JP4336799B2 - Portable electronic device, power supply control circuit and control method for portable electronic device - Google Patents

Description

  The present invention relates to a control circuit for a power supply circuit having a plurality of types of output voltages. In particular, the present invention relates to a control circuit for a power supply circuit that generates a plurality of types of power supply voltages from a single-voltage power supply used in portable electronic devices such as mobile phones.

  Today, electronic devices such as mobile phones, PDAs, PHSs, televisions, personal computers, and the like continue to be miniaturized, integrated, and highly functionalized, and various electronic circuits are mounted at high density inside. In particular, electronic devices that are carried and used, such as mobile phones, PHS, PDA, and MD players, are required to be further downsized and integrated.

  Electronic devices are composed of various electronic components. Electronic components may require unique voltages due to their physical characteristics. For example, an LSI requires a specific drive voltage depending on the process, and a liquid crystal backlight requires a specific drive voltage due to diode characteristics. As a result, the electronic device may require a plurality of types of power supply voltages inside.

  Therefore, conventionally, a configuration has been used in which a voltage conversion circuit is inserted between each of a plurality of electronic components that require individual power supply voltages.

  Typical examples of the voltage conversion circuit are a regulator and a DC-DC converter. However, when a plurality of voltages lower than the battery voltage are produced, the regulator is more advantageous in terms of miniaturization. This is because the DC-DC converter has a large circuit scale and is likely to cause noise. However, in order to make a voltage higher than the battery voltage, there is no choice but to use a DC-DC converter.

  In an electronic device using a circuit using a voltage converter such as a regulator, there is the following document as a prior art for extending the battery life.

  Publication 1 discloses a circuit having a power storage unit, a regulator that converts the output voltage of the power storage unit, a control circuit that uses the output of the regulator as a power source, and a storage amount detection circuit that monitors the power of the power storage unit. And monitoring the output of the storage amount detection circuit, and when the remaining amount of power is reduced below a predetermined value by a voltage signal from the storage portion, the operation of the regulator is stopped and the storage portion and the control circuit are connected. It is disclosed that the battery usage period is extended by direct connection (Patent Document 1).

  Publication 2 discloses a circuit including an LSI that can operate at half the power supply voltage in the initial state, and the LSI is connected to the power supply via a step-down circuit that reduces the output of the power supply voltage to 1/2. In the case where the output voltage of the power supply is lowered due to aging, the LSI is disclosed to switch the connection directly to the power supply without going through the step-down circuit (Patent Document 2). In the publication 2, since the battery can be used even when the power supply voltage is lowered due to secular change, the usable period of the battery can be extended.

  Publication 3 is a stabilized power supply device for a system control circuit that is used for cordless electronic equipment and does not match the output voltage of a battery, and has a current monitor. When the load current is small, a series regulator is used. A circuit that supplies power to the system control circuit from a high-efficiency switching regulator in addition to the series regulator is disclosed in the case where the output of the battery is supplied to the system control circuit via a power supply and the load current is large. (Patent Document 3).

  Although there are conventional techniques as described above, in general, a regulator consumes power by the product of the voltage difference between the input and output generated in the regulator and the current flowing through the regulator. In a circuit using a regulator, when the power consumption of a circuit subsequent to the regulator increases, the current flowing through the regulator also increases and the power consumed by the regulator increases. This power consumption is not preferable because it reduces the power that can be consumed by a circuit subsequent to the regulator.

  The power that can be stored in the battery is limited. Therefore, it is necessary to reduce the power consumption of the portable electronic device in order to reduce the trouble of charging the battery and to drive the portable electronic device comfortably for a long time. In addition, power consumption is accompanied by heat generation, which hinders high-density mounting. Since there is a strong demand for miniaturization and integration of portable electronic devices, it is necessary to reduce the power consumption of portable electronic devices also from this point.

JP2002-034148 JP-A-01-187614 JP-A-01-008933

  The problem to be solved by the present invention is to reduce the power consumption of a portable electronic device. Another object of the present invention is to reduce power consumption of a portable electronic device equipped with an electronic circuit that requires a plurality of individual voltages.

  Another object of the present invention is to increase the driving time of the portable electronic device by reducing the power consumption of the portable electronic device.

  Another object of the present invention is to suppress the heat generation of the portable electronic device by reducing the power consumption of the portable electronic device and to mount the electronic circuits of the portable electronic device with high density.

  Another object of the present invention is to reduce power consumption by appropriately controlling the power supply when the load on the electronic circuit fluctuates in real time.

  Another object of the present invention is to dynamically optimize the applied voltage of a regulator in accordance with the current flowing through the regulator in a circuit using the regulator.

