JP2006058292A - Electronic equipment with function for displaying battery residual usable time, and method of displaying battery residual usable time - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To calculate a battery residual usable time corresponding to a current using condition, and to display it on at least one out of two display means. <P>SOLUTION: A video camera 60 is provided with a microcomputer 63 provided with a communication circuit 65 attached with a battery pack 1 for outputting battery residual capacity information, charge/discharge current detection information and battery cell voltage detection information, and for receiving the each information from the battery pack 1, a calculation circuit 66 for calculating a battery residual amount in the present, based on the each received information from the battery pack 1, a display control circuit 67 for generating a display signal and a panel/EFV control circuit 68, a display device 64 having a liquid crystal panel 101 and a view finder (EFV) 102, and a panel opening and closing switch 79 for detecting the opening and closing of the liquid crystal panel 101. The panel/EFV control circuit 68 displays the battery residual usable time on at least one out of the liquid crystal panel 101 and the view finder 102, based on a detection result in the panel opening and closing switch 79. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to an electronic device with a battery remaining time display function for displaying a remaining usable time of a battery pack used as a power source of an electronic device such as a video camera, a portable telephone, or a personal computer, and a display of the remaining battery used time. It is about the method.

  Conventionally, a battery pack composed of a secondary battery such as a lithium ion battery, a NiCd battery, or a nickel metal hydride battery is well known.

  This known battery pack includes, for example, a microcomputer (so-called microcomputer) for calculating the remaining amount of the battery and communicating with an electronic device powered by the battery, a peripheral circuit of the microcomputer, and the microcomputer. In many cases, a battery cell state detection circuit or the like necessary for calculating the remaining battery level is incorporated.

  Patent documents 1 to 3 are known as conventional techniques.

JP-A-4-2978 JP-A-2-146936 JP-A-2-193533

  In addition, various electronic devices loaded with the battery pack as described above may have a display device that can display the remaining capacity of the battery. In a conventional electronic device having such a display device, for example, the remaining battery capacity is often calculated and displayed from the terminal voltage of the battery power supply (terminal voltage of the battery pack), for example.

  However, this method of calculating the remaining battery capacity from the terminal voltage of the battery power supply has the following problems.

  That is, first, when the discharge characteristics (battery terminal voltage-discharge voltage) differ depending on the type of battery cell, each battery cell must have a conversion formula from the terminal voltage to the remaining battery capacity. It is difficult to respond to

  Secondly, the battery remaining capacity display shows the ratio (ie,%) when the capacity when the battery is fully charged is 100, and indicates the remaining usable time of an electronic device such as a video camera. I can't know.

Thirdly, in the current situation, the display is only shown with accuracy at a rough level (for example, four levels) from the discharge characteristics.
Therefore, the present invention has been made in view of the above, and can cope with the types of battery cells and future battery cells, and can know the remaining usable time of the battery. It is an object of the present invention to provide an electronic device with a battery usage remaining time display function with high accuracy and a method for displaying the remaining battery usage time.

  In order to solve the above-described problems, the present invention is equipped with a battery pack that outputs battery remaining capacity information, charge / discharge current detection information, and battery cell voltage detection information. Receiving communication means, calculating power consumption based on the charge / discharge current detection information and battery cell voltage detection information received by the communication means, and a coefficient depending on the power consumption and the power consumption held by itself Calculation means for calculating the remaining battery usage time corresponding to the current usage status based on the remaining battery capacity information, first display means, second display means openable and closable with respect to the main body, and the second The first detection means for detecting the open / closed state of the display means, and the first display means and the second display means, depending on the detection result of the first detection means. Characterized in that it also comprises a selection control means for performing control so as to display the battery use remaining time from said computing means into one.

  Here, the image display apparatus further includes second detection means for detecting whether the second display means is reversed, and the selection control means performs control according to the detection results of the first and second detection means. Can be mentioned. Further, the image display device further includes third detection means for detecting the presence or absence of the user's eyepiece on the first display means, and the selection control means performs control according to the detection results of the first and third detection means. To do. The electronic device main body has a power save mode, and further includes fourth detection means for detecting whether or not the power save mode is set. The selection control means includes the first and fourth detection means. Control may be performed according to the detection result. Furthermore, the first display means is a viewfinder, and the second display means is a liquid crystal panel.

  Further, the present invention transmits the remaining battery capacity information of the battery cell built in the battery pack, the charge / discharge current detection information, and the battery cell voltage detection information from the battery pack to the electronic device side using the battery, On the electronic device side having the first display means and the second display means that can be opened and closed with respect to the main body, power consumption is calculated based on the transmitted charge / discharge current detection information and the battery cell voltage detection information. And a calculation step of calculating a remaining battery usage time corresponding to the current usage status based on the power consumption and a coefficient depending on the power consumption held by the user and the remaining battery capacity information, and opening and closing of the second display means A detection step of detecting a state by the first detection means, and a first detection means and a second display means according to a detection result of the first detection means. And having a selection control step of performing control so as to display the battery use remaining time from said calculating means to one even without.

