, in the configuration in which the main control unit 17 monitors the presence or absence of an operation on the power switch 13 when executing the second supply process, the operating power supply Po is constantly supplied to the main control unit 17 for monitoring. There is a need. On the other hand, in this measuring apparatus 1, without monitoring by such a main control unit 17, the operation of the power supply control unit 14 (D-type flip-flop 21) capable of reducing power consumption with a simple configuration is possible. When the power switch 13 is operated, the second supply process can be executed. For this reason, according to this measuring apparatus 1, as a result of being able to reduce power consumption for monitoring by the main control unit 17, it is possible to reduce power consumption.

  Further, according to the measuring apparatus 1, the main control unit 17 as a clock control unit that operates by the operation power source Po and controls the setting of the mode of the RTC 16 is provided, so that a power source different from the operation power source Po is provided. Since it is possible to reliably control the mode setting of the RTC 16 without providing a clock control unit that operates at the same time, it is not necessary to provide a separate power source for such a clock control unit, thereby simplifying the configuration. it can.

  Note that the electronic device is not limited to the above configuration. For example, the first supply process is executed when the power supply unit 11 inputs the external power supply Pe while the RTC 16 is set to the first mode, and the power supply unit is set while the RTC 16 is set to the second mode. The configuration example in which the second supply process is executed when the external power source Pe inputs the external power source Pe has been described above, but conversely, the power source unit 11 is in the external power source Pe with the RTC 16 set to the second mode. A power supply control unit that executes the first supply process when the RTC 16 is set to the first mode and executes the second supply process when the power supply unit 11 inputs the external power supply Pe. The configuration can also be adopted. In this configuration, the above-described power control is performed by controlling the power supply unit 11 using the output signal (Q bar signal) of the Q bar terminal in the D flip flop having the Q bar terminal in the D flip flop 21 described above. Processing similar to that of the unit 14 can be executed by the power supply control unit.

  Further, the example in which the D-type flip-flop 21 is operated by the operating power supply Po has been described above. However, the configuration in which the D-type flip-flop 21 is operated by a power source (for example, a battery power source) different from the operating power source Po is adopted. You can also.

  In addition, the example in which the setting of the mode of the RTC 16 is controlled using the main control unit 17 as the clock control unit that operates with the operation power supply Po has been described above. However, a power supply other than the operation power supply Po (for example, a battery power supply) It is also possible to employ a configuration in which the setting of the mode of the RTC 16 is controlled using the clock control unit that operates at

  Further, although the example in which the power supply control unit 14 is configured by including the D-type flip-flop 21 has been described above, the power supply control unit 14 can also be configured by including other types of flip-flops. In place of the reset IC 22, the power supply control unit can be configured using a delay circuit that delays the CLR signal Scrr (inputs the CLR signal Scr later than the PR signal Spr).

  Moreover, although it described above about the example applied to the measuring apparatus 1 as an example of an electronic device, it can apply to various electronic devices which require power supply, such as a recorder, an inspection apparatus, and household appliances, for example.

DESCRIPTION OF SYMBOLS 1 Measuring apparatus 11 Power supply part 12 Main switch 13 Power switch 14 Power supply control part 15 Measurement part 16 Real time clock 17 Main control part 21 D-type flip-flop Pe External power supply Po Operation power supply Sck CK signal Scrl CLR signal Sd D signal Spr PR signal Sq Q signal

Claims (3)

A power supply unit that generates an operation power supply from the external power supply when an external power supply is input, a start operation that instructs a supply start of the operation power supply to a supply target, and a stop operation that instructs a supply stop of the operation power supply And a first supply process for supplying the generated operating power to the supply target regardless of whether or not the start operation is performed on the operation unit when the power supply unit inputs the external power. A power supply control unit for executing a second supply process for supplying the generated operating power supply to the supply target when the power supply unit is inputting the external power supply and the start operation is performed; With
A real-time clock that can be set to a first mode that always operates with an internal power supply and that outputs a clock signal and a second mode that stops outputting the clock signal,
The power supply control unit operates regardless of whether or not the start operation is performed, and the power supply unit is in a state where the real-time clock is set to one of the first mode and the second mode. The first supply process is executed when the unit inputs the external power source, and the real-time clock is set to the other mode of the first mode and the second mode. An electronic device that executes the second supply process when a power supply unit inputs the external power supply.   The power control unit includes a CLR terminal for inputting a clear signal based on the power supply for operation, a PR terminal for inputting an operation signal output at the time of a start operation, a D terminal for inputting a D signal based on the power supply for operation, The power supply unit comprises a CK terminal for inputting the clock signal, and a D-type flip-flop having a Q terminal for outputting a Q signal for instructing the power supply unit to start supplying the operating power supply. 2. The electronic device according to claim 1, wherein the first supply process and the second supply process are executed by outputting and stopping the output of the Q signal according to whether the external power source is input and whether the clock signal is output. machine.   When the operation power supply is supplied to the supply target, the operation power supply operates and the real-time clock is set to one of the modes, and the operation power supply is supplied to the supply target. 3. The electronic device according to claim 1, further comprising a clock controller configured to set the real-time clock to the other mode when the stop operation is performed in a state where the operation is stopped.

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