In order to solve the above problems, the present invention is a power supply control circuit of a portable electronic device, a power supply circuit including a plurality of regulators, a battery, a resistor provided between the battery and the power supply circuit, A DC-DC converter provided in parallel with the resistor between the battery and the power supply circuit; a switch for switching an output of the battery to either the resistor or the DC-DC converter; and the resistor Detecting means for detecting a load current flowing through the battery, the output of the battery is connected to the resistor, and the output current of the battery is equal to or greater than a first predetermined value when the DC-DC converter is in a stopped state. Is continued for a first predetermined period, the detection means controls the switch to switch the output of the battery to the DC-DC converter, and starts the operation of the DC-DC converter, The battery Is connected to the DC-DC converter in operation, and the DC-DC converter is in a state where the efficiency of the DC-DC converter is kept below a second predetermined value for a second predetermined period, the DC-DC The converter controls the switch to switch the output of the battery to the resistor and stops its operation .

In order to solve the above problems, the present invention provides a power supply circuit including a plurality of regulators, a battery, a resistor provided between the battery and the power supply circuit, and between the battery and the power supply circuit. A DC-DC converter provided in parallel with the resistor, a switch for switching the output of the battery to either the resistor or the DC-DC converter, and detection means for detecting a load current flowing through the resistor A control method for a power supply control circuit of a portable electronic device comprising: the output of the battery is connected to the resistor, and the output current of the battery is a first when the DC-DC converter is in a stopped state. When the state equal to or greater than the predetermined value continues for a first predetermined period, the detection means controls the switch to switch the output of the battery to the DC-DC converter, and the DC-DC converter Start working When the output of the battery is connected to the operating DC-DC converter, the efficiency of the DC-DC converter continues to be below a second predetermined value for a second predetermined period. The DC-DC converter controls the switch to switch the output of the battery to the resistor and stops its own operation .

In order to solve the above problems, a portable electronic device according to the present invention includes a power supply circuit including a plurality of regulators, a battery, a resistor provided between the battery and the power supply circuit, the battery and the power supply. A DC-DC converter provided in parallel with the resistor between the circuit, a switch for switching the output of the battery to either the resistor or the DC-DC converter, and a load current flowing through the resistor Detecting means for detecting, and when the output of the battery is connected to the resistor and the DC-DC converter is in a stopped state, a state in which the output current of the battery is equal to or higher than a first predetermined value is a first predetermined value. When the period continues, the detection means controls the switch to switch the output of the battery to the DC-DC converter and starts the operation of the DC-DC converter. In operation When the DC-DC converter is connected to the C-DC converter and the efficiency of the DC-DC converter continues to be equal to or lower than a second predetermined value for a second predetermined period, the DC-DC converter A power supply control circuit is provided for controlling the switch to switch the output of the battery to the resistor and stopping its own operation .

  According to the present invention, it is possible to reduce power consumption by performing optimal power supply switching in accordance with the size of the load in real time.

  According to the present invention, low power consumption can be realized, so that a portable electronic device using a battery as a power source can be driven for a long time.

  According to the present invention, since an efficient power supply circuit can be realized with a small circuit scale, the portable electronic device can be miniaturized.

  According to the present invention, the power generation of the portable electronic device can be reduced and the heat generation can be suppressed, so that the circuit can be mounted at high density.

  According to the present invention, power consumption of a power supply circuit including a regulator as a plurality of transformer circuits can be reduced.

  According to the present invention, in a circuit using a regulator, the applied voltage of the regulator can be dynamically optimized according to the current flowing through the regulator.

  The best mode for carrying out the present invention will be described. The embodiment described below does not limit the technical scope of the present invention.

  A first embodiment of the present invention will be described. FIG. 1 is a block diagram showing a configuration of a portable electronic device including a power supply control circuit according to the present invention. In the block diagram, circuit portions not related to the present invention are omitted.

  The main battery 1 is a battery used as a power source for portable electronic devices. Preferred are lithium ion batteries and nickel metal hydride batteries. Hereinafter, a lithium ion battery will be described as an example. The power supply circuit 2 is a power supply circuit composed of a plurality of transformers, and outputs a plurality of types of voltages from a single input voltage. In the present embodiment, the power supply circuit 2 includes regulators (hereinafter abbreviated as REG) 21, 22, 24, 25 and a DC-DC converter 23. The output of the power supply circuit 2 is used as a power supply for a plurality of devices such as the communication system device 3 described below.

  The communication system device 3 is a circuit having a communication function, and includes a modem, a transmission amplifier, a reception amplifier, and the like. The diode 4 is a diode for preventing a backflow of current from the backup battery 11. The clock function device 5 is a circuit having a clock function. The display unit 6 is a display circuit composed of an LCD or the like. The application device 7 is a circuit composed of a sound source circuit, a camera module, and the like. The control system device 8 is a circuit having a control function for the entire portable electronic device, and includes a CPU and a memory, and controls the communication system device 3 and the like through a bus.