  In the present invention, the remaining battery capacity information, the charge / discharge current detection information, and the battery cell voltage detection information from the battery pack are received, the current remaining battery level is calculated based on each received information, and the calculation result By displaying the remaining battery level based on the battery level, it is possible to display the remaining battery level even if it is a battery cell type or future battery cell, and the remaining battery life can be displayed. The display accuracy of the remaining amount can also be improved. Further, it is possible to perform control to detect the open / closed state of the second display means and to display the remaining battery usage time on at least one of the first display means and the second display means.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

  FIG. 1 shows, as an embodiment of the present invention, a battery pack 1 and a camera-integrated video tape recorder (hereinafter referred to as a video camera 60) as an example of an electronic device with a battery remaining amount display function in which the battery pack 1 is loaded. A configuration example of the system consisting of

  In FIG. 1, the video camera 60 is mounted with a battery pack 1 that outputs at least battery remaining capacity information, charge / discharge current detection information, and battery cell voltage detection information, and receives the information from the battery pack 1. Communication circuit 65, a calculation circuit 66 for calculating the current remaining battery level based on the information from the battery pack 1 received by the communication circuit 65, and a display based on the calculation result of the calculation circuit 66. A microcomputer (hereinafter referred to as a microcomputer) 63 having at least a display control circuit 67 for generating a signal, and a display signal corresponding to a calculation result in the calculation circuit 66 of the microcomputer 63 are supplied. And a display device 64 for displaying the quantity. The video camera 60 has a configuration for shooting and various configurations for recording / reproducing the shot video signal. In the example of FIG. 1, a microcomputer 63, a display device 64, and the like are provided as main components of the present invention. It is shown.

  On the other hand, the battery pack 1 includes a microcomputer 10, a battery cell 20, a charge / discharge current detection circuit 80 that detects a charge / discharge current, a voltage detection circuit 18 that detects a voltage between terminals of the battery cell 20, and a battery cell. And a temperature sensor 19 for detecting the temperature of 20 at least. The microcomputer 10 includes a communication circuit 72 for communicating with the video camera 60 and an information generation circuit 71 for generating information indicating the state of the battery pack 1. In the information generation circuit 71 of this configuration example, temperature detection information is generated as information indicating the state of the battery pack 1 together with the remaining battery capacity information, charge / discharge current detection information, and battery cell voltage detection information. Information such as the remaining battery capacity from the information generation circuit 71 is sent to the video camera 60 via the communication circuit 72. The detailed configuration of the battery pack 1 will be described later.

  The positive terminal of the battery pack 1 is connected to the positive terminal of the video camera 60, the negative terminal of the battery pack 1 is connected to the negative terminal of the video camera 60, and the video camera is connected from the battery pack 1 via these positive terminal and negative terminal. Power is supplied to 60. In addition, communication of information between the battery pack 1 and the video camera 60 is performed via the control terminal (C). The communication using the control terminal (C) between the microcomputer 10 of the battery pack 1 and the video camera 60 is performed via the buffer amplifiers 11 and 12 on the battery pack 1 side, and the buffer amplifier 61, on the video camera 60 side. 62.

  The video camera 60 receives the information indicating the state of the battery pack 1 transmitted from the battery pack 1 via the control terminal (information indicating the remaining battery capacity, which will be described later in this configuration example), and the microcomputer 63 Into.

  The information received via the communication circuit 65 of the microcomputer 63 is sent to the calculation circuit 66, where the remaining time that the video camera 60 can use (in other words, the battery can be used) from the information such as the remaining battery capacity. Various calculations are performed to obtain the remaining time). Note that the remaining time that can be used by the video camera 60 is, for example, the remaining recording time when a captured video signal is recorded on a recording medium such as a tape or the remaining reproduction time when it is played back, that is, the video during recording or playback. The operating time of the camera 60 can be mentioned.

  The display control circuit 67 is based on the remaining battery time information obtained by the calculation circuit 66, for example, so-called on-screen display (OSD) display or the remaining battery power displayed on the display means of the display device 64 of the video camera 60 main body. Generate a time indication signal.

  The display device 64 includes, for example, a viewfinder (EVF) 102, a liquid crystal panel 101, etc. as the display means, and the battery remaining supplied from the display control circuit 67 on the display screen of these display means. Display based on the time display signal. As a specific example of the remaining battery time displayed on the display means, for example, a display example as shown in FIG. 2 can be given. That is, in this FIG. 2, the time display 122 by the number of the remaining battery time (40 minutes in the example of FIG. 2, for example 40 minutes in the case of English) and the level of the battery fully charged state is 100%. An example is shown in which a level display 121 for visualizing the current remaining battery time ratio intuitively and easily is displayed on the display screen 120 of the display means. In the level display 121, the level can be changed, for example, in four steps, or more, or steplessly according to the remaining battery time. A more detailed configuration and operation of the display device 64 will be described later.

  As described above, in the system according to the present embodiment, the remaining battery time is displayed to the user of the video camera 60 by displaying the remaining battery time on the display screen of the display unit of the display device 64 of the video camera 60. In other words, it is possible to notify the operable time of the video camera 60). In this embodiment, the remaining battery time display method can be displayed intuitively and easily by using the remaining battery level display method based on the level display 121. The remaining battery level display accuracy is improved by using the remaining battery level display method based on the minute unit display. For this reason, the user of the video camera 60 can easily manage shooting time, playback time, and the like.

  In the present embodiment system, the remaining battery time is calculated as described above based on the battery characteristics described below.

  For example, when the battery is discharged at a constant power consumption, the integrated amount of discharge current with respect to the discharge time is approximately proportional to time as shown in the graph of FIG. Here, when the lowest voltage (battery end voltage) that can be used by the video camera 60 is determined, the point of the battery end voltage in FIG. 3 is between the start of discharge and complete discharge (the state where there is no energy in the battery cell 20). Exists.

  Further, the remaining amount of the accumulated discharge current until the complete discharge with respect to the discharge time is as shown in the graph of FIG. In the graph of FIG. 4, when the end of the battery is taken as the origin and the coordinate axis is drawn, the vertical axis represents the remaining discharge current accumulated until the end of the battery, and the horizontal axis represents the remaining time until the end of the battery. Therefore, if the accumulated discharge current remaining until the end of the battery is known, the remaining battery time can be uniquely determined.

  Furthermore, when the power consumption of the video camera 60 is large, for example, the discharge current is also large, so the discharge characteristics in this case are as shown in the graph in FIG. From the graph of FIG. 5, it can be seen that the ratio of the remaining time with respect to the same accumulated discharge current is smaller than in the case where the power consumption is small as shown in FIG. When the power consumption is large, the discharge current integrated remaining amount from when the battery is terminated to complete discharge also changes due to the influence of the internal impedance of the battery cell 20.