  The backup memory 9 is a memory for holding data that needs to be held even when the main battery 1 does not operate, such as the calling telephone number of the mobile electronic device itself. The backup battery 11 is a battery that supplies power to the clock function device 5 and the backup memory 9. The resistor 10 is used to limit the current of the backup battery 11 when the main battery 1 is charged.

  The data input unit 12 is a component composed of key buttons and the like, and is used for data input by a user of the portable electronic device. The power supply circuit power supply voltage detecting means 13 is a circuit for detecting an input voltage supplied to the power supply circuit 2. The load current detection means 14 is a load current flowing through the resistor 16 from the voltage value of the main battery 1 supplied from the battery voltage detection means 15 and the input voltage value of the power supply circuit 2 supplied from the power supply voltage detection means 13 for power supply circuit. Is a circuit for detecting When the load current exceeds a predetermined current value, a signal for turning on the DC-DC converter is output.

  The load current detection means 14 does not operate when the DC-DC converter 18 is in an operating state, and operates only when the DC-DC converter 18 is in a non-operating state. The load current detection unit 14 determines the operation or non-operation of the DC-DC converter 18 based on a signal from the DC-DC converter 18. Note that the load current detection unit 14 has the control circuit (not shown) inside to perform the above operation.

  The battery voltage detection means 15 is a circuit that measures and outputs the voltage of the main battery 1, and preferably comprises a voltage device. The resistor 16 is a high-precision low-resistance resistor that is inserted between the main battery 1 and the power supply circuit 2. The resistor 16 is used for current monitoring. The switch 17 is a switch that is turned on or off based on a switch control signal from the DC-DC converter 18 and the load current detection means 14. The DC-DC converter 18 is a switching type transformer.

  Next, the characteristics of the DC-DC converter 18 will be described with reference to FIGS.

  FIG. 3 shows the relationship between the output current and efficiency of a general DC-DC converter. Here, the efficiency is a ratio of input power (voltage × current) to output power (voltage × current). The higher the efficiency, the more input power is transferred to the output. In FIG. 3, the DC-DC converter has a characteristic that the efficiency is high when the output current is large, and the efficiency is low when the output current is small, and the loss inside the DC-DC converter increases. ing.

  The DC-DC converter 18 of the present embodiment has characteristics as shown in FIG. 3, and the efficiency is 90% at 100 mA to 200 mA.

  FIG. 4 shows a case where the output of the main battery 1 is connected to the power supply circuit 2 via the DC-DC converter 18 (hereinafter referred to as DC-DC converter operation), and the output of the main battery 1 is switched to the switch 17 and the resistor. 16 is a graph comparing the output of the main battery 1 when connected to the power supply circuit 2 via 16 (hereinafter referred to as battery operation).

  A line 401 represents a battery operation in the case of a load current of 200 mA. Line 402 represents the DC-DC converter operation for a load current of 200 mA. A line 403 represents the battery operation when the load current is 100 mA. Line 404 represents the DC-DC converter operation for a load current of 100 mA. On the lines 402 and 404, the output voltage of the DC-DC converter 18 is 3.0V. Here, the load current indicates a current required for the power supply circuit 2.

  FIG. 5 is also a graph similar to FIG. 4 is different from FIG. 4 in that the output voltage of the DC-DC converter 18 is 3.0 V in FIG. 4 and is 2.8 V in FIG.

  A line 501 represents the battery operation when the load current is 200 mA. Line 502 represents the DC-DC converter operation for a load current of 200 mA. A line 503 represents the battery operation when the load current is 100 mA. Line 504 represents the DC-DC converter operation for a load current of 100 mA.

  Since the lithium ion battery used as the main battery 1 in this embodiment has a flat characteristic around 3.7 V, the operation of the DC-DC converter is around 3.7 V from FIGS. 4 and 5. Compared to battery operation, the output current of the main battery 1 is reduced by about 10%. That is, the power consumption of the main battery 1 is smaller in the DC-DC converter operation than in the battery operation.

  FIG. 6 is a graph comparing the output current of the main battery 1 in the case of DC-DC converter operation and in the case of battery operation, as in FIGS. 4 and 5.

  Since the DC-DC converter 18 of the present embodiment has the characteristics as shown in FIG. 3, the efficiency at 20 mA to 40 mA is about 70%.

  Line 601 represents the DC-DC converter operation for a load current of 40 mA. A line 602 represents the battery operation when the load current is 40 mA. Line 603 represents the DC-DC converter operation for a load current of 20 mA. A line 604 represents the battery operation in the case of a load current of 20 mA. In the lines 601 to 604, the output voltage, that is, the input voltage of the power supply circuit 2 is 3.0V.

  FIG. 7 is a graph similar to FIG. 6 is different from FIG. 6 in that the output voltage of the DC-DC converter 18 is set to 3.0 V in FIG. 6 and is set to 2.8 V in FIG.

  Line 701 represents the DC-DC converter operation for a load current of 40 mA. A line 702 represents the battery operation when the load current is 40 mA. Line 703 represents the DC-DC converter operation for a load current of 20 mA. A line 704 represents a battery operation in the case of a load current of 20 mA.

  In the case of FIG. 6 and FIG. 7, the output current of the main battery 1 is reduced by about 10% in the vicinity of 3.7 V in the battery operation compared to the DC-DC converter operation.

  As described above, due to the characteristics of the DC-DC converter 18, when the current required by the power supply circuit 2 is large, the DC-DC converter operation requires less power consumption of the main battery 1. On the other hand, when the current required by the power supply circuit 2 is small, the battery operation requires less power consumption of the main battery 1.

  Therefore, power consumption can be reduced by controlling whether to supply power to the power supply circuit 2 via the DC-DC converter 18 according to the magnitude of the output current of the main battery 1. .

  Next, the operation of the power supply control circuit according to the first embodiment of the present application will be described. In this embodiment, at the start of operation, the switch 17 is turned on and the DC-DC converter 18 is in a non-operating state. The portable electronic device starts to operate simultaneously with power-on, and supplies current to the power supply circuit 2 via the resistor 16 and the switch 17. The power supply circuit 2 uses the REGs 21, 22, 24, 25 and the DC-DC converter 23 included therein to convert the input voltage from the main battery 1 to the communication system device 3, the clock function device 5, and the backup memory 9, respectively. The voltage is converted into a voltage suitable for the display unit 6, the application device 7, and the control system device 8 and output. As a result, each device is applied with a voltage suitable for the device and starts operating normally.

  The power consumption of the circuit group in the subsequent stage of the power supply circuit 2 including the communication system device 3 varies depending on the operation. For example, when the application is operated, since the application device 7 operates, the power consumption increases and the current flowing through the REG 24 increases. Further, for example, the communication communication device 3 varies in power consumption depending on whether or not the portable electronic device is communicating, and if communication is in progress, the wireless communication environment varies depending on the environment.

  Next, the operation based on the power supply voltage detecting means 13 for the power supply circuit, the load current detecting means 14, the battery voltage detecting means 15, the resistor 16, the switch 17, and the DC-DC converter 18 will be described. When the portable electronic device is operating on a battery, if the power consumption of the subsequent circuit of the power supply circuit 2 such as the communication device 3 increases and the output current of the main battery 1 increases, the input voltage of the power supply circuit 2 becomes the load The current drops from the output voltage of the main battery 1 by the voltage drop caused by the resistor 16. The input voltage of the power supply circuit 2 is detected by the power supply voltage detection means 13 for power supply circuit. On the other hand, the output voltage of the main battery 1 is detected by the battery voltage detection means 15. Based on these two voltage values and the resistance value of the resistor 16, the load current detection means 14 measures the output current of the main battery 1.

  When the load current detection unit 14 detects that the output current of the main battery 1 is greater than or equal to a predetermined value and this state continues for a certain period, the load current detection unit 14 sends a switch OFF signal to the switch 17. Is output. Upon receiving the signal, the switch 17 cuts off the current path between the main battery 1 and the resistor 16.

  On the other hand, along with the output of the OFF signal to the switch 17, the load current detection means 14 outputs an operation start signal to the DC-DC converter 18. The DC-DC converter 18 that has received the signal starts a step-down operation.

  When the portable electronic device is operating as a DC-DC converter, when the output current of the main battery 1 decreases, the DUTY of the output of the buffer 120 inside the DC-DC converter 18 decreases as will be described later. To do. When the decrease in DUTY falls below a predetermined value, the DC-DC converter 18 stops its operation and turns on the switch 17.

  With the above configuration, when the amount of current from the main battery 1 becomes large while the portable electronic device is operating on the battery, the switch 17 is turned off and the power is supplied from the main battery 1 via the DC-DC converter 18. When power is supplied to the circuit 2 and the amount of current from the main battery 1 becomes small while the portable electronic device is operating as a DC-DC converter, the DC-DC converter 18 is turned off, the switch 17 and the resistor By supplying power from the main battery 1 to the power supply circuit 2 via 16, it is possible to perform optimal power supply corresponding to dynamic fluctuations in the current consumption of the power supply circuit 2.

  The predetermined value is preferably set to a value that reverses the power consumption of the circuit between the DC-DC converter operation and the battery operation. Further, in consideration of manufacturing variation of each circuit and instantaneous disturbance of circuit operation, hysteresis may be provided for a predetermined value or a width may be provided. For example, it is also preferable that the threshold value for switching from the DC-DC converter operation to the battery operation is 50 mA, and the threshold value for switching from the battery operation to the DC-DC converter operation is 60 mA.

  FIG. 2 is a block diagram showing the configuration of the DC-DC converter 18 of the power supply control circuit according to the present invention.