  This can be expressed by the following equation (1).

R = Qd × f (W)
= (Q−g (W)) × f (W) (1)
In this equation (1), R represents the time until the battery is terminated (remaining time), Qd is the accumulated discharge current until the battery is terminated, W is the power consumption of the set (video camera 60), and f ( W) indicates a coefficient (depending on electric power), Q indicates an accumulated discharge current remaining amount, and g (W) indicates a remaining amount at the time of battery termination (dependent on electric power).

  In this equation (1), f (W) is a coefficient for converting the discharge current integrated remaining amount into the remaining time, and depends on the power consumption. Further, g (W) is the accumulated remaining amount of discharge current from the end of the battery to complete discharge, and depends on the power consumption.

  Further, considering the temperature change of the battery cell 20, the above formula (1) is a calculation formula as shown in the formula (2).

R = Qd × f (W) × h ₁ (T)
= (Q−g (W) × h ₂ (T)) × f (W) × h ₁ (T) (2)
In this equation (2), T represents the temperature of the battery cell, h ₁ (T) and h ₂ (T) represent the temperature dependence coefficient of the battery cell, and Q, h ₁ (T), h ₂ (T ) Is held by the battery pack 1, and f (W) and g (W) are held by the video camera 60.

From this equation (2), it can be seen that f (W) and h (W) are respectively multiplied by temperature dependent coefficients h ₁ (T) and h ₂ (T).

Further, the temperature dependency coefficients h ₁ (T) and h ₂ (T) take different values depending on the type of the battery cell. Thereby, it becomes possible to absorb the difference in mathematical formulas due to the difference in battery cells.

Furthermore, in the above formulas (1) and (2), the power consumption W varies depending on the usage status of the video camera 60. For example, the time R ₁ until the battery is terminated when the power consumption is W ₁ , and the time R ₂ until the battery is terminated when the power consumption is W ₂ (W ₁ ≠ W ₂ ) are expressed by Equations (3) and ( 4), Equation (5), and Equation (6). Expressions (3) and (4) correspond to Expression (1), and Expressions (5) and (6) correspond to Expression (2).

R ₁ = (Q−g (W ₁ )) × f (W ₁ ) (3)
R ₂ = (Q−g (W ₂ )) × f (W ₂ ) (4)
R ₁ = (Q−g (W ₁ ) × h ₂ (T)) × f (W ₁ ) × h ₁ (T) (5)
_{R 2 = (Q-g (} W 2) × h 2 (T)) × f (W 2) × h 1 (T) (6)
Even when the power consumption W of the video camera 60 changes as in these formulas (3) to (6), the remaining battery level is calculated according to the power consumption change in the system according to the present embodiment. It is possible to display the remaining battery time corresponding to changes in the usage status of the camera 60.

  In other words, in the system of this embodiment, the remaining battery time is calculated using only the power consumption regardless of the type (contents) of the usage state of the video camera 60, and the video is calculated for the calculation of the remaining battery time. It turns out that the special parameter which shows the use condition of the camera 60 is not required. This indicates that the battery remaining time calculation method is a versatile method that does not depend on the type of the video camera 60. A specific example in which the power consumption changes depending on the usage status of the video camera 60 as described above will be described later.

  Next, the flowchart of FIG. 6 shows the procedure of data reception and remaining amount calculation when the microcomputer 63 of the video camera 60 calculates the remaining battery time based on information such as the remaining battery capacity from the battery pack 1. It explains using.

  In FIG. 6, it is determined whether or not the power is turned on in step ST31. When the power is not turned on, the determination in step ST31 is repeated, and when the power is turned on, the process proceeds to step ST32.

  In step ST32, it is determined whether or not communication with the battery pack 1 is possible. If communication is not possible, the process ends. If communication is possible, the process proceeds to step ST33.

In step ST33, each data of the current I, the voltage V, the discharge current integrated remaining amount Q, and the temperature dependence coefficients h ₁ (T) and h ₂ (T) is received from the battery pack 1 as data necessary for the remaining amount calculation. .

  In the next step ST34, the power consumption W is calculated. In step ST35, f (W) and g (W) are calculated. In step ST36, the above equations (2), (5), (6) (temperature change) Is not calculated, the remaining time R until the end of the battery is calculated using Equation (1), Equation (3), Equation (4)).

  Thereafter, in step ST36, it is determined whether or not the remaining amount can be displayed. If the remaining amount cannot be displayed, the process returns to step ST32. If the remaining amount can be displayed, the remaining amount is displayed on the display device 64 in step ST38. I do. That is, as the remaining amount display, as described above, the usable time of the battery pack 1 (usable time of the video camera 60) and the remaining capacity of the battery pack 1 (for example, the remaining capacity up to the battery end point). indicate.

  As described above, according to the system of FIG. 1, the coefficient for correcting the difference in the discharge characteristics of the battery cell 20 of the battery pack 1 is used for calculating the remaining amount, whereby the remaining amount calculation algorithm is applied to the battery cell. The algorithm can be unified without depending. In addition, since the remaining battery capacity is displayed in units of time, the user can manage the shooting time. Furthermore, as the remaining battery time display, for example, by using not only the level display 121 in four stages but also the time display 122 in units of hours, it is possible to improve the accuracy of the remaining battery display. .

  Next, a specific configuration example of the battery pack 1 is shown in FIG.

In FIG. 7, the positive electrode of the battery cell 20 in the ₊ positive terminal of the battery pack 1 TM, also the negative pole of the battery cell 20 via the current detection resistor R7 the negative terminal of the battery pack 1 TM _- is connected to the Yes.

  The microcomputer 10 built in the battery pack 1 is supplied with power from a microcomputer power supply 16 including a series regulator and a reset circuit, and the microcomputer 10 operates with the power supplied from the microcomputer power supply 16. The charging current detection input terminal DI1 of the microcomputer 10 is connected to the output terminal of the operational amplifier 13 provided for charging current detection, and the discharge current detection input terminal DI2 is connected to the output terminal of the operational amplifier 14 provided for discharge current detection. It is connected. The interrupt input terminal of the microcomputer 10 is connected to the output terminal of the 2-input NAND gate 15 in which the output terminals of the operational amplifiers 13 and 14 are connected to the two input terminals. Further, the output terminal of the 2-input NAND gate 15 is For example, it is connected to a power supply terminal via a pull-up resistor R8. The temperature detection input terminal of the microcomputer 10 is connected to the output terminal of the temperature sensor 19 that detects the ambient temperature of the battery cell 20, and the voltage detection input terminal is the output terminal of the voltage detection circuit 18 that detects the terminal voltage of the battery cell 20. The cycle data input terminal is an output terminal of a nonvolatile memory 17 to be described later, the ground terminal is a negative electrode of the battery cell 20, an input terminal (SIN terminal) for communication with the video camera 60, and an output terminal (SOUT terminal). ) Is connected to the buffer amplifiers 11 and 12. Note that the terminals to which analog inputs such as the charging current detection input terminal DI1, the discharge current detection input terminal DI2, the temperature detection input terminal, and the voltage detection input terminal are made are all A / D input ports. An A / D converter for digitally converting these analog inputs is built in.

  The voltage detection circuit 18 is a voltage dividing resistor made up of resistors R9 and R10, and detects the voltage across the terminals of the battery cell 20 using this voltage dividing resistor. The voltage detection value from the voltage detection circuit 18 is supplied to the voltage detection input terminal of the microcomputer 10. Therefore, the microcomputer 10 can know the voltage between the terminals of the battery cell 20 based on the voltage detection value from the voltage detection circuit 18 supplied to the voltage detection input terminal.

  The temperature sensor 19 is composed of, for example, a temperature detection thermistor, and is disposed near or in contact with the battery cell 20. The temperature detection value of the temperature sensor 19 is supplied to the temperature detection input terminal of the microcomputer 10. It is like that. Therefore, the microcomputer 10 can know the temperature of the battery cell 20 based on the temperature detection value supplied to the temperature detection input terminal.

  Next, the non-inverting input terminal of the operational amplifier 13 is connected to the negative electrode of the battery cell 20 via a resistor R3 and a current / voltage detecting resistor R7, and the inverting input terminal is a negative feedback resistor R2 for setting an amplification factor and a resistor R1. Connected with. Therefore, a voltage value obtained by amplifying the current value flowing in the battery pack 1 (current value flowing during charging) from the output terminal of the operational amplifier 13 according to the ratio of the resistance values of the resistors R1 and R2 (R2 / R1). Will be output. On the other hand, the non-inverting input terminal of the operational amplifier 14 is connected to the negative electrode of the battery cell 20 via a resistor R6 and a current / voltage detecting resistor R7, and the inverting input terminal is connected to a negative feedback resistor R5 and a resistor R4. Therefore, the voltage value obtained by amplifying the current value flowing in the battery pack 1 (current value flowing during discharge) from the output terminal of the operational amplifier 14 in accordance with the resistance value ratio (R5 / R4) of the resistors R4 and R5. Will be output.

  The transistor switch Tr1 is made of, for example, a field effect transistor, the gate is connected to the switching control output terminal SW1 of the microcomputer 10, and the resistor R1 is connected between the drain and the source. Therefore, when the signal level from the switching control output terminal SW1 of the microcomputer 10 becomes, for example, a high (H) level, the transistor switch Tr1 is turned on, and thereby the resistance value of the resistor R1 is approximately 0 (transistor switch Tr1). And the amplification factor (amplifier gain) of the operational amplifier 13 in which the amplification factor is set according to the ratio of the resistance values of the resistors R1 and R2 (R2 / R1) becomes large. On the other hand, when the signal level from the switching control output terminal SW1 of the microcomputer 10 becomes, for example, a low (L) level, the transistor switch Tr1 is turned off, whereby the amplification factor of the operational amplifier 13 is the resistance of the resistors R1 and R2. The amplification factor according to the value ratio (R2 / R1), that is, a smaller amplification factor (amplifier gain) than when the transistor switch Tr1 is ON. Similarly, the transistor switch Tr2 is also composed of, for example, a field effect transistor, the gate is connected to the switching control output terminal SW2 of the microcomputer 10, and the resistor R4 is connected between the drain and the source. Therefore, when the signal level from the switching control output terminal SW2 of the microcomputer 10 becomes, for example, a high (H) level, the transistor switch Tr2 is turned on, and thereby the resistance value of the resistor R4 is approximately 0 (the transistor switch Tr2 Only the internal resistance), and the amplification factor (amplifier gain) of the operational amplifier 14 becomes large. On the other hand, when the signal level from the switching control output terminal SW2 of the microcomputer 10 becomes, for example, a low (L) level, the transistor switch Tr2 is turned OFF, thereby reducing the amplification factor (amplifier gain) of the operational amplifier 14.

  Here, the microcomputer 10 always monitors the levels of the charge current detection input terminal DI1 and the discharge current detection input terminal DI2 in the normal operation mode (Run time), and the levels of these terminals DI1 and DI2 are constant levels. When this is the case, the signal levels of the switching control output terminals SW1 and SW2 are both set to a low level. As a result, both the transistor switches Tr1 and Tr2 are turned OFF, and the amplifier gains of the operational amplifiers 13 and 14 are reduced. Therefore, the microcomputer 10 in the normal operation mode (Run time) uses the output value from the operational amplifiers 13 and 14 with the amplifier gain reduced, and the current value flowing in the battery pack 1 (current value flowing during charging or It is possible to measure the current value that flows during discharge. Therefore, for example, if the value of the current flowing during charging / discharging is known, the charge / discharge current integrated value can be calculated.