  A resistor 101 and a resistor 102 constitute a voltage dividing circuit for the output of the DC-DC converter 18. The reference voltage circuit 103 outputs a reference voltage Vref. The error amplifier 105 compares the output of the voltage dividing circuit with the output voltage Vref of the reference voltage circuit 103, and outputs a voltage proportional to the input voltage difference. If the reference voltage Vref is larger than the output of the voltage dividing circuit, a positive voltage is output. If the reference voltage Vref is smaller than the output of the voltage dividing circuit, a negative voltage is output.

  The oscillator 104 is an oscillator that outputs an AC signal. The comparator 115 compares the output of the oscillator 104 with the output of the error amplifier 105. If the output of the error amplifier 105 is larger than the output of the oscillator 104, High is output. If the output of the error amplifier 105 is smaller than the output of the oscillator 104, Low is output. The comparator 115 is also connected to the output of the protection circuit 111. When the output of the protection circuit 111 is High, the output of the comparator 115 outputs High regardless of the values of the other two inputs.

  The buffers 106 and 116 are buffers with an enable function for driving the FET. When Low is input to the enable pin, the buffer functions. When High is input to the enable pin, an open output is performed regardless of the input value of the buffer. The buffer 120 is a buffer that inverts the output of the buffer 106.

  The resistor 117 is a pull-up resistor, and the resistor 118 is a pull-down resistor. This is used to prevent the input levels of the FETs 107 and 108 from becoming unstable when High is input to the enable pins of the buffers 106 and 116 and the output is open.

  The transistor 107 is a Pch MOSFET, and the transistor 108 is an Nch MOSFET. The coil 109 is connected to the outputs of the transistors 107 and 108. A smoothing function of the output voltage is realized by the capacitor 110 and the coil 109.

  The MAXDUTY detection circuit 112 is a circuit that monitors the output of the buffer 120. When the output DUTY of the buffer 120 is equal to or greater than a predetermined value, High is output to the protection circuit 111. Further, when the output DUTY of the buffer 120 is smaller than a predetermined value, Low is output to the protection circuit 111. The protection circuit 111 buffers the output of the MAXDUTY detection circuit 112 and inputs it to the comparator 115.

  The MINDUTY detection circuit 113 is a circuit that monitors the output of the buffer 120. When the DUTY output from the buffer 120 is equal to or smaller than a predetermined value, Low is output to the delay circuit 114. Further, when the DUTY output from the buffer 120 is larger than a predetermined value, High is output to the delay circuit 114.

  The delay circuit 114 outputs Low when the MINDUTY detection circuit 113 outputs Low during a predetermined period. On the other hand, if the MINDUTY detection circuit 113 does not continue to output Low during a predetermined period, it outputs High. The output of the delay circuit 114 is connected to the input of the controller 119.

  The controller 119 is a circuit that controls the DC-DC converter 18 and the switch 17 and controls communication with the load current detection means 14. The controller 119 is connected to the delay circuit 114, the buffers 106 and 116, the switch 17, and the load current detection unit 14. The operation or non-operation of the DC-DC converter 18 is controlled by the output to the enable terminals of the gates 106 and 116. When the output from the delay circuit 114 becomes Low when the DC-DC converter 18 is in an operating state, the output to the gates 106 and 116 is set to High, so that the operation of the DC-DC converter 18 is performed. And the switch 17 is turned on.

  On the other hand, when the DC-DC converter 18 is in the non-operating state and the control signal for turning on the DC-DC converter 18 is input from the load current detection means 14, the gates 106 and 116 are connected to the enable terminals. By making the output low, the DC-DC converter 18 is put into an operating state.

  The controller 119 notifies the load current detecting means 14 at least every switching of the operation state whether the DC-DC converter 18 is in an operation state or a non-operation state.

  Next, details of the operation of the DC-DC converter 18 will be described. First, the case where the DC-DC converter 18 is in an operating state will be described. In the operation state, Low is output from the controller 119 to the buffers 106 and 116, and the buffers 106 and 116 are in an enabled state and function as normal buffers. The output of the protection circuit 111 is also Low, and the comparator 115 compares the outputs of the oscillator 104 and the error amplifier 105.

  First, for the sake of explanation, it is assumed that the output of the oscillator 104 is directly connected to the buffers 106 and 116.

  In that case, the FET 107 and the FET 108 are alternately turned on and off in accordance with the output frequency of the oscillator 104. When the DUTY of the output of the oscillator 104 is 50% (the ratio of High and Low is 1: 1), the input of the coil 109 has the same time ratio as the output voltage of the main battery 1 and the 0V voltage as the ground. Based on the output frequency of 104, they are alternately connected.

  The output voltage of the FETs 107 and 108 is smoothed by the coil 109 and the capacitor 110 and output from the DC-DC converter 18. In this case, ideally, a voltage half the output voltage of the main battery 1 is output from the DC-DC converter 18.

  However, the actual DC-DC converter 18 does not have a configuration in which the output of the oscillator 104 is directly connected to the buffers 106 and 116, and the output of the DC-DC converter 18 is connected to the resistors 101 and 102 and the reference voltage circuit 103. In this configuration, the error amplifier 105 and the comparator 115 are used for feedback.

  The output of the DC-DC converter 18 is divided by the resistors 101 and 102, and the divided voltage is compared with the output of the reference voltage circuit 113 by the error amplifier 105. When the divided voltage is larger, that is, when the output of the DC-DC converter 18 is larger than a predetermined voltage, the error amplifier 105 outputs a positive voltage.

  When the error amplifier 105 outputs a positive voltage, the output of the comparator 115 becomes higher than the DUTY of the AC output of the oscillator 104 (high time ratio is high).

  As a result, the output DUTY of the buffer 106 and the buffer 116 also increases. The FET 108 is turned on for a longer time than the FET 107, and the output of the DC-DC converter 18 smoothed by the coil 109 and the capacitor 110 becomes low.

  When the output of the DC-DC converter 18 is smaller than the predetermined voltage, the output of the DCDC converter circuit 18 is increased as a result of performing the reverse operation of the above operation. In this way, feedback is applied so that the divided voltage by the resistors 101 and 102 of the output of the DC-DC converter 18 becomes the reference voltage Vref.

  Further, when the output current of the DC-DC converter 18 is large, since the outflow current from the capacitor 110 is large, the voltage of the capacitor 110 immediately decreases. Therefore, due to the above mechanism, the output DUTY of the buffers 106 and 116 is reduced. On the other hand, when the output current of the DC-DC converter 18 is small, the DUTY of the outputs of the buffers 106 and 116 increases.

  Since the outputs of the buffers 106 and 116 and the output of the buffer 120 are inverted, when the output current of the DC-DC converter 18 increases, the DUTY of the output of the buffer 120 increases and the output of the DC-DC converter 18 increases. As the output current decreases, the output DUTY of the buffer 120 decreases.

  Next, the MAXDUTY circuit 112 will be described. The MAXDUTY detection circuit 112 fixes the output of the buffer 115 to High through the protection circuit 111 when the DUTY of the output of the buffer 120 becomes higher than a predetermined value. As a result, the FET 107 is turned off, the FET 108 is turned on, the input voltage of the coil 109 becomes 0V, and the output smoothed by the coil 109 and the capacitor 110 approaches 0V. As described above, the configuration in which the DUTY of the output of the buffer 106 cannot exceed the predetermined threshold value prevents the DC-DC converter 18 from outputting an excessive current.

  Next, operations of the MINDUTY detection circuit 113, the delay circuit 114, and the controller 119 will be described.

  When the output current of the DC-DC converter 18 decreases, the DUTY of the buffer 120 decreases. That is, the efficiency of the DC-DC converter 18 can be monitored by detecting the DUTY output from the buffer 120.

  The MINDUTY detection circuit 113 outputs Low when the DUTY of the buffer 120 is less than or equal to the threshold value. The delay circuit 114 sets the output to Low when the output of the MINDUTY detection circuit 113 is Low for a predetermined period.

  When the output from the delay circuit 114 becomes Low when the DC-DC converter 18 is in an operating state, the controller 119 sets the output to the gates 106 and 116 to High so that the DC-DC conversion is performed. The operation of the device 18 is stopped and the switch 17 is turned on by using a control signal to the switch 17.

  Next, the case where the DC-DC converter 18 is in a non-operating state will be described. When a control signal for turning on the DC-DC converter 18 is input from the load current detection unit 14, the controller 119 sets the outputs to the enable terminals of the gates 106 and 116 to Low, and the DC-DC converter 18. Start operation.

  Next, the operation of the present invention will be described using a timing chart. FIG. 8 shows the timing when transitioning from battery operation to DC-DC converter operation. In FIG. 8A, the vertical axis represents the input voltage of the power supply circuit 2, and the horizontal axis represents time. In FIG. 8B, the vertical axis represents the current output from the main battery 1, and the horizontal axis represents time. In FIG. 8C, the vertical axis represents the logic level of the load current detection signal, which is an internal signal of the load current detection means 14, and the logic level of the DC-DC converter ON / OFF signal of the load current detection means 14, The horizontal axis is time.

  First, during the battery operation of the portable electronic device, when the power required by the power supply circuit 2 increases, the current output from the main battery 1 increases. As the current increases, the voltage drop generated by the resistor 16 increases. At time t0, the load current detection unit 14 detects from the voltage difference between both ends of the resistor 16 that the current flowing through the resistor 17 has exceeded a predetermined maximum current value.

  The load current detection means 14 internally changes the load current detection signal from the OFF level to the ON level. Subsequently, when the load current flowing through the resistor 16 exceeds the maximum current value for a predetermined period (between t0 and t1), the load current detecting means 14 detects the ON / OFF signal of the DCDC conversion circuit 18. Is switched from OFF to ON, and the switch 17 is turned OFF.