  On the other hand, when the charge / discharge current value flowing in the battery pack 1 becomes a minute current value equal to or less than the predetermined value during the normal operation mode (run time), the amplifier gain is reduced. The output values from the operational amplifiers 13 and 14 are also reduced. That is, the levels of the charging current detection input terminal DI1 and the discharge current detection input terminal DI2 are also reduced. At this time, if the level of the terminals DI1 and DI2 becomes equal to or lower than a certain level and the state continues for a certain time, the microcomputer 10 determines that there is no load and shifts to the power saving mode (sleep mode). . In this power saving mode, the power consumption is smaller than that in the normal operation mode, so that the circuit can save energy.

  When the microcomputer 10 enters the power saving mode (sleep mode), both the signal levels of the switching control output terminals SW1 and SW2 are set to the high level. As a result, the transistor switches Tr1 and Tr2 are both turned ON, and the amplifier gains of the operational amplifiers 13 and 14 are increased. Therefore, the microcomputer 10 in the power saving mode (sleep mode) uses the output value from the operational amplifiers 13 and 14 in which the amplifier gain is increased, and the minute current value flowing in the battery pack 1 (the minute current flowing during charging). Value or a minute current value that flows during discharge) can be measured.

  Here, when the charging / discharging current value flowing in the battery pack 1 becomes a current value equal to or higher than the predetermined value in the power saving mode, the operational amplifiers 13 and 14 having the amplifier gain reduced are used. The output value of both increases. That is, the levels of the two input terminals of the 2-input NAND gate 15 are both high, and therefore the output of the 2-input NAND gate 15 is low. Thus, when the output level of the two-input NAND gate 15 supplied to the interrupt input terminal becomes a low level, the microcomputer 10 cancels the power saving mode and shifts to the normal operation mode.

  As described above, according to the configuration of FIG. 7, the power consumption is smaller in the power saving mode than in the normal operation mode, so that the circuit can save energy. Further, according to the configuration of FIG. 7, the microcomputer 10 can switch the amplifier gains of the operational amplifiers 13 and 14 by controlling the transistors Tr1 and Tr2 on / off with the switching control outputs SW1 and SW2. Detection of a minute current value in the power saving mode and measurement of a current value in the normal operation mode can be combined with the above configuration.

  Next, the non-volatile memory 17 is composed of, for example, an EEP-ROM that stores at least data (cycle data) of the maximum number of charge / discharge cycles that can be used by the battery cell 20. The microcomputer 10 measures the number of charge / discharge cycles of the battery cell 20 based on the data (cycle data) of the maximum number of charge / discharge cycles from the nonvolatile memory 17 and the detected voltage from the voltage detection circuit 18, and When the number of charge / discharge cycles of the cell 20 reaches the maximum number of charge / discharge cycles, a flag to that effect is transmitted to the video camera 60.

  When the video camera 60 receives the flag transmitted from the battery pack 1, the video camera 60 displays on the display device 64, for example, to prompt the user to replace the battery pack 1. As an example of this display, for example, a display such as “This battery is out of date, please replace it” is performed. Thereby, the user or the like can easily know the life of the battery pack 1.

  Next, as described above, when the power consumption changes depending on the usage status of the video camera 60, the following usage status can be cited as an example.

  As shown in FIGS. 8 to 10, the video camera 60 of this embodiment includes a viewfinder 102 formed of a small cathode ray tube and a liquid crystal panel (liquid crystal display) 101 with a backlight as the display device 64. It will be. The viewfinder 102 is the same as that provided in a normal video camera, and displays a photographed image or a video reproduced from a video tape. The liquid crystal panel 101 is also provided for the purpose of displaying a photographed image, a reproduced image, etc., basically like the viewfinder 102 described above.

  However, the liquid crystal panel 101 provided in the video camera 60 of the present embodiment is housed in the video camera 60 main body as shown in FIG. 8, and the arrow 111 in the figure from the video camera 60 main body as shown in FIG. For example, a state that can be opened and closed up to 90 degrees toward the front, and a state that can rotate up to 210 degrees forward in the direction shown by an arrow 110 in the figure can be taken. The state in which the liquid crystal panel 101 is rotated 180 degrees in the forward direction from the opened state in FIG. 9 is the state shown in FIG. 10, and hereinafter, changing the liquid crystal panel 101 to the state in FIG. I will call it. Further, the state in which the liquid crystal panel 101 is housed in the main body of the video camera 60 as shown in FIG. 8 is called a panel closed state, and the state in which the liquid crystal panel 101 is opened in the direction shown by the arrow 111 in FIG. We will call it a state. In the video camera 60 of the present embodiment, the liquid crystal panel 101 can be opened and closed as described above, and can be rotated forward, so that, for example, an image being shot can be viewed without looking at the viewfinder 102. In addition, various ways of using the video camera 60 can be realized. Note that the specific configuration of the opening / closing and rotating mechanism of the liquid crystal panel 101 is not directly related to the present invention, and thus detailed description thereof will be omitted.

  The video camera 60 of this embodiment includes the viewfinder 102 and the liquid crystal panel 101 as the display device 64 as described above. Depending on the usage status of the video camera 60, for example, the viewfinder 102 and the liquid crystal panel 101 may be used. There are cases where both are used simultaneously, only one is used, or both are not used. That is, in the video camera 60 of the present embodiment, the power consumption changes because the viewfinder 102 and the liquid crystal panel 101 are not used depending on the use situation.

  In the system of the present embodiment, even if the power consumption changes depending on the usage state of the video camera 60 as described above, the remaining battery level is calculated according to the change in the power consumption as described above. The battery remaining time display corresponding to the change of the situation is possible.