  As a result, at time t1, the DC-DC converter 18 starts operating, and the switch 17 cuts off the current path between the main battery 1 and the resistor 16.

  Next, switching from the DC-DC converter operation to the battery operation will be described with reference to FIG. In FIG. 9A, the vertical axis represents the input voltage of the power supply circuit 2, and the horizontal axis represents time. In FIG. 9B, the vertical axis represents the current output from the main battery 1, and the horizontal axis represents time. 9C, the vertical axis represents the logic level of the PWM signal that is the output of the buffer 120, and the horizontal axis represents time. In FIG. 9D, the vertical axis represents the output logic level of the MINDUTY detection circuit and the output logic level of the delay circuit 114, respectively, and the horizontal axis represents time.

  In the portable electronic device in the DC-DC converter operation state, when the power consumption of the entire device is reduced and the output current from the main battery 1 is reduced, the DUTY of the PWM signal in the DC-DC converter 18 is reduced. . The MINDUTY detection circuit 112 in the DCDC conversion circuit 18 switches the output from High to Low when the DUTY of the PWM signal decreases a predetermined threshold (time t0). After a lapse of a predetermined time after the output of the MINDUTY detection circuit 113 becomes low (t1), the output of the delay circuit 114 also becomes low.

  When the output of the delay circuit 114 becomes Low, the controller 119 sets the enable of the buffers 106 and 116 to High, thereby stopping the operation of the DC-DC converter 18 and turning on the switch 17, thereby Is switched to battery operation.

  FIG. 10 shows the flow of switching between DC-DC converter operation and battery operation. S1001, S1002, and S1003 are configured in a DC-DC converter operation state, and S1004, S1005, and S1006 are configured in a battery operation state.

  When the portable electronic device is turned on, the process starts and the battery operation starts (S1004). Next, the voltage difference between both ends of the resistor 16 is measured to determine whether or not the voltage difference exceeds a predetermined value (S1005). If it does not exceed the predetermined value (S1005, NO side), the voltage difference between both ends of the resistor 16 is repeatedly measured to determine whether it exceeds the predetermined value. On the other hand, if it exceeds the predetermined value (S1005, YES side), it is determined whether or not a predetermined time elapses when the predetermined value is exceeded (S1006). When the voltage difference between both ends of the resistor 16 exceeds the predetermined value and the predetermined time has not elapsed (S1006, NO side), the battery operation is continued and the process returns to S1005. On the other hand, when the predetermined time has passed in the state where the voltage difference between both ends of the resistor 16 exceeds the predetermined value (S1006, YES side), the battery operation is terminated and the operation of the DC-DC converter operation is started (S1001). .

  Next, when the operation of the DC-DC converter is started, the DUTY of the output of the buffer 106 is detected. It is determined whether or not the detected DUTY is below the minimum value (S1002). If it is not below the minimum value (S1002, NO side), it is determined whether the repeatedly detected DUTY is below the minimum value. On the other hand, when the value is below the minimum value (S1002, YES side), it is determined whether or not a predetermined time elapses while the value is below the minimum value (S1003). If the predetermined time has not elapsed in the state where the output DUTY of the buffer 106 is below the minimum value (S1003, NO side), the DC-DC converter operation is continued, and the process returns to S1002. On the other hand, when the predetermined time has elapsed in the state where the output DUTY of the buffer 106 is below the minimum value (S1003, YES side), the DC-DC converter operation is terminated and the battery operation is started (S1004).

As another embodiment, a variation to the first embodiment will be described.

  In the first embodiment, FIG. 10 shows a mode in which the battery operation is started immediately after the start, but the DC-DC converter operation may be started immediately after the start.

  4 and 5, it can be seen that when the battery voltage is around 3.2 V, the efficiency of the battery operation and the DC-DC converter operation is reversed. Therefore, when the battery voltage is smaller than 3.2 V, a restriction may be provided so as not to follow the DC-DC converter operation even if the amount of current of the main battery 1 increases.

  In the first embodiment, the control circuit inside the load current detection unit 14 and the controller 119 of the DC-DC converter 18 are switched between the DC-DC converter operation and the battery operation. Functions may be realized using the device 8.

  In the first embodiment, the battery operation is stopped or started and the DC-DC converter operation is started or stopped at the same time. However, in order to avoid an instantaneous interruption of the power supply to the power supply circuit 2, control different from this is performed. You may go. For example, referring to FIG. 8, when the battery operation is stopped and the DC-DC converter operation is started, the operation start timing of the DC-DC converter may be set earlier than t1. Further, for example, a large-capacitance capacitor for avoiding a momentary interruption can be inserted into the input of the power supply circuit 2.

  In the first embodiment, at the start of the operation of the mobile electronic device, the switch 17 is in the ON state, the DC-DC converter 18 is in the non-operating state, and the battery operation is performed. At the start, the DC-DC converter operation may be performed with the switch 17 in the OFF state and the DC-DC converter 18 in the operating state.