  Note that there are various patterns as shown in FIG. 11 as usage patterns of the viewfinder 102 and the liquid crystal panel 101 in the video camera 60 of the present embodiment. That is, the video camera 60 of the present embodiment has a power save mode for saving power consumption, and whether the viewfinder 102 and the liquid crystal panel 101 are used / not used (ON / OFF of the power save mode). ON / OFF) is controlled as shown in FIG.

  In FIG. 11, when the power save mode is OFF, the liquid crystal panel 101 is turned on and the viewfinder (EVF) 102 is turned off and the liquid crystal panel 101 is closed when the liquid crystal panel 101 is opened. In the state, the liquid crystal panel 101 is turned off and the viewfinder 102 is turned on. In the panel inversion state where the liquid crystal panel 101 is rotated, both the liquid crystal panel 101 and the viewfinder 102 are turned off. That is, when the power save mode is OFF, the user of the video camera 60 thinks that the user of the video camera 60 does not look at the viewfinder 102 when the panel is open, and only the liquid crystal panel 101 is turned ON, and the liquid crystal panel 101 is viewed when the panel is closed. Since it is not possible, only the viewfinder 102 is turned on. In the panel inversion state, it is assumed that there is another person who looks at the liquid crystal panel 101 in addition to the user who looks at the viewfinder 102, and both are turned on.

  On the other hand, in FIG. 11, when the power save mode is ON, when the panel is open, the liquid crystal panel 101 is turned ON and the viewfinder 102 is turned OFF. When the panel is closed and the user is in contact with the viewfinder 102 When the liquid crystal panel 101 is turned off and the viewfinder 102 is turned on, and both the liquid crystal panel 101 and the viewfinder 102 are closed when the panel is closed and the user is not in contact with the viewfinder 102 Is turned off, and the liquid crystal panel 101 and the viewfinder 102 are both turned on when the user is in the panel inverted state and the viewfinder 102 is in the eyepiece. Sometimes (eye separation) the liquid crystal panel 1 To ON the only one. That is, when the power save mode is ON, in order to save power, the user of the video camera 60 thinks that the user of the video camera 60 does not look at the viewfinder 102 in the panel open state, and only the liquid crystal panel 101 is turned on. In addition, since the liquid crystal panel 101 cannot be seen in the eyepiece state, only the viewfinder 102 is turned on, and the liquid crystal panel 101 cannot be seen in the closed state and the eyepiece state, and the viewfinder 102 is not seen. Considering that both are turned off, in the panel inverted state and in the eyepiece state, in addition to the user viewing the viewfinder 102, it is considered that there is another person looking at the liquid crystal panel 101. In the eye state, the viewfinder 102 is not seen and the liquid crystal panel 101 Is turned ON only the liquid crystal panel 101 believes have been observed.

  The display control of the viewfinder 102 and the liquid crystal panel 101 according to the usage pattern of the video camera 60 as shown in FIG. 11 is performed according to the flowcharts as shown in FIGS.

  Here, the video camera 60 of this embodiment includes a panel opening / closing switch 79 for detecting whether the liquid crystal panel 101 is in the panel open state or the panel closed state, as shown in FIG. A panel inversion switch 70 for detecting whether the liquid crystal panel 101 is in the panel inversion state and an eye sensor 78 for detecting whether a user is looking at the viewfinder 102 are provided. ing.

  Therefore, in the flowchart of FIG. 12, first, in step ST1, it is determined whether the state of the panel open / close switch 79 is ON (panel open state) / OFF (panel closed state). If it is determined in step ST1 that the panel open / close switch 79 is ON, the process proceeds to step ST2, and a panel open flag is set as information indicating that the panel open / close switch 79 is ON in step ST2. Set the value to “1”. If it is determined in step ST1 that the panel open / close switch 79 is OFF, the process proceeds to step ST3, and the panel open flag is used as information indicating that the panel open / close switch 79 is OFF in step ST3. Set the value of to "0".

  In the next step ST4, it is determined whether the state of the panel inversion switch 70 is ON (panel inversion state) / OFF (panel non-inversion state). If it is determined in step ST4 that the panel reverse switch 70 is ON, the process proceeds to step ST5. In step ST5, a panel reverse flag is set as information indicating that the panel reverse switch 70 is ON. Set the value to “1”. If it is determined in step ST4 that the panel inversion switch 70 is OFF, the process proceeds to step ST6, and information indicating that the panel inversion switch 70 is OFF in step ST6 is a panel inversion flag. Set the value of to "0".

  In the next step ST7, it is determined whether the eye sensor 78 is ON (eyepiece state) / OFF (eye separation state). The eye sensor 78 is an infrared sensor provided inside the viewfinder 102, for example, and is turned on when the user is in contact with the viewfinder 102, and is turned off when the user is away. If it is determined in step ST7 that the eye sensor 78 is ON, the process proceeds to step ST8, and the value of the eye flag is used as information indicating that the eye sensor 78 is ON in step ST8. Set to “1”. If it is determined in step ST7 that the eyepiece sensor 78 is OFF, the process proceeds to step ST9. In step ST9, the value of the eyepiece flag is used as information indicating that the eyepiece sensor 78 is OFF. Set to “0”.

  As described above, when the values of the panel open flag, the panel inversion flag, and the eyepiece flag are set, they are sent to the panel / EVF control unit 68 provided in the microcomputer 63 of the video camera 60 of FIG.

  The panel / EVF control unit 68 controls each unit as shown in the flowchart of FIG. 13 based on the flags.

  In the flowchart of FIG. 13, first, in step ST11, it is determined whether or not the power save mode is set to the ON / OFF mode. In the system of this embodiment, the mode to be set as the power save mode is selected from the operation menu items by the mode input unit 69 as a soft key of the video camera 60, for example, as shown in FIG. The flag is set to “1” when the power save mode is ON and “0” when the power save mode is OFF (hereinafter referred to as a power save flag). Therefore, in step ST11, it is determined whether the value of the power save flag is “1” or “0”. In the determination of step ST11, when the value of the power save flag is “1”, the process proceeds to step ST12, and when it is “0”, the process proceeds to step ST21.

  In step ST21 that proceeds when the power save flag is “0”, that is, when the power save mode is OFF, whether the value of the panel open flag is “1” or “0”. Determine. If it is determined in step ST21 that the value of the panel open flag is “0”, the process proceeds to step ST24. In step ST24, the liquid crystal panel 102 is turned off and the viewfinder is turned off as shown in FIG. (EVF) 101 is turned ON. On the other hand, when it is determined in step ST21 that the value of the panel open flag is “1”, the process proceeds to step ST22.

  In step ST22, it is determined whether the value of the panel inversion flag is “1” or “0”. If it is determined in step ST22 that the value of the panel inversion flag is "0", the process proceeds to step ST25. In step ST25, the liquid crystal panel 102 is turned on and the viewfinder is turned on as shown in FIG. 101 is turned off. On the other hand, when it is determined in step ST22 that the value of the panel open flag is “1”, the process proceeds to step ST23. In step ST23, both the liquid crystal panel 102 and the viewfinder 101 are turned on as shown in FIG. To do.

  On the other hand, when it is determined in step ST11 that the power save flag is “1”, that is, in step ST12 which is advanced when the power save mode is ON, the value of the panel open flag is “ It is determined whether the value is “1” or “0”. If it is determined in step ST12 that the value of the panel open flag is “0”, the process proceeds to step ST16. If it is determined to be “1”, the process proceeds to step ST13.

  In step ST16 that proceeds when it is determined in step ST12 that the value of the panel open flag is “0”, it is determined whether the value of the eyepiece flag is “1” or “0”. To do. If it is determined in step ST16 that the value of the eyepiece flag is “0”, the process proceeds to step ST18. In step ST18, both the liquid crystal panel 102 and the viewfinder 101 are turned off as shown in FIG. . On the other hand, if it is determined in step ST16 that the value of the eyepiece flag is “1”, the process proceeds to step ST17. In step ST17, the liquid crystal panel 102 is turned off and the viewfinder 101 is turned off as shown in FIG. Turn it on.

  Further, in step ST13 which proceeds when it is determined in step ST12 that the value of the panel open flag is “1”, the value of the panel inversion flag takes either “1” or “0”. It is determined whether or not. If it is determined in step ST13 that the value of the panel inversion flag is “0”, the process proceeds to step ST19. In step ST19, the liquid crystal panel 102 is turned on and the viewfinder 101 is turned on as shown in FIG. Turn off. On the other hand, when it is determined in step ST13 that the value of the panel inversion flag is “1”, the process proceeds to step ST14.

  In this step ST14, it is determined whether the value of the eyepiece flag is “1” or “0”. If it is determined in step ST14 that the value of the eyepiece flag is “0”, the process proceeds to step ST20. In step ST20, the liquid crystal panel 102 is turned on and the viewfinder 101 is turned off as shown in FIG. To. On the other hand, when it is determined in step ST14 that the value of the eyepiece flag is “1”, the process proceeds to step ST15. In step ST15, both the liquid crystal panel 102 and the viewfinder 101 are turned on as shown in FIG. To do.

  As shown in FIGS. 11 to 13 described above, the ON / OFF control of the liquid crystal panel 101 and the viewfinder 102 is specifically realized by the following configuration.

  Returning to FIG. 1, the video camera 60 includes an EVF driving circuit 73 that drives the viewfinder 102 based on the display signal from the display control circuit 67, and the display signal from the display control circuit 67. An LCD drive circuit 74 for driving the liquid crystal panel 101, an EVF drive circuit 73 connected to the plus terminal and the minus terminal, and a DC / DC converter 77 for supplying power to the LCD drive circuit 74 are provided. As a configuration for performing ON / OFF control of the panel 101 and the viewfinder 102, a changeover switch 75 provided between the DC / DC converter 77 and the EVF drive circuit 73, the DC / DC converter 77, and the LCD drive are provided. The change-over switch 75 provided between the circuit 74 and FIGS. Also provided with said panel · EVF controller 68 that performs ON / OFF control of the changeover switch 75, 76 according to the flowchart of.

  That is, in the video camera 60 of the present embodiment, the panel / EVF control unit 68 performs ON / OFF control of the changeover switches 75 and 76 as shown in FIGS. The above-described ON / OFF control 102 is realized.

  As described above, the power consumption of the video camera 60 is changed by the ON / OFF control of the liquid crystal panel 101 and the viewfinder 102.

  In the above description, a video camera is taken as an example of an electronic device to which a battery pack is attached. However, the electronic device referred to in the present invention is not limited to the video camera, and various electronic devices such as a portable telephone and a personal computer. Any device may be used as long as it has a display device capable of displaying the remaining battery time and the like.

  In the electronic apparatus with a battery remaining amount display function according to the embodiment of the present invention described above, a battery pack that outputs remaining battery capacity information, charge / discharge current detection information, and battery cell voltage detection information is mounted. A communication means for receiving the information from the battery, a calculation means for calculating a current remaining battery level based on the information from the battery pack received by the communication means, and the battery remaining from the calculation means. Display means for displaying the amount, and in the battery remaining amount display method according to the embodiment of the present invention, the remaining battery capacity information of the battery cell built in the battery pack and the charge / discharge current detection information And the battery cell voltage detection information are transmitted from the battery pack to the electronic device using the battery, and the electronic device transmits the transmitted buffer. Based on the remaining battery capacity information, the charge / discharge current detection information, and the battery cell voltage detection information, the current battery remaining amount is obtained by calculation, and the calculated battery remaining amount is displayed on the display means. . That is, the remaining battery capacity information, the charge / discharge current detection information, and the battery cell voltage detection information from the battery pack are received, the current remaining battery level is calculated based on the received information, and the calculated result is Displays the remaining battery power.