  In the first embodiment, the power supply circuit 2 has a plurality of REG and DC-DC converters, but is not limited to this mode. For example, the present invention can be applied even when the power supply circuit 2 includes only one REG or does not include a DC-DC converter. It suffices if it is possible to switch whether or not to connect the REG and the battery via a DC-DC converter before the REG input.

1 is a power supply control circuit according to a first embodiment of the present invention. It is a DC-DC converter of the 1st example concerning the present invention. General DC-DC converter efficiency It is a figure which shows the output current of the battery at the time of DC-DC converter use and the time of non-use. It is a figure which shows the output current of the battery at the time of DC-DC converter use and the time of non-use. It is a figure which shows the output current of the battery at the time of DC-DC converter use and the time of non-use. It is a figure which shows the output current of the battery at the time of DC-DC converter use and the time of non-use. It is a figure which shows operation | movement at the time of switching from battery operation to DC-DC converter operation | movement. It is a figure which shows operation | movement at the time of switching from DC-DC converter operation | movement to battery operation. It is a flowchart which shows operation | movement of the 1st Example which concerns on this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Main battery 2 Power supply circuit 3 Communication system device 4 Backflow prevention diode 5 Clock function device 6 Display part 7 Application device 8 Control system device 9 Backup memory 10 Resistance 11 Backup battery 12 Data input part 13 Power supply voltage detection means for power supply circuits 14 Load current detection means 15 Battery voltage detection means 16 Resistor 17 Switch 18 DC-DC converter 21 Regulator 22 Regulator 23 DC-DC converter 24 Regulator 25 Regulator 101 Resistor 102 Resistor 103 Reference voltage circuit 104 Oscillator 105 Error amplifier 106 Enable pin Buffer with input 107 P-channel FET
108 N-channel FET
109 coil 110 capacitor 111 protection circuit 112 MAXDUTY detection circuit 113 MINDUTY detection circuit 114 delay circuit 115 comparator 116 buffer with enable pin input 117 pull-up resistor 118 pull-down resistor 119 controller

Claims (3)

A power supply control circuit for a portable electronic device,
A power supply circuit including a plurality of regulators;
Battery,
A resistor provided between the battery and the power supply circuit;
A DC-DC converter provided in parallel with the resistor between the battery and the power supply circuit;
A switch for switching the output of the battery to either the resistor or the DC-DC converter;
Detecting means for detecting a load current flowing through the resistor,
When the output of the battery is connected to the resistor and the DC-DC converter is in a stopped state, when the output current of the battery continues a state equal to or higher than a first predetermined value for a first predetermined period, The detection means controls the switch to switch the output of the battery to the DC-DC converter and starts the operation of the DC-DC converter,
When the output of the battery is connected to the operating DC-DC converter, when the efficiency of the DC-DC converter continues below a second predetermined value for a second predetermined period, The DC-DC converter controls the switch to switch the output of the battery to the resistor and stops its operation.
A power supply control circuit. A power supply circuit including a plurality of regulators;
Battery,
A resistor provided between the battery and the power supply circuit;
A DC-DC converter provided in parallel with the resistor between the battery and the power supply circuit;
A switch for switching the output of the battery to either the resistor or the DC-DC converter;
Detecting means for detecting a load current flowing through the resistor;
A control method for a power supply control circuit of a portable electronic device comprising:
When the output of the battery is connected to the resistor and the DC-DC converter is in a stopped state, when the output current of the battery continues a state equal to or higher than a first predetermined value for a first predetermined period, The detection means controls the switch to switch the output of the battery to the DC-DC converter and starts the operation of the DC-DC converter,
When the output of the battery is connected to the operating DC-DC converter, when the efficiency of the DC-DC converter continues below a second predetermined value for a second predetermined period, The DC-DC converter controls the switch to switch the output of the battery to the resistor and stops its operation.
A control method for a power supply control circuit . A power supply circuit including a plurality of regulators;
Battery,
A resistor provided between the battery and the power supply circuit;
A DC-DC converter provided in parallel with the resistor between the battery and the power supply circuit;
A switch for switching the output of the battery to either the resistor or the DC-DC converter;
Detecting means for detecting a load current flowing through the resistor,
When the output of the battery is connected to the resistor and the DC-DC converter is in a stopped state, when the output current of the battery continues a state equal to or higher than a first predetermined value for a first predetermined period, The detection means controls the switch to switch the output of the battery to the DC-DC converter and starts the operation of the DC-DC converter,
When the output of the battery is connected to the operating DC-DC converter, when the efficiency of the DC-DC converter continues below a second predetermined value for a second predetermined period, The DC-DC converter controls the switch to switch the output of the battery to the resistor and stops its operation.
A portable electronic device comprising a power supply control circuit .

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