  Here, the information of the correction coefficient at the time of battery remaining amount calculation is output from the battery pack, and the calculation means may calculate the remaining battery amount corrected by the correction coefficient. The remaining battery capacity information of the battery pack is discharge current integrated remaining capacity information, and the remaining battery capacity calculated by the computing means is the remaining battery usage time. The display means may display a number indicating the remaining battery time and / or a ratio to the remaining battery time in a fully charged state as the remaining battery power. The display means includes a liquid crystal panel and / or a viewfinder, and includes a selection control means for selecting a use mode in which one or both of the liquid crystal panel and the viewfinder are used.

  Therefore, according to the embodiment of the present invention, the battery remaining capacity information, the charge / discharge current detection information, and the battery cell voltage detection information are transmitted from the battery pack to the electronic device. Since the remaining amount is calculated and displayed, it is possible to display the remaining amount of battery even if it is a type of battery cell or a future battery cell, and also the remaining usable time of the battery can be displayed. Furthermore, it is possible to improve the display accuracy of the remaining battery level.

  It should be noted that the present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the scope of the present invention.

It is a block circuit diagram which shows one structural example of the system with which embodiment of this invention is applied. It is a figure which shows an example of the battery remaining time displayed on a display screen. It is a figure which shows the relationship between discharge current integration amount of a battery, and time. It is a figure which shows the relationship between discharge current integration remaining amount of a battery, and time. It is a figure which shows the relationship between the discharge current integration remaining amount of a battery at the time of high power consumption, and time. It is a flowchart which shows the algorithm of residual amount calculation. It is a circuit diagram which shows the specific structural example of a battery pack. It is an external view of the video camera with the liquid crystal panel closed. It is an external view of the video camera with the liquid crystal panel opened. It is an external view of the video camera in a state where the liquid crystal panel is inverted. It is a figure used for description of ON / OFF control of a liquid crystal panel and a viewfinder. It is a production | generation flowchart of a flag. It is a flowchart of ON / OFF control of a liquid crystal panel and a viewfinder.

Explanation of symbols

  1 battery pack, 10 microcomputer, 18 voltage detection circuit 19 temperature sensor, 20 battery cell, 60 video camera, 63 microcomputer, 64 display device, 65 communication circuit, 66 calculation circuit, 67 display control circuit, 68 panel / EVF control unit, 69 mode input unit, 70 panel reverse switch, 71 information generation circuit, 72 communication circuit, 73 EVF drive circuit, 74 LCD drive circuit, 75, 76 changeover switch, 79 panel open / close switch, 78 eye sensor, 80 charge / discharge current detection circuit

Claims (10)

A battery pack that outputs battery remaining capacity information, charge / discharge current detection information, and battery cell voltage detection information is attached,
Communication means for receiving the information from the battery pack;
The power consumption is calculated based on the charging / discharging current detection information and the battery cell voltage detection information received by the communication means, and the coefficient depending on the power consumption and the power consumption held by itself and the remaining battery capacity information Computing means for calculating the remaining battery usage time corresponding to the current usage status,
First display means;
A second display means that can be opened and closed with respect to the main body;
First detecting means for detecting an open / closed state of the second display means;
Selection control for performing control so that at least one of the first display means and the second display means displays the remaining battery usage time from the calculation means according to the detection result of the first detection means. An electronic device with a remaining battery usage time display function. A second detecting means for detecting the presence or absence of inversion of the second display means;
The electronic device with battery remaining time display function according to claim 1, wherein the selection control means performs control according to the detection results of the first and second detection means. Further comprising third detection means for detecting the presence or absence of the user's eyepiece on the first display means,
2. The electronic device with battery remaining time display function according to claim 1, wherein the selection control means performs control according to detection results of the first and third detection means. The electronic device body has a power save mode,
A fourth detecting means for detecting whether or not the power save mode is set;
2. The electronic device with battery remaining time display function according to claim 1, wherein the selection control means performs control according to detection results of the first and fourth detection means.   2. The electronic device with battery remaining time display function according to claim 1, wherein the first display means is a viewfinder, and the second display means is a liquid crystal panel. The remaining battery capacity information of the battery cells built in the battery pack, charge / discharge current detection information, and battery cell voltage detection information are transmitted from the battery pack to the electronic device using the battery,
On the electronic device side having the first display means and the second display means that can be opened and closed with respect to the main body, power consumption is calculated based on the transmitted charge / discharge current detection information and the battery cell voltage detection information. And a calculation step of calculating a remaining battery usage time corresponding to the current usage status based on the power consumption and a coefficient depending on the power consumption held by itself and the remaining battery capacity information,
A detection step of detecting the open / closed state of the second display means by the first detection means;
Selection control for performing control so that at least one of the first display means and the second display means displays the remaining battery usage time from the calculation means according to the detection result of the first detection means. And displaying the remaining battery usage time. A second detecting means for detecting the presence or absence of inversion of the second display means;
7. The method for displaying remaining battery usage time according to claim 6, wherein in the selection control step, control is performed in accordance with detection results of the first and second detection means. Further comprising third detection means for detecting the presence or absence of the user's eyepiece on the first display means,
7. The battery remaining time display method according to claim 6, wherein in the selection control step, control is performed according to detection results of the first and third detection means. The electronic device body has a power save mode,
A fourth detecting means for detecting whether or not the power save mode is set;
7. The battery remaining time display method according to claim 6, wherein in the selection control step, control is performed according to detection results of the first and fourth detection means.   7. The display method of the remaining battery usage time according to claim 6, wherein the first display means is a viewfinder, and the second display means is a liquid crystal panel.